How the described code goes wrong
The stdio library buffers data, allocating memory to store the buffered data. The GNU C library dynamically allocates file structures (some libraries, notably on Solaris, use pointers to statically allocated file structures, but the buffer is still dynamically allocated unless you set the buffering otherwise).
If your thread works with a copy of a pointer to the global file pointer (because you passed the file pointer to the function as an argument), then it is conceivable that the code would continue to access the data structure that was orginally allocated (even though it was freed by the close), and would read data from the buffer that was already present. It would only be when you exit the function, or read beyond the contents of the buffer, that things start going wrong - or the space that was previously allocated to the file structure is reallocated for a new use.
void somefunc(FILE *fp, ...)
while (fgets(buffer, sizeof(buffer), fp) != 0)
/* Pass global file pointer by value */
Proof of Concept Code
Tested on MacOS X 10.5.8 (Leopard) with GCC 4.0.1:
const char etc_passwd = "/etc/passwd";
static void error(const char *fmt, const char *str)
fprintf(stderr, fmt, str);
static void abuse(FILE *fp, const char *filename)
if (fgets(buffer1, sizeof(buffer1), fp) == 0)
error("Failed to read buffer1 from %s\n", filename);
printf("buffer1: %s", buffer1);
/* Dangerous!!! */
if ((global_fp = fopen(etc_passwd, "r")) == 0)
error("Failed to open file %s\n", etc_passwd);
if (fgets(buffer2, sizeof(buffer2), fp) == 0)
error("Failed to read buffer2 from %s\n", filename);
printf("buffer2: %s", buffer2);
int main(int argc, char **argv)
if (argc != 2)
error("Usage: %s file\n", argv);
if ((global_fp = fopen(argv, "r")) == 0)
error("Failed to open file %s\n", argv);
When run on its own source code, the output was:
Osiris JL: ./xx xx.c
buffer1: #include <stdio.h>
So, empirical proof that on some systems, the scenario I outlined can occur.
How to fix the code
The fix to the code is discussed well in other answers. If you avoid the problem I illustrated (for example, by avoiding global file pointers), that is simplest. Assuming that is not possible, it may be sufficient to compile with the appropriate flags (on many Unix-like systems, the compiler flag '
-D_REENTRANT' does the job), and you will end up using thread-safe versions of the basic standard I/O functions. Failing that, you may need to put explicit thread-safe management policies around the access to the file pointers; a mutex or something similar (and modify the code to ensure that the threads use the mutex before using the corresponding file pointer).