Without knowing your target platform, some sort of hardware acceleration is highly recommended. OpenGL 2.0+ (or ES 2.0+) is the most likely thing to help — using GLSL you get a C-style language in which the interesting bit for you would be supplying a fragment program, which is what the GPU should do per pixel based on the input textures in order to produce a colour for output. Where you're outputting to is implicit, but you can output to an image then subsequently use that image as input, which would hook right in to your idea (2). Depending on the exact hardware you're targeting, it may be relevant that Direct3d has a very similar construct in HLSL and NVidia supply a more proprietary equivalent called Cg that I think nowadays can compile to GLSL or HLSL.
Otherwise: idea (1) is a smart move, especially if the user is allowed to open images of arbitrary size. It causes the time spent to be a function of the size of the brush, not the image. You need to be reasonably precise in your thinking if you're doing things at subpixel accuracy.
Idea (2) potentially has precision ramifications (especially if coupled to hardware). To maintain the exact same results, obviously your intermediate buffers need to be of the same precision as your intermediate variables, which in a typical consumer-oriented drawing application often means that file inputs are 8bpp/channel but intermediate storage needs to be at least 16bpp/channel if you don't want errors to accumulate. This is likely to be the biggest potential barrier to hardware acceleration, since older hardware tends to limit you to 8bpp/channel intermediate buffers. Modern hardware can do floating point buffers of decent precision.
It is possible to gain an advantage from precomputation on layers to be applied afterwards, but the information per pixel generally needs to be more complicated than merely a colour, and may end up being no more simple than just storing the original buffers. Probably the smart thing to do is peephole optimisation. So if you have two additive layers on top of each other, you can easily replace that with a single additive layer. Ditto for two multiplicative or two XOR. So you'd implement a loop that looked at the effect queue, finds any patterns that it knows how to turn into a simpler form and makes those substitutions. And repeat until no substitutions can be found. For optimisation purposes you may even want to implement some compound operations that aren't directly offered to the user. Though, again, you need to consider precision.
In the common case, with normal blending applied to all layers, you'd end up with a single operation for arbitrarily many layers above.