# Why use functors over functions?

Compare

``````double average = CalculateAverage(values.begin(), values.end());
``````

with

``````double average = std::for_each(values.begin(), values.end(), CalculateAverage());
``````

What are the benefits of using a functor over a function? Isn't the first a lot easier to read (even before the implementation is added)?

Assume the functor is defined like this:

``````class CalculateAverage
{
private:
std::size_t num;
double sum;
public:

CalculateAverage() : num (0) , sum (0)
{
}

void operator () (double elem)
{
num++;
sum += elem;
}

operator double() const
{
return sum / num;
}
};
``````
• You need loop over the array by yourself in the first case. Isn't it? Commented Jun 23, 2011 at 9:23
• Will `for_each` really return the average? Don't you need `accumulate`? See sgi.com/tech/stl/accumulate.html. Here, your second line applies CalculateAvarage()() to each member of the sequence, so you'd need some clever running average calculation, plus an instance of CalculateAverage that you can query after the `for_each`. `for_each` will return a copy of your functor. Commented Jun 23, 2011 at 9:42
• Functors give you more flexibility, at the cost of usually using slightly more memory, at the cost of being more difficult to use correctly, and at the cost of some efficiency. The memory cost is minuscule per object, but when it is 100% (as in the case of one function pointer versus double that amount of memory) and you have a zillion objects, it counts. The "use correctly" cost includes that functors can be freely copied, so to share state must use internal pointer and possibly dynamic allocation. And that latter is also main efficiency cost. Commented Jun 23, 2011 at 9:48
• @juanchopanza: probably OP assumes implicit conversion CalculateAverage to double. And I don't understand how to calculate average (not sum!) with accumulate(). we need to divide by number of elements.. how accumulate's BinaryOperation knows about this number? If BinaryOperation has state and counts sum and number of elements in parallel (and does not use it second operand at all) - is it really more clear solution then for_each ? Commented Jun 23, 2011 at 12:28
• @user396672: The way you use accumulate could be for example, `struct Average { double total; uintmax_t count; Average() : total(0), count(0) {} Average operator+(double d) { total += d; count += 1; }; operator double() { return total / count; /* undefined if 0! */ }};`. You don't need to use the binary operator parameter at all if you don't want, and the operator doesn't need to track the count, the accumulator can (and should) do it. I think this is about equally clear with the functor you'd pass to `for_each`, the difference is you implement `operator+` instead of `operator()`. Commented Jun 23, 2011 at 14:38

At least four good reasons:

Separation of concerns

In your particular example, the functor-based approach has the advantage of separating the iteration logic from the average-calculation logic. So you can use your functor in other situations (think about all the other algorithms in the STL), and you can use other functors with `for_each`.

Parameterisation

You can parameterise a functor more easily. So for instance, you could have a `CalculateAverageOfPowers` functor that takes the average of the squares, or cubes, etc. of your data, which would be written thus:

``````class CalculateAverageOfPowers
{
public:
CalculateAverageOfPowers(float p) : acc(0), n(0), p(p) {}
void operator() (float x) { acc += pow(x, p); n++; }
float getAverage() const { return acc / n; }
private:
float acc;
int   n;
float p;
};
``````

You could of course do the same thing with a traditional function, but then makes it difficult to use with function pointers, because it has a different prototype to `CalculateAverage`.

Statefulness

And as functors can be stateful, you could do something like this:

``````CalculateAverage avg;
avg = std::for_each(dataA.begin(), dataA.end(), avg);
avg = std::for_each(dataB.begin(), dataB.end(), avg);
avg = std::for_each(dataC.begin(), dataC.end(), avg);
``````

to average across a number of different data-sets.

Note that almost all STL algorithms/containers that accept functors require them to be "pure" predicates, i.e. have no observable change in state over time. `for_each` is a special case in this regard (see e.g. Effective Standard C++ Library - for_each vs. transform).

Performance

Functors can often be inlined by the compiler (the STL is a bunch of templates, after all). Whilst the same is theoretically true of functions, compilers typically won't inline through a function pointer. The canonical example is to compare `std::sort` vs `qsort`; the STL version is often 5-10x faster, assuming the comparison predicate itself is simple.

Summary

Of course, it's possible to emulate the first three with traditional functions and pointers, but it becomes a great deal simpler with functors.

• The `acc` in your example, is that a global variable? Commented Jun 23, 2011 at 9:44
• You're welcome, but I was trying to give a hint about something a little bigger, which affects your answer fundamentally (I think). I just tried your code, and Visual C++ protests `operator =' function is unavailable in 'CalculateAverageOfPowers'`. g++ similarly complains `error: non-static const member 'const float CalculateAverageOfPowers::p', can't use default assignment operator` Commented Jun 23, 2011 at 9:58
• @Matthieu: That's a fair point. To be honest, I'm echoing the sentiment that Scott Meyers makes in "Effective STL", and that I've observed in practice. I'll look into profiling `std::sort` with functor vs. function-pointer. But fundamentally, I don't think there's any reason that `qsort` couldn't be implemented in the same way as `std::sort` with a function pointer. Commented Jun 23, 2011 at 10:12
• @Matthieu: "last time I tested qsort it allocated extra memory" - I'm surprised, I'd expect there to be adequate space on the stack for qsort, and for pretty much any qsort implementation to rely on this. Furthermore, malloc is allowed to fail and qsort isn't, so typically it would have to abort as a special-case. Finally, qsort does not require a table of pointers, the element size is one of its parameters and pointers to the elements are passed to the comparator function. You can qsort an array of anything and expect the same locality as other similar array operations. Commented Jun 23, 2011 at 10:55
• The statefulness example is really good, I hadn't thought of using functors like that. Commented Jun 23, 2011 at 11:45

• Unlike Functions Functor can have state.
• Functor fits into OOP paradigm as compared to functions.
• Functor often may be inlined unlike Function pointers
• Functor doesn't require vtable and runtime dispatching, and hence more efficient in most cases.

`std::for_each` is easily the most capricious and least useful of the standard algorithms. It's just a nice wrapper for a loop. However, even it has advantages.

Consider what your first version of `CalculateAverage` must look like. It will have a loop over the iterators, and then do stuff with each element. What happens if you write that loop incorrectly? Oops; there's a compiler or runtime error. The second version can never have such errors. Yes, it's not a lot of code, but why do we have to write loops so often? Why not just once?

Now, consider real algorithms; the ones that actually do work. Do you want to write `std::sort`? Or `std::find`? Or `std::nth_element`? Do you even know how to implement it in the most efficient way possible? How many times do you want to implement these complex algorithms?

As for ease of reading, that's in the eyes of the beholder. As I said, `std::for_each` is hardly the first choice for algorithms (especially with C++0x's range-based for syntax). But if you're talking about real algorithms, they're very readable; `std::sort` sorts a list. Some of the more obscure ones like `std::nth_element` won't be as familiar, but you can always look it up in your handy C++ reference.

And even std::for_each is perfectly readable once you use Lambda's in C++0x.

•Unlike Functions Functor can have state.

This is very interesting because std::binary_function, std::less and std::equal_to has a template for an operator() that is const. But what if you wanted to print a debug message with the current call count for that object, how would you do it?

Here is template for std::equal_to:

``````struct equal_to : public binary_function<_Tp, _Tp, bool>
{
bool
operator()(const _Tp& __x, const _Tp& __y) const
{ return __x == __y; }
};
``````

I can think of 3 ways to allow the operator() to be const, and yet change a member variable. But what is the best way? Take this example:

``````#include <iostream>
#include <string>
#include <algorithm>
#include <functional>
#include <cassert>  // assert() MACRO

// functor for comparing two integer's, the quotient when integer division by 10.
// So 50..59 are same, and 60..69 are same.
// Used by std::sort()

struct lessThanByTen: public std::less<int>
{
private:
// data members
int count;  // nr of times operator() was called

public:
// default CTOR sets count to 0
lessThanByTen() :
count(0)
{
}

// @override the bool operator() in std::less<int> which simply compares two integers
bool operator() ( const int& arg1, const int& arg2) const
{
// this won't compile, because a const method cannot change a member variable (count)
//      ++count;

// Solution 1. this trick allows the const method to change a member variable
++(*(int*)&count);

// Solution 2. this trick also fools the compilers, but is a lot uglier to decipher
++(*(const_cast<int*>(&count)));

// Solution 3. a third way to do same thing:
{
// first, stack copy gets bumped count member variable
int incCount = count+1;

const int *iptr = &count;

// this is now the same as ++count
*(const_cast<int*>(iptr)) = incCount;
}

std::cout << "DEBUG: operator() called " << count << " times.\n";

return (arg1/10) < (arg2/10);
}
};

void test1();
void printArray( const std::string msg, const int nums[], const size_t ASIZE);

int main()
{
test1();
return 0;
}

void test1()
{
// unsorted numbers
int inums[] = {33, 20, 10, 21, 30, 31, 32, 22, };

printArray( "BEFORE SORT", inums, 8 );

// sort by quotient of integer division by 10
std::sort( inums, inums+8, lessThanByTen() );

printArray( "AFTER  SORT", inums, 8 );

}

//! @param msg can be "this is a const string" or a std::string because of implicit string(const char *) conversion.
//! print "msg: 1,2,3,...N", where 1..8 are numbers in nums[] array

void printArray( const std::string msg, const int nums[], const size_t ASIZE)
{
std::cout << msg << ": ";
for (size_t inx = 0; inx < ASIZE; ++inx)
{
if (inx > 0)
std::cout << ",";
std::cout << nums[inx];
}
std::cout << "\n";
}
``````

Because all 3 solutions are compiled in, it increments count by 3. Here's the output:

``````gcc -g -c Main9.cpp
gcc -g Main9.o -o Main9 -lstdc++
./Main9
BEFORE SORT: 33,20,10,21,30,31,32,22
DEBUG: operator() called 3 times.
DEBUG: operator() called 6 times.
DEBUG: operator() called 9 times.
DEBUG: operator() called 12 times.
DEBUG: operator() called 15 times.
DEBUG: operator() called 12 times.
DEBUG: operator() called 15 times.
DEBUG: operator() called 15 times.
DEBUG: operator() called 18 times.
DEBUG: operator() called 18 times.
DEBUG: operator() called 21 times.
DEBUG: operator() called 21 times.
DEBUG: operator() called 24 times.
DEBUG: operator() called 27 times.
DEBUG: operator() called 30 times.
DEBUG: operator() called 33 times.
DEBUG: operator() called 36 times.
AFTER  SORT: 10,20,21,22,33,30,31,32
``````
• The 4th solution is to make count mutable. Commented Feb 16, 2013 at 10:15

In the first approach the iteration code has to be duplicated in all functions that wants to do something with the collection. The second approach hide the details of iteration.

OOP is keyword here.

4.1 What are Functors ?

Functors are functions with a state. In C++ you can realize them as a class with one or more private members to store the state and with an overloaded operator () to execute the function. Functors can encapsulate C and C++ function pointers employing the concepts templates and polymorphism. You can build up a list of pointers to member functions of arbitrary classes and call them all through the same interface without bothering about their class or the need of a pointer to an instance. All the functions just have got to have the same return-type and calling parameters. Sometimes functors are also known as closures. You can also use functors to implement callbacks.

You are comparing functions on different level of abstraction.

You can implement `CalculateAverage(begin, end)` either as:

``````template<typename Iter>
double CalculateAverage(Iter begin, Iter end)
{
return std::accumulate(begin, end, 0.0, std::plus<double>) / std::distance(begin, end)
}
``````

or you can do it with a for loop

``````template<typename Iter>
double CalculateAverage(Iter begin, Iter end)
{
double sum = 0;
int count = 0;
for(; begin != end; ++begin) {
sum += *begin;
++count;
}
return sum / count;
}
``````

The former requires you to know more things, but once you know them, is simpler and leaves fewer possibilities for error.

It also only uses two generic components (`std::accumulate` and `std::plus`), which is often the case in more complex case too. You can often have a simple, universal functor (or function; plain old function can act as functor) and simply combine it with whatever algorithm you need.