I recently tore my hair out debugging this piece of code (slightly modified for simplicity of presentation):
char *packedData; unsigned char* indexBegin, *indexEnd; int block, row; // +------ bad! // v int cRow = std::upper_bound( indexBegin, indexEnd, row&255 ) - indexBegin - 1; char value = *(packedData + (block + cRow) * bytesPerRow);
Of course, assigning the difference of two pointers (the result of
std::upper_bound minus the beginning of the searched array) to an int, rather than a ptrdiff_t, is wrong in a 64-bit environment, but the particular bad behavior that resulted was very unexpected. I'd expect this to fail when the array at [indexBegin, indexEnd) was more than 2GB in size, so that the difference overflowed an int; but what actually happened was a crash when indexBegin and indexEnd had values on opposite sides of 2^31 (i.e. indexBegin = 0x7fffffe0, indexEnd = 0x80000010). Further investigation revealed the following x86-64 assembly code (generated by MSVC++ 2005, with optimizations):
; (inlined code of std::upper_bound, which leaves indexBegin in rbx, ; the result of upper_bound in r9, block at *(r12+0x28), and data at ; *(r12+0x40), immediately precedes this point) movsxd rcx, r9d ; movsxd?! movsxd rax, ebx ; movsxd?! sub rcx, rax lea rdx, [rcx+rdi-1] movsxd rax, dword ptr [r12+28h] imul rdx, rax mov rax, qword ptr [r12+40h] mov rcx, byte ptr[rdx+rax]
This code treats the pointers being subtracted as signed, 32-bit values, sign-extending them into 64-bit registers before subtracting them and multiplying the result by another sign-extended 32-bit value, and then indexes another array with the 64-bit result of that computation. Try as I might, I can't figure out under what theory this could ever be correct. Had the pointers been subtracted as 64-bit values, or had there been another instruction, right after the imul, that sign-extended edx into rdx (or had the final mov referenced rax+edx, but I don't think that's available in x86-64), everything would be fine (nominally dangerous, but I happen to know that [indexBegin, indexEnd) will never even approach 2GB in length).
The question is somewhat academic, since my actual bug is easily fixed by just using a 64-bit type to hold the pointer difference, but is this a compiler bug, or is there some obscure part of the language specification that allows the compiler to assume that the operands of a subtraction will individually fit into the result type?
EDIT: the only situation I can think of that would make what the compiler has done okay, is if it's allowed to assume that integer underflows will never happen (so that if I subtract two numbers and assign the result to a
signed int, the compiler would be free to actually use a larger signed integral type, which turns out to be wrong in this case). Is that allowed by the language spec?