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CWE-190 (整数溢出或超界折返) — Vulnerability Class 861

861 vulnerabilities classified as CWE-190 (整数溢出或超界折返). AI Chinese analysis included.

CWE-190 represents a critical logic flaw where arithmetic operations exceed the maximum capacity of the assigned integer data type, causing the value to wrap around to a negative number or zero. Attackers typically exploit this vulnerability by manipulating input values to trigger the overflow, thereby bypassing security checks that assume the resulting number remains positive or within expected bounds. This often leads to severe consequences such as buffer overflows, memory corruption, or unauthorized access. To prevent such issues, developers must implement rigorous input validation and use safe arithmetic libraries that detect potential overflows before execution. Additionally, employing static analysis tools and adhering to secure coding standards ensures that integer calculations are handled with appropriate bounds checking, effectively mitigating the risk of wraparound errors in production environments.

MITRE CWE Description
The product performs a calculation that can produce an integer overflow or wraparound when the logic assumes that the resulting value will always be larger than the original value. This occurs when an integer value is incremented to a value that is too large to store in the associated representation. When this occurs, the value may become a very small or negative number.
Common Consequences (5)
AvailabilityDoS: Crash, Exit, or Restart, DoS: Resource Consumption (Memory), DoS: Instability
This weakness can generally lead to undefined behavior and therefore crashes. When the calculated result is used for resource allocation, this weakness can cause too many (or too few) resources to be allocated, possibly enabling crashes if the product requests more resources than can be provided.
IntegrityModify Memory
If the value in question is important to data (as opposed to flow), simple data corruption has occurred. Also, if the overflow/wraparound results in other conditions such as buffer overflows, further memory corruption may occur.
Confidentiality, Availability, Access ControlExecute Unauthorized Code or Commands, Bypass Protection Mechanism
This weakness can sometimes trigger buffer overflows, which can be used to execute arbitrary code. This is usually outside the scope of the product's implicit security policy.
Availability, OtherAlter Execution Logic, DoS: Crash, Exit, or Restart, DoS: Resource Consumption (CPU)
If the overflow/wraparound occurs in a loop index variable, this could cause the loop to terminate at the wrong time - too early, too late, or not at all (i.e., infinite loops). With too many iterations, some loops could consume too many resources such as memory, file handles, etc., possibly leading…
Access ControlBypass Protection Mechanism
If integer values are used in security-critical decisions, such as calculating quotas or allocation limits, integer overflows can be used to cause an incorrect security decision.
Mitigations (5)
RequirementsEnsure that all protocols are strictly defined, such that all out-of-bounds behavior can be identified simply, and require strict conformance to the protocol.
RequirementsUse a language that does not allow this weakness to occur or provides constructs that make this weakness easier to avoid. If possible, choose a language or compiler that performs automatic bounds checking.
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 [REF-1482]. Use libraries or frameworks that make it easier to handle numbers without unexpected consequences. Examples include safe integer handling packages such as SafeInt (C++) or IntegerLib (C or C++). [REF-106]
ImplementationPerform input validation on any numeric input by ensuring that it is within the expected range. Enforce that the input meets both the minimum and maximum requirements for the expected range. Use unsigned integers where possible. This makes it easier to perform validation for integer overflows. When signed integers are required, ensure that the range check includes minimum values as well as maximum…
ImplementationUnderstand the programming language's underlying representation and how it interacts with numeric calculation (CWE-681). Pay close attention to byte size discrepancies, precision, signed/unsigned distinctions, truncation, conversion and casting between types, "not-a-number" calculations, and how the language handles numbers that are too large or too small for its underlying representation. [REF-7]…
Examples (2)
The following image processing code allocates a table for images.
img_t table_ptr; /*struct containing img data, 10kB each*/ int num_imgs; ... num_imgs = get_num_imgs(); table_ptr = (img_t*)malloc(sizeof(img_t)*num_imgs); ...
Bad · C
The following code excerpt from OpenSSH 3.3 demonstrates a classic case of integer overflow:
nresp = packet_get_int(); if (nresp > 0) { response = xmalloc(nresp*sizeof(char*)); for (i = 0; i < nresp; i++) response[i] = packet_get_string(NULL); }
Bad · C
CVE IDTitleCVSSSeverityPublished
CVE-2019-18302 Siemens SPPA-T3000 输入验证错误漏洞 — SPPA-T3000 MS3000 Migration Server 7.5 -2019-12-12
CVE-2019-18303 Siemens SPPA-T3000 输入验证错误漏洞 — SPPA-T3000 MS3000 Migration Server 7.5 -2019-12-12
CVE-2019-18304 Siemens SPPA-T3000 输入验证错误漏洞 — SPPA-T3000 MS3000 Migration Server 7.5 -2019-12-12
CVE-2019-18305 Siemens SPPA-T3000 输入验证错误漏洞 — SPPA-T3000 MS3000 Migration Server 7.5 -2019-12-12
CVE-2019-5085 LEAD Technologies LEADTOOLS 输入验证错误漏洞 — LEADTOOLS libltdic.so 9.8 -2019-12-11
CVE-2019-5093 LEAD Technologies LEADTOOLS 输入验证错误漏洞 — LEADTOOLS libltdic.so 9.8 -2019-12-11
CVE-2019-5100 LEAD Technologies LEADTOOLS 输入验证错误漏洞 — LEADTOOLS 7.8 -2019-11-06
CVE-2019-5089 Investintech Able2Extract Professional 输入验证错误漏洞 — Able2Extract Professional 7.8 -2019-11-05
CVE-2018-16301 编码撤回 — tcpdump 7.0 -2019-10-03
CVE-2019-11927 WhatsApp 输入验证错误漏洞 — WhatsApp for Android 7.8 -2019-09-27
CVE-2019-11476 Integer overflow in whoopsie results in out-of-bounds heap write — Whoopsie 8.4 -2019-08-29
CVE-2019-5040 Openweave-core和Google Nest Cam IQ Indoor 输入验证错误漏洞 — Nest Labs 9.1 -2019-08-20
CVE-2019-5037 Google Nest Cam IQ Indoor 输入验证错误漏洞 — Nest Labs 7.5 -2019-08-20
CVE-2015-5297 Pixman 输入验证错误漏洞 — pixman 9.8 -2019-07-31
CVE-2019-5060 SDL2_image 输入验证错误漏洞 — SDL 8.8 -2019-07-31
CVE-2019-5059 SDL2_image 输入验证错误漏洞 — SDL 8.8 -2019-07-31
CVE-2019-10142 Linux kernel 输入验证错误漏洞 — kernel 8.4 -2019-07-30
CVE-2019-5052 Simple DirectMedia Layer 输入验证错误漏洞 — Simple DirectMedia 8.8 -2019-07-03
CVE-2019-11477 Integer overflow in TCP_SKB_CB(skb)->tcp_gso_segs — Linux kernel 7.5 -2019-06-18
CVE-2019-6753 Foxit Reader和Foxit PhantomPDF 输入验证错误漏洞 — Reader 6.5 -2019-06-03
CVE-2019-9139 DaviewIndy 输入验证错误漏洞 — DaviewIndy 7.8 -2019-04-25
CVE-2019-9138 DaviewIndy 输入验证错误漏洞 — DaviewIndy 7.8 -2019-04-25
CVE-2019-9137 DaviewIndy 输入验证错误漏洞 — DaviewIndy 7.8 -2019-04-25
CVE-2019-9133 KMPlayer Subtitles parser Heap Overflow Vulnerability — KMPlayer 7.8 -2019-04-09
CVE-2013-2806 Rockwell Automation RSLinx Enterprise 输入验证错误漏洞 — RSLinx Enterprise Software 7.5 -2019-03-26
CVE-2013-2807 Rockwell Automation RSLinx Enterprise 缓冲区错误漏洞 — RSLinx Enterprise Software 7.5 -2019-03-26
CVE-2019-3856 libssh2 输入验证错误漏洞 — libssh2 8.8 -2019-03-25
CVE-2019-3857 libssh2 输入验证错误漏洞 — libssh2 8.8 -2019-03-25
CVE-2019-3863 libssh2 缓冲区错误漏洞 — libssh2 8.8 -2019-03-25
CVE-2019-3855 libssh2 输入验证错误漏洞 — libssh2 8.8 -2019-03-21

Vulnerabilities classified as CWE-190 (整数溢出或超界折返) represent 861 CVEs. The CWE taxonomy describes the weakness; review individual CVEs for product-specific impact.