Let's assume square matrices.

If you count the number of additions (there are no subtractions) in classic matrix multiplication, you get N^3 additions. There are N^2 elements, and each element is the dot-product of a row and column consisting of N-1 additions, so almost exactly N^3 additions.

To count the number of additions in divide-and-conquer matrix multiplication, let's see how it works:

*Split up NxN matrix into four (N/2)x(N/2) matrices, then treat it as a 2x2 matrix and perform block multiplication recursively.* For example multiplying two 8x8 matrices:

```
┌┌A A A A┐┌B B B B┐┐ ┌┌a a a a┐┌b b b b┐┐
││A A A A││B B B B││ ││a a a a││b b b b││
││A A A A││B B B B││ ││a a a a││b b b b││
│└A A A A┘└B B B B┘│ │└a a a a┘└b b b b┘│
│┌C C C C┐┌D D D D┐│*│┌c c c c┐┌d d d d┐│
││C C C C││D D D D││ ││c c c c││d d d d││
││C C C C││D D D D││ ││c c c c││d d d d││
└└C C C C┘└D D D D┘┘ └└c c c c┘└d d d d┘┘
```

The new matrix will be:

```
┌┌ ┐┌ ┐┐
││ Aa+Bc ││ Ab+Bd ││
││ ││ ││
│└ ┘└ ┘│
│┌ ┐┌ ┐│
││ Ca+Dc ││ Cb+Dd ││
││ ││ ││
└└ ┘└ ┘┘
(where for example Aa is a 4x4 matrix multiplication)
```

Each multiplication of [N/2xN/2]*[N/2xN/2] is a subproblem of size N/2. We must do 8 of these subproblems. This gives us a recurrence from the above:

```
additions[N] = 8*additions[N/2] + N^2
```

That is, if we pay the price of N^2 additions, we are allowed to break down the problem of size N into 8 subproblems of size N/2.
We can solve using the Master Theorem (or more general Akra-Bazzi Theorem), or by inspection:

```
additions[N] = 8*(8*(8*(8*(..1..) +(N/8)^2) +(N/4)^2) +(N/2)^2) +N^2
```

Using the Master Theorem, `additions[N] = O(N^(log_2(8))) = O(N^3)`

Why would we do this since it's the same order of growth? We wouldn't. It turns out that in order to get better asymptotic complexity, you don't want to do this, you want to use an algebraic trick called Strassen's method. See http://www.cs.berkeley.edu/~jordan/courses/170-fall05/notes/dc.pdf on page 4. Our new recurrence relation comes from counting the number of multiplications and additions as shown on that page. There are 18 additions of [N/2xN/2] matrices required to form an NxN matrix.

```
additions[N] = 7*additions[N/2] + 18*(N/2)^2
= 7*additions[N/2] + (18/4)*(N/2)^2
```

As we see, we have to do one fewer subproblem, but at the cost of doing more work in combining. The master theorem says that `additions[N] = O(N^(log_2(7))) ~= O(N^2.807)`

.

So asymptotically, there will be FEWER additions, but only asymptotically. The real story is revealed when we simulate both recurrence relations:

```
#!/usr/bin/python3
n = 1 # NxN matrix
normal = 1
naive = 1
strassen = 1
print('NUMBER OF ADDITIONS')
print(' NxN | normal naive strassen | best')
print('-'*60)
while n < 1000000000:
n *= 2
normal = (n-1)*n**2
naive = 8*naive + n**2
strassen = 7*strassen + (18/4)*n**2
print('{:>10} | {:>8.2e} {:>8.2e} {:>8.2e} | {}'.format(
n,
normal, naive, strassen/normal,
'strassen' if strassen<n**3 else 'normal'
))
```

Results:

```
NUMBER OF ADDITIONS
NxN | normal naive strassen | best
------------------------------------------------------------
2 | 4.00e+00 1.20e+01 2.50e+01 | normal
4 | 4.80e+01 1.12e+02 2.47e+02 | normal
8 | 4.48e+02 9.60e+02 2.02e+03 | normal
16 | 3.84e+03 7.94e+03 1.53e+04 | normal
32 | 3.17e+04 6.45e+04 1.12e+05 | normal
64 | 2.58e+05 5.20e+05 7.99e+05 | normal
128 | 2.08e+06 4.18e+06 5.67e+06 | normal
256 | 1.67e+07 3.35e+07 4.00e+07 | normal
512 | 1.34e+08 2.68e+08 2.81e+08 | normal
1024 | 1.07e+09 2.15e+09 1.97e+09 | normal
2048 | 8.59e+09 1.72e+10 1.38e+10 | normal
4096 | 6.87e+10 1.37e+11 9.68e+10 | normal
8192 | 5.50e+11 1.10e+12 6.78e+11 | normal
16384 | 4.40e+12 8.80e+12 4.75e+12 | normal
32768 | 3.52e+13 7.04e+13 3.32e+13 | strassen
65536 | 2.81e+14 5.63e+14 2.33e+14 | strassen
131072 | 2.25e+15 4.50e+15 1.63e+15 | strassen
262144 | 1.80e+16 3.60e+16 1.14e+16 | strassen
524288 | 1.44e+17 2.88e+17 7.98e+16 | strassen
1048576 | 1.15e+18 2.31e+18 5.59e+17 | strassen
2097152 | 9.22e+18 1.84e+19 3.91e+18 | strassen
4194304 | 7.38e+19 1.48e+20 2.74e+19 | strassen
8388608 | 5.90e+20 1.18e+21 1.92e+20 | strassen
16777216 | 4.72e+21 9.44e+21 1.34e+21 | strassen
33554432 | 3.78e+22 7.56e+22 9.39e+21 | strassen
67108864 | 3.02e+23 6.04e+23 6.57e+22 | strassen
134217728 | 2.42e+24 4.84e+24 4.60e+23 | strassen
268435456 | 1.93e+25 3.87e+25 3.22e+24 | strassen
536870912 | 1.55e+26 3.09e+26 2.25e+25 | strassen
1073741824 | 1.24e+27 2.48e+27 1.58e+26 | strassen
```

As we can see, with respect to additions only, Strassen outperforms the traditional normal matrix-multiplication **with respect to number of additions**, but only once your matrices exceed the size of roughly 30000x30000.

(Also note that the naive divide-and-conquer multiplication performs asymptotically the same, in terms of additions, as traditional matrix multiplication. However it still performs "worse" by initially a factor of 3, but as the matrix size increases, asymptotically worse by a factor of exactly 2 . Of course this tells us nothing about the true complexity which involves multiplications, but if it did, we might still want to use it if we had a parallel algorithm which could take advantage of the different computation structure.)

additionsis easily googlable, only the number of operations. – ninjagecko Feb 20 '12 at 6:40