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In terms of performance, what would work faster? Is there a difference? Is it platform dependent?

//1. Using vector<string>::iterator:
vector<string> vs = GetVector();

for(vector<string>::iterator it = vs.begin(); it != vs.end(); ++it)
{
   *it = "Am I faster?";
}

//2. Using size_t index:
for(size_t i = 0; i < vs.size(); ++i)
{
   //One option:
   vs.at(i) = "Am I faster?";
   //Another option:
   vs[i] = "Am I faster?";
}
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4  
I have been doing benchmarks myself, and vector.at is much slower than using an iterator, however using vector[i] is much faster than using an iterator. However, you can make the loop even faster by grabbing the pointer to the first element and looping while the current pointer is less than or equal to the pointer of the last element; similar to iterators, but less overhead and is consequently not as nice to look at code-wise. This test was done on Windows with Visual Studio 2008. Concerning your question, I do believe that's platform dependent, it depends on the implementation. –  leetNightshade Feb 27 '12 at 17:35
    
However, continuing from my off topic point about iterating the pointers yourself, should always be faster no matter the platform. –  leetNightshade Feb 27 '12 at 17:36
    
@leetNightshade: Certain compilers, when running into subscripts instead of a pointer arithmetics, could use SIMD instructions, which would make it faster. –  user405725 Apr 13 '13 at 3:14

14 Answers 14

up vote 20 down vote accepted

Why not write a test and find out?

Edit: My bad - I thought I was timing the optimised version but wasn't. On my machine, compiled with g++ -O2, the iterator version is slightly slower than the operator[] version, but probably not significantly so.

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

int main() {
    const int BIG = 20000000;
    vector <int> v;
    for ( int i = 0; i < BIG; i++ ) {
        v.push_back( i );
    }

    int now = time(0);
    cout << "start" << endl;
    int n = 0;
    for(vector<int>::iterator it = v.begin(); it != v.end(); ++it) {
        n += *it;
    }

    cout << time(0) - now << endl;
    now = time(0);
    for(size_t i = 0; i < v.size(); ++i) {
        n += v[i];
    }
    cout << time(0) - now << endl;

    return n != 0;
}
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3  
Did you test with full optimisation and try it with both the iterator version first and with the array version first? There may be a slight difference in performance but 2x? Not a chance. –  James Hopkin Apr 22 '09 at 11:17
    
You'll get better performance measurements by using clock() rather than time(), or use whatever high-resolution timer your OS kernel provides. –  Kristopher Johnson Apr 22 '09 at 12:18
4  
in my tests (using "time" shell builtin and all cout's disabled and one test commented out each time) both versions are equally fast (changed the code so it allocates in the constructor, each element has value "2"). actually the time changes in each test with around 10ms, which i suspect is because of the non-determinism of memory allocation. and sometimes the one, and sometimes the other test is 10ms faster than the other. –  Johannes Schaub - litb Apr 22 '09 at 12:38
1  
@litb - yes, I suspect the slight differences on my machine may be due to its lack of memory. I didn't mean to imply the difference was significant. –  anon Apr 22 '09 at 12:48
3  
@anon: It's not about higher resolution. It's about using clock() rather than time() to explicitly ignore "all the other activities that can be gonig on in a modern OS while your code runs". clock() measures CPU time used for that process alone. –  Lightness Races in Orbit Mar 5 '11 at 19:20

Using an iterator results in incrementing a pointer (for incrementing) and for dereferencing into dereferencing a pointer.
With an index, incrementing should be equally fast, but looking up an element involves an addition (data pointer+index) and dereferencing that pointer, but the difference should be marginal.

Benchmark results for 500M iterations, vector size 10, with gcc 4.3.3 (-O3), linux 2.6.29.1 x86_64:
at(): 9158
operator[]: 4269
iterator: 3914ms

YMMV, but if using an index makes the code more readable/understandable, you should do it.

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Which OS and compiler were the profiled results from? Which implementation of STL were they using? Were the results made with or without optimizations turned on? Be careful, all of this may change the results. To be sure you should profile your own code in your own environment. –  Brian R. Bondy Apr 22 '09 at 11:11
2  
-1 sorry. If you look here: velocityreviews.com/forums/…, you'll see that this guy didn't use any compiler optimisation flags, so the results are essentially meaningless. –  j_random_hacker Apr 22 '09 at 11:12
1  
-1 Agree with j_random_hacker - if you read the thread all the way through, there's some interesting stuff about the pitfalls of profiling, and also some more reliable results. –  James Hopkin Apr 22 '09 at 11:14
1  
-1, indeed. Quoting numbers without understanding them seems to be a trap that got both tstennner and the bencmarker. –  MSalters Apr 22 '09 at 11:15
1  
+2 now that you've updated with more sensible measuring criteria :) –  j_random_hacker Apr 22 '09 at 16:55

If you don't need indexing, don't use it. The iterator concept is there for your best. Iterators are very easy to optimize, while direct access needs some extra knowledge.

Indexing is meant for direct access. The brackets and the at method do this. at will, unlike [], check for out of bounds indexing, so it will be slower.

The credo is: don't ask for what you don't need. Then the compiler won't charge you for what you don't use.

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As everyone else here is saying, do benchmarks.

Having said that, I would argue that the iterator is faster since at() does range checking as well, i.e. it throws an out_of_range exception if the index is out of bounds. That check itself propbably incurrs some overhead.

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I would guess the first variant is faster.

But it's implementation dependent. To be sure you should profile your own code.

Why profile your own code?

Because these factors will all vary the results:

  • Which OS
  • Which compiler
  • Which implementation of STL was being used
  • Were optimizations turned on?
  • ... (other factors)
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Since you're looking at efficiency, you should realise that the following variations are potentially more efficient:

//1. Using vector<string>::iterator:

vector<string> vs = GetVector();
for(vector<string>::iterator it = vs.begin(), end = vs.end(); it != end; ++it)
{
   //...
}

//2. Using size_t index:

vector<string> vs = GetVector();
for(size_t i = 0, size = vs.size(); i != size; ++i)
{
   //...
}

since the end/size function is only called once rather than every time through the loop. It's likely that the compiler will inline these functions anyway, but this way makes sure.

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The question isn't about how to write efficient code, it is about iterators vs. indexes, but thanks for the input –  Gal Goldman Apr 22 '09 at 12:55

You can use this test code and compare results! Dio it!

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


struct AAA{
    int n;
    string str;
};
int main() { 
    const int BIG = 5000000; 
    vector <AAA> v; 
    for ( int i = 0; i < BIG; i++ ) { 
        AAA a = {i, "aaa"};
        v.push_back( a ); 
    } 

    clock_t now;
    cout << "start" << endl; 
    int n = 0; 
    now = clock(); 
    for(vector<AAA>::iterator it = v.begin(); it != v.end(); ++it) { 
        n += it->n; 
    } 
   cout << clock() - now << endl; 

    n = 0;
    now = clock(); 
    for(size_t i = 0; i < v.size(); ++i) { 
        n += v[i].n; 
    } 
    cout << clock() - now << endl; 

    getchar();
    return n != 0; 
} 
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1  
Uhm … that’s not really all that different form Neil’s code. Why bother posting it? –  Konrad Rudolph Feb 12 '10 at 10:11

The first one will be faster in debug mode because index access creates iterators behind the scene, but in release mode where everything should be inlined, the difference should be negligible or null

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If you are using VisualStudio 2005 or 2008, to get the best performance out of the vector you'll need to define _SECURE_SCL=0

By default _SECURE_SCL is on which makes iterating over a contain significantly slower. That said leave it on in debug builds, it will make tracking down any errors much easier. One word of caution, since the macro changes the size of iterators and containers, you'll have to be consistent across all compilation units that share a stl container.

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I think the only answer could be a test on your platform. Generally the only thing which is standardized in the STL is the type of iterators a collection offers and the complexity of algorithms.

I would say that there is no (not much of a difference) between those two versions- the only difference I could think of would be tjat the code has to iterate through the whole collection when it has to compute the length of an array (I'm not sure if the length is stored in a variable inside the vector, then the overhead wouldn't matter)

Accessing the elements with "at" should take a little bit longer than directly accessing it with [] because it checks if you are in the bounds of the vector and throws an exception if you are out of bounds (it seems [] is normally just using pointer arithmetic - so it should be faster)

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I found this thread now when trying to optimize my OpenGL code and wanted to share my results even though the thread is old.

Background: I have 4 vectors, sizes ranging from 6 to 12. Write happens only once at the beginning of the code and read occurs for each of the elements in the vectors every 0.1 milliseconds

The following is the stripped down version of the code used first:

for(vector<T>::iterator it = someVector.begin(); it < someVector.end(); it++)
{
    T a = *it;

    // Various other operations
}

The frame rate using this method was about 7 frames per second (fps).

However, when I changed the code to the following, the frame rate almost doubled to 15fps.

for(size_t index = 0; index < someVector.size(); ++index)
{
    T a = someVector[index];

    // Various other operations
}
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Have you tried pre-incrementing the iterator instead? Since post-inc requires an extra copy step this might have an influence. –  Mike Lischke May 3 '13 at 8:26

The difference should be negligible. std::vector guarantees that its elements are laid out consecutively in memory. Therefore, most stl implementations implement iterators into std::vector as a plain pointer. With this is mind, the only difference between the two versions should be that the first one increments a pointer, and in the second increments an index which is then added to a pointer. So my guess would be the second one is maybe one extremly fast (in terms of cycles) machine instruction more.

Try and check the machine code your compiler produces.

In general, however, the advice would be to profile if it really matters. Thinking about this kind of question prematurely usually does not give you too much back. Usually, your code's hotspots will be elsewhere where you might not suspect it at first sight.

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Here's a code I wrote, compiled in Code::Blocks v12.11, using the default mingw compiler. This creates a huge vector, then accesses each element by using iterators, at(), and index. Each is looped once by calling the last element by function, and once by saving the last element to temporary memory.

Timing is done using GetTickCount.

#include <iostream>
#include <windows.h>
#include <vector>
using namespace std;

int main()
{
    cout << "~~ Vector access speed test ~~" << endl << endl;
    cout << "~ Initialization ~" << endl;
    long long t;
    int a;
    vector <int> test (0);
    for (int i = 0; i < 100000000; i++)
    {
        test.push_back(i);
    }
    cout << "~ Initialization complete ~" << endl << endl;


    cout << "     iterator test: ";
    t = GetTickCount();
    for (vector<int>::iterator it = test.begin(); it < test.end(); it++)
    {
        a = *it;
    }
    cout << GetTickCount() - t << endl;



    cout << "Optimised iterator: ";
    t=GetTickCount();
    vector<int>::iterator endofv = test.end();
    for (vector<int>::iterator it = test.begin(); it < endofv; it++)
    {
        a = *it;
    }
    cout << GetTickCount() - t << endl;



    cout << "                At: ";
    t=GetTickCount();
    for (int i = 0; i < test.size(); i++)
    {
        a = test.at(i);
    }
    cout << GetTickCount() - t << endl;



    cout << "      Optimised at: ";
    t = GetTickCount();
    int endof = test.size();
    for (int i = 0; i < endof; i++)
    {
        a = test.at(i);
    }
    cout << GetTickCount() - t << endl;



    cout << "             Index: ";
    t=GetTickCount();
    for (int i = 0; i < test.size(); i++)
    {
        a = test[i];
    }
    cout << GetTickCount() - t << endl;



    cout << "   Optimised Index: ";
    t = GetTickCount();
    int endofvec = test.size();
    for (int i = 0; i < endofvec; i++)
    {
        a = test[i];
    }
    cout << GetTickCount() - t << endl;

    cin.ignore();
}

Based on this, I personally got that "optimised" versions are faster than "non-optimised" Iterators are slower than vector.at() which is slower than direct indices.

I suggest you compile and run the code for yourselves.

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It really depends on what you are doing, but if you have to keep re-declaring the iterator, Iterators become MARGINALLY SLOWER. In my tests, the fastest possible iteration would be to declare a simple * to your vectors array and Iterate through that.

for example:

Vector Iteration and pulling two functions per pass.

vector<MyTpe> avector(128);
vector<MyTpe>::iterator B=avector.begin();
vector<MyTpe>::iterator E=avector.end()-1;
for(int i=0; i<1024; ++i){
 B=avector.begin();
   while(B!=E)
   {
       float t=B->GetVal(Val1,12,Val2); float h=B->GetVal(Val1,12,Val2);
    ++B;
  }}

Vector Took 90 clicks (0.090000 seconds)

But if you did it with pointers...

for(int i=0; i<1024; ++i){
MyTpe *P=&(avector[0]);
   for(int i=0; i<avector.size(); ++i)
   {
   float t=P->GetVal(Val1,12,Val2); float h=P->GetVal(Val1,12,Val2);
   }}

Vector Took 18 clicks (0.018000 Seconds)

Which is roughly equivalent to...

MyTpe Array[128];
for(int i=0; i<1024; ++i)
{
   for(int p=0; p<128; ++p){
    float t=Array[p].GetVal(Val1, 12, Val2); float h=Array[p].GetVal(Val2,12,Val2);
    }}

Array Took 15 clicks (0.015000 seconds).

If you eliminate the call to avector.size(), the time becomes the same.

Finally, calling with [ ]

for(int i=0; i<1024; ++i){
   for(int i=0; i<avector.size(); ++i){
   float t=avector[i].GetVal(Val1,12,Val2); float h=avector[i].GetVal(Val1,12,Val2);
   }}

Vector Took 33 clicks (0.033000 seconds)

Timed with clock()

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