I am currently trying to implement a PNG encoder in C++ based on libpng that uses OpenMP to speed up the compression process. The tool is already able to generate PNG files from
This is too long for a comment but is not really an answer either--
I'm not sure you can do this without modifying libpng (or writing your own encoder). In any case, it will help if you understand how PNG compression is implemented:
At the high level, the image is a set of rows of pixels (generally 32-bit values representing RGBA tuples).
Each row can independently have a filter applied to it -- the filter's sole purpose is to make the row more "compressible". For example, the "sub" filter makes each pixel's value the difference between it and the one to its left. This delta encoding might seem silly at first glance, but if the colours between adjacent pixels are similar (which tends to be the case) then the resulting values are very small regardless of the actual colours they represent. It's easier to compress such data because it's much more repetitive.
Going down a level, the image data can be seen as a stream of bytes (rows are no longer distinguished from each other). These bytes are compressed, yielding another stream of bytes. The compressed data is arbitrarily broken up into segments (anywhere you want!) written to one IDAT chunk each (along with a little bookkeeping overhead per chunk, including a CRC checksum).
The lowest level brings us to the interesting part, which is the compression step itself. The PNG format uses the zlib compressed data format. zlib itself is just a wrapper (with more bookkeeping, including an Adler-32 checksum) around the real compressed data format, deflate (zip files use this too). deflate supports two compression techniques: Huffman coding (which reduces the number of bits required to represent some byte-string to the optimal number given the frequency that each different byte occurs in the string), and LZ77 encoding (which lets duplicate strings that have already occurred be referenced instead of written to the output twice).
The tricky part about parallelizing deflate compression is that in general, compressing one part of the input stream requires that the previous part also be available in case it needs to be referenced. But, just like PNGs can have multiple IDAT chunks, deflate is broken up into multiple "blocks". Data in one block can reference previously encoded data in another block, but it doesn't have to (of course, it may affect the compression ratio if it doesn't).
So, a general strategy for parallelizing deflate would be to break the input into multiple large sections (so that the compression ratio stays high), compress each section into a series of blocks, then glue the blocks together (this is actually tricky since blocks don't always end on a byte boundary -- but you can put an empty non-compressed block (type 00), which will align to a byte boundary, in-between sections). This isn't trivial, however, and requires control over the very lowest level of compression (creating deflate blocks manually), creating the proper zlib wrapper spanning all the blocks, and stuffing all this into IDAT chunks.
If you want to go with your own implementation, I'd suggest reading my own zlib/deflate implementation (and how I use it) which I expressly created for compressing PNGs (it's written in Haxe for Flash but should be comparatively easy to port to C++). Since Flash is single-threaded, I don't do any parallelization, but I do split the encoding up into virtually independent sections ("virtually" because there's the fractional-byte state preserved between sections) over multiple frames, which amounts to largely the same thing.
Good luck!
I finally got it to parallelize the compression process. As mentioned by Cameron in the comment to his answer I had to strip the zlib header from the zstreams to combine them. Stripping the footer was not required as zlib offers an option called Z_SYNC_FLUSH which can be used for all chunks (except the last one which has to be written with Z_FINISH) to write to a byte boundary. So you can simply concatenate the stream outputs afterwards. Eventually, the adler32 checksum has to be calculated over all threads and copied to the end of the combined zstreams.
If you are interested in the result you can find the complete proof of concept at https://github.com/anvio/png-parallel