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Recently, I asked a question, with title as "Is malloc thread safe?", and inside that I asked, "Is malloc re-entrant?"

I was under the impression that all re-entrant are thread-safe.

Is this assumption wrong?

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up vote 31 down vote accepted

Re-entrant functions do not rely on global variables that are exposed in the C library headers .. take strtok() vs strtok_r() for example in C.

Some functions need a place to store a 'work in progress' , re-entrant functions allow you to specify this pointer within the thread's own storage, not in a global.

errno, however, is a slightly different case on POSIX systems :)

In short, reentrant often means thread safe (as in "use the reentrant version of that function if you're using threads"), but thread safe does not always mean re-entrant. Some functions do not rely on some exposed global variable that other threads could clobber.

malloc() has no need to be reentrant, it does not depend on anything out of the scope of the entry point for any given thread.

Functions that return statically allocated values are not thread safe without the use of a mutex, futex, or other atomic locking mechanism. Yet, they don't need to be reentrant.

i.e.:

static char *foo(unsigned int flags)
{
  static char ret[2] = { 0 };

  if (flags & FOO_BAR)
    ret[0] = 'c';
  else if (flags & BAR_FOO)
    ret[0] = 'd';
  else
    ret[0] = 'e';

  ret[1] = 'A';

  return ret;
}

So, as you can see, having multiple threads use that without some kind of locking would be a disaster .. but it has no purpose being re-entrant. You'll run into that when dynamically allocated memory is taboo on some embedded platform.

In purely functional programming, reentrant often doesn't imply thread safe, it would depend on the behavior of defined or anonymous functions passed to the function entry point, recursion, etc.

A better way to put 'thread safe' is safe for concurrent access , which better illustrates the need.

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@tinketim, Appreciate your clear and detailed response, thanks. – Alphaneo May 15 '09 at 2:13
1  
Reentrant does not imply thread-safe. Pure functions imply thread-safety. – Julio Guerra May 30 '13 at 13:36
    
Great answer Tim. Just to clarify, my understanding from your "often" is that thread-safe doesn't imply reentrant, but also reentrant doesn't imply thread-safe. Would you be able to find an example of a reentrant function which is not thread-safe? – Riccardo Jun 9 '14 at 8:28
    
@ Tim Post "In short, reentrant often means thread safe (as in "use the reentrant version of that function if you're using threads"), but thread safe does not always mean re-entrant." qt says opposite: "Hence, a thread-safe function is always reentrant, but a reentrant function is not always thread-safe." – where_is_tftp Feb 11 '15 at 10:11
    
and wikipedia says yet something another: "This definition of reentrancy differs from that of thread-safety in multi-threaded environments. A reentrant subroutine can achieve thread-safety,[1] but being reentrant alone might not be sufficient to be thread-safe in all situations. Conversely, thread-safe code does not necessarily have to be reentrant (...)" – where_is_tftp Feb 11 '15 at 10:28

It depends on the definition. For example Qt uses the following:

  • A thread-safe* function can be called simultaneously from multiple threads, even when the invocations use shared data, because all references to the shared data are serialized.

  • A reentrant function can also be called simultaneously from multiple threads, but only if each invocation uses its own data.

Hence, a thread-safe function is always reentrant, but a reentrant function is not always thread-safe.

By extension, a class is said to be reentrant if its member functions can be called safely from multiple threads, as long as each thread uses a different instance of the class. The class is thread-safe if its member functions can be called safely from multiple threads, even if all the threads use the same instance of the class.

but they also caution:

Note: Terminology in the multithreading domain isn't entirely standardized. POSIX uses definitions of reentrant and thread-safe that are somewhat different for its C APIs. When using other object-oriented C++ class libraries with Qt, be sure the definitions are understood.

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1  
This definition of reentrant is too strong. – qweruiop Oct 25 '14 at 2:33
2  
Downvote. A thread-safe function is NOT always reentrant. – SandBag_1996 Oct 9 '15 at 2:07

TL;DR: A function can be reentrant, thread-safe, both or neither.

The Wikipedia articles for thread-safety and reentrancy are well worth reading. Here are a few citations:

A function is thread-safe if:

it only manipulates shared data structures in a manner that guarantees safe execution by multiple threads at the same time.

A function is reentrant if:

it can be interrupted at any point during its execution and then safely called again ("re-entered") before its previous invocations complete execution.

As examples of possible reentrance, the Wikipedia gives the example of a function designed to be called by system interrupts: suppose it is already running when another interrupt happens. But don't think you're safe just because you don't code with system interrupts: you can have reentrance problems in a single-threaded program if you use callbacks or recursive functions.

The key for avoiding confusion is that reentrant refers to only one thread executing. It is a concept from the time when no multitasking operating systems existed.

Examples

(Slightly modified from the Wikipedia articles)

Example 1: not thread-safe, not reentrant

/* As this function uses a non-const global variable without
   any precaution, it is neither reentrant nor thread-safe. */

int t;

void swap(int *x, int *y)
{
    t = *x;
    *x = *y;
    *y = t;
}

Example 2: thread-safe, not reentrant

/* We use a thread local variable: the function is now
   thread-safe but still not reentrant (within the
   same thread). */

__thread int t;

void swap(int *x, int *y)
{
    t = *x;
    *x = *y;
    *y = t;
}

Example 3: not thread-safe, reentrant

/* We save the global state in a local variable and we restore
   it at the end of the function.  The function is now reentrant
   but it is not thread safe. */

int t;

void swap(int *x, int *y)
{
    int s;
    s = t;
    t = *x;
    *x = *y;
    *y = t;
    t = s;
}

Example 4: thread-safe, reentrant

/* We use a local variable: the function is now
   thread-safe and reentrant, we have ascended to
   higher plane of existence.  */

void swap(int *x, int *y)
{
    int t;
    t = *x;
    *x = *y;
    *y = t;
}
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In addition to previous answers: two re-entrant functions can be not thread-safe if they handle shared data without locking.

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Since re-entrant code shouldn't handle shared data, I stand corrected. re-entrant code is thread-safe as already stated by others. – stefaanv May 13 '09 at 13:10

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