# Why is SSE scalar sqrt(x) slower than rsqrt(x) * x?

I've been profiling some of our core math on an Intel Core Duo, and while looking at various approaches to square root I've noticed something odd: using the SSE scalar operations, it is faster to take a reciprocal square root and multiply it to get the sqrt, than it is to use the native sqrt opcode!

I'm testing it with a loop something like:

inline float TestSqrtFunction( float in );

void TestFunc()
{
#define ARRAYSIZE 4096
#define NUMITERS 16386
float flIn[ ARRAYSIZE ]; // filled with random numbers ( 0 .. 2^22 )
float flOut [ ARRAYSIZE ]; // filled with 0 to force fetch into L1 cache

cyclecounter.Start();
for ( int i = 0 ; i < NUMITERS ; ++i )
for ( int j = 0 ; j < ARRAYSIZE ; ++j )
{
flOut[j] = TestSqrtFunction( flIn[j] );
// unrolling this loop makes no difference -- I tested it.
}
cyclecounter.Stop();
printf( "%d loops over %d floats took %.3f milliseconds",
NUMITERS, ARRAYSIZE, cyclecounter.Milliseconds() );
}

I've tried this with a few different bodies for the TestSqrtFunction, and I've got some timings that are really scratching my head. The worst of all by far was using the native sqrt() function and letting the "smart" compiler "optimize". At 24ns/float, using the x87 FPU this was pathetically bad:

inline float TestSqrtFunction( float in )
{  return sqrt(in); }

The next thing I tried was using an intrinsic to force the compiler to use SSE's scalar sqrt opcode:

inline void SSESqrt( float * restrict pOut, float * restrict pIn )
{
_mm_store_ss( pOut, _mm_sqrt_ss( _mm_load_ss( pIn ) ) );
// compiles to movss, sqrtss, movss
}

This was better, at 11.9ns/float. I also tried Carmack's wacky Newton-Rhapson approximation technique, which ran even better than the hardware, at 4.3ns/float, although with an error of 1 in 210 (which is too much for my purposes).

The doozy was when I tried the SSE op for reciprocal square root, and then used a multiply to get the square root ( x * 1/√x = √x ). Even though this takes two dependent operations, it was the fastest solution by far, at 1.24ns/float and accurate to 2-14:

inline void SSESqrt_Recip_Times_X( float * restrict pOut, float * restrict pIn )
{
__m128 in = _mm_load_ss( pIn );
_mm_store_ss( pOut, _mm_mul_ss( in, _mm_rsqrt_ss( in ) ) );
// compiles to movss, movaps, rsqrtss, mulss, movss
}

My question is basically what gives? Why is SSE's built-in-to-hardware square root opcode slower than synthesizing it out of two other math operations?

I'm sure that this is really the cost of the op itself, because I've verified:

• All data fits in cache, and accesses are sequential
• the functions are inlined
• unrolling the loop makes no difference
• compiler flags are set to full optimization (and the assembly is good, I checked)

(edit: stephentyrone correctly points out that operations on long strings of numbers should use the vectorizing SIMD packed ops, like rsqrtps — but the array data structure here is for testing purposes only: what I am really trying to measure is scalar performance for use in code that can't be vectorized.)

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I have no idea, but that really is interesting. –  BoltBait Oct 6 '09 at 23:49
x / sqrt(x) = sqrt(x). Or, put another way: x^1 * x^(-1/2) = x^(1 - 1/2) = x^(1/2) = sqrt(x) –  Crashworks Oct 29 '09 at 17:13
of course, inline float SSESqrt( float restrict fIn ) { float fOut; _mm_store_ss( &fOut, _mm_sqrt_ss( _mm_load_ss( &fIn ) ) ); return fOut; }. But this is a bad idea because it can easily induce a load-hit-store stall if the CPU writes the floats to the stack and then reads them back immediately -- juggling from the vector register to a float register for the return value in particular is bad news. Besides, the underlying machine opcodes that the SSE intrinsics represent take address operands anyway. –  Crashworks Feb 16 '10 at 19:35
How much LHS matters depends on the particular gen and stepping of a given x86: my experience is that on anything up to i7, moving data between register sets (eg FPU to SSE to eax) is very bad, while a round trip between xmm0 and stack and back isn't, because of Intel's store-forwarding. You can time it yourself to see for sure. Generally the easiest way to see potential LHS is to look at the emitted assembly and see where data is juggled between register sets; your compiler might do the smart thing, or it might not. As to normalizing vectors, I wrote up my results here: bit.ly/9W5zoU –  Crashworks Feb 16 '10 at 23:44
For the PowerPC, yes: IBM has a CPU simulator that can predict LHS and many other pipeline bubbles through static analysis. Some PPCs also have a hardware counter for LHS that you can poll. It's harder for the x86; good profiling tools are scarcer (VTune is somewhat broken these days) and the reordered pipelines are less deterministic. You can try to measure it empirically by measuring instructions per cycle, which can be done precisely with the hardware performance counters. The "instructions retired" and "total cycles" registers can be read with eg PAPI or PerfSuite (bit.ly/an6cMt). –  Crashworks Feb 17 '10 at 19:52

sqrtss gives a correctly rounded result. rsqrtss gives an approximation to the reciprocal, accurate to about 11 bits.

sqrtss is generating a far more accurate result, for when accuracy is required. rsqrtss exists for the cases when an approximation suffices, but speed is required. If you read Intel's documentation, you will also find an instruction sequence (reciprocal square-root approximation followed by a single Newton-Raphson step) that gives nearly full precision (~23 bits of accuracy, if I remember properly), and is still somewhat faster than sqrtss.

edit: If speed is critical, and you're really calling this in a loop for many values, you should be using the vectorized versions of these instructions, rsqrtps or sqrtps, both of which process four floats per instruction.

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+1 great answer, real detail + good mention of vectorisation. –  Tom Leys Oct 7 '09 at 0:16
The n/r step gives you 22-bits of accuracy (it doubles it); 23-bits would be exactly full accuracy. –  Jasper Bekkers Jul 12 '11 at 15:51
@Jasper Bekkers: No, it wouldn't. First, float has 24 bits of precision. Second, sqrtss is correctly rounded, which requires ~50 bits before rounding, and cannot be achieved using a simple N/R iteration in single precision. –  Stephen Canon Jul 12 '11 at 15:54
This is definitely the reason. To extend this result: Intel's Embree project (software.intel.com/en-us/articles/…), uses vectorization for its mathematics. You can download the source at that link and look at how they do their 3/4 D Vectors. Their vector normalization uses rsqrt followed by an iteration of newton-raphson, which is then very accurate and still faster than 1/ssqrt! –  Brandon Pelfrey Jun 24 '12 at 15:29
A small caveat: x*rsqrt(x) results in NaN if x is either zero or infinity. 0*rsqrt(0) = 0 * INF = NaN. INF*rsqrt(INF) = INF * 0 = NaN. For this reason, CUDA on NVIDIA GPUs computes approximate single-precision square roots as recip(rsqrt(x)), with the hardware providing both a fast approximation to the reciprocal and the reciprocal square root. Obviously, explicit checks handling the two special cases are also possible (but would be slower on the GPU). –  njuffa Aug 4 '12 at 20:37

This is also true for division. MULSS(a,RCPSS(b)) is way faster than DIVSS(a,b). In fact it's still faster even when you increase its precision with a Newton-Rhapson iteration.

Intel and AMD both recommend this technique in their optimisation manuals. In applications which don't require IEEE-754 compliance, the only reason to use div/sqrt is code readability.

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Instead of supplying an answer, that actually might be incorrect (I'm also not going to check or argue about cache and other stuff, let's say they are identical) I'll try to point you to the source that can answer your question.
The difference might lie in how sqrt and rsqrt are computed. You can read more here http://www.intel.com/products/processor/manuals/. I'd suggest to start from reading about processor functions you are using, there are some info, especially about rsqrt (cpu is using internal lookup table with huge approximation, which makes it much simpler to get the result). It may seem, that rsqrt is so much faster than sqrt, that 1 additional mul operation (which isn't to costly) might not change the situation here.

Edit: Few facts that might be worth mentioning:
1. Once I was doing some micro optimalizations for my graphics library and I've used rsqrt for computing length of vectors. (instead of sqrt, I've multiplied my sum of squared by rsqrt of it, which is exactly what you've done in your tests), and it performed better.
2. Computing rsqrt using simple lookup table might be easier, as for rsqrt, when x goes to infinity, 1/sqrt(x) goes to 0, so for small x's the function values doesn't change (a lot), whereas for sqrt - it goes to infinity, so it's that simple case ;).

Also, clarification: I'm not sure where I've found it in books I've linked, but I'm pretty sure I've read that rsqrt is using some lookup table, and it should be used only, when the result doesn't need to be exact, although - I might be wrong as well, as it was some time ago :).

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Newton-Raphson converges to the zero of f(x) using increments equals to -f/f' where f' is the derivative.

For x=sqrt(y), you can try to solve f(x) = 0 for x using f(x) = x^2 - y;

Then the increment is: dx = -f/f' = 1/2 (x - y/x) = 1/2 (x^2 - y) / x which has a slow divide in it.

You can try other functions (like f(x) = 1/y - 1/x^2) but they will be equally complicated.

Let's look at 1/sqrt(y) now. You can try f(x) = x^2 - 1/y, but it will be equally complicated: dx = 2xy / (y*x^2 - 1) for instance. One non-obvious alternate choice for f(x) is: f(x) = y - 1/x^2

Then: dx = -f/f' = (y - 1/x^2) / (2/x^3) = 1/2 * x * (1 - y * x^2)

Ah! It's not a trivial expression, but you only have multiplies in it, no divide. => Faster!

And: the full update step new_x = x + dx then reads:

x *= 3/2 - y/2 * x * x which is easy too.

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