Analysing recursive functions (or even evaulating them) is a nontrivial task. A (in my opinion) good introduction can be found in Don Knuths Concrete Mathematics.

However, let's analyse these examples now:

We define a function that gives us the time needed by a function. Let's say that `t(n)`

denotes the time needed by `pow(x,n)`

, i.e. a function of `n`

.

Then we can conclude, that `t(0)=c`

, because if we call `pow(x,0)`

, we have to check wether (`n==0`

), and then return 1, wich can be done in constant time (hence the constant `c`

).

Now we consider the other case: `n>0`

. Here we obtain `t(n) = d + t(n-1)`

. That's because we have again to check `n==1`

, compute `pow(x, n-1`

, hence (`t(n-1)`

), and multiply the result by `x`

. Checking and multiplying can be done in constant time (constant `d`

), the recursive calculation of `pow`

needs `t(n-1)`

.

Now we can "expand" the term `t(n)`

:

```
t(n) =
d + t(n-1) =
d + (d + t(n-2)) =
d + d + t(n-2) =
d + d + d + t(n-3) =
... =
d + d + d + ... + t(1) =
d + d + d + ... + c
```

So, how long does it take until we reach `t(1)`

? Since we start at `t(n)`

and we subtract 1 in each step, it takes `n-1`

steps to reach `t(n-(n-1)) = t(1)`

. That, on the other hands, means, that we get `n-1`

times the constant `d`

, and `t(1)`

is evaluated to `c`

.

So we obtain:

```
t(n) =
...
d + d + d + ... + c =
(n-1) * d + c
```

So we get that `t(n)=(n-1) * d + c`

wich is element of O(n).

`pow2`

can be done using Masters theorem. Since we can assume that time functions for algorithms are monotonically increasing. So now we have the time `t(n)`

needed for the computation of `pow2(x,n)`

:

```
t(0) = c (since constant time needed fo computation of pow(x,0))
```

for `n>0`

we get

```
/ t((n-1)/2) + d if n is odd (d is constant cost)
t(n) = <
\ t(n/2) + d if n is even (d is constant cost)
```

The above can be "simplified" to:

```
t(n) = floor(t(n/2)) + d <= t(n/2) + d (since t is monotonically increasing)
```

So we obtain `t(n) <= t(n/2) + d`

, wich can be solved using the masters theorem to `t(n) = O(log n)`

(see section Application to Popular Algorithms in the wikipedia link, example "Binary Search").