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) = 3^{v} for all v < k, then the f(k) is:

1 + 2 * (3^{1} + 3^{2} + ... + 3^{k-1}), which is trivially 3^{k}, 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.