The best approach varies depending on the audio you're analyzing. For monophonic input, such as a singer, flute, or trumpet, an autocorrelation approach can work well. The idea here is that you're trying to find the period of the wave form by comparing it against itself at various intervals to find the best match. Imagine you have a sound wave with a period that starts over after every 400 samples. If you were to iterate over some number of samples, always comparing the sample at index i with the sample at index (i + 400), perhaps by subtracting one from another and adding this result to a running total, you'd find that your total would be 0 if the wave was a perfect match of itself at this interval of 400. Of course, you don't know that 400 is your magic number, and so you need to check a variety of intervals that fall within your possible range. You could exclude intervals that would result in a frequency that's impossibly low or high. You also would obviously not expect to find a perfect match, but generally speaking, the interval where the match is closest is your frequency for a monophonic pitch.

For polyphonic sources, or instruments with a timbre that's very rich in harmonics like violin or guitar, you may need to use a different approach. FFT based approaches are widely used for this in order to break down audio segments into their harmonic pitch content. It's then a matter of applying some rules that you come up with for deciding which frequencies coming out of the FFT are your best bet.