# How can i calculate the number of times specific function will get executed in recursion

This question is in reference to blow code:

cost = [[1, 10, 75, 92],
[-1, 0, 35, 50],
[-1, -1, 0, 80],
[-1, -1, -1, 0]]

def min_cost(source, destination):
if s==d or s == d-1:
return cost[s][d]
mc = cost[s][d]
for i in range(s+1, d):
tmp = min_cost(s, i) + min_cost(i, d)
if tmp < mc:
mc = tmp
return mc


When i did dry run of same i saw min_cost(1,3) is getting executed 2 times. I read in one book where author mentioned if we had 10 stations in between then min_cost(1, 3) would run 144 times.

How can we figure out these number without actually doing dry run. I know using recursion equations we can figure out the time taken by function but how can say that a specific function will be executed this many number of times?

• Thanks for pointing it out. Just made that edit. :) – Raghav salotra Jun 5 '18 at 16:22
• Alan Turing and Gödel have proven that you can't know the number of executions of a function in a certain code without executing it. This problem is analogous to the Halting problem, that states that you cannot know in advance wether a program will halt or not during the execution. en.wikipedia.org/wiki/Halting_problem – David Lemon Jun 12 '18 at 14:40

While I understand that you don't want a dry run to just count the calls, I'd like to nevertheless do it first, just to see what's going on. So, here goes:

def min_cost(s, d):
global count
count += 1
if s==d or s == d-1:
return cost[s][d]
mc = cost[s][d]
for i in range(s+1, d):
tmp = min_cost(s, i) + min_cost(i, d)
if tmp < mc:
mc = tmp
return mc

for n in range (2, 8):
cost = [[0 for i in range (n)] for j in range (n)]
count = 0
min_cost(0, n-1)
print (str (n) + ': ' + str (count))


The output is:

2: 1
3: 3
4: 9
5: 27
6: 81
7: 243


So, we see that the number of calls for d-s=k is 3 to the power of (k-1). Knowing what we have to prove sometimes greatly simplifies finding the proof.

Now, to the proof itself. It will be proof by induction. First, note that the number of calls of min_cost(s, d) depends only on the value of d-s, and not on the individual values of s and d.

The base is that, for d-s=1, we get one call. For d-s>1, we make our one call, and from it the following calls:

min_cost(s, s+1) and min_cost(s+1, d)
min_cost(s, s+2) and min_cost(s+2, d)
...
min_cost(s, d-1) and min_cost(d-1, d)


So, for d-s=k, the number of calls f(k) is:

f(k) = 1 +
f(1) + f(k-1) +
f(2) + f(k-2) +
... +
f(k-1) + f(1)
= 2 * (f(1) + f(2) + ... + f(k-1))


If, by the induction hypothesis, we have already proved that f(v) = 3v for all v < k, then the f(k) is:
1 + 2 * (31 + 32 + ... + 3k-1), which is trivially 3k, completing our proof.

Lastly, note that, while the presented algorithm is exponential, the underlying problem can be solved in polynomial time, most simply in O((d-s)^2) by memoizing the calls for which we already did all the work.

• I think that the idea of counter as you have done is perfect. – SaidbakR Jun 5 '18 at 17:35
• @Gassa Yes there is a polynomial solution for this as well . My motivation over here was to come up with hypothesis using which i can predict the # of calls for some input given. Thanks for Answer. – Raghav salotra Jun 5 '18 at 17:57
• @Gassa: very nice intuition, running the code with a counter, then proving the "guess" by induction. Of course, this works for simple formulas. Otherwise, Master Theorem (see CLRS) should have you covered, once you have the recurrence relations. – Mircea Jun 12 '18 at 12:52

There are several options to calculate that amount when one is working with recursion. The simplest would be to add another variable to the recursive method which is increased every time it gets recursed and in the last statement where it is returned it does not increment, but just return the last amount, which will recursive 'back' to the upper request.

Example in pseudo code:

function recursionfunction(x, y, recursioncount) {
if(expressionIsFalse) {
recursionfunction(x, y, recursioncount+1);
} else {
return recursioncount;
}
}

print recursionfunction('','', 0);


Another way of working is assigning a variable by reference, a pointer or a global variable (depending on the programming language) and incrementing that counter.