ref: 9f2d60f9cd52a1cc5ae92e02bd862c8cb4b85f13
dir: /src/maud.c/
/* libSoX MAUD file format handler, by Lutz Vieweg 1993 * * supports: mono and stereo, linear, a-law and u-law reading and writing * * an IFF format; description at http://lclevy.free.fr/amiga/MAUDINFO.TXT * * Copyright 1998-2006 Chris Bagwell and SoX Contributors * This source code is freely redistributable and may be used for * any purpose. This copyright notice must be maintained. * Lance Norskog And Sundry Contributors are not responsible for * the consequences of using this software. */ #include "sox_i.h" #include <string.h> #include <stdlib.h> #include <stdio.h> #include <errno.h> /* Private data for MAUD file */ typedef struct { uint32_t nsamples; } priv_t; static void maudwriteheader(sox_format_t *); /* * Do anything required before you start reading samples. * Read file header. * Find out sampling rate, * size and encoding of samples, * mono/stereo/quad. */ static int startread(sox_format_t * ft) { priv_t * p = (priv_t *) ft->priv; char buf[12]; char *chunk_buf; unsigned short bitpersam; uint32_t nom; unsigned short denom; unsigned short chaninf; uint32_t chunksize; uint32_t trash32; uint16_t trash16; int rc; /* Needed for rawread() */ rc = lsx_rawstartread(ft); if (rc) return rc; /* read FORM chunk */ if (lsx_reads(ft, buf, (size_t)4) == SOX_EOF || strncmp(buf, "FORM", (size_t)4) != 0) { lsx_fail_errno(ft,SOX_EHDR,"MAUD: header does not begin with magic word `FORM'"); return (SOX_EOF); } lsx_readdw(ft, &trash32); /* totalsize */ if (lsx_reads(ft, buf, (size_t)4) == SOX_EOF || strncmp(buf, "MAUD", (size_t)4) != 0) { lsx_fail_errno(ft,SOX_EHDR,"MAUD: `FORM' chunk does not specify `MAUD' as type"); return(SOX_EOF); } /* read chunks until 'BODY' (or end) */ while (lsx_reads(ft, buf, (size_t)4) == SOX_SUCCESS && strncmp(buf,"MDAT",(size_t)4) != 0) { /* buf[4] = 0; lsx_debug("chunk %s",buf); */ if (strncmp(buf,"MHDR",(size_t)4) == 0) { lsx_readdw(ft, &chunksize); if (chunksize != 8*4) { lsx_fail_errno(ft,SOX_EHDR,"MAUD: MHDR chunk has bad size"); return(SOX_EOF); } /* number of samples stored in MDAT */ lsx_readdw(ft, &(p->nsamples)); /* number of bits per sample as stored in MDAT */ lsx_readw(ft, &bitpersam); /* number of bits per sample after decompression */ lsx_readw(ft, &trash16); lsx_readdw(ft, &nom); /* clock source frequency */ lsx_readw(ft, &denom); /* clock devide */ if (denom == 0) { lsx_fail_errno(ft,SOX_EHDR,"MAUD: frequency denominator == 0, failed"); return (SOX_EOF); } ft->signal.rate = nom / denom; lsx_readw(ft, &chaninf); /* channel information */ switch (chaninf) { case 0: ft->signal.channels = 1; break; case 1: ft->signal.channels = 2; break; default: lsx_fail_errno(ft,SOX_EFMT,"MAUD: unsupported number of channels in file"); return (SOX_EOF); } lsx_readw(ft, &chaninf); /* number of channels (mono: 1, stereo: 2, ...) */ if (chaninf != ft->signal.channels) { lsx_fail_errno(ft,SOX_EFMT,"MAUD: unsupported number of channels in file"); return(SOX_EOF); } lsx_readw(ft, &chaninf); /* compression type */ lsx_readdw(ft, &trash32); /* rest of chunk, unused yet */ lsx_readdw(ft, &trash32); lsx_readdw(ft, &trash32); if (bitpersam == 8 && chaninf == 0) { ft->encoding.bits_per_sample = 8; ft->encoding.encoding = SOX_ENCODING_UNSIGNED; } else if (bitpersam == 8 && chaninf == 2) { ft->encoding.bits_per_sample = 8; ft->encoding.encoding = SOX_ENCODING_ALAW; } else if (bitpersam == 8 && chaninf == 3) { ft->encoding.bits_per_sample = 8; ft->encoding.encoding = SOX_ENCODING_ULAW; } else if (bitpersam == 16 && chaninf == 0) { ft->encoding.bits_per_sample = 16; ft->encoding.encoding = SOX_ENCODING_SIGN2; } else { lsx_fail_errno(ft,SOX_EFMT,"MAUD: unsupported compression type detected"); return(SOX_EOF); } continue; } if (strncmp(buf,"ANNO",(size_t)4) == 0) { lsx_readdw(ft, &chunksize); if (chunksize & 1) chunksize++; chunk_buf = lsx_malloc(chunksize + (size_t)1); if (lsx_readbuf(ft, chunk_buf, (size_t)chunksize) != chunksize) { lsx_fail_errno(ft,SOX_EOF,"MAUD: Unexpected EOF in ANNO header"); return(SOX_EOF); } chunk_buf[chunksize] = '\0'; lsx_debug("%s",chunk_buf); free(chunk_buf); continue; } /* some other kind of chunk */ lsx_readdw(ft, &chunksize); if (chunksize & 1) chunksize++; lsx_seeki(ft, (off_t)chunksize, SEEK_CUR); continue; } if (strncmp(buf,"MDAT",(size_t)4) != 0) { lsx_fail_errno(ft,SOX_EFMT,"MAUD: MDAT chunk not found"); return(SOX_EOF); } lsx_readdw(ft, &(p->nsamples)); return(SOX_SUCCESS); } static int startwrite(sox_format_t * ft) { priv_t * p = (priv_t *) ft->priv; int rc; /* Needed for rawwrite() */ rc = lsx_rawstartwrite(ft); if (rc) return rc; /* If you have to seek around the output file */ if (! ft->seekable) { lsx_fail_errno(ft,SOX_EOF,"Output .maud file must be a file, not a pipe"); return (SOX_EOF); } p->nsamples = 0x7f000000; maudwriteheader(ft); p->nsamples = 0; return (SOX_SUCCESS); } static size_t write_samples(sox_format_t * ft, const sox_sample_t *buf, size_t len) { priv_t * p = (priv_t *) ft->priv; p->nsamples += len; return lsx_rawwrite(ft, buf, len); } static int stopwrite(sox_format_t * ft) { /* All samples are already written out. */ priv_t *p = (priv_t*)ft->priv; uint32_t mdat_size; /* MDAT chunk size */ mdat_size = p->nsamples * (ft->encoding.bits_per_sample >> 3); lsx_padbytes(ft, (size_t) (mdat_size%2)); if (lsx_seeki(ft, (off_t)0, 0) != 0) { lsx_fail_errno(ft,errno,"can't rewind output file to rewrite MAUD header"); return(SOX_EOF); } maudwriteheader(ft); return(SOX_SUCCESS); } #define MAUDHEADERSIZE (4+(4+4+32)+(4+4+19+1)+(4+4)) static void maudwriteheader(sox_format_t * ft) { priv_t * p = (priv_t *) ft->priv; uint32_t mdat_size; /* MDAT chunk size */ mdat_size = p->nsamples * (ft->encoding.bits_per_sample >> 3); lsx_writes(ft, "FORM"); lsx_writedw(ft, MAUDHEADERSIZE + mdat_size + mdat_size%2); /* size of file */ lsx_writes(ft, "MAUD"); /* File type */ lsx_writes(ft, "MHDR"); lsx_writedw(ft, 8*4); /* number of bytes to follow */ lsx_writedw(ft, p->nsamples); /* number of samples stored in MDAT */ switch (ft->encoding.encoding) { case SOX_ENCODING_UNSIGNED: lsx_writew(ft, 8); /* number of bits per sample as stored in MDAT */ lsx_writew(ft, 8); /* number of bits per sample after decompression */ break; case SOX_ENCODING_SIGN2: lsx_writew(ft, 16); /* number of bits per sample as stored in MDAT */ lsx_writew(ft, 16); /* number of bits per sample after decompression */ break; case SOX_ENCODING_ALAW: case SOX_ENCODING_ULAW: lsx_writew(ft, 8); /* number of bits per sample as stored in MDAT */ lsx_writew(ft, 16); /* number of bits per sample after decompression */ break; default: break; } lsx_writedw(ft, (unsigned)(ft->signal.rate + .5)); /* sample rate, Hz */ lsx_writew(ft, (int) 1); /* clock devide */ if (ft->signal.channels == 1) { lsx_writew(ft, 0); /* channel information */ lsx_writew(ft, 1); /* number of channels (mono: 1, stereo: 2, ...) */ } else { lsx_writew(ft, 1); lsx_writew(ft, 2); } switch (ft->encoding.encoding) { case SOX_ENCODING_UNSIGNED: case SOX_ENCODING_SIGN2: lsx_writew(ft, 0); /* no compression */ break; case SOX_ENCODING_ULAW: lsx_writew(ft, 3); break; case SOX_ENCODING_ALAW: lsx_writew(ft, 2); break; default: break; } lsx_writedw(ft, 0); /* reserved */ lsx_writedw(ft, 0); /* reserved */ lsx_writedw(ft, 0); /* reserved */ lsx_writes(ft, "ANNO"); lsx_writedw(ft, 19); /* length of block */ lsx_writes(ft, "file created by SoX"); lsx_padbytes(ft, (size_t)1); lsx_writes(ft, "MDAT"); lsx_writedw(ft, p->nsamples * (ft->encoding.bits_per_sample >> 3)); /* samples in file */ } LSX_FORMAT_HANDLER(maud) { static char const * const names[] = {"maud", NULL}; static unsigned const write_encodings[] = { SOX_ENCODING_SIGN2, 16, 0, SOX_ENCODING_UNSIGNED, 8, 0, SOX_ENCODING_ULAW, 8, 0, SOX_ENCODING_ALAW, 8, 0, 0}; static sox_format_handler_t const handler = {SOX_LIB_VERSION_CODE, "Used with the ‘Toccata’ sound-card on the Amiga", names, SOX_FILE_BIG_END | SOX_FILE_MONO | SOX_FILE_STEREO, startread, lsx_rawread, lsx_rawstopread, startwrite, write_samples, stopwrite, NULL, write_encodings, NULL, sizeof(priv_t) }; return &handler; }