// Game_Music_Emu 0.5.5. http://www.slack.net/~ant/ #include "resampler.h" #include #include /* Copyright (C) 2003-2006 Shay Green. This module 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 module 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 module; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #include "blargg_source.h" // TODO: fix this. hack since resampler holds back some output. unsigned const resampler_extra = 34; enum { shift = 14 }; int const unit = 1 << shift; blargg_err_t Resampler_setup( struct Resampler* this, double oversample, double rolloff, double gain ) { (void) rolloff; this->gain_ = (int)((1 << gain_bits) * gain); this->step = (int) ( oversample * unit + 0.5); this->rate_ = 1.0 / unit * this->step; return 0; } blargg_err_t Resampler_reset( struct Resampler* this, int pairs ) { // expand allocations a bit Resampler_resize( this, pairs ); this->resampler_size = this->oversamples_per_frame + (this->oversamples_per_frame >> 2); this->buffer_size = this->resampler_size; this->pos = 0; this->write_pos = 0; return 0; } void Resampler_resize( struct Resampler* this, int pairs ) { int new_sample_buf_size = pairs * 2; if ( this->sample_buf_size != new_sample_buf_size ) { this->sample_buf_size = new_sample_buf_size; this->oversamples_per_frame = (int) (pairs * this->rate_) * 2 + 2; Resampler_clear( this ); } } void mix_mono( struct Resampler* this, struct Stereo_Buffer* stereo_buf, dsample_t* out_ ) { int const bass = BLIP_READER_BASS( stereo_buf->bufs [0] ); BLIP_READER_BEGIN( sn, stereo_buf->bufs [0] ); int count = this->sample_buf_size >> 1; BLIP_READER_ADJ_( sn, count ); typedef dsample_t stereo_dsample_t [2]; stereo_dsample_t* BLARGG_RESTRICT out = (stereo_dsample_t*) out_ + count; stereo_dsample_t const* BLARGG_RESTRICT in = (stereo_dsample_t const*) this->sample_buf + count; int offset = -count; int const gain = this->gain_; do { int s = BLIP_READER_READ_RAW( sn ) >> (blip_sample_bits - 16); BLIP_READER_NEXT_IDX_( sn, bass, offset ); int l = (in [offset] [0] * gain >> gain_bits) + s; int r = (in [offset] [1] * gain >> gain_bits) + s; BLIP_CLAMP( l, l ); out [offset] [0] = (blip_sample_t) l; BLIP_CLAMP( r, r ); out [offset] [1] = (blip_sample_t) r; } while ( ++offset ); BLIP_READER_END( sn, stereo_buf->bufs [0] ); } void mix_stereo( struct Resampler* this, struct Stereo_Buffer* stereo_buf, dsample_t* out_ ) { int const bass = BLIP_READER_BASS( stereo_buf->bufs [0] ); BLIP_READER_BEGIN( snc, stereo_buf->bufs [0] ); BLIP_READER_BEGIN( snl, stereo_buf->bufs [1] ); BLIP_READER_BEGIN( snr, stereo_buf->bufs [2] ); int count = this->sample_buf_size >> 1; BLIP_READER_ADJ_( snc, count ); BLIP_READER_ADJ_( snl, count ); BLIP_READER_ADJ_( snr, count ); typedef dsample_t stereo_dsample_t [2]; stereo_dsample_t* BLARGG_RESTRICT out = (stereo_dsample_t*) out_ + count; stereo_dsample_t const* BLARGG_RESTRICT in = (stereo_dsample_t const*) this->sample_buf + count; int offset = -count; int const gain = this->gain_; do { int sc = BLIP_READER_READ_RAW( snc ) >> (blip_sample_bits - 16); int sl = BLIP_READER_READ_RAW( snl ) >> (blip_sample_bits - 16); int sr = BLIP_READER_READ_RAW( snr ) >> (blip_sample_bits - 16); BLIP_READER_NEXT_IDX_( snc, bass, offset ); BLIP_READER_NEXT_IDX_( snl, bass, offset ); BLIP_READER_NEXT_IDX_( snr, bass, offset ); int l = (in [offset] [0] * gain >> gain_bits) + sl + sc; int r = (in [offset] [1] * gain >> gain_bits) + sr + sc; BLIP_CLAMP( l, l ); out [offset] [0] = (blip_sample_t) l; BLIP_CLAMP( r, r ); out [offset] [1] = (blip_sample_t) r; } while ( ++offset ); BLIP_READER_END( snc, stereo_buf->bufs [0] ); BLIP_READER_END( snl, stereo_buf->bufs [1] ); BLIP_READER_END( snr, stereo_buf->bufs [2] ); } void mix_stereo_no_center( struct Resampler* this, struct Stereo_Buffer* stereo_buf, dsample_t* out_ ) { int const bass = BLIP_READER_BASS( stereo_buf->bufs [0] ); BLIP_READER_BEGIN( snl, stereo_buf->bufs [1] ); BLIP_READER_BEGIN( snr, stereo_buf->bufs [2] ); int count = this->sample_buf_size >> 1; BLIP_READER_ADJ_( snl, count ); BLIP_READER_ADJ_( snr, count ); typedef dsample_t stereo_dsample_t [2]; stereo_dsample_t* BLARGG_RESTRICT out = (stereo_dsample_t*) out_ + count; stereo_dsample_t const* BLARGG_RESTRICT in = (stereo_dsample_t const*) this->sample_buf + count; int offset = -count; int const gain = this->gain_; do { int sl = BLIP_READER_READ_RAW( snl ) >> (blip_sample_bits - 16); int sr = BLIP_READER_READ_RAW( snr ) >> (blip_sample_bits - 16); BLIP_READER_NEXT_IDX_( snl, bass, offset ); BLIP_READER_NEXT_IDX_( snr, bass, offset ); int l = (in [offset] [0] * gain >> gain_bits) + sl; int r = (in [offset] [1] * gain >> gain_bits) + sr; BLIP_CLAMP( l, l ); out [offset] [0] = (blip_sample_t) l; BLIP_CLAMP( r, r ); out [offset] [1] = (blip_sample_t) r; } while ( ++offset ); BLIP_READER_END( snl, stereo_buf->bufs [1] ); BLIP_READER_END( snr, stereo_buf->bufs [2] ); } dsample_t const* resample_( struct Resampler* this, dsample_t** out_, dsample_t const* out_end, dsample_t const in [], int in_size ) { in_size -= write_offset; if ( in_size > 0 ) { dsample_t* BLIP_RESTRICT out = *out_; dsample_t const* const in_end = in + in_size; int const step = this->step; int pos = this->pos; // TODO: IIR filter, then linear resample // TODO: detect skipped sample, allowing merging of IIR and resample? do { #define INTERP( i, out )\ out = (in [0 + i] * (unit - pos) + ((in [2 + i] + in [4 + i] + in [6 + i]) << shift) +\ in [8 + i] * pos) >> (shift + 2); int out_0; INTERP( 0, out_0 ) INTERP( 1, out [0] = out_0; out [1] ) out += stereo; pos += step; in += ((unsigned) pos >> shift) * stereo; pos &= unit - 1; } while ( in < in_end && out < out_end ); this->pos = pos; *out_ = out; } return in; } inline int resample_wrapper( struct Resampler* this, dsample_t out [], int* out_size, dsample_t const in [], int in_size ) { assert( Resampler_rate( this ) ); dsample_t* out_ = out; int result = resample_( this, &out_, out + *out_size, in, in_size ) - in; assert( out_ <= out + *out_size ); assert( result <= in_size ); *out_size = out_ - out; return result; } int skip_input( struct Resampler* this, int count ) { this->write_pos -= count; if ( this->write_pos < 0 ) // occurs when downsampling { count += this->write_pos; this->write_pos = 0; } memmove( this->buf, &this->buf [count], this->write_pos * sizeof this->buf [0] ); return count; } void play_frame_( struct Resampler* this, struct Stereo_Buffer* stereo_buf, dsample_t* out ) { long pair_count = this->sample_buf_size >> 1; blip_time_t blip_time = Blip_count_clocks( &stereo_buf->bufs [0], pair_count ); int sample_count = this->oversamples_per_frame - this->write_pos + resampler_extra; int new_count = this->callback( this->callback_data, blip_time, sample_count, &this->buf [this->write_pos] ); assert( new_count < resampler_size ); Buffer_end_frame( stereo_buf, blip_time ); /* Blip_end_frame( &stereo_buf->bufs [0], blip_time ); */ assert( Blip_samples_avail( &stereo_buf->bufs [0] ) == pair_count * 2 ); this->write_pos += new_count; assert( (unsigned) this->write_pos <= this->buffer_size ); new_count = this->sample_buf_size; if ( new_count ) skip_input( this, resample_wrapper( this, this->sample_buf, &new_count, this->buf, this->write_pos ) ); assert( new_count == (long) this->sample_buf_size ); int bufs_used = stereo_buf->stereo_added | stereo_buf->was_stereo; if ( bufs_used <= 1 ) { mix_mono( this, stereo_buf, out ); Blip_remove_samples( &stereo_buf->bufs [0], pair_count ); Blip_remove_silence( &stereo_buf->bufs [1], pair_count ); Blip_remove_silence( &stereo_buf->bufs [2], pair_count ); } else if ( bufs_used & 1 ) { mix_stereo( this, stereo_buf, out ); Blip_remove_samples( &stereo_buf->bufs [0], pair_count ); Blip_remove_samples( &stereo_buf->bufs [1], pair_count ); Blip_remove_samples( &stereo_buf->bufs [2], pair_count ); } else { mix_stereo_no_center( this, stereo_buf, out ); Blip_remove_silence( &stereo_buf->bufs [0], pair_count ); Blip_remove_samples( &stereo_buf->bufs [1], pair_count ); Blip_remove_samples( &stereo_buf->bufs [2], pair_count ); } // to do: this might miss opportunities for optimization if ( !Blip_samples_avail( &stereo_buf->bufs [0] ) ) { stereo_buf->was_stereo = stereo_buf->stereo_added; stereo_buf->stereo_added = 0; } /* mix_mono( this, stereo_buf, out ); Blip_remove_samples( &stereo_buf->bufs [0], pair_count ); */ } void Resampler_play( struct Resampler* this, long count, dsample_t* out, struct Stereo_Buffer* stereo_buf ) { // empty extra buffer long remain = this->sample_buf_size - this->buf_pos; if ( remain ) { if ( remain > count ) remain = count; count -= remain; memcpy( out, &this->sample_buf [this->buf_pos], remain * sizeof *out ); out += remain; this->buf_pos += remain; } // entire frames while ( count >= (long) this->sample_buf_size ) { play_frame_( this, stereo_buf, out ); out += this->sample_buf_size; count -= this->sample_buf_size; } // extra if ( count ) { play_frame_( this, stereo_buf, this->sample_buf ); this->buf_pos = count; memcpy( out, this->sample_buf, count * sizeof *out ); out += count; } }