One fundamental reason is that there is no difference between a pointer to the first element of a dynamically allocated array of T
and a pointer to any other T
.
Consider a fictitious function that returns the number of elements a pointer points to.
Let's call it "size".
Sounds really nice, right?
If it weren't for the fact that all pointers are created equal:
char* p = new char[10];
size_t ps = size(p+1); // What?
char a[10] = {0};
size_t as = size(a); // Hmm...
size_t bs = size(a + 1); // Wut?
char i = 0;
size_t is = size(&i); // OK?
You could argue that the first should be 9
, the second 10
, the third 9
, and the last 1
, but to accomplish this you need to add a "size tag" on every single object.
A char
will require 128 bits of storage (because of alignment) on a 64-bit machine. This is sixteen times more than what is necessary.
(Above, the ten-character array a
would require at least 168 bytes.)
This may be convenient, but it's also unacceptably expensive.
You could of course envision a version that is only well-defined if the argument really is a pointer to the first element of a dynamic allocation by the default operator new
, but this isn't nearly as useful as one might think.
std::vector
). (Of course templates were only added to C++ later thannew
, so that's speaking with hindsight only.)delete[] a
doesn't necessarily need to know the size any more thanfree(p)
does. The only reason you might need to know the size is if you need to call destructors, but forint
there's no such need.