I can actually think of one reason why an IntPtr (or UIntPtr) would be useful: accessing elements of an array requires native-sized integers. Though native integers are never exposed to the programmer, they are internally used in IL. Something like
some_array[index] in C# will actually compile down to
some_array[(int)checked((IntPtr)index)] in IL. I noticed this after disassembling my own code with ILSpy. (The
index variable is 64-bit in my code.) To verify that the disassembler wasn't making a mistake, Microsoft's own ILDASM tool shows the existence of
conv.i instructions within my assembly. Those instructions convert integers to the system's native representation. I don't know what the performance implication is having all these conversion instructions in the IL code, but hopefully the JIT is smart enough to optimize the performance penalty away; if not, the next best thing is to allow manipulating native integers without conversions (which, in my opinion, might be the main motivation to use a native type).
Currently, the F# language allows the use of
nativeint and and its unsigned counterpart for arithmetic. However, arrays can only be indexed by
int in F# which means
nativeint is not very useful for the purposes of indexing arrays.
If it really bothers you that much, write your own compiler that lifts restrictions on native integer use, create your own language, write your code in IL, or tweak the IL after compiling. Personally, I think it's a bad idea to squeeze out extra performance or save memory by using native int. If you wanted your code to fit the system like a glove, you'd best be using a lower level language with support for processor intrinsics.