The CERT C Secure Coding Standard was developed specifically for versions of the C programming language defined by
- ISO/IEC 9899:2011 ISO/IEC, Programming Languages—C, 3rd ed. [ISO/IEC 9899:2011]
- ISO/IEC 9899:2011/Cor.1:2012, Technical Corrigendum 1
Although the guidelines for this standard were developed for C11, they can also be applied to earlier versions of the C programming language, including C99. Variations between versions of the C Standard that would affect the proper application of these guidelines are noted where applicable.
Most guidelines have a noncompliant code example that is a C11-conforming program to ensure that the problem identified by the guideline is within the scope of the standard. However, the best solutions to secure coding problems are often platform specific. In many cases, this standard provides appropriate compliant solutions for both POSIX and Windows operating systems. Language and library extensions that have been published as ISO/IEC technical reports or technical specifications are frequently given precedence, such as those described by ISO/IEC TR 24731-2, Extensions to the C Library—Part II: Dynamic Allocation Functions [ ISO/IEC TR 24731-2:2010 ]. In many cases, compliant solutions are also provided for specific platforms such as Linux or OpenBSD. Occasionally, interesting or illustrative implementation-specific behaviors are described.
Rationale
A coding standard for the C programming language can create the highest value for the longest period of time by focusing on the C Standard (C11) and the relevant post- C11 technical reports.
The C Standard documents existing practice where possible. That is, most features must be tested in an implementation before being included in the standard. The CERT C Coding Standard has a different purpose: to establish a set of best practices, which sometimes requires introducing new practices that may not be widely known or used when existing practices are inadequate. To put it a different way, the CERT C Coding Standard attempts to drive change rather than just document it.
For example, the optional but normative Annex K, “Bounds-Checking Interfaces,” introduced in C11, is gaining support but at present is implemented by only a few vendors. It introduces functions such as memcpy_s(), which serve the purpose of security by adding the destination buffer size to the API. A forward-looking document could not reasonably ignore these functions simply because they are not yet widely implemented. The base C Standard is more widely implemented than Annex K, but even if it were not, it is the direction in which the industry is moving. Developers of new C code, especially, need guidance that is usable, on and makes the best use of, the compilers and tools that are now being developed and are being supported into the future.
Some vendors have extensions to C, and some also have implemented only part of the C Standard before stopping development. Consequently, it is not possible to back up and discuss only C95, C90, or C99. The vendor support equation is too complicated to draw a line and say that a certain compiler supports exactly a certain standard. Whatever demarcation point is selected, different vendors are on opposite sides of it for different parts of the language. Supporting all possibilities would require testing the cross-product of each compiler with each language feature. Consequently, we have selected a demarcation point that is the most recent in time so that the rules and recommendations defined by the standard will be applicable for as long as possible. As a result of the variations in support, source-code portability is enhanced when the programmer uses only the features specified by C99. This is one of many trade-offs between security and portability inherent to C language programming.
The value of forward-looking information increases with time before it starts to decrease. The value of backward-looking information starts to decrease immediately.
For all of these reasons, the priority of this standard is to support new code development using C11 and the post-C11 technical reports that have not been incorporated into the C Standard. A close-second priority is supporting remediation of old code using C99 and the technical reports.
This coding standard does make contributions to support older compilers when these contributions can be significant and doing so does not compromise other priorities. The intent is not to capture all deviations from the standard but to capture only a few important ones.
Issues Not Addressed
A number of issues are not addressed by this secure coding standard.
Coding Style
Coding style issues are subjective, and it has proven impossible to develop a consensus on appropriate style guidelines. Consequently, the CERT C Secure Coding Standard does not require the enforcement of any particular coding style but only suggests that development organizations define or adopt style guidelines and apply these guidelines consistently. The easiest way to apply a coding style consistently is to use a code-formatting tool. Many interactive development environments (IDEs) provide such capabilities.
Controversial Rules
In general, the CERT coding standards try to avoid the inclusion of controversial rules that lack a broad consensus
At one extreme, a secure coding standard can be developed for a particular release of a compiler from a particular vendor. At the other extreme, the standards can be designed to be not only compiler independent but also language independent.
A coding standard for a particular compiler release has the largest possible benefit to the smallest group of users. Targeting a particular compiler allows for the definition of rules and guidelines that deal specifically with the peculiarities of that implementation, including defects in the implementation and non-standard extensions. At the other extreme, a language- independent coding standard has the least possible benefit to the largest possible group of users, as the rules and guidelines specified at this level of abstraction are largely notional.
The secure coding standards proposed by CERT are based on documented standard language versions as defined by official or de facto standards organizations. For example, secure coding standards are planned for the following languages:
Wiki Markup C programming language (ISO/IEC 9899:1999) \[5\]Wiki Markup C+\+ programming language ( ISO/IEC 9899:1999) \[6\]Wiki Markup Sun Microsystems' Java2 Platform Standard Edition 5.0 API Specification \[19\]Wiki Markup C# programming language (ISO/IEC 23270:2003) \[7\]
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Applicable technical corrigenda and documented language extensions such as the ISO/IEC TR 24731 extensions to the C library \[8\] will also be considered. |
The scope allows specific guidance to be provided to broad classes of users. Programming language standards, like those created by ISO/IEC, are primarily intended for compiler implementers. Secure coding standards are ancillary documents that provide rules and guidance directly to developers who program languages defined by these standards.