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163 lines
7.3 KiB
C
163 lines
7.3 KiB
C
//
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// 6502_und.h
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// A2Mac
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//
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// Created by Tamas Rudnai on 7/27/20.
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// Copyright © 2019, 2020 Tamas Rudnai. All rights reserved.
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//
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// This file is part of Steve ][ -- The Apple ][ Emulator.
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//
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// Steve ][ is free software: you can redistribute it and/or modify
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// it under the terms of the GNU General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// Steve ][ is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU General Public License for more details.
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//
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// You should have received a copy of the GNU General Public License
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// along with Steve ][. If not, see <https://www.gnu.org/licenses/>.
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//
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// Documentations:
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//
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// http://nesdev.com/6502_cpu.txt
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// http://www.oxyron.de/html/opcodes02.html
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// https://macgui.com/kb/article/46
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// https://www.masswerk.at/6502/6502_instruction_set.html
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//
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#ifndef _6502_C_h
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#define _6502_C_h
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// http://6502.org/tutorials/interrupts.html
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//
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// 2.3 WAI: FASTER INTERRUPT SERVICE ON THE 65C02
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//
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// WDC's 65C02 has a "wait" instruction, WAI. This allows a special case of ultra-fast IRQ interrupt service.
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//
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// In the earlier doorbell comparison, the guests, after ringing the doorbell, had to wait for you to put down what you were doing and get to the door, which introduced a small delay before they would see the door open. The comparison now is that you have already put your work down and gone to the door so you're right there ready to open it immediately upon hearing the bell.
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//
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// If the main part of the work can be paused until the next interrupt, you can set the interrupt-disable bit I-- yes, set it-- execute WAI, and have the very next instruction to be the beginning of the ISR. There will be no jumping through vectors; and since you know exactly where the program pointer will be when the interrupt hits, you will not necessarily need to save any registers your ISR uses. If you do, you can do it before the interrupt.
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//
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// The WAI guarantees that the processor will not be in the middle of executing another instruction when the IRQ line is pulled down, so we can eliminate that part of the latency. The other part of the latency, the 7-clock interrupt sequence, gets eliminated by the fact that we have used SEI to disable the normal IRQ operation, so the IRQ will only have the effect of re-starting the processor and making it continue on with the next instruction instead of taking the vector. And since we don't take the vector, we won't use RTI at the end either.
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//
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// Here's the idea. The LDA and STA instructions were selected only arbitrarily for the example. The xxx just represent the continuation of code execution after the interrupt service is finished.
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//
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// STA VIA1IER ; Pre-interrupt code finishes here.
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// SEI ; Disable interrupts if not already done.
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// WAI ; Put processor into pause mode.
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// LDA VIA1PB ; First instruction of ISR goes here.
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// . ; (Notice the code is straight-lined.)
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// . ; Service the interrupt.
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// .
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// xxx ; End of ISR moves right into the next thing
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// xxx ; for the computer to do, without using RTI.
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// 6502 instructions with additional addressing modes
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// ADC AND CMP EOR LDA ORA SBC STA - (zp) addressing mode
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case 0x12: ORA( src_ind() ); return 5; // ORA (zpg)
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case 0x32: AND( src_ind() ); return 5; // AND (zpg)
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case 0x52: EOR( src_ind() ); return 5; // EOR (zpg)
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case 0x72: ADC( src_ind() ); return 5; // ADC (zpg)
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case 0x92: STA( addr_ind() ); return 5; // STA (zpg)
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case 0xB2: LDA( src_ind() ); return 5; // LDA (zpg)
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case 0xD2: CMP( src_ind() ); return 5; // CMP (zpg)
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case 0xF2: SBC( src_ind() ); return 5; // SBC (zpg)
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// BIT - imm abs,X zp,X addressing modes
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case 0x34: BIT( src_zp_X() ); return 4; // BIT zpg,X
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case 0x3C: BIT( src_abs_X() ); return 4; // BIT abs,X
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case 0x89: BITI( imm() ); return 2; // BIT imm
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// DEC INC - acc addressing mode
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case 0x1A: INA(); return 2; // INA imm (INC A)
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case 0x3A: DEA(); return 2; // DEA imm (DEC A)
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// JMP - (abs,X) addressing mode
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case 0x7C: JMP( addr_ind_ind_X()); return 6; // abs_addr_X() ); return 6; // JMP abs,X
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// Additional instructions
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// BRA - BRanch Always
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case 0x80: BRA( rel_addr() ); return 3; // BRA reladdr
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// PHX PHY PLX PLY - PusH or PulL X or Y register
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case 0x5A: PHY(); return 3; // PHY
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case 0x7A: PLY(); return 4; // PLY
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case 0xDA: PHX(); return 3; // PHX
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case 0xFA: PLX(); return 4; // PLX
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// STZ - STore Zero
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case 0x64: STZ_zp( addr_zp() ); return 3; // STZ zpg
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case 0x74: STZ_zp( addr_zp_X() ); return 4; // STZ zpg,X
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case 0x9C: STZ( addr_abs() ); return 4; // STZ abs
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case 0x9E: STZ( addr_abs_X() ); return 5; // STZ abs,X
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// TRB - Test and Reset Bits
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case 0x04: TSB_zp( addr_zp() ); return 5; // TSB zpg
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case 0x0C: TSB( addr_abs() ); return 6; // TSB abs
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case 0x14: TRB_zp( addr_zp() ); return 5; // TRB zpg
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case 0x1C: TRB( addr_abs() ); return 6; // TRB abs
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/// Undocumented NOPs
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case 0x02:
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case 0x22:
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case 0x42:
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case 0x62:
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case 0x82:
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case 0xC2:
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case 0xE2: NOP(); fetch(); return 2; // NOP* (2 bytes) (undocumented)
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case 0x44: NOP(); fetch(); return 3; // NOP* (2 bytes) (undocumented)
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case 0x54:
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case 0xD4:
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case 0xF4: NOP(); fetch(); return 4; // NOP* (2 bytes) (undocumented)
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case 0x5C: NOP(); fetch16(); return 8; // NOP* (3 bytes) (undocumented)
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case 0xDC:
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case 0xFC: NOP(); fetch16(); return 4; // NOP* (3 bytes) (undocumented)
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case 0x03:
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case 0x13:
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case 0x23:
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case 0x33:
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case 0x43:
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case 0x53:
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case 0x63:
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case 0x73:
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case 0x83:
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case 0x93:
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case 0xA3:
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case 0xB3:
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case 0xC3:
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case 0xD3:
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case 0xE3:
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case 0xF3:
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case 0x0B:
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case 0x1B:
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case 0x2B:
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case 0x3B:
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case 0x4B:
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case 0x5B:
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case 0x6B:
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case 0x7B:
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case 0x8B:
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case 0x9B:
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case 0xAB:
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case 0xBB:
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case 0xEB:
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case 0xFB: NOP(); return 1; // NOP* (1 byte) (undocumented)
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#endif /* _6502_C_h */
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