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CWE-78 (OS命令中使用的特殊元素转义处理不恰当(OS命令注入)) — Vulnerability Class 2740

2740 vulnerabilities classified as CWE-78 (OS命令中使用的特殊元素转义处理不恰当(OS命令注入)). AI Chinese analysis included.

CWE-78 represents a critical input validation weakness where software constructs operating system commands using untrusted external data without proper sanitization. Attackers typically exploit this by injecting malicious shell metacharacters, such as semicolons or pipes, into user-supplied fields like form inputs or URL parameters. This manipulation allows the attacker to alter the intended command structure, enabling arbitrary code execution, data exfiltration, or complete system compromise. To mitigate this risk, developers must strictly avoid passing user input directly to OS command interpreters. Instead, they should utilize safe, language-specific APIs that do not invoke the shell, or implement rigorous input validation and parameterization techniques. By treating all external data as inherently untrusted and applying strict allow-list filtering, organizations can effectively neutralize special elements and prevent command injection vulnerabilities.

MITRE CWE Description
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. This 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: The application intends to execute a single, fixed program that is under its own control. It intends to use externally-supplied inputs as arguments to that program. For example, the program might use system("nslookup [HOSTNAME]") to run nslookup and allow the user to supply a HOSTNAME, which is used as an argument. Attackers cannot prevent nslookup from executing. However, if the program does not remove command separators from the HOSTNAME argument, attackers could place the separators into the arguments, which allows them to execute their own program afte…
Common Consequences (1)
Confidentiality, Integrity, Availability, Non-RepudiationExecute Unauthorized Code or Commands, DoS: Crash, Exit, or Restart, Read Files or Directories, Modify Files or Directories, Read Application Data, Modify Application Data, Hide Activities
Attackers could execute unauthorized operating system commands, which could then be used to disable the product, or read and modify data for which the attacker does not have permissions to access directly. Since the targeted application is directly executing the commands instead of the attacker, any…
Mitigations (5)
Architecture and DesignIf at all possible, use library calls rather than external processes to recreate the desired functionality.
Architecture and Design, OperationRun the code in a "jail" or similar sandbox environment that enforces strict boundaries between the process and the operating system. This may effectively restrict which files can be accessed in a particular directory or which commands can be executed by the software. OS-level examples include the Unix chroot jail, AppArmor, and SELinux. In general, managed code may provide some protection. For ex…
Effectiveness: Limited
Architecture and DesignFor any data that will be used to generate a command to be executed, keep as much of that data out of external control as possible. For example, in web applications, this may require storing the data locally in the session's state instead of sending it out to the client in a hidden form field.
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.
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. For example, consider using the ESAPI Encoding control [REF-45] or a similar tool, library, or framework. These will help the programmer encode outputs in a manner less prone to error.
Examples (2)
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.
$userName = $_POST["user"]; $command = 'ls -l /home/' . $userName; system($command);
Bad · PHP
;rm -rf /
Attack
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.
int main(int argc, char** argv) { char cmd[CMD_MAX] = "/usr/bin/cat "; strcat(cmd, argv[1]); system(cmd); }
Bad · C
CVE IDTitleCVSSSeverityPublished
CVE-2026-5974 FoundationAgents MetaGPT terminal.py Bash.run os command injection — MetaGPT 7.3 High2026-04-09
CVE-2026-5973 FoundationAgents MetaGPT common.py get_mime_type os command injection — MetaGPT 7.3 High2026-04-09
CVE-2026-5972 FoundationAgents MetaGPT terminal.py Terminal.run_command os command injection — MetaGPT 7.3 High2026-04-09
CVE-2026-5854 Totolink A7100RU CGI cstecgi.cgi setWiFiEasyCfg os command injection — A7100RU 9.8 Critical2026-04-09
CVE-2026-5853 Totolink A7100RU CGI cstecgi.cgi setIpv6LanCfg os command injection — A7100RU 9.8 Critical2026-04-09
CVE-2026-5852 Totolink A7100RU CGI cstecgi.cgi setIptvCfg os command injection — A7100RU 9.8 Critical2026-04-09
CVE-2026-5851 Totolink A7100RU CGI cstecgi.cgi setUPnPCfg os command injection — A7100RU 9.8 Critical2026-04-09
CVE-2026-5850 Totolink A7100RU CGI cstecgi.cgi setVpnPassCfg os command injection — A7100RU 9.8 Critical2026-04-09
CVE-2026-5844 D-Link DIR-882 HNAP1 SetNetworkSettings prog.cgi sprintf os command injection — DIR-882 7.2 High2026-04-09
CVE-2026-5831 Agions taskflow-ai terminal_execute handlers.ts os command injection — taskflow-ai 6.3 Medium2026-04-09
CVE-2026-40032 UAC < 3.3.0-rc1 Command Injection via Placeholder Substitution — UAC 7.8 High2026-04-08
CVE-2026-40030 parseusbs < 1.9 Command Injection via Volume Path Argument — parseusbs 7.8 High2026-04-08
CVE-2026-40029 parseusbs < 1.9 Command Injection via Crafted LNK Filename — parseusbs 7.8 High2026-04-08
CVE-2026-5802 idachev mcp-javadc HTTP os command injection — mcp-javadc 7.3 High2026-04-08
CVE-2026-39862 Tophat has a Command Injection Vulnerability When Accessing a Maliciously Crafted Tophat Link — tophat 8.8AIHighAI2026-04-08
CVE-2026-30818 OS Command Injection Vulnerability in dnsmasq Module in TP-Link AX53 — AX53 v1.0 8.0AIHighAI2026-04-08
CVE-2026-30815 OS Command Injection Vulnerability in OpenVPN Module in TP-Link AX53 — AX53 v1.0 8.0AIHighAI2026-04-08
CVE-2026-27806 Fleet Affected by Local Privilege Escalation via Tcl Command Injection in Orbit — fleet 7.8 High2026-04-08
CVE-2026-5208 Improper Neutralization of Special Elements used in an OS Command ('OS Command Injection') in coolercontrold — coolercontrold 8.2 High2026-04-08
CVE-2026-5741 suvarchal docker-mcp-server HTTP index.ts pull_image os command injection — docker-mcp-server 7.3 High2026-04-07
CVE-2026-39382 dbt has a Command Injection in Reusable Workflow via Unsanitized comment-body Output — dbt-core 8.8AIHighAI2026-04-07
CVE-2026-4631 Cockpit: cockpit: unauthenticated remote code execution due to ssh command-line argument injection — Red Hat Enterprise Linux 10 9.8 Critical2026-04-07
CVE-2026-35585 File Browser has a Command Injection via Hook Runner — filebrowser 8.8AIHighAI2026-04-07
CVE-2026-35581 Emissary has a Command Injection via PLACE_NAME Configuration in Executrix — emissary 7.2 High2026-04-07
CVE-2026-35521 Pi-hole FTL affected by Remote Code Execution (RCE) via dhcp.hosts Newline Injection — FTL 8.8 High2026-04-07
CVE-2026-35520 Pi-hole FTL affected by Remote Code Execution (RCE) via dhcp.leaseTime Newline Injection — FTL 8.8 High2026-04-07
CVE-2026-35519 Pi-hole FTL affected by Remote Code Execution (RCE) via dns.hostRecord Newline Injection — FTL 8.8 High2026-04-07
CVE-2026-35518 Pi-hole FTL affected by Remote Code Execution (RCE) via dns.cnameRecords Newline Injection — FTL 8.8 High2026-04-07
CVE-2026-35517 Pi-hole FTL affected by Remote Code Execution (RCE) via dns.upstreams Newline Injection — FTL 8.8 High2026-04-07
CVE-2026-35463 pyLoad has Improper Neutralization of Special Elements used in an OS Command — pyload 8.8 High2026-04-07

Vulnerabilities classified as CWE-78 (OS命令中使用的特殊元素转义处理不恰当(OS命令注入)) represent 2740 CVEs. The CWE taxonomy describes the weakness; review individual CVEs for product-specific impact.