One way of using multi-threading for Q2 is to do it in two passes (each using T threads internally, where T can be chosen freely):

Compute `c[i] = a[i] + b[i] + c[i-1]`

for all cells in the usual multi-threaded fashion, i.e. after dividing the input into ranges [0,r1), [r1,r2), ... [rk,n) and applying one thread to each range. Yes, this will be incorrect for all ranges except the first one, and step 2 will correct it.

Compute corrections, again in a multi-threaded fashion. For this, we look up the right-most value of each range, i.e. `corr1:=c[r1-1]`

, `corr2:=corr1+c[r2-1]`

, `corr3:=corr2+c[r3-1]`

etc., which gives us the *correcting value* for each thread, and then calculate, again using multi-threading with the same ranges as before, `c[i] += corrk`

where `corrk`

is the thread-specific correcting value for the k-th thread. (For the zeroth thread, we can use `corr0:=0`

, so that thread doesn't need to do anything.)

This improves the theoretical running time by a factor T where T is the number of threads (which can be chosen freely), so it's an optimal solution as far as multithreading is concerned.

To illustrate how this works, here is an example where we assume arrays of length `n==30`

. We further assume that we use 3 threads: One to compute the range `c[0..9]`

, one for `c[10..19]`

and one for `c[20..29]`

.

Clearly, the goal is that in cell `c[i]`

, for any `0<i<n`

, we get

```
c[i] == a[0]+...+a[i]+b[0]+...+b[i]
```

(i.e., the sum of all `a[0..i]`

and all `b[0..i]`

) after the algorithm has finished. Let's have a look at how the algorithm gets there, for an example cell `i==23`

. This cell is handled by the third thread, i.e. the thread responsible for the range `c[20..29]`

.

Step 1: The thread sets

```
c[20] = a[20]+b[20]
c[21] = c[20]+a[21]+b[21] == a[20]+a[21]+b[20]+b[21]
c[22] = c[21]+a[22]+b[22] == a[20]+a[21]+a[22]+b[20]+b[21]+b[22]
c[23] = c[22]+a[23]+b[23] == a[20]+a[21]+a[22]+a[23]+b[20]+b[21]+b[22]+b[23]
...
```

So, after step 1 has finished, we have the some of `a[20..23]`

and `b[20..23]`

in cell `c[23]`

. What is missing, is the sum of `a[0..19]`

and `b[0..19]`

.

Similarly, the first and second threads have set the values in `c[0..9]`

and `c[10..19]`

such that

```
c[0] = a[0]+b[0]
c[1] = c[0]+a[1]+b[1] == a[0]+a[1]+b[0]+b[1]
...
c[9] = a[0]+...+a[9]+b[0]+...+b[9]
```

and

```
c[10] = a[10]+b[10]
...
c[19] = a[10]+...+a[19]+b[10]+...+b[19]
```

Step 2: The correcting value for the third thread, `corr2`

is the sum of `corr1`

and the right-most value computed by the second thread, while `corr1`

is the right-most value computed by first thread. Hence

```
corr2 == c[9]+c[19] == (a[0]+...+a[9]+b[0]+...+b[9]) + (a[10]+...+a[19]+b[10]+...+b[19])
```

And this is indeed the sum missing from the value of `c[23]`

after step 1. In step 2, we add this value to all elements `c[20..29]`

, hence, after step 2 has finished, `c[23]`

is correct (and so are all other cells).

The reason why this works is that the calculation of the cell values is a left-to-right, strictly incremental operation, and the order of operations for the calcuation of a single cell doesn't matter (because `+`

is associative and commutative). Hence the end-result ("right-most value") of any given thread after step 1 can be used to correct the results of threads responsible for the ranges to its right in step 2.