1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-04 15:05:36 +00:00
CLK/InstructionSets/M68k/Instruction.hpp

504 lines
14 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.

//
// Instruction.hpp
// Clock Signal
//
// Created by Thomas Harte on 10/04/2022.
// Copyright © 2022 Thomas Harte. All rights reserved.
//
#ifndef InstructionSets_68k_Instruction_hpp
#define InstructionSets_68k_Instruction_hpp
#include "Model.hpp"
#include <cassert>
#include <cstdint>
#include <string>
namespace InstructionSet {
namespace M68k {
enum class Operation: uint8_t {
Undefined,
//
// 68000 operations.
//
NOP,
ABCD, SBCD, NBCD,
ADDb, ADDw, ADDl,
ADDAw, ADDAl,
ADDXb, ADDXw, ADDXl,
SUBb, SUBw, SUBl,
SUBAw, SUBAl,
SUBXb, SUBXw, SUBXl,
MOVEb, MOVEw, MOVEl,
MOVEAw, MOVEAl,
LEA, PEA,
MOVEtoSR, MOVEfromSR,
MOVEtoCCR,
MOVEtoUSP, MOVEfromUSP,
ORItoSR, ORItoCCR,
ANDItoSR, ANDItoCCR,
EORItoSR, EORItoCCR,
BTST, BCLR,
BCHG, BSET,
CMPb, CMPw, CMPl,
CMPAw, CMPAl,
TSTb, TSTw, TSTl,
JMP,
JSR, RTS,
DBcc,
Scc,
Bccb, Bccw,
BSRb, BSRw,
CLRb, CLRw, CLRl,
NEGXb, NEGXw, NEGXl,
NEGb, NEGw, NEGl,
ASLb, ASLw, ASLl, ASLm,
ASRb, ASRw, ASRl, ASRm,
LSLb, LSLw, LSLl, LSLm,
LSRb, LSRw, LSRl, LSRm,
ROLb, ROLw, ROLl, ROLm,
RORb, RORw, RORl, RORm,
ROXLb, ROXLw, ROXLl, ROXLm,
ROXRb, ROXRw, ROXRl, ROXRm,
MOVEMtoRl, MOVEMtoRw,
MOVEMtoMl, MOVEMtoMw,
MOVEPl, MOVEPw,
ANDb, ANDw, ANDl,
EORb, EORw, EORl,
NOTb, NOTw, NOTl,
ORb, ORw, ORl,
MULUw, MULSw,
DIVUw, DIVSw,
RTE, RTR,
TRAP, TRAPV,
CHKw,
EXG, SWAP,
TAS,
EXTbtow, EXTwtol,
LINKw, UNLINK,
STOP, RESET,
//
// 68010 additions.
//
MOVEfromCCR,
MOVEtoC, MOVEfromC,
MOVESb, MOVESw, MOVESl,
BKPT, RTD,
//
// 68020 additions.
//
TRAPcc,
CALLM, RTM,
BFCHG, BFCLR,
BFEXTS, BFEXTU,
BFFFO, BFINS,
BFSET, BFTST,
PACK, UNPK,
CASb, CASw, CASl,
CAS2w, CAS2l,
// CHK2 and CMP2 are distinguished by their extension word;
// since this code deals in Preinstructions, i.e. as much
// as can be derived from the instruction word alone, in addition
// to the full things, the following enums result.
CHKorCMP2b, CHKorCMP2w, CHKorCMP2l,
// DIVS.l, DIVSL.l, DIVU.l and DIVUL.l are all distinguishable
// only by the extension word.
DIVSorDIVUl,
// MULS.l, MULSL.l, MULU.l and MULUL.l are all distinguishable
// only by the extension word.
MULSorMULUl,
Bccl, BSRl,
LINKl, CHKl,
EXTbtol,
// Coprocessor instructions are omitted for now, until I can
// determine by what mechanism the number of
// "OPTIONAL COPROCESSOR-DEFINED EXTENSION WORDS" is determined.
// cpBcc, cpDBcc, cpGEN,
// cpScc, cpTRAPcc, cpRESTORE,
// cpSAVE,
//
// 68030 additions.
//
PFLUSH, PFLUSHA,
PLOADR, PLOADW,
PMOVE, PMOVEFD,
PTESTR, PTESTW,
//
// 68040 additions.
//
// TODO: the big addition of the 68040 is incorporation of the FPU; should I make decoding of those instructions
// dependent upon a 68040 being selected, or should I offer a separate decoder in order to support systems with
// a coprocessor?
//
// Introspection.
//
Max68000 = RESET,
Max68010 = RTD,
Max68020 = EXTbtol,
Max68030 = PTESTW,
Max68040 = PTESTW,
};
// Provide per-model max entries in Operation.
template <Model> struct OperationMax {};
template <> struct OperationMax<Model::M68000> {
static constexpr Operation value = Operation::Max68000;
};
template <> struct OperationMax<Model::M68010> {
static constexpr Operation value = Operation::Max68010;
};
template <> struct OperationMax<Model::M68020> {
static constexpr Operation value = Operation::Max68020;
};
template <> struct OperationMax<Model::M68030> {
static constexpr Operation value = Operation::Max68030;
};
template <> struct OperationMax<Model::M68040> {
static constexpr Operation value = Operation::Max68040;
};
const char *to_string(Operation op);
template <Model model>
constexpr bool requires_supervisor(Operation op) {
switch(op) {
case Operation::MOVEfromSR:
if constexpr (model == Model::M68000) {
return false;
}
[[fallthrough]];
case Operation::ORItoSR: case Operation::ANDItoSR:
case Operation::EORItoSR: case Operation::RTE:
case Operation::RESET: case Operation::STOP:
case Operation::MOVEtoUSP: case Operation::MOVEfromUSP:
case Operation::MOVEtoC: case Operation::MOVEfromC:
case Operation::MOVEtoSR:
return true;
default:
return false;
}
}
enum class DataSize {
Byte = 0,
Word = 1,
LongWord = 2,
};
/// Classifies operations by the size of their memory accesses, if any.
///
/// For any operations that don't fit the neat model of reading one or two operands,
/// then writing zero or one, the size determines the data size of the operands only,
/// not any other accesses.
template <Operation t_operation = Operation::Undefined>
constexpr DataSize operand_size(Operation operation = Operation::Undefined);
template <Operation t_op = Operation::Undefined>
constexpr uint32_t quick(uint16_t instruction, Operation r_op = Operation::Undefined) {
switch((t_op != Operation::Undefined) ? t_op : r_op) {
case Operation::Bccb:
case Operation::BSRb:
case Operation::MOVEl: return uint32_t(int8_t(instruction));
case Operation::TRAP: return uint32_t(instruction & 15);
case Operation::BKPT: return uint32_t(instruction & 7);
default: {
uint32_t value = (instruction >> 9) & 7;
value |= (value - 1)&8;
return value;
}
}
}
static constexpr uint8_t FetchOp1 = (1 << 0);
static constexpr uint8_t FetchOp2 = (1 << 1);
static constexpr uint8_t StoreOp1 = (1 << 2);
static constexpr uint8_t StoreOp2 = (1 << 3);
/*!
Provides a bitfield with a value in the range 015 indicating which of the provided operation's
operands are accessed via standard fetch and store cycles; the bitfield is composted of
[Fetch/Store]Op[1/2] as defined above.
Unusual bus sequences, such as TAS or MOVEM, are not described here.
*/
template <Model model, Operation t_operation = Operation::Undefined>
constexpr uint8_t operand_flags(Operation r_operation = Operation::Undefined);
/// Lists the various condition codes used by the 680x0.
enum class Condition {
True = 0x00, False = 0x01,
High = 0x02, LowOrSame = 0x03,
CarryClear = 0x04, CarrySet = 0x05,
NotEqual = 0x06, Equal = 0x07,
OverflowClear = 0x08, OverflowSet = 0x09,
Positive = 0x0a, Negative = 0x0b,
GreaterThanOrEqual = 0x0c, LessThan = 0x0d,
GreaterThan = 0x0e, LessThanOrEqual = 0x0f,
};
/// Indicates the addressing mode applicable to an operand.
///
/// Implementation notes:
///
/// Those entries starting 0b00 or 0b01 are mapped as per the 68000's native encoding;
/// those starting 0b00 are those which are indicated directly by a mode field and those starting
/// 0b01 are those which are indicated by a register field given a mode of 0b111. The only minor
/// exception is AddressRegisterDirect, which exists on a 68000 but isn't specifiable by a
/// mode and register, it's contextual based on the instruction.
///
/// Those modes starting in 0b10 are the various extended addressing modes introduced as
/// of the 68020, which can be detected only after interpreting an extension word. At the
/// Preinstruction stage:
///
/// * AddressRegisterIndirectWithIndexBaseDisplacement, MemoryIndirectPostindexed
/// and MemoryIndirectPreindexed will have been partially decoded as
/// AddressRegisterIndirectWithIndex8bitDisplacement; and
/// * ProgramCounterIndirectWithIndexBaseDisplacement,
/// ProgramCounterMemoryIndirectPostindexed and
/// ProgramCounterMemoryIndirectPreindexed will have been partially decoded
/// as ProgramCounterIndirectWithIndex8bitDisplacement.
enum class AddressingMode: uint8_t {
/// No adddressing mode; this operand doesn't exist.
None = 0b01'101,
/// Dn
DataRegisterDirect = 0b00'000,
/// An
AddressRegisterDirect = 0b00'001,
/// (An)
AddressRegisterIndirect = 0b00'010,
/// (An)+
AddressRegisterIndirectWithPostincrement = 0b00'011,
/// -(An)
AddressRegisterIndirectWithPredecrement = 0b00'100,
/// (d16, An)
AddressRegisterIndirectWithDisplacement = 0b00'101,
/// (d8, An, Xn)
AddressRegisterIndirectWithIndex8bitDisplacement = 0b00'110,
/// (bd, An, Xn) [68020+]
AddressRegisterIndirectWithIndexBaseDisplacement = 0b10'000,
/// ([bd, An, Xn], od) [68020+]
MemoryIndirectPostindexed = 0b10'001,
/// ([bd, An], Xn, od) [68020+]
MemoryIndirectPreindexed = 0b10'010,
/// (d16, PC)
ProgramCounterIndirectWithDisplacement = 0b01'010,
/// (d8, PC, Xn)
ProgramCounterIndirectWithIndex8bitDisplacement = 0b01'011,
/// (bd, PC, Xn) [68020+]
ProgramCounterIndirectWithIndexBaseDisplacement = 0b10'011,
/// ([bd, PC, Xn], od) [68020+]
ProgramCounterMemoryIndirectPostindexed = 0b10'100,
/// ([bc, PC], Xn, od) [68020+]
ProgramCounterMemoryIndirectPreindexed = 0b10'101,
/// (xxx).W
AbsoluteShort = 0b01'000,
/// (xxx).L
AbsoluteLong = 0b01'001,
/// #
ImmediateData = 0b01'100,
/// An additional word of data. Differs from ImmediateData by being
/// a fixed size, rather than the @c operand_size of the operation.
ExtensionWord = 0b01'111,
/// .q; value is embedded in the opcode.
Quick = 0b01'110,
};
/// Guaranteed to be 1+[largest value used by AddressingMode].
static constexpr int AddressingModeCount = 0b10'110;
/*!
A preinstruction is as much of an instruction as can be decoded with
only the first instruction word — i.e. an operation, and:
* on the 68000 and 68010, the complete addressing modes;
* on subsequent, a decent proportion of the addressing mode. See
the notes on @c AddressingMode for potential aliasing.
*/
class Preinstruction {
public:
Operation operation = Operation::Undefined;
// Instructions come with 0, 1 or 2 operands;
// the getters below act to provide a list of operands
// that is terminated by an AddressingMode::None.
//
// For two-operand instructions, argument 0 is a source
// and argument 1 is a destination.
//
// For one-operand instructions, only argument 0 will
// be provided, and will be a source and/or destination as
// per the semantics of the operation.
//
// The versions templated on index do a range check;
// if using the runtime versions then results for indices
// other than 0 and 1 are undefined.
AddressingMode mode(int index) const {
return AddressingMode(operands_[index] >> 3);
}
template <int index> AddressingMode mode() const {
if constexpr (index > 1) {
return AddressingMode::None;
}
return mode(index);
}
int reg(int index) const {
return operands_[index] & 7;
}
template <int index> int reg() const {
if constexpr (index > 1) {
return 0;
}
return reg(index);
}
/// @returns 07 to indicate data registers 0 to 7, or 815 to indicate address registers 0 to 7 respectively.
/// Provides undefined results if the addressing mode is not either @c DataRegisterDirect or
/// @c AddressRegisterDirect.
int lreg(int index) const {
return operands_[index] & 0xf;
}
/// @returns @c true if this instruction requires supervisor privileges; @c false otherwise.
bool requires_supervisor() const {
return flags_ & Flags::IsSupervisor;
}
/// @returns @c true if this instruction will require further fetching than can be encoded in a
/// @c Preinstruction. In practice this means it is one of a very small quantity of 68020+
/// instructions; those that can rationalise extension words into one of the two operands will
/// do so. Use the free function @c extension_words(instruction.operation) to
/// look up the number of additional words required.
///
/// (specifically affected, at least: PACK, UNPK, CAS, CAS2)
bool requires_further_extension() const {
return flags_ & Flags::RequiresFurtherExtension;
}
/// @returns The number of additional extension words required, beyond those encoded as operands.
int additional_extension_words() const {
return flags_ & Flags::RequiresFurtherExtension ? (flags_ & Flags::ConditionMask) >> Flags::ConditionShift : 0;
}
/// @returns The @c DataSize used for operands of this instruction, i.e. byte, word or longword.
DataSize operand_size() const {
return DataSize((flags_ & Flags::SizeMask) >> Flags::SizeShift);
}
/// @returns The condition code evaluated by this instruction if applicable. If this instruction is not
/// conditional, the result is undefined.
Condition condition() const {
return Condition((flags_ & Flags::ConditionMask) >> Flags::ConditionShift);
}
private:
uint8_t operands_[2] = { uint8_t(AddressingMode::None), uint8_t(AddressingMode::None)};
uint8_t flags_ = 0;
std::string operand_description(int index, int opcode) const;
public:
Preinstruction(
Operation operation,
AddressingMode op1_mode, int op1_reg,
AddressingMode op2_mode, int op2_reg,
bool is_supervisor,
int extension_words,
DataSize size,
Condition condition) : operation(operation)
{
operands_[0] = uint8_t((uint8_t(op1_mode) << 3) | op1_reg);
operands_[1] = uint8_t((uint8_t(op2_mode) << 3) | op2_reg);
flags_ = uint8_t(
(is_supervisor ? Flags::IsSupervisor : 0x00) |
(extension_words ? Flags::RequiresFurtherExtension : 0x00) |
(int(condition) << Flags::ConditionShift) |
(extension_words << Flags::ConditionShift) |
(int(size) << Flags::SizeShift)
);
}
struct Flags {
static constexpr uint8_t IsSupervisor = 0b1000'0000;
static constexpr uint8_t RequiresFurtherExtension = 0b0100'0000;
static constexpr uint8_t ConditionMask = 0b0011'1100;
static constexpr uint8_t SizeMask = 0b0000'0011;
static constexpr int IsSupervisorShift = 7;
static constexpr int RequiresFurtherExtensionShift = 6;
static constexpr int ConditionShift = 2;
static constexpr int SizeShift = 0;
};
Preinstruction() {}
/// Produces a string description of this instruction; if @c opcode
/// is supplied then any quick fields in this instruction will be decoded;
/// otherwise they'll be printed as just 'Q'.
std::string to_string(int opcode = -1) const;
/// Produces a slightly-more-idiomatic version of the operation name than
/// a direct to_string(instruction.operation) would, given that this decoder
/// sometimes aliases operations, disambiguating based on addressing mode
/// (e.g. MOVEQ is MOVE.l with the Q addressing mode).
const char *operation_string() const;
};
}
}
#include "Implementation/InstructionOperandSize.hpp"
#include "Implementation/InstructionOperandFlags.hpp"
#endif /* InstructionSets_68k_Instruction_hpp */