In UNIX systems we know malloc() is a non-reentrant function (system call). Why is that?

Similarly, printf() also is said to be non-reentrant; why?

I know the definition of re-entrancy, but I wanted to know why it applies to these functions. What prevents them being guaranteed reentrant?

  • 1
    @ripunjay-tripathi : printf, if it is printing to common resource, e.g. stdio. malloc because it rely on locks. Remember there is a difference between Reentrant and thread safety. where malloc is thread-safe. look at this post. stackoverflow.com/questions/855763/malloc-thread-safe.
    – yadab
    Oct 15, 2010 at 10:53
  • Where did you find the "canonical implementation"? Functions are reentrant if the developers say they are. glibc developers don't say malloc or printf are reentrant: so they aren't.
    – pmg
    Oct 15, 2010 at 10:57
  • 1
    @pmg, the words about "canonical implementation" were added by me. Here's what I meant. It's obvious that reentrancy is a property of an implementation, not of an interface. However, for example, POSIX doesn't list malloc and printf as reentrant functions, and this is for reason. In this quesiton, the OP wanted to know what the reason is.
    – P Shved
    Oct 15, 2010 at 11:09
  • @pmg: and I think slightly more to the point of the question, POSIX doesn't say that malloc has to be reentrant, and so the glibc developers can do so and still claim to be developing "a UNIX system". Oct 15, 2010 at 11:11
  • 4
    @Pavel: reentrancy is a property of interface as well as implementation. Required semantics are part of the interface. A reentrant interface is one of which all implementations must be reentrant. When considering the motivations of the POSIX authors, there's no "canonical" implementation. What matters is whether any reasonable implementation strategy, that the standards authors wish to permit, would be unable to (efficiently) implement a reentrant malloc. If so, then malloc will be marked non-reentrant, regardless of whether that implementation strategy is "canonical" or even common. Oct 15, 2010 at 11:14

6 Answers 6


malloc and printf usually use global structures, and employ lock-based synchronization internally. That's why they're not reentrant.

The malloc function could either be thread-safe or thread-unsafe. Both are not reentrant:

  1. Malloc operates on a global heap, and it's possible that two different invocations of malloc that happen at the same time, return the same memory block. (The 2nd malloc call should happen before an address of the chunk is fetched, but the chunk is not marked as unavailable). This violates the postcondition of malloc, so this implementation would not be re-entrant.

  2. To prevent this effect, a thread-safe implementation of malloc would use lock-based synchronization. However, if malloc is called from signal handler, the following situation may happen:

    malloc();            //initial call
      lock(memory_lock); //acquire lock inside malloc implementation
    signal_handler();    //interrupt and process signal
    malloc();            //call malloc() inside signal handler
      lock(memory_lock); //try to acquire lock in malloc implementation
      // DEADLOCK!  We wait for release of memory_lock, but 
      // it won't be released because the original malloc call is interrupted

    This situation won't happen when malloc is simply called from different threads. Indeed, the reentrancy concept goes beyond thread-safety and also requires functions to work properly even if one of its invocation never terminates. That's basically the reasoning why any function with locks would be not re-entrant.

The printf function also operated on global data. Any output stream usually employs a global buffer attached to the resource data are sent to (a buffer for terminal, or for a file). The print process is usually a sequence of copying data to buffer and flushing the buffer afterwards. This buffer should be protected by locks in the same way malloc does. Therefore, printf is also non-reentrant.

  • Finally, thank you. I was about to write more or less the same, but your answer appeared just as I was starting to type mine. +1.
    – janneb
    Oct 15, 2010 at 11:02
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    "any function with locks would be not re-entrant". I worked on a system where you could flag mutexes to disable signals, either just while waiting on the mutex, or throughout the time the mutex is held. Obviously it was easy to mis-use, and you have to guarantee the function would return, but it was used to access globals from reentrant functions (generally in the kernel). I assume without proof that other kernels have equivalent mechanisms, but also that the standard doesn't want to require such shenanigans where avoidable. Oct 15, 2010 at 11:24
  • @Steve: For instance, in the Linux kernel spinlocks typically disable interrupts when the lock is taken. "Normal" sleeping mutexes OTOH run with interrupts enabled.
    – janneb
    Oct 15, 2010 at 11:34
  • 2
    As of C11, malloc and printf are both required to be thread-safe (and POSIX has required this since 2001). However, it's still not safe to use them from an async signal handler.
    – zwol
    Sep 21, 2016 at 13:07
  • Will a reentrant lock make malloc reentrant?
    – cntswj
    Oct 25, 2021 at 5:27

Let's understand what we mean by re-entrant. A re-entrant function can be invoked before a previous invocation has finished. This might happen if

  • a function is called in a signal handler (or more generally than Unix some interrupt handler) for a signal that was raised during execution of the function
  • a function is called recursively

malloc isn't re-entrant because it is managing several global data structures that track free memory blocks.

printf isn't re-entrant because it modifies a global variable i.e. the content of the FILE* stout.


There are at least three concepts here, all of which are conflated in colloquial language, which might be why you were confused.

  • thread-safe
  • critical section
  • re-entrant

To take the easiest one first: Both malloc and printf are thread-safe. They have been guaranteed to be thread-safe in Standard C since 2011, in POSIX since 2001, and in practice since long before that. What this means is that the following program is guaranteed not to crash or exhibit bad behavior:

#include <pthread.h>
#include <stdio.h>

void *printme(void *msg) {
  while (1)
    printf("%s\r", (char*)msg);

int main() {
  pthread_t thr;
  pthread_create(&thr, NULL, printme, "hello");        
  pthread_create(&thr, NULL, printme, "goodbye");        
  pthread_join(thr, NULL);

An example of a function which is not thread-safe is strtok. If you call strtok from two different threads simultaneously, the result is undefined behavior — because strtok internally uses a static buffer to keep track of its state. glibc adds strtok_r to fix this problem, and C11 added the same thing (but optionally and under a different name, because Not Invented Here) as strtok_s.

Okay, but doesn't printf use global resources to build its output, too? In fact, what would it even mean to print to stdout from two threads simultaneously? That brings us to the next topic. Obviously printf is going to be a critical section in any program that uses it. Only one thread of execution is allowed to be inside the critical section at once.

At least in POSIX-compliant systems, this is achieved by having printf begin with a call to flockfile(stdout) and end with a call to funlockfile(stdout), which is basically like taking a global mutex associated with stdout.

However, each distinct FILE in the program is allowed to have its own mutex. This means that one thread can call fprintf(f1,...) at the same time that a second thread is in the middle of a call to fprintf(f2,...). There's no race condition here. (Whether your libc actually runs those two calls in parallel is a QoI issue. I don't actually know what glibc does.)

Similarly, malloc is unlikely to be a critical section in any modern system, because modern systems are smart enough to keep one pool of memory for each thread in the system, rather than having all N threads fight over a single pool. (The sbrk system call will still probably be a critical section, but malloc spends very little of its time in sbrk. Or mmap, or whatever the cool kids are using these days.)

Okay, so what does re-entrancy actually mean? Basically, it means that the function can safely be called recursively — the current invocation is "put on hold" while a second invocation runs, and then the first invocation is still able to "pick up where it left off." (Technically this might not be due to a recursive call: the first invocation might be in Thread A, which gets interrupted in the middle by Thread B, which makes the second invocation. But that scenario is just a special case of thread-safety, so we can forget about it in this paragraph.)

Neither printf nor malloc can possibly be called recursively by a single thread, because they are leaf functions (they don't call themselves nor call out to any user-controlled code that could possibly make a recursive call). And, as we saw above, they've been thread-safe against *multi-*threaded re-entrant calls since 2001 (by using locks).

So, whoever told you that printf and malloc were non-reentrant was wrong; what they meant to say was probably that both of them have the potential to be critical sections in your program — bottlenecks where only one thread can get through at a time.

Pedantic note: glibc does provide an extension by which printf can be made to call arbitrary user code, including re-calling itself. This is perfectly safe in all its permutations — at least as far as thread-safety is concerned. (Obviously it opens the door to absolutely insane format-string vulnerabilities.) There are two variants: register_printf_function (which is documented and reasonably sane, but officially "deprecated") and register_printf_specifier (which is almost identical except for one extra undocumented parameter and a total lack of user-facing documentation). I wouldn't recommend either of them, and mention them here merely as an interesting aside.

#include <stdio.h>
#include <printf.h>  // glibc extension

int widget(FILE *fp, const struct printf_info *info, const void *const *args) {
  static int count = 5;
  int w = *((const int *) args[0]);
  printf("boo!");  // direct recursive call
  return fprintf(fp, --count ? "<%W>" : "<%d>", w);  // indirect recursive call
int widget_arginfo(const struct printf_info *info, size_t n, int *argtypes) {
  argtypes[0] = PA_INT;
  return 1;
int main() {
  register_printf_function('W', widget, widget_arginfo);
  printf("|%W|\n", 42);
  • 11
    This answer is almost correct; but it's missing a key concept from POSIX, async signal safety. Application code can execute in the middle of a call to either printf or malloc as a result of an asynchronous signal. Neither function is required to be async-signal-safe, so it is unsafe to call them from the handler for an asynchronous signal. That is what POSIX system programmers mean when they say that printf and malloc are "not reentrant".
    – zwol
    Sep 21, 2016 at 13:06
  • 1
    "So, whoever told you that printf and malloc were non-reentrant was wrong" What about signal handlers? With threads the original thread will eventually get the CPU back and continue but with signal handlers nothing happens until the signal handler returns... Oct 11, 2016 at 21:47
  • 1
    Jerry: When I gave this answer, I was under the impression that "reentrant" and "async-signal-safe" were not synonyms, and that malloc/printf are "reentrant but not async-signal-safe". Actually, I'm still under that impression; but @zwol's comment suggests that there is a significant fraction of the population that believes they are synonyms, and thus that any function that isn't async-signal-safe can't possibly be "reentrant", by definition. Sounds like Jerry is also in that camp. I guess the moral is: when using jargon, one should know one's audience and their assumptions. :) Oct 12, 2016 at 22:48
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    @Quuxplusone I would personally say that "reentrant" is a poorly defined term and that one should avoid using it in favor of "thread safe", "recursive-call safe", or "async signal safe", which have clearer definitions. All functions that are async-signal safe are recursive-call safe and thread-safe, and all functions that are recursive-call safe are thread-safe, but the converses are not true. Recursive call safety is only a relevant category for library functions that call back into user code (qsort for instance) and it's also a term I made up just now, I don't think standards use it.
    – zwol
    Oct 13, 2016 at 14:43
  • 1
    @zwol: Etymologically, it sure looks like "reentrant" should be a synonym for "recursive-call-safe," and that's how I've been using it. By the way, int f(void (*g)()) { static int x = 0; ++x; g(); } is an example of a function that is recursive-call-safe but not thread-safe, in that calling f([]{}) simultaneously from two different threads will result in a data race on x but calling f([]{ f([]{}); }) is completely safe. (Sorry for the C++ lambdas. Space is limited here. ;)) Oct 13, 2016 at 22:06

Most likely because you can't start writing output while another call to printf is still printing it's self. The same goes for memory allocation and deallocation.

  • 1
    This explains what "re-entrant" is, but not why these functions are non re-entrant.
    – ChrisF
    Oct 15, 2010 at 10:19
  • Oh great so. I was foolish for asking this about printf. Thanks. But can't we call malloc() from two different threads simultaneously ? Oct 15, 2010 at 10:19
  • "you can't start writing output while another call to printf is still printing it's self." Why? What bit of printf causes that? It's not obvious. Maybe the result would be Hello, woSOMETHINGELSErld!, but all you asked would be nevertheless printed?
    – P Shved
    Oct 15, 2010 at 10:24
  • 1
    @RIPUNJAY TRIPATHI: It depends on the implementation, but usually malloc is thread safe if you have threading support switched on in your compilation.
    – JeremyP
    Oct 15, 2010 at 10:28
  • @Jeremy: Are thread-safety and reenterancy one and same? I thought they are two different things. Oct 15, 2010 at 10:47

It's because both works with global resources: heap memory structures and console.

EDIT: the heap is nothing else than a kind linked list structure. Each malloc or free modifies it, so having several threads in the same time with writing access to it will damage its consistency.

EDIT2: another detail: they could be made reentrant by default by using mutexes. But this approach is costly, and there is no garanty that they will be always used in MT environment.

So there are two solutions: to make 2 library functions, one reentrant and one not or leave the mutex part to the user. They've choosed the second.

Also, it can be because the original versions of these functions were non-reentrant, so the've been declared so for compatibility.

  • 1
    So you claim that malloc is not thread-safe? Interesting... (-1) And you also claim that including mutexes makes the function reentrant... Even more interesting! (-2)
    – P Shved
    Oct 15, 2010 at 10:41
  • @PavelShved - whether malloc is thread-safe or not is an arguable point. At least offer a reference to help clear the issue. From your own post do you not say it is possible that malloc can be thread unsafe?
    – ryyker
    Nov 11, 2014 at 21:06

If you try calling malloc from two separate threads (unless you have a thread-safe version, not guaranteed by C standard), bad things happen, because there's only one heap for two threads. Same for printf- the behaviour is undefined. That's what makes them in reality non-reentrant.

  • OK, but where can it fail ? Will be good if I get some examples. Oct 15, 2010 at 10:24
  • It is undefined behavior in the C specification, there is not example of where it may fail, cause at the time when writing the C specification this was a non issue (no threads at all). It might work find on some implementations and not at all on others while both implementations may follow the specification.
    – UnixShadow
    Oct 15, 2010 at 10:39
  • @RIPUNJAY: It could happen that both calls to malloc return the same pointer, because because both malloc invocations determined that block to be available (the first invocation would be interrupted between determining the block as free and marking it as allocated). Oct 15, 2010 at 10:45
  • @UnixShadow:Sorry there is some problem. If there was NO threads concept at all, why RE-ENTERANCY is linked to that ? Oct 15, 2010 at 10:48
  • @deadmg: thread safety and RE-ENTERANCY are different though they are related.
    – yadab
    Oct 15, 2010 at 11:05

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