# Why is pow(int, int) so slow?

I've been working on a few project Euler exercises to improve my knowledge of C++.

I've written the following function:

int a = 0,b = 0,c = 0;

for (a = 1; a <= SUMTOTAL; a++)
{
for (b = a+1; b <= SUMTOTAL-a; b++)
{
c = SUMTOTAL-(a+b);

if (c == sqrt(pow(a,2)+pow(b,2)) && b < c)
{
std::cout << "a: " << a << " b: " << b << " c: "<< c << std::endl;
std::cout << a * b * c << std::endl;
}
}
}

This computes in 17 milliseconds.

However, if I change the line

if (c == sqrt(pow(a,2)+pow(b,2)) && b < c)

to

if (c == sqrt((a*a)+(b*b)) && b < c)

the computation takes place in 2 milliseconds. Is there some obvious implementation detail of pow(int, int) that I'm missing which makes the first expression compute so much slower?

• a*a is probably 1 instruction. pow is at least a function call, plus whatever work the function does. Commented Dec 10, 2016 at 6:24
• This computes in 17 milliseconds. -- First, pow is a floating point function. Second, posting how much time a function takes only makes sense if you're running an optimized build. If you're running an unoptimized of "debug" build, the time is meaningless. And last, but not least, don't use pow if the exponent is an integer Commented Dec 10, 2016 at 6:33
• This review might be interesting for you. It's both a library call, as well as a "overpowered" function as ringo said.
– Zeta
Commented Dec 10, 2016 at 8:35
• It's probably faster if you use c*c = a*a + b*b: multiplication, especially integer multiplication, is faster than square root. But it's only correct if c*c doesn't overflow. Commented Dec 10, 2016 at 10:51
• @RoelSchroeven But if c*c overflows, then a*a + b*b would also overflow (assuming that they are in fact equal), so it probably should not matter much. Commented Dec 10, 2016 at 13:07

pow() works with real floating-point numbers and uses under the hood the formula

pow(x,y) = e^(y log(x))

to calculate x^y. The int are converted to double before calling pow. (log is the natural logarithm, e-based)

x^2 using pow() is therefore slower than x*x.

• Using pow even with integer exponents may yield incorrect results (PaulMcKenzie)
• In addition to using a math function with double type, pow is a function call (while x*x isn't) (jtbandes)
• Many modern compilers will in fact optimize out pow with constant integer arguments, but this should not be relied upon.
• Not only is it slower, you can get inexact answers, even for integer base and exponents. Commented Dec 10, 2016 at 6:38
• @YanZhou -- It will not always give the exact results, else this would never have been asked Commented Dec 10, 2016 at 6:44
• @PaulMcKenzie As I said, it is the case with reputable libm. Not every libm give exact. As far as I know, AMD libm, Intel libimf, OpenLibm, BSD libm and its derivatives such as the one in macOS will all give you pow(5, 2) == 25, the example you cited. GNU libc is the most widely used on linux, but it does not make it the gold standard Commented Dec 10, 2016 at 6:50
• @PaulMcKenzie One correction, GNU libc shall also give the same results. The post you cited is probably using GCC+Code Blocks on Windows, MS libm was the less reputable one. Commented Dec 10, 2016 at 6:52
• My point is that nothing in the C++ standard guarantees that pow gives exact results, even with integer exponents. Make life happy and compute pow using a lookup table, or some other means that guarantees there is no round-off error, regardless of the library being used. Commented Dec 10, 2016 at 6:53

You've picked one of the slowest possible ways to check

c*c == a*a + b*b   // assuming c is non-negative

That compiles to three integer multiplications (one of which can be hoisted out of the loop). Even without pow(), you're still converting to double and taking a square root, which is terrible for throughput. (And also latency, but branch prediction + speculative execution on modern CPUs means that latency isn't a factor here).

Intel Haswell's SQRTSD instruction has a throughput of one per 8-14 cycles (source: Agner Fog's instruction tables), so even if your sqrt() version keeps the FP sqrt execution unit saturated, it's still about 4 times slower than what I got gcc to emit (below).

You can also optimize the loop condition to break out of the loop when the b < c part of the condition becomes false, so the compiler only has to do one version of that check.

void foo_optimized()
{
for (int a = 1; a <= SUMTOTAL; a++) {
for (int b = a+1; b < SUMTOTAL-a-b; b++) {
// int c = SUMTOTAL-(a+b);   // gcc won't always transform signed-integer math, so this prevents hoisting (SUMTOTAL-a) :(
int c = (SUMTOTAL-a) - b;
// if (b >= c) break;  // just changed the loop condition instead

// the compiler can hoist a*a out of the loop for us
if (/* b < c && */ c*c == a*a + b*b) {
// Just print a newline.  std::endl also flushes, which bloats the asm
std::cout << "a: " << a << " b: " << b << " c: "<< c << '\n';
std::cout << a * b * c << '\n';
}
}
}
}

This compiles (with gcc6.2 -O3 -mtune=haswell) to code with this inner loop. See the full code on the Godbolt compiler explorer.

# a*a is hoisted out of the loop.  It's in r15d
.L6:
sub     ebx, 1    # c--
add     r12d, r14d        # ivtmp.36, ivtmp.43  # not sure what this is or why it's in the loop, would have to look again at the asm outside
cmp     ebp, ebx  # b, _39
jg      .L13    ## This is the loop-exit branch, not-taken until the end
## .L13 is the rest of the outer loop.
##  It sets up for the next entry to this inner loop.
.L8:
mov     eax, ebp        # multiply a copy of the counters
mov     edx, ebx
imul    eax, ebp        # b*b
imul    edx, ebx        # c*c
add     eax, r15d       # a*a + b*b
cmp     edx, eax  # tmp137, tmp139
jne     .L6
## Fall-through into the cout print code when we find a match
## extremely rare, so should predict near-perfectly

On Intel Haswell, all these instructions are 1 uop each. (And the cmp/jcc pairs macro-fuse into compare-and-branch uops.) So that's 10 fused-domain uops, which can issue at one iteration per 2.5 cycles.

Haswell runs imul r32, r32 with a throughput of one iteration per clock, so the two multiplies inside the inner loop aren't saturating port 1 at two multiplies per 2.5c. This leaves room to soak up the inevitable resource conflicts from ADD and SUB stealing port 1.

We're not even close to any other execution-port bottlenecks, so the front-end bottleneck is the only issue, and this should run at one iteration per 2.5 cycles on Intel Haswell and later.

Loop-unrolling could help here to reduce the number of uops per check. e.g. use lea ecx, [rbx+1] to compute b+1 for the next iteration, so we can imul ebx, ebx without using a MOV to make it non-destructive.

A strength-reduction is also possible: Given b*b we could try to compute (b-1) * (b-1) without an IMUL. (b-1) * (b-1) = b*b - 2*b + 1, so maybe we can do an lea ecx, [rbx*2 - 1] and then subtract that from b*b. (There are no addressing-modes that subtract instead of add. Hmm, maybe we could keep -b in a register, and count up towards zero, so we could use lea ecx, [rcx + rbx*2 - 1] to update b*b in ECX, given -b in EBX).

Unless you actually bottleneck on IMUL throughput, this might end up taking more uops and not be a win. It might be fun to see how well a compiler would do with this strength-reduction in the C++ source.

You could probably also vectorize this with SSE or AVX, checking 4 or 8 consecutive b values in parallel. Since hits are really rare, you just check if any of the 8 had a hit and then sort out which one it was in the rare case that there was a match.