163

In his book The C++ Standard Library (Second Edition) Nicolai Josuttis states that lambdas can be better optimized by the compiler than plain functions.

In addition, C++ compilers optimize lambdas better than they do ordinary functions. (Page 213)

Why is that?

I thought when it comes to inlining there shouldn't be any difference any more. The only reason I could think of is that compilers might have a better local context with lambdas and such can make more assumptions and perform more optimizations.

  • Related. – iammilind Dec 5 '12 at 11:46
  • Basically, the statement applies to all function objects, not just lambdas. – newacct Dec 5 '12 at 22:45
  • 4
    That would be incorrect because function pointers are function objects too. – Johannes Schaub - litb Dec 8 '12 at 23:23
  • 2
    @litb: I think I disagree with that.^W^W^W^W^W^W (after looking into standard) I wasn't aware of that C++ism, though I think in common parlance (and according to wikipedia), people mean instance-of-some-callable-class when they say function object. – Sebastian Mach Oct 18 '13 at 6:35
  • 1
    Some compilers can better optimize lambdas than plain functions, but not all :-( – Cody Gray Nov 1 '16 at 13:01
167

The reason is that lambdas are function objects so passing them to a function template will instantiate a new function specifically for that object. The compiler can thus trivially inline the lambda call.

For functions, on the other hand, the old caveat applies: a function pointer gets passed to the function template, and compilers traditionally have a lot of problems inlining calls via function pointers. They can theoretically be inlined, but only if the surrounding function is inlined as well.

As an example, consider the following function template:

template <typename Iter, typename F>
void map(Iter begin, Iter end, F f) {
    for (; begin != end; ++begin)
        *begin = f(*begin);
}

Calling it with a lambda like this:

int a[] = { 1, 2, 3, 4 };
map(begin(a), end(a), [](int n) { return n * 2; });

Results in this instantiation (created by the compiler):

template <>
void map<int*, _some_lambda_type>(int* begin, int* end, _some_lambda_type f) {
    for (; begin != end; ++begin)
        *begin = f.operator()(*begin);
}

… the compiler knows _some_lambda_type::operator () and can inline calls to it trivially. (And invoking the function map with any other lambda would create a new instantiation of map since each lambda has a distinct type.)

But when called with a function pointer, the instantiation looks as follows:

template <>
void map<int*, int (*)(int)>(int* begin, int* end, int (*f)(int)) {
    for (; begin != end; ++begin)
        *begin = f(*begin);
}

… and here f points to a different address for each call to map and thus the compiler cannot inline calls to f unless the surrounding call to map has also been inlined so that the compiler can resolve f to one specific function.

  • 4
    Perhaps it's worth mentioning that instantiating the same function template with a different lambda expression will create a whole new function with a unique type, which might well be a drawback. – chill Dec 5 '12 at 13:19
  • 2
    @greggo Absolutely. The problem is when handling functions which cannot be inlined (because they are too large). Here the call to the callback can still be inlined in the case of a lambda, but not in the case of a function pointer. std::sort is the classical example of this using lambdas instead of a function pointer here brings up to seven-fold (probably more, but I have no data on that!) performance increases. – Konrad Rudolph Mar 4 '14 at 16:37
  • 1
    @greggo You’re confusing two functions here: the one we are passing the lambda to (e.g. std::sort, or map in my example) and the lambda itself. The lambda is usually small. The other function – not necessarily. We’re concerned with inlining calls to the lambda inside the other function. – Konrad Rudolph Mar 4 '14 at 17:03
  • 2
    @greggo I know. This is literally what the last sentence of my answer says, though. – Konrad Rudolph Mar 4 '14 at 17:43
  • 1
    What I find curious (having just stumbled upon it) is that given a simple boolean function pred whose definition is visible, and using gcc v5.3, std::find_if(b, e, pred) does not inline pred, but std::find_if(b, e, [](int x){return pred(x);}) does. Clang manages to inline both, but doesn't produce code as fast as g++ with the lambda. – rici Feb 1 '16 at 20:47
25

Because when you pass a "function" to an algorithm you are in fact passing in a pointer to function so it has to do an indirect call via the pointer to the function. When you use a lambda you are passing in an object to a template instance specially instantiated for that type and the call to the lambda function is a direct call, not a call via a function pointer so can much more likely be inlined.

  • 4
    "the call to the lambda function is a direct call" - indeed. And the same thing is true for all function objects, not just lambdas. It's just function pointers that can't be inlined as easily, if at all. – Pete Becker Dec 5 '12 at 12:45

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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