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I often see code that converts ints to doubles to ints to doubles and back once again (sometimes for good reasons, sometimes not), and it just occurred to me that this seems like a "hidden" cost in my program. Let's assume the conversion method is truncation.

So, just how expensive is it? I'm sure it varies depending on hardware, so let's assume a newish Intel processor (Haswell, if you like, though I'll take anything). Some metrics I'd be interested in (though a good answer needn't have all of them):

  1. # of generated instructions
  2. # of cycles used
  3. Relative cost compared to basic arithmetic operations

I would also assume that the way we would most acutely experience the impact of a slow conversion would be with respect to power usage rather than execution speed, given the difference in how many computations we can perform each second relative to how much data can actually arrive at the CPU each second.

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2 Answers 2

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Here's what I could dig up myself, for x86-64 doing FP math with SSE2 (not legacy x87 where changing the rounding mode for C++'s truncation semantics was expensive):

  1. When I take a look at the generated assembly from clang and gcc, it looks like the cast int to double, it boils down to one instruction: cvttsd2si.

    From double to int it's cvtsi2sd. (cvtsi2sdl AT&T syntax for cvtsi2sd with 32-bit operand-size.)

    With auto-vectorization, we get cvtdq2pd.

    So I suppose the question becomes: what is the cost of those?

  2. These instructions each cost approximately the same as an FP addsd plus a movq xmm, r64 (fp <- integer) or movq r64, xmm (integer <- fp), because they decode to 2 uops which on the same ports, on mainstream (Sandybridge/Haswell/Sklake) Intel CPUs.

    The Intel® 64 and IA-32 Architectures Optimization Reference Manual says that cost of the cvttsd2si instruction is 5 latency (see Appendix C-16). cvtsi2sd, depending on your architecture, has latency varying from 1 on Silvermont to more like 7-16 on several other architectures.

    Agner Fog's instruction tables have more accurate/sensible numbers, like 5-cycle latency for cvtsi2sd on Silvermont (with 1 per 2 clock throughput), or 4c latency on Haswell, with one per clock throughput (if you avoid the dependency on the destination register from merging with the old upper half, like gcc usually does with pxor xmm0,xmm0).

    SIMD packed-float to packed-int is great; single uop. But converting to double requires a shuffle to change element size. SIMD float/double<->int64_t doesn't exist until AVX512, but can be done manually with limited range.

    Intel's manual defines latency as: "The number of clock cycles that are required for the execution core to complete the execution of all of the μops that form an instruction." But a more useful definition is the number of clocks from an input being ready until the output becomes ready. Throughput is more important than latency if there's enough parallelism for out-of-order execution to do its job: What considerations go into predicting latency for operations on modern superscalar processors and how can I calculate them by hand?.

  3. The same Intel manual says that an integer add instruction costs 1 latency and an integer imul costs 3 (Appendix C-27). FP addsd and mulsd run at 2 per clock throughput, with 4 cycle latency, on Skylake. Same for the SIMD versions, and for FMA, with 128 or 256-bit vectors.

    On Haswell, addsd / addpd is only 1 per clock throughput, but 3 cycle latency thanks to a dedicated FP-add unit.

So, the answer boils down to:

1) It's hardware optimized, and the compiler leverages the hardware machinery.

2) It costs only a bit more than a multiply does in terms of the # of cycles in one direction, and a highly variable amount in the other (depending on your architecture). Its cost is neither free nor absurd, but probably warrants more attention given how easy it is write code that incurs the cost in a non-obvious way.

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    For clarity: Agner Fog's awesome manual "Instruction Tables" reports that on Haswell, the integer register-register add has latency = 1, reciprocal throughput = 0.25; integer register-register mul/imull 64x64-bit has lat = 3, 1/thru = 1, floating-point register-register addss/ps/sd/pd has lat = 3, 1/thru = 1, floating-point register-register mulss/ps/sd/pd has lat = 5, 1/thru = 0.5, and the various cvt* conversions between 32-bit and 64-bit integers and floating-point values for the most part have lat = 3-4 and 1/thru = 1. Feb 23, 2015 at 7:27
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    @IwillnotexistIdonotexist - Thorough :). Much obliged!
    – Mark
    Feb 23, 2015 at 7:29
  • Yes, float/double <-> int conversion costs about as much as FP addition, and in fact runs on the same execution units. (agner.org/optimize). SIMD float<->int is efficient, but SIMD double<->int needs a shuffle uop as well, and SIMD float/double<->int64_t doesn't exist until AVX512. Sep 26, 2018 at 14:52
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    Ended up making a major edit to correct this answer. There were some serious gaps in the picture you came up with based on digging into manuals back when you wrote this. I maybe should have just written my own answer, so let me know if you want to roll this back; I can put what I wrote in a separate answer. Sep 26, 2018 at 15:24
  • Thanks to everyone involved for this fantastic answer. This has been super useful!
    – iestyn
    Oct 20, 2021 at 22:24
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Of course this kind of question depends on the exact hardware and even on the mode.

On x86 my i7 when used in 32-bit mode with default options (gcc -m32 -O3) the conversion from int to double is quite fast, the opposite instead is much slower because the C standard mandates an absurd rule (truncation of decimals).

This way of rounding is bad both for math and for hardware and requires the FPU to switch to this special rounding mode, perform the truncation, and switch back to a sane way of rounding.

If you need speed doing the float->int conversion using the simple fistp instruction is faster and also much better for computation results, but requires some inline assembly.

inline int my_int(double x)
{
  int r;
  asm ("fldl %1\n"
       "fistpl %0\n"
       :"=m"(r)
       :"m"(x));
  return r;
}

is more than 6 times faster than naive x = (int)y; conversion (and doesn't have a bias toward 0).

The very same processor, when used in 64-bit mode however has no speed problems and using the fistp code actually makes the code run somewhat slower.

Apparently the hardware guys gave up and implemented the bad rounding algorithm directly in hardware (so badly rounding code can now run fast).

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    On what platform did you come to the conclusion that it is 6x faster? A year or two back, I got involved with a similar question, where someone asked why the code in your answer was better, and my immediate response was "how do you know it's better", and it very much turns out that if you have an SSE capable processor (so for x86, something introduced since about 2000), then it's faster to NOT use this trick, but just let the compiler generate the "right" instruction. I'll see if I can find my answer, but have to go to work now, so will do later. Feb 23, 2015 at 9:43
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    @MatsPetersson: this was tested on an i7 but compiling -m32, the problem is not present (actually it's faster to use naive conversion) when compiling 64 bit code.
    – 6502
    Feb 23, 2015 at 11:52
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    What if you use -m32 -msse2? Feb 23, 2015 at 21:55
  • @MatsPetersson: You'd need to use -m32 -msse2 -mfpmath=sse to actually use SSE2 for scalar FP math. Or -m32 -msse3 for fisttp (truncating conversion without changing the rounding mode). gcc targeting x86-64 defaults to -mfpmath=sse, of course, but 32-bit still defaults to x87, mostly only using SSE when auto-vectorizing, IIRC. Sep 26, 2018 at 14:44
  • Or convert to integer with round-to-nearest, if you can find a function that your compiler fully inlines with fistp or cvtsd2si, like (int)rint(x) or lrint(x), maybe with -fno-math-errno. round() for float in C++ Sep 26, 2018 at 14:44

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