# Execution time difference in matrix multiplication caused by parentheses

Given the two 1D `numpy` arrays `a` and `b` with

``````N = 100000
a = np.randn(N)
b = np.randn(N)
``````

Why is there a considerable execution time difference between the following two expressions:

``````# expression 1
c = a @ a * b @ b

# expression 2
c = (a @ a) * (b @ b)
``````

Using the `%timeit` magic of Jupyter Notebook I get the following results:

%timeit a @ a * b @ b

223 µs ± 6.97 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)

and

%timeit (a @ a) * (b @ b)

17.4 µs ± 27.3 ns per loop (mean ± std. dev. of 7 runs, 100000 loops each)

In both versions you do two dot products of length-N vectors. However, in addition the first solution performs N multiplications while the second solution only needs one.

`a @ a * b @ b` is equivalent to `((a @ a) * b) @ b` or

``````aa = a @ a  # N multiplications and additions -> scalar
aab = aa * b  # N multiplications -> vector
aabb = aab @ b  # N multiplications and additions -> scalar
``````

`(a @ a) * (b @ b)` is equivalent to

``````aa = a @ a  # N multiplications and additions -> scalar
bb = b @ b  # N multiplications and additions -> scalar
aabb = aa * bb  # 1 multiplication -> scalar
``````

The fact that matrix multiplication performance can depend on how to set the parentheses is well known. There exist algorithms to optimize matrix chain multiplication by exploiting this fact.

Update: As I just learned, numpy has a function for optimizing multiple matrix multiplications: `numpy.linalg.multidot`