Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

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


(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.

share|improve this question
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:… – johnbakers Jun 6 '13 at 10:35
up vote 4 down vote accepted

Within the limited context of a single operation of the matrices and a single vector involved, you and tmyklebu have it right. However, there is usually a larger context you need to be aware of before you apply it in practice. That issue revolves around how often A and B change relative to how often v changes. If A and B are relatively static (they don't change very often) compared with v, you may be better off precomputing AB and applying it to whatever value v happens to have.

Furthermore, in practice, there is some geometry comprised of multiple vectors which can be more efficiently transformed and computed together by first computing AB and then applying that transformation to all of the vectors in the geometry.

share|improve this answer
+1 for noting the case of a static AB applied over a variety of different vectors, as is indeed often the case in graphics. – johnbakers Jun 6 '13 at 4:35

Your thinking is correct, yes. Finding the optimal way to multiply a chain of matrices is a famous example of a problem solvable using dynamic programming.

share|improve this answer
That's interesting; since in 3D graphics we are usually dealing with 4x4 matrices in our calculations and 4-element vectors that are typically at one end of the chain, it would seem this problem is a bit easier to diagnose and results in the simple observation that always starting with the vector and ensuring that every calculation involves a vector is the right way to go. – johnbakers Jun 6 '13 at 4:02
@Fellowshee: Yes, but outside 3D graphics, big matrices are rather more common :) (Of course, I've never seen anyone use matrix chain multiplication as anything other than a handy DP example.) – tmyklebu Jun 6 '13 at 6:26

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.