To my knowledge, a CPU performs best with a datum that is aligned on the boundary equal to the size of that datum. For example, if every
int datum is 4 bytes in size, then the address of every
int must be a multiple of 4 to make the CPU happy; same with 2-byte
short data and 8-byte
double data. For this reason,
new operator and
malloc function always return an address that is a multiple of 8 and, therefore, is a multiple of 4 and 2.
In my program, some time-critical algorithms that are meant to process large byte arrays allow striding through the computation by converting each contiguous 4 bytes into an
unsigned int and, in this way, do the arithmetic much faster. However, the address of the byte array is not guaranteed to be a multiple of 4 because only a part of a byte array may need to be processed.
As far as I know, Intel CPUs operate on misaligned data properly but at the expense of speed. If operating on misaligned data is slower enough, the algorithms in my program would need to be redesigned. In this connection I've got two questions, the first of which is supported with the following code:
// the address of array0 is a multiple of 4: unsigned char* array0 = new unsigned char; array0 = 0x00; array0 = 0x11; array0 = 0x22; array0 = 0x33; // the address of array1 is a multiple of 4 too: unsigned char* array1 = new unsigned char; array1 = 0x00; array1 = 0x00; array1 = 0x11; array1 = 0x22; array1 = 0x33; // OP1: the address of the 1st operand is a multiple of 4, // which is optimal for an unsigned int: unsigned int anUInt0 = *((unsigned int*)array0) + 1234; // OP2: the address of the 1st operand is not a multiple of 4: unsigned int anUInt1 = *((unsigned int*)(array1 + 1)) + 1234;
So the questions are:
How much slower is OP2 compared to OP1 on x86, x86-64, and Itanium processors (if neglect the cost of type casting and address increment)?
When writing cross-platform portable code, about what kinds of processors should I be concerned regarding misaligned data access? (I already know about RISC ones)