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Consider the following code

 vector<double> v;
 // fill v
 const vector<double>::iterator end =v.end();
 for(vector<double>::iterator i = v.bgin(); i != end; ++i) {
   // do stuff

Are compilers like g++, clang++, icc able to unroll loops like this. Unfortunately I do not know assembly to be able verify from the output whether the loop gets unrolled or not. (and I only have access to g++.)

To me it seems that this will require more smartness than usual on behalf of the compiler, first to deduce that the iterator is a random access iterator, and then figure out the number of times the loop is executed. Can compilers do this when optimization is enabled ?

Thanks for your replies, and before some of you start lecturing about premature optimization, this is an excercise in curiosity.

share|improve this question
I'm going to guess that there is no unrolling to be done since the size cannot be predicted. –  user195488 Jul 17 '12 at 18:57
+1 for preemtive protection against accusations of premature optimization :-) –  Aasmund Eldhuset Jul 17 '12 at 18:57
It's definitely possible to unroll without knowing the trip count. It just takes a bit of clean-up code... I've done it many times before. –  Mysticial Jul 17 '12 at 18:58
@san You define it as const, not as a constant. Its value is determined at runtime, not at compile-time, so constness cannot be used to optimize/unroll the loop. –  Jonathan Grynspan Jul 17 '12 at 19:07
MSVC did not unroll this loop in any of my tests (full optimization level, favor speed and fp:fast) –  harold Jul 17 '12 at 19:18

4 Answers 4

up vote 3 down vote accepted

To me it seems that this will require more smartness than usual on behalf of the compiler, first to deduce that the iterator is a random access iterator, and then figure out the number of times the loop is executed.

The STL, being comprised entirely of templates, has all the code inline. So, random access iterators reduce to pointers already when the compiler begins to apply optimizations. One of the reasons the STL was created was so that there would be less need for a programmer to outwit the compiler. You should rely on the STL to do the right thing until proven otherwise.

Of course, it is still up to you to choose the proper tool from the STL to use...

Edit: There was discussion about whether g++ does any loop unrolling. On the versions that I am using, loop unrolling is not part of -O, -O2, or -O3, and I get identical assembly for the latter two levels with the following code:

void foo (std::vector<int> &v) {
    volatile int c = 0;
    const std::vector<int>::const_iterator end = v.end();
    for (std::vector<int>::iterator i = v.begin(); i != end; ++i) {
        *i = c++;

With the corresponding assembly -O2 assembly:

        movq    8(%rdi), %rcx
        movq    (%rdi), %rax
        movl    $0, -4(%rsp)
        cmpq    %rax, %rcx
        je      .L4
        .p2align 4,,10
        .p2align 3
        movl    -4(%rsp), %edx
        movl    %edx, (%rax)
        addq    $4, %rax
        addl    $1, %edx
        cmpq    %rax, %rcx
        movl    %edx, -4(%rsp)
        jne     .L3

With the -funroll-loops option added, the function expands into something much much larger. But, the documentation warns about this option:

Unroll loops whose number of iterations can be determined at compile time or upon entry to the loop. -funroll-loops implies -frerun-cse-after-loop. It also turns on complete loop peeling (i.e. complete removal of loops with small constant number of iterations). This option makes code larger, and may or may not make it run faster.

As a further argument to dissuade you from unrolling loops yourself, I'll finish this answer with an illustration of applying Duff's Device to the foo function above:

void foo_duff (std::vector<int> &v) {
    volatile int c = 0;
    const std::vector<int>::const_iterator end = v.end();
    std::vector<int>::iterator i = v.begin();
    switch ((end - i) % 4) do {
    case 0: *i++ = c++;
    case 3: *i++ = c++;
    case 2: *i++ = c++;
    case 1: *i++ = c++;
    } while (i != end);

GCC has another loop optimization flag:

Perform loop optimizations on trees. This flag is enabled by default at -O and higher.

This option enables simple loop optimizations for the innermost loops, include complete loop unrolling (peeling) for loops with a fixed number of iterations. (Thanks to doc for pointing this out to me.)

share|improve this answer
Thanks for the detailed reply. One question: should the const_iterator be a const iterator ? Doesnt the former mean that the dereferenced object is constant, but the iterator is not ? –  san Jul 17 '12 at 20:47
@san: I used const_iterator to show I did not intend to use end to modify anything. You could also make end const to indicate the variable itself will not change. But I think the compiler can infer that from the fact it is local, and not being used in the loop. –  jxh Jul 17 '12 at 20:55
Right, I thought that the compiler figures it out the other way around from the fact that end is not supposed to be dereferenced. But I guess one could use some nasty tricks by dereferencing beyond the container, so the compiler cannot disallow it. –  san Jul 17 '12 at 21:00
@san: No, I think you are right, the compiler can figure it out, so long as the local iterator is not passed to some other function by reference. But, I added the other const, just for you. –  jxh Jul 17 '12 at 21:14
Aha. If I change my test code to copy from the volatile to *i, instead of the other way around, at least apple-gcc-4.2 actually does unroll the loop. Strange that would make a difference, but… that's a good illustration of the fact that it's harder to prove a negative ("the compiler can't do X because I can't come up with an example that makes it do X" doesn't work) than a positive ("the compiler can do X because I came up with an example that makes it do X"). :) –  abarnert Jul 17 '12 at 22:45

I would propose that whether or not the compiler CAN unroll the loop, with modern pipelined architectures and caches, unless your "do stuff" is trivial, there is little benefit in doing so, and in many cases doing so would be a performance HIT instead of a boon. If your "do stuff" is nontrivial, unrolling the loop will create multiple copies of this nontrivial code, which will take extra time to load into the cache, significantly slowing down the first iteration through the unrolled loop. At the same time, it will evict more code from the cache, which may have been necessary for performing the "do stuff" if it makes any function calls, which would then need to be reloaded into the cache again. The purpose for unrolling loops made a lot of sense before cacheless pipelined non-branch-predictive architectures, with the goal being to reduce the overhead associated with the loop logic. Nowadays with cache-based pipelined branch-predictive hardware, your cpu will be pipelined well into the next loop iteration, speculatively executing the loop code again, by the time you detect the i==end exit condition, at which point the processor will throw out that final speculatively-executed set of results. In such an architecture, loop unrolling makes very little sense. It would further bloat code for virtually no benefit.

share|improve this answer
upvoted for the excellent point ! –  san Jul 17 '12 at 19:50
+1, because this is a good explanation for why it usually won't unroll the loop, even if it can. But the OP is asking whether, if it were ever worth doing, the compiler would be able to do so, and I'm not sure how to completely answer that without actually dreaming up a case where it would be worth doing… –  abarnert Jul 17 '12 at 19:55
@abarnert I think that coying to a volatile does qualify as'trivial' and hence a great test case. Cannot think of anything shorter that wont get optimized away completely –  san Jul 17 '12 at 19:59
@san: Actually, it looks like copying from a volatile is a better test case, given user315052's answer. And maybe putting inline asm inside the loop would be even more trivial? Oh well, we've got the answer proven, so no more effort seems needed. –  abarnert Jul 17 '12 at 22:43
@abarnert It also could be that the deciding factor there was the compiler, 'cause number of instructions wise they should be quite equivalent. –  san Jul 17 '12 at 22:55

The short answer is yes. It will unroll as much as it can. In your case, it depends how you define end obviously (I assume your example is generic). Not only will most modern compilers unroll, but they will also vectorize and do other optimizations that will often blow your own solutions out of the water.

So what I'm saying is don't prematurely optimize! Just kidding :)

share|improve this answer
I define end as a constant iterator outside of the loop. –  san Jul 17 '12 at 19:04
It won't unroll as much as it can; it'll unroll as much as it thinks is worth unrolling. And in many cases, that will be not at all. –  abarnert Jul 17 '12 at 19:53
I don't think compiler is able to unroll iterator based loop as it can do with counted loops. v.end() is not a constexpr, so how compiler can know where loop ends at compile time? Maybe with some mad tracing of pointers it could optimize local object, but it's totally impossible when v would be a function argument. –  doc Nov 30 '14 at 3:06

Simple answer: generally NO! At least when it comes to complete loop unrolling.

Let's test loop unrolling on this simple, dirty-coded (for testing purposes) structure.

struct Test
    Test(): begin(arr), end(arr + 4) {}

    double * begin;
    double * end;
    double arr[4];

First let's take counted loop and compile it without any optimizations.

double counted(double param, Test & d)
    for (int i = 0; i < 4; i++)
        param += d.arr[i];
    return param;

Here's what gcc 4.9 produces.

counted(double, Test&):
    pushq   %rbp
    movq    %rsp, %rbp
    movsd   %xmm0, -24(%rbp)
    movq    %rdi, -32(%rbp)
    movl    $0, -4(%rbp)
    jmp .L2
    movq    -32(%rbp), %rax
    movl    -4(%rbp), %edx
    movslq  %edx, %rdx
    addq    $2, %rdx
    movsd   (%rax,%rdx,8), %xmm0
    movsd   -24(%rbp), %xmm1
    addsd   %xmm0, %xmm1
    movq    %xmm1, %rax
    movq    %rax, -24(%rbp)
    addl    $1, -4(%rbp)
    cmpl    $3, -4(%rbp)
    jle .L3
    movq    -24(%rbp), %rax
    movq    %rax, -40(%rbp)
    movsd   -40(%rbp), %xmm0
    popq    %rbp

As expected loop hasn't been unrolled and, since no optimizations were performed, code is generally very verbose. Now let's turn on -O3 flag. Produced disassembly:

counted(double, Test&):
    addsd   16(%rdi), %xmm0
    addsd   24(%rdi), %xmm0
    addsd   32(%rdi), %xmm0
    addsd   40(%rdi), %xmm0

Voila, loop has been unrolled this time.

Now let's take a look at iterated loop. Function containing the loop will look like this.

double iterated(double param, Test & d)
  for (double * it = d.begin; it != d.end; ++it)
    param += *it;
  return param;

Still using -O3 flag, let's take a look at disassembly.

iterated(double, Test&):
    movq    (%rdi), %rax
    movq    8(%rdi), %rdx
    cmpq    %rdx, %rax
    je  .L3
    addsd   (%rax), %xmm0
    addq    $8, %rax
    cmpq    %rdx, %rax
    jne .L4
    rep ret

Code looks better than in the very first case, because optimizations were performed, but loop hasn't been unrolled this time!

What about funroll-loops and funroll-all-loops flags? They will produce result similar to this

iterated(double, Test&):
    movq    (%rdi), %rsi
    movq    8(%rdi), %rcx
    cmpq    %rcx, %rsi
    je  .L3
    movq    %rcx, %rdx
    leaq    8(%rsi), %rax
    addsd   (%rsi), %xmm0
    subq    %rsi, %rdx
    subq    $8, %rdx
    shrq    $3, %rdx
    andl    $7, %edx
    cmpq    %rcx, %rax
    je  .L43
    testq   %rdx, %rdx
    je  .L4
    cmpq    $1, %rdx
    je  .L29
    cmpq    $2, %rdx
    je  .L30
    cmpq    $3, %rdx
    je  .L31
    cmpq    $4, %rdx
    je  .L32
    cmpq    $5, %rdx
    je  .L33
    cmpq    $6, %rdx
    je  .L34
    addsd   (%rax), %xmm0
    leaq    16(%rsi), %rax
    addsd   (%rax), %xmm0
    addq    $8, %rax
    addsd   (%rax), %xmm0
    addq    $8, %rax
    addsd   (%rax), %xmm0
    addq    $8, %rax
    addsd   (%rax), %xmm0
    addq    $8, %rax
    addsd   (%rax), %xmm0
    addq    $8, %rax
    addsd   (%rax), %xmm0
    addq    $8, %rax
    cmpq    %rcx, %rax
    je  .L44
    addsd   (%rax), %xmm0
    addq    $64, %rax
    addsd   -56(%rax), %xmm0
    addsd   -48(%rax), %xmm0
    addsd   -40(%rax), %xmm0
    addsd   -32(%rax), %xmm0
    addsd   -24(%rax), %xmm0
    addsd   -16(%rax), %xmm0
    addsd   -8(%rax), %xmm0
    cmpq    %rcx, %rax
    jne .L4
    rep ret
    rep ret
    rep ret

Compare results with unrolled loop for counted loop. It's clearly not the same. What we see here is that gcc divided the loop into 8 element chunks. This can increase performance in some cases, because loop exit condition is checked once per 8 normal loop iterations. With additional flags vectorization could be also performed. But it isn't complete loop unrolling.

Iterated loop will be unrolled however if Test object is not a function argument.

double iteratedLocal(double param)
  Test d;
  for (double * it = d.begin; it != d.end; ++it)
    param += *it;
  return param;

Disassembly produced with only -O3 flag:

    addsd   -40(%rsp), %xmm0
    addsd   -32(%rsp), %xmm0
    addsd   -24(%rsp), %xmm0
    addsd   -16(%rsp), %xmm0

As you can see loop has been unrolled. This is because compiler can now safely assume that end has fixed value, while it couldn't predict that for function argument.

Test structure is statically allocated however. Things are more complicated with dynamically allocated structures like std::vector. From my observations on modified Test structure, so that it ressembles dynamically allocated container, it looks like gcc tries its best to unroll loops, but in most cases generated code is not as simple as one above.

As you ask for other compilers, here's output from clang 3.4.1 (-O3 flag)

counted(double, Test&):                      # @counted(double, Test&)
    addsd   16(%rdi), %xmm0
    addsd   24(%rdi), %xmm0
    addsd   32(%rdi), %xmm0
    addsd   40(%rdi), %xmm0

iterated(double, Test&):                     # @iterated(double, Test&)
    movq    (%rdi), %rax
    movq    8(%rdi), %rcx
    cmpq    %rcx, %rax
    je  .LBB1_2
.LBB1_1:                                # %.lr.ph
    addsd   (%rax), %xmm0
    addq    $8, %rax
    cmpq    %rax, %rcx
    jne .LBB1_1
.LBB1_2:                                # %._crit_edge

iteratedLocal(double):                     # @iteratedLocal(double)
    leaq    -32(%rsp), %rax
    movq    %rax, -48(%rsp)
    leaq    (%rsp), %rax
    movq    %rax, -40(%rsp)
    xorl    %eax, %eax
    jmp .LBB2_1
.LBB2_2:                                # %._crit_edge4
    movsd   -24(%rsp,%rax), %xmm1
    addq    $8, %rax
.LBB2_1:                                # =>This Inner Loop Header: Depth=1
    movaps  %xmm0, %xmm2
    cmpq    $24, %rax
    movaps  %xmm1, %xmm0
    addsd   %xmm2, %xmm0
    jne .LBB2_2

Intel's icc 13.01 (-O3 flag)

counted(double, Test&):
        addsd     16(%rdi), %xmm0                               #24.5
        addsd     24(%rdi), %xmm0                               #24.5
        addsd     32(%rdi), %xmm0                               #24.5
        addsd     40(%rdi), %xmm0                               #24.5
        ret                                                     #25.10
iterated(double, Test&):
        movq      (%rdi), %rdx                                  #30.26
        movq      8(%rdi), %rcx                                 #30.41
        cmpq      %rcx, %rdx                                    #30.41
        je        ..B3.25       # Prob 50%                      #30.41
        subq      %rdx, %rcx                                    #30.7
        movb      $0, %r8b                                      #30.7
        lea       7(%rcx), %rax                                 #30.7
        sarq      $2, %rax                                      #30.7
        shrq      $61, %rax                                     #30.7
        lea       7(%rax,%rcx), %rcx                            #30.7
        sarq      $3, %rcx                                      #30.7
        cmpq      $16, %rcx                                     #30.7
        jl        ..B3.26       # Prob 10%                      #30.7
        movq      %rdx, %rdi                                    #30.7
        andq      $15, %rdi                                     #30.7
        je        ..B3.6        # Prob 50%                      #30.7
        testq     $7, %rdi                                      #30.7
        jne       ..B3.26       # Prob 10%                      #30.7
        movl      $1, %edi                                      #30.7
..B3.6:                         # Preds ..B3.5 ..B3.3
        lea       16(%rdi), %rax                                #30.7
        cmpq      %rax, %rcx                                    #30.7
        jl        ..B3.26       # Prob 10%                      #30.7
        movq      %rcx, %rax                                    #30.7
        xorl      %esi, %esi                                    #30.7
        subq      %rdi, %rax                                    #30.7
        andq      $15, %rax                                     #30.7
        negq      %rax                                          #30.7
        addq      %rcx, %rax                                    #30.7
        testq     %rdi, %rdi                                    #30.7
        jbe       ..B3.11       # Prob 2%                       #30.7
..B3.9:                         # Preds ..B3.7 ..B3.9
        addsd     (%rdx,%rsi,8), %xmm0                          #31.9
        incq      %rsi                                          #30.7
        cmpq      %rdi, %rsi                                    #30.7
        jb        ..B3.9        # Prob 82%                      #30.7
..B3.11:                        # Preds ..B3.9 ..B3.7
        pxor      %xmm6, %xmm6                                  #28.12
        movaps    %xmm6, %xmm7                                  #28.12
        movaps    %xmm6, %xmm5                                  #28.12
        movsd     %xmm0, %xmm7                                  #28.12
        movaps    %xmm6, %xmm4                                  #28.12
        movaps    %xmm6, %xmm3                                  #28.12
        movaps    %xmm6, %xmm2                                  #28.12
        movaps    %xmm6, %xmm1                                  #28.12
        movaps    %xmm6, %xmm0                                  #28.12
..B3.12:                        # Preds ..B3.12 ..B3.11
        addpd     (%rdx,%rdi,8), %xmm7                          #31.9
        addpd     16(%rdx,%rdi,8), %xmm6                        #31.9
        addpd     32(%rdx,%rdi,8), %xmm5                        #31.9
        addpd     48(%rdx,%rdi,8), %xmm4                        #31.9
        addpd     64(%rdx,%rdi,8), %xmm3                        #31.9
        addpd     80(%rdx,%rdi,8), %xmm2                        #31.9
        addpd     96(%rdx,%rdi,8), %xmm1                        #31.9
        addpd     112(%rdx,%rdi,8), %xmm0                       #31.9
        addq      $16, %rdi                                     #30.7
        cmpq      %rax, %rdi                                    #30.7
        jb        ..B3.12       # Prob 82%                      #30.7
        addpd     %xmm6, %xmm7                                  #28.12
        addpd     %xmm4, %xmm5                                  #28.12
        addpd     %xmm2, %xmm3                                  #28.12
        addpd     %xmm0, %xmm1                                  #28.12
        addpd     %xmm5, %xmm7                                  #28.12
        addpd     %xmm1, %xmm3                                  #28.12
        addpd     %xmm3, %xmm7                                  #28.12
        movaps    %xmm7, %xmm0                                  #28.12
        unpckhpd  %xmm7, %xmm0                                  #28.12
        addsd     %xmm0, %xmm7                                  #28.12
        movaps    %xmm7, %xmm0                                  #28.12
..B3.14:                        # Preds ..B3.13 ..B3.26
        lea       1(%rax), %rsi                                 #30.7
        cmpq      %rsi, %rcx                                    #30.7
        jb        ..B3.25       # Prob 50%                      #30.7
        subq      %rax, %rcx                                    #30.7
        cmpb      $1, %r8b                                      #30.7
        jne       ..B3.17       # Prob 50%                      #30.7
..B3.16:                        # Preds ..B3.17 ..B3.15
        xorl      %r8d, %r8d                                    #30.7
        jmp       ..B3.21       # Prob 100%                     #30.7
..B3.17:                        # Preds ..B3.15
        cmpq      $2, %rcx                                      #30.7
        jl        ..B3.16       # Prob 10%                      #30.7
        movq      %rcx, %r8                                     #30.7
        xorl      %edi, %edi                                    #30.7
        pxor      %xmm1, %xmm1                                  #28.12
        lea       (%rdx,%rax,8), %rsi                           #31.19
        andq      $-2, %r8                                      #30.7
        movsd     %xmm0, %xmm1                                  #28.12
..B3.19:                        # Preds ..B3.19 ..B3.18
        addpd     (%rsi,%rdi,8), %xmm1                          #31.9
        addq      $2, %rdi                                      #30.7
        cmpq      %r8, %rdi                                     #30.7
        jb        ..B3.19       # Prob 82%                      #30.7
        movaps    %xmm1, %xmm0                                  #28.12
        unpckhpd  %xmm1, %xmm0                                  #28.12
        addsd     %xmm0, %xmm1                                  #28.12
        movaps    %xmm1, %xmm0                                  #28.12
..B3.21:                        # Preds ..B3.20 ..B3.16
        cmpq      %rcx, %r8                                     #30.7
        jae       ..B3.25       # Prob 2%                       #30.7
        lea       (%rdx,%rax,8), %rax                           #31.19
..B3.23:                        # Preds ..B3.23 ..B3.22
        addsd     (%rax,%r8,8), %xmm0                           #31.9
        incq      %r8                                           #30.7
        cmpq      %rcx, %r8                                     #30.7
        jb        ..B3.23       # Prob 82%                      #30.7
..B3.25:                        # Preds ..B3.23 ..B3.21 ..B3.14 ..B3.1
        ret                                                     #32.14
..B3.26:                        # Preds ..B3.2 ..B3.6 ..B3.4    # Infreq
        movb      $1, %r8b                                      #30.7
        xorl      %eax, %eax                                    #30.7
        jmp       ..B3.14       # Prob 100%                     #30.7
        lea       -8(%rsp), %rax                                #8.13
        lea       -40(%rsp), %rdx                               #7.11
        cmpq      %rax, %rdx                                    #33.41
        je        ..B4.15       # Prob 50%                      #33.41
        movq      %rax, -48(%rsp)                               #32.12
        movq      %rdx, -56(%rsp)                               #32.12
        xorl      %eax, %eax                                    #33.7
..B4.13:                        # Preds ..B4.11 ..B4.13
        addsd     -40(%rsp,%rax,8), %xmm0                       #34.9
        incq      %rax                                          #33.7
        cmpq      $4, %rax                                      #33.7
        jb        ..B4.13       # Prob 82%                      #33.7
..B4.15:                        # Preds ..B4.13 ..B4.1
        ret                                                     #35.14

To avoid misunderstandings. If counted loop condition would rely on external parameter like this one.

double countedDep(double param, Test & d)
    for (int i = 0; i < d.size; i++)
        param += d.arr[i];
    return param;

Such loop also will not be unrolled.

share|improve this answer
"...it isn't loop unrolling as such..." is just a false statement unless you have a very strange definition of loop unrolling. –  jxh Nov 30 '14 at 10:33
@jxh if it's still a loop then how it became unrolled for you? It's just chopped into 8 element chunks and in expense of extra code and conditions. –  doc Nov 30 '14 at 10:47
Wikipedia explains what loop unrolling means, and it doesn't mean what you seem to think it means. –  jxh Nov 30 '14 at 10:52
@jxh yes, but it's not complete loop unrolling. That's what I meant by "loop unrolling as such". –  doc Nov 30 '14 at 11:04
I think it is quite obvious a compiler cannot "completely unroll a loop into something without any loops" unless it knows exactly how many iterations will be performed. It is also obvious to me that completely unrolling a loop is a pointless optimization unless the number of iterations is very small, so I am not sure your narrow point is any improvement over my correct answer. –  jxh Nov 30 '14 at 11:12

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