Below are two programs that are almost identical except that I switched the i and j variables around. They both run in different amounts of time. Could someone explain why this happens?

Version 1

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

main () {
  int i,j;
  static int x[4000][4000];
  for (i = 0; i < 4000; i++) {
    for (j = 0; j < 4000; j++) {
      x[j][i] = i + j; }

Version 2

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

main () {
  int i,j;
  static int x[4000][4000];
  for (j = 0; j < 4000; j++) {
     for (i = 0; i < 4000; i++) {
       x[j][i] = i + j; }
  • 31
    en.wikipedia.org/wiki/… Mar 30, 2012 at 2:21
  • 9
    Can you add some benchmark results?
    – naught101
    Mar 30, 2012 at 3:25
  • 3
  • 14
    @naught101 The benchmarks will show a performance difference of anywhere between 3 to 10 times. This is basic C/C++, I'm completely stumped as to how this got so many votes...
    – TC1
    Mar 30, 2012 at 9:12
  • 16
    @TC1: I don't think it's that basic; maybe intermediate. But it should be no surprise that the "basic" stuff tends to be useful to more people, hence the many upvotes. Moreover, this is a question that's hard to google, even if it is "basic".
    – LarsH
    Mar 30, 2012 at 18:50

7 Answers 7


As others have said, the issue is the store to the memory location in the array: x[i][j]. Here's a bit of insight why:

You have a 2-dimensional array, but memory in the computer is inherently 1-dimensional. So while you imagine your array like this:

0,0 | 0,1 | 0,2 | 0,3
1,0 | 1,1 | 1,2 | 1,3
2,0 | 2,1 | 2,2 | 2,3

Your computer stores it in memory as a single line:

0,0 | 0,1 | 0,2 | 0,3 | 1,0 | 1,1 | 1,2 | 1,3 | 2,0 | 2,1 | 2,2 | 2,3

In the 2nd example, you access the array by looping over the 2nd number first, i.e.:

                                x[1][0] etc...

Meaning that you're hitting them all in order. Now look at the 1st version. You're doing:

                                        x[1][1] etc...

Because of the way C laid out the 2-d array in memory, you're asking it to jump all over the place. But now for the kicker: Why does this matter? All memory accesses are the same, right?

No: because of caches. Data from your memory gets brought over to the CPU in little chunks (called 'cache lines'), typically 64 bytes. If you have 4-byte integers, that means you're geting 16 consecutive integers in a neat little bundle. It's actually fairly slow to fetch these chunks of memory; your CPU can do a lot of work in the time it takes for a single cache line to load.

Now look back at the order of accesses: The second example is (1) grabbing a chunk of 16 ints, (2) modifying all of them, (3) repeat 4000*4000/16 times. That's nice and fast, and the CPU always has something to work on.

The first example is (1) grab a chunk of 16 ints, (2) modify only one of them, (3) repeat 4000*4000 times. That's going to require 16 times the number of "fetches" from memory. Your CPU will actually have to spend time sitting around waiting for that memory to show up, and while it's sitting around you're wasting valuable time.

Important Note:

Now that you have the answer, here's an interesting note: there's no inherent reason that your second example has to be the fast one. For instance, in Fortran, the first example would be fast and the second one slow. That's because instead of expanding things out into conceptual "rows" like C does, Fortran expands into "columns", i.e.:

0,0 | 1,0 | 2,0 | 0,1 | 1,1 | 2,1 | 0,2 | 1,2 | 2,2 | 0,3 | 1,3 | 2,3

The layout of C is called 'row-major' and Fortran's is called 'column-major'. As you can see, it's very important to know whether your programming language is row-major or column-major! Here's a link for more info: http://en.wikipedia.org/wiki/Row-major_order

  • 8
    You have the "first" and "second" versions around the wrong way; the first example varies the first index in the inner loop, and will be the slower executing example.
    – caf
    Mar 30, 2012 at 5:39
  • 1
    Great answer. If Mark wants read more about such nitty gritty, I'd recommend a book like Write Great Code.
    – wkl
    Mar 30, 2012 at 13:59
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    Bonus points for pointing out that C changed the row order from Fortran. For scientific computing L2 cache size is everything because if all your arrays fit into L2 then computation can be completed without going to main memory. Mar 30, 2012 at 15:26
  • 4
    @birryree: The freely-available What Every Programmer Should Know About Memory is also a good read.
    – caf
    Mar 30, 2012 at 22:38
  • Great answer but I actually imagine array as 0,0 1,0 2,0.. Why wouls you say 0,0 1,0 2,0 ? Oct 14, 2013 at 19:07

Nothing to do with assembly. This is due to cache misses.

C multidimensional arrays are stored with the last dimension as the fastest. So the first version will miss the cache on every iteration, whereas the second version won't. So the second version should be substantially faster.

See also: http://en.wikipedia.org/wiki/Loop_interchange.


Version 2 will run much faster because it uses your computer's cache better than version 1. If you think about it, arrays are just contiguous areas of memory. When you request an element in an array, your OS will probably bring in a memory page into cache that contains that element. However, since the next few elements are also on that page (because they are contiguous), the next access will already be in cache! This is what version 2 is doing to get it's speed up.

Version 1, on the other hand, is accessing elements column wise, and not row wise. This sort of access is not contiguous at the memory level, so the program cannot take advantage of the OS caching as much.

  • With these array sizes, probably the cache manager in the CPU rather than in the OS is responsible here.
    – krlmlr
    Mar 30, 2012 at 8:59

The reason is cache-local data access. In the second program you're scanning linearly through memory which benefits from caching and prefetching. Your first program's memory usage pattern is far more spread out and therefore has worse cache behavior.


Besides the other excellent answers on cache hits, there is also a possible optimization difference. Your second loop is likely to be optimized by the compiler into something equivalent to:

for (j=0; j<4000; j++) {
  int *p = x[j];
  for (i=0; i<4000; i++) {
    *p++ = i+j;

This is less likely for the first loop, because it would need to increment the pointer "p" with 4000 each time.

EDIT: p++ and even *p++ = .. can be compiled to a single CPU instruction in most CPU's. *p = ..; p += 4000 cannot, so there is less benefit in optimising it. It's also more difficult, because the compiler needs to know and use the size of the inner array. And it does not occur that often in the inner loop in normal code (it occurs only for multidimensional arrays, where the last index is kept constant in the loop, and the second to last one is stepped), so optimisation is less of a priority.

  • I don't get what 'because it would need to jump the pointer "p" with 4000 each time' means.
    – Veedrac
    Mar 6, 2016 at 20:57
  • @Veedrac The pointer would need to be incremented with 4000 inside the inner loop: p += 4000 i.s.o. p++
    – fishinear
    Mar 7, 2016 at 8:46
  • Why would the compiler find that a problem? i is already incremented by a non-unit value, given it's a pointer increment.
    – Veedrac
    Mar 7, 2016 at 11:16
  • I've added more explanation
    – fishinear
    Mar 7, 2016 at 14:55
  • Try typing int *f(int *p) { *p++ = 10; return p; } int *g(int *p) { *p = 10; p += 4000; return p; } into gcc.godbolt.org. The two seem to compile basically the same.
    – Veedrac
    Mar 7, 2016 at 17:13

This line the culprit :


The second version uses continuous memory thus will be substantially faster.

I tried with


and the time of execution is 13s for version1 versus 0.6s for version2.


I try to give a generic answer.

Because i[y][x] is a shorthand for *(i + y*array_width + x) in C (try out the classy int P[3]; 0[P] = 0xBEEF;).

As you iterate over y, you iterate over chunks of size array_width * sizeof(array_element). If you have that in your inner loop, then you will have array_width * array_height iterations over those chunks.

By flipping the order, you will have only array_height chunk-iterations, and between any chunk-iteration, you will have array_width iterations of only sizeof(array_element).

While on really old x86-CPUs this did not matter much, nowadays' x86 do a lot of prefetching and caching of data. You probably produce many cache misses in your slower iteration-order.

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