# Optimization of double subtraction in C++

I have the following code that I use to compute the distance between two vectors:

``````double dist(vector<double> & vecA, vector<double> & vecB){
double curDist = 0.0;
for (size_t i = 0; i < vecA.size(); i++){
double dif = vecA[i] - vecB[i];
curDist += dif * dif;
}

return curDist;
}
``````

This function is a major bottleneck in my application since it relies on a lot of distance calculations, consuming more than 60% of CPU time on a typical input. Additionally, the following line:

``````double dif = vecA[i] - vecB[i];
``````

is responsible for more than 77% of CPU time in this function. My question is: is it possible to somehow optimize this function?

Notes:

• To profile my application I have used Intel Amplifier XE;
• Reducing the number of distance computations is not a feasible solution for me;
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How large are these vectors? –  Mysticial Feb 14 '12 at 19:31
If that line really takes more than half the CPU time, it would seem to be cache related (ie first access to each element takes a cache hit) and not really easily optimized by speeding up code. You may need to look into vector based instructions to alleviate that a bit (a'la SSE3) –  Joachim Isaksson Feb 14 '12 at 19:34
Is this the STL's vector? Would be a shame if all the people here assume it is and it isn't. –  eznme Feb 14 '12 at 19:48
@ Mooing duck - it also computes the square of the distance between two points represented as coordinate vectors. –  patros Feb 14 '12 at 20:38
Have you single-stepped the loop, one instruction at a time, to make sure it's not calling hidden functions or bounds-checking? –  Mike Dunlavey Feb 14 '12 at 22:32

There are two possible issues I can think of right now:

• This computation is memory bound.
• There is an iteration-to-iteration dependency on `curDist`.

This computation is memory bound.

Your dataset is larger than your CPU cache. So in this case, no amount of optimization is going to help unless you can restructure your algorithm.

There is an iteration-to-iteration dependency on `curDist`.

You have a dependency on `curDist`. This will block vectorization by the compiler. (Also, don't always trust the profiler numbers to the line. They can be inaccurate especially after compiler optimizations.)

Normally, the compiler vectorizer can split up the `curDist` into multiple partial sums to and unroll/vectorize the loop. But it can't do that under strict-floating-point behavior. You can try relaxing your floating-point mode if you haven't already. Or you can split the sum and unroll it yourself.

For example, this kind of optimization is something the compiler can do with integers, but not necessarily with floating-point:

``````double curDist0 = 0.0;
double curDist1 = 0.0;
double curDist2 = 0.0;
double curDist3 = 0.0;
for (size_t i = 0; i < vecA.size() - 3; i += 4){
double dif0 = vecA[i + 0] - vecB[i + 0];
double dif1 = vecA[i + 1] - vecB[i + 1];
double dif2 = vecA[i + 2] - vecB[i + 2];
double dif3 = vecA[i + 3] - vecB[i + 3];
curDist0 += dif0 * dif0;
curDist1 += dif1 * dif1;
curDist2 += dif2 * dif2;
curDist3 += dif3 * dif3;
}

//  Do some sort of cleanup in case (vecA.size() % 4 != 0)

double curDist = curDist0 + curDist1 + curDist2 + curDist3;
``````
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I see you're using Visual Studio C++ 2010. That compiler doesn't support vectorization yet... You might get better performance with ICC or GCC. –  Mysticial Feb 14 '12 at 19:46
may want to check your for loop there... ;) –  Nim Feb 14 '12 at 19:47
@Nim Thanks for catching that. :) –  Mysticial Feb 14 '12 at 19:48
Good answer! You need i+=4 and then just add the original loop for the last (up to 3 steps) starting from where the unrolled one left. –  Johan Lundberg Feb 14 '12 at 19:50
@MooingDuck I usually just duplicate the original loop. But in nearly all my applications, I can force the dataset to a multiple of some power-of-two, so I don't have the issue in the first place. To be truely efficient, you need some startup code to align the data before entering a fully unrolled+vectorized loop. –  Mysticial Feb 14 '12 at 19:58

You could eliminate the call to `vecA.size()` for each iteration of the loop, just call it once before the loop. You could also do loop unrolling to give yourself more computation per loop iteration. What compiler are you using, and what optimization settings? Compiler will often do unrolling for you, but you could manually do it.

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Beat me to the `vecA.size()` by mere moments. The compiler may or may not be able to determine that this value will remain constant for the during of the loop, so it may not be able to optimize it out. Loop unrolling is another good idea. –  Zéychin Feb 14 '12 at 19:38
Actually, `vector::size` is a constant-time operation and the compiler should be able to inline it and optimize it away... –  rodrigo Feb 14 '12 at 19:41
I'm using Visual Studio C++ 2010 with default parameters. Please note that the profiler's results shows that vecA.size() does not consume a significant part of CPU time. –  Alceu Costa Feb 14 '12 at 19:44
"constant-time" doesn't mean it's as fast as a local variable access that's likely sitting in a register. Compiler can't guarantee that vector::size will remain constant through the loop. But if you had a local var that you put the size in, compiler would know the value can't change –  TJD Feb 14 '12 at 19:46
@TJD You were right: eliminating the call to vecA.size() did reduce the overall CPU time. Now my next step is to solve the subtraction line problem, which is the major bottleneck. –  Alceu Costa Feb 15 '12 at 16:21

If it's feasible (if the range of the numbers isn't huge) you may want to explore using fixed point to store these numbers, rather than doubles.

Fixed point would turn these into int operations rather than double operations.

Another interesting thing is that assuming your profile is correct, the lookups seems to be a significant factor (otherwise the multiplication would likely be more costly than the subtractions).

I'd try using a const vector iterator rather than the random access lookup. It may help in two ways: 1 - it is constant, and 2 - the serial nature of the iterator may let the processor do better caching.

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To use fixed point arithmetic do I need a special library? –  Alceu Costa Feb 15 '12 at 16:22
You either need to use a library or implement it yourself. There's plenty of info on stackoverflow if you search for it. –  patros Feb 16 '12 at 21:32
If your platform does not have (or is not using) an ALU that supports floating point math, floating point libraries, by nature, are slow and consume additional non-volatile memory. I suggest instead using 32-bit (`long`) or 64-bit (`long long`) fixed-point arithmetic. Then convert the final result to floating point at the end of the algorithm. I did this on a project a couple years ago to improve the performance of an I2T algorithm and it worked wonderfully.