# Vector-Matrix multiplication order can affect performance?

This is not a row-major vs column-major question. This is an order of calculation question as pertaining to performance, based on the associative property of matrix multiplication: `A(BC)=(AB)C`

If I have 2 matrices, `A` and `B`, and a vector `v` and I want to multiply them all together in a certain order, for example `ABv`, I can do `(AB)v` or `A(Bv)`.

It occurs to me, programmatically, that I get better performance from far fewer calculations if I use the second method and always multiply a matrix with a vector.

For example, if we are dealing with 4x4 matrices:

`AB` results in 16 individual calculations, a new matrix, each result is from a dot product

`Matrix*vector` results in 4 calculations, each from a dot product

Therefore:

`(AB)v` is 16+4 dot product calculations=20

`A(Bv)` is two matrix-vector products, or 4+4 dot product calculations = 8

Am I thinking correctly? This suggests that performing many many vector-matrix expressions like this will dramatically improve performance if I start with the vector each time?

Thus it would make sense to structure a matrix library that performs based on vector*matrix left-to-right calculation order (even if you choose to notate right-to-left with column-major formatting) since multiplying a vector with matrix products is very common in graphics.

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andand and tmyklebu explained it correctly already. As a further insight I'd to add, that in computer graphics, especially when using a programmable transformation pipeline, one normally deals with quasi static matrices (the matrices are constants for large bunch of vectors). Often you have a compund View · Model matrix `MV` and a projection matrix `P` procomputed. `MV` usually condenses a large number of transformations and the intermediary product `MV · v` is required for certain calculations (illumination). So effectively it boils down to your `A·(B·v)` case. – datenwolf Jun 6 '13 at 5:56
But, there is one important development in modern graphics hardware (GPUs): While GPUs used to be vector architectures in the early days (Shader Model 2), Shader Model 3 GPUs are in fact (super)scalar architectures, where vectorization happens by performing regular scalar operations in parallel. And this changes the numbers a bit. However inner/dot products are still executed faster from a dot product operation, than doing the scalar dance manually. – datenwolf Jun 6 '13 at 6:00
@datenwolf Thank you, I have asked an additional question that pertains to how the shader performs this calculation directly with regards to eficiency – johnbakers Jun 6 '13 at 6:08
@datenwolf I don't know if you are on the OpenGL forums, and perhaps I should put this as a question on here, but I know you have implemented your own linear algebra library and you probably have some insight on this particular conundrum I've come across: opengl.org/discussion_boards/showthread.php/… – johnbakers Jun 6 '13 at 10:35