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In C, I have a task where I must do multiplication, inversion, trasposition, addition etc. etc. with huge matrices allocated as 2-dimensional arrays, (arrays of arrays).

I have found the gcc flag -funroll-all-loops. If I understand correctly, this will unroll all loops automatically without any efforts by the programmer.

My questions:

a) Does gcc include this kind of optimization with the various optimization flags as -O1, -O2 etc.?

b) Do I have to use any pragmas inside my code to take advantage of loop unrolling or are loops identified automatically?

c) Why is this option not enabled by default if the unrolling increases the performance?

d) What are the recommended gcc optimization flags to compile the program in the best way possible? (I must run this program optimized for a single CPU family, that is the same of the machine where I compile the code, actually I use march=native and -O2 flags)

EDIT

Seems that there are controversities about the use of unroll that in some cases may slow down the performance. In my situations there are various methods that do simply math operations in 2 nested for cycles for iterate matrix elements done for an huge amount of elements. In this scenario how unroll could slow down or increase the performance?

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    "Why this option is not enabled by default if the unrolling increase the performance?" - From the docs: funroll-all-loops: ...This usually makes programs run more slowly.. You can hit instruction cache misses and your code size will increase. It's not an automatic benefit. Jun 13, 2014 at 0:48
  • Also, loop unrolling doesn't always improve performance.
    – Mysticial
    Jun 13, 2014 at 0:49
  • To answer 1, according to the docs Ed mentioned none of the -O options add -funroll-loops or -funroll-all-loops. Jun 13, 2014 at 0:51
  • so when unroll loops is usefull and when slowdown the performances?
    – AndreaF
    Jun 13, 2014 at 1:03
  • basically all the operations are done in double nested for cycle loops to iterate the matrix elements, with simple math operations for each element, in this scenario I don't know why should or should not improve the performance.
    – AndreaF
    Jun 13, 2014 at 1:27

3 Answers 3

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Why unroll loops?

Modern processors pipeline instructions. They like knowing what's coming next and make all sorts of fancy optimisations based on assumptions of which order the instructions should be executed.

At the end of a loop though, there are two possibilities! Either you go back to the top, or continue on. The processor makes an educated guess on which is going to happen. If it gets it right, everything is good. If not, it has to flush the pipeline and stall for a bit while it prepares for taking the other branch.

As you can imagine, unrolling a loop eliminates branches and the potential for those stalls, especially in cases where the odds are against a guess.

Imagine a loop of code that executes 3 times, then continues. If you assume (as the processor probably would) that at the end you'll repeat the loop. 2/3 of the time, you'll be correct! 1/3 of the time though, you'll stall.

On the other hand, imagine the same situation, but the code loops 3000 times. Here, there's probably only a gain 1/3000 of the time from unrolling.

Why not unroll loops?

Part of the processor fanciness mentioned above involves loading the instructions from the executable in memory into the processor's onboard instruction cache (shortened to I-cache). This holds a limited amount of instructions which can be accessed quickly, but may stall when new instructions need to be loaded from memory.

Let's go back to the previous examples. Assume a reasonably small amount of code inside the loop takes up n bytes of I-cache. If we unroll the loop, it's now taking up n * 3 bytes. A bit more, but it'll probably fit in a single cache line just fine so your cache will be working optimally and not needing to stall reading from main memory.

The 3000-loop, however, unrolls to use a whopping n * 3000 bytes of I-cache. That's going to require several reads from memory, and probably push some other useful stuff from elsewhere in the program out of the I-cache.

So what do I do?

As you can see, unrolling provides more benefits for shorter loops but ends up trashing performance if you're intending to loop a large number of times.

Usually, a smart compiler will take a decent guess about which loops to unroll but you can force it if you're sure you know better. How do you get to know better? The only way is to try it both ways and compare timings!

Premature optimization is the root of all evil -- Donald Knuth

Profile first, optimise later.

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    So, you would presumably not recommend using -funroll-loops on anything but compilation units that have specifically been determined to benefit from it, if at all?
    – SamB
    Nov 21, 2015 at 19:45
  • Downvote because unrolling loops is not the same as repeating code thousands of times. See Duff device for a better example. Jan 5, 2017 at 19:25
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    "-funroll-loops Unroll loops whose number of iterations can be determined at compile time or upon entry to the loop" Jan 5, 2017 at 19:39
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    This isn't an accurate description of the benefits of unrolling loops. Unrolling generally doens't "eliminate" branches, since the unrolled loop still has a branch, and it usually doesn't help with branch prediction: any moderately large number of iterations will have the same prediction behavior: correctly predicted taken (loop back to top) and then mispredicted once on exit. For small iteration counts loop unrolling generally results in worse prediction since you need to have another "tail handling" portion for the odd iterations which can also mispredict.
    – BeeOnRope
    Dec 13, 2017 at 0:32
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    The main benefits of loop unrolling are: (1) reduction of the overhead associated with the end-of-loop check and loop counter variables and (2) efficiencies obtained when several iterations of the loop can be optimized as a whole.
    – BeeOnRope
    Dec 13, 2017 at 0:37
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Loop unrolling does not work if the compiler can't predict the exact amount of iterations of the loop at compile time (or at least predict an upper bound, and then skip as many iterations as needed). This means that if your matrix size is variable, the flag will have no effect.

Now to answer your questions:

a) Does gcc include this kind of optimization with the various optimization flags as -O1, -O2 etc.?

Nope, you have to explicitly set it since it may or may not make the code run faster and it usually makes the executable bigger.

b) Do I have to use any pragmas inside my code to take advantage of loop unrolling or are loops identified automatically?

No pragmas. With -funroll-loops the compiler heuristically decides which loops to unroll. If you want to force unrolling you can use -funroll-all-loops, but it usually makes the code run slower.

c) Why is this option not enabled by default if the unrolling increases the performance?

It doesn't always increase performance! Also, not everything is about performance. Some people actually care about having small executables since they have little memory (see: embedded systems)

d) What are the recommended gcc optimization flags to compile the program in the best way possible? (I must run this program optimized for a single CPU family, that is the same of the machine where I compile the code, actually I use march=native and -O2 flags)

There's no silver bullet. You'll need to think, test and see. There is actually a theorem that states that no perfect compiler can ever exist.

Did you profile your program? Profiling is a very useful skill for these things.

Source (mostly): https://gcc.gnu.org/onlinedocs/gcc-3.4.4/gcc/Optimize-Options.html

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    You have the wrong definition of "loop unrolling". Loop unrolling doesn't (only) refer to duplicating the body of a loop N times for a loop with N iterations so the loop completely disappears. It also refers to duplicating the body 2, 4 or more generally M times, and then running the loop fewer times (by a factor of M) but it's still a loop. The former technique could be called "completely unrolling" but it isn't very applicable since usually you don't have a compile-time constant trip count.
    – BeeOnRope
    Dec 13, 2017 at 0:35
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You are getting a theoretical background about the issue and it leaves enough space to guess what you are getting in a real run. It is said that the option is not always increasing performance because it depends on a variety of factors, for instance on the loop implementation, its load/body and others.

Each code is different and if you are interested in finding the better performance solution it is good idea just to run both variants, measure theirs execution times and compare.

Look at this approach in the answer below to have an idea of time measurement. In two words, you just wrap your code into the cycle which will lead your program running to take several seconds. As you are optimizing loops themselves it is good idea to write a shell script, which runs your app many times.

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