I am writing an audio file to an SD/MMC storage card in real time, in WAVE format, working on an ARM board. Said card is (and must remain) in FAT32 format. I can write a valid WAVE file just fine, provided I know how much I'm going to write beforehand.
I want to be able to put placeholder data in the Chunk Data Size field of the RIFF and data chunks, write my audio data, and then go back and update the Chunk Data Size field in those two chunks so that they have correct values, but...
I have a working filesystem and some stdio functions, with some caveats:
- fwrite() supports
a, but not any
- fseek() does not work in write mode.
I did not write the implementations of the above functions (I am using ARM's RL-FLashFS), and I am not certain what the justification for the restrictions/partial implementations is. Adding in the missing functionality personally is probably an option, but I would like to avoid it if possible (I have no other need of those features, do not forsee any, and can't really afford to spend too much time on it.) Switching to a different implementation is also not an option here.
I have very limited memory available, and I do not know how much audio data will be received, except that it will almost certainly be more than I can keep in memory at any one time.
I could write a file with the raw interleaved audio data in it while keeping track of how many bytes I write, close it, then open it again for reading, open a second file for writing, write the header into the second file, and copy the audio data over. That is, I could post-process it into a properly formatted valid WAVE file. I have done this and it works fine. But I want to avoid post-processing large amounts of data if at all possible.
Perhaps I could somehow concatenate two files in place? (I.e. write the data, then write the chunks to a separate file, then join them in the filesystem, avoiding much of the time spent copying potentially vast amounts of data.) My understanding of that is that, if possible, it would still involve some copying due to block orientation of the storage.
EDIT: I really should have mentioned this, but there is no OS running here. I have some stdio functions running on top of a hardware abstraction layer, and that's about it.