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TL;DR: Why is multiplying/casting data in size_t slow and why does this vary per platform?

I'm having some performance issues that I don't fully understand. The context is a camera frame grabber where a 128x128 uint16_t image is read and post-processed at a rate of several 100 Hz.

In the post-processing I generate a histogram frame->histo which is of uint32_t and has thismaxval = 2^16 elements, basically I tally all intensity values. Using this histogram I calculate the sum and squared sum:

double sum=0, sumsquared=0;
size_t thismaxval = 1 << 16;

for(size_t i = 0; i < thismaxval; i++) {
    sum += (double)i * frame->histo[i];
    sumsquared += (double)(i * i) * frame->histo[i];
}

Profiling the code with profile I got the following (samples, percentage, code):

 58228 32.1263 :  sum += (double)i * frame->histo[i];
116760 64.4204 :  sumsquared += (double)(i * i) * frame->histo[i];

or, the first line takes up 32% of CPU time, the second line 64%.

I did some benchmarking and it seems to be the datatype/casting that's problematic. When I change the code to

uint_fast64_t isum=0, isumsquared=0;

for(uint_fast32_t i = 0; i < thismaxval; i++) {
    isum += i * frame->histo[i];
    isumsquared += (i * i) * frame->histo[i];
}

it runs ~10x faster. However, this performance hit also varies per platform. On the workstation, a Core i7 CPU 950 @ 3.07GHz the code is 10x faster. On my Macbook8,1, which has a Intel Core i7 Sandy Bridge 2.7 GHz (2620M) the code is only 2x faster.

Now I am wondering:

  1. Why is the original code so slow and easily sped up?
  2. Why does this vary per platform so much?

Update:

I compiled the above code with

g++ -O3  -Wall cast_test.cc -o cast_test

Update2:

I ran the optimized codes through a profiler (Instruments on Mac, like Shark) and found two things:

1) The looping itself takes a considerable amount of time in some cases. thismaxval is of type size_t.

  1. for(size_t i = 0; i < thismaxval; i++) takes 17% of my total runtime
  2. for(uint_fast32_t i = 0; i < thismaxval; i++) takes 3.5%
  3. for(int i = 0; i < thismaxval; i++) does not show up in the profiler, I assume it's less than 0.1%

2) The datatypes and casting matter as follows:

  1. sumsquared += (double)(i * i) * histo[i]; 15% (with size_t i)
  2. sumsquared += (double)(i * i) * histo[i]; 36% (with uint_fast32_t i)
  3. isumsquared += (i * i) * histo[i]; 13% (with uint_fast32_t i, uint_fast64_t isumsquared)
  4. isumsquared += (i * i) * histo[i]; 11% (with int i, uint_fast64_t isumsquared)

Surprisingly, int is faster than uint_fast32_t?

Update4:

I ran some more tests with different datatypes and different compilers, on one machine. The results are as follows.

For testd 0 -- 2 the relevant code is

    for(loop_t i = 0; i < thismaxval; i++)
        sumsquared += (double)(i * i) * histo[i];

with sumsquared a double, and loop_t size_t, uint_fast32_t and int for tests 0, 1 and 2.

For tests 3--5 the code is

    for(loop_t i = 0; i < thismaxval; i++)
        isumsquared += (i * i) * histo[i];

with isumsquared of type uint_fast64_t and loop_t again size_t, uint_fast32_t and int for tests 3, 4 and 5.

The compilers I used are gcc 4.2.1, gcc 4.4.7, gcc 4.6.3 and gcc 4.7.0. The timings are in percentages of total cpu time of the code, so they show relative performance, not absolute (although the runtime was quite constant at 21s). The cpu time is for both two lines, because I'm not quite sure if the profiler correctly separated the two lines of code.

gcc:    4.2.1  4.4.7  4.6.3  4.7.0
----------------------------------
test 0: 21.85  25.15  22.05  21.85
test 1: 21.9   25.05  22     22
test 2: 26.35  25.1   21.95  19.2
test 3: 7.15   8.35   18.55  19.95
test 4: 11.1   8.45   7.35   7.1
test 5: 7.1    7.8    6.9    7.05

or:

casting performance

Based on this, it seems that casting is expensive, regardless of what integer type I use.

Also, it seems gcc 4.6 and 4.7 are not able to optimize loop 3 (size_t and uint_fast64_t) properly.

share|improve this question
    
could you also try it with uint_fast32_t? A wild guess is that it is faster due to the fact that the second datatype has the same bitlength as the machine instructions (64-bit). Guessing that you have a 64bit machine at least. I would expect that the fast32 is also slower. edit could you also test the size of both uint_fast32_t and uint_fast64_t? My guess is that the 32 is actually 64 bits. –  Yuri May 15 '12 at 7:57
    
Do you mean uint_fast32_t isum? I could try, although I think that could overflow, which is why I used uint_fast64_t. –  Tim May 15 '12 at 8:00
3  
Well, for 1.: Reason somehow dictates that casting ints to floats and doing float operations should be slower than doing int operations directly (although int-to-float shouldn't be as evil as float-to-int), even more so with the not that optimal x87 stack. Do you compile it with SSE support? –  Christian Rau May 15 '12 at 8:04
    
I made a small mistake in the previous comment, cant edit that anymore. Disregard that :). If you print the sizeof(uint_fast32_t), my guess is that you will see 8 bytes. This means that it is the same size as a machine instruction, and it could be that this is faster to process. –  Yuri May 15 '12 at 8:04
1  
Can you post the disassembly? –  harold May 15 '12 at 10:15

2 Answers 2

up vote 3 down vote accepted

For your original questions:

  1. The code is slow because it involves the conversion from integer to float data types. That's why it's easily sped up when you use also an integer datatype for the sum-variables because it doesn't require a float-conversion anymore.
  2. The difference is the result of several factors. For example it depends on how efficient a platform is able to perform an int->float conversion. Furthermore this conversion could also mess up processor-internal optimizations in the program flow and prediction engine, caches, ... and also the internal parallelizing-features of the processors can have a huge influence in such calculations.

For the additional questions:

  • "Surprisingly int is faster than uint_fast32_t"? What's the sizeof(size_t) and sizeof(int) on your platform? One guess I can make is, that both are probably 64bit and therefore a cast to 32bit not only can give you calculation errors but also includes a different-size-casting penalty.

In general try to avoid visible and hidden casts as good as possible if these aren't really necessary. For example try to find out what real datatype is hidden behind "size_t" on your environment (gcc) and use that one for the loop-variable. In your example the square of uint's cannot be a float datatype so it makes no sense to use double here. Stick to integer types to achieve maximum performance.

share|improve this answer
    
Thanks. I knew that casts are not ideal, but I didn't know it was so expensive. Regarding your second point: the machine is 64bit, but uint_fast32_t should be at least 32 bit if I understand it correctly, so if 64bit shouldn't it use that instead? I don't see why this explains that int is faster than uint_fast32_t. Also I don't see why the for-loop performance differs so much with different integer types. –  Tim May 16 '12 at 14:32
1  
Well, since uint_fast32_t should be the fastest integer type with at least 32 bits, the implementation should be smart enough to use a 64bit type if that is faster on a 64 bit system. But otherwise good answer, of course. –  Christian Rau May 16 '12 at 14:47
    
I ran some more tests and the bottom line is that casting is just expensive. I was surprised it was that expensive though. –  Tim May 17 '12 at 16:15
    
the other difference between uint_fast32_t and int is signedness, I can't think of any intrinsic reason why that should matter but we're talking about how hard the compiler writer and chip designer have thought about making specific rare sequences go fast. –  jthill May 17 '12 at 16:29
1  
one thing you can do is maintain parallel loop counters, double di = 0; for ( int i=0 ; i < thismaxval ; ++i,++di ). –  jthill May 17 '12 at 16:37

On x86, the conversion of uint64_t to floating point is slower because there are only instructions to convert int64_t, int32_t and int16_t. int16_t and in 32-bit mode int64_t can only be converted using x87 instructions, not SSE.

When converting uint64_t to floating point, GCC 4.2.1 first converts the value as if it were an int64_t and then adds 264 if it was negative to compensate. (When using the x87, on Windows and *BSD or if you changed the precision control, beware that the conversion ignores precision control but the addition respects it.)

An uint32_t is first extended to int64_t.

When converting 64-bit integers in 32-bit mode on processors with certain 64-bit capabilities, a store-to-load forwarding issue may cause stalls. The 64-bit integer is written as two 32-bit values and read back as one 64-bit value. This can be very bad if the conversion is part of a long dependency chain (not in this case).

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