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I'm starting a new project in plain C (c99) that is going to work primarily with text. Because of external project constraints, this code has to be extremely simple and compact, consisting of a single source-code file without external dependencies or libraries except for libc and similar ubiquitous system libraries.

With that understanding, what are some best-practices, gotchas, tricks, or other techniques that can help make the string handling of the project more robust and secure?

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Does using C in the first place count as a gotcha? /* ouch, stop! just kidding! */ –  delnan Jan 2 '11 at 20:33
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@anatolyg: Why would anyone want to use wide characters? Uhg. –  R.. Jan 2 '11 at 21:02
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This question is amazing … so many wrong answers based on misconceptions about apparently “safe” solution. Wow, C makes safe string handling really hard. –  Konrad Rudolph Jan 3 '11 at 8:57
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@Konrad: The only thing that makes it hard is the enormous volume of misinformation and bad examples out there. –  R.. Jan 3 '11 at 14:02
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@R..: I think what Konrad is saying is that practices for "safe" string handling are not obvious in C. Sure, anything's easy if you know how to do it. But C is an "enough rope" language with little direction and lots of bad precedents. That makes doing things "right" hard. –  tylerl Jan 3 '11 at 22:54
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closed as not constructive by casperOne Aug 21 '12 at 12:08

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7 Answers

up vote 25 down vote accepted

Without any additional information about what your code is doing, I would recommend designing all your interfaces like this:

size_t foobar(char *dest, size_t buf_size, /* operands here */)

with semantics like snprintf:

  • dest points to a buffer of size at least buf_size.
  • If buf_size is zero, null/invalid pointers are acceptable for dest and nothing will be written.
  • If buf_size is non-zero, dest is always null-terminated.
  • Each function foobar returns the length of the full non-truncated output; the output has been truncated if buf_size is less than or equal to the return value.

This way, when the caller can easily know the destination buffer size that's required, a sufficiently large buffer can be obtained in advance. If the caller cannot easily know, it can call the function once with either a zero argument for buf_size, or with a buffer that's "probably big enough" and only retry if you ran out of space.

You can also make a wrapped version of such calls analogous to the GNU asprintf function, but if you want your code to be as flexible as possible I would avoid doing any allocation in the actual string functions. Handling the possibility of failure is always easier at the caller level, and many callers can ensure that failure is never a possibility by using a local buffer or a buffer that was obtained much earlier in the program so that the success or failure of a larger operation is atomic (which greatly simplifies error handling).

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Have a look at strlcpy and strlcat , see the original paper for details.

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Concatenation is almost always a bad idiom (in terms of safety, performance, and complexity). –  R.. Jan 2 '11 at 20:52
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Some thoughts from a long-time embedded developer, most of which elaborate on your requirement for simplicity and are not C-specific:

  • Decide which string-handling functions you'll need, and keep that set as small as possible to minimize the points of failure.

  • Follow R.'s suggestion to define a clear interface that is consistent across all string handlers. A strict, small-but-detailed set of rules allows you to use pattern-matching as a debugging tool: you can be suspicious of any code that looks different from the rest.

  • As Bart van Ingen Schenau noted, track the buffer length independently of the string length. If you'll always be working with text it's safe to use the standard null character to indicate end-of-string, but it's up to you to ensure the text+null will fit in the buffer.

  • Ensure consistent behavior across all string handlers, particularly where the standard functions are lacking: truncation, null inputs, null-termination, padding, etc.

  • If you absolutely need to violate any of your rules, create a separate function for that purpose and name it appropriately. In other words, give each function a single unambiguous behavior. So you might use str_copy_and_pad() for a function that always pads its target with nulls.

  • Wherever possible, use safe built-in functions (e.g. memmove() per Jonathan Leffler) to do the heavy lifting. But test them to be sure they're doing what you think they're doing!

  • Check for errors as soon as possible. Undetected buffer overruns can lead to "ricochet" errors that are notoriously difficult to locate.

  • Write tests for every function to ensure it satisfies its contract. Be sure to cover the edge cases (off by 1, null/empty strings, source/destination overlap, etc.) And this may sound obvious, but be sure you understand how to create and detect a buffer underrun/overrun, then write tests that explicitly generate and check for those problems. (My QA folks are probably sick of hearing my instructions to "don't just test to make sure it works; test to make sure it doesn't break.")

Here are some techniques that have worked for me:

  • Create wrappers for your memory-management routines that allocate "fence bytes" on either end of your buffers during allocation and check them upon deallocation. You can also verify them within your string handlers, perhaps when a STR_DEBUG macro is set. Caveat: you'll need to test your diagnostics thoroughly, lest they create additional points of failure.

  • Create a data structure that encapsulates both the buffer and its length. (It can also contain the fence bytes if you use them.) Caveat: you now have a non-standard data structure that your entire code base must manage, which may mean a substantial re-write (and therefore additional points of failure).

  • Make your string handlers validate their inputs. If a function forbids null pointers, check for them explicitly. If it requires a valid string (like strlen() should) and you know the buffer length, check that the buffer contains a null character. In other words, verify any assumptions you might be making about the code or data.

  • Write your tests first. That will help you understand each function's contract--exactly what it expects from the caller, and what the caller should expect from it. You'll find yourself thinking about the ways you'll use it, the ways it might break, and about the edge cases it must handle.

Thanks so much for asking this question! I wish more developers would think about these issues--especially before they start coding. Good luck, and best wishes for a robust, successful product!

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+1 for the first half and the last paragraph. They're good enough that I'm withholding judgement on the second half. :-) Testing for null pointers is one of my Considered Harmfuls and while fancy structures can help you debug, they also make your code a lot more of a pain to use and integrate with other code. I would instead work on rigorously testing your functions to satisfy their contracts, and then you don't need any further runtime checking mess. –  R.. Jan 3 '11 at 17:17
    
@R.: I agree that thorough tests are key, and that "fancy structures" often do more harm than good. But simple ones, used correctly, can also increase robustness and testability, particularly if they're an integral part of the design. Can you explain your dislike of null-pointer tests? I'm a fan of testing everything I can, but I'll often use macros (e.g. #ifdef TEST) to surround tests that may be expensive or redundant. Thanks for your thoughts! –  Adam Liss Jan 3 '11 at 17:39
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My part in a long discussion on the merits or demerits of testing for NULL pointers is here: stackoverflow.com/questions/4390007/… –  R.. Jan 3 '11 at 23:02
    
Thanks for the (non-NULL) reference! Lots of good ideas there. I think tylerl's situation is unusual in that he's starting from scratch and therefore controls the complete design. So, here, it's less a question of "playing nice with others" and all about defining a coherent set of strict rules and enforcing them everywhere. At least until the code is mature, I'd rather err on the side of over-validating than miss subtle bugs that propagate through the developing system. –  Adam Liss Jan 3 '11 at 23:24
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Two cents:

  1. Always use the "n" version of the string functions: strncpy, strncmp, (or wcsncpy, wcsncmp etc.)
  2. Always allocate using the +1 idiom: e.g. char* str[MAX_STR_SIZE+1], and then pass MAX_STR_SIZE as the size for the "n" version of the string functions and finish with str[MAX_STR_SIZE] = '\0'; to make sure all strings are properly finalized.

The final step is important since the "n" version of the string functions won't append '\0' after copying if the maximum size was reached.

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-1 s/always/never/ for strncpy. This function does not do what people think it does, and it's almost never useful. –  R.. Jan 2 '11 at 20:51
    
@R..: What is it exactly that you think its doing? Can you give a concrete example? –  hillel Jan 2 '11 at 20:57
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strncpy does not null-terminate, and does null-pad the whole remainder of the destination buffer, which is a huge waste of time. You can work around the former by adding your own null padding, but not the latter. It was never intended for use as a "safe string handling" function, but for working with fixed-size fields in Unix directory tables and database files. snprintf(dest, n, "%s", src) is the only correct "safe strcpy" in standard C, but it's likely to be a lot slower. –  R.. Jan 2 '11 at 21:14
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By the way, truncation in itself can be a major bug and in some cases might lead to privilege elevation or DoS, so throwing "safe" string functions that truncate their output at a problem is not a way to make it "safe" or "secure". Instead, you should ensure that the destination buffer is the right size and simply use strcpy (or better yet, memcpy if you already know the source string length). –  R.. Jan 2 '11 at 21:15
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Note that strncat() is even more confusing in its interface than strncpy() - what exactly is that length argument, again? It isn't what you'd expect based on what you supply strncpy() etc - so it is more error prone even than strncpy(). For copying strings around, I'm increasingly of the opinion that there is a strong argument that you only need memmove() because you always know all the sizes ahead of time and make sure there's enough space ahead of time. Use memmove() in preference to any of strcpy(), strcat(), strncpy(), strncat(), memcpy(). –  Jonathan Leffler Jan 2 '11 at 21:24
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  • Work with arrays on the stack whenever this is possible and initialize them properly. You don't have to keep track of allocations, sizes and initializations.

    char myCopy[] = { "the interesting string" };
    
  • For medium sized strings C99 has VLA. They are a bit less usable since you can't initialize them. But you still have the first two of the above advantages.

    char myBuffer[n];
    myBuffer[0] = '\0';
    
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VLA is a stack overflow waiting to happen. (The bad kind of SO, not the good kind that does your homework for you. :-) –  R.. Jan 2 '11 at 23:09
    
@R, yes, if one misuses the feature. But there are appropriate uses, with the necessary checks. After all, you wouldn't do a malloc from unchecked user input either. –  Matthew Flaschen Jan 3 '11 at 1:32
    
@Matthew: The only good use for VLA I've ever found required some serious invention, and it's still only a theoretical class of problems: recursive problems where the total memory usage across all levels of recursion is known to be O(n) but where any one level could use up to C*n space (obviously only a finite number of levels could actually use this much). VLA is the only tool that makes it possible without malloc, assuming O(n^2) does not fit on the stack. But for every real-world case I've ever seen, a moderately large constant dimension is just as good as VLA. –  R.. Jan 3 '11 at 14:07
    
@R.. there are cases for VLA which are not too bad, in particular pointers to VLA can even be used with malloc if you like. By that you can have some sort of very basic dynamic types. But sure that is off topic, here. For the use of them on the stack I'd stick to that "medium sized" that I mentioned in the answer. –  Jens Gustedt Jan 3 '11 at 16:08
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Some important gotchas are:

  • In C, there is no relation at all between string length and buffer size. A string always runs up to (and including) the first '\0'-character. It is your responsibility as a programmer to make sure this character can be found within the reserved buffer for that string.
  • Always explicitly keep track of buffer sizes. The compiler keeps track of array sizes, but that information will be lost to you before you know it.
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When it comes to time vs space, don't forget to pick the standard bit twiddling from here

During my early firmware projects, I used the look up tables to count the bit set in a O(1) operation efficiency.

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