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CLK/InstructionSets/x86/Instruction.hpp
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

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//
// Instruction.hpp
// Clock Signal
//
// Created by Thomas Harte on 15/01/21.
// Copyright © 2021 Thomas Harte. All rights reserved.
//
#ifndef InstructionSets_x86_Instruction_h
#define InstructionSets_x86_Instruction_h
#include <cstdint>
namespace InstructionSet {
namespace x86 {
/*
Operations are documented below to establish expectations as to which
instruction fields will be meaningful for each; this is a work-in-progress
and may currently contain errors in the opcode descriptions — especially
where implicit register dependencies are afoot.
*/
enum class Operation: uint8_t {
Invalid,
/// ASCII adjust after addition; source will be AL and destination will be AX.
AAA,
/// ASCII adjust before division; destination will be AX and source will be a multiplier.
AAD,
/// ASCII adjust after multiplication; destination will be AX and source will be a divider.
AAM,
/// ASCII adjust after subtraction; source will be AL and destination will be AX.
AAS,
/// Decimal adjust after addition; source and destination will be AL.
DAA,
/// Decimal adjust after subtraction; source and destination will be AL.
DAS,
/// Convert byte into word; source will be AL, destination will be AH.
CBW,
/// Convert word to double word; source will be AX and destination will be DX.
CWD,
/// Escape, for a coprocessor; perform the bus cycles necessary to read the source and destination and perform a NOP.
ESC,
/// Stops the processor until the next interrupt is fired.
HLT,
/// Waits until the WAIT input is asserted; if an interrupt occurs then it is serviced but returns to the WAIT.
WAIT,
/// Add with carry; source, destination, operand and displacement will be populated appropriately.
ADC,
/// Add; source, destination, operand and displacement will be populated appropriately.
ADD,
/// Subtract with borrow; source, destination, operand and displacement will be populated appropriately.
SBB,
/// Subtract; source, destination, operand and displacement will be populated appropriately.
SUB,
/// Unsigned multiply; multiplies the source value by AX or AL, storing the result in DX:AX or AX.
MUL,
/// Signed multiply; multiplies the source value by AX or AL, storing the result in DX:AX or AX.
IMUL,
/// Unsigned divide; divide the source value by AX or AL, storing the quotient in AL and the remainder in AH.
DIV,
/// Signed divide; divide the source value by AX or AL, storing the quotient in AL and the remainder in AH.
IDIV,
/// Increment; source, destination, operand and displacement will be populated appropriately.
INC,
/// Decrement; source, destination, operand and displacement will be populated appropriately.
DEC,
/// Reads from the port specified by source to the destination.
IN,
/// Writes from the port specified by destination from the source.
OUT,
// Various jumps; see the displacement to calculate targets.
JO, JNO, JB, JNB, JE, JNE, JBE, JNBE,
JS, JNS, JP, JNP, JL, JNL, JLE, JNLE,
/// Far call; see the segment() and offset() fields.
CALLF,
/// Displacement call; followed by a 16-bit operand providing a call offset.
CALLD,
/// Near call.
CALLN,
/// Return from interrupt.
IRET,
/// Near return; if source is not ::None then it will be an ::Immediate indicating how many additional bytes to remove from the stack.
RETF,
/// Far return; if source is not ::None then it will be an ::Immediate indicating how many additional bytes to remove from the stack.
RETN,
/// Near jump; if an operand is not ::None then it gives an absolute destination; otherwise see the displacement.
JMPN,
/// Far jump to the indicated segment and offset.
JMPF,
/// Relative jump performed only if CX = 0; see the displacement.
JPCX,
/// Generates a software interrupt of the level stated in the operand.
INT,
/// Generates a software interrupt of level 3.
INT3,
/// Generates a software interrupt of level 4 if overflow is set.
INTO,
/// Load status flags to AH.
LAHF,
/// Load status flags from AH.
SAHF,
/// Load a segment and offset from the source into DS and the destination.
LDS,
/// Load a segment and offset from the source into ES and the destination.
LES,
/// Computes the effective address of the source and loads it into the destination.
LEA,
/// Compare [bytes or words, per operation size]; source and destination implied to be DS:[SI] and ES:[DI].
CMPS,
/// Load string; reads from DS:SI into AL or AX, subject to segment override.
LODS,
/// Move string; moves a byte or word from DS:SI to ES:DI. If a segment override is provided, it overrides the the source.
MOVS,
/// Scan string; reads a byte or word from DS:SI and compares it to AL or AX.
SCAS,
/// Store string; store AL or AX to ES:DI.
STOS,
// Perform a possibly-conditional loop, decrementing CX. See the displacement.
LOOP, LOOPE, LOOPNE,
/// Loads the destination with the source.
MOV,
/// Negatives; source and destination point to the same thing, to negative.
NEG,
/// Logical NOT; source and destination point to the same thing, to negative.
NOT,
/// Logical AND; source, destination, operand and displacement will be populated appropriately.
AND,
/// Logical OR of source onto destination.
OR,
/// Logical XOR of source onto destination.
XOR,
/// NOP; no further fields.
NOP,
/// POP from the stack to destination.
POP,
/// POP from the stack to the flags register.
POPF,
/// PUSH the source to the stack.
PUSH,
/// PUSH the flags register to the stack.
PUSHF,
/// Rotate the destination left through carry the number of bits indicated by source.
RCL,
/// Rotate the destination right through carry the number of bits indicated by source.
RCR,
/// Rotate the destination left the number of bits indicated by source.
ROL,
/// Rotate the destination right the number of bits indicated by source.
ROR,
/// Arithmetic shift left the destination by the number of bits indicated by source.
SAL,
/// Arithmetic shift right the destination by the number of bits indicated by source.
SAR,
/// Logical shift right the destination by the number of bits indicated by source.
SHR,
/// Clear carry flag; no source or destination provided.
CLC,
/// Clear direction flag; no source or destination provided.
CLD,
/// Clear interrupt flag; no source or destination provided.
CLI,
/// Set carry flag.
STC,
/// Set decimal flag.
STD,
/// Set interrupt flag.
STI,
/// Complement carry flag; no source or destination provided.
CMC,
/// Compare; source, destination, operand and displacement will be populated appropriately.
CMP,
/// Sets flags based on the result of a logical AND of source and destination.
TEST,
/// Exchanges the contents of the source and destination.
XCHG,
/// Load AL with DS:[AL+BX].
XLAT,
};
enum class Size: uint8_t {
Implied = 0,
Byte = 1,
Word = 2,
DWord = 4,
};
enum class Source: uint8_t {
None,
CS, DS, ES, SS,
AL, AH, AX,
BL, BH, BX,
CL, CH, CX,
DL, DH, DX,
SI, DI,
BP, SP,
IndBXPlusSI,
IndBXPlusDI,
IndBPPlusSI,
IndBPPlusDI,
IndSI,
IndDI,
DirectAddress,
IndBP,
IndBX,
Immediate
};
enum class Repetition: uint8_t {
None, RepE, RepNE
};
class Instruction {
public:
Operation operation = Operation::Invalid;
bool operator ==(const Instruction &rhs) const {
return
repetition_size_ == rhs.repetition_size_ &&
sources_ == rhs.sources_ &&
displacement_ == rhs.displacement_ &&
operand_ == rhs.operand_;
}
private:
// b0, b1: a Repetition;
// b2+: operation size.
uint8_t repetition_size_ = 0;
// b0b5: source;
// b6b11: destination;
// b12b14: segment override;
// b15: lock.
uint16_t sources_ = 0;
// Unpackable fields.
int16_t displacement_ = 0;
uint16_t operand_ = 0; // ... or used to store a segment for far operations.
public:
Source source() const { return Source(sources_ & 0x3f); }
Source destination() const { return Source((sources_ >> 6) & 0x3f); }
bool lock() const { return sources_ & 0x8000; }
Source segment_override() const { return Source((sources_ >> 12) & 7); }
Repetition repetition() const { return Repetition(repetition_size_ & 3); }
Size operation_size() const { return Size(repetition_size_ >> 2); }
uint16_t segment() const { return uint16_t(operand_); }
uint16_t offset() const { return uint16_t(displacement_); }
int16_t displacement() const { return displacement_; }
uint16_t operand() const { return operand_; }
Instruction() noexcept {}
Instruction(
Operation operation,
Source source,
Source destination,
bool lock,
Source segment_override,
Repetition repetition,
Size operation_size,
int16_t displacement,
uint16_t operand) noexcept :
operation(operation),
repetition_size_(uint8_t((int(operation_size) << 2) | int(repetition))),
sources_(uint16_t(
int(source) |
(int(destination) << 6) |
(int(segment_override) << 12) |
(int(lock) << 15)
)),
displacement_(displacement),
operand_(operand) {}
};
static_assert(sizeof(Instruction) <= 8);
}
}
#endif /* InstructionSets_x86_Instruction_h */