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CWE-121 (栈缓冲区溢出) — Vulnerability Class 2530

2530 vulnerabilities classified as CWE-121 (栈缓冲区溢出). AI Chinese analysis included.

CWE-121 represents a critical memory safety weakness where program data exceeds the allocated bounds of a stack-allocated buffer, corrupting adjacent memory structures. Attackers typically exploit this vulnerability by injecting malicious payloads that overwrite the function’s return address or saved frame pointer, thereby hijacking control flow to execute arbitrary code with the privileges of the compromised process. This exploitation is particularly dangerous because stack buffers are local variables, making the attack surface common in low-level languages like C and C++. Developers mitigate this risk by enforcing strict input validation, utilizing safe string handling functions that prevent unbounded writes, and adopting modern programming languages with automatic memory management. Additionally, implementing compiler-level protections such as stack canaries and Address Space Layout Randomization significantly raises the barrier for successful exploitation, ensuring system integrity remains intact against buffer overflow attempts.

MITRE CWE Description
A stack-based buffer overflow condition is a condition where the buffer being overwritten is allocated on the stack (i.e., is a local variable or, rarely, a parameter to a function).
Common Consequences (3)
AvailabilityModify Memory, DoS: Crash, Exit, or Restart, DoS: Resource Consumption (CPU), DoS: Resource Consumption (Memory)
Buffer overflows generally lead to crashes. Other attacks leading to lack of availability are possible, including putting the program into an infinite loop.
Integrity, Confidentiality, Availability, Access ControlModify Memory, Execute Unauthorized Code or Commands, Bypass Protection Mechanism
Buffer overflows often can be used to execute arbitrary code, which is usually outside the scope of a program's implicit security policy.
Integrity, Confidentiality, Availability, Access Control, OtherModify Memory, Execute Unauthorized Code or Commands, Bypass Protection Mechanism, Other
When the consequence is arbitrary code execution, this can often be used to subvert any other security service.
Mitigations (5)
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
Architecture and DesignUse an abstraction library to abstract away risky APIs. Not a complete solution.
ImplementationImplement and perform bounds checking on input.
ImplementationDo not use dangerous functions such as gets. Use safer, equivalent functions which check for boundary errors.
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)
While buffer overflow examples can be rather complex, it is possible to have very simple, yet still exploitable, stack-based buffer overflows:
#define BUFSIZE 256 int main(int argc, char **argv) { char buf[BUFSIZE]; strcpy(buf, argv[1]); }
Bad · C
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.
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); }
Bad · C
CVE IDTitleCVSSSeverityPublished
CVE-2023-21604 Adobe Acrobat Reader Stack-based Buffer Overflow Arbitrary code execution — Acrobat Reader 7.8 High2023-01-18
CVE-2023-21610 Adobe Acrobat Reader Stack-based Buffer Overflow Arbitrary code execution — Acrobat Reader 7.8 High2023-01-18
CVE-2022-3159 Siemens Teamcenter Visualization 和 JT2Go 缓冲区错误漏洞 — JT2Go 7.8 High2023-01-13
CVE-2017-16333 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16334 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16335 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16336 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16328 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16329 INSTEON Hub 缓冲区错误漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16330 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16331 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16332 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16324 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16325 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16326 INSTEON Hub 缓冲区错误漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16327 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16318 INSTEON Hub 缓冲区错误漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16319 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16320 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16321 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16322 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16323 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16315 Insteon Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16316 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16317 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16312 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16313 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16314 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16302 INSTEON Hub 缓冲区错误漏洞 — Hub 9.9 -2023-01-11
CVE-2017-16303 INSTEON Hub 安全漏洞 — Hub 9.9 -2023-01-11

Vulnerabilities classified as CWE-121 (栈缓冲区溢出) represent 2530 CVEs. The CWE taxonomy describes the weakness; review individual CVEs for product-specific impact.