Let's face it, everybody hates using malloc(), realloc(), and free(). The goal of memtools is to alleviate the headache that inevitably comes with allocating
your own memory. memtools tackles this by giving the user a few new powerful tools: memprint(), memcomment(), memtest(), and memviolated(). Behind the
scenes memtools replaces malloc(), realloc(), and free() with its own wrappers of these functions. These wrappers keep a table of all your memory allocations
making these tools possible. When you compile with -DMEMTOOLS, memtools will replace the standard allocation functions with the wrappers and enable its tools.
When you switch off the MEMTOOLS macro, all of the tools disappear and the wrappers are restored to the original functions.
The memtools philospphy is that all of its tools should NOT affect the logic of your program. This means all the tools can be though of as void returning
functions. This may seem like a strange decision, as at first glance the following statement seems quite powerful:
/* DO NOT DO THIS, THIS IS BAD!!! */
if(pointer_is_valid(ptr)){
dereference_my_pointer(ptr);
} else {
try_to_fix_bad_pointer(&ptr);
}While memtools could indeed provide the above functionality (and does if you want to dig deep into the weeds), this would be catastrophic for the development process, only creating further headaches. memtools is not built like this because it is better to fix code at compile time rather than at run time. This means that writing code trying to fix other code is a terrible idea, and you really shouldn't do it. The other reason is that you want to be able to turn off memtools when it's time to compile the production version of your code (memtools introduces non-trivial overhead that is acceptable for debugging but would likely make your customers sad). With the above code, it's not clear what part of it should be turned off for production, so that makes it even more messy!
Ok, so you know how not to use memtools, so how should you use it? First, I'll explain what each tool does and then we'll look at some examples.
memprint()- prints all allocated memory blocks along with any comments and whether this memory has been 'violated' (we'll talk about violation later)memcomment(ptr, comment)- attaches a comment to a block of memory that will be printed out in memprint.memtest(ptr, comment)- takes in a pointer and prints whether or not this pointer points to allocated memory.memviolated(ptr, comment)- takes in a pointer and prints whether the memory block this pointer is inside has been 'violated'. memtools does memory violation checking by over-allocating memory blocks and storing a special number at the ends of the block. If memtools detects this memory has been overwritten, it decides that this block has been 'violated'. While this isn't a catch-all solution (it's possible the same number is overwritten or that memory outside the header and footer is violated) it certainly is helpful.
Now that we know about all of the tools, let's look at an example usage:
#include <memtools.h>
#include <stdlib.h>
int main(int argc, const char** argv){
int *array, N, *head;
N = atoi(argv[1]);
array = malloc((sizeof *array)*N);
memcomment(array, "This is my array with %d integers", N);
for(head = array; head != array + N; ++head){
memtest(head, "Checking head pointer on %d iteration", (head - array)/(sizeof *array));
*head = rand();
}
free(array);
memprint();
}A few comments on this code. First, you can see that memcomment not only allows string literals, but also printf style formattable strings which is quite handy!
Second, I like to use memtest on every pointer dereference in my code. This allows an extremely fine granularity on where exactly I caused a segfault. Finally, I
like to end the program with a call to memprint() when I know that all of my memory should be deallocated. If it doesn't report 0 bytes in 0 blocks, then I know
that I have a memory leak somewhere in my code (and it will tell me where!).
Right now, memtools uses an array to hold all the allocations which is not ideal for search. I plan to move to a binary tree where the integer value of the pointer is used as its key. This should provide a much faster lookup time (for large amounts of allocations). I would also like to support multiple comments and comment deletion for memory allocations (though I'm not quite sure how to move forward from a user standpoint here). If you'd like to help contribute, please contact me!