If you check the Conway's Game of Life you will find that there is a lot in common with the Race Problem.

Here is the analogy:

- The initial state (the seed of the system):
- Game of Life: initial pattern on the grid. Every cell having the following parameters:
- x and y coordinate
- whether the cell is alive or dead

- Race Problem: n cars each one having predetermined parameters and the length of the track l. Every car has the following parameters:
- top speed
- acceleration
- handling factor
- position on track
- current speed

- The rules are applied at discrete moments which are called ticks.
- Game of Life: the rules are applied simultaneously to every cell from the previous generation producing a next generation. Each generation is a pure function of the preceding one.
- Race Problem: the rules are applied simultaneously to every car from the previous state producing a next state. This happens every 2 seconds. Same as in Game of Life each step is a pure function of the preceding one which means that it only depends on the parameters of the cars from the previous state.

What's different is that the Game of Life never ends whereas the Race Problem should terminate when the current position of every car is greater or equal to the track length l (Although the last statement is arguable: due to the handling factor it's possible that in some conditions some cars will never reach the finish line).

The key point is that **calculations are done at discrete moments** which answers your question:

But how can I figure out at what instance I should make the calculations?

You can take the idea from the Algorithms section to solve this problem. You need to have 2 arrays of cars: one representing the current state and the other representing the next step. On each iteration you recalculate the current position and the speed of every car following the rules from the assignment and check whether the loop should terminate. Before the next iteration you swap the array roles so that the successor array in the last iteration becomes the current array in the next iteration.

The high level pseudo-code may look like this:

```
n = ..; // initial number of cars
l = ..; // track length
Car[] currentState = initializeState(n, l);
Car[] nextState = clone(currentState);
for (int iteration = 0; iteration < MAX_ITERATIONS; iteration++) {
calculateNextState(currentState, nextState, iteration);
swap(currentState, nextState);
if (shouldTerminate(currentState, l) {
break;
}
}
printResultOrClaimNotTerminated(currentState);
```

The rules are applied in the calculateNextState(..) function. In the most naive implementation you check every pair of cars which gives you

`O (C(n, 2)) = O (n * (n - 1) / 2) = O (n ^ 2)`

complexity for each iteration. However you can think of possible optimizations here. For example you can **sort the cars by current position** first (`O (n * log(n))`

) and then traverse the sorted array checking only adjacent cars (`O (2 * n)`

). You can do this since if the 10 meters condition doesn't satisfy for adjacent cars it won't satisfy for non-adjacent cars. This will give you the resulting complexity of:

```
O (n * log(n))
```

which is much better. The sorted array of cars will naturally give you the car with last position to which you need to apply the nitro boost rule. Probably there can be other optimizations. This answers your question:

For each instance should I be checking all C(n,2) combinations of every pair of drivers and compute the result?