Mercurial > hg > xemacs-beta
view src/miscplay.c @ 404:2f8bb876ab1d r21-2-32
Import from CVS: tag r21-2-32
| author | cvs |
|---|---|
| date | Mon, 13 Aug 2007 11:16:07 +0200 |
| parents | 74fd4e045ea6 |
| children |
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/* miscplay.c - general routines related to playing sounds ** ** Copyright (C) 1995,96 by Markus Gutschke (gutschk@math.uni-muenster.de) ** This was sawed out from version 1.3 of linuxplay.c by ** Robert Bihlmeyer <robbe@orcus.priv.at>. ** ** Parts of this code were inspired by sunplay.c, which is copyright 1989 by ** Jef Poskanzer and 1991,92 by Jamie Zawinski; c.f. sunplay.c for further ** information. ** ** Permission to use, copy, modify, and distribute this software and its ** documentation for any purpose and without fee is hereby granted, provided ** that the above copyright notice appear in all copies and that both that ** copyright notice and this permission notice appear in supporting ** documentation. This software is provided "as is" without express or ** implied warranty. */ #ifdef HAVE_CONFIG_H #include <config.h> #endif #include "miscplay.h" #include "lisp.h" #include "syssignal.h" #include "sysfile.h" #define warn(str) message("audio: %s ",GETTEXT(str)) #include <stdlib.h> #ifdef __GNUC__ #define UNUSED(x) ((void)(x)) #else #define UNUSED(x) #endif /* Maintain global variable for keeping parser state information; this struct is set to zero before the first invocation of the parser. The use of a global variable prevents multiple concurrent executions of this code, but this does not happen anyways... */ enum wvState { wvMain, wvSubchunk, wvOutOfBlock, wvSkipChunk, wvSoundChunk, wvFatal, wvFatalNotify }; static union { struct { int align; enum wvState state; size_t left; unsigned char leftover[HEADERSZ]; signed long chunklength; } wave; struct { int align; int isdata; int skipping; size_t left; unsigned char leftover[HEADERSZ]; } audio; } parsestate; /* Use a global buffer as scratch-pad for possible conversions of the sampling format */ unsigned char miscplay_sndbuf[SNDBUFSZ]; /* Initialize global parser state information to zero */ void reset_parsestate() { memset(&parsestate,0,sizeof(parsestate)); } /* Verify that we could fully parse the entire soundfile; this is needed only for files in WAVE format */ int parse_wave_complete() { if (parsestate.wave.state != wvOutOfBlock && parsestate.wave.state != wvFatal) { warn("Unexpected end of WAVE file"); return 0; } else return 1; } /* There is no special treatment required for parsing raw data files; we assume that these files contain data in 8bit unsigned format that has been sampled at 8kHz; there is no extra header */ static size_t parseraw(void **data,size_t *sz,void **outbuf) { int rc = *sz; *outbuf = *data; *sz = 0; return(rc); } /* Currently we cannot cope with files in VOC format; if you really need to play these files, they should be converted by using SOX */ static size_t parsevoc(void **data,size_t *sz,void **outbuf) { UNUSED(data); UNUSED(sz); UNUSED(outbuf); return(0); } /* We need to perform some look-ahead in order to parse files in WAVE format; this might require re-partioning of the data segments if headers cross the boundaries between two read operations. This is done in a two-step way: first we request a certain amount of bytes... */ static inline int waverequire(void **data,size_t *sz,size_t rq) { int rc = 1; if (rq > HEADERSZ) { warn("Header size exceeded while parsing WAVE file"); parsestate.wave.state = wvFatal; *sz = 0; return(0); } if ((rq -= parsestate.wave.left) <= 0) return(rc); if (rq > *sz) {rq = *sz; rc = 0;} memcpy(parsestate.wave.leftover+parsestate.wave.left, *data,rq); parsestate.wave.left += rq; (*(unsigned char **)data) += rq; *sz -= rq; return(rc); } /* ...and next we remove this many bytes from the buffer */ static inline void waveremove(size_t rq) { if (parsestate.wave.left <= rq) parsestate.wave.left = 0; else { parsestate.wave.left -= rq; memmove(parsestate.wave.leftover, parsestate.wave.leftover+rq, parsestate.wave.left); } return; } /* Sound files in WAVE format can contain an arbitrary amount of tagged chunks; this requires quite some effort for parsing the data */ static size_t parsewave(void **data,size_t *sz,void **outbuf) { for (;;) switch (parsestate.wave.state) { case wvMain: if (!waverequire(data,sz,20)) return(0); /* Keep compatibility with Linux 68k, etc. by not relying on byte-sex */ parsestate.wave.chunklength = parsestate.wave.leftover[16] + 256*(parsestate.wave.leftover[17] + 256*(parsestate.wave.leftover[18] + 256*parsestate.wave.leftover[19])); waveremove(20); parsestate.wave.state = wvSubchunk; break; case wvSubchunk: if (!waverequire(data,sz,parsestate.wave.chunklength)) return(0); parsestate.wave.align = parsestate.wave.chunklength < 14 ? 1 : parsestate.wave.leftover[12]; if (parsestate.wave.align != 1 && parsestate.wave.align != 2 && parsestate.wave.align != 4) { warn("Illegal datawidth detected while parsing WAVE file"); parsestate.wave.state = wvFatal; } else parsestate.wave.state = wvOutOfBlock; waveremove(parsestate.wave.chunklength); break; case wvOutOfBlock: if (!waverequire(data,sz,8)) return(0); /* Keep compatibility with Linux 68k, etc. by not relying on byte-sex */ parsestate.wave.chunklength = parsestate.wave.leftover[4] + 256*(parsestate.wave.leftover[5] + 256*(parsestate.wave.leftover[6] + 256*(parsestate.wave.leftover[7] & 0x7F))); if (memcmp(parsestate.wave.leftover,"data",4)) parsestate.wave.state = wvSkipChunk; else parsestate.wave.state = wvSoundChunk; waveremove(8); break; case wvSkipChunk: if (parsestate.wave.chunklength > 0 && *sz > 0 && (signed long)*sz < (signed long)parsestate.wave.chunklength) { parsestate.wave.chunklength -= *sz; *sz = 0; } else { if (parsestate.wave.chunklength > 0 && *sz > 0) { *sz -= parsestate.wave.chunklength; (*(unsigned char **)data) += parsestate.wave.chunklength; } parsestate.wave.state = wvOutOfBlock; } break; case wvSoundChunk: { size_t count,rq; if (parsestate.wave.left) { /* handle leftover bytes from last alignment operation */ count = parsestate.wave.left; rq = HEADERSZ-count; if (rq > (size_t) parsestate.wave.chunklength) rq = parsestate.wave.chunklength; if (!waverequire(data,sz,rq)) { parsestate.wave.chunklength -= parsestate.wave.left - count; return(0); } parsestate.wave.chunklength -= rq; *outbuf = parsestate.wave.leftover; parsestate.wave.left = 0; return(rq); } if (*sz >= (size_t) parsestate.wave.chunklength) { count = parsestate.wave.chunklength; rq = 0; } else { count = *sz; count -= rq = count % parsestate.wave.align; } *outbuf = *data; (*(unsigned char **)data) += count; *sz -= count; if ((parsestate.wave.chunklength -= count) < parsestate.wave.align) { parsestate.wave.state = wvOutOfBlock; /* Some broken software (e.g. SOX) attaches junk to the end of a sound chunk; so, let's ignore this... */ if (parsestate.wave.chunklength) parsestate.wave.state = wvSkipChunk; } else if (rq) /* align data length to a multiple of datasize; keep additional data in "leftover" buffer --- this is necessary to ensure proper functioning of the sndcnv... routines */ waverequire(data,sz,rq); return(count); } case wvFatalNotify: warn("Irrecoverable error while parsing WAVE file"); parsestate.wave.state = wvFatal; break; case wvFatal: default: *sz = 0; return(0); } } /* Strip the header from files in Sun/DEC audio format; this requires some extra processing as the header can be an arbitrary size and it might result in alignment errors for subsequent conversions --- thus we do some buffering, where needed */ static size_t parsesundecaudio(void **data,size_t *sz,void **outbuf) { /* There is data left over from the last invocation of this function; join it with the new data and return a sound chunk that is as big as a single entry */ if (parsestate.audio.left) { if (parsestate.audio.left + *sz > (size_t) parsestate.audio.align) { int count; memmove(parsestate.audio.leftover + parsestate.audio.left, *data, count = parsestate.audio.align - parsestate.audio.left); *outbuf = parsestate.audio.leftover; *sz -= count; *data = (*(char **)data) + count; parsestate.audio.left = 0; return(parsestate.audio.align); } else { /* We need even more data in order to get one complete single entry! */ memmove(parsestate.audio.leftover + parsestate.audio.left, *data, *sz); *data = (*(char **)data) + *sz; parsestate.audio.left += *sz; *sz = 0; return(0); } } /* This is the main sound chunk, strip of any extra data that does not fit the alignment requirements and move these bytes into the leftover buffer*/ if (parsestate.audio.isdata) { int rc = *sz; *outbuf = *data; if ((parsestate.audio.left = rc % parsestate.audio.align) != 0) { memmove(parsestate.audio.leftover, (char *)*outbuf + rc - parsestate.audio.left, parsestate.audio.left); rc -= parsestate.audio.left; } *sz = 0; return(rc); } /* This is the first invocation of this function; we need to parse the header information and determine how many bytes we need to skip until the start of the sound chunk */ if (!parsestate.audio.skipping) { unsigned char *header = (unsigned char *) *data; if (*sz < 8) { warn("Irrecoverable error while parsing Sun/DEC audio file"); return(0); } /* Keep compatibility with Linux 68k, etc. by not relying on byte-sex */ if (header[3]) { /* Sun audio (big endian) */ parsestate.audio.align = ((header[15] > 2)+1)*header[23]; parsestate.audio.skipping = header[7]+256*(header[6]+256* (header[5]+256*header[4])); } else { /* DEC audio (little endian) */ parsestate.audio.align = ((header[12] > 2)+1)*header[20]; parsestate.audio.skipping = header[4]+256*(header[5]+256* (header[6]+256*header[7])); }} /* We are skipping extra data that has been attached to header; most usually this will be just a comment, such as the original filename and/or the creation date. Make sure that we do not return less than one single sound sample entry to the caller; if this happens, rather decide to move those few bytes into the leftover buffer and deal with it later */ if (*sz >= (size_t) parsestate.audio.skipping) { /* Skip just the header information and return the sound chunk */ int rc = *sz - parsestate.audio.skipping; *outbuf = (char *)*data + parsestate.audio.skipping; if ((parsestate.audio.left = rc % parsestate.audio.align) != 0) { memmove(parsestate.audio.leftover, (char *)*outbuf + rc - parsestate.audio.left, parsestate.audio.left); rc -= parsestate.audio.left; } *sz = 0; parsestate.audio.skipping = 0; parsestate.audio.isdata++; return(rc); } else { /* Skip everything */ parsestate.audio.skipping -= *sz; return(0); } } /* If the soundcard could not be set to natively support the data format, we try to do some limited on-the-fly conversion to a different format; if no conversion is needed, though, we can output directly */ size_t sndcnvnop(void **data,size_t *sz,void **outbuf) { int rc = *sz; *outbuf = *data; *sz = 0; return(rc); } /* Convert 8 bit unsigned stereo data to 8 bit unsigned mono data */ size_t sndcnv8U_2mono(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; count = *sz / 2; if (count > SNDBUFSZ) { *sz -= 2*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; while (count--) *dest++ = (unsigned char)(((int)*(src)++ + (int)*(src)++) / 2); *data = src; return(rc); } /* Convert 8 bit signed stereo data to 8 bit signed mono data */ size_t sndcnv8S_2mono(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc, count; count = *sz / 2; if (count > SNDBUFSZ) { *sz -= 2*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; while (count--) *dest++ = (unsigned char)(((int)*((signed char *)(src++)) + (int)*((signed char *)(src++))) / 2); *data = src; return(rc); } /* Convert 8 bit signed stereo data to 8 bit unsigned mono data */ size_t sndcnv2monounsigned(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; count = *sz / 2; if (count > SNDBUFSZ) { *sz -= 2*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; while (count--) *dest++ = (unsigned char)(((int)*((signed char *)(src++)) + (int)*((signed char *)(src++))) / 2) ^ 0x80; *data = src; return(rc); } /* Convert 8 bit signed mono data to 8 bit unsigned mono data */ size_t sndcnv2unsigned(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; count = *sz; if (count > SNDBUFSZ) { *sz -= SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; while (count--) *dest++ = *(src)++ ^ 0x80; *data = src; return(rc); } /* Convert a number in the range -32768..32767 to an 8 bit ulaw encoded number --- I hope, I got this conversion right :-) */ static inline signed char int2ulaw(int i) { /* Lookup table for fast calculation of number of bits that need shifting*/ static short int t_bits[128] = { 0,1,2,2,3,3,3,3,4,4,4,4,4,4,4,4,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5, 6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6, 7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7, 7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7}; REGISTER int bits,logi; /* unrolling this condition (hopefully) improves execution speed */ if (i < 0) { if ((i = (132-i)) > 0x7FFF) i = 0x7FFF; logi = (i >> ((bits = t_bits[i/256])+4)); return((bits << 4 | logi) ^ 0x7F); } else { if ((i = 132+i) > 0x7FFF) i = 0x7FFF; logi = (i >> ((bits = t_bits[i/256])+4)); return(~(bits << 4 | logi)); } } /* Convert from 8 bit ulaw mono to 8 bit linear mono */ size_t sndcnvULaw_2linear(void **data,size_t *sz,void **outbuf) { /* conversion table stolen from Linux's ulaw.h */ static unsigned char ulaw_dsp[] = { 3, 7, 11, 15, 19, 23, 27, 31, 35, 39, 43, 47, 51, 55, 59, 63, 66, 68, 70, 72, 74, 76, 78, 80, 82, 84, 86, 88, 90, 92, 94, 96, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 113, 114, 114, 115, 115, 116, 116, 117, 117, 118, 118, 119, 119, 120, 120, 121, 121, 121, 122, 122, 122, 122, 123, 123, 123, 123, 124, 124, 124, 124, 125, 125, 125, 125, 125, 125, 126, 126, 126, 126, 126, 126, 126, 126, 127, 127, 127, 127, 127, 127, 127, 127, 127, 127, 127, 127, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 253, 249, 245, 241, 237, 233, 229, 225, 221, 217, 213, 209, 205, 201, 197, 193, 190, 188, 186, 184, 182, 180, 178, 176, 174, 172, 170, 168, 166, 164, 162, 160, 158, 157, 156, 155, 154, 153, 152, 151, 150, 149, 148, 147, 146, 145, 144, 143, 143, 142, 142, 141, 141, 140, 140, 139, 139, 138, 138, 137, 137, 136, 136, 135, 135, 135, 134, 134, 134, 134, 133, 133, 133, 133, 132, 132, 132, 132, 131, 131, 131, 131, 131, 131, 130, 130, 130, 130, 130, 130, 130, 130, 129, 129, 129, 129, 129, 129, 129, 129, 129, 129, 129, 129, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, 128, }; unsigned char *p=(unsigned char *)*data; *outbuf = *data; while ((*sz)--) *p++ = ulaw_dsp[*p]; *sz = 0; *data = p; return p - (unsigned char *)*outbuf; } /* Convert 8 bit ulaw stereo data to 8 bit ulaw mono data */ size_t sndcnvULaw_2mono(void **data,size_t *sz,void **outbuf) { static short int ulaw2int[256] = { /* Precomputed lookup table for conversion from ulaw to 15 bit signed */ -16062,-15550,-15038,-14526,-14014,-13502,-12990,-12478, -11966,-11454,-10942,-10430, -9918, -9406, -8894, -8382, -7998, -7742, -7486, -7230, -6974, -6718, -6462, -6206, -5950, -5694, -5438, -5182, -4926, -4670, -4414, -4158, -3966, -3838, -3710, -3582, -3454, -3326, -3198, -3070, -2942, -2814, -2686, -2558, -2430, -2302, -2174, -2046, -1950, -1886, -1822, -1758, -1694, -1630, -1566, -1502, -1438, -1374, -1310, -1246, -1182, -1118, -1054, -990, -942, -910, -878, -846, -814, -782, -750, -718, -686, -654, -622, -590, -558, -526, -494, -462, -438, -422, -406, -390, -374, -358, -342, -326, -310, -294, -278, -262, -246, -230, -214, -198, -186, -178, -170, -162, -154, -146, -138, -130, -122, -114, -106, -98, -90, -82, -74, -66, -60, -56, -52, -48, -44, -40, -36, -32, -28, -24, -20, -16, -12, -8, -4, +0, +16062,+15550,+15038,+14526,+14014,+13502,+12990,+12478, +11966,+11454,+10942,+10430, +9918, +9406, +8894, +8382, +7998, +7742, +7486, +7230, +6974, +6718, +6462, +6206, +5950, +5694, +5438, +5182, +4926, +4670, +4414, +4158, +3966, +3838, +3710, +3582, +3454, +3326, +3198, +3070, +2942, +2814, +2686, +2558, +2430, +2302, +2174, +2046, +1950, +1886, +1822, +1758, +1694, +1630, +1566, +1502, +1438, +1374, +1310, +1246, +1182, +1118, +1054, +990, +942, +910, +878, +846, +814, +782, +750, +718, +686, +654, +622, +590, +558, +526, +494, +462, +438, +422, +406, +390, +374, +358, +342, +326, +310, +294, +278, +262, +246, +230, +214, +198, +186, +178, +170, +162, +154, +146, +138, +130, +122, +114, +106, +98, +90, +82, +74, +66, +60, +56, +52, +48, +44, +40, +36, +32, +28, +24, +20, +16, +12, +8, +4, +0}; REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; count = *sz / 2; if (count > SNDBUFSZ) { *sz -= 2*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; while (count--) /* it is not possible to directly interpolate between two ulaw encoded data bytes, thus we need to convert to linear format first and later we convert back to ulaw format */ *dest++ = int2ulaw(ulaw2int[*(src)++] + ulaw2int[*(src)++]); *data = src; return(rc); } size_t sndcnv16swap(void **data,size_t *sz,void **outbuf) { size_t cnt = *sz / 2; unsigned short *p; *outbuf = *data; p = (unsigned short *) *outbuf; while (cnt--) { *p++ = ((*p & 0x00ff) << 8) | (*p >> 8); } *data = p; cnt = *sz; *sz = 0; return cnt; } /* Convert 16 bit little endian signed stereo data to 16 bit little endian signed mono data */ size_t sndcnv16_2monoLE(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; signed short i; count = *sz / 2; if (count > SNDBUFSZ) { *sz -= 2*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; for (count /= 2; count--; ) { i = ((int)(src[0]) + 256*(int)(src[1]) + (int)(src[2]) + 256*(int)(src[3])) / 2; src += 4; *dest++ = (unsigned char)(i & 0xFF); *dest++ = (unsigned char)((i / 256) & 0xFF); } *data = src; return(rc); } /* Convert 16 bit big endian signed stereo data to 16 bit big endian signed mono data */ size_t sndcnv16_2monoBE(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; signed short i; count = *sz / 2; if (count > SNDBUFSZ) { *sz -= 2*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; for (count /= 2; count--; ) { i = ((int)(src[1]) + 256*(int)(src[0]) + (int)(src[3]) + 256*(int)(src[2])) / 2; src += 4; *dest++ = (unsigned char)((i / 256) & 0xFF); *dest++ = (unsigned char)(i & 0xFF); } *data = src; return(rc); } /* Convert 16 bit little endian signed data to 8 bit unsigned data */ size_t sndcnv2byteLE(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; count = *sz / 2; if (count > SNDBUFSZ) { *sz -= 2*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; while (count--) { *dest++ = (unsigned char)(((signed char *)src)[1] ^ (signed char)0x80); src += 2; } *data = src; return(rc); } /* Convert 16 bit big endian signed data to 8 bit unsigned data */ size_t sndcnv2byteBE(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; count = *sz / 2; if (count > SNDBUFSZ) { *sz -= 2*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; while (count--) { *dest++ = (unsigned char)(((signed char *)src)[0] ^ (signed char)0x80); src += 2; } *data = src; return(rc); } /* Convert 16 bit little endian signed stereo data to 8 bit unsigned mono data */ size_t sndcnv2monobyteLE(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; count = *sz / 4; if (count > SNDBUFSZ) { *sz -= 4*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; while (count--) { *dest++ = (unsigned char)(((int)((signed char *)src)[1] + (int)((signed char *)src)[3]) / 2 ^ 0x80); src += 4; } *data = src; return(rc); } /* Convert 16 bit big endian signed stereo data to 8 bit unsigned mono data */ size_t sndcnv2monobyteBE(void **data,size_t *sz,void **outbuf) { REGISTER unsigned char *src; REGISTER unsigned char *dest; int rc,count; count = *sz / 4; if (count > SNDBUFSZ) { *sz -= 4*SNDBUFSZ; count = SNDBUFSZ; } else *sz = 0; rc = count; src = (unsigned char *) *data; *outbuf = dest = miscplay_sndbuf; while (count--) { *dest++ = (unsigned char)(((int)((signed char *)src)[0] + (int)((signed char *)src)[2]) / 2 ^ 0x80); src += 4; } *data = src; return(rc); } /* Look at the header of the sound file and try to determine the format; we can recognize files in VOC, WAVE, and, Sun/DEC-audio format--- everything else is assumed to be raw 8 bit unsigned data sampled at 8kHz */ fmtType analyze_format(unsigned char *format,int *fmt,int *speed, int *tracks, size_t (**parsesndfile)(void **,size_t *sz, void **)) { /* Keep compatibility with Linux 68k, etc. by not relying on byte-sex */ if (!memcmp(format,"Creative Voice File\x1A\x1A\x00",22) && (format[22]+256*format[23]) == ((0x1233-format[24]-256*format[25])&0xFFFF)) { /* VOC */ *fmt = AFMT_U8; *speed = 8000; *tracks = 2; *parsesndfile = parsevoc; return(fmtVoc); } else if (!memcmp(format,"RIFF",4) && !memcmp(format+8,"WAVEfmt ",8)) { /* WAVE */ if (memcmp(format+20,"\001\000\001"/* PCM mono */,4) && memcmp(format+20,"\001\000\002"/* PCM stereo */,4)) return(fmtIllegal); *fmt = (format[32]/(*tracks = format[22])) == 1 ? AFMT_U8 : AFMT_S16_LE; /* Keep compatibility with Linux 68k, etc. by not relying on byte-sex */ *speed = format[24]+256*(format[25]+256* (format[26]+256*format[27])); *parsesndfile = parsewave; return(fmtWave); } else if (!memcmp(format,".snd",4)) { /* Sun Audio (big endian) */ if (format[7]+256*(format[6]+256*(format[5]+256*format[4])) < 24) { *fmt = AFMT_MU_LAW; *speed = 8000; *tracks = 1; *parsesndfile = parsesundecaudio; return(fmtSunAudio); } if (!memcmp(format+12,"\000\000\000\001",4)) *fmt = AFMT_MU_LAW; else if (!memcmp(format+12,"\000\000\000\002",4)) *fmt = AFMT_S8; else if (!memcmp(format+12,"\000\000\000\003",4)) *fmt = AFMT_S16_BE; else return(fmtIllegal); /* Keep compatibility with Linux 68k, etc. by not relying on byte-sex */ *speed = format[19]+256*(format[18]+256* (format[17]+256*format[16])); *tracks = format[23]; *parsesndfile = parsesundecaudio; return(fmtSunAudio); } else if (!memcmp(format,".sd",4)) { /* DEC Audio (little endian) */ if (format[4]+256*(format[5]+256*(format[6]+256*format[7])) < 24) { *fmt = AFMT_MU_LAW; *speed = 8000; *tracks = 1; *parsesndfile = parsesundecaudio; return(fmtSunAudio); } if (!memcmp(format+12,"\001\000\000",4)) *fmt = AFMT_MU_LAW; else if (!memcmp(format+12,"\002\000\000",4)) *fmt = AFMT_S8; else if (!memcmp(format+12,"\003\000\000",4)) *fmt = AFMT_S16_LE; else return(fmtIllegal); /* Keep compatibility with Linux 68k, etc. by not relying on byte-sex */ *speed = format[16]+256*(format[17]+256* (format[18]+256*format[19])); *tracks = format[20]; *parsesndfile = parsesundecaudio; return(fmtSunAudio); } else { *fmt = AFMT_U8; *speed = 8000; *tracks = 1; *parsesndfile = parseraw; return(fmtRaw); } }