/* TiMidity++ -- MIDI to WAVE converter and player Copyright (C) 1999-2004 Masanao Izumo Copyright (C) 1995 Tuukka Toivonen 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA recache.c Code related to resample cache. */ #include #include #include #include "timidity.h" #include "common.h" #include "instrum.h" #include "playmidi.h" #include "tables.h" #include "mblock.h" #include "recache.h" #include "resample.h" namespace TimidityPlus { #define CACHE_DATA_LEN (allocate_cache_size / sizeof(sample_t)) inline uint32_t sp_hash(Sample *sp, int note) { return ((uint32_t)(intptr_t)(sp)+(uint32_t)(note)); } #define RESAMPLATION_CACHE _x = do_resamplation(src, ofs, &resrc); \ dest[i] = (int16_t) ((_x > 32767) ? 32767 \ : ((_x < -32768) ? -32768 : _x)) void Recache::free_cache_data(void) { free(cache_data); reuse_mblock(&hash_entry_pool); } void Recache::resamp_cache_reset(void) { if (cache_data == NULL) { cache_data = (sample_t *) safe_large_malloc((CACHE_DATA_LEN + 1) * sizeof(sample_t)); memset(cache_data, 0, (CACHE_DATA_LEN + 1) * sizeof(sample_t)); init_mblock(&hash_entry_pool); } cache_data_len = 0; memset(cache_hash_table, 0, sizeof(cache_hash_table)); memset(channel_note_table, 0, sizeof(channel_note_table)); reuse_mblock(&hash_entry_pool); } struct cache_hash *Recache::resamp_cache_fetch(Sample *sp, int note) { unsigned int addr; struct cache_hash *p; if (sp->vibrato_control_ratio || (sp->modes & MODES_PINGPONG) || (sp->sample_rate == playback_rate && sp->root_freq == get_note_freq(sp, sp->note_to_use))) return NULL; addr = sp_hash(sp, note) % HASH_TABLE_SIZE; p = cache_hash_table[addr]; while (p && (p->note != note || p->sp != sp)) p = p->next; if (p && p->resampled != NULL) return p; return NULL; } void Recache::resamp_cache_refer_on(Voice *vp, int32_t sample_start) { unsigned int addr; struct cache_hash *p; int note, ch; ch = vp->channel; if (vp->vibrato_control_ratio || player->channel[ch].portamento || (vp->sample->modes & MODES_PINGPONG) || vp->orig_frequency != vp->frequency || (vp->sample->sample_rate == playback_rate && vp->sample->root_freq == get_note_freq(vp->sample, vp->sample->note_to_use))) return; note = vp->note; if (channel_note_table[ch].cache[note]) resamp_cache_refer_off(ch, note, sample_start); addr = sp_hash(vp->sample, note) % HASH_TABLE_SIZE; p = cache_hash_table[addr]; while (p && (p->note != note || p->sp != vp->sample)) p = p->next; if (! p) { p = (struct cache_hash *) new_segment(&hash_entry_pool, sizeof(struct cache_hash)); p->cnt = 0; p->note = vp->note; p->sp = vp->sample; p->resampled = NULL; p->next = cache_hash_table[addr]; cache_hash_table[addr] = p; } channel_note_table[ch].cache[note] = p; channel_note_table[ch].on[note] = sample_start; } void Recache::resamp_cache_refer_off(int ch, int note, int32_t sample_end) { int32_t sample_start, len; struct cache_hash *p; Sample *sp; p = channel_note_table[ch].cache[note]; if (p == NULL) return; sp = p->sp; if (sp->sample_rate == playback_rate && sp->root_freq == get_note_freq(sp, sp->note_to_use)) return; sample_start = channel_note_table[ch].on[note]; len = sample_end - sample_start; if (len < 0) { channel_note_table[ch].cache[note] = NULL; return; } if (! (sp->modes & MODES_LOOPING)) { double a; int32_t slen; a = ((double) sp->root_freq * playback_rate) / ((double) sp->sample_rate * get_note_freq(sp, note)); slen = (int32_t) ((sp->data_length >> FRACTION_BITS) * a); if (len > slen) len = slen; } p->cnt += len; channel_note_table[ch].cache[note] = NULL; } void Recache::resamp_cache_refer_alloff(int ch, int32_t sample_end) { int i; for (i = 0; i < 128; i++) resamp_cache_refer_off(ch, i, sample_end); } void Recache::resamp_cache_create(void) { int i, skip; int32_t n, t1, t2, total; struct cache_hash **array; /* It is NP completion that solve the best cache hit rate. * So I thought better algorism O(n log n), but not a best solution. * Follows implementation takes good hit rate, and it is fast. */ n = t1 = t2 = 0; total = 0; /* set size per count */ for (i = 0; i < HASH_TABLE_SIZE; i++) { struct cache_hash *p, *q; p = cache_hash_table[i], q = NULL; while (p) { struct cache_hash *tmp; t1 += p->cnt; tmp = p, p = p->next; if (tmp->cnt > 0) { Sample *sp; splen_t newlen; sp = tmp->sp; sample_resamp_info(sp, tmp->note, NULL, NULL, &newlen); if (newlen > 0) { total += tmp->cnt; tmp->r = (double) newlen / tmp->cnt; tmp->next = q, q = tmp; n++; } } } cache_hash_table[i] = q; } if (n == 0) { return; } array = (struct cache_hash **) new_segment(&hash_entry_pool, n * sizeof(struct cache_hash *)); n = 0; for (i = 0; i < HASH_TABLE_SIZE; i++) { struct cache_hash *p; for (p = cache_hash_table[i]; p; p = p->next) array[n++] = p; } if ((uint32_t)total > CACHE_DATA_LEN) qsort_cache_array(array, 0, n - 1); skip = 0; for (i = 0; i < n; i++) { if (array[i]->r != 0 && cache_resampling(array[i]) == CACHE_RESAMPLING_OK) t2 += array[i]->cnt; else skip++; } /* update cache_hash_table */ if (skip) for (i = 0; i < HASH_TABLE_SIZE; i++) { struct cache_hash *p, *q; p = cache_hash_table[i], q = NULL; while (p) { struct cache_hash *tmp; tmp = p, p = p->next; if (tmp->resampled) tmp->next = q, q = tmp; } cache_hash_table[i] = q; } } double Recache::sample_resamp_info(Sample *sp, int note, splen_t *loop_start, splen_t *loop_end, splen_t *data_length) { splen_t xls, xle, ls, le, ll, newlen; double a, xxls, xxle, xn; a = ((double) sp->sample_rate * get_note_freq(sp, note)) / ((double) sp->root_freq * playback_rate); a = TIM_FSCALENEG((double) (int32_t) TIM_FSCALE(a, FRACTION_BITS), FRACTION_BITS); xn = sp->data_length / a; if (xn >= SPLEN_T_MAX) { /* Ignore this sample */ *data_length = 0; return 0.0; } newlen = (splen_t) (TIM_FSCALENEG(xn, FRACTION_BITS) + 0.5); ls = sp->loop_start; le = sp->loop_end; ll = le - ls; xxls = ls / a + 0.5; if (xxls >= SPLEN_T_MAX) { /* Ignore this sample */ *data_length = 0; return 0.0; } xls = (splen_t) xxls; xxle = le / a + 0.5; if (xxle >= SPLEN_T_MAX) { /* Ignore this sample */ *data_length = 0; return 0.0; } xle = (splen_t) xxle; if ((sp->modes & MODES_LOOPING) && ((xle - xls) >> FRACTION_BITS) < MIN_LOOPLEN) { splen_t n; splen_t newxle; double xl; /* Resampled new loop length */ double xnewxle; xl = ll / a; if (xl >= SPLEN_T_MAX) { /* Ignore this sample */ *data_length = 0; return 0.0; } n = (splen_t) (0.0001 + MIN_LOOPLEN / TIM_FSCALENEG(xl, FRACTION_BITS)) + 1; xnewxle = le / a + n * xl + 0.5; if (xnewxle >= SPLEN_T_MAX) { /* Ignore this sample */ *data_length = 0; return 0.0; } newxle = (splen_t) xnewxle; newlen += (newxle - xle) >> FRACTION_BITS; xle = newxle; } if (loop_start) *loop_start = (splen_t) (xls & ~FRACTION_MASK); if (loop_end) *loop_end = (splen_t) (xle & ~FRACTION_MASK); *data_length = newlen << FRACTION_BITS; return a; } void Recache::qsort_cache_array(struct cache_hash **a, int32_t first, int32_t last) { int32_t i = first, j = last; struct cache_hash *x, *t; if (j - i < SORT_THRESHOLD) { insort_cache_array(a + i, j - i + 1); return; } x = a[(first + last) / 2]; for (;;) { while (a[i]->r < x->r) i++; while (x->r < a[j]->r) j--; if (i >= j) break; t = a[i], a[i] = a[j], a[j] = t; i++, j--; } if (first < i - 1) qsort_cache_array(a, first, i - 1); if (j + 1 < last) qsort_cache_array(a, j + 1, last); } void Recache::insort_cache_array(struct cache_hash **data, int32_t n) { int32_t i, j; struct cache_hash *x; for (i = 1; i < n; i++) { x = data[i]; for (j = i - 1; j >= 0 && x->r < data[j]->r; j--) data[j + 1] = data[j]; data[j + 1] = x; } } int Recache::cache_resampling(struct cache_hash *p) { Sample *sp, *newsp; sample_t *src, *dest; splen_t newlen, ofs, le, ls, ll, xls, xle; int32_t incr, _x; resample_rec_t resrc; double a; int8_t note; sp = p->sp; if (sp->note_to_use) note = sp->note_to_use; else note = p->note; a = sample_resamp_info(sp, note, &xls, &xle, &newlen); if (newlen == 0) return CACHE_RESAMPLING_NOTOK; newlen >>= FRACTION_BITS; if (cache_data_len + newlen + 1 > CACHE_DATA_LEN) return CACHE_RESAMPLING_NOTOK; resrc.loop_start = ls = sp->loop_start; resrc.loop_end = le = sp->loop_end; resrc.data_length = sp->data_length; ll = sp->loop_end - sp->loop_start; dest = cache_data + cache_data_len; src = sp->data; newsp = (Sample *) new_segment(&hash_entry_pool, sizeof(Sample)); memcpy(newsp, sp, sizeof(Sample)); newsp->data = dest; ofs = 0; incr = (splen_t) (TIM_FSCALE(a, FRACTION_BITS) + 0.5); if (sp->modes & MODES_LOOPING) for (splen_t i = 0; i < newlen; i++) { if (ofs >= le) ofs -= ll; RESAMPLATION_CACHE; ofs += incr; } else for (splen_t i = 0; i < newlen; i++) { RESAMPLATION_CACHE; ofs += incr; } newsp->loop_start = xls; newsp->loop_end = xle; newsp->data_length = newlen << FRACTION_BITS; if (sp->modes & MODES_LOOPING) loop_connect(dest, (int32_t) (xls >> FRACTION_BITS), (int32_t) (xle >> FRACTION_BITS)); dest[xle >> FRACTION_BITS] = dest[xls >> FRACTION_BITS]; newsp->root_freq = get_note_freq(newsp, note); newsp->sample_rate = playback_rate; p->resampled = newsp; cache_data_len += newlen + 1; return CACHE_RESAMPLING_OK; } void Recache::loop_connect(sample_t *data, int32_t start, int32_t end) { int i, mixlen; int32_t t0, t1; mixlen = MIXLEN; if (start < mixlen) mixlen = start; if (end - start < mixlen) mixlen = end - start; if (mixlen <= 0) return; t0 = start - mixlen; t1 = end - mixlen; for (i = 0; i < mixlen; i++) { double x, b; b = i / (double) mixlen; /* 0 <= b < 1 */ x = b * data[t0 + i] + (1.0 - b) * data[t1 + i]; if (x < -32768) data[t1 + i] = -32768; else if (x > 32767) data[t1 + i] = 32767; else data[t1 + i] = (sample_t) x; } } }