/* ** Copyright (C) 2002,2003 Erik de Castro Lopo ** ** This program is free software; you can redistribute it and/or modify ** it under the terms of the GNU General Public License as published by ** the Free Software Foundation; either version 2 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 General Public License for more details. ** ** You should have received a copy of the GNU General Public License ** along with this program; if not, write to the Free Software ** Foundation, Inc., 51 Franklin Steet, Fifth Floor, Boston, MA 02110-1301, USA. */ #include #include #include #include "config.h" #include "float_cast.h" #include "common.h" static void linear_reset (SRC_PRIVATE *psrc) ; /*======================================================================================== */ #define LINEAR_MAGIC_MARKER MAKE_MAGIC('l','i','n','e','a','r') typedef struct { int linear_magic_marker ; int channels ; long in_count, in_used ; long out_count, out_gen ; float last_value [1] ; } LINEAR_DATA ; /*---------------------------------------------------------------------------------------- */ int linear_process (SRC_PRIVATE *psrc, SRC_DATA *data) { LINEAR_DATA *linear ; double src_ratio, input_index ; int ch ; if (psrc->private_data == NULL) return SRC_ERR_NO_PRIVATE ; linear = (LINEAR_DATA*) psrc->private_data ; linear->in_count = data->input_frames * linear->channels ; linear->out_count = data->output_frames * linear->channels ; linear->in_used = linear->out_gen = 0 ; src_ratio = psrc->last_ratio ; input_index = psrc->last_position ; /* Calculate samples before first sample in input array. */ while (input_index > 0.0 && input_index < 1.0 && linear->out_gen < linear->out_count) { if (linear->in_used + input_index > linear->in_count) break ; if (fabs (psrc->last_ratio - data->src_ratio) > SRC_MIN_RATIO_DIFF) src_ratio = psrc->last_ratio + linear->out_gen * (data->src_ratio - psrc->last_ratio) / (linear->out_count - 1) ; for (ch = 0 ; ch < linear->channels ; ch++) { data->data_out [linear->out_gen] = linear->last_value [ch] + input_index * (data->data_in [ch] - linear->last_value [ch]) ; linear->out_gen ++ ; } ; /* Figure out the next index. */ input_index += 1.0 / src_ratio ; } ; /* Main processing loop. */ while (linear->out_gen < linear->out_count) { linear->in_used += linear->channels * lrint (floor (input_index)) ; input_index -= floor (input_index) ; if (linear->in_used + input_index > linear->in_count) break ; if (fabs (psrc->last_ratio - data->src_ratio) > SRC_MIN_RATIO_DIFF) src_ratio = psrc->last_ratio + linear->out_gen * (data->src_ratio - psrc->last_ratio) / (linear->out_count - 1) ; for (ch = 0 ; ch < linear->channels ; ch++) { data->data_out [linear->out_gen] = data->data_in [linear->in_used + ch] + input_index * (data->data_in [linear->in_used + linear->channels + ch] - data->data_in [linear->in_used + ch]) ; linear->out_gen ++ ; } ; /* Figure out the next index. */ input_index += 1.0 / src_ratio ; } ; /*- if (input_index > linear->in_count - linear->in_used) { input_index -= linear->in_count - linear->in_used ; linear->in_used = linear->in_count ; puts ("XXXXXXXXXX") ; /+*-exit (1) ;-*+/ } ; -*/ psrc->last_position = input_index ; for (ch = 0 ; ch < linear->channels ; ch++) { linear->last_value [ch] = data->data_in [linear->in_used - linear->channels + ch] ; /*- data->data_out [0 + ch] = -0.9 ; data->data_out [linear->out_gen - linear->channels + ch] = 0.9 ; -*/ } ; /* Save current ratio rather then target ratio. */ psrc->last_ratio = src_ratio ; data->input_frames_used = linear->in_used / linear->channels ; data->output_frames_gen = linear->out_gen / linear->channels ; return SRC_ERR_NO_ERROR ; } /* linear_process */ /*------------------------------------------------------------------------------ */ const char* linear_get_name (int src_enum) { if (src_enum == SRC_LINEAR) return "Linear Interpolator" ; return NULL ; } /* linear_get_name */ const char* linear_get_description (int src_enum) { if (src_enum == SRC_LINEAR) return "Linear interpolator, very fast, poor quality." ; return NULL ; } /* linear_get_descrition */ int linear_set_converter (SRC_PRIVATE *psrc, int src_enum) { LINEAR_DATA *linear ; if (src_enum != SRC_LINEAR) return SRC_ERR_BAD_CONVERTER ; if (psrc->private_data != NULL) { linear = (LINEAR_DATA*) psrc->private_data ; if (linear->linear_magic_marker != LINEAR_MAGIC_MARKER) { free (psrc->private_data) ; psrc->private_data = NULL ; } ; } ; if (psrc->private_data == NULL) { linear = calloc (1, sizeof (*linear) + psrc->channels * sizeof (float)) ; if (linear == NULL) return SRC_ERR_MALLOC_FAILED ; psrc->private_data = linear ; } ; linear->linear_magic_marker = LINEAR_MAGIC_MARKER ; linear->channels = psrc->channels ; psrc->process = linear_process ; psrc->reset = linear_reset ; linear_reset (psrc) ; return SRC_ERR_NO_ERROR ; } /* linear_set_converter */ /*=================================================================================== */ static void linear_reset (SRC_PRIVATE *psrc) { LINEAR_DATA *linear ; linear = (LINEAR_DATA*) psrc->private_data ; if (linear == NULL) return ; memset (linear->last_value, 0, sizeof (linear->last_value [0]) * linear->channels) ; } /* linear_reset */