/* * Copyright (C) 2023 nukeykt * * This file is part of YM3812-LLE. * * 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. * * YM3812 emulator * Thanks: * Travis Goodspeed: * YM3812 decap and die shot * */ #include "fmopl2.h" void FMOPL2_DoShiftRegisters(fmopl2_t *chip, int sel) { int j; int to = sel; int from = sel ^ 1; int rot = sel == 0 ? 1 : 0; #define CH_ROTATE(x) rot ? ((x << 1) | ((x >> 8) & 1)) : x #define OP_ROTATE(x) rot ? ((x << 1) | ((x >> 17) & 1)) : x // channel registers // fnum for (j = 0; j < 10; j++) chip->ch_fnum[j][to] = CH_ROTATE(chip->ch_fnum[j][from]); // block for (j = 0; j < 3; j++) chip->ch_block[j][to] = CH_ROTATE(chip->ch_block[j][from]); // kon chip->ch_keyon[to] = CH_ROTATE(chip->ch_keyon[from]); // connect chip->ch_connect[to] = CH_ROTATE(chip->ch_connect[from]); // feedback for (j = 0; j < 3; j++) chip->ch_fb[j][to] = CH_ROTATE(chip->ch_fb[j][from]); // multi for (j = 0; j < 4; j++) chip->op_multi[j][to] = OP_ROTATE(chip->op_multi[j][from]); // ksr chip->op_ksr[to] = OP_ROTATE(chip->op_ksr[from]); // egt chip->op_egt[to] = OP_ROTATE(chip->op_egt[from]); // vib chip->op_vib[to] = OP_ROTATE(chip->op_vib[from]); // am chip->op_am[to] = OP_ROTATE(chip->op_am[from]); // tl for (j = 0; j < 6; j++) chip->op_tl[j][to] = OP_ROTATE(chip->op_tl[j][from]); // ksl for (j = 0; j < 2; j++) chip->op_ksl[j][to] = OP_ROTATE(chip->op_ksl[j][from]); // ar for (j = 0; j < 4; j++) chip->op_ar[j][to] = OP_ROTATE(chip->op_ar[j][from]); // dr for (j = 0; j < 4; j++) chip->op_dr[j][to] = OP_ROTATE(chip->op_dr[j][from]); // sl for (j = 0; j < 4; j++) chip->op_sl[j][to] = OP_ROTATE(chip->op_sl[j][from]); // rr for (j = 0; j < 4; j++) chip->op_rr[j][to] = OP_ROTATE(chip->op_rr[j][from]); // wf for (j = 0; j < 2; j++) chip->op_wf[j][to] = OP_ROTATE(chip->op_wf[j][from]); #undef CH_ROTATE #undef OP_ROTATE } enum { eg_state_attack = 0, eg_state_decay, eg_state_sustain, eg_state_release }; void FMOPL2_Clock(fmopl2_t *chip) { int i; chip->mclk1 = !chip->input.mclk; chip->mclk2 = chip->input.mclk; chip->reset1 = !chip->input.ic; chip->io_rd = !chip->input.rd; chip->io_wr = !chip->input.wr; chip->io_cs = !chip->input.cs; chip->io_a0 = chip->input.address & 1; if (chip->mclk1) { int prescaler_reset = !(chip->prescaler_reset_l[1] & 2) && chip->reset1; chip->prescaler_reset_l[0] = (chip->prescaler_reset_l[1] << 1) | chip->reset1; if (prescaler_reset) chip->prescaler_cnt[0] = 0; else chip->prescaler_cnt[0] = (chip->prescaler_cnt[1] + 1) & 3; chip->prescaler_l1[0] = !prescaler_reset && chip->prescaler_cnt[1] == 1; chip->prescaler_l2[0] = chip->prescaler_cnt[1] == 3; } if (chip->mclk2) { chip->prescaler_reset_l[1] = chip->prescaler_reset_l[0]; chip->prescaler_cnt[1] = chip->prescaler_cnt[0]; chip->prescaler_l1[1] = chip->prescaler_l1[0]; chip->prescaler_l2[1] = chip->prescaler_l2[0]; } chip->clk1 = chip->prescaler_l1[1]; chip->clk2 = chip->prescaler_l2[1]; chip->io_read0 = !chip->reset1 && chip->io_cs && chip->io_rd && !chip->io_a0; chip->io_read1 = !chip->reset1 && chip->io_cs && chip->io_rd && chip->io_a0; chip->io_write = !chip->reset1 && chip->io_cs && chip->io_wr; chip->io_write0 = !chip->reset1 && chip->io_cs && chip->io_wr && !chip->io_a0; chip->io_write1 = !chip->reset1 && chip->io_cs && chip->io_wr && chip->io_a0; chip->io_dir = chip->io_cs && chip->io_rd; int irq = chip->t1_status || chip->t2_status || chip->unk_status1 || chip->unk_status2; if (!chip->io_dir) chip->io_data = chip->input.data_i; if (chip->io_write) chip->data_latch = chip->io_data; if (chip->write0) chip->write0_sr = 0; else if (chip->io_write0) chip->write0_sr = 1; if (chip->write1) chip->write1_sr = 0; else if (chip->io_write1) chip->write1_sr = 1; if (chip->mclk1) { chip->write0_latch[1] = chip->write0_latch[0]; chip->write1_latch[1] = chip->write1_latch[0]; } if (chip->mclk2) { chip->write0_latch[0] = chip->write0_sr; chip->write0_latch[2] = chip->write0_latch[1]; chip->write1_latch[0] = chip->write1_sr; chip->write1_latch[2] = chip->write1_latch[1]; } if (chip->clk1) { chip->write0_latch[4] = chip->write0_latch[3]; chip->write1_latch[4] = chip->write1_latch[3]; } if (chip->clk2) { chip->write0_latch[3] = chip->write0_latch[2]; chip->write0_latch[5] = chip->write0_latch[4]; chip->write1_latch[3] = chip->write1_latch[2]; chip->write1_latch[5] = chip->write1_latch[4]; } chip->write0 = chip->write0_latch[5]; chip->write1 = chip->write1_latch[5]; //// if (chip->o_clk1 == chip->clk1 && chip->o_clk2 == chip->clk2 && chip->o_reset1 == chip->reset1 && chip->o_write0 == chip->write0 && chip->o_write1 == chip->write1 && chip->o_data_latch == chip->data_latch) goto end; // opt chip->o_clk1 = chip->clk1; chip->o_clk2 = chip->clk2; chip->o_reset1 = chip->reset1; chip->o_write0 = chip->write0; chip->o_write1 = chip->write1; chip->o_data_latch = chip->data_latch; if (chip->write0) { chip->reg_sel1 = chip->data_latch == 1; chip->reg_sel2 = chip->data_latch == 2; chip->reg_sel3 = chip->data_latch == 3; chip->reg_sel4 = chip->data_latch == 4; chip->reg_sel8 = chip->data_latch == 8; chip->reg_selbd = chip->data_latch == 0xbd; } chip->reg_sel4_wr = chip->write1 && chip->reg_sel4 && (chip->data_latch & 128) == 0; chip->reg_sel4_rst = (chip->write1 && chip->reg_sel4 && (chip->data_latch & 128) != 0) || chip->reset1; if (chip->reset1) { chip->reg_test = 0; chip->reg_timer1 = 0; chip->reg_timer2 = 0; chip->reg_notesel = 0; chip->reg_csm = 0; chip->rhythm = 0; chip->reg_rh_kon = 0; chip->reg_da = 0; chip->reg_dv = 0; } else if (chip->write1) { if (chip->reg_sel1) chip->reg_test = chip->data_latch & 255; if (chip->reg_sel2) chip->reg_timer1 = chip->data_latch & 255; if (chip->reg_sel3) chip->reg_timer2 = chip->data_latch & 255; if (chip->reg_sel8) { chip->reg_notesel = (chip->data_latch & 64) != 0; chip->reg_csm = (chip->data_latch & 128) != 0; } if (chip->reg_selbd) { chip->reg_rh_kon = chip->data_latch & 31; chip->rhythm = (chip->data_latch & 32) != 0; chip->reg_dv = (chip->data_latch & 64) != 0; chip->reg_da = (chip->data_latch & 128) != 0; } } if (chip->reset1) { chip->reg_t1_mask = 0; chip->reg_t2_mask = 0; chip->reg_t1_start = 0; chip->reg_t2_start = 0; chip->reg_mode_b3 = 0; chip->reg_mode_b4 = 0; } else if (chip->reg_sel4_wr) { chip->reg_t1_mask = (chip->data_latch & 64) != 0; chip->reg_t2_mask = (chip->data_latch & 32) != 0; chip->reg_t1_start = (chip->data_latch & 1) != 0; chip->reg_t2_start = (chip->data_latch & 2) != 0; chip->reg_mode_b3 = (chip->data_latch & 8) != 0; chip->reg_mode_b4 = (chip->data_latch & 16) != 0; } { chip->fsm_reset = !(chip->fsm_reset_l[1] & 2) && chip->reset1; chip->fsm_cnt1_of = (chip->fsm_cnt1[1] & 5) == 5; chip->fsm_cnt2_of = chip->fsm_cnt1_of && (chip->fsm_cnt2[1] & 2) != 0; chip->fsm_cnt = (chip->fsm_cnt2[1] << 3) | chip->fsm_cnt1[1]; chip->fsm_sel[0] = chip->fsm_cnt == 20 && chip->rhythm; chip->fsm_sel[1] = chip->fsm_cnt == 19 && chip->rhythm; chip->fsm_sel[2] = chip->fsm_cnt == 18 && chip->rhythm; chip->fsm_sel[3] = chip->fsm_cnt == 17 && chip->rhythm; chip->fsm_sel[4] = chip->fsm_cnt == 16 && chip->rhythm; chip->fsm_sel[5] = chip->fsm_cnt == 20 && chip->rhythm; chip->fsm_sel[6] = chip->fsm_cnt == 19 && chip->rhythm; chip->fsm_sel[7] = (chip->fsm_cnt & 5) == 4; chip->fsm_sel[8] = chip->fsm_cnt == 16; chip->fsm_sel[9] = (chip->fsm_cnt & 29) == 5; chip->fsm_sel[10] = chip->fsm_cnt == 16; chip->fsm_sel[11] = chip->fsm_cnt == 11; chip->fsm_sel[12] = chip->fsm_cnt == 20; int fsm_mc = !(chip->fsm_sel[7] || (chip->fsm_cnt & 2) != 0); chip->fsm_out[0] = ((chip->connect_l[1] & 2) != 0 || chip->fsm_sel[0] || chip->fsm_sel[1] || fsm_mc) && !chip->fsm_sel[2]; chip->fsm_out[1] = fsm_mc && !chip->fsm_sel[3] && !chip->fsm_sel[4]; chip->fsm_out[2] = !fsm_mc && !chip->fsm_sel[5] && !chip->fsm_sel[6]; chip->fsm_out[3] = !(chip->fsm_l1[1] && 1); chip->fsm_out[4] = chip->fsm_l2[1]; chip->fsm_out[5] = chip->fsm_sel[10]; chip->fsm_out[6] = chip->fsm_sel[11]; chip->fsm_out[7] = chip->fsm_sel[12]; chip->fsm_out[8] = (chip->fsm_l3[1] & 1) != 0; chip->fsm_out[9] = (chip->fsm_l3[1] & 2) != 0; chip->fsm_out[10] = (chip->fsm_l3[1] & 2) != 0; chip->fsm_out[11] = (chip->fsm_l4[1] & 2) != 0 && chip->rhythm; chip->fsm_out[12] = (chip->fsm_l5[1] & 4) != 0; chip->fsm_out[13] = (chip->fsm_l6[1] & 4) != 0; chip->fsm_out[14] = !(chip->fsm_out[12] || (chip->fsm_cnt & 16) != 0); chip->fsm_out[15] = !(chip->fsm_out[12] || chip->fsm_out[13]); } if (chip->clk1) { if (chip->fsm_reset || chip->fsm_cnt1_of) chip->fsm_cnt1[0] = 0; else chip->fsm_cnt1[0] = (chip->fsm_cnt1[1] + 1) & 7; if (chip->fsm_reset || chip->fsm_cnt2_of) chip->fsm_cnt2[0] = 0; else chip->fsm_cnt2[0] = (chip->fsm_cnt2[1] + chip->fsm_cnt1_of) & 3; chip->fsm_reset_l[0] = (chip->fsm_reset_l[1] << 1) | chip->reset1; chip->fsm_l1[0] = !chip->fsm_sel[8] && !chip->fsm_sel[9] && (chip->fsm_cnt & 8) == 0; chip->fsm_l2[0] = chip->fsm_sel[10]; chip->fsm_l3[0] = (chip->fsm_l3[1] << 1) | chip->fsm_sel[12]; chip->fsm_l4[0] = (chip->fsm_l4[1] << 1) | ((chip->fsm_cnt & 16) != 0); chip->fsm_l5[0] = (chip->fsm_l5[1] << 1) | ((chip->fsm_cnt & 8) != 0); chip->fsm_l6[0] = (chip->fsm_l6[1] << 1) | ((chip->fsm_cnt & 16) != 0); } if (chip->clk2) { chip->fsm_cnt1[1] = chip->fsm_cnt1[0]; chip->fsm_cnt2[1] = chip->fsm_cnt2[0]; chip->fsm_reset_l[1] = chip->fsm_reset_l[0]; chip->fsm_l1[1] = chip->fsm_l1[0]; chip->fsm_l2[1] = chip->fsm_l2[0]; chip->fsm_l3[1] = chip->fsm_l3[0]; chip->fsm_l4[1] = chip->fsm_l4[0]; chip->fsm_l5[1] = chip->fsm_l5[0]; chip->fsm_l6[1] = chip->fsm_l6[0]; } if (chip->clk1) chip->timer_st_load_l = chip->fsm_out[8]; chip->timer_st_load = chip->fsm_out[8] && !chip->timer_st_load_l; if (chip->timer_st_load) chip->t1_start = chip->reg_t1_start; if (chip->clk1) { int lfo = chip->lfo_cnt[1]; int add = chip->fsm_out[8]; chip->lfo_cnt[0] = (chip->reg_test & 128) != 0 ? 0 : (lfo + add) & 1023; chip->vib_cnt[0] = (chip->reg_test & 128) != 0 ? 0 : (chip->vib_cnt[1] + chip->vib_step) & 7; } if (chip->clk2) { chip->lfo_cnt[1] = chip->lfo_cnt[0]; chip->vib_cnt[1] = chip->vib_cnt[0]; } { int lfo = chip->lfo_cnt[1]; int add = chip->fsm_out[8]; chip->t1_step = (((lfo & 3) + add) & 4) != 0; chip->t2_step = (((lfo & 15) + add) & 16) != 0; chip->am_step = (((lfo & 63) + add) & 64) != 0; chip->vib_step = (((lfo & 1023) + add) & 1024) != 0; chip->vib_step |= (chip->reg_test & 8) != 0 && add; } if (chip->clk1) { int value = chip->t1_load ? chip->reg_timer1 : chip->t1_cnt[1]; value += ((chip->t1_start_l[1] & 1) != 0 && chip->t1_step) || (chip->reg_test & 2) != 0; chip->t1_of[0] = (value & 256) != 0; chip->t1_cnt[0] = (chip->t1_start_l[1] & 1) == 0 ? 0 : (value & 255); value = (chip->t2_of[1] || (chip->t2_start_l[1] & 3) == 1) ? chip->reg_timer2 : chip->t2_cnt[1]; value += ((chip->t2_start_l[1] & 1) != 0 && chip->t2_step) || (chip->reg_test & 2) != 0; chip->t2_of[0] = (value & 256) != 0; chip->t2_cnt[0] = (chip->t2_start_l[1] & 1) == 0 ? 0 : (value & 255); chip->t1_start_l[0] = (chip->t1_start_l[1] << 1) | chip->t1_start; chip->t2_start_l[0] = (chip->t2_start_l[1] << 1) | chip->reg_t2_start; } if (chip->clk2) { chip->t1_cnt[1] = chip->t1_cnt[0]; chip->t1_of[1] = chip->t1_of[0]; chip->t2_cnt[1] = chip->t2_cnt[0]; chip->t2_of[1] = chip->t2_of[0]; chip->t1_start_l[1] = chip->t1_start_l[0]; chip->t2_start_l[1] = chip->t2_start_l[0]; chip->t1_load = (chip->t1_of[1] || (chip->t1_start_l[1] & 3) == 1); // opt } if (chip->reg_sel4_rst || chip->reg_t1_mask) chip->t1_status = 0; else if (chip->t1_of[1]) chip->t1_status = 1; if (chip->reg_sel4_rst || chip->reg_t2_mask) chip->t2_status = 0; else if (chip->t2_of[1]) chip->t2_status = 1; if (chip->reg_sel4_rst || chip->reg_mode_b4) chip->unk_status1 = 0; else if (0) chip->unk_status1 = 1; chip->unk_status2 = 0; if (chip->clk1) chip->csm_load_l = chip->fsm_out[10]; chip->csm_load = chip->fsm_out[10] && !chip->csm_load_l; if (chip->csm_load) chip->csm_kon = chip->reg_csm && chip->t1_load; chip->rh_sel0 = chip->rhythm && chip->fsm_out[5]; if (chip->clk1) { chip->rh_sel[0] = (chip->rh_sel[1] << 1) | chip->rh_sel0; } if (chip->clk2) { chip->rh_sel[1] = chip->rh_sel[0]; } //if (chip->clk1) // opt { chip->keyon_comb = chip->keyon || chip->csm_kon || (chip->rh_sel0 && (chip->reg_rh_kon & 16) != 0) // bd0 || ((chip->rh_sel[1] & 1) != 0 && (chip->reg_rh_kon & 1) != 0) // hh || ((chip->rh_sel[1] & 2) != 0 && (chip->reg_rh_kon & 4) != 0) // tom || ((chip->rh_sel[1] & 4) != 0 && (chip->reg_rh_kon & 16) != 0) // bd1 || ((chip->rh_sel[1] & 8) != 0 && (chip->reg_rh_kon & 8) != 0) // sd || ((chip->rh_sel[1] & 16) != 0 && (chip->reg_rh_kon & 2) != 0); // tc } if (chip->reset1) chip->address = 0; else if ((chip->data_latch & 0xe0) != 0 && chip->write0) chip->address = chip->data_latch; if (chip->write0) chip->address_valid = (chip->data_latch & 0xe0) != 0; if (chip->reset1) chip->data = 0; else if (chip->address_valid && chip->write1) chip->data = chip->data_latch; chip->address_valid2 = chip->address_valid_l[1] && !chip->write0; if (chip->clk1) { chip->address_valid_l[0] = (chip->address_valid && chip->write1) || chip->address_valid2; int slot_cnt1_of = (chip->slot_cnt1[1] & 5) == 5; if (chip->fsm_out[8] || slot_cnt1_of) chip->slot_cnt1[0] = 0; else chip->slot_cnt1[0] = (chip->slot_cnt1[1] + 1) & 7; if (chip->fsm_out[8] || (slot_cnt1_of && (chip->slot_cnt2[1] & 2) != 0)) chip->slot_cnt2[0] = 0; else chip->slot_cnt2[0] = (chip->slot_cnt2[1] + slot_cnt1_of) & 3; } if (chip->clk2) { chip->address_valid_l[1] = chip->address_valid_l[0]; chip->slot_cnt1[1] = chip->slot_cnt1[0]; chip->slot_cnt2[1] = chip->slot_cnt2[0]; chip->slot_cnt = (chip->slot_cnt2[1] << 3) | chip->slot_cnt1[1]; // opt } if (chip->clk1) { int sel_ch = (chip->address & 0xf0) == 0xa0 || (chip->address & 0xf0) == 0xb0 || (chip->address & 0xf0) == 0xc0; int addr_add = sel_ch && ((chip->address & 8) != 0 || (chip->address & 6) == 6); int addr_sel = chip->address & 1; addr_sel |= (((chip->address >> 1) + addr_add) & 7) << 1; if (!sel_ch) addr_sel |= chip->address & 16; int addr_match = addr_sel == chip->slot_cnt && chip->address_valid2; int sel_20 = (chip->address & 0xe0) == 0x20 && addr_match; int sel_40 = (chip->address & 0xe0) == 0x40 && addr_match; int sel_60 = (chip->address & 0xe0) == 0x60 && addr_match; int sel_80 = (chip->address & 0xe0) == 0x80 && addr_match; int sel_e0 = (chip->address & 0xe0) == 0xe0 && addr_match && (chip->reg_test & 32) != 0; int sel_a0 = (chip->address & 0xf0) == 0xa0 && addr_match; int sel_b0 = (chip->address & 0xf0) == 0xb0 && addr_match; int sel_c0 = (chip->address & 0xf0) == 0xc0 && addr_match; FMOPL2_DoShiftRegisters(chip, 0); if (chip->reset1) { for (i = 0; i < 10; i++) chip->ch_fnum[i][0] &= ~1; for (i = 0; i < 3; i++) chip->ch_block[i][0] &= ~1; chip->ch_keyon[0] &= ~1; chip->ch_connect[0] &= ~1; for (i = 0; i < 3; i++) chip->ch_fb[i][0] &= ~1; for (i = 0; i < 4; i++) chip->op_multi[i][0] &= ~1; chip->op_ksr[0] &= ~1; chip->op_egt[0] &= ~1; chip->op_vib[0] &= ~1; chip->op_am[0] &= ~1; for (i = 0; i < 6; i++) chip->op_tl[i][0] &= ~1; for (i = 0; i < 2; i++) chip->op_ksl[i][0] &= ~1; for (i = 0; i < 4; i++) chip->op_ar[i][0] &= ~1; for (i = 0; i < 4; i++) chip->op_dr[i][0] &= ~1; for (i = 0; i < 4; i++) chip->op_sl[i][0] &= ~1; for (i = 0; i < 4; i++) chip->op_rr[i][0] &= ~1; for (i = 0; i < 2; i++) chip->op_wf[i][0] &= ~1; } else { if (sel_a0) { for (i = 0; i < 8; i++) chip->ch_fnum[i][0] &= ~1; for (i = 0; i < 8; i++) chip->ch_fnum[i][0] |= (chip->data >> i) & 1; } if (sel_b0) { for (i = 8; i < 10; i++) chip->ch_fnum[i][0] &= ~1; for (i = 0; i < 3; i++) chip->ch_block[i][0] &= ~1; chip->ch_keyon[0] &= ~1; for (i = 8; i < 10; i++) chip->ch_fnum[i][0] |= (chip->data >> (i - 8)) & 1; for (i = 0; i < 3; i++) chip->ch_block[i][0] |= (chip->data >> (i + 2)) & 1; chip->ch_keyon[0] |= (chip->data >> 5) & 1; } if (sel_c0) { chip->ch_connect[0] &= ~1; for (i = 0; i < 3; i++) chip->ch_fb[i][0] &= ~1; chip->ch_connect[0] |= (chip->data >> 0) & 1; for (i = 0; i < 3; i++) chip->ch_fb[i][0] |= (chip->data >> (i + 1)) & 1; } if (sel_20) { for (i = 0; i < 4; i++) chip->op_multi[i][0] &= ~1; chip->op_ksr[0] &= ~1; chip->op_egt[0] &= ~1; chip->op_vib[0] &= ~1; chip->op_am[0] &= ~1; for (i = 0; i < 4; i++) chip->op_multi[i][0] |= (chip->data >> i) & 1; chip->op_ksr[0] |= (chip->data >> 4) & 1; chip->op_egt[0] |= (chip->data >> 5) & 1; chip->op_vib[0] |= (chip->data >> 6) & 1; chip->op_am[0] |= (chip->data >> 7) & 1; } if (sel_40) { for (i = 0; i < 6; i++) chip->op_tl[i][0] &= ~1; for (i = 0; i < 2; i++) chip->op_ksl[i][0] &= ~1; for (i = 0; i < 6; i++) chip->op_tl[i][0] |= (chip->data >> i) & 1; for (i = 0; i < 2; i++) chip->op_ksl[i][0] |= (chip->data >> (i + 6)) & 1; } if (sel_60) { for (i = 0; i < 4; i++) chip->op_ar[i][0] &= ~1; for (i = 0; i < 4; i++) chip->op_dr[i][0] &= ~1; for (i = 0; i < 4; i++) chip->op_ar[i][0] |= (chip->data >> (i + 4)) & 1; for (i = 0; i < 4; i++) chip->op_dr[i][0] |= (chip->data >> i) & 1; } if (sel_80) { for (i = 0; i < 4; i++) chip->op_sl[i][0] &= ~1; for (i = 0; i < 4; i++) chip->op_rr[i][0] &= ~1; for (i = 0; i < 4; i++) chip->op_sl[i][0] |= (chip->data >> (i + 4)) & 1; for (i = 0; i < 4; i++) chip->op_rr[i][0] |= (chip->data >> i) & 1; } if (sel_e0) { for (i = 0; i < 2; i++) chip->op_wf[i][0] &= ~1; for (i = 0; i < 2; i++) chip->op_wf[i][0] |= (chip->data >> i) & 1; } } } if (chip->clk2) { FMOPL2_DoShiftRegisters(chip, 1); } //if (chip->clk2) // opt { int shift = 0; if (chip->fsm_out[13]) shift = 8; else if (chip->fsm_out[12]) shift = 5; else if (chip->fsm_out[15]) shift = 2; chip->block = 0; chip->fnum = 0; for (i = 0; i < 3; i++) chip->block |= ((chip->ch_block[i][1] >> shift) & 1) << i; for (i = 0; i < 10; i++) chip->fnum |= ((chip->ch_fnum[i][1] >> shift) & 1) << i; chip->keyon = (chip->ch_keyon[1] >> shift) & 1; chip->connect = (chip->ch_connect[1] >> shift) & 1; chip->fb = 0; if (chip->fsm_out[13]) shift = 5; else if (chip->fsm_out[12]) shift = 2; else if (chip->fsm_out[15]) shift = 8; for (i = 0; i < 3; i++) chip->fb |= ((chip->ch_fb[i][1] >> shift) & 1) << i; chip->multi = 0; chip->tl = 0; chip->ksl = 0; chip->ar = 0; chip->dr = 0; chip->sl = 0; chip->rr = 0; chip->wf = 0; for (i = 0; i < 4; i++) chip->multi |= ((chip->op_multi[i][1] >> 17) & 1) << i; chip->ksr = (chip->op_ksr[1] >> 17) & 1; chip->egt = (chip->op_egt[1] >> 17) & 1; chip->vib = (chip->op_vib[1] >> 17) & 1; chip->am = (chip->op_am[1] >> 17) & 1; for (i = 0; i < 6; i++) chip->tl |= ((chip->op_tl[i][1] >> 17) & 1) << i; for (i = 0; i < 2; i++) chip->ksl |= ((chip->op_ksl[i][1] >> 17) & 1) << i; for (i = 0; i < 4; i++) chip->ar |= ((chip->op_ar[i][1] >> 17) & 1) << i; for (i = 0; i < 4; i++) chip->dr |= ((chip->op_dr[i][1] >> 17) & 1) << i; for (i = 0; i < 4; i++) chip->sl |= ((chip->op_sl[i][1] >> 17) & 1) << i; for (i = 0; i < 4; i++) chip->rr |= ((chip->op_rr[i][1] >> 17) & 1) << i; for (i = 0; i < 2; i++) chip->wf |= ((chip->op_wf[i][1] >> 17) & 1) << i; } if (chip->clk1) { chip->connect_l[0] = (chip->connect_l[1] << 1) | chip->connect; chip->fb_l[0][0] = chip->fb; chip->fb_l[1][0] = chip->fb_l[0][1]; } if (chip->clk2) { chip->connect_l[1] = chip->connect_l[0]; chip->fb_l[0][1] = chip->fb_l[0][0]; chip->fb_l[1][1] = chip->fb_l[1][0]; } if (chip->clk1) { chip->eg_load1_l = chip->fsm_out[8]; chip->eg_load2_l = chip->fsm_out[9]; chip->eg_load3_l = chip->eg_subcnt_l[1] && chip->eg_sync_l[1]; } chip->eg_load1 = !chip->eg_load1_l && chip->fsm_out[8]; chip->eg_load2 = !chip->eg_load2_l && chip->fsm_out[9]; chip->eg_load3 = !chip->eg_load3_l && chip->eg_subcnt_l[1] && chip->eg_sync_l[1]; { if (chip->eg_load1) chip->trem_step = chip->am_step; if (chip->eg_load2) chip->trem_out = chip->trem_value[1] & 127; if (chip->clk1) { int bit = chip->trem_value[1] & 1; int reset = chip->reset1 || (chip->reg_test & 128) != 0; int step = ((chip->trem_step || (chip->reg_test & 8) != 0) && (chip->fsm_out[9] || chip->trem_dir[1])) && chip->fsm_out[14]; int carry = chip->fsm_out[14] && chip->trem_carry[1]; bit += step + carry; int of = (chip->trem_out == 0) || (chip->trem_out & 105) == 105; chip->trem_carry[0] = (bit & 2) != 0; chip->trem_value[0] = (chip->trem_value[1] >> 1) & 255; if (!reset) chip->trem_value[0] |= (bit & 1) << 8; chip->trem_of[0] = of; if (reset) chip->trem_dir[0] = 0; else chip->trem_dir[0] = chip->trem_dir[1] ^ (of && !chip->trem_of[1]); } if (chip->clk2) { chip->trem_carry[1] = chip->trem_carry[0]; chip->trem_value[1] = chip->trem_value[0]; chip->trem_of[1] = chip->trem_of[0]; chip->trem_dir[1] = chip->trem_dir[0]; } } { if (chip->eg_load3) { chip->eg_timer_low = chip->eg_timer[1] & 3; chip->eg_shift = 0; if (chip->eg_timer_masked[1] & 0x1555) chip->eg_shift |= 1; if (chip->eg_timer_masked[1] & 0x666) chip->eg_shift |= 2; if (chip->eg_timer_masked[1] & 0x1878) chip->eg_shift |= 4; if (chip->eg_timer_masked[1] & 0x1f80) chip->eg_shift |= 8; } if (chip->clk1) { int bit = chip->eg_timer[1] & 1; int bit2; int carry = chip->eg_carry[1] || (chip->eg_subcnt[1] && chip->eg_sync_l[1]); bit += carry; if (chip->reset1) bit2 = 0; else bit2 = bit & 1; chip->eg_timer[0] = (chip->eg_timer[1] >> 1) & 0x1ffff; chip->eg_timer[0] |= bit2 << 17; chip->eg_carry[0] = (bit & 2) != 0; chip->eg_sync_l[0] = chip->fsm_out[8]; chip->eg_mask[0] = (chip->reset1 || chip->fsm_out[8]) ? 0 : (chip->eg_mask[1] || bit2); chip->eg_timer_masked[0] = (chip->eg_timer_masked[1] >> 1) & 0x1ffff; if (!chip->eg_mask[1]) chip->eg_timer_masked[0] |= bit2 << 17; if (chip->reset1) chip->eg_subcnt[0] = 0; else chip->eg_subcnt[0] = chip->eg_subcnt[1] ^ chip->fsm_out[8]; chip->eg_subcnt_l[0] = chip->eg_subcnt[1]; } if (chip->clk2) { chip->eg_timer[1] = chip->eg_timer[0]; chip->eg_carry[1] = chip->eg_carry[0]; chip->eg_sync_l[1] = chip->eg_sync_l[0]; chip->eg_mask[1] = chip->eg_mask[0]; chip->eg_timer_masked[1] = chip->eg_timer_masked[0]; chip->eg_subcnt[1] = chip->eg_subcnt[0]; chip->eg_subcnt_l[1] = chip->eg_subcnt_l[0]; } } if (chip->clk1) { static const int eg_stephi[4][4] = { { 0, 0, 0, 0 }, { 1, 0, 0, 0 }, { 1, 0, 1, 0 }, { 1, 1, 1, 0 } }; int state = 0; if (chip->eg_state[0][1] & 0x20000) state |= 1; if (chip->eg_state[1][1] & 0x20000) state |= 2; int dokon = state == eg_state_release && chip->keyon_comb; int rate_sel = dokon ? eg_state_attack : state; int rate = 0; int ksr; if (rate_sel == 0) rate |= chip->ar; if (rate_sel == 1) rate |= chip->dr; if (rate_sel == 3 || (rate_sel == 2 && !chip->egt)) rate |= chip->rr; int sl = chip->sl; if (chip->sl == 15) sl |= 16; int ns = chip->reg_notesel ? (chip->fnum & 256) != 0 : (chip->fnum & 512) != 0; if (chip->ksr) ksr = (chip->block << 1) | ns; else ksr = chip->block >> 1; int rate_hi = rate + (ksr >> 2); if (rate_hi & 16) rate_hi = 15; int maxrate = rate_hi == 15; int rate12 = rate_hi == 12; int rate13 = rate_hi == 13; int rate14 = rate_hi == 14; int inclow = 0; if (rate_hi < 12 && rate != 0 && chip->eg_subcnt[1]) { int sum = (rate_hi + chip->eg_shift) & 15; switch (sum) { case 12: inclow = 1; break; case 13: inclow = (ksr & 2) != 0; break; case 14: inclow = (ksr & 1) != 0; break; } } int stephi = eg_stephi[ksr & 3][chip->eg_timer_low]; int step1 = 0; int step2 = 0; int step3 = 0; switch (rate_hi) { case 12: step1 = stephi || chip->eg_subcnt[1]; break; case 13: if (stephi) step2 = 1; else step1 = 1; break; case 14: if (stephi) step3 = 1; else step2 = 1; break; case 15: step3 = 1; break; } step1 |= inclow; int level = 0; for (i = 0; i < 9; i++) { level |= ((chip->eg_level[i][1] >> 17) & 1) << i; } int slreach = (level >> 4) == sl; int zeroreach = level == 0; int silent = (level & 0x1f8) == 0x1f8; int nextstate = eg_state_attack; if (chip->reset1) nextstate = eg_state_release; else if (dokon) nextstate = eg_state_attack; else { if (!chip->keyon_comb) nextstate = eg_state_release; else if (state == eg_state_attack) nextstate = zeroreach ? eg_state_decay : eg_state_attack; else if (state == eg_state_decay) nextstate = slreach ? eg_state_sustain : eg_state_decay; else if (state == eg_state_sustain) nextstate = eg_state_sustain; else if (state == eg_state_release) nextstate = eg_state_release; } int linear = !dokon && !silent && ((state & 2) != 0 || (state == eg_state_decay && !slreach)); int exponent = state == eg_state_attack && chip->keyon_comb && !maxrate && !zeroreach; int instantattack = dokon && maxrate; int mute = chip->reset1 || (state != eg_state_attack && silent && !dokon); int level2 = mute ? 0x1ff : (instantattack ? 0 : level); int add = 0; int addshift = 0; if (exponent) add |= (~level) >> 1; if (linear) add |= 4; if (step1) addshift |= add >> 2; if (step2) addshift |= add >> 1; if (step3) addshift |= add >> 0; int levelnext = level2 + addshift; static const int eg_ksltable[16] = { 0, 32, 40, 45, 48, 51, 53, 55, 56, 58, 59, 60, 61, 62, 63, 64 }; int ksl; ksl = eg_ksltable[chip->fnum >> 6] ^ 127; ksl += ((chip->block ^ 7) + 1) << 3; if (ksl & 128) ksl = 0; else ksl = (ksl ^ 63) & 63; static int eg_kslshift[4] = { 31, 1, 2, 0 }; ksl = (ksl << 2) >> eg_kslshift[chip->ksl]; int ksltl = ksl + (chip->tl << 2); int tremolo; if (!chip->am) tremolo = 0; else if (chip->reg_dv) tremolo = chip->trem_out >> 2; else tremolo = chip->trem_out >> 4; int ksltltrem = ksltl + tremolo; int levelof = 0; if (ksltltrem & 0x200) levelof = 1; int totallevel = level + (ksltltrem & 0x1ff); if (totallevel & 0x200) levelof = 1; int totallevelclamp = (chip->reg_test & 1) != 0 ? 0 : (levelof ? 0x1ff : (totallevel & 0x1ff)); chip->eg_dokon = dokon; chip->eg_state[0][0] = (chip->eg_state[0][1] << 1) | ((nextstate & 1) != 0); chip->eg_state[1][0] = (chip->eg_state[1][1] << 1) | ((nextstate & 2) != 0); for (i = 0; i < 9; i++) { chip->eg_level[i][0] = (chip->eg_level[i][1] << 1) | ((levelnext >> i) & 1); } chip->eg_out[0] = totallevelclamp; if (chip->fsm_out[9]) { for (i = 0; i < 9; i++) { if (chip->eg_out[1] & (1 << i)) chip->dbg_serial[0] |= 1 << (17 - i); } } chip->eg_mute[0] = (chip->eg_mute[1] << 1) | mute; } if (chip->clk2) { chip->eg_state[0][1] = chip->eg_state[0][0]; chip->eg_state[1][1] = chip->eg_state[1][0]; for (i = 0; i < 9; i++) { chip->eg_level[i][1] = chip->eg_level[i][0]; } chip->eg_out[1] = chip->eg_out[0]; chip->eg_mute[1] = chip->eg_mute[0]; } if (chip->clk1) { static const int pg_multi[16] = { 1, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 20, 24, 24, 30, 30 }; int fnum = chip->fnum; int freq; int pg_add; int vib_sel1 = (chip->vib_cnt[1] & 3) == 2; int vib_sel2 = (chip->vib_cnt[1] & 1) == 1; int vib_sh0 = chip->reg_dv && chip->vib && vib_sel1; int vib_sh1 = (chip->reg_dv && chip->vib && vib_sel2) || (!chip->reg_dv && chip->vib && vib_sel1); int vib_sh2 = !chip->reg_dv && chip->vib && vib_sel2; int vib_sign = (chip->vib_cnt[1] & 4) != 0 && chip->vib; int vib_add = 0; int pg_out = 0; int phase; int noise_bit; if (vib_sh0) vib_add |= (chip->fnum >> 7) & 7; if (vib_sh1) vib_add |= (chip->fnum >> 8) & 3; if (vib_sh2) vib_add |= (chip->fnum >> 9) & 1; if (vib_sign) { vib_add ^= 1023; } fnum += vib_add; fnum += vib_sign; if (vib_sign) fnum &= 1023; freq = (fnum << chip->block) >> 1; pg_add = (freq * pg_multi[chip->multi]) >> 1; for (i = 0; i < 19; i++) { pg_out |= ((chip->pg_phase[i][1] >> 17) & 1) << i; } phase = ((chip->eg_dokon || (chip->reg_test & 4) != 0) ? 0 : pg_out) + pg_add; for (i = 0; i < 19; i++) { chip->pg_phase[i][0] = chip->pg_phase[i][1] << 1; chip->pg_phase[i][0] |= (phase >> i) & 1; } chip->dbg_serial[0] = chip->dbg_serial[1] >> 1; if (chip->fsm_out[9]) { chip->dbg_serial[0] |= pg_out & 511; } noise_bit = ((chip->noise_lfsr[1] >> 22) ^ (chip->noise_lfsr[1] >> 8)) & 1; if ((chip->noise_lfsr[1] & 0x7fffff) == 0) noise_bit |= 1; noise_bit |= (chip->reg_test & 128) != 0; chip->noise_lfsr[0] = (chip->noise_lfsr[1] << 1) | noise_bit; } if (chip->clk2) { for (i = 0; i < 19; i++) { chip->pg_phase[i][1] = chip->pg_phase[i][0]; } chip->noise_lfsr[1] = chip->noise_lfsr[0]; chip->pg_out = 0; for (i = 0; i < 10; i++) { chip->pg_out |= ((chip->pg_phase[i+9][1] >> 17) & 1) << i; } chip->dbg_serial[1] = chip->dbg_serial[0]; } { int hh = chip->fsm_out[4] && chip->rhythm; int sd = chip->fsm_out[7] && chip->rhythm; int tc = chip->fsm_out[8] && chip->rhythm; int rhy = (chip->fsm_out[4] || chip->fsm_out[7] || chip->fsm_out[8]) && chip->rhythm; if (chip->clk1) chip->hh_load = chip->fsm_out[4]; if (!chip->hh_load && chip->fsm_out[5]) { chip->hh_bit2 = (chip->pg_out >> 2) & 1; chip->hh_bit3 = (chip->pg_out >> 3) & 1; chip->hh_bit7 = (chip->pg_out >> 7) & 1; chip->hh_bit8 = (chip->pg_out >> 8) & 1; } if (chip->clk1) chip->tc_load = tc; if (!chip->tc_load && tc) { chip->tc_bit3 = (chip->pg_out >> 3) & 1; chip->tc_bit5 = (chip->pg_out >> 5) & 1; } if (chip->clk1) // opt { int rm_bit; int noise = (chip->noise_lfsr[1] >> 22) & 1; rm_bit = (chip->hh_bit2 ^ chip->hh_bit7) | (chip->tc_bit5 ^ chip->hh_bit3) | (chip->tc_bit5 ^ chip->tc_bit3); chip->pg_out_rhy = 0; if (!rhy) chip->pg_out_rhy |= chip->pg_out; if (hh) { chip->pg_out_rhy |= rm_bit << 9; if (noise ^ rm_bit) chip->pg_out_rhy |= 0xd0; else chip->pg_out_rhy |= 0x34; } if (sd) chip->pg_out_rhy |= (chip->hh_bit8 << 9) | ((noise ^ chip->hh_bit8) << 8); if (tc) chip->pg_out_rhy |= (rm_bit << 9) | 0x100; } } { if (chip->clk1) { static const int logsin[128] = { 0x6c3, 0x58b, 0x4e4, 0x471, 0x41a, 0x3d3, 0x398, 0x365, 0x339, 0x311, 0x2ed, 0x2cd, 0x2af, 0x293, 0x279, 0x261, 0x24b, 0x236, 0x222, 0x20f, 0x1fd, 0x1ec, 0x1dc, 0x1cd, 0x1be, 0x1b0, 0x1a2, 0x195, 0x188, 0x17c, 0x171, 0x166, 0x15b, 0x150, 0x146, 0x13c, 0x133, 0x129, 0x121, 0x118, 0x10f, 0x107, 0x0ff, 0x0f8, 0x0f0, 0x0e9, 0x0e2, 0x0db, 0x0d4, 0x0cd, 0x0c7, 0x0c1, 0x0bb, 0x0b5, 0x0af, 0x0a9, 0x0a4, 0x09f, 0x099, 0x094, 0x08f, 0x08a, 0x086, 0x081, 0x07d, 0x078, 0x074, 0x070, 0x06c, 0x068, 0x064, 0x060, 0x05c, 0x059, 0x055, 0x052, 0x04e, 0x04b, 0x048, 0x045, 0x042, 0x03f, 0x03c, 0x039, 0x037, 0x034, 0x031, 0x02f, 0x02d, 0x02a, 0x028, 0x026, 0x024, 0x022, 0x020, 0x01e, 0x01c, 0x01a, 0x018, 0x017, 0x015, 0x014, 0x012, 0x011, 0x00f, 0x00e, 0x00d, 0x00c, 0x00a, 0x009, 0x008, 0x007, 0x007, 0x006, 0x005, 0x004, 0x004, 0x003, 0x002, 0x002, 0x001, 0x001, 0x001, 0x001, 0x000, 0x000, 0x000, 0x000 }; static const int logsin_d[128] = { 0x196, 0x07c, 0x04a, 0x035, 0x029, 0x022, 0x01d, 0x019, 0x015, 0x013, 0x012, 0x00f, 0x00e, 0x00d, 0x00d, 0x00c, 0x00b, 0x00a, 0x00a, 0x009, 0x009, 0x009, 0x008, 0x007, 0x007, 0x007, 0x007, 0x006, 0x007, 0x006, 0x006, 0x005, 0x005, 0x005, 0x005, 0x005, 0x004, 0x005, 0x004, 0x004, 0x005, 0x004, 0x004, 0x003, 0x004, 0x003, 0x003, 0x003, 0x003, 0x004, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x002, 0x003, 0x003, 0x003, 0x003, 0x002, 0x002, 0x002, 0x002, 0x002, 0x002, 0x002, 0x002, 0x002, 0x002, 0x002, 0x002, 0x002, 0x001, 0x002, 0x002, 0x002, 0x001, 0x001, 0x001, 0x002, 0x002, 0x001, 0x001, 0x002, 0x001, 0x001, 0x001, 0x001, 0x001, 0x001, 0x001, 0x001, 0x001, 0x001, 0x001, 0x001, 0x000, 0x001, 0x000, 0x001, 0x000, 0x001, 0x001, 0x000, 0x000, 0x001, 0x001, 0x001, 0x001, 0x000, 0x000, 0x000, 0x001, 0x000, 0x000, 0x001, 0x000, 0x001, 0x000, 0x000, 0x000, 0x000, 0x000, 0x000, 0x000 }; static const int pow[128] = { 0x3f5, 0x3ea, 0x3df, 0x3d4, 0x3c9, 0x3bf, 0x3b4, 0x3a9, 0x39f, 0x394, 0x38a, 0x37f, 0x375, 0x36a, 0x360, 0x356, 0x34c, 0x342, 0x338, 0x32e, 0x324, 0x31a, 0x310, 0x306, 0x2fd, 0x2f3, 0x2e9, 0x2e0, 0x2d6, 0x2cd, 0x2c4, 0x2ba, 0x2b1, 0x2a8, 0x29e, 0x295, 0x28c, 0x283, 0x27a, 0x271, 0x268, 0x25f, 0x257, 0x24e, 0x245, 0x23c, 0x234, 0x22b, 0x223, 0x21a, 0x212, 0x209, 0x201, 0x1f9, 0x1f0, 0x1e8, 0x1e0, 0x1d8, 0x1d0, 0x1c8, 0x1c0, 0x1b8, 0x1b0, 0x1a8, 0x1a0, 0x199, 0x191, 0x189, 0x181, 0x17a, 0x172, 0x16b, 0x163, 0x15c, 0x154, 0x14d, 0x146, 0x13e, 0x137, 0x130, 0x129, 0x122, 0x11b, 0x114, 0x10c, 0x106, 0x0ff, 0x0f8, 0x0f1, 0x0ea, 0x0e3, 0x0dc, 0x0d6, 0x0cf, 0x0c8, 0x0c2, 0x0bb, 0x0b5, 0x0ae, 0x0a8, 0x0a1, 0x09b, 0x094, 0x08e, 0x088, 0x082, 0x07b, 0x075, 0x06f, 0x069, 0x063, 0x05d, 0x057, 0x051, 0x04b, 0x045, 0x03f, 0x039, 0x033, 0x02d, 0x028, 0x022, 0x01c, 0x016, 0x011, 0x00b, 0x006, 0x000, }; static const int pow_d[128] = { 0x005, 0x005, 0x005, 0x006, 0x006, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x006, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x004, 0x005, 0x004, 0x004, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x005, 0x004, 0x004, 0x004, 0x005, 0x004, 0x005, 0x004, 0x004, 0x004, 0x005, 0x004, 0x004, 0x005, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x003, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x004, 0x003, 0x004, 0x004, 0x004, 0x003, 0x003, 0x003, 0x003, 0x004, 0x003, 0x003, 0x003, 0x003, 0x003, 0x004, 0x004, 0x003, 0x003, 0x004, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x004, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x003, 0x002, 0x003, 0x003, 0x003, 0x003, 0x003, 0x002, 0x003, }; int phase = chip->pg_out_rhy + chip->op_mod[1]; int sign = (phase & 512) != 0; int quarter = (phase & 256) != 0; phase &= 255; if (quarter) phase ^= 255; int ls = logsin[phase >> 1]; if ((phase & 1) == 0) ls += logsin_d[phase >> 1]; int att = chip->op_logsin[1] + (chip->eg_out[1] << 3); if (att & 4096) att = 4095; int pw = pow[(att >> 1) & 127]; if ((att & 1) == 0) pw += pow_d[(att >> 1) & 127]; int value = 0; if (chip->op_mute[1] & 2) { value = ((chip->op_pow[1] | 0x400) << 1) >> chip->op_shift[1]; } if (chip->op_sign[1] & 2) value ^= 8191; int sign_wf = sign && chip->wf == 0; int mute_wf = !((chip->wf == 1 && sign) || (chip->wf == 3 && quarter)); int fb1 = 0; int fb2 = 0; for (i = 0; i < 14; i++) { int j = i; if (i == 13) j = 12; fb1 |= ((chip->op_fb[0][j][1] >> 5) & 1) << i; fb2 |= ((chip->op_fb[1][j][1] >> 5) & 1) << i; } int fb_sum = fb1 + fb2; fb_sum &= 16383; if (fb_sum & 8192) fb_sum |= ~8191; int mod = 0; if (chip->fsm_out[2] && !(chip->connect_l[1] & 2)) mod |= value & 1023; if (chip->fsm_out[1]) { if (chip->fb_l[1][1]) { mod |= (fb_sum >> (9 - chip->fb_l[1][1])) & 1023; } } chip->op_logsin[0] = ls; chip->op_shift[0] = (att >> 8) & 15; chip->op_pow[0] = pw; chip->op_mute[0] = (chip->op_mute[1] << 1) | mute_wf; chip->op_sign[0] = (chip->op_sign[1] << 1) | sign_wf; for (i = 0; i < 13; i++) { int bit; chip->op_fb[0][i][0] = chip->op_fb[0][i][1] << 1; if (chip->fsm_out[2]) bit = (value >> i) & 1; else bit = (chip->op_fb[0][i][1] >> 8) & 1; chip->op_fb[0][i][0] |= bit; chip->op_fb[1][i][0] = chip->op_fb[1][i][1] << 1; if (chip->fsm_out[2]) bit = (chip->op_fb[0][i][1] >> 8) & 1; else bit = (chip->op_fb[1][i][1] >> 8) & 1; chip->op_fb[1][i][0] |= bit; } chip->op_mod[0] = mod & 1023; chip->op_value = value; } if (chip->clk2) { chip->op_logsin[1] = chip->op_logsin[0]; chip->op_shift[1] = chip->op_shift[0]; chip->op_pow[1] = chip->op_pow[0]; chip->op_mute[1] = chip->op_mute[0]; chip->op_sign[1] = chip->op_sign[0]; for (i = 0; i < 13; i++) { chip->op_fb[0][i][1] = chip->op_fb[0][i][0]; chip->op_fb[1][i][1] = chip->op_fb[1][i][0]; } chip->op_mod[1] = chip->op_mod[0]; } } { int accm_out = chip->fsm_out[8] ? (chip->accm_value[1] & 0x7fff) : 0; if (chip->fsm_out[8] && !(chip->accm_value[1] & 0x20000)) accm_out |= 0x8000; int top = (chip->accm_value[1] >> 15) & 7; int clamplow = top == 4 || top == 5 || top == 6; int clamphigh = top == 3 || top == 2 || top == 1; if (chip->clk1) chip->accm_load1_l = chip->fsm_out[8]; chip->accm_load1 = !chip->accm_load1_l && chip->fsm_out[8]; if (chip->accm_load1) { chip->accm_clamplow = clamplow; chip->accm_clamphigh = clamphigh; chip->accm_top = (accm_out >> 9) & 127; } if (chip->clk1) { int add = 0; int op_out = chip->op_value; if (op_out & 0x1000) op_out |= ~0xfff; if (!(chip->eg_mute[1] & 2) && chip->fsm_out[0]) add = chip->fsm_out[11] ? (op_out * 2) : op_out; int value = chip->fsm_out[8] ? 0 : chip->accm_value[1]; value += add; chip->op_value_debug = add; int sign = ((chip->accm_top & 64) != 0 && !chip->accm_clamplow) || chip->accm_clamphigh; int top_unsigned = chip->accm_top & 63; if (!sign) top_unsigned ^= 63; int shift = 0; if (top_unsigned & 32) shift |= 7; if ((top_unsigned & 48) == 16) shift |= 6; if ((top_unsigned & 56) == 8) shift |= 5; if ((top_unsigned & 60) == 4) shift |= 4; if ((top_unsigned & 62) == 2) shift |= 3; if (top_unsigned == 1) shift |= 2; if (top_unsigned == 0) shift |= 1; if (chip->accm_clamplow) shift |= 7; if (chip->accm_clamphigh) shift |= 7; int accm_bit = 0; if (chip->fsm_out[6]) accm_bit |= sign; if (chip->accm_sel[1] & 1) accm_bit |= (shift & 1) != 0; if (chip->accm_sel[1] & 2) accm_bit |= (shift & 2) != 0; if (chip->accm_sel[1] & 4) accm_bit |= (shift & 4) != 0; if ((chip->accm_sel[1] & 7) == 0 && !chip->fsm_out[6]) { if (top_unsigned & 32) accm_bit |= (chip->accm_shifter[1] >> 6) & 1; if ((top_unsigned & 48) == 16) accm_bit |= (chip->accm_shifter[1] >> 5) & 1; if ((top_unsigned & 56) == 8) accm_bit |= (chip->accm_shifter[1] >> 4) & 1; if ((top_unsigned & 60) == 4) accm_bit |= (chip->accm_shifter[1] >> 3) & 1; if ((top_unsigned & 62) == 2) accm_bit |= (chip->accm_shifter[1] >> 2) & 1; if (top_unsigned == 1) accm_bit |= (chip->accm_shifter[1] >> 1) & 1; if (top_unsigned == 0) accm_bit |= chip->accm_shifter[1] & 1; if (chip->accm_clamphigh) accm_bit |= 1; if (chip->accm_clamplow) accm_bit = 0; } chip->accm_value[0] = value & 0x3ffff; chip->accm_shifter[0] = (chip->accm_shifter[1] >> 1) & 0x7fff; if (chip->fsm_out[8]) chip->accm_shifter[0] |= accm_out; chip->accm_sel[0] = (chip->accm_sel[1] << 1) | chip->fsm_out[6]; chip->accm_mo[0] = accm_bit; } if (chip->clk2) { chip->accm_value[1] = chip->accm_value[0]; chip->accm_shifter[1] = chip->accm_shifter[0]; chip->accm_sel[1] = chip->accm_sel[0]; chip->accm_mo[1] = chip->accm_mo[0]; } } end: chip->o_sh = chip->fsm_out[3]; chip->o_mo = chip->accm_mo[1]; chip->o_irq_pull = irq; chip->o_sy = chip->clk1; if (chip->io_read0) { chip->io_data &= ~6; if (chip->reg_test & 64) chip->io_data |= chip->dbg_serial[1] & 1; if (irq) chip->io_data |= 128; if (chip->t1_status) chip->io_data |= 64; if (chip->t2_status) chip->io_data |= 32; if (chip->unk_status1) chip->io_data |= 16; if (chip->unk_status2) chip->io_data |= 8; } if (chip->io_dir) { chip->data_o = chip->io_data; chip->data_z = 0; } else chip->data_z = 1; }