The values come from an examination from the algorithm `T`

. For example, when you have a simple loop:

```
for (i=0; i < n; ++i) {
sum += i;
}
```

then you perform the operations `i<n`

, `++i`

and `sum+=i`

n times, and `i=0`

once. So `f(n)==n`

, `c==4`

(for the four operations, elevating the "once" to "n times" for correctness of values), `x==1`

(for `n==0`

, you still perform `i=0`

and `i<n`

, so the formula would not work). This gives you an O(n) performance (linear in the number of inputs).

For the nested loops:

```
for (i=0; i < n; ++i) {
for (j=0; j<n; ++j) {
sum += j;
}
}
```

The calculations are similar, with `f(n)==n^2`

, giving you O(n^2).

So there is no cut-n-dry way of telling the exact values of `c`

and `x`

, but most of the time the hard part is coming up with `f`

-- and the "smallest" of that too (an O(n^2) algorithm is also an O(n^3) algorithm according to the definition you provided, but you want to characterize that algorithm with O(n^2) instead of O(n^3)). The ordering of `f`

s is based on their growth when `n`

approaches infinity: `f(n)=n^3`

grows slower than `f(n)=2^n`

, even if for small `n`

s the former is larger than the latter.

Note that in theory the actual values of `x`

and `c`

become irrelevant as `n`

approaches infinity, that is why they don't show up in the `O(n)`

notation itself. This does not mean, however that for (relatively) small values if `n`

, the number of instructions are not much larger than `f(n)`

(e.g. you have 1000 instructions within the for loop).

Also, the O(n) notation gives you *worst* performance, which might be much higher than what you observe in real life (average-case cost) or in the overall usage of a data structure (amortized cost), for example.