// // // 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 "../../../Numeric/Carry.hpp" #include "../../../Numeric/RegisterSizes.hpp" #include "../Interrupts.hpp" #include namespace InstructionSet::x86 { template IntT *resolve( InstructionT &instruction, Source source, DataPointer pointer, ContextT &context, IntT *none = nullptr, IntT *immediate = nullptr ); template uint32_t address( InstructionT &instruction, DataPointer pointer, ContextT &context ) { // TODO: non-word indexes and bases. if constexpr (source == Source::DirectAddress) { return instruction.offset(); } uint32_t address; uint16_t zero = 0; address = *resolve(instruction, pointer.index(), pointer, context, &zero); if constexpr (is_32bit(ContextT::model)) { address <<= pointer.scale(); } address += instruction.offset(); if constexpr (source == Source::IndirectNoBase) { return address; } return address + *resolve(instruction, pointer.base(), pointer, context); } template IntT *register_(ContextT &context) { static constexpr bool supports_dword = is_32bit(ContextT::model); switch(source) { case Source::eAX: // Slightly contorted if chain here and below: // // (i) does the `constexpr` version of a `switch`; and // (i) ensures .eax() etc aren't called on @c registers for 16-bit processors, so they need not implement 32-bit storage. if constexpr (supports_dword && std::is_same_v) { return &context.registers.eax(); } else if constexpr (std::is_same_v) { return &context.registers.ax(); } else if constexpr (std::is_same_v) { return &context.registers.al(); } else { return nullptr; } case Source::eCX: if constexpr (supports_dword && std::is_same_v) { return &context.registers.ecx(); } else if constexpr (std::is_same_v) { return &context.registers.cx(); } else if constexpr (std::is_same_v) { return &context.registers.cl(); } else { return nullptr; } case Source::eDX: if constexpr (supports_dword && std::is_same_v) { return &context.registers.edx(); } else if constexpr (std::is_same_v) { return &context.registers.dx(); } else if constexpr (std::is_same_v) { return &context.registers.dl(); } else if constexpr (std::is_same_v) { return nullptr; } case Source::eBX: if constexpr (supports_dword && std::is_same_v) { return &context.registers.ebx(); } else if constexpr (std::is_same_v) { return &context.registers.bx(); } else if constexpr (std::is_same_v) { return &context.registers.bl(); } else if constexpr (std::is_same_v) { return nullptr; } case Source::eSPorAH: if constexpr (supports_dword && std::is_same_v) { return &context.registers.esp(); } else if constexpr (std::is_same_v) { return &context.registers.sp(); } else if constexpr (std::is_same_v) { return &context.registers.ah(); } else { return nullptr; } case Source::eBPorCH: if constexpr (supports_dword && std::is_same_v) { return &context.registers.ebp(); } else if constexpr (std::is_same_v) { return &context.registers.bp(); } else if constexpr (std::is_same_v) { return &context.registers.ch(); } else { return nullptr; } case Source::eSIorDH: if constexpr (supports_dword && std::is_same_v) { return &context.registers.esi(); } else if constexpr (std::is_same_v) { return &context.registers.si(); } else if constexpr (std::is_same_v) { return &context.registers.dh(); } else { return nullptr; } case Source::eDIorBH: if constexpr (supports_dword && std::is_same_v) { return &context.registers.edi(); } else if constexpr (std::is_same_v) { return &context.registers.di(); } else if constexpr (std::is_same_v) { return &context.registers.bh(); } else { return nullptr; } default: return nullptr; } } template uint32_t address( InstructionT &instruction, DataPointer pointer, ContextT &context ) { // TODO: at least on the 8086 this isn't how register 'addresses' are resolved; instead whatever was the last computed address // remains in the address register and is returned. Find out what other x86s do and make a decision. switch(pointer.source()) { default: return 0; case Source::eAX: return *register_(context); case Source::eCX: return *register_(context); case Source::eDX: return *register_(context); case Source::eBX: return *register_(context); case Source::eSPorAH: return *register_(context); case Source::eBPorCH: return *register_(context); case Source::eSIorDH: return *register_(context); case Source::eDIorBH: return *register_(context); case Source::Indirect: return address(instruction, pointer, context); case Source::IndirectNoBase: return address(instruction, pointer, context); case Source::DirectAddress: return address(instruction, pointer, context); } } template IntT *resolve( InstructionT &instruction, Source source, DataPointer pointer, ContextT &context, IntT *none, IntT *immediate ) { // Rules: // // * if this is a memory access, set target_address and break; // * otherwise return the appropriate value. uint32_t target_address; switch(source) { case Source::eAX: return register_(context); case Source::eCX: return register_(context); case Source::eDX: return register_(context); case Source::eBX: return register_(context); case Source::eSPorAH: return register_(context); case Source::eBPorCH: return register_(context); case Source::eSIorDH: return register_(context); case Source::eDIorBH: return register_(context); // Segment registers are always 16-bit. case Source::ES: if constexpr (std::is_same_v) return &context.registers.es(); else return nullptr; case Source::CS: if constexpr (std::is_same_v) return &context.registers.cs(); else return nullptr; case Source::SS: if constexpr (std::is_same_v) return &context.registers.ss(); else return nullptr; case Source::DS: if constexpr (std::is_same_v) return &context.registers.ds(); else return nullptr; // 16-bit models don't have FS and GS. case Source::FS: if constexpr (is_32bit(ContextT::model) && std::is_same_v) return &context.registers.fs(); else return nullptr; case Source::GS: if constexpr (is_32bit(ContextT::model) && std::is_same_v) return &context.registers.gs(); else return nullptr; case Source::Immediate: *immediate = instruction.operand(); return immediate; case Source::None: return none; case Source::Indirect: target_address = address(instruction, pointer, context); break; case Source::IndirectNoBase: target_address = address(instruction, pointer, context); break; case Source::DirectAddress: target_address = address(instruction, pointer, context); break; } // If execution has reached here then a memory fetch is required. // Do it and exit. return &context.memory.template access(instruction.data_segment(), target_address); }; namespace Primitive { // The below takes a reference in order properly to handle PUSH SP, which should place the value of SP after the // push onto the stack. template void push(IntT value, ContextT &context) { context.registers.sp_ -= sizeof(IntT); context.memory.template access( InstructionSet::x86::Source::SS, context.registers.sp_) = value; context.memory.template write_back(); } template IntT pop(ContextT &context) { const auto value = context.memory.template access( InstructionSet::x86::Source::SS, context.registers.sp_); context.registers.sp_ += sizeof(IntT); return value; } // // Comments below on intended functioning of each operation 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 // template void aaa(CPU::RegisterPair16 &ax, ContextT &context) { // P. 313 /* IF ((AL AND 0FH) > 9) OR (AF = 1) THEN AL ← (AL + 6); AH ← AH + 1; AF ← 1; CF ← 1; ELSE AF ← 0; CF ← 0; FI; AL ← AL AND 0FH; */ /* The AF and CF flags are set to 1 if the adjustment results in a decimal carry; otherwise they are cleared to 0. The OF, SF, ZF, and PF flags are undefined. */ if((ax.halves.low & 0x0f) > 9 || context.status.template flag()) { ax.halves.low += 6; ++ax.halves.high; context.status.template set_from(1); } else { context.status.template set_from(0); } ax.halves.low &= 0x0f; } template void aad(CPU::RegisterPair16 &ax, uint8_t imm, ContextT &context) { /* tempAL ← AL; tempAH ← AH; AL ← (tempAL + (tempAH * imm8)) AND FFH; (* imm8 is set to 0AH for the AAD mnemonic *) AH ← 0 */ /* The SF, ZF, and PF flags are set according to the result; the OF, AF, and CF flags are undefined. */ ax.halves.low = ax.halves.low + (ax.halves.high * imm); ax.halves.high = 0; context.status.template set_from(ax.halves.low); } template void aam(CPU::RegisterPair16 &ax, uint8_t imm, ContextT &context) { /* tempAL ← AL; AH ← tempAL / imm8; (* imm8 is set to 0AH for the AAD mnemonic *) AL ← tempAL MOD imm8; */ /* The SF, ZF, and PF flags are set according to the result. The OF, AF, and CF flags are undefined. */ /* If ... an immediate value of 0 is used, it will cause a #DE (divide error) exception. */ if(!imm) { interrupt(Interrupt::DivideError, context); return; } ax.halves.high = ax.halves.low / imm; ax.halves.low = ax.halves.low % imm; context.status.template set_from(ax.halves.low); } template void aas(CPU::RegisterPair16 &ax, ContextT &context) { /* IF ((AL AND 0FH) > 9) OR (AF = 1) THEN AL ← AL – 6; AH ← AH – 1; AF ← 1; CF ← 1; ELSE CF ← 0; AF ← 0; FI; AL ← AL AND 0FH; */ /* The AF and CF flags are set to 1 if there is a decimal borrow; otherwise, they are cleared to 0. The OF, SF, ZF, and PF flags are undefined. */ if((ax.halves.low & 0x0f) > 9 || context.status.template flag()) { ax.halves.low -= 6; --ax.halves.high; context.status.template set_from(1); } else { context.status.template set_from(0); } ax.halves.low &= 0x0f; } template void daa(uint8_t &al, ContextT &context) { /* (as modified by https://www.felixcloutier.com/x86/daa ...) old_AL ← AL; old_CF ← CF; CF ← 0; IF (((AL AND 0FH) > 9) or AF = 1) THEN AL ← AL + 6; CF ← old_CF OR CarryFromLastAddition; (* CF OR carry from AL ← AL + 6 *) AF ← 1; ELSE AF ← 0; FI; IF ((old_AL > 99H) or old_CF = 1) THEN AL ← AL + 60H; CF ← 1; ELSE CF ← 0; FI; */ /* The CF and AF flags are set if the adjustment of the value results in a decimal carry in either digit of the result (see the “Operation” section above). The SF, ZF, and PF flags are set according to the result. The OF flag is undefined. */ const uint8_t old_al = al; const auto old_carry = context.status.template flag(); context.status.template set_from(0); if((al & 0x0f) > 0x09 || context.status.template flag()) { context.status.template set_from(old_carry | (al > 0xf9)); al += 0x06; context.status.template set_from(1); } else { context.status.template set_from(0); } if(old_al > 0x99 || old_carry) { al += 0x60; context.status.template set_from(1); } else { context.status.template set_from(0); } context.status.template set_from(al); } template void das(uint8_t &al, ContextT &context) { /* (as modified by https://www.felixcloutier.com/x86/daa ...) old_AL ← AL; old_CF ← CF; CF ← 0; IF (((AL AND 0FH) > 9) or AF = 1) THEN AL ← AL - 6; CF ← old_CF OR CarryFromLastAddition; (* CF OR borrow from AL ← AL - 6 *) AF ← 1; ELSE AF ← 0; FI; IF ((old_AL > 99H) or old_CF = 1) THEN AL ← AL - 60H; CF ← 1; ELSE CF ← 0; FI; */ /* The CF and AF flags are set if the adjustment of the value results in a decimal carry in either digit of the result (see the “Operation” section above). The SF, ZF, and PF flags are set according to the result. The OF flag is undefined. */ const uint8_t old_al = al; const auto old_carry = context.status.template flag(); context.status.template set_from(0); if((al & 0x0f) > 0x09 || context.status.template flag()) { context.status.template set_from(old_carry | (al < 0x06)); al -= 0x06; context.status.template set_from(1); } else { context.status.template set_from(0); } if(old_al > 0x99 || old_carry) { al -= 0x60; context.status.template set_from(1); } else { context.status.template set_from(0); } context.status.template set_from(al); } template void add(IntT &destination, IntT source, ContextT &context) { /* DEST ← DEST + SRC [+ CF]; */ /* The OF, SF, ZF, AF, CF, and PF flags are set according to the result. */ const IntT result = destination + source + (with_carry ? context.status.template carry_bit() : 0); context.status.template set_from( Numeric::carried_out() - 1>(destination, source, result)); context.status.template set_from( Numeric::carried_in<4>(destination, source, result)); context.status.template set_from( Numeric::overflow(destination, source, result)); context.status.template set_from(result); destination = result; } template void sub(IntT &destination, IntT source, ContextT &context) { /* DEST ← DEST - (SRC [+ CF]); */ /* The OF, SF, ZF, AF, CF, and PF flags are set according to the result. */ const IntT result = destination - source - (with_borrow ? context.status.template carry_bit() : 0); context.status.template set_from( Numeric::carried_out() - 1>(destination, source, result)); context.status.template set_from( Numeric::carried_in<4>(destination, source, result)); context.status.template set_from( Numeric::overflow(destination, source, result)); context.status.template set_from(result); if constexpr (write_back) { destination = result; } } template void test(IntT &destination, IntT source, ContextT &context) { /* TEMP ← SRC1 AND SRC2; SF ← MSB(TEMP); IF TEMP = 0 THEN ZF ← 0; ELSE ZF ← 1; FI: PF ← BitwiseXNOR(TEMP[0:7]); CF ← 0; OF ← 0; */ /* The OF and CF flags are cleared to 0. The SF, ZF, and PF flags are set according to the result (see the “Operation” section above). The state of the AF flag is undefined. */ const IntT result = destination & source; context.status.template set_from(0); context.status.template set_from(result); } template void xchg(IntT &destination, IntT &source) { /* TEMP ← DEST DEST ← SRC SRC ← TEMP */ std::swap(destination, source); } template void mul(IntT &destination_high, IntT &destination_low, IntT source, ContextT &context) { /* IF byte operation THEN AX ← AL * SRC ELSE (* word or doubleword operation *) IF OperandSize = 16 THEN DX:AX ← AX * SRC ELSE (* OperandSize = 32 *) EDX:EAX ← EAX * SRC FI; */ /* The OF and CF flags are cleared to 0 if the upper half of the result is 0; otherwise, they are set to 1. The SF, ZF, AF, and PF flags are undefined. */ destination_high = (destination_low * source) >> (8 * sizeof(IntT)); destination_low *= source; context.status.template set_from(destination_high); } template void imul(IntT &destination_high, IntT &destination_low, IntT source, ContextT &context) { /* (as modified by https://www.felixcloutier.com/x86/daa ...) IF (OperandSize = 8) THEN AX ← AL ∗ SRC (* signed multiplication *) IF (AX = SignExtend(AL)) THEN CF = 0; OF = 0; ELSE CF = 1; OF = 1; FI; ELSE IF OperandSize = 16 THEN DX:AX ← AX ∗ SRC (* signed multiplication *) IF (DX:AX = SignExtend(AX)) THEN CF = 0; OF = 0; ELSE CF = 1; OF = 1; FI; ELSE (* OperandSize = 32 *) EDX:EAX ← EAX ∗ SRC (* signed multiplication *) IF (EDX:EAX = SignExtend(EAX)) THEN CF = 0; OF = 0; ELSE CF = 1; OF = 1; FI; FI; */ using sIntT = typename std::make_signed::type; destination_high = (sIntT(destination_low) * sIntT(source)) >> (8 * sizeof(IntT)); destination_low = IntT(sIntT(destination_low) * sIntT(source)); const auto sign_extension = (destination_low & Numeric::top_bit()) ? IntT(~0) : 0; context.status.template set_from(destination_high != sign_extension); } template void div(IntT &destination_high, IntT &destination_low, IntT source, ContextT &context) { /* IF SRC = 0 THEN #DE; (* divide error *) FI; IF OperandSize = 8 (* word/byte operation *) THEN temp ← AX / SRC; IF temp > FFH THEN #DE; (* divide error *) ; ELSE AL ← temp; AH ← AX MOD SRC; FI; ELSE IF OperandSize = 16 (* doubleword/word operation *) THEN temp ← DX:AX / SRC; IF temp > FFFFH THEN #DE; (* divide error *) ; ELSE AX ← temp; DX ← DX:AX MOD SRC; FI; ELSE (* quadword/doubleword operation *) temp ← EDX:EAX / SRC; IF temp > FFFFFFFFH THEN #DE; (* divide error *) ; ELSE EAX ← temp; EDX ← EDX:EAX MOD SRC; FI; FI; FI; */ /* The CF, OF, SF, ZF, AF, and PF flags are undefined. */ if(!source) { InstructionSet::x86::interrupt(Interrupt::DivideError, context); return; } // TEMPORARY HACK. Will not work with DWords. const uint32_t dividend = (destination_high << (8 * sizeof(IntT))) + destination_low; const auto result = dividend / source; if(IntT(result) != result) { interrupt(Interrupt::DivideError, context); return; } destination_low = IntT(result); destination_high = dividend % source; } template void idiv(IntT &destination_high, IntT &destination_low, IntT source, ContextT &context) { /* IF SRC = 0 THEN #DE; (* divide error *) FI; IF OperandSize = 8 (* word/byte operation *) THEN temp ← AX / SRC; (* signed division *) IF (temp > 7FH) OR (temp < 80H) (* if a positive result is greater than 7FH or a negative result is less than 80H *) THEN #DE; (* divide error *) ; ELSE AL ← temp; AH ← AX MOD SRC; FI; ELSE IF OperandSize = 16 (* doubleword/word operation *) THEN temp ← DX:AX / SRC; (* signed division *) IF (temp > 7FFFH) OR (temp < 8000H) (* if a positive result is greater than 7FFFH or a negative result is less than 8000H *) THEN #DE; (* divide error *) ; ELSE AX ← temp; DX ← DX:AX MOD SRC; FI; ELSE (* quadword/doubleword operation *) temp ← EDX:EAX / SRC; (* signed division *) IF (temp > 7FFFFFFFH) OR (temp < 80000000H) (* if a positive result is greater than 7FFFFFFFH or a negative result is less than 80000000H *) THEN #DE; (* divide error *) ; ELSE EAX ← temp; EDX ← EDX:EAX MOD SRC; FI; FI; FI; */ /* The CF, OF, SF, ZF, AF, and PF flags are undefined. */ if(!source) { interrupt(Interrupt::DivideError, context); return; } // TEMPORARY HACK. Will not work with DWords. using sIntT = typename std::make_signed::type; const int32_t dividend = (sIntT(destination_high) << (8 * sizeof(IntT))) + destination_low; const auto result = dividend / sIntT(source); if(sIntT(result) != result) { interrupt(Interrupt::DivideError, context); return; } destination_low = IntT(result); destination_high = dividend % sIntT(source); } template void inc(IntT &destination, ContextT &context) { /* DEST ← DEST + 1; */ /* The CF flag is not affected. The OF, SF, ZF, AF, and PF flags are set according to the result. */ ++destination; context.status.template set_from(destination == Numeric::top_bit()); context.status.template set_from(((destination - 1) ^ destination) & 0x10); context.status.template set_from(destination); } template void jump(bool condition, IntT displacement, ContextT &context) { /* IF condition THEN EIP ← EIP + SignExtend(DEST); IF OperandSize = 16 THEN EIP ← EIP AND 0000FFFFH; FI; FI; */ // TODO: proper behaviour in 32-bit. if(condition) { context.flow_controller.jump(context.registers.ip() + displacement); } } template void loop(IntT &counter, OffsetT displacement, ContextT &context) { --counter; if(counter) { context.flow_controller.jump(context.registers.ip() + displacement); } } template void loope(IntT &counter, OffsetT displacement, ContextT &context) { --counter; if(counter && context.status.template flag()) { context.flow_controller.jump(context.registers.ip() + displacement); } } template void loopne(IntT &counter, OffsetT displacement, ContextT &context) { --counter; if(counter && !context.status.template flag()) { context.flow_controller.jump(context.registers.ip() + displacement); } } template void dec(IntT &destination, ContextT &context) { /* DEST ← DEST - 1; */ /* The CF flag is not affected. The OF, SF, ZF, AF, and PF flags are set according to the result. */ context.status.template set_from(destination == Numeric::top_bit()); --destination; context.status.template set_from(destination); context.status.template set_from(((destination + 1) ^ destination) & 0x10); } template void and_(IntT &destination, IntT source, ContextT &context) { /* DEST ← DEST AND SRC; */ /* The OF and CF flags are cleared; the SF, ZF, and PF flags are set according to the result. The state of the AF flag is undefined. */ destination &= source; context.status.template set_from(0); context.status.template set_from(destination); } template void or_(IntT &destination, IntT source, ContextT &context) { /* DEST ← DEST OR SRC; */ /* The OF and CF flags are cleared; the SF, ZF, and PF flags are set according to the result. The state of the AF flag is undefined. */ destination |= source; context.status.template set_from(0); context.status.template set_from(destination); } template void xor_(IntT &destination, IntT source, ContextT &context) { /* DEST ← DEST XOR SRC; */ /* The OF and CF flags are cleared; the SF, ZF, and PF flags are set according to the result. The state of the AF flag is undefined. */ destination ^= source; context.status.template set_from(0); context.status.template set_from(destination); } template void neg(IntT &destination, ContextT &context) { /* IF DEST = 0 THEN CF ← 0 ELSE CF ← 1; FI; DEST ← –(DEST) */ /* The CF flag cleared to 0 if the source operand is 0; otherwise it is set to 1. The OF, SF, ZF, AF, and PF flags are set according to the result. */ context.status.template set_from(Numeric::carried_in<4>(IntT(0), destination, IntT(-destination))); destination = -destination; context.status.template set_from(destination); context.status.template set_from(destination == Numeric::top_bit()); context.status.template set_from(destination); } template void not_(IntT &destination) { /* DEST ← NOT DEST; */ /* Flags affected: none. */ destination = ~destination; } template void call_relative(IntT offset, ContextT &context) { push(context.registers.ip(), context); context.flow_controller.jump(context.registers.ip() + offset); } template void call_absolute(IntT target, ContextT &context) { push(context.registers.ip(), context); context.flow_controller.jump(target); } template void jump_absolute(IntT target, ContextT &context) { context.flow_controller.jump(target); } template void call_far(InstructionT &instruction, ContextT &context) { // TODO: eliminate 16-bit assumption below. const Source source_segment = instruction.data_segment(); context.memory.preauthorise_stack_write(sizeof(uint16_t) * 2); uint16_t source_address; const auto pointer = instruction.destination(); switch(pointer.source()) { default: case Source::Immediate: push(context.registers.cs(), context); push(context.registers.ip(), context); context.flow_controller.jump(instruction.segment(), instruction.offset()); return; case Source::Indirect: source_address = address(instruction, pointer, context); break; case Source::IndirectNoBase: source_address = address(instruction, pointer, context); break; case Source::DirectAddress: source_address = address(instruction, pointer, context); break; } context.memory.preauthorise_read(source_segment, source_address, sizeof(uint16_t) * 2); push(context.registers.cs(), context); push(context.registers.ip(), context); const uint16_t offset = context.memory.template access(source_segment, source_address); source_address += 2; const uint16_t segment = context.memory.template access(source_segment, source_address); context.flow_controller.jump(segment, offset); } template void jump_far(InstructionT &instruction, ContextT &context) { // TODO: eliminate 16-bit assumption below. uint16_t source_address = 0; const auto pointer = instruction.destination(); switch(pointer.source()) { default: case Source::Immediate: context.flow_controller.jump(instruction.segment(), instruction.offset()); return; case Source::Indirect: source_address = address(instruction, pointer, context); break; case Source::IndirectNoBase: source_address = address(instruction, pointer, context); break; case Source::DirectAddress: source_address = address(instruction, pointer, context); break; } const Source source_segment = instruction.data_segment(); const uint16_t offset = context.memory.template access(source_segment, source_address); source_address += 2; const uint16_t segment =context. memory.template access(source_segment, source_address); context.flow_controller.jump(segment, offset); } template void iret(ContextT &context) { // TODO: all modes other than 16-bit real mode. context.memory.preauthorise_stack_read(sizeof(uint16_t) * 3); const auto ip = pop(context); const auto cs = pop(context); context.status.set(pop(context)); context.flow_controller.jump(cs, ip); } template void ret_near(InstructionT instruction, ContextT &context) { const auto ip = pop(context); context.registers.sp() += instruction.operand(); context.flow_controller.jump(ip); } template void ret_far(InstructionT instruction, ContextT &context) { context.memory.preauthorise_stack_read(sizeof(uint16_t) * 2); const auto ip = pop(context); const auto cs = pop(context); context.registers.sp() += instruction.operand(); context.flow_controller.jump(cs, ip); } template void ld( InstructionT &instruction, uint16_t &destination, ContextT &context ) { const auto pointer = instruction.source(); auto source_address = address(instruction, pointer, context); const Source source_segment = instruction.data_segment(); destination = context.memory.template access(source_segment, source_address); source_address += 2; switch(selector) { case Source::DS: context.registers.ds() = context.memory.template access(source_segment, source_address); break; case Source::ES: context.registers.es() = context.memory.template access(source_segment, source_address); break; } } template void lea( const InstructionT &instruction, IntT &destination, ContextT &context ) { // TODO: address size. destination = IntT(address(instruction, instruction.source(), context)); } template void xlat( const InstructionT &instruction, ContextT &context ) { AddressT address; if constexpr (std::is_same_v) { address = context.registers.bx() + context.registers.al(); } context.registers.al() = context.memory.template access(instruction.data_segment(), address); } template void mov(IntT &destination, IntT source) { destination = source; } template void into(ContextT &context) { if(context.status.template flag()) { interrupt(Interrupt::OnOverflow, context); } } template void sahf(uint8_t &ah, ContextT &context) { /* EFLAGS(SF:ZF:0:AF:0:PF:1:CF) ← AH; */ context.status.template set_from(ah); context.status.template set_from(!(ah & 0x40)); context.status.template set_from(ah & 0x10); context.status.template set_from(!(ah & 0x04)); context.status.template set_from(ah & 0x01); } template void lahf(uint8_t &ah, ContextT &context) { /* AH ← EFLAGS(SF:ZF:0:AF:0:PF:1:CF); */ ah = (context.status.template flag() ? 0x80 : 0x00) | (context.status.template flag() ? 0x40 : 0x00) | (context.status.template flag() ? 0x10 : 0x00) | (context.status.template flag() ? 0x00 : 0x04) | 0x02 | (context.status.template flag() ? 0x01 : 0x00); } template void cbw(IntT &ax) { constexpr IntT test_bit = 1 << (sizeof(IntT) * 4 - 1); constexpr IntT low_half = (1 << (sizeof(IntT) * 4)) - 1; if(ax & test_bit) { ax |= ~low_half; } else { ax &= low_half; } } template void cwd(IntT &dx, IntT ax) { dx = ax & Numeric::top_bit() ? IntT(~0) : IntT(0); } // TODO: changes to the interrupt flag do quite a lot more in protected mode. template void clc(ContextT &context) { context.status.template set_from(0); } template void cld(ContextT &context) { context.status.template set_from(0); } template void cli(ContextT &context) { context.status.template set_from(0); } template void stc(ContextT &context) { context.status.template set_from(1); } template void std(ContextT &context) { context.status.template set_from(1); } template void sti(ContextT &context) { context.status.template set_from(1); } template void cmc(ContextT &context) { context.status.template set_from(!context.status.template flag()); } template void salc(uint8_t &al, ContextT &context) { al = context.status.template flag() ? 0xff : 0x00; } template void setmo(IntT &destination, ContextT &context) { destination = ~0; context.status.template set_from(0); context.status.template set_from(destination); } template void rcl(IntT &destination, uint8_t count, ContextT &context) { /* (* RCL and RCR instructions *) SIZE ← OperandSize CASE (determine count) OF SIZE = 8: tempCOUNT ← (COUNT AND 1FH) MOD 9; SIZE = 16: tempCOUNT ← (COUNT AND 1FH) MOD 17; SIZE = 32: tempCOUNT ← COUNT AND 1FH; ESAC; */ /* (* RCL instruction operation *) WHILE (tempCOUNT ≠ 0) DO tempCF ← MSB(DEST); DEST ← (DEST * 2) + CF; CF ← tempCF; tempCOUNT ← tempCOUNT – 1; OD; ELIHW; IF COUNT = 1 THEN OF ← MSB(DEST) XOR CF; ELSE OF is undefined; FI; */ /* The CF flag contains the value of the bit shifted into it. The OF flag is affected only for single- bit rotates (see “Description” above); it is undefined for multi-bit rotates. The SF, ZF, AF, and PF flags are not affected. */ const auto temp_count = count % (Numeric::bit_size() + 1); auto carry = context.status.template carry_bit(); switch(temp_count) { case 0: break; case Numeric::bit_size(): { const IntT temp_carry = destination & 1; destination = (destination >> 1) | (carry << (Numeric::bit_size() - 1)); carry = temp_carry; } break; default: { const IntT temp_carry = destination & (Numeric::top_bit() >> (temp_count - 1)); destination = (destination << temp_count) | (destination >> (Numeric::bit_size() + 1 - temp_count)) | (carry << (temp_count - 1)); carry = temp_carry ? 1 : 0; } break; } context.status.template set_from(carry); context.status.template set_from( ((destination >> (Numeric::bit_size() - 1)) & 1) ^ carry ); } template void rcr(IntT &destination, uint8_t count, ContextT &context) { /* (* RCR instruction operation *) IF COUNT = 1 THEN OF ← MSB(DEST) XOR CF; ELSE OF is undefined; FI; WHILE (tempCOUNT ≠ 0) DO tempCF ← LSB(SRC); DEST ← (DEST / 2) + (CF * 2SIZE); CF ← tempCF; tempCOUNT ← tempCOUNT – 1; OD; */ auto carry = context.status.template carry_bit(); context.status.template set_from( ((destination >> (Numeric::bit_size() - 1)) & 1) ^ carry ); const auto temp_count = count % (Numeric::bit_size() + 1); switch(temp_count) { case 0: break; case Numeric::bit_size(): { const IntT temp_carry = destination & Numeric::top_bit(); destination = (destination << 1) | carry; carry = temp_carry; } break; default: { const IntT temp_carry = destination & (1 << (temp_count - 1)); destination = (destination >> temp_count) | (destination << (Numeric::bit_size() + 1 - temp_count)) | (carry << (Numeric::bit_size() - temp_count)); carry = temp_carry; } break; } context.status.template set_from(carry); } template void rol(IntT &destination, uint8_t count, ContextT &context) { /* (* ROL and ROR instructions *) SIZE ← OperandSize CASE (determine count) OF SIZE = 8: tempCOUNT ← COUNT MOD 8; SIZE = 16: tempCOUNT ← COUNT MOD 16; SIZE = 32: tempCOUNT ← COUNT MOD 32; ESAC; */ /* (* ROL instruction operation *) WHILE (tempCOUNT ≠ 0) DO tempCF ← MSB(DEST); DEST ← (DEST * 2) + tempCF; tempCOUNT ← tempCOUNT – 1; OD; ELIHW; IF COUNT = 1 THEN OF ← MSB(DEST) XOR CF; ELSE OF is undefined; FI; */ /* The CF flag contains the value of the bit shifted into it. The OF flag is affected only for single- bit rotates (see “Description” above); it is undefined for multi-bit rotates. The SF, ZF, AF, and PF flags are not affected. */ const auto temp_count = count & (Numeric::bit_size() - 1); if(!count) { // TODO: is this 8086-specific? i.e. do the other x86s also exit without affecting flags when temp_count = 0? return; } if(temp_count) { destination = (destination << temp_count) | (destination >> (Numeric::bit_size() - temp_count)); } context.status.template set_from(destination & 1); context.status.template set_from( ((destination >> (Numeric::bit_size() - 1)) ^ destination) & 1 ); } template void ror(IntT &destination, uint8_t count, ContextT &context) { /* (* ROL and ROR instructions *) SIZE ← OperandSize CASE (determine count) OF SIZE = 8: tempCOUNT ← COUNT MOD 8; SIZE = 16: tempCOUNT ← COUNT MOD 16; SIZE = 32: tempCOUNT ← COUNT MOD 32; ESAC; */ /* (* ROR instruction operation *) WHILE (tempCOUNT ≠ 0) DO tempCF ← LSB(DEST); DEST ← (DEST / 2) + (tempCF * 2^SIZE); tempCOUNT ← tempCOUNT – 1; OD; ELIHW; IF COUNT = 1 THEN OF ← MSB(DEST) XOR MSB - 1 (DEST); ELSE OF is undefined; FI; */ /* The CF flag contains the value of the bit shifted into it. The OF flag is affected only for single- bit rotates (see “Description” above); it is undefined for multi-bit rotates. The SF, ZF, AF, and PF flags are not affected. */ const auto temp_count = count & (Numeric::bit_size() - 1); if(!count) { // TODO: is this 8086-specific? i.e. do the other x86s also exit without affecting flags when temp_count = 0? return; } if(temp_count) { destination = (destination >> temp_count) | (destination << (Numeric::bit_size() - temp_count)); } context.status.template set_from(destination & Numeric::top_bit()); context.status.template set_from( (destination ^ (destination << 1)) & Numeric::top_bit() ); } /* tempCOUNT ← (COUNT AND 1FH); tempDEST ← DEST; WHILE (tempCOUNT ≠ 0) DO IF instruction is SAL or SHL THEN CF ← MSB(DEST); ELSE (* instruction is SAR or SHR *) CF ← LSB(DEST); FI; IF instruction is SAL or SHL THEN DEST ← DEST ∗ 2; ELSE IF instruction is SAR THEN DEST ← DEST / 2 (*Signed divide, rounding toward negative infinity*); ELSE (* instruction is SHR *) DEST ← DEST / 2 ; (* Unsigned divide *); FI; FI; tempCOUNT ← tempCOUNT – 1; OD; (* Determine overflow for the various instructions *) IF COUNT = 1 THEN IF instruction is SAL or SHL THEN OF ← MSB(DEST) XOR CF; ELSE IF instruction is SAR THEN OF ← 0; ELSE (* instruction is SHR *) OF ← MSB(tempDEST); FI; FI; ELSE IF COUNT = 0 THEN All flags remain unchanged; ELSE (* COUNT neither 1 or 0 *) OF ← undefined; FI; FI; */ /* The CF flag contains the value of the last bit shifted out of the destination operand; it is undefined for SHL and SHR instructions where the count is greater than or equal to the size (in bits) of the destination operand. The OF flag is affected only for 1-bit shifts (see “Description” above); otherwise, it is undefined. The SF, ZF, and PF flags are set according to the result. If the count is 0, the flags are not affected. For a non-zero count, the AF flag is undefined. */ template void sal(IntT &destination, uint8_t count, ContextT &context) { switch(count) { case 0: return; case Numeric::bit_size(): context.status.template set_from(destination & 1); destination = 0; break; default: if(count > Numeric::bit_size()) { context.status.template set_from(0); destination = 0; } else { const auto mask = (Numeric::top_bit() >> (count - 1)); context.status.template set_from( destination & mask ); context.status.template set_from( (destination ^ (destination << 1)) & mask ); destination <<= count; } break; } context.status.template set_from(destination); } template void sar(IntT &destination, uint8_t count, ContextT &context) { if(!count) { return; } const IntT sign = Numeric::top_bit() & destination; if(count >= Numeric::bit_size()) { destination = sign ? IntT(~0) : IntT(0); context.status.template set_from(sign); } else { const IntT mask = 1 << (count - 1); context.status.template set_from(destination & mask); destination = (destination >> count) | (sign ? ~(IntT(~0) >> count) : 0); } context.status.template set_from(0); context.status.template set_from(destination); } template void shr(IntT &destination, uint8_t count, ContextT &context) { if(!count) { return; } context.status.template set_from(Numeric::top_bit() & destination); if(count == Numeric::bit_size()) { context.status.template set_from(Numeric::top_bit() & destination); destination = 0; } else if(count > Numeric::bit_size()) { context.status.template set_from(0); destination = 0; } else { const IntT mask = 1 << (count - 1); context.status.template set_from(destination & mask); destination >>= count; } context.status.template set_from(destination); } template void popf(ContextT &context) { context.status.set(pop(context)); } template void pushf(ContextT &context) { uint16_t value = context.status.get(); push(value, context); } template bool repetition_over(const AddressT &eCX) { return repetition != Repetition::None && !eCX; } template void repeat(AddressT &eCX, ContextT &context) { if( repetition == Repetition::None || // No repetition => stop. !(--eCX) // [e]cx is zero after being decremented => stop. ) { return; } if constexpr (repetition != Repetition::Rep) { // If this is RepE or RepNE, also test the zero flag. if((repetition == Repetition::RepNE) == context.status.template flag()) { return; } } context.flow_controller.repeat_last(); } template void cmps(const InstructionT &instruction, AddressT &eCX, AddressT &eSI, AddressT &eDI, ContextT &context) { if(repetition_over(eCX)) { return; } IntT lhs = context.memory.template access(instruction.data_segment(), eSI); const IntT rhs = context.memory.template access(Source::ES, eDI); eSI += context.status.template direction() * sizeof(IntT); eDI += context.status.template direction() * sizeof(IntT); Primitive::sub(lhs, rhs, context); repeat(eCX, context); } template void scas(AddressT &eCX, AddressT &eDI, IntT &eAX, ContextT &context) { if(repetition_over(eCX)) { return; } const IntT rhs = context.memory.template access(Source::ES, eDI); eDI += context.status.template direction() * sizeof(IntT); Primitive::sub(eAX, rhs, context); repeat(eCX, context); } template void lods(const InstructionT &instruction, AddressT &eCX, AddressT &eSI, IntT &eAX, ContextT &context) { if(repetition_over(eCX)) { return; } eAX = context.memory.template access(instruction.data_segment(), eSI); eSI += context.status.template direction() * sizeof(IntT); repeat(eCX, context); } template void movs(const InstructionT &instruction, AddressT &eCX, AddressT &eSI, AddressT &eDI, ContextT &context) { if(repetition_over(eCX)) { return; } context.memory.template access(Source::ES, eDI) = context.memory.template access(instruction.data_segment(), eSI); eSI += context.status.template direction() * sizeof(IntT); eDI += context.status.template direction() * sizeof(IntT); repeat(eCX, context); } template void stos(AddressT &eCX, AddressT &eDI, IntT &eAX, ContextT &context) { if(repetition_over(eCX)) { return; } context.memory.template access(Source::ES, eDI) = eAX; eDI += context.status.template direction() * sizeof(IntT); repeat(eCX, context); } template void outs(const InstructionT &instruction, AddressT &eCX, uint16_t port, AddressT &eSI, ContextT &context) { if(repetition_over(eCX)) { return; } context.io.template out( port, context.memory.template access(instruction.data_segment(), eSI) ); eSI += context.status.template direction() * sizeof(IntT); repeat(eCX, context); } template void ins(AddressT &eCX, uint16_t port, AddressT &eDI, ContextT &context) { if(repetition_over(eCX)) { return; } context.memory.template access(Source::ES, eDI) = context.io.template in(port); eDI += context.status.template direction() * sizeof(IntT); repeat(eCX, context); } template void out(uint16_t port, IntT value, ContextT &context) { context.io.template out(port, value); } template void in(uint16_t port, IntT &value, ContextT &context) { value = context.io.template in(port); } } 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 = [&]() -> IntT& { return *resolve( instruction, instruction.source().source(), instruction.source(), context, nullptr, &immediate); }; const auto source_rmw = [&]() -> IntT& { return *resolve( instruction, instruction.source().source(), instruction.source(), context, nullptr, &immediate); }; const auto destination_r = [&]() -> IntT& { return *resolve( instruction, instruction.destination().source(), instruction.destination(), context, nullptr, &immediate); }; const auto destination_w = [&]() -> IntT& { return *resolve( instruction, instruction.destination().source(), instruction.destination(), context, nullptr, &immediate); }; const auto destination_rmw = [&]() -> IntT& { 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; // * return directly if there is definitely no possible write back to RAM; // * otherwise use the source() and destination() lambdas, and break in order to allow a writeback if necessary. switch(instruction.operation()) { default: assert(false); case Operation::AAA: Primitive::aaa(context.registers.axp(), context); return; case Operation::AAD: Primitive::aad(context.registers.axp(), instruction.operand(), context); return; case Operation::AAM: Primitive::aam(context.registers.axp(), instruction.operand(), context); return; case Operation::AAS: Primitive::aas(context.registers.axp(), context); return; case Operation::DAA: Primitive::daa(context.registers.al(), context); return; case Operation::DAS: Primitive::das(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::ESC: case Operation::NOP: 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::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); return; case Operation::LES: if constexpr (data_size == DataSize::Word) Primitive::ld(instruction, destination_w(), context); return; case Operation::LEA: Primitive::lea(instruction, destination_w(), context); return; case Operation::MOV: Primitive::mov(destination_w(), source_r()); break; case Operation::JO: jcc(context.status.template condition()); return; case Operation::JNO: jcc(!context.status.template condition()); return; case Operation::JB: jcc(context.status.template condition()); return; case Operation::JNB: jcc(!context.status.template condition()); return; case Operation::JZ: jcc(context.status.template condition()); return; case Operation::JNZ: jcc(!context.status.template condition()); return; case Operation::JBE: jcc(context.status.template condition()); return; case Operation::JNBE: jcc(!context.status.template condition()); return; case Operation::JS: jcc(context.status.template condition()); return; case Operation::JNS: jcc(!context.status.template condition()); return; case Operation::JP: jcc(!context.status.template condition()); return; case Operation::JNP: jcc(context.status.template condition()); return; case Operation::JL: jcc(context.status.template condition()); return; case Operation::JNL: jcc(!context.status.template condition()); return; case Operation::JLE: jcc(context.status.template condition()); return; case Operation::JNLE: jcc(!context.status.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 { // TODO. } 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 { // TODO. } 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); break; case Operation::PUSH: Primitive::push(source_r(), context); break; case Operation::POPF: Primitive::popf(context); break; case Operation::PUSHF: Primitive::pushf(context); break; case Operation::CMPS: Primitive::cmps(instruction, eCX(), eSI(), eDI(), context); break; case Operation::CMPS_REPE: Primitive::cmps(instruction, eCX(), eSI(), eDI(), context); break; case Operation::CMPS_REPNE: Primitive::cmps(instruction, eCX(), eSI(), eDI(), context); break; case Operation::SCAS: Primitive::scas(eCX(), eDI(), pair_low(), context); break; case Operation::SCAS_REPE: Primitive::scas(eCX(), eDI(), pair_low(), context); break; case Operation::SCAS_REPNE: Primitive::scas(eCX(), eDI(), pair_low(), context); break; case Operation::LODS: Primitive::lods(instruction, eCX(), eSI(), pair_low(), context); break; case Operation::LODS_REP: Primitive::lods(instruction, eCX(), eSI(), pair_low(), context); break; 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); break; case Operation::OUTS_REP: Primitive::outs(instruction, eCX(), context.registers.dx(), eSI(), context); break; 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. // // TODO: can I eliminate this with some RAII magic? context.memory.template write_back(); } 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); Primitive::push(context.status.get(), context); context.status.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 */