Home > CWE List > VIEW SLICE: CWE-844: Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011) (4.16) |
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CWE VIEW: Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)
CWE entries in this view (graph) are fully or partially eliminated by following the guidance presented in the book "The CERT Oracle Secure Coding Standard for Java" published in 2011. This view is considered obsolete as a newer version of the coding standard is available.
The following graph shows the tree-like relationships between
weaknesses that exist at different levels of abstraction. At the highest level, categories
and pillars exist to group weaknesses. Categories (which are not technically weaknesses) are
special CWE entries used to group weaknesses that share a common characteristic. Pillars are
weaknesses that are described in the most abstract fashion. Below these top-level entries
are weaknesses are varying levels of abstraction. Classes are still very abstract, typically
independent of any specific language or technology. Base level weaknesses are used to
present a more specific type of weakness. A variant is a weakness that is described at a
very low level of detail, typically limited to a specific language or technology. A chain is
a set of weaknesses that must be reachable consecutively in order to produce an exploitable
vulnerability. While a composite is a set of weaknesses that must all be present
simultaneously in order to produce an exploitable vulnerability.
Show Details:
844 - Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)
- (845)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS))
Weaknesses in this category are related to rules in the Input Validation and Data Sanitization (IDS) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Improper Encoding or Escaping of Output
- (116)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
116
(Improper Encoding or Escaping of Output)
The product prepares a structured message for communication with another component, but encoding or escaping of the data is either missing or done incorrectly. As a result, the intended structure of the message is not preserved.
Output Sanitization
Output Validation
Output Encoding
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Use of Externally-Controlled Format String
- (134)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
134
(Use of Externally-Controlled Format String)
The product uses a function that accepts a format string as an argument, but the format string originates from an external source.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Improper Neutralization of Line Delimiters
- (144)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
144
(Improper Neutralization of Line Delimiters)
The product receives input from an upstream component, but it does not neutralize or incorrectly neutralizes special elements that could be interpreted as line delimiters when they are sent to a downstream component.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Improper Neutralization of Escape, Meta, or Control Sequences
- (150)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
150
(Improper Neutralization of Escape, Meta, or Control Sequences)
The product receives input from an upstream component, but it does not neutralize or incorrectly neutralizes special elements that could be interpreted as escape, meta, or control character sequences when they are sent to a downstream component.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Incorrect Behavior Order: Validate Before Canonicalize
- (180)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
180
(Incorrect Behavior Order: Validate Before Canonicalize)
The product validates input before it is canonicalized, which prevents the product from detecting data that becomes invalid after the canonicalization step.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Collapse of Data into Unsafe Value
- (182)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
182
(Collapse of Data into Unsafe Value)
The product filters data in a way that causes it to be reduced or "collapsed" into an unsafe value that violates an expected security property.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Authentication Bypass by Alternate Name
- (289)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
289
(Authentication Bypass by Alternate Name)
The product performs authentication based on the name of a resource being accessed, or the name of the actor performing the access, but it does not properly check all possible names for that resource or actor.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Improper Handling of Highly Compressed Data (Data Amplification)
- (409)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
409
(Improper Handling of Highly Compressed Data (Data Amplification))
The product does not handle or incorrectly handles a compressed input with a very high compression ratio that produces a large output.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Permissive Regular Expression
- (625)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
625
(Permissive Regular Expression)
The product uses a regular expression that does not sufficiently restrict the set of allowed values.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Use of Non-Canonical URL Paths for Authorization Decisions
- (647)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
647
(Use of Non-Canonical URL Paths for Authorization Decisions)
The product defines policy namespaces and makes authorization decisions based on the assumption that a URL is canonical. This can allow a non-canonical URL to bypass the authorization.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Improper Neutralization of Special Elements used in an OS Command ('OS Command Injection')
- (78)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
78
(Improper Neutralization of Special Elements used in an OS Command ('OS Command Injection'))
The product constructs all or part of an OS command using externally-influenced input from an upstream component, but it does not neutralize or incorrectly neutralizes special elements that could modify the intended OS command when it is sent to a downstream component.
Shell injection
Shell metacharacters
OS Command Injection
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Inappropriate Encoding for Output Context
- (838)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
845
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)) >
838
(Inappropriate Encoding for Output Context)
The product uses or specifies an encoding when generating output to a downstream component, but the specified encoding is not the same as the encoding that is expected by the downstream component.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 3 - Declarations and Initialization (DCL)
- (846)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
846
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 3 - Declarations and Initialization (DCL))
Weaknesses in this category are related to rules in the Declarations and Initialization (DCL) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Improper Initialization
- (665)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
846
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 3 - Declarations and Initialization (DCL)) >
665
(Improper Initialization)
The product does not initialize or incorrectly initializes a resource, which might leave the resource in an unexpected state when it is accessed or used.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 4 - Expressions (EXP)
- (847)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
847
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 4 - Expressions (EXP))
Weaknesses in this category are related to rules in the Expressions (EXP) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Unchecked Return Value
- (252)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
847
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 4 - Expressions (EXP)) >
252
(Unchecked Return Value)
The product does not check the return value from a method or function, which can prevent it from detecting unexpected states and conditions.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Signal Handler Use of a Non-reentrant Function
- (479)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
847
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 4 - Expressions (EXP)) >
479
(Signal Handler Use of a Non-reentrant Function)
The product defines a signal handler that calls a non-reentrant function.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Comparison of Object References Instead of Object Contents
- (595)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
847
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 4 - Expressions (EXP)) >
595
(Comparison of Object References Instead of Object Contents)
The product compares object references instead of the contents of the objects themselves, preventing it from detecting equivalent objects.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Use of Wrong Operator in String Comparison
- (597)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
847
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 4 - Expressions (EXP)) >
597
(Use of Wrong Operator in String Comparison)
The product uses the wrong operator when comparing a string, such as using "==" when the .equals() method should be used instead.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 5 - Numeric Types and Operations (NUM)
- (848)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
848
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 5 - Numeric Types and Operations (NUM))
Weaknesses in this category are related to rules in the Numeric Types and Operations (NUM) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Numeric Truncation Error
- (197)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
848
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 5 - Numeric Types and Operations (NUM)) >
197
(Numeric Truncation Error)
Truncation errors occur when a primitive is cast to a primitive of a smaller size and data is lost in the conversion.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Divide By Zero
- (369)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
848
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 5 - Numeric Types and Operations (NUM)) >
369
(Divide By Zero)
The product divides a value by zero.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Incorrect Conversion between Numeric Types
- (681)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
848
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 5 - Numeric Types and Operations (NUM)) >
681
(Incorrect Conversion between Numeric Types)
When converting from one data type to another, such as long to integer, data can be omitted or translated in a way that produces unexpected values. If the resulting values are used in a sensitive context, then dangerous behaviors may occur.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)
- (849)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ))
Weaknesses in this category are related to rules in the Object Orientation (OBJ) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Passing Mutable Objects to an Untrusted Method
- (374)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
374
(Passing Mutable Objects to an Untrusted Method)
The product sends non-cloned mutable data as an argument to a method or function.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Returning a Mutable Object to an Untrusted Caller
- (375)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
375
(Returning a Mutable Object to an Untrusted Caller)
Sending non-cloned mutable data as a return value may result in that data being altered or deleted by the calling function.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Comparison of Classes by Name
- (486)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
486
(Comparison of Classes by Name)
The product compares classes by name, which can cause it to use the wrong class when multiple classes can have the same name.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Public cloneable() Method Without Final ('Object Hijack')
- (491)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
491
(Public cloneable() Method Without Final ('Object Hijack'))
A class has a cloneable() method that is not declared final, which allows an object to be created without calling the constructor. This can cause the object to be in an unexpected state.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Use of Inner Class Containing Sensitive Data
- (492)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
492
(Use of Inner Class Containing Sensitive Data)
Inner classes are translated into classes that are accessible at package scope and may expose code that the programmer intended to keep private to attackers.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Critical Public Variable Without Final Modifier
- (493)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
493
(Critical Public Variable Without Final Modifier)
The product has a critical public variable that is not final, which allows the variable to be modified to contain unexpected values.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Cloneable Class Containing Sensitive Information
- (498)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
498
(Cloneable Class Containing Sensitive Information)
The code contains a class with sensitive data, but the class is cloneable. The data can then be accessed by cloning the class.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Public Static Field Not Marked Final
- (500)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
500
(Public Static Field Not Marked Final)
An object contains a public static field that is not marked final, which might allow it to be modified in unexpected ways.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Array Declared Public, Final, and Static
- (582)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
582
(Array Declared Public, Final, and Static)
The product declares an array public, final, and static, which is not sufficient to prevent the array's contents from being modified.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Critical Data Element Declared Public
- (766)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
849
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)) >
766
(Critical Data Element Declared Public)
The product declares a critical variable, field, or member to be public when intended security policy requires it to be private.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)
- (850)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
850
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET))
Weaknesses in this category are related to rules in the Methods (MET) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Reliance on Package-level Scope
- (487)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
850
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)) >
487
(Reliance on Package-level Scope)
Java packages are not inherently closed; therefore, relying on them for code security is not a good practice.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
finalize() Method Without super.finalize()
- (568)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
850
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)) >
568
(finalize() Method Without super.finalize())
The product contains a finalize() method that does not call super.finalize().
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Improper Following of Specification by Caller
- (573)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
850
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)) >
573
(Improper Following of Specification by Caller)
The product does not follow or incorrectly follows the specifications as required by the implementation language, environment, framework, protocol, or platform.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Object Model Violation: Just One of Equals and Hashcode Defined
- (581)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
850
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)) >
581
(Object Model Violation: Just One of Equals and Hashcode Defined)
The product does not maintain equal hashcodes for equal objects.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
finalize() Method Declared Public
- (583)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
850
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)) >
583
(finalize() Method Declared Public)
The product violates secure coding principles for mobile code by declaring a finalize() method public.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Explicit Call to Finalize()
- (586)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
850
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)) >
586
(Explicit Call to Finalize())
The product makes an explicit call to the finalize() method from outside the finalizer.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Call to Non-ubiquitous API
- (589)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
850
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)) >
589
(Call to Non-ubiquitous API)
The product uses an API function that does not exist on all versions of the target platform. This could cause portability problems or inconsistencies that allow denial of service or other consequences.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Reachable Assertion
- (617)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
850
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)) >
617
(Reachable Assertion)
The product contains an assert() or similar statement that can be triggered by an attacker, which leads to an application exit or other behavior that is more severe than necessary.
assertion failure
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)
- (851)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR))
Weaknesses in this category are related to rules in the Exceptional Behavior (ERR) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Generation of Error Message Containing Sensitive Information
- (209)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
209
(Generation of Error Message Containing Sensitive Information)
The product generates an error message that includes sensitive information about its environment, users, or associated data.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Improper Handling of Missing Values
- (230)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
230
(Improper Handling of Missing Values)
The product does not handle or incorrectly handles when a parameter, field, or argument name is specified, but the associated value is missing, i.e. it is empty, blank, or null.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Improper Handling of Undefined Values
- (232)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
232
(Improper Handling of Undefined Values)
The product does not handle or incorrectly handles when a value is not defined or supported for the associated parameter, field, or argument name.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Uncaught Exception
- (248)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
248
(Uncaught Exception)
An exception is thrown from a function, but it is not caught.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
J2EE Bad Practices: Use of System.exit()
- (382)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
382
(J2EE Bad Practices: Use of System.exit())
A J2EE application uses System.exit(), which also shuts down its container.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Detection of Error Condition Without Action
- (390)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
390
(Detection of Error Condition Without Action)
The product detects a specific error, but takes no actions to handle the error.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Use of NullPointerException Catch to Detect NULL Pointer Dereference
- (395)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
395
(Use of NullPointerException Catch to Detect NULL Pointer Dereference)
Catching NullPointerException should not be used as an alternative to programmatic checks to prevent dereferencing a null pointer.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Declaration of Throws for Generic Exception
- (397)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
397
(Declaration of Throws for Generic Exception)
Throwing overly broad exceptions promotes complex error handling code that is more likely to contain security vulnerabilities.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Improper Cleanup on Thrown Exception
- (460)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
460
(Improper Cleanup on Thrown Exception)
The product does not clean up its state or incorrectly cleans up its state when an exception is thrown, leading to unexpected state or control flow.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Exposure of Sensitive System Information to an Unauthorized Control Sphere
- (497)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
497
(Exposure of Sensitive System Information to an Unauthorized Control Sphere)
The product does not properly prevent sensitive system-level information from being accessed by unauthorized actors who do not have the same level of access to the underlying system as the product does.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Return Inside Finally Block
- (584)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
584
(Return Inside Finally Block)
The code has a return statement inside a finally block, which will cause any thrown exception in the try block to be discarded.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Uncaught Exception in Servlet
- (600)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
600
(Uncaught Exception in Servlet )
The Servlet does not catch all exceptions, which may reveal sensitive debugging information.
Missing Catch Block
Chain - a Compound Element that is a sequence of two or more separate weaknesses that can be closely linked together within software. One weakness, X, can directly create the conditions that are necessary to cause another weakness, Y, to enter a vulnerable condition. When this happens, CWE refers to X as "primary" to Y, and Y is "resultant" from X. Chains can involve more than two weaknesses, and in some cases, they might have a tree-like structure.
Unchecked Return Value to NULL Pointer Dereference
- (690)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
690
(Unchecked Return Value to NULL Pointer Dereference)
The product does not check for an error after calling a function that can return with a NULL pointer if the function fails, which leads to a resultant NULL pointer dereference.
Pillar - a weakness that is the most abstract type of weakness and represents a theme for all class/base/variant weaknesses related to it. A Pillar is different from a Category as a Pillar is still technically a type of weakness that describes a mistake, while a Category represents a common characteristic used to group related things.
Improper Check or Handling of Exceptional Conditions
- (703)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
703
(Improper Check or Handling of Exceptional Conditions)
The product does not properly anticipate or handle exceptional conditions that rarely occur during normal operation of the product.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Incorrect Control Flow Scoping
- (705)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
851
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)) >
705
(Incorrect Control Flow Scoping)
The product does not properly return control flow to the proper location after it has completed a task or detected an unusual condition.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 9 - Visibility and Atomicity (VNA)
- (852)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
852
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 9 - Visibility and Atomicity (VNA))
Weaknesses in this category are related to rules in the Visibility and Atomicity (VNA) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Concurrent Execution using Shared Resource with Improper Synchronization ('Race Condition')
- (362)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
852
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 9 - Visibility and Atomicity (VNA)) >
362
(Concurrent Execution using Shared Resource with Improper Synchronization ('Race Condition'))
The product contains a concurrent code sequence that requires temporary, exclusive access to a shared resource, but a timing window exists in which the shared resource can be modified by another code sequence operating concurrently.
Race Condition
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Race Condition within a Thread
- (366)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
852
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 9 - Visibility and Atomicity (VNA)) >
366
(Race Condition within a Thread)
If two threads of execution use a resource simultaneously, there exists the possibility that resources may be used while invalid, in turn making the state of execution undefined.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Improper Resource Locking
- (413)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
852
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 9 - Visibility and Atomicity (VNA)) >
413
(Improper Resource Locking)
The product does not lock or does not correctly lock a resource when the product must have exclusive access to the resource.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Unsynchronized Access to Shared Data in a Multithreaded Context
- (567)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
852
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 9 - Visibility and Atomicity (VNA)) >
567
(Unsynchronized Access to Shared Data in a Multithreaded Context)
The product does not properly synchronize shared data, such as static variables across threads, which can lead to undefined behavior and unpredictable data changes.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Improper Synchronization
- (662)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
852
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 9 - Visibility and Atomicity (VNA)) >
662
(Improper Synchronization)
The product utilizes multiple threads or processes to allow temporary access to a shared resource that can only be exclusive to one process at a time, but it does not properly synchronize these actions, which might cause simultaneous accesses of this resource by multiple threads or processes.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Improper Locking
- (667)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
852
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 9 - Visibility and Atomicity (VNA)) >
667
(Improper Locking)
The product does not properly acquire or release a lock on a resource, leading to unexpected resource state changes and behaviors.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 10 - Locking (LCK)
- (853)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
853
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 10 - Locking (LCK))
Weaknesses in this category are related to rules in the Locking (LCK) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Unrestricted Externally Accessible Lock
- (412)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
853
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 10 - Locking (LCK)) >
412
(Unrestricted Externally Accessible Lock)
The product properly checks for the existence of a lock, but the lock can be externally controlled or influenced by an actor that is outside of the intended sphere of control.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Improper Resource Locking
- (413)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
853
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 10 - Locking (LCK)) >
413
(Improper Resource Locking)
The product does not lock or does not correctly lock a resource when the product must have exclusive access to the resource.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Double-Checked Locking
- (609)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
853
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 10 - Locking (LCK)) >
609
(Double-Checked Locking)
The product uses double-checked locking to access a resource without the overhead of explicit synchronization, but the locking is insufficient.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Improper Locking
- (667)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
853
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 10 - Locking (LCK)) >
667
(Improper Locking)
The product does not properly acquire or release a lock on a resource, leading to unexpected resource state changes and behaviors.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Missing Synchronization
- (820)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
853
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 10 - Locking (LCK)) >
820
(Missing Synchronization)
The product utilizes a shared resource in a concurrent manner but does not attempt to synchronize access to the resource.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Deadlock
- (833)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
853
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 10 - Locking (LCK)) >
833
(Deadlock)
The product contains multiple threads or executable segments that are waiting for each other to release a necessary lock, resulting in deadlock.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 11 - Thread APIs (THI)
- (854)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
854
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 11 - Thread APIs (THI))
Weaknesses in this category are related to rules in the Thread APIs (THI) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Call to Thread run() instead of start()
- (572)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
854
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 11 - Thread APIs (THI)) >
572
(Call to Thread run() instead of start())
The product calls a thread's run() method instead of calling start(), which causes the code to run in the thread of the caller instead of the callee.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Incorrect Control Flow Scoping
- (705)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
854
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 11 - Thread APIs (THI)) >
705
(Incorrect Control Flow Scoping)
The product does not properly return control flow to the proper location after it has completed a task or detected an unusual condition.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 12 - Thread Pools (TPS)
- (855)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
855
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 12 - Thread Pools (TPS))
Weaknesses in this category are related to rules in the Thread Pools (TPS) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Missing Report of Error Condition
- (392)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
855
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 12 - Thread Pools (TPS)) >
392
(Missing Report of Error Condition)
The product encounters an error but does not provide a status code or return value to indicate that an error has occurred.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Asymmetric Resource Consumption (Amplification)
- (405)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
855
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 12 - Thread Pools (TPS)) >
405
(Asymmetric Resource Consumption (Amplification))
The product does not properly control situations in which an adversary can cause the product to consume or produce excessive resources without requiring the adversary to invest equivalent work or otherwise prove authorization, i.e., the adversary's influence is "asymmetric."
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Insufficient Resource Pool
- (410)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
855
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 12 - Thread Pools (TPS)) >
410
(Insufficient Resource Pool)
The product's resource pool is not large enough to handle peak demand, which allows an attacker to prevent others from accessing the resource by using a (relatively) large number of requests for resources.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 13 - Thread-Safety Miscellaneous (TSM)
- (856)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
856
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 13 - Thread-Safety Miscellaneous (TSM))
Weaknesses in this category are related to rules in the Thread-Safety Miscellaneous (TSM) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)
- (857)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO))
Weaknesses in this category are related to rules in the Input Output (FIO) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Incorrect Calculation of Multi-Byte String Length
- (135)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
135
(Incorrect Calculation of Multi-Byte String Length)
The product does not correctly calculate the length of strings that can contain wide or multi-byte characters.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Use of Incorrect Byte Ordering
- (198)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
198
(Use of Incorrect Byte Ordering)
The product receives input from an upstream component, but it does not account for byte ordering (e.g. big-endian and little-endian) when processing the input, causing an incorrect number or value to be used.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Incorrect Default Permissions
- (276)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
276
(Incorrect Default Permissions)
During installation, installed file permissions are set to allow anyone to modify those files.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Incorrect Execution-Assigned Permissions
- (279)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
279
(Incorrect Execution-Assigned Permissions)
While it is executing, the product sets the permissions of an object in a way that violates the intended permissions that have been specified by the user.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Exposure of Private Personal Information to an Unauthorized Actor
- (359)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
359
(Exposure of Private Personal Information to an Unauthorized Actor)
The product does not properly prevent a person's private, personal information from being accessed by actors who either (1) are not explicitly authorized to access the information or (2) do not have the implicit consent of the person about whom the information is collected.
Privacy violation
Privacy leak
Privacy leakage
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Insecure Temporary File
- (377)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
377
(Insecure Temporary File)
Creating and using insecure temporary files can leave application and system data vulnerable to attack.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Improper Resource Shutdown or Release
- (404)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
404
(Improper Resource Shutdown or Release)
The product does not release or incorrectly releases a resource before it is made available for re-use.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Asymmetric Resource Consumption (Amplification)
- (405)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
405
(Asymmetric Resource Consumption (Amplification))
The product does not properly control situations in which an adversary can cause the product to consume or produce excessive resources without requiring the adversary to invest equivalent work or otherwise prove authorization, i.e., the adversary's influence is "asymmetric."
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Incomplete Cleanup
- (459)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
459
(Incomplete Cleanup)
The product does not properly "clean up" and remove temporary or supporting resources after they have been used.
Insufficient Cleanup
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Insertion of Sensitive Information into Log File
- (532)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
532
(Insertion of Sensitive Information into Log File)
The product writes sensitive information to a log file.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Improper Handling of Windows Device Names
- (67)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
67
(Improper Handling of Windows Device Names)
The product constructs pathnames from user input, but it does not handle or incorrectly handles a pathname containing a Windows device name such as AUX or CON. This typically leads to denial of service or an information exposure when the application attempts to process the pathname as a regular file.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Incorrect Permission Assignment for Critical Resource
- (732)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
732
(Incorrect Permission Assignment for Critical Resource)
The product specifies permissions for a security-critical resource in a way that allows that resource to be read or modified by unintended actors.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Allocation of Resources Without Limits or Throttling
- (770)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
857
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)) >
770
(Allocation of Resources Without Limits or Throttling)
The product allocates a reusable resource or group of resources on behalf of an actor without imposing any restrictions on the size or number of resources that can be allocated, in violation of the intended security policy for that actor.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER)
- (858)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
858
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER))
Weaknesses in this category are related to rules in the Serialization (SER) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Execution with Unnecessary Privileges
- (250)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
858
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER)) >
250
(Execution with Unnecessary Privileges)
The product performs an operation at a privilege level that is higher than the minimum level required, which creates new weaknesses or amplifies the consequences of other weaknesses.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Cleartext Transmission of Sensitive Information
- (319)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
858
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER)) >
319
(Cleartext Transmission of Sensitive Information)
The product transmits sensitive or security-critical data in cleartext in a communication channel that can be sniffed by unauthorized actors.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Uncontrolled Resource Consumption
- (400)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
858
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER)) >
400
(Uncontrolled Resource Consumption)
The product does not properly control the allocation and maintenance of a limited resource, thereby enabling an actor to influence the amount of resources consumed, eventually leading to the exhaustion of available resources.
Resource Exhaustion
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Serializable Class Containing Sensitive Data
- (499)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
858
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER)) >
499
(Serializable Class Containing Sensitive Data)
The code contains a class with sensitive data, but the class does not explicitly deny serialization. The data can be accessed by serializing the class through another class.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Deserialization of Untrusted Data
- (502)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
858
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER)) >
502
(Deserialization of Untrusted Data)
The product deserializes untrusted data without sufficiently ensuring that the resulting data will be valid.
Marshaling, Unmarshaling
Pickling, Unpickling
PHP Object Injection
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Call to Non-ubiquitous API
- (589)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
858
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER)) >
589
(Call to Non-ubiquitous API)
The product uses an API function that does not exist on all versions of the target platform. This could cause portability problems or inconsistencies that allow denial of service or other consequences.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Allocation of Resources Without Limits or Throttling
- (770)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
858
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER)) >
770
(Allocation of Resources Without Limits or Throttling)
The product allocates a reusable resource or group of resources on behalf of an actor without imposing any restrictions on the size or number of resources that can be allocated, in violation of the intended security policy for that actor.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)
- (859)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC))
Weaknesses in this category are related to rules in the Platform Security (SEC) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Direct Use of Unsafe JNI
- (111)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
111
(Direct Use of Unsafe JNI)
When a Java application uses the Java Native Interface (JNI) to call code written in another programming language, it can expose the application to weaknesses in that code, even if those weaknesses cannot occur in Java.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Incorrect Privilege Assignment
- (266)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
266
(Incorrect Privilege Assignment)
A product incorrectly assigns a privilege to a particular actor, creating an unintended sphere of control for that actor.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Least Privilege Violation
- (272)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
272
(Least Privilege Violation)
The elevated privilege level required to perform operations such as chroot() should be dropped immediately after the operation is performed.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Channel Accessible by Non-Endpoint
- (300)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
300
(Channel Accessible by Non-Endpoint)
The product does not adequately verify the identity of actors at both ends of a communication channel, or does not adequately ensure the integrity of the channel, in a way that allows the channel to be accessed or influenced by an actor that is not an endpoint.
Adversary-in-the-Middle / AITM
Man-in-the-Middle / MITM
Person-in-the-Middle / PITM
Monkey-in-the-Middle
Monster-in-the-Middle
Manipulator-in-the-Middle
On-path attack
Interception attack
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Authentication Bypass by Assumed-Immutable Data
- (302)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
302
(Authentication Bypass by Assumed-Immutable Data)
The authentication scheme or implementation uses key data elements that are assumed to be immutable, but can be controlled or modified by the attacker.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Cleartext Transmission of Sensitive Information
- (319)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
319
(Cleartext Transmission of Sensitive Information)
The product transmits sensitive or security-critical data in cleartext in a communication channel that can be sniffed by unauthorized actors.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Improper Verification of Cryptographic Signature
- (347)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
347
(Improper Verification of Cryptographic Signature)
The product does not verify, or incorrectly verifies, the cryptographic signature for data.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Use of Externally-Controlled Input to Select Classes or Code ('Unsafe Reflection')
- (470)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
470
(Use of Externally-Controlled Input to Select Classes or Code ('Unsafe Reflection'))
The product uses external input with reflection to select which classes or code to use, but it does not sufficiently prevent the input from selecting improper classes or code.
Reflection Injection
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Download of Code Without Integrity Check
- (494)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
494
(Download of Code Without Integrity Check)
The product downloads source code or an executable from a remote location and executes the code without sufficiently verifying the origin and integrity of the code.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Incorrect Permission Assignment for Critical Resource
- (732)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
732
(Incorrect Permission Assignment for Critical Resource)
The product specifies permissions for a security-critical resource in a way that allows that resource to be read or modified by unintended actors.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Reliance on Untrusted Inputs in a Security Decision
- (807)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
859
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)) >
807
(Reliance on Untrusted Inputs in a Security Decision)
The product uses a protection mechanism that relies on the existence or values of an input, but the input can be modified by an untrusted actor in a way that bypasses the protection mechanism.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 17 - Runtime Environment (ENV)
- (860)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
860
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 17 - Runtime Environment (ENV))
Weaknesses in this category are related to rules in the Runtime Environment (ENV) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Acceptance of Extraneous Untrusted Data With Trusted Data
- (349)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
860
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 17 - Runtime Environment (ENV)) >
349
(Acceptance of Extraneous Untrusted Data With Trusted Data)
The product, when processing trusted data, accepts any untrusted data that is also included with the trusted data, treating the untrusted data as if it were trusted.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Incorrect Permission Assignment for Critical Resource
- (732)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
860
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 17 - Runtime Environment (ENV)) >
732
(Incorrect Permission Assignment for Critical Resource)
The product specifies permissions for a security-critical resource in a way that allows that resource to be read or modified by unintended actors.
Category - a CWE entry that contains a set of other entries that share a common characteristic.
The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)
- (861)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC))
Weaknesses in this category are related to rules in the Miscellaneous (MSC) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Use of Hard-coded Password
- (259)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
259
(Use of Hard-coded Password)
The product contains a hard-coded password, which it uses for its own inbound authentication or for outbound communication to external components.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Missing Encryption of Sensitive Data
- (311)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
311
(Missing Encryption of Sensitive Data)
The product does not encrypt sensitive or critical information before storage or transmission.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Use of Insufficiently Random Values
- (330)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
330
(Use of Insufficiently Random Values)
The product uses insufficiently random numbers or values in a security context that depends on unpredictable numbers.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Insufficient Entropy in PRNG
- (332)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
332
(Insufficient Entropy in PRNG)
The lack of entropy available for, or used by, a Pseudo-Random Number Generator (PRNG) can be a stability and security threat.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Improper Handling of Insufficient Entropy in TRNG
- (333)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
333
(Improper Handling of Insufficient Entropy in TRNG)
True random number generators (TRNG) generally have a limited source of entropy and therefore can fail or block.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Same Seed in Pseudo-Random Number Generator (PRNG)
- (336)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
336
(Same Seed in Pseudo-Random Number Generator (PRNG))
A Pseudo-Random Number Generator (PRNG) uses the same seed each time the product is initialized.
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Predictable Seed in Pseudo-Random Number Generator (PRNG)
- (337)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
337
(Predictable Seed in Pseudo-Random Number Generator (PRNG))
A Pseudo-Random Number Generator (PRNG) is initialized from a predictable seed, such as the process ID or system time.
Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource.
Uncontrolled Resource Consumption
- (400)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
400
(Uncontrolled Resource Consumption)
The product does not properly control the allocation and maintenance of a limited resource, thereby enabling an actor to influence the amount of resources consumed, eventually leading to the exhaustion of available resources.
Resource Exhaustion
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Missing Release of Memory after Effective Lifetime
- (401)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
401
(Missing Release of Memory after Effective Lifetime)
The product does not sufficiently track and release allocated memory after it has been used, which slowly consumes remaining memory.
Memory Leak
Variant - a weakness that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource.
Use of Singleton Pattern Without Synchronization in a Multithreaded Context
- (543)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
543
(Use of Singleton Pattern Without Synchronization in a Multithreaded Context)
The product uses the singleton pattern when creating a resource within a multithreaded environment.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Allocation of Resources Without Limits or Throttling
- (770)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
770
(Allocation of Resources Without Limits or Throttling)
The product allocates a reusable resource or group of resources on behalf of an actor without imposing any restrictions on the size or number of resources that can be allocated, in violation of the intended security policy for that actor.
Base - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource.
Use of Hard-coded Credentials
- (798)
844
(Weaknesses Addressed by The CERT Oracle Secure Coding Standard for Java (2011)) >
861
(The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)) >
798
(Use of Hard-coded Credentials)
The product contains hard-coded credentials, such as a password or cryptographic key.
Relationship
The relationships in this view were determined based on specific statements within the rules from the standard. Not all rules have direct relationships to individual weaknesses, although they likely have chaining relationships in specific circumstances.
View ComponentsA | B | C | D | E | F | G | H | I | J | K | L | M | N | O | P | Q | R | S | T | U | V | W | X | Y | Z
CWE-349: Acceptance of Extraneous Untrusted Data With Trusted Data
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Edit Custom FilterThe product, when processing trusted data, accepts any untrusted data that is also included with the trusted data, treating the untrusted data as if it were trusted.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence)
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-770: Allocation of Resources Without Limits or Throttling
View customized information:
For users who are interested in more notional aspects of a weakness. Example: educators, technical writers, and project/program managers.
For users who are concerned with the practical application and details about the nature of a weakness and how to prevent it from happening. Example: tool developers, security researchers, pen-testers, incident response analysts.
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Edit Custom FilterThe product allocates a reusable resource or group of resources on behalf of an actor without imposing any restrictions on the size or number of resources that can be allocated, in violation of the intended security policy for that actor.
Code frequently has to work with limited resources, so programmers must be careful to ensure that resources are not consumed too quickly, or too easily. Without use of quotas, resource limits, or other protection mechanisms, it can be easy for an attacker to consume many resources by rapidly making many requests, or causing larger resources to be used than is needed. When too many resources are allocated, or if a single resource is too large, then it can prevent the code from working correctly, possibly leading to a denial of service. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Often Prevalent) Example 1 This code allocates a socket and forks each time it receives a new connection. (bad code)
Example Language: C
sock=socket(AF_INET, SOCK_STREAM, 0);
while (1) { newsock=accept(sock, ...); }printf("A connection has been accepted\n"); pid = fork(); The program does not track how many connections have been made, and it does not limit the number of connections. Because forking is a relatively expensive operation, an attacker would be able to cause the system to run out of CPU, processes, or memory by making a large number of connections. Alternatively, an attacker could consume all available connections, preventing others from accessing the system remotely. Example 2 In the following example a server socket connection is used to accept a request to store data on the local file system using a specified filename. The method openSocketConnection establishes a server socket to accept requests from a client. When a client establishes a connection to this service the getNextMessage method is first used to retrieve from the socket the name of the file to store the data, the openFileToWrite method will validate the filename and open a file to write to on the local file system. The getNextMessage is then used within a while loop to continuously read data from the socket and output the data to the file until there is no longer any data from the socket. (bad code)
Example Language: C
int writeDataFromSocketToFile(char *host, int port)
{ char filename[FILENAME_SIZE]; char buffer[BUFFER_SIZE]; int socket = openSocketConnection(host, port); if (socket < 0) { printf("Unable to open socket connection"); }return(FAIL); if (getNextMessage(socket, filename, FILENAME_SIZE) > 0) { if (openFileToWrite(filename) > 0) {
while (getNextMessage(socket, buffer, BUFFER_SIZE) > 0){
if (!(writeToFile(buffer) > 0)) }break;
closeFile(); closeSocket(socket); This example creates a situation where data can be dumped to a file on the local file system without any limits on the size of the file. This could potentially exhaust file or disk resources and/or limit other clients' ability to access the service. Example 3 In the following example, the processMessage method receives a two dimensional character array containing the message to be processed. The two-dimensional character array contains the length of the message in the first character array and the message body in the second character array. The getMessageLength method retrieves the integer value of the length from the first character array. After validating that the message length is greater than zero, the body character array pointer points to the start of the second character array of the two-dimensional character array and memory is allocated for the new body character array. (bad code)
Example Language: C
/* process message accepts a two-dimensional character array of the form [length][body] containing the message to be processed */ int processMessage(char **message) { char *body;
int length = getMessageLength(message[0]); if (length > 0) { body = &message[1][0]; }processMessageBody(body); return(SUCCESS); else { printf("Unable to process message; invalid message length"); }return(FAIL); This example creates a situation where the length of the body character array can be very large and will consume excessive memory, exhausting system resources. This can be avoided by restricting the length of the second character array with a maximum length check Also, consider changing the type from 'int' to 'unsigned int', so that you are always guaranteed that the number is positive. This might not be possible if the protocol specifically requires allowing negative values, or if you cannot control the return value from getMessageLength(), but it could simplify the check to ensure the input is positive, and eliminate other errors such as signed-to-unsigned conversion errors (CWE-195) that may occur elsewhere in the code. (good code)
Example Language: C
unsigned int length = getMessageLength(message[0]);
if ((length > 0) && (length < MAX_LENGTH)) {...} Example 4 In the following example, a server object creates a server socket and accepts client connections to the socket. For every client connection to the socket a separate thread object is generated using the ClientSocketThread class that handles request made by the client through the socket. (bad code)
Example Language: Java
public void acceptConnections() {
try {
ServerSocket serverSocket = new ServerSocket(SERVER_PORT);
int counter = 0; boolean hasConnections = true; while (hasConnections) { Socket client = serverSocket.accept(); }Thread t = new Thread(new ClientSocketThread(client)); t.setName(client.getInetAddress().getHostName() + ":" + counter++); t.start(); serverSocket.close(); } catch (IOException ex) {...} In this example there is no limit to the number of client connections and client threads that are created. Allowing an unlimited number of client connections and threads could potentially overwhelm the system and system resources. The server should limit the number of client connections and the client threads that are created. This can be easily done by creating a thread pool object that limits the number of threads that are generated. (good code)
Example Language: Java
public static final int SERVER_PORT = 4444;
public static final int MAX_CONNECTIONS = 10; ... public void acceptConnections() { try {
ServerSocket serverSocket = new ServerSocket(SERVER_PORT);
int counter = 0; boolean hasConnections = true; while (hasConnections) { hasConnections = checkForMoreConnections(); }Socket client = serverSocket.accept(); Thread t = new Thread(new ClientSocketThread(client)); t.setName(client.getInetAddress().getHostName() + ":" + counter++); ExecutorService pool = Executors.newFixedThreadPool(MAX_CONNECTIONS); pool.execute(t); serverSocket.close(); } catch (IOException ex) {...} Example 5 An unnamed web site allowed a user to purchase tickets for an event. A menu option allowed the user to purchase up to 10 tickets, but the back end did not restrict the actual number of tickets that could be purchased.
Example 6 Here the problem is that every time a connection is made, more memory is allocated. So if one just opened up more and more connections, eventually the machine would run out of memory. (bad code)
Example Language: C
bar connection() {
foo = malloc(1024); }return foo; endConnection(bar foo) { free(foo); }int main() { while(1) { }foo=connection(); }endConnection(foo)
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Relationship
This entry is different from uncontrolled resource consumption (CWE-400) in that there are other weaknesses that are related to inability to control resource consumption, such as holding on to a resource too long after use, or not correctly keeping track of active resources so that they can be managed and released when they are finished (CWE-771).
Theoretical
Vulnerability theory is largely about how behaviors and resources interact. "Resource exhaustion" can be regarded as either a consequence or an attack, depending on the perspective. This entry is an attempt to reflect one of the underlying weaknesses that enable these attacks (or consequences) to take place.
CWE-582: Array Declared Public, Final, and Static
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Edit Custom FilterThe product declares an array public, final, and static, which is not sufficient to prevent the array's contents from being modified.
Because arrays are mutable objects, the final constraint requires that the array object itself be assigned only once, but makes no guarantees about the values of the array elements. Since the array is public, a malicious program can change the values stored in the array. As such, in most cases an array declared public, final and static is a bug.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 The following Java Applet code mistakenly declares an array public, final and static. (bad code)
Example Language: Java
public final class urlTool extends Applet {
public final static URL[] urls; }...
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weakness fits within the context of external information sources.
CWE-405: Asymmetric Resource Consumption (Amplification)
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Edit Custom FilterThe product does not properly control situations in which an adversary can cause the product to consume or produce excessive resources without requiring the adversary to invest equivalent work or otherwise prove authorization, i.e., the adversary's influence is "asymmetric."
This can lead to poor performance due to "amplification" of resource consumption, typically in a non-linear fashion. This situation is worsened if the product allows malicious users or attackers to consume more resources than their access level permits.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Operating Systems Class: Not OS-Specific (Undetermined Prevalence) Architectures Class: Not Architecture-Specific (Undetermined Prevalence) Technologies Class: Not Technology-Specific (Undetermined Prevalence) Class: Client Server (Undetermined Prevalence) Example 1 This code listens on a port for DNS requests and sends the result to the requesting address. (bad code)
Example Language: Python
sock = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
sock.bind( (UDP_IP,UDP_PORT) ) while true: data = sock.recvfrom(1024)
if not data: break
(requestIP, nameToResolve) = parseUDPpacket(data) record = resolveName(nameToResolve) sendResponse(requestIP,record) This code sends a DNS record to a requesting IP address. UDP allows the source IP address to be easily changed ('spoofed'), thus allowing an attacker to redirect responses to a target, which may be then be overwhelmed by the network traffic. Example 2 This function prints the contents of a specified file requested by a user. (bad code)
Example Language: PHP
function printFile($username,$filename){
//read file into string $file = file_get_contents($filename); if ($file && isOwnerOf($username,$filename)){ echo $file; }return true; else{ echo 'You are not authorized to view this file'; }return false; This code first reads a specified file into memory, then prints the file if the user is authorized to see its contents. The read of the file into memory may be resource intensive and is unnecessary if the user is not allowed to see the file anyway. Example 3 The DTD and the very brief XML below illustrate what is meant by an XML bomb. The ZERO entity contains one character, the letter A. The choice of entity name ZERO is being used to indicate length equivalent to that exponent on two, that is, the length of ZERO is 2^0. Similarly, ONE refers to ZERO twice, therefore the XML parser will expand ONE to a length of 2, or 2^1. Ultimately, we reach entity THIRTYTWO, which will expand to 2^32 characters in length, or 4 GB, probably consuming far more data than expected. (attack code)
Example Language: XML
<?xml version="1.0"?>
<!DOCTYPE MaliciousDTD [ <!ENTITY ZERO "A"> <!ENTITY ONE "&ZERO;&ZERO;"> <!ENTITY TWO "&ONE;&ONE;"> ... <!ENTITY THIRTYTWO "&THIRTYONE;&THIRTYONE;"> ]> <data>&THIRTYTWO;</data> Example 4 This example attempts to check if an input string is a "sentence" [REF-1164]. (bad code)
Example Language: JavaScript
var test_string = "Bad characters: $@#";
var bad_pattern = /^(\w+\s?)*$/i; var result = test_string.search(bad_pattern); The regular expression has a vulnerable backtracking clause inside (\w+\s?)*$ which can be triggered to cause a Denial of Service by processing particular phrases. To fix the backtracking problem, backtracking is removed with the ?= portion of the expression which changes it to a lookahead and the \2 which prevents the backtracking. The modified example is: (good code)
Example Language: JavaScript
var test_string = "Bad characters: $@#";
var good_pattern = /^((?=(\w+))\2\s?)*$/i; var result = test_string.search(good_pattern); Note that [REF-1164] has a more thorough (and lengthy) explanation of everything going on within the RegEx. Example 5 An adversary can cause significant resource consumption on a server by filtering the cryptographic algorithms offered by the client to the ones that are the most resource-intensive on the server side. After discovering which cryptographic algorithms are supported by the server, a malicious client can send the initial cryptographic handshake messages that contains only the resource-intensive algorithms. For some cryptographic protocols, these messages can be completely prefabricated, as the resource-intensive part of the handshake happens on the server-side first (such as TLS), rather than on the client side. In the case of cryptographic protocols where the resource-intensive part should happen on the client-side first (such as SSH), a malicious client can send a forged/precalculated computation result, which seems correct to the server, so the resource-intensive part of the handshake is going to happen on the server side. A malicious client is required to send only the initial messages of a cryptographic handshake to initiate the resource-consuming part of the cryptographic handshake. These messages are usually small, and generating them requires minimal computational effort, enabling a denial-of-service attack. An additional risk is the fact that higher key size increases the effectiveness of the attack. Cryptographic protocols where the clients have influence over the size of the used key (such as TLS 1.3 or SSH) are most at risk, as the client can enforce the highest key size supported by the server.
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CWE-289: Authentication Bypass by Alternate Name
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Edit Custom FilterThe product performs authentication based on the name of a resource being accessed, or the name of the actor performing the access, but it does not properly check all possible names for that resource or actor.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence)
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Relationship
Overlaps equivalent encodings, canonicalization, authorization, multiple trailing slash, trailing space, mixed case, and other equivalence issues.
Theoretical
Alternate names are useful in data driven manipulation attacks, not just for authentication.
CWE-302: Authentication Bypass by Assumed-Immutable Data
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Edit Custom FilterThe authentication scheme or implementation uses key data elements that are assumed to be immutable, but can be controlled or modified by the attacker.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 In the following example, an "authenticated" cookie is used to determine whether or not a user should be granted access to a system. (bad code)
Example Language: Java
boolean authenticated = new Boolean(getCookieValue("authenticated")).booleanValue();
if (authenticated) { ... }Modifying the value of a cookie on the client-side is trivial, but many developers assume that cookies are essentially immutable.
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weakness fits within the context of external information sources.
CWE-589: Call to Non-ubiquitous API
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Edit Custom FilterThe product uses an API function that does not exist on all versions of the target platform. This could cause portability problems or inconsistencies that allow denial of service or other consequences.
Some functions that offer security features supported by the OS are not available on all versions of the OS in common use. Likewise, functions are often deprecated or made obsolete for security reasons and should not be used.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-572: Call to Thread run() instead of start()
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Edit Custom FilterThe product calls a thread's run() method instead of calling start(), which causes the code to run in the thread of the caller instead of the callee.
In most cases a direct call to a Thread object's run() method is a bug. The programmer intended to begin a new thread of control, but accidentally called run() instead of start(), so the run() method will execute in the caller's thread of control.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 The following excerpt from a Java program mistakenly calls run() instead of start(). (bad code)
Example Language: Java
Thread thr = new Thread() {
public void run() { };... }thr.run();
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CWE-300: Channel Accessible by Non-Endpoint
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Edit Custom FilterThe product does not adequately verify the identity of actors at both ends of a communication channel, or does not adequately ensure the integrity of the channel, in a way that allows the channel to be accessed or influenced by an actor that is not an endpoint.
In order to establish secure communication between two parties, it is often important to adequately verify the identity of entities at each end of the communication channel. Inadequate or inconsistent verification may result in insufficient or incorrect identification of either communicating entity. This can have negative consequences such as misplaced trust in the entity at the other end of the channel. An attacker can leverage this by interposing between the communicating entities and masquerading as the original entity. In the absence of sufficient verification of identity, such an attacker can eavesdrop and potentially modify the communication between the original entities.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 In the Java snippet below, data is sent over an unencrypted channel to a remote server. (bad code)
Example Language: Java
Socket sock;
PrintWriter out; try { sock = new Socket(REMOTE_HOST, REMOTE_PORT);
out = new PrintWriter(echoSocket.getOutputStream(), true); // Write data to remote host via socket output stream. ... By eavesdropping on the communication channel or posing as the endpoint, an attacker would be able to read all of the transmitted data.
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Maintenance
The summary identifies multiple distinct possibilities, suggesting that this is a category that must be broken into more specific weaknesses.
CWE-319: Cleartext Transmission of Sensitive Information
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Edit Custom FilterThe product transmits sensitive or security-critical data in cleartext in a communication channel that can be sniffed by unauthorized actors.
Many communication channels can be "sniffed" (monitored) by adversaries during data transmission. For example, in networking, packets can traverse many intermediary nodes from the source to the destination, whether across the internet, an internal network, the cloud, etc. Some actors might have privileged access to a network interface or any link along the channel, such as a router, but they might not be authorized to collect the underlying data. As a result, network traffic could be sniffed by adversaries, spilling security-critical data. Applicable communication channels are not limited to software products. Applicable channels include hardware-specific technologies such as internal hardware networks and external debug channels, supporting remote JTAG debugging. When mitigations are not applied to combat adversaries within the product's threat model, this weakness significantly lowers the difficulty of exploitation by such adversaries. When full communications are recorded or logged, such as with a packet dump, an adversary could attempt to obtain the dump long after the transmission has occurred and try to "sniff" the cleartext from the recorded communications in the dump itself. Even if the information is encoded in a way that is not human-readable, certain techniques could determine which encoding is being used, then decode the information. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
Relevant to the view "Hardware Design" (CWE-1194)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Class: Cloud Computing (Undetermined Prevalence) Class: Mobile (Undetermined Prevalence) Class: ICS/OT (Often Prevalent) Class: System on Chip (Undetermined Prevalence) Test/Debug Hardware (Often Prevalent) Example 1 The following code attempts to establish a connection to a site to communicate sensitive information. (bad code)
Example Language: Java
try {
URL u = new URL("http://www.secret.example.org/"); }HttpURLConnection hu = (HttpURLConnection) u.openConnection(); hu.setRequestMethod("PUT"); hu.connect(); OutputStream os = hu.getOutputStream(); hu.disconnect(); catch (IOException e) {
//...
}Though a connection is successfully made, the connection is unencrypted and it is possible that all sensitive data sent to or received from the server will be read by unintended actors. Example 2 In 2022, the OT:ICEFALL study examined products by 10 different Operational Technology (OT) vendors. The researchers reported 56 vulnerabilities and said that the products were "insecure by design" [REF-1283]. If exploited, these vulnerabilities often allowed adversaries to change how the products operated, ranging from denial of service to changing the code that the products executed. Since these products were often used in industries such as power, electrical, water, and others, there could even be safety implications. Multiple vendors used cleartext transmission of sensitive information in their OT products. Example 3 A TAP accessible register is read/written by a JTAG based tool, for internal use by authorized users. However, an adversary can connect a probing device and collect the values from the unencrypted channel connecting the JTAG interface to the authorized user, if no additional protections are employed. Example 4 The following Azure CLI command lists the properties of a particular storage account: (informative)
Example Language: Shell
az storage account show -g {ResourceGroupName} -n {StorageAccountName}
The JSON result might be: (bad code)
Example Language: JSON
{
"name": "{StorageAccountName}",
}
"enableHttpsTrafficOnly": false, "type": "Microsoft.Storage/storageAccounts" The enableHttpsTrafficOnly value is set to false, because the default setting for Secure transfer is set to Disabled. This allows cloud storage resources to successfully connect and transfer data without the use of encryption (e.g., HTTP, SMB 2.1, SMB 3.0, etc.). Azure's storage accounts can be configured to only accept requests from secure connections made over HTTPS. The secure transfer setting can be enabled using Azure's Portal (GUI) or programmatically by setting the enableHttpsTrafficOnly property to True on the storage account, such as: (good code)
Example Language: Shell
az storage account update -g {ResourceGroupName} -n {StorageAccountName} --https-only true
The change can be confirmed from the result by verifying that the enableHttpsTrafficOnly value is true: (good code)
Example Language: JSON
{
"name": "{StorageAccountName}",
}
"enableHttpsTrafficOnly": true, "type": "Microsoft.Storage/storageAccounts"
Note: to enable secure transfer using Azure's Portal instead of the command line:
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Maintenance
The Taxonomy_Mappings to ISA/IEC 62443 were added in CWE 4.10, but they are still under review and might change in future CWE versions. These draft mappings were performed by members of the "Mapping CWE to 62443" subgroup of the CWE-CAPEC ICS/OT Special Interest Group (SIG), and their work is incomplete as of CWE 4.10. The mappings are included to facilitate discussion and review by the broader ICS/OT community, and they are likely to change in future CWE versions.
CWE-498: Cloneable Class Containing Sensitive Information
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Edit Custom FilterThe code contains a class with sensitive data, but the class is cloneable. The data can then be accessed by cloning the class.
Cloneable classes are effectively open classes, since data cannot be hidden in them. Classes that do not explicitly deny cloning can be cloned by any other class without running the constructor.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C++ (Undetermined Prevalence) Java (Undetermined Prevalence) C# (Undetermined Prevalence) Example 1 The following example demonstrates the weakness. (bad code)
Example Language: Java
public class CloneClient {
public CloneClient() //throws
java.lang.CloneNotSupportedException { Teacher t1 = new Teacher("guddu","22,nagar road"); //... // Do some stuff to remove the teacher. Teacher t2 = (Teacher)t1.clone(); System.out.println(t2.name); public static void main(String args[]) { new CloneClient(); class Teacher implements Cloneable { public Object clone() { try { return super.clone(); }catch (java.lang.CloneNotSupportedException e) { throw new RuntimeException(e.toString()); public String name; public String clas; public Teacher(String name,String clas) { this.name = name; this.clas = clas; Make classes uncloneable by defining a clone function like: (good code)
Example Language: Java
public final void clone() throws java.lang.CloneNotSupportedException {
throw new java.lang.CloneNotSupportedException(); }
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-182: Collapse of Data into Unsafe Value
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Edit Custom FilterThe product filters data in a way that causes it to be reduced or "collapsed" into an unsafe value that violates an expected security property.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence)
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Relationship
Overlaps regular expressions, although an implementation might not necessarily use regexp's.
CWE-486: Comparison of Classes by Name
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Edit Custom FilterThe product compares classes by name, which can cause it to use the wrong class when multiple classes can have the same name.
If the decision to trust the methods and data of an object is based on the name of a class, it is possible for malicious users to send objects of the same name as trusted classes and thereby gain the trust afforded to known classes and types.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 In this example, the expression in the if statement compares the class of the inputClass object to a trusted class by comparing the class names. (bad code)
Example Language: Java
if (inputClass.getClass().getName().equals("TrustedClassName")) {
// Do something assuming you trust inputClass // ... However, multiple classes can have the same name therefore comparing an object's class by name can allow untrusted classes of the same name as the trusted class to be use to execute unintended or incorrect code. To compare the class of an object to the intended class the getClass() method and the comparison operator "==" should be used to ensure the correct trusted class is used, as shown in the following example. (good code)
Example Language: Java
if (inputClass.getClass() == TrustedClass.class) {
// Do something assuming you trust inputClass // ... Example 2 In this example, the Java class, TrustedClass, overrides the equals method of the parent class Object to determine equivalence of objects of the class. The overridden equals method first determines if the object, obj, is the same class as the TrustedClass object and then compares the object's fields to determine if the objects are equivalent. (bad code)
Example Language: Java
public class TrustedClass {
...
@Override public boolean equals(Object obj) { boolean isEquals = false;
// first check to see if the object is of the same class if (obj.getClass().getName().equals(this.getClass().getName())) { // then compare object fields ... if (...) { isEquals = true; }return isEquals; ... However, the equals method compares the class names of the object, obj, and the TrustedClass object to determine if they are the same class. As with the previous example using the name of the class to compare the class of objects can lead to the execution of unintended or incorrect code if the object passed to the equals method is of another class with the same name. To compare the class of an object to the intended class, the getClass() method and the comparison operator "==" should be used to ensure the correct trusted class is used, as shown in the following example. (good code)
Example Language: Java
public boolean equals(Object obj) {
...
// first check to see if the object is of the same class if (obj.getClass() == this.getClass()) { ... }...
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weakness fits within the context of external information sources.
CWE-595: Comparison of Object References Instead of Object Contents
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Edit Custom FilterThe product compares object references instead of the contents of the objects themselves, preventing it from detecting equivalent objects.
For example, in Java, comparing objects using == usually produces deceptive results, since the == operator compares object references rather than values; often, this means that using == for strings is actually comparing the strings' references, not their values.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) JavaScript (Undetermined Prevalence) PHP (Undetermined Prevalence) Class: Not Language-Specific (Undetermined Prevalence) Example 1 In the example below, two Java String objects are declared and initialized with the same string values. An if statement is used to determine if the strings are equivalent. (bad code)
Example Language: Java
String str1 = new String("Hello");
String str2 = new String("Hello"); if (str1 == str2) { System.out.println("str1 == str2"); }However, the if statement will not be executed as the strings are compared using the "==" operator. For Java objects, such as String objects, the "==" operator compares object references, not object values. While the two String objects above contain the same string values, they refer to different object references, so the System.out.println statement will not be executed. To compare object values, the previous code could be modified to use the equals method: (good code)
if (str1.equals(str2)) {
System.out.println("str1 equals str2"); }Example 2 In the following Java example, two BankAccount objects are compared in the isSameAccount method using the == operator. (bad code)
Example Language: Java
public boolean isSameAccount(BankAccount accountA, BankAccount accountB) {
return accountA == accountB; }Using the == operator to compare objects may produce incorrect or deceptive results by comparing object references rather than values. The equals() method should be used to ensure correct results or objects should contain a member variable that uniquely identifies the object. The following example shows the use of the equals() method to compare the BankAccount objects and the next example uses a class get method to retrieve the bank account number that uniquely identifies the BankAccount object to compare the objects. (good code)
Example Language: Java
public boolean isSameAccount(BankAccount accountA, BankAccount accountB) {
return accountA.equals(accountB); }
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-362: Concurrent Execution using Shared Resource with Improper Synchronization ('Race Condition')
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Edit Custom FilterA race condition occurs within concurrent environments, and it is effectively a property of a code sequence. Depending on the context, a code sequence may be in the form of a function call, a small number of instructions, a series of program invocations, etc. A race condition violates these properties, which are closely related:
A race condition exists when an "interfering code sequence" can still access the shared resource, violating exclusivity. The interfering code sequence could be "trusted" or "untrusted." A trusted interfering code sequence occurs within the product; it cannot be modified by the attacker, and it can only be invoked indirectly. An untrusted interfering code sequence can be authored directly by the attacker, and typically it is external to the vulnerable product. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C (Sometimes Prevalent) C++ (Sometimes Prevalent) Java (Sometimes Prevalent) Technologies Class: Mobile (Undetermined Prevalence) Class: ICS/OT (Undetermined Prevalence) Example 1 This code could be used in an e-commerce application that supports transfers between accounts. It takes the total amount of the transfer, sends it to the new account, and deducts the amount from the original account. (bad code)
Example Language: Perl
$transfer_amount = GetTransferAmount();
$balance = GetBalanceFromDatabase(); if ($transfer_amount < 0) { FatalError("Bad Transfer Amount"); }$newbalance = $balance - $transfer_amount; if (($balance - $transfer_amount) < 0) { FatalError("Insufficient Funds"); }SendNewBalanceToDatabase($newbalance); NotifyUser("Transfer of $transfer_amount succeeded."); NotifyUser("New balance: $newbalance"); A race condition could occur between the calls to GetBalanceFromDatabase() and SendNewBalanceToDatabase(). Suppose the balance is initially 100.00. An attack could be constructed as follows: (attack code)
Example Language: Other
In the following pseudocode, the attacker makes two simultaneous calls of the program, CALLER-1 and CALLER-2. Both callers are for the same user account.
CALLER-1 (the attacker) is associated with PROGRAM-1 (the instance that handles CALLER-1). CALLER-2 is associated with PROGRAM-2. CALLER-1 makes a transfer request of 80.00. PROGRAM-1 calls GetBalanceFromDatabase and sets $balance to 100.00 PROGRAM-1 calculates $newbalance as 20.00, then calls SendNewBalanceToDatabase(). Due to high server load, the PROGRAM-1 call to SendNewBalanceToDatabase() encounters a delay. CALLER-2 makes a transfer request of 1.00. PROGRAM-2 calls GetBalanceFromDatabase() and sets $balance to 100.00. This happens because the previous PROGRAM-1 request was not processed yet. PROGRAM-2 determines the new balance as 99.00. After the initial delay, PROGRAM-1 commits its balance to the database, setting it to 20.00. PROGRAM-2 sends a request to update the database, setting the balance to 99.00 At this stage, the attacker should have a balance of 19.00 (due to 81.00 worth of transfers), but the balance is 99.00, as recorded in the database. To prevent this weakness, the programmer has several options, including using a lock to prevent multiple simultaneous requests to the web application, or using a synchronization mechanism that includes all the code between GetBalanceFromDatabase() and SendNewBalanceToDatabase(). Example 2 The following function attempts to acquire a lock in order to perform operations on a shared resource. (bad code)
Example Language: C
void f(pthread_mutex_t *mutex) {
pthread_mutex_lock(mutex);
/* access shared resource */ pthread_mutex_unlock(mutex); However, the code does not check the value returned by pthread_mutex_lock() for errors. If pthread_mutex_lock() cannot acquire the mutex for any reason, the function may introduce a race condition into the program and result in undefined behavior. In order to avoid data races, correctly written programs must check the result of thread synchronization functions and appropriately handle all errors, either by attempting to recover from them or reporting them to higher levels. (good code)
Example Language: C
int f(pthread_mutex_t *mutex) {
int result;
result = pthread_mutex_lock(mutex); if (0 != result) return result;
/* access shared resource */ return pthread_mutex_unlock(mutex); Example 3 Suppose a processor's Memory Management Unit (MMU) has 5 other shadow MMUs to distribute its workload for its various cores. Each MMU has the start address and end address of "accessible" memory. Any time this accessible range changes (as per the processor's boot status), the main MMU sends an update message to all the shadow MMUs. Suppose the interconnect fabric does not prioritize such "update" packets over other general traffic packets. This introduces a race condition. If an attacker can flood the target with enough messages so that some of those attack packets reach the target before the new access ranges gets updated, then the attacker can leverage this scenario.
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Research Gap
Race conditions in web applications are under-studied and probably under-reported. However, in 2008 there has been growing interest in this area.
Research Gap
Much of the focus of race condition research has been in Time-of-check Time-of-use (TOCTOU) variants (CWE-367), but many race conditions are related to synchronization problems that do not necessarily require a time-of-check.
Research Gap
From a classification/taxonomy perspective, the relationships between concurrency and program state need closer investigation and may be useful in organizing related issues.
Maintenance
The relationship between race conditions and synchronization problems (CWE-662) needs to be further developed. They are not necessarily two perspectives of the same core concept, since synchronization is only one technique for avoiding race conditions, and synchronization can be used for other purposes besides race condition prevention.
CWE-766: Critical Data Element Declared Public
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Edit Custom FilterThe product declares a critical variable, field, or member to be public when intended security policy requires it to be private.
This issue makes it more difficult to maintain the product, which indirectly affects security by making it more difficult or time-consuming to find and/or fix vulnerabilities. It also might make it easier to introduce vulnerabilities. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C++ (Undetermined Prevalence) C# (Undetermined Prevalence) Java (Undetermined Prevalence) Example 1 The following example declares a critical variable public, making it accessible to anyone with access to the object in which it is contained. (bad code)
Example Language: C++
public: char* password;
Instead, the critical data should be declared private. (good code)
Example Language: C++
private: char* password;
Even though this example declares the password to be private, there are other possible issues with this implementation, such as the possibility of recovering the password from process memory (CWE-257). Example 2 The following example shows a basic user account class that includes member variables for the username and password as well as a public constructor for the class and a public method to authorize access to the user account. (bad code)
Example Language: C++
#define MAX_PASSWORD_LENGTH 15
#define MAX_USERNAME_LENGTH 15 class UserAccount { public:
UserAccount(char *username, char *password)
{ if ((strlen(username) > MAX_USERNAME_LENGTH) || }(strlen(password) > MAX_PASSWORD_LENGTH)) { ExitError("Invalid username or password"); }strcpy(this->username, username); strcpy(this->password, password); int authorizeAccess(char *username, char *password) { if ((strlen(username) > MAX_USERNAME_LENGTH) ||
(strlen(password) > MAX_PASSWORD_LENGTH)) { ExitError("Invalid username or password"); }// if the username and password in the input parameters are equal to // the username and password of this account class then authorize access if (strcmp(this->username, username) || strcmp(this->password, password)) return 0;
// otherwise do not authorize access else return 1;
char username[MAX_USERNAME_LENGTH+1]; char password[MAX_PASSWORD_LENGTH+1]; However, the member variables username and password are declared public and therefore will allow access and changes to the member variables to anyone with access to the object. These member variables should be declared private as shown below to prevent unauthorized access and changes. (good code)
Example Language: C++
class UserAccount
{ public: ...
private: char username[MAX_USERNAME_LENGTH+1]; };char password[MAX_PASSWORD_LENGTH+1];
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CWE-493: Critical Public Variable Without Final Modifier
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Edit Custom FilterThe product has a critical public variable that is not final, which allows the variable to be modified to contain unexpected values.
If a field is non-final and public, it can be changed once the value is set by any function that has access to the class which contains the field. This could lead to a vulnerability if other parts of the program make assumptions about the contents of that field.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) C++ (Undetermined Prevalence) Example 1 Suppose this WidgetData class is used for an e-commerce web site. The programmer attempts to prevent price-tampering attacks by setting the price of the widget using the constructor. (bad code)
Example Language: Java
public final class WidgetData extends Applet {
public float price; }... public WidgetData(...) { this.price = LookupPrice("MyWidgetType"); }The price field is not final. Even though the value is set by the constructor, it could be modified by anybody that has access to an instance of WidgetData. Example 2 Assume the following code is intended to provide the location of a configuration file that controls execution of the application. (bad code)
Example Language: C++
public string configPath = "/etc/application/config.dat";
(bad code)
Example Language: Java
public String configPath = new String("/etc/application/config.dat");
While this field is readable from any function, and thus might allow an information leak of a pathname, a more serious problem is that it can be changed by any function.
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weakness fits within the context of external information sources.
CWE-833: Deadlock
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Edit Custom FilterThe product contains multiple threads or executable segments that are waiting for each other to release a necessary lock, resulting in deadlock.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
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CWE-397: Declaration of Throws for Generic Exception
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Edit Custom FilterThrowing overly broad exceptions promotes complex error handling code that is more likely to contain security vulnerabilities.
Declaring a method to throw Exception or Throwable makes it difficult for callers to perform proper error handling and error recovery. Java's exception mechanism, for example, is set up to make it easy for callers to anticipate what can go wrong and write code to handle each specific exceptional circumstance. Declaring that a method throws a generic form of exception defeats this system.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C++ (Undetermined Prevalence) Java (Undetermined Prevalence) C# (Undetermined Prevalence) Example 1 The following method throws three types of exceptions. (good code)
Example Language: Java
public void doExchange() throws IOException, InvocationTargetException, SQLException {
... }While it might seem tidier to write (bad code)
public void doExchange() throws Exception {
... }doing so hampers the caller's ability to understand and handle the exceptions that occur. Further, if a later revision of doExchange() introduces a new type of exception that should be treated differently than previous exceptions, there is no easy way to enforce this requirement. Example 2 Early versions of C++ (C++98, C++03, C++11) included a feature known as Dynamic Exception Specification. This allowed functions to declare what type of exceptions it may throw. It is possible to declare a general class of exception to cover any derived exceptions that may be throw. (bad code)
int myfunction() throw(std::exception) {
if (0) throw out_of_range(); }throw length_error(); In the example above, the code declares that myfunction() can throw an exception of type "std::exception" thus hiding details about the possible derived exceptions that could potentially be thrown.
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Applicable Platform
For C++, this weakness only applies to C++98, C++03, and C++11. It relies on a feature known as Dynamic Exception Specification, which was part of early versions of C++ but was deprecated in C++11. It has been removed for C++17 and later.
CWE-502: Deserialization of Untrusted Data
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This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Ruby (Undetermined Prevalence) PHP (Undetermined Prevalence) Python (Undetermined Prevalence) JavaScript (Undetermined Prevalence) Technologies Class: ICS/OT (Often Prevalent) Example 1 This code snippet deserializes an object from a file and uses it as a UI button: (bad code)
Example Language: Java
try {
File file = new File("object.obj"); }ObjectInputStream in = new ObjectInputStream(new FileInputStream(file)); javax.swing.JButton button = (javax.swing.JButton) in.readObject(); in.close(); This code does not attempt to verify the source or contents of the file before deserializing it. An attacker may be able to replace the intended file with a file that contains arbitrary malicious code which will be executed when the button is pressed. To mitigate this, explicitly define final readObject() to prevent deserialization. An example of this is: (good code)
Example Language: Java
private final void readObject(ObjectInputStream in) throws java.io.IOException {
throw new java.io.IOException("Cannot be deserialized"); } Example 2 In Python, the Pickle library handles the serialization and deserialization processes. In this example derived from [REF-467], the code receives and parses data, and afterwards tries to authenticate a user based on validating a token. (bad code)
Example Language: Python
try {
class ExampleProtocol(protocol.Protocol):
def dataReceived(self, data): # Code that would be here would parse the incoming data # After receiving headers, call confirmAuth() to authenticate def confirmAuth(self, headers): try: token = cPickle.loads(base64.b64decode(headers['AuthToken'])) if not check_hmac(token['signature'], token['data'], getSecretKey()): raise AuthFail self.secure_data = token['data'] except: raise AuthFail Unfortunately, the code does not verify that the incoming data is legitimate. An attacker can construct a illegitimate, serialized object "AuthToken" that instantiates one of Python's subprocesses to execute arbitrary commands. For instance,the attacker could construct a pickle that leverages Python's subprocess module, which spawns new processes and includes a number of arguments for various uses. Since Pickle allows objects to define the process for how they should be unpickled, the attacker can direct the unpickle process to call Popen in the subprocess module and execute /bin/sh.
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CWE-390: Detection of Error Condition Without Action
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Edit Custom FilterThis table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following example attempts to allocate memory for a character. After the call to malloc, an if statement is used to check whether the malloc function failed. (bad code)
Example Language: C
foo=malloc(sizeof(char)); //the next line checks to see if malloc failed
if (foo==NULL) { //We do nothing so we just ignore the error. }The conditional successfully detects a NULL return value from malloc indicating a failure, however it does not do anything to handle the problem. Unhandled errors may have unexpected results and may cause the program to crash or terminate. Instead, the if block should contain statements that either attempt to fix the problem or notify the user that an error has occurred and continue processing or perform some cleanup and gracefully terminate the program. The following example notifies the user that the malloc function did not allocate the required memory resources and returns an error code. (good code)
Example Language: C
foo=malloc(sizeof(char)); //the next line checks to see if malloc failed
if (foo==NULL) { printf("Malloc failed to allocate memory resources"); }return -1; Example 2 In the following C++ example the method readFile() will read the file whose name is provided in the input parameter and will return the contents of the file in char string. The method calls open() and read() may result in errors if the file does not exist or does not contain any data to read. These errors will be thrown when the is_open() method and good() method indicate errors opening or reading the file. However, these errors are not handled within the catch statement. Catch statements that do not perform any processing will have unexpected results. In this case an empty char string will be returned, and the file will not be properly closed. (bad code)
Example Language: C++
char* readfile (char *filename) {
try {
// open input file
ifstream infile; infile.open(filename); if (!infile.is_open()) { throw "Unable to open file " + filename; }// get length of file infile.seekg (0, ios::end); int length = infile.tellg(); infile.seekg (0, ios::beg); // allocate memory char *buffer = new char [length]; // read data from file infile.read (buffer,length); if (!infile.good()) { throw "Unable to read from file " + filename; }infile.close(); return buffer; catch (...) { /* bug: insert code to handle this later */ }The catch statement should contain statements that either attempt to fix the problem or notify the user that an error has occurred and continue processing or perform some cleanup and gracefully terminate the program. The following C++ example contains two catch statements. The first of these will catch a specific error thrown within the try block, and the second catch statement will catch all other errors from within the catch block. Both catch statements will notify the user that an error has occurred, close the file, and rethrow to the block that called the readFile() method for further handling or possible termination of the program. (good code)
Example Language: C++
char* readFile (char *filename) {
try {
// open input file
ifstream infile; infile.open(filename); if (!infile.is_open()) { throw "Unable to open file " + filename; }// get length of file infile.seekg (0, ios::end); int length = infile.tellg(); infile.seekg (0, ios::beg); // allocate memory char *buffer = new char [length]; // read data from file infile.read (buffer,length); if (!infile.good()) { throw "Unable to read from file " + filename; }infile.close(); return buffer; catch (char *str) { printf("Error: %s \n", str); }infile.close(); throw str; catch (...) { printf("Error occurred trying to read from file \n"); }infile.close(); throw; Example 3 In the following Java example the method readFile will read the file whose name is provided in the input parameter and will return the contents of the file in a String object. The constructor of the FileReader object and the read method call may throw exceptions and therefore must be within a try/catch block. While the catch statement in this example will catch thrown exceptions in order for the method to compile, no processing is performed to handle the thrown exceptions. Catch statements that do not perform any processing will have unexpected results. In this case, this will result in the return of a null String. (bad code)
Example Language: Java
public String readFile(String filename) {
String retString = null;
try { // initialize File and FileReader objects
File file = new File(filename); FileReader fr = new FileReader(file); // initialize character buffer long fLen = file.length(); char[] cBuf = new char[(int) fLen]; // read data from file int iRead = fr.read(cBuf, 0, (int) fLen); // close file fr.close(); retString = new String(cBuf); /* do nothing, but catch so it'll compile... */ }return retString; The catch statement should contain statements that either attempt to fix the problem, notify the user that an exception has been raised and continue processing, or perform some cleanup and gracefully terminate the program. The following Java example contains three catch statements. The first of these will catch the FileNotFoundException that may be thrown by the FileReader constructor called within the try/catch block. The second catch statement will catch the IOException that may be thrown by the read method called within the try/catch block. The third catch statement will catch all other exceptions thrown within the try block. For all catch statements the user is notified that the exception has been thrown and the exception is rethrown to the block that called the readFile() method for further processing or possible termination of the program. Note that with Java it is usually good practice to use the getMessage() method of the exception class to provide more information to the user about the exception raised. (good code)
Example Language: Java
public String readFile(String filename) throws FileNotFoundException, IOException, Exception {
String retString = null;
try { // initialize File and FileReader objects
File file = new File(filename); FileReader fr = new FileReader(file); // initialize character buffer long fLen = file.length(); char [] cBuf = new char[(int) fLen]; // read data from file int iRead = fr.read(cBuf, 0, (int) fLen); // close file fr.close(); retString = new String(cBuf); System.err.println ("Error: FileNotFoundException opening the input file: " + filename ); } catch (IOException ex) {System.err.println ("" + ex.getMessage() ); throw new FileNotFoundException(ex.getMessage()); System.err.println("Error: IOException reading the input file.\n" + ex.getMessage() ); } catch (Exception ex) {throw new IOException(ex); System.err.println("Error: Exception reading the input file.\n" + ex.getMessage() ); }throw new Exception(ex); return retString;
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weakness fits within the context of external information sources.
CWE-111: Direct Use of Unsafe JNI
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Edit Custom FilterWhen a Java application uses the Java Native Interface (JNI) to call code written in another programming language, it can expose the application to weaknesses in that code, even if those weaknesses cannot occur in Java.
Many safety features that programmers may take for granted do not apply for native code, so you must carefully review all such code for potential problems. The languages used to implement native code may be more susceptible to buffer overflows and other attacks. Native code is unprotected by the security features enforced by the runtime environment, such as strong typing and array bounds checking.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Seven Pernicious Kingdoms" (CWE-700)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 The following code defines a class named Echo. The class declares one native method (defined below), which uses C to echo commands entered on the console back to the user. The following C code defines the native method implemented in the Echo class: (bad code)
Example Language: Java
class Echo {
public native void runEcho(); static { System.loadLibrary("echo"); public static void main(String[] args) { new Echo().runEcho(); (bad code)
Example Language: C
#include <jni.h>
#include "Echo.h"//the java class above compiled with javah #include <stdio.h> JNIEXPORT void JNICALL Java_Echo_runEcho(JNIEnv *env, jobject obj) { char buf[64]; }gets(buf); printf(buf); Because the example is implemented in Java, it may appear that it is immune to memory issues like buffer overflow vulnerabilities. Although Java does do a good job of making memory operations safe, this protection does not extend to vulnerabilities occurring in source code written in other languages that are accessed using the Java Native Interface. Despite the memory protections offered in Java, the C code in this example is vulnerable to a buffer overflow because it makes use of gets(), which does not check the length of its input. The Sun Java(TM) Tutorial provides the following description of JNI [See Reference]: The JNI framework lets your native method utilize Java objects in the same way that Java code uses these objects. A native method can create Java objects, including arrays and strings, and then inspect and use these objects to perform its tasks. A native method can also inspect and use objects created by Java application code. A native method can even update Java objects that it created or that were passed to it, and these updated objects are available to the Java application. Thus, both the native language side and the Java side of an application can create, update, and access Java objects and then share these objects between them. The vulnerability in the example above could easily be detected through a source code audit of the native method implementation. This may not be practical or possible depending on the availability of the C source code and the way the project is built, but in many cases it may suffice. However, the ability to share objects between Java and native methods expands the potential risk to much more insidious cases where improper data handling in Java may lead to unexpected vulnerabilities in native code or unsafe operations in native code corrupt data structures in Java. Vulnerabilities in native code accessed through a Java application are typically exploited in the same manner as they are in applications written in the native language. The only challenge to such an attack is for the attacker to identify that the Java application uses native code to perform certain operations. This can be accomplished in a variety of ways, including identifying specific behaviors that are often implemented with native code or by exploiting a system information exposure in the Java application that reveals its use of JNI [See Reference].
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CWE-369: Divide By Zero
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This weakness typically occurs when an unexpected value is provided to the product, or if an error occurs that is not properly detected. It frequently occurs in calculations involving physical dimensions such as size, length, width, and height.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
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weakness may be introduced. The Phase identifies a point in the life cycle at which
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given
phase.
Example 1 The following Java example contains a function to compute an average but does not validate that the input value used as the denominator is not zero. This will create an exception for attempting to divide by zero. If this error is not handled by Java exception handling, unexpected results can occur. (bad code)
Example Language: Java
public int computeAverageResponseTime (int totalTime, int numRequests) {
return totalTime / numRequests; }By validating the input value used as the denominator the following code will ensure that a divide by zero error will not cause unexpected results. The following Java code example will validate the input value, output an error message, and throw an exception. (good code)
public int computeAverageResponseTime (int totalTime, int numRequests) throws ArithmeticException {
if (numRequests == 0) { }System.out.println("Division by zero attempted!"); }throw ArithmeticException; return totalTime / numRequests; Example 2 The following C/C++ example contains a function that divides two numeric values without verifying that the input value used as the denominator is not zero. This will create an error for attempting to divide by zero, if this error is not caught by the error handling capabilities of the language, unexpected results can occur. (bad code)
Example Language: C
double divide(double x, double y){
return x/y; }By validating the input value used as the denominator the following code will ensure that a divide by zero error will not cause unexpected results. If the method is called and a zero is passed as the second argument a DivideByZero error will be thrown and should be caught by the calling block with an output message indicating the error. (good code)
const int DivideByZero = 10;
double divide(double x, double y){ if ( 0 == y ){ }throw DivideByZero; }return x/y; ... try{ divide(10, 0); }catch( int i ){ if(i==DivideByZero) { }cerr<<"Divide by zero error"; }
Example 3 The following C# example contains a function that divides two numeric values without verifying that the input value used as the denominator is not zero. This will create an error for attempting to divide by zero, if this error is not caught by the error handling capabilities of the language, unexpected results can occur. (bad code)
Example Language: C#
int Division(int x, int y){
return (x / y); }The method can be modified to raise, catch and handle the DivideByZeroException if the input value used as the denominator is zero. (good code)
int SafeDivision(int x, int y){
try{ }return (x / y); }catch (System.DivideByZeroException dbz){ System.Console.WriteLine("Division by zero attempted!"); }return 0;
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CWE-609: Double-Checked Locking
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Edit Custom FilterThe product uses double-checked locking to access a resource without the overhead of explicit synchronization, but the locking is insufficient.
Double-checked locking refers to the situation where a programmer checks to see if a resource has been initialized, grabs a lock, checks again to see if the resource has been initialized, and then performs the initialization if it has not occurred yet. This should not be done, as it is not guaranteed to work in all languages and on all architectures. In summary, other threads may not be operating inside the synchronous block and are not guaranteed to see the operations execute in the same order as they would appear inside the synchronous block.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 It may seem that the following bit of code achieves thread safety while avoiding unnecessary synchronization... (bad code)
Example Language: Java
if (helper == null) {
synchronized (this) {
if (helper == null) { }helper = new Helper(); }return helper; The programmer wants to guarantee that only one Helper() object is ever allocated, but does not want to pay the cost of synchronization every time this code is called. Suppose that helper is not initialized. Then, thread A sees that helper==null and enters the synchronized block and begins to execute: (bad code)
helper = new Helper();
If a second thread, thread B, takes over in the middle of this call and helper has not finished running the constructor, then thread B may make calls on helper while its fields hold incorrect values.
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CWE-494: Download of Code Without Integrity Check
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Edit Custom FilterThe product downloads source code or an executable from a remote location and executes the code without sufficiently verifying the origin and integrity of the code.
An attacker can execute malicious code by compromising the host server, performing DNS spoofing, or modifying the code in transit.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 This example loads an external class from a local subdirectory. (bad code)
Example Language: Java
URL[] classURLs= new URL[]{
new URL("file:subdir/") };URLClassLoader loader = new URLClassLoader(classURLs); Class loadedClass = Class.forName("loadMe", true, loader); This code does not ensure that the class loaded is the intended one, for example by verifying the class's checksum. An attacker may be able to modify the class file to execute malicious code. Example 2 This code includes an external script to get database credentials, then authenticates a user against the database, allowing access to the application. (bad code)
Example Language: PHP
//assume the password is already encrypted, avoiding CWE-312
function authenticate($username,$password){ include("http://external.example.com/dbInfo.php"); //dbInfo.php makes $dbhost, $dbuser, $dbpass, $dbname available mysql_connect($dbhost, $dbuser, $dbpass) or die ('Error connecting to mysql'); mysql_select_db($dbname); $query = 'Select * from users where username='.$username.' And password='.$password; $result = mysql_query($query); if(mysql_numrows($result) == 1){ mysql_close(); }return true; else{ mysql_close(); }return false; } This code does not verify that the external domain accessed is the intended one. An attacker may somehow cause the external domain name to resolve to an attack server, which would provide the information for a false database. The attacker may then steal the usernames and encrypted passwords from real user login attempts, or simply allow themself to access the application without a real user account. This example is also vulnerable to an Adversary-in-the-Middle AITM (CWE-300) attack.
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Research Gap
This is critical for mobile code, but it is likely to become more and more common as developers continue to adopt automated, network-based product distributions and upgrades. Software-as-a-Service (SaaS) might introduce additional subtleties. Common exploitation scenarios may include ad server compromises and bad upgrades.
CWE-250: Execution with Unnecessary Privileges
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Edit Custom FilterThe product performs an operation at a privilege level that is higher than the minimum level required, which creates new weaknesses or amplifies the consequences of other weaknesses.
New weaknesses can be exposed because running with extra privileges, such as root or Administrator, can disable the normal security checks being performed by the operating system or surrounding environment. Other pre-existing weaknesses can turn into security vulnerabilities if they occur while operating at raised privileges. Privilege management functions can behave in some less-than-obvious ways, and they have different quirks on different platforms. These inconsistencies are particularly pronounced if you are transitioning from one non-root user to another. Signal handlers and spawned processes run at the privilege of the owning process, so if a process is running as root when a signal fires or a sub-process is executed, the signal handler or sub-process will operate with root privileges. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Class: Mobile (Undetermined Prevalence) Example 1 This code temporarily raises the program's privileges to allow creation of a new user folder. (bad code)
Example Language: Python
def makeNewUserDir(username):
While the program only raises its privilege level to create the folder and immediately lowers it again, if the call to os.mkdir() throws an exception, the call to lowerPrivileges() will not occur. As a result, the program is indefinitely operating in a raised privilege state, possibly allowing further exploitation to occur. Example 2 The following code calls chroot() to restrict the application to a subset of the filesystem below APP_HOME in order to prevent an attacker from using the program to gain unauthorized access to files located elsewhere. The code then opens a file specified by the user and processes the contents of the file. (bad code)
Example Language: C
chroot(APP_HOME);
chdir("/"); FILE* data = fopen(argv[1], "r+"); ... Constraining the process inside the application's home directory before opening any files is a valuable security measure. However, the absence of a call to setuid() with some non-zero value means the application is continuing to operate with unnecessary root privileges. Any successful exploit carried out by an attacker against the application can now result in a privilege escalation attack because any malicious operations will be performed with the privileges of the superuser. If the application drops to the privilege level of a non-root user, the potential for damage is substantially reduced. Example 3 This application intends to use a user's location to determine the timezone the user is in: (bad code)
Example Language: Java
locationClient = new LocationClient(this, this, this);
locationClient.connect(); Location userCurrLocation; userCurrLocation = locationClient.getLastLocation(); setTimeZone(userCurrLocation); This is unnecessary use of the location API, as this information is already available using the Android Time API. Always be sure there is not another way to obtain needed information before resorting to using the location API. Example 4 This code uses location to determine the user's current US State location. First the application must declare that it requires the ACCESS_FINE_LOCATION permission in the application's manifest.xml: (bad code)
Example Language: XML
<uses-permission android:name="android.permission.ACCESS_FINE_LOCATION"/>
During execution, a call to getLastLocation() will return a location based on the application's location permissions. In this case the application has permission for the most accurate location possible: (bad code)
Example Language: Java
locationClient = new LocationClient(this, this, this);
locationClient.connect(); Location userCurrLocation; userCurrLocation = locationClient.getLastLocation(); deriveStateFromCoords(userCurrLocation); While the application needs this information, it does not need to use the ACCESS_FINE_LOCATION permission, as the ACCESS_COARSE_LOCATION permission will be sufficient to identify which US state the user is in.
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Relationship Maintenance Maintenance
The Taxonomy_Mappings to ISA/IEC 62443 were added in CWE 4.10, but they are still under review and might change in future CWE versions. These draft mappings were performed by members of the "Mapping CWE to 62443" subgroup of the CWE-CAPEC ICS/OT Special Interest Group (SIG), and their work is incomplete as of CWE 4.10. The mappings are included to facilitate discussion and review by the broader ICS/OT community, and they are likely to change in future CWE versions.
CWE-586: Explicit Call to Finalize()
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While the Java Language Specification allows an object's finalize() method to be called from outside the finalizer, doing so is usually a bad idea. For example, calling finalize() explicitly means that finalize() will be called more than once: the first time will be the explicit call and the last time will be the call that is made after the object is garbage collected.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 The following code fragment calls finalize() explicitly: (bad code)
Example Language: Java
// time to clean up widget.finalize();
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CWE-359: Exposure of Private Personal Information to an Unauthorized Actor
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Edit Custom FilterThis table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Class: Mobile (Undetermined Prevalence) Example 1 The following code contains a logging statement that tracks the contents of records added to a database by storing them in a log file. Among other values that are stored, the getPassword() function returns the user-supplied plaintext password associated with the account. (bad code)
Example Language: C#
pass = GetPassword();
... dbmsLog.WriteLine(id + ":" + pass + ":" + type + ":" + tstamp); The code in the example above logs a plaintext password to the filesystem. Although many developers trust the filesystem as a safe storage location for data, it should not be trusted implicitly, particularly when privacy is a concern. Example 2 This code uses location to determine the user's current US State location. First the application must declare that it requires the ACCESS_FINE_LOCATION permission in the application's manifest.xml: (bad code)
Example Language: XML
<uses-permission android:name="android.permission.ACCESS_FINE_LOCATION"/>
During execution, a call to getLastLocation() will return a location based on the application's location permissions. In this case the application has permission for the most accurate location possible: (bad code)
Example Language: Java
locationClient = new LocationClient(this, this, this);
locationClient.connect(); Location userCurrLocation; userCurrLocation = locationClient.getLastLocation(); deriveStateFromCoords(userCurrLocation); While the application needs this information, it does not need to use the ACCESS_FINE_LOCATION permission, as the ACCESS_COARSE_LOCATION permission will be sufficient to identify which US state the user is in. Example 3 In 2004, an employee at AOL sold approximately 92 million private customer e-mail addresses to a spammer marketing an offshore gambling web site [REF-338]. In response to such high-profile exploits, the collection and management of private data is becoming increasingly regulated.
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weakness fits within the context of external information sources.
Other There are many types of sensitive information that products must protect from attackers, including system data, communications, configuration, business secrets, intellectual property, and an individual's personal (private) information. Private personal information may include a password, phone number, geographic location, personal messages, credit card number, etc. Private information is important to consider whether the person is a user of the product, or part of a data set that is processed by the product. An exposure of private information does not necessarily prevent the product from working properly, and in fact the exposure might be intended by the developer, e.g. as part of data sharing with other organizations. However, the exposure of personal private information can still be undesirable or explicitly prohibited by law or regulation. Some types of private information include:
Some of this information may be characterized as PII (Personally Identifiable Information), Protected Health Information (PHI), etc. Categories of private information may overlap or vary based on the intended usage or the policies and practices of a particular industry. Sometimes data that is not labeled as private can have a privacy implication in a different context. For example, student identification numbers are usually not considered private because there is no explicit and publicly-available mapping to an individual student's personal information. However, if a school generates identification numbers based on student social security numbers, then the identification numbers should be considered private. Maintenance
This entry overlaps many other entries that are not organized around the kind of sensitive information that is exposed. However, because privacy is treated with such importance due to regulations and other factors, and it may be useful for weakness-finding tools to highlight capabilities that detect personal private information instead of system information, it is not clear whether - and how - this entry should be deprecated.
CWE-497: Exposure of Sensitive System Information to an Unauthorized Control Sphere
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Edit Custom FilterThe product does not properly prevent sensitive system-level information from being accessed by unauthorized actors who do not have the same level of access to the underlying system as the product does.
Network-based products, such as web applications, often run on top of an operating system or similar environment. When the product communicates with outside parties, details about the underlying system are expected to remain hidden, such as path names for data files, other OS users, installed packages, the application environment, etc. This system information may be provided by the product itself, or buried within diagnostic or debugging messages. Debugging information helps an adversary learn about the system and form an attack plan. An information exposure occurs when system data or debugging information leaves the program through an output stream or logging function that makes it accessible to unauthorized parties. Using other weaknesses, an attacker could cause errors to occur; the response to these errors can reveal detailed system information, along with other impacts. An attacker can use messages that reveal technologies, operating systems, and product versions to tune the attack against known vulnerabilities in these technologies. A product may use diagnostic methods that provide significant implementation details such as stack traces as part of its error handling mechanism. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following code prints the path environment variable to the standard error stream: (bad code)
Example Language: C
char* path = getenv("PATH");
... sprintf(stderr, "cannot find exe on path %s\n", path); Example 2 This code prints all of the running processes belonging to the current user. (bad code)
Example Language: PHP
//assume getCurrentUser() returns a username that is guaranteed to be alphanumeric (avoiding CWE-78) $userName = getCurrentUser(); $command = 'ps aux | grep ' . $userName; system($command); If invoked by an unauthorized web user, it is providing a web page of potentially sensitive information on the underlying system, such as command-line arguments (CWE-497). This program is also potentially vulnerable to a PATH based attack (CWE-426), as an attacker may be able to create malicious versions of the ps or grep commands. While the program does not explicitly raise privileges to run the system commands, the PHP interpreter may by default be running with higher privileges than users. Example 3 The following code prints an exception to the standard error stream: (bad code)
Example Language: Java
try {
... } catch (Exception e) {e.printStackTrace(); }(bad code)
try {
... } catch (Exception e) {Console.Writeline(e); }Depending upon the system configuration, this information can be dumped to a console, written to a log file, or exposed to a remote user. In some cases the error message tells the attacker precisely what sort of an attack the system will be vulnerable to. For example, a database error message can reveal that the application is vulnerable to a SQL injection attack. Other error messages can reveal more oblique clues about the system. In the example above, the search path could imply information about the type of operating system, the applications installed on the system, and the amount of care that the administrators have put into configuring the program. Example 4 The following code constructs a database connection string, uses it to create a new connection to the database, and prints it to the console. (bad code)
Example Language: C#
string cs="database=northwind; server=mySQLServer...";
SqlConnection conn=new SqlConnection(cs); ... Console.Writeline(cs); Depending on the system configuration, this information can be dumped to a console, written to a log file, or exposed to a remote user. In some cases the error message tells the attacker precisely what sort of an attack the system is vulnerable to. For example, a database error message can reveal that the application is vulnerable to a SQL injection attack. Other error messages can reveal more oblique clues about the system. In the example above, the search path could imply information about the type of operating system, the applications installed on the system, and the amount of care that the administrators have put into configuring the program.
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-583: finalize() Method Declared Public
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Edit Custom FilterThe product violates secure coding principles for mobile code by declaring a finalize() method public.
A product should never call finalize explicitly, except to call super.finalize() inside an implementation of finalize(). In mobile code situations, the otherwise error prone practice of manual garbage collection can become a security threat if an attacker can maliciously invoke a finalize() method because it is declared with public access.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 The following Java Applet code mistakenly declares a public finalize() method. (bad code)
Example Language: Java
public final class urlTool extends Applet {
public void finalize() { }... }... Mobile code, in this case a Java Applet, is code that is transmitted across a network and executed on a remote machine. Because mobile code developers have little if any control of the environment in which their code will execute, special security concerns become relevant. One of the biggest environmental threats results from the risk that the mobile code will run side-by-side with other, potentially malicious, mobile code. Because all of the popular web browsers execute code from multiple sources together in the same JVM, many of the security guidelines for mobile code are focused on preventing manipulation of your objects' state and behavior by adversaries who have access to the same virtual machine where your product is running.
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weakness fits within the context of external information sources.
CWE-568: finalize() Method Without super.finalize()
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The Java Language Specification states that it is a good practice for a finalize() method to call super.finalize().
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 The following method omits the call to super.finalize(). (bad code)
Example Language: Java
protected void finalize() {
discardNative(); }
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-209: Generation of Error Message Containing Sensitive Information
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Edit Custom FilterThe product generates an error message that includes sensitive information about its environment, users, or associated data.
The sensitive information may be valuable information on its own (such as a password), or it may be useful for launching other, more serious attacks. The error message may be created in different ways:
An attacker may use the contents of error messages to help launch another, more focused attack. For example, an attempt to exploit a path traversal weakness (CWE-22) might yield the full pathname of the installed application. In turn, this could be used to select the proper number of ".." sequences to navigate to the targeted file. An attack using SQL injection (CWE-89) might not initially succeed, but an error message could reveal the malformed query, which would expose query logic and possibly even passwords or other sensitive information used within the query. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages PHP (Often Prevalent) Java (Often Prevalent) Class: Not Language-Specific (Undetermined Prevalence) Example 1 In the following example, sensitive information might be printed depending on the exception that occurs. (bad code)
Example Language: Java
try {
/.../ }catch (Exception e) { System.out.println(e); }If an exception related to SQL is handled by the catch, then the output might contain sensitive information such as SQL query structure or private information. If this output is redirected to a web user, this may represent a security problem. Example 2 This code tries to open a database connection, and prints any exceptions that occur. (bad code)
Example Language: PHP
try {
openDbConnection(); }//print exception message that includes exception message and configuration file location catch (Exception $e) { echo 'Caught exception: ', $e->getMessage(), '\n'; }echo 'Check credentials in config file at: ', $Mysql_config_location, '\n'; If an exception occurs, the printed message exposes the location of the configuration file the script is using. An attacker can use this information to target the configuration file (perhaps exploiting a Path Traversal weakness). If the file can be read, the attacker could gain credentials for accessing the database. The attacker may also be able to replace the file with a malicious one, causing the application to use an arbitrary database. Example 3 The following code generates an error message that leaks the full pathname of the configuration file. If this code is running on a server, such as a web application, then the person making the request should not know what the full pathname of the configuration directory is. By submitting a username that does not produce a $file that exists, an attacker could get this pathname. It could then be used to exploit path traversal or symbolic link following problems that may exist elsewhere in the application. Example 4 In the example below, the method getUserBankAccount retrieves a bank account object from a database using the supplied username and account number to query the database. If an SQLException is raised when querying the database, an error message is created and output to a log file. (bad code)
Example Language: Java
public BankAccount getUserBankAccount(String username, String accountNumber) {
BankAccount userAccount = null;
String query = null; try { if (isAuthorizedUser(username)) { } catch (SQLException ex) {query = "SELECT * FROM accounts WHERE owner = " }+ username + " AND accountID = " + accountNumber; DatabaseManager dbManager = new DatabaseManager(); Connection conn = dbManager.getConnection(); Statement stmt = conn.createStatement(); ResultSet queryResult = stmt.executeQuery(query); userAccount = (BankAccount)queryResult.getObject(accountNumber); String logMessage = "Unable to retrieve account information from database,\nquery: " + query; }Logger.getLogger(BankManager.class.getName()).log(Level.SEVERE, logMessage, ex); return userAccount; The error message that is created includes information about the database query that may contain sensitive information about the database or query logic. In this case, the error message will expose the table name and column names used in the database. This data could be used to simplify other attacks, such as SQL injection (CWE-89) to directly access the database.
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-703: Improper Check or Handling of Exceptional Conditions
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Edit Custom FilterThe product does not properly anticipate or handle exceptional conditions that rarely occur during normal operation of the product.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Class: Not Technology-Specific (Undetermined Prevalence) Example 1 Consider the following code segment: (bad code)
Example Language: C
char buf[10], cp_buf[10];
fgets(buf, 10, stdin); strcpy(cp_buf, buf); The programmer expects that when fgets() returns, buf will contain a null-terminated string of length 9 or less. But if an I/O error occurs, fgets() will not null-terminate buf. Furthermore, if the end of the file is reached before any characters are read, fgets() returns without writing anything to buf. In both of these situations, fgets() signals that something unusual has happened by returning NULL, but in this code, the warning will not be noticed. The lack of a null terminator in buf can result in a buffer overflow in the subsequent call to strcpy(). Example 2 The following method throws three types of exceptions. (good code)
Example Language: Java
public void doExchange() throws IOException, InvocationTargetException, SQLException {
... }While it might seem tidier to write (bad code)
public void doExchange() throws Exception {
... }doing so hampers the caller's ability to understand and handle the exceptions that occur. Further, if a later revision of doExchange() introduces a new type of exception that should be treated differently than previous exceptions, there is no easy way to enforce this requirement.
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weakness fits within the context of external information sources.
Relationship
This is a high-level class that might have some overlap with other classes. It could be argued that even "normal" weaknesses such as buffer overflows involve unusual or exceptional conditions. In that sense, this might be an inherent aspect of most other weaknesses within CWE, similar to API Abuse (CWE-227) and Indicator of Poor Code Quality (CWE-398). However, this entry is currently intended to unify disparate concepts that do not have other places within the Research Concepts view (CWE-1000).
CWE-460: Improper Cleanup on Thrown Exception
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Edit Custom FilterThe product does not clean up its state or incorrectly cleans up its state when an exception is thrown, leading to unexpected state or control flow.
Often, when functions or loops become complicated, some level of resource cleanup is needed throughout execution. Exceptions can disturb the flow of the code and prevent the necessary cleanup from happening.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C (Undetermined Prevalence) C++ (Undetermined Prevalence) Java (Undetermined Prevalence) C# (Undetermined Prevalence) Example 1 The following example demonstrates the weakness. (bad code)
Example Language: Java
public class foo {
public static final void main( String args[] ) {
boolean returnValue; returnValue=doStuff(); public static final boolean doStuff( ) { boolean threadLock; boolean truthvalue=true; try { while( //check some condition ) { threadLock=true; //do some stuff to truthvalue threadLock=false; catch (Exception e){ System.err.println("You did something bad"); if (something) return truthvalue; return truthvalue; In this case, a thread might be left locked accidentally.
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weakness fits within the context of external information sources.
CWE-116: Improper Encoding or Escaping of Output
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Edit Custom FilterThe product prepares a structured message for communication with another component, but encoding or escaping of the data is either missing or done incorrectly. As a result, the intended structure of the message is not preserved.
Improper encoding or escaping can allow attackers to change the commands that are sent to another component, inserting malicious commands instead. Most products follow a certain protocol that uses structured messages for communication between components, such as queries or commands. These structured messages can contain raw data interspersed with metadata or control information. For example, "GET /index.html HTTP/1.1" is a structured message containing a command ("GET") with a single argument ("/index.html") and metadata about which protocol version is being used ("HTTP/1.1"). If an application uses attacker-supplied inputs to construct a structured message without properly encoding or escaping, then the attacker could insert special characters that will cause the data to be interpreted as control information or metadata. Consequently, the component that receives the output will perform the wrong operations, or otherwise interpret the data incorrectly. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Often Prevalent) Technologies AI/ML (Undetermined Prevalence) Database Server (Often Prevalent) Web Server (Often Prevalent) Example 1 This code displays an email address that was submitted as part of a form. (bad code)
Example Language: JSP
<% String email = request.getParameter("email"); %>
... Email Address: <%= email %> The value read from the form parameter is reflected back to the client browser without having been encoded prior to output, allowing various XSS attacks (CWE-79). Example 2 Consider a chat application in which a front-end web application communicates with a back-end server. The back-end is legacy code that does not perform authentication or authorization, so the front-end must implement it. The chat protocol supports two commands, SAY and BAN, although only administrators can use the BAN command. Each argument must be separated by a single space. The raw inputs are URL-encoded. The messaging protocol allows multiple commands to be specified on the same line if they are separated by a "|" character. First let's look at the back end command processor code (bad code)
Example Language: Perl
$inputString = readLineFromFileHandle($serverFH);
# generate an array of strings separated by the "|" character. @commands = split(/\|/, $inputString); foreach $cmd (@commands) { # separate the operator from its arguments based on a single whitespace ($operator, $args) = split(/ /, $cmd, 2); $args = UrlDecode($args); if ($operator eq "BAN") { ExecuteBan($args); }elsif ($operator eq "SAY") { ExecuteSay($args); }The front end web application receives a command, encodes it for sending to the server, performs the authorization check, and sends the command to the server. (bad code)
Example Language: Perl
$inputString = GetUntrustedArgument("command");
($cmd, $argstr) = split(/\s+/, $inputString, 2); # removes extra whitespace and also changes CRLF's to spaces $argstr =~ s/\s+/ /gs; $argstr = UrlEncode($argstr); if (($cmd eq "BAN") && (! IsAdministrator($username))) { die "Error: you are not the admin.\n"; }# communicate with file server using a file handle $fh = GetServerFileHandle("myserver"); print $fh "$cmd $argstr\n"; It is clear that, while the protocol and back-end allow multiple commands to be sent in a single request, the front end only intends to send a single command. However, the UrlEncode function could leave the "|" character intact. If an attacker provides: (attack code)
SAY hello world|BAN user12
then the front end will see this is a "SAY" command, and the $argstr will look like "hello world | BAN user12". Since the command is "SAY", the check for the "BAN" command will fail, and the front end will send the URL-encoded command to the back end: (result)
SAY hello%20world|BAN%20user12
The back end, however, will treat these as two separate commands: (result)
SAY hello world
BAN user12 Notice, however, that if the front end properly encodes the "|" with "%7C", then the back end will only process a single command. Example 3 This example takes user input, passes it through an encoding scheme and then creates a directory specified by the user. (bad code)
Example Language: Perl
sub GetUntrustedInput {
return($ARGV[0]); }sub encode { my($str) = @_; }$str =~ s/\&/\&/gs; $str =~ s/\"/\"/gs; $str =~ s/\'/\'/gs; $str =~ s/\</\</gs; $str =~ s/\>/\>/gs; return($str); sub doit { my $uname = encode(GetUntrustedInput("username")); }print "<b>Welcome, $uname!</b><p>\n"; system("cd /home/$uname; /bin/ls -l"); The programmer attempts to encode dangerous characters, however the denylist for encoding is incomplete (CWE-184) and an attacker can still pass a semicolon, resulting in a chain with command injection (CWE-77). Additionally, the encoding routine is used inappropriately with command execution. An attacker doesn't even need to insert their own semicolon. The attacker can instead leverage the encoding routine to provide the semicolon to separate the commands. If an attacker supplies a string of the form: (attack code)
' pwd
then the program will encode the apostrophe and insert the semicolon, which functions as a command separator when passed to the system function. This allows the attacker to complete the command injection.
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Relationship
This weakness is primary to all weaknesses related to injection (CWE-74) since the inherent nature of injection involves the violation of structured messages.
Relationship CWE-116 and CWE-20 have a close association because, depending on the nature of the structured message, proper input validation can indirectly prevent special characters from changing the meaning of a structured message. For example, by validating that a numeric ID field should only contain the 0-9 characters, the programmer effectively prevents injection attacks. However, input validation is not always sufficient, especially when less stringent data types must be supported, such as free-form text. Consider a SQL injection scenario in which a last name is inserted into a query. The name "O'Reilly" would likely pass the validation step since it is a common last name in the English language. However, it cannot be directly inserted into the database because it contains the "'" apostrophe character, which would need to be escaped or otherwise neutralized. In this case, stripping the apostrophe might reduce the risk of SQL injection, but it would produce incorrect behavior because the wrong name would be recorded. Terminology
The usage of the "encoding" and "escaping" terms varies widely. For example, in some programming languages, the terms are used interchangeably, while other languages provide APIs that use both terms for different tasks. This overlapping usage extends to the Web, such as the "escape" JavaScript function whose purpose is stated to be encoding. The concepts of encoding and escaping predate the Web by decades. Given such a context, it is difficult for CWE to adopt a consistent vocabulary that will not be misinterpreted by some constituency.
Theoretical
This is a data/directive boundary error in which data boundaries are not sufficiently enforced before it is sent to a different control sphere.
Research Gap
While many published vulnerabilities are related to insufficient output encoding, there is such an emphasis on input validation as a protection mechanism that the underlying causes are rarely described. Within CVE, the focus is primarily on well-understood issues like cross-site scripting and SQL injection. It is likely that this weakness frequently occurs in custom protocols that support multiple encodings, which are not necessarily detectable with automated techniques.
CWE-573: Improper Following of Specification by Caller
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Edit Custom FilterThe product does not follow or incorrectly follows the specifications as required by the implementation language, environment, framework, protocol, or platform.
When leveraging external functionality, such as an API, it is important that the caller does so in accordance with the requirements of the external functionality or else unintended behaviors may result, possibly leaving the system vulnerable to any number of exploits.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
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relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
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Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
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CWE-409: Improper Handling of Highly Compressed Data (Data Amplification)
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Edit Custom FilterThe product does not handle or incorrectly handles a compressed input with a very high compression ratio that produces a large output.
An example of data amplification is a "decompression bomb," a small ZIP file that can produce a large amount of data when it is decompressed.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The DTD and the very brief XML below illustrate what is meant by an XML bomb. The ZERO entity contains one character, the letter A. The choice of entity name ZERO is being used to indicate length equivalent to that exponent on two, that is, the length of ZERO is 2^0. Similarly, ONE refers to ZERO twice, therefore the XML parser will expand ONE to a length of 2, or 2^1. Ultimately, we reach entity THIRTYTWO, which will expand to 2^32 characters in length, or 4 GB, probably consuming far more data than expected. (attack code)
Example Language: XML
<?xml version="1.0"?>
<!DOCTYPE MaliciousDTD [ <!ENTITY ZERO "A"> <!ENTITY ONE "&ZERO;&ZERO;"> <!ENTITY TWO "&ONE;&ONE;"> ... <!ENTITY THIRTYTWO "&THIRTYONE;&THIRTYONE;"> ]> <data>&THIRTYTWO;</data>
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CWE-333: Improper Handling of Insufficient Entropy in TRNG
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Edit Custom FilterTrue random number generators (TRNG) generally have a limited source of entropy and therefore can fail or block.
The rate at which true random numbers can be generated is limited. It is important that one uses them only when they are needed for security.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 This code uses a TRNG to generate a unique session id for new connections to a server: (bad code)
Example Language: C
while (1){
if (haveNewConnection()){
if (hwRandom()){
int sessionID = hwRandom(); } } }createNewConnection(sessionID); This code does not attempt to limit the number of new connections or make sure the TRNG can successfully generate a new random number. An attacker may be able to create many new connections and exhaust the entropy of the TRNG. The TRNG may then block and cause the program to crash or hang.
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Maintenance
As of CWE 4.5, terminology related to randomness, entropy, and
predictability can vary widely. Within the developer and other
communities, "randomness" is used heavily. However, within
cryptography, "entropy" is distinct, typically implied as a
measurement. There are no commonly-used definitions, even within
standards documents and cryptography papers. Future versions of
CWE will attempt to define these terms and, if necessary,
distinguish between them in ways that are appropriate for
different communities but do not reduce the usability of CWE for
mapping, understanding, or other scenarios.
CWE-230: Improper Handling of Missing Values
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Edit Custom FilterThe product does not handle or incorrectly handles when a parameter, field, or argument name is specified, but the associated value is missing, i.e. it is empty, blank, or null.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 This Android application has registered to handle a URL when sent an intent: (bad code)
Example Language: Java
... IntentFilter filter = new IntentFilter("com.example.URLHandler.openURL"); MyReceiver receiver = new MyReceiver(); registerReceiver(receiver, filter); ... public class UrlHandlerReceiver extends BroadcastReceiver { @Override
public void onReceive(Context context, Intent intent) { if("com.example.URLHandler.openURL".equals(intent.getAction())) {
String URL = intent.getStringExtra("URLToOpen");
int length = URL.length(); ... } The application assumes the URL will always be included in the intent. When the URL is not present, the call to getStringExtra() will return null, thus causing a null pointer exception when length() is called.
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Research Gap
Some "crash by port scan" bugs are probably due to this, but lack of diagnosis makes it difficult to be certain.
CWE-232: Improper Handling of Undefined Values
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Edit Custom FilterThe product does not handle or incorrectly handles when a value is not defined or supported for the associated parameter, field, or argument name.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 In this example, an address parameter is read and trimmed of whitespace. (bad code)
Example Language: Java
String address = request.getParameter("address");
address = address.trim(); String updateString = "UPDATE shippingInfo SET address='?' WHERE email='cwe@example.com'"; emailAddress = con.prepareStatement(updateString); emailAddress.setString(1, address); If the value of the address parameter is null (undefined), the servlet will throw a NullPointerException when the trim() is attempted.
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weakness fits within the context of external information sources.
CWE-67: Improper Handling of Windows Device Names
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Edit Custom FilterThe product constructs pathnames from user input, but it does not handle or incorrectly handles a pathname containing a Windows device name such as AUX or CON. This typically leads to denial of service or an information exposure when the application attempts to process the pathname as a regular file.
Not properly handling virtual filenames (e.g. AUX, CON, PRN, COM1, LPT1) can result in different types of vulnerabilities. In some cases an attacker can request a device via injection of a virtual filename in a URL, which may cause an error that leads to a denial of service or an error page that reveals sensitive information. A product that allows device names to bypass filtering runs the risk of an attacker injecting malicious code in a file with the name of a device.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Operating Systems Class: Windows (Undetermined Prevalence)
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weakness fits within the context of external information sources.
CWE-665: Improper Initialization
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Edit Custom FilterThe product does not initialize or incorrectly initializes a resource, which might leave the resource in an unexpected state when it is accessed or used.
This can have security implications when the associated resource is expected to have certain properties or values, such as a variable that determines whether a user has been authenticated or not.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 Here, a boolean initiailized field is consulted to ensure that initialization tasks are only completed once. However, the field is mistakenly set to true during static initialization, so the initialization code is never reached. (bad code)
Example Language: Java
private boolean initialized = true;
public void someMethod() { if (!initialized) {
// perform initialization tasks ... initialized = true; Example 2 The following code intends to limit certain operations to the administrator only. (bad code)
Example Language: Perl
$username = GetCurrentUser();
$state = GetStateData($username); if (defined($state)) { $uid = ExtractUserID($state); }# do stuff if ($uid == 0) { DoAdminThings(); }If the application is unable to extract the state information - say, due to a database timeout - then the $uid variable will not be explicitly set by the programmer. This will cause $uid to be regarded as equivalent to "0" in the conditional, allowing the original user to perform administrator actions. Even if the attacker cannot directly influence the state data, unexpected errors could cause incorrect privileges to be assigned to a user just by accident. Example 3 The following code intends to concatenate a string to a variable and print the string. (bad code)
Example Language: C
char str[20];
strcat(str, "hello world"); printf("%s", str); This might seem innocent enough, but str was not initialized, so it contains random memory. As a result, str[0] might not contain the null terminator, so the copy might start at an offset other than 0. The consequences can vary, depending on the underlying memory. If a null terminator is found before str[8], then some bytes of random garbage will be printed before the "hello world" string. The memory might contain sensitive information from previous uses, such as a password (which might occur as a result of CWE-14 or CWE-244). In this example, it might not be a big deal, but consider what could happen if large amounts of memory are printed out before the null terminator is found. If a null terminator isn't found before str[8], then a buffer overflow could occur, since strcat will first look for the null terminator, then copy 12 bytes starting with that location. Alternately, a buffer over-read might occur (CWE-126) if a null terminator isn't found before the end of the memory segment is reached, leading to a segmentation fault and crash.
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CWE-667: Improper Locking
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Edit Custom FilterThe product does not properly acquire or release a lock on a resource, leading to unexpected resource state changes and behaviors.
Locking is a type of synchronization behavior that ensures that multiple independently-operating processes or threads do not interfere with each other when accessing the same resource. All processes/threads are expected to follow the same steps for locking. If these steps are not followed precisely - or if no locking is done at all - then another process/thread could modify the shared resource in a way that is not visible or predictable to the original process. This can lead to data or memory corruption, denial of service, etc. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
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weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
Example 1 In the following Java snippet, methods are defined to get and set a long field in an instance of a class that is shared across multiple threads. Because operations on double and long are nonatomic in Java, concurrent access may cause unexpected behavior. Thus, all operations on long and double fields should be synchronized. (bad code)
Example Language: Java
private long someLongValue;
public long getLongValue() { return someLongValue; }public void setLongValue(long l) { someLongValue = l; }Example 2 This code tries to obtain a lock for a file, then writes to it. (bad code)
Example Language: PHP
function writeToLog($message){
$logfile = fopen("logFile.log", "a"); }//attempt to get logfile lock if (flock($logfile, LOCK_EX)) { fwrite($logfile,$message); }// unlock logfile flock($logfile, LOCK_UN); else { print "Could not obtain lock on logFile.log, message not recorded\n"; }fclose($logFile); PHP by default will wait indefinitely until a file lock is released. If an attacker is able to obtain the file lock, this code will pause execution, possibly leading to denial of service for other users. Note that in this case, if an attacker can perform an flock() on the file, they may already have privileges to destroy the log file. However, this still impacts the execution of other programs that depend on flock(). Example 3 The following function attempts to acquire a lock in order to perform operations on a shared resource. (bad code)
Example Language: C
void f(pthread_mutex_t *mutex) {
pthread_mutex_lock(mutex);
/* access shared resource */ pthread_mutex_unlock(mutex); However, the code does not check the value returned by pthread_mutex_lock() for errors. If pthread_mutex_lock() cannot acquire the mutex for any reason, the function may introduce a race condition into the program and result in undefined behavior. In order to avoid data races, correctly written programs must check the result of thread synchronization functions and appropriately handle all errors, either by attempting to recover from them or reporting them to higher levels. (good code)
Example Language: C
int f(pthread_mutex_t *mutex) {
int result;
result = pthread_mutex_lock(mutex); if (0 != result) return result;
/* access shared resource */ return pthread_mutex_unlock(mutex); Example 4 It may seem that the following bit of code achieves thread safety while avoiding unnecessary synchronization... (bad code)
Example Language: Java
if (helper == null) {
synchronized (this) {
if (helper == null) { }helper = new Helper(); }return helper; The programmer wants to guarantee that only one Helper() object is ever allocated, but does not want to pay the cost of synchronization every time this code is called. Suppose that helper is not initialized. Then, thread A sees that helper==null and enters the synchronized block and begins to execute: (bad code)
helper = new Helper();
If a second thread, thread B, takes over in the middle of this call and helper has not finished running the constructor, then thread B may make calls on helper while its fields hold incorrect values.
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Maintenance
Deeper research is necessary for synchronization and related mechanisms, including locks, mutexes, semaphores, and other mechanisms. Multiple entries are dependent on this research, which includes relationships to concurrency, race conditions, reentrant functions, etc. CWE-662 and its children - including CWE-667, CWE-820, CWE-821, and others - may need to be modified significantly, along with their relationships.
CWE-150: Improper Neutralization of Escape, Meta, or Control Sequences
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Edit Custom FilterThe product receives input from an upstream component, but it does not neutralize or incorrectly neutralizes special elements that could be interpreted as escape, meta, or control character sequences when they are sent to a downstream component.
As data is parsed, an injected/absent/malformed delimiter may cause the process to take unexpected actions.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence)
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-144: Improper Neutralization of Line Delimiters
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Edit Custom FilterThe product receives input from an upstream component, but it does not neutralize or incorrectly neutralizes special elements that could be interpreted as line delimiters when they are sent to a downstream component.
As data is parsed, an injected/absent/malformed delimiter may cause the process to take unexpected actions.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence)
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Relationship
Depending on the language and syntax being used, this could be the same as the record delimiter (CWE-143).
CWE-78: Improper Neutralization of Special Elements used in an OS Command ('OS Command Injection')
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Edit Custom FilterThis weakness can lead to a vulnerability in environments in which the attacker does not have direct access to the operating system, such as in web applications. Alternately, if the weakness occurs in a privileged program, it could allow the attacker to specify commands that normally would not be accessible, or to call alternate commands with privileges that the attacker does not have. The problem is exacerbated if the compromised process does not follow the principle of least privilege, because the attacker-controlled commands may run with special system privileges that increases the amount of damage. There are at least two subtypes of OS command injection:
From a weakness standpoint, these variants represent distinct programmer errors. In the first variant, the programmer clearly intends that input from untrusted parties will be part of the arguments in the command to be executed. In the second variant, the programmer does not intend for the command to be accessible to any untrusted party, but the programmer probably has not accounted for alternate ways in which malicious attackers can provide input. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 This example code intends to take the name of a user and list the contents of that user's home directory. It is subject to the first variant of OS command injection. (bad code)
Example Language: PHP
$userName = $_POST["user"];
$command = 'ls -l /home/' . $userName; system($command); The $userName variable is not checked for malicious input. An attacker could set the $userName variable to an arbitrary OS command such as: (attack code)
;rm -rf /
Which would result in $command being: (result)
ls -l /home/;rm -rf /
Since the semi-colon is a command separator in Unix, the OS would first execute the ls command, then the rm command, deleting the entire file system. Also note that this example code is vulnerable to Path Traversal (CWE-22) and Untrusted Search Path (CWE-426) attacks. Example 2 The following simple program accepts a filename as a command line argument and displays the contents of the file back to the user. The program is installed setuid root because it is intended for use as a learning tool to allow system administrators in-training to inspect privileged system files without giving them the ability to modify them or damage the system. (bad code)
Example Language: C
int main(int argc, char** argv) {
char cmd[CMD_MAX] = "/usr/bin/cat "; }strcat(cmd, argv[1]); system(cmd); Because the program runs with root privileges, the call to system() also executes with root privileges. If a user specifies a standard filename, the call works as expected. However, if an attacker passes a string of the form ";rm -rf /", then the call to system() fails to execute cat due to a lack of arguments and then plows on to recursively delete the contents of the root partition. Note that if argv[1] is a very long argument, then this issue might also be subject to a buffer overflow (CWE-120). Example 3 This example is a web application that intends to perform a DNS lookup of a user-supplied domain name. It is subject to the first variant of OS command injection. (bad code)
Example Language: Perl
use CGI qw(:standard);
$name = param('name'); $nslookup = "/path/to/nslookup"; print header; if (open($fh, "$nslookup $name|")) { while (<$fh>) { }print escapeHTML($_); }print "<br>\n"; close($fh); Suppose an attacker provides a domain name like this: (attack code)
cwe.mitre.org%20%3B%20/bin/ls%20-l
The "%3B" sequence decodes to the ";" character, and the %20 decodes to a space. The open() statement would then process a string like this: (result)
/path/to/nslookup cwe.mitre.org ; /bin/ls -l
As a result, the attacker executes the "/bin/ls -l" command and gets a list of all the files in the program's working directory. The input could be replaced with much more dangerous commands, such as installing a malicious program on the server. Example 4 The example below reads the name of a shell script to execute from the system properties. It is subject to the second variant of OS command injection. (bad code)
Example Language: Java
String script = System.getProperty("SCRIPTNAME");
if (script != null) System.exec(script);
If an attacker has control over this property, then they could modify the property to point to a dangerous program. Example 5 In the example below, a method is used to transform geographic coordinates from latitude and longitude format to UTM format. The method gets the input coordinates from a user through a HTTP request and executes a program local to the application server that performs the transformation. The method passes the latitude and longitude coordinates as a command-line option to the external program and will perform some processing to retrieve the results of the transformation and return the resulting UTM coordinates. (bad code)
Example Language: Java
public String coordinateTransformLatLonToUTM(String coordinates)
{ String utmCoords = null;
try { String latlonCoords = coordinates;
Runtime rt = Runtime.getRuntime(); Process exec = rt.exec("cmd.exe /C latlon2utm.exe -" + latlonCoords); // process results of coordinate transform // ... catch(Exception e) {...} return utmCoords; However, the method does not verify that the contents of the coordinates input parameter includes only correctly-formatted latitude and longitude coordinates. If the input coordinates were not validated prior to the call to this method, a malicious user could execute another program local to the application server by appending '&' followed by the command for another program to the end of the coordinate string. The '&' instructs the Windows operating system to execute another program. Example 6 The following code is from an administrative web application designed to allow users to kick off a backup of an Oracle database using a batch-file wrapper around the rman utility and then run a cleanup.bat script to delete some temporary files. The script rmanDB.bat accepts a single command line parameter, which specifies what type of backup to perform. Because access to the database is restricted, the application runs the backup as a privileged user. (bad code)
Example Language: Java
...
String btype = request.getParameter("backuptype"); String cmd = new String("cmd.exe /K \" c:\\util\\rmanDB.bat "
+btype+ "&&c:\\utl\\cleanup.bat\"") System.Runtime.getRuntime().exec(cmd); ... The problem here is that the program does not do any validation on the backuptype parameter read from the user. Typically the Runtime.exec() function will not execute multiple commands, but in this case the program first runs the cmd.exe shell in order to run multiple commands with a single call to Runtime.exec(). Once the shell is invoked, it will happily execute multiple commands separated by two ampersands. If an attacker passes a string of the form "& del c:\\dbms\\*.*", then the application will execute this command along with the others specified by the program. Because of the nature of the application, it runs with the privileges necessary to interact with the database, which means whatever command the attacker injects will run with those privileges as well. Example 7 The following code is a wrapper around the UNIX command cat which prints the contents of a file to standard out. It is also injectable: (bad code)
Example Language: C
#include <stdio.h>
#include <unistd.h> int main(int argc, char **argv) { char cat[] = "cat "; char *command; size_t commandLength; commandLength = strlen(cat) + strlen(argv[1]) + 1; command = (char *) malloc(commandLength); strncpy(command, cat, commandLength); strncat(command, argv[1], (commandLength - strlen(cat)) ); system(command); return (0); Used normally, the output is simply the contents of the file requested, such as Story.txt: (informative)
./catWrapper Story.txt
(result)
When last we left our heroes...
However, if the provided argument includes a semicolon and another command, such as: (attack code)
Story.txt; ls
Then the "ls" command is executed by catWrapper with no complaint: (result)
./catWrapper Story.txt; ls
Two commands would then be executed: catWrapper, then ls. The result might look like: (result)
When last we left our heroes...
Story.txt SensitiveFile.txt PrivateData.db a.out* If catWrapper had been set to have a higher privilege level than the standard user, arbitrary commands could be executed with that higher privilege.
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weakness fits within the context of external information sources.
Terminology
The "OS command injection" phrase carries different meanings to different people. For some people, it only refers to cases in which the attacker injects command separators into arguments for an application-controlled program that is being invoked. For some people, it refers to any type of attack that can allow the attacker to execute OS commands of their own choosing. This usage could include untrusted search path weaknesses (CWE-426) that cause the application to find and execute an attacker-controlled program. Further complicating the issue is the case when argument injection (CWE-88) allows alternate command-line switches or options to be inserted into the command line, such as an "-exec" switch whose purpose may be to execute the subsequent argument as a command (this -exec switch exists in the UNIX "find" command, for example). In this latter case, however, CWE-88 could be regarded as the primary weakness in a chain with CWE-78.
Research Gap
More investigation is needed into the distinction between the OS command injection variants, including the role with argument injection (CWE-88). Equivalent distinctions may exist in other injection-related problems such as SQL injection.
CWE-413: Improper Resource Locking
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Edit Custom FilterThe product does not lock or does not correctly lock a resource when the product must have exclusive access to the resource.
When a resource is not properly locked, an attacker could modify the resource while it is being operated on by the product. This might violate the product's assumption that the resource will not change, potentially leading to unexpected behaviors.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following function attempts to acquire a lock in order to perform operations on a shared resource. (bad code)
Example Language: C
void f(pthread_mutex_t *mutex) {
pthread_mutex_lock(mutex);
/* access shared resource */ pthread_mutex_unlock(mutex); However, the code does not check the value returned by pthread_mutex_lock() for errors. If pthread_mutex_lock() cannot acquire the mutex for any reason, the function may introduce a race condition into the program and result in undefined behavior. In order to avoid data races, correctly written programs must check the result of thread synchronization functions and appropriately handle all errors, either by attempting to recover from them or reporting them to higher levels. (good code)
Example Language: C
int f(pthread_mutex_t *mutex) {
int result;
result = pthread_mutex_lock(mutex); if (0 != result) return result;
/* access shared resource */ return pthread_mutex_unlock(mutex); Example 2 This Java example shows a simple BankAccount class with deposit and withdraw methods. (bad code)
Example Language: Java
public class BankAccount {
// variable for bank account balance private double accountBalance; // constructor for BankAccount public BankAccount() { accountBalance = 0; }// method to deposit amount into BankAccount public void deposit(double depositAmount) { double newBalance = accountBalance + depositAmount; accountBalance = newBalance; // method to withdraw amount from BankAccount public void withdraw(double withdrawAmount) { double newBalance = accountBalance - withdrawAmount; accountBalance = newBalance; // other methods for accessing the BankAccount object ... However, the deposit and withdraw methods have shared access to the account balance private class variable. This can result in a race condition if multiple threads attempt to call the deposit and withdraw methods simultaneously where the account balance is modified by one thread before another thread has completed modifying the account balance. For example, if a thread attempts to withdraw funds using the withdraw method before another thread that is depositing funds using the deposit method completes the deposit then there may not be sufficient funds for the withdraw transaction. To prevent multiple threads from having simultaneous access to the account balance variable the deposit and withdraw methods should be synchronized using the synchronized modifier. (good code)
Example Language: Java
public class BankAccount {
...
// synchronized method to deposit amount into BankAccount public synchronized void deposit(double depositAmount) { ... }// synchronized method to withdraw amount from BankAccount public synchronized void withdraw(double withdrawAmount) { ... }... An alternative solution is to use a lock object to ensure exclusive access to the bank account balance variable. As shown below, the deposit and withdraw methods use the lock object to set a lock to block access to the BankAccount object from other threads until the method has completed updating the bank account balance variable. (good code)
Example Language: Java
public class BankAccount {
...
// lock object for thread access to methods private ReentrantLock balanceChangeLock; // condition object to temporarily release lock to other threads private Condition sufficientFundsCondition; // method to deposit amount into BankAccount public void deposit(double amount) { // set lock to block access to BankAccount from other threads balanceChangeLock.lock(); try { double newBalance = balance + amount;
balance = newBalance; // inform other threads that funds are available sufficientFundsCondition.signalAll(); finally { // unlock lock object }balanceChangeLock.unlock(); // method to withdraw amount from bank account public void withdraw(double amount) { // set lock to block access to BankAccount from other threads balanceChangeLock.lock(); try { while (balance < amount) {
// temporarily unblock access // until sufficient funds are available sufficientFundsCondition.await(); double newBalance = balance - amount; balance = newBalance; finally { // unlock lock object }balanceChangeLock.unlock(); ...
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weakness fits within the context of external information sources.
CWE-404: Improper Resource Shutdown or Release
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Edit Custom FilterThe product does not release or incorrectly releases a resource before it is made available for re-use.
When a resource is created or allocated, the developer is responsible for properly releasing the resource as well as accounting for all potential paths of expiration or invalidation, such as a set period of time or revocation.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following method never closes the new file handle. Given enough time, the Finalize() method for BufferReader should eventually call Close(), but there is no guarantee as to how long this action will take. In fact, there is no guarantee that Finalize() will ever be invoked. In a busy environment, the Operating System could use up all of the available file handles before the Close() function is called. (bad code)
Example Language: Java
private void processFile(string fName)
{ BufferReader fil = new BufferReader(new FileReader(fName)); }String line; while ((line = fil.ReadLine()) != null) { processLine(line); }The good code example simply adds an explicit call to the Close() function when the system is done using the file. Within a simple example such as this the problem is easy to see and fix. In a real system, the problem may be considerably more obscure. (good code)
Example Language: Java
private void processFile(string fName)
{ BufferReader fil = new BufferReader(new FileReader(fName)); }String line; while ((line = fil.ReadLine()) != null) { processLine(line); }fil.Close(); Example 2 This code attempts to open a connection to a database and catches any exceptions that may occur. (bad code)
Example Language: Java
try {
Connection con = DriverManager.getConnection(some_connection_string); }catch ( Exception e ) { log( e ); }If an exception occurs after establishing the database connection and before the same connection closes, the pool of database connections may become exhausted. If the number of available connections is exceeded, other users cannot access this resource, effectively denying access to the application. Example 3 Under normal conditions the following C# code executes a database query, processes the results returned by the database, and closes the allocated SqlConnection object. But if an exception occurs while executing the SQL or processing the results, the SqlConnection object is not closed. If this happens often enough, the database will run out of available cursors and not be able to execute any more SQL queries. (bad code)
Example Language: C#
...
SqlConnection conn = new SqlConnection(connString); SqlCommand cmd = new SqlCommand(queryString); cmd.Connection = conn; conn.Open(); SqlDataReader rdr = cmd.ExecuteReader(); HarvestResults(rdr); conn.Connection.Close(); ... Example 4 The following C function does not close the file handle it opens if an error occurs. If the process is long-lived, the process can run out of file handles. (bad code)
Example Language: C
int decodeFile(char* fName) {
char buf[BUF_SZ];
FILE* f = fopen(fName, "r"); if (!f) { printf("cannot open %s\n", fName); }return DECODE_FAIL; else { while (fgets(buf, BUF_SZ, f)) {
if (!checkChecksum(buf)) { }return DECODE_FAIL; }else { decodeBlock(buf); }fclose(f); return DECODE_SUCCESS; Example 5 In this example, the program does not use matching functions such as malloc/free, new/delete, and new[]/delete[] to allocate/deallocate the resource. (bad code)
Example Language: C++
class A {
void foo(); };void A::foo(){ int *ptr; }ptr = (int*)malloc(sizeof(int)); delete ptr; Example 6 In this example, the program calls the delete[] function on non-heap memory. (bad code)
Example Language: C++
class A{
void foo(bool); };void A::foo(bool heap) { int localArray[2] = { }11,22 };int *p = localArray; if (heap){ p = new int[2]; }delete[] p;
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-662: Improper Synchronization
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Edit Custom FilterThe product utilizes multiple threads or processes to allow temporary access to a shared resource that can only be exclusive to one process at a time, but it does not properly synchronize these actions, which might cause simultaneous accesses of this resource by multiple threads or processes.
Synchronization refers to a variety of behaviors and mechanisms that allow two or more independently-operating processes or threads to ensure that they operate on shared resources in predictable ways that do not interfere with each other. Some shared resource operations cannot be executed atomically; that is, multiple steps must be guaranteed to execute sequentially, without any interference by other processes. Synchronization mechanisms vary widely, but they may include locking, mutexes, and semaphores. When a multi-step operation on a shared resource cannot be guaranteed to execute independent of interference, then the resulting behavior can be unpredictable. Improper synchronization could lead to data or memory corruption, denial of service, etc. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
Example 1 The following function attempts to acquire a lock in order to perform operations on a shared resource. (bad code)
Example Language: C
void f(pthread_mutex_t *mutex) {
pthread_mutex_lock(mutex);
/* access shared resource */ pthread_mutex_unlock(mutex); However, the code does not check the value returned by pthread_mutex_lock() for errors. If pthread_mutex_lock() cannot acquire the mutex for any reason, the function may introduce a race condition into the program and result in undefined behavior. In order to avoid data races, correctly written programs must check the result of thread synchronization functions and appropriately handle all errors, either by attempting to recover from them or reporting them to higher levels. (good code)
Example Language: C
int f(pthread_mutex_t *mutex) {
int result;
result = pthread_mutex_lock(mutex); if (0 != result) return result;
/* access shared resource */ return pthread_mutex_unlock(mutex); Example 2 The following code intends to fork a process, then have both the parent and child processes print a single line. (bad code)
Example Language: C
static void print (char * string) {
char * word;
int counter; for (word = string; counter = *word++; ) { putc(counter, stdout);
fflush(stdout); /* Make timing window a little larger... */ sleep(1); int main(void) { pid_t pid;
pid = fork(); if (pid == -1) { exit(-2); }else if (pid == 0) { print("child\n"); }else { print("PARENT\n"); }exit(0); One might expect the code to print out something like:
PARENT
child
However, because the parent and child are executing concurrently, and stdout is flushed each time a character is printed, the output might be mixed together, such as:
PcAhRiElNdT
[blank line]
[blank line]
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Maintenance
Deeper research is necessary for synchronization and related mechanisms, including locks, mutexes, semaphores, and other mechanisms. Multiple entries are dependent on this research, which includes relationships to concurrency, race conditions, reentrant functions, etc. CWE-662 and its children - including CWE-667, CWE-820, CWE-821, and others - may need to be modified significantly, along with their relationships.
CWE-347: Improper Verification of Cryptographic Signature
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Edit Custom FilterThis table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 In the following code, a JarFile object is created from a downloaded file. (bad code)
Example Language: Java
File f = new File(downloadedFilePath);
JarFile jf = new JarFile(f); The JAR file that was potentially downloaded from an untrusted source is created without verifying the signature (if present). An alternate constructor that accepts a boolean verify parameter should be used instead.
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-838: Inappropriate Encoding for Output Context
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Edit Custom FilterThe product uses or specifies an encoding when generating output to a downstream component, but the specified encoding is not the same as the encoding that is expected by the downstream component.
This weakness can cause the downstream component to use a decoding method that produces different data than what the product intended to send. When the wrong encoding is used - even if closely related - the downstream component could decode the data incorrectly. This can have security consequences when the provided boundaries between control and data are inadvertently broken, because the resulting data could introduce control characters or special elements that were not sent by the product. The resulting data could then be used to bypass protection mechanisms such as input validation, and enable injection attacks. While using output encoding is essential for ensuring that communications between components are accurate, the use of the wrong encoding - even if closely related - could cause the downstream component to misinterpret the output. For example, HTML entity encoding is used for elements in the HTML body of a web page. However, a programmer might use entity encoding when generating output for that is used within an attribute of an HTML tag, which could contain functional Javascript that is not affected by the HTML encoding. While web applications have received the most attention for this problem, this weakness could potentially apply to any type of product that uses a communications stream that could support multiple encodings. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 This code dynamically builds an HTML page using POST data: (bad code)
Example Language: PHP
$username = $_POST['username'];
$picSource = $_POST['picsource']; $picAltText = $_POST['picalttext']; ... echo "<title>Welcome, " . htmlentities($username) ."</title>"; echo "<img src='". htmlentities($picSource) ." ' alt='". htmlentities($picAltText) . '" />'; ... The programmer attempts to avoid XSS exploits (CWE-79) by encoding the POST values so they will not be interpreted as valid HTML. However, the htmlentities() encoding is not appropriate when the data are used as HTML attributes, allowing more attributes to be injected. For example, an attacker can set picAltText to: (attack code)
"altTextHere' onload='alert(document.cookie)"
This will result in the generated HTML image tag: (result)
Example Language: HTML
<img src='pic.jpg' alt='altTextHere' onload='alert(document.cookie)' />
The attacker can inject arbitrary javascript into the tag due to this incorrect encoding.
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-459: Incomplete Cleanup
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Edit Custom FilterThe product does not properly "clean up" and remove temporary or supporting resources after they have been used.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 Stream resources in a Java application should be released in a finally block, otherwise an exception thrown before the call to close() would result in an unreleased I/O resource. In the example below, the close() method is called in the try block (incorrect). (bad code)
Example Language: Java
try {
InputStream is = new FileInputStream(path); } catch (Throwable t) {byte b[] = new byte[is.available()]; is.read(b); is.close(); log.error("Something bad happened: " + t.getMessage()); }
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Relationship
CWE-459 is a child of CWE-404 because, while CWE-404 covers any type of improper shutdown or release of a resource, CWE-459 deals specifically with a multi-step shutdown process in which a crucial step for "proper" cleanup is omitted or impossible. That is, CWE-459 deals specifically with a cleanup or shutdown process that does not successfully remove all potentially sensitive data.
Relationship
Overlaps other categories such as permissions and containment. Concept needs further development. This could be primary (e.g. leading to infoleak) or resultant (e.g. resulting from unhandled error conditions or early termination).
CWE-180: Incorrect Behavior Order: Validate Before Canonicalize
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Edit Custom FilterThe product validates input before it is canonicalized, which prevents the product from detecting data that becomes invalid after the canonicalization step.
This can be used by an attacker to bypass the validation and launch attacks that expose weaknesses that would otherwise be prevented, such as injection.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following code attempts to validate a given input path by checking it against an allowlist and then return the canonical path. In this specific case, the path is considered valid if it starts with the string "/safe_dir/". (bad code)
Example Language: Java
String path = getInputPath();
if (path.startsWith("/safe_dir/")) { File f = new File(path); }return f.getCanonicalPath(); The problem with the above code is that the validation step occurs before canonicalization occurs. An attacker could provide an input path of "/safe_dir/../" that would pass the validation step. However, the canonicalization process sees the double dot as a traversal to the parent directory and hence when canonicized the path would become just "/". To avoid this problem, validation should occur after canonicalization takes place. In this case canonicalization occurs during the initialization of the File object. The code below fixes the issue. (good code)
Example Language: Java
String path = getInputPath();
File f = new File(path); if (f.getCanonicalPath().startsWith("/safe_dir/")) { return f.getCanonicalPath(); }
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-135: Incorrect Calculation of Multi-Byte String Length
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Edit Custom FilterThe product does not correctly calculate the length of strings that can contain wide or multi-byte characters.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C (Undetermined Prevalence) C++ (Undetermined Prevalence) Example 1 The following example would be exploitable if any of the commented incorrect malloc calls were used. (bad code)
Example Language: C
#include <stdio.h>
#include <strings.h> #include <wchar.h> int main() { wchar_t wideString[] = L"The spazzy orange tiger jumped " \ "over the tawny jaguar."; wchar_t *newString; printf("Strlen() output: %d\nWcslen() output: %d\n", strlen(wideString), wcslen(wideString)); /* Wrong because the number of chars in a string isn't related to its length in bytes // newString = (wchar_t *) malloc(strlen(wideString)); */ /* Wrong because wide characters aren't 1 byte long! // newString = (wchar_t *) malloc(wcslen(wideString)); */ /* Wrong because wcslen does not include the terminating null */ newString = (wchar_t *) malloc(wcslen(wideString) * sizeof(wchar_t)); /* correct! */ newString = (wchar_t *) malloc((wcslen(wideString) + 1) * sizeof(wchar_t)); /* ... */ The output from the printf() statement would be: (result)
Strlen() output: 0
Wcslen() output: 53
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weakness fits within the context of external information sources.
CWE-705: Incorrect Control Flow Scoping
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Edit Custom FilterThe product does not properly return control flow to the proper location after it has completed a task or detected an unusual condition.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following example attempts to resolve a hostname. (bad code)
Example Language: Java
protected void doPost (HttpServletRequest req, HttpServletResponse res) throws IOException {
String ip = req.getRemoteAddr(); }InetAddress addr = InetAddress.getByName(ip); ... out.println("hello " + addr.getHostName()); A DNS lookup failure will cause the Servlet to throw an exception. Example 2 This code queries a server and displays its status when a request comes from an authorized IP address. (bad code)
Example Language: PHP
$requestingIP = $_SERVER['REMOTE_ADDR'];
if(!in_array($requestingIP,$ipAllowList)){ echo "You are not authorized to view this page"; }http_redirect($errorPageURL); $status = getServerStatus(); echo $status; ... This code redirects unauthorized users, but continues to execute code after calling http_redirect(). This means even unauthorized users may be able to access the contents of the page or perform a DoS attack on the server being queried. Also, note that this code is vulnerable to an IP address spoofing attack (CWE-212). Example 3 Included in the doPost() method defined below is a call to System.exit() in the event of a specific exception. (bad code)
Example Language: Java
Public void doPost(HttpServletRequest request, HttpServletResponse response) throws ServletException, IOException {
try { }... } catch (ApplicationSpecificException ase) {logger.error("Caught: " + ase.toString()); }System.exit(1);
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-681: Incorrect Conversion between Numeric Types
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Edit Custom FilterWhen converting from one data type to another, such as long to integer, data can be omitted or translated in a way that produces unexpected values. If the resulting values are used in a sensitive context, then dangerous behaviors may occur.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 In the following Java example, a float literal is cast to an integer, thus causing a loss of precision. (bad code)
Example Language: Java
int i = (int) 33457.8f;
Example 2 This code adds a float and an integer together, casting the result to an integer. (bad code)
Example Language: PHP
$floatVal = 1.8345;
$intVal = 3; $result = (int)$floatVal + $intVal; Normally, PHP will preserve the precision of this operation, making $result = 4.8345. After the cast to int, it is reasonable to expect PHP to follow rounding convention and set $result = 5. However, the explicit cast to int always rounds DOWN, so the final value of $result is 4. This behavior may have unintended consequences. Example 3 In this example the variable amount can hold a negative value when it is returned. Because the function is declared to return an unsigned int, amount will be implicitly converted to unsigned. (bad code)
Example Language: C
unsigned int readdata () {
int amount = 0; }... if (result == ERROR) amount = -1; ... return amount; If the error condition in the code above is met, then the return value of readdata() will be 4,294,967,295 on a system that uses 32-bit integers. Example 4 In this example, depending on the return value of accecssmainframe(), the variable amount can hold a negative value when it is returned. Because the function is declared to return an unsigned value, amount will be implicitly cast to an unsigned number. (bad code)
Example Language: C
unsigned int readdata () {
int amount = 0; }... amount = accessmainframe(); ... return amount; If the return value of accessmainframe() is -1, then the return value of readdata() will be 4,294,967,295 on a system that uses 32-bit integers.
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-276: Incorrect Default Permissions
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Edit Custom FilterDuring installation, installed file permissions are set to allow anyone to modify those files.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
Relevant to the view "Hardware Design" (CWE-1194)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Class: Not Technology-Specific (Undetermined Prevalence) Class: ICS/OT (Undetermined Prevalence)
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-279: Incorrect Execution-Assigned Permissions
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Edit Custom FilterWhile it is executing, the product sets the permissions of an object in a way that violates the intended permissions that have been specified by the user.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence)
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-732: Incorrect Permission Assignment for Critical Resource
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Edit Custom FilterThe product specifies permissions for a security-critical resource in a way that allows that resource to be read or modified by unintended actors.
When a resource is given a permission setting that provides access to a wider range of actors than required, it could lead to the exposure of sensitive information, or the modification of that resource by unintended parties. This is especially dangerous when the resource is related to program configuration, execution, or sensitive user data. For example, consider a misconfigured storage account for the cloud that can be read or written by a public or anonymous user.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Class: Not Technology-Specific (Undetermined Prevalence) Class: Cloud Computing (Often Prevalent) Example 1 The following code sets the umask of the process to 0 before creating a file and writing "Hello world" into the file. (bad code)
Example Language: C
#define OUTFILE "hello.out"
umask(0); FILE *out; /* Ignore link following (CWE-59) for brevity */ out = fopen(OUTFILE, "w"); if (out) { fprintf(out, "hello world!\n"); }fclose(out); After running this program on a UNIX system, running the "ls -l" command might return the following output: (result)
-rw-rw-rw- 1 username 13 Nov 24 17:58 hello.out
The "rw-rw-rw-" string indicates that the owner, group, and world (all users) can read the file and write to it. Example 2 This code creates a home directory for a new user, and makes that user the owner of the directory. If the new directory cannot be owned by the user, the directory is deleted. (bad code)
Example Language: PHP
function createUserDir($username){
$path = '/home/'.$username; }if(!mkdir($path)){ return false; }if(!chown($path,$username)){ rmdir($path); }return false; return true; Because the optional "mode" argument is omitted from the call to mkdir(), the directory is created with the default permissions 0777. Simply setting the new user as the owner of the directory does not explicitly change the permissions of the directory, leaving it with the default. This default allows any user to read and write to the directory, allowing an attack on the user's files. The code also fails to change the owner group of the directory, which may result in access by unexpected groups. This code may also be vulnerable to Path Traversal (CWE-22) attacks if an attacker supplies a non alphanumeric username. Example 3 The following code snippet might be used as a monitor to periodically record whether a web site is alive. To ensure that the file can always be modified, the code uses chmod() to make the file world-writable. (bad code)
Example Language: Perl
$fileName = "secretFile.out";
if (-e $fileName) { chmod 0777, $fileName; }my $outFH; if (! open($outFH, ">>$fileName")) { ExitError("Couldn't append to $fileName: $!"); }my $dateString = FormatCurrentTime(); my $status = IsHostAlive("cwe.mitre.org"); print $outFH "$dateString cwe status: $status!\n"; close($outFH); The first time the program runs, it might create a new file that inherits the permissions from its environment. A file listing might look like: (result)
-rw-r--r-- 1 username 13 Nov 24 17:58 secretFile.out
This listing might occur when the user has a default umask of 022, which is a common setting. Depending on the nature of the file, the user might not have intended to make it readable by everyone on the system. The next time the program runs, however - and all subsequent executions - the chmod will set the file's permissions so that the owner, group, and world (all users) can read the file and write to it: (result)
-rw-rw-rw- 1 username 13 Nov 24 17:58 secretFile.out
Perhaps the programmer tried to do this because a different process uses different permissions that might prevent the file from being updated. Example 4 This program creates and reads from an admin file to determine privilege information. If the admin file doesn't exist, the program will create one. In order to create the file, the program must have write privileges to write to the file. After the file is created, the permissions need to be changed to read only. (bad code)
Example Language: Go
const adminFile = "/etc/admin-users"
func createAdminFileIfNotExists() error {
file, err := os.Create(adminFile)
}if err != nil {
return err
}return nil
func changeModeOfAdminFile() error {
fileMode := os.FileMode(0440)
}if err := os.Chmod(adminFile, fileMode); err != nil {
return err
}return nil os.Create will create a file with 0666 permissions before umask if the specified file does not exist. A typical umask of 0022 would result in the file having 0644 permissions. That is, the file would have world-writable and world-readable permissions. In this scenario, it is advised to use the more customizable method of os.OpenFile with the os.O_WRONLY and os.O_CREATE flags specifying 0640 permissions to create the admin file. This is because on a typical system where the umask is 0022, the perm 0640 applied in os.OpenFile will result in a file of 0620 where only the owner and group can write. Example 5 The following command recursively sets world-readable permissions for a directory and all of its children: (bad code)
Example Language: Shell
chmod -R ugo+r DIRNAME
If this command is run from a program, the person calling the program might not expect that all the files under the directory will be world-readable. If the directory is expected to contain private data, this could become a security problem. Example 6 The following Azure command updates the settings for a storage account: (bad code)
Example Language: Shell
az storage account update --name <storage-account> --resource-group <resource-group> --allow-blob-public-access true
However, "Allow Blob Public Access" is set to true, meaning that anonymous/public users can access blobs. The command could be modified to disable "Allow Blob Public Access" by setting it to false. (good code)
Example Language: Shell
az storage account update --name <storage-account> --resource-group <resource-group> --allow-blob-public-access false
Example 7 The following Google Cloud Storage command gets the settings for a storage account named 'BUCKET_NAME': (informative)
Example Language: Shell
gsutil iam get gs://BUCKET_NAME
Suppose the command returns the following result: (bad code)
Example Language: JSON
{
"bindings":[{
}
"members":[
},
"projectEditor: PROJECT-ID",
],"projectOwner: PROJECT-ID" "role":"roles/storage.legacyBucketOwner" {
"members":[
]
"allUsers",
}"projectViewer: PROJECT-ID" ], "role":"roles/storage.legacyBucketReader" This result includes the "allUsers" or IAM role added as members, causing this policy configuration to allow public access to cloud storage resources. There would be a similar concern if "allAuthenticatedUsers" was present. The command could be modified to remove "allUsers" and/or "allAuthenticatedUsers" as follows: (good code)
Example Language: Shell
gsutil iam ch -d allUsers gs://BUCKET_NAME
gsutil iam ch -d allAuthenticatedUsers gs://BUCKET_NAME
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Maintenance
CWE-266: Incorrect Privilege Assignment
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Edit Custom FilterA product incorrectly assigns a privilege to a particular actor, creating an unintended sphere of control for that actor.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following example demonstrates the weakness. (bad code)
Example Language: C
seteuid(0);
/* do some stuff */ seteuid(getuid()); Example 2 The following example demonstrates the weakness. (bad code)
Example Language: Java
AccessController.doPrivileged(new PrivilegedAction() {
public Object run() {
// privileged code goes here, for example:
}System.loadLibrary("awt"); return null; // nothing to return Example 3 This application sends a special intent with a flag that allows the receiving application to read a data file for backup purposes. (bad code)
Example Language: Java
Intent intent = new Intent();
intent.setAction("com.example.BackupUserData"); intent.setData(file_uri); intent.addFlags(FLAG_GRANT_READ_URI_PERMISSION); sendBroadcast(intent); (attack code)
Example Language: Java
public class CallReceiver extends BroadcastReceiver {
@Override }public void onReceive(Context context, Intent intent) { Uri userData = intent.getData(); }stealUserData(userData); Any malicious application can register to receive this intent. Because of the FLAG_GRANT_READ_URI_PERMISSION included with the intent, the malicious receiver code can read the user's data.
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-377: Insecure Temporary File
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Edit Custom FilterCreating and using insecure temporary files can leave application and system data vulnerable to attack.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following code uses a temporary file for storing intermediate data gathered from the network before it is processed. (bad code)
Example Language: C
if (tmpnam_r(filename)) {
FILE* tmp = fopen(filename,"wb+"); while((recv(sock,recvbuf,DATA_SIZE, 0) > 0)&(amt!=0)) amt = fwrite(recvbuf,1,DATA_SIZE,tmp); ... This otherwise unremarkable code is vulnerable to a number of different attacks because it relies on an insecure method for creating temporary files. The vulnerabilities introduced by this function and others are described in the following sections. The most egregious security problems related to temporary file creation have occurred on Unix-based operating systems, but Windows applications have parallel risks. This section includes a discussion of temporary file creation on both Unix and Windows systems. Methods and behaviors can vary between systems, but the fundamental risks introduced by each are reasonably constant.
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Other Applications require temporary files so frequently that many different mechanisms exist for creating them in the C Library and Windows(R) API. Most of these functions are vulnerable to various forms of attacks. The functions designed to aid in the creation of temporary files can be broken into two groups based whether they simply provide a filename or actually open a new file. - Group 1: "Unique" Filenames: The first group of C Library and WinAPI functions designed to help with the process of creating temporary files do so by generating a unique file name for a new temporary file, which the program is then supposed to open. This group includes C Library functions like tmpnam(), tempnam(), mktemp() and their C++ equivalents prefaced with an _ (underscore) as well as the GetTempFileName() function from the Windows API. This group of functions suffers from an underlying race condition on the filename chosen. Although the functions guarantee that the filename is unique at the time it is selected, there is no mechanism to prevent another process or an attacker from creating a file with the same name after it is selected but before the application attempts to open the file. Beyond the risk of a legitimate collision caused by another call to the same function, there is a high probability that an attacker will be able to create a malicious collision because the filenames generated by these functions are not sufficiently randomized to make them difficult to guess. If a file with the selected name is created, then depending on how the file is opened the existing contents or access permissions of the file may remain intact. If the existing contents of the file are malicious in nature, an attacker may be able to inject dangerous data into the application when it reads data back from the temporary file. If an attacker pre-creates the file with relaxed access permissions, then data stored in the temporary file by the application may be accessed, modified or corrupted by an attacker. On Unix based systems an even more insidious attack is possible if the attacker pre-creates the file as a link to another important file. Then, if the application truncates or writes data to the file, it may unwittingly perform damaging operations for the attacker. This is an especially serious threat if the program operates with elevated permissions. Finally, in the best case the file will be opened with the a call to open() using the O_CREAT and O_EXCL flags or to CreateFile() using the CREATE_NEW attribute, which will fail if the file already exists and therefore prevent the types of attacks described above. However, if an attacker is able to accurately predict a sequence of temporary file names, then the application may be prevented from opening necessary temporary storage causing a denial of service (DoS) attack. This type of attack would not be difficult to mount given the small amount of randomness used in the selection of the filenames generated by these functions. - Group 2: "Unique" Files: The second group of C Library functions attempts to resolve some of the security problems related to temporary files by not only generating a unique file name, but also opening the file. This group includes C Library functions like tmpfile() and its C++ equivalents prefaced with an _ (underscore), as well as the slightly better-behaved C Library function mkstemp(). The tmpfile() style functions construct a unique filename and open it in the same way that fopen() would if passed the flags "wb+", that is, as a binary file in read/write mode. If the file already exists, tmpfile() will truncate it to size zero, possibly in an attempt to assuage the security concerns mentioned earlier regarding the race condition that exists between the selection of a supposedly unique filename and the subsequent opening of the selected file. However, this behavior clearly does not solve the function's security problems. First, an attacker can pre-create the file with relaxed access-permissions that will likely be retained by the file opened by tmpfile(). Furthermore, on Unix based systems if the attacker pre-creates the file as a link to another important file, the application may use its possibly elevated permissions to truncate that file, thereby doing damage on behalf of the attacker. Finally, if tmpfile() does create a new file, the access permissions applied to that file will vary from one operating system to another, which can leave application data vulnerable even if an attacker is unable to predict the filename to be used in advance. Finally, mkstemp() is a reasonably safe way create temporary files. It will attempt to create and open a unique file based on a filename template provided by the user combined with a series of randomly generated characters. If it is unable to create such a file, it will fail and return -1. On modern systems the file is opened using mode 0600, which means the file will be secure from tampering unless the user explicitly changes its access permissions. However, mkstemp() still suffers from the use of predictable file names and can leave an application vulnerable to denial of service attacks if an attacker causes mkstemp() to fail by predicting and pre-creating the filenames to be used.
CWE-532: Insertion of Sensitive Information into Log File
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Edit Custom FilterThis table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
Example 1 In the following code snippet, a user's full name and credit card number are written to a log file. (bad code)
Example Language: Java
logger.info("Username: " + usernme + ", CCN: " + ccn);
Example 2 This code stores location information about the current user: (bad code)
Example Language: Java
locationClient = new LocationClient(this, this, this);
locationClient.connect(); currentUser.setLocation(locationClient.getLastLocation()); ... catch (Exception e) { AlertDialog.Builder builder = new AlertDialog.Builder(this); }builder.setMessage("Sorry, this application has experienced an error."); AlertDialog alert = builder.create(); alert.show(); Log.e("ExampleActivity", "Caught exception: " + e + " While on User:" + User.toString()); When the application encounters an exception it will write the user object to the log. Because the user object contains location information, the user's location is also written to the log. Example 3 In the example below, the method getUserBankAccount retrieves a bank account object from a database using the supplied username and account number to query the database. If an SQLException is raised when querying the database, an error message is created and output to a log file. (bad code)
Example Language: Java
public BankAccount getUserBankAccount(String username, String accountNumber) {
BankAccount userAccount = null;
String query = null; try { if (isAuthorizedUser(username)) { } catch (SQLException ex) {query = "SELECT * FROM accounts WHERE owner = " }+ username + " AND accountID = " + accountNumber; DatabaseManager dbManager = new DatabaseManager(); Connection conn = dbManager.getConnection(); Statement stmt = conn.createStatement(); ResultSet queryResult = stmt.executeQuery(query); userAccount = (BankAccount)queryResult.getObject(accountNumber); String logMessage = "Unable to retrieve account information from database,\nquery: " + query; }Logger.getLogger(BankManager.class.getName()).log(Level.SEVERE, logMessage, ex); return userAccount; The error message that is created includes information about the database query that may contain sensitive information about the database or query logic. In this case, the error message will expose the table name and column names used in the database. This data could be used to simplify other attacks, such as SQL injection (CWE-89) to directly access the database.
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-332: Insufficient Entropy in PRNG
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Edit Custom FilterThe lack of entropy available for, or used by, a Pseudo-Random Number Generator (PRNG) can be a stability and security threat.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
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weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence)
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Maintenance
As of CWE 4.5, terminology related to randomness, entropy, and
predictability can vary widely. Within the developer and other
communities, "randomness" is used heavily. However, within
cryptography, "entropy" is distinct, typically implied as a
measurement. There are no commonly-used definitions, even within
standards documents and cryptography papers. Future versions of
CWE will attempt to define these terms and, if necessary,
distinguish between them in ways that are appropriate for
different communities but do not reduce the usability of CWE for
mapping, understanding, or other scenarios.
CWE-410: Insufficient Resource Pool
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Edit Custom FilterThe product's resource pool is not large enough to handle peak demand, which allows an attacker to prevent others from accessing the resource by using a (relatively) large number of requests for resources.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 In the following snippet from a Tomcat configuration file, a JDBC connection pool is defined with a maximum of 5 simultaneous connections (with a 60 second timeout). In this case, it may be trivial for an attacker to instigate a denial of service (DoS) by using up all of the available connections in the pool. (bad code)
Example Language: XML
<Resource name="jdbc/exampledb"
auth="Container" type="javax.sql.DataSource" removeAbandoned="true" removeAbandonedTimeout="30" maxActive="5" maxIdle="5" maxWait="60000" username="testuser" password="testpass" driverClassName="com.mysql.jdbc.Driver" url="jdbc:mysql://localhost/exampledb"/>
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CWE-382: J2EE Bad Practices: Use of System.exit()
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Edit Custom Filter
It is never a good idea for a web application to attempt to shut down the application container. Access to a function that can shut down the application is an avenue for Denial of Service (DoS) attacks.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 Included in the doPost() method defined below is a call to System.exit() in the event of a specific exception. (bad code)
Example Language: Java
Public void doPost(HttpServletRequest request, HttpServletResponse response) throws ServletException, IOException {
try { }... } catch (ApplicationSpecificException ase) {logger.error("Caught: " + ase.toString()); }System.exit(1);
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CWE-272: Least Privilege Violation
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Edit Custom FilterThe elevated privilege level required to perform operations such as chroot() should be dropped immediately after the operation is performed.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following example demonstrates the weakness. (bad code)
Example Language: C
setuid(0);
// Do some important stuff setuid(old_uid); // Do some non privileged stuff. Example 2 The following example demonstrates the weakness. (bad code)
Example Language: Java
AccessController.doPrivileged(new PrivilegedAction() {
public Object run() {
// privileged code goes here, for example:
}System.loadLibrary("awt"); return null; // nothing to return Example 3 The following code calls chroot() to restrict the application to a subset of the filesystem below APP_HOME in order to prevent an attacker from using the program to gain unauthorized access to files located elsewhere. The code then opens a file specified by the user and processes the contents of the file. (bad code)
Example Language: C
chroot(APP_HOME);
chdir("/"); FILE* data = fopen(argv[1], "r+"); ... Constraining the process inside the application's home directory before opening any files is a valuable security measure. However, the absence of a call to setuid() with some non-zero value means the application is continuing to operate with unnecessary root privileges. Any successful exploit carried out by an attacker against the application can now result in a privilege escalation attack because any malicious operations will be performed with the privileges of the superuser. If the application drops to the privilege level of a non-root user, the potential for damage is substantially reduced.
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Other If system privileges are not dropped when it is reasonable to do so, this is not a vulnerability by itself. According to the principle of least privilege, access should be allowed only when it is absolutely necessary to the function of a given system, and only for the minimal necessary amount of time. Any further allowance of privilege widens the window of time during which a successful exploitation of the system will provide an attacker with that same privilege. If at all possible, limit the allowance of system privilege to small, simple sections of code that may be called atomically. When a program calls a privileged function, such as chroot(), it must first acquire root privilege. As soon as the privileged operation has completed, the program should drop root privilege and return to the privilege level of the invoking user.
CWE-311: Missing Encryption of Sensitive Data
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Edit Custom FilterThe product does not encrypt sensitive or critical information before storage or transmission.
The lack of proper data encryption passes up the guarantees of confidentiality, integrity, and accountability that properly implemented encryption conveys.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 This code writes a user's login information to a cookie so the user does not have to login again later. (bad code)
Example Language: PHP
function persistLogin($username, $password){
$data = array("username" => $username, "password"=> $password); }setcookie ("userdata", $data); The code stores the user's username and password in plaintext in a cookie on the user's machine. This exposes the user's login information if their computer is compromised by an attacker. Even if the user's machine is not compromised, this weakness combined with cross-site scripting (CWE-79) could allow an attacker to remotely copy the cookie. Also note this example code also exhibits Plaintext Storage in a Cookie (CWE-315). Example 2 The following code attempts to establish a connection, read in a password, then store it to a buffer. (bad code)
Example Language: C
server.sin_family = AF_INET; hp = gethostbyname(argv[1]);
if (hp==NULL) error("Unknown host"); memcpy( (char *)&server.sin_addr,(char *)hp->h_addr,hp->h_length); if (argc < 3) port = 80; else port = (unsigned short)atoi(argv[3]); server.sin_port = htons(port); if (connect(sock, (struct sockaddr *)&server, sizeof server) < 0) error("Connecting"); ... while ((n=read(sock,buffer,BUFSIZE-1))!=-1) { write(dfd,password_buffer,n); ... While successful, the program does not encrypt the data before writing it to a buffer, possibly exposing it to unauthorized actors. Example 3 The following code attempts to establish a connection to a site to communicate sensitive information. (bad code)
Example Language: Java
try {
URL u = new URL("http://www.secret.example.org/"); }HttpURLConnection hu = (HttpURLConnection) u.openConnection(); hu.setRequestMethod("PUT"); hu.connect(); OutputStream os = hu.getOutputStream(); hu.disconnect(); catch (IOException e) { //... Though a connection is successfully made, the connection is unencrypted and it is possible that all sensitive data sent to or received from the server will be read by unintended actors.
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Relationship
There is an overlapping relationship between insecure storage of sensitive information (CWE-922) and missing encryption of sensitive information (CWE-311). Encryption is often used to prevent an attacker from reading the sensitive data. However, encryption does not prevent the attacker from erasing or overwriting the data.
CWE-401: Missing Release of Memory after Effective Lifetime
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Edit Custom FilterThe product does not sufficiently track and release allocated memory after it has been used, which slowly consumes remaining memory.
This is often triggered by improper handling of malformed data or unexpectedly interrupted sessions. In some languages, developers are responsible for tracking memory allocation and releasing the memory. If there are no more pointers or references to the memory, then it can no longer be tracked and identified for release.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C (Undetermined Prevalence) C++ (Undetermined Prevalence) Example 1 The following C function leaks a block of allocated memory if the call to read() does not return the expected number of bytes: (bad code)
Example Language: C
char* getBlock(int fd) {
char* buf = (char*) malloc(BLOCK_SIZE);
if (!buf) { return NULL; }if (read(fd, buf, BLOCK_SIZE) != BLOCK_SIZE) { return NULL; return buf;
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Relationship
This is often a resultant weakness due to improper handling of malformed data or early termination of sessions.
Terminology
"memory leak" has sometimes been used to describe other kinds of issues, e.g. for information leaks in which the contents of memory are inadvertently leaked (CVE-2003-0400 is one such example of this terminology conflict).
CWE-392: Missing Report of Error Condition
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Edit Custom FilterThe product encounters an error but does not provide a status code or return value to indicate that an error has occurred.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 In the following snippet from a doPost() servlet method, the server returns "200 OK" (default) even if an error occurs. (bad code)
Example Language: Java
try {
// Something that may throw an exception. ... logger.error("Caught: " + t.toString()); }return;
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CWE-820: Missing Synchronization
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Edit Custom FilterThe product utilizes a shared resource in a concurrent manner but does not attempt to synchronize access to the resource.
If access to a shared resource is not synchronized, then the resource may not be in a state that is expected by the product. This might lead to unexpected or insecure behaviors, especially if an attacker can influence the shared resource.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
Example 1 The following code intends to fork a process, then have both the parent and child processes print a single line. (bad code)
Example Language: C
static void print (char * string) {
char * word;
int counter; for (word = string; counter = *word++; ) { putc(counter, stdout);
fflush(stdout); /* Make timing window a little larger... */ sleep(1); int main(void) { pid_t pid;
pid = fork(); if (pid == -1) { exit(-2); }else if (pid == 0) { print("child\n"); }else { print("PARENT\n"); }exit(0); One might expect the code to print out something like:
PARENT
child
However, because the parent and child are executing concurrently, and stdout is flushed each time a character is printed, the output might be mixed together, such as:
PcAhRiElNdT
[blank line]
[blank line]
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Maintenance
Deeper research is necessary for synchronization and related mechanisms, including locks, mutexes, semaphores, and other mechanisms. Multiple entries are dependent on this research, which includes relationships to concurrency, race conditions, reentrant functions, etc. CWE-662 and its children - including CWE-667, CWE-820, CWE-821, and others - may need to be modified significantly, along with their relationships.
CWE-197: Numeric Truncation Error
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Edit Custom FilterTruncation errors occur when a primitive is cast to a primitive of a smaller size and data is lost in the conversion.
When a primitive is cast to a smaller primitive, the high order bits of the large value are lost in the conversion, potentially resulting in an unexpected value that is not equal to the original value. This value may be required as an index into a buffer, a loop iterator, or simply necessary state data. In any case, the value cannot be trusted and the system will be in an undefined state. While this method may be employed viably to isolate the low bits of a value, this usage is rare, and truncation usually implies that an implementation error has occurred.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C (Undetermined Prevalence) C++ (Undetermined Prevalence) Java (Undetermined Prevalence) C# (Undetermined Prevalence) Example 1 This example, while not exploitable, shows the possible mangling of values associated with truncation errors: (bad code)
Example Language: C
int intPrimitive;
short shortPrimitive; intPrimitive = (int)(~((int)0) ^ (1 << (sizeof(int)*8-1))); shortPrimitive = intPrimitive; printf("Int MAXINT: %d\nShort MAXINT: %d\n", intPrimitive, shortPrimitive); The above code, when compiled and run on certain systems, returns the following output: (result)
Int MAXINT: 2147483647
Short MAXINT: -1 This problem may be exploitable when the truncated value is used as an array index, which can happen implicitly when 64-bit values are used as indexes, as they are truncated to 32 bits. Example 2 In the following Java example, the method updateSalesForProduct is part of a business application class that updates the sales information for a particular product. The method receives as arguments the product ID and the integer amount sold. The product ID is used to retrieve the total product count from an inventory object which returns the count as an integer. Before calling the method of the sales object to update the sales count the integer values are converted to The primitive type short since the method requires short type for the method arguments. (bad code)
Example Language: Java
...
// update sales database for number of product sold with product ID public void updateSalesForProduct(String productID, int amountSold) { // get the total number of products in inventory database int productCount = inventory.getProductCount(productID); // convert integer values to short, the method for the // sales object requires the parameters to be of type short short count = (short) productCount; short sold = (short) amountSold; // update sales database for product sales.updateSalesCount(productID, count, sold); ... However, a numeric truncation error can occur if the integer values are higher than the maximum value allowed for the primitive type short. This can cause unexpected results or loss or corruption of data. In this case the sales database may be corrupted with incorrect data. Explicit casting from a from a larger size primitive type to a smaller size primitive type should be prevented. The following example an if statement is added to validate that the integer values less than the maximum value for the primitive type short before the explicit cast and the call to the sales method. (good code)
Example Language: Java
...
// update sales database for number of product sold with product ID public void updateSalesForProduct(String productID, int amountSold) { // get the total number of products in inventory database int productCount = inventory.getProductCount(productID); // make sure that integer numbers are not greater than // maximum value for type short before converting if ((productCount < Short.MAX_VALUE) && (amountSold < Short.MAX_VALUE)) { // convert integer values to short, the method for the // sales object requires the parameters to be of type short short count = (short) productCount; short sold = (short) amountSold; // update sales database for product sales.updateSalesCount(productID, count, sold); else { // throw exception or perform other processing ... }...
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Research Gap
This weakness has traditionally been under-studied and under-reported, although vulnerabilities in popular software have been published in 2008 and 2009.
CWE-581: Object Model Violation: Just One of Equals and Hashcode Defined
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Java objects are expected to obey a number of invariants related to equality. One of these invariants is that equal objects must have equal hashcodes. In other words, if a.equals(b) == true then a.hashCode() == b.hashCode().
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
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weakness may be introduced. The Phase identifies a point in the life cycle at which
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given
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Languages Java (Undetermined Prevalence)
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CWE-374: Passing Mutable Objects to an Untrusted Method
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The function or method that has been called can alter or delete the mutable data. This could violate assumptions that the calling function has made about its state. In situations where unknown code is called with references to mutable data, this external code could make changes to the data sent. If this data was not previously cloned, the modified data might not be valid in the context of execution.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
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Languages C (Undetermined Prevalence) C++ (Undetermined Prevalence) Java (Undetermined Prevalence) C# (Undetermined Prevalence) Example 1 The following example demonstrates the weakness. (bad code)
Example Language: C
private:
int foo;
complexType bar; String baz; otherClass externalClass; public: void doStuff() {
externalClass.doOtherStuff(foo, bar, baz) }In this example, bar and baz will be passed by reference to doOtherStuff() which may change them. Example 2 In the following Java example, the BookStore class manages the sale of books in a bookstore, this class includes the member objects for the bookstore inventory and sales database manager classes. The BookStore class includes a method for updating the sales database and inventory when a book is sold. This method retrieves a Book object from the bookstore inventory object using the supplied ISBN number for the book class, then calls a method for the sales object to update the sales information and then calls a method for the inventory object to update inventory for the BookStore. (bad code)
Example Language: Java
public class BookStore {
private BookStoreInventory inventory;
private SalesDBManager sales; ... // constructor for BookStore public BookStore() { this.inventory = new BookStoreInventory(); }this.sales = new SalesDBManager(); ... public void updateSalesAndInventoryForBookSold(String bookISBN) { // Get book object from inventory using ISBN Book book = inventory.getBookWithISBN(bookISBN); // update sales information for book sold sales.updateSalesInformation(book); // update inventory inventory.updateInventory(book); // other BookStore methods ... public class Book { private String title; }private String author; private String isbn; // Book object constructors and get/set methods ... However, in this example the Book object that is retrieved and passed to the method of the sales object could have its contents modified by the method. This could cause unexpected results when the book object is sent to the method for the inventory object to update the inventory. In the Java programming language arguments to methods are passed by value, however in the case of objects a reference to the object is passed by value to the method. When an object reference is passed as a method argument a copy of the object reference is made within the method and therefore both references point to the same object. This allows the contents of the object to be modified by the method that holds the copy of the object reference. [REF-374] In this case the contents of the Book object could be modified by the method of the sales object prior to the call to update the inventory. To prevent the contents of the Book object from being modified, a copy of the Book object should be made before the method call to the sales object. In the following example a copy of the Book object is made using the clone() method and the copy of the Book object is passed to the method of the sales object. This will prevent any changes being made to the original Book object. (good code)
Example Language: Java
...
public void updateSalesAndInventoryForBookSold(String bookISBN) { // Get book object from inventory using ISBN Book book = inventory.getBookWithISBN(bookISBN); // Create copy of book object to make sure contents are not changed Book bookSold = (Book) book.clone(); // update sales information for book sold sales.updateSalesInformation(bookSold); // update inventory inventory.updateInventory(book); ...
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CWE-625: Permissive Regular Expression
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Edit Custom FilterThe product uses a regular expression that does not sufficiently restrict the set of allowed values.
This effectively causes the regexp to accept substrings that match the pattern, which produces a partial comparison to the target. In some cases, this can lead to other weaknesses. Common errors include:
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
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achieve a different impact.
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
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weakness may be introduced. The Phase identifies a point in the life cycle at which
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given
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This listing shows possible areas for which the given
weakness could appear. These
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Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Perl (Undetermined Prevalence) PHP (Undetermined Prevalence) Example 1 The following code takes phone numbers as input, and uses a regular expression to reject invalid phone numbers. (bad code)
Example Language: Perl
$phone = GetPhoneNumber();
if ($phone =~ /\d+-\d+/) {
# looks like it only has hyphens and digits
}
system("lookup-phone $phone"); else { error("malformed number!"); }An attacker could provide an argument such as: "; ls -l ; echo 123-456" This would pass the check, since "123-456" is sufficient to match the "\d+-\d+" portion of the regular expression. Example 2 This code uses a regular expression to validate an IP string prior to using it in a call to the "ping" command. (bad code)
Example Language: Python
import subprocess
import re def validate_ip_regex(ip: str):
ip_validator = re.compile(r"((25[0-5]|(2[0-4]|1\d|[1-9]|)\d)\.?\b){4}")
if ip_validator.match(ip):
return ip
else:
raise ValueError("IP address does not match valid pattern.")
def run_ping_regex(ip: str):
validated = validate_ip_regex(ip)
# The ping command treats zero-prepended IP addresses as octal result = subprocess.call(["ping", validated]) print(result) Since the regular expression does not have anchors (CWE-777), i.e. is unbounded without ^ or $ characters, then prepending a 0 or 0x to the beginning of the IP address will still result in a matched regex pattern. Since the ping command supports octal and hex prepended IP addresses, it will use the unexpectedly valid IP address (CWE-1389). For example, "0x63.63.63.63" would be considered equivalent to "99.63.63.63". As a result, the attacker could potentially ping systems that the attacker cannot reach directly.
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CWE-337: Predictable Seed in Pseudo-Random Number Generator (PRNG)
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Edit Custom FilterA Pseudo-Random Number Generator (PRNG) is initialized from a predictable seed, such as the process ID or system time.
The use of predictable seeds significantly reduces the number of possible seeds that an attacker would need to test in order to predict which random numbers will be generated by the PRNG.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
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weakness may be introduced. The Phase identifies a point in the life cycle at which
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This listing shows possible areas for which the given
weakness could appear. These
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Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 Both of these examples use a statistical PRNG seeded with the current value of the system clock to generate a random number: (bad code)
Example Language: Java
Random random = new Random(System.currentTimeMillis());
int accountID = random.nextInt(); (bad code)
Example Language: C
srand(time());
int randNum = rand(); An attacker can easily predict the seed used by these PRNGs, and so also predict the stream of random numbers generated. Note these examples also exhibit CWE-338 (Use of Cryptographically Weak PRNG).
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Maintenance
As of CWE 4.5, terminology related to randomness, entropy, and
predictability can vary widely. Within the developer and other
communities, "randomness" is used heavily. However, within
cryptography, "entropy" is distinct, typically implied as a
measurement. There are no commonly-used definitions, even within
standards documents and cryptography papers. Future versions of
CWE will attempt to define these terms and, if necessary,
distinguish between them in ways that are appropriate for
different communities but do not reduce the usability of CWE for
mapping, understanding, or other scenarios.
CWE-491: Public cloneable() Method Without Final ('Object Hijack')
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Edit Custom FilterA class has a cloneable() method that is not declared final, which allows an object to be created without calling the constructor. This can cause the object to be in an unexpected state.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
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relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
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weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 In this example, a public class "BankAccount" implements the cloneable() method which declares "Object clone(string accountnumber)": (bad code)
Example Language: Java
public class BankAccount implements Cloneable{
public Object clone(String accountnumber) throws
CloneNotSupportedException { Object returnMe = new BankAccount(account number);
... Example 2 In the example below, a clone() method is defined without being declared final. (bad code)
Example Language: Java
protected Object clone() throws CloneNotSupportedException {
... }
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CWE-500: Public Static Field Not Marked Final
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Edit Custom FilterAn object contains a public static field that is not marked final, which might allow it to be modified in unexpected ways.
Public static variables can be read without an accessor and changed without a mutator by any classes in the application.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
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Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
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weakness may be introduced. The Phase identifies a point in the life cycle at which
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may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
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Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C++ (Undetermined Prevalence) Java (Undetermined Prevalence) Example 1 The following examples use of a public static String variable to contain the name of a property/configuration file for the application. (bad code)
Example Language: C++
class SomeAppClass {
public: static string appPropertiesConfigFile = "app/properties.config";
... (bad code)
Example Language: Java
public class SomeAppClass {
public static String appPropertiesFile = "app/Application.properties"; ... Having a public static variable that is not marked final (constant) may allow the variable to the altered in a way not intended by the application. In this example the String variable can be modified to indicate a different on nonexistent properties file which could cause the application to crash or caused unexpected behavior. (good code)
Example Language: C++
class SomeAppClass {
public: static const string appPropertiesConfigFile = "app/properties.config";
... (good code)
Example Language: Java
public class SomeAppClass {
public static final String appPropertiesFile = "app/Application.properties"; ...
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CWE-366: Race Condition within a Thread
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Edit Custom FilterIf two threads of execution use a resource simultaneously, there exists the possibility that resources may be used while invalid, in turn making the state of execution undefined.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
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may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
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weakness may be introduced. The Phase identifies a point in the life cycle at which
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This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C (Undetermined Prevalence) C++ (Undetermined Prevalence) Java (Undetermined Prevalence) C# (Undetermined Prevalence) Example 1 The following example demonstrates the weakness. (bad code)
Example Language: C
int foo = 0;
int storenum(int num) { static int counter = 0; }counter++; if (num > foo) foo = num; return foo; (bad code)
Example Language: Java
public classRace {
static int foo = 0;
public static void main() { new Threader().start(); foo = 1; public static class Threader extends Thread { public void run() { System.out.println(foo); }
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CWE-617: Reachable Assertion
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Edit Custom FilterThe product contains an assert() or similar statement that can be triggered by an attacker, which leads to an application exit or other behavior that is more severe than necessary.
While assertion is good for catching logic errors and reducing the chances of reaching more serious vulnerability conditions, it can still lead to a denial of service. For example, if a server handles multiple simultaneous connections, and an assert() occurs in one single connection that causes all other connections to be dropped, this is a reachable assertion that leads to a denial of service. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
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given
phase.
Example 1 In the excerpt below, an AssertionError (an unchecked exception) is thrown if the user hasn't entered an email address in an HTML form. (bad code)
Example Language: Java
String email = request.getParameter("email_address");
assert email != null;
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CWE-487: Reliance on Package-level Scope
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Edit Custom FilterJava packages are not inherently closed; therefore, relying on them for code security is not a good practice.
The purpose of package scope is to prevent accidental access by other parts of a program. This is an ease-of-software-development feature but not a security feature.
This table specifies different individual consequences
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
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Languages Java (Undetermined Prevalence) Example 1 The following example demonstrates the weakness. (bad code)
Example Language: Java
package math;
public class Lebesgue implements Integration{ public final Static String youAreHidingThisFunction(functionToIntegrate){
return ...;
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CWE-807: Reliance on Untrusted Inputs in a Security Decision
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Edit Custom FilterThe product uses a protection mechanism that relies on the existence or values of an input, but the input can be modified by an untrusted actor in a way that bypasses the protection mechanism.
Developers may assume that inputs such as cookies, environment variables, and hidden form fields cannot be modified. However, an attacker could change these inputs using customized clients or other attacks. This change might not be detected. When security decisions such as authentication and authorization are made based on the values of these inputs, attackers can bypass the security of the software. Without sufficient encryption, integrity checking, or other mechanism, any input that originates from an outsider cannot be trusted. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
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may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Architectural Concepts" (CWE-1008)
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about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
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given
phase.
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or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following code excerpt reads a value from a browser cookie to determine the role of the user. (bad code)
Example Language: Java
Cookie[] cookies = request.getCookies();
for (int i =0; i< cookies.length; i++) { Cookie c = cookies[i]; }if (c.getName().equals("role")) { userRole = c.getValue(); }Example 2 The following code could be for a medical records application. It performs authentication by checking if a cookie has been set. (bad code)
Example Language: PHP
$auth = $_COOKIES['authenticated'];
if (! $auth) { if (AuthenticateUser($_POST['user'], $_POST['password']) == "success") { }// save the cookie to send out in future responses }setcookie("authenticated", "1", time()+60*60*2); else { ShowLoginScreen(); }die("\n"); DisplayMedicalHistory($_POST['patient_ID']); The programmer expects that the AuthenticateUser() check will always be applied, and the "authenticated" cookie will only be set when authentication succeeds. The programmer even diligently specifies a 2-hour expiration for the cookie. However, the attacker can set the "authenticated" cookie to a non-zero value such as 1. As a result, the $auth variable is 1, and the AuthenticateUser() check is not even performed. The attacker has bypassed the authentication. Example 3 In the following example, an authentication flag is read from a browser cookie, thus allowing for external control of user state data. (bad code)
Example Language: Java
Cookie[] cookies = request.getCookies();
for (int i =0; i< cookies.length; i++) { Cookie c = cookies[i]; }if (c.getName().equals("authenticated") && Boolean.TRUE.equals(c.getValue())) { authenticated = true; }Example 4 The following code samples use a DNS lookup in order to decide whether or not an inbound request is from a trusted host. If an attacker can poison the DNS cache, they can gain trusted status. (bad code)
Example Language: C
struct hostent *hp;struct in_addr myaddr;
char* tHost = "trustme.example.com"; myaddr.s_addr=inet_addr(ip_addr_string); hp = gethostbyaddr((char *) &myaddr, sizeof(struct in_addr), AF_INET); if (hp && !strncmp(hp->h_name, tHost, sizeof(tHost))) { trusted = true; } else {trusted = false; }(bad code)
Example Language: Java
String ip = request.getRemoteAddr();
InetAddress addr = InetAddress.getByName(ip); if (addr.getCanonicalHostName().endsWith("trustme.com")) { trusted = true; }(bad code)
Example Language: C#
IPAddress hostIPAddress = IPAddress.Parse(RemoteIpAddress);
IPHostEntry hostInfo = Dns.GetHostByAddress(hostIPAddress); if (hostInfo.HostName.EndsWith("trustme.com")) { trusted = true; }IP addresses are more reliable than DNS names, but they can also be spoofed. Attackers can easily forge the source IP address of the packets they send, but response packets will return to the forged IP address. To see the response packets, the attacker has to sniff the traffic between the victim machine and the forged IP address. In order to accomplish the required sniffing, attackers typically attempt to locate themselves on the same subnet as the victim machine. Attackers may be able to circumvent this requirement by using source routing, but source routing is disabled across much of the Internet today. In summary, IP address verification can be a useful part of an authentication scheme, but it should not be the single factor required for authentication.
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CWE-584: Return Inside Finally Block
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Edit Custom FilterThe code has a return statement inside a finally block, which will cause any thrown exception in the try block to be discarded.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
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Example 1 In the following code excerpt, the IllegalArgumentException will never be delivered to the caller. The finally block will cause the exception to be discarded. (bad code)
Example Language: Java
try {
... }throw IllegalArgumentException(); finally { return r; }
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CWE-375: Returning a Mutable Object to an Untrusted Caller
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Edit Custom FilterSending non-cloned mutable data as a return value may result in that data being altered or deleted by the calling function.
In situations where functions return references to mutable data, it is possible that the external code which called the function may make changes to the data sent. If this data was not previously cloned, the class will then be using modified data which may violate assumptions about its internal state.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
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Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
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or a class of such platforms. The platform is listed along with how frequently the given
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Languages C (Undetermined Prevalence) C++ (Undetermined Prevalence) Java (Undetermined Prevalence) C# (Undetermined Prevalence) Example 1 This class has a private list of patients, but provides a way to see the list : (bad code)
Example Language: Java
public class ClinicalTrial {
private PatientClass[] patientList = new PatientClass[50]; }public getPatients(...){ return patientList; }While this code only means to allow reading of the patient list, the getPatients() method returns a reference to the class's original patient list instead of a reference to a copy of the list. Any caller of this method can arbitrarily modify the contents of the patient list even though it is a private member of the class.
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CWE-336: Same Seed in Pseudo-Random Number Generator (PRNG)
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Edit Custom FilterA Pseudo-Random Number Generator (PRNG) uses the same seed each time the product is initialized.
Given the deterministic nature of PRNGs, using the same seed for each initialization will lead to the same output in the same order. If an attacker can guess (or knows) the seed, then the attacker may be able to determine the random numbers that will be produced from the PRNG.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
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similar items that may exist at higher and lower levels of abstraction. In addition,
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may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following code uses a statistical PRNG to generate account IDs. (bad code)
Example Language: Java
private static final long SEED = 1234567890;
public int generateAccountID() { Random random = new Random(SEED); }return random.nextInt(); Because the program uses the same seed value for every invocation of the PRNG, its values are predictable, making the system vulnerable to attack. Example 2 This code attempts to generate a unique random identifier for a user's session. (bad code)
Example Language: PHP
function generateSessionID($userID){
srand($userID); }return rand(); Because the seed for the PRNG is always the user's ID, the session ID will always be the same. An attacker could thus predict any user's session ID and potentially hijack the session. If the user IDs are generated sequentially, or otherwise restricted to a narrow range of values, then this example also exhibits a Small Seed Space (CWE-339).
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Maintenance
As of CWE 4.5, terminology related to randomness, entropy, and
predictability can vary widely. Within the developer and other
communities, "randomness" is used heavily. However, within
cryptography, "entropy" is distinct, typically implied as a
measurement. There are no commonly-used definitions, even within
standards documents and cryptography papers. Future versions of
CWE will attempt to define these terms and, if necessary,
distinguish between them in ways that are appropriate for
different communities but do not reduce the usability of CWE for
mapping, understanding, or other scenarios.
CWE-499: Serializable Class Containing Sensitive Data
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Edit Custom FilterThe code contains a class with sensitive data, but the class does not explicitly deny serialization. The data can be accessed by serializing the class through another class.
Serializable classes are effectively open classes since data cannot be hidden in them. Classes that do not explicitly deny serialization can be serialized by any other class, which can then in turn use the data stored inside it.
This table specifies different individual consequences
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violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
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Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
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weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
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given
phase.
This listing shows possible areas for which the given
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Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 This code creates a new record for a medical patient: (bad code)
Example Language: Java
class PatientRecord {
private String name; }private String socialSecurityNum; public Patient(String name,String ssn) { this.SetName(name); }this.SetSocialSecurityNumber(ssn); This object does not explicitly deny serialization, allowing an attacker to serialize an instance of this object and gain a patient's name and Social Security number even though those fields are private.
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CWE-479: Signal Handler Use of a Non-reentrant Function
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Edit Custom FilterNon-reentrant functions are functions that cannot safely be called, interrupted, and then recalled before the first call has finished without resulting in memory corruption. This can lead to an unexpected system state and unpredictable results with a variety of potential consequences depending on context, including denial of service and code execution. Many functions are not reentrant, but some of them can result in the corruption of memory if they are used in a signal handler. The function call syslog() is an example of this. In order to perform its functionality, it allocates a small amount of memory as "scratch space." If syslog() is suspended by a signal call and the signal handler calls syslog(), the memory used by both of these functions enters an undefined, and possibly, exploitable state. Implementations of malloc() and free() manage metadata in global structures in order to track which memory is allocated versus which memory is available, but they are non-reentrant. Simultaneous calls to these functions can cause corruption of the metadata. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
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may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C (Undetermined Prevalence) C++ (Undetermined Prevalence) Example 1 In this example, a signal handler uses syslog() to log a message: (bad code)
char *message;
void sh(int dummy) { syslog(LOG_NOTICE,"%s\n",message); }sleep(10); exit(0); int main(int argc,char* argv[]) { ... }signal(SIGHUP,sh); signal(SIGTERM,sh); sleep(10); exit(0); If the execution of the first call to the signal handler is suspended after invoking syslog(), and the signal handler is called a second time, the memory allocated by syslog() enters an undefined, and possibly, exploitable state.
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CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 10 - Locking (LCK)
Weaknesses in this category are related to rules in the Locking (LCK) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 11 - Thread APIs (THI)
Weaknesses in this category are related to rules in the Thread APIs (THI) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 12 - Thread Pools (TPS)
Weaknesses in this category are related to rules in the Thread Pools (TPS) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 13 - Thread-Safety Miscellaneous (TSM)
Weaknesses in this category are related to rules in the Thread-Safety Miscellaneous (TSM) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 14 - Input Output (FIO)
Weaknesses in this category are related to rules in the Input Output (FIO) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 15 - Serialization (SER)
Weaknesses in this category are related to rules in the Serialization (SER) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 16 - Platform Security (SEC)
Weaknesses in this category are related to rules in the Platform Security (SEC) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 17 - Runtime Environment (ENV)
Weaknesses in this category are related to rules in the Runtime Environment (ENV) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 18 - Miscellaneous (MSC)
Weaknesses in this category are related to rules in the Miscellaneous (MSC) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 2 - Input Validation and Data Sanitization (IDS)
Weaknesses in this category are related to rules in the Input Validation and Data Sanitization (IDS) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 3 - Declarations and Initialization (DCL)
Weaknesses in this category are related to rules in the Declarations and Initialization (DCL) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 4 - Expressions (EXP)
Weaknesses in this category are related to rules in the Expressions (EXP) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 5 - Numeric Types and Operations (NUM)
Weaknesses in this category are related to rules in the Numeric Types and Operations (NUM) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 6 - Object Orientation (OBJ)
Weaknesses in this category are related to rules in the Object Orientation (OBJ) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 7 - Methods (MET)
Weaknesses in this category are related to rules in the Methods (MET) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 8 - Exceptional Behavior (ERR)
Weaknesses in this category are related to rules in the Exceptional Behavior (ERR) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE CATEGORY: The CERT Oracle Secure Coding Standard for Java (2011) Chapter 9 - Visibility and Atomicity (VNA)
Weaknesses in this category are related to rules in the Visibility and Atomicity (VNA) chapter of The CERT Oracle Secure Coding Standard for Java (2011).
CWE-248: Uncaught Exception
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When an exception is not caught, it may cause the program to crash or expose sensitive information.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
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exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C++ (Undetermined Prevalence) Java (Undetermined Prevalence) C# (Undetermined Prevalence) Example 1 The following example attempts to resolve a hostname. (bad code)
Example Language: Java
protected void doPost (HttpServletRequest req, HttpServletResponse res) throws IOException {
String ip = req.getRemoteAddr(); }InetAddress addr = InetAddress.getByName(ip); ... out.println("hello " + addr.getHostName()); A DNS lookup failure will cause the Servlet to throw an exception. Example 2 The _alloca() function allocates memory on the stack. If an allocation request is too large for the available stack space, _alloca() throws an exception. If the exception is not caught, the program will crash, potentially enabling a denial of service attack. _alloca() has been deprecated as of Microsoft Visual Studio 2005(R). It has been replaced with the more secure _alloca_s(). Example 3 EnterCriticalSection() can raise an exception, potentially causing the program to crash. Under operating systems prior to Windows 2000, the EnterCriticalSection() function can raise an exception in low memory situations. If the exception is not caught, the program will crash, potentially enabling a denial of service attack.
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-600: Uncaught Exception in Servlet
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Edit Custom FilterThe Servlet does not catch all exceptions, which may reveal sensitive debugging information.
When a Servlet throws an exception, the default error response the Servlet container sends back to the user typically includes debugging information. This information is of great value to an attacker. For example, a stack trace might show the attacker a malformed SQL query string, the type of database being used, and the version of the application container. This information enables the attacker to target known vulnerabilities in these components.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
Example 1 The following example attempts to resolve a hostname. (bad code)
Example Language: Java
protected void doPost (HttpServletRequest req, HttpServletResponse res) throws IOException {
String ip = req.getRemoteAddr(); }InetAddress addr = InetAddress.getByName(ip); ... out.println("hello " + addr.getHostName()); A DNS lookup failure will cause the Servlet to throw an exception.
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Maintenance
The "Missing Catch Block" concept is probably broader than just Servlets, but the broader concept is not sufficiently covered in CWE.
CWE-252: Unchecked Return Value
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Edit Custom FilterThe product does not check the return value from a method or function, which can prevent it from detecting unexpected states and conditions.
Two common programmer assumptions are "this function call can never fail" and "it doesn't matter if this function call fails". If an attacker can force the function to fail or otherwise return a value that is not expected, then the subsequent program logic could lead to a vulnerability, because the product is not in a state that the programmer assumes. For example, if the program calls a function to drop privileges but does not check the return code to ensure that privileges were successfully dropped, then the program will continue to operate with the higher privileges.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 Consider the following code segment: (bad code)
Example Language: C
char buf[10], cp_buf[10];
fgets(buf, 10, stdin); strcpy(cp_buf, buf); The programmer expects that when fgets() returns, buf will contain a null-terminated string of length 9 or less. But if an I/O error occurs, fgets() will not null-terminate buf. Furthermore, if the end of the file is reached before any characters are read, fgets() returns without writing anything to buf. In both of these situations, fgets() signals that something unusual has happened by returning NULL, but in this code, the warning will not be noticed. The lack of a null terminator in buf can result in a buffer overflow in the subsequent call to strcpy(). Example 2 In the following example, it is possible to request that memcpy move a much larger segment of memory than assumed: (bad code)
Example Language: C
int returnChunkSize(void *) {
/* if chunk info is valid, return the size of usable memory, * else, return -1 to indicate an error */ ... int main() { ... }memcpy(destBuf, srcBuf, (returnChunkSize(destBuf)-1)); ... If returnChunkSize() happens to encounter an error it will return -1. Notice that the return value is not checked before the memcpy operation (CWE-252), so -1 can be passed as the size argument to memcpy() (CWE-805). Because memcpy() assumes that the value is unsigned, it will be interpreted as MAXINT-1 (CWE-195), and therefore will copy far more memory than is likely available to the destination buffer (CWE-787, CWE-788). Example 3 The following code does not check to see if memory allocation succeeded before attempting to use the pointer returned by malloc(). (bad code)
Example Language: C
buf = (char*) malloc(req_size);
strncpy(buf, xfer, req_size); The traditional defense of this coding error is: "If my program runs out of memory, it will fail. It doesn't matter whether I handle the error or allow the program to die with a segmentation fault when it tries to dereference the null pointer." This argument ignores three important considerations:
Example 4 The following examples read a file into a byte array. (bad code)
Example Language: C#
char[] byteArray = new char[1024];
for (IEnumerator i=users.GetEnumerator(); i.MoveNext() ;i.Current()) { String userName = (String) i.Current(); }String pFileName = PFILE_ROOT + "/" + userName; StreamReader sr = new StreamReader(pFileName); sr.Read(byteArray,0,1024);//the file is always 1k bytes sr.Close(); processPFile(userName, byteArray); (bad code)
Example Language: Java
FileInputStream fis;
byte[] byteArray = new byte[1024]; for (Iterator i=users.iterator(); i.hasNext();) { String userName = (String) i.next();
String pFileName = PFILE_ROOT + "/" + userName; FileInputStream fis = new FileInputStream(pFileName); fis.read(byteArray); // the file is always 1k bytes fis.close(); processPFile(userName, byteArray); The code loops through a set of users, reading a private data file for each user. The programmer assumes that the files are always 1 kilobyte in size and therefore ignores the return value from Read(). If an attacker can create a smaller file, the program will recycle the remainder of the data from the previous user and treat it as though it belongs to the attacker. Example 5 The following code does not check to see if the string returned by getParameter() is null before calling the member function compareTo(), potentially causing a NULL dereference. (bad code)
Example Language: Java
String itemName = request.getParameter(ITEM_NAME);
if (itemName.compareTo(IMPORTANT_ITEM) == 0) { ... }... The following code does not check to see if the string returned by the Item property is null before calling the member function Equals(), potentially causing a NULL dereference. (bad code)
Example Language: Java
String itemName = request.Item(ITEM_NAME);
if (itemName.Equals(IMPORTANT_ITEM)) { ... }... The traditional defense of this coding error is: "I know the requested value will always exist because.... If it does not exist, the program cannot perform the desired behavior so it doesn't matter whether I handle the error or allow the program to die dereferencing a null value." But attackers are skilled at finding unexpected paths through programs, particularly when exceptions are involved. Example 6 The following code shows a system property that is set to null and later dereferenced by a programmer who mistakenly assumes it will always be defined. (bad code)
Example Language: Java
System.clearProperty("os.name");
... String os = System.getProperty("os.name"); if (os.equalsIgnoreCase("Windows 95")) System.out.println("Not supported"); The traditional defense of this coding error is: "I know the requested value will always exist because.... If it does not exist, the program cannot perform the desired behavior so it doesn't matter whether I handle the error or allow the program to die dereferencing a null value." But attackers are skilled at finding unexpected paths through programs, particularly when exceptions are involved. Example 7 The following VB.NET code does not check to make sure that it has read 50 bytes from myfile.txt. This can cause DoDangerousOperation() to operate on an unexpected value. (bad code)
Example Language: C#
Dim MyFile As New FileStream("myfile.txt", FileMode.Open, FileAccess.Read, FileShare.Read)
Dim MyArray(50) As Byte MyFile.Read(MyArray, 0, 50) DoDangerousOperation(MyArray(20)) In .NET, it is not uncommon for programmers to misunderstand Read() and related methods that are part of many System.IO classes. The stream and reader classes do not consider it to be unusual or exceptional if only a small amount of data becomes available. These classes simply add the small amount of data to the return buffer, and set the return value to the number of bytes or characters read. There is no guarantee that the amount of data returned is equal to the amount of data requested. Example 8 It is not uncommon for Java programmers to misunderstand read() and related methods that are part of many java.io classes. Most errors and unusual events in Java result in an exception being thrown. But the stream and reader classes do not consider it unusual or exceptional if only a small amount of data becomes available. These classes simply add the small amount of data to the return buffer, and set the return value to the number of bytes or characters read. There is no guarantee that the amount of data returned is equal to the amount of data requested. This behavior makes it important for programmers to examine the return value from read() and other IO methods to ensure that they receive the amount of data they expect. Example 9 This example takes an IP address from a user, verifies that it is well formed and then looks up the hostname and copies it into a buffer. (bad code)
Example Language: C
void host_lookup(char *user_supplied_addr){
struct hostent *hp;
in_addr_t *addr; char hostname[64]; in_addr_t inet_addr(const char *cp); /*routine that ensures user_supplied_addr is in the right format for conversion */ validate_addr_form(user_supplied_addr); addr = inet_addr(user_supplied_addr); hp = gethostbyaddr( addr, sizeof(struct in_addr), AF_INET); strcpy(hostname, hp->h_name); If an attacker provides an address that appears to be well-formed, but the address does not resolve to a hostname, then the call to gethostbyaddr() will return NULL. Since the code does not check the return value from gethostbyaddr (CWE-252), a NULL pointer dereference (CWE-476) would then occur in the call to strcpy(). Note that this code is also vulnerable to a buffer overflow (CWE-119). Example 10 The following function attempts to acquire a lock in order to perform operations on a shared resource. (bad code)
Example Language: C
void f(pthread_mutex_t *mutex) {
pthread_mutex_lock(mutex);
/* access shared resource */ pthread_mutex_unlock(mutex); However, the code does not check the value returned by pthread_mutex_lock() for errors. If pthread_mutex_lock() cannot acquire the mutex for any reason, the function may introduce a race condition into the program and result in undefined behavior. In order to avoid data races, correctly written programs must check the result of thread synchronization functions and appropriately handle all errors, either by attempting to recover from them or reporting them to higher levels. (good code)
Example Language: C
int f(pthread_mutex_t *mutex) {
int result;
result = pthread_mutex_lock(mutex); if (0 != result) return result;
/* access shared resource */ return pthread_mutex_unlock(mutex);
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-690: Unchecked Return Value to NULL Pointer Dereference
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Edit Custom FilterThe product does not check for an error after calling a function that can return with a NULL pointer if the function fails, which leads to a resultant NULL pointer dereference.
While unchecked return value weaknesses are not limited to returns of NULL pointers (see the examples in CWE-252), functions often return NULL to indicate an error status. When this error condition is not checked, a NULL pointer dereference can occur.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C (Undetermined Prevalence) C++ (Undetermined Prevalence) Example 1 The code below makes a call to the getUserName() function but doesn't check the return value before dereferencing (which may cause a NullPointerException). (bad code)
Example Language: Java
String username = getUserName();
if (username.equals(ADMIN_USER)) { ... }Example 2 This example takes an IP address from a user, verifies that it is well formed and then looks up the hostname and copies it into a buffer. (bad code)
Example Language: C
void host_lookup(char *user_supplied_addr){
struct hostent *hp;
in_addr_t *addr; char hostname[64]; in_addr_t inet_addr(const char *cp); /*routine that ensures user_supplied_addr is in the right format for conversion */ validate_addr_form(user_supplied_addr); addr = inet_addr(user_supplied_addr); hp = gethostbyaddr( addr, sizeof(struct in_addr), AF_INET); strcpy(hostname, hp->h_name); If an attacker provides an address that appears to be well-formed, but the address does not resolve to a hostname, then the call to gethostbyaddr() will return NULL. Since the code does not check the return value from gethostbyaddr (CWE-252), a NULL pointer dereference (CWE-476) would then occur in the call to strcpy(). Note that this code is also vulnerable to a buffer overflow (CWE-119).
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-400: Uncontrolled Resource Consumption
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Edit Custom FilterThe product does not properly control the allocation and maintenance of a limited resource, thereby enabling an actor to influence the amount of resources consumed, eventually leading to the exhaustion of available resources.
Limited resources include memory, file system storage, database connection pool entries, and CPU. If an attacker can trigger the allocation of these limited resources, but the number or size of the resources is not controlled, then the attacker could cause a denial of service that consumes all available resources. This would prevent valid users from accessing the product, and it could potentially have an impact on the surrounding environment. For example, a memory exhaustion attack against an application could slow down the application as well as its host operating system. There are at least three distinct scenarios which can commonly lead to resource exhaustion:
Resource exhaustion problems are often result due to an incorrect implementation of the following situations:
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 The following example demonstrates the weakness. (bad code)
Example Language: Java
class Worker implements Executor {
...
public void execute(Runnable r) { try { ... }catch (InterruptedException ie) { // postpone response Thread.currentThread().interrupt(); public Worker(Channel ch, int nworkers) { ... }protected void activate() { Runnable loop = new Runnable() { public void run() { try { for (;;) { }Runnable r = ...; }r.run(); catch (InterruptedException ie) { ... }new Thread(loop).start(); There are no limits to runnables. Potentially an attacker could cause resource problems very quickly. Example 2 This code allocates a socket and forks each time it receives a new connection. (bad code)
Example Language: C
sock=socket(AF_INET, SOCK_STREAM, 0);
while (1) { newsock=accept(sock, ...); }printf("A connection has been accepted\n"); pid = fork(); The program does not track how many connections have been made, and it does not limit the number of connections. Because forking is a relatively expensive operation, an attacker would be able to cause the system to run out of CPU, processes, or memory by making a large number of connections. Alternatively, an attacker could consume all available connections, preventing others from accessing the system remotely. Example 3 In the following example a server socket connection is used to accept a request to store data on the local file system using a specified filename. The method openSocketConnection establishes a server socket to accept requests from a client. When a client establishes a connection to this service the getNextMessage method is first used to retrieve from the socket the name of the file to store the data, the openFileToWrite method will validate the filename and open a file to write to on the local file system. The getNextMessage is then used within a while loop to continuously read data from the socket and output the data to the file until there is no longer any data from the socket. (bad code)
Example Language: C
int writeDataFromSocketToFile(char *host, int port)
{ char filename[FILENAME_SIZE]; char buffer[BUFFER_SIZE]; int socket = openSocketConnection(host, port); if (socket < 0) { printf("Unable to open socket connection"); }return(FAIL); if (getNextMessage(socket, filename, FILENAME_SIZE) > 0) { if (openFileToWrite(filename) > 0) {
while (getNextMessage(socket, buffer, BUFFER_SIZE) > 0){
if (!(writeToFile(buffer) > 0)) }break;
closeFile(); closeSocket(socket); This example creates a situation where data can be dumped to a file on the local file system without any limits on the size of the file. This could potentially exhaust file or disk resources and/or limit other clients' ability to access the service. Example 4 In the following example, the processMessage method receives a two dimensional character array containing the message to be processed. The two-dimensional character array contains the length of the message in the first character array and the message body in the second character array. The getMessageLength method retrieves the integer value of the length from the first character array. After validating that the message length is greater than zero, the body character array pointer points to the start of the second character array of the two-dimensional character array and memory is allocated for the new body character array. (bad code)
Example Language: C
/* process message accepts a two-dimensional character array of the form [length][body] containing the message to be processed */ int processMessage(char **message) { char *body;
int length = getMessageLength(message[0]); if (length > 0) { body = &message[1][0]; }processMessageBody(body); return(SUCCESS); else { printf("Unable to process message; invalid message length"); }return(FAIL); This example creates a situation where the length of the body character array can be very large and will consume excessive memory, exhausting system resources. This can be avoided by restricting the length of the second character array with a maximum length check Also, consider changing the type from 'int' to 'unsigned int', so that you are always guaranteed that the number is positive. This might not be possible if the protocol specifically requires allowing negative values, or if you cannot control the return value from getMessageLength(), but it could simplify the check to ensure the input is positive, and eliminate other errors such as signed-to-unsigned conversion errors (CWE-195) that may occur elsewhere in the code. (good code)
Example Language: C
unsigned int length = getMessageLength(message[0]);
if ((length > 0) && (length < MAX_LENGTH)) {...} Example 5 In the following example, a server object creates a server socket and accepts client connections to the socket. For every client connection to the socket a separate thread object is generated using the ClientSocketThread class that handles request made by the client through the socket. (bad code)
Example Language: Java
public void acceptConnections() {
try {
ServerSocket serverSocket = new ServerSocket(SERVER_PORT);
int counter = 0; boolean hasConnections = true; while (hasConnections) { Socket client = serverSocket.accept(); }Thread t = new Thread(new ClientSocketThread(client)); t.setName(client.getInetAddress().getHostName() + ":" + counter++); t.start(); serverSocket.close(); } catch (IOException ex) {...} In this example there is no limit to the number of client connections and client threads that are created. Allowing an unlimited number of client connections and threads could potentially overwhelm the system and system resources. The server should limit the number of client connections and the client threads that are created. This can be easily done by creating a thread pool object that limits the number of threads that are generated. (good code)
Example Language: Java
public static final int SERVER_PORT = 4444;
public static final int MAX_CONNECTIONS = 10; ... public void acceptConnections() { try {
ServerSocket serverSocket = new ServerSocket(SERVER_PORT);
int counter = 0; boolean hasConnections = true; while (hasConnections) { hasConnections = checkForMoreConnections(); }Socket client = serverSocket.accept(); Thread t = new Thread(new ClientSocketThread(client)); t.setName(client.getInetAddress().getHostName() + ":" + counter++); ExecutorService pool = Executors.newFixedThreadPool(MAX_CONNECTIONS); pool.execute(t); serverSocket.close(); } catch (IOException ex) {...} Example 6 In the following example, the serve function receives an http request and an http response writer. It reads the entire request body. (bad code)
Example Language: Go
func serve(w http.ResponseWriter, r *http.Request) {
var body []byte
}if r.Body != nil {
if data, err := io.ReadAll(r.Body); err == nil {
}
body = data
}Because ReadAll is defined to read from src until EOF, it does not treat an EOF from Read as an error to be reported. This example creates a situation where the length of the body supplied can be very large and will consume excessive memory, exhausting system resources. This can be avoided by ensuring the body does not exceed a predetermined length of bytes. MaxBytesReader prevents clients from accidentally or maliciously sending a large request and wasting server resources. If possible, the code could be changed to tell ResponseWriter to close the connection after the limit has been reached. (good code)
Example Language: Go
func serve(w http.ResponseWriter, r *http.Request) {
var body []byte
}const MaxRespBodyLength = 1e6 if r.Body != nil {
r.Body = http.MaxBytesReader(w, r.Body, MaxRespBodyLength)
}if data, err := io.ReadAll(r.Body); err == nil {
body = data
}
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Theoretical
Vulnerability theory is largely about how behaviors and resources interact. "Resource exhaustion" can be regarded as either a consequence or an attack, depending on the perspective. This entry is an attempt to reflect the underlying weaknesses that enable these attacks (or consequences) to take place.
Other Database queries that take a long time to process are good DoS targets. An attacker would have to write a few lines of Perl code to generate enough traffic to exceed the site's ability to keep up. This would effectively prevent authorized users from using the site at all. Resources can be exploited simply by ensuring that the target machine must do much more work and consume more resources in order to service a request than the attacker must do to initiate a request. A prime example of this can be found in old switches that were vulnerable to "macof" attacks (so named for a tool developed by Dugsong). These attacks flooded a switch with random IP and MAC address combinations, therefore exhausting the switch's cache, which held the information of which port corresponded to which MAC addresses. Once this cache was exhausted, the switch would fail in an insecure way and would begin to act simply as a hub, broadcasting all traffic on all ports and allowing for basic sniffing attacks. Maintenance
"Resource consumption" could be interpreted as a consequence instead of an insecure behavior, so this entry is being considered for modification. It appears to be referenced too frequently when more precise mappings are available. Some of its children, such as CWE-771, might be better considered as a chain.
Maintenance
The Taxonomy_Mappings to ISA/IEC 62443 were added in CWE 4.10, but they are still under review and might change in future CWE versions. These draft mappings were performed by members of the "Mapping CWE to 62443" subgroup of the CWE-CAPEC ICS/OT Special Interest Group (SIG), and their work is incomplete as of CWE 4.10. The mappings are included to facilitate discussion and review by the broader ICS/OT community, and they are likely to change in future CWE versions.
CWE-412: Unrestricted Externally Accessible Lock
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Edit Custom FilterThe product properly checks for the existence of a lock, but the lock can be externally controlled or influenced by an actor that is outside of the intended sphere of control.
This prevents the product from acting on associated resources or performing other behaviors that are controlled by the presence of the lock. Relevant locks might include an exclusive lock or mutex, or modifying a shared resource that is treated as a lock. If the lock can be held for an indefinite period of time, then the denial of service could be permanent.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Example 1 This code tries to obtain a lock for a file, then writes to it. (bad code)
Example Language: PHP
function writeToLog($message){
$logfile = fopen("logFile.log", "a"); }//attempt to get logfile lock if (flock($logfile, LOCK_EX)) { fwrite($logfile,$message); }// unlock logfile flock($logfile, LOCK_UN); else { print "Could not obtain lock on logFile.log, message not recorded\n"; }fclose($logFile); PHP by default will wait indefinitely until a file lock is released. If an attacker is able to obtain the file lock, this code will pause execution, possibly leading to denial of service for other users. Note that in this case, if an attacker can perform an flock() on the file, they may already have privileges to destroy the log file. However, this still impacts the execution of other programs that depend on flock().
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Relationship
This overlaps Insufficient Resource Pool when the "pool" is of size 1. It can also be resultant from race conditions, although the timing window could be quite large in some cases.
CWE-567: Unsynchronized Access to Shared Data in a Multithreaded Context
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Edit Custom FilterThe product does not properly synchronize shared data, such as static variables across threads, which can lead to undefined behavior and unpredictable data changes.
Within servlets, shared static variables are not protected from concurrent access, but servlets are multithreaded. This is a typical programming mistake in J2EE applications, since the multithreading is handled by the framework. When a shared variable can be influenced by an attacker, one thread could wind up modifying the variable to contain data that is not valid for a different thread that is also using the data within the variable. Note that this weakness is not unique to servlets. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 The following code implements a basic counter for how many times the page has been accesed. (bad code)
Example Language: Java
public static class Counter extends HttpServlet {
static int count = 0; }protected void doGet(HttpServletRequest in, HttpServletResponse out) throws ServletException, IOException { out.setContentType("text/plain"); }PrintWriter p = out.getWriter(); count++; p.println(count + " hits so far!"); Consider when two separate threads, Thread A and Thread B, concurrently handle two different requests:
At this point, both Thread A and Thread B print that one hit has been seen, even though two separate requests have been processed. The value of count should be 2, not 1. While this example does not have any real serious implications, if the shared variable in question is used for resource tracking, then resource consumption could occur. Other scenarios exist.
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weakness fits within the context of external information sources.
CWE-134: Use of Externally-Controlled Format String
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Edit Custom FilterThe product uses a function that accepts a format string as an argument, but the format string originates from an external source.
When an attacker can modify an externally-controlled format string, this can lead to buffer overflows, denial of service, or data representation problems. It should be noted that in some circumstances, such as internationalization, the set of format strings is externally controlled by design. If the source of these format strings is trusted (e.g. only contained in library files that are only modifiable by the system administrator), then the external control might not itself pose a vulnerability. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Seven Pernicious Kingdoms" (CWE-700)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages C (Often Prevalent) C++ (Often Prevalent) Perl (Rarely Prevalent) Example 1 The following program prints a string provided as an argument. (bad code)
Example Language: C
#include <stdio.h>
void printWrapper(char *string) { printf(string); int main(int argc, char **argv) { char buf[5012]; memcpy(buf, argv[1], 5012); printWrapper(argv[1]); return (0); The example is exploitable, because of the call to printf() in the printWrapper() function. Note: The stack buffer was added to make exploitation more simple. Example 2 The following code copies a command line argument into a buffer using snprintf(). (bad code)
Example Language: C
int main(int argc, char **argv){
char buf[128]; }... snprintf(buf,128,argv[1]); This code allows an attacker to view the contents of the stack and write to the stack using a command line argument containing a sequence of formatting directives. The attacker can read from the stack by providing more formatting directives, such as %x, than the function takes as arguments to be formatted. (In this example, the function takes no arguments to be formatted.) By using the %n formatting directive, the attacker can write to the stack, causing snprintf() to write the number of bytes output thus far to the specified argument (rather than reading a value from the argument, which is the intended behavior). A sophisticated version of this attack will use four staggered writes to completely control the value of a pointer on the stack. Example 3 Certain implementations make more advanced attacks even easier by providing format directives that control the location in memory to read from or write to. An example of these directives is shown in the following code, written for glibc: (bad code)
Example Language: C
printf("%d %d %1$d %1$d\n", 5, 9);
This code produces the following output: 5 9 5 5 It is also possible to use half-writes (%hn) to accurately control arbitrary DWORDS in memory, which greatly reduces the complexity needed to execute an attack that would otherwise require four staggered writes, such as the one mentioned in the first example.
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Applicable Platform This weakness is possible in any programming language that support format strings. Research Gap
Format string issues are under-studied for languages other than C. Memory or disk consumption, control flow or variable alteration, and data corruption may result from format string exploitation in applications written in other languages such as Perl, PHP, Python, etc.
Other While Format String vulnerabilities typically fall under the Buffer Overflow category, technically they are not overflowed buffers. The Format String vulnerability is fairly new (circa 1999) and stems from the fact that there is no realistic way for a function that takes a variable number of arguments to determine just how many arguments were passed in. The most common functions that take a variable number of arguments, including C-runtime functions, are the printf() family of calls. The Format String problem appears in a number of ways. A *printf() call without a format specifier is dangerous and can be exploited. For example, printf(input); is exploitable, while printf(y, input); is not exploitable in that context. The result of the first call, used incorrectly, allows for an attacker to be able to peek at stack memory since the input string will be used as the format specifier. The attacker can stuff the input string with format specifiers and begin reading stack values, since the remaining parameters will be pulled from the stack. Worst case, this improper use may give away enough control to allow an arbitrary value (or values in the case of an exploit program) to be written into the memory of the running program. Frequently targeted entities are file names, process names, identifiers. Format string problems are a classic C/C++ issue that are now rare due to the ease of discovery. One main reason format string vulnerabilities can be exploited is due to the %n operator. The %n operator will write the number of characters, which have been printed by the format string therefore far, to the memory pointed to by its argument. Through skilled creation of a format string, a malicious user may use values on the stack to create a write-what-where condition. Once this is achieved, they can execute arbitrary code. Other operators can be used as well; for example, a %9999s operator could also trigger a buffer overflow, or when used in file-formatting functions like fprintf, it can generate a much larger output than intended.
CWE-470: Use of Externally-Controlled Input to Select Classes or Code ('Unsafe Reflection')
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Edit Custom FilterThe product uses external input with reflection to select which classes or code to use, but it does not sufficiently prevent the input from selecting improper classes or code.
If the product uses external inputs to determine which class to instantiate or which method to invoke, then an attacker could supply values to select unexpected classes or methods. If this occurs, then the attacker could create control flow paths that were not intended by the developer. These paths could bypass authentication or access control checks, or otherwise cause the product to behave in an unexpected manner. This situation becomes a doomsday scenario if the attacker can upload files into a location that appears on the product's classpath (CWE-427) or add new entries to the product's classpath (CWE-426). Under either of these conditions, the attacker can use reflection to introduce new, malicious behavior into the product.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Seven Pernicious Kingdoms" (CWE-700)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) PHP (Undetermined Prevalence) Class: Interpreted (Sometimes Prevalent) Example 1 A common reason that programmers use the reflection API is to implement their own command dispatcher. The following example shows a command dispatcher that does not use reflection: (good code)
Example Language: Java
String ctl = request.getParameter("ctl");
Worker ao = null; if (ctl.equals("Add")) { ao = new AddCommand(); }else if (ctl.equals("Modify")) { ao = new ModifyCommand(); }else { throw new UnknownActionError(); }ao.doAction(request); A programmer might refactor this code to use reflection as follows: (bad code)
Example Language: Java
String ctl = request.getParameter("ctl");
Class cmdClass = Class.forName(ctl + "Command"); Worker ao = (Worker) cmdClass.newInstance(); ao.doAction(request); The refactoring initially appears to offer a number of advantages. There are fewer lines of code, the if/else blocks have been entirely eliminated, and it is now possible to add new command types without modifying the command dispatcher. However, the refactoring allows an attacker to instantiate any object that implements the Worker interface. If the command dispatcher is still responsible for access control, then whenever programmers create a new class that implements the Worker interface, they must remember to modify the dispatcher's access control code. If they do not modify the access control code, then some Worker classes will not have any access control. One way to address this access control problem is to make the Worker object responsible for performing the access control check. An example of the re-refactored code follows: (bad code)
Example Language: Java
String ctl = request.getParameter("ctl");
Class cmdClass = Class.forName(ctl + "Command"); Worker ao = (Worker) cmdClass.newInstance(); ao.checkAccessControl(request); ao.doAction(request); Although this is an improvement, it encourages a decentralized approach to access control, which makes it easier for programmers to make access control mistakes. This code also highlights another security problem with using reflection to build a command dispatcher. An attacker can invoke the default constructor for any kind of object. In fact, the attacker is not even constrained to objects that implement the Worker interface; the default constructor for any object in the system can be invoked. If the object does not implement the Worker interface, a ClassCastException will be thrown before the assignment to ao, but if the constructor performs operations that work in the attacker's favor, the damage will already have been done. Although this scenario is relatively benign in simple products, in larger products where complexity grows exponentially it is not unreasonable that an attacker could find a constructor to leverage as part of an attack.
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CWE-798: Use of Hard-coded Credentials
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Edit Custom FilterThere are two main variations:
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Class: Mobile (Undetermined Prevalence) Class: ICS/OT (Often Prevalent) Example 1 The following code uses a hard-coded password to connect to a database: (bad code)
Example Language: Java
...
DriverManager.getConnection(url, "scott", "tiger"); ... This is an example of an external hard-coded password on the client-side of a connection. This code will run successfully, but anyone who has access to it will have access to the password. Once the program has shipped, there is no going back from the database user "scott" with a password of "tiger" unless the program is patched. A devious employee with access to this information can use it to break into the system. Even worse, if attackers have access to the bytecode for application, they can use the javap -c command to access the disassembled code, which will contain the values of the passwords used. The result of this operation might look something like the following for the example above: (attack code)
javap -c ConnMngr.class
22: ldc #36; //String jdbc:mysql://ixne.com/rxsql
24: ldc #38; //String scott 26: ldc #17; //String tiger Example 2 The following code is an example of an internal hard-coded password in the back-end: (bad code)
Example Language: C
int VerifyAdmin(char *password) {
if (strcmp(password, "Mew!")) {
printf("Incorrect Password!\n");
return(0) printf("Entering Diagnostic Mode...\n"); return(1); (bad code)
Example Language: Java
int VerifyAdmin(String password) {
if (!password.equals("Mew!")) { }return(0) }//Diagnostic Mode return(1); Every instance of this program can be placed into diagnostic mode with the same password. Even worse is the fact that if this program is distributed as a binary-only distribution, it is very difficult to change that password or disable this "functionality." Example 3 The following code examples attempt to verify a password using a hard-coded cryptographic key. (bad code)
Example Language: C
int VerifyAdmin(char *password) {
if (strcmp(password,"68af404b513073584c4b6f22b6c63e6b")) {
printf("Incorrect Password!\n"); return(0); printf("Entering Diagnostic Mode...\n"); return(1); (bad code)
Example Language: Java
public boolean VerifyAdmin(String password) {
if (password.equals("68af404b513073584c4b6f22b6c63e6b")) {
System.out.println("Entering Diagnostic Mode..."); }return true; System.out.println("Incorrect Password!"); return false; (bad code)
Example Language: C#
int VerifyAdmin(String password) {
if (password.Equals("68af404b513073584c4b6f22b6c63e6b")) { }Console.WriteLine("Entering Diagnostic Mode..."); }return(1); Console.WriteLine("Incorrect Password!"); return(0); The cryptographic key is within a hard-coded string value that is compared to the password. It is likely that an attacker will be able to read the key and compromise the system. Example 4 The following examples show a portion of properties and configuration files for Java and ASP.NET applications. The files include username and password information but they are stored in cleartext. This Java example shows a properties file with a cleartext username / password pair. (bad code)
Example Language: Java
# Java Web App ResourceBundle properties file ... webapp.ldap.username=secretUsername webapp.ldap.password=secretPassword ... The following example shows a portion of a configuration file for an ASP.Net application. This configuration file includes username and password information for a connection to a database but the pair is stored in cleartext. (bad code)
Example Language: ASP.NET
...
<connectionStrings> <add name="ud_DEV" connectionString="connectDB=uDB; uid=db2admin; pwd=password; dbalias=uDB;" providerName="System.Data.Odbc" /> </connectionStrings>... Username and password information should not be included in a configuration file or a properties file in cleartext as this will allow anyone who can read the file access to the resource. If possible, encrypt this information. Example 5 In 2022, the OT:ICEFALL study examined products by 10 different Operational Technology (OT) vendors. The researchers reported 56 vulnerabilities and said that the products were "insecure by design" [REF-1283]. If exploited, these vulnerabilities often allowed adversaries to change how the products operated, ranging from denial of service to changing the code that the products executed. Since these products were often used in industries such as power, electrical, water, and others, there could even be safety implications. Multiple vendors used hard-coded credentials in their OT products.
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reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Maintenance
The Taxonomy_Mappings to ISA/IEC 62443 were added in CWE 4.10, but they are still under review and might change in future CWE versions. These draft mappings were performed by members of the "Mapping CWE to 62443" subgroup of the CWE-CAPEC ICS/OT Special Interest Group (SIG), and their work is incomplete as of CWE 4.10. The mappings are included to facilitate discussion and review by the broader ICS/OT community, and they are likely to change in future CWE versions.
CWE-259: Use of Hard-coded Password
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Edit Custom FilterThe product contains a hard-coded password, which it uses for its own inbound authentication or for outbound communication to external components.
A hard-coded password typically leads to a significant authentication failure that can be difficult for the system administrator to detect. Once detected, it can be difficult to fix, so the administrator may be forced into disabling the product entirely. There are two main variations: Inbound: the product contains an authentication mechanism that checks for a hard-coded password.
Outbound: the product connects to another system or component, and it contains hard-coded password for connecting to that component.
In the Inbound variant, a default administration account is created, and a simple password is hard-coded into the product and associated with that account. This hard-coded password is the same for each installation of the product, and it usually cannot be changed or disabled by system administrators without manually modifying the program, or otherwise patching the product. If the password is ever discovered or published (a common occurrence on the Internet), then anybody with knowledge of this password can access the product. Finally, since all installations of the product will have the same password, even across different organizations, this enables massive attacks such as worms to take place. The Outbound variant applies to front-end systems that authenticate with a back-end service. The back-end service may require a fixed password which can be easily discovered. The programmer may simply hard-code those back-end credentials into the front-end product. Any user of that program may be able to extract the password. Client-side systems with hard-coded passwords pose even more of a threat, since the extraction of a password from a binary is usually very simple. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Class: ICS/OT (Undetermined Prevalence) Example 1 The following code uses a hard-coded password to connect to a database: (bad code)
Example Language: Java
...
DriverManager.getConnection(url, "scott", "tiger"); ... This is an example of an external hard-coded password on the client-side of a connection. This code will run successfully, but anyone who has access to it will have access to the password. Once the program has shipped, there is no going back from the database user "scott" with a password of "tiger" unless the program is patched. A devious employee with access to this information can use it to break into the system. Even worse, if attackers have access to the bytecode for application, they can use the javap -c command to access the disassembled code, which will contain the values of the passwords used. The result of this operation might look something like the following for the example above: (attack code)
javap -c ConnMngr.class
22: ldc #36; //String jdbc:mysql://ixne.com/rxsql
24: ldc #38; //String scott 26: ldc #17; //String tiger Example 2 The following code is an example of an internal hard-coded password in the back-end: (bad code)
Example Language: C
int VerifyAdmin(char *password) {
if (strcmp(password, "Mew!")) {
printf("Incorrect Password!\n");
return(0) printf("Entering Diagnostic Mode...\n"); return(1); (bad code)
Example Language: Java
int VerifyAdmin(String password) {
if (!password.equals("Mew!")) { }return(0) }//Diagnostic Mode return(1); Every instance of this program can be placed into diagnostic mode with the same password. Even worse is the fact that if this program is distributed as a binary-only distribution, it is very difficult to change that password or disable this "functionality." Example 3 The following examples show a portion of properties and configuration files for Java and ASP.NET applications. The files include username and password information but they are stored in cleartext. This Java example shows a properties file with a cleartext username / password pair. (bad code)
Example Language: Java
# Java Web App ResourceBundle properties file ... webapp.ldap.username=secretUsername webapp.ldap.password=secretPassword ... The following example shows a portion of a configuration file for an ASP.Net application. This configuration file includes username and password information for a connection to a database but the pair is stored in cleartext. (bad code)
Example Language: ASP.NET
...
<connectionStrings> <add name="ud_DEV" connectionString="connectDB=uDB; uid=db2admin; pwd=password; dbalias=uDB;" providerName="System.Data.Odbc" /> </connectionStrings>... Username and password information should not be included in a configuration file or a properties file in cleartext as this will allow anyone who can read the file access to the resource. If possible, encrypt this information. Example 4 In 2022, the OT:ICEFALL study examined products by 10 different Operational Technology (OT) vendors. The researchers reported 56 vulnerabilities and said that the products were "insecure by design" [REF-1283]. If exploited, these vulnerabilities often allowed adversaries to change how the products operated, ranging from denial of service to changing the code that the products executed. Since these products were often used in industries such as power, electrical, water, and others, there could even be safety implications. Multiple vendors used hard-coded credentials in their OT products.
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Maintenance
This entry could be split into multiple variants: an inbound variant (as seen in the second demonstrative example) and an outbound variant (as seen in the first demonstrative example). These variants are likely to have different consequences, detectability, etc. More importantly, from a vulnerability theory perspective, they could be characterized as different behaviors.
CWE-198: Use of Incorrect Byte Ordering
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Edit Custom FilterThe product receives input from an upstream component, but it does not account for byte ordering (e.g. big-endian and little-endian) when processing the input, causing an incorrect number or value to be used.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence)
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-492: Use of Inner Class Containing Sensitive Data
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Edit Custom FilterInner classes are translated into classes that are accessible at package scope and may expose code that the programmer intended to keep private to attackers.
Inner classes quietly introduce several security concerns because of the way they are translated into Java bytecode. In Java source code, it appears that an inner class can be declared to be accessible only by the enclosing class, but Java bytecode has no concept of an inner class, so the compiler must transform an inner class declaration into a peer class with package level access to the original outer class. More insidiously, since an inner class can access private fields in its enclosing class, once an inner class becomes a peer class in bytecode, the compiler converts private fields accessed by the inner class into protected fields.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 The following Java Applet code mistakenly makes use of an inner class. (bad code)
Example Language: Java
public final class urlTool extends Applet {
private final class urlHelper { }... }... Example 2 The following example shows a basic use of inner classes. The class OuterClass contains the private member inner class InnerClass. The private inner class InnerClass includes the method concat that accesses the private member variables of the class OuterClass to output the value of one of the private member variables of the class OuterClass and returns a string that is a concatenation of one of the private member variables of the class OuterClass, the separator input parameter of the method and the private member variable of the class InnerClass. (bad code)
Example Language: Java
public class OuterClass {
// private member variables of OuterClass
}private String memberOne; private String memberTwo; // constructor of OuterClass public OuterClass(String varOne, String varTwo) { this.memberOne = varOne; }this.memberTwo = varTwo; // InnerClass is a member inner class of OuterClass private class InnerClass { private String innerMemberOne; }public InnerClass(String innerVarOne) { this.innerMemberOne = innerVarOne; }public String concat(String separator) {
// InnerClass has access to private member variables of OuterClass
}System.out.println("Value of memberOne is: " + memberOne); return OuterClass.this.memberTwo + separator + this.innerMemberOne; Although this is an acceptable use of inner classes it demonstrates one of the weaknesses of inner classes that inner classes have complete access to all member variables and methods of the enclosing class even those that are declared private and protected. When inner classes are compiled and translated into Java bytecode the JVM treats the inner class as a peer class with package level access to the enclosing class. To avoid this weakness of inner classes, consider using either static inner classes, local inner classes, or anonymous inner classes. The following Java example demonstrates the use of static inner classes using the previous example. The inner class InnerClass is declared using the static modifier that signifies that InnerClass is a static member of the enclosing class OuterClass. By declaring an inner class as a static member of the enclosing class, the inner class can only access other static members and methods of the enclosing class and prevents the inner class from accessing nonstatic member variables and methods of the enclosing class. In this case the inner class InnerClass can only access the static member variable memberTwo of the enclosing class OuterClass but cannot access the nonstatic member variable memberOne. (good code)
Example Language: Java
public class OuterClass {
// private member variables of OuterClass private String memberOne; private static String memberTwo; // constructor of OuterClass public OuterClass(String varOne, String varTwo) { this.memberOne = varOne; }this.memberTwo = varTwo; // InnerClass is a static inner class of OuterClass private static class InnerClass { private String innerMemberOne; public InnerClass(String innerVarOne) { this.innerMemberOne = innerVarOne; }public String concat(String separator) {
// InnerClass only has access to static member variables of OuterClass
return memberTwo + separator + this.innerMemberOne; The only limitation with using a static inner class is that as a static member of the enclosing class the inner class does not have a reference to instances of the enclosing class. For many situations this may not be ideal. An alternative is to use a local inner class or an anonymous inner class as shown in the next examples. Example 3 In the following example the BankAccount class contains the private member inner class InterestAdder that adds interest to the bank account balance. The start method of the BankAccount class creates an object of the inner class InterestAdder, the InterestAdder inner class implements the ActionListener interface with the method actionPerformed. A Timer object created within the start method of the BankAccount class invokes the actionPerformed method of the InterestAdder class every 30 days to add the interest to the bank account balance based on the interest rate passed to the start method as an input parameter. The inner class InterestAdder needs access to the private member variable balance of the BankAccount class in order to add the interest to the bank account balance. However as demonstrated in the previous example, because InterestAdder is a non-static member inner class of the BankAccount class, InterestAdder also has access to the private member variables of the BankAccount class - including the sensitive data contained in the private member variables for the bank account owner's name, Social Security number, and the bank account number. (bad code)
Example Language: Java
public class BankAccount {
// private member variables of BankAccount class private String accountOwnerName; private String accountOwnerSSN; private int accountNumber; private double balance; // constructor for BankAccount class public BankAccount(String accountOwnerName, String accountOwnerSSN, int accountNumber, double initialBalance, int initialRate) { this.accountOwnerName = accountOwnerName; }this.accountOwnerSSN = accountOwnerSSN; this.accountNumber = accountNumber; this.balance = initialBalance; this.start(initialRate); // start method will add interest to balance every 30 days // creates timer object and interest adding action listener object public void start(double rate) { ActionListener adder = new InterestAdder(rate); }Timer t = new Timer(1000 * 3600 * 24 * 30, adder); t.start(); // InterestAdder is an inner class of BankAccount class // that implements the ActionListener interface private class InterestAdder implements ActionListener { private double rate;
public InterestAdder(double aRate) { this.rate = aRate; }public void actionPerformed(ActionEvent event) {
// update interest
double interest = BankAccount.this.balance * rate / 100; BankAccount.this.balance += interest; In the following example the InterestAdder class from the above example is declared locally within the start method of the BankAccount class. As a local inner class InterestAdder has its scope restricted to the method (or enclosing block) where it is declared, in this case only the start method has access to the inner class InterestAdder, no other classes including the enclosing class has knowledge of the inner class outside of the start method. This allows the inner class to access private member variables of the enclosing class but only within the scope of the enclosing method or block. (good code)
Example Language: Java
public class BankAccount {
// private member variables of BankAccount class private String accountOwnerName; private String accountOwnerSSN; private int accountNumber; private double balance; // constructor for BankAccount class public BankAccount(String accountOwnerName, String accountOwnerSSN, int accountNumber, double initialBalance, int initialRate) { this.accountOwnerName = accountOwnerName; }this.accountOwnerSSN = accountOwnerSSN; this.accountNumber = accountNumber; this.balance = initialBalance; this.start(initialRate); // start method will add interest to balance every 30 days // creates timer object and interest adding action listener object public void start(final double rate) { // InterestAdder is a local inner class // that implements the ActionListener interface class InterestAdder implements ActionListener { public void actionPerformed(ActionEvent event)
{
// update interest
double interest = BankAccount.this.balance * rate / 100; BankAccount.this.balance += interest; ActionListener adder = new InterestAdder(); Timer t = new Timer(1000 * 3600 * 24 * 30, adder); t.start(); A similar approach would be to use an anonymous inner class as demonstrated in the next example. An anonymous inner class is declared without a name and creates only a single instance of the inner class object. As in the previous example the anonymous inner class has its scope restricted to the start method of the BankAccount class. (good code)
Example Language: Java
public class BankAccount {
// private member variables of BankAccount class private String accountOwnerName; private String accountOwnerSSN; private int accountNumber; private double balance; // constructor for BankAccount class public BankAccount(String accountOwnerName, String accountOwnerSSN, int accountNumber, double initialBalance, int initialRate) { this.accountOwnerName = accountOwnerName; }this.accountOwnerSSN = accountOwnerSSN; this.accountNumber = accountNumber; this.balance = initialBalance; this.start(initialRate); // start method will add interest to balance every 30 days // creates timer object and interest adding action listener object public void start(final double rate) { // anonymous inner class that implements the ActionListener interface ActionListener adder = new ActionListener() { public void actionPerformed(ActionEvent event)
{ double interest = BankAccount.this.balance * rate / 100; BankAccount.this.balance += interest; Timer t = new Timer(1000 * 3600 * 24 * 30, adder); t.start(); Example 4 In the following Java example a simple applet provides the capability for a user to input a URL into a text field and have the URL opened in a new browser window. The applet contains an inner class that is an action listener for the submit button, when the user clicks the submit button the inner class action listener's actionPerformed method will open the URL entered into the text field in a new browser window. As with the previous examples using inner classes in this manner creates a security risk by exposing private variables and methods. Inner classes create an additional security risk with applets as applets are executed on a remote machine through a web browser within the same JVM and therefore may run side-by-side with other potentially malicious code. (bad code)
public class UrlToolApplet extends Applet {
// private member variables for applet components private Label enterUrlLabel; private TextField enterUrlTextField; private Button submitButton; // init method that adds components to applet // and creates button listener object public void init() { setLayout(new FlowLayout()); }enterUrlLabel = new Label("Enter URL: "); enterUrlTextField = new TextField("", 20); submitButton = new Button("Submit"); add(enterUrlLabel); add(enterUrlTextField); add(submitButton); ActionListener submitButtonListener = new SubmitButtonListener(); submitButton.addActionListener(submitButtonListener); // button listener inner class for UrlToolApplet class private class SubmitButtonListener implements ActionListener { public void actionPerformed(ActionEvent evt) {
if (evt.getSource() == submitButton) {
String urlString = enterUrlTextField.getText(); }URL url = null; try { url = new URL(urlString); } catch (MalformedURLException e) {System.err.println("Malformed URL: " + urlString); }if (url != null) { getAppletContext().showDocument(url); }As with the previous examples a solution to this problem would be to use a static inner class, a local inner class or an anonymous inner class. An alternative solution would be to have the applet implement the action listener rather than using it as an inner class as shown in the following example. (good code)
Example Language: Java
public class UrlToolApplet extends Applet implements ActionListener {
// private member variables for applet components private Label enterUrlLabel; private TextField enterUrlTextField; private Button submitButton; // init method that adds components to applet public void init() { setLayout(new FlowLayout()); }enterUrlLabel = new Label("Enter URL: "); enterUrlTextField = new TextField("", 20); submitButton = new Button("Submit"); add(enterUrlLabel); add(enterUrlTextField); add(submitButton); submitButton.addActionListener(this); // implementation of actionPerformed method of ActionListener interface public void actionPerformed(ActionEvent evt) { if (evt.getSource() == submitButton) {
String urlString = enterUrlTextField.getText(); }URL url = null; try { url = new URL(urlString); } catch (MalformedURLException e) {System.err.println("Malformed URL: " + urlString); }if (url != null) { getAppletContext().showDocument(url); }
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Other
Mobile code, in this case a Java Applet, is code that is transmitted across a network and executed on a remote machine. Because mobile code developers have little if any control of the environment in which their code will execute, special security concerns become relevant. One of the biggest environmental threats results from the risk that the mobile code will run side-by-side with other, potentially malicious, mobile code. Because all of the popular web browsers execute code from multiple sources together in the same JVM, many of the security guidelines for mobile code are focused on preventing manipulation of your objects' state and behavior by adversaries who have access to the same virtual machine where your program is running.
CWE-330: Use of Insufficiently Random Values
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Edit Custom FilterThe product uses insufficiently random numbers or values in a security context that depends on unpredictable numbers.
When product generates predictable values in a context requiring unpredictability, it may be possible for an attacker to guess the next value that will be generated, and use this guess to impersonate another user or access sensitive information.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Class: Not Technology-Specific (Undetermined Prevalence) Example 1 This code attempts to generate a unique random identifier for a user's session. (bad code)
Example Language: PHP
function generateSessionID($userID){
srand($userID); }return rand(); Because the seed for the PRNG is always the user's ID, the session ID will always be the same. An attacker could thus predict any user's session ID and potentially hijack the session. This example also exhibits a Small Seed Space (CWE-339). Example 2 The following code uses a statistical PRNG to create a URL for a receipt that remains active for some period of time after a purchase. (bad code)
Example Language: Java
String GenerateReceiptURL(String baseUrl) {
Random ranGen = new Random(); }ranGen.setSeed((new Date()).getTime()); return(baseUrl + ranGen.nextInt(400000000) + ".html"); This code uses the Random.nextInt() function to generate "unique" identifiers for the receipt pages it generates. Because Random.nextInt() is a statistical PRNG, it is easy for an attacker to guess the strings it generates. Although the underlying design of the receipt system is also faulty, it would be more secure if it used a random number generator that did not produce predictable receipt identifiers, such as a cryptographic PRNG.
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
Relationship
This can be primary to many other weaknesses such as cryptographic errors, authentication errors, symlink following, information leaks, and others.
Maintenance
As of CWE 4.3, CWE-330 and its descendants are being
investigated by the CWE crypto team to identify gaps
related to randomness and unpredictability, as well as
the relationships between randomness and cryptographic
primitives. This "subtree analysis" might
result in the addition or deprecation of existing
entries; the reorganization of relationships in some
views, e.g. the research view (CWE-1000); more consistent
use of terminology; and/or significant modifications to
related entries.
Maintenance
As of CWE 4.5, terminology related to randomness, entropy, and
predictability can vary widely. Within the developer and other
communities, "randomness" is used heavily. However, within
cryptography, "entropy" is distinct, typically implied as a
measurement. There are no commonly-used definitions, even within
standards documents and cryptography papers. Future versions of
CWE will attempt to define these terms and, if necessary,
distinguish between them in ways that are appropriate for
different communities but do not reduce the usability of CWE for
mapping, understanding, or other scenarios.
CWE-647: Use of Non-Canonical URL Paths for Authorization Decisions
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Edit Custom FilterThe product defines policy namespaces and makes authorization decisions based on the assumption that a URL is canonical. This can allow a non-canonical URL to bypass the authorization.
If an application defines policy namespaces and makes authorization decisions based on the URL, but it does not require or convert to a canonical URL before making the authorization decision, then it opens the application to attack. For example, if the application only wants to allow access to http://www.example.com/mypage, then the attacker might be able to bypass this restriction using equivalent URLs such as:
Therefore it is important to specify access control policy that is based on the path information in some canonical form with all alternate encodings rejected (which can be accomplished by a default deny rule). This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Architectural Concepts" (CWE-1008)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Class: Not Language-Specific (Undetermined Prevalence) Technologies Web Server (Undetermined Prevalence) Example 1 Example from CAPEC (CAPEC ID: 4, "Using Alternative IP Address Encodings"). An attacker identifies an application server that applies a security policy based on the domain and application name, so the access control policy covers authentication and authorization for anyone accessing http://example.domain:8080/application. However, by putting in the IP address of the host the application authentication and authorization controls may be bypassed http://192.168.0.1:8080/application. The attacker relies on the victim applying policy to the namespace abstraction and not having a default deny policy in place to manage exceptions.
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-395: Use of NullPointerException Catch to Detect NULL Pointer Dereference
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Edit Custom FilterCatching NullPointerException should not be used as an alternative to programmatic checks to prevent dereferencing a null pointer.
Programmers typically catch NullPointerException under three circumstances:
Of these three circumstances, only the last is acceptable. This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "Software Development" (CWE-699)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) Example 1 The following code mistakenly catches a NullPointerException. (bad code)
Example Language: Java
try {
mysteryMethod();
} catch (NullPointerException npe) {}
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-543: Use of Singleton Pattern Without Synchronization in a Multithreaded Context
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Edit Custom FilterThe product uses the singleton pattern when creating a resource within a multithreaded environment.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
Relevant to the view "CISQ Data Protection Measures" (CWE-1340)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
This listing shows possible areas for which the given
weakness could appear. These
may be for specific named Languages, Operating Systems, Architectures, Paradigms,
Technologies,
or a class of such platforms. The platform is listed along with how frequently the given
weakness appears for that instance.
Languages Java (Undetermined Prevalence) C++ (Undetermined Prevalence) Example 1 This method is part of a singleton pattern, yet the following singleton() pattern is not thread-safe. It is possible that the method will create two objects instead of only one. (bad code)
Example Language: Java
private static NumberConverter singleton;
public static NumberConverter get_singleton() { if (singleton == null) { }singleton = new NumberConverter(); }return singleton; Consider the following course of events:
At this point, the threads have created and returned two different objects.
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
CWE-597: Use of Wrong Operator in String Comparison
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Edit Custom FilterThe product uses the wrong operator when comparing a string, such as using "==" when the .equals() method should be used instead.
In Java, using == or != to compare two strings for equality actually compares two objects for equality rather than their string values for equality. Chances are good that the two references will never be equal. While this weakness often only affects program correctness, if the equality is used for a security decision, the unintended comparison result could be leveraged to affect program security.
This table specifies different individual consequences
associated with the weakness. The Scope identifies the application security area that is
violated, while the Impact describes the negative technical impact that arises if an
adversary succeeds in exploiting this weakness. The Likelihood provides information about
how likely the specific consequence is expected to be seen relative to the other
consequences in the list. For example, there may be high likelihood that a weakness will be
exploited to achieve a certain impact, but a low likelihood that it will be exploited to
achieve a different impact.
This table shows the weaknesses and high level categories that are related to this
weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to
similar items that may exist at higher and lower levels of abstraction. In addition,
relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user
may want to explore.
Relevant to the view "Research Concepts" (CWE-1000)
Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305)
The different Modes of Introduction provide information
about how and when this
weakness may be introduced. The Phase identifies a point in the life cycle at which
introduction
may occur, while the Note provides a typical scenario related to introduction during the
given
phase.
Example 1 In the example below, two Java String objects are declared and initialized with the same string values. An if statement is used to determine if the strings are equivalent. (bad code)
Example Language: Java
String str1 = new String("Hello");
String str2 = new String("Hello"); if (str1 == str2) { System.out.println("str1 == str2"); }However, the if statement will not be executed as the strings are compared using the "==" operator. For Java objects, such as String objects, the "==" operator compares object references, not object values. While the two String objects above contain the same string values, they refer to different object references, so the System.out.println statement will not be executed. To compare object values, the previous code could be modified to use the equals method: (good code)
if (str1.equals(str2)) {
System.out.println("str1 equals str2"); }Example 2 In the example below, three JavaScript variables are declared and initialized with the same values. Note that JavaScript will change a value between numeric and string as needed, which is the reason an integer is included with the strings. An if statement is used to determine whether the values are the same. (bad code)
Example Language: JavaScript
<p id="ieq3s1" type="text">(i === s1) is FALSE</p>
<p id="s4eq3i" type="text">(s4 === i) is FALSE</p> <p id="s4eq3s1" type="text">(s4 === s1) is FALSE</p> var i = 65; var s1 = '65'; var s4 = new String('65'); if (i === s1) { document.getElementById("ieq3s1").innerHTML = "(i === s1) is TRUE";
}if (s4 === i) { document.getElementById("s4eq3i").innerHTML = "(s4 === i) is TRUE";
}if (s4 === s1) { document.getElementById("s4eq3s1").innerHTML = "(s4 === s1) is TRUE";
}However, the body of the if statement will not be executed, as the "===" compares both the type of the variable AND the value. As the types of the first comparison are number and string, it fails. The types in the second are int and reference, so this one fails as well. The types in the third are reference and string, so it also fails. While the variables above contain the same values, they are contained in different types, so the document.getElementById... statement will not be executed in any of the cases. To compare object values, the previous code is modified and shown below to use the "==" for value comparison so the comparison in this example executes the HTML statement: (good code)
Example Language: JavaScript
<p id="ieq2s1" type="text">(i == s1) is FALSE</p>
<p id="s4eq2i" type="text">(s4 == i) is FALSE</p> <p id="s4eq2s1" type="text">(s4 == s1) is FALSE</p> var i = 65; var s1 = '65'; var s4 = new String('65'); if (i == s1) { document.getElementById("ieq2s1").innerHTML = "(i == s1) is TRUE";
}if (s4 == i) { document.getElementById("s4eq2i").innerHTML = "(s4 == i) is TRUE";
}if (s4 == s1) { document.getElementById("s4eq2s1").innerHTML = "(s4 == s1) is TRUE";
}Example 3 In the example below, two PHP variables are declared and initialized with the same numbers - one as a string, the other as an integer. Note that PHP will change the string value to a number for a comparison. An if statement is used to determine whether the values are the same. (bad code)
Example Language: PHP
var $i = 65;
var $s1 = "65"; if ($i === $s1) { echo '($i === $s1) is TRUE'. "\n";
}else { echo '($i === $s1) is FALSE'. "\n";
}However, the body of the if statement will not be executed, as the "===" compares both the type of the variable AND the value. As the types of the first comparison are number and string, it fails. While the variables above contain the same values, they are contained in different types, so the TRUE portion of the if statement will not be executed. To compare object values, the previous code is modified and shown below to use the "==" for value comparison (string converted to number) so the comparison in this example executes the TRUE statement: (good code)
Example Language: PHP
var $i = 65;
var $s1 = "65"; if ($i == $s1) { echo '($i == $s1) is TRUE'. "\n";
}else { echo '($i == $s1) is FALSE'. "\n";
}
This MemberOf Relationships table shows additional CWE Categories and Views that
reference this weakness as a member. This information is often useful in understanding where a
weakness fits within the context of external information sources.
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