furnace/extern/YMF276-LLE/fmopn2.h

/*
 * Copyright (C) 2022-2023 nukeykt
 *
 * This file is part of YMF276-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.
 *
 *  YMF276/YM3438 emulator.
 *  Thanks:
 *      John McMaster (siliconpr0n.org):
 *          Yamaha YM3438 & YM2610 decap and die shot.
 *      org, andkorzh, HardWareMan (emu-russia):
 *          help & support, YMF276 and YM2612 decap.
 *
 */

#pragma once
#include <stdint.h>

enum {
    fmopn2_flags_ym3438 = 1,
};

typedef struct {
    int phi;
    int ic;
} fmopn2_prescaler_input_t;

typedef struct {
    int phi_phase;
    int ic;
    int rd;
    int wr;
    int cs;
    int address;
    int data;
    int test;
    int i_fsm_reset; // (chip->ic_check_latch[1] & 16) != 0;
} fmopn2_input_t;

typedef struct {
    int flags;
    // input
    fmopn2_input_t input_old, input;
    int i_phi1;
    int i_phi2;

    fmopn2_prescaler_input_t pinput, pinput_old;

    // clock
    int ic_latch[2]; // 12
    int ic_check_latch[2]; // 4
    int prescaler_latch[2]; // 6
    int phi1_latch[2];
    int phi2_latch[2];
    int dphi1_latch[4];
    int dphi2_latch[3];
    int dclk1;
    int dclk2;
    int fsm_reset;

    // output
    int dac_val;
    int out_l;
    int out_r;

    // io
    int write_addr_trig;
    int write_addr_trig_sync;
    int write_addr_dlatch;
    int write_addr_sr[2];
    int write_data_trig;
    int write_data_trig_sync;
    int write_data_dlatch;
    int write_data_sr[2];

    int data_latch;
    int bank_latch;

    int busy_cnt[2];
    int busy_latch[2];

    int io_ic_latch[2];

    int write_fm_address[2];
    int fm_address[2];
    int write_fm_data[2];
    int fm_data[2];
    int status_timer_a_dlatch;
    int status_timer_b_dlatch;

    // mode registers
    int write_mode_21[2];
    int write_mode_22[2];
    int write_mode_24[2];
    int write_mode_25[2];
    int write_mode_26[2];
    int write_mode_27[2];
    int write_mode_28[2];
    int write_mode_2a[2];
    int write_mode_2b[2];
    int write_mode_2c[2];

    int mode_test_21[2];
    int mode_lfo_en[2];
    int mode_lfo_freq[2];
    int mode_timer_a_reg[2];
    int mode_timer_b_reg[2];
    int mode_ch3[2];
    int mode_timer_a_load[2];
    int mode_timer_a_enable[2];
    int mode_timer_a_reset[2];
    int mode_timer_b_load[2];
    int mode_timer_b_enable[2];
    int mode_timer_b_reset[2];
    int mode_kon_operator[2];
    int mode_kon_channel[2];
    int mode_dac_data[2];
    int mode_dac_en[2];
    int mode_test_2c[2];

    int mode_kon[4][2];

    // operator registers
    int slot_multi[2][4][2];
    int slot_dt[2][3][2];
    int slot_tl[2][7][2];
    int slot_ar[2][5][2];
    int slot_ks[2][2][2];
    int slot_dr[2][5][2];
    int slot_am[2][1][2];
    int slot_sr[2][5][2];
    int slot_rr[2][4][2];
    int slot_sl[2][4][2];
    int slot_ssg_eg[2][4][2];
    // channel registers
    int chan_fnum[11][2];
    int chan_fnum_ch3[11][2];
    int chan_block[3][2];
    int chan_block_ch3[3][2];
    int chan_a4[2];
    int chan_ac[2];
    int chan_connect[3][2];
    int chan_fb[3][2];
    int chan_pms[3][2];
    int chan_ams[2][2];
    int chan_pan[2][2];

    int reg_cnt1[2];
    int reg_cnt2[2];

    // lfo

    int lfo_cnt1[2];
    int lfo_cnt2[2];

    int lfo_dlatch;
    int lfo_dlatch_load;
    int lfo_inc_latch[2];

    // pg
    int pg_fnum[2][2];
    int pg_kcode[2][2];
    int pg_fnum_lfo1;
    int pg_fnum_lfo2;
    int pg_lfo_shift;
    int pg_lfo_sign;
    int pg_lfo;
    int pg_freq1;
    int pg_freq2;
    int pg_freq3;
    int pg_freq4;
    int pg_freq5[2];
    int pg_freq6;
    int pg_freq_m1;
    int pg_block;
    int pg_dt[2];
    int pg_detune[2];
    int pg_multi[2][2];
    int pg_multi2;
    int pg_inc[2];
    int pg_inc_mask[2];
    int pg_phase[20][2];
    int pg_reset_latch[2];
    int pg_debug[2];
    int pg_reset[2];

    // eg
    int eg_prescaler[2];
    int eg_prescaler_clock_l[2];
    int eg_prescaler_l;
    int eg_clock_delay[2];
    int eg_step[2];
    int eg_timer_load;
    int eg_timer[2];
    int eg_timer_carry[2];
    int eg_timer_mask[2];
    int eg_timer_masked[2];
    int eg_timer_low_lock;
    int eg_shift_lock;
    int eg_level[10][2];
    int eg_level_latch[2];
    int eg_level_latch_inv;
    int eg_state[2][2];
    int eg_ssg_dir[2];
    int eg_ssg_inv[2];
    int eg_ssg_holdup[2];
    int eg_ssg_enable[2];
    int eg_ssg_pgreset[2];
    int eg_ssg_pgrepeat[2];
    int eg_key[2];
    int eg_rate_nonzero[2];
    int eg_rate;
    int eg_ksv;
    int eg_rate2;
    int eg_inc1;
    int eg_inc2;
    int eg_rate12;
    int eg_rate13;
    int eg_rate14;
    int eg_rate15;
    int eg_maxrate[2];
    int eg_incsh0;
    int eg_incsh1;
    int eg_incsh2;
    int eg_incsh3;
    int eg_incsh_nonzero[2];
    int eg_inc_total;
    int eg_level_ssg[2];
    int eg_sl[2][2];
    int eg_nextlevel[2];
    int eg_kon_csm[2];
    int eg_kon_latch[2];
    int eg_tl[2][2];
    int eg_ams;
    int eg_lfo[2];
    int eg_ch3_latch[2];
    int eg_out;
    int eg_out_tl;
    int eg_out_total;
    int eg_debug[2];

    // op
    int op_mod[10][2];
    int op_phase[2];
    int op_logsin_base[2];
    int op_logsin_delta[2];
    int op_logsin_add_delta[2];
    int op_atten[2];
    int op_env[2];
    int op_pow_base[2];
    int op_pow_delta[2];
    int op_pow_add_delta[2];
    int op_shift[2];
    int op_sign[2];
    int op_output[2];
    int op_op1[2][14][2];
    int op_op2[14][2];
    int op_mod_sum[2];
    int op_dofeedback[2];

    // accumulator

    int ch_accm[14][2];
    int ch_out[9][2];
    int ch_out_dlatch;
    int ch_out_pan_dlatch;
    int ch_dac_load;
    int ch_out_debug[2];
    int ch_accm_l[2];
    int ch_accm_r[2];

    // timers
    int timer_dlatch;
    int timer_a_cnt[2];
    int timer_a_load_latch[2];
    int timer_a_load_old[2];
    int timer_a_load_dlatch;
    int timer_a_of[2];
    int timer_a_status[2];
    int timer_b_subcnt[2];
    int timer_b_subcnt_of[2];
    int timer_b_cnt[2];
    int timer_b_load_latch[2];
    int timer_b_load_old[2];
    int timer_b_load_dlatch;
    int timer_b_of[2];
    int timer_b_status[2];
    int timer_csm_key_dlatch;

    // fm algorithm
    int alg_mod_op1_0;
    int alg_mod_op1_1;
    int alg_mod_op2;
    int alg_mod_prev_0;
    int alg_mod_prev_1;
    int alg_output;
    int alg_mod_op1_0_l;
    int alg_mod_op1_1_l;
    int alg_mod_op2_l;
    int alg_mod_prev_0_l;
    int alg_mod_prev_1_l;
    int alg_output_l;

    // fsm
    int fsm_cnt1[2];
    int fsm_cnt2[2];
    // fsm table output
    int fsm_clock_eg;
    int fsm_clock_timers1;
    int fsm_clock_timers;
    int fsm_op4_sel;
    int fsm_op1_sel;
    int fsm_op2_sel;
    int fsm_op3_sel;
    int fsm_sel2;
    int fsm_sel23;
    int fsm_ch3_sel;
    int fsm_dac_load;
    int fsm_dac_out_sel;
    int fsm_dac_ch6;

    // ymf276
    int fsm_clock_eg_l;
    int fsm_op1_sel_l;
    int fsm_sel1_l;
    int fsm_sel2_l;
    int fsm_sel23_l;
    int fsm_ch3_sel_l;
    int fsm_dac_load_l;
    int fsm_dac_out_sel_l;
    int fsm_dac_ch6_l;
    int fsm_lro_l[2];
    int fsm_wco_l[2];
    int fsm_lro_l2[2];
    int fsm_wco_l2[2];
    int fsm_op1_sel_l2[2];
    int fsm_op1_sel_l3[2];
    int fsm_shifter_ctrl[2];
    int fsm_load_l;
    int fsm_load_r;

    int dac_shifter[2];
    int dac_so_l[2];
    int o_bco;
    int o_wco;
    int o_lro;
    int o_so;
} fmopn2_t;


int FMOPN2_ReadStatus(fmopn2_t *chip);

void FMOPN2_Clock(fmopn2_t *chip, int phi);
the final challenge 2023-11-25 22:46:46 +00:00			`/*`
			`* Copyright (C) 2022-2023 nukeykt`
			`*`
			`* This file is part of YMF276-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.`
			`*`
			`* YMF276/YM3438 emulator.`
			`* Thanks:`
			`* John McMaster (siliconpr0n.org):`
			`* Yamaha YM3438 & YM2610 decap and die shot.`
			`* org, andkorzh, HardWareMan (emu-russia):`
			`* help & support, YMF276 and YM2612 decap.`
			`*`
			`*/`

			`#pragma once`
			`#include <stdint.h>`

			`enum {`
			`fmopn2_flags_ym3438 = 1,`
			`};`

			`typedef struct {`
			`int phi;`
			`int ic;`
			`} fmopn2_prescaler_input_t;`

			`typedef struct {`
			`int phi_phase;`
			`int ic;`
			`int rd;`
			`int wr;`
			`int cs;`
			`int address;`
			`int data;`
			`int test;`
			`int i_fsm_reset; // (chip->ic_check_latch[1] & 16) != 0;`
			`} fmopn2_input_t;`

			`typedef struct {`
			`int flags;`
			`// input`
			`fmopn2_input_t input_old, input;`
			`int i_phi1;`
			`int i_phi2;`

			`fmopn2_prescaler_input_t pinput, pinput_old;`

			`// clock`
			`int ic_latch[2]; // 12`
			`int ic_check_latch[2]; // 4`
			`int prescaler_latch[2]; // 6`
			`int phi1_latch[2];`
			`int phi2_latch[2];`
			`int dphi1_latch[4];`
			`int dphi2_latch[3];`
			`int dclk1;`
			`int dclk2;`
			`int fsm_reset;`

			`// output`
			`int dac_val;`
			`int out_l;`
			`int out_r;`

			`// io`
			`int write_addr_trig;`
			`int write_addr_trig_sync;`
			`int write_addr_dlatch;`
			`int write_addr_sr[2];`
			`int write_data_trig;`
			`int write_data_trig_sync;`
			`int write_data_dlatch;`
			`int write_data_sr[2];`

			`int data_latch;`
			`int bank_latch;`

			`int busy_cnt[2];`
			`int busy_latch[2];`

			`int io_ic_latch[2];`

			`int write_fm_address[2];`
			`int fm_address[2];`
			`int write_fm_data[2];`
			`int fm_data[2];`
			`int status_timer_a_dlatch;`
			`int status_timer_b_dlatch;`

			`// mode registers`
			`int write_mode_21[2];`
			`int write_mode_22[2];`
			`int write_mode_24[2];`
			`int write_mode_25[2];`
			`int write_mode_26[2];`
			`int write_mode_27[2];`
			`int write_mode_28[2];`
			`int write_mode_2a[2];`
			`int write_mode_2b[2];`
			`int write_mode_2c[2];`

			`int mode_test_21[2];`
			`int mode_lfo_en[2];`
			`int mode_lfo_freq[2];`
			`int mode_timer_a_reg[2];`
			`int mode_timer_b_reg[2];`
			`int mode_ch3[2];`
			`int mode_timer_a_load[2];`
			`int mode_timer_a_enable[2];`
			`int mode_timer_a_reset[2];`
			`int mode_timer_b_load[2];`
			`int mode_timer_b_enable[2];`
			`int mode_timer_b_reset[2];`
			`int mode_kon_operator[2];`
			`int mode_kon_channel[2];`
			`int mode_dac_data[2];`
			`int mode_dac_en[2];`
			`int mode_test_2c[2];`

			`int mode_kon[4][2];`

			`// operator registers`
			`int slot_multi[2][4][2];`
			`int slot_dt[2][3][2];`
			`int slot_tl[2][7][2];`
			`int slot_ar[2][5][2];`
			`int slot_ks[2][2][2];`
			`int slot_dr[2][5][2];`
			`int slot_am[2][1][2];`
			`int slot_sr[2][5][2];`
			`int slot_rr[2][4][2];`
			`int slot_sl[2][4][2];`
			`int slot_ssg_eg[2][4][2];`
			`// channel registers`
			`int chan_fnum[11][2];`
			`int chan_fnum_ch3[11][2];`
			`int chan_block[3][2];`
			`int chan_block_ch3[3][2];`
			`int chan_a4[2];`
			`int chan_ac[2];`
			`int chan_connect[3][2];`
			`int chan_fb[3][2];`
			`int chan_pms[3][2];`
			`int chan_ams[2][2];`
			`int chan_pan[2][2];`

			`int reg_cnt1[2];`
			`int reg_cnt2[2];`

			`// lfo`

			`int lfo_cnt1[2];`
			`int lfo_cnt2[2];`

			`int lfo_dlatch;`
			`int lfo_dlatch_load;`
			`int lfo_inc_latch[2];`

			`// pg`
			`int pg_fnum[2][2];`
			`int pg_kcode[2][2];`
			`int pg_fnum_lfo1;`
			`int pg_fnum_lfo2;`
			`int pg_lfo_shift;`
			`int pg_lfo_sign;`
			`int pg_lfo;`
			`int pg_freq1;`
			`int pg_freq2;`
			`int pg_freq3;`
			`int pg_freq4;`
			`int pg_freq5[2];`
			`int pg_freq6;`
			`int pg_freq_m1;`
			`int pg_block;`
			`int pg_dt[2];`
			`int pg_detune[2];`
			`int pg_multi[2][2];`
			`int pg_multi2;`
			`int pg_inc[2];`
			`int pg_inc_mask[2];`
			`int pg_phase[20][2];`
			`int pg_reset_latch[2];`
			`int pg_debug[2];`
			`int pg_reset[2];`

			`// eg`
			`int eg_prescaler[2];`
			`int eg_prescaler_clock_l[2];`
			`int eg_prescaler_l;`
			`int eg_clock_delay[2];`
			`int eg_step[2];`
			`int eg_timer_load;`
			`int eg_timer[2];`
			`int eg_timer_carry[2];`
			`int eg_timer_mask[2];`
			`int eg_timer_masked[2];`
			`int eg_timer_low_lock;`
			`int eg_shift_lock;`
			`int eg_level[10][2];`
			`int eg_level_latch[2];`
			`int eg_level_latch_inv;`
			`int eg_state[2][2];`
			`int eg_ssg_dir[2];`
			`int eg_ssg_inv[2];`
			`int eg_ssg_holdup[2];`
			`int eg_ssg_enable[2];`
			`int eg_ssg_pgreset[2];`
			`int eg_ssg_pgrepeat[2];`
			`int eg_key[2];`
			`int eg_rate_nonzero[2];`
			`int eg_rate;`
			`int eg_ksv;`
			`int eg_rate2;`
			`int eg_inc1;`
			`int eg_inc2;`
			`int eg_rate12;`
			`int eg_rate13;`
			`int eg_rate14;`
			`int eg_rate15;`
			`int eg_maxrate[2];`
			`int eg_incsh0;`
			`int eg_incsh1;`
			`int eg_incsh2;`
			`int eg_incsh3;`
			`int eg_incsh_nonzero[2];`
			`int eg_inc_total;`
			`int eg_level_ssg[2];`
			`int eg_sl[2][2];`
			`int eg_nextlevel[2];`
			`int eg_kon_csm[2];`
			`int eg_kon_latch[2];`
			`int eg_tl[2][2];`
			`int eg_ams;`
			`int eg_lfo[2];`
			`int eg_ch3_latch[2];`
			`int eg_out;`
			`int eg_out_tl;`
			`int eg_out_total;`
			`int eg_debug[2];`

			`// op`
			`int op_mod[10][2];`
			`int op_phase[2];`
			`int op_logsin_base[2];`
			`int op_logsin_delta[2];`
			`int op_logsin_add_delta[2];`
			`int op_atten[2];`
			`int op_env[2];`
			`int op_pow_base[2];`
			`int op_pow_delta[2];`
			`int op_pow_add_delta[2];`
			`int op_shift[2];`
			`int op_sign[2];`
			`int op_output[2];`
			`int op_op1[2][14][2];`
			`int op_op2[14][2];`
			`int op_mod_sum[2];`
			`int op_dofeedback[2];`

			`// accumulator`

			`int ch_accm[14][2];`
			`int ch_out[9][2];`
			`int ch_out_dlatch;`
			`int ch_out_pan_dlatch;`
			`int ch_dac_load;`
			`int ch_out_debug[2];`
			`int ch_accm_l[2];`
			`int ch_accm_r[2];`

			`// timers`
			`int timer_dlatch;`
			`int timer_a_cnt[2];`
			`int timer_a_load_latch[2];`
			`int timer_a_load_old[2];`
			`int timer_a_load_dlatch;`
			`int timer_a_of[2];`
			`int timer_a_status[2];`
			`int timer_b_subcnt[2];`
			`int timer_b_subcnt_of[2];`
			`int timer_b_cnt[2];`
			`int timer_b_load_latch[2];`
			`int timer_b_load_old[2];`
			`int timer_b_load_dlatch;`
			`int timer_b_of[2];`
			`int timer_b_status[2];`
			`int timer_csm_key_dlatch;`

			`// fm algorithm`
			`int alg_mod_op1_0;`
			`int alg_mod_op1_1;`
			`int alg_mod_op2;`
			`int alg_mod_prev_0;`
			`int alg_mod_prev_1;`
			`int alg_output;`
			`int alg_mod_op1_0_l;`
			`int alg_mod_op1_1_l;`
			`int alg_mod_op2_l;`
			`int alg_mod_prev_0_l;`
			`int alg_mod_prev_1_l;`
			`int alg_output_l;`

			`// fsm`
			`int fsm_cnt1[2];`
			`int fsm_cnt2[2];`
			`// fsm table output`
			`int fsm_clock_eg;`
			`int fsm_clock_timers1;`
			`int fsm_clock_timers;`
			`int fsm_op4_sel;`
			`int fsm_op1_sel;`
			`int fsm_op2_sel;`
			`int fsm_op3_sel;`
			`int fsm_sel2;`
			`int fsm_sel23;`
			`int fsm_ch3_sel;`
			`int fsm_dac_load;`
			`int fsm_dac_out_sel;`
			`int fsm_dac_ch6;`

			`// ymf276`
			`int fsm_clock_eg_l;`
			`int fsm_op1_sel_l;`
			`int fsm_sel1_l;`
			`int fsm_sel2_l;`
			`int fsm_sel23_l;`
			`int fsm_ch3_sel_l;`
			`int fsm_dac_load_l;`
			`int fsm_dac_out_sel_l;`
			`int fsm_dac_ch6_l;`
			`int fsm_lro_l[2];`
			`int fsm_wco_l[2];`
			`int fsm_lro_l2[2];`
			`int fsm_wco_l2[2];`
			`int fsm_op1_sel_l2[2];`
			`int fsm_op1_sel_l3[2];`
			`int fsm_shifter_ctrl[2];`
			`int fsm_load_l;`
			`int fsm_load_r;`

			`int dac_shifter[2];`
			`int dac_so_l[2];`
			`int o_bco;`
			`int o_wco;`
			`int o_lro;`
			`int o_so;`
			`} fmopn2_t;`


			`int FMOPN2_ReadStatus(fmopn2_t *chip);`

			`void FMOPN2_Clock(fmopn2_t *chip, int phi);`