# Calculate the Fibonacci number (recursive approach) in compile time (constexpr) in C++11

I wrote the program Fibonacci number calculation in compile time (constexpr) problem using the template metaprogramming techniques supported in C++11. The purpose of this is to calculate the difference in the run-time between the template metaprogramming approach and the old conventional approach.

``````// Template Metaprograming Approach
template<int  N>
constexpr int fibonacci() {return fibonacci<N-1>() + fibonacci<N-2>(); }
template<>
constexpr int fibonacci<1>() { return 1; }
template<>
constexpr int fibonacci<0>() { return 0; }

// Conventional Approach
int fibonacci(int N) {
if ( N == 0 ) return 0;
else if ( N == 1 ) return 1;
else
return (fibonacci(N-1) + fibonacci(N-2));
}
``````

I ran both programs for N = 40 on my GNU/Linux system and measured the time and found that that conventional solution (1.15 second) is around two times slower than the template-based solution (0.55 second). This is a significant improvement as both approaches are based on the recursion.

To understand it more I compiled the program (-fdump-tree-all flag) in g++ and found that compiler actually generated the 40 different functions (like fibonacci<40>, fibonacci<39>...fibonacci<0>).

``````constexpr int fibonacci() [with int N = 40] () {
int D.29948, D.29949, D.29950;
D.29949 = fibonacci<39> ();
D.29950 = fibonacci<38> ();
D.29948 = D.29949 + D.29950;
return D.29948;
}

constexpr int fibonacci() [with int N = 39] () {
int D.29952, D.29953, D.29954;
D.29953 = fibonacci<38> ();
D.29954 = fibonacci<37> ();
D.29952 = D.29953 + D.29954;
return D.29952;
}
...
...
...
constexpr int fibonacci() [with int N = 0] () {
int D.29962;
D.29962 = 0;
return D.29962;
}
``````

I also debugged the program in GDB and found that all the above functions are executed an equal number of times as with the conventional recursive approach. If both versions of the program are executing the function an equal number of times (recursive), then how is this achieved by template metaprogramming techniques? I would also like to know your opinion about how and why a template metaprogramming based approach is taking half time compared to the other version? Can this program be made faster than the current one?

Basically my intention here is to understand what's going on internally as much as possible.

My machine is GNU/Linux with GCC 4.8.1, and I used the optimization `-o3` for both programs.

• Don't use simple `f(n) = f(n - 1) + f(n - 2)` formula to calculate Fibonacci numbers. Mar 25, 2014 at 20:30
• Are the times you reported from executing debug code or non-debug code? Mar 25, 2014 at 20:40
• @Constructor which method do you prefer? I personally like raising a {1,1 \n 1, 0} matrix to power n-1, and taking the top-left variable for the answer. I found it takes to perform extremely fast, if done properly. You can also add the matrix-to-2^k hack for even more speed. Anyway, unto the question, it's generally a bad idea to template-of-template, too much space.
– user1241335
Mar 25, 2014 at 20:42
• @Shingetsu Yes, it is the fastest solution (with logarithmic time complexity). But I meant that simple formula is not appropriate due to numerous and meaningless recursive calls. Mar 25, 2014 at 20:57

Try this:

``````template<size_t N>
struct fibonacci : integral_constant<size_t, fibonacci<N-1>{} + fibonacci<N-2>{}> {};

template<> struct fibonacci<1> : integral_constant<size_t,1> {};
template<> struct fibonacci<0> : integral_constant<size_t,0> {};
``````

With clang and `-Os`, this compiles in roughly 0.5s and runs in zero time for `N=40`. Your "conventional" approach compiles in roughly 0.4s and runs in 0.8s. Just for checking, the result is `102334155` right?

When I tried your own `constexpr` solution the compiler run for a couple of minutes and then I stopped it because apparently memory was full (computer started freezing). The compiler was trying to compute the final result and your implementation is extremely inefficient to be used at compile time.

With this solution, template instantiations at `N-2`, `N-1` are re-used when instantiating `N`. So `fibonacci<40>` is actually known at compile time as a value, and there is nothing to do at run-time. This is a dynamic programming approach and of course you can do the same at run time if you store all values at `0` through `N-1` before computing at `N`.

With your solution, the compiler can evaluate `fibonacci<N>()` at compile time but is not required to. In your case, all or part of computation is left for run time. In my case, all computation is attempted at compile time, hence never ending.

• I think it can be done shorter using the code from the question: `template<size_t N> struct Fibonacci : std::integral_constant<size_t, fibonacci<N>()> {}; Mar 25, 2014 at 20:59
• @Constructor Well, this is meant as an alternative implementation. As I said, the `constexpr` solution of the question never managed to compile for `N=40`. It appears template instantiations are memoized, while results of `constexpr` function calls are not.
– iavr
Mar 25, 2014 at 21:01
• I think that there is a problem (possibly a bug) in clang. Compare: gcc `N = 40`, clang `N = 26` and clang `N = 27` (the result for clang is same for all `N > 26`). Mar 25, 2014 at 21:14
• Not really, for me at least. `121393`, `196418`, `102334155` for `N=26,27,40` for both gcc and clang.
– iavr
Mar 25, 2014 at 21:20
• It is strange. I think that the maximum step of constexpr evaluation mentioned by clang (`N = 27` in my example) should be specified in the its setting. Mar 25, 2014 at 21:44

The reason is that your runtime solution is not optimal. For every fib number, functions are called several times. The fibonacci sequence, has overlapping subproblems, so for example `fib(6)` calls `fib(4)`, and `fib(5)` also calls `fib(4)`.

The template based approach, uses (inadvertently) a Dynamic Programming approach, meaning that it stores values for previously calculated numbers, avoiding repetition. So, when `fib(5)` calls `fib(4)`, the number was already calculated when `fib(6)` did.

I recommend looking up "dynamic programming fibonacci" and trying that, it should speed things up dramatically.

• Thanks for your explanation and suggestion.But I had mentioned in my question that in both cases number of function calls were same so you still think that template based uses dynamic programming approach. Yes I am aware about the dynamic programming approach would speed up things but I wanted to check the difference in two by using recursive(slower) approach. Mar 26, 2014 at 2:12
• @tmp are you sure it has the same number of calls? It doesnt make sense that a template with a given parameter set gets instantiated more than once. It is not even a function call to begin with. Mar 26, 2014 at 2:22

Adding -O1 (or higher) to GCC4.8.1 will make fibonacci<40>() a compile time constant and all the template generated code will disappear from your assembly. The following code

``````int foo()
{
return fibonacci<40>();
}
``````

will result in the assembly output

``````foo():
movl    \$102334155, %eax
ret
``````

This gives the best runtime performance.

However, it looks like you are building without optimizations (-O0) so you get something quite a bit different. The assembly output for each of the 40 fibonacci functions look basically identical (except for the 0 and 1 cases)

``````int fibonacci<40>():
pushq   %rbp
movq    %rsp, %rbp
pushq   %rbx
subq    \$8, %rsp
call    int fibonacci<39>()
movl    %eax, %ebx
call    int fibonacci<38>()
popq    %rbx
popq    %rbp
ret
``````

This is straight forward, it sets up the stack, calls the two other fibonacci functions, adds the value, tears down the stack, and returns. No branching, and no comparisons.

Now compare that with the assembly from the conventional approach

``````fibonacci(int):
pushq   %rbp
pushq   %rbx
subq    \$8, %rsp
movl    %edi, %ebx
movl    \$0, %eax
testl   %edi, %edi
je  .L2
movb    \$1, %al
cmpl    \$1, %edi
je  .L2
leal    -1(%rdi), %edi
call    fibonacci(int)
movl    %eax, %ebp
leal    -2(%rbx), %edi
call    fibonacci(int)
.L2:
popq    %rbx
popq    %rbp
ret
``````

Each time the function is called it needs to do check if N is 0 or 1 and act appropriately. This comparison is not needed in the template version because it is built into the function via the magic of templates. My guess is that the un-optimized version of the template code is faster because you avoid those comparisons and would also not have any missed branch predictions.

• I did tried all the optimization flag(o1 o2 o3) and did not find any such thing on my terminal. Did you see it in your case which you have explained or it is just your assumption. Mar 26, 2014 at 2:00
• I verified it using gcc.godbolt.org and all of the assembly output I show is a cut and paste from there. I made no assumptions. Mar 26, 2014 at 17:26
• I don't believe this is making use of c++ constexpr, simply the compiler optimizer doing something which is good, but not guaranteed. Apr 30, 2017 at 9:36

Maybe just use a more efficient algorithm?

``````constexpr pair<double, double> helper(size_t n, const pair<double, double>& g)
{
return n % 2
? make_pair(g.second * g.second + g.first * g.first, g.second * g.second + 2 * g.first * g.second)
: make_pair(2 * g.first * g.second - g.first * g.first, g.second * g.second + g.first * g.first);
}

constexpr pair<double, double> fibonacciRecursive(size_t n)
{
return n < 2
? make_pair<double, double>(n, 1)
: helper(n, fibonacciRecursive(n / 2));
}

constexpr double fibonacci(size_t n)
{
return fibonacciRecursive(n).first;
}
``````

My code is based on an idea described by D. Knuth in the first part of his "The Art of Computer Programming". I can't remember the exact place in this book, but I'm sure that the algorithm was described there.

• Why do you use `double`? Mar 25, 2014 at 21:48
• Numbers in Fibonacci sequence grow very fast so we need to prevent overflowing. Mar 25, 2014 at 21:50
• Not so fast to cause an overflow of `int` for `N = 40`. Mar 25, 2014 at 21:55
• How do you measure speed? Seems to me it doesn't work slowly Mar 25, 2014 at 22:01
• What speed do you mean? I meant that `f(40) < std::numeric_limits<int>::max()`. Mar 26, 2014 at 8:20