Duckstation/src/core/cpu_newrec_compiler.cpp

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2023-10-03 14:39:18 +00:00
// SPDX-FileCopyrightText: 2023 Connor McLaughlin <stenzek@gmail.com>
// SPDX-License-Identifier: (GPL-3.0 OR CC-BY-NC-ND-4.0)
#include "cpu_newrec_compiler.h"
#include "common/assert.h"
#include "common/log.h"
#include "common/small_string.h"
#include "cpu_code_cache.h"
#include "cpu_core_private.h"
#include "cpu_disasm.h"
#include "pgxp.h"
#include "settings.h"
#include <cstdint>
#include <limits>
Log_SetChannel(NewRec::Compiler);
// TODO: direct link skip delay slot check
// TODO: speculative constants
// TODO: std::bitset in msvc has bounds checks even in release...
const std::array<std::array<const void*, 2>, 3> CPU::NewRec::Compiler::s_pgxp_mem_load_functions = {
{{{reinterpret_cast<const void*>(&PGXP::CPU_LBx), reinterpret_cast<const void*>(&PGXP::CPU_LBx)}},
{{reinterpret_cast<const void*>(&PGXP::CPU_LHU), reinterpret_cast<const void*>(&PGXP::CPU_LH)}},
{{reinterpret_cast<const void*>(&PGXP::CPU_LW)}}}};
const std::array<const void*, 3> CPU::NewRec::Compiler::s_pgxp_mem_store_functions = {
{reinterpret_cast<const void*>(&PGXP::CPU_SB), reinterpret_cast<const void*>(&PGXP::CPU_SH),
reinterpret_cast<const void*>(&PGXP::CPU_SW)}};
CPU::NewRec::Compiler::Compiler() = default;
CPU::NewRec::Compiler::~Compiler() = default;
void CPU::NewRec::Compiler::Reset(CodeCache::Block* block, u8* code_buffer, u32 code_buffer_space, u8* far_code_buffer,
u32 far_code_space)
{
m_block = block;
m_compiler_pc = block->pc;
m_cycles = 0;
m_gte_done_cycle = 0;
inst = nullptr;
iinfo = nullptr;
m_current_instruction_pc = 0;
m_current_instruction_branch_delay_slot = false;
m_dirty_pc = false;
m_dirty_instruction_bits = false;
m_dirty_gte_done_cycle = true;
m_block_ended = false;
m_constant_reg_values.fill(0);
m_constant_regs_valid.reset();
m_constant_regs_dirty.reset();
for (u32 i = 0; i < NUM_HOST_REGS; i++)
ClearHostReg(i);
m_register_alloc_counter = 0;
m_constant_reg_values[static_cast<u32>(Reg::zero)] = 0;
m_constant_regs_valid.set(static_cast<u32>(Reg::zero));
m_load_delay_dirty = EMULATE_LOAD_DELAYS;
m_load_delay_register = Reg::count;
m_load_delay_value_register = NUM_HOST_REGS;
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InitSpeculativeRegs();
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}
void CPU::NewRec::Compiler::BeginBlock()
{
#if 0
GenerateCall(reinterpret_cast<const void*>(&CPU::CodeCache::LogCurrentState));
#endif
if (m_block->protection == CodeCache::PageProtectionMode::ManualCheck)
{
Log_DebugPrintf("Generate manual protection for PC %08X", m_block->pc);
const u8* ram_ptr = Bus::g_ram + VirtualAddressToPhysical(m_block->pc);
const u8* shadow_ptr = reinterpret_cast<const u8*>(m_block->Instructions());
GenerateBlockProtectCheck(ram_ptr, shadow_ptr, m_block->size * sizeof(Instruction));
}
if (m_block->uncached_fetch_ticks > 0 || m_block->icache_line_count > 0)
GenerateICacheCheckAndUpdate();
if (g_settings.bios_tty_logging)
{
if (m_block->pc == 0xa0)
GenerateCall(reinterpret_cast<const void*>(&CPU::HandleA0Syscall));
else if (m_block->pc == 0xb0)
GenerateCall(reinterpret_cast<const void*>(&CPU::HandleB0Syscall));
}
inst = m_block->Instructions();
iinfo = m_block->InstructionsInfo();
m_current_instruction_pc = m_block->pc;
m_current_instruction_branch_delay_slot = false;
m_compiler_pc += sizeof(Instruction);
m_dirty_pc = true;
m_dirty_instruction_bits = true;
}
const void* CPU::NewRec::Compiler::CompileBlock(CodeCache::Block* block, u32* host_code_size, u32* host_far_code_size)
{
JitCodeBuffer& buffer = CodeCache::GetCodeBuffer();
Reset(block, buffer.GetFreeCodePointer(), buffer.GetFreeCodeSpace(), buffer.GetFreeFarCodePointer(),
buffer.GetFreeFarCodeSpace());
Log_DebugPrintf("Block range: %08X -> %08X", block->pc, block->pc + block->size * 4);
BeginBlock();
for (;;)
{
CompileInstruction();
if (iinfo->is_last_instruction || m_block_ended)
{
if (!m_block_ended)
{
// Block was truncated. Link it.
EndBlock(m_compiler_pc, false);
}
break;
}
inst++;
iinfo++;
m_current_instruction_pc += sizeof(Instruction);
m_compiler_pc += sizeof(Instruction);
m_dirty_pc = true;
m_dirty_instruction_bits = true;
}
// Nothing should be valid anymore
for (u32 i = 0; i < NUM_HOST_REGS; i++)
DebugAssert(!IsHostRegAllocated(i));
for (u32 i = 1; i < static_cast<u32>(Reg::count); i++)
DebugAssert(!m_constant_regs_dirty.test(i) && !m_constant_regs_valid.test(i));
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m_speculative_constants.memory.clear();
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u32 code_size, far_code_size;
const void* code = EndCompile(&code_size, &far_code_size);
*host_code_size = code_size;
*host_far_code_size = far_code_size;
buffer.CommitCode(code_size);
buffer.CommitFarCode(far_code_size);
return code;
}
void CPU::NewRec::Compiler::SetConstantReg(Reg r, u32 v)
{
DebugAssert(r < Reg::count && r != Reg::zero);
// There might still be an incoming load delay which we need to cancel.
CancelLoadDelaysToReg(r);
if (m_constant_regs_valid.test(static_cast<u32>(r)) && m_constant_reg_values[static_cast<u8>(r)] == v)
{
// Shouldn't be any host regs though.
DebugAssert(!CheckHostReg(0, HR_TYPE_CPU_REG, r).has_value());
return;
}
m_constant_reg_values[static_cast<u32>(r)] = v;
m_constant_regs_valid.set(static_cast<u32>(r));
m_constant_regs_dirty.set(static_cast<u32>(r));
if (const std::optional<u32> hostreg = CheckHostReg(0, HR_TYPE_CPU_REG, r); hostreg.has_value())
{
Log_DebugPrintf("Discarding guest register %s in host register %s due to constant set", GetRegName(r),
GetHostRegName(hostreg.value()));
FreeHostReg(hostreg.value());
}
}
void CPU::NewRec::Compiler::CancelLoadDelaysToReg(Reg reg)
{
if (m_load_delay_register != reg)
return;
Log_DebugPrintf("Cancelling load delay to %s", GetRegName(reg));
m_load_delay_register = Reg::count;
if (m_load_delay_value_register != NUM_HOST_REGS)
ClearHostReg(m_load_delay_value_register);
}
void CPU::NewRec::Compiler::UpdateLoadDelay()
{
if (m_load_delay_dirty)
{
// we shouldn't have a static load delay.
DebugAssert(!HasLoadDelay());
// have to invalidate registers, we might have one of them cached
// TODO: double check the order here, will we trash a new value? we shouldn't...
// thankfully since this only happens on the first instruction, we can get away with just killing anything which
// isn't in write mode, because nothing could've been written before it, and the new value overwrites any
// load-delayed value
Log_DebugPrintf("Invalidating non-dirty registers, and flushing load delay from state");
constexpr u32 req_flags = (HR_ALLOCATED | HR_MODE_WRITE);
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& ra = m_host_regs[i];
if (ra.type != HR_TYPE_CPU_REG || !IsHostRegAllocated(i) || ((ra.flags & req_flags) == req_flags))
continue;
Log_DebugPrintf("Freeing non-dirty cached register %s in %s", GetRegName(ra.reg), GetHostRegName(i));
DebugAssert(!(ra.flags & HR_MODE_WRITE));
ClearHostReg(i);
}
// remove any non-dirty constants too
for (u32 i = 1; i < static_cast<u32>(Reg::count); i++)
{
if (!HasConstantReg(static_cast<Reg>(i)) || HasDirtyConstantReg(static_cast<Reg>(i)))
continue;
Log_DebugPrintf("Clearing non-dirty constant %s", GetRegName(static_cast<Reg>(i)));
ClearConstantReg(static_cast<Reg>(i));
}
Flush(FLUSH_LOAD_DELAY_FROM_STATE);
}
// commit the delayed register load
FinishLoadDelay();
// move next load delay forward
if (m_next_load_delay_register != Reg::count)
{
// if it somehow got flushed, read it back in.
if (m_next_load_delay_value_register == NUM_HOST_REGS)
{
AllocateHostReg(HR_MODE_READ, HR_TYPE_NEXT_LOAD_DELAY_VALUE, m_next_load_delay_register);
DebugAssert(m_next_load_delay_value_register != NUM_HOST_REGS);
}
HostRegAlloc& ra = m_host_regs[m_next_load_delay_value_register];
ra.flags |= HR_MODE_WRITE;
ra.type = HR_TYPE_LOAD_DELAY_VALUE;
m_load_delay_register = m_next_load_delay_register;
m_load_delay_value_register = m_next_load_delay_value_register;
m_next_load_delay_register = Reg::count;
m_next_load_delay_value_register = NUM_HOST_REGS;
}
}
void CPU::NewRec::Compiler::FinishLoadDelay()
{
DebugAssert(!m_load_delay_dirty);
if (!HasLoadDelay())
return;
// we may need to reload the value..
if (m_load_delay_value_register == NUM_HOST_REGS)
{
AllocateHostReg(HR_MODE_READ, HR_TYPE_LOAD_DELAY_VALUE, m_load_delay_register);
DebugAssert(m_load_delay_value_register != NUM_HOST_REGS);
}
// kill any (old) cached value for this register
DeleteMIPSReg(m_load_delay_register, false);
Log_DebugPrintf("Finished delayed load to %s in host register %s", GetRegName(m_load_delay_register),
GetHostRegName(m_load_delay_value_register));
// and swap the mode over so it gets written back later
HostRegAlloc& ra = m_host_regs[m_load_delay_value_register];
DebugAssert(ra.reg == m_load_delay_register);
ra.flags = (ra.flags & IMMUTABLE_HR_FLAGS) | HR_ALLOCATED | HR_MODE_READ | HR_MODE_WRITE;
ra.counter = m_register_alloc_counter++;
ra.type = HR_TYPE_CPU_REG;
// constants are gone
Log_DebugPrintf("Clearing constant in %s due to load delay", GetRegName(m_load_delay_register));
ClearConstantReg(m_load_delay_register);
m_load_delay_register = Reg::count;
m_load_delay_value_register = NUM_HOST_REGS;
}
void CPU::NewRec::Compiler::FinishLoadDelayToReg(Reg reg)
{
if (m_load_delay_dirty)
{
// inter-block :(
UpdateLoadDelay();
return;
}
if (m_load_delay_register != reg)
return;
FinishLoadDelay();
}
u32 CPU::NewRec::Compiler::GetFlagsForNewLoadDelayedReg() const
{
return g_settings.gpu_pgxp_enable ? (HR_MODE_WRITE | HR_CALLEE_SAVED) : (HR_MODE_WRITE);
}
void CPU::NewRec::Compiler::ClearConstantReg(Reg r)
{
DebugAssert(r < Reg::count && r != Reg::zero);
m_constant_reg_values[static_cast<u32>(r)] = 0;
m_constant_regs_valid.reset(static_cast<u32>(r));
m_constant_regs_dirty.reset(static_cast<u32>(r));
}
void CPU::NewRec::Compiler::FlushConstantRegs(bool invalidate)
{
for (u32 i = 1; i < static_cast<u32>(Reg::count); i++)
{
if (m_constant_regs_dirty.test(static_cast<u32>(i)))
FlushConstantReg(static_cast<Reg>(i));
if (invalidate)
ClearConstantReg(static_cast<Reg>(i));
}
}
CPU::Reg CPU::NewRec::Compiler::MipsD() const
{
return inst->r.rd;
}
u32 CPU::NewRec::Compiler::GetConditionalBranchTarget(CompileFlags cf) const
{
// compiler pc has already been advanced when swapping branch delay slots
const u32 current_pc = m_compiler_pc - (cf.delay_slot_swapped ? sizeof(Instruction) : 0);
return current_pc + (inst->i.imm_sext32() << 2);
}
u32 CPU::NewRec::Compiler::GetBranchReturnAddress(CompileFlags cf) const
{
// compiler pc has already been advanced when swapping branch delay slots
return m_compiler_pc + (cf.delay_slot_swapped ? 0 : sizeof(Instruction));
}
bool CPU::NewRec::Compiler::TrySwapDelaySlot(Reg rs, Reg rt, Reg rd)
{
if constexpr (!SWAP_BRANCH_DELAY_SLOTS)
return false;
const Instruction* next_instruction = inst + 1;
DebugAssert(next_instruction < (m_block->Instructions() + m_block->size));
const Reg opcode_rs = next_instruction->r.rs;
const Reg opcode_rt = next_instruction->r.rt;
const Reg opcode_rd = next_instruction->r.rd;
#ifdef _DEBUG
TinyString disasm;
DisassembleInstruction(&disasm, m_current_instruction_pc + 4, next_instruction->bits);
#endif
// Just in case we read it in the instruction.. but the block should end after this.
const Instruction* const backup_instruction = inst;
const u32 backup_instruction_pc = m_current_instruction_pc;
const bool backup_instruction_delay_slot = m_current_instruction_branch_delay_slot;
if (next_instruction->bits == 0)
{
// nop
goto is_safe;
}
// can't swap when the branch is the first instruction because of bloody load delays
if ((EMULATE_LOAD_DELAYS && m_block->pc == m_current_instruction_pc) || m_load_delay_dirty ||
(HasLoadDelay() && (m_load_delay_register == rs || m_load_delay_register == rt || m_load_delay_register == rd)))
{
goto is_unsafe;
}
switch (next_instruction->op)
{
case InstructionOp::addi:
case InstructionOp::addiu:
case InstructionOp::slti:
case InstructionOp::sltiu:
case InstructionOp::andi:
case InstructionOp::ori:
case InstructionOp::xori:
case InstructionOp::lui:
case InstructionOp::lb:
case InstructionOp::lh:
case InstructionOp::lwl:
case InstructionOp::lw:
case InstructionOp::lbu:
case InstructionOp::lhu:
case InstructionOp::lwr:
case InstructionOp::sb:
case InstructionOp::sh:
case InstructionOp::swl:
case InstructionOp::sw:
case InstructionOp::swr:
{
if ((rs != Reg::zero && rs == opcode_rt) || (rt != Reg::zero && rt == opcode_rt) ||
(rd != Reg::zero && (rd == opcode_rs || rd == opcode_rt)) ||
(HasLoadDelay() && (m_load_delay_register == opcode_rs || m_load_delay_register == opcode_rt)))
{
goto is_unsafe;
}
}
break;
case InstructionOp::lwc2: // LWC2
case InstructionOp::swc2: // SWC2
break;
case InstructionOp::funct: // SPECIAL
{
switch (next_instruction->r.funct)
{
case InstructionFunct::sll:
case InstructionFunct::srl:
case InstructionFunct::sra:
case InstructionFunct::sllv:
case InstructionFunct::srlv:
case InstructionFunct::srav:
case InstructionFunct::add:
case InstructionFunct::addu:
case InstructionFunct::sub:
case InstructionFunct::subu:
case InstructionFunct::and_:
case InstructionFunct::or_:
case InstructionFunct::xor_:
case InstructionFunct::nor:
case InstructionFunct::slt:
case InstructionFunct::sltu:
{
if ((rs != Reg::zero && rs == opcode_rd) || (rt != Reg::zero && rt == opcode_rd) ||
(rd != Reg::zero && (rd == opcode_rs || rd == opcode_rt)) ||
(HasLoadDelay() && (m_load_delay_register == opcode_rs || m_load_delay_register == opcode_rt ||
m_load_delay_register == opcode_rd)))
{
goto is_unsafe;
}
}
break;
case InstructionFunct::mult:
case InstructionFunct::multu:
case InstructionFunct::div:
case InstructionFunct::divu:
{
if (HasLoadDelay() && (m_load_delay_register == opcode_rs || m_load_delay_register == opcode_rt))
goto is_unsafe;
}
break;
default:
goto is_unsafe;
}
}
break;
case InstructionOp::cop0: // COP0
case InstructionOp::cop1: // COP1
case InstructionOp::cop2: // COP2
case InstructionOp::cop3: // COP3
{
if (next_instruction->cop.IsCommonInstruction())
{
switch (next_instruction->cop.CommonOp())
{
case CopCommonInstruction::mfcn: // MFC0
case CopCommonInstruction::cfcn: // CFC0
{
if ((rs != Reg::zero && rs == opcode_rt) || (rt != Reg::zero && rt == opcode_rt) ||
(rd != Reg::zero && rd == opcode_rt) || (HasLoadDelay() && m_load_delay_register == opcode_rt))
{
goto is_unsafe;
}
}
break;
case CopCommonInstruction::mtcn: // MTC0
case CopCommonInstruction::ctcn: // CTC0
break;
}
}
else
{
// swap when it's GTE
if (next_instruction->op != InstructionOp::cop2)
goto is_unsafe;
}
}
break;
default:
goto is_unsafe;
}
is_safe:
#ifdef _DEBUG
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Log_DebugFmt("Swapping delay slot {:08X} {}", m_current_instruction_pc + 4, disasm);
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#endif
CompileBranchDelaySlot();
inst = backup_instruction;
m_current_instruction_pc = backup_instruction_pc;
m_current_instruction_branch_delay_slot = backup_instruction_delay_slot;
return true;
is_unsafe:
#ifdef _DEBUG
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Log_DebugFmt("NOT swapping delay slot {:08X} {}", m_current_instruction_pc + 4, disasm);
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#endif
return false;
}
void CPU::NewRec::Compiler::SetCompilerPC(u32 newpc)
{
m_compiler_pc = newpc;
m_dirty_pc = true;
}
u32 CPU::NewRec::Compiler::GetFreeHostReg(u32 flags)
{
const u32 req_flags = HR_USABLE | (flags & HR_CALLEE_SAVED);
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
if ((m_host_regs[i].flags & (req_flags | HR_NEEDED | HR_ALLOCATED)) == req_flags)
return i;
}
// find register with lowest counter
u32 lowest = NUM_HOST_REGS;
u16 lowest_count = std::numeric_limits<u16>::max();
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
const HostRegAlloc& ra = m_host_regs[i];
if ((ra.flags & (req_flags | HR_NEEDED)) != req_flags)
continue;
DebugAssert(ra.flags & HR_ALLOCATED);
if (ra.type == HR_TYPE_TEMP)
{
// can't punt temps
continue;
}
if (ra.counter < lowest_count)
{
lowest = i;
lowest_count = ra.counter;
}
}
//
AssertMsg(lowest != NUM_HOST_REGS, "Register allocation failed.");
const HostRegAlloc& ra = m_host_regs[lowest];
switch (ra.type)
{
case HR_TYPE_CPU_REG:
{
// If the register is needed later, and we're allocating a callee-saved register, try moving it to a caller-saved
// register.
if (iinfo->UsedTest(ra.reg) && flags & HR_CALLEE_SAVED)
{
u32 caller_saved_lowest = NUM_HOST_REGS;
u16 caller_saved_lowest_count = std::numeric_limits<u16>::max();
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
constexpr u32 caller_req_flags = HR_USABLE;
constexpr u32 caller_req_mask = HR_USABLE | HR_NEEDED | HR_CALLEE_SAVED;
const HostRegAlloc& caller_ra = m_host_regs[i];
if ((caller_ra.flags & caller_req_mask) != caller_req_flags)
continue;
if (!(caller_ra.flags & HR_ALLOCATED))
{
caller_saved_lowest = i;
caller_saved_lowest_count = 0;
break;
}
if (caller_ra.type == HR_TYPE_TEMP)
continue;
if (caller_ra.counter < caller_saved_lowest_count)
{
caller_saved_lowest = i;
caller_saved_lowest_count = caller_ra.counter;
}
}
if (caller_saved_lowest_count < lowest_count)
{
Log_DebugPrintf("Moving caller-saved host register %s with MIPS register %s to %s for allocation",
GetHostRegName(lowest), GetRegName(ra.reg), GetHostRegName(caller_saved_lowest));
if (IsHostRegAllocated(caller_saved_lowest))
FreeHostReg(caller_saved_lowest);
CopyHostReg(caller_saved_lowest, lowest);
SwapHostRegAlloc(caller_saved_lowest, lowest);
DebugAssert(!IsHostRegAllocated(lowest));
return lowest;
}
}
Log_DebugPrintf("Freeing register %s in host register %s for allocation", GetHostRegName(lowest),
GetRegName(ra.reg));
}
break;
case HR_TYPE_LOAD_DELAY_VALUE:
{
Log_DebugPrintf("Freeing load delay register %s in host register %s for allocation", GetHostRegName(lowest),
GetRegName(ra.reg));
}
break;
case HR_TYPE_NEXT_LOAD_DELAY_VALUE:
{
Log_DebugPrintf("Freeing next load delay register %s in host register %s due for allocation",
GetHostRegName(lowest), GetRegName(ra.reg));
}
break;
default:
{
Panic("Unknown type freed");
}
break;
}
FreeHostReg(lowest);
return lowest;
}
const char* CPU::NewRec::Compiler::GetReadWriteModeString(u32 flags)
{
if ((flags & (HR_MODE_READ | HR_MODE_WRITE)) == (HR_MODE_READ | HR_MODE_WRITE))
return "read-write";
else if (flags & HR_MODE_READ)
return "read-only";
else if (flags & HR_MODE_WRITE)
return "write-only";
else
return "UNKNOWN";
}
u32 CPU::NewRec::Compiler::AllocateHostReg(u32 flags, HostRegAllocType type /* = HR_TYPE_TEMP */,
Reg reg /* = Reg::count */)
{
// Cancel any load delays before booting anything out
if (flags & HR_MODE_WRITE && (type == HR_TYPE_CPU_REG || type == HR_TYPE_NEXT_LOAD_DELAY_VALUE))
CancelLoadDelaysToReg(reg);
// Already have a matching type?
if (type != HR_TYPE_TEMP)
{
const std::optional<u32> check_reg = CheckHostReg(flags, type, reg);
// shouldn't be allocating >1 load delay in a single instruction..
// TODO: prefer callee saved registers for load delay
DebugAssert((type != HR_TYPE_LOAD_DELAY_VALUE && type != HR_TYPE_NEXT_LOAD_DELAY_VALUE) || !check_reg.has_value());
if (check_reg.has_value())
return check_reg.value();
}
const u32 hreg = GetFreeHostReg(flags);
HostRegAlloc& ra = m_host_regs[hreg];
ra.flags = (ra.flags & IMMUTABLE_HR_FLAGS) | (flags & ALLOWED_HR_FLAGS) | HR_ALLOCATED | HR_NEEDED;
ra.type = type;
ra.reg = reg;
ra.counter = m_register_alloc_counter++;
switch (type)
{
case HR_TYPE_CPU_REG:
{
DebugAssert(reg != Reg::zero);
Log_DebugPrintf("Allocate host reg %s to guest reg %s in %s mode", GetHostRegName(hreg), GetRegName(reg),
GetReadWriteModeString(flags));
if (flags & HR_MODE_READ)
{
DebugAssert(ra.reg > Reg::zero && ra.reg < Reg::count);
if (HasConstantReg(reg))
{
// may as well flush it now
Log_DebugPrintf("Flush constant register in guest reg %s to host reg %s", GetRegName(reg),
GetHostRegName(hreg));
LoadHostRegWithConstant(hreg, GetConstantRegU32(reg));
m_constant_regs_dirty.reset(static_cast<u8>(reg));
ra.flags |= HR_MODE_WRITE;
}
else
{
LoadHostRegFromCPUPointer(hreg, &g_state.regs.r[static_cast<u8>(reg)]);
}
}
if (flags & HR_MODE_WRITE && HasConstantReg(reg))
{
DebugAssert(reg != Reg::zero);
Log_DebugPrintf("Clearing constant register in guest reg %s due to write mode in %s", GetRegName(reg),
GetHostRegName(hreg));
ClearConstantReg(reg);
}
}
break;
case HR_TYPE_LOAD_DELAY_VALUE:
{
DebugAssert(!m_load_delay_dirty && (!HasLoadDelay() || !(flags & HR_MODE_WRITE)));
Log_DebugPrintf("Allocating load delayed guest register %s in host reg %s in %s mode", GetRegName(reg),
GetHostRegName(hreg), GetReadWriteModeString(flags));
m_load_delay_register = reg;
m_load_delay_value_register = hreg;
if (flags & HR_MODE_READ)
LoadHostRegFromCPUPointer(hreg, &g_state.load_delay_value);
}
break;
case HR_TYPE_NEXT_LOAD_DELAY_VALUE:
{
Log_DebugPrintf("Allocating next load delayed guest register %s in host reg %s in %s mode", GetRegName(reg),
GetHostRegName(hreg), GetReadWriteModeString(flags));
m_next_load_delay_register = reg;
m_next_load_delay_value_register = hreg;
if (flags & HR_MODE_READ)
LoadHostRegFromCPUPointer(hreg, &g_state.next_load_delay_value);
}
break;
case HR_TYPE_TEMP:
{
DebugAssert(!(flags & (HR_MODE_READ | HR_MODE_WRITE)));
Log_DebugPrintf("Allocate host reg %s as temporary", GetHostRegName(hreg));
}
break;
default:
Panic("Unknown type");
break;
}
return hreg;
}
std::optional<u32> CPU::NewRec::Compiler::CheckHostReg(u32 flags, HostRegAllocType type /* = HR_TYPE_TEMP */,
Reg reg /* = Reg::count */)
{
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& ra = m_host_regs[i];
if (!(ra.flags & HR_ALLOCATED) || ra.type != type || ra.reg != reg)
continue;
DebugAssert(ra.flags & HR_MODE_READ);
if (flags & HR_MODE_WRITE)
{
DebugAssert(type == HR_TYPE_CPU_REG);
if (!(ra.flags & HR_MODE_WRITE))
{
Log_DebugPrintf("Switch guest reg %s from read to read-write in host reg %s", GetRegName(reg),
GetHostRegName(i));
}
if (HasConstantReg(reg))
{
DebugAssert(reg != Reg::zero);
Log_DebugPrintf("Clearing constant register in guest reg %s due to write mode in %s", GetRegName(reg),
GetHostRegName(i));
ClearConstantReg(reg);
}
}
ra.flags |= (flags & ALLOWED_HR_FLAGS) | HR_NEEDED;
ra.counter = m_register_alloc_counter++;
// Need a callee saved reg?
if (flags & HR_CALLEE_SAVED && !(ra.flags & HR_CALLEE_SAVED))
{
// Need to move it to one which is
const u32 new_reg = GetFreeHostReg(HR_CALLEE_SAVED);
Log_DebugPrintf("Rename host reg %s to %s for callee saved", GetHostRegName(i), GetHostRegName(new_reg));
CopyHostReg(new_reg, i);
SwapHostRegAlloc(i, new_reg);
DebugAssert(!IsHostRegAllocated(i));
return new_reg;
}
return i;
}
return std::nullopt;
}
u32 CPU::NewRec::Compiler::AllocateTempHostReg(u32 flags)
{
return AllocateHostReg(flags, HR_TYPE_TEMP);
}
void CPU::NewRec::Compiler::SwapHostRegAlloc(u32 lhs, u32 rhs)
{
HostRegAlloc& lra = m_host_regs[lhs];
HostRegAlloc& rra = m_host_regs[rhs];
const u8 lra_flags = lra.flags;
lra.flags = (lra.flags & IMMUTABLE_HR_FLAGS) | (rra.flags & ~IMMUTABLE_HR_FLAGS);
rra.flags = (rra.flags & IMMUTABLE_HR_FLAGS) | (lra_flags & ~IMMUTABLE_HR_FLAGS);
std::swap(lra.type, rra.type);
std::swap(lra.reg, rra.reg);
std::swap(lra.counter, rra.counter);
}
void CPU::NewRec::Compiler::FlushHostReg(u32 reg)
{
HostRegAlloc& ra = m_host_regs[reg];
if (ra.flags & HR_MODE_WRITE)
{
switch (ra.type)
{
case HR_TYPE_CPU_REG:
{
DebugAssert(ra.reg > Reg::zero && ra.reg < Reg::count);
Log_DebugPrintf("Flushing register %s in host register %s to state", GetRegName(ra.reg), GetHostRegName(reg));
StoreHostRegToCPUPointer(reg, &g_state.regs.r[static_cast<u8>(ra.reg)]);
}
break;
case HR_TYPE_LOAD_DELAY_VALUE:
{
DebugAssert(m_load_delay_value_register == reg);
Log_DebugPrintf("Flushing load delayed register %s in host register %s to state", GetRegName(ra.reg),
GetHostRegName(reg));
StoreHostRegToCPUPointer(reg, &g_state.load_delay_value);
m_load_delay_value_register = NUM_HOST_REGS;
}
break;
case HR_TYPE_NEXT_LOAD_DELAY_VALUE:
{
DebugAssert(m_next_load_delay_value_register == reg);
Log_WarningPrintf("Flushing NEXT load delayed register %s in host register %s to state", GetRegName(ra.reg),
GetHostRegName(reg));
StoreHostRegToCPUPointer(reg, &g_state.next_load_delay_value);
m_next_load_delay_value_register = NUM_HOST_REGS;
}
break;
default:
break;
}
ra.flags = (ra.flags & ~HR_MODE_WRITE) | HR_MODE_READ;
}
}
void CPU::NewRec::Compiler::FreeHostReg(u32 reg)
{
DebugAssert(IsHostRegAllocated(reg));
FlushHostReg(reg);
ClearHostReg(reg);
}
void CPU::NewRec::Compiler::ClearHostReg(u32 reg)
{
HostRegAlloc& ra = m_host_regs[reg];
ra.flags &= IMMUTABLE_HR_FLAGS;
ra.type = HR_TYPE_TEMP;
ra.counter = 0;
ra.reg = Reg::count;
}
void CPU::NewRec::Compiler::MarkRegsNeeded(HostRegAllocType type, Reg reg)
{
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& ra = m_host_regs[i];
if (ra.flags & HR_ALLOCATED && ra.type == type && ra.reg == reg)
ra.flags |= HR_NEEDED;
}
}
void CPU::NewRec::Compiler::RenameHostReg(u32 reg, u32 new_flags, HostRegAllocType new_type, Reg new_reg)
{
// only supported for cpu regs for now
DebugAssert(new_type == HR_TYPE_TEMP || new_type == HR_TYPE_CPU_REG || new_type == HR_TYPE_NEXT_LOAD_DELAY_VALUE);
const std::optional<u32> old_reg = CheckHostReg(0, new_type, new_reg);
if (old_reg.has_value())
{
// don't writeback
ClearHostReg(old_reg.value());
}
// kill any load delay to this reg
if (new_type == HR_TYPE_CPU_REG || new_type == HR_TYPE_NEXT_LOAD_DELAY_VALUE)
CancelLoadDelaysToReg(new_reg);
if (new_type == HR_TYPE_CPU_REG)
{
Log_DebugPrintf("Renaming host reg %s to guest reg %s", GetHostRegName(reg), GetRegName(new_reg));
}
else if (new_type == HR_TYPE_NEXT_LOAD_DELAY_VALUE)
{
Log_DebugPrintf("Renaming host reg %s to load delayed guest reg %s", GetHostRegName(reg), GetRegName(new_reg));
DebugAssert(m_next_load_delay_register == Reg::count && m_next_load_delay_value_register == NUM_HOST_REGS);
m_next_load_delay_register = new_reg;
m_next_load_delay_value_register = reg;
}
else
{
Log_DebugPrintf("Renaming host reg %s to temp", GetHostRegName(reg));
}
HostRegAlloc& ra = m_host_regs[reg];
ra.flags = (ra.flags & IMMUTABLE_HR_FLAGS) | HR_NEEDED | HR_ALLOCATED | (new_flags & ALLOWED_HR_FLAGS);
ra.counter = m_register_alloc_counter++;
ra.type = new_type;
ra.reg = new_reg;
}
void CPU::NewRec::Compiler::ClearHostRegNeeded(u32 reg)
{
DebugAssert(reg < NUM_HOST_REGS && IsHostRegAllocated(reg));
HostRegAlloc& ra = m_host_regs[reg];
if (ra.flags & HR_MODE_WRITE)
ra.flags |= HR_MODE_READ;
ra.flags &= ~HR_NEEDED;
}
void CPU::NewRec::Compiler::ClearHostRegsNeeded()
{
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& ra = m_host_regs[i];
if (!(ra.flags & HR_ALLOCATED))
continue;
// shouldn't have any temps left
DebugAssert(ra.type != HR_TYPE_TEMP);
if (ra.flags & HR_MODE_WRITE)
ra.flags |= HR_MODE_READ;
ra.flags &= ~HR_NEEDED;
}
}
void CPU::NewRec::Compiler::DeleteMIPSReg(Reg reg, bool flush)
{
DebugAssert(reg != Reg::zero);
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& ra = m_host_regs[i];
if (ra.flags & HR_ALLOCATED && ra.type == HR_TYPE_CPU_REG && ra.reg == reg)
{
if (flush)
FlushHostReg(i);
ClearHostReg(i);
ClearConstantReg(reg);
return;
}
}
if (flush)
FlushConstantReg(reg);
ClearConstantReg(reg);
}
bool CPU::NewRec::Compiler::TryRenameMIPSReg(Reg to, Reg from, u32 fromhost, Reg other)
{
// can't rename when in form Rd = Rs op Rt and Rd == Rs or Rd == Rt
if (to == from || to == other || !iinfo->RenameTest(from))
return false;
Log_DebugPrintf("Renaming MIPS register %s to %s", GetRegName(from), GetRegName(to));
if (iinfo->LiveTest(from))
FlushHostReg(fromhost);
// remove all references to renamed-to register
DeleteMIPSReg(to, false);
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CancelLoadDelaysToReg(to);
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// and do the actual rename, new register has been modified.
m_host_regs[fromhost].reg = to;
m_host_regs[fromhost].flags |= HR_MODE_READ | HR_MODE_WRITE;
return true;
}
void CPU::NewRec::Compiler::UpdateHostRegCounters()
{
const CodeCache::InstructionInfo* const info_end = m_block->InstructionsInfo() + m_block->size;
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& ra = m_host_regs[i];
if ((ra.flags & (HR_ALLOCATED | HR_NEEDED)) != HR_ALLOCATED)
continue;
// Try not to punt out load delays.
if (ra.type != HR_TYPE_CPU_REG)
{
ra.counter = std::numeric_limits<u16>::max();
continue;
}
DebugAssert(IsHostRegAllocated(i));
const CodeCache::InstructionInfo* cur = iinfo;
const Reg reg = ra.reg;
if (!(cur->reg_flags[static_cast<u8>(reg)] & CodeCache::RI_USED))
{
ra.counter = 0;
continue;
}
// order based on the number of instructions until this register is used
u16 counter_val = std::numeric_limits<u16>::max();
for (; cur != info_end; cur++, counter_val--)
{
if (cur->ReadsReg(reg))
break;
}
ra.counter = counter_val;
}
}
void CPU::NewRec::Compiler::Flush(u32 flags)
{
// TODO: Flush unneeded caller-saved regs (backup/replace calle-saved needed with caller-saved)
if (flags &
(FLUSH_FREE_UNNEEDED_CALLER_SAVED_REGISTERS | FLUSH_FREE_CALLER_SAVED_REGISTERS | FLUSH_FREE_ALL_REGISTERS))
{
const u32 req_mask = (flags & FLUSH_FREE_ALL_REGISTERS) ?
HR_ALLOCATED :
((flags & FLUSH_FREE_CALLER_SAVED_REGISTERS) ? (HR_ALLOCATED | HR_CALLEE_SAVED) :
(HR_ALLOCATED | HR_CALLEE_SAVED | HR_NEEDED));
constexpr u32 req_flags = HR_ALLOCATED;
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& ra = m_host_regs[i];
if ((ra.flags & req_mask) == req_flags)
FreeHostReg(i);
}
}
if (flags & FLUSH_INVALIDATE_MIPS_REGISTERS)
{
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& ra = m_host_regs[i];
if (ra.flags & HR_ALLOCATED && ra.type == HR_TYPE_CPU_REG)
FreeHostReg(i);
}
FlushConstantRegs(true);
}
else
{
if (flags & FLUSH_FLUSH_MIPS_REGISTERS)
{
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& ra = m_host_regs[i];
if ((ra.flags & (HR_ALLOCATED | HR_MODE_WRITE)) == (HR_ALLOCATED | HR_MODE_WRITE) && ra.type == HR_TYPE_CPU_REG)
FlushHostReg(i);
}
// flush any constant registers which are dirty too
FlushConstantRegs(false);
}
}
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if (flags & FLUSH_INVALIDATE_SPECULATIVE_CONSTANTS)
InvalidateSpeculativeValues();
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}
void CPU::NewRec::Compiler::FlushConstantReg(Reg r)
{
DebugAssert(m_constant_regs_valid.test(static_cast<u32>(r)));
Log_DebugPrintf("Writing back register %s with constant value 0x%08X", GetRegName(r),
m_constant_reg_values[static_cast<u32>(r)]);
StoreConstantToCPUPointer(m_constant_reg_values[static_cast<u32>(r)], &g_state.regs.r[static_cast<u32>(r)]);
m_constant_regs_dirty.reset(static_cast<u32>(r));
}
void CPU::NewRec::Compiler::BackupHostState()
{
DebugAssert(m_host_state_backup_count < m_host_state_backup.size());
// need to back up everything...
HostStateBackup& bu = m_host_state_backup[m_host_state_backup_count];
bu.cycles = m_cycles;
bu.gte_done_cycle = m_gte_done_cycle;
bu.compiler_pc = m_compiler_pc;
bu.dirty_pc = m_dirty_pc;
bu.dirty_instruction_bits = m_dirty_instruction_bits;
bu.dirty_gte_done_cycle = m_dirty_gte_done_cycle;
bu.block_ended = m_block_ended;
bu.inst = inst;
bu.current_instruction_pc = m_current_instruction_pc;
bu.current_instruction_delay_slot = m_current_instruction_branch_delay_slot;
bu.const_regs_valid = m_constant_regs_valid;
bu.const_regs_dirty = m_constant_regs_dirty;
bu.const_regs_values = m_constant_reg_values;
bu.host_regs = m_host_regs;
bu.register_alloc_counter = m_register_alloc_counter;
bu.load_delay_dirty = m_load_delay_dirty;
bu.load_delay_register = m_load_delay_register;
bu.load_delay_value_register = m_load_delay_value_register;
bu.next_load_delay_register = m_next_load_delay_register;
bu.next_load_delay_value_register = m_next_load_delay_value_register;
m_host_state_backup_count++;
}
void CPU::NewRec::Compiler::RestoreHostState()
{
DebugAssert(m_host_state_backup_count > 0);
m_host_state_backup_count--;
HostStateBackup& bu = m_host_state_backup[m_host_state_backup_count];
m_host_regs = std::move(bu.host_regs);
m_constant_reg_values = std::move(bu.const_regs_values);
m_constant_regs_dirty = std::move(bu.const_regs_dirty);
m_constant_regs_valid = std::move(bu.const_regs_valid);
m_current_instruction_branch_delay_slot = bu.current_instruction_delay_slot;
m_current_instruction_pc = bu.current_instruction_pc;
inst = bu.inst;
m_block_ended = bu.block_ended;
m_dirty_gte_done_cycle = bu.dirty_gte_done_cycle;
m_dirty_instruction_bits = bu.dirty_instruction_bits;
m_dirty_pc = bu.dirty_pc;
m_compiler_pc = bu.compiler_pc;
m_register_alloc_counter = bu.register_alloc_counter;
m_load_delay_dirty = bu.load_delay_dirty;
m_load_delay_register = bu.load_delay_register;
m_load_delay_value_register = bu.load_delay_value_register;
m_next_load_delay_register = bu.next_load_delay_register;
m_next_load_delay_value_register = bu.next_load_delay_value_register;
m_gte_done_cycle = bu.gte_done_cycle;
m_cycles = bu.cycles;
}
void CPU::NewRec::Compiler::AddLoadStoreInfo(void* code_address, u32 code_size, u32 address_register, u32 data_register,
MemoryAccessSize size, bool is_signed, bool is_load)
{
DebugAssert(CodeCache::IsUsingFastmem());
DebugAssert(address_register < NUM_HOST_REGS);
DebugAssert(data_register < NUM_HOST_REGS);
u32 gpr_bitmask = 0;
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
if (IsHostRegAllocated(i))
gpr_bitmask |= (1u << i);
}
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CPU::CodeCache::AddLoadStoreInfo(code_address, code_size, m_current_instruction_pc, m_block->pc, m_cycles,
gpr_bitmask, static_cast<u8>(address_register), static_cast<u8>(data_register), size,
is_signed, is_load);
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}
void CPU::NewRec::Compiler::CompileInstruction()
{
#ifdef _DEBUG
TinyString str;
DisassembleInstruction(&str, m_current_instruction_pc, inst->bits);
Log_DebugFmt("Compiling{} {:08X}: {}", m_current_instruction_branch_delay_slot ? " branch delay slot" : "",
m_current_instruction_pc, str);
#endif
m_cycles++;
if (IsNopInstruction(*inst))
{
UpdateLoadDelay();
return;
}
switch (inst->op)
{
#define PGXPFN(x) reinterpret_cast<const void*>(&PGXP::x)
// clang-format off
// TODO: PGXP for jalr
case InstructionOp::funct:
{
switch (inst->r.funct)
{
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case InstructionFunct::sll: CompileTemplate(&Compiler::Compile_sll_const, &Compiler::Compile_sll, PGXPFN(CPU_SLL), TF_WRITES_D | TF_READS_T); SpecExec_sll(); break;
case InstructionFunct::srl: CompileTemplate(&Compiler::Compile_srl_const, &Compiler::Compile_srl, PGXPFN(CPU_SRL), TF_WRITES_D | TF_READS_T); SpecExec_srl(); break;
case InstructionFunct::sra: CompileTemplate(&Compiler::Compile_sra_const, &Compiler::Compile_sra, PGXPFN(CPU_SRA), TF_WRITES_D | TF_READS_T); SpecExec_sra(); break;
case InstructionFunct::sllv: CompileTemplate(&Compiler::Compile_sllv_const, &Compiler::Compile_sllv, PGXPFN(CPU_SLLV), TF_WRITES_D | TF_READS_S | TF_READS_T); SpecExec_sllv(); break;
case InstructionFunct::srlv: CompileTemplate(&Compiler::Compile_srlv_const, &Compiler::Compile_srlv, PGXPFN(CPU_SRLV), TF_WRITES_D | TF_READS_S | TF_READS_T); SpecExec_srlv(); break;
case InstructionFunct::srav: CompileTemplate(&Compiler::Compile_srav_const, &Compiler::Compile_srav, PGXPFN(CPU_SRAV), TF_WRITES_D | TF_READS_S | TF_READS_T); SpecExec_srav(); break;
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case InstructionFunct::jr: CompileTemplate(&Compiler::Compile_jr_const, &Compiler::Compile_jr, nullptr, TF_READS_S); break;
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case InstructionFunct::jalr: CompileTemplate(&Compiler::Compile_jalr_const, &Compiler::Compile_jalr, nullptr, /*TF_WRITES_D |*/ TF_READS_S | TF_NO_NOP); SpecExec_jalr(); break;
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case InstructionFunct::syscall: Compile_syscall(); break;
case InstructionFunct::break_: Compile_break(); break;
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case InstructionFunct::mfhi: SpecCopyReg(inst->r.rd, Reg::hi); CompileMoveRegTemplate(inst->r.rd, Reg::hi, g_settings.gpu_pgxp_cpu); break;
case InstructionFunct::mthi: SpecCopyReg(Reg::hi, inst->r.rs); CompileMoveRegTemplate(Reg::hi, inst->r.rs, g_settings.gpu_pgxp_cpu); break;
case InstructionFunct::mflo: SpecCopyReg(inst->r.rd, Reg::lo); CompileMoveRegTemplate(inst->r.rd, Reg::lo, g_settings.gpu_pgxp_cpu); break;
case InstructionFunct::mtlo: SpecCopyReg(Reg::lo, inst->r.rs); CompileMoveRegTemplate(Reg::lo, inst->r.rs, g_settings.gpu_pgxp_cpu); break;
case InstructionFunct::mult: CompileTemplate(&Compiler::Compile_mult_const, &Compiler::Compile_mult, PGXPFN(CPU_MULT), TF_READS_S | TF_READS_T | TF_WRITES_LO | TF_WRITES_HI | TF_COMMUTATIVE); SpecExec_mult(); break;
case InstructionFunct::multu: CompileTemplate(&Compiler::Compile_multu_const, &Compiler::Compile_multu, PGXPFN(CPU_MULTU), TF_READS_S | TF_READS_T | TF_WRITES_LO | TF_WRITES_HI | TF_COMMUTATIVE); SpecExec_multu(); break;
case InstructionFunct::div: CompileTemplate(&Compiler::Compile_div_const, &Compiler::Compile_div, PGXPFN(CPU_DIV), TF_READS_S | TF_READS_T | TF_WRITES_LO | TF_WRITES_HI); SpecExec_div(); break;
case InstructionFunct::divu: CompileTemplate(&Compiler::Compile_divu_const, &Compiler::Compile_divu, PGXPFN(CPU_DIVU), TF_READS_S | TF_READS_T | TF_WRITES_LO | TF_WRITES_HI); SpecExec_divu(); break;
case InstructionFunct::add: CompileTemplate(&Compiler::Compile_add_const, &Compiler::Compile_add, PGXPFN(CPU_ADD), TF_WRITES_D | TF_READS_S | TF_READS_T | TF_COMMUTATIVE | TF_CAN_OVERFLOW | TF_RENAME_WITH_ZERO_T); SpecExec_add(); break;
case InstructionFunct::addu: CompileTemplate(&Compiler::Compile_addu_const, &Compiler::Compile_addu, PGXPFN(CPU_ADD), TF_WRITES_D | TF_READS_S | TF_READS_T | TF_COMMUTATIVE | TF_RENAME_WITH_ZERO_T); SpecExec_addu(); break;
case InstructionFunct::sub: CompileTemplate(&Compiler::Compile_sub_const, &Compiler::Compile_sub, PGXPFN(CPU_SUB), TF_WRITES_D | TF_READS_S | TF_READS_T | TF_CAN_OVERFLOW | TF_RENAME_WITH_ZERO_T); SpecExec_sub(); break;
case InstructionFunct::subu: CompileTemplate(&Compiler::Compile_subu_const, &Compiler::Compile_subu, PGXPFN(CPU_SUB), TF_WRITES_D | TF_READS_S | TF_READS_T | TF_RENAME_WITH_ZERO_T); SpecExec_subu(); break;
case InstructionFunct::and_: CompileTemplate(&Compiler::Compile_and_const, &Compiler::Compile_and, PGXPFN(CPU_AND_), TF_WRITES_D | TF_READS_S | TF_READS_T | TF_COMMUTATIVE); SpecExec_and(); break;
case InstructionFunct::or_: CompileTemplate(&Compiler::Compile_or_const, &Compiler::Compile_or, PGXPFN(CPU_OR_), TF_WRITES_D | TF_READS_S | TF_READS_T | TF_COMMUTATIVE | TF_RENAME_WITH_ZERO_T); SpecExec_or(); break;
case InstructionFunct::xor_: CompileTemplate(&Compiler::Compile_xor_const, &Compiler::Compile_xor, PGXPFN(CPU_XOR_), TF_WRITES_D | TF_READS_S | TF_READS_T | TF_COMMUTATIVE | TF_RENAME_WITH_ZERO_T); SpecExec_xor(); break;
case InstructionFunct::nor: CompileTemplate(&Compiler::Compile_nor_const, &Compiler::Compile_nor, PGXPFN(CPU_NOR), TF_WRITES_D | TF_READS_S | TF_READS_T | TF_COMMUTATIVE); SpecExec_nor(); break;
case InstructionFunct::slt: CompileTemplate(&Compiler::Compile_slt_const, &Compiler::Compile_slt, PGXPFN(CPU_SLT), TF_WRITES_D | TF_READS_T | TF_READS_S); SpecExec_slt(); break;
case InstructionFunct::sltu: CompileTemplate(&Compiler::Compile_sltu_const, &Compiler::Compile_sltu, PGXPFN(CPU_SLTU), TF_WRITES_D | TF_READS_T | TF_READS_S); SpecExec_sltu(); break;
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default: Panic("fixme funct"); break;
}
}
break;
case InstructionOp::j: Compile_j(); break;
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case InstructionOp::jal: Compile_jal(); SpecExec_jal(); break;
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case InstructionOp::b: CompileTemplate(&Compiler::Compile_b_const, &Compiler::Compile_b, nullptr, TF_READS_S | TF_CAN_SWAP_DELAY_SLOT); SpecExec_b(); break;
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case InstructionOp::blez: CompileTemplate(&Compiler::Compile_blez_const, &Compiler::Compile_blez, nullptr, TF_READS_S | TF_CAN_SWAP_DELAY_SLOT); break;
case InstructionOp::bgtz: CompileTemplate(&Compiler::Compile_bgtz_const, &Compiler::Compile_bgtz, nullptr, TF_READS_S | TF_CAN_SWAP_DELAY_SLOT); break;
case InstructionOp::beq: CompileTemplate(&Compiler::Compile_beq_const, &Compiler::Compile_beq, nullptr, TF_READS_S | TF_READS_T | TF_COMMUTATIVE | TF_CAN_SWAP_DELAY_SLOT); break;
case InstructionOp::bne: CompileTemplate(&Compiler::Compile_bne_const, &Compiler::Compile_bne, nullptr, TF_READS_S | TF_READS_T | TF_COMMUTATIVE | TF_CAN_SWAP_DELAY_SLOT); break;
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case InstructionOp::addi: CompileTemplate(&Compiler::Compile_addi_const, &Compiler::Compile_addi, PGXPFN(CPU_ADDI), TF_WRITES_T | TF_READS_S | TF_COMMUTATIVE | TF_CAN_OVERFLOW | TF_RENAME_WITH_ZERO_IMM); SpecExec_addi(); break;
case InstructionOp::addiu: CompileTemplate(&Compiler::Compile_addiu_const, &Compiler::Compile_addiu, PGXPFN(CPU_ADDI), TF_WRITES_T | TF_READS_S | TF_COMMUTATIVE | TF_RENAME_WITH_ZERO_IMM); SpecExec_addiu(); break;
case InstructionOp::slti: CompileTemplate(&Compiler::Compile_slti_const, &Compiler::Compile_slti, PGXPFN(CPU_SLTI), TF_WRITES_T | TF_READS_S); SpecExec_slti(); break;
case InstructionOp::sltiu: CompileTemplate(&Compiler::Compile_sltiu_const, &Compiler::Compile_sltiu, PGXPFN(CPU_SLTIU), TF_WRITES_T | TF_READS_S); SpecExec_sltiu(); break;
case InstructionOp::andi: CompileTemplate(&Compiler::Compile_andi_const, &Compiler::Compile_andi, PGXPFN(CPU_ANDI), TF_WRITES_T | TF_READS_S | TF_COMMUTATIVE); SpecExec_andi(); break;
case InstructionOp::ori: CompileTemplate(&Compiler::Compile_ori_const, &Compiler::Compile_ori, PGXPFN(CPU_ORI), TF_WRITES_T | TF_READS_S | TF_COMMUTATIVE | TF_RENAME_WITH_ZERO_IMM); SpecExec_ori(); break;
case InstructionOp::xori: CompileTemplate(&Compiler::Compile_xori_const, &Compiler::Compile_xori, PGXPFN(CPU_XORI), TF_WRITES_T | TF_READS_S | TF_COMMUTATIVE | TF_RENAME_WITH_ZERO_IMM); SpecExec_xori(); break;
case InstructionOp::lui: Compile_lui(); SpecExec_lui(); break;
case InstructionOp::lb: CompileLoadStoreTemplate(&Compiler::Compile_lxx, MemoryAccessSize::Byte, false, true, TF_READS_S | TF_WRITES_T | TF_LOAD_DELAY); SpecExec_lxx(MemoryAccessSize::Byte, true); break;
case InstructionOp::lbu: CompileLoadStoreTemplate(&Compiler::Compile_lxx, MemoryAccessSize::Byte, false, false, TF_READS_S | TF_WRITES_T | TF_LOAD_DELAY); SpecExec_lxx(MemoryAccessSize::Byte, false); break;
case InstructionOp::lh: CompileLoadStoreTemplate(&Compiler::Compile_lxx, MemoryAccessSize::HalfWord, false, true, TF_READS_S | TF_WRITES_T | TF_LOAD_DELAY); SpecExec_lxx(MemoryAccessSize::HalfWord, true); break;
case InstructionOp::lhu: CompileLoadStoreTemplate(&Compiler::Compile_lxx, MemoryAccessSize::HalfWord, false, false, TF_READS_S | TF_WRITES_T | TF_LOAD_DELAY); SpecExec_lxx(MemoryAccessSize::HalfWord, false); break;
case InstructionOp::lw: CompileLoadStoreTemplate(&Compiler::Compile_lxx, MemoryAccessSize::Word, false, false, TF_READS_S | TF_WRITES_T | TF_LOAD_DELAY); SpecExec_lxx(MemoryAccessSize::Word, false); break;
case InstructionOp::lwl: CompileLoadStoreTemplate(&Compiler::Compile_lwx, MemoryAccessSize::Word, false, false, TF_READS_S | /*TF_READS_T | TF_WRITES_T | */TF_LOAD_DELAY); SpecExec_lwx(false); break;
case InstructionOp::lwr: CompileLoadStoreTemplate(&Compiler::Compile_lwx, MemoryAccessSize::Word, false, false, TF_READS_S | /*TF_READS_T | TF_WRITES_T | */TF_LOAD_DELAY); SpecExec_lwx(true); break;
case InstructionOp::sb: CompileLoadStoreTemplate(&Compiler::Compile_sxx, MemoryAccessSize::Byte, true, false, TF_READS_S | TF_READS_T); SpecExec_sxx(MemoryAccessSize::Byte); break;
case InstructionOp::sh: CompileLoadStoreTemplate(&Compiler::Compile_sxx, MemoryAccessSize::HalfWord, true, false, TF_READS_S | TF_READS_T); SpecExec_sxx(MemoryAccessSize::HalfWord); break;
case InstructionOp::sw: CompileLoadStoreTemplate(&Compiler::Compile_sxx, MemoryAccessSize::Word, true, false, TF_READS_S | TF_READS_T); SpecExec_sxx(MemoryAccessSize::Word); break;
case InstructionOp::swl: CompileLoadStoreTemplate(&Compiler::Compile_swx, MemoryAccessSize::Word, false, false, TF_READS_S | /*TF_READS_T | TF_WRITES_T | */TF_LOAD_DELAY); SpecExec_swx(false); break;
case InstructionOp::swr: CompileLoadStoreTemplate(&Compiler::Compile_swx, MemoryAccessSize::Word, false, false, TF_READS_S | /*TF_READS_T | TF_WRITES_T | */TF_LOAD_DELAY); SpecExec_swx(true); break;
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case InstructionOp::cop0:
{
if (inst->cop.IsCommonInstruction())
{
switch (inst->cop.CommonOp())
{
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case CopCommonInstruction::mfcn: if (inst->r.rt != Reg::zero) { CompileTemplate(nullptr, &Compiler::Compile_mfc0, nullptr, TF_WRITES_T | TF_LOAD_DELAY); } SpecExec_mfc0(); break;
case CopCommonInstruction::mtcn: CompileTemplate(nullptr, &Compiler::Compile_mtc0, PGXPFN(CPU_MTC0), TF_READS_T); SpecExec_mtc0(); break;
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default: Compile_Fallback(); break;
}
}
else
{
switch (inst->cop.Cop0Op())
{
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case Cop0Instruction::rfe: CompileTemplate(nullptr, &Compiler::Compile_rfe, nullptr, 0); SpecExec_rfe(); break;
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default: Compile_Fallback(); break;
}
}
}
break;
case InstructionOp::cop2:
{
if (inst->cop.IsCommonInstruction())
{
switch (inst->cop.CommonOp())
{
case CopCommonInstruction::mfcn: if (inst->r.rt != Reg::zero) { CompileTemplate(nullptr, &Compiler::Compile_mfc2, nullptr, TF_GTE_STALL); } break;
case CopCommonInstruction::cfcn: if (inst->r.rt != Reg::zero) { CompileTemplate(nullptr, &Compiler::Compile_mfc2, nullptr, TF_GTE_STALL); } break;
case CopCommonInstruction::mtcn: CompileTemplate(nullptr, &Compiler::Compile_mtc2, PGXPFN(CPU_MTC2), TF_GTE_STALL | TF_READS_T | TF_PGXP_WITHOUT_CPU); break;
case CopCommonInstruction::ctcn: CompileTemplate(nullptr, &Compiler::Compile_mtc2, PGXPFN(CPU_MTC2), TF_GTE_STALL | TF_READS_T | TF_PGXP_WITHOUT_CPU); break;
default: Compile_Fallback(); break;
}
}
else
{
// GTE ops
CompileTemplate(nullptr, &Compiler::Compile_cop2, nullptr, TF_GTE_STALL);
}
}
break;
case InstructionOp::lwc2: CompileLoadStoreTemplate(&Compiler::Compile_lwc2, MemoryAccessSize::Word, false, false, TF_GTE_STALL | TF_READS_S | TF_LOAD_DELAY); break;
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case InstructionOp::swc2: CompileLoadStoreTemplate(&Compiler::Compile_swc2, MemoryAccessSize::Word, true, false, TF_GTE_STALL | TF_READS_S); SpecExec_swc2(); break;
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default: Panic("Fixme"); break;
// clang-format on
#undef PGXPFN
}
ClearHostRegsNeeded();
UpdateLoadDelay();
#if 0
const void* end = GetCurrentCodePointer();
if (start != end && !m_current_instruction_branch_delay_slot)
{
CodeCache::DisassembleAndLogHostCode(start,
static_cast<u32>(static_cast<const u8*>(end) - static_cast<const u8*>(start)));
}
#endif
}
void CPU::NewRec::Compiler::CompileBranchDelaySlot(bool dirty_pc /* = true */)
{
// Update load delay at the end of the previous instruction.
UpdateLoadDelay();
// TODO: Move cycle add before this.
inst++;
iinfo++;
m_current_instruction_pc += sizeof(Instruction);
m_current_instruction_branch_delay_slot = true;
m_compiler_pc += sizeof(Instruction);
m_dirty_pc = dirty_pc;
m_dirty_instruction_bits = true;
CompileInstruction();
m_current_instruction_branch_delay_slot = false;
}
void CPU::NewRec::Compiler::CompileTemplate(void (Compiler::*const_func)(CompileFlags),
void (Compiler::*func)(CompileFlags), const void* pgxp_cpu_func, u32 tflags)
{
// TODO: This is where we will do memory operand optimization. Remember to kill constants!
// TODO: Swap S and T if commutative
// TODO: For and, treat as zeroing if imm is zero
// TODO: Optimize slt + bne to cmp + jump
// TODO: Prefer memory operands when load delay is dirty, since we're going to invalidate immediately after the first
// instruction..
// TODO: andi with zero -> zero const
// TODO: load constant so it can be flushed if it's not overwritten later
// TODO: inline PGXP ops.
// TODO: don't rename on sltu.
bool allow_constant = static_cast<bool>(const_func);
Reg rs = inst->r.rs.GetValue();
Reg rt = inst->r.rt.GetValue();
Reg rd = inst->r.rd.GetValue();
if (tflags & TF_GTE_STALL)
StallUntilGTEComplete();
// throw away instructions writing to $zero
if (!(tflags & TF_NO_NOP) && (!g_settings.cpu_recompiler_memory_exceptions || !(tflags & TF_CAN_OVERFLOW)) &&
((tflags & TF_WRITES_T && rt == Reg::zero) || (tflags & TF_WRITES_D && rd == Reg::zero)))
{
Log_DebugPrintf("Skipping instruction because it writes to zero");
return;
}
// handle rename operations
if ((tflags & TF_RENAME_WITH_ZERO_T && HasConstantRegValue(rt, 0)))
{
DebugAssert((tflags & (TF_WRITES_D | TF_READS_S | TF_READS_T)) == (TF_WRITES_D | TF_READS_S | TF_READS_T));
CompileMoveRegTemplate(rd, rs, true);
return;
}
else if ((tflags & (TF_RENAME_WITH_ZERO_T | TF_COMMUTATIVE)) == (TF_RENAME_WITH_ZERO_T | TF_COMMUTATIVE) &&
HasConstantRegValue(rs, 0))
{
DebugAssert((tflags & (TF_WRITES_D | TF_READS_S | TF_READS_T)) == (TF_WRITES_D | TF_READS_S | TF_READS_T));
CompileMoveRegTemplate(rd, rt, true);
return;
}
else if (tflags & TF_RENAME_WITH_ZERO_IMM && inst->i.imm == 0)
{
CompileMoveRegTemplate(rt, rs, true);
return;
}
if (pgxp_cpu_func && g_settings.gpu_pgxp_enable && ((tflags & TF_PGXP_WITHOUT_CPU) || g_settings.UsingPGXPCPUMode()))
{
std::array<Reg, 2> reg_args = {{Reg::count, Reg::count}};
u32 num_reg_args = 0;
if (tflags & TF_READS_S)
reg_args[num_reg_args++] = rs;
if (tflags & TF_READS_T)
reg_args[num_reg_args++] = rt;
if (tflags & TF_READS_LO)
reg_args[num_reg_args++] = Reg::lo;
if (tflags & TF_READS_HI)
reg_args[num_reg_args++] = Reg::hi;
DebugAssert(num_reg_args <= 2);
GeneratePGXPCallWithMIPSRegs(pgxp_cpu_func, inst->bits, reg_args[0], reg_args[1]);
}
// if it's a commutative op, and we have one constant reg but not the other, swap them
// TODO: make it swap when writing to T as well
// TODO: drop the hack for rd == rt
if (tflags & TF_COMMUTATIVE && !(tflags & TF_WRITES_T) &&
((HasConstantReg(rs) && !HasConstantReg(rt)) || (tflags & TF_WRITES_D && rd == rt)))
{
Log_DebugPrintf("Swapping S:%s and T:%s due to commutative op and constants", GetRegName(rs), GetRegName(rt));
std::swap(rs, rt);
}
CompileFlags cf = {};
if (tflags & TF_READS_S)
{
MarkRegsNeeded(HR_TYPE_CPU_REG, rs);
if (HasConstantReg(rs))
cf.const_s = true;
else
allow_constant = false;
}
if (tflags & TF_READS_T)
{
MarkRegsNeeded(HR_TYPE_CPU_REG, rt);
if (HasConstantReg(rt))
cf.const_t = true;
else
allow_constant = false;
}
if (tflags & TF_READS_LO)
{
MarkRegsNeeded(HR_TYPE_CPU_REG, Reg::lo);
if (HasConstantReg(Reg::lo))
cf.const_lo = true;
else
allow_constant = false;
}
if (tflags & TF_READS_HI)
{
MarkRegsNeeded(HR_TYPE_CPU_REG, Reg::hi);
if (HasConstantReg(Reg::hi))
cf.const_hi = true;
else
allow_constant = false;
}
// Needed because of potential swapping
if (tflags & TF_READS_S)
cf.mips_s = static_cast<u8>(rs);
if (tflags & (TF_READS_T | TF_WRITES_T))
cf.mips_t = static_cast<u8>(rt);
if (allow_constant)
{
// woot, constant path
(this->*const_func)(cf);
return;
}
UpdateHostRegCounters();
if (tflags & TF_CAN_SWAP_DELAY_SLOT && TrySwapDelaySlot(cf.MipsS(), cf.MipsT()))
cf.delay_slot_swapped = true;
if (tflags & TF_READS_S &&
(tflags & TF_NEEDS_REG_S || !cf.const_s || (tflags & TF_WRITES_D && rd != Reg::zero && rd == rs)))
{
cf.host_s = AllocateHostReg(HR_MODE_READ, HR_TYPE_CPU_REG, rs);
cf.const_s = false;
cf.valid_host_s = true;
}
if (tflags & TF_READS_T &&
(tflags & (TF_NEEDS_REG_T | TF_WRITES_T) || !cf.const_t || (tflags & TF_WRITES_D && rd != Reg::zero && rd == rt)))
{
cf.host_t = AllocateHostReg(HR_MODE_READ, HR_TYPE_CPU_REG, rt);
cf.const_t = false;
cf.valid_host_t = true;
}
if (tflags & (TF_READS_LO | TF_WRITES_LO))
{
cf.host_lo =
AllocateHostReg(((tflags & TF_READS_LO) ? HR_MODE_READ : 0u) | ((tflags & TF_WRITES_LO) ? HR_MODE_WRITE : 0u),
HR_TYPE_CPU_REG, Reg::lo);
cf.const_lo = false;
cf.valid_host_lo = true;
}
if (tflags & (TF_READS_HI | TF_WRITES_HI))
{
cf.host_hi =
AllocateHostReg(((tflags & TF_READS_HI) ? HR_MODE_READ : 0u) | ((tflags & TF_WRITES_HI) ? HR_MODE_WRITE : 0u),
HR_TYPE_CPU_REG, Reg::hi);
cf.const_hi = false;
cf.valid_host_hi = true;
}
const HostRegAllocType write_type =
(tflags & TF_LOAD_DELAY && EMULATE_LOAD_DELAYS) ? HR_TYPE_NEXT_LOAD_DELAY_VALUE : HR_TYPE_CPU_REG;
if (tflags & TF_CAN_OVERFLOW && g_settings.cpu_recompiler_memory_exceptions)
{
// allocate a temp register for the result, then swap it back
const u32 tempreg = AllocateHostReg(0, HR_TYPE_TEMP);
;
if (tflags & TF_WRITES_D)
{
cf.host_d = tempreg;
cf.valid_host_d = true;
}
else if (tflags & TF_WRITES_T)
{
cf.host_t = tempreg;
cf.valid_host_t = true;
}
(this->*func)(cf);
if (tflags & TF_WRITES_D && rd != Reg::zero)
{
DeleteMIPSReg(rd, false);
RenameHostReg(tempreg, HR_MODE_WRITE, write_type, rd);
}
else if (tflags & TF_WRITES_T && rt != Reg::zero)
{
DeleteMIPSReg(rt, false);
RenameHostReg(tempreg, HR_MODE_WRITE, write_type, rt);
}
else
{
FreeHostReg(tempreg);
}
}
else
{
if (tflags & TF_WRITES_D && rd != Reg::zero)
{
if (tflags & TF_READS_S && cf.valid_host_s && TryRenameMIPSReg(rd, rs, cf.host_s, Reg::count))
cf.host_d = cf.host_s;
else
cf.host_d = AllocateHostReg(HR_MODE_WRITE, write_type, rd);
cf.valid_host_d = true;
}
if (tflags & TF_WRITES_T && rt != Reg::zero)
{
if (tflags & TF_READS_S && cf.valid_host_s && TryRenameMIPSReg(rt, rs, cf.host_s, Reg::count))
cf.host_t = cf.host_s;
else
cf.host_t = AllocateHostReg(HR_MODE_WRITE, write_type, rt);
cf.valid_host_t = true;
}
(this->*func)(cf);
}
}
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void CPU::NewRec::Compiler::CompileLoadStoreTemplate(void (Compiler::*func)(CompileFlags, MemoryAccessSize, bool, bool,
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const std::optional<VirtualMemoryAddress>&),
MemoryAccessSize size, bool store, bool sign, u32 tflags)
{
const Reg rs = inst->i.rs;
const Reg rt = inst->i.rt;
if (tflags & TF_GTE_STALL)
StallUntilGTEComplete();
CompileFlags cf = {};
if (tflags & TF_READS_S)
{
MarkRegsNeeded(HR_TYPE_CPU_REG, rs);
cf.mips_s = static_cast<u8>(rs);
}
if (tflags & (TF_READS_T | TF_WRITES_T))
{
if (tflags & TF_READS_T)
MarkRegsNeeded(HR_TYPE_CPU_REG, rt);
cf.mips_t = static_cast<u8>(rt);
}
UpdateHostRegCounters();
// constant address?
std::optional<VirtualMemoryAddress> addr;
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bool use_fastmem = CodeCache::IsUsingFastmem() && !g_settings.cpu_recompiler_memory_exceptions &&
!SpecIsCacheIsolated() && !CodeCache::HasPreviouslyFaultedOnPC(m_current_instruction_pc);
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if (HasConstantReg(rs))
{
addr = GetConstantRegU32(rs) + inst->i.imm_sext32();
cf.const_s = true;
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if (!Bus::CanUseFastmemForAddress(addr.value()))
{
Log_DebugFmt("Not using fastmem for {:08X}", addr.value());
use_fastmem = false;
}
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}
else
{
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const std::optional<VirtualMemoryAddress> spec_addr = SpecExec_LoadStoreAddr();
if (use_fastmem && spec_addr.has_value() && !Bus::CanUseFastmemForAddress(spec_addr.value()))
{
Log_DebugFmt("Not using fastmem for speculative {:08X}", spec_addr.value());
use_fastmem = false;
}
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if constexpr (HAS_MEMORY_OPERANDS)
{
// don't bother caching it since we're going to flush anyway
// TODO: make less rubbish, if it's caller saved we don't need to flush...
const std::optional<u32> hreg = CheckHostReg(HR_MODE_READ, HR_TYPE_CPU_REG, rs);
if (hreg.has_value())
{
cf.valid_host_s = true;
cf.host_s = hreg.value();
}
}
else
{
// need rs in a register
cf.host_s = AllocateHostReg(HR_MODE_READ, HR_TYPE_CPU_REG, rs);
cf.valid_host_s = true;
}
}
// reads T -> store, writes T -> load
// for now, we defer the allocation to afterwards, because C call
if (tflags & TF_READS_T)
{
if (HasConstantReg(rt))
{
cf.const_t = true;
}
else
{
if constexpr (HAS_MEMORY_OPERANDS)
{
const std::optional<u32> hreg = CheckHostReg(HR_MODE_READ, HR_TYPE_CPU_REG, rt);
if (hreg.has_value())
{
cf.valid_host_t = true;
cf.host_t = hreg.value();
}
}
else
{
cf.host_t = AllocateHostReg(HR_MODE_READ, HR_TYPE_CPU_REG, rt);
cf.valid_host_t = true;
}
}
}
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(this->*func)(cf, size, sign, use_fastmem, addr);
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}
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void CPU::NewRec::Compiler::FlushForLoadStore(const std::optional<VirtualMemoryAddress>& address, bool store,
bool use_fastmem)
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{
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if (use_fastmem)
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return;
// TODO: Stores don't need to flush GTE cycles...
Flush(FLUSH_FOR_C_CALL | FLUSH_FOR_LOADSTORE);
}
void CPU::NewRec::Compiler::CompileMoveRegTemplate(Reg dst, Reg src, bool pgxp_move)
{
if (dst == src || dst == Reg::zero)
return;
if (HasConstantReg(src))
{
DeleteMIPSReg(dst, false);
SetConstantReg(dst, GetConstantRegU32(src));
}
else
{
const u32 srcreg = AllocateHostReg(HR_MODE_READ, HR_TYPE_CPU_REG, src);
if (!TryRenameMIPSReg(dst, src, srcreg, Reg::count))
{
const u32 dstreg = AllocateHostReg(HR_MODE_WRITE, HR_TYPE_CPU_REG, dst);
CopyHostReg(dstreg, srcreg);
ClearHostRegNeeded(dstreg);
}
}
// TODO: This could be made better if we only did it for registers where there was a previous MFC2.
if (g_settings.gpu_pgxp_enable && pgxp_move)
{
// might've been renamed, so use dst here
GeneratePGXPCallWithMIPSRegs(reinterpret_cast<const void*>(&PGXP::CPU_MOVE),
(static_cast<u32>(dst) << 8) | (static_cast<u32>(src)), dst);
}
}
void CPU::NewRec::Compiler::Compile_j()
{
const u32 newpc = (m_compiler_pc & UINT32_C(0xF0000000)) | (inst->j.target << 2);
// TODO: Delay slot swap.
// We could also move the cycle commit back.
CompileBranchDelaySlot();
EndBlock(newpc, true);
}
void CPU::NewRec::Compiler::Compile_jr_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()));
const u32 newpc = GetConstantRegU32(cf.MipsS());
if (newpc & 3 && g_settings.cpu_recompiler_memory_exceptions)
{
EndBlockWithException(Exception::AdEL);
return;
}
CompileBranchDelaySlot();
EndBlock(newpc, true);
}
void CPU::NewRec::Compiler::Compile_jal()
{
const u32 newpc = (m_compiler_pc & UINT32_C(0xF0000000)) | (inst->j.target << 2);
SetConstantReg(Reg::ra, GetBranchReturnAddress({}));
CompileBranchDelaySlot();
EndBlock(newpc, true);
}
void CPU::NewRec::Compiler::Compile_jalr_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()));
const u32 newpc = GetConstantRegU32(cf.MipsS());
if (MipsD() != Reg::zero)
SetConstantReg(MipsD(), GetBranchReturnAddress({}));
CompileBranchDelaySlot();
EndBlock(newpc, true);
}
void CPU::NewRec::Compiler::Compile_syscall()
{
EndBlockWithException(Exception::Syscall);
}
void CPU::NewRec::Compiler::Compile_break()
{
EndBlockWithException(Exception::BP);
}
void CPU::NewRec::Compiler::Compile_b_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()));
const u8 irt = static_cast<u8>(inst->i.rt.GetValue());
const bool bgez = ConvertToBoolUnchecked(irt & u8(1));
const bool link = (irt & u8(0x1E)) == u8(0x10);
const s32 rs = GetConstantRegS32(cf.MipsS());
const bool taken = bgez ? (rs >= 0) : (rs < 0);
const u32 taken_pc = GetConditionalBranchTarget(cf);
if (link)
SetConstantReg(Reg::ra, GetBranchReturnAddress(cf));
CompileBranchDelaySlot();
EndBlock(taken ? taken_pc : m_compiler_pc, true);
}
void CPU::NewRec::Compiler::Compile_b(CompileFlags cf)
{
const u8 irt = static_cast<u8>(inst->i.rt.GetValue());
const bool bgez = ConvertToBoolUnchecked(irt & u8(1));
const bool link = (irt & u8(0x1E)) == u8(0x10);
if (link)
SetConstantReg(Reg::ra, GetBranchReturnAddress(cf));
Compile_bxx(cf, bgez ? BranchCondition::GreaterEqualZero : BranchCondition::LessThanZero);
}
void CPU::NewRec::Compiler::Compile_blez(CompileFlags cf)
{
Compile_bxx(cf, BranchCondition::LessEqualZero);
}
void CPU::NewRec::Compiler::Compile_blez_const(CompileFlags cf)
{
Compile_bxx_const(cf, BranchCondition::LessEqualZero);
}
void CPU::NewRec::Compiler::Compile_bgtz(CompileFlags cf)
{
Compile_bxx(cf, BranchCondition::GreaterThanZero);
}
void CPU::NewRec::Compiler::Compile_bgtz_const(CompileFlags cf)
{
Compile_bxx_const(cf, BranchCondition::GreaterThanZero);
}
void CPU::NewRec::Compiler::Compile_beq(CompileFlags cf)
{
Compile_bxx(cf, BranchCondition::Equal);
}
void CPU::NewRec::Compiler::Compile_beq_const(CompileFlags cf)
{
Compile_bxx_const(cf, BranchCondition::Equal);
}
void CPU::NewRec::Compiler::Compile_bne(CompileFlags cf)
{
Compile_bxx(cf, BranchCondition::NotEqual);
}
void CPU::NewRec::Compiler::Compile_bne_const(CompileFlags cf)
{
Compile_bxx_const(cf, BranchCondition::NotEqual);
}
void CPU::NewRec::Compiler::Compile_bxx_const(CompileFlags cf, BranchCondition cond)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
bool taken;
switch (cond)
{
case BranchCondition::Equal:
taken = GetConstantRegU32(cf.MipsS()) == GetConstantRegU32(cf.MipsT());
break;
case BranchCondition::NotEqual:
taken = GetConstantRegU32(cf.MipsS()) != GetConstantRegU32(cf.MipsT());
break;
case BranchCondition::GreaterThanZero:
taken = GetConstantRegS32(cf.MipsS()) > 0;
break;
case BranchCondition::GreaterEqualZero:
taken = GetConstantRegS32(cf.MipsS()) >= 0;
break;
case BranchCondition::LessThanZero:
taken = GetConstantRegS32(cf.MipsS()) < 0;
break;
case BranchCondition::LessEqualZero:
taken = GetConstantRegS32(cf.MipsS()) <= 0;
break;
default:
Panic("Unhandled condition");
return;
}
const u32 taken_pc = GetConditionalBranchTarget(cf);
CompileBranchDelaySlot();
EndBlock(taken ? taken_pc : m_compiler_pc, true);
}
void CPU::NewRec::Compiler::Compile_sll_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsT()) << inst->r.shamt);
}
void CPU::NewRec::Compiler::Compile_srl_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsT()) >> inst->r.shamt);
}
void CPU::NewRec::Compiler::Compile_sra_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), static_cast<u32>(GetConstantRegS32(cf.MipsT()) >> inst->r.shamt));
}
void CPU::NewRec::Compiler::Compile_sllv_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsT()) << (GetConstantRegU32(cf.MipsS()) & 0x1Fu));
}
void CPU::NewRec::Compiler::Compile_srlv_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsT()) >> (GetConstantRegU32(cf.MipsS()) & 0x1Fu));
}
void CPU::NewRec::Compiler::Compile_srav_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), static_cast<u32>(GetConstantRegS32(cf.MipsT()) >> (GetConstantRegU32(cf.MipsS()) & 0x1Fu)));
}
void CPU::NewRec::Compiler::Compile_and_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsS()) & GetConstantRegU32(cf.MipsT()));
}
void CPU::NewRec::Compiler::Compile_or_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsS()) | GetConstantRegU32(cf.MipsT()));
}
void CPU::NewRec::Compiler::Compile_xor_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsS()) ^ GetConstantRegU32(cf.MipsT()));
}
void CPU::NewRec::Compiler::Compile_nor_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), ~(GetConstantRegU32(cf.MipsS()) | GetConstantRegU32(cf.MipsT())));
}
void CPU::NewRec::Compiler::Compile_slt_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), BoolToUInt32(GetConstantRegS32(cf.MipsS()) < GetConstantRegS32(cf.MipsT())));
}
void CPU::NewRec::Compiler::Compile_sltu_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), BoolToUInt32(GetConstantRegU32(cf.MipsS()) < GetConstantRegU32(cf.MipsT())));
}
void CPU::NewRec::Compiler::Compile_mult_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
const u64 res =
static_cast<u64>(static_cast<s64>(GetConstantRegS32(cf.MipsS())) * static_cast<s64>(GetConstantRegS32(cf.MipsT())));
SetConstantReg(Reg::hi, static_cast<u32>(res >> 32));
SetConstantReg(Reg::lo, static_cast<u32>(res));
}
void CPU::NewRec::Compiler::Compile_multu_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
const u64 res = static_cast<u64>(GetConstantRegU32(cf.MipsS())) * static_cast<u64>(GetConstantRegU32(cf.MipsT()));
SetConstantReg(Reg::hi, static_cast<u32>(res >> 32));
SetConstantReg(Reg::lo, static_cast<u32>(res));
}
void CPU::NewRec::Compiler::Compile_div_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
const s32 num = GetConstantRegS32(cf.MipsS());
const s32 denom = GetConstantRegS32(cf.MipsT());
s32 lo, hi;
if (denom == 0)
{
// divide by zero
lo = (num >= 0) ? UINT32_C(0xFFFFFFFF) : UINT32_C(1);
hi = static_cast<u32>(num);
}
else if (static_cast<u32>(num) == UINT32_C(0x80000000) && denom == -1)
{
// unrepresentable
lo = UINT32_C(0x80000000);
hi = 0;
}
else
{
lo = num / denom;
hi = num % denom;
}
SetConstantReg(Reg::hi, hi);
SetConstantReg(Reg::lo, lo);
}
void CPU::NewRec::Compiler::Compile_divu_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
const u32 num = GetConstantRegU32(cf.MipsS());
const u32 denom = GetConstantRegU32(cf.MipsT());
u32 lo, hi;
if (denom == 0)
{
// divide by zero
lo = UINT32_C(0xFFFFFFFF);
hi = static_cast<u32>(num);
}
else
{
lo = num / denom;
hi = num % denom;
}
SetConstantReg(Reg::hi, hi);
SetConstantReg(Reg::lo, lo);
}
void CPU::NewRec::Compiler::Compile_add_const(CompileFlags cf)
{
// TODO: Overflow
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
if (MipsD() != Reg::zero)
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsS()) + GetConstantRegU32(cf.MipsT()));
}
void CPU::NewRec::Compiler::Compile_addu_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsS()) + GetConstantRegU32(cf.MipsT()));
}
void CPU::NewRec::Compiler::Compile_sub_const(CompileFlags cf)
{
// TODO: Overflow
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
if (MipsD() != Reg::zero)
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsS()) - GetConstantRegU32(cf.MipsT()));
}
void CPU::NewRec::Compiler::Compile_subu_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()) && HasConstantReg(cf.MipsT()));
SetConstantReg(MipsD(), GetConstantRegU32(cf.MipsS()) - GetConstantRegU32(cf.MipsT()));
}
void CPU::NewRec::Compiler::Compile_addi_const(CompileFlags cf)
{
// TODO: Overflow
DebugAssert(HasConstantReg(cf.MipsS()));
if (cf.MipsT() != Reg::zero)
SetConstantReg(cf.MipsT(), GetConstantRegU32(cf.MipsS()) + inst->i.imm_sext32());
}
void CPU::NewRec::Compiler::Compile_addiu_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()));
SetConstantReg(cf.MipsT(), GetConstantRegU32(cf.MipsS()) + inst->i.imm_sext32());
}
void CPU::NewRec::Compiler::Compile_slti_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()));
SetConstantReg(cf.MipsT(), BoolToUInt32(GetConstantRegS32(cf.MipsS()) < static_cast<s32>(inst->i.imm_sext32())));
}
void CPU::NewRec::Compiler::Compile_sltiu_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()));
SetConstantReg(cf.MipsT(), GetConstantRegU32(cf.MipsS()) < inst->i.imm_sext32());
}
void CPU::NewRec::Compiler::Compile_andi_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()));
SetConstantReg(cf.MipsT(), GetConstantRegU32(cf.MipsS()) & inst->i.imm_zext32());
}
void CPU::NewRec::Compiler::Compile_ori_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()));
SetConstantReg(cf.MipsT(), GetConstantRegU32(cf.MipsS()) | inst->i.imm_zext32());
}
void CPU::NewRec::Compiler::Compile_xori_const(CompileFlags cf)
{
DebugAssert(HasConstantReg(cf.MipsS()));
SetConstantReg(cf.MipsT(), GetConstantRegU32(cf.MipsS()) ^ inst->i.imm_zext32());
}
void CPU::NewRec::Compiler::Compile_lui()
{
if (inst->i.rt == Reg::zero)
return;
SetConstantReg(inst->i.rt, inst->i.imm_zext32() << 16);
}
static constexpr const std::array<std::pair<u32*, u32>, 16> s_cop0_table = {
{{nullptr, 0x00000000u},
{nullptr, 0x00000000u},
{nullptr, 0x00000000u},
{&CPU::g_state.cop0_regs.BPC, 0xffffffffu},
{nullptr, 0},
{&CPU::g_state.cop0_regs.BDA, 0xffffffffu},
{&CPU::g_state.cop0_regs.TAR, 0x00000000u},
{&CPU::g_state.cop0_regs.dcic.bits, CPU::Cop0Registers::DCIC::WRITE_MASK},
{&CPU::g_state.cop0_regs.BadVaddr, 0x00000000u},
{&CPU::g_state.cop0_regs.BDAM, 0xffffffffu},
{nullptr, 0x00000000u},
{&CPU::g_state.cop0_regs.BPCM, 0xffffffffu},
{&CPU::g_state.cop0_regs.sr.bits, CPU::Cop0Registers::SR::WRITE_MASK},
{&CPU::g_state.cop0_regs.cause.bits, CPU::Cop0Registers::CAUSE::WRITE_MASK},
{&CPU::g_state.cop0_regs.EPC, 0x00000000u},
{&CPU::g_state.cop0_regs.PRID, 0x00000000u}}};
u32* CPU::NewRec::Compiler::GetCop0RegPtr(Cop0Reg reg)
{
return (static_cast<u8>(reg) < s_cop0_table.size()) ? s_cop0_table[static_cast<u8>(reg)].first : nullptr;
}
u32 CPU::NewRec::Compiler::GetCop0RegWriteMask(Cop0Reg reg)
{
return (static_cast<u8>(reg) < s_cop0_table.size()) ? s_cop0_table[static_cast<u8>(reg)].second : 0;
}
void CPU::NewRec::Compiler::Compile_mfc0(CompileFlags cf)
{
const Cop0Reg r = static_cast<Cop0Reg>(MipsD());
const u32* ptr = GetCop0RegPtr(r);
if (!ptr)
{
Log_ErrorPrintf("Read from unknown cop0 reg %u", static_cast<u32>(r));
Compile_Fallback();
return;
}
DebugAssert(cf.valid_host_t);
LoadHostRegFromCPUPointer(cf.host_t, ptr);
}
std::pair<u32*, CPU::NewRec::Compiler::GTERegisterAccessAction>
CPU::NewRec::Compiler::GetGTERegisterPointer(u32 index, bool writing)
{
if (!writing)
{
// Most GTE registers can be read directly. Handle the special cases here.
if (index == 15) // SXY3
{
// mirror of SXY2
index = 14;
}
switch (index)
{
case 28: // IRGB
case 29: // ORGB
{
return std::make_pair(&g_state.gte_regs.r32[index], GTERegisterAccessAction::CallHandler);
}
break;
default:
{
return std::make_pair(&g_state.gte_regs.r32[index], GTERegisterAccessAction::Direct);
}
break;
}
}
else
{
switch (index)
{
case 1: // V0[z]
case 3: // V1[z]
case 5: // V2[z]
case 8: // IR0
case 9: // IR1
case 10: // IR2
case 11: // IR3
case 36: // RT33
case 44: // L33
case 52: // LR33
case 58: // H - sign-extended on read but zext on use
case 59: // DQA
case 61: // ZSF3
case 62: // ZSF4
{
// sign-extend z component of vector registers
return std::make_pair(&g_state.gte_regs.r32[index], GTERegisterAccessAction::SignExtend16);
}
break;
case 7: // OTZ
case 16: // SZ0
case 17: // SZ1
case 18: // SZ2
case 19: // SZ3
{
// zero-extend unsigned values
return std::make_pair(&g_state.gte_regs.r32[index], GTERegisterAccessAction::ZeroExtend16);
}
break;
case 15: // SXY3
{
// writing to SXYP pushes to the FIFO
return std::make_pair(&g_state.gte_regs.r32[index], GTERegisterAccessAction::PushFIFO);
}
break;
case 28: // IRGB
case 30: // LZCS
case 63: // FLAG
{
return std::make_pair(&g_state.gte_regs.r32[index], GTERegisterAccessAction::CallHandler);
}
case 29: // ORGB
case 31: // LZCR
{
// read-only registers
return std::make_pair(&g_state.gte_regs.r32[index], GTERegisterAccessAction::Ignore);
}
default:
{
// written as-is, 2x16 or 1x32 bits
return std::make_pair(&g_state.gte_regs.r32[index], GTERegisterAccessAction::Direct);
}
}
}
}
void CPU::NewRec::Compiler::AddGTETicks(TickCount ticks)
{
// TODO: check, int has +1 here
m_gte_done_cycle = m_cycles + ticks;
Log_DebugPrintf("Adding %d GTE ticks", ticks);
}
void CPU::NewRec::Compiler::StallUntilGTEComplete()
{
// TODO: hack to match old rec.. this may or may not be correct behavior
// it's the difference between stalling before and after the current instruction's cycle
DebugAssert(m_cycles > 0);
m_cycles--;
if (!m_dirty_gte_done_cycle)
{
// simple case - in block scheduling
if (m_gte_done_cycle > m_cycles)
{
Log_DebugPrintf("Stalling for %d ticks from GTE", m_gte_done_cycle - m_cycles);
m_cycles += (m_gte_done_cycle - m_cycles);
}
}
else
{
// switch to in block scheduling
Log_DebugPrintf("Flushing GTE stall from state");
Flush(FLUSH_GTE_STALL_FROM_STATE);
}
m_cycles++;
}
void CPU::NewRec::BackpatchLoadStore(void* exception_pc, const CodeCache::LoadstoreBackpatchInfo& info)
{
// remove the cycles we added for the memory read, then take them off again after the backpatch
// the normal rec path will add the ram read ticks later, so we need to take them off at the end
DebugAssert(!info.is_load || info.cycles >= Bus::RAM_READ_TICKS);
const TickCount cycles_to_add =
static_cast<TickCount>(static_cast<u32>(info.cycles)) - (info.is_load ? Bus::RAM_READ_TICKS : 0);
const TickCount cycles_to_remove = static_cast<TickCount>(static_cast<u32>(info.cycles));
JitCodeBuffer& buffer = CodeCache::GetCodeBuffer();
void* thunk_address = buffer.GetFreeFarCodePointer();
const u32 thunk_size = CompileLoadStoreThunk(
thunk_address, buffer.GetFreeFarCodeSpace(), exception_pc, info.code_size, cycles_to_add, cycles_to_remove,
info.gpr_bitmask, info.address_register, info.data_register, info.AccessSize(), info.is_signed, info.is_load);
#if 0
Log_DebugPrintf("**Backpatch Thunk**");
CodeCache::DisassembleAndLogHostCode(thunk_address, thunk_size);
#endif
// backpatch to a jump to the slowmem handler
CodeCache::EmitJump(exception_pc, thunk_address, true);
buffer.CommitFarCode(thunk_size);
}
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void CPU::NewRec::Compiler::InitSpeculativeRegs()
{
for (u8 i = 0; i < static_cast<u8>(Reg::count); i++)
m_speculative_constants.regs[i] = g_state.regs.r[i];
m_speculative_constants.cop0_sr = g_state.cop0_regs.sr.bits;
m_speculative_constants.memory.clear();
}
void CPU::NewRec::Compiler::InvalidateSpeculativeValues()
{
m_speculative_constants.regs.fill(std::nullopt);
m_speculative_constants.memory.clear();
m_speculative_constants.cop0_sr.reset();
}
CPU::NewRec::Compiler::SpecValue CPU::NewRec::Compiler::SpecReadReg(Reg reg)
{
return m_speculative_constants.regs[static_cast<u8>(reg)];
}
void CPU::NewRec::Compiler::SpecWriteReg(Reg reg, SpecValue value)
{
if (reg == Reg::zero)
return;
m_speculative_constants.regs[static_cast<u8>(reg)] = value;
}
void CPU::NewRec::Compiler::SpecInvalidateReg(Reg reg)
{
if (reg == Reg::zero)
return;
m_speculative_constants.regs[static_cast<u8>(reg)].reset();
}
void CPU::NewRec::Compiler::SpecCopyReg(Reg dst, Reg src)
{
if (dst == Reg::zero)
return;
m_speculative_constants.regs[static_cast<u8>(dst)] = m_speculative_constants.regs[static_cast<u8>(src)];
}
CPU::NewRec::Compiler::SpecValue CPU::NewRec::Compiler::SpecReadMem(VirtualMemoryAddress address)
{
auto it = m_speculative_constants.memory.find(address);
if (it != m_speculative_constants.memory.end())
return it->second;
u32 value;
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if ((address & SCRATCHPAD_ADDR_MASK) == SCRATCHPAD_ADDR)
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{
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u32 scratchpad_offset = address & SCRATCHPAD_OFFSET_MASK;
std::memcpy(&value, &CPU::g_state.scratchpad[scratchpad_offset], sizeof(value));
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return value;
}
const PhysicalMemoryAddress phys_addr = address & PHYSICAL_MEMORY_ADDRESS_MASK;
if (Bus::IsRAMAddress(phys_addr))
{
u32 ram_offset = phys_addr & Bus::g_ram_mask;
std::memcpy(&value, &Bus::g_ram[ram_offset], sizeof(value));
return value;
}
return std::nullopt;
}
void CPU::NewRec::Compiler::SpecWriteMem(u32 address, SpecValue value)
{
auto it = m_speculative_constants.memory.find(address);
if (it != m_speculative_constants.memory.end())
{
it->second = value;
return;
}
const PhysicalMemoryAddress phys_addr = address & PHYSICAL_MEMORY_ADDRESS_MASK;
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if ((address & SCRATCHPAD_ADDR_MASK) == SCRATCHPAD_ADDR || Bus::IsRAMAddress(phys_addr))
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m_speculative_constants.memory.emplace(address, value);
}
void CPU::NewRec::Compiler::SpecInvalidateMem(VirtualMemoryAddress address)
{
SpecWriteMem(address, std::nullopt);
}
bool CPU::NewRec::Compiler::SpecIsCacheIsolated()
{
if (!m_speculative_constants.cop0_sr.has_value())
return false;
const Cop0Registers::SR sr{m_speculative_constants.cop0_sr.value()};
return sr.Isc;
}
void CPU::NewRec::Compiler::SpecExec_b()
{
const bool link = (static_cast<u8>(inst->i.rt.GetValue()) & u8(0x1E)) == u8(0x10);
if (link)
SpecWriteReg(Reg::ra, m_compiler_pc);
}
void CPU::NewRec::Compiler::SpecExec_jal()
{
SpecWriteReg(Reg::ra, m_compiler_pc);
}
void CPU::NewRec::Compiler::SpecExec_jalr()
{
SpecWriteReg(inst->r.rd, m_compiler_pc);
}
void CPU::NewRec::Compiler::SpecExec_sll()
{
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rt.has_value())
SpecWriteReg(inst->r.rd, rt.value() << inst->r.shamt);
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_srl()
{
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rt.has_value())
SpecWriteReg(inst->r.rd, rt.value() >> inst->r.shamt);
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_sra()
{
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rt.has_value())
SpecWriteReg(inst->r.rd, static_cast<u32>(static_cast<s32>(rt.value()) >> inst->r.shamt));
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_sllv()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, rt.value() << (rs.value() & 0x1F));
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_srlv()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, rt.value() >> (rs.value() & 0x1F));
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_srav()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, static_cast<u32>(static_cast<s32>(rt.value()) >> (rs.value() & 0x1F)));
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_mult()
{
// TODO
SpecInvalidateReg(Reg::hi);
SpecInvalidateReg(Reg::lo);
}
void CPU::NewRec::Compiler::SpecExec_multu()
{
// TODO
SpecInvalidateReg(Reg::hi);
SpecInvalidateReg(Reg::lo);
}
void CPU::NewRec::Compiler::SpecExec_div()
{
// TODO
SpecInvalidateReg(Reg::hi);
SpecInvalidateReg(Reg::lo);
}
void CPU::NewRec::Compiler::SpecExec_divu()
{
// TODO
SpecInvalidateReg(Reg::hi);
SpecInvalidateReg(Reg::lo);
}
void CPU::NewRec::Compiler::SpecExec_add()
{
SpecExec_addu();
}
void CPU::NewRec::Compiler::SpecExec_addu()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, rs.value() + rt.value());
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_sub()
{
SpecExec_subu();
}
void CPU::NewRec::Compiler::SpecExec_subu()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, rs.value() - rt.value());
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_and()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, rs.value() & rt.value());
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_or()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, rs.value() | rt.value());
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_xor()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, rs.value() ^ rt.value());
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_nor()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, ~(rs.value() | rt.value()));
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_slt()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, BoolToUInt32(static_cast<s32>(rs.value()) < static_cast<s32>(rt.value())));
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_sltu()
{
const SpecValue rs = SpecReadReg(inst->r.rs);
const SpecValue rt = SpecReadReg(inst->r.rt);
if (rs.has_value() && rt.has_value())
SpecWriteReg(inst->r.rd, BoolToUInt32(rs.value() < rt.value()));
else
SpecInvalidateReg(inst->r.rd);
}
void CPU::NewRec::Compiler::SpecExec_addi()
{
SpecExec_addiu();
}
void CPU::NewRec::Compiler::SpecExec_addiu()
{
const SpecValue rs = SpecReadReg(inst->i.rs);
if (rs.has_value())
SpecWriteReg(inst->i.rt, rs.value() + inst->i.imm_sext32());
else
SpecInvalidateReg(inst->i.rt);
}
void CPU::NewRec::Compiler::SpecExec_slti()
{
const SpecValue rs = SpecReadReg(inst->i.rs);
if (rs.has_value())
SpecWriteReg(inst->i.rt, BoolToUInt32(static_cast<s32>(rs.value()) < static_cast<s32>(inst->i.imm_sext32())));
else
SpecInvalidateReg(inst->i.rt);
}
void CPU::NewRec::Compiler::SpecExec_sltiu()
{
const SpecValue rs = SpecReadReg(inst->i.rs);
if (rs.has_value())
SpecWriteReg(inst->i.rt, BoolToUInt32(rs.value() < inst->i.imm_sext32()));
else
SpecInvalidateReg(inst->i.rt);
}
void CPU::NewRec::Compiler::SpecExec_andi()
{
const SpecValue rs = SpecReadReg(inst->i.rs);
if (rs.has_value())
SpecWriteReg(inst->i.rt, rs.value() & inst->i.imm_zext32());
else
SpecInvalidateReg(inst->i.rt);
}
void CPU::NewRec::Compiler::SpecExec_ori()
{
const SpecValue rs = SpecReadReg(inst->i.rs);
if (rs.has_value())
SpecWriteReg(inst->i.rt, rs.value() | inst->i.imm_zext32());
else
SpecInvalidateReg(inst->i.rt);
}
void CPU::NewRec::Compiler::SpecExec_xori()
{
const SpecValue rs = SpecReadReg(inst->i.rs);
if (rs.has_value())
SpecWriteReg(inst->i.rt, rs.value() ^ inst->i.imm_zext32());
else
SpecInvalidateReg(inst->i.rt);
}
void CPU::NewRec::Compiler::SpecExec_lui()
{
SpecWriteReg(inst->i.rt, inst->i.imm_zext32() << 16);
}
CPU::NewRec::Compiler::SpecValue CPU::NewRec::Compiler::SpecExec_LoadStoreAddr()
{
const SpecValue rs = SpecReadReg(inst->i.rs);
return rs.has_value() ? (rs.value() + inst->i.imm_sext32()) : rs;
}
void CPU::NewRec::Compiler::SpecExec_lxx(MemoryAccessSize size, bool sign)
{
const SpecValue addr = SpecExec_LoadStoreAddr();
SpecValue val;
if (!addr.has_value() || !(val = SpecReadMem(addr.value())).has_value())
{
SpecInvalidateReg(inst->i.rt);
return;
}
switch (size)
{
case MemoryAccessSize::Byte:
val = sign ? SignExtend32(static_cast<u8>(val.value())) : ZeroExtend32(static_cast<u8>(val.value()));
break;
case MemoryAccessSize::HalfWord:
val = sign ? SignExtend32(static_cast<u16>(val.value())) : ZeroExtend32(static_cast<u16>(val.value()));
break;
case MemoryAccessSize::Word:
break;
default:
UnreachableCode();
}
SpecWriteReg(inst->r.rt, val);
}
void CPU::NewRec::Compiler::SpecExec_lwx(bool lwr)
{
// TODO
SpecInvalidateReg(inst->i.rt);
}
void CPU::NewRec::Compiler::SpecExec_sxx(MemoryAccessSize size)
{
const SpecValue addr = SpecExec_LoadStoreAddr();
if (!addr.has_value())
return;
SpecValue rt = SpecReadReg(inst->i.rt);
if (rt.has_value())
{
switch (size)
{
case MemoryAccessSize::Byte:
rt = ZeroExtend32(static_cast<u8>(rt.value()));
break;
case MemoryAccessSize::HalfWord:
rt = ZeroExtend32(static_cast<u16>(rt.value()));
break;
case MemoryAccessSize::Word:
break;
default:
UnreachableCode();
}
}
SpecWriteMem(addr.value(), rt);
}
void CPU::NewRec::Compiler::SpecExec_swx(bool swr)
{
const SpecValue addr = SpecExec_LoadStoreAddr();
if (addr.has_value())
SpecInvalidateMem(addr.value() & ~3u);
}
void CPU::NewRec::Compiler::SpecExec_swc2()
{
const SpecValue addr = SpecExec_LoadStoreAddr();
if (addr.has_value())
SpecInvalidateMem(addr.value());
}
void CPU::NewRec::Compiler::SpecExec_mfc0()
{
const Cop0Reg rd = static_cast<Cop0Reg>(inst->r.rd.GetValue());
if (rd != Cop0Reg::SR)
{
SpecInvalidateReg(inst->r.rt);
return;
}
SpecWriteReg(inst->r.rt, m_speculative_constants.cop0_sr);
}
void CPU::NewRec::Compiler::SpecExec_mtc0()
{
const Cop0Reg rd = static_cast<Cop0Reg>(inst->r.rd.GetValue());
if (rd != Cop0Reg::SR || !m_speculative_constants.cop0_sr.has_value())
return;
SpecValue val = SpecReadReg(inst->r.rt);
if (val.has_value())
{
constexpr u32 mask = Cop0Registers::SR::WRITE_MASK;
val = (m_speculative_constants.cop0_sr.value() & mask) | (val.value() & mask);
}
m_speculative_constants.cop0_sr = val;
}
void CPU::NewRec::Compiler::SpecExec_rfe()
{
if (!m_speculative_constants.cop0_sr.has_value())
return;
const u32 val = m_speculative_constants.cop0_sr.value();
m_speculative_constants.cop0_sr = (val & UINT32_C(0b110000)) | ((val & UINT32_C(0b111111)) >> 2);
}