It depends on how many vectors or matrices you want to work on at a time, and whether you want to draw the results or not.

GLSL (OpenGL Shading Language) already has a maths library built in. It has functions and operators for matrix maths, transpose, inverse; vector dot and cross products; multiplying a vector by a matrix, etc.

When you're drawing geometry or whatever with OpenGL, you use these built-in functions in your shaders on the GPU. No point in a 3d math library replicating what is already there.

If you want to do small scale vector/matrix maths without drawing anything, for instance a ray - plane intersection test, then the CPU is better. Copying the values to the GPU and copying the result back would take much longer than just doing the math on the CPU. (Even if the GPU were actually faster - typical speeds today are 2Ghz+ for CPU, < 1Ghz for GPU.) This is why math libraries just use the CPU.

If you want to do "industrial scale" matrix/vector math without drawing, then yes it is worth considering the GPU. (This is why CUDA and OpenCL exist.) With a modern version of OpenGL that supports transform feedback and texture buffer objects (usually V3+) you can do maths on hundreds to thousands of matrices/vectors on the GPU, and OpenGL 4.3 makes it even easier with compute shaders. It isn't quite as convenient or efficient as CUDA/OpenCL, but if you already know OpenGL it is much easier.

Hope this helps.