/* * CIA_SC.cpp - Single-cycle 6526 emulation * * Frodo (C) 1994-1997,2002-2005 Christian Bauer * * 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 */ /* * Notes: * ------ * * - The Emulate() function is called for every emulated Phi2 * clock cycle. It counts down the timers and triggers * interrupts if necessary. * - The TOD clocks are counted by CountTOD() during the VBlank, so * the input frequency is 50Hz * - The fields KeyMatrix and RevMatrix contain one bit for each * key on the C64 keyboard (0: key pressed, 1: key released). * KeyMatrix is used for normal keyboard polling (PRA->PRB), * RevMatrix for reversed polling (PRB->PRA). * * Incompatibilities: * ------------------ * * - The TOD clock should not be stopped on a read access, but be * latched * - The SDR interrupt is faked * - Some small incompatibilities with the timers */ #include "sysdeps.h" #include "CIA.h" #include "CPUC64.h" #include "CPU1541.h" #include "VIC.h" #include "Prefs.h" // Timer states enum { T_STOP, T_WAIT_THEN_COUNT, T_LOAD_THEN_STOP, T_LOAD_THEN_COUNT, T_LOAD_THEN_WAIT_THEN_COUNT, T_COUNT, T_COUNT_THEN_STOP }; /* * Constructors */ MOS6526::MOS6526(MOS6510 *CPU) : the_cpu(CPU) {} MOS6526_1::MOS6526_1(MOS6510 *CPU, MOS6569 *VIC) : MOS6526(CPU), the_vic(VIC) {} MOS6526_2::MOS6526_2(MOS6510 *CPU, MOS6569 *VIC, MOS6502_1541 *CPU1541) : MOS6526(CPU), the_vic(VIC), the_cpu_1541(CPU1541) {} /* * Reset the CIA */ void MOS6526::Reset(void) { pra = prb = ddra = ddrb = 0; ta = tb = 0xffff; latcha = latchb = 1; tod_10ths = tod_sec = tod_min = tod_hr = 0; alm_10ths = alm_sec = alm_min = alm_hr = 0; sdr = icr = cra = crb = int_mask = 0; tod_halt = false; tod_divider = 0; ta_cnt_phi2 = tb_cnt_phi2 = tb_cnt_ta = false; ta_irq_next_cycle = tb_irq_next_cycle = false; ta_state = tb_state = T_STOP; } void MOS6526_1::Reset(void) { MOS6526::Reset(); // Clear keyboard matrix and joystick states for (int i=0; i<8; i++) KeyMatrix[i] = RevMatrix[i] = 0xff; Joystick1 = Joystick2 = 0xff; prev_lp = 0x10; } void MOS6526_2::Reset(void) { MOS6526::Reset(); // VA14/15 = 0 the_vic->ChangedVA(0); // IEC IECLines = 0xd0; } /* * Get CIA state */ void MOS6526::GetState(MOS6526State *cs) { cs->pra = pra; cs->prb = prb; cs->ddra = ddra; cs->ddrb = ddrb; cs->ta_lo = ta & 0xff; cs->ta_hi = ta >> 8; cs->tb_lo = tb & 0xff; cs->tb_hi = tb >> 8; cs->latcha = latcha; cs->latchb = latchb; cs->cra = cra; cs->crb = crb; cs->tod_10ths = tod_10ths; cs->tod_sec = tod_sec; cs->tod_min = tod_min; cs->tod_hr = tod_hr; cs->alm_10ths = alm_10ths; cs->alm_sec = alm_sec; cs->alm_min = alm_min; cs->alm_hr = alm_hr; cs->sdr = sdr; cs->int_data = icr; cs->int_mask = int_mask; } /* * Restore CIA state */ void MOS6526::SetState(MOS6526State *cs) { pra = cs->pra; prb = cs->prb; ddra = cs->ddra; ddrb = cs->ddrb; ta = (cs->ta_hi << 8) | cs->ta_lo; tb = (cs->tb_hi << 8) | cs->tb_lo; latcha = cs->latcha; latchb = cs->latchb; cra = cs->cra; crb = cs->crb; tod_10ths = cs->tod_10ths; tod_sec = cs->tod_sec; tod_min = cs->tod_min; tod_hr = cs->tod_hr; alm_10ths = cs->alm_10ths; alm_sec = cs->alm_sec; alm_min = cs->alm_min; alm_hr = cs->alm_hr; sdr = cs->sdr; icr = cs->int_data; int_mask = cs->int_mask; tod_halt = false; ta_cnt_phi2 = ((cra & 0x20) == 0x00); tb_cnt_phi2 = ((crb & 0x60) == 0x00); tb_cnt_ta = ((crb & 0x60) == 0x40); ta_state = (cra & 1) ? T_COUNT : T_STOP; tb_state = (crb & 1) ? T_COUNT : T_STOP; } /* * Read from register (CIA 1) */ uint8 MOS6526_1::ReadRegister(uint16 adr) { switch (adr) { case 0x00: { uint8 ret = pra | ~ddra, tst = (prb | ~ddrb) & Joystick1; if (!(tst & 0x01)) ret &= RevMatrix[0]; // AND all active columns if (!(tst & 0x02)) ret &= RevMatrix[1]; if (!(tst & 0x04)) ret &= RevMatrix[2]; if (!(tst & 0x08)) ret &= RevMatrix[3]; if (!(tst & 0x10)) ret &= RevMatrix[4]; if (!(tst & 0x20)) ret &= RevMatrix[5]; if (!(tst & 0x40)) ret &= RevMatrix[6]; if (!(tst & 0x80)) ret &= RevMatrix[7]; return ret & Joystick2; } case 0x01: { uint8 ret = ~ddrb, tst = (pra | ~ddra) & Joystick2; if (!(tst & 0x01)) ret &= KeyMatrix[0]; // AND all active rows if (!(tst & 0x02)) ret &= KeyMatrix[1]; if (!(tst & 0x04)) ret &= KeyMatrix[2]; if (!(tst & 0x08)) ret &= KeyMatrix[3]; if (!(tst & 0x10)) ret &= KeyMatrix[4]; if (!(tst & 0x20)) ret &= KeyMatrix[5]; if (!(tst & 0x40)) ret &= KeyMatrix[6]; if (!(tst & 0x80)) ret &= KeyMatrix[7]; return (ret | (prb & ddrb)) & Joystick1; } case 0x02: return ddra; case 0x03: return ddrb; case 0x04: return ta; case 0x05: return ta >> 8; case 0x06: return tb; case 0x07: return tb >> 8; case 0x08: tod_halt = false; return tod_10ths; case 0x09: return tod_sec; case 0x0a: return tod_min; case 0x0b: tod_halt = true; return tod_hr; case 0x0c: return sdr; case 0x0d: { uint8 ret = icr; // Read and clear ICR icr = 0; the_cpu->ClearCIAIRQ(); // Clear IRQ return ret; } case 0x0e: return cra; case 0x0f: return crb; } return 0; // Can't happen } /* * Read from register (CIA 2) */ uint8 MOS6526_2::ReadRegister(uint16 adr) { switch (adr) { case 0x00: return (pra | ~ddra) & 0x3f | IECLines & the_cpu_1541->IECLines; case 0x01: return prb | ~ddrb; case 0x02: return ddra; case 0x03: return ddrb; case 0x04: return ta; case 0x05: return ta >> 8; case 0x06: return tb; case 0x07: return tb >> 8; case 0x08: tod_halt = false; return tod_10ths; case 0x09: return tod_sec; case 0x0a: return tod_min; case 0x0b: tod_halt = true; return tod_hr; case 0x0c: return sdr; case 0x0d: { uint8 ret = icr; // Read and clear ICR icr = 0; the_cpu->ClearNMI(); return ret; } case 0x0e: return cra; case 0x0f: return crb; } return 0; // Can't happen } /* * Write to register (CIA 1) */ // Write to port B, check for lightpen interrupt inline void MOS6526_1::check_lp(void) { if ((prb | ~ddrb) & 0x10 != prev_lp) the_vic->TriggerLightpen(); prev_lp = (prb | ~ddrb) & 0x10; } void MOS6526_1::WriteRegister(uint16 adr, uint8 byte) { switch (adr) { case 0x0: pra = byte; break; case 0x1: prb = byte; check_lp(); break; case 0x2: ddra = byte; break; case 0x3: ddrb = byte; check_lp(); break; case 0x4: latcha = (latcha & 0xff00) | byte; break; case 0x5: latcha = (latcha & 0xff) | (byte << 8); if (!(cra & 1)) // Reload timer if stopped ta = latcha; break; case 0x6: latchb = (latchb & 0xff00) | byte; break; case 0x7: latchb = (latchb & 0xff) | (byte << 8); if (!(crb & 1)) // Reload timer if stopped tb = latchb; break; case 0x8: if (crb & 0x80) alm_10ths = byte & 0x0f; else tod_10ths = byte & 0x0f; break; case 0x9: if (crb & 0x80) alm_sec = byte & 0x7f; else tod_sec = byte & 0x7f; break; case 0xa: if (crb & 0x80) alm_min = byte & 0x7f; else tod_min = byte & 0x7f; break; case 0xb: if (crb & 0x80) alm_hr = byte & 0x9f; else tod_hr = byte & 0x9f; break; case 0xc: sdr = byte; TriggerInterrupt(8); // Fake SDR interrupt for programs that need it break; case 0xd: if (byte & 0x80) int_mask |= byte & 0x7f; else int_mask &= ~byte; if (icr & int_mask & 0x1f) { // Trigger IRQ if pending icr |= 0x80; the_cpu->TriggerCIAIRQ(); } break; case 0xe: has_new_cra = true; // Delay write by 1 cycle new_cra = byte; ta_cnt_phi2 = ((byte & 0x20) == 0x00); break; case 0xf: has_new_crb = true; // Delay write by 1 cycle new_crb = byte; tb_cnt_phi2 = ((byte & 0x60) == 0x00); tb_cnt_ta = ((byte & 0x60) == 0x40); break; } } /* * Write to register (CIA 2) */ void MOS6526_2::WriteRegister(uint16 adr, uint8 byte) { switch (adr) { case 0x0:{ pra = byte; the_vic->ChangedVA(~(pra | ~ddra) & 3); uint8 old_lines = IECLines; IECLines = (~byte << 2) & 0x80 // DATA | (~byte << 2) & 0x40 // CLK | (~byte << 1) & 0x10; // ATN if ((IECLines ^ old_lines) & 0x10) { // ATN changed the_cpu_1541->NewATNState(); if (old_lines & 0x10) // ATN 1->0 the_cpu_1541->IECInterrupt(); } break; } case 0x1: prb = byte; break; case 0x2: ddra = byte; the_vic->ChangedVA(~(pra | ~ddra) & 3); break; case 0x3: ddrb = byte; break; case 0x4: latcha = (latcha & 0xff00) | byte; break; case 0x5: latcha = (latcha & 0xff) | (byte << 8); if (!(cra & 1)) // Reload timer if stopped ta = latcha; break; case 0x6: latchb = (latchb & 0xff00) | byte; break; case 0x7: latchb = (latchb & 0xff) | (byte << 8); if (!(crb & 1)) // Reload timer if stopped tb = latchb; break; case 0x8: if (crb & 0x80) alm_10ths = byte & 0x0f; else tod_10ths = byte & 0x0f; break; case 0x9: if (crb & 0x80) alm_sec = byte & 0x7f; else tod_sec = byte & 0x7f; break; case 0xa: if (crb & 0x80) alm_min = byte & 0x7f; else tod_min = byte & 0x7f; break; case 0xb: if (crb & 0x80) alm_hr = byte & 0x9f; else tod_hr = byte & 0x9f; break; case 0xc: sdr = byte; TriggerInterrupt(8); // Fake SDR interrupt for programs that need it break; case 0xd: if (byte & 0x80) int_mask |= byte & 0x7f; else int_mask &= ~byte; if (icr & int_mask & 0x1f) { // Trigger NMI if pending icr |= 0x80; the_cpu->TriggerNMI(); } break; case 0xe: has_new_cra = true; // Delay write by 1 cycle new_cra = byte; ta_cnt_phi2 = ((byte & 0x20) == 0x00); break; case 0xf: has_new_crb = true; // Delay write by 1 cycle new_crb = byte; tb_cnt_phi2 = ((byte & 0x60) == 0x00); tb_cnt_ta = ((byte & 0x60) == 0x40); break; } } /* * Emulate CIA for one cycle/raster line */ void MOS6526::EmulateCycle(void) { bool ta_underflow = false; // Timer A state machine switch (ta_state) { case T_WAIT_THEN_COUNT: ta_state = T_COUNT; // fall through case T_STOP: goto ta_idle; case T_LOAD_THEN_STOP: ta_state = T_STOP; ta = latcha; // Reload timer goto ta_idle; case T_LOAD_THEN_COUNT: ta_state = T_COUNT; ta = latcha; // Reload timer goto ta_idle; case T_LOAD_THEN_WAIT_THEN_COUNT: ta_state = T_WAIT_THEN_COUNT; if (ta == 1) goto ta_interrupt; // Interrupt if timer == 1 else { ta = latcha; // Reload timer goto ta_idle; } case T_COUNT: goto ta_count; case T_COUNT_THEN_STOP: ta_state = T_STOP; goto ta_count; } // Count timer A ta_count: if (ta_cnt_phi2) if (!ta || !--ta) { // Decrement timer, underflow? if (ta_state != T_STOP) { ta_interrupt: ta = latcha; // Reload timer ta_irq_next_cycle = true; // Trigger interrupt in next cycle icr |= 1; // But set ICR bit now if (cra & 8) { // One-shot? cra &= 0xfe; // Yes, stop timer new_cra &= 0xfe; ta_state = T_LOAD_THEN_STOP; // Reload in next cycle } else ta_state = T_LOAD_THEN_COUNT; // No, delay one cycle (and reload) } ta_underflow = true; } // Delayed write to CRA? ta_idle: if (has_new_cra) { switch (ta_state) { case T_STOP: case T_LOAD_THEN_STOP: if (new_cra & 1) { // Timer started, wasn't running if (new_cra & 0x10) // Force load ta_state = T_LOAD_THEN_WAIT_THEN_COUNT; else // No force load ta_state = T_WAIT_THEN_COUNT; } else { // Timer stopped, was already stopped if (new_cra & 0x10) // Force load ta_state = T_LOAD_THEN_STOP; } break; case T_COUNT: if (new_cra & 1) { // Timer started, was already running if (new_cra & 0x10) // Force load ta_state = T_LOAD_THEN_WAIT_THEN_COUNT; } else { // Timer stopped, was running if (new_cra & 0x10) // Force load ta_state = T_LOAD_THEN_STOP; else // No force load ta_state = T_COUNT_THEN_STOP; } break; case T_LOAD_THEN_COUNT: case T_WAIT_THEN_COUNT: if (new_cra & 1) { if (new_cra & 8) { // One-shot? new_cra &= 0xfe; // Yes, stop timer ta_state = T_STOP; } else if (new_cra & 0x10) // Force load ta_state = T_LOAD_THEN_WAIT_THEN_COUNT; } else { ta_state = T_STOP; } break; } cra = new_cra & 0xef; has_new_cra = false; } // Timer B state machine switch (tb_state) { case T_WAIT_THEN_COUNT: tb_state = T_COUNT; // fall through case T_STOP: goto tb_idle; case T_LOAD_THEN_STOP: tb_state = T_STOP; tb = latchb; // Reload timer goto tb_idle; case T_LOAD_THEN_COUNT: tb_state = T_COUNT; tb = latchb; // Reload timer goto ta_idle; case T_LOAD_THEN_WAIT_THEN_COUNT: tb_state = T_WAIT_THEN_COUNT; if (tb == 1) goto tb_interrupt; // Interrupt if timer == 1 else { tb = latchb; // Reload timer goto tb_idle; } case T_COUNT: goto tb_count; case T_COUNT_THEN_STOP: tb_state = T_STOP; goto tb_count; } // Count timer B tb_count: if (tb_cnt_phi2 || (tb_cnt_ta && ta_underflow)) if (!tb || !--tb) { // Decrement timer, underflow? if (tb_state != T_STOP) { tb_interrupt: tb = latchb; // Reload timer tb_irq_next_cycle = true; // Trigger interrupt in next cycle icr |= 2; // But set ICR bit now if (crb & 8) { // One-shot? crb &= 0xfe; // Yes, stop timer new_crb &= 0xfe; tb_state = T_LOAD_THEN_STOP; // Reload in next cycle } else tb_state = T_LOAD_THEN_COUNT; // No, delay one cycle (and reload) } } // Delayed write to CRB? tb_idle: if (has_new_crb) { switch (tb_state) { case T_STOP: case T_LOAD_THEN_STOP: if (new_crb & 1) { // Timer started, wasn't running if (new_crb & 0x10) // Force load tb_state = T_LOAD_THEN_WAIT_THEN_COUNT; else // No force load tb_state = T_WAIT_THEN_COUNT; } else { // Timer stopped, was already stopped if (new_crb & 0x10) // Force load tb_state = T_LOAD_THEN_STOP; } break; case T_COUNT: if (new_crb & 1) { // Timer started, was already running if (new_crb & 0x10) // Force load tb_state = T_LOAD_THEN_WAIT_THEN_COUNT; } else { // Timer stopped, was running if (new_crb & 0x10) // Force load tb_state = T_LOAD_THEN_STOP; else // No force load tb_state = T_COUNT_THEN_STOP; } break; case T_LOAD_THEN_COUNT: case T_WAIT_THEN_COUNT: if (new_crb & 1) { if (new_crb & 8) { // One-shot? new_crb &= 0xfe; // Yes, stop timer tb_state = T_STOP; } else if (new_crb & 0x10) // Force load tb_state = T_LOAD_THEN_WAIT_THEN_COUNT; } else { tb_state = T_STOP; } break; } crb = new_crb & 0xef; has_new_crb = false; } } /* * Count CIA TOD clock (called during VBlank) */ void MOS6526::CountTOD(void) { uint8 lo, hi; // Decrement frequency divider if (tod_divider) tod_divider--; else { // Reload divider according to 50/60 Hz flag if (cra & 0x80) tod_divider = 4; else tod_divider = 5; // 1/10 seconds tod_10ths++; if (tod_10ths > 9) { tod_10ths = 0; // Seconds lo = (tod_sec & 0x0f) + 1; hi = tod_sec >> 4; if (lo > 9) { lo = 0; hi++; } if (hi > 5) { tod_sec = 0; // Minutes lo = (tod_min & 0x0f) + 1; hi = tod_min >> 4; if (lo > 9) { lo = 0; hi++; } if (hi > 5) { tod_min = 0; // Hours lo = (tod_hr & 0x0f) + 1; hi = (tod_hr >> 4) & 1; tod_hr &= 0x80; // Keep AM/PM flag if (lo > 9) { lo = 0; hi++; } tod_hr |= (hi << 4) | lo; if ((tod_hr & 0x1f) > 0x11) tod_hr = tod_hr & 0x80 ^ 0x80; } else tod_min = (hi << 4) | lo; } else tod_sec = (hi << 4) | lo; } // Alarm time reached? Trigger interrupt if enabled if (tod_10ths == alm_10ths && tod_sec == alm_sec && tod_min == alm_min && tod_hr == alm_hr) TriggerInterrupt(4); } } /* * Trigger IRQ (CIA 1) */ void MOS6526_1::TriggerInterrupt(int bit) { icr |= bit; if (int_mask & bit) { icr |= 0x80; the_cpu->TriggerCIAIRQ(); } } /* * Trigger NMI (CIA 2) */ void MOS6526_2::TriggerInterrupt(int bit) { icr |= bit; if (int_mask & bit) { icr |= 0x80; the_cpu->TriggerNMI(); } }