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CWE-787 (跨界内存写) — Vulnerability Class 2200

2200 vulnerabilities classified as CWE-787 (跨界内存写). AI Chinese analysis included.

CWE-787 represents a critical memory management weakness where software incorrectly writes data beyond the allocated boundaries of a buffer. This flaw typically arises from insufficient bounds checking, allowing attackers to overwrite adjacent memory locations with malicious payloads. Exploitation often leads to arbitrary code execution, denial of service, or privilege escalation by corrupting critical system structures or control flow data. Developers mitigate this risk by implementing rigorous input validation and utilizing safe programming practices that enforce strict boundary checks before any memory operation. Employing modern languages with automatic memory management, such as Rust or Java, further reduces exposure by preventing direct pointer arithmetic. Additionally, static analysis tools and fuzzing techniques help identify potential out-of-bounds conditions during the development lifecycle, ensuring that buffer operations remain within their intended limits and preserving application integrity against memory corruption attacks.

MITRE CWE Description
The product writes data past the end, or before the beginning, of the intended buffer.
Common Consequences (3)
IntegrityModify Memory, Execute Unauthorized Code or Commands
Write operations could cause memory corruption. In some cases, an adversary can modify control data such as return addresses in order to execute unexpected code.
AvailabilityDoS: Crash, Exit, or Restart
Attempting to access out-of-range, invalid, or unauthorized memory could cause the product to crash.
OtherUnexpected State
Subsequent write operations can produce undefined or unexpected results.
Mitigations (5)
RequirementsUse a language that does not allow this weakness to occur or provides constructs that make this weakness easier to avoid. For example, many languages that perform their own memory management, such as Java and Perl, are not subject to buffer overflows. Other languages, such as Ada and C#, typically provide overflow protection, but the protection can be disabled by the programmer. Be wary that a lan…
Architecture and DesignUse a vetted library or framework that does not allow this weakness to occur or provides constructs that make this weakness easier to avoid. Examples include the Safe C String Library (SafeStr) by Messier and Viega [REF-57], and the Strsafe.h library from Microsoft [REF-56]. These libraries provide safer versions of overflow-prone string-handling functions.
Operation, Build and CompilationUse automatic buffer overflow detection mechanisms that are offered by certain compilers or compiler extensions. Examples include: the Microsoft Visual Studio /GS flag, Fedora/Red Hat FORTIFY_SOURCE GCC flag, StackGuard, and ProPolice, which provide various mechanisms including canary-based detection and range/index checking. D3-SFCV (Stack Frame Canary Validation) from D3FEND [REF-1334] discusses…
Effectiveness: Defense in Depth
ImplementationConsider adhering to the following rules when allocating and managing an application's memory: Double check that the buffer is as large as specified. When using functions that accept a number of bytes to copy, such as strncpy(), be aware that if the destination buffer size is equal to the source buffer size, it may not NULL-terminate the string. Check buffer boundaries if accessing the buffer in a…
Operation, Build and CompilationRun or compile the software using features or extensions that randomly arrange the positions of a program's executable and libraries in memory. Because this makes the addresses unpredictable, it can prevent an attacker from reliably jumping to exploitable code. Examples include Address Space Layout Randomization (ASLR) [REF-58] [REF-60] and Position-Independent Executables (PIE) [REF-64]. Imported…
Effectiveness: Defense in Depth
Examples (2)
The following code attempts to save four different identification numbers into an array.
int id_sequence[3]; /* Populate the id array. */ id_sequence[0] = 123; id_sequence[1] = 234; id_sequence[2] = 345; id_sequence[3] = 456;
Bad · C
In the following code, it is possible to request that memcpy move a much larger segment of memory than assumed:
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)); ... }
Bad · C
CVE IDTitleCVSSSeverityPublished
CVE-2021-32939 FATEK Automation FvDesigner 缓冲区错误漏洞 — FATEK Automation FvDesigner 7.8 -2021-08-11
CVE-2021-36004 Adobe InDesign CoolType out of bounds write vulnerability could lead to arbitrary stack manipulation — InDesign 8.8 High2021-07-27
CVE-2021-33684 SAP NetWeaver AS ABAP 缓冲区错误漏洞 — SAP NetWeaver AS ABAP and ABAP Platform 6.5 -2021-07-14
CVE-2021-33681 SAP 3D Visual Enterprise Viewer 缓冲区错误漏洞 — SAP 3D Visual Enterprise Viewer 8.1 -2021-07-14
CVE-2021-34331 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34323 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34319 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34318 Siemens Jt2go和Siemens Teamcenter Visualization 输入验证错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34316 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34314 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34311 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34310 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34309 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34305 Siemens Jt2go缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34300 Siemens Jt2go 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34297 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34295 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34293 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-34291 Siemens Jt2go 和 Siemens Teamcenter Visualization 缓冲区错误漏洞 — JT2Go 7.8 -2021-07-13
CVE-2021-22555 Heap Out-Of-Bounds Write in Netfilter IP6T_SO_SET_REPLACE — Linux Kernel 8.3 High2021-07-07
CVE-2021-3630 DjVuLibre 缓冲区错误漏洞 — djvulibre 7.1 -2021-06-30
CVE-2021-21871 PowerISO 缓冲区错误漏洞 — PowerISO 7.8 -2021-06-29
CVE-2021-32988 winproladder 缓冲区错误漏洞 — FATEK Automation WinProladder 8.8 -2021-06-29
CVE-2021-31514 Opentext OpenText Brava! 缓冲区错误漏洞 — Brava! Desktop 7.8 -2021-06-29
CVE-2021-31513 OpenText Brava! 缓冲区错误漏洞 — Brava! Desktop 7.8 -2021-06-29
CVE-2021-31511 Opentext OpenText Brava! 缓冲区错误漏洞 — Brava! Desktop 7.8 -2021-06-29
CVE-2021-31509 OpenText Brava! 缓冲区错误漏洞 — Brava! Desktop 7.8 -2021-06-29
CVE-2021-31508 Opentext OpenText Brava! 缓冲区错误漏洞 — Brava! Desktop 7.8 -2021-06-29
CVE-2021-28586 Adobe After Effects PDF file parsing out-of-bounds write could lead to remote code execution vulnerability — After Effects 7.8 -2021-06-28
CVE-2021-21099 Adobe InDesign PCX file parsing out-of-bounds write vulnerability could lead to remote code execution — InDesign 8.8 High2021-06-28

Vulnerabilities classified as CWE-787 (跨界内存写) represent 2200 CVEs. The CWE taxonomy describes the weakness; review individual CVEs for product-specific impact.