// // // PerformImplementation.hpp // Clock Signal // // Created by Thomas Harte on 05/10/2023. // Copyright © 2023 Thomas Harte. All rights reserved. // #ifndef PerformImplementation_h #define PerformImplementation_h #include "Arithmetic.hpp" #include "BCD.hpp" #include "FlowControl.hpp" #include "InOut.hpp" #include "LoadStore.hpp" #include "Logical.hpp" #include "Repetition.hpp" #include "Resolver.hpp" #include "ShiftRoll.hpp" #include "Stack.hpp" #include "../Interrupts.hpp" #include "../AccessType.hpp" // // Comments throughout headers above come from the 1997 edition of the // Intel Architecture Software Developer’s Manual; that year all such // definitions still fitted within a single volume, Volume 2. // // Order Number 243191; e.g. https://www.ardent-tool.com/CPU/docs/Intel/IA/243191-002.pdf // namespace InstructionSet::x86 { template < DataSize data_size, AddressSize address_size, typename InstructionT, typename ContextT > void perform( const InstructionT &instruction, ContextT &context ) { using IntT = typename DataSizeType::type; using AddressT = typename AddressSizeType::type; // Establish source() and destination() shorthands to fetch data if necessary. // // C++17, which this project targets at the time of writing, does not provide templatised lambdas. // So the following division is in part a necessity. // // (though GCC offers C++20 syntax as an extension, and Clang seems to follow along, so maybe I'm overthinking) IntT immediate; const auto source_r = [&]() -> read_t { return resolve( instruction, instruction.source().source(), instruction.source(), context, nullptr, &immediate); }; const auto source_rmw = [&]() -> modify_t { return resolve( instruction, instruction.source().source(), instruction.source(), context, nullptr, &immediate); }; const auto destination_r = [&]() -> read_t { return resolve( instruction, instruction.destination().source(), instruction.destination(), context, nullptr, &immediate); }; const auto destination_w = [&]() -> write_t { return resolve( instruction, instruction.destination().source(), instruction.destination(), context, nullptr, &immediate); }; const auto destination_rmw = [&]() -> modify_t { return resolve( instruction, instruction.destination().source(), instruction.destination(), context, nullptr, &immediate); }; // Performs a displacement jump only if @c condition is true. const auto jcc = [&](bool condition) { Primitive::jump( condition, instruction.displacement(), context); }; const auto shift_count = [&]() -> uint8_t { static constexpr uint8_t mask = (ContextT::model != Model::i8086) ? 0x1f : 0xff; switch(instruction.source().source()) { case Source::None: return 1; case Source::Immediate: return uint8_t(instruction.operand()) & mask; default: return context.registers.cl() & mask; } }; // Some instructions use a pair of registers as an extended accumulator — DX:AX or EDX:EAX. // The two following return the high and low parts of that pair; they also work in Byte mode to return AH:AL, // i.e. AX split into high and low parts. const auto pair_high = [&]() -> IntT& { if constexpr (data_size == DataSize::Byte) return context.registers.ah(); else if constexpr (data_size == DataSize::Word) return context.registers.dx(); else if constexpr (data_size == DataSize::DWord) return context.registers.edx(); }; const auto pair_low = [&]() -> IntT& { if constexpr (data_size == DataSize::Byte) return context.registers.al(); else if constexpr (data_size == DataSize::Word) return context.registers.ax(); else if constexpr (data_size == DataSize::DWord) return context.registers.eax(); }; // For the string operations, evaluate to either SI and DI or ESI and EDI, depending on the address size. const auto eSI = [&]() -> AddressT& { if constexpr (std::is_same_v) { return context.registers.si(); } else { return context.registers.esi(); } }; const auto eDI = [&]() -> AddressT& { if constexpr (std::is_same_v) { return context.registers.di(); } else { return context.registers.edi(); } }; // For counts, provide either eCX or CX depending on address size. const auto eCX = [&]() -> AddressT& { if constexpr (std::is_same_v) { return context.registers.cx(); } else { return context.registers.ecx(); } }; // Gets the port for an IN or OUT; these are always 16-bit. const auto port = [&](Source source) -> uint16_t { switch(source) { case Source::DirectAddress: return instruction.offset(); default: return context.registers.dx(); } }; // Guide to the below: // // * use hard-coded register names where appropriate, otherwise use the source_X() and destination_X() lambdas; // * return directly if there is definitely no possible write back to RAM; // * break if there's a chance of writeback. switch(instruction.operation()) { default: assert(false); case Operation::ESC: case Operation::NOP: return; case Operation::AAM: Primitive::aam(context.registers.axp(), uint8_t(instruction.operand()), context); return; case Operation::AAD: Primitive::aad(context.registers.axp(), uint8_t(instruction.operand()), context); return; case Operation::AAA: Primitive::aaas(context.registers.axp(), context); return; case Operation::AAS: Primitive::aaas(context.registers.axp(), context); return; case Operation::DAA: Primitive::daas(context.registers.al(), context); return; case Operation::DAS: Primitive::daas(context.registers.al(), context); return; case Operation::CBW: Primitive::cbw(pair_low()); return; case Operation::CWD: Primitive::cwd(pair_high(), pair_low()); return; case Operation::HLT: context.flow_controller.halt(); return; case Operation::WAIT: context.flow_controller.wait(); return; case Operation::ADC: Primitive::add(destination_rmw(), source_r(), context); break; case Operation::ADD: Primitive::add(destination_rmw(), source_r(), context); break; case Operation::SBB: Primitive::sub(destination_rmw(), source_r(), context); break; case Operation::SUB: Primitive::sub(destination_rmw(), source_r(), context); break; case Operation::CMP: Primitive::sub(destination_r(), source_r(), context); return; case Operation::TEST: Primitive::test(destination_r(), source_r(), context); return; case Operation::MUL: Primitive::mul(pair_high(), pair_low(), source_r(), context); return; case Operation::IMUL_1: Primitive::imul(pair_high(), pair_low(), source_r(), context); return; case Operation::DIV: Primitive::div(pair_high(), pair_low(), source_r(), context); return; case Operation::IDIV: Primitive::idiv(pair_high(), pair_low(), source_r(), context); return; case Operation::IDIV_REP: if constexpr (ContextT::model == Model::i8086) { Primitive::idiv(pair_high(), pair_low(), source_r(), context); break; } else { static_assert(int(Operation::IDIV_REP) == int(Operation::LEAVE)); if constexpr (std::is_same_v || std::is_same_v) { Primitive::leave(); } } return; case Operation::INC: Primitive::inc(destination_rmw(), context); break; case Operation::DEC: Primitive::dec(destination_rmw(), context); break; case Operation::AND: Primitive::and_(destination_rmw(), source_r(), context); break; case Operation::OR: Primitive::or_(destination_rmw(), source_r(), context); break; case Operation::XOR: Primitive::xor_(destination_rmw(), source_r(), context); break; case Operation::NEG: Primitive::neg(source_rmw(), context); break; // TODO: should be a destination. case Operation::NOT: Primitive::not_(source_rmw()); break; // TODO: should be a destination. case Operation::CALLrel: Primitive::call_relative(instruction.displacement(), context); return; case Operation::CALLabs: Primitive::call_absolute(destination_r(), context); return; case Operation::CALLfar: Primitive::call_far(instruction, context); return; case Operation::JMPrel: jcc(true); return; case Operation::JMPabs: Primitive::jump_absolute(destination_r(), context); return; case Operation::JMPfar: Primitive::jump_far(instruction, context); return; case Operation::JCXZ: jcc(!eCX()); return; case Operation::LOOP: Primitive::loop(eCX(), instruction.offset(), context); return; case Operation::LOOPE: Primitive::loope(eCX(), instruction.offset(), context); return; case Operation::LOOPNE: Primitive::loopne(eCX(), instruction.offset(), context); return; case Operation::IRET: Primitive::iret(context); return; case Operation::RETnear: Primitive::ret_near(instruction, context); return; case Operation::RETfar: Primitive::ret_far(instruction, context); return; case Operation::INT: interrupt(instruction.operand(), context); return; case Operation::INTO: Primitive::into(context); return; case Operation::SAHF: Primitive::sahf(context.registers.ah(), context); return; case Operation::LAHF: Primitive::lahf(context.registers.ah(), context); return; case Operation::LDS: if constexpr (data_size == DataSize::Word) { Primitive::ld(instruction, destination_w(), context); context.segments.did_update(Source::DS); } return; case Operation::LES: if constexpr (data_size == DataSize::Word) { Primitive::ld(instruction, destination_w(), context); context.segments.did_update(Source::ES); } return; case Operation::LEA: Primitive::lea(instruction, destination_w(), context); return; case Operation::MOV: Primitive::mov(destination_w(), source_r()); if constexpr (std::is_same_v) { context.segments.did_update(instruction.destination().source()); } break; case Operation::JO: jcc(context.flags.template condition()); return; case Operation::JNO: jcc(!context.flags.template condition()); return; case Operation::JB: jcc(context.flags.template condition()); return; case Operation::JNB: jcc(!context.flags.template condition()); return; case Operation::JZ: jcc(context.flags.template condition()); return; case Operation::JNZ: jcc(!context.flags.template condition()); return; case Operation::JBE: jcc(context.flags.template condition()); return; case Operation::JNBE: jcc(!context.flags.template condition()); return; case Operation::JS: jcc(context.flags.template condition()); return; case Operation::JNS: jcc(!context.flags.template condition()); return; case Operation::JP: jcc(!context.flags.template condition()); return; case Operation::JNP: jcc(context.flags.template condition()); return; case Operation::JL: jcc(context.flags.template condition()); return; case Operation::JNL: jcc(!context.flags.template condition()); return; case Operation::JLE: jcc(context.flags.template condition()); return; case Operation::JNLE: jcc(!context.flags.template condition()); return; case Operation::RCL: Primitive::rcl(destination_rmw(), shift_count(), context); break; case Operation::RCR: Primitive::rcr(destination_rmw(), shift_count(), context); break; case Operation::ROL: Primitive::rol(destination_rmw(), shift_count(), context); break; case Operation::ROR: Primitive::ror(destination_rmw(), shift_count(), context); break; case Operation::SAL: Primitive::sal(destination_rmw(), shift_count(), context); break; case Operation::SAR: Primitive::sar(destination_rmw(), shift_count(), context); break; case Operation::SHR: Primitive::shr(destination_rmw(), shift_count(), context); break; case Operation::CLC: Primitive::clc(context); return; case Operation::CLD: Primitive::cld(context); return; case Operation::CLI: Primitive::cli(context); return; case Operation::STC: Primitive::stc(context); return; case Operation::STD: Primitive::std(context); return; case Operation::STI: Primitive::sti(context); return; case Operation::CMC: Primitive::cmc(context); return; case Operation::XCHG: Primitive::xchg(destination_rmw(), source_rmw()); break; case Operation::SALC: Primitive::salc(context.registers.al(), context); return; case Operation::SETMO: if constexpr (ContextT::model == Model::i8086) { Primitive::setmo(destination_w(), context); break; } else { static_assert(int(Operation::SETMO) == int(Operation::ENTER)); Primitive::enter(instruction, context); } return; case Operation::SETMOC: if constexpr (ContextT::model == Model::i8086) { // Test CL out here to avoid taking a reference to memory if // no write is going to occur. if(context.registers.cl()) { Primitive::setmo(destination_w(), context); } break; } else { static_assert(int(Operation::SETMOC) == int(Operation::BOUND)); Primitive::bound(instruction, destination_r(), source_r(), context); } return; case Operation::OUT: Primitive::out(port(instruction.destination().source()), pair_low(), context); return; case Operation::IN: Primitive::in(port(instruction.source().source()), pair_low(), context); return; case Operation::XLAT: Primitive::xlat(instruction, context); return; case Operation::POP: destination_w() = Primitive::pop(context); if constexpr (std::is_same_v) { context.segments.did_update(instruction.destination().source()); } break; case Operation::PUSH: Primitive::push(source_rmw(), context); // PUSH SP modifies SP before pushing it; // hence PUSH is sometimes read-modify-write. break; case Operation::POPF: if constexpr (std::is_same_v || std::is_same_v) { Primitive::popf(context); } return; case Operation::PUSHF: if constexpr (std::is_same_v || std::is_same_v) { Primitive::pushf(context); } return; case Operation::POPA: if constexpr (std::is_same_v || std::is_same_v) { Primitive::popa(context); } return; case Operation::PUSHA: if constexpr (std::is_same_v || std::is_same_v) { Primitive::pusha(context); } return; case Operation::CMPS: Primitive::cmps(instruction, eCX(), eSI(), eDI(), context); return; case Operation::CMPS_REPE: Primitive::cmps(instruction, eCX(), eSI(), eDI(), context); return; case Operation::CMPS_REPNE: Primitive::cmps(instruction, eCX(), eSI(), eDI(), context); return; case Operation::SCAS: Primitive::scas(eCX(), eDI(), pair_low(), context); return; case Operation::SCAS_REPE: Primitive::scas(eCX(), eDI(), pair_low(), context); return; case Operation::SCAS_REPNE: Primitive::scas(eCX(), eDI(), pair_low(), context); return; case Operation::LODS: Primitive::lods(instruction, eCX(), eSI(), pair_low(), context); return; case Operation::LODS_REP: Primitive::lods(instruction, eCX(), eSI(), pair_low(), context); return; case Operation::MOVS: Primitive::movs(instruction, eCX(), eSI(), eDI(), context); break; case Operation::MOVS_REP: Primitive::movs(instruction, eCX(), eSI(), eDI(), context); break; case Operation::STOS: Primitive::stos(eCX(), eDI(), pair_low(), context); break; case Operation::STOS_REP: Primitive::stos(eCX(), eDI(), pair_low(), context); break; case Operation::OUTS: Primitive::outs(instruction, eCX(), context.registers.dx(), eSI(), context); return; case Operation::OUTS_REP: Primitive::outs(instruction, eCX(), context.registers.dx(), eSI(), context); return; case Operation::INS: Primitive::ins(eCX(), context.registers.dx(), eDI(), context); break; case Operation::INS_REP: Primitive::ins(eCX(), context.registers.dx(), eDI(), context); break; } // Write to memory if required to complete this operation. // // This is not currently handled via RAII because of the amount of context that would need to place onto the stack; // instead code has been set up to make sure there is only at most one writeable target on loan for potential // write back. I might flip-flop on this, especially if I can verify whether extra stack context is easily // optimised out. context.memory.template write_back(); } // // Public function; just a trampoline into a version of perform templated on data and address size. // // Which, yes, means there's an outer switch leading to an inner switch, which could be reduced to one big switch. // It'd be a substantial effort to find the most neat expression of that, I think, so it is not currently done. // template < typename InstructionT, typename ContextT > void perform( const InstructionT &instruction, ContextT &context ) { auto size = [](DataSize operation_size, AddressSize address_size) constexpr -> int { return int(operation_size) + (int(address_size) << 2); }; // Dispatch to a function specialised on data and address size. switch(size(instruction.operation_size(), instruction.address_size())) { // 16-bit combinations. case size(DataSize::Byte, AddressSize::b16): perform(instruction, context); return; case size(DataSize::Word, AddressSize::b16): perform(instruction, context); return; // 32-bit combinations. // // The if constexprs below ensure that `perform` isn't compiled for incompatible data or address size and // model combinations. So if a caller nominates a 16-bit model it can supply registers and memory objects // that don't implement 32-bit registers or accesses. case size(DataSize::Byte, AddressSize::b32): if constexpr (is_32bit(ContextT::model)) { perform(instruction, context); return; } break; case size(DataSize::Word, AddressSize::b32): if constexpr (is_32bit(ContextT::model)) { perform(instruction, context); return; } break; case size(DataSize::DWord, AddressSize::b16): if constexpr (is_32bit(ContextT::model)) { perform(instruction, context); return; } break; case size(DataSize::DWord, AddressSize::b32): if constexpr (is_32bit(ContextT::model)) { perform(instruction, context); return; } break; default: break; } // This is reachable only if the data and address size combination in use isn't available // on the processor model nominated. assert(false); } template < typename ContextT > void interrupt( int index, ContextT &context ) { const uint32_t address = static_cast(index) << 2; context.memory.preauthorise_read(address, sizeof(uint16_t) * 2); context.memory.preauthorise_stack_write(sizeof(uint16_t) * 3); const uint16_t ip = context.memory.template access(address); const uint16_t cs = context.memory.template access(address + 2); auto flags = context.flags.get(); Primitive::push(flags, context); context.flags.template set_from(0); // Push CS and IP. Primitive::push(context.registers.cs(), context); Primitive::push(context.registers.ip(), context); // Set new destination. context.flow_controller.jump(cs, ip); } } #endif /* PerformImplementation_h */