ref: ceffff92190351bc83dc94fbfb72dc31a481ceea
dir: /src/tx16w.c/
/* libSoX Yamaha TX-16W sampler file support * * May 20, 1993 * Copyright 1993 Rob Talley (rob@aii.com) * This source code is freely redistributable and may be used for * any purpose. This copyright notice and the following copyright * notice must be maintained intact. No warranty whatsoever is * provided. This code is furnished AS-IS as a component of the * larger work Copyright 1991 Lance Norskog and Sundry Contributors. * Much appreciation to ross-c for his sampConv utility for SGI/IRIX * from where these methods were derived. * * Jan 24, 1994 * Pat McElhatton, HP Media Technology Lab <patmc@apollo.hp.com> * Handles reading of files which do not have the sample rate field * set to one of the expected by looking at some other bytes in the * attack/loop length fields, and defaulting to 33kHz if the sample * rate is still unknown. * * January 12, 1995 * Copyright 1995 Mark Lakata (lakata@physics.berkeley.edu) * Additions to tx16w.c SOX handler. This version writes as well as * reads TX16W format. * * July 31, 1998 * Cleaned up by Leigh Smith (leigh@psychokiller.dialix.oz.au) * for incorporation into the main sox distribution. * * September 24, 1998 * Forced output to mono signed words to match input. It was basically * doing this anyways but now the user will see a display that it's been * overridden. cbagwell@sprynet.com * */ #include "sox_i.h" #include <stdio.h> #include <string.h> #define TXMAXLEN 0x3FF80 /* Private data for TX16 file */ typedef struct { size_t samples_out; size_t bytes_out; size_t rest; /* bytes remaining in sample file */ sox_sample_t odd; sox_bool odd_flag; } priv_t; struct WaveHeader_ { char filetype[6]; /* = "LM8953", */ unsigned char nulls[10], dummy_aeg[6], /* space for the AEG (never mind this) */ format, /* 0x49 = looped, 0xC9 = non-looped */ sample_rate, /* 1 = 33 kHz, 2 = 50 kHz, 3 = 16 kHz */ atc_length[3], /* I'll get to this... */ rpt_length[3], unused[2]; /* set these to null, to be on the safe side */ }; static const unsigned char magic1[4] = {0, 0x06, 0x10, 0xF6}; static const unsigned char magic2[4] = {0, 0x52, 0x00, 0x52}; /* * 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) { int c; char filetype[7]; int8_t format; unsigned char sample_rate; size_t num_samp_bytes = 0; unsigned char gunk[8]; int blewIt; uint8_t trash; priv_t * sk = (priv_t *) ft->priv; /* If you need to seek around the input file. */ if (! ft->seekable) { lsx_fail_errno(ft,SOX_EOF,"txw input file must be a file, not a pipe"); return(SOX_EOF); } /* This is dumb but portable, just count the bytes til EOF */ while (lsx_read_b_buf(ft, &trash, (size_t) 1) == 1) num_samp_bytes++; num_samp_bytes -= 32; /* calculate num samples by sub header size */ lsx_seeki(ft, (off_t)0, 0); /* rewind file */ sk->rest = num_samp_bytes; /* set how many sample bytes to read */ /* first 6 bytes are file type ID LM8953 */ lsx_readchars(ft, filetype, sizeof(filetype) - 1); filetype[6] = '\0'; for( c = 16; c > 0 ; c-- ) /* Discard next 16 bytes */ lsx_readb(ft, &trash); lsx_readsb(ft, &format); lsx_readb(ft, &sample_rate); /* * save next 8 bytes - if sample rate is 0, then we need * to look at gunk[2] and gunk[5] to get real rate */ for( c = 0; c < 8; c++ ) lsx_readb(ft, &(gunk[c])); /* * We should now be pointing at start of raw sample data in file */ /* Check to make sure we got a good filetype ID from file */ lsx_debug("Found header filetype %s",filetype); if(strcmp(filetype,"LM8953")) { lsx_fail_errno(ft,SOX_EHDR,"Invalid filetype ID in input file header, != LM8953"); return(SOX_EOF); } /* * Set up the sample rate as indicated by the header */ switch( sample_rate ) { case 1: ft->signal.rate = 1e5 / 3; break; case 2: ft->signal.rate = 1e5 / 2; break; case 3: ft->signal.rate = 1e5 / 6; break; default: blewIt = 1; switch( gunk[2] & 0xFE ) { case 0x06: if ( (gunk[5] & 0xFE) == 0x52 ) { blewIt = 0; ft->signal.rate = 1e5 / 3; } break; case 0x10: if ( (gunk[5] & 0xFE) == 0x00 ) { blewIt = 0; ft->signal.rate = 1e5 / 2; } break; case 0xF6: if ( (gunk[5] & 0xFE) == 0x52 ) { blewIt = 0; ft->signal.rate = 1e5 / 6; } break; } if ( blewIt ) { lsx_debug("Invalid sample rate identifier found %d", sample_rate); ft->signal.rate = 1e5 / 3; } } lsx_debug("Sample rate = %g", ft->signal.rate); ft->signal.channels = 1 ; /* not sure about stereo sample data yet ??? */ ft->encoding.bits_per_sample = 12; ft->encoding.encoding = SOX_ENCODING_SIGN2; return(SOX_SUCCESS); } /* * Read up to len samples from file. * Convert to sox_sample_t. * Place in buf[]. * Return number of samples read. */ static size_t read_samples(sox_format_t * ft, sox_sample_t *buf, size_t len) { priv_t * sk = (priv_t *) ft->priv; size_t done = 0; unsigned char uc1,uc2,uc3; unsigned short s1,s2; /* * This gets called by the top level 'process' routine. * We will essentially get called with a buffer pointer * and a max length to read. Graciously, it is always * an even amount so we don't have to worry about * hanging onto the left over odd samples since there * won't be any. Something to look out for though :-( * We return the number of samples we read. * We will get called over and over again until we return * 0 bytes read. */ /* * This is ugly but it's readable! * Read three bytes from stream, then decompose these into * two unsigned short samples. * TCC 3.0 appeared to do unwanted things, so we really specify * exactly what we want to happen. * Convert unsigned short to sox_sample_t then shift up the result * so that the 12-bit sample lives in the most significant * 12-bits of the sox_sample_t. * This gets our two samples into the internal format which we * deposit into the given buffer and adjust our counts respectivly. */ for(done = 0; done < len; ) { if(sk->rest < 3) break; /* Finished reading from file? */ lsx_readb(ft, &uc1); lsx_readb(ft, &uc2); lsx_readb(ft, &uc3); sk->rest -= 3; /* adjust remaining for bytes we just read */ s1 = (unsigned short) (uc1 << 4) | (((uc2 >> 4) & 017)); s2 = (unsigned short) (uc3 << 4) | (( uc2 & 017 )); *buf = (sox_sample_t) s1; *buf = (*buf << 20); buf++; /* sample one is done */ *buf = (sox_sample_t) s2; *buf = (*buf << 20); buf++; /* sample two is done */ done += 2; /* adjust converted & stored sample count */ } return done; } static int startwrite(sox_format_t * ft) { priv_t * sk = (priv_t *) ft->priv; struct WaveHeader_ WH; lsx_debug("tx16w selected output"); memset(&WH, 0, sizeof(struct WaveHeader_)); /* If you have to seek around the output file */ if (! ft->seekable) { lsx_fail_errno(ft,SOX_EOF,"Output .txw file must be a file, not a pipe"); return(SOX_EOF); } /* dummy numbers, just for place holder, real header is written at end of processing, since byte count is needed */ lsx_writebuf(ft, &WH, (size_t) 32); sk->bytes_out = 32; return(SOX_SUCCESS); } static size_t write_samples(sox_format_t * ft, const sox_sample_t *buf, size_t len0) { priv_t * sk = (priv_t *) ft->priv; size_t last_i, i = 0, len = min(len0, TXMAXLEN - sk->samples_out); sox_sample_t w1, w2; while (i < len) { last_i = i; if (sk->odd_flag) { w1 = sk->odd; sk->odd_flag = sox_false; } else w1 = *buf++ >> 20, ++i; if (i < len) { w2 = *buf++ >> 20, ++i; if (lsx_writesb(ft, (w1 >> 4) & 0xFF) || lsx_writesb(ft, (((w1 & 0x0F) << 4) | (w2 & 0x0F)) & 0xFF) || lsx_writesb(ft, (w2 >> 4) & 0xFF)) { i = last_i; break; } sk->samples_out += 2; sk->bytes_out += 3; } else { sk->odd = w1; sk->odd_flag = sox_true; } } return i; } static int stopwrite(sox_format_t * ft) { priv_t * sk = (priv_t *) ft->priv; struct WaveHeader_ WH; int AttackLength, LoopLength, i; if (sk->odd_flag) { sox_sample_t pad = 0; write_samples(ft, &pad, (size_t) 1); } /* All samples are already written out. */ /* If file header needs fixing up, for example it needs the */ /* the number of samples in a field, seek back and write them here. */ lsx_debug("tx16w:output finished"); memset(&WH, 0, sizeof(struct WaveHeader_)); memcpy(WH.filetype, "LM8953", 6); for (i=0;i<10;i++) WH.nulls[i]=0; for (i=0;i<6;i++) WH.dummy_aeg[i]=0; for (i=0;i<2;i++) WH.unused[i]=0; for (i=0;i<2;i++) WH.dummy_aeg[i] = 0; for (i=2;i<6;i++) WH.dummy_aeg[i] = 0x7F; WH.format = 0xC9; /* loop off */ /* the actual sample rate is not that important ! */ if (ft->signal.rate < 24000) WH.sample_rate = 3; else if (ft->signal.rate < 41000) WH.sample_rate = 1; else WH.sample_rate = 2; if (sk->samples_out >= TXMAXLEN) { lsx_warn("Sound too large for TX16W. Truncating, Loop Off"); AttackLength = TXMAXLEN/2; LoopLength = TXMAXLEN/2; } else if (sk->samples_out >=TXMAXLEN/2) { AttackLength = TXMAXLEN/2; LoopLength = sk->samples_out - TXMAXLEN/2; if (LoopLength < 0x40) { LoopLength +=0x40; AttackLength -= 0x40; } } else if (sk->samples_out >= 0x80) { AttackLength = sk->samples_out -0x40; LoopLength = 0x40; } else { AttackLength = 0x40; LoopLength = 0x40; for(i=sk->samples_out;i<0x80;i++) { lsx_writeb(ft, 0); lsx_writeb(ft, 0); lsx_writeb(ft, 0); sk->bytes_out += 3; } } /* Fill up to 256 byte blocks; the TX16W seems to like that */ while ((sk->bytes_out % 0x100) != 0) { lsx_writeb(ft, 0); sk->bytes_out++; } WH.atc_length[0] = 0xFF & AttackLength; WH.atc_length[1] = 0xFF & (AttackLength >> 8); WH.atc_length[2] = (0x01 & (AttackLength >> 16)) + magic1[WH.sample_rate]; WH.rpt_length[0] = 0xFF & LoopLength; WH.rpt_length[1] = 0xFF & (LoopLength >> 8); WH.rpt_length[2] = (0x01 & (LoopLength >> 16)) + magic2[WH.sample_rate]; lsx_rewind(ft); lsx_writebuf(ft, &WH, (size_t) 32); return(SOX_SUCCESS); } LSX_FORMAT_HANDLER(txw) { static char const * const names[] = {"txw", NULL}; static sox_rate_t const write_rates[] = {1e5/6, 1e5/3, 1e5/2, 0}; static unsigned const write_encodings[] = {SOX_ENCODING_SIGN2, 12, 0, 0}; static sox_format_handler_t const handler = {SOX_LIB_VERSION_CODE, "Yamaha TX-16W sampler", names, SOX_FILE_MONO, startread, read_samples, NULL, startwrite, write_samples, stopwrite, NULL, write_encodings, write_rates, sizeof(priv_t) }; return &handler; }