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In order to get the actual performance of a modern computer relatively to cache misses (how 'spread' is the data in memory), I conducted a simple test where I allocate 500 MB of RAM, and then perform a constant number of reads, and I perform that test with increasing byte offsets. Finally, I wrap over the end of the 1000 MB buffer when I reach it.

I'm quite surprised by the results. It looks like there is a cost barrier around 32 bytes, and another one around 32 KB. I guess this has something to do with L1/L2/L3 cache loads, or virtual memory page size? What stunned me the most is that there seems to be only about 16 completely different memory locations that are being cached. That's very low!!! Any explanations (OS, hardware)?

Here are the results on 3 different computers, from the fastest one to the cheapest one, followed by my simple test code (uses only standard libs).

16 GB RAM fast HP workstation (test in 32 bits Windows):

time=0.364000 byteIncrement=4 numReadLocations=262144000 numReads=262144000
time=0.231000 byteIncrement=8 numReadLocations=131072000 numReads=262144000
time=0.339000 byteIncrement=16 numReadLocations=65536000 numReads=262144000
time=0.567000 byteIncrement=32 numReadLocations=32768000 numReads=262144000
time=1.177000 byteIncrement=64 numReadLocations=16384000 numReads=262144000
time=1.806000 byteIncrement=128 numReadLocations=8192000 numReads=262144000
time=2.293000 byteIncrement=256 numReadLocations=4096000 numReads=262144000
time=2.464000 byteIncrement=512 numReadLocations=2048000 numReads=262144000
time=2.621000 byteIncrement=1024 numReadLocations=1024000 numReads=262144000
time=2.775000 byteIncrement=2048 numReadLocations=512000 numReads=262144000
time=2.908000 byteIncrement=4096 numReadLocations=256000 numReads=262144000
time=3.007000 byteIncrement=8192 numReadLocations=128000 numReads=262144000
time=3.183000 byteIncrement=16384 numReadLocations=64000 numReads=262144000
time=3.758000 byteIncrement=32768 numReadLocations=32000 numReads=262144000
time=4.287000 byteIncrement=65536 numReadLocations=16000 numReads=262144000
time=6.366000 byteIncrement=131072 numReadLocations=8000 numReads=262144000
time=6.124000 byteIncrement=262144 numReadLocations=4000 numReads=262144000
time=5.295000 byteIncrement=524288 numReadLocations=2000 numReads=262144000
time=5.540000 byteIncrement=1048576 numReadLocations=1000 numReads=262144000
time=5.844000 byteIncrement=2097152 numReadLocations=500 numReads=262144000
time=5.785000 byteIncrement=4194304 numReadLocations=250 numReads=262144000
time=5.714000 byteIncrement=8388608 numReadLocations=125 numReads=262144000
time=5.825000 byteIncrement=16777216 numReadLocations=62 numReads=262144000
time=5.759000 byteIncrement=33554432 numReadLocations=31 numReads=262144000
time=2.222000 byteIncrement=67108864 numReadLocations=15 numReads=262144000
time=0.471000 byteIncrement=134217728 numReadLocations=7 numReads=262144000
time=0.377000 byteIncrement=268435456 numReadLocations=3 numReads=262144000
time=0.166000 byteIncrement=536870912 numReadLocations=1 numReads=262144000

4 GB RAM MacBookPro 2010 (test in 32 bits Windows):

time=0.476000 byteIncrement=4 numReadLocations=262144000 numReads=262144000
time=0.357000 byteIncrement=8 numReadLocations=131072000 numReads=262144000
time=0.634000 byteIncrement=16 numReadLocations=65536000 numReads=262144000
time=1.173000 byteIncrement=32 numReadLocations=32768000 numReads=262144000
time=2.360000 byteIncrement=64 numReadLocations=16384000 numReads=262144000
time=3.469000 byteIncrement=128 numReadLocations=8192000 numReads=262144000
time=3.990000 byteIncrement=256 numReadLocations=4096000 numReads=262144000
time=3.549000 byteIncrement=512 numReadLocations=2048000 numReads=262144000
time=3.758000 byteIncrement=1024 numReadLocations=1024000 numReads=262144000
time=3.867000 byteIncrement=2048 numReadLocations=512000 numReads=262144000
time=4.275000 byteIncrement=4096 numReadLocations=256000 numReads=262144000
time=4.310000 byteIncrement=8192 numReadLocations=128000 numReads=262144000
time=4.584000 byteIncrement=16384 numReadLocations=64000 numReads=262144000
time=5.144000 byteIncrement=32768 numReadLocations=32000 numReads=262144000
time=6.100000 byteIncrement=65536 numReadLocations=16000 numReads=262144000
time=8.111000 byteIncrement=131072 numReadLocations=8000 numReads=262144000
time=6.256000 byteIncrement=262144 numReadLocations=4000 numReads=262144000
time=6.311000 byteIncrement=524288 numReadLocations=2000 numReads=262144000
time=6.416000 byteIncrement=1048576 numReadLocations=1000 numReads=262144000
time=6.635000 byteIncrement=2097152 numReadLocations=500 numReads=262144000
time=6.530000 byteIncrement=4194304 numReadLocations=250 numReads=262144000
time=6.544000 byteIncrement=8388608 numReadLocations=125 numReads=262144000
time=6.545000 byteIncrement=16777216 numReadLocations=62 numReads=262144000
time=5.272000 byteIncrement=33554432 numReadLocations=31 numReads=262144000
time=1.524000 byteIncrement=67108864 numReadLocations=15 numReads=262144000
time=0.538000 byteIncrement=134217728 numReadLocations=7 numReads=262144000
time=0.508000 byteIncrement=268435456 numReadLocations=3 numReads=262144000
time=0.817000 byteIncrement=536870912 numReadLocations=1 numReads=262144000

4GB RAM cheap Acer "family computer":

time=0.732000 byteIncrement=4 numReadLocations=262144000 numReads=262144000
time=0.549000 byteIncrement=8 numReadLocations=131072000 numReads=262144000
time=0.765000 byteIncrement=16 numReadLocations=65536000 numReads=262144000
time=1.196000 byteIncrement=32 numReadLocations=32768000 numReads=262144000
time=2.318000 byteIncrement=64 numReadLocations=16384000 numReads=262144000
time=2.483000 byteIncrement=128 numReadLocations=8192000 numReads=262144000
time=2.760000 byteIncrement=256 numReadLocations=4096000 numReads=262144000
time=3.194000 byteIncrement=512 numReadLocations=2048000 numReads=262144000
time=3.369000 byteIncrement=1024 numReadLocations=1024000 numReads=262144000
time=3.720000 byteIncrement=2048 numReadLocations=512000 numReads=262144000
time=4.842000 byteIncrement=4096 numReadLocations=256000 numReads=262144000
time=5.797000 byteIncrement=8192 numReadLocations=128000 numReads=262144000
time=9.865000 byteIncrement=16384 numReadLocations=64000 numReads=262144000
time=19.273000 byteIncrement=32768 numReadLocations=32000 numReads=262144000
time=19.282000 byteIncrement=65536 numReadLocations=16000 numReads=262144000
time=19.606000 byteIncrement=131072 numReadLocations=8000 numReads=262144000
time=20.242000 byteIncrement=262144 numReadLocations=4000 numReads=262144000
time=20.956000 byteIncrement=524288 numReadLocations=2000 numReads=262144000
time=22.627000 byteIncrement=1048576 numReadLocations=1000 numReads=262144000
time=24.336000 byteIncrement=2097152 numReadLocations=500 numReads=262144000
time=24.403000 byteIncrement=4194304 numReadLocations=250 numReads=262144000
time=23.060000 byteIncrement=8388608 numReadLocations=125 numReads=262144000
time=20.553000 byteIncrement=16777216 numReadLocations=62 numReads=262144000
time=14.460000 byteIncrement=33554432 numReadLocations=31 numReads=262144000
time=1.752000 byteIncrement=67108864 numReadLocations=15 numReads=262144000
time=0.963000 byteIncrement=134217728 numReadLocations=7 numReads=262144000
time=0.687000 byteIncrement=268435456 numReadLocations=3 numReads=262144000
time=0.453000 byteIncrement=536870912 numReadLocations=1 numReads=262144000

Code:

#include <stdio.h>
#include <stdlib.h>
#include <time.h>

#define MEMBLOCSIZE ((2<<20)*500)//1000MB

int readMemory( int* data, int* dataEnd, int numReads, int incrementPerRead ) {
  int accum = 0;
  int* ptr = data;

  while(true) {
    accum += *ptr;
    if( numReads-- == 0)
      return accum;

    ptr += incrementPerRead;

    if( ptr >= dataEnd )
      ptr = data;
  }
}

int main()
{
  int* data = (int*)malloc(MEMBLOCSIZE);
  int* dataEnd = data+(MEMBLOCSIZE / sizeof(int));

  int numReads = (MEMBLOCSIZE / sizeof(int));
  int dummyTotal = 0;
  int increment = 1;
  for( int loop = 0; loop < 28; ++loop ) {
    int startTime = clock();

    dummyTotal += readMemory(data, dataEnd, numReads, increment);

    int endTime = clock();
    double deltaTime = double(endTime-startTime)/double(CLOCKS_PER_SEC);

    printf("time=%f byteIncrement=%d numReadLocations=%d numReads=%d\n",
      deltaTime, increment*sizeof(int), MEMBLOCSIZE/(increment*sizeof(int)), numReads);

    increment *= 2;
  }
  //Use dummyTotal: make sure the optimizer is not removing my code...
  return dummyTotal == 666 ? 1: 0;
}

Based on some comments I modified my test to use only 250 MB of RAM, and to do 16 consecutive reads for each 'read' in case it activates the prefetching. It still has similar results, however it is the case that the last tests, the ones reading few distant locations, have a better performance (2 seconds instead of 5), so it is probably because prefetching was not activated with the initial test.

#define MEMBLOCSIZE 262144000//250MB

int readMemory( int* data, int* dataEnd, int numReads, int incrementPerRead ) {
  int accum = 0;
  int* ptr = data;

  while(true) {
    accum += *ptr;
    if( numReads-- == 0)
      return accum;

    //Do 16 consecutive reads
    for( int i = 1; i < 17; ++i )
      accum += *(ptr+i);

    ptr += incrementPerRead;

    if( ptr >= dataEnd+17 )
      ptr = data;
  }
}

Results for this updated test for MacBookPro 2010:

time=0.691000 byteIncrement=4 numReadLocations=65536000 numReads=65536000
time=0.620000 byteIncrement=8 numReadLocations=32768000 numReads=65536000
time=0.715000 byteIncrement=16 numReadLocations=16384000 numReads=65536000
time=0.827000 byteIncrement=32 numReadLocations=8192000 numReads=65536000
time=0.917000 byteIncrement=64 numReadLocations=4096000 numReads=65536000
time=1.440000 byteIncrement=128 numReadLocations=2048000 numReads=65536000
time=2.646000 byteIncrement=256 numReadLocations=1024000 numReads=65536000
time=3.720000 byteIncrement=512 numReadLocations=512000 numReads=65536000
time=3.854000 byteIncrement=1024 numReadLocations=256000 numReads=65536000
time=4.673000 byteIncrement=2048 numReadLocations=128000 numReads=65536000
time=4.729000 byteIncrement=4096 numReadLocations=64000 numReads=65536000
time=4.784000 byteIncrement=8192 numReadLocations=32000 numReads=65536000
time=5.021000 byteIncrement=16384 numReadLocations=16000 numReads=65536000
time=5.022000 byteIncrement=32768 numReadLocations=8000 numReads=65536000
time=4.871000 byteIncrement=65536 numReadLocations=4000 numReads=65536000
time=5.163000 byteIncrement=131072 numReadLocations=2000 numReads=65536000
time=5.276000 byteIncrement=262144 numReadLocations=1000 numReads=65536000
time=4.699000 byteIncrement=524288 numReadLocations=500 numReads=65536000
time=1.997000 byteIncrement=1048576 numReadLocations=250 numReads=65536000
time=2.118000 byteIncrement=2097152 numReadLocations=125 numReads=65536000
time=2.071000 byteIncrement=4194304 numReadLocations=62 numReads=65536000
time=2.036000 byteIncrement=8388608 numReadLocations=31 numReads=65536000
time=1.923000 byteIncrement=16777216 numReadLocations=15 numReads=65536000
time=1.084000 byteIncrement=33554432 numReadLocations=7 numReads=65536000
time=0.607000 byteIncrement=67108864 numReadLocations=3 numReads=65536000
time=0.622000 byteIncrement=134217728 numReadLocations=1 numReads=65536000
share|improve this question
3  
You are forgetting things like prefetching. Additionally there are different kinds of implementations of caches (e.g. associativity) that varies from CPU to CPU which plays a big role in things like which cache entries kicks out which older one. –  PlasmaHH Nov 2 '12 at 10:40
3  
What is the point of testing 16GB RAM on Windows 32-bit. Most of it won't be addressable anyway. –  Anirudh Ramanathan Nov 2 '12 at 11:07
1  
@Cthulhu: Funny you should say that, I've been using the same for years. There exist ramdisks (such as superspeed) which will use the non-addressable memory and among others allow you to put your swap file on the ramdisk. Windows will of course still only see 3.25 GiB, but swapping now works at the speed of memcpy rather than SATA (and with 0ms seek). Which means that other than normally, the computer is perfectly usable while running on "virtual memory". If you are stranded with XP for some reason (which does not have working 64 bit support), this is the best option that you have. –  Damon Nov 2 '12 at 11:14
    
I don't think it matters, but #define MEMBLOCSIZE ((2<<20)*500)//500MB the comment is wrong, it's actually 1000MB. –  Daniel Fischer Nov 2 '12 at 11:18
1  
@Cthulhu About the 16GB: that was just to give machine specs to show there was enough RAM for the test. I know 32 bits is not using all that. –  Jerome CG Nov 2 '12 at 11:27

1 Answer 1

Note that most of the below, as any conclusions you drew, is speculative. Memory benchmarking is ultra complex, and a relatively naive benchmarking in a way like you have done it rarely gives a lot of definite information about the performance of a real program.

The primary "cost barrier" as you name it at 32 kiB is probably more at 64kiB (or a combination of both). Since you do not initialize the memory, Windows will pull in zero pages as you read them. The allocation granularity is 64 kiB, and pages are always "readied" (and prefetched if you memory map) in that size, even if only one of the pages in the 64 kiB range is moved into your working set. This is something I found out experimenting with memory mapping.

Your process working set as set by Windows is ridiculously small by default, therefore as you iterate over that memory block, you will constantly have page faults. Some are less expensive, only changing a flag in the page descriptor, others (at 64 kiB) are more expensive, pulling 16 new pages from the zero pool (or, in the worst case, if the pool is empty, zeroing pages). This may very well explain one of the "cost barriers" you see.

Another cost barrier is, as you correctly noticed, cache associativity. Different addresses at larger power-of-two offsets use the same cache entries. Given "unhealthy" offsets, one can cause the same cache lines being evicted over and over again. This is one of the two primary reasons why alignment is good, but excessive over-alignment is bad (the other one being no locality of data).

The cost barrier at 32 bytes is surprising, if anything, one could imagine it being at 64 bytes (crossing cache lines on your test architecture). Prefetching should for the most part eliminate this kind of stall, but prefetching is usually only activated (if you do not explicitly hint it) after the second cache line miss with a given stride.

This is perfectly acceptable for "real" programs, which either read just one location and another, or iterate over bulks of data sequentially. It may, on the other hand, easily give confusing results when doing artificial measurements. It may also be a possible explanation why you see a cost barrier at 32 kiB. If prefetching doesn't work, then that would be the point where you run out of L1 cache on a typical x86.

share|improve this answer
    
I understand that moving pages to my working set have an initial cost. However all these pages have been read already in the very first loop iteration, so I would expect that to not be a factor for the subsequent loops... Now, it's quite possible that the barriers are around 64 and 64K (instead of 32); a 32 bytes offset crosses the 64 bytes barrier at every 2 reads; it's normal that the performance degradation is not steep since the 'barrier crossing' frequencies are increasing at each step. –  Jerome CG Nov 2 '12 at 11:41
    
I modified the test to read only 250MB, and to do 16 reads of consecutive ints for each 'single reads' in case the prefetching has some heuristics on the number of reads before it activates. I still get similar results however. Oh, and thanks for your detailed answer :-) –  Jerome CG Nov 2 '12 at 11:54
    
Just updated the question to add this new test. Seems that doing 16 contiguous reads for each 'read' operation does have an influence since the test with few distanced read locations take half the time. However it still seems to be the case that not many distanced locations seem to be loaded in the fastest cache, which still surprises me. –  Jerome CG Nov 2 '12 at 12:13
    
@JeromeCG: Moving pages to your working set is a constant (or rather, recurring) cost, not an initial one. The default maximum WS is 345 pages, or 1380 kiB, respectively. That is a ridiculously small number. Which means if you are reading (and re-reading) dozens or hundreds of megabytes worth of data, you get page faults all the time, not just initially. Those are normally of the "cheap" kind, though, unless the machine is really, really low on physical RAM (not the case for you). –  Damon Nov 2 '12 at 14:02
    
I see, that would explain some of the costs then. I still find it surpriging that in my 2nd test, when I read series of 68 bytes at 31 different locations, and the read locations are not moving at all, the performance is still not optimal compared to when we read at a single memory location. I would expect that for these 31X68 bytes all that data fits in the L1 cache and have optimal speed, just as fast as if all the reads were at a single location... –  Jerome CG Nov 2 '12 at 14:50

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