I need to perform a rather complex check over a vector and I have to repeat it thousands and millions of times. To make it more efficient, I translate given formula into C++ source code and compile it in heavily-optimized binary, which I call in my code. The formula is always purely Boolean: only &&, || and ! used. Typical source code looks like this:

#include <assert.h>
#include <vector>

using DataType = std::vector<bool>;

static const char T = 1;
static const char F = 0;
const std::size_t maxidx = 300;

extern "C" bool check (const DataType& l);

bool check (const DataType& l) {
  assert (l.size() == maxidx);
  return (l[0] && l[1] && l[2]) || (l[3] && l[4] && l[5]); //etc, very large line with && and || everywhere

I compile it as follows:

g++  -std=c++11 -Ofast -march=native -fpic -c check.cpp

Performance of the resulting binary is crucial.

It worked perfectly util recent test case with the large number of variables (300, as you can see above). With this test case, g++ consumes more than 100 GB of memory and freezes forever.

My question is pretty straightforward: how can I simplify that code for the compiler? Should I use some additional variables, get rid of vector or something else?

EDIT1: Ok, here is the screenshot from top utility.

enter image description here

cc1plus is busy with my code. The check function depends on 584 variables (sorry for a imprecise number in the example above) and it contains 450'000 expressions.

I would agree with @akakatak's comment below. It seems that g++ performs something O(N^2).

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    Uuh... what? 100GB? Not with this code. Sounds like you have a bug elsewhere. – Lundin Jun 1 '16 at 10:35
  • You could try to break it into multiple statements (bool x1 = l[0] && l[1] && l[2]; bool x2 = l[3] && l[4] && l[5]; bool x3 = x1 || x2; ) – Thilo Jun 1 '16 at 10:38
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    @Lundin It simplified example, of course. I can't show the real one, but the idea stays the same. Imagine that 'return' line contains several thousands of boolean expressions. – CaptainTrunky Jun 1 '16 at 10:39
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    If the shown example code reproduces the problem when you use the actual expression, then I would recommend reporting a bug to gcc bugtracker with the reproducing example code. – eerorika Jun 1 '16 at 10:45
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    I tried to compile repeating of (l[0] && l[1] && l[2]) || ... in a return-statement where l is std::vector<bool> const & with g++ -c test.cpp -O3. The compilation time seems O(N^2) where N is the number of repeating. For N = 2048, 1.5 GB is used, and for N = 4096, at least 8 GB is used for my environment. – akakatak Jun 1 '16 at 12:10

The obvious optimization here is to toss out the vector and use a bit-field, based on the fastest possible integer type:

uint_fast8_t item [n];

You could write this as

#define ITEM_BYTES(items) ((items) / sizeof(uint_fast8_t))
#define ITEM_SIZE(items) ( ITEM_BYTES(items) / CHAR_BIT + (ITEM_BYTES(items)%CHAR_BIT!=0) )
uint_fast8_t item [ITEM_SIZE(n)];

Now you have a chunk of memory with n segments, where each segment is the ideal size for your CPU. In each such segment, set bits to 1=true or 0=false, using bitwise operators.

Depending on how you want to optimize, you would group the bits in different ways. I would suggest storing 3 bits of data in every segment, since you always wish to check 3 adjacent boolean numbers. This mean that "n" in the above example will be the total number of booleans divided by 3.

You can then simply iterate through the array like:

bool items_ok ()
  for(size_t i=0; i<n; i++)
    if( (item[i] & 0x7u) == 0x7u )
      return true;
  return false;

With the above method you optimize:

  • The data size in which comparisons are made, and with it possible alignment issues.
  • The overall memory use.
  • The number of branches needed for the comparisons.

This also rules out any risks of ineffectiveness caused by the usual C++ meta programming. I would never trust std::vector, std::array or std::bitfield to produce optimal code.

Once you have the above working you can always test if std::bitfield etc containers yields the very same, effective machine code. If you find that they spawned any form of unrelated madness in your machine code, then don't use them.

  • Good answer, but it would be interesting to compare with same approach, but with std::array. It should not cause much (or any?) overhead. – Erik Alapää Jun 1 '16 at 11:32
  • @ErikAlapää Having programmed to and fro in C++ for the past 20 years, I have zero trust in any container with a std:: prefix. Maybe if you have the latest and greatest version of gcc and nothing else, you'll get an equally efficient result as what I proposed here. I would never rely on that though. – Lundin Jun 1 '16 at 11:41
  • I have programmed in C++ to and fro for the last 24 years, and STL is one of the most efficient libraries in the world. When I am in plain C I miss it sorely, almost as much as I miss destructors and smart pointers. Of course, a std::vector uses malloc/new, but a std::array is pretty bare-bones. – Erik Alapää Jun 1 '16 at 11:47
  • @ErikAlapää As always, disassemble the results. Anything else is just subjective speculation over how wonderful/horrible STL is. There's the C++ fan boys who never want to hear that C++ is slower than C, and there's the old, bitter C programmers who never wants to hear that C++ is as fast as C. Unfortunately, neither will see reason even when you rub the disassembly in their face. – Lundin Jun 1 '16 at 11:55
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    Disassembly is good, facts and measurements are paramount. But some things are better in C++/STL by design, e.g. std::sort being faster than C qsort since comparison operator can be bound at compile time. – Erik Alapää Jun 1 '16 at 12:17

It's a necro-posting a little bit, but I still should share my results.

The solution proposed by Thilo in comments above is the best. It's very simple and it provides measurable compile time improvement. Just split your expression into chunks of the same size. But, in my experience, you have to choose an appropriate sub expression length carefully - you can encounter significant execution performance drop in case of large number of sub expressions; a compiler will not be able to optimize the whole expression perfectly.

  • @KennyOstrom The problem in my question is not 3SAT. But the whole project relied a lot on SAT solving and SAT-counting, so I had to perform various manipulations over Boolean expressions. I tried to implement some JIT-like techniques to improve overall performance and faced introduced problem: some Boolean expressions are too heavy for GCC. – CaptainTrunky Mar 3 '17 at 7:19

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