This is inspired by this question and the comments on one particular answer in that I learnt that strncpy is not a very safe string handling function in C and that it pads zeros, until it reaches n, something I was unaware of.

Specifically, to quote R..

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. 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).

And from Jonathan Leffler

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().

So, I'm clearly a little rusty on the C standard library. Therefore, I'd like to pose the question:

What C standard library functions are used inappropriately/in ways that may cause/lead to security problems/code defects/inefficiencies?

In the interests of objectivity, I have a number of criteria for an answer:

  • Please, if you can, cite design reasons behind the function in question i.e. its intended purpose.
  • Please highlight the misuse to which the code is currently put.
  • Please state why that misuse may lead towards a problem. I know that should be obvious but it prevents soft answers.

Please avoid:

  • Debates over naming conventions of functions (except where this unequivocably causes confusion).
  • "I prefer x over y" - preference is ok, we all have them but I'm interested in actual unexpected side effects and how to guard against them.

As this is likely to be considered subjective and has no definite answer I'm flagging for community wiki straight away.

I am also working as per C99.

closed as too broad by meagar Dec 15 '17 at 19:59

Please edit the question to limit it to a specific problem with enough detail to identify an adequate answer. Avoid asking multiple distinct questions at once. See the How to Ask page for help clarifying this question. If this question can be reworded to fit the rules in the help center, please edit the question.

  • Any function can be used inappropriately and in ways that can lead to security holes. – Falmarri Jan 3 '11 at 21:36
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    @Falmarri - but some are frequently used inappropriately where others aren't, some seem to encourage misuse where others don't. – Steve314 Jan 3 '11 at 21:41

14 Answers 14

up vote 23 down vote accepted

A common pitfall with the strtok() function is to assume that the parsed string is left unchanged, while it actually replaces the separator character with '\0'.

Also, strtok() is used by making subsequent calls to it, until the entire string is tokenized. Some library implementations store strtok()'s internal status in a global variable, which may induce some nasty suprises, if strtok() is called from multiple threads at the same time.

The CERT C Secure Coding Standard lists many of these pitfalls you asked about.

  • +1 For mirroring my thoughts on strtok() and for mentioning the CERT C Secure Coding Standard. – Jonathan Leffler Jan 3 '11 at 22:28
  • +1, that's a great link, also @Jonathan sorry to quote you but you guys made me think "I definitely need to understand what's going on much more clearly". Hope you don't mind being famous! – user257111 Jan 3 '11 at 22:30
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    Technically, it is the library function rather than the compiler that stores the state. The big problem is if you isolate a token in your string, and then call a function which, unbeknownst to you, itself calls strtok(). – Jonathan Leffler Jan 3 '11 at 22:34
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    strtok is required to keep its internal status globally even with threads, at least in a POSIX environment where threads are specified. This is because a conforming program could start parsing in one thread and finish in another. Of course MS has their own version of threads where they can specify the different (thread-local) behavior like they do, but it conflicts with POSIX. – R.. Jan 4 '11 at 2:47
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    This is now community wiki which is good, but it still looks like I have to accept an answer, so I'm accepting this one for the CERT C Secure Coding Standard, which provides oodles of useful information. – user257111 Jan 4 '11 at 22:42

What C standard library functions are used inappropriately/in ways that may cause/lead to security problems/code defects/inefficiencies ?

I'm gonna go with the obvious :

char *gets(char *s);

With its remarkable particularity that it's simply impossible to use it appropriately.

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    MacOS X actually prints out a runtime warning when you use it. – onemasse Jan 3 '11 at 21:53
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    gets(): the absolute zero of software security. – j_random_hacker Jan 3 '11 at 21:58
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    Note that C0x will remove gets() from the standard. Unfortunately, it will be another 10-20 years after that is finalized before it is removed from most implementations - backwards compatibility with insecurity dictates that. – Jonathan Leffler Jan 3 '11 at 23:23
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    @onemasse: does it really? I hadn't noticed (but then, I don't use it, even in throwaway code!). Much better that it warns about that than about mktemp(), which I do see periodically in some of the code I work on. – Jonathan Leffler Jan 3 '11 at 23:24
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    MSVC might. Their deal with the committee is that they'll support the new standard if the committee adds all their hideous *_s "secure" functions to the standard to force *nix implementations to pollute themselves with it. ;-) – R.. Jan 4 '11 at 2:45

In almost all cases, atoi() should not be used (this also applies to atof(), atol() and atoll()).

This is because these functions do not detect out-of-range errors at all - the standard simply says "If the value of the result cannot be represented, the behavior is undefined.". So the only time they can be safely used is if you can prove that the input will certainly be within range (for example, if you pass a string of length 4 or less to atoi(), it cannot be out of range).

Instead, use one of the strtol() family of functions.

  • +1 for pointing out the (mostly theoretical, but still) danger of atoi and UB. – R.. Jan 4 '11 at 3:10
  • Excellent point. There is no reason to use ato*. – Stephen Canon Jan 4 '11 at 19:09
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    It's actually pretty handy if you know what platform your code will run on, which, chances are, you do. E.g. MSVC says The return value is 0 for atoi and _wtoi, if the input cannot be converted to a value of that type., so it's pretty well-defiend. (Also, this is another example where "undefined" and "implementation-defined" actually aren't exactly different -- they can both be defined by the implementation.) – Mehrdad Nov 12 '11 at 5:09

Let us extend the question to interfaces in a broader sense.


technically it is not even clear what it is, a variable, a macro, an implicit function call? In practice on modern systems it is mostly a macro that transforms into a function call to have a thread specific error state. It is evil:

  • because it may cause overhead for the caller to access the value, to check the "error" (which might just be an exceptional event)
  • because it even imposes at some places that the caller clears this "variable" before making a library call
  • because it implements a simple error return by setting a global state, of the library.

The forthcoming standard gets the definition of errno a bit more straight, but these uglinesses remain

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    While it's a bit ugly, there's very little that's error-prone or dangerous about errno. It's a macro which evaluates to a modifiable lvalue of type int, which is plenty well-defined. As far as I can tell, this means you can take and save its address and access the current value through that address if you like. The only "bad practices" I can think of that errno might encourage are (1) modelling your own libraries error reporting on it, and (2) using &errno as a cheap universally-portable thread-id. :-) – R.. Jan 4 '11 at 3:00
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    Quoth the standard: "The macro... errno which exapands to a modifiable lvalue that has type int...". So it is clear that it is a macro. – Raedwald Jan 5 '11 at 13:38
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    @Matt: it states explicitly that it has thread local storage duration. This is possible, there, since the new standard will have a thread model, quite close to POSIX BTW. – Jens Gustedt Jan 6 '11 at 11:16
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    @Matt: If it's a modifiable lvalue of type int, taking the address of it is valid, and it can't be the same as another thread's errno address. This does not depend on compiler-level TLS. For example &(*__errno_location()) is the same as __errno_location(). If you're writing your own locking code using atomic primitives (C1x, gcc builtins, or asm), &errno seems like the safest "owner id" you can get without pulling in dependency on a specific threads implementation (pthreads, solaris, windows, etc.). I agree it's a bit evil though... – R.. Jan 6 '11 at 16:17
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    @R, @Matt: the standard doesn't impose that the lvalue is the same between two subsequent uses of the macro by the same thread, I think. Although I have to admit that it sounds a bit insane to assume differently, but you could imagine that the library in addition of the thread-id keeps track of some other state of the thread and re-assigns a new address here and then. – Jens Gustedt Jan 6 '11 at 17:53

There is often a strtok_r.

For realloc, if you need to use the old pointer, it's not that hard to use another variable. If your program fails with an allocation error, then cleaning up the old pointer is often not really necessary.

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    I was going to say that this should be a comment, not an answer, but you can't comment without rep, so here, have some. – Stephen Canon Jan 3 '11 at 23:09
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    At the point when you say "often there is strtok_r()", you run into "occasionally there isn't" and "what are you going to do when it is not available?". The secondary issue is the assumed platform - the question talks about C99, where strtok_r() is not available (nor is strtok_s() in general - from TR 24731-1). – Jonathan Leffler Jan 4 '11 at 0:02

I would put printf and scanf pretty high up on this list. The fact that you have to get the formatting specifiers exactly correct makes these functions tricky to use and extremely easy to get wrong. It's also very hard to avoid buffer overruns when reading data out. Moreover, the "printf format string vulnerability" has probably caused countless security holes when well-intentioned programmers specify client-specified strings as the first argument to printf, only to find the stack smashed and security compromised many years down the line.

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    if your compiler is not able to tell you "you have used %x with an int number", ditch it, or turn its warning flags on. – BatchyX Jan 3 '11 at 21:44
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    I disagree. It's only when the format string is computed at runtime instead of a constant string that they become dangerous. GCC even has a nice warning option -Wformat-nonliteral for that case (which of course should be combined with -Werror to make warnings errors). – Adam Rosenfield Jan 3 '11 at 21:48
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    while you're at it, just enable -Wall, which also enable -Wformat. – BatchyX Jan 3 '11 at 21:57
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    using the %n format specifier is perfectly fine when used correctly. This is even needed in some cases (that's why it's there). – BatchyX Jan 3 '11 at 22:14
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    The sprintf() function may also lead to buffer overruns if variables are output as something bigger than expected. For example, code might expect that an "unsigned long" will take at most eleven bytes (ten digits and a null terminator) but crash on 64-bit systems where an unsigned long might take 21. – supercat Jan 3 '11 at 22:29

Any of the functions that manipulate global state, like gmtime() or localtime(). These functions simply can't be used safely in multiple threads.

EDIT: rand() is in the same category it would seem. At least there are no guarantees of thread-safety, and on my Linux system the man page warns that it is non-reentrant and non-threadsafe.

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    As far as I know, the only conformant way to make rand thread-safe would be to synchronize it with a mutex, which would hurt performance quite a bit. For a given seed, it's supposed to always return the same sequence of pseudo-random numbers, so using a thread-local state could break this semantic in conformant applications which use their own mutex around calls to rand. – R.. Jan 5 '11 at 16:39
  • ... or which initially use srand and rand only in the main thread, then after initialization continue to use it in a newly created thread while never again using it in the main thread. – R.. Jan 6 '11 at 16:30

One of my bêtes noire is strtok(), because it is non-reentrant and because it hacks the string it is processing into pieces, inserting NUL at the end of each token it isolates. The problems with this are legion; it is distressingly often touted as a solution to a problem, but is as often a problem itself. Not always - it can be used safely. But only if you are careful. The same is true of most functions, with the notable exception of gets() which cannot be used safely.

  • It's worth pointing out that strtok() was probably added because the pattern (strchr() or strpbrk() to look for a delimiter; overwrite delimiter with '\0'; loop until no more delimiters) is so common. – caf Jan 3 '11 at 23:35
  • @caf: that works if you don't need to know what the delimiter was, but not when you do need to know the delimiter. See the question linked in my answer - and the pathetic excuses for apologia from those advocating strtok(). It isn't often I use downvotes; there are two answers there with downvotes from me! – Jonathan Leffler Jan 3 '11 at 23:39
  • Well, I tend to think that strtok() is a little unfairly maligned, even if some of the criticisms are fair. Perhaps because I've found more than one occasion when it was exactly what I wanted - as long as you stay within its intended domain (parsing simple strings like PATH variables) rather than trying to parse complex documents with it, I don't think it's too bad. – caf Jan 3 '11 at 23:53
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    @caf: The problem is that, as soon as somebody wants to take your code and use it in a library setting rather than in main(), they run into a nasty surprise and have to rip out strtok and replace it with a sane alternative. – R.. Jan 4 '11 at 3:08
  • @R.: Well, yes - all of the above should be taken modulo the usual caveats that apply to all non-reentrant functions. – caf Jan 4 '11 at 3:56

There's already one answer about realloc, but I have a different take on it. A lot of time, I've seen people write realloc when they mean free; malloc - in other words, when they have a buffer full of trash that needs to change size before storing new data. This of course leads to potentially-large, cache-thrashing memcpy of trash that's about to be overwritten.

If used correctly with growing data (in a way that avoids worst-case O(n^2) performance for growing an object to size n, i.e. growing the buffer geometrically instead of linearly when you run out of space), realloc has doubtful benefit over simply doing your own new malloc, memcpy, and free cycle. The only way realloc can ever avoid doing this internally is when you're working with a single object at the top of the heap.

If you like to zero-fill new objects with calloc, it's easy to forget that realloc won't zero-fill the new part.

And finally, one more common use of realloc is to allocate more than you need, then resize the allocated object down to just the required size. But this can actually be harmful (additional allocation and memcpy) on implementations that strictly segregate chunks by size, and in other cases might increase fragmentation (by splitting off part of a large free chunk to store a new small object, instead of using an existing small free chunk).

I'm not sure if I'd say realloc encourages bad practice, but it's a function I'd watch out for.

  • My guess is that the object being realloc()-ed can be extended in-place often enough to make preferring it over free(); malloc(); worthwhile. And your point about realloc()ing down to a smaller size causing fragmentation is weak I think -- yes, it could cause fragmentation, namely the exact amount of fragmentation that would have been caused if we had known the correct size to ask for at the time of the original malloc() call. – j_random_hacker Jan 4 '11 at 9:10
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    No. In the worst case, over-allocate and realloc-down provides fragmentation as bad as if you'd never performed the realloc-down. It will never be as good as allocating the right amount to begin with unless the right amount could only have been obtained by splitting off from a larger free chunk. As for extending in-place, if you're talking about an object that grows over time (like a buffer reading in a long file), you can only grow it geometrically or you'll risk O(n^2) copying time. When growing geometrically, extending in-place is almost never possible. – R.. Jan 4 '11 at 13:26
  • As an example of the fragmentation, suppose you have a program that allocates 100k chunks and reallocates them down to ~1k, and makes no other allocation operations. After heap_size/100k (=20000 on many 32-bit systems) allocations, the next will fail, despite only 1% of the heap being "in-use". An allocator can avoid this issue by always moving chunks when they're resized down by a large factor, at the expense of some performance... – R.. Jan 4 '11 at 13:29
  • See what you mean about fragmentation. But your scenario is unlikely: usually a realloc-down happens soon after the orginal allocation, before other allocations happen. Also I don't see another, better way to approach the problem when you don't know the necessary size -- the only possibly sane alternative being to try exponentially larger guesses until one fits, but (a) usually that's more trouble than it's worth, (b) it requires O(log n) allocations and (c) it relies on being able to reacquire the data you're trying to store multiple times (impossible if, say, you're reading from a pipe). – j_random_hacker Jan 4 '11 at 15:37
  • Also not sure why you think growing geometrically and in-place is "almost never" possible. I don't have stats (nor I suspect do you), but I expect a decent proportion of reallocations act on the most recently (re)allocated block, which is likely to be so extendable. I think the strongest thing you could say against realloc() here is that this likelihood of in-place extension of the most recently allocated block reduces the chance of actually getting O(n^2) behaviour from a poorly-thought-out (linearly-growing) growth scheme, thereby encouraging this bad practice. – j_random_hacker Jan 4 '11 at 15:47

How about the malloc family in general? The vast majority of large, long-lived programs I've seen use dynamic memory allocation all over the place as if it were free. Of course real-time developers know this is a myth, and careless use of dynamic allocation can lead to catastrophic blow-up of memory usage and/or fragmentation of address space to the point of memory exhaustion.

In some higher-level languages without machine-level pointers, dynamic allocation is not so bad because the implementation can move objects and defragment memory during the program's lifetime, as long as it can keep references to these objects up-to-date. A non-conventional C implementation could do this too, but working out the details is non-trivial and it would incur a very significant cost in all pointer dereferences and make pointers rather large, so for practical purposes, it's not possible in C.

My suspicion is that the correct solution is usually for long-lived programs to perform their small routine allocations as usual with malloc, but to keep large, long-lived data structures in a form where they can be reconstructed and replaced periodically to fight fragmentation, or as large malloc blocks containing a number of structures that make up a single large unit of data in the application (like a whole web page presentation in a browser), or on-disk with a fixed-size in-memory cache or memory-mapped files.

On a wholly different tack, I've never really understood the benefits of atan() when there is atan2(). The difference is that atan2() takes two arguments, and returns an angle anywhere in the range -π..+π. Further, it avoids divide by zero errors and loss of precision errors (dividing a very small number by a very large number, or vice versa). By contrast, the atan() function only returns a value in the range -π/2..+π/2, and you have to do the division beforehand (I don't recall a scenario where atan() could be used without there being a division, short of simply generating a table of arctangents). Providing 1.0 as the divisor for atan2() when given a simple value is not pushing the limits.

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    atan( ) is often used when doing certain trig operations (but you're right that there's always an implicit 1 hiding somewhere, and it wouldn't hurt to make it explicit). – Stephen Canon Jan 3 '11 at 23:11
  • I would note one benefit of atan( ), however: it's ~2x faster on a good math library, because it doesn't need to do the divide. I suspect that's why it exists. – Stephen Canon Jan 4 '11 at 1:51
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    Sometimes atan is not used for trigonometry but as a nice smooth (actually analytic) function with desirable monotonicity and boundary conditions. – R.. Jan 4 '11 at 3:06

Another answer, since these are not really related, rand:

  • it is of unspecified random quality
  • it is not re-entrant

Some of this functions are modifying some global state. (In windows) this state is shared per single thread - you can get unexpected result. For example, the first call of rand in every thread will give the same result, and it requires some care to make it pseudorandom, but deterministic (for debug purposes).

basename() and dirname() aren't threadsafe.

  • These are a functions of a single argument that modify their argument. This is like saying avoid += because it's not threadsafe. – user79758 Jan 3 '11 at 23:57
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    No, they are not threadsafe. From the manpage: "The basename() function returns a pointer to internal static storage space that will be overwritten by subsequent calls. The function may modify the string pointed to by path." – arsenm Jan 4 '11 at 0:04
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    Whether or not they are threadsafe, basename and dirname are not part of the C standard library. – Stephen Canon Jan 4 '11 at 0:58