To figure this one out, let's imagine rewriting this code in an equivalent way:
public static int F (int N) {
if ( N == 1 ) return 1;
int k = F(N - 1);
return F(N - k);
}
All I've done here is pull out the inner call to F(N - 1)
and move it to the top-level so that we can more clearly see that this code makes two calls to F
and that the second call is to a subproblem that depends on the first call.
To determine the runtime here, we'll need to figure out what k is so we can see what kind of recursive call we're making. Interesting, it turns out that F(N) = 1 for all N. You can spot this pattern here:
- F(1) = 1.
- F(2) = F(2 - F(1)) = F(2 - 1) = F(1) = 1
- F(3) = F(3 - F(2)) = F(3 - 1) = F(2) = 1
- F(4) = F(4 - F(3)) = F(4 - 1) = F(3) = 1
It's a great exercise to prove this by induction.
So this means that the call to F(N - k) will call F(N - 1). This means that the code is functionally equivalent to
public static int F (int N) {
if ( N == 1 ) return 1;
int k = F(N - 1);
return F(N - 1);
}
This has recurrence relation
- F(1) = 1
- F(n) = 2F(n-1) + 1
Which solves F(n) = 2n - 1. (Again, you can formally prove this by induction if you'd like). Therefore, the complexity is Θ(2n).
To validate this, here's a (really hacky) C script that calls the function on a number of different inputs, reporting the returned value and the number of calls made:
#include <stdio.h>
/* Slightly modified version of F that tracks the number of calls made
* using the second out parameter.
*/
static int F (int N, int* numCalls) {
/* Track the number of calls. */
(*numCalls)++;
if ( N == 1 ) return 1;
return F (N - F (N-1, numCalls), numCalls);
}
int main() {
for (int i = 1; i < 10; i++) {
int numCalls = 0;
int result = F(i, &numCalls);
printf("F(%d) = %d, making %d calls.\n", i, result, numCalls);
}
}
The output is
F(1) = 1, making 1 calls.
F(2) = 1, making 3 calls.
F(3) = 1, making 7 calls.
F(4) = 1, making 15 calls.
F(5) = 1, making 31 calls.
F(6) = 1, making 63 calls.
F(7) = 1, making 127 calls.
F(8) = 1, making 255 calls.
F(9) = 1, making 511 calls.
Notice that evaluating F(i) always takes 2i - 1 calls (just as the theory predicted!) and always returns 1, empirically validating the mathematical analysis.