/*
** Copyright (C) 2001-2016 Erik de Castro Lopo <erikd@mega-nerd.com>
**
** 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 "sfconfig.h"
#include <stdio.h>
#include <string.h>
#include <math.h>
#include "sndfile.h"
#include "common.h"
static SF_FORMAT_INFO const simple_formats [] =
{
{ SF_FORMAT_AIFF | SF_FORMAT_PCM_16,
"AIFF (Apple/SGI 16 bit PCM)", "aiff"
},
{ SF_FORMAT_AIFF | SF_FORMAT_FLOAT,
"AIFF (Apple/SGI 32 bit float)", "aifc"
},
{ SF_FORMAT_AIFF | SF_FORMAT_PCM_S8,
"AIFF (Apple/SGI 8 bit PCM)", "aiff"
},
{ SF_FORMAT_AU | SF_FORMAT_PCM_16,
"AU (Sun/Next 16 bit PCM)", "au"
},
{ SF_FORMAT_AU | SF_FORMAT_ULAW,
"AU (Sun/Next 8-bit u-law)", "au"
},
{ SF_FORMAT_CAF | SF_FORMAT_ALAC_16,
"CAF (Apple 16 bit ALAC)", "caf"
},
{ SF_FORMAT_CAF | SF_FORMAT_PCM_16,
"CAF (Apple 16 bit PCM)", "caf"
},
#if HAVE_EXTERNAL_XIPH_LIBS
{ SF_FORMAT_FLAC | SF_FORMAT_PCM_16,
"FLAC 16 bit", "flac"
},
#endif
{ SF_FORMAT_RAW | SF_FORMAT_VOX_ADPCM,
"OKI Dialogic VOX ADPCM", "vox"
},
#if HAVE_EXTERNAL_XIPH_LIBS
{ SF_FORMAT_OGG | SF_FORMAT_VORBIS,
"Ogg Vorbis (Xiph Foundation)", "oga"
},
#endif
{ SF_FORMAT_WAV | SF_FORMAT_PCM_16,
"WAV (Microsoft 16 bit PCM)", "wav"
},
{ SF_FORMAT_WAV | SF_FORMAT_FLOAT,
"WAV (Microsoft 32 bit float)", "wav"
},
{ SF_FORMAT_WAV | SF_FORMAT_IMA_ADPCM,
"WAV (Microsoft 4 bit IMA ADPCM)", "wav"
},
{ SF_FORMAT_WAV | SF_FORMAT_MS_ADPCM,
"WAV (Microsoft 4 bit MS ADPCM)", "wav"
},
{ SF_FORMAT_WAV | SF_FORMAT_PCM_U8,
"WAV (Microsoft 8 bit PCM)", "wav"
},
} ; /* simple_formats */
int
psf_get_format_simple_count (void)
{ return (sizeof (simple_formats) / sizeof (SF_FORMAT_INFO)) ;
} /* psf_get_format_simple_count */
int
psf_get_format_simple (SF_FORMAT_INFO *data)
{ int indx ;
if (data->format < 0 || data->format >= (SIGNED_SIZEOF (simple_formats) / SIGNED_SIZEOF (SF_FORMAT_INFO)))
return SFE_BAD_COMMAND_PARAM ;
indx = data->format ;
memcpy (data, &(simple_formats [indx]), SIGNED_SIZEOF (SF_FORMAT_INFO)) ;
return 0 ;
} /* psf_get_format_simple */
/*============================================================================
** Major format info.
*/
static SF_FORMAT_INFO const major_formats [] =
{
{ SF_FORMAT_AIFF, "AIFF (Apple/SGI)", "aiff" },
{ SF_FORMAT_AU, "AU (Sun/NeXT)", "au" },
{ SF_FORMAT_AVR, "AVR (Audio Visual Research)", "avr" },
{ SF_FORMAT_CAF, "CAF (Apple Core Audio File)", "caf" },
#if HAVE_EXTERNAL_XIPH_LIBS
{ SF_FORMAT_FLAC, "FLAC (Free Lossless Audio Codec)", "flac" },
#endif
{ SF_FORMAT_HTK, "HTK (HMM Tool Kit)", "htk" },
{ SF_FORMAT_SVX, "IFF (Amiga IFF/SVX8/SV16)", "iff" },
{ SF_FORMAT_MAT4, "MAT4 (GNU Octave 2.0 / Matlab 4.2)", "mat" },
{ SF_FORMAT_MAT5, "MAT5 (GNU Octave 2.1 / Matlab 5.0)", "mat" },
{ SF_FORMAT_MPC2K, "MPC (Akai MPC 2k)", "mpc" },
#if HAVE_EXTERNAL_XIPH_LIBS
{ SF_FORMAT_OGG, "OGG (OGG Container format)", "oga" },
#endif
{ SF_FORMAT_PAF, "PAF (Ensoniq PARIS)", "paf" },
{ SF_FORMAT_PVF, "PVF (Portable Voice Format)", "pvf" },
{ SF_FORMAT_RAW, "RAW (header-less)", "raw" },
{ SF_FORMAT_RF64, "RF64 (RIFF 64)", "rf64" },
{ SF_FORMAT_SD2, "SD2 (Sound Designer II)", "sd2" },
{ SF_FORMAT_SDS, "SDS (Midi Sample Dump Standard)", "sds" },
{ SF_FORMAT_IRCAM, "SF (Berkeley/IRCAM/CARL)", "sf" },
{ SF_FORMAT_VOC, "VOC (Creative Labs)", "voc" },
{ SF_FORMAT_W64, "W64 (SoundFoundry WAVE 64)", "w64" },
{ SF_FORMAT_WAV, "WAV (Microsoft)", "wav" },
{ SF_FORMAT_NIST, "WAV (NIST Sphere)", "wav" },
{ SF_FORMAT_WAVEX, "WAVEX (Microsoft)", "wav" },
{ SF_FORMAT_WVE, "WVE (Psion Series 3)", "wve" },
{ SF_FORMAT_XI, "XI (FastTracker 2)", "xi" },
} ; /* major_formats */
int
psf_get_format_major_count (void)
{ return (sizeof (major_formats) / sizeof (SF_FORMAT_INFO)) ;
} /* psf_get_format_major_count */
int
psf_get_format_major (SF_FORMAT_INFO *data)
{ int indx ;
if (data->format < 0 || data->format >= (SIGNED_SIZEOF (major_formats) / SIGNED_SIZEOF (SF_FORMAT_INFO)))
return SFE_BAD_COMMAND_PARAM ;
indx = data->format ;
memcpy (data, &(major_formats [indx]), SIGNED_SIZEOF (SF_FORMAT_INFO)) ;
return 0 ;
} /* psf_get_format_major */
/*============================================================================
** Subtype format info.
*/
static SF_FORMAT_INFO subtype_formats [] =
{
{ SF_FORMAT_PCM_S8, "Signed 8 bit PCM", NULL },
{ SF_FORMAT_PCM_16, "Signed 16 bit PCM", NULL },
{ SF_FORMAT_PCM_24, "Signed 24 bit PCM", NULL },
{ SF_FORMAT_PCM_32, "Signed 32 bit PCM", NULL },
{ SF_FORMAT_PCM_U8, "Unsigned 8 bit PCM", NULL },
{ SF_FORMAT_FLOAT, "32 bit float", NULL },
{ SF_FORMAT_DOUBLE, "64 bit float", NULL },
{ SF_FORMAT_ULAW, "U-Law", NULL },
{ SF_FORMAT_ALAW, "A-Law", NULL },
{ SF_FORMAT_IMA_ADPCM, "IMA ADPCM", NULL },
{ SF_FORMAT_MS_ADPCM, "Microsoft ADPCM", NULL },
{ SF_FORMAT_GSM610, "GSM 6.10", NULL },
{ SF_FORMAT_G721_32, "32kbs G721 ADPCM", NULL },
{ SF_FORMAT_G723_24, "24kbs G723 ADPCM", NULL },
{ SF_FORMAT_DWVW_12, "12 bit DWVW", NULL },
{ SF_FORMAT_DWVW_16, "16 bit DWVW", NULL },
{ SF_FORMAT_DWVW_24, "24 bit DWVW", NULL },
{ SF_FORMAT_VOX_ADPCM, "VOX ADPCM", "vox" },
{ SF_FORMAT_DPCM_16, "16 bit DPCM", NULL },
{ SF_FORMAT_DPCM_8, "8 bit DPCM", NULL },
#if HAVE_EXTERNAL_XIPH_LIBS
{ SF_FORMAT_VORBIS, "Vorbis", NULL },
#endif
{ SF_FORMAT_ALAC_16, "16 bit ALAC", NULL },
{ SF_FORMAT_ALAC_20, "20 bit ALAC", NULL },
{ SF_FORMAT_ALAC_24, "24 bit ALAC", NULL },
{ SF_FORMAT_ALAC_32, "32 bit ALAC", NULL },
} ; /* subtype_formats */
int
psf_get_format_subtype_count (void)
{ return (sizeof (subtype_formats) / sizeof (SF_FORMAT_INFO)) ;
} /* psf_get_format_subtype_count */
int
psf_get_format_subtype (SF_FORMAT_INFO *data)
{ int indx ;
if (data->format < 0 || data->format >= (SIGNED_SIZEOF (subtype_formats) / SIGNED_SIZEOF (SF_FORMAT_INFO)))
{ data->format = 0 ;
return SFE_BAD_COMMAND_PARAM ;
} ;
indx = data->format ;
memcpy (data, &(subtype_formats [indx]), sizeof (SF_FORMAT_INFO)) ;
return 0 ;
} /* psf_get_format_subtype */
/*==============================================================================
*/
int
psf_get_format_info (SF_FORMAT_INFO *data)
{ int k, format ;
if (SF_CONTAINER (data->format))
{ format = SF_CONTAINER (data->format) ;
for (k = 0 ; k < (SIGNED_SIZEOF (major_formats) / SIGNED_SIZEOF (SF_FORMAT_INFO)) ; k++)
{ if (format == major_formats [k].format)
{ memcpy (data, &(major_formats [k]), sizeof (SF_FORMAT_INFO)) ;
return 0 ;
} ;
} ;
}
else if (SF_CODEC (data->format))
{ format = SF_CODEC (data->format) ;
for (k = 0 ; k < (SIGNED_SIZEOF (subtype_formats) / SIGNED_SIZEOF (SF_FORMAT_INFO)) ; k++)
{ if (format == subtype_formats [k].format)
{ memcpy (data, &(subtype_formats [k]), sizeof (SF_FORMAT_INFO)) ;
return 0 ;
} ;
} ;
} ;
memset (data, 0, sizeof (SF_FORMAT_INFO)) ;
return SFE_BAD_COMMAND_PARAM ;
} /* psf_get_format_info */
/*==============================================================================
*/
double
psf_calc_signal_max (SF_PRIVATE *psf, int normalize)
{ BUF_UNION ubuf ;
sf_count_t position ;
double max_val, temp, *data ;
int k, len, readcount, save_state ;
/* If the file is not seekable, there is nothing we can do. */
if (! psf->sf.seekable)
{ psf->error = SFE_NOT_SEEKABLE ;
return 0.0 ;
} ;
if (! psf->read_double)
{ psf->error = SFE_UNIMPLEMENTED ;
return 0.0 ;
} ;
save_state = sf_command ((SNDFILE*) psf, SFC_GET_NORM_DOUBLE, NULL, 0) ;
sf_command ((SNDFILE*) psf, SFC_SET_NORM_DOUBLE, NULL, normalize) ;
/* Brute force. Read the whole file and find the biggest sample. */
/* Get current position in file */
position = sf_seek ((SNDFILE*) psf, 0, SEEK_CUR) ;
/* Go to start of file. */
sf_seek ((SNDFILE*) psf, 0, SEEK_SET) ;
data = ubuf.dbuf ;
/* Make sure len is an integer multiple of the channel count. */
len = ARRAY_LEN (ubuf.dbuf) - (ARRAY_LEN (ubuf.dbuf) % psf->sf.channels) ;
for (readcount = 1, max_val = 0.0 ; readcount > 0 ; /* nothing */)
{ readcount = sf_read_double ((SNDFILE*) psf, data, len) ;
for (k = 0 ; k < readcount ; k++)
{ temp = fabs (data [k]) ;
max_val = temp > max_val ? temp : max_val ;
} ;
} ;
/* Return to SNDFILE to original state. */
sf_seek ((SNDFILE*) psf, position, SEEK_SET) ;
sf_command ((SNDFILE*) psf, SFC_SET_NORM_DOUBLE, NULL, save_state) ;
return max_val ;
} /* psf_calc_signal_max */
int
psf_calc_max_all_channels (SF_PRIVATE *psf, double *peaks, int normalize)
{ BUF_UNION ubuf ;
sf_count_t position ;
double temp, *data ;
int k, len, readcount, save_state ;
int chan ;
/* If the file is not seekable, there is nothing we can do. */
if (! psf->sf.seekable)
return (psf->error = SFE_NOT_SEEKABLE) ;
if (! psf->read_double)
return (psf->error = SFE_UNIMPLEMENTED) ;
save_state = sf_command ((SNDFILE*) psf, SFC_GET_NORM_DOUBLE, NULL, 0) ;
sf_command ((SNDFILE*) psf, SFC_SET_NORM_DOUBLE, NULL, normalize) ;
memset (peaks, 0, sizeof (double) * psf->sf.channels) ;
/* Brute force. Read the whole file and find the biggest sample for each channel. */
position = sf_seek ((SNDFILE*) psf, 0, SEEK_CUR) ; /* Get current position in file */
sf_seek ((SNDFILE*) psf, 0, SEEK_SET) ; /* Go to start of file. */
len = ARRAY_LEN (ubuf.dbuf) - (ARRAY_LEN (ubuf.dbuf) % psf->sf.channels) ;
data = ubuf.dbuf ;
chan = 0 ;
readcount = len ;
while (readcount > 0)
{ readcount = sf_read_double ((SNDFILE*) psf, data, len) ;
for (k = 0 ; k < readcount ; k++)
{ temp = fabs (data [k]) ;
peaks [chan] = temp > peaks [chan] ? temp : peaks [chan] ;
chan = (chan + 1) % psf->sf.channels ;
} ;
} ;
sf_seek ((SNDFILE*) psf, position, SEEK_SET) ; /* Return to original position. */
sf_command ((SNDFILE*) psf, SFC_SET_NORM_DOUBLE, NULL, save_state) ;
return 0 ;
} /* psf_calc_max_all_channels */
int
psf_get_signal_max (SF_PRIVATE *psf, double *peak)
{ int k ;
if (psf->peak_info == NULL)
return SF_FALSE ;
peak [0] = psf->peak_info->peaks [0].value ;
for (k = 1 ; k < psf->sf.channels ; k++)
peak [0] = SF_MAX (peak [0], psf->peak_info->peaks [k].value) ;
return SF_TRUE ;
} /* psf_get_signal_max */
int
psf_get_max_all_channels (SF_PRIVATE *psf, double *peaks)
{ int k ;
if (psf->peak_info == NULL)
return SF_FALSE ;
for (k = 0 ; k < psf->sf.channels ; k++)
peaks [k] = psf->peak_info->peaks [k].value ;
return SF_TRUE ;
} /* psf_get_max_all_channels */