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CWE-20 (输入验证不恰当) — Vulnerability Class 3320

3320 vulnerabilities classified as CWE-20 (输入验证不恰当). AI Chinese analysis included.

CWE-20 represents a critical software weakness where applications fail to properly verify the integrity, format, or type of incoming data before processing it. This oversight allows attackers to inject malicious payloads, such as SQL injection strings or cross-site scripting code, which can bypass security controls and compromise system integrity. Exploitation typically occurs when untrusted data from external sources, like user forms or network packets, is treated as executable code or trusted input. To mitigate this risk, developers must implement rigorous input validation strategies, including strict type checking, length constraints, and allow-listing acceptable characters. Additionally, employing parameterized queries and output encoding ensures that even if validation fails, the injected data remains inert, thereby preserving application security and preventing unauthorized execution or data exposure.

MITRE CWE Description
The product receives input or data, but it does not validate or incorrectly validates that the input has the properties that are required to process the data safely and correctly. Input validation is a frequently-used technique for checking potentially dangerous inputs in order to ensure that the inputs are safe for processing within the code, or when communicating with other components. Input can consist of: raw data - strings, numbers, parameters, file contents, etc. metadata - information about the raw data, such as headers or size Data can be simple or structured. Structured data can be composed of many nested layers, composed of combinations of metadata and raw data, with other simple or structured data. Many properties of raw data or metadata may need to be validated upon entry into the code, such as: specified quantities such as size, length, frequency, price, rate, number of operations, time, etc. implied or derived quantities, such as the actual size of a file instead of a specified size indexes, offsets, or positions into more complex data structures symbolic keys or other elements into hash tables, associative arrays, etc. well-formedness, i.e. syntactic correctness - compliance with expected syntax lexical token correctness - compliance with rules for what is treated as a token specified or derived type - the actual type of the input (or what the input appears to be) consistency - between individual data el…
Common Consequences (3)
AvailabilityDoS: Crash, Exit, or Restart, DoS: Resource Consumption (CPU), DoS: Resource Consumption (Memory)
An attacker could provide unexpected values and cause a program crash or arbitrary control of resource allocation, leading to excessive consumption of resources such as memory and CPU.
ConfidentialityRead Memory, Read Files or Directories
An attacker could read confidential data if they are able to control resource references.
Integrity, Confidentiality, AvailabilityModify Memory, Execute Unauthorized Code or Commands
An attacker could use malicious input to modify data or possibly alter control flow in unexpected ways, including arbitrary command execution.
Mitigations (5)
Architecture and DesignConsider using language-theoretic security (LangSec) techniques that characterize inputs using a formal language and build "recognizers" for that language. This effectively requires parsing to be a distinct layer that effectively enforces a boundary between raw input and internal data representations, instead of allowing parser code to be scattered throughout the program, where it could be subjec…
Architecture and DesignUse an input validation framework such as Struts or the OWASP ESAPI Validation API. Note that using a framework does not automatically address all input validation problems; be mindful of weaknesses that could arise from misusing the framework itself (CWE-1173).
Architecture and Design, ImplementationUnderstand all the potential areas where untrusted inputs can enter the product, including but not limited to: parameters or arguments, cookies, anything read from the network, environment variables, reverse DNS lookups, query results, request headers, URL components, e-mail, files, filenames, databases, and any external systems that provide data to the application. Remember that such inputs may b…
ImplementationAssume all input is malicious. Use an "accept known good" input validation strategy, i.e., use a list of acceptable inputs that strictly conform to specifications. Reject any input that does not strictly conform to specifications, or transform it into something that does. When performing input validation, consider all potentially relevant properties, including length, type of input, the full range…
Effectiveness: High
Architecture and DesignFor any security checks that are performed on the client side, ensure that these checks are duplicated on the server side, in order to avoid CWE-602. Attackers can bypass the client-side checks by modifying values after the checks have been performed, or by changing the client to remove the client-side checks entirely. Then, these modified values would be submitted to the server. Even though clien…
Examples (2)
This example demonstrates a shopping interaction in which the user is free to specify the quantity of items to be purchased and a total is calculated.
... public static final double price = 20.00; int quantity = currentUser.getAttribute("quantity"); double total = price * quantity; chargeUser(total); ...
Bad · Java
This example asks the user for a height and width of an m X n game board with a maximum dimension of 100 squares.
... #define MAX_DIM 100 ... /* board dimensions */ int m,n, error; board_square_t *board; printf("Please specify the board height: \n"); error = scanf("%d", &m); if ( EOF == error ){ die("No integer passed: Die evil hacker!\n"); } printf("Please specify the board width: \n"); error = scanf("%d", &n); if ( EOF == error ){ die("No integer passed: Die evil hacker!\n"); } if ( m > MAX_DIM || n > MAX_DIM ) { die("Value too large: Die evil hacker!\n"); } board = (board_square_t*) malloc( m * n * sizeof(board_square_t)); ...
Bad · C
CVE IDTitleCVSSSeverityPublished
CVE-2018-0387 Cisco Webex Teams 输入验证漏洞 — Cisco Webex Teams unknown 8.8 -2018-07-18
CVE-2018-0394 Cisco Cloud Services Platform 2100 输入验证漏洞 — Cisco Cloud Services Platform 2100 unknown 8.8 -2018-07-18
CVE-2018-10616 ABB Panel Builder 800 输入验证漏洞 — ABB Panel Builder 800 8.4 -2018-07-18
CVE-2017-15137 Red Hat OpenShift 安全漏洞 — atomic-openshift 7.1 -2018-07-16
CVE-2018-0369 多款Cisco产品Cisco StarOS 输入验证漏洞 — Cisco StarOS unknown 8.6 -2018-07-16
CVE-2016-9494 Hughes high-performance broadband satellite modems, models HN7740S DW7000 HN7000S/SM, are potentially vulnerable to improper input validation, potentially leading to denial of service — HN7740S 6.5 -2018-07-13
CVE-2018-10891 Moodle 注入漏洞 — moodle 7.3 -2018-07-10
CVE-2018-10888 libgit2 安全漏洞 — libgit2 6.5 -2018-07-10
CVE-2018-10885 Red Hat atomic-openshift 安全漏洞 — atomic-openshift 7.5 -2018-07-05
CVE-2018-10843 Red Hat OpenShift Container Platform source-to-image component 权限许可和访问控制漏洞 — source-to-image 7.8 -2018-07-02
CVE-2017-7466 Ansible 安全漏洞 — ansible 8.0 -2018-06-22
CVE-2017-2669 Dovecot 安全漏洞 — dovecot 7.5 -2018-06-21
CVE-2018-0298 多款Cisco产品FXOS和UCS Fabric Interconnect Software 输入验证漏洞 — Cisco FXOS Software and UCS Fabric Interconnect unknown 7.5 -2018-06-21
CVE-2018-0299 Cisco Nexus 4000 Series Switch NX-OS 输入验证漏洞 — Cisco Nexus 4000 unknown 6.5 -2018-06-21
CVE-2018-0302 多款Cisco产品FXOS Software和UCS Fabric Interconnect Software CLI解析器输入验证错误漏洞 — Cisco FXOS Software and UCS Fabric Interconnect unknown 7.8 -2018-06-21
CVE-2018-0303 多款Cisco产品FXOS Software和NX-OS Software Discovery Protocol组件输入验证漏洞 — Cisco FXOS and NX-OS unknown 8.8 -2018-06-21
CVE-2018-0306 多款Cisco产品NX-OS Software CLI解析器输入验证错误漏洞 — Cisco NX-OS unknown 7.8 -2018-06-21
CVE-2018-0313 多款Cisco产品NX-OS Software 输入验证漏洞 — Cisco NX-OS unknown 8.8 -2018-06-21
CVE-2018-0337 Cisco NX-OS Software 输入验证错误漏洞 — Cisco NX-OS unknown 7.8 -2018-06-21
CVE-2018-0371 Cisco Acano X-Series、Meeting Server 1000和Meeting Server 2000 Web Admin Interface 输入验证漏洞 — Cisco Meeting Server unknown 6.5 -2018-06-21
CVE-2018-0373 Cisco AnyConnect Secure Mobility Client for Windows Desktop 输入验证漏洞 — Cisco AnyConnect Secure Mobility Client unknown 5.5 -2018-06-21
CVE-2018-0291 多款Cisco产品NX-OS Software Simple Network Management Protocol input packet processor 安全漏洞 — Cisco NX-OS unknown 6.5 -2018-06-20
CVE-2018-0295 多款Cisco产品NX-OS Software 输入验证漏洞 — Cisco NX-OS unknown 7.5 -2018-06-20
CVE-2018-0301 多款Cisco产品NX-OS Software 输入验证漏洞 — Cisco NX-OS unknown 9.8 -2018-06-20
CVE-2018-0304 多款Cisco产品FXOS Software和NX-OS Software Fabric Services组件输入验证漏洞 — Cisco FXOS and NX-OS unknown 9.8 -2018-06-20
CVE-2018-0307 多款Cisco产品NX-OS Software CLI 输入验证错误漏洞 — Cisco NX-OS unknown 6.7 -2018-06-20
CVE-2018-0308 多款Cisco产品FXOS Software和NX-OS Software Fabric Services组件输入验证漏洞 — Cisco FXOS and NX-OS unknown 9.8 -2018-06-20
CVE-2018-0312 多款Cisco产品FXOS Software和NX-OS Software Fabric Services组件输入验证漏洞 — Cisco FXOS and NX-OS unknown 9.8 -2018-06-20
CVE-2018-0314 多款Cisco产品FXOS Software和NX-OS Software Fabric Services组件输入验证漏洞 — Cisco FXOS and NX-OS unknown 9.8 -2018-06-20
CVE-2018-1061 Python 资源管理错误漏洞 — python 7.5 -2018-06-19

Vulnerabilities classified as CWE-20 (输入验证不恰当) represent 3320 CVEs. The CWE taxonomy describes the weakness; review individual CVEs for product-specific impact.