1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-22 12:33:29 +00:00
CLK/InstructionSets/M50740/Decoder.cpp
2021-01-23 15:45:21 -05:00

283 lines
9.6 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

//
// Decoder.cpp
// Clock Signal
//
// Created by Thomas Harte on 15/01/21.
// Copyright © 2021 Thomas Harte. All rights reserved.
//
#include "Decoder.hpp"
#include <algorithm>
namespace InstructionSet {
namespace M50740 {
Instruction Decoder::instrucion_for_opcode(uint8_t opcode) {
switch(opcode) {
default: return Instruction(opcode);
#define Map(opcode, operation, addressing_mode) case opcode: return Instruction(Operation::operation, AddressingMode::addressing_mode, opcode);
/* 0x00 0x0f */
Map(0x00, BRK, Implied); Map(0x01, ORA, XIndirect);
Map(0x02, JSR, ZeroPageIndirect); Map(0x03, BBS0, AccumulatorRelative);
Map(0x05, ORA, ZeroPage);
Map(0x06, ASL, ZeroPage); Map(0x07, BBS0, ZeroPageRelative);
Map(0x08, PHP, Implied); Map(0x09, ORA, Immediate);
Map(0x0a, ASL, Accumulator); Map(0x0b, SEB0, Accumulator);
Map(0x0d, ORA, Absolute);
Map(0x0e, ASL, Absolute); Map(0x0f, SEB0, ZeroPage);
/* 0x10 0x1f */
Map(0x10, BPL, Relative); Map(0x11, ORA, IndirectY);
Map(0x12, CLT, Implied); Map(0x13, BBC0, AccumulatorRelative);
Map(0x15, ORA, ZeroPageX);
Map(0x16, ASL, ZeroPageX); Map(0x17, BBC0, ZeroPageRelative);
Map(0x18, CLC, Implied); Map(0x19, ORA, AbsoluteY);
Map(0x1a, DEC, Accumulator); Map(0x1b, CLB0, Accumulator);
Map(0x1d, ORA, AbsoluteX);
Map(0x1e, ASL, AbsoluteX); Map(0x1f, CLB0, ZeroPage);
/* 0x20 0x2f */
Map(0x20, JSR, Absolute); Map(0x21, AND, XIndirect);
Map(0x22, JSR, SpecialPage); Map(0x23, BBS1, AccumulatorRelative);
Map(0x24, BIT, ZeroPage); Map(0x25, AND, ZeroPage);
Map(0x26, ROL, ZeroPage); Map(0x27, BBS1, ZeroPageRelative);
Map(0x28, PLP, Implied); Map(0x29, AND, Immediate);
Map(0x2a, ROL, Accumulator); Map(0x2b, SEB1, Accumulator);
Map(0x2c, BIT, Absolute); Map(0x2d, AND, Absolute);
Map(0x2e, ROL, Absolute); Map(0x2f, SEB1, ZeroPage);
/* 0x30 0x3f */
Map(0x30, BMI, Relative); Map(0x31, AND, IndirectY);
Map(0x32, SET, Implied); Map(0x33, BBC1, AccumulatorRelative);
Map(0x35, AND, ZeroPageX);
Map(0x36, ROL, ZeroPageX); Map(0x37, BBC1, ZeroPageRelative);
Map(0x38, SEC, Implied); Map(0x39, AND, AbsoluteY);
Map(0x3a, INC, Accumulator); Map(0x3b, CLB1, Accumulator);
Map(0x3c, LDM, ImmediateZeroPage); Map(0x3d, AND, AbsoluteX);
Map(0x3e, ROL, AbsoluteX); Map(0x3f, CLB1, ZeroPage);
/* 0x40 0x4f */
Map(0x40, RTI, Implied); Map(0x41, EOR, XIndirect);
Map(0x42, STP, Implied); Map(0x43, BBS2, AccumulatorRelative);
Map(0x44, COM, ZeroPage); Map(0x45, EOR, ZeroPage);
Map(0x46, LSR, ZeroPage); Map(0x47, BBS2, ZeroPageRelative);
Map(0x48, PHA, Implied); Map(0x49, EOR, Immediate);
Map(0x4a, LSR, Accumulator); Map(0x4b, SEB2, Accumulator);
Map(0x4c, JMP, Absolute); Map(0x4d, EOR, Absolute);
Map(0x4e, LSR, Absolute); Map(0x4f, SEB2, ZeroPage);
/* 0x50 0x5f */
Map(0x50, BVC, Relative); Map(0x51, EOR, IndirectY);
Map(0x53, BBC2, AccumulatorRelative);
Map(0x55, EOR, ZeroPageX);
Map(0x56, LSR, ZeroPageX); Map(0x57, BBC2, ZeroPageRelative);
Map(0x58, CLI, Implied); Map(0x59, EOR, AbsoluteY);
Map(0x5b, CLB2, Accumulator);
Map(0x5d, EOR, AbsoluteX);
Map(0x5e, LSR, AbsoluteX); Map(0x5f, CLB2, ZeroPage);
/* 0x60 0x6f */
Map(0x60, RTS, Implied); Map(0x61, ADC, XIndirect);
Map(0x63, BBS3, AccumulatorRelative);
Map(0x64, TST, ZeroPage); Map(0x65, ADC, ZeroPage);
Map(0x66, ROR, ZeroPage); Map(0x67, BBS3, ZeroPageRelative);
Map(0x68, PLA, Implied); Map(0x69, ADC, Immediate);
Map(0x6a, ROR, Accumulator); Map(0x6b, SEB3, Accumulator);
Map(0x6c, JMP, AbsoluteIndirect); Map(0x6d, ADC, Absolute);
Map(0x6e, ROR, Absolute); Map(0x6f, SEB3, ZeroPage);
/* 0x70 0x7f */
Map(0x70, BVS, Relative); Map(0x71, ADC, IndirectY);
Map(0x73, BBC3, AccumulatorRelative);
Map(0x75, ADC, ZeroPageX);
Map(0x76, ROR, ZeroPageX); Map(0x77, BBC3, ZeroPageRelative);
Map(0x78, SEI, Implied); Map(0x79, ADC, AbsoluteY);
Map(0x7b, CLB3, Accumulator);
Map(0x7d, ADC, AbsoluteX);
Map(0x7e, ROR, AbsoluteX); Map(0x7f, CLB3, ZeroPage);
/* 0x80 0x8f */
Map(0x80, BRA, Relative); Map(0x81, STA, XIndirect);
Map(0x82, RRF, ZeroPage); Map(0x83, BBS4, AccumulatorRelative);
Map(0x84, STY, ZeroPage); Map(0x85, STA, ZeroPage);
Map(0x86, STX, ZeroPage); Map(0x87, BBS4, ZeroPageRelative);
Map(0x88, DEY, Implied);
Map(0x8a, TXA, Implied); Map(0x8b, SEB4, Accumulator);
Map(0x8c, STY, Absolute); Map(0x8d, STA, Absolute);
Map(0x8e, STX, Absolute); Map(0x8f, SEB4, ZeroPage);
/* 0x90 0x9f */
Map(0x90, BCC, Relative); Map(0x91, STA, IndirectY);
Map(0x93, BBC4, AccumulatorRelative);
Map(0x94, STY, ZeroPageX); Map(0x95, STA, ZeroPageX);
Map(0x96, STX, ZeroPageX); Map(0x97, BBC4, ZeroPageRelative);
Map(0x98, TYA, Implied); Map(0x99, STA, AbsoluteY);
Map(0x9a, TXS, Implied); Map(0x9b, CLB4, Accumulator);
Map(0x9d, ADC, AbsoluteX);
Map(0x9f, CLB4, ZeroPage);
/* 0xa0 0xaf */
Map(0xa0, LDY, Immediate); Map(0xa1, LDA, XIndirect);
Map(0xa2, LDX, Immediate); Map(0xa3, BBS5, AccumulatorRelative);
Map(0xa4, LDY, ZeroPage); Map(0xa5, LDA, ZeroPage);
Map(0xa6, LDX, ZeroPage); Map(0xa7, BBS5, ZeroPageRelative);
Map(0xa8, TAY, Implied); Map(0xa9, LDA, Immediate);
Map(0xaa, TAX, Implied); Map(0xab, SEB5, Accumulator);
Map(0xac, LDY, Absolute); Map(0xad, LDA, Absolute);
Map(0xae, LDX, Absolute); Map(0xaf, SEB5, ZeroPage);
/* 0xb0 0xbf */
Map(0xb0, BCS, Relative); Map(0xb1, STA, IndirectY);
Map(0xb2, JMP, ZeroPageIndirect); Map(0xb3, BBC5, AccumulatorRelative);
Map(0xb4, LDY, ZeroPageX); Map(0xb5, LDA, ZeroPageX);
Map(0xb6, LDX, ZeroPageY); Map(0xb7, BBC5, ZeroPageRelative);
Map(0xb8, CLV, Implied); Map(0xb9, LDA, AbsoluteY);
Map(0xba, TSX, Implied); Map(0xbb, CLB5, Accumulator);
Map(0xbc, LDY, AbsoluteX); Map(0xbd, LDA, AbsoluteX);
Map(0xbe, LDX, AbsoluteY); Map(0xbf, CLB5, ZeroPage);
/* 0xc0 0xcf */
Map(0xc0, CPY, Immediate); Map(0xc1, CMP, XIndirect);
Map(0xc2, SLW, Implied); Map(0xc3, BBS6, AccumulatorRelative);
Map(0xc4, CPY, ZeroPage); Map(0xc5, CMP, ZeroPage);
Map(0xc6, DEC, ZeroPage); Map(0xc7, BBS6, ZeroPageRelative);
Map(0xc8, INY, Implied); Map(0xc9, CMP, Immediate);
Map(0xca, DEX, Implied); Map(0xcb, SEB6, Accumulator);
Map(0xcc, CPY, Absolute); Map(0xcd, CMP, Absolute);
Map(0xce, DEC, Absolute); Map(0xcf, SEB6, ZeroPage);
/* 0xd0 0xdf */
Map(0xd0, BNE, Relative); Map(0xd1, CMP, IndirectY);
Map(0xd3, BBC6, AccumulatorRelative);
Map(0xd5, CMP, ZeroPageX);
Map(0xd6, DEC, ZeroPageX); Map(0xd7, BBC6, ZeroPageRelative);
Map(0xd8, CLD, Implied); Map(0xd9, CMP, AbsoluteY);
Map(0xdb, CLB6, Accumulator);
Map(0xdd, CMP, AbsoluteX);
Map(0xde, DEC, AbsoluteX); Map(0xdf, CLB6, ZeroPage);
/* 0xe0 0xef */
Map(0xe0, CPX, Immediate); Map(0xe1, SBC, XIndirect);
Map(0xe2, FST, Implied); Map(0xe3, BBS7, AccumulatorRelative);
Map(0xe4, CPX, ZeroPage); Map(0xe5, SBC, ZeroPage);
Map(0xe6, INC, ZeroPage); Map(0xe7, BBS7, ZeroPageRelative);
Map(0xe8, INX, Implied); Map(0xe9, SBC, Immediate);
Map(0xea, NOP, Implied); Map(0xeb, SEB7, Accumulator);
Map(0xec, CPX, Absolute); Map(0xed, SBC, Absolute);
Map(0xee, INC, Absolute); Map(0xef, SEB7, ZeroPage);
/* 0xf0 0xff */
Map(0xf0, BEQ, Relative); Map(0xf1, SBC, IndirectY);
Map(0xf3, BBC7, AccumulatorRelative);
Map(0xf5, SBC, ZeroPageX);
Map(0xf6, INC, ZeroPageX); Map(0xf7, BBC7, ZeroPageRelative);
Map(0xf8, SED, Implied); Map(0xf9, SBC, AbsoluteY);
Map(0xfb, CLB7, Accumulator);
Map(0xfd, SBC, AbsoluteX);
Map(0xfe, INC, AbsoluteX); Map(0xff, CLB7, ZeroPage);
#undef Map
}
}
std::pair<int, InstructionSet::M50740::Instruction> Decoder::decode(const uint8_t *source, size_t length) {
const uint8_t *const end = source + length;
if(phase_ == Phase::Instruction && source != end) {
const uint8_t instruction = *source;
++source;
++consumed_;
// Determine the instruction in hand, and finish now if its undefined.
instr_ = instrucion_for_opcode(instruction);
if(instr_.operation == Operation::Invalid) {
consumed_ = 0;
return std::make_pair(1, instr_);
}
// Obtain an operand size and roll onto the correct phase.
operand_size_ = size(instr_.addressing_mode);
phase_ = operand_size_ ? Phase::AwaitingOperand : Phase::ReadyToPost;
operand_bytes_ = 0;
}
if(phase_ == Phase::AwaitingOperand && source != end) {
const int outstanding_bytes = operand_size_ - operand_bytes_;
const int bytes_to_consume = std::min(int(end - source), outstanding_bytes);
consumed_ += bytes_to_consume;
source += bytes_to_consume;
operand_bytes_ += bytes_to_consume;
if(operand_size_ == operand_bytes_) {
phase_ = Phase::ReadyToPost;
} else {
return std::make_pair(-(operand_size_ - operand_bytes_), Instruction());
}
}
if(phase_ == Phase::ReadyToPost) {
const auto result = std::make_pair(consumed_, instr_);
consumed_ = 0;
phase_ = Phase::Instruction;
return result;
}
// Decoding didn't complete, without it being clear how many more bytes are required.
return std::make_pair(0, Instruction());
}
}
}