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As I understand it normal C++ code is translated into assembler at compile time, which is then executed by the CPU at run-time. So I do not quite understand what the fuss is with the advantages of template metaprogramming?

Wikipedia says the following about template metaprogramming:

Template metaprogramming is a metaprogramming technique in which templates are used by a compiler to generate temporary source code, which is merged by the compiler with the rest of the source code and then compiled. The output of these templates include compile-time constants, data structures, and complete functions. The use of templates can be thought of as compile-time execution.

This didn't really seem to emphasise the advantages of template metaprogramming to me...?

I'm asking because I am interested in what template metaprogramming could do for optimizing/improving efficiency of low latency C++ applications. I have probably not understood something correctly along the way, so please feel free to correct my understanding.

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You won't understand it until you need to do it. – Seth Carnegie Feb 23 '13 at 20:13
@SethCarnegie do you have any examples where you have found it extremely useful? – user997112 Feb 23 '13 at 20:27
@user997112 matrix multiplication is one application where the use of template metaprogramming can avoid many costly temporaries in complex expressions involving matrix operations. – juanchopanza Feb 23 '13 at 20:32
up vote 3 down vote accepted

Have you read the zillions of articles out there that thoroughly discuss TM? For example:

A simple way of looking at (one kind) of template metaprogramming is as "strong" memoization. A common example is the following:

Lets say your program needs the compute a factorial for some number. With TM you can compute the factorial in compile-time, which increases compile time (and binary size) but decreases runtime. The example code is from the 2nd site above; if you were doing it the "naive" way, you'd have code that looks like:

int factorial( int n) {
    return (n==0) ? 1 : n*factorial(n-1)l

int main() {
    cout << factorial(5) << endl;
    return 0;

With TM we can compute the factorial at compile-time:

// factorial.cpp

#include <iostream>

template <int N>
struct Factorial {
    enum { value = N * Factorial<N-1>::value };

template <>
struct Factorial<1> {
    enum { value = 1 };

// example use
int main() {
    const int fact5 = Factorial<15>::value;
    std::cout << fact5 << endl;
    return 0;

Here Factorial<15>::value is essentially a compile-time constant. As always, simplistic examples aren't particularly useful, but hopefully you get the gist of it.

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Ok but the fact does remain that this would be only useful if I always wanted to know factorial 15 in my run-time execution? I appreciate it was a simple example- but (the factorial example is the usual example for explaining TMP) if I had a calculator with a factorial button, I could have just declared a const int and then used my calculator to get he value, rather than writing all that code? – user997112 Feb 23 '13 at 20:28
You're right; this is what TM is very often used for: generating compile-time lookup tables. Even though this may seem trivial, there are clever TM implementations of stuff like crc32 and md5 (that take advantage of similarly-constructed lookup tables) that increase hashing performance noticeably. Consider a calculation that's not as simple as doing 5! on your calculator. – David Titarenco Feb 23 '13 at 20:33
@user997112 so each time you needed a new factorial, you would get your calculator, calculate the number, type it into your program, instead of writing Factorial<TheNumber>::value? – juanchopanza Feb 23 '13 at 20:34
@user997112 Yes. I need 345 factorial. I use a template. You have to calculate it first, then put it into your code. If you want to do that, then fine. – juanchopanza Feb 23 '13 at 20:52
@user997112: It's also more expressive to use a template. Consider 12! which happens to be 479001600. You'll have const long blah = 479001600. What does that mean to anyone? I'll have const long blah = Factorial<12>::value -- I guess you could add a comment, but then you have to change comments every time you change values. Using templates has clear advantages here. – David Titarenco Feb 23 '13 at 20:56

Another example would be how to calculate the Fibonacci Sequence.

Normal recursive way to do it :

uint64_t fibonacci(int n) {
    if (n <= 2)
        return 1;
        return fibonacci(n - 1) + fibonacci(n - 2);

Using metaprogramming :

template< int n > struct Fibonacci {
    static const uint64_t value = Fibonacci< n-1 >::value +  Fibonacci< n-2 >::value;

template<> struct Fibonacci< 1 > {
    static const uint64_t value = 1;

template<> struct Fibonacci< 0 > {
    static const uint64_t value = 0;

Now you can try by yourself to call fibonacci(80) or Fibonacci<80>::value. The recursive function will probably not work and crash, the one using metaprogramming will be perfectly fine and quite fast.

share|improve this answer
how does the Compiler avoid the big recursion (without tail recursion)? – Sebastian Godelet Feb 24 '13 at 12:53

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