The behaviour of
free() depends heavily on the operating system and C library that you are using. In most implementations there are actually two memory allocators in play:
The OS memory allocator, which uses the virtual memory facilities of the processor to provide a process with its own address space and maps physical memory pages into that address space for use.
The C library memory allocator, which is in fact part of the application code and uses the pages provided by the OS to provide fine-grained memory management facilities, as provided by
In general, calling
free() does one or more of the following:
It marks the pointed-to memory area as free in the C memory allocator. This allows that memory to be reused.
free() does not zero-out freed memory.
It may return memory to the OS, depending on the settings of the C memory allocator and whether it is actually possible to free that part of the heap. If memory is not returned to the OS, it can be reused by future
malloc() calls by the same application.
If you try to access memory that has been freed, usually one of three things will happen:
The memory has been returned to the OS, and your program, typically, crashes. If you ask me, that is probably the best scenario - you have a problem, sure, but you know it.
The memory has not been reused, therefore your old data is still there. Your program goes on as if nothing was wrong. This is in my opinion the worst case scenario. Your code appears to work correctly and, if Murphy has a say in this, it will continue to do so until it reaches your end users - then it will fail spectacularly.
The memory has been reused by your program, and your code will start messing around with its own data. If you are careful (and lucky?), you will probably notice that the results are off. If not, well...
If you are on Linux/Unix Valgrind is a good tool to catch memory management problems like this. There are also replacement libraries for the C memory allocator, such as DUMA that will also allow you to detect such issues.