#include "opnafm.h" #include "opnatables.h" enum { CH3_MODE_NORMAL = 0, CH3_MODE_CSM = 1, CH3_MODE_SE = 2 }; static void opna_fm_slot_reset(struct opna_fm_slot *slot) { slot->phase = 0; slot->env = 1023; slot->env_count = 0; slot->env_state = ENV_RELEASE; slot->rate_shifter = 0; slot->rate_selector = 0; slot->rate_mul = 0; slot->tl = 0; slot->sl = 0; slot->ar = 0; slot->dr = 0; slot->sr = 0; slot->rr = 0; slot->mul = 0; slot->det = 0; slot->ks = 0; slot->keyon = false; } void opna_fm_chan_reset(struct opna_fm_channel *chan) { for (int i = 0; i < 4; i++) { opna_fm_slot_reset(&chan->slot[i]); } chan->fbmem1 = 0; chan->fbmem2 = 0; chan->alg_mem = 0; chan->alg = 0; chan->fb = 0; chan->fnum = 0; chan->blk = 0; } void opna_fm_reset(struct opna_fm *fm) { for (int i = 0; i < 6; i++) { opna_fm_chan_reset(&fm->channel[i]); fm->lselect[i] = true; fm->rselect[i] = true; } fm->blkfnum_h = 0; fm->env_div3 = 0; fm->ch3.mode = CH3_MODE_NORMAL; for (int i = 0; i < 3; i++) { fm->ch3.fnum[i] = 0; fm->ch3.blk[i] = 0; } } #define LIBOPNA_ENABLE_HIRES // maximum output: 2042<<2 = 8168 static int16_t opna_fm_slotout(struct opna_fm_slot *slot, int16_t modulation) { unsigned pind = (slot->phase >> 10); pind += modulation >> 1; bool minus = pind & (1<<(LOGSINTABLEBIT+1)); bool reverse = pind & (1<phase >> 8); pind_hires += modulation << 1; minus = pind_hires & (1<<(LOGSINTABLEHIRESBIT+1)); reverse = pind_hires & (1<env << 2) + (slot->tl << 5); #else int logout = logsintable[pind] + (slot->env << 2) + (slot->tl << 5); #endif // LIBOPNA_ENABLE_HIRES int selector = logout & ((1<> EXPTABLEBIT; if (shifter > 13) shifter = 13; int16_t out = (exptable[selector] << 2) >> shifter; if (minus) out = -out; return out; } static unsigned blkfnum2freq(unsigned blk, unsigned fnum) { return (fnum << blk) >> 1; } #define F(n) (!!(fnum & (1 << ((n)-1)))) static unsigned blkfnum2keycode(unsigned blk, unsigned fnum) { unsigned keycode = blk<<2; keycode |= F(11) << 1; keycode |= (F(11) && (F(10)||F(9)||F(8))) || ((!F(11))&&F(10)&&F(9)&&F(8)); return keycode; } #undef F static void opna_fm_slot_phase(struct opna_fm_slot *slot, unsigned freq) { // TODO: detune // freq += slot->dt; unsigned det = dettable[slot->det & 0x3][slot->keycode]; if (slot->det & 0x4) det = -det; freq += det; freq &= (1U<<17)-1; int mul = slot->mul << 1; if (!mul) mul = 1; slot->phase += ((freq * mul)>>1); } void opna_fm_chan_phase(struct opna_fm_channel *chan) { unsigned freq = blkfnum2freq(chan->blk, chan->fnum); for (int i = 0; i < 4; i++) { opna_fm_slot_phase(&chan->slot[i], freq); } } static void opna_fm_chan_phase_se(struct opna_fm_channel *chan, struct opna_fm *fm) { unsigned freq; freq = blkfnum2freq(fm->ch3.blk[2], fm->ch3.fnum[1]); opna_fm_slot_phase(&chan->slot[0], freq); freq = blkfnum2freq(fm->ch3.blk[0], fm->ch3.fnum[0]); opna_fm_slot_phase(&chan->slot[2], freq); freq = blkfnum2freq(fm->ch3.blk[1], fm->ch3.fnum[2]); opna_fm_slot_phase(&chan->slot[1], freq); freq = blkfnum2freq(chan->blk, chan->fnum); opna_fm_slot_phase(&chan->slot[3], freq); } int16_t opna_fm_chanout(struct opna_fm_channel *chan) { int16_t fb = chan->fbmem1 + chan->fbmem2; int16_t slot0 = chan->fbmem1; chan->fbmem1 = chan->fbmem2; if (!chan->fb) fb = 0; chan->fbmem2 = opna_fm_slotout(&chan->slot[0], fb >> (9 - chan->fb)); int16_t slot2; int16_t out = 0; switch (chan->alg) { case 0: slot2 = opna_fm_slotout(&chan->slot[2], chan->alg_mem); chan->alg_mem = opna_fm_slotout(&chan->slot[1], slot0); out = opna_fm_slotout(&chan->slot[3], slot2); break; case 1: slot2 = opna_fm_slotout(&chan->slot[2], chan->alg_mem); chan->alg_mem = slot0; chan->alg_mem += opna_fm_slotout(&chan->slot[1], 0); out = opna_fm_slotout(&chan->slot[3], slot2); break; case 2: slot2 = opna_fm_slotout(&chan->slot[2], chan->alg_mem); chan->alg_mem = opna_fm_slotout(&chan->slot[1], 0); out = opna_fm_slotout(&chan->slot[3], slot0 + slot2); break; case 3: slot2 = opna_fm_slotout(&chan->slot[2], 0); out = opna_fm_slotout(&chan->slot[3], slot2 + chan->alg_mem); chan->alg_mem = opna_fm_slotout(&chan->slot[1], slot0); break; case 4: out = opna_fm_slotout(&chan->slot[1], slot0); slot2 = opna_fm_slotout(&chan->slot[2], 0); out += opna_fm_slotout(&chan->slot[3], slot2); break; case 5: out = opna_fm_slotout(&chan->slot[2], chan->alg_mem); chan->alg_mem = slot0; out += opna_fm_slotout(&chan->slot[1], slot0); out += opna_fm_slotout(&chan->slot[3], slot0); break; case 6: out = opna_fm_slotout(&chan->slot[1], slot0); out += opna_fm_slotout(&chan->slot[2], 0); out += opna_fm_slotout(&chan->slot[3], 0); break; case 7: out = slot0; out += opna_fm_slotout(&chan->slot[1], 0); out += opna_fm_slotout(&chan->slot[2], 0); out += opna_fm_slotout(&chan->slot[3], 0); break; } return out; } static void opna_fm_slot_setrate(struct opna_fm_slot *slot, int status) { int r; switch (status) { case ENV_ATTACK: r = slot->ar; break; case ENV_DECAY: r = slot->dr; break; case ENV_SUSTAIN: r = slot->sr; break; case ENV_RELEASE: r = (slot->rr*2+1); break; default: return; } if (!r) { slot->rate_selector = 0; slot->rate_mul = 0; slot->rate_shifter = 0; return; } int rate = 2*r + (slot->keycode >> (3 - slot->ks)); if (rate > 63) rate = 63; int rate_shifter = 11 - (rate >> 2); if (rate_shifter < 0) { slot->rate_selector = (rate & ((1<<2)-1)) + 4; slot->rate_mul = 1<<(-rate_shifter-1); slot->rate_shifter = 0; } else { slot->rate_selector = rate & ((1<<2)-1); slot->rate_mul = 1; slot->rate_shifter = rate_shifter; } } static void opna_fm_slot_env(struct opna_fm_slot *slot) { slot->env_count++; if (!(slot->env_count & ((1<rate_shifter)-1))) { int rate_index = (slot->env_count >> slot->rate_shifter) & 7; int env_inc = rateinctable[slot->rate_selector][rate_index]; env_inc *= slot->rate_mul; switch (slot->env_state) { int newenv; int sl; case ENV_ATTACK: newenv = slot->env + (((-slot->env-1) * env_inc) >> 4); if (newenv <= 0) { slot->env = 0; slot->env_state = ENV_DECAY; opna_fm_slot_setrate(slot, ENV_DECAY); } else { slot->env = newenv; } break; case ENV_DECAY: slot->env += env_inc; sl = slot->sl; if (sl == 0xf) sl = 0x1f; if (slot->env >= (sl << 5)) { slot->env_state = ENV_SUSTAIN; opna_fm_slot_setrate(slot, ENV_SUSTAIN); } break; case ENV_SUSTAIN: slot->env += env_inc; if (slot->env >= 1023) slot->env = 1023; break; case ENV_RELEASE: slot->env += env_inc; if (slot->env >= 1023) { slot->env = 1023; slot->env_state = ENV_OFF; } break; } } } void opna_fm_slot_key(struct opna_fm_channel *chan, int slotnum, bool keyon) { struct opna_fm_slot *slot = &chan->slot[slotnum]; if (keyon) { if (!slot->keyon) { slot->keyon = true; slot->env_state = ENV_ATTACK; slot->env_count = 0; slot->phase = 0; opna_fm_slot_setrate(slot, ENV_ATTACK); } } else { if ((slot->env_state != ENV_OFF) && slot->keyon) { slot->keyon = false; slot->env_state = ENV_RELEASE; opna_fm_slot_setrate(slot, ENV_RELEASE); } } } void opna_fm_slot_set_det(struct opna_fm_slot *slot, unsigned det) { det &= 0x7; slot->det = det; } void opna_fm_slot_set_mul(struct opna_fm_slot *slot, unsigned mul) { mul &= 0xf; slot->mul = mul; } void opna_fm_slot_set_tl(struct opna_fm_slot *slot, unsigned tl) { tl &= 0x7f; slot->tl = tl; } void opna_fm_slot_set_ks(struct opna_fm_slot *slot, unsigned ks) { ks &= 0x3; slot->ks = ks; } void opna_fm_slot_set_ar(struct opna_fm_slot *slot, unsigned ar) { ar &= 0x1f; slot->ar = ar; if (slot->env_state == ENV_ATTACK) { opna_fm_slot_setrate(slot, ENV_ATTACK); } } void opna_fm_slot_set_dr(struct opna_fm_slot *slot, unsigned dr) { dr &= 0x1f; slot->dr = dr; if (slot->env_state == ENV_DECAY) { opna_fm_slot_setrate(slot, ENV_DECAY); } } void opna_fm_slot_set_sr(struct opna_fm_slot *slot, unsigned sr) { sr &= 0x1f; slot->sr = sr; if (slot->env_state == ENV_SUSTAIN) { opna_fm_slot_setrate(slot, ENV_SUSTAIN); } } void opna_fm_slot_set_sl(struct opna_fm_slot *slot, unsigned sl) { sl &= 0xf; slot->sl = sl; } void opna_fm_slot_set_rr(struct opna_fm_slot *slot, unsigned rr) { rr &= 0xf; slot->rr = rr; if (slot->env_state == ENV_RELEASE) { opna_fm_slot_setrate(slot, ENV_RELEASE); } } void opna_fm_chan_set_blkfnum(struct opna_fm_channel *chan, unsigned blk, unsigned fnum) { blk &= 0x7; fnum &= 0x7ff; chan->blk = blk; chan->fnum = fnum; for (int i = 0; i < 4; i++) { chan->slot[i].keycode = blkfnum2keycode(chan->blk, chan->fnum); opna_fm_slot_setrate(&chan->slot[i], chan->slot[i].env_state); } } void opna_fm_chan_set_alg(struct opna_fm_channel *chan, unsigned alg) { alg &= 0x7; chan->alg = alg; } void opna_fm_chan_set_fb(struct opna_fm_channel *chan, unsigned fb) { fb &= 0x7; chan->fb = fb; } //#include void opna_fm_writereg(struct opna_fm *fm, unsigned reg, unsigned val) { val &= (1<<8)-1; if (reg > 0x1ff) return; switch (reg) { case 0x27: { unsigned mode = val >> 6; if (mode != fm->ch3.mode) { // printf("0x27\n"); // printf(" mode = %d\n", mode); fm->ch3.mode = mode; } } return; case 0x28: { int c = val & 0x3; if (c == 3) return; if (val & 0x4) c += 3; for (int i = 0; i < 4; i++) { opna_fm_slot_key(&fm->channel[c], i, (val & (1<<(4+i)))); } } return; } int c = reg & 0x3; if (c == 3) return; if (reg & (1<<8)) c += 3; int s = ((reg & (1<<3)) >> 3) | ((reg & (1<<2)) >> 1); struct opna_fm_channel *chan = &fm->channel[c]; struct opna_fm_slot *slot = &chan->slot[s]; switch (reg & 0xf0) { case 0x30: opna_fm_slot_set_det(slot, (val >> 4) & 0x7); opna_fm_slot_set_mul(slot, val & 0xf); break; case 0x40: opna_fm_slot_set_tl(slot, val & 0x7f); break; case 0x50: opna_fm_slot_set_ks(slot, (val >> 6) & 0x3); opna_fm_slot_set_ar(slot, val & 0x1f); break; case 0x60: opna_fm_slot_set_dr(slot, val & 0x1f); break; case 0x70: opna_fm_slot_set_sr(slot, val & 0x1f); break; case 0x80: opna_fm_slot_set_sl(slot, (val >> 4) & 0xf); opna_fm_slot_set_rr(slot, val & 0xf); break; case 0xa0: { unsigned blk = (fm->blkfnum_h >> 3) & 0x7; unsigned fnum = ((fm->blkfnum_h & 0x7) << 8) | (val & 0xff); switch (reg & 0xc) { case 0x0: opna_fm_chan_set_blkfnum(chan, blk, fnum); break; case 0x8: c %= 3; fm->ch3.blk[c] = blk; fm->ch3.fnum[c] = fnum; break; case 0x4: case 0xc: fm->blkfnum_h = val & 0x3f; break; } } break; case 0xb0: switch (reg & 0xc) { case 0x0: opna_fm_chan_set_alg(chan, val & 0x7); opna_fm_chan_set_fb(chan, (val >> 3) & 0x7); break; case 0x4: fm->lselect[c] = val & 0x80; fm->rselect[c] = val & 0x40; break; } break; } } void opna_fm_chan_env(struct opna_fm_channel *chan) { for (int i = 0; i < 4; i++) { opna_fm_slot_env(&chan->slot[i]); } } void opna_fm_mix(struct opna_fm *fm, int16_t *buf, unsigned samples) { for (unsigned i = 0; i < samples; i++) { if (!fm->env_div3) { for (int c = 0; c < 6; c++) { opna_fm_chan_env(&fm->channel[c]); } fm->env_div3 = 3; } fm->env_div3--; int32_t lo = buf[i*2+0]; int32_t ro = buf[i*2+1]; for (int c = 0; c < 6; c++) { int16_t o = opna_fm_chanout(&fm->channel[c]); // TODO: CSM if (c == 2 && fm->ch3.mode != CH3_MODE_NORMAL) { opna_fm_chan_phase_se(&fm->channel[c], fm); } else { opna_fm_chan_phase(&fm->channel[c]); } o >>= 1; if (fm->lselect[c]) lo += o; if (fm->rselect[c]) ro += o; } if (lo < INT16_MIN) lo = INT16_MIN; if (lo > INT16_MAX) lo = INT16_MAX; if (ro < INT16_MIN) ro = INT16_MIN; if (ro > INT16_MAX) ro = INT16_MAX; buf[i*2+0] = lo; buf[i*2+1] = ro; } }