1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-12-27 01:31:42 +00:00
CLK/InstructionSets/x86/Decoder.cpp
Thomas Harte 5f413a38df Switches all American-style dates.
I'd failed to configure my new computer appropriately, it seems.
2021-01-16 22:09:19 -05:00

626 lines
20 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.

//
// x86.cpp
// Clock Signal
//
// Created by Thomas Harte on 01/01/21.
// Copyright © 2021 Thomas Harte. All rights reserved.
//
#include "Decoder.hpp"
#include <algorithm>
#include <cassert>
#include <utility>
using namespace InstructionSet::x86;
// Only 8086 is suppoted for now.
Decoder::Decoder(Model) {}
std::pair<int, InstructionSet::x86::Instruction> Decoder::decode(const uint8_t *source, size_t length) {
const uint8_t *const end = source + length;
// MARK: - Prefixes (if present) and the opcode.
/// Helper macro for those that follow.
#define SetOpSrcDestSize(op, src, dest, size) \
operation_ = Operation::op; \
source_ = Source::src; \
destination_ = Source::dest; \
operation_size_ = size
/// Covers anything which is complete as soon as the opcode is encountered.
#define Complete(op, src, dest, size) \
SetOpSrcDestSize(op, src, dest, size); \
phase_ = Phase::ReadyToPost
/// Handles instructions of the form rr, kk and rr, jjkk, i.e. a destination register plus an operand.
#define RegData(op, dest, size) \
SetOpSrcDestSize(op, DirectAddress, dest, size); \
source_ = Source::Immediate; \
operand_size_ = size; \
phase_ = Phase::AwaitingDisplacementOrOperand
/// Handles instructions of the form Ax, jjkk where the latter is implicitly an address.
#define RegAddr(op, dest, op_size, addr_size) \
SetOpSrcDestSize(op, DirectAddress, dest, op_size); \
operand_size_ = addr_size; \
phase_ = Phase::AwaitingDisplacementOrOperand
/// Handles instructions of the form jjkk, Ax where the former is implicitly an address.
#define AddrReg(op, source, op_size, addr_size) \
SetOpSrcDestSize(op, source, DirectAddress, op_size); \
operand_size_ = addr_size; \
destination_ = Source::DirectAddress; \
phase_ = Phase::AwaitingDisplacementOrOperand
/// Covers both `mem/reg, reg` and `reg, mem/reg`.
#define MemRegReg(op, format, size) \
operation_ = Operation::op; \
phase_ = Phase::ModRegRM; \
modregrm_format_ = ModRegRMFormat::format; \
operand_size_ = 0; \
operation_size_ = size
/// Handles JO, JNO, JB, etc — jumps with a single byte displacement.
#define Jump(op) \
operation_ = Operation::op; \
phase_ = Phase::AwaitingDisplacementOrOperand; \
displacement_size_ = 1
/// Handles far CALL and far JMP — fixed four byte operand operations.
#define Far(op) \
operation_ = Operation::op; \
phase_ = Phase::AwaitingDisplacementOrOperand; \
operand_size_ = 4; \
while(phase_ == Phase::Instruction && source != end) {
// Retain the instruction byte, in case additional decoding is deferred
// to the ModRegRM byte.
instr_ = *source;
++source;
++consumed_;
switch(instr_) {
default: {
const auto result = std::make_pair(consumed_, Instruction());
reset_parsing();
return result;
}
#define PartialBlock(start, operation) \
case start + 0x00: MemRegReg(operation, MemReg_Reg, 1); break; \
case start + 0x01: MemRegReg(operation, MemReg_Reg, 2); break; \
case start + 0x02: MemRegReg(operation, Reg_MemReg, 1); break; \
case start + 0x03: MemRegReg(operation, Reg_MemReg, 2); break; \
case start + 0x04: RegData(operation, AL, 1); break; \
case start + 0x05: RegData(operation, AX, 2)
PartialBlock(0x00, ADD); break;
case 0x06: Complete(PUSH, ES, None, 2); break;
case 0x07: Complete(POP, None, ES, 2); break;
PartialBlock(0x08, OR); break;
case 0x0e: Complete(PUSH, CS, None, 2); break;
PartialBlock(0x10, ADC); break;
case 0x16: Complete(PUSH, SS, None, 2); break;
case 0x17: Complete(POP, None, SS, 2); break;
PartialBlock(0x18, SBB); break;
case 0x1e: Complete(PUSH, DS, None, 2); break;
case 0x1f: Complete(POP, None, DS, 2); break;
PartialBlock(0x20, AND); break;
case 0x26: segment_override_ = Source::ES; break;
case 0x27: Complete(DAA, AL, AL, 1); break;
PartialBlock(0x28, SUB); break;
case 0x2e: segment_override_ = Source::CS; break;
case 0x2f: Complete(DAS, AL, AL, 1); break;
PartialBlock(0x30, XOR); break;
case 0x36: segment_override_ = Source::SS; break;
case 0x37: Complete(AAA, AL, AX, 1); break;
PartialBlock(0x38, CMP); break;
case 0x3e: segment_override_ = Source::DS; break;
case 0x3f: Complete(AAS, AL, AX, 1); break;
#undef PartialBlock
#define RegisterBlock(start, operation) \
case start + 0x00: Complete(operation, AX, AX, 2); break; \
case start + 0x01: Complete(operation, CX, CX, 2); break; \
case start + 0x02: Complete(operation, DX, DX, 2); break; \
case start + 0x03: Complete(operation, BX, BX, 2); break; \
case start + 0x04: Complete(operation, SP, SP, 2); break; \
case start + 0x05: Complete(operation, BP, BP, 2); break; \
case start + 0x06: Complete(operation, SI, SI, 2); break; \
case start + 0x07: Complete(operation, DI, DI, 2)
RegisterBlock(0x40, INC); break;
RegisterBlock(0x48, DEC); break;
RegisterBlock(0x50, PUSH); break;
RegisterBlock(0x58, POP); break;
#undef RegisterBlock
// 0x600x6f: not used.
case 0x70: Jump(JO); break;
case 0x71: Jump(JNO); break;
case 0x72: Jump(JB); break;
case 0x73: Jump(JNB); break;
case 0x74: Jump(JE); break;
case 0x75: Jump(JNE); break;
case 0x76: Jump(JBE); break;
case 0x77: Jump(JNBE); break;
case 0x78: Jump(JS); break;
case 0x79: Jump(JNS); break;
case 0x7a: Jump(JP); break;
case 0x7b: Jump(JNP); break;
case 0x7c: Jump(JL); break;
case 0x7d: Jump(JNL); break;
case 0x7e: Jump(JLE); break;
case 0x7f: Jump(JNLE); break;
case 0x80: MemRegReg(Invalid, MemRegADD_to_CMP, 1); break;
case 0x81: MemRegReg(Invalid, MemRegADD_to_CMP, 2); break;
case 0x82: MemRegReg(Invalid, MemRegADC_to_CMP, 1); break;
case 0x83: MemRegReg(Invalid, MemRegADC_to_CMP, 2); break;
case 0x84: MemRegReg(TEST, MemReg_Reg, 1); break;
case 0x85: MemRegReg(TEST, MemReg_Reg, 2); break;
case 0x86: MemRegReg(XCHG, Reg_MemReg, 1); break;
case 0x87: MemRegReg(XCHG, Reg_MemReg, 2); break;
case 0x88: MemRegReg(MOV, MemReg_Reg, 1); break;
case 0x89: MemRegReg(MOV, MemReg_Reg, 2); break;
case 0x8a: MemRegReg(MOV, Reg_MemReg, 1); break;
case 0x8b: MemRegReg(MOV, Reg_MemReg, 2); break;
// 0x8c: not used.
case 0x8d: MemRegReg(LEA, Reg_MemReg, 2); break;
case 0x8e: MemRegReg(MOV, SegReg, 2); break;
case 0x8f: MemRegReg(POP, MemRegPOP, 2); break;
case 0x90: Complete(NOP, None, None, 0); break; // Or XCHG AX, AX?
case 0x91: Complete(XCHG, AX, CX, 2); break;
case 0x92: Complete(XCHG, AX, DX, 2); break;
case 0x93: Complete(XCHG, AX, BX, 2); break;
case 0x94: Complete(XCHG, AX, SP, 2); break;
case 0x95: Complete(XCHG, AX, BP, 2); break;
case 0x96: Complete(XCHG, AX, SI, 2); break;
case 0x97: Complete(XCHG, AX, DI, 2); break;
case 0x98: Complete(CBW, AL, AH, 1); break;
case 0x99: Complete(CWD, AX, DX, 2); break;
case 0x9a: Far(CALLF); break;
case 0x9b: Complete(WAIT, None, None, 0); break;
case 0x9c: Complete(PUSHF, None, None, 2); break;
case 0x9d: Complete(POPF, None, None, 2); break;
case 0x9e: Complete(SAHF, None, None, 1); break;
case 0x9f: Complete(LAHF, None, None, 1); break;
case 0xa0: RegAddr(MOV, AL, 1, 1); break;
case 0xa1: RegAddr(MOV, AX, 2, 2); break;
case 0xa2: AddrReg(MOV, AL, 1, 1); break;
case 0xa3: AddrReg(MOV, AX, 2, 2); break;
case 0xa4: Complete(MOVS, None, None, 1); break;
case 0xa5: Complete(MOVS, None, None, 2); break;
case 0xa6: Complete(CMPS, None, None, 1); break;
case 0xa7: Complete(CMPS, None, None, 2); break;
case 0xa8: RegData(TEST, AL, 1); break;
case 0xa9: RegData(TEST, AX, 2); break;
case 0xaa: Complete(STOS, None, None, 1); break;
case 0xab: Complete(STOS, None, None, 2); break;
case 0xac: Complete(LODS, None, None, 1); break;
case 0xad: Complete(LODS, None, None, 2); break;
case 0xae: Complete(SCAS, None, None, 1); break;
case 0xaf: Complete(SCAS, None, None, 2); break;
case 0xb0: RegData(MOV, AL, 1); break;
case 0xb1: RegData(MOV, CL, 1); break;
case 0xb2: RegData(MOV, DL, 1); break;
case 0xb3: RegData(MOV, BL, 1); break;
case 0xb4: RegData(MOV, AH, 1); break;
case 0xb5: RegData(MOV, CH, 1); break;
case 0xb6: RegData(MOV, DH, 1); break;
case 0xb7: RegData(MOV, BH, 1); break;
case 0xb8: RegData(MOV, AX, 2); break;
case 0xb9: RegData(MOV, CX, 2); break;
case 0xba: RegData(MOV, DX, 2); break;
case 0xbb: RegData(MOV, BX, 2); break;
case 0xbc: RegData(MOV, SP, 2); break;
case 0xbd: RegData(MOV, BP, 2); break;
case 0xbe: RegData(MOV, SI, 2); break;
case 0xbf: RegData(MOV, DI, 2); break;
case 0xc2: RegData(RETN, None, 2); break;
case 0xc3: Complete(RETN, None, None, 2); break;
case 0xc4: MemRegReg(LES, Reg_MemReg, 2); break;
case 0xc5: MemRegReg(LDS, Reg_MemReg, 2); break;
case 0xc6: MemRegReg(MOV, MemRegMOV, 1); break;
case 0xc7: MemRegReg(MOV, MemRegMOV, 2); break;
case 0xca: RegData(RETF, None, 2); break;
case 0xcb: Complete(RETF, None, None, 4); break;
case 0xcc: Complete(INT3, None, None, 0); break;
case 0xcd: RegData(INT, None, 1); break;
case 0xce: Complete(INTO, None, None, 0); break;
case 0xcf: Complete(IRET, None, None, 0); break;
case 0xd0: case 0xd1:
phase_ = Phase::ModRegRM;
modregrm_format_ = ModRegRMFormat::MemRegROL_to_SAR;
operation_size_ = 1 + (instr_ & 1);
source_ = Source::Immediate;
operand_ = 1;
break;
case 0xd2: case 0xd3:
phase_ = Phase::ModRegRM;
modregrm_format_ = ModRegRMFormat::MemRegROL_to_SAR;
operation_size_ = 1 + (instr_ & 1);
source_ = Source::CL;
break;
case 0xd4: RegData(AAM, AX, 1); break;
case 0xd5: RegData(AAD, AX, 1); break;
case 0xd7: Complete(XLAT, None, None, 1); break;
case 0xd8: MemRegReg(ESC, MemReg_Reg, 0); break;
case 0xd9: MemRegReg(ESC, MemReg_Reg, 0); break;
case 0xda: MemRegReg(ESC, MemReg_Reg, 0); break;
case 0xdb: MemRegReg(ESC, MemReg_Reg, 0); break;
case 0xdc: MemRegReg(ESC, MemReg_Reg, 0); break;
case 0xdd: MemRegReg(ESC, MemReg_Reg, 0); break;
case 0xde: MemRegReg(ESC, MemReg_Reg, 0); break;
case 0xdf: MemRegReg(ESC, MemReg_Reg, 0); break;
case 0xe0: Jump(LOOPNE); break;
case 0xe1: Jump(LOOPE); break;
case 0xe2: Jump(LOOP); break;
case 0xe3: Jump(JPCX); break;
case 0xe4: RegAddr(IN, AL, 1, 1); break;
case 0xe5: RegAddr(IN, AX, 2, 1); break;
case 0xe6: AddrReg(OUT, AL, 1, 1); break;
case 0xe7: AddrReg(OUT, AX, 2, 1); break;
case 0xe8: RegData(CALLD, None, 2); break;
case 0xe9: RegData(JMPN, None, 2); break;
case 0xea: Far(JMPF); break;
case 0xeb: Jump(JMPN); break;
case 0xec: Complete(IN, DX, AL, 1); break;
case 0xed: Complete(IN, DX, AX, 1); break;
case 0xee: Complete(OUT, AL, DX, 1); break;
case 0xef: Complete(OUT, AX, DX, 2); break;
case 0xf4: Complete(HLT, None, None, 1); break;
case 0xf5: Complete(CMC, None, None, 1); break;
case 0xf6: MemRegReg(Invalid, MemRegTEST_to_IDIV, 1); break;
case 0xf7: MemRegReg(Invalid, MemRegTEST_to_IDIV, 2); break;
case 0xf8: Complete(CLC, None, None, 1); break;
case 0xf9: Complete(STC, None, None, 1); break;
case 0xfa: Complete(CLI, None, None, 1); break;
case 0xfb: Complete(STI, None, None, 1); break;
case 0xfc: Complete(CLD, None, None, 1); break;
case 0xfd: Complete(STD, None, None, 1); break;
case 0xfe: MemRegReg(Invalid, MemRegINC_DEC, 1); break;
case 0xff: MemRegReg(Invalid, MemRegINC_to_PUSH, 1); break;
// Other prefix bytes.
case 0xf0: lock_ = true; break;
case 0xf2: repetition_ = Repetition::RepNE; break;
case 0xf3: repetition_ = Repetition::RepE; break;
}
}
#undef Far
#undef Jump
#undef MemRegReg
#undef AddrReg
#undef RegAddr
#undef RegData
#undef Complete
#undef SetOpSrcDestSize
// MARK: - ModRegRM byte, if any.
if(phase_ == Phase::ModRegRM && source != end) {
const uint8_t mod = *source >> 6; // i.e. mode.
const uint8_t reg = (*source >> 3) & 7; // i.e. register.
const uint8_t rm = *source & 7; // i.e. register/memory.
++source;
++consumed_;
Source memreg;
constexpr Source reg_table[3][8] = {
{},
{
Source::AL, Source::CL, Source::DL, Source::BL,
Source::AH, Source::CH, Source::DH, Source::BH,
}, {
Source::AX, Source::CX, Source::DX, Source::BX,
Source::SP, Source::BP, Source::SI, Source::DI,
}
};
switch(mod) {
case 0: {
constexpr Source rm_table[8] = {
Source::IndBXPlusSI, Source::IndBXPlusDI,
Source::IndBPPlusSI, Source::IndBPPlusDI,
Source::IndSI, Source::IndDI,
Source::DirectAddress, Source::IndBX,
};
memreg = rm_table[rm];
} break;
default: {
constexpr Source rm_table[8] = {
Source::IndBXPlusSI, Source::IndBXPlusDI,
Source::IndBPPlusSI, Source::IndBPPlusDI,
Source::IndSI, Source::IndDI,
Source::IndBP, Source::IndBX,
};
memreg = rm_table[rm];
displacement_size_ = 1 + (mod == 2);
} break;
// Other operand is just a register.
case 3:
memreg = reg_table[operation_size_][rm];
// LES and LDS accept a memory argument only, not a register.
if(operation_ == Operation::LES || operation_ == Operation::LDS) {
const auto result = std::make_pair(consumed_, Instruction());
reset_parsing();
return result;
}
break;
}
switch(modregrm_format_) {
case ModRegRMFormat::Reg_MemReg:
case ModRegRMFormat::MemReg_Reg: {
if(modregrm_format_ == ModRegRMFormat::Reg_MemReg) {
source_ = memreg;
destination_ = reg_table[operation_size_][reg];
} else {
source_ = reg_table[operation_size_][reg];
destination_ = memreg;
}
} break;
case ModRegRMFormat::MemRegTEST_to_IDIV:
source_ = destination_ = memreg;
switch(reg) {
default: {
const auto result = std::make_pair(consumed_, Instruction());
reset_parsing();
return result;
}
case 0: operation_ = Operation::TEST; break;
case 2: operation_ = Operation::NOT; break;
case 3: operation_ = Operation::NEG; break;
case 4: operation_ = Operation::MUL; break;
case 5: operation_ = Operation::IMUL; break;
case 6: operation_ = Operation::DIV; break;
case 7: operation_ = Operation::IDIV; break;
}
break;
case ModRegRMFormat::SegReg: {
source_ = memreg;
constexpr Source seg_table[4] = {
Source::ES, Source::CS,
Source::SS, Source::DS,
};
if(reg & 4) {
const auto result = std::make_pair(consumed_, Instruction());
reset_parsing();
return result;
}
destination_ = seg_table[reg];
} break;
case ModRegRMFormat::MemRegROL_to_SAR:
destination_ = memreg;
switch(reg) {
default: {
const auto result = std::make_pair(consumed_, Instruction());
reset_parsing();
return result;
}
case 0: operation_ = Operation::ROL; break;
case 2: operation_ = Operation::ROR; break;
case 3: operation_ = Operation::RCL; break;
case 4: operation_ = Operation::RCR; break;
case 5: operation_ = Operation::SAL; break;
case 6: operation_ = Operation::SHR; break;
case 7: operation_ = Operation::SAR; break;
}
break;
case ModRegRMFormat::MemRegINC_DEC:
source_ = destination_ = memreg;
switch(reg) {
default: {
const auto result = std::make_pair(consumed_, Instruction());
reset_parsing();
return result;
}
case 0: operation_ = Operation::INC; break;
case 1: operation_ = Operation::DEC; break;
}
break;
case ModRegRMFormat::MemRegINC_to_PUSH:
source_ = destination_ = memreg;
switch(reg) {
default: {
const auto result = std::make_pair(consumed_, Instruction());
reset_parsing();
return result;
}
case 0: operation_ = Operation::INC; break;
case 1: operation_ = Operation::DEC; break;
case 2: operation_ = Operation::CALLN; break;
case 3:
operation_ = Operation::CALLF;
operand_size_ = 4;
source_ = Source::Immediate;
break;
case 4: operation_ = Operation::JMPN; break;
case 5:
operation_ = Operation::JMPF;
operand_size_ = 4;
source_ = Source::Immediate;
break;
case 6: operation_ = Operation::PUSH; break;
}
break;
case ModRegRMFormat::MemRegPOP:
source_ = destination_ = memreg;
if(reg != 0) {
reset_parsing();
return std::make_pair(consumed_, Instruction());
}
break;
case ModRegRMFormat::MemRegMOV:
source_ = Source::Immediate;
destination_ = memreg;
operand_size_ = operation_size_;
break;
case ModRegRMFormat::MemRegADD_to_CMP:
destination_ = memreg;
operand_size_ = operation_size_;
switch(reg) {
default: operation_ = Operation::ADD; break;
case 1: operation_ = Operation::OR; break;
case 2: operation_ = Operation::ADC; break;
case 3: operation_ = Operation::SBB; break;
case 4: operation_ = Operation::AND; break;
case 5: operation_ = Operation::SUB; break;
case 6: operation_ = Operation::XOR; break;
case 7: operation_ = Operation::CMP; break;
}
break;
case ModRegRMFormat::MemRegADC_to_CMP:
destination_ = memreg;
source_ = Source::Immediate;
operand_size_ = 1; // ... and always 1; it'll be sign extended if
// the operation requires it.
switch(reg) {
default: {
const auto result = std::make_pair(consumed_, Instruction());
reset_parsing();
return result;
}
case 0: operation_ = Operation::ADD; break;
case 2: operation_ = Operation::ADC; break;
case 3: operation_ = Operation::SBB; break;
case 5: operation_ = Operation::SUB; break;
case 7: operation_ = Operation::CMP; break;
}
break;
default: assert(false);
}
phase_ = (displacement_size_ + operand_size_) ? Phase::AwaitingDisplacementOrOperand : Phase::ReadyToPost;
}
// MARK: - Displacement and operand.
if(phase_ == Phase::AwaitingDisplacementOrOperand && source != end) {
const int required_bytes = displacement_size_ + operand_size_;
const int outstanding_bytes = required_bytes - operand_bytes_;
const int bytes_to_consume = std::min(int(end - source), outstanding_bytes);
// TODO: I can surely do better than this?
for(int c = 0; c < bytes_to_consume; c++) {
inward_data_ = (inward_data_ >> 8) | (uint64_t(source[0]) << 56);
++source;
}
consumed_ += bytes_to_consume;
operand_bytes_ += bytes_to_consume;
if(bytes_to_consume == outstanding_bytes) {
phase_ = Phase::ReadyToPost;
switch(operand_size_) {
default: operand_ = 0; break;
case 1:
operand_ = inward_data_ >> 56; inward_data_ <<= 8;
// Sign extend if a single byte operand is feeding a two-byte instruction.
if(operation_size_ == 2 && operation_ != Operation::IN && operation_ != Operation::OUT) {
operand_ |= (operand_ & 0x80) ? 0xff00 : 0x0000;
}
break;
case 4: displacement_size_ = 2; [[fallthrough]];
case 2: operand_ = inward_data_ >> 48; inward_data_ <<= 16; break;
break;
}
switch(displacement_size_) {
default: displacement_ = 0; break;
case 1: displacement_ = int8_t(inward_data_ >> 56); break;
case 2: displacement_ = int16_t(inward_data_ >> 48); break;
}
} else {
// Provide a genuine measure of further bytes required.
return std::make_pair(-(outstanding_bytes - bytes_to_consume), Instruction());
}
}
// MARK: - Check for completion.
if(phase_ == Phase::ReadyToPost) {
const auto result = std::make_pair(
consumed_,
Instruction(
operation_,
source_,
destination_,
lock_,
segment_override_,
repetition_,
Size(operation_size_),
displacement_,
operand_)
);
reset_parsing();
return result;
}
// i.e. not done yet.
return std::make_pair(0, Instruction());
}