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CLK/Processors/Z80/Z80.hpp

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//
// Z80.hpp
// Clock Signal
//
// Created by Thomas Harte on 14/05/2017.
// Copyright © 2017 Thomas Harte. All rights reserved.
//
#ifndef Z80_hpp
#define Z80_hpp
#include <cstdint>
#include <cstring>
#include <cstdio>
#include <vector>
#include "../MicroOpScheduler.hpp"
#include "../RegisterSizes.hpp"
namespace CPU {
namespace Z80 {
/*
The list of registers that can be accessed via @c set_value_of_register and @c set_value_of_register.
*/
enum Register {
ProgramCounter,
StackPointer,
A, Flags, AF,
B, C, BC,
D, E, DE,
H, L, HL,
ADash, FlagsDash, AFDash,
BDash, CDash, BCDash,
DDash, EDash, DEDash,
HDash, LDash, HLDash,
IXh, IXl, IX,
IYh, IYl, IY,
R, I,
IFF1, IFF2, IM
};
/*
Flags as defined on the Z80; can be used to decode the result of @c get_flags or to form a value for @c set_flags.
*/
enum Flag: uint8_t {
Sign = 0x80,
Zero = 0x40,
Bit5 = 0x20,
HalfCarry = 0x10,
Bit3 = 0x08,
Parity = 0x04,
Overflow = 0x04,
Subtract = 0x02,
Carry = 0x01
};
/*!
Subclasses will be given the task of performing bus operations, allowing them to provide whatever interface they like
between a Z80 and the rest of the system. @c BusOperation lists the types of bus operation that may be requested.
*/
enum BusOperation {
ReadOpcode = 0,
Read, Write,
Input, Output,
Interrupt,
// BusRequest, BusAcknowledge,
Internal
};
struct MachineCycle {
BusOperation operation;
int length;
uint16_t *address;
uint8_t *value;
};
struct MicroOp {
enum Type {
BusOperation,
DecodeOperation,
MoveToNextProgram,
Increment8,
Increment16,
Decrement8,
Decrement16,
Move8,
Move16,
AssembleAF,
DisassembleAF,
And,
Or,
Xor,
TestNZ,
TestZ,
TestNC,
TestC,
TestPO,
TestPE,
TestP,
TestM,
ADD16, ADC16, SBC16,
CP8, SUB8, SBC8, ADD8, ADC8,
NEG,
ExDEHL, ExAFAFDash, EXX,
EI, DI, IM,
LDI, LDIR, LDD, LDDR,
CPI, CPIR, CPD, CPDR,
INI, INIR, IND, INDR,
OUTI, OUTD, OUT_R,
RLA, RLCA, RRA, RRCA,
RLC, RRC, RL, RR,
SLA, SRA, SLL, SRL,
RLD, RRD,
SetInstructionPage,
CalculateIndexAddress,
RETN,
HALT,
DJNZ,
DAA,
CPL,
SCF,
CCF,
RES,
BIT,
SET,
CalculateRSTDestination,
SetAFlags,
SetInFlags,
SetZero,
IndexedPlaceHolder
};
Type type;
void *source;
void *destination;
MachineCycle machine_cycle;
};
/*!
@abstact An abstract base class for emulation of a Z80 processor via the curiously recurring template pattern/f-bounded polymorphism.
@discussion Subclasses should implement @c perform_machine_cycle in
order to provide the bus on which the Z80 operates and @c flush(), which is called upon completion of a continuous run
of cycles to allow a subclass to bring any on-demand activities up to date.
*/
template <class T> class Processor: public MicroOpScheduler<MicroOp> {
private:
uint8_t a_, i_, r_;
RegisterPair bc_, de_, hl_;
RegisterPair afDash_, bcDash_, deDash_, hlDash_;
RegisterPair ix_, iy_, pc_, sp_;
bool iff1_, iff2_;
int interrupt_mode_;
uint8_t sign_result_; // the sign flag is set if the value in sign_result_ is negative
uint8_t zero_result_; // the zero flag is set if the value in zero_result_ is zero
uint8_t half_carry_result_; // the half-carry flag is set if bit 4 of half_carry_result_ is set
uint8_t bit53_result_; // the bit 3 and 5 flags are set if the corresponding bits of bit53_result_ are set
uint8_t parity_overflow_result_; // the parity/overflow flag is set if the corresponding bit of parity_overflow_result_ is set
uint8_t subtract_flag_; // contains a copy of the subtract flag in isolation
uint8_t carry_result_; // the carry flag is set if bit 0 of carry_result_ is set
uint8_t halt_mask_;
int number_of_cycles_;
uint8_t operation_;
RegisterPair temp16_;
uint8_t temp8_;
struct InstructionPage {
std::vector<MicroOp *> instructions;
std::vector<MicroOp> all_operations;
std::vector<MicroOp> fetch_decode_execute;
uint8_t r_step_;
InstructionPage() : r_step_(1) {}
};
InstructionPage *current_instruction_page_;
InstructionPage base_page_;
InstructionPage ed_page_;
InstructionPage fd_page_;
InstructionPage dd_page_;
InstructionPage cb_page_;
InstructionPage fdcb_page_;
InstructionPage ddcb_page_;
#define NOP {MicroOp::MoveToNextProgram}
#define INDEX() {MicroOp::IndexedPlaceHolder}, FETCH(temp8_, pc_), WAIT(5), {MicroOp::CalculateIndexAddress, &index}
#define FINDEX() {MicroOp::IndexedPlaceHolder}, FETCH(temp8_, pc_), {MicroOp::CalculateIndexAddress, &index}
#define INDEX_ADDR() (add_offsets ? temp16_ : index)
/// Fetches into x from address y, and then increments y.
#define FETCH(x, y) {MicroOp::BusOperation, nullptr, nullptr, {Read, 3, &y.full, &x}}, {MicroOp::Increment16, &y.full}
/// Fetches into x from address y.
#define FETCHL(x, y) {MicroOp::BusOperation, nullptr, nullptr, {Read, 3, &y.full, &x}}
/// Stores x to address y, and then increments y.
#define STORE(x, y) {MicroOp::BusOperation, nullptr, nullptr, {Write, 3, &y.full, &x}}, {MicroOp::Increment16, &y.full}
/// Stores x to address y.
#define STOREL(x, y) {MicroOp::BusOperation, nullptr, nullptr, {Write, 3, &y.full, &x}}
/// Fetches the 16-bit quantity x from address y, incrementing y twice.
#define FETCH16(x, y) FETCH(x.bytes.low, y), FETCH(x.bytes.high, y)
/// Fetches the 16-bit quantity x from address y, incrementing y once.
#define FETCH16L(x, y) FETCH(x.bytes.low, y), FETCHL(x.bytes.high, y)
/// Stores the 16-bit quantity x to address y, incrementing y once.
#define STORE16L(x, y) STORE(x.bytes.low, y), STOREL(x.bytes.high, y)
/// Outputs the 8-bit value to the 16-bit port
#define OUT(port, value) {MicroOp::BusOperation, nullptr, nullptr, {Output, 4, &port.full, &value}}
/// Inputs the 8-bit value from the 16-bit port
#define IN(port, value) {MicroOp::BusOperation, nullptr, nullptr, {Input, 4, &port.full, &value}}
#define PUSH(x) {MicroOp::Decrement16, &sp_.full}, STOREL(x.bytes.high, sp_), {MicroOp::Decrement16, &sp_.full}, STOREL(x.bytes.low, sp_)
#define POP(x) FETCHL(x.bytes.low, sp_), {MicroOp::Increment16, &sp_.full}, FETCHL(x.bytes.high, sp_), {MicroOp::Increment16, &sp_.full}
#define JP(cc) Program(FETCH16(temp16_, pc_), {MicroOp::cc}, {MicroOp::Move16, &temp16_.full, &pc_.full})
#define CALL(cc) Program(FETCH16(temp16_, pc_), {MicroOp::cc}, WAIT(1), PUSH(pc_), {MicroOp::Move16, &temp16_.full, &pc_.full})
#define RET(cc) Program(WAIT(1), {MicroOp::cc}, POP(pc_))
#define JR(cc) Program(FETCH(temp8_, pc_), {MicroOp::cc}, WAIT(5), {MicroOp::CalculateIndexAddress, &pc_.full}, {MicroOp::Move16, &temp16_.full, &pc_.full})
#define RST() Program(WAIT(1), {MicroOp::CalculateRSTDestination}, PUSH(pc_), {MicroOp::Move16, &temp16_.full, &pc_.full})
#define LD(a, b) Program({MicroOp::Move8, &b, &a})
#define LD_GROUP(r, ri) \
LD(r, bc_.bytes.high), LD(r, bc_.bytes.low), LD(r, de_.bytes.high), LD(r, de_.bytes.low), \
LD(r, index.bytes.high), LD(r, index.bytes.low), Program(INDEX(), FETCHL(ri, INDEX_ADDR())), LD(r, a_)
#define READ_OP_GROUP(op) \
Program({MicroOp::op, &bc_.bytes.high}), Program({MicroOp::op, &bc_.bytes.low}), \
Program({MicroOp::op, &de_.bytes.high}), Program({MicroOp::op, &de_.bytes.low}), \
Program({MicroOp::op, &index.bytes.high}), Program({MicroOp::op, &index.bytes.low}), \
Program(INDEX(), FETCHL(temp8_, INDEX_ADDR()), {MicroOp::op, &temp8_}), \
Program({MicroOp::op, &a_})
#define RMW(x, op, ...) Program(INDEX(), FETCHL(x, INDEX_ADDR()), {MicroOp::op, &x}, WAIT(1), STOREL(x, INDEX_ADDR()))
#define RMWI(x, op, ...) Program(WAIT(2), FETCHL(x, INDEX_ADDR()), {MicroOp::op, &x}, WAIT(1), STOREL(x, INDEX_ADDR()))
#define MODIFY_OP_GROUP(op) \
Program({MicroOp::op, &bc_.bytes.high}), Program({MicroOp::op, &bc_.bytes.low}), \
Program({MicroOp::op, &de_.bytes.high}), Program({MicroOp::op, &de_.bytes.low}), \
Program({MicroOp::op, &index.bytes.high}), Program({MicroOp::op, &index.bytes.low}), \
RMW(temp8_, op), \
Program({MicroOp::op, &a_})
#define IX_MODIFY_OP_GROUP(op) \
RMWI(bc_.bytes.high, op), \
RMWI(bc_.bytes.low, op), \
RMWI(de_.bytes.high, op), \
RMWI(de_.bytes.low, op), \
RMWI(hl_.bytes.high, op), \
RMWI(hl_.bytes.low, op), \
RMWI(temp8_, op), \
RMWI(a_, op)
#define IX_READ_OP_GROUP(op) \
Program(WAIT(2), FETCHL(temp8_, INDEX_ADDR()), {MicroOp::op, &temp8_}, WAIT(1)), \
Program(WAIT(2), FETCHL(temp8_, INDEX_ADDR()), {MicroOp::op, &temp8_}, WAIT(1)), \
Program(WAIT(2), FETCHL(temp8_, INDEX_ADDR()), {MicroOp::op, &temp8_}, WAIT(1)), \
Program(WAIT(2), FETCHL(temp8_, INDEX_ADDR()), {MicroOp::op, &temp8_}, WAIT(1)), \
Program(WAIT(2), FETCHL(temp8_, INDEX_ADDR()), {MicroOp::op, &temp8_}, WAIT(1)), \
Program(WAIT(2), FETCHL(temp8_, INDEX_ADDR()), {MicroOp::op, &temp8_}, WAIT(1)), \
Program(WAIT(2), FETCHL(temp8_, INDEX_ADDR()), {MicroOp::op, &temp8_}, WAIT(1)), \
Program(WAIT(2), FETCHL(temp8_, INDEX_ADDR()), {MicroOp::op, &temp8_}, WAIT(1))
#define ADD16(d, s) Program(WAIT(4), WAIT(3), {MicroOp::ADD16, &s.full, &d.full})
#define ADC16(d, s) Program(WAIT(4), WAIT(3), {MicroOp::ADC16, &s.full, &d.full})
#define SBC16(d, s) Program(WAIT(4), WAIT(3), {MicroOp::SBC16, &s.full, &d.full})
#define WAIT(n) {MicroOp::BusOperation, nullptr, nullptr, {Internal, n} }
#define Program(...) { __VA_ARGS__, {MicroOp::MoveToNextProgram} }
typedef MicroOp InstructionTable[256][20];
void assemble_page(InstructionPage &target, InstructionTable &table, bool add_offsets) {
size_t number_of_micro_ops = 0;
size_t lengths[256];
// Count number of micro-ops required.
for(int c = 0; c < 256; c++) {
size_t length = 0;
while(table[c][length].type != MicroOp::MoveToNextProgram) length++;
length++;
lengths[c] = length;
number_of_micro_ops += length;
}
// Allocate a landing area.
target.all_operations.resize(number_of_micro_ops);
target.instructions.resize(256, nullptr);
// Copy in all programs and set pointers.
size_t destination = 0;
for(int c = 0; c < 256; c++) {
target.instructions[c] = &target.all_operations[destination];
for(int t = 0; t < lengths[c];) {
// Skip zero-length bus cycles.
if(table[c][t].type == MicroOp::BusOperation && table[c][t].machine_cycle.length == 0) {
t++;
continue;
}
// If an index placeholder is hit then drop it, and if offsets aren't being added,
// then also drop the indexing that follows, which is assumed to be everything
// up to and including the next ::CalculateIndexAddress. Coupled to the INDEX() macro.
if(table[c][t].type == MicroOp::IndexedPlaceHolder) {
t++;
if(!add_offsets) {
while(table[c][t].type != MicroOp::CalculateIndexAddress) t++;
t++;
}
}
target.all_operations[destination] = table[c][t];
destination++;
t++;
}
}
}
void assemble_ed_page(InstructionPage &target) {
#define IN_C(r) Program(IN(bc_, r), {MicroOp::SetInFlags, &r})
#define OUT_C(r) Program(OUT(bc_, r))
#define IN_OUT(r) IN_C(r), OUT_C(r)
#define NOP_ROW() NOP, NOP, NOP, NOP, NOP, NOP, NOP, NOP, NOP, NOP, NOP, NOP, NOP, NOP, NOP, NOP
InstructionTable ed_program_table = {
NOP_ROW(), /* 0x00 */
NOP_ROW(), /* 0x10 */
NOP_ROW(), /* 0x20 */
NOP_ROW(), /* 0x30 */
/* 0x40 IN B, (C); 0x41 OUT (C), B */ IN_OUT(bc_.bytes.high),
/* 0x42 SBC HL, BC */ SBC16(hl_, bc_), /* 0x43 LD (nn), BC */ Program(FETCH16(temp16_, pc_), STORE16L(bc_, temp16_)),
/* 0x44 NEG */ Program({MicroOp::NEG}), /* 0x45 RETN */ Program(POP(pc_), {MicroOp::RETN}),
/* 0x46 IM 0 */ Program({MicroOp::IM}), /* 0x47 LD I, A */ LD(i_, a_),
/* 0x40 IN B, (C); 0x41 OUT (C), B */ IN_OUT(bc_.bytes.low),
/* 0x4a ADC HL, BC */ ADC16(hl_, bc_), /* 0x4b LD BC, (nn) */ Program(FETCH16(temp16_, pc_), FETCH16L(bc_, temp16_)),
/* 0x4c NEG */ Program({MicroOp::NEG}), /* 0x4d RETI */ Program(POP(pc_), {MicroOp::RETN}),
/* 0x4e IM 0/1 */ Program({MicroOp::IM}), /* 0x4f LD R, A */ LD(r_, a_),
/* 0x40 IN B, (C); 0x41 OUT (C), B */ IN_OUT(de_.bytes.high),
/* 0x52 SBC HL, DE */ SBC16(hl_, de_), /* 0x53 LD (nn), DE */ Program(FETCH16(temp16_, pc_), STORE16L(de_, temp16_)),
/* 0x54 NEG */ Program({MicroOp::NEG}), /* 0x55 RETN */ Program(POP(pc_), {MicroOp::RETN}),
/* 0x56 IM 1 */ Program({MicroOp::IM}), /* 0x57 LD A, I */ Program({MicroOp::Move8, &i_, &a_}, {MicroOp::SetAFlags}),
/* 0x40 IN B, (C); 0x41 OUT (C), B */ IN_OUT(de_.bytes.low),
/* 0x5a ADC HL, DE */ ADC16(hl_, de_), /* 0x5b LD DE, (nn) */ Program(FETCH16(temp16_, pc_), FETCH16L(de_, temp16_)),
/* 0x5c NEG */ Program({MicroOp::NEG}), /* 0x5d RETN */ Program(POP(pc_), {MicroOp::RETN}),
/* 0x5e IM 2 */ Program({MicroOp::IM}), /* 0x5f LD A, R */ Program({MicroOp::Move8, &r_, &a_}, {MicroOp::SetAFlags}),
/* 0x40 IN B, (C); 0x41 OUT (C), B */ IN_OUT(hl_.bytes.high),
/* 0x62 SBC HL, HL */ SBC16(hl_, hl_), /* 0x63 LD (nn), HL */ Program(FETCH16(temp16_, pc_), STORE16L(hl_, temp16_)),
/* 0x64 NEG */ Program({MicroOp::NEG}), /* 0x65 RETN */ Program(POP(pc_), {MicroOp::RETN}),
/* 0x66 IM 0 */ Program({MicroOp::IM}), /* 0x67 RRD */ Program(FETCHL(temp8_, hl_), WAIT(4), {MicroOp::RRD}, STOREL(temp8_, hl_)),
/* 0x40 IN B, (C); 0x41 OUT (C), B */ IN_OUT(hl_.bytes.low),
/* 0x6a ADC HL, HL */ ADC16(hl_, hl_), /* 0x6b LD HL, (nn) */ Program(FETCH16(temp16_, pc_), FETCH16L(hl_, temp16_)),
/* 0x6c NEG */ Program({MicroOp::NEG}), /* 0x6d RETN */ Program(POP(pc_), {MicroOp::RETN}),
/* 0x6e IM 0/1 */ Program({MicroOp::IM}), /* 0x6f RLD */ Program(FETCHL(temp8_, hl_), WAIT(4), {MicroOp::RLD}, STOREL(temp8_, hl_)),
/* 0x70 IN (C) */ IN_C(temp8_), /* 0x71 OUT (C), 0 */ Program({MicroOp::SetZero}, OUT(bc_, temp8_)),
/* 0x72 SBC HL, SP */ SBC16(hl_, sp_), /* 0x73 LD (nn), SP */ Program(FETCH16(temp16_, pc_), STORE16L(sp_, temp16_)),
/* 0x74 NEG */ Program({MicroOp::NEG}), /* 0x75 RETN */ Program(POP(pc_), {MicroOp::RETN}),
/* 0x76 IM 1 */ Program({MicroOp::IM}), /* 0x77 XX */ NOP,
/* 0x40 IN B, (C); 0x41 OUT (C), B */ IN_OUT(a_),
/* 0x7a ADC HL, SP */ ADC16(hl_, sp_), /* 0x7b LD SP, (nn) */ Program(FETCH16(temp16_, pc_), FETCH16L(sp_, temp16_)),
/* 0x7c NEG */ Program({MicroOp::NEG}), /* 0x7d RETN */ Program(POP(pc_), {MicroOp::RETN}),
/* 0x7e IM 2 */ Program({MicroOp::IM}), /* 0x7f XX */ NOP,
NOP_ROW(), /* 0x80 */
NOP_ROW(), /* 0x90 */
/* 0xa0 LDI */ Program(FETCHL(temp8_, hl_), STOREL(temp8_, de_), WAIT(2), {MicroOp::LDI}),
/* 0xa1 CPI */ Program(FETCHL(temp8_, hl_), WAIT(5), {MicroOp::CPI}),
/* 0xa2 INI */ Program(WAIT(1), IN(bc_, temp8_), STOREL(temp8_, hl_), {MicroOp::INI}),
/* 0xa3 OTI */ Program(WAIT(1), FETCHL(temp8_, hl_), {MicroOp::OUTI}, OUT(bc_, temp8_)),
NOP, NOP, NOP, NOP,
/* 0xa8 LDD */ Program(FETCHL(temp8_, hl_), STOREL(temp8_, de_), WAIT(2), {MicroOp::LDD}),
/* 0xa9 CPD */ Program(FETCHL(temp8_, hl_), WAIT(5), {MicroOp::CPD}),
/* 0xaa IND */ Program(WAIT(1), IN(bc_, temp8_), STOREL(temp8_, hl_), {MicroOp::IND}),
/* 0xab OTD */ Program(WAIT(1), FETCHL(temp8_, hl_), {MicroOp::OUTD}, OUT(bc_, temp8_)),
NOP, NOP, NOP, NOP,
/* 0xb0 LDIR */ Program(FETCHL(temp8_, hl_), STOREL(temp8_, de_), WAIT(2), {MicroOp::LDIR}, WAIT(5)),
/* 0xb1 CPIR */ Program(FETCHL(temp8_, hl_), WAIT(5), {MicroOp::CPIR}, WAIT(5)),
/* 0xb2 INIR */ Program(WAIT(1), IN(bc_, temp8_), STOREL(temp8_, hl_), {MicroOp::INIR}, WAIT(5)),
/* 0xb3 OTIR */ Program(WAIT(1), FETCHL(temp8_, hl_), {MicroOp::OUTI}, OUT(bc_, temp8_), {MicroOp::OUT_R}, WAIT(5)),
NOP, NOP, NOP, NOP,
/* 0xb8 LDDR */ Program(FETCHL(temp8_, hl_), STOREL(temp8_, de_), WAIT(2), {MicroOp::LDDR}, WAIT(5)),
/* 0xb9 CPDR */ Program(FETCHL(temp8_, hl_), WAIT(5), {MicroOp::CPDR}, WAIT(5)),
/* 0xba INDR */ Program(WAIT(1), IN(bc_, temp8_), STOREL(temp8_, hl_), {MicroOp::INDR}, WAIT(5)),
/* 0xbb OTDR */ Program(WAIT(1), FETCHL(temp8_, hl_), {MicroOp::OUTD}, OUT(bc_, temp8_), {MicroOp::OUT_R}, WAIT(5)),
NOP, NOP, NOP, NOP,
NOP_ROW(), /* 0xc0 */
NOP_ROW(), /* 0xd0 */
NOP_ROW(), /* 0xe0 */
NOP_ROW(), /* 0xf0 */
};
assemble_page(target, ed_program_table, false);
#undef NOP_ROW
}
void assemble_cb_page(InstructionPage &target, RegisterPair &index, bool add_offsets) {
#define OCTO_OP_GROUP(m, x) m(x), m(x), m(x), m(x), m(x), m(x), m(x), m(x)
#define CB_PAGE(m, p) m(RLC), m(RRC), m(RL), m(RR), m(SLA), m(SRA), m(SLL), m(SRL), OCTO_OP_GROUP(p, BIT), OCTO_OP_GROUP(m, RES), OCTO_OP_GROUP(m, SET)
InstructionTable cb_program_table = {
/* 0x00 RLC B; 0x01 RLC C; 0x02 RLC D; 0x03 RLC E; 0x04 RLC H; 0x05 RLC L; 0x06 RLC (HL); 0x07 RLC A */
/* 0x08 RRC B; 0x09 RRC C; 0x0a RRC D; 0x0b RRC E; 0x0c RRC H; 0x0d RRC L; 0x0e RRC (HL); 0x0f RRC A */
/* 0x10 RL B; 0x11 RL C; 0x12 RL D; 0x13 RL E; 0x14 RL H; 0x15 RL L; 0x16 RL (HL); 0x17 RL A */
/* 0x18 RR B; 0x99 RR C; 0x1a RR D; 0x1b RR E; 0x1c RR H; 0x1d RR L; 0x1e RR (HL); 0x1f RR A */
/* 0x20 SLA B; 0x21 SLA C; 0x22 SLA D; 0x23 SLA E; 0x24 SLA H; 0x25 SLA L; 0x26 SLA (HL); 0x27 SLA A */
/* 0x28 SRA B; 0x29 SRA C; 0x2a SRA D; 0x2b SRA E; 0x2c SRA H; 0x2d SRA L; 0x2e SRA (HL); 0x2f SRA A */
/* 0x30 SLL B; 0x31 SLL C; 0x32 SLL D; 0x33 SLL E; 0x34 SLL H; 0x35 SLL L; 0x36 SLL (HL); 0x37 SLL A */
/* 0x38 SRL B; 0x39 SRL C; 0x3a SRL D; 0x3b SRL E; 0x3c SRL H; 0x3d SRL L; 0x3e SRL (HL); 0x3f SRL A */
/* 0x40 0x7f: BIT */
/* 0x80 0xcf: RES */
/* 0xd0 0xdf: SET */
CB_PAGE(MODIFY_OP_GROUP, READ_OP_GROUP)
};
InstructionTable offsets_cb_program_table = {
CB_PAGE(IX_MODIFY_OP_GROUP, IX_READ_OP_GROUP)
};
assemble_page(target, add_offsets ? offsets_cb_program_table : cb_program_table, add_offsets);
#undef OCTO_OP_GROUP
#undef CB_PAGE
}
void assemble_base_page(InstructionPage &target, RegisterPair &index, bool add_offsets, InstructionPage &cb_page) {
#define INC_DEC_LD(r) \
Program({MicroOp::Increment8, &r}), \
Program({MicroOp::Decrement8, &r}), \
Program(FETCH(r, pc_))
#define INC_INC_DEC_LD(rf, r) \
Program(WAIT(2), {MicroOp::Increment16, &rf.full}), INC_DEC_LD(r)
#define DEC_INC_DEC_LD(rf, r) \
Program(WAIT(2), {MicroOp::Decrement16, &rf.full}), INC_DEC_LD(r)
InstructionTable base_program_table = {
/* 0x00 NOP */ NOP, /* 0x01 LD BC, nn */ Program(FETCH16(bc_, pc_)),
/* 0x02 LD (BC), A */ Program(STOREL(a_, bc_)),
/* 0x03 INC BC; 0x04 INC B; 0x05 DEC B; 0x06 LD B, n */
INC_INC_DEC_LD(bc_, bc_.bytes.high),
/* 0x07 RLCA */ Program({MicroOp::RLCA}),
/* 0x08 EX AF, AF' */ Program({MicroOp::ExAFAFDash}), /* 0x09 ADD HL, BC */ ADD16(index, bc_),
/* 0x0a LD A, (BC) */ Program(FETCHL(a_, bc_)),
/* 0x0b DEC BC; 0x0c INC C; 0x0d DEC C; 0x0e LD C, n */
DEC_INC_DEC_LD(bc_, bc_.bytes.low),
/* 0x0f RRCA */ Program({MicroOp::RRCA}),
/* 0x10 DJNZ */ Program(WAIT(1), FETCH(temp8_, pc_), {MicroOp::DJNZ}, WAIT(5), {MicroOp::CalculateIndexAddress, &pc_.full}, {MicroOp::Move16, &temp16_.full, &pc_.full}),
/* 0x11 LD DE, nn */ Program(FETCH16(de_, pc_)),
/* 0x12 LD (DE), A */ Program(STOREL(a_, de_)),
/* 0x13 INC DE; 0x14 INC D; 0x15 DEC D; 0x16 LD D, n */
INC_INC_DEC_LD(de_, de_.bytes.high),
/* 0x17 RLA */ Program({MicroOp::RLA}),
/* 0x18 JR */ Program(FETCH(temp8_, pc_), WAIT(5), {MicroOp::CalculateIndexAddress, &pc_.full}, {MicroOp::Move16, &temp16_.full, &pc_.full}),
/* 0x19 ADD HL, DE */ ADD16(index, de_),
/* 0x1a LD A, (DE) */ Program(FETCHL(a_, de_)),
/* 0x1b DEC DE; 0x1c INC E; 0x1d DEC E; 0x1e LD E, n */
DEC_INC_DEC_LD(de_, de_.bytes.low),
/* 0x1f RRA */ Program({MicroOp::RRA}),
/* 0x20 JR NZ */ JR(TestNZ), /* 0x21 LD HL, nn */ Program(FETCH16(index, pc_)),
/* 0x22 LD (nn), HL */ Program(FETCH16(temp16_, pc_), STORE16L(index, temp16_)),
/* 0x23 INC HL; 0x24 INC H; 0x25 DEC H; 0x26 LD H, n */
INC_INC_DEC_LD(index, index.bytes.high),
/* 0x27 DAA */ Program({MicroOp::DAA}),
/* 0x28 JR Z */ JR(TestZ), /* 0x29 ADD HL, HL */ ADD16(index, index),
/* 0x2a LD HL, (nn) */ Program(FETCH16(temp16_, pc_), FETCH16L(index, temp16_)),
/* 0x2b DEC HL; 0x2c INC L; 0x2d DEC L; 0x2e LD L, n */
DEC_INC_DEC_LD(index, index.bytes.low),
/* 0x2f CPL */ Program({MicroOp::CPL}),
/* 0x30 JR NC */ JR(TestNC), /* 0x31 LD SP, nn */ Program(FETCH16(sp_, pc_)),
/* 0x32 LD (nn), A */ Program(FETCH16(temp16_, pc_), STOREL(a_, temp16_)),
/* 0x33 INC SP */ Program(WAIT(2), {MicroOp::Increment16, &sp_.full}),
/* 0x34 INC (HL) */ Program(INDEX(), FETCHL(temp8_, INDEX_ADDR()), WAIT(1), {MicroOp::Increment8, &temp8_}, STOREL(temp8_, INDEX_ADDR())),
/* 0x35 DEC (HL) */ Program(INDEX(), FETCHL(temp8_, INDEX_ADDR()), WAIT(1), {MicroOp::Decrement8, &temp8_}, STOREL(temp8_, INDEX_ADDR())),
/* 0x36 LD (HL), n */ Program({MicroOp::IndexedPlaceHolder}, FETCH(temp8_, pc_), {MicroOp::CalculateIndexAddress, &index}, FETCH(temp8_, pc_), WAIT(add_offsets ? 2 : 0), STOREL(temp8_, INDEX_ADDR())),
/* 0x37 SCF */ Program({MicroOp::SCF}),
/* 0x38 JR C */ JR(TestC),
/* 0x39 ADD HL, SP */ ADD16(index, sp_),
/* 0x3a LD A, (nn) */ Program(FETCH16(temp16_, pc_), FETCHL(a_, temp16_)),
/* 0x3b DEC SP */ Program(WAIT(2), {MicroOp::Decrement16, &sp_.full}),
/* 0x3c INC A; 0x3d DEC A; 0x3e LD A, n */
INC_DEC_LD(a_),
/* 0x3f CCF */ Program({MicroOp::CCF}),
/* 0x40 LD B, B; 0x41 LD B, C; 0x42 LD B, D; 0x43 LD B, E; 0x44 LD B, H; 0x45 LD B, L; 0x46 LD B, (HL); 0x47 LD B, A */
LD_GROUP(bc_.bytes.high, bc_.bytes.high),
/* 0x48 LD C, B; 0x49 LD C, C; 0x4a LD C, D; 0x4b LD C, E; 0x4c LD C, H; 0x4d LD C, L; 0x4e LD C, (HL); 0x4f LD C, A */
LD_GROUP(bc_.bytes.low, bc_.bytes.low),
/* 0x50 LD D, B; 0x51 LD D, C; 0x52 LD D, D; 0x53 LD D, E; 0x54 LD D, H; 0x55 LD D, L; 0x56 LD D, (HL); 0x57 LD D, A */
LD_GROUP(de_.bytes.high, de_.bytes.high),
/* 0x58 LD E, B; 0x59 LD E, C; 0x5a LD E, D; 0x5b LD E, E; 0x5c LD E, H; 0x5d LD E, L; 0x5e LD E, (HL); 0x5f LD E, A */
LD_GROUP(de_.bytes.low, de_.bytes.low),
/* 0x60 LD H, B; 0x61 LD H, C; 0x62 LD H, D; 0x63 LD H, E; 0x64 LD H, H; 0x65 LD H, L; 0x66 LD H, (HL); 0x67 LD H, A */
LD_GROUP(index.bytes.high, hl_.bytes.high),
/* 0x68 LD L, B; 0x69 LD L, C; 0x6a LD L, D; 0x6b LD L, E; 0x6c LD L, H; 0x6d LD H, L; 0x6e LD L, (HL); 0x6f LD L, A */
LD_GROUP(index.bytes.low, hl_.bytes.low),
/* 0x70 LD (HL), B */ Program(INDEX(), STOREL(bc_.bytes.high, INDEX_ADDR())),
/* 0x71 LD (HL), C */ Program(INDEX(), STOREL(bc_.bytes.low, INDEX_ADDR())),
/* 0x72 LD (HL), D */ Program(INDEX(), STOREL(de_.bytes.high, INDEX_ADDR())),
/* 0x73 LD (HL), E */ Program(INDEX(), STOREL(de_.bytes.low, INDEX_ADDR())),
/* 0x74 LD (HL), H */ Program(INDEX(), STOREL(hl_.bytes.high, INDEX_ADDR())), // neither of these stores parts of the index register;
/* 0x75 LD (HL), L */ Program(INDEX(), STOREL(hl_.bytes.low, INDEX_ADDR())), // they always store exactly H and L.
/* 0x76 HALT */ Program({MicroOp::HALT}),
/* 0x77 LD (HL), A */ Program(INDEX(), STOREL(a_, INDEX_ADDR())),
/* 0x78 LD A, B; 0x79 LD A, C; 0x7a LD A, D; 0x7b LD A, E; 0x7c LD A, H; 0x7d LD A, L; 0x7e LD A, (HL); 0x7f LD A, A */
LD_GROUP(a_, a_),
/* 0x80 ADD B; 0x81 ADD C; 0x82 ADD D; 0x83 ADD E; 0x84 ADD H; 0x85 ADD L; 0x86 ADD (HL); 0x87 ADD A */
READ_OP_GROUP(ADD8),
/* 0x88 ADC B; 0x89 ADC C; 0x8a ADC D; 0x8b ADC E; 0x8c ADC H; 0x8d ADC L; 0x8e ADC (HL); 0x8f ADC A */
READ_OP_GROUP(ADC8),
/* 0x90 SUB B; 0x91 SUB C; 0x92 SUB D; 0x93 SUB E; 0x94 SUB H; 0x95 SUB L; 0x96 SUB (HL); 0x97 SUB A */
READ_OP_GROUP(SUB8),
/* 0x98 SBC B; 0x99 SBC C; 0x9a SBC D; 0x9b SBC E; 0x9c SBC H; 0x9d SBC L; 0x9e SBC (HL); 0x9f SBC A */
READ_OP_GROUP(SBC8),
/* 0xa0 AND B; 0xa1 AND C; 0xa2 AND D; 0xa3 AND E; 0xa4 AND H; 0xa5 AND L; 0xa6 AND (HL); 0xa7 AND A */
READ_OP_GROUP(And),
/* 0xa8 XOR B; 0xa9 XOR C; 0xaa XOR D; 0xab XOR E; 0xac XOR H; 0xad XOR L; 0xae XOR (HL); 0xaf XOR A */
READ_OP_GROUP(Xor),
/* 0xb0 OR B; 0xb1 OR C; 0xb2 OR D; 0xb3 OR E; 0xb4 OR H; 0xb5 OR L; 0xb6 OR (HL); 0xb7 OR A */
READ_OP_GROUP(Or),
/* 0xb8 CP B; 0xb9 CP C; 0xba CP D; 0xbb CP E; 0xbc CP H; 0xbd CP L; 0xbe CP (HL); 0xbf CP A */
READ_OP_GROUP(CP8),
/* 0xc0 RET NZ */ RET(TestNZ), /* 0xc1 POP BC */ Program(POP(bc_)),
/* 0xc2 JP NZ */ JP(TestNZ), /* 0xc3 JP nn */ Program(FETCH16L(temp16_, pc_), {MicroOp::Move16, &temp16_.full, &pc_.full}),
/* 0xc4 CALL NZ */ CALL(TestNZ), /* 0xc5 PUSH BC */ Program(WAIT(1), PUSH(bc_)),
/* 0xc6 ADD A, n */ Program(FETCH(temp8_, pc_), {MicroOp::ADD8, &temp8_}),
/* 0xc7 RST 00h */ RST(),
/* 0xc8 RET Z */ RET(TestZ), /* 0xc9 RET */ Program(POP(pc_)),
/* 0xca JP Z */ JP(TestZ), /* 0xcb [CB page] */Program({MicroOp::SetInstructionPage, &cb_page}, FINDEX()),
/* 0xcc CALL Z */ CALL(TestZ), /* 0xcd CALL */ Program(FETCH16(temp16_, pc_), WAIT(1), PUSH(pc_), {MicroOp::Move16, &temp16_.full, &pc_.full}),
/* 0xce ADC A, n */ Program(FETCH(temp8_, pc_), {MicroOp::ADC8, &temp8_}),
/* 0xcf RST 08h */ RST(),
/* 0xd0 RET NC */ RET(TestNC), /* 0xd1 POP DE */ Program(POP(de_)),
/* 0xd2 JP NC */ JP(TestNC), /* 0xd3 OUT (n), A */Program(FETCH(temp16_.bytes.low, pc_), {MicroOp::Move8, &a_, &temp16_.bytes.high}, OUT(temp16_, a_)),
/* 0xd4 CALL NC */ CALL(TestNC), /* 0xd5 PUSH DE */ Program(WAIT(1), PUSH(de_)),
/* 0xd6 SUB n */ Program(FETCH(temp8_, pc_), {MicroOp::SUB8, &temp8_}),
/* 0xd7 RST 10h */ RST(),
/* 0xd8 RET C */ RET(TestC), /* 0xd9 EXX */ Program({MicroOp::EXX}),
/* 0xda JP C */ JP(TestC), /* 0xdb IN A, (n) */Program(FETCH(temp16_.bytes.low, pc_), {MicroOp::Move8, &a_, &temp16_.bytes.high}, IN(temp16_, a_)),
/* 0xdc CALL C */ CALL(TestC), /* 0xdd [DD page] */Program({MicroOp::SetInstructionPage, &dd_page_}),
/* 0xde SBC A, n */ Program(FETCH(temp8_, pc_), {MicroOp::SBC8, &temp8_}),
/* 0xdf RST 18h */ RST(),
/* 0xe0 RET PO */ RET(TestPO), /* 0xe1 POP HL */ Program(POP(index)),
/* 0xe2 JP PO */ JP(TestPO), /* 0xe3 EX (SP), HL */Program(POP(temp16_), WAIT(1), PUSH(index), WAIT(2), {MicroOp::Move16, &temp16_.full, &index.full}),
/* 0xe4 CALL PO */ CALL(TestPO), /* 0xe5 PUSH HL */ Program(WAIT(1), PUSH(index)),
/* 0xe6 AND n */ Program(FETCH(temp8_, pc_), {MicroOp::And, &temp8_}),
/* 0xe7 RST 20h */ RST(),
/* 0xe8 RET PE */ RET(TestPE), /* 0xe9 JP (HL) */ Program({MicroOp::Move16, &index.full, &pc_.full}),
/* 0xea JP PE */ JP(TestPE), /* 0xeb EX DE, HL */Program({MicroOp::ExDEHL}),
/* 0xec CALL PE */ CALL(TestPE), /* 0xed [ED page] */Program({MicroOp::SetInstructionPage, &ed_page_}),
/* 0xee XOR n */ Program(FETCH(temp8_, pc_), {MicroOp::Xor, &temp8_}),
/* 0xef RST 28h */ RST(),
/* 0xf0 RET p */ RET(TestP), /* 0xf1 POP AF */ Program(POP(temp16_), {MicroOp::DisassembleAF}),
/* 0xf2 JP P */ JP(TestP), /* 0xf3 DI */ Program({MicroOp::DI}),
/* 0xf4 CALL P */ CALL(TestP), /* 0xf5 PUSH AF */ Program(WAIT(1), {MicroOp::AssembleAF}, PUSH(temp16_)),
/* 0xf6 OR n */ Program(FETCH(temp8_, pc_), {MicroOp::Or, &temp8_}),
/* 0xf7 RST 30h */ RST(),
/* 0xf8 RET M */ RET(TestM), /* 0xf9 LD SP, HL */Program(WAIT(2), {MicroOp::Move16, &index.full, &sp_.full}),
/* 0xfa JP M */ JP(TestM), /* 0xfb EI */ Program({MicroOp::EI}),
/* 0xfc CALL M */ CALL(TestM), /* 0xfd [FD page] */Program({MicroOp::SetInstructionPage, &fd_page_}),
/* 0xfe CP n */ Program(FETCH(temp8_, pc_), {MicroOp::CP8, &temp8_}),
/* 0xff RST 38h */ RST(),
};
assemble_cb_page(cb_page, index, add_offsets);
assemble_page(target, base_program_table, add_offsets);
}
void assemble_fetch_decode_execute(InstructionPage &target, int length) {
// TODO: this can't legitimately be static and contain references to this via pc_ and operation_;
// make it something else that is built at instance construction.
const MicroOp fetch_decode_execute[] = {
{ MicroOp::BusOperation, nullptr, nullptr, {(length == 4) ? ReadOpcode : Read, length, &pc_.full, &operation_}},
{ MicroOp::DecodeOperation },
{ MicroOp::MoveToNextProgram }
};
target.fetch_decode_execute.resize(3);
target.fetch_decode_execute[0] = fetch_decode_execute[0];
target.fetch_decode_execute[1] = fetch_decode_execute[1];
target.fetch_decode_execute[2] = fetch_decode_execute[2];
}
void decode_operation(uint8_t operation) {
schedule_program(current_instruction_page_->instructions[operation]);
}
public:
Processor() : MicroOpScheduler(),
halt_mask_(0xff),
sp_(0xffff),
pc_(0x0000),
a_(0xff),
interrupt_mode_(0),
iff1_(false),
iff2_(false) {
set_flags(0xff);
assemble_base_page(base_page_, hl_, false, cb_page_);
assemble_base_page(dd_page_, ix_, true, ddcb_page_);
assemble_base_page(fd_page_, iy_, true, fdcb_page_);
assemble_ed_page(ed_page_);
fdcb_page_.r_step_ = 0;
ddcb_page_.r_step_ = 0;
assemble_fetch_decode_execute(base_page_, 4);
assemble_fetch_decode_execute(dd_page_, 4);
assemble_fetch_decode_execute(fd_page_, 4);
assemble_fetch_decode_execute(ed_page_, 4);
assemble_fetch_decode_execute(cb_page_, 4);
assemble_fetch_decode_execute(fdcb_page_, 3);
assemble_fetch_decode_execute(ddcb_page_, 3);
}
/*!
Runs the Z80 for a supplied number of cycles.
@discussion Subclasses must implement @c perform_machine_cycle(const MachineCycle &cycle) .
If it is a read operation then @c value will be seeded with the value 0xff.
@param number_of_cycles The number of cycles to run the Z80 for.
*/
void run_for_cycles(int number_of_cycles) {
#define checkSchedule() \
if(!scheduled_programs_[schedule_programs_read_pointer_]) {\
current_instruction_page_ = &base_page_;\
schedule_program(base_page_.fetch_decode_execute.data());\
}
number_of_cycles_ += number_of_cycles;
checkSchedule();
while(1) {
const MicroOp *operation = scheduled_program_counter_;
scheduled_program_counter_++;
#define set_parity(v) \
parity_overflow_result_ = v^1;\
parity_overflow_result_ ^= parity_overflow_result_ >> 4;\
parity_overflow_result_ ^= parity_overflow_result_ << 2;\
parity_overflow_result_ ^= parity_overflow_result_ >> 1;
switch(operation->type) {
case MicroOp::BusOperation:
if(number_of_cycles_ < operation->machine_cycle.length) { scheduled_program_counter_--; return; }
number_of_cycles_ -= operation->machine_cycle.length;
number_of_cycles_ -= static_cast<T *>(this)->perform_machine_cycle(operation->machine_cycle);
break;
case MicroOp::MoveToNextProgram:
move_to_next_program();
checkSchedule();
break;
case MicroOp::DecodeOperation:
r_ = (r_ & 0x80) | ((r_ + current_instruction_page_->r_step_) & 0x7f);
pc_.full++;
decode_operation(operation_ & halt_mask_);
break;
case MicroOp::Increment16: (*(uint16_t *)operation->source)++; break;
case MicroOp::Decrement16: (*(uint16_t *)operation->source)--; break;
case MicroOp::Move8: *(uint8_t *)operation->destination = *(uint8_t *)operation->source; break;
case MicroOp::Move16: *(uint16_t *)operation->destination = *(uint16_t *)operation->source; break;
case MicroOp::AssembleAF:
temp16_.bytes.high = a_;
temp16_.bytes.low = get_flags();
break;
case MicroOp::DisassembleAF:
a_ = temp16_.bytes.high;
set_flags(temp16_.bytes.low);
break;
#pragma mark - Logical
#define set_logical_flags(hf) \
sign_result_ = zero_result_ = bit53_result_ = a_; \
set_parity(a_); \
half_carry_result_ = hf; \
subtract_flag_ = 0; \
carry_result_ = 0;
case MicroOp::And:
a_ &= *(uint8_t *)operation->source;
set_logical_flags(Flag::HalfCarry);
break;
case MicroOp::Or:
a_ |= *(uint8_t *)operation->source;
set_logical_flags(0);
break;
case MicroOp::Xor:
a_ ^= *(uint8_t *)operation->source;
set_logical_flags(0);
break;
#undef set_logical_flags
case MicroOp::CPL:
a_ ^= 0xff;
subtract_flag_ = Flag::Subtract;
half_carry_result_ = Flag::HalfCarry;
bit53_result_ = a_;
break;
case MicroOp::CCF:
half_carry_result_ = carry_result_ << 4;
carry_result_ ^= Flag::Carry;
subtract_flag_ = 0;
bit53_result_ = a_;
break;
case MicroOp::SCF:
carry_result_ = Flag::Carry;
half_carry_result_ = 0;
subtract_flag_ = 0;
bit53_result_ = a_;
break;
#pragma mark - Flow control
case MicroOp::DJNZ:
bc_.bytes.high--;
if(!bc_.bytes.high) {
move_to_next_program();
checkSchedule();
}
break;
case MicroOp::CalculateRSTDestination:
temp16_.full = operation_ & 0x38;
break;
#pragma mark - 8-bit arithmetic
case MicroOp::CP8: {
uint8_t value = *(uint8_t *)operation->source;
int result = a_ - value;
int halfResult = (a_&0xf) - (value&0xf);
// overflow for a subtraction is when the signs were originally
// different and the result is different again
int overflow = (value^a_) & (result^a_);
sign_result_ = // set sign and zero
zero_result_ = (uint8_t)result;
bit53_result_ = value; // set the 5 and 3 flags, which come
// from the operand atypically
carry_result_ = result >> 8;
half_carry_result_ = halfResult;
parity_overflow_result_ = overflow >> 5;
subtract_flag_ = Flag::Subtract;
} break;
case MicroOp::SUB8: {
uint8_t value = *(uint8_t *)operation->source;
int result = a_ - value;
int halfResult = (a_&0xf) - (value&0xf);
// overflow for a subtraction is when the signs were originally
// different and the result is different again
int overflow = (value^a_) & (result^a_);
a_ = (uint8_t)result;
sign_result_ = zero_result_ = bit53_result_ = (uint8_t)result;
carry_result_ = result >> 8;
half_carry_result_ = halfResult;
parity_overflow_result_ = overflow >> 5;
subtract_flag_ = Flag::Subtract;
} break;
case MicroOp::SBC8: {
uint8_t value = *(uint8_t *)operation->source;
int result = a_ - value - (carry_result_ & Flag::Carry);
int halfResult = (a_&0xf) - (value&0xf) - (carry_result_ & Flag::Carry);
// overflow for a subtraction is when the signs were originally
// different and the result is different again
int overflow = (value^a_) & (result^a_);
a_ = (uint8_t)result;
sign_result_ = zero_result_ = bit53_result_ = (uint8_t)result;
carry_result_ = result >> 8;
half_carry_result_ = halfResult;
parity_overflow_result_ = overflow >> 5;
subtract_flag_ = Flag::Subtract;
} break;
case MicroOp::ADD8: {
uint8_t value = *(uint8_t *)operation->source;
int result = a_ + value;
int halfResult = (a_&0xf) + (value&0xf);
// overflow for addition is when the signs were originally
// the same and the result is different
int overflow = ~(value^a_) & (result^a_);
a_ = (uint8_t)result;
sign_result_ = zero_result_ = bit53_result_ = (uint8_t)result;
carry_result_ = result >> 8;
half_carry_result_ = halfResult;
parity_overflow_result_ = overflow >> 5;
subtract_flag_ = 0;
} break;
case MicroOp::ADC8: {
uint8_t value = *(uint8_t *)operation->source;
int result = a_ + value + (carry_result_ & Flag::Carry);
int halfResult = (a_&0xf) + (value&0xf) + (carry_result_ & Flag::Carry);
// overflow for addition is when the signs were originally
// the same and the result is different
int overflow = ~(value^a_) & (result^a_);
a_ = (uint8_t)result;
sign_result_ = zero_result_ = bit53_result_ = (uint8_t)result;
carry_result_ = result >> 8;
half_carry_result_ = halfResult;
parity_overflow_result_ = overflow >> 5;
subtract_flag_ = 0;
} break;
case MicroOp::NEG: {
int overflow = (a_ == 0x80);
int result = -a_;
int halfResult = -(a_&0xf);
a_ = (uint8_t)result;
bit53_result_ = sign_result_ = zero_result_ = a_;
parity_overflow_result_ = overflow ? Flag::Overflow : 0;
subtract_flag_ = Flag::Subtract;
carry_result_ = result >> 8;
half_carry_result_ = halfResult;
} break;
case MicroOp::Increment8: {
uint8_t value = *(uint8_t *)operation->source;
int result = value + 1;
// with an increment, overflow occurs if the sign changes from
// positive to negative
int overflow = (value ^ result) & ~value;
int half_result = (value&0xf) + 1;
*(uint8_t *)operation->source = (uint8_t)result;
// sign, zero and 5 & 3 are set directly from the result
bit53_result_ = sign_result_ = zero_result_ = (uint8_t)result;
half_carry_result_ = half_result;
parity_overflow_result_ = overflow >> 5;
subtract_flag_ = 0;
} break;
case MicroOp::Decrement8: {
uint8_t value = *(uint8_t *)operation->source;
int result = value - 1;
// with a decrement, overflow occurs if the sign changes from
// negative to positive
int overflow = (value ^ result) & value;
int half_result = (value&0xf) - 1;
*(uint8_t *)operation->source = (uint8_t)result;
// sign, zero and 5 & 3 are set directly from the result
bit53_result_ = sign_result_ = zero_result_ = (uint8_t)result;
half_carry_result_ = half_result;
parity_overflow_result_ = overflow >> 5;
subtract_flag_ = Flag::Subtract;
} break;
case MicroOp::DAA: {
int lowNibble = a_ & 0xf;
int highNibble = a_ >> 4;
int amountToAdd = 0;
if(carry_result_ & Flag::Carry)
{
amountToAdd = (lowNibble > 0x9 || (half_carry_result_ & Flag::HalfCarry)) ? 0x66 : 0x60;
}
else
{
if(half_carry_result_ & Flag::HalfCarry)
{
if(lowNibble > 0x9)
amountToAdd = (highNibble > 0x8) ? 0x66 : 0x06;
else
amountToAdd = (highNibble > 0x9) ? 0x66 : 0x06;
}
else
{
if(lowNibble > 0x9)
amountToAdd = (highNibble > 0x8) ? 0x66 : 0x06;
else
amountToAdd = (highNibble > 0x9) ? 0x60 : 0x00;
}
}
if(!(carry_result_ & Flag::Carry))
{
if(lowNibble > 0x9)
{
if(highNibble > 0x8) carry_result_ = Flag::Carry;
}
else
{
if(highNibble > 0x9) carry_result_ = Flag::Carry;
}
}
if(subtract_flag_)
{
a_ -= amountToAdd;
half_carry_result_ = ((half_carry_result_ & Flag::HalfCarry) && lowNibble < 0x6) ? Flag::HalfCarry : 0;
}
else
{
a_ += amountToAdd;
half_carry_result_ = (lowNibble > 0x9) ? Flag::HalfCarry : 0;
}
sign_result_ = zero_result_ = bit53_result_ = a_;
set_parity(a_);
} break;
#pragma mark - 16-bit arithmetic
case MicroOp::ADD16: {
uint16_t sourceValue = *(uint16_t *)operation->source;
uint16_t destinationValue = *(uint16_t *)operation->destination;
int result = sourceValue + destinationValue;
int halfResult = (sourceValue&0xfff) + (destinationValue&0xfff);
bit53_result_ = (uint8_t)(result >> 8);
carry_result_ = result >> 16;
half_carry_result_ = (halfResult >> 8);
subtract_flag_ = 0;
*(uint16_t *)operation->destination = (uint16_t)result;
} break;
case MicroOp::ADC16: {
uint16_t sourceValue = *(uint16_t *)operation->source;
uint16_t destinationValue = *(uint16_t *)operation->destination;
int result = sourceValue + destinationValue + (carry_result_ & Flag::Carry);
int halfResult = (sourceValue&0xfff) + (destinationValue&0xfff) + (carry_result_ & Flag::Carry);
int overflow = (result ^ destinationValue) & ~(destinationValue ^ sourceValue);
bit53_result_ =
sign_result_ = (uint8_t)(result >> 8);
zero_result_ = (uint8_t)(result | sign_result_);
subtract_flag_ = 0;
carry_result_ = result >> 16;
half_carry_result_ = halfResult >> 8;
parity_overflow_result_ = overflow >> 13;
*(uint16_t *)operation->destination = (uint16_t)result;
} break;
case MicroOp::SBC16: {
uint16_t sourceValue = *(uint16_t *)operation->source;
uint16_t destinationValue = *(uint16_t *)operation->destination;
int result = destinationValue - sourceValue - (carry_result_ & Flag::Carry);
int halfResult = (destinationValue&0xfff) - (sourceValue&0xfff) - (carry_result_ & Flag::Carry);
// subtraction, so parity rules are:
// signs of operands were different,
// sign of result is different
int overflow = (result ^ destinationValue) & (sourceValue ^ destinationValue);
bit53_result_ =
sign_result_ = (uint8_t)(result >> 8);
zero_result_ = (uint8_t)(result | sign_result_);
subtract_flag_ = Flag::Subtract;
carry_result_ = result >> 16;
half_carry_result_ = halfResult >> 8;
parity_overflow_result_ = overflow >> 13;
*(uint16_t *)operation->destination = (uint16_t)result;
} break;
#pragma mark - Conditionals
case MicroOp::TestNZ: if(!zero_result_) { move_to_next_program(); checkSchedule(); } break;
case MicroOp::TestZ: if(zero_result_) { move_to_next_program(); checkSchedule(); } break;
case MicroOp::TestNC: if(carry_result_ & Flag::Carry) { move_to_next_program(); checkSchedule(); } break;
case MicroOp::TestC: if(!(carry_result_ & Flag::Carry)) { move_to_next_program(); checkSchedule(); } break;
case MicroOp::TestPO: if(parity_overflow_result_ & Flag::Parity) { move_to_next_program(); checkSchedule(); } break;
case MicroOp::TestPE: if(!(parity_overflow_result_ & Flag::Parity)) { move_to_next_program(); checkSchedule(); } break;
case MicroOp::TestP: if(sign_result_ & Flag::Sign) { move_to_next_program(); checkSchedule(); } break;
case MicroOp::TestM: if(!(sign_result_ & Flag::Sign)) { move_to_next_program(); checkSchedule(); } break;
#pragma mark - Exchange
#define swap(a, b) temp = a.full; a.full = b.full; b.full = temp;
case MicroOp::ExDEHL: {
uint16_t temp;
swap(de_, hl_);
} break;
case MicroOp::ExAFAFDash: {
uint8_t a = a_;
uint8_t f = get_flags();
set_flags(afDash_.bytes.low);
a_ = afDash_.bytes.high;
afDash_.bytes.high = a;
afDash_.bytes.low = f;
} break;
case MicroOp::EXX: {
uint16_t temp;
swap(de_, deDash_);
swap(bc_, bcDash_);
swap(hl_, hlDash_);
} break;
#undef swap
#pragma mark - Repetition
#define REPEAT(test) \
if(test) { \
pc_.full -= 2; \
} else { \
move_to_next_program(); \
checkSchedule(); \
}
#define LDxR_STEP(dir) \
bc_.full--; \
de_.full += dir; \
hl_.full += dir; \
bit53_result_ = a_ + temp8_; \
subtract_flag_ = 0; \
half_carry_result_ = 0; \
parity_overflow_result_ = bc_.full ? Flag::Parity : 0;
case MicroOp::LDDR: {
LDxR_STEP(-1);
REPEAT(bc_.full);
} break;
case MicroOp::LDIR: {
LDxR_STEP(1);
REPEAT(bc_.full);
} break;
case MicroOp::LDD: {
LDxR_STEP(-1);
} break;
case MicroOp::LDI: {
LDxR_STEP(1);
} break;
#undef LDxR_STEP
#define CPxR_STEP(dir) \
hl_.full += dir; \
bc_.full--; \
\
uint8_t result = a_ - temp8_; \
uint8_t halfResult = (a_&0xf) - (temp8_&0xf); \
\
parity_overflow_result_ = bc_.full ? Flag::Parity : 0; \
half_carry_result_ = halfResult; \
subtract_flag_ = Flag::Subtract; \
bit53_result_ = (uint8_t)((result&0x8) | ((result&0x2) << 4)); \
sign_result_ = zero_result_ = result;
case MicroOp::CPDR: {
CPxR_STEP(-1);
REPEAT(bc_.full && sign_result_);
} break;
case MicroOp::CPIR: {
CPxR_STEP(1);
REPEAT(bc_.full && sign_result_);
} break;
case MicroOp::CPD: {
CPxR_STEP(-1);
} break;
case MicroOp::CPI: {
CPxR_STEP(1);
} break;
#undef CPxR_STEP
#define INxR_STEP(dir) \
bc_.bytes.high--; \
hl_.full += dir; \
\
sign_result_ = zero_result_ = bit53_result_ = bc_.bytes.high; \
subtract_flag_ = (temp8_ >> 6) & Flag::Subtract; \
\
int next_bc = bc_.bytes.low + dir; \
int summation = temp8_ + (next_bc&0xff); \
\
if(summation > 0xff) { \
carry_result_ = Flag::Carry; \
half_carry_result_ = Flag::HalfCarry; \
} else { \
carry_result_ = 0; \
half_carry_result_ = 0; \
} \
\
summation = (summation&7) ^ bc_.bytes.high; \
set_parity(summation);
case MicroOp::INDR: {
INxR_STEP(-1);
REPEAT(bc_.bytes.high);
} break;
case MicroOp::INIR: {
INxR_STEP(1);
REPEAT(bc_.bytes.high);
} break;
case MicroOp::IND: {
INxR_STEP(-1);
} break;
case MicroOp::INI: {
INxR_STEP(1);
} break;
#undef INxR_STEP
#define OUTxR_STEP(dir) \
bc_.bytes.high--; \
hl_.full += dir; \
\
sign_result_ = zero_result_ = bit53_result_ = bc_.bytes.high; \
subtract_flag_ = (temp8_ >> 6) & Flag::Subtract; \
\
int summation = temp8_ + hl_.bytes.low; \
if(summation > 0xff) { \
carry_result_ = Flag::Carry; \
half_carry_result_ = Flag::HalfCarry; \
} else { \
carry_result_ = half_carry_result_ = 0; \
} \
\
summation = (summation&7) ^ bc_.bytes.high; \
set_parity(summation);
case MicroOp::OUT_R:
REPEAT(bc_.bytes.high);
break;
case MicroOp::OUTD: {
OUTxR_STEP(-1);
} break;
case MicroOp::OUTI: {
OUTxR_STEP(1);
} break;
#undef OUTxR_STEP
#pragma mark - Bit Manipulation
case MicroOp::BIT: {
uint8_t result = *(uint8_t *)operation->source & (1 << ((operation_ >> 3)&7));
sign_result_ = zero_result_ = result;
bit53_result_ = *(uint8_t *)operation->source; // This is a divergence between FUSE and The Undocumented Z80 Documented.
half_carry_result_ = Flag::HalfCarry;
subtract_flag_ = 0;
parity_overflow_result_ = result ? 0 : Flag::Parity;
} break;
case MicroOp::RES:
*(uint8_t *)operation->source &= ~(1 << ((operation_ >> 3)&7));
break;
case MicroOp::SET:
*(uint8_t *)operation->source |= (1 << ((operation_ >> 3)&7));
break;
#pragma mark - Rotation and shifting
#define set_rotate_flags() \
bit53_result_ = a_; \
carry_result_ = new_carry; \
subtract_flag_ = half_carry_result_ = 0;
case MicroOp::RLA: {
uint8_t new_carry = a_ >> 7;
a_ = (uint8_t)((a_ << 1) | (carry_result_ & Flag::Carry));
set_rotate_flags();
} break;
case MicroOp::RRA: {
uint8_t new_carry = a_ & 1;
a_ = (uint8_t)((a_ >> 1) | (carry_result_ << 7));
set_rotate_flags();
} break;
case MicroOp::RLCA: {
uint8_t new_carry = a_ >> 7;
a_ = (uint8_t)((a_ << 1) | new_carry);
set_rotate_flags();
} break;
case MicroOp::RRCA: {
uint8_t new_carry = a_ & 1;
a_ = (uint8_t)((a_ >> 1) | (new_carry << 7));
set_rotate_flags();
} break;
#undef set_rotate_flags
#define set_shift_flags() \
sign_result_ = zero_result_ = bit53_result_ = *(uint8_t *)operation->source; \
set_parity(sign_result_); \
half_carry_result_ = 0; \
subtract_flag_ = 0;
case MicroOp::RLC:
carry_result_ = *(uint8_t *)operation->source >> 7;
*(uint8_t *)operation->source = (uint8_t)((*(uint8_t *)operation->source << 1) | carry_result_);
set_shift_flags();
break;
case MicroOp::RRC:
carry_result_ = *(uint8_t *)operation->source;
*(uint8_t *)operation->source = (uint8_t)((*(uint8_t *)operation->source >> 1) | (carry_result_ << 7));
set_shift_flags();
break;
case MicroOp::RL: {
uint8_t next_carry = *(uint8_t *)operation->source >> 7;
*(uint8_t *)operation->source = (uint8_t)((*(uint8_t *)operation->source << 1) | (carry_result_ & Flag::Carry));
carry_result_ = next_carry;
set_shift_flags();
} break;
case MicroOp::RR: {
uint8_t next_carry = *(uint8_t *)operation->source;
*(uint8_t *)operation->source = (uint8_t)((*(uint8_t *)operation->source >> 1) | (carry_result_ << 7));
carry_result_ = next_carry;
set_shift_flags();
} break;
case MicroOp::SLA:
carry_result_ = *(uint8_t *)operation->source >> 7;
*(uint8_t *)operation->source = (uint8_t)(*(uint8_t *)operation->source << 1);
set_shift_flags();
break;
case MicroOp::SRA:
carry_result_ = *(uint8_t *)operation->source;
*(uint8_t *)operation->source = (uint8_t)((*(uint8_t *)operation->source >> 1) | (*(uint8_t *)operation->source & 0x80));
set_shift_flags();
break;
case MicroOp::SLL:
carry_result_ = *(uint8_t *)operation->source >> 7;
*(uint8_t *)operation->source = (uint8_t)(*(uint8_t *)operation->source << 1) | 1;
set_shift_flags();
break;
case MicroOp::SRL:
carry_result_ = *(uint8_t *)operation->source;
*(uint8_t *)operation->source = (uint8_t)((*(uint8_t *)operation->source >> 1));
set_shift_flags();
break;
#undef set_shift_flags
#define set_decimal_rotate_flags() \
subtract_flag_ = 0; \
half_carry_result_ = 0; \
set_parity(a_); \
bit53_result_ = zero_result_ = sign_result_ = a_;
case MicroOp::RRD: {
uint8_t low_nibble = a_ & 0xf;
a_ = (a_ & 0xf0) | (temp8_ & 0xf);
temp8_ = (temp8_ >> 4) | (low_nibble << 4);
set_decimal_rotate_flags();
} break;
case MicroOp::RLD: {
uint8_t low_nibble = a_ & 0xf;
a_ = (a_ & 0xf0) | (temp8_ >> 4);
temp8_ = (temp8_ << 4) | low_nibble;
set_decimal_rotate_flags();
} break;
#undef set_decimal_rotate_flags
#pragma mark - Interrupt state
case MicroOp::EI:
iff1_ = iff2_ = true;
break;
case MicroOp::DI:
iff1_ = iff2_ = false;
break;
case MicroOp::IM:
switch(operation_ & 0x18) {
case 0x00: interrupt_mode_ = 0; break;
case 0x08: interrupt_mode_ = 0; break; // IM 0/1
case 0x10: interrupt_mode_ = 1; break;
case 0x18: interrupt_mode_ = 2; break;
}
break;
#pragma mark - Input
case MicroOp::SetInFlags:
subtract_flag_ = half_carry_result_ = 0;
sign_result_ = zero_result_ = bit53_result_ = *(uint8_t *)operation->source;
set_parity(sign_result_);
break;
case MicroOp::SetAFlags:
subtract_flag_ = half_carry_result_ = 0;
parity_overflow_result_ = iff2_ ? Flag::Parity : 0;
sign_result_ = zero_result_ = bit53_result_ = a_;
break;
case MicroOp::SetZero:
temp8_ = 0;
break;
#pragma mark - Special-case Flow
case MicroOp::RETN:
iff1_ = iff2_;
break;
case MicroOp::HALT:
halt_mask_ = 0x00;
break;
#pragma mark - Internal bookkeeping
case MicroOp::SetInstructionPage:
current_instruction_page_ = (InstructionPage *)operation->source;
schedule_program(current_instruction_page_->fetch_decode_execute.data());
break;
case MicroOp::CalculateIndexAddress:
temp16_.full = *(uint16_t *)operation->source + (int8_t)temp8_;
break;
case MicroOp::IndexedPlaceHolder:
printf("Hit placeholder!!!\n");
return;
}
#undef set_parity
}
}
/*!
Called to announce the end of a run_for_cycles period, allowing deferred work to take place.
Users of the Z80 template may override this.
*/
void flush() {}
int perform_machine_cycle(const MachineCycle &cycle) {
return 0;
}
/*!
Gets the flags register.
@see set_flags
@returns The current value of the flags register.
*/
uint8_t get_flags() {
uint8_t result =
(sign_result_ & Flag::Sign) |
(zero_result_ ? 0 : Flag::Zero) |
(bit53_result_ & (Flag::Bit5 | Flag::Bit3)) |
(half_carry_result_ & Flag::HalfCarry) |
(parity_overflow_result_ & Flag::Parity) |
subtract_flag_ |
(carry_result_ & Flag::Carry);
return result;
}
/*!
Sets the flags register.
@see set_flags
@param flags The new value of the flags register.
*/
void set_flags(uint8_t flags) {
sign_result_ = flags;
zero_result_ = (flags & Flag::Zero) ^ Flag::Zero;
bit53_result_ = flags;
half_carry_result_ = flags;
parity_overflow_result_ = flags;
subtract_flag_ = flags & Flag::Subtract;
carry_result_ = flags;
}
/*!
Gets the value of a register.
@see set_value_of_register
@param r The register to set.
@returns The value of the register. 8-bit registers will be returned as unsigned.
*/
uint16_t get_value_of_register(Register r) {
switch (r) {
case Register::ProgramCounter: return pc_.full;
case Register::StackPointer: return sp_.full;
case Register::A: return a_;
case Register::Flags: return get_flags();
case Register::AF: return (uint16_t)((a_ << 8) | get_flags());
case Register::B: return bc_.bytes.high;
case Register::C: return bc_.bytes.low;
case Register::BC: return bc_.full;
case Register::D: return de_.bytes.high;
case Register::E: return de_.bytes.low;
case Register::DE: return de_.full;
case Register::H: return hl_.bytes.high;
case Register::L: return hl_.bytes.low;
case Register::HL: return hl_.full;
case Register::ADash: return afDash_.bytes.high;
case Register::FlagsDash: return afDash_.bytes.low;
case Register::AFDash: return afDash_.full;
case Register::BDash: return bcDash_.bytes.high;
case Register::CDash: return bcDash_.bytes.low;
case Register::BCDash: return bcDash_.full;
case Register::DDash: return deDash_.bytes.high;
case Register::EDash: return deDash_.bytes.low;
case Register::DEDash: return deDash_.full;
case Register::HDash: return hlDash_.bytes.high;
case Register::LDash: return hlDash_.bytes.low;
case Register::HLDash: return hlDash_.full;
case Register::IXh: return ix_.bytes.high;
case Register::IXl: return ix_.bytes.low;
case Register::IX: return ix_.full;
case Register::IYh: return iy_.bytes.high;
case Register::IYl: return iy_.bytes.low;
case Register::IY: return iy_.full;
case Register::R: return r_;
case Register::I: return i_;
case Register::IFF1: return iff1_ ? 1 : 0;
case Register::IFF2: return iff2_ ? 1 : 0;
case Register::IM: return interrupt_mode_;
default: return 0;
}
}
/*!
Sets the value of a register.
@see get_value_of_register
@param r The register to set.
@param value The value to set. If the register is only 8 bit, the value will be truncated.
*/
void set_value_of_register(Register r, uint16_t value) {
switch (r) {
case Register::ProgramCounter: pc_.full = value; break;
case Register::StackPointer: sp_.full = value; break;
case Register::A: a_ = (uint8_t)value; break;
case Register::AF: a_ = (uint8_t)(value >> 8); // deliberate fallthrough...
case Register::Flags: set_flags((uint8_t)value); break;
case Register::B: bc_.bytes.high = (uint8_t)value; break;
case Register::C: bc_.bytes.low = (uint8_t)value; break;
case Register::BC: bc_.full = value; break;
case Register::D: de_.bytes.high = (uint8_t)value; break;
case Register::E: de_.bytes.low = (uint8_t)value; break;
case Register::DE: de_.full = value; break;
case Register::H: hl_.bytes.high = (uint8_t)value; break;
case Register::L: hl_.bytes.low = (uint8_t)value; break;
case Register::HL: hl_.full = value; break;
case Register::ADash: afDash_.bytes.high = (uint8_t)value; break;
case Register::FlagsDash: afDash_.bytes.low = (uint8_t)value; break;
case Register::AFDash: afDash_.full = value; break;
case Register::BDash: bcDash_.bytes.high = (uint8_t)value; break;
case Register::CDash: bcDash_.bytes.low = (uint8_t)value; break;
case Register::BCDash: bcDash_.full = value; break;
case Register::DDash: deDash_.bytes.high = (uint8_t)value; break;
case Register::EDash: deDash_.bytes.low = (uint8_t)value; break;
case Register::DEDash: deDash_.full = value; break;
case Register::HDash: hlDash_.bytes.high = (uint8_t)value; break;
case Register::LDash: hlDash_.bytes.low = (uint8_t)value; break;
case Register::HLDash: hlDash_.full = value; break;
case Register::IXh: ix_.bytes.high = (uint8_t)value; break;
case Register::IXl: ix_.bytes.low = (uint8_t)value; break;
case Register::IX: ix_.full = value; break;
case Register::IYh: iy_.bytes.high = (uint8_t)value; break;
case Register::IYl: iy_.bytes.low = (uint8_t)value; break;
case Register::IY: iy_.full = value; break;
case Register::R: r_ = (uint8_t)value; break;
case Register::I: i_ = (uint8_t)value; break;
case Register::IFF1: iff1_ = !!value; break;
case Register::IFF2: iff2_ = !!value; break;
case Register::IM: interrupt_mode_ = value % 2; break;
default: break;
}
}
/*!
Gets the value of the HALT output line.
*/
bool get_halt_line() {
return halt_mask_ == 0x00;
}
};
}
}
#endif /* Z80_hpp */