ref: 2f0e01bb1b09a88b43624d4c9e678751af81e0f0
dir: /libst.3/
.de Sh .br .ne 5 .PP \fB\\$1\fR .PP .. .de Sp .if t .sp .5v .if n .sp .. .TH ST 3 "October 15 1996" .SH NAME libst \- Sound Tools : sound sample file and effects libraries. .SH SYNOPSIS .B cc \fIfile.c\fB -o \fIfile \fBlibst.a .SH DESCRIPTION .I Sound\ Tools is a library of sound sample file format readers/writers and sound effects processors. .P Sound Tools includes skeleton C files to assist you in writing new formats and effects. The full skeleton driver, skel.c, helps you write drivers for a new format which has data structures. The simple skeleton drivers help you write a new driver for raw (headerless) formats, or for formats which just have a simple header followed by raw data. .P Most sound sample formats are fairly simple: they are just a string of bytes or words and are presumed to be sampled at a known data rate. Most of them have a short data structure at the beginning of the file. .SH INTERNALS The Sound Tools formats and effects operate on an internal buffer format of signed 32-bit longs. The data processing routines are called with buffers of these samples, and buffer sizes which refer to the number of samples processed, not the number of bytes. File readers translate the input samples to signed longs and return the number of longs read. For example, data in linear signed byte format is left-shifted 24 bits. .P This does cause problems in processing the data. For example: .br *obuf++ = (*ibuf++ + *ibuf++)/2; .br would .I not mix down left and right channels into one monophonic channel, because the resulting samples would overflow 32 bits. Instead, the ``avg'' effects must use: .br *obuf++ = *ibuf++/2 + *ibuf++/2; .br .P Stereo data is stored with the left and right speaker data in successive samples. Quadraphonic data is stored in this order: left front, right front, left rear, right rear. .SH FORMATS A .I format is responsible for translating between sound sample files and an internal buffer. The internal buffer is store in signed longs with a fixed sampling rate. The .I format operates from two data structures: a format structure, and a private structure. .P The format structure contains a list of control parameters for the sample: sampling rate, data size (bytes, words, floats, etc.), encoding (unsigned, signed, logarithmic), number of sound channels. It also contains other state information: whether the sample file needs to be byte-swapped, whether fseek() will work, its suffix, its file stream pointer, its .I format pointer, and the .I private structure for the .I format . .P The .I private area is just a preallocated data array for the .I format to use however it wishes. It should have a defined data structure and cast the array to that structure. See voc.c for the use of a private data area. Voc.c has to track the number of samples it writes and when finishing, seek back to the beginning of the file and write it out. The private area is not very large. The ``echo'' effect has to malloc() a much larger area for its delay line buffers. .P A .I format has 6 routines: .TP 20 startread Set up the format parameters, or read in a data header, or do what needs to be done. .TP 20 read Given a buffer and a length: read up to that many samples, transform them into signed long integers, and copy them into the buffer. Return the number of samples actually read. .TP 20 stopread Do what needs to be done. .TP 20 startwrite Set up the format parameters, or write out a data header, or do what needs to be done. .TP 20 write Given a buffer and a length: copy that many samples out of the buffer, convert them from signed longs to the appropriate data, and write them to the file. If it can't write out all the samples, fail. .TP 20 stopwrite Fix up any file header, or do what needs to be done. .SH EFFECTS An effects loop has one input and one output stream. It has 5 routines. .TP 20 getopts is called with a character string argument list for the effect. .TP 20 start is called with the signal parameters for the input and output streams. .TP 20 flow is called with input and output data buffers, and (by reference) the input and output data buffer sizes. It processes the input buffer into the output buffer, and sets the size variables to the numbers of samples actually processed. It is under no obligation to read from the input buffer or write to the output buffer during the same call. If the call returns ST_EOF then this should be used as an indication that this effect will no longer read any data and can be used to switch to drain mode sooner. .TP 20 drain is called after there are no more input data samples. If the effect wishes to generate more data samples it copies the generated data into a given buffer and returns the number of samples generated. If it fills the buffer, it will be called again, etc. The echo effect uses this to fade away. .TP 20 stop is called when there are no more input samples to process. .I stop may generate output samples on its own. See echo.c for how to do this, and see that what it does is absolutely bogus. .SH COMMENTS Theoretically, formats can be used to manipulate several files inside one program. Multi-sample files, for example the download for a sampling keyboard, can be handled cleanly with this feature. .SH PORTABILITY PROBLEMS Many computers don't supply arithmetic shifting, so do multiplies and divides instead of << and >>. The compiler will do the right thing if the CPU supplies arithmetic shifting. .P Do all arithmetic conversions one stage at a time. I've had too many problems with "obviously clean" combinations. .P In general, don't worry about "efficiency". The sox.c base translator is disk-bound on any machine (other than a 8088 PC with an SMD disk controller). Just comment your code and make sure it's clean and simple. You'll find that DSP code is extremely painful to write as it is. .SH BUGS The HCOM format is not re-entrant; it can only be used once in a program. .P The program/library interface is pretty weak. There's too much ad-hoc information which a program is supposed to gather up. Sound Tools wants to be an object-oriented dataflow architecture.