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Is it possible to optimize a series of "glued together" std::functions and/or is there any implementation that attempts to do this?

What I mean is most easily expressed mathematically: say I want to make a std::function that is a function of a function:

f(x,y,z) = x^2 * y^3 * z^4
g(x,y,z) = f(x,y,z) / (x*y^2)

Is there a way for an STL/compiler implementor to optimize away parts of the arithmetic is calling a function object of g, created from a function object of f?

This would be a kind of symbolic simplification of the functions, but because this is a std::function, it would have to be spotted on a machine level.

Due to this being an optimization, which takes time, and probably isn't free (in clock cycles and/or memory), it probably isn't allowed by the Standard? It leans very close to a language that is typically ran through a VM. (I'm thinking LLVM more than Java here, with runtime optimizations).

EDIT: In order to make the discussion "more useful", here's a short code snippet (I understand a lambda is not a std::function, but a lambda can be stored in a std::function, so assuming auto below means std::function<T> with the appropriate T will express perfectly what I meant above):

auto f = [](const double x, const double y, const double z){ return x*x*y*y*y*z*z*z*z; };
auto g = [](const double c, const double y, const double z){ return f(x,y,z)/(x*y*y); };

A "trivial" compiler would make g equivalent to

double g(const double x, const double y, const double z){ return x*x*y*y*y*z*z*z*z/(x*y*y); }

While an optimized std::function could make it (mathematically and in every other sense correct!):

double g( const double x, const double y, const double z){ return x*y*z*z*z*z; }

Note that although I'm talking about mathematical functions here, similar transformations could be made for functions in the general sense, but that would take more introspection, which means overhead.

I can see this being very important when designing mathematical and physics simulations, where the generality of compositing existing library functions into user-case functions, with all the usual mathematical simplifications could make for a nice method of expressive, yet performant calculation software.

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Optimization is allowed by the standard. There is nothing in the standard to say "thou shalt not optimize". (Well, there are some caveats around volatile in particular, but not for the code you are asking about.) It is perhaps more a question of whether the compiler can safely make the optimization, and whether it is worth the compiler writers' time to look for the optimization. –  Jonathan Leffler Jul 21 '11 at 14:53
I don't think it's forbidden by the standard, because it takes time. But it probably is forbidden, because it changes the semantics. For x == 0 or y == 0, the unoptimized version gives NaN, the optimized would simple return 0. –  Henrik Jul 21 '11 at 14:55
I would guess this kind of optimization is possible with constexpr functions. –  Richard Jul 21 '11 at 14:56
@duedl0r: yes, if x, y and z are of type float or double, I would expect g(0,0,0) to calculate 0 / 0 and thus return NaN. –  Henrik Jul 21 '11 at 15:16
I don't understand what it has to do with std::function (and c++0x). You need to show the code to make discussion useful. –  Gene Bushuyev Jul 21 '11 at 17:42
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2 Answers 2

up vote 4 down vote accepted

This is why you leave the optimizing to the compiler. They're algebraically equivalent but not equivalent due to FP imprecision. Your two versions of g would yield subtly different answers, which could be very important if called in an inner loop- not to mention the behavioural difference if x, y, z was 0.

Secondly, as the contents of function are unknown until run-time, there's no way the compiler could perform such optimizations as it doesn't have the data it needs.

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The compiler is allowed to optimize in specific allowed cases, or if the optimized code behaves "as if" it were the unopotimized code.

In this case not only would x or y being 0 change the results, but if f overflowed, or the data types were floating point or user defined the results could change as a result of such optimization. Thus I suspect in practice you'll never see it happen and would have to (if possible) compose a combined function at compile time (presumably using templates).

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Note that, at least in C, if undefined behavior such as overflow or division by zero occurs, then the program is allowed to do anything—and as a consequence, optimizations are free to ignore those cases, such as (not that any compiler necessarily does this, nor is it necessarily an optimization) optimizing x*x + x*y + y*y to (x+y)*(x+y). –  Antal S-Z Jul 21 '11 at 16:08
undefined behavior is not a side effect to prevent optimization, it's a license to a compiler to do (almost) anything :-) –  Gene Bushuyev Jul 21 '11 at 17:40
@Antal: Except that those two aren't equivalent ;-) ((x+y)*(x+y) is equivalent to x*x + 2*x*y + y*y). In addition, it is only actual overflow that yields undefined behavior, not potential overflow: if the compiler does perform some sort of arithmetic transformation, it must ensure that for any inputs into the original expression that yield valid results, the transformed expression yields the same valid results. –  James McNellis Jul 21 '11 at 20:40
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