You seem to be a bit confused about what
malloc() does and about the role of NULL.
malloc() function allocates space, but does not initialize the space to any value. The return value from
malloc() is a pointer to (the first byte of) that space. Unless you attempt to allocate zero bytes1, the return value from
malloc() will only be NULL if it was unable to allocate as much space as you asked for2.
Therefore, your program will not print "Hello World" unless your system is running extremely short of memory. The pointer
string will be a valid memory location.
What is completely undefined is the data that
string points at. You would have to initialize it somehow, for example, with:
strcpy(string, "Hello World");
Now you could safely do:
Before you initialize it, it is not 'safe' to read the memory; there is no guarantee about what you'll find in it. Your program won't crash, but what you see is what you get.
You can also safely use:
if (fgets(string, 500, stdin) != 0)
printf("Read: %s", string);
fgets() reserves a space for the terminal
'\0'; you don't have to shrink the space by one.
How can I check if
string has been changed by something like
strcat() or ...
For most practical purposes, you can't determine if it has been modified because there is no defined content for the memory. If you really wanted to know, you could probably do:
char *string_copy = malloc(500);
if (string_copy != NULL)
memmove(string_copy, string, 500);
to make a copy of the original content of the memory that was allocated, and then use:
if (memcmp(string_copy, string, 500) != 0)
...someone changed either string or string_copy (or both)...
It is rather thin ice; the value in the allocated space is not defined, but in practice, I'd be surprised to find it doesn't work. On the other hand, I can't think of a circumstance where I'd be interested in this knowledge. If I allocate memory, it is in order to use it — usually almost immediately.
1 If you allocate zero bytes, you get one of two implementation-defined behaviours. Either you get a NULL pointer returned, or you get a valid, non-NULL pointer to zero bytes of accessible memory (so you can't safely access) that is distinct from any other memory allocation. The result, either way, can be safely passed to
free(). If you allocate zero bytes, any attempt to access memory via the pointer returned leads to undefined behaviour.
2 Beware that on Linux, you can ask for massive amounts of memory and
malloc() will claim to allocate it for you, but you may find that when you come to access it, it is not available after all.