ref: b691654525bcadb8474734fd421943a8708d4c84
dir: /common/libsndfile/src/paf.c/
/* ** Copyright (C) 1999-2000 Erik de Castro Lopo <erikd@zip.com.au> ** ** This program is free software; you can redistribute it and/or modify ** it under the terms of the GNU Lesser General Public License as published by ** the Free Software Foundation; either version 2.1 of the License, or ** (at your option) any later version. ** ** This program is distributed in the hope that it will be useful, ** but WITHOUT ANY WARRANTY; without even the implied warranty of ** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ** GNU Lesser General Public License for more details. ** ** You should have received a copy of the GNU Lesser General Public License ** along with this program; if not, write to the Free Software ** Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include <stdio.h> #include <unistd.h> #include <fcntl.h> #include <string.h> #include <ctype.h> #include "sndfile.h" #include "config.h" #include "sfendian.h" #include "common.h" #include "pcm.h" /*------------------------------------------------------------------------------ ** Macros to handle big/little endian issues. */ #if (CPU_IS_LITTLE_ENDIAN == 1) # define MAKE_MARKER(a,b,c,d) ((a)|((b)<<8)|((c)<<16)|((d)<<24)) #elif (CPU_IS_BIG_ENDIAN == 1) # define MAKE_MARKER(a,b,c,d) (((a)<<24)|((b)<<16)|((c)<<8)|(d)) #else # error "Cannot determine endian-ness of processor." #endif #define FAP_MARKER (MAKE_MARKER ('f', 'a', 'p', ' ')) #define PAF_MARKER (MAKE_MARKER (' ', 'p', 'a', 'f')) /*------------------------------------------------------------------------------ ** Other defines. */ #define PAF_HEADER_LENGTH 2048 /*------------------------------------------------------------------------------ ** Typedefs. */ typedef struct { unsigned int version ; unsigned int endianness ; unsigned int samplerate ; unsigned int format ; unsigned int channels ; unsigned int source ; } PAF_FMT ; typedef struct { unsigned int index, blocks, channels, samplesperblock, blockcount, blocksize, samplecount ; unsigned char *block ; int *samples ; unsigned char data [4] ; } PAF24_PRIVATE ; /*------------------------------------------------------------------------------ ** Private static functions. */ static int paf24_reader_init (SF_PRIVATE *psf) ; static int paf24_writer_init (SF_PRIVATE *psf) ; static int paf24_read_block (SF_PRIVATE *psf, PAF24_PRIVATE *ppaf24) ; static int paf24_close (SF_PRIVATE *psf) ; static int paf24_read_s (SF_PRIVATE *psf, short *ptr, int len) ; static int paf24_read_i (SF_PRIVATE *psf, int *ptr, int len) ; static int paf24_read_d (SF_PRIVATE *psf, double *ptr, int len, int normalize) ; static int paf24_write_s (SF_PRIVATE *psf, short *ptr, int len) ; static int paf24_write_i (SF_PRIVATE *psf, int *ptr, int len) ; static int paf24_write_d (SF_PRIVATE *psf, double *ptr, int len, int normalize) ; static off_t paf24_seek (SF_PRIVATE *psf, off_t offset, int whence) ; static void endswap_paf_fmt (PAF_FMT *ppaf_fmt) ; /*------------------------------------------------------------------------------ ** Public functions. */ int paf_open_read (SF_PRIVATE *psf) { PAF_FMT paf_fmt ; unsigned int marker ; int error ; fread (&marker, sizeof (marker), 1, psf->file) ; if (marker != PAF_MARKER && marker != FAP_MARKER) return SFE_PAF_NO_MARKER ; psf_sprintf (psf, "Signature : %D\n", marker) ; fread (&paf_fmt, sizeof (PAF_FMT), 1, psf->file) ; if (CPU_IS_LITTLE_ENDIAN && marker == PAF_MARKER) endswap_paf_fmt (&paf_fmt) ; else if (CPU_IS_BIG_ENDIAN && marker == FAP_MARKER) endswap_paf_fmt (&paf_fmt) ; psf_sprintf (psf, "Version : %d\n", paf_fmt.version) ; if (paf_fmt.version != 0) { psf_sprintf (psf, "*** Bad version number. Should be zero.\n") ; return SFE_PAF_VERSION ; } ; psf_sprintf (psf, "Endianness : %d => ", paf_fmt.endianness) ; if (paf_fmt.endianness) psf_sprintf (psf, "Little\n", paf_fmt.endianness) ; else psf_sprintf (psf, "Big\n", paf_fmt.endianness) ; psf_sprintf (psf, "Sample Rate : %d\n", paf_fmt.samplerate) ; if (psf->filelength < PAF_HEADER_LENGTH) return SFE_PAF_SHORT_HEADER ; psf->dataoffset = PAF_HEADER_LENGTH ; psf->datalength = psf->filelength - psf->dataoffset ; psf->current = 0 ; psf->endian = paf_fmt.endianness ? SF_ENDIAN_LITTLE : SF_ENDIAN_BIG ; psf->sf.seekable = SF_TRUE ; if (fseek (psf->file, psf->dataoffset, SEEK_SET)) return SFE_BAD_SEEK ; psf->sf.samplerate = paf_fmt.samplerate ; psf->sf.channels = paf_fmt.channels ; /* Only fill in type major. */ psf->sf.format = SF_FORMAT_PAF ; psf->sf.sections = 1 ; psf_sprintf (psf, "Format : %d => ", paf_fmt.format) ; switch (paf_fmt.format) { case 0 : psf_sprintf (psf, "16 bit linear PCM\n") ; psf->sf.pcmbitwidth = 16 ; psf->bytewidth = BITWIDTH2BYTES (psf->sf.pcmbitwidth) ; psf->sf.format |= paf_fmt.endianness ? SF_FORMAT_PCM_LE : SF_FORMAT_PCM_BE ; ; if (psf->endian == SF_ENDIAN_BIG) { psf->read_short = (func_short) pcm_read_bes2s ; psf->read_int = (func_int) pcm_read_bes2i ; psf->read_double = (func_double) pcm_read_bes2d ; } else { psf->read_short = (func_short) pcm_read_les2s ; psf->read_int = (func_int) pcm_read_les2i ; psf->read_double = (func_double) pcm_read_les2d ; } ; psf->blockwidth = psf->bytewidth * psf->sf.channels ; psf_sprintf (psf, "X blockwidth : %d\n", psf->blockwidth) ; if (psf->blockwidth) psf->sf.samples = psf->datalength / psf->blockwidth ; else psf_sprintf (psf, "*** Warning : blockwidth == 0.\n") ; psf_sprintf (psf, "X samples : %d\n", psf->sf.samples) ; break ; case 1 : psf_sprintf (psf, "24 bit linear PCM\n") ; psf->sf.pcmbitwidth = 24 ; psf->bytewidth = BITWIDTH2BYTES (psf->sf.pcmbitwidth) ; psf->sf.format |= paf_fmt.endianness ? SF_FORMAT_PCM_LE : SF_FORMAT_PCM_BE ; ; psf->read_short = (func_short) paf24_read_s ; psf->read_int = (func_int) paf24_read_i ; psf->read_double = (func_double) paf24_read_d ; if ((error = paf24_reader_init (psf))) return error ; psf->seek_func = (func_seek) paf24_seek ; psf->close = (func_close) paf24_close ; psf->blockwidth = psf->bytewidth * psf->sf.channels ; psf_sprintf (psf, "X blockwidth : %d\n", psf->blockwidth) ; psf->sf.samples = 10 * psf->datalength / (32 * psf->sf.channels) ; psf_sprintf (psf, "X samples : %d\n", psf->sf.samples) ; break ; default : psf_sprintf (psf, "Unknown\n") ; return SFE_PAF_UNKNOWN_FORMAT ; break ; } ; psf_sprintf (psf, "Channels : %d\n", paf_fmt.channels) ; psf_sprintf (psf, "Source : %d => ", paf_fmt.source) ; switch (paf_fmt.source) { case 1 : psf_sprintf (psf, "Analog Recording\n") ; break ; case 2 : psf_sprintf (psf, "Digital Transfer\n") ; break ; case 3 : psf_sprintf (psf, "Multi-track Mixdown\n") ; break ; case 5 : psf_sprintf (psf, "Audio Resulting From DSP Processing\n") ; break ; default : psf_sprintf (psf, "Unknown\n") ; break ; } ; return 0 ; } /* paf_open_read */ /*------------------------------------------------------------------------------ */ int paf_open_write (SF_PRIVATE *psf) { PAF_FMT paf_fmt ; int format, subformat, error, count ; unsigned int marker, big_endian_file ; format = psf->sf.format & SF_FORMAT_TYPEMASK ; subformat = psf->sf.format & SF_FORMAT_SUBMASK ; if (format != SF_FORMAT_PAF) return SFE_BAD_OPEN_FORMAT ; if (subformat == SF_FORMAT_PCM_BE) { big_endian_file = 1 ; paf_fmt.endianness = 0 ; } else if (subformat == SF_FORMAT_PCM_LE) { big_endian_file = 0 ; paf_fmt.endianness = 1 ; } else return SFE_BAD_OPEN_FORMAT ; paf_fmt.version = 0 ; paf_fmt.samplerate = psf->sf.samplerate ; switch (psf->sf.pcmbitwidth) { case 16 : paf_fmt.format = 0 ; psf->bytewidth = 2 ; break ; case 24 : paf_fmt.format = 1 ; psf->bytewidth = 3 ; break ; default : return SFE_PAF_UNKNOWN_FORMAT ; } ; paf_fmt.channels = psf->sf.channels ; paf_fmt.source = 0 ; psf->bytewidth = BITWIDTH2BYTES (psf->sf.pcmbitwidth) ; psf->endian = big_endian_file ? SF_ENDIAN_BIG : SF_ENDIAN_LITTLE ; psf->sf.seekable = SF_TRUE ; psf->blockwidth = psf->bytewidth * psf->sf.channels ; psf->dataoffset = PAF_HEADER_LENGTH ; psf->datalength = psf->blockwidth * psf->sf.samples ; psf->filelength = psf->datalength + psf->dataoffset ; psf->error = 0 ; switch (paf_fmt.format) { case 0 : /* 16-bit linear PCM. */ if (big_endian_file) { psf->write_short = (func_short) pcm_write_s2bes ; psf->write_int = (func_int) pcm_write_i2bes ; psf->write_double = (func_double) pcm_write_d2bes ; } else { psf->write_short = (func_short) pcm_write_s2les ; psf->write_int = (func_int) pcm_write_i2les ; psf->write_double = (func_double) pcm_write_d2les ; } ; break ; case 1 : /* 24-bit linear PCM */ psf->write_short = (func_short) paf24_write_s ; psf->write_int = (func_int) paf24_write_i ; psf->write_double = (func_double) paf24_write_d ; if ((error = paf24_writer_init (psf))) return error ; psf->seek_func = (func_seek) paf24_seek ; psf->close = (func_close) paf24_close ; break ; default : break ; } ; if (big_endian_file) { if (CPU_IS_LITTLE_ENDIAN) endswap_paf_fmt (&paf_fmt) ; marker = PAF_MARKER ; } else { if (CPU_IS_BIG_ENDIAN) endswap_paf_fmt (&paf_fmt) ; marker = FAP_MARKER ; } ; fwrite (&marker, sizeof (marker), 1, psf->file) ; fwrite (&paf_fmt, sizeof (PAF_FMT), 1, psf->file) ; /* Fill the file from current position to dataoffset with zero bytes. */ memset (psf->buffer, 0, sizeof (psf->buffer)) ; count = psf->dataoffset - ftell (psf->file) ; while (count > 0) { int current = (count > sizeof (psf->buffer)) ? sizeof (psf->buffer) : count ; fwrite (psf->buffer, current, 1, psf->file) ; count -= current ; } ; return 0 ; } /* paf_open_write */ /*=============================================================================== ** 24 bit PAF files have a really weird encoding. ** For a mono file, 10 samples (each being 3 bytes) are packed into a 32 byte ** block. The 8 ints in this 32 byte block are then endian swapped (as ints) ** if necessary before being written to disk. ** For a stereo file, blocks of 10 samples from the same channel are encoded ** into 32 bytes as fro the mono case. The 32 block bytes are then interleaved ** on disk. ** Reading has to reverse the above process :-). ** Weird!!! ** ** The code below attempts to gain efficiency while maintaining readability. */ static int paf24_reader_init (SF_PRIVATE *psf) { PAF24_PRIVATE *ppaf24 ; unsigned int paf24size ; paf24size = sizeof (PAF24_PRIVATE) + psf->sf.channels * (32 + 10 * sizeof (int)) ; if (! (psf->fdata = malloc (paf24size))) return SFE_MALLOC_FAILED ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; memset (ppaf24, 0, paf24size) ; ppaf24->channels = psf->sf.channels ; ppaf24->block = (unsigned char*) ppaf24->data ; ppaf24->samples = (int*) (ppaf24->data + 32 * ppaf24->channels) ; ppaf24->blocksize = 32 * ppaf24->channels ; ppaf24->samplesperblock = 10 ; if (psf->datalength % ppaf24->blocksize) { psf_sprintf (psf, "*** Warning : file seems to be truncated.\n") ; ppaf24->blocks = psf->datalength / ppaf24->blocksize + 1 ; } else ppaf24->blocks = psf->datalength / ppaf24->blocksize ; psf->sf.samples = ppaf24->samplesperblock * ppaf24->blocks ; paf24_read_block (psf, ppaf24) ; /* Read first block. */ return 0 ; } /* paf24_reader_init */ static int paf24_read_block (SF_PRIVATE *psf, PAF24_PRIVATE *ppaf24) { int k, *iptr, newsample, channel ; unsigned char *cptr ; ppaf24->blockcount ++ ; ppaf24->samplecount = 0 ; if (ppaf24->blockcount > ppaf24->blocks) { memset (ppaf24->samples, 0, ppaf24->samplesperblock * ppaf24->channels) ; return 1 ; } ; /* Read the block. */ if ((k = fread (ppaf24->block, 1, ppaf24->blocksize, psf->file)) != ppaf24->blocksize) psf_sprintf (psf, "*** Warning : short read (%d != %d).\n", k, ppaf24->blocksize) ; /* Do endian swapping if necessary. */ iptr = (int*) (ppaf24->data) ; if ((CPU_IS_BIG_ENDIAN && psf->endian == SF_ENDIAN_LITTLE) || (CPU_IS_LITTLE_ENDIAN && psf->endian == SF_ENDIAN_BIG)) { for (k = 0 ; k < 8 * ppaf24->channels ; k++) iptr [k] = ENDSWAP_INT (iptr [k]) ; } ; /* Unpack block. */ for (k = 0 ; k < 10 * ppaf24->channels ; k++) { channel = k % ppaf24->channels ; cptr = ppaf24->block + 32 * channel + 3 * (k / ppaf24->channels) ; newsample = (cptr [0] << 8) | (cptr [1] << 16) | (cptr [2] << 24) ; ppaf24->samples [k] = newsample / 256 ; } ; return 1 ; } /* paf24_read_block */ static int paf24_read (SF_PRIVATE *psf, PAF24_PRIVATE *ppaf24, int *ptr, int len) { int count, total = 0, index = 0 ; while (index < len) { if (ppaf24->blockcount >= ppaf24->blocks && ppaf24->samplecount >= ppaf24->samplesperblock) { memset (&(ptr[index]), 0, (len - index) * sizeof (int)) ; return total ; } ; if (ppaf24->samplecount >= ppaf24->samplesperblock) paf24_read_block (psf, ppaf24) ; count = (ppaf24->samplesperblock - ppaf24->samplecount) * ppaf24->channels ; count = (len - index > count) ? count : len - index ; memcpy (&(ptr[index]), &(ppaf24->samples [ppaf24->samplecount * ppaf24->channels]), count * sizeof (int)) ; index += count ; ppaf24->samplecount += count / ppaf24->channels ; total = index ; } ; return total ; } /* paf24_read */ static int paf24_read_s (SF_PRIVATE *psf, short *ptr, int len) { PAF24_PRIVATE *ppaf24 ; int *iptr ; int k, bufferlen, readcount = 0, count ; int index = 0, total = 0 ; if (! psf->fdata) return 0 ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; iptr = (int*) psf->buffer ; bufferlen = psf->sf.channels * ((SF_BUFFER_LEN / psf->blockwidth) * psf->blockwidth) / sizeof (int) ; while (len > 0) { readcount = (len >= bufferlen) ? bufferlen : len ; count = paf24_read (psf, ppaf24, iptr, readcount) ; for (k = 0 ; k < readcount ; k++) ptr [index+k] = (short) (iptr [k] / 256) ; index += readcount ; total += count ; len -= readcount ; } ; return total ; } /* paf24_read_s */ static int paf24_read_i (SF_PRIVATE *psf, int *ptr, int len) { PAF24_PRIVATE *ppaf24 ; int total ; if (! psf->fdata) return 0 ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; total = paf24_read (psf, ppaf24, ptr, len) ; return total ; } /* paf24_read_i */ static int paf24_read_d (SF_PRIVATE *psf, double *ptr, int len, int normalize) { PAF24_PRIVATE *ppaf24 ; int *iptr ; int k, bufferlen, readcount = 0, count ; int index = 0, total = 0 ; if (! psf->fdata) return 0 ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; iptr = (int*) psf->buffer ; bufferlen = psf->sf.channels * ((SF_BUFFER_LEN / psf->blockwidth) * psf->blockwidth) / sizeof (int) ; while (len > 0) { readcount = (len >= bufferlen) ? bufferlen : len ; count = paf24_read (psf, ppaf24, iptr, readcount) ; for (k = 0 ; k < readcount ; k++) ptr [index+k] = (double) (iptr [k]) ; index += readcount ; total += count ; len -= readcount ; } ; return total ; } /* paf24_read_d */ /*--------------------------------------------------------------------------- */ static int paf24_writer_init (SF_PRIVATE *psf) { PAF24_PRIVATE *ppaf24 ; unsigned int paf24size ; paf24size = sizeof (PAF24_PRIVATE) + psf->sf.channels * (32 + 10 * sizeof (int)) ; if (! (psf->fdata = malloc (paf24size))) return SFE_MALLOC_FAILED ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; memset (ppaf24, 0, paf24size) ; ppaf24->channels = psf->sf.channels ; ppaf24->block = (unsigned char*) ppaf24->data ; ppaf24->samples = (int*) (ppaf24->data + 32 * ppaf24->channels) ; ppaf24->blocksize = 32 * ppaf24->channels ; ppaf24->samplesperblock = 10 ; if (psf->datalength % ppaf24->blocksize) { psf_sprintf (psf, "*** Warning : file seems to be truncated.\n") ; ppaf24->blocks = psf->datalength / ppaf24->blocksize + 1 ; } else ppaf24->blocks = psf->datalength / ppaf24->blocksize ; psf->sf.samples = ppaf24->samplesperblock * ppaf24->blocks ; return 0 ; } /* paf24_writer_init */ static int paf24_write_block (SF_PRIVATE *psf, PAF24_PRIVATE *ppaf24) { int k, *iptr, nextsample, channel ; unsigned char *cptr ; /* First pack block. */ for (k = 0 ; k < 10 * ppaf24->channels ; k++) { channel = k % ppaf24->channels ; cptr = ppaf24->block + 32 * channel + 3 * (k / ppaf24->channels) ; nextsample = ppaf24->samples [k] ; cptr [0] = nextsample & 0xFF ; cptr [1] = (nextsample >> 8) & 0xFF ; cptr [2] = (nextsample >> 16) & 0xFF ; } ; /* Do endian swapping if necessary. */ iptr = (int*) (ppaf24->data) ; if ((CPU_IS_BIG_ENDIAN && psf->endian == SF_ENDIAN_LITTLE) || (CPU_IS_LITTLE_ENDIAN && psf->endian == SF_ENDIAN_BIG)) { for (k = 0 ; k < 8 * ppaf24->channels ; k++) iptr [k] = ENDSWAP_INT (iptr [k]) ; } ; /* Write block to disk. */ if ((k = fwrite (ppaf24->block, 1, ppaf24->blocksize, psf->file)) != ppaf24->blocksize) psf_sprintf (psf, "*** Warning : short write (%d != %d).\n", k, ppaf24->blocksize) ; ppaf24->blockcount ++ ; ppaf24->samplecount = 0 ; return 1 ; } /* paf24_write_block */ static int paf24_write (SF_PRIVATE *psf, PAF24_PRIVATE *ppaf24, int *ptr, int len) { int count, total = 0, index = 0 ; while (index < len) { count = (ppaf24->samplesperblock - ppaf24->samplecount) * ppaf24->channels ; if (count > len - index) count = len - index ; memcpy (&(ppaf24->samples [ppaf24->samplecount * ppaf24->channels]), &(ptr [index]), count * sizeof (int)) ; index += count ; ppaf24->samplecount += count / ppaf24->channels ; total = index ; if (ppaf24->samplecount >= ppaf24->samplesperblock) paf24_write_block (psf, ppaf24) ; } ; return total ; } /* paf24_write */ static int paf24_write_s (SF_PRIVATE *psf, short *ptr, int len) { PAF24_PRIVATE *ppaf24 ; int *iptr ; int k, bufferlen, writecount = 0, count ; int index = 0, total = 0 ; if (! psf->fdata) return 0 ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; iptr = (int*) psf->buffer ; bufferlen = psf->sf.channels * ((SF_BUFFER_LEN / psf->blockwidth) * psf->blockwidth) / sizeof (int) ; while (len > 0) { writecount = (len >= bufferlen) ? bufferlen : len ; for (k = 0 ; k < writecount ; k++) iptr [k] = ((int) ptr [index+k]) * 256 ; count = paf24_write (psf, ppaf24, iptr, writecount) ; index += writecount ; total += count ; len -= writecount ; } ; return total ; } /* paf24_write_s */ static int paf24_write_i (SF_PRIVATE *psf, int *ptr, int len) { PAF24_PRIVATE *ppaf24 ; int total = 0 ; if (! psf->fdata) return 0 ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; total = paf24_write (psf, ppaf24, ptr, len) ; return total ; } /* paf24_write_i */ static int paf24_write_d (SF_PRIVATE *psf, double *ptr, int len, int normalize) { PAF24_PRIVATE *ppaf24 ; int *iptr ; int k, bufferlen, writecount = 0, count ; int index = 0, total = 0 ; if (! psf->fdata) return 0 ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; iptr = (int*) psf->buffer ; bufferlen = psf->sf.channels * ((SF_BUFFER_LEN / psf->blockwidth) * psf->blockwidth) / sizeof (int) ; while (len > 0) { writecount = (len >= bufferlen) ? bufferlen : len ; for (k = 0 ; k < writecount ; k++) iptr [k] = (int) ptr [index+k] ; count = paf24_write (psf, ppaf24, iptr, writecount) ; index += writecount ; total += count ; len -= writecount ; } ; return total ; } /* paf24_write_d */ /*--------------------------------------------------------------------------- */ static off_t paf24_seek (SF_PRIVATE *psf, off_t offset, int whence) { PAF24_PRIVATE *ppaf24 ; int newblock, newsample ; if (! psf->fdata) return 0 ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; if (! (psf->blockwidth && psf->datalength && psf->dataoffset)) { psf->error = SFE_BAD_SEEK ; return ((off_t) -1) ; } ; switch (whence) { case SEEK_SET : if (offset < 0 || offset > ppaf24->blocks * ppaf24->samplesperblock) { psf->error = SFE_BAD_SEEK ; return ((off_t) -1) ; } ; newblock = offset / ppaf24->samplesperblock ; newsample = offset % ppaf24->samplesperblock ; break ; case SEEK_CUR : if (psf->current + offset < 0 || psf->current + offset > ppaf24->blocks * ppaf24->samplesperblock) { psf->error = SFE_BAD_SEEK ; return ((off_t) -1) ; } ; newblock = (psf->current + offset) / ppaf24->samplesperblock ; newsample = (psf->current + offset) % ppaf24->samplesperblock ; break ; case SEEK_END : if (offset > 0 || ppaf24->samplesperblock * ppaf24->blocks + offset < 0) { psf->error = SFE_BAD_SEEK ; return ((off_t) -1) ; } ; newblock = (ppaf24->samplesperblock * ppaf24->blocks + offset) / ppaf24->samplesperblock ; newsample = (ppaf24->samplesperblock * ppaf24->blocks + offset) % ppaf24->samplesperblock ; break ; default : psf->error = SFE_BAD_SEEK ; return ((off_t) -1) ; } ; if (psf->mode == SF_MODE_READ) { fseek (psf->file, (int) (psf->dataoffset + newblock * ppaf24->blocksize), SEEK_SET) ; ppaf24->blockcount = newblock ; paf24_read_block (psf, ppaf24) ; ppaf24->samplecount = newsample ; } else { /* What to do about write??? */ psf->error = SFE_BAD_SEEK ; return ((off_t) -1) ; } ; psf->current = newblock * ppaf24->samplesperblock + newsample ; return psf->current ; } /* paf24_seek */ /*--------------------------------------------------------------------------- */ static int paf24_close (SF_PRIVATE *psf) { PAF24_PRIVATE *ppaf24 ; if (! psf->fdata) return 0 ; ppaf24 = (PAF24_PRIVATE*) psf->fdata ; if (psf->mode == SF_MODE_WRITE) { if (ppaf24->samplecount && ppaf24->samplecount < ppaf24->samplesperblock) paf24_write_block (psf, ppaf24) ; } ; free (psf->fdata) ; psf->fdata = NULL ; return 0 ; } /* paf24_close */ /*--------------------------------------------------------------------------- */ static void endswap_paf_fmt (PAF_FMT *ppaf_fmt) { ppaf_fmt->version = ENDSWAP_INT (ppaf_fmt->version) ; ppaf_fmt->endianness = ENDSWAP_INT (ppaf_fmt->endianness) ; ppaf_fmt->samplerate = ENDSWAP_INT (ppaf_fmt->samplerate) ; ppaf_fmt->format = ENDSWAP_INT (ppaf_fmt->format) ; ppaf_fmt->channels = ENDSWAP_INT (ppaf_fmt->channels) ; ppaf_fmt->source = ENDSWAP_INT (ppaf_fmt->source) ; } /* endswap_paf_fmt */