The first of the two linked article raises two complaints above and beyond the "check the call succeeded" points already raised here.
When this is done, the old contents are discarded and left in memory somewhere. For secure memory applications where it is important to erase all traces of data, this behavior is inappropriate.
This is a valid point if you happen to be storing sensitive data (e.g. private keys, unhashed(!) passwords etc.) and want to make it harder for exploits to recover the data or other processes on the system to steal the data.
Since it moves memory around, any old pointers to that memory become invalid and could cause the program to crash or otherwise misbehave.
This point seems like nonsense to me. Their proposed solution is no better, they
malloc(), copy and then
free() the original which has the same net effect - the address has changed. If you wanted to avoid moving the memory you might be able to use some platform specific calls to do that, if you arranged for there to be sufficient free address space near them. If you knew a priori how much address space to reserve then you'd probably not be thinking of calling
realloc() in the first place though!
If you're gambling on
realloc() never moving, always growing then you've probably got bigger problems to worry about anyway and switching to
malloc() + copy +
free() can't possibly solve that.
Besides the "check your return value properly point", the most interesting point from the second article is a warning about:
Do not realloc your buffer by 1 byte at a time.
This is guaranteed to churn your memory heap
This is a potentially valid point, but it's not a criticism of
realloc() itself; the same would happen if you used
free(). The real fix is to grow buffers sensibly regardless of how you grow them or better yet allocate in correct sized chunks up front.
They also have a point about
Using realloc to return memory to the system.
They're correct here in that using any size other than 0 might not actually make a return. It probably makes things no worse, but this usage still seems like an example of premature "optimisation". The fix again is to use sensible sized allocations to begin with.
Sort answer: it's not unsafe, but it's not a magical solution to all your problems either.