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I don't understand this example I came across:

int Multiply(int x, int m){
    return x * m;}

template<int m>
int MultiplyBy(int x){
    return x * m;}

int a,b;
a = Multiply(10,8);
b = MultiplyBy<8>(10);

In the above example the template function is faster than the simple function because the compiler knows that it can multiply by a power of 2 by using a shift operation. x*8 is replaced by x << , which is faster. In the case of the simple function, the compiler doesnt know the value of m and therefore cannot do the optimization unless the function can be inlined.

As I understand it, the reason the template can optimize is because the compiler knows the value of the argument (8) at compile-time, whereas the simple function will not know the value of x (or m) until run-time. So how is inlining the simple function going to change this fact? Inlining doesn't provide any run-time knowledge of the argument value??

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The template version is faster because you're hard-coding one of the operands. Inlining both versions will produce markedly different code, and a dump-to-assembly and examination of said-same will likely reveal this. Will it further be enhanced since it is a power of two? Perhaps. – WhozCraig Mar 20 '13 at 18:54
up vote 4 down vote accepted

Inlining doesn't provide any run-time knowledge of the argument value??

Inlining per se doesn't. However, since the second argument is a compile-time constant, the compiler can propagate that constant into the inlined function.

Since the first argument is also a compile-time constant, the entire

a = Multiply(10,8);

can be replaced with

a = 80;

In fact, this is precisely what my compiler (gcc 4.7.2) does when I turn on optimizations.

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In fact, it does more optimizations than just the above complete elimination of the multiplication when both args are compile-time constants. For example, if one argument is compile-time constant, on some x86 CPUs, it implements the complete table from section 9.2 of… plus more for other simple decompositions. – FrankH. Mar 26 '13 at 14:14
a = Multiply(10,8);

Let's manually inline the function call:

a = 10 * 8;

Now, of course 8 is a compile-time constant here, so the compiler can use the bit-shift optimization as described. However, it would likely perform a better optimization and just replace 10 * 8 with 80. Compilers are very smart - given a constant expression, such as 10 * 8, they can work out the result at compile time.

That would be different had you done:

int x;
std::cin >> x;
a = Multiply(10,x);

If you inline Multiply here, you get:

int x;
std::cin >> x;
a = 10 * x;

The compiler doesn't know the value of x at compile-time and therefore can't optimize this in the same way.

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