There are no *reliable* resources that will tell you how long various standard shader functions take. Not even for a particular piece of hardware.

The reason for this has to do with instruction scheduling and the way modern shader architectures work. Take a simple `sin`

function. Let's say that the hardware has a special hardware to compute the sine of a value, so it's not manually using a Tailor series or something. However, let's also say that it takes a sequence of 4 opcodes to actually compute it. Therefore, `sin`

would take "4 cycles".

*However*, all of those opcodes are scalar operations. Therefore, while they're going on, you could in fact have some 3-vector dot-products, or in the case of some hardware, 4-vector dot-products going on *at the same time*, on the same processor. Therefore, if the hardware has 4-vector dot-products with scalar operations, the number of cycles it takes to execute a `sin`

and a matrix-vector multiply is... still 4.

So how much did the `sin`

operation cost? If you take out the matrix multiply, nothing gets faster. If you take out the `sin`

, nothing still gets faster. How much does it cost? You can't say, because the cost of a single operation is irrelevant; the only measurable quantity is the cost of the *shader itself*.

Ultimately, all you can do is try to build your shader reasonably and see what the performance is. Unless you have low-level debugging tools to deprocess the underlying shader assembly (and no, DX assembly isn't good enough), that's really the best you can do.