Ok, I tried all sorts of titles and they all failed (so if someone come up with a better title, feel free to edit it :P)
I have the following problem: I am using a API to access hardware, that I don't coded, to add libraries to that API I need to inherit from the API interface, and the API do everything.
I put in that API, a music generator library, the problem is that the mentioned API only call the music library when the buffer is empty, and ask for a hardcoded amount of data (exactly 1024*16 samples... dunno why).
This mean that the music generator library, cannot use all the CPU potential, while playing music, even if the music library is not keeping up, the CPU use remains low (like 3%), so in parts of the music that there are too complex stuff, the buffer underuns (ie: the soundcard plays the area in the buffer that is empty, because the music library function don't returned yet).
Tweaking the hardcoded number, would only make the software work in some machines, and not work in others, depending of several factors...
So I came up with two solutions: Hack the API with some new buffer logic, but I don't figured anything on that area.
Or the one that I actually figured the logic: Make the music library have its own thread, it will have its own separate buffer that it will fill all the time, when the API calls the music library for more data, instead of generating, it will plainly copy the data from that separate buffer to the soundcard buffer, and then resumes generate music.
My problem is that although I have several years of programming experience, I always avoided multi-threading, I don't know even where to start...
The question is: Can someone find another solution, OR point me into a place that will give me info on how to implement my threaded solution?
I am not READING files, I am GENERATING, or CALCULATING, the music, got it? This is NOT a .wav or .ogg library. This is why I mentioned CPU time, if I could use 100% CPU, I would never get a underrun, but I can only use CPU in the short time between the program realizing that the buffer is reaching the end, and the actual end of the buffer, and this time sometimes is less than the time the program takes to calculate the music.