%% MP3 reading and writing
%
% These function, mp3read and mp3write, aim to exactly duplicate 
% the operation of wavread and wavwrite for accessing soundfiles, 
% except the soundfiles are in Mpeg-Audio layer 3 (MP3) compressed 
% format.  All the hard work is done by external binaries written 
% by others: mp3info to query the format of existing mp3 files, 
% mpg123 to decode mp3 files, and lame to encode audio files.
% Binaries for these files are widely available (and may be
% included in this distribution).  
%
% These functions were originally developed for access to very 
% large mp3 files (i.e. many hours long), and so avoid creating 
% the entire uncompressed audio stream if possible.  mp3read 
% allows you to specify the range of frames you want to read 
% (as a second argument), and mp3read will construct an mpg123 
% command that skips blocks to decode only the part of the file 
% that is required.  This can be much quicker (and require less 
% memory/temporary disk) than decoding the whole file.
%
% mpg123 also provides for "on the fly" downsampling at conversion 
% to mono, which are supported as extra options in mp3read.
%
% mpg123 can read MP3s across the network.  This is supported 
% if the FILE argument is a URL (e.g. beginning 'http://...').
%
% mp3info sometimes gets the file size wrong (as returned by the
% mp3read(...'size') syntax).  I'm not sure when this happens
% exactly, but it's probably a result of VBR files. In the worst
% case, figuring the number of samples in such a file requires
% scanning through the whole file, and mp3info doesn't usually do
% this. 
%
% For more information, including advice on handling MP4 files, 
% see http://labrosa.ee.columbia.edu/matlab/mp3read.html

%% Example usage
% Here, we read a wav file in, then write it out as an MP3, then 
% read the resulting MP3 back in, and compare it to the original 
% file.

% Read an audio waveform
[d,sr] = wavread('piano.wav');
% Save to mp3 (default settings)
mp3write(d,sr,'piano.mp3');
% Read it back again
[d2,sr] = mp3read('piano.mp3');
% mp3 encoding involves some extra padding at each end; we attempt 
% to cut it off at the start, but can't do that at the end, because 
% mp3read doesn't know how long the original was.  But we do, so..
% Chop it down to be the same length as the original
d2 = d2(1:length(d),:);
% What is the SNR (distortion)?
ddiff = d - d2;
disp(['SNR is ',num2str(10*log10(sum(d(:).^2)/sum(ddiff(:).^2))),' dB']);
% Do they look similar?
subplot(211)
specgram(d(:,1),1024,sr);
subplot(212)
plot(1:5000,d(10000+(1:5000),1),1:5000,d2(10000+(1:5000)));
% Yes, pretty close
%
% NB: lame followed by mpg123 causes a little attenuation; you 
% can get a better match by scaling up the read-back waveform:
ddiff = d - 1.052*d2;
disp(['SNR is ',num2str(10*log10(sum(d(:).^2)/sum(ddiff(:).^2))),' dB']);

%% Delay, size, and alignment
%
% In mid-2006 I noticed that mp3read followed by mp3write followed by
% mp3read effectively delayed the waveform by 2257 samples (at 44
% kHz). So I introduced code to discard the first 2257 samples to ensure
% that the waveforms remained time aligned. As best I could understand,
% mpg123 (v 0.5.9) was including the "warm-up" samples from the
% synthesis filterbank which are more properly discarded.
%
% Then in late 2009 I noticed that some chord recognition code, which
% used mp3read to read files which were then segmented on the basis of
% some hand-marked timings, suddenly started getting much poorer
% results. It turned out that I had upgraded my version of mpg123 to v
% 1.9.0, and the warm-up samples had been fixed in this version. So my
% code was discarding 2257 *good* samples, and the data was skewed 51ms
% early relative to the hand labels.
%
% Hence, the current version of mp3read does not
% discard any samples by default -- appropriate for the recent versions
% of mpg123 included here. But if you know you're running an old, v
% 0.5.9, mpg123, you should edit the mp3read.m source to set the flag
% MPG123059 = 1.
% 
% Note also that the 'size' function relies on the number of 
% blocks reported by mp3info.  However, many mp3 files include 
% additional information about the size of the file in the
% so-called Xing header, embedded in the first frame, which can 
% specify that a certain number of samples from start and end 
% should additionally be dropped.  mp3info doesn't read that, 
% and there's no way for my code to probe it except by running 
% mpg123.  Hence, the results of mp3read(fn,'size') may sometimes 
% overestimate the length of the actual vector you'll get if 
% you read the whole file.

%% External binaries
% The m files rely on three external binaries, each of which is
% available for Linux, Mac OS X, or Windows:
%
% *mpg123* is a high-performance mp3 decoder.  Its home page is
% http://www.mpg123.de/ .  
%
% *mp3info* is a utility to read technical information on an mp3
% file. Its home page is http://www.ibiblio.org/mp3info/ .  
%
% *lame* is an open-source MP3 encoder.  Its homepage is
% http://lame.sourceforge.net/ .
%
% The various authors of these packages are gratefully acknowledged 
% for doing all the hard work to make these Matlab functions possible.

%% Installation
% The two routines, mp3read.m and mp3write.m, will look for their 
% binaries (mpg123 and mp3info for mp3read; lame for mp3write) in 
% the same directory where they are installed.  Binaries for
% different architectures are distinguished by their extension, 
% which is the standard Matlab computer code e.g. ".mac" for Mac
% PPC OS X, ".glnx86" for i386-linux.  The exception is Windows,
% where the binaries have the extension ".exe".  
%
% Temporary files 
% will be written to (a) a directory taken from the environment 
% variable TMPDIR (b) /tmp if it exists, or (c) the current 
% directory.  This can easily be changed by editing the m files.

% Last updated: $Date: 2009/03/15 18:29:58 $
% Dan Ellis <dpwe@ee.columbia.edu>