1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-18 17:06:15 +00:00
CLK/InstructionSets/M50740/Executor.cpp
2024-01-19 22:02:26 -05:00

852 lines
26 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.

//
// Executor.hpp
// Clock Signal
//
// Created by Thomas Harte on 16/1/21.
// Copyright © 2021 Thomas Harte. All rights reserved.
//
#include "Executor.hpp"
#include "../../Machines/Utility/MemoryFuzzer.hpp"
#include "../../Outputs/Log.hpp"
#include <algorithm>
#include <cassert>
#include <cstring>
using namespace InstructionSet::M50740;
namespace {
constexpr int port_remap[] = {0, 1, 2, 0, 3};
Log::Logger<Log::Source::M50740> logger;
}
Executor::Executor(PortHandler &port_handler) : port_handler_(port_handler) {
// Cut down the list of all generated performers to those the processor actually uses, and install that
// for future referencing by action_for.
Decoder decoder;
for(size_t c = 0; c < 256; c++) {
const auto instruction = decoder.instrucion_for_opcode(uint8_t(c));
// Treat invalid as NOP, because I've got to do _something_.
if(instruction.operation == Operation::Invalid) {
performers_[c] = performer_lookup_.performer(Operation::NOP, instruction.addressing_mode);
} else {
performers_[c] = performer_lookup_.performer(instruction.operation, instruction.addressing_mode);
}
}
// Fuzz RAM; then set anything that may be replaced by ROM to FF.
Memory::Fuzz(memory_);
memset(&memory_[0x100], 0xff, memory_.size() - 0x100);
}
void Executor::set_rom(const std::vector<uint8_t> &rom) {
// Copy into place, and reset.
const auto length = std::min(size_t(0x1000), rom.size());
memcpy(&memory_[0x2000 - length], rom.data(), length);
reset();
}
void Executor::run_for(Cycles cycles) {
// The incoming clock is divided by four; the local cycles_ count
// ensures that fractional parts are kept track of.
cycles_ += cycles;
CachingExecutor::run_for(cycles_.divide(Cycles(4)).as<int>());
}
void Executor::reset() {
// Just jump to the reset vector.
set_program_counter(uint16_t(memory_[0x1ffe] | (memory_[0x1fff] << 8)));
}
void Executor::set_interrupt_line(bool line) {
// Super hack: interrupt now, if permitted. Otherwise do nothing.
// So this will fail to catch enabling of interrupts while the line
// is active, amongst other things.
if(interrupt_line_ != line) {
interrupt_line_ = line;
if(line) {
set_interrupt_request(interrupt_control_, 0x02, 0x1ff4);
}
}
}
uint8_t Executor::read(uint16_t address) {
address &= 0x1fff;
// Deal with RAM and ROM accesses quickly.
if(address < 0x60 || address >= 0x100) return memory_[address];
port_handler_.run_ports_for(cycles_since_port_handler_.flush<Cycles>());
switch(address) {
default:
logger.error().append("Unrecognised read from %02x", address);
return 0xff;
// "Port R"; sixteen four-bit ports
case 0xd0: case 0xd1: case 0xd2: case 0xd3: case 0xd4: case 0xd5: case 0xd6: case 0xd7:
case 0xd8: case 0xd9: case 0xda: case 0xdb: case 0xdc: case 0xdd: case 0xde: case 0xdf:
logger.error().append("Unimplemented Port R read from %04x", address);
return 0x00;
// Ports P0P3.
case 0xe0: case 0xe2:
case 0xe4: case 0xe8: {
const int port = port_remap[(address - 0xe0) >> 1];
const uint8_t input = port_handler_.get_port_input(port);
// In the direction registers, a 0 indicates input, a 1 indicates output.
return (input &~ port_directions_[port]) | (port_outputs_[port] & port_directions_[port]);
}
case 0xe1: case 0xe3:
case 0xe5: case 0xe9:
return port_directions_[port_remap[(address - 0xe0) >> 1]];
// Timers.
case 0xf9: return prescalers_[0].value;
case 0xfa: return timers_[0].value;
case 0xfb: return timers_[1].value;
case 0xfc: return prescalers_[1].value;
case 0xfd: return timers_[2].value;
case 0xfe: return interrupt_control_;
case 0xff: return timer_control_;
}
}
void Executor::set_port_output(int port) {
// Force 'output' to a 1 anywhere that a bit is set as input.
port_handler_.set_port_output(port, port_outputs_[port] | ~port_directions_[port]);
}
void Executor::write(uint16_t address, uint8_t value) {
address &= 0x1fff;
// RAM writes are easy.
if(address < 0x60) {
memory_[address] = value;
return;
}
// ROM 'writes' are almost as easy (albeit unexpected).
if(address >= 0x100) {
logger.info().append("Attempted ROM write of %02x to %04x", value, address);
return;
}
// Push time to the port handler.
port_handler_.run_ports_for(cycles_since_port_handler_.flush<Cycles>());
switch(address) {
default:
logger.error().append("Unrecognised write of %02x to %04x", value, address);
break;
// "Port R"; sixteen four-bit ports
case 0xd0: case 0xd1: case 0xd2: case 0xd3: case 0xd4: case 0xd5: case 0xd6: case 0xd7:
case 0xd8: case 0xd9: case 0xda: case 0xdb: case 0xdc: case 0xdd: case 0xde: case 0xdf:
logger.error().append("Unimplemented Port R write of %02x to %04x", value, address);
break;
// Ports P0P3.
case 0xe0: case 0xe2:
case 0xe4: case 0xe8: {
const int port = port_remap[(address - 0xe0) >> 1];
port_outputs_[port] = value;
set_port_output(port);
}
break;
case 0xe1: case 0xe3:
case 0xe5: case 0xe9: {
const int port = port_remap[(address - 0xe0) >> 1];
port_directions_[port] = value;
set_port_output(port);
} break;
// Timers.
//
// Reloading of value with the reload value is a guess, based upon what I take
// to be the intended usage of timer 2 in handling key repeat on the Apple IIgs.
case 0xf9: prescalers_[0].value = prescalers_[0].reload_value = value; break;
case 0xfa: timers_[0].value = timers_[0].reload_value = value; break;
case 0xfb: timers_[1].value = timers_[1].reload_value = value; break;
case 0xfc: prescalers_[1].value = prescalers_[1].reload_value = value; break;
case 0xfd: timers_[2].value = timers_[2].reload_value = value; break;
case 0xfe: interrupt_control_ = value; break;
case 0xff: timer_control_ = value; break;
}
}
void Executor::push(uint8_t value) {
write(s_, value);
--s_;
}
uint8_t Executor::pull() {
++s_;
return read(s_);
}
void Executor::set_flags(uint8_t flags) {
negative_result_ = flags;
overflow_result_ = uint8_t(flags << 1);
index_mode_ = flags & 0x20;
decimal_mode_ = flags & 0x08;
interrupt_disable_ = flags & 0x04;
zero_result_ = !(flags & 0x02);
carry_flag_ = flags & 0x01;
}
uint8_t Executor::flags() {
return
(negative_result_ & 0x80) |
((overflow_result_ & 0x80) >> 1) |
(index_mode_ ? 0x20 : 0x00) |
(decimal_mode_ ? 0x08 : 0x00) |
interrupt_disable_ |
(zero_result_ ? 0x00 : 0x02) |
carry_flag_;
}
template<bool is_brk> inline void Executor::perform_interrupt(uint16_t vector) {
// BRK has an unused operand.
++program_counter_;
push(uint8_t(program_counter_ >> 8));
push(uint8_t(program_counter_ & 0xff));
push(flags() | (is_brk ? 0x10 : 0x00));
set_program_counter(uint16_t(memory_[vector] | (memory_[vector+1] << 8)));
}
void Executor::set_interrupt_request(uint8_t &reg, uint8_t value, uint16_t vector) {
// TODO: this allows interrupts through only if fully enabled at the time they
// signal. Which isn't quite correct, albeit that it seems sufficient for the
// IIgs ADB controller.
reg |= value;
if(!interrupt_disable_ && (reg & (value >> 1))) {
perform_interrupt<false>(vector);
}
}
template <Operation operation, AddressingMode addressing_mode> void Executor::perform() {
// Post cycle cost; this emulation _does not provide accurate timing_.
#define TLength(mode, base) case AddressingMode::mode: subtract_duration(base + t_lengths[index_mode_]); break;
#define Length(mode, base) case AddressingMode::mode: subtract_duration(base); break;
switch(operation) {
case Operation::ADC: case Operation::AND: case Operation::CMP: case Operation::EOR:
case Operation::LDA: case Operation::ORA: case Operation::SBC:
{
constexpr int t_lengths[] = {
0,
operation == Operation::LDA ? 2 : (operation == Operation::CMP ? 1 : 3)
};
switch(addressing_mode) {
TLength(XIndirect, 6);
TLength(ZeroPage, 3);
TLength(Immediate, 2);
TLength(Absolute, 4);
TLength(IndirectY, 6);
TLength(ZeroPageX, 4);
TLength(AbsoluteY, 5);
TLength(AbsoluteX, 5);
default: assert(false);
}
} break;
case Operation::ASL: case Operation::DEC: case Operation::INC: case Operation::LSR:
case Operation::ROL: case Operation::ROR:
switch(addressing_mode) {
Length(ZeroPage, 5);
Length(Accumulator, 2);
Length(Absolute, 6);
Length(ZeroPageX, 6);
Length(AbsoluteX, 7);
default: assert(false);
}
break;
case Operation::BBC0: case Operation::BBC1: case Operation::BBC2: case Operation::BBC3:
case Operation::BBC4: case Operation::BBC5: case Operation::BBC6: case Operation::BBC7:
case Operation::BBS0: case Operation::BBS1: case Operation::BBS2: case Operation::BBS3:
case Operation::BBS4: case Operation::BBS5: case Operation::BBS6: case Operation::BBS7:
switch(addressing_mode) {
Length(AccumulatorRelative, 4);
Length(ZeroPageRelative, 5);
default: assert(false);
}
break;
case Operation::BPL: case Operation::BMI: case Operation::BEQ: case Operation::BNE:
case Operation::BCS: case Operation::BCC: case Operation::BVS: case Operation::BVC:
case Operation::INX: case Operation::INY:
subtract_duration(2);
break;
case Operation::CPX: case Operation::CPY: case Operation::BIT: case Operation::LDX:
case Operation::LDY:
switch(addressing_mode) {
Length(Immediate, 2);
Length(ZeroPage, 3);
Length(Absolute, 4);
Length(ZeroPageX, 4);
Length(ZeroPageY, 4);
Length(AbsoluteX, 5);
Length(AbsoluteY, 5);
default: assert(false);
}
break;
case Operation::BRA: subtract_duration(4); break;
case Operation::BRK: subtract_duration(7); break;
case Operation::CLB0: case Operation::CLB1: case Operation::CLB2: case Operation::CLB3:
case Operation::CLB4: case Operation::CLB5: case Operation::CLB6: case Operation::CLB7:
case Operation::SEB0: case Operation::SEB1: case Operation::SEB2: case Operation::SEB3:
case Operation::SEB4: case Operation::SEB5: case Operation::SEB6: case Operation::SEB7:
switch(addressing_mode) {
Length(Accumulator, 2);
Length(ZeroPage, 5);
default: assert(false);
}
break;
case Operation::CLC: case Operation::CLD: case Operation::CLT: case Operation::CLV:
case Operation::CLI:
case Operation::DEX: case Operation::DEY: case Operation::FST: case Operation::NOP:
case Operation::SEC: case Operation::SED: case Operation::SEI: case Operation::SET:
case Operation::SLW: case Operation::STP: case Operation::TAX: case Operation::TAY:
case Operation::TSX: case Operation::TXA: case Operation::TXS: case Operation::TYA:
subtract_duration(2);
break;
case Operation::COM: subtract_duration(5); break;
case Operation::JMP:
switch(addressing_mode) {
Length(Absolute, 3);
Length(AbsoluteIndirect, 5);
Length(ZeroPageIndirect, 4);
default: assert(false);
}
break;
case Operation::JSR:
switch(addressing_mode) {
Length(ZeroPageIndirect, 7);
Length(Absolute, 6);
Length(SpecialPage, 5);
default: assert(false);
}
break;
case Operation::LDM: subtract_duration(4); break;
case Operation::PHA: case Operation::PHP: case Operation::TST:
subtract_duration(3);
break;
case Operation::PLA: case Operation::PLP:
subtract_duration(4);
break;
case Operation::RRF: subtract_duration(8); break;
case Operation::RTI: subtract_duration(6); break;
case Operation::RTS: subtract_duration(6); break;
case Operation::STA: case Operation::STX: case Operation::STY:
switch(addressing_mode) {
Length(XIndirect, 7);
Length(ZeroPage, 4);
Length(Absolute, 5);
Length(IndirectY, 7);
Length(ZeroPageX, 5);
Length(ZeroPageY, 5);
Length(AbsoluteY, 6);
Length(AbsoluteX, 6);
default: assert(false);
}
break;
default: assert(false);
}
// Deal with all modes that don't access memory up here;
// those that access memory will go through a slightly longer
// sequence below that wraps the address and checks whether
// a write is valid [if required].
unsigned int address;
#define next8() memory_[(program_counter_ + 1) & 0x1fff]
#define next16() uint16_t(memory_[(program_counter_ + 1) & 0x1fff] | (memory_[(program_counter_ + 2) & 0x1fff] << 8))
// Underlying assumption below: the instruction stream will never
// overlap with IO ports.
switch(addressing_mode) {
// Addressing modes with no further memory access.
case AddressingMode::Implied:
perform<operation>(nullptr);
++program_counter_;
return;
case AddressingMode::Accumulator:
perform<operation>(&a_);
++program_counter_;
return;
case AddressingMode::Immediate:
perform<operation>(&next8());
program_counter_ += 2;
return;
// Special-purpose addressing modes.
case AddressingMode::Relative:
address = unsigned(program_counter_ + 1 + size(addressing_mode) + int8_t(next8()));
break;
case AddressingMode::SpecialPage: address = 0x1f00 | next8(); break;
case AddressingMode::ImmediateZeroPage:
// LDM only...
write(memory_[(program_counter_+2)&0x1fff], memory_[(program_counter_+1)&0x1fff]);
program_counter_ += 1 + size(addressing_mode);
return;
case AddressingMode::AccumulatorRelative:
case AddressingMode::ZeroPageRelative: {
// Order of bytes is: (i) zero page address; (ii) relative jump.
uint8_t value;
if constexpr (addressing_mode == AddressingMode::AccumulatorRelative) {
value = a_;
address = unsigned(program_counter_ + 1 + size(addressing_mode) + int8_t(next8()));
} else {
value = read(next8());
address = unsigned(program_counter_ + 1 + size(addressing_mode) + int8_t(memory_[(program_counter_+2)&0x1fff]));
}
program_counter_ += 1 + size(addressing_mode);
switch(operation) {
case Operation::BBS0: case Operation::BBS1: case Operation::BBS2: case Operation::BBS3:
case Operation::BBS4: case Operation::BBS5: case Operation::BBS6: case Operation::BBS7: {
if constexpr (operation >= Operation::BBS0 && operation <= Operation::BBS7) {
constexpr uint8_t mask = 1 << (int(operation) - int(Operation::BBS0));
if(value & mask) {
set_program_counter(uint16_t(address));
subtract_duration(2);
}
}
} return;
case Operation::BBC0: case Operation::BBC1: case Operation::BBC2: case Operation::BBC3:
case Operation::BBC4: case Operation::BBC5: case Operation::BBC6: case Operation::BBC7: {
if constexpr (operation >= Operation::BBC0 && operation <= Operation::BBC7) {
constexpr uint8_t mask = 1 << (int(operation) - int(Operation::BBC0));
if(!(value & mask)) {
set_program_counter(uint16_t(address));
subtract_duration(2);
}
}
} return;
default: assert(false);
}
} break;
// Addressing modes with a memory access.
case AddressingMode::Absolute: address = next16(); break;
case AddressingMode::AbsoluteX: address = next16() + x_; break;
case AddressingMode::AbsoluteY: address = next16() + y_; break;
case AddressingMode::ZeroPage: address = next8(); break;
case AddressingMode::ZeroPageX: address = (next8() + x_) & 0xff; break;
case AddressingMode::ZeroPageY: address = (next8() + y_) & 0xff; break;
case AddressingMode::ZeroPageIndirect:
address = next8();
address = unsigned(memory_[address] | (memory_[(address + 1) & 0xff] << 8));
break;
case AddressingMode::XIndirect:
address = (next8() + x_) & 0xff;
address = unsigned(memory_[address] | (memory_[(address + 1)&0xff] << 8));
break;
case AddressingMode::IndirectY:
address = unsigned((memory_[next8()] | (memory_[(next8()+1)&0xff] << 8)) + y_);
break;
case AddressingMode::AbsoluteIndirect:
address = next16();
address = unsigned(memory_[address & 0x1fff] | (memory_[(address + 1) & 0x1fff] << 8));
break;
default:
assert(false);
}
#undef next16
#undef next8
program_counter_ += 1 + size(addressing_mode);
// Check for a branch; those don't go through the memory accesses below.
switch(operation) {
case Operation::BRA: case Operation::JMP:
set_program_counter(uint16_t(address));
return;
case Operation::JSR: {
// Push one less than the actual return address.
const auto return_address = program_counter_ - 1;
push(uint8_t(return_address >> 8));
push(uint8_t(return_address & 0xff));
set_program_counter(uint16_t(address));
} return;
#define Bcc(c) if(c) { set_program_counter(uint16_t(address)); subtract_duration(2); } return
case Operation::BPL: Bcc(!(negative_result_&0x80));
case Operation::BMI: Bcc(negative_result_&0x80);
case Operation::BEQ: Bcc(!zero_result_);
case Operation::BNE: Bcc(zero_result_);
case Operation::BCS: Bcc(carry_flag_);
case Operation::BCC: Bcc(!carry_flag_);
case Operation::BVS: Bcc(overflow_result_ & 0x80);
case Operation::BVC: Bcc(!(overflow_result_ & 0x80));
#undef Bcc
default: break;
}
assert(access_type(operation) != AccessType::None);
if constexpr(access_type(operation) == AccessType::Read) {
uint8_t source = read(uint16_t(address));
perform<operation>(&source);
return;
}
uint8_t value;
if constexpr(access_type(operation) == AccessType::ReadModifyWrite) {
value = read(uint16_t(address));
} else {
value = 0xff;
}
perform<operation>(&value);
write(uint16_t(address), value);
}
template <Operation operation> void Executor::perform(uint8_t *operand [[maybe_unused]]) {
#define set_nz(a) negative_result_ = zero_result_ = (a)
switch(operation) {
case Operation::LDA:
if(index_mode_) {
write(x_, *operand);
set_nz(*operand);
} else {
set_nz(a_ = *operand);
}
break;
case Operation::LDX: set_nz(x_ = *operand); break;
case Operation::LDY: set_nz(y_ = *operand); break;
case Operation::STA: *operand = a_; break;
case Operation::STX: *operand = x_; break;
case Operation::STY: *operand = y_; break;
case Operation::TXA: set_nz(a_ = x_); break;
case Operation::TYA: set_nz(a_ = y_); break;
case Operation::TXS: s_ = x_; break;
case Operation::TAX: set_nz(x_ = a_); break;
case Operation::TAY: set_nz(y_ = a_); break;
case Operation::TSX: set_nz(x_ = s_); break;
case Operation::SEB0: case Operation::SEB1: case Operation::SEB2: case Operation::SEB3:
case Operation::SEB4: case Operation::SEB5: case Operation::SEB6: case Operation::SEB7:
if constexpr(operation >= Operation::SEB0 && operation <= Operation::SEB7) {
*operand |= 1 << (int(operation) - int(Operation::SEB0));
}
break;
case Operation::CLB0: case Operation::CLB1: case Operation::CLB2: case Operation::CLB3:
case Operation::CLB4: case Operation::CLB5: case Operation::CLB6: case Operation::CLB7:
if constexpr(operation >= Operation::CLB0 && operation <= Operation::CLB7) {
*operand &= ~(1 << (int(operation) - int(Operation::CLB0)));
}
break;
case Operation::CLI: interrupt_disable_ = 0x00; break;
case Operation::SEI: interrupt_disable_ = 0x04; break;
case Operation::CLT: index_mode_ = false; break;
case Operation::SET: index_mode_ = true; break;
case Operation::CLD: decimal_mode_ = false; break;
case Operation::SED: decimal_mode_ = true; break;
case Operation::CLC: carry_flag_ = 0; break;
case Operation::SEC: carry_flag_ = 1; break;
case Operation::CLV: overflow_result_ = 0; break;
case Operation::DEX: --x_; set_nz(x_); break;
case Operation::INX: ++x_; set_nz(x_); break;
case Operation::DEY: --y_; set_nz(y_); break;
case Operation::INY: ++y_; set_nz(y_); break;
case Operation::DEC: --*operand; set_nz(*operand); break;
case Operation::INC: ++*operand; set_nz(*operand); break;
case Operation::RTS: {
uint16_t target = pull();
target |= pull() << 8;
set_program_counter(target+1);
--program_counter_; // To undo the unavoidable increment
// after exiting from here.
} break;
case Operation::RTI: {
set_flags(pull());
uint16_t target = pull();
target |= pull() << 8;
set_program_counter(target);
--program_counter_; // To undo the unavoidable increment
// after exiting from here.
} break;
case Operation::BRK:
perform_interrupt<true>(0x1ff4);
--program_counter_; // To undo the unavoidable increment
// after exiting from here.
break;
case Operation::STP: set_is_stopped(true); break;
case Operation::COM: set_nz(*operand ^= 0xff); break;
case Operation::FST: case Operation::SLW: case Operation::NOP:
// TODO: communicate FST and SLW onwards, I imagine. Find out what they interface with.
break;
case Operation::PHA: push(a_); break;
case Operation::PHP: push(flags()); break;
case Operation::PLA: set_nz(a_ = pull()); break;
case Operation::PLP: set_flags(pull()); break;
case Operation::ASL:
carry_flag_ = *operand >> 7;
*operand <<= 1;
set_nz(*operand);
break;
case Operation::LSR:
carry_flag_ = *operand & 1;
*operand >>= 1;
set_nz(*operand);
break;
case Operation::ROL: {
const uint8_t temp8 = uint8_t((*operand << 1) | carry_flag_);
carry_flag_ = *operand >> 7;
set_nz(*operand = temp8);
} break;
case Operation::ROR: {
const uint8_t temp8 = uint8_t((*operand >> 1) | (carry_flag_ << 7));
carry_flag_ = *operand & 1;
set_nz(*operand = temp8);
} break;
case Operation::RRF:
*operand = uint8_t((*operand >> 4) | (*operand << 4));
break;
case Operation::BIT:
zero_result_ = *operand & a_;
negative_result_ = *operand;
overflow_result_ = uint8_t(*operand << 1);
break;
case Operation::TST:
set_nz(*operand);
break;
/*
Operations affected by the index mode flag: ADC, AND, CMP, EOR, LDA, ORA, and SBC.
*/
#define index(op) \
if(index_mode_) { \
uint8_t t = read(x_); \
op(t); \
write(x_, t); \
} else { \
op(a_); \
}
#define op_ora(x) set_nz(x |= *operand)
#define op_and(x) set_nz(x &= *operand)
#define op_eor(x) set_nz(x ^= *operand)
case Operation::ORA: index(op_ora); break;
case Operation::AND: index(op_and); break;
case Operation::EOR: index(op_eor); break;
#undef op_eor
#undef op_and
#undef op_ora
#undef index
#define op_cmp(x) { \
const uint16_t temp16 = x - *operand; \
set_nz(uint8_t(temp16)); \
carry_flag_ = (~temp16 >> 8)&1; \
}
case Operation::CMP:
if(index_mode_) {
op_cmp(read(x_));
} else {
op_cmp(a_);
}
break;
case Operation::CPX: op_cmp(x_); break;
case Operation::CPY: op_cmp(y_); break;
#undef op_cmp
case Operation::SBC:
case Operation::ADC: {
const uint8_t a = index_mode_ ? read(x_) : a_;
if(decimal_mode_) {
if(operation == Operation::ADC) {
uint16_t partials = 0;
int result = carry_flag_;
#define nibble(mask, limit, adjustment, carry) \
result += (a & mask) + (*operand & mask); \
partials += result & mask; \
if(result >= limit) result = ((result + (adjustment)) & (carry - 1)) + carry;
nibble(0x000f, 0x000a, 0x0006, 0x00010);
nibble(0x00f0, 0x00a0, 0x0060, 0x00100);
#undef nibble
overflow_result_ = uint8_t((partials ^ a) & (partials ^ *operand));
set_nz(uint8_t(result));
carry_flag_ = (result >> 8) & 1;
} else {
unsigned int result = 0;
unsigned int borrow = carry_flag_ ^ 1;
const uint16_t decimal_result = uint16_t(a - *operand - borrow);
#define nibble(mask, adjustment, carry) \
result += (a & mask) - (*operand & mask) - borrow; \
if(result > mask) result -= adjustment; \
borrow = (result > mask) ? carry : 0; \
result &= (carry - 1);
nibble(0x000f, 0x0006, 0x00010);
nibble(0x00f0, 0x0060, 0x00100);
#undef nibble
overflow_result_ = uint8_t((decimal_result ^ a) & (~decimal_result ^ *operand));
set_nz(uint8_t(result));
carry_flag_ = ((borrow >> 8)&1)^1;
}
} else {
int result;
if(operation == Operation::ADC) {
result = int(a + *operand + carry_flag_);
overflow_result_ = uint8_t((result ^ a) & (result ^ *operand));
} else {
result = int(a + ~*operand + carry_flag_);
overflow_result_ = uint8_t((result ^ a) & (result ^ ~*operand));
}
set_nz(uint8_t(result));
carry_flag_ = (result >> 8) & 1;
}
if(index_mode_) {
write(x_, a);
} else {
a_ = a;
}
} break;
/*
Already removed from the instruction stream:
* all branches and jumps;
* LDM.
*/
default:
logger.error().append("Unimplemented operation: %d", operation);
assert(false);
}
#undef set_nz
}
inline void Executor::subtract_duration(int duration) {
// Pass along.
CachingExecutor::subtract_duration(duration);
// Update count for potential port accesses.
cycles_since_port_handler_ += Cycles(duration);
// Update timer 1 and 2 prescaler.
constexpr int t12_divider = 4; // A divide by 4 has already been applied before counting instruction lengths; therefore
// this additional divide by 4 produces the correct net divide by 16.
timer_divider_ += duration;
const int clock_ticks = timer_divider_ / t12_divider;
timer_divider_ &= (t12_divider-1);
// Update timers 1 and 2.
const int t12_ticks = update_timer(prescalers_[0], timer_divider_ / t12_divider);
if(update_timer(timers_[0], t12_ticks)) {
set_interrupt_request(interrupt_control_, 0x20, 0x1ff8);
}
if(update_timer(timers_[1], t12_ticks)) {
set_interrupt_request(interrupt_control_, 0x08, 0x1ff6);
}
// If timer X is disabled, stop.
if(timer_control_&0x20) {
return;
}
// Update timer X prescaler.
switch(timer_control_ & 0x0c) {
default: {
const int tx_ticks = update_timer(prescalers_[1], clock_ticks);
if(update_timer(timers_[2], tx_ticks)) {
set_interrupt_request(timer_control_, 0x80, 0x1ffa);
}
} break;
case 0x04:
logger.error().append("TODO: Timer X; Pulse output mode");
break;
case 0x08:
logger.error().append("TODO: Timer X; Event counter mode");
break;
case 0x0c:
logger.error().append("TODO: Timer X; Pulse width measurement mode");
break;
}
}
inline int Executor::update_timer(Timer &timer, int count) {
const int next_value = timer.value - count;
if(next_value < 0) {
// Determine how many reloads were required to get above zero.
const int reload_value = timer.reload_value ? timer.reload_value : 256;
const int underflow_count = 1 - next_value / reload_value;
timer.value = uint8_t((next_value % reload_value) + timer.reload_value);
return underflow_count;
}
timer.value = uint8_t(next_value);
return 0;
}
uint8_t Executor::get_output_mask(int port) {
return port_directions_[port];
}