Octave Detection can be very tricky, especially on a polyphonic signal where the fundamental harmonic and/or other harmonics are missing. Assuming that you are correctly detecting 'pitch' and not just 'harmonics' (see Wikipedia link below), then you could use an Octave Detection algorithm that I developed.
In order to do pitch detection for PitchScope Player, I decided on a 2 Stage Algorithm that works like this: a) First the ScalePitch of a note is detected -- 'ScalePitch' has 12 possible pitch values: { E, F, F#, G, G#, A, A#, B, C, C#, D, D# }. And after ScalePitch and Time-Width of a note is determined, b) then the Octave (fundamental) of that note is calculated by examining ALL the harmonics of 4 possible Octave-Candidate notes.
The complete C++ source code and executable for my pitch detection application, PitchScope Player, is on GitHub (link below), and you could compile and step through it to see how my Octave Detection Algorithm works.
You would want to focus on the function FundCandidCalcer::Calc_Best_Octave_Candidate() within in the file FundCandidCalcer.cpp to see that algorithm in C++. The diagram below also gives a rough idea how to calculate the Octave.
https://en.wikipedia.org/wiki/Transcription_(music)#Pitch_detection
https://github.com/CreativeDetectors/PitchScope_Player
The diagram below demonstrates the Octave Detection algorithm which I developed to pick the correct Octave-Candidate note (that is, the correct Fundamental), once the ScalePitch for that note has been determined.