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I'm having trouble refactoring my C++ code. The code itself is barely 200 lines, if even, however, being an image processing affair, it loops a lot, and the roadblocks I'm encoutering (I assume) deal with very gritty details (e.g. memory access).

The program produces a correct output, but is supposed to ultimately run in realtime. Initially, it took ~3 minutes per 320x240px frame, but it's at around 2 seconds now (running approximately as fast on mid-range workstation and low-end laptop hardware; red flag?). Still a far cry from 24 times per second, however. Basically, any change I make propagates through the millions of repetitions, and tracking my beginner mistakes has become exponentially more cumbersome as I approach the realtime mark.

At 2 points, the program calculates a less computationally expensive variant of Euclidean distance, called taxicab distance (the sum of absolute differences).

Now, the abridged version:

std::vector<int> positiveRows, positiveCols;
/* looping through pixels, reading values */
distance = (abs(pValues[0] - qValues[0]) + abs(pValues[1] - qValues[1]) + abs(pValues[2] - qValues[2]));
if(distance < threshold)

If I wrap the functionality, as follows:

int taxicab_dist(int Lp,
                 int ap,
                 int bp,
                 int Lq,
                 int aq,
                 int bq)
    return (abs(Lp - Lq) + abs(ap - aq) + abs(bp - bq));

and call it from within the same .cpp file, there is no performance degradation. If I instead declare and define it in separate .hpp / .cpp files, I get a significant slowdown. This directly opposes what I've been told in my undergraduate courses ("including a file is the same as copy-pasting it"). The closest I've gotten to the original code's performance was by declaring the arguments const, but it still takes ~100ms longer, which my judgement says is not affordable for such a meager task. Then again, I don't see why it slows down (significantly) if I also make them const int&. Then, when I do the most sensible thing, and choose to take arrays as arguments, again I take a performance hit. I don't even dare attempt any templating shenanigans, or try making the function modify its behavior so that it accepts an arbitrary number of pairs, at least not until I understand what I've gotten myself into.

So my question is: how can take the calculation definition to a separate file, and have it perform the same as the original solution? Furthermore, should the fact that compilers are optimizing my program to run 2 seconds instead of 15 be a huge red flag (bad algorithm design, not using more exotic C++ keywords / features)?

I'm guessing the main reason why I've failed to find an answer is because I don't know what is the name of this stuff. I've heard the terms "vectorization" tossed around quite a bit in the HPC community. Would this be related to that?

If it helps in any way at all, the code it its entirety can be found here.

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How about putting the function in a header file, and mark it inline? –  Joachim Pileborg Jul 4 '14 at 16:10
Also, you could try to profile your program to see where the bottlenecks are. –  Joachim Pileborg Jul 4 '14 at 16:11
You could pre-allocate or reserve space in your vector for either the average number of elements or the maximum. Vectors start out "small" then perform reallocations as necessary. The reallocations take time and fragment memory. –  Thomas Matthews Jul 4 '14 at 16:35
Try inline of small functions, such as your taxicab_dist. The overhead of calling and returning may be greater than or equal to the performance in the function. –  Thomas Matthews Jul 4 '14 at 17:01
Alternative: enable LTO (Link Time Optimization). And for the record, there is no contradiction: including is copy/pasting, but here you copy/paste the declaration only (after the split), and the compiler optimizes better when seeing the definition of the function rather than just its declaration. –  Matthieu M. Jul 4 '14 at 17:02

1 Answer 1

up vote 2 down vote accepted

As Joachim Pileborg says, you should profile first. Find out where in your program most of the execution time occurs. This is the place where you should optimize.

Reserving space in vector
Vectors start out small and then reallocate as necessary. This involves allocating a larger space in memory and then copying the old elements to the new vector. Finally deallocating the memory. The std::vector has the capability of reserving space upon construction. For large sizes of vectors, this can be a time saver, eliminating many reallocations.

Compiling with speed optimizations
With modern compilers, you should set the optimizations for high speed and see what they can do. The compiler writers have many tricks up their sleeve and can often spot locations to optimize that you or I miss.

Truth is assembly language
You will need to view the assembly language listing. If the assembly language shows only two instructions in the area you think is the bottleneck, you really can't get faster.

Loop unrolling
You may be able to get more performance by copying the content in a for loop many times. This is called loop unrolling. In some processors, branch or jump instructions cost more execution time than data processing instructions. Unrolling a loop reduces the number of executed branch instructions. Again, the compiler may automatically perform this when you raise the optimization level.

Data cache optimization
Search the web for "Data cache optimization". Loading and unloading the data cache wastes time. If your data can fit into the processor's data cache, it doesn't have to keep loading an unloading (called cache misses). Also remember to perform all your operations on the data in one place before performing other operations. This reduces the likelihood of the processor reloading the cache.

Multi-processor computing
If your platform has more than one processor, such as a Graphics Processing Unit (GPU), you may be able to delegate some tasks to it. Be aware that you have also added time by communicating with the other processor. So for small tasks, the communications overhead may waste the time you gained by delegating.

Parallel computing
Similar to multi-processors, you can have the Operating System delegate the tasks. The OS could delegate to different cores in your processor (if you have a multi-core processor) or it runs it in another thread. Again there is a cost: overhead of managing the task or thread and communications.

The three rules of Optimization:

  1. Don't
  2. Don't
  3. Profile
    After you profile, review the area where the most execution takes place. This will gain you more time than optimizing a section that never gets called. Design optimizations will generally get you more time than code optimizations. Likewise, requirement changes (such as elimination) may gain you more time than design optimizations.

After your program is working correctly and is robust, you can optimize, only if warranted. If your UI is so slow that the User can go get a cup of coffee, it is a good place to optimize. If you gain 100 milliseconds by optimizing data transfer, but your program waits 1 second for the human response, you have not gained anything. Consider this as driving really fast to a stop sign. Regardless of your speed, you still have to stop.

If you still need performance gain, search the web for "Optimizations c++", or "data optimizations" or "performance optimization".

share|improve this answer
Regarding raising optimization levels, it's not always guaranteed that it will create faster code. There are many examples where raising from second level (-O2 on GCC) to third level (-O3) actually lowered performance. Turning on (or off) individual optimizations might give better results. Experiment! –  Joachim Pileborg Jul 4 '14 at 17:03
@JoachimPileborg: Good point. I'm only raising the point that optimizations should be tried before a beginner optimizes the code. I've seen compilers unroll loops for me, I've also seen compilers write different code that has the same performance as code I've written. –  Thomas Matthews Jul 4 '14 at 17:15
Loop unrolling doesn't seem elegant, and I'd like to avoid it if possible, instead opting to let the compiler handle it to the best of its ability. Actually, I did some trivial OpenMP and CUDA tests, and this refactoring is essentially prep work for parallelization. Making an educated guess, I'd say data caches are the primary culprits here (resulting from very non-sequential memory access). However, I have yet to learn how to diagnose these sorts of problems. If you guys could recommend any quality resources for getting into profiling, that would be awesome. –  bcoka Jul 4 '14 at 19:44

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