/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2006 by Nicolas Pitre * Copyright (C) 2006-2007 by Stéphane Doyon * * 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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include #include #include #include #include "sound.h" #include "buffer.h" #include "system.h" #include "tdspeed.h" #include "settings.h" #define assert(cond) #define MIN_RATE 8000 #define MAX_RATE 48000 /* double buffer for double rate */ #define MINFREQ 100 #define FIXED_BUFSIZE 3072 /* 48KHz factor 3.0 */ struct tdspeed_state_s { bool stereo; int32_t shift_max; /* maximum displacement on a frame */ int32_t src_step; /* source window pace */ int32_t dst_step; /* destination window pace */ int32_t dst_order; /* power of two for dst_step */ int32_t ovl_shift; /* overlap buffer frame shift */ int32_t ovl_size; /* overlap buffer used size */ int32_t ovl_space; /* overlap buffer size */ int32_t *ovl_buff[2]; /* overlap buffer */ }; static struct tdspeed_state_s tdspeed_state; static int32_t *overlap_buffer[2] = { NULL, NULL }; static int32_t *outbuf[2] = { NULL, NULL }; void tdspeed_init() { if (global_settings.timestretch_enabled) { /* Allocate buffers */ if (overlap_buffer[0] == NULL) overlap_buffer[0] = (int32_t *) buffer_alloc(FIXED_BUFSIZE * sizeof(int32_t)); if (overlap_buffer[1] == NULL) overlap_buffer[1] = (int32_t *) buffer_alloc(FIXED_BUFSIZE * sizeof(int32_t)); if (outbuf[0] == NULL) outbuf[0] = (int32_t *) buffer_alloc(TDSPEED_OUTBUFSIZE * sizeof(int32_t)); if (outbuf[1] == NULL) outbuf[1] = (int32_t *) buffer_alloc(TDSPEED_OUTBUFSIZE * sizeof(int32_t)); } } bool tdspeed_config(int samplerate, bool stereo, int32_t factor) { struct tdspeed_state_s *st = &tdspeed_state; int src_frame_sz; /* Check buffers were allocated ok */ if (overlap_buffer[0] == NULL || overlap_buffer[1] == NULL) return false; if (outbuf[0] == NULL || outbuf[1] == NULL) return false; /* Check parameters */ if (factor == PITCH_SPEED_100) return false; if (samplerate < MIN_RATE || samplerate > MAX_RATE) return false; if (factor < STRETCH_MIN || factor > STRETCH_MAX) return false; st->stereo = stereo; st->dst_step = samplerate / MINFREQ; if (factor > PITCH_SPEED_100) st->dst_step = st->dst_step * PITCH_SPEED_100 / factor; st->dst_order = 1; while (st->dst_step >>= 1) st->dst_order++; st->dst_step = (1 << st->dst_order); st->src_step = st->dst_step * factor / PITCH_SPEED_100; st->shift_max = (st->dst_step > st->src_step) ? st->dst_step : st->src_step; src_frame_sz = st->shift_max + st->dst_step; if (st->dst_step > st->src_step) src_frame_sz += st->dst_step - st->src_step; st->ovl_space = ((src_frame_sz - 2)/st->src_step) * st->src_step + src_frame_sz; if (st->src_step > st->dst_step) st->ovl_space += 2*st->src_step - st->dst_step; if (st->ovl_space > FIXED_BUFSIZE) st->ovl_space = FIXED_BUFSIZE; st->ovl_size = 0; st->ovl_shift = 0; st->ovl_buff[0] = overlap_buffer[0]; if (stereo) st->ovl_buff[1] = overlap_buffer[1]; else st->ovl_buff[1] = st->ovl_buff[0]; return true; } static int tdspeed_apply(int32_t *buf_out[2], int32_t *buf_in[2], int data_len, int last, int out_size) /* data_len in samples */ { struct tdspeed_state_s *st = &tdspeed_state; int32_t *curr, *prev, *dest[2], *d; int32_t i, j, next_frame, prev_frame, shift, src_frame_sz; bool stereo = buf_in[0] != buf_in[1]; assert(stereo == st->stereo); src_frame_sz = st->shift_max + st->dst_step; if (st->dst_step > st->src_step) src_frame_sz += st->dst_step - st->src_step; /* deal with overlap data first, if any */ if (st->ovl_size) { int32_t have, copy, steps; have = st->ovl_size; if (st->ovl_shift > 0) have -= st->ovl_shift; /* append just enough data to have all of the overlap buffer consumed */ steps = (have - 1) / st->src_step; copy = steps * st->src_step + src_frame_sz - have; if (copy < src_frame_sz - st->dst_step) copy += st->src_step; /* one more step to allow for pregap data */ if (copy > data_len) copy = data_len; assert(st->ovl_size +copy <= FIXED_BUFSIZE); memcpy(st->ovl_buff[0] + st->ovl_size, buf_in[0], copy * sizeof(int32_t)); if (stereo) memcpy(st->ovl_buff[1] + st->ovl_size, buf_in[1], copy * sizeof(int32_t)); if (!last && have + copy < src_frame_sz) { /* still not enough to process at least one frame */ st->ovl_size += copy; return 0; } /* recursively call ourselves to process the overlap buffer */ have = st->ovl_size; st->ovl_size = 0; if (copy == data_len) { assert( (have+copy) <= FIXED_BUFSIZE); return tdspeed_apply(buf_out, st->ovl_buff, have+copy, last, out_size); } assert( (have+copy) <= FIXED_BUFSIZE); i = tdspeed_apply(buf_out, st->ovl_buff, have+copy, -1, out_size); dest[0] = buf_out[0] + i; dest[1] = buf_out[1] + i; /* readjust pointers to account for data already consumed */ next_frame = copy - src_frame_sz + st->src_step; prev_frame = next_frame - st->ovl_shift; } else { dest[0] = buf_out[0]; dest[1] = buf_out[1]; next_frame = prev_frame = 0; if (st->ovl_shift > 0) next_frame += st->ovl_shift; else prev_frame += -st->ovl_shift; } st->ovl_shift = 0; /* process all complete frames */ while (data_len - next_frame >= src_frame_sz) { /* find frame overlap by autocorelation */ int64_t min_delta = ~(1ll << 63); /* most positive */ shift = 0; #define INC1 8 #define INC2 32 /* Power of 2 of a 28bit number requires 56bits, can accumulate 256times in a 64bit variable. */ assert(st->dst_step / INC2 <= 256); assert(next_frame + st->shift_max - 1 + st->dst_step-1 < data_len); assert(prev_frame + st->dst_step - 1 < data_len); for (i = 0; i < st->shift_max; i += INC1) { int64_t delta = 0; curr = buf_in[0] + next_frame + i; prev = buf_in[0] + prev_frame; for (j = 0; j < st->dst_step; j += INC2, curr += INC2, prev += INC2) { int32_t diff = *curr - *prev; delta += (int64_t)diff * diff; if (delta >= min_delta) goto skip; } if (stereo) { curr = buf_in[1] +next_frame + i; prev = buf_in[1] +prev_frame; for (j = 0; j < st->dst_step; j += INC2, curr += INC2, prev += INC2) { int32_t diff = *curr - *prev; delta += (int64_t)diff * diff; if (delta >= min_delta) goto skip; } } min_delta = delta; shift = i; skip:; } /* overlap fading-out previous frame with fading-in current frame */ curr = buf_in[0] + next_frame + shift; prev = buf_in[0] + prev_frame; d = dest[0]; assert(next_frame + shift + st->dst_step - 1 < data_len); assert(prev_frame + st->dst_step - 1 < data_len); assert(dest[0] - buf_out[0] + st->dst_step - 1 < out_size); for (i = 0, j = st->dst_step; j; i++, j--) { *d++ = (*curr++ * (int64_t)i + *prev++ * (int64_t)j) >> st->dst_order; } dest[0] = d; if (stereo) { curr = buf_in[1] +next_frame + shift; prev = buf_in[1] +prev_frame; d = dest[1]; for (i = 0, j = st->dst_step; j; i++, j--) { assert(d < buf_out[1] +out_size); *d++ = (*curr++ * (int64_t) i + *prev++ * (int64_t) j) >> st->dst_order; } dest[1] = d; } /* adjust pointers for next frame */ prev_frame = next_frame + shift + st->dst_step; next_frame += st->src_step; /* here next_frame - prev_frame = src_step - dst_step - shift */ assert(next_frame - prev_frame == st->src_step - st->dst_step - shift); } /* now deal with remaining partial frames */ if (last == -1) { /* special overlap buffer processing: remember frame shift only */ st->ovl_shift = next_frame - prev_frame; } else if (last != 0) { /* last call: purge all remaining data to output buffer */ i = data_len -prev_frame; assert(dest[0] +i <= buf_out[0] +out_size); memcpy(dest[0], buf_in[0] +prev_frame, i * sizeof(int32_t)); dest[0] += i; if (stereo) { assert(dest[1] +i <= buf_out[1] +out_size); memcpy(dest[1], buf_in[1] +prev_frame, i * sizeof(int32_t)); dest[1] += i; } } else { /* preserve remaining data + needed overlap data for next call */ st->ovl_shift = next_frame - prev_frame; i = (st->ovl_shift < 0) ? next_frame : prev_frame; st->ovl_size = data_len - i; assert(st->ovl_size <= FIXED_BUFSIZE); memcpy(st->ovl_buff[0], buf_in[0]+i, st->ovl_size * sizeof(int32_t)); if (stereo) memcpy(st->ovl_buff[1], buf_in[1]+i, st->ovl_size * sizeof(int32_t)); } return dest[0] - buf_out[0]; } long tdspeed_est_output_size() { return TDSPEED_OUTBUFSIZE; } long tdspeed_est_input_size(long size) { struct tdspeed_state_s *st = &tdspeed_state; size = (size -st->ovl_size) *st->src_step / st->dst_step; if (size < 0) size = 0; return size; } int tdspeed_doit(int32_t *src[], int count) { count = tdspeed_apply( (int32_t *[2]) { outbuf[0], outbuf[1] }, src, count, 0, TDSPEED_OUTBUFSIZE); src[0] = outbuf[0]; src[1] = outbuf[1]; return count; }