Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I have a simple function that takes two variables by reference:

void foo(int*& it2,
         bit_reader<big_endian_tag>& reader2)
    for(/* ... */)
        *it2++ = boo(reader2.next());
        // it2++ => 0x14001d890 add qword ptr [r12], 0x4

The problem here is that for it2 and reader2 the optimizer makes the computer write to memory instead of registers during the loop.

However, the following code puts the variables properly into registers during the loop, but has an extra overhead in the form of unnecessary copies, before and after the loop:

void foo2(int*& it2,
         bit_reader<big_endian_tag>& reader2)
    auto reader = reader2;
    auto it     = it2;

    for(/* ... */)
        *it++ = boo(reader.next());
        // it++ => 0x14001d890 add r15, 0x4

    reader2 = reader;
    it2 = it;


How can I make the first example generate the same code as the second example but without the extra copies?

share|improve this question
How do you expect to change it2 and reader2 without writing to the memory where they are stored? –  aschepler Aug 15 '12 at 21:34
I would expect the compiler to keep it2 and reader2 in registers while the loop is running and only write them back into memory at the end of the loop. –  ronag Aug 15 '12 at 21:39
It theoretically could, if it could also prove that boo(reader.next()) can never, ever be affected by the updated values. –  Bo Persson Aug 15 '12 at 21:43
@LokiAstari: Yes. –  ronag Aug 15 '12 at 21:56
I actually expect the writes to go to L1 cache, which in this case (no store-load dependency) might be just as fast as a register. –  MSalters Aug 16 '12 at 8:53

3 Answers 3

up vote 5 down vote accepted

The problem is that the compiler cannot prove it2 does not change within the function. (Well, it could, but that's vastly beyond the intended capabilities of a normal C++ compiler.)

How does it know boo(reader2.next()); doesn't change the value? Consider:

int* i = 0;

struct foo
    int myInt;
    int blah() { i = &myInt; return 5; }

void bar(int*& ptr, const foo& f)
    *ptr = f.blah(); // changes value of ptr!

int otherInt;
i = &otherInt;

bar(i, foo());

This does not assign anything to otherInt, whereas after your transformation it would:

void bar(int*& ptr, const foo& f)
    int* ptrCopy = ptr;
    *ptrCopy = f.blah(); // changes ptr, but not ptrCopy

So unless the compiler can prove the behavior is the same, it cannot make the optimization.

C99 solves this problem with the restrict keyword, but C++ has no equivalent. There are extensions that exist in most C++ compilers though, such as __restrict__ or __restrict.

To do it in standard C++, you just have to be explicit and make the copy yourself

share|improve this answer
I tried passing them as pointer and using __restrict, however that made no difference. I guess doing the copies explicitly is the best way. –  ronag Aug 15 '12 at 22:02
@ronag: Hm, I've never actually used it myself so I can't be of much help there. :( If your code can be simplified into a self-contained and compileable example, I would recommend you ask a second question. –  GManNickG Aug 15 '12 at 22:17

Well, you cannot.

When you pass the parameters by non-const reference, you ask the compiler to update the original variables. So it has to write the new values to memory.

share|improve this answer
I understand that, but it doesn't have to write to memory in every loop iteration, only at the end of the loop, as I am doing in my second example. –  ronag Aug 15 '12 at 21:43
The compiler must be able to realize that. The expression *it2++ = boo(reader2.next()); is really hard for the compiler to analyze, so most don't care to cache values that might be visible from the outside. –  Bo Persson Aug 15 '12 at 21:47

It is all about optimizing for the "memory hierarchies", doing computation is fastest when done directly on registers and that's why you really really want to take stuff from memory and copy it into registers before computing anything on it and then copy the result back into the memory location you need to. The performance you gain by computing directly on registers will generally offset the cost of loading and saving the memory to and from registers.

How do you ensure you get stuff from memory into registers? e.g.

size_t size;
double* arr;
for (int i = 0; i < size - 1; ++i) {
    double a = arr[i];     // copy to register
    double b = arr[i + 1]; // copy to register
    b = a*b + b;           // make sure flop computation is done in registers
    arr[i] = b;            // copy back to memory
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.