These kind of questions always require a mixture of mathematical insight and efficient programming. They don't want brute force.

## First Insight

Numbers can be grouped according to how they will pair with other groups.

Putting them into:

```
1 - 50 | 51 - 75 | 76 - 100
A | B | C
```

- Group
`A`

can pair with anything.
- Group
`B`

can pair with `A`

and `B`

, and `possibly`

`C`

- Group
`C`

can pair with `A`

and `possibly`

`B`

, but not `C`

The `possibly`

is where we need some more insight.

## Second Insight

For each number in B we need to check how many numbers there are up to its complement with 150. For example, with `62`

from group `B`

we want to know from group `C`

how many numbers are less than or equal to `88`

.

For each number in `C`

we add up the tallies up to it, e.g. tallies for 76, 77, 78, ..., 88. This is known mathematically as the partial sum.

In the standard library there is a function which produces a `partial_sum`

```
vector<int> tallies(25); // this is room for the tallies from C
vector<int> partial_sums(25);
partial_sum(tallies.begin(), tallies.end(), partial_sums.begin());
```

Symmetry means this sum only needs to be done for one group.

## Third (much later) insight

Calculating the totals for group `A`

and `B`

can be done using `partial_sum`

, too. So rather than only calculating for group `C`

, and having to track the totals some other way, just store the totals for each number from 1 to 100, and then create the partial_sum over the whole thing. `partial_sums[50]`

will give you the amount of numbers less than or equal to 50, partial_sums[75] those less than or equal to 75, and partial_sums[100] should be 10 million, i.e. all the numbers less than or equal to 100.

Finally we can calculate the combinations from `B`

and `C`

. We want to add together all the multiples of totals for 50 and 100, 51 and 99, 52 and 98, etc. we can do this by iterating through the tallies from 50 to 75 and the partial_sums from 100 to 75. There is a standard library function `inner_product`

which can handle this.

This seems quite linear to me.

```
random_device rd;
mt19937 gen(rd());
uniform_int_distribution<> dis(1, 100);
vector<int> tallies(100);
for(int i=0; i < 10000000; ++i) {
tallies[dis(gen)]++;
}
vector<int> partial_sums(100);
partial_sum(tallies.begin(), tallies.end(), partial_sums.begin());
int A = partial_sums[50];
int AB = partial_sums[75];
int ABC = partial_sums[100];
int B = AB - A;
int C = ABC - AB;
int A_match = A * ABC;
int B_match = B * B;
int C_match = inner_product(&tallies[50], &tallies[75],
partial_sums.rend(), 0);
```