I came to this thread to get an idea of what the modern processors are doing in regard to integer math and the number of cycles required to do them. I worked on this problem of speeding up 32-bit integer multiplies and divides on the 65c816 processor in the 1990's. Using the method below, I was able to triple the speed of the standard math libraries available in the ORCA/M compilers at the time.

So the idea that multiplies are faster than adds is simply not the case (except rarely) but like people said it depends upon how the architecture is implemented. If there are enough steps being performed available between clock cycles, yes a multiply could effectively be the same speed as an add based on the clock, but there would be a lot of wasted time. In that case it would be nice to have an instruction that performs multiple (dependent) adds / subtracts given one instruction and multiple values. One can dream.

On the 65c816 processor, there were no multiply or divide instructions. Mult and Div were done with shifts and adds.

To perform a 16 bit add, you would do the following:

```
LDA $0000 - loaded a value into the Accumulator (5 cycles)
ADC $0002 - add with carry (5 cycles)
STA $0004 - store the value in the Accumulator back to memory (5 cycles)
15 cycles total for an add
```

If dealing with a call like from C, you would have additional overhead of dealing with pushing and pulling values off the stack. Creating routines that would do two multiples at once would save overhead for example.

The traditional way of doing the multiply is shifts and adds through the entire value of the one number. Each time the carry became a one as it is shifted left would mean you needed to add the value again. This required a test of each bit and a shift of the result.

I replaced that with a lookup table of 256 items so as the carry bits would not need to be checked. It was also possible to determine overflow before doing the multiply to not waste time. (On a modern processor this could be done in parallel but I don't know if they do this in the hardware). Given two 32 bit numbers and prescreened overflow, one of the multipliers is always 16 bits or less, thus one would only need to run through 8 bit multiplies once or twice to perform the entire 32 bit multiply. The result of this was multiplies that were 3 times as fast.

the speed of the 16 bit multiplies ranged from 12 cycles to about 37 cycles

```
multiply by 2 (0000 0010)
LDA $0000 - loaded a value into the Accumulator (5 cycles).
ASL - shift left (2 cycles).
STA $0004 - store the value in the Accumulator back to memory (5 cycles).
12 cycles plus call overhead.
```

```
multiply by (0101 1010)
LDA $0000 - loaded a value into the Accumulator (5 cycles)
ASL - shift left (2 cycles)
ASL - shift left (2 cycles)
ADC $0000 - add with carry for next bit (5 cycles)
ASL - shift left (2 cycles)
ADC $0000 - add with carry for next bit (5 cycles)
ASL - shift left (2 cycles)
ASL - shift left (2 cycles)
ADC $0000 - add with carry for next bit (5 cycles)
ASL - shift left (2 cycles)
STA $0004 - store the value in the Accumulator back to memory (5 cycles)
37 cycles plus call overhead
```

Since the databus of the AppleIIgs for which this was written was only 8 bits wide, to load 16 bit values required 5 cycles to load from memory, one extra for the pointer, and one extra cycle for the second byte.

LDA instruction (1 cycle because it is an 8 bit value)
$0000 (16 bit value requires two cycles to load)
memory location (requires two cycles to load because of an 8 bit data bus)

Modern processors would be able to do this faster because they have a 32 bit data bus at worst. In the processor logic itself the system of gates would have no additional delay at all compared to the data bus delay since the whole value would get loaded at once.

To do the complete 32 bit multiply, you would need to do the above twice and add the results together to get the final answer. The modern processors should be able to do the two in parallel and add the results for the answer. Combined with the overflow precheck done in parallel, it would minimize the time required to do the multiply.

Anyway it is readily apparent that multiplies require significantly more effort than an add. How many steps to process the operation between cpu clock cycles would determine how many cycles of the clock would be required. If the clock is slow enough, then the adds would appear to be the same speed as a multiply.

Regards,
Ken

twoadditions.`std::push_heap`

, etc.) so I could process items in a prioritized order. I ran out of ideas to make its faster; it took me a lot of guess-and-check debugging/profiling to figure out the cause, and I was left scratching my head when I saw an`imul`

instruction that I didn't expect. I know it's surprising, but my task was pretty darn typical, and this pointer subtraction in the heap really was the bottleneck.12more comments