124

I have a class called Writer that has a function writeVector like so:

void Drawer::writeVector(vector<T> vec, bool index=true)
{
    for (unsigned int i = 0; i < vec.size(); i++) {
        if (index) {
            cout << i << "\t";
        }
        cout << vec[i] << "\n";
    }
}

I'm trying not to have a duplicate code, while still worrying about the performance. In the function, I'm doing the if (index) check on every round of my for-loop, even though the result is always the same. This is against "worrying about the performance".

I could easily avoid this by placing the check outside of my for-loop. However, I'll get loads of duplicate code:

void Drawer::writeVector(...)
{
    if (index) {
        for (...) {
            cout << i << "\t" << vec[i] << "\n";
        }
    }
    else {
        for (...) {
            cout << vec[i] << "\n";
        }
    }
}

So these are both "bad" solutions for me. What I've been thinking, is two private functions, one of them outs the index and then calls the other. The other one only outs the value. However, I can't figure out how to use it with my program, I'd still need the if check to see which one to call...

According to the problem, polymorphism seems like a correct solution. But I can't see how should I use it here. What would be the preferred way to solve this kind of problem?

This is not a real program, I'm just interested in learning how this kind of problem should be solved.

15
  • 9
    @JonathonReinhart Maybe some people want to learn programming, and are curious on how to solve problems?
    – Skamah One
    Jun 1, 2013 at 10:10
  • 9
    I have given this question +1. This kind of optimization may not often be necessary, but firstly, pointing out this fact can be part of the answer, and secondly, rare types of optimization are still highly relevant to programming.
    – jogojapan
    Jun 1, 2013 at 10:39
  • 31
    The question is about good design which avoids code duplication and complicated logic inside the loop. It is a good question, no need to downvote it.
    – Ali
    Jun 1, 2013 at 10:55
  • 5
    It's an interesting question, usually the loop-transformation passes in the compiler will solve this very efficiently. if the function is sufficiently small like this one the inliner will take care about it and will most likely kill the branch off completely. I'd rather change the code until the inliner is happily inlining the code than solving this with templates. Jun 1, 2013 at 13:39
  • 5
    @JonathonReinhart: Why can't you guys just assume the OP has already profiled his code and just answer the darn question? Even if the OP hasn't, whoever sees this question in the future likely has. You're not doing anyone any favors by dismissing the question with stupid "Why do you care?" comments.
    – user541686
    Jun 1, 2013 at 21:13

4 Answers 4

80

Pass in the body of the loop as a functor. It gets inlined at compile-time, no performance penalty.

The idea of passing in what varies is ubiquitous in the C++ Standard Library. It is called the strategy pattern.

If you are allowed to use C++11, you can do something like this:

#include <iostream>
#include <set>
#include <vector>

template <typename Container, typename Functor, typename Index = std::size_t>
void for_each_indexed(const Container& c, Functor f, Index index = 0) {

    for (const auto& e : c)
        f(index++, e);
}

int main() {

    using namespace std;

    set<char> s{'b', 'a', 'c'};

    // indices starting at 1 instead of 0
    for_each_indexed(s, [](size_t i, char e) { cout<<i<<'\t'<<e<<'\n'; }, 1u);

    cout << "-----" << endl;

    vector<int> v{77, 88, 99};

    // without index
    for_each_indexed(v, [](size_t , int e) { cout<<e<<'\n'; });
}

This code is not perfect but you get the idea.

In old C++98 it looks like this:

#include <iostream>
#include <vector>
using namespace std;

struct with_index {
  void operator()(ostream& out, vector<int>::size_type i, int e) {
    out << i << '\t' << e << '\n';
  }
};

struct without_index {
  void operator()(ostream& out, vector<int>::size_type i, int e) {
    out << e << '\n';
  }
};


template <typename Func>
void writeVector(const vector<int>& v, Func f) {
  for (vector<int>::size_type i=0; i<v.size(); ++i) {
    f(cout, i, v[i]);
  }
}

int main() {

  vector<int> v;
  v.push_back(77);
  v.push_back(88);
  v.push_back(99);

  writeVector(v, with_index());

  cout << "-----" << endl;

  writeVector(v, without_index());

  return 0;
}

Again, the code is far from perfect but it gives you the idea.

20
  • 4
    for(int i=0;i<100;i++){cout<<"Thank you!"<<endl;} :D This is the kind of solution I was looking for, it works like a charm :) You could improve it with few comments (had problems understanding it at first), but I got it so no problem :)
    – Skamah One
    Jun 1, 2013 at 10:38
  • 1
    I am glad it helped! Please check my update with C++11 code, it is less bloated compared to the C++98 version.
    – Ali
    Jun 1, 2013 at 10:49
  • 3
    Nitpick: this is fine in OP's example case because the loop body is so small, but if it was bigger (imagine a dozen lines of code instead of just a single cout << e << "\n";) there would still be quite some code duplication.
    – syam
    Jun 1, 2013 at 12:27
  • 3
    Why are the structures and operator overloading used in the C++03 example? Why not just make two functions and pass the pointers to them?
    – Malcolm
    Jun 2, 2013 at 6:22
  • 2
    @Malcolm Inlining. If they are structures, chances are the function calls can be inlined. If you pass a function pointer, chances are those calls cannot be inlined.
    – Ali
    Jun 2, 2013 at 8:46
40

In the function, I'm doing the if (index) check on every round of my for-loop, even though the result is always the same. This is against "worrying about the performance".

If this is indeed the case, the branch predictor will have no problem in predicting the (constant) result. As such, this will only cause a mild overhead for mispredictions in the first few iterations. It's nothing to worry about in terms of performance

In this case I advocate for keeping the test inside the loop for clarity.

7
  • 3
    It's just an example, I'm here to learn how should this kind of problem be solved. I'm just curious, not even creating a real program. Should've mentioned it in the question.
    – Skamah One
    Jun 1, 2013 at 10:17
  • 41
    In that case, keep in mind that premature optimization is the root of all evil. When programming, always focus on code readability and make sure others understand what you are trying to do. Only consider micro-optimizations and various hacks after profiling your program and identifying hotspots. You should never consider optimizations without establishing the need for them. Very often, performance problems are not where you expect them to be. Jun 1, 2013 at 10:20
  • 3
    And in this particular example (ok, understood, this is just an example) it is very likely that the time spent for loop control and if test is nearly invisible beside time spent for IO. This is often an issue with C++ : choosing between readability at the cost of maintenance and (hypothetical) efficiency.
    – kriss
    Jun 1, 2013 at 14:20
  • 8
    You're assuming that the code is running on a processor that has branch prediction to begin with. The majority of systems running C++ don't. (Although, probably the majority of systems with a useful std::cout do)
    – Ben Voigt
    Jun 1, 2013 at 14:34
  • 2
    -1. Yes, branch prediction will work well here. Yes, the condition might actually be hoisted outside the loop by the compiler. Yes, POITROAE. But branches within a loop are a dangerous thing that often has performance impact, and I don't think dismissing those by just saying "branch prediction" is a good advice if someone really cares about performance. The most notable example is that a vectorizing compiler will need predication to handle this, producing less efficient code than for branch-less loops.
    – Oak
    Jun 6, 2013 at 20:34
35

To expand on Ali's answer, which is perfectly correct but still duplicates some code (part of the loop body, this is unfortunately hardly avoidable when using the strategy pattern)...

Granted in this particular case the code duplication is not much but there's a way to reduce it even more, which comes in handy if the function body is bigger than just a few instructions.

The key is to use the compiler's ability to perform constant folding / dead code elimination. We can do that by manually mapping the runtime value of index to a compile-time value (easy to do when there are only a limited number of cases -- two in this case) and use a non-type template argument which is known at compile-time:

template<bool index = true>
//                  ^^^^^^ note: the default value is now part of the template version
//                         see below to understand why
void writeVector(const vector<int>& vec) {
    for (size_t i = 0; i < vec.size(); ++i) {
        if (index) { // compile-time constant: this test will always be eliminated
            cout << i << "\t"; // this will only be kept if "index" is true
        }
        cout << vec[i] << "\n";
    }
}

void writeVector(const vector<int>& vec, bool index)
//                                            ^^^^^ note: no more default value, otherwise
//                                            it would clash with the template overload
{
    if (index) // runtime decision
        writeVector<true>(vec);
        //          ^^^^ map it to a compile-time constant
    else
        writeVector<false>(vec);
}

This way we end up with compiled code which is equivalent to your second code example (outer if / inner for) but without duplicating the code ourselves. Now we can make the template version of writeVector as complicated as we want, there will always be a single piece of code to maintain.

Note how the template version (which takes a compile-time constant in the form of a non-type template argument) and the non-template version (which takes a runtime variable as a function argument) are overloaded. This allows you to choose the most relevant version depending on your needs, having a rather similar, easy to remember syntax in both cases:

writeVector<true>(vec);   // you already know at compile-time which version you want
                          // no need to go through the non-template runtime dispatching

writeVector(vec, index);  // you don't know at compile-time what "index" will be
                          // so you have to use the non-template runtime dispatching

writeVector(vec);         // you can even use your previous syntax using a default argument
                          // it will call the template overload directly
10
  • 2
    Please keep in mind that you removed the code duplication at the expense of making the logic inside the loop more complicated. I see it neither better nor worse than what I proposed for this particular simple example. +1 anyways!
    – Ali
    Jun 1, 2013 at 13:14
  • 1
    I like your proposal because it shows another possible optimization. It is very possible that index could be a template constant from the start. In this case it could be replaced by a runtime constant by the caller of writeVector and writeVector changed to some template. Avoiding any further change to the original code.
    – kriss
    Jun 1, 2013 at 14:24
  • 1
    @kriss: Actually my previous solution already allowed that if you called doWriteVector directly but I agree the name was unfortunate. I just changed it to have two overloaded writeVector functions (one template, the other a regular function) so that the result is more homogeneous. Thanks for the suggestion. ;)
    – syam
    Jun 1, 2013 at 14:45
  • 4
    IMO this is the best answer. +1
    – user541686
    Jun 1, 2013 at 21:22
  • 1
    @Mehrdad Except that it doesn't answer the original question Avoiding if statement inside a for loop? It does answer how to avoid the performance penalty though. As for the "duplication", a more realistic example with use cases would be needed to see how it is best factored out. As I said before, I upvoted this answer.
    – Ali
    Jun 2, 2013 at 8:54
0

In most of cases, your code is already good for performance and readability. A good compiler is capable to detect loop invariants and do appropriate optimizations. Consider the following example which is very close to your code:

#include <cstdio>
#include <iterator>

void write_vector(int* begin, int* end, bool print_index = false) {
    unsigned index = 0;
    for(int* it = begin; it != end; ++it) {
        if (print_index) {
            std::printf("%d: %d\n", index, *it);
        } else {
            std::printf("%d\n", *it);
        }
        ++index;
    }
}

int my_vector[] = {
    1, 2, 3, 4, 5, 6, 7, 8, 9, 10,
};


int main(int argc, char** argv) {
    write_vector(std::begin(my_vector), std::end(my_vector));
}

I am using the following command line to compile it:

g++ --version
g++ (GCC) 4.9.1
Copyright (C) 2014 Free Software Foundation, Inc.
This is free software; see the source for copying conditions.  There is NO
warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
g++ -O3 -std=c++11 main.cpp

Then, let's dump assembly:

objdump -d a.out | c++filt > main.s

The result assembly of write_vector is:

00000000004005c0 <write_vector(int*, int*, bool)>:
  4005c0:   48 39 f7                cmp    %rsi,%rdi
  4005c3:   41 54                   push   %r12
  4005c5:   49 89 f4                mov    %rsi,%r12
  4005c8:   55                      push   %rbp
  4005c9:   53                      push   %rbx
  4005ca:   48 89 fb                mov    %rdi,%rbx
  4005cd:   74 25                   je     4005f4 <write_vector(int*, int*, bool)+0x34>
  4005cf:   84 d2                   test   %dl,%dl
  4005d1:   74 2d                   je     400600 <write_vector(int*, int*, bool)+0x40>
  4005d3:   31 ed                   xor    %ebp,%ebp
  4005d5:   0f 1f 00                nopl   (%rax)
  4005d8:   8b 13                   mov    (%rbx),%edx
  4005da:   89 ee                   mov    %ebp,%esi
  4005dc:   31 c0                   xor    %eax,%eax
  4005de:   bf a4 06 40 00          mov    $0x4006a4,%edi
  4005e3:   48 83 c3 04             add    $0x4,%rbx
  4005e7:   83 c5 01                add    $0x1,%ebp
  4005ea:   e8 81 fe ff ff          callq  400470 <printf@plt>
  4005ef:   49 39 dc                cmp    %rbx,%r12
  4005f2:   75 e4                   jne    4005d8 <write_vector(int*, int*, bool)+0x18>
  4005f4:   5b                      pop    %rbx
  4005f5:   5d                      pop    %rbp
  4005f6:   41 5c                   pop    %r12
  4005f8:   c3                      retq   
  4005f9:   0f 1f 80 00 00 00 00    nopl   0x0(%rax)
  400600:   8b 33                   mov    (%rbx),%esi
  400602:   31 c0                   xor    %eax,%eax
  400604:   bf a8 06 40 00          mov    $0x4006a8,%edi
  400609:   48 83 c3 04             add    $0x4,%rbx
  40060d:   e8 5e fe ff ff          callq  400470 <printf@plt>
  400612:   49 39 dc                cmp    %rbx,%r12
  400615:   75 e9                   jne    400600 <write_vector(int*, int*, bool)+0x40>
  400617:   eb db                   jmp    4005f4 <write_vector(int*, int*, bool)+0x34>
  400619:   0f 1f 80 00 00 00 00    nopl   0x0(%rax)

We can see, that at the begging of the function, we check the value and jump to one of two possible loops:

  4005cf:   84 d2                   test   %dl,%dl
  4005d1:   74 2d                   je     400600 <write_vector(int*, int*, bool)+0x40>

Of course, this only works if a compiler is capable to detect that a condition is actual invariant. Usually, it perfectly works for flags and simple inline functions. But if the condition is "complex", consider using approaches from other answers.

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