Duckstation/src/core/cpu_newrec_compiler_riscv64.cpp

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// SPDX-FileCopyrightText: 2024 Connor McLaughlin <stenzek@gmail.com>
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// SPDX-License-Identifier: (GPL-3.0 OR CC-BY-NC-ND-4.0)
#include "cpu_newrec_compiler_riscv64.h"
#include "cpu_code_cache_private.h"
#include "cpu_core_private.h"
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#include "cpu_pgxp.h"
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#include "cpu_recompiler_thunks.h"
#include "gte.h"
#include "settings.h"
#include "timing_event.h"
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#include "common/align.h"
#include "common/assert.h"
#include "common/log.h"
#include "common/memmap.h"
#include "common/string_util.h"
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#include <limits>
#ifdef CPU_ARCH_RISCV64
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Log_SetChannel(CPU::NewRec);
#ifdef ENABLE_HOST_DISASSEMBLY
extern "C" {
#include "riscv-disas.h"
}
#endif
// For LW/SW/etc.
#define PTR(x) ((u32)(((u8*)(x)) - ((u8*)&g_state))), RSTATE
static constexpr u32 BLOCK_LINK_SIZE = 8; // auipc+jr
namespace CPU::NewRec {
using namespace biscuit;
using CPU::Recompiler::rvEmitCall;
using CPU::Recompiler::rvEmitDSExtW;
using CPU::Recompiler::rvEmitDUExtW;
using CPU::Recompiler::rvEmitFarLoad;
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using CPU::Recompiler::rvEmitJmp;
using CPU::Recompiler::rvEmitMov;
using CPU::Recompiler::rvEmitMov64;
using CPU::Recompiler::rvEmitSExtB;
using CPU::Recompiler::rvEmitSExtH;
using CPU::Recompiler::rvEmitUExtB;
using CPU::Recompiler::rvEmitUExtH;
using CPU::Recompiler::rvGetAddressImmediates;
using CPU::Recompiler::rvIsCallerSavedRegister;
using CPU::Recompiler::rvIsValidSExtITypeImm;
using CPU::Recompiler::rvMoveAddressToReg;
RISCV64Compiler s_instance;
Compiler* g_compiler = &s_instance;
} // namespace CPU::NewRec
bool CPU::Recompiler::rvIsCallerSavedRegister(u32 id)
{
return (id == 1 || (id >= 3 && id < 8) || (id >= 10 && id <= 17) || (id >= 28 && id <= 31));
}
bool CPU::Recompiler::rvIsValidSExtITypeImm(u32 imm)
{
return (static_cast<u32>((static_cast<s32>(imm) << 20) >> 20) == imm);
}
std::pair<s32, s32> CPU::Recompiler::rvGetAddressImmediates(const void* cur, const void* target)
{
const s64 disp = static_cast<s64>(reinterpret_cast<intptr_t>(target) - reinterpret_cast<intptr_t>(cur));
Assert(disp >= static_cast<s64>(std::numeric_limits<s32>::min()) &&
disp <= static_cast<s64>(std::numeric_limits<s32>::max()));
const s64 hi = disp + 0x800;
const s64 lo = disp - (hi & 0xFFFFF000);
return std::make_pair(static_cast<s32>(hi >> 12), static_cast<s32>((lo << 52) >> 52));
}
void CPU::Recompiler::rvMoveAddressToReg(biscuit::Assembler* rvAsm, const biscuit::GPR& reg, const void* addr)
{
const auto [hi, lo] = rvGetAddressImmediates(rvAsm->GetCursorPointer(), addr);
rvAsm->AUIPC(reg, hi);
rvAsm->ADDI(reg, reg, lo);
}
void CPU::Recompiler::rvEmitMov(biscuit::Assembler* rvAsm, const biscuit::GPR& rd, u32 imm)
{
// Borrowed from biscuit, but doesn't emit an ADDI if the lower 12 bits are zero.
const u32 lower = imm & 0xFFF;
const u32 upper = (imm & 0xFFFFF000) >> 12;
const s32 simm = static_cast<s32>(imm);
if (rvIsValidSExtITypeImm(simm))
{
rvAsm->ADDI(rd, biscuit::zero, static_cast<s32>(lower));
}
else
{
const bool needs_increment = (lower & 0x800) != 0;
const u32 upper_imm = needs_increment ? upper + 1 : upper;
rvAsm->LUI(rd, upper_imm);
rvAsm->ADDI(rd, rd, static_cast<int32_t>(lower));
}
}
void CPU::Recompiler::rvEmitMov64(biscuit::Assembler* rvAsm, const biscuit::GPR& rd, const biscuit::GPR& scratch,
u64 imm)
{
// TODO: Make better..
rvEmitMov(rvAsm, rd, static_cast<u32>(imm >> 32));
rvEmitMov(rvAsm, scratch, static_cast<u32>(imm));
rvAsm->SLLI64(rd, rd, 32);
rvAsm->SLLI64(scratch, scratch, 32);
rvAsm->SRLI64(scratch, scratch, 32);
rvAsm->ADD(rd, rd, scratch);
}
u32 CPU::Recompiler::rvEmitJmp(biscuit::Assembler* rvAsm, const void* ptr, const biscuit::GPR& link_reg)
{
// TODO: use J if displacement is <1MB, needs a bool because backpatch must be 8 bytes
const auto [hi, lo] = rvGetAddressImmediates(rvAsm->GetCursorPointer(), ptr);
rvAsm->AUIPC(RSCRATCH, hi);
rvAsm->JALR(link_reg, lo, RSCRATCH);
return 8;
}
u32 CPU::Recompiler::rvEmitCall(biscuit::Assembler* rvAsm, const void* ptr)
{
return rvEmitJmp(rvAsm, ptr, biscuit::ra);
}
void CPU::Recompiler::rvEmitFarLoad(biscuit::Assembler* rvAsm, const biscuit::GPR& reg, const void* addr,
bool sign_extend_word)
{
const auto [hi, lo] = rvGetAddressImmediates(rvAsm->GetCursorPointer(), addr);
rvAsm->AUIPC(reg, hi);
if (sign_extend_word)
rvAsm->LW(reg, lo, reg);
else
rvAsm->LWU(reg, lo, reg);
}
void CPU::Recompiler::rvEmitFarStore(biscuit::Assembler* rvAsm, const biscuit::GPR& reg, const void* addr,
const biscuit::GPR& tempreg)
{
const auto [hi, lo] = rvGetAddressImmediates(rvAsm->GetCursorPointer(), addr);
rvAsm->AUIPC(tempreg, hi);
rvAsm->SW(reg, lo, tempreg);
}
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void CPU::Recompiler::rvEmitSExtB(biscuit::Assembler* rvAsm, const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvAsm->SLLI(rd, rs, 24);
rvAsm->SRAIW(rd, rd, 24);
}
void CPU::Recompiler::rvEmitUExtB(biscuit::Assembler* rvAsm, const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvAsm->ANDI(rd, rs, 0xFF);
}
void CPU::Recompiler::rvEmitSExtH(biscuit::Assembler* rvAsm, const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvAsm->SLLI(rd, rs, 16);
rvAsm->SRAIW(rd, rd, 16);
}
void CPU::Recompiler::rvEmitUExtH(biscuit::Assembler* rvAsm, const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvAsm->SLLI(rd, rs, 16);
rvAsm->SRLI(rd, rd, 16);
}
void CPU::Recompiler::rvEmitDSExtW(biscuit::Assembler* rvAsm, const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvAsm->ADDIW(rd, rs, 0);
}
void CPU::Recompiler::rvEmitDUExtW(biscuit::Assembler* rvAsm, const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvAsm->SLLI64(rd, rs, 32);
rvAsm->SRLI64(rd, rd, 32);
}
void CPU::CodeCache::DisassembleAndLogHostCode(const void* start, u32 size)
{
#ifdef ENABLE_HOST_DISASSEMBLY
const u8* cur = static_cast<const u8*>(start);
const u8* end = cur + size;
char buf[256];
while (cur < end)
{
rv_inst inst;
size_t instlen;
inst_fetch(cur, &inst, &instlen);
disasm_inst(buf, std::size(buf), rv64, static_cast<u64>(reinterpret_cast<uintptr_t>(cur)), inst);
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DEBUG_LOG("\t0x{:016X}\t{}", static_cast<u64>(reinterpret_cast<uintptr_t>(cur)), buf);
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cur += instlen;
}
#else
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ERROR_LOG("Not compiled with ENABLE_HOST_DISASSEMBLY.");
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#endif
}
u32 CPU::CodeCache::GetHostInstructionCount(const void* start, u32 size)
{
#ifdef ENABLE_HOST_DISASSEMBLY
const u8* cur = static_cast<const u8*>(start);
const u8* end = cur + size;
u32 icount = 0;
while (cur < end)
{
rv_inst inst;
size_t instlen;
inst_fetch(cur, &inst, &instlen);
cur += instlen;
icount++;
}
return icount;
#else
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ERROR_LOG("Not compiled with ENABLE_HOST_DISASSEMBLY.");
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return 0;
#endif
}
u32 CPU::CodeCache::EmitASMFunctions(void* code, u32 code_size)
{
using namespace CPU::Recompiler;
using namespace biscuit;
Assembler actual_asm(static_cast<u8*>(code), code_size);
Assembler* rvAsm = &actual_asm;
Label dispatch;
g_enter_recompiler = reinterpret_cast<decltype(g_enter_recompiler)>(rvAsm->GetCursorPointer());
{
// TODO: reserve some space for saving caller-saved registers
// Need the CPU state for basically everything :-)
rvMoveAddressToReg(rvAsm, RSTATE, &g_state);
// Fastmem setup
if (IsUsingFastmem())
rvAsm->LD(RMEMBASE, PTR(&g_state.fastmem_base));
// Downcount isn't set on entry, so we need to initialize it
rvMoveAddressToReg(rvAsm, RARG1, TimingEvents::GetHeadEventPtr());
rvAsm->LD(RARG1, 0, RARG1);
rvAsm->LW(RARG1, OFFSETOF(TimingEvent, m_downcount), RARG1);
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rvAsm->SW(RARG1, PTR(&g_state.downcount));
// Fall through to event dispatcher
}
// check events then for frame done
g_check_events_and_dispatch = rvAsm->GetCursorPointer();
{
Label skip_event_check;
rvAsm->LW(RARG1, PTR(&g_state.pending_ticks));
rvAsm->LW(RARG2, PTR(&g_state.downcount));
rvAsm->BLTU(RARG1, RARG2, &skip_event_check);
g_run_events_and_dispatch = rvAsm->GetCursorPointer();
rvEmitCall(rvAsm, reinterpret_cast<const void*>(&TimingEvents::RunEvents));
rvAsm->Bind(&skip_event_check);
}
// TODO: align?
g_dispatcher = rvAsm->GetCursorPointer();
{
rvAsm->Bind(&dispatch);
// x9 <- s_fast_map[pc >> 16]
rvAsm->LWU(RARG1, PTR(&g_state.pc));
rvMoveAddressToReg(rvAsm, RARG3, g_code_lut.data());
rvAsm->SRLI(RARG2, RARG1, 16);
rvAsm->SLLI(RARG1, RARG1, 1);
rvAsm->SLLI(RARG2, RARG2, 3);
rvAsm->ADD(RARG2, RARG2, RARG3);
rvAsm->LD(RARG2, 0, RARG2);
// blr(x9[pc * 2]) (fast_map[pc >> 2])
rvAsm->ADD(RARG1, RARG1, RARG2);
rvAsm->LD(RARG1, 0, RARG1);
rvAsm->JR(RARG1);
}
g_compile_or_revalidate_block = rvAsm->GetCursorPointer();
{
rvAsm->LW(RARG1, PTR(&g_state.pc));
rvEmitCall(rvAsm, reinterpret_cast<const void*>(&CompileOrRevalidateBlock));
rvAsm->J(&dispatch);
}
g_discard_and_recompile_block = rvAsm->GetCursorPointer();
{
rvAsm->LW(RARG1, PTR(&g_state.pc));
rvEmitCall(rvAsm, reinterpret_cast<const void*>(&DiscardAndRecompileBlock));
rvAsm->J(&dispatch);
}
g_interpret_block = rvAsm->GetCursorPointer();
{
rvEmitCall(rvAsm, CodeCache::GetInterpretUncachedBlockFunction());
rvAsm->J(&dispatch);
}
// TODO: align?
return static_cast<u32>(rvAsm->GetCodeBuffer().GetSizeInBytes());
}
u32 CPU::CodeCache::EmitJump(void* code, const void* dst, bool flush_icache)
{
// TODO: get rid of assembler construction here
{
biscuit::Assembler assembler(static_cast<u8*>(code), BLOCK_LINK_SIZE);
CPU::Recompiler::rvEmitCall(&assembler, dst);
DebugAssert(assembler.GetCodeBuffer().GetSizeInBytes() <= BLOCK_LINK_SIZE);
if (assembler.GetCodeBuffer().GetRemainingBytes() > 0)
assembler.NOP();
}
if (flush_icache)
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MemMap::FlushInstructionCache(code, BLOCK_LINK_SIZE);
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return BLOCK_LINK_SIZE;
}
CPU::NewRec::RISCV64Compiler::RISCV64Compiler() = default;
CPU::NewRec::RISCV64Compiler::~RISCV64Compiler() = default;
const void* CPU::NewRec::RISCV64Compiler::GetCurrentCodePointer()
{
return rvAsm->GetCursorPointer();
}
void CPU::NewRec::RISCV64Compiler::Reset(CodeCache::Block* block, u8* code_buffer, u32 code_buffer_space,
u8* far_code_buffer, u32 far_code_space)
{
Compiler::Reset(block, code_buffer, code_buffer_space, far_code_buffer, far_code_space);
// TODO: don't recreate this every time..
DebugAssert(!m_emitter && !m_far_emitter && !rvAsm);
m_emitter = std::make_unique<Assembler>(code_buffer, code_buffer_space);
m_far_emitter = std::make_unique<Assembler>(far_code_buffer, far_code_space);
rvAsm = m_emitter.get();
// Need to wipe it out so it's correct when toggling fastmem.
m_host_regs = {};
const u32 membase_idx = CodeCache::IsUsingFastmem() ? RMEMBASE.Index() : NUM_HOST_REGS;
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
HostRegAlloc& hra = m_host_regs[i];
if (i == RARG1.Index() || i == RARG2.Index() || i == RARG3.Index() || i == RSCRATCH.Index() ||
i == RSTATE.Index() || i == membase_idx || i < 5 /* zero, ra, sp, gp, tp */)
{
continue;
}
hra.flags = HR_USABLE | (rvIsCallerSavedRegister(i) ? 0 : HR_CALLEE_SAVED);
}
}
void CPU::NewRec::RISCV64Compiler::SwitchToFarCode(
bool emit_jump,
void (biscuit::Assembler::*inverted_cond)(biscuit::GPR, biscuit::GPR, biscuit::Label*) /* = nullptr */,
const biscuit::GPR& rs1 /* = biscuit::zero */, const biscuit::GPR& rs2 /* = biscuit::zero */)
{
DebugAssert(rvAsm == m_emitter.get());
if (emit_jump)
{
const void* target = m_far_emitter->GetCursorPointer();
if (inverted_cond)
{
Label skip;
(rvAsm->*inverted_cond)(rs1, rs2, &skip);
rvEmitJmp(rvAsm, target);
rvAsm->Bind(&skip);
}
else
{
rvEmitCall(rvAsm, target);
}
}
rvAsm = m_far_emitter.get();
}
void CPU::NewRec::RISCV64Compiler::SwitchToNearCode(bool emit_jump)
{
DebugAssert(rvAsm == m_far_emitter.get());
if (emit_jump)
rvEmitJmp(rvAsm, m_emitter->GetCursorPointer());
rvAsm = m_emitter.get();
}
void CPU::NewRec::RISCV64Compiler::EmitMov(const biscuit::GPR& dst, u32 val)
{
rvEmitMov(rvAsm, dst, val);
}
void CPU::NewRec::RISCV64Compiler::EmitCall(const void* ptr)
{
rvEmitCall(rvAsm, ptr);
}
void CPU::NewRec::RISCV64Compiler::SafeImmSExtIType(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm,
void (biscuit::Assembler::*iop)(GPR, GPR, u32),
void (biscuit::Assembler::*rop)(GPR, GPR, GPR))
{
DebugAssert(rd != RSCRATCH && rs != RSCRATCH);
if (rvIsValidSExtITypeImm(imm))
{
(rvAsm->*iop)(rd, rs, imm);
return;
}
rvEmitMov(rvAsm, RSCRATCH, imm);
(rvAsm->*rop)(rd, rs, RSCRATCH);
}
void CPU::NewRec::RISCV64Compiler::SafeADDI(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm)
{
SafeImmSExtIType(rd, rs, imm, reinterpret_cast<void (biscuit::Assembler::*)(GPR, GPR, u32)>(&Assembler::ADDI),
&Assembler::ADD);
}
void CPU::NewRec::RISCV64Compiler::SafeADDIW(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm)
{
SafeImmSExtIType(rd, rs, imm, reinterpret_cast<void (biscuit::Assembler::*)(GPR, GPR, u32)>(&Assembler::ADDIW),
&Assembler::ADDW);
}
void CPU::NewRec::RISCV64Compiler::SafeSUBIW(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm)
{
const u32 nimm = static_cast<u32>(-static_cast<s32>(imm));
SafeImmSExtIType(rd, rs, nimm, reinterpret_cast<void (biscuit::Assembler::*)(GPR, GPR, u32)>(&Assembler::ADDIW),
&Assembler::ADDW);
}
void CPU::NewRec::RISCV64Compiler::SafeANDI(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm)
{
SafeImmSExtIType(rd, rs, imm, &Assembler::ANDI, &Assembler::AND);
}
void CPU::NewRec::RISCV64Compiler::SafeORI(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm)
{
SafeImmSExtIType(rd, rs, imm, &Assembler::ORI, &Assembler::OR);
}
void CPU::NewRec::RISCV64Compiler::SafeXORI(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm)
{
SafeImmSExtIType(rd, rs, imm, &Assembler::XORI, &Assembler::XOR);
}
void CPU::NewRec::RISCV64Compiler::SafeSLTI(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm)
{
SafeImmSExtIType(rd, rs, imm, reinterpret_cast<void (biscuit::Assembler::*)(GPR, GPR, u32)>(&Assembler::SLTI),
&Assembler::SLT);
}
void CPU::NewRec::RISCV64Compiler::SafeSLTIU(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm)
{
SafeImmSExtIType(rd, rs, imm, reinterpret_cast<void (biscuit::Assembler::*)(GPR, GPR, u32)>(&Assembler::SLTIU),
&Assembler::SLTU);
}
void CPU::NewRec::RISCV64Compiler::EmitSExtB(const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvEmitSExtB(rvAsm, rd, rs);
}
void CPU::NewRec::RISCV64Compiler::EmitUExtB(const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvEmitUExtB(rvAsm, rd, rs);
}
void CPU::NewRec::RISCV64Compiler::EmitSExtH(const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvEmitSExtH(rvAsm, rd, rs);
}
void CPU::NewRec::RISCV64Compiler::EmitUExtH(const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvEmitUExtH(rvAsm, rd, rs);
}
void CPU::NewRec::RISCV64Compiler::EmitDSExtW(const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvEmitDSExtW(rvAsm, rd, rs);
}
void CPU::NewRec::RISCV64Compiler::EmitDUExtW(const biscuit::GPR& rd, const biscuit::GPR& rs)
{
rvEmitDUExtW(rvAsm, rd, rs);
}
void CPU::NewRec::RISCV64Compiler::GenerateBlockProtectCheck(const u8* ram_ptr, const u8* shadow_ptr, u32 size)
{
// store it first to reduce code size, because we can offset
// TODO: 64-bit displacement is needed :/
// rvMoveAddressToReg(rvAsm, RARG1, ram_ptr);
// rvMoveAddressToReg(rvAsm, RARG2, shadow_ptr);
rvEmitMov64(rvAsm, RARG1, RSCRATCH, static_cast<u64>(reinterpret_cast<uintptr_t>(ram_ptr)));
rvEmitMov64(rvAsm, RARG2, RSCRATCH, static_cast<u64>(reinterpret_cast<uintptr_t>(shadow_ptr)));
u32 offset = 0;
Label block_changed;
while (size >= 8)
{
rvAsm->LD(RARG3, offset, RARG1);
rvAsm->LD(RSCRATCH, offset, RARG2);
rvAsm->BNE(RARG3, RSCRATCH, &block_changed);
offset += 8;
size -= 8;
}
while (size >= 4)
{
rvAsm->LWU(RARG3, offset, RARG1);
rvAsm->LWU(RSCRATCH, offset, RARG2);
rvAsm->BNE(RARG3, RSCRATCH, &block_changed);
offset += 4;
size -= 4;
}
DebugAssert(size == 0);
Label block_unchanged;
rvAsm->J(&block_unchanged);
rvAsm->Bind(&block_changed);
rvEmitJmp(rvAsm, CodeCache::g_discard_and_recompile_block);
rvAsm->Bind(&block_unchanged);
}
void CPU::NewRec::RISCV64Compiler::GenerateICacheCheckAndUpdate()
{
if (!m_block->HasFlag(CodeCache::BlockFlags::IsUsingICache))
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{
if (m_block->HasFlag(CodeCache::BlockFlags::NeedsDynamicFetchTicks))
{
rvEmitFarLoad(rvAsm, RARG2, GetFetchMemoryAccessTimePtr());
rvAsm->LW(RARG1, PTR(&g_state.pending_ticks));
rvEmitMov(rvAsm, RARG3, m_block->size);
rvAsm->MULW(RARG2, RARG2, RARG3);
rvAsm->ADD(RARG1, RARG1, RARG2);
rvAsm->SW(RARG1, PTR(&g_state.pending_ticks));
}
else
{
rvAsm->LW(RARG1, PTR(&g_state.pending_ticks));
SafeADDIW(RARG1, RARG1, static_cast<u32>(m_block->uncached_fetch_ticks));
rvAsm->SW(RARG1, PTR(&g_state.pending_ticks));
}
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}
else if (m_block->icache_line_count > 0)
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{
const auto& ticks_reg = RARG1;
const auto& current_tag_reg = RARG2;
const auto& existing_tag_reg = RARG3;
VirtualMemoryAddress current_pc = m_block->pc & ICACHE_TAG_ADDRESS_MASK;
rvAsm->LW(ticks_reg, PTR(&g_state.pending_ticks));
rvEmitMov(rvAsm, current_tag_reg, current_pc);
for (u32 i = 0; i < m_block->icache_line_count; i++, current_pc += ICACHE_LINE_SIZE)
{
const TickCount fill_ticks = GetICacheFillTicks(current_pc);
if (fill_ticks <= 0)
continue;
const u32 line = GetICacheLine(current_pc);
const u32 offset = OFFSETOF(State, icache_tags) + (line * sizeof(u32));
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// TODO: Verify sign extension here...
Label cache_hit;
rvAsm->LW(existing_tag_reg, offset, RSTATE);
rvAsm->BEQ(existing_tag_reg, current_tag_reg, &cache_hit);
rvAsm->SW(current_tag_reg, offset, RSTATE);
SafeADDIW(ticks_reg, ticks_reg, static_cast<u32>(fill_ticks));
rvAsm->Bind(&cache_hit);
if (i != (m_block->icache_line_count - 1))
SafeADDIW(current_tag_reg, current_tag_reg, ICACHE_LINE_SIZE);
}
rvAsm->SW(ticks_reg, PTR(&g_state.pending_ticks));
}
}
void CPU::NewRec::RISCV64Compiler::GenerateCall(const void* func, s32 arg1reg /*= -1*/, s32 arg2reg /*= -1*/,
s32 arg3reg /*= -1*/)
{
if (arg1reg >= 0 && arg1reg != static_cast<s32>(RARG1.Index()))
rvAsm->MV(RARG1, GPR(arg1reg));
if (arg2reg >= 0 && arg2reg != static_cast<s32>(RARG2.Index()))
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rvAsm->MV(RARG2, GPR(arg2reg));
if (arg3reg >= 0 && arg3reg != static_cast<s32>(RARG3.Index()))
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rvAsm->MV(RARG3, GPR(arg3reg));
EmitCall(func);
}
void CPU::NewRec::RISCV64Compiler::EndBlock(const std::optional<u32>& newpc, bool do_event_test)
{
if (newpc.has_value())
{
if (m_dirty_pc || m_compiler_pc != newpc)
{
EmitMov(RSCRATCH, newpc.value());
rvAsm->SW(RSCRATCH, PTR(&g_state.pc));
}
}
m_dirty_pc = false;
// flush regs
Flush(FLUSH_END_BLOCK);
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EndAndLinkBlock(newpc, do_event_test, false);
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}
void CPU::NewRec::RISCV64Compiler::EndBlockWithException(Exception excode)
{
// flush regs, but not pc, it's going to get overwritten
// flush cycles because of the GTE instruction stuff...
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Flush(FLUSH_END_BLOCK | FLUSH_FOR_EXCEPTION | FLUSH_FOR_C_CALL);
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// TODO: flush load delay
// TODO: break for pcdrv
EmitMov(RARG1, Cop0Registers::CAUSE::MakeValueForException(excode, m_current_instruction_branch_delay_slot, false,
inst->cop.cop_n));
EmitMov(RARG2, m_current_instruction_pc);
EmitCall(reinterpret_cast<const void*>(static_cast<void (*)(u32, u32)>(&CPU::RaiseException)));
m_dirty_pc = false;
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EndAndLinkBlock(std::nullopt, true, false);
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}
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void CPU::NewRec::RISCV64Compiler::EndAndLinkBlock(const std::optional<u32>& newpc, bool do_event_test,
bool force_run_events)
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{
// event test
// pc should've been flushed
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DebugAssert(!m_dirty_pc && !m_block_ended);
m_block_ended = true;
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// TODO: try extracting this to a function
// TODO: move the cycle flush in here..
// save cycles for event test
const TickCount cycles = std::exchange(m_cycles, 0);
// pending_ticks += cycles
// if (pending_ticks >= downcount) { dispatch_event(); }
if (do_event_test || m_gte_done_cycle > cycles || cycles > 0)
rvAsm->LW(RARG1, PTR(&g_state.pending_ticks));
if (do_event_test)
rvAsm->LW(RARG2, PTR(&g_state.downcount));
if (cycles > 0)
{
SafeADDIW(RARG1, RARG1, cycles);
rvAsm->SW(RARG1, PTR(&g_state.pending_ticks));
}
if (m_gte_done_cycle > cycles)
{
SafeADDIW(RARG2, RARG1, m_gte_done_cycle - cycles);
rvAsm->SW(RARG1, PTR(&g_state.gte_completion_tick));
}
if (do_event_test)
{
// TODO: see if we can do a far jump somehow with this..
Label cont;
rvAsm->BLT(RARG1, RARG2, &cont);
rvEmitJmp(rvAsm, CodeCache::g_run_events_and_dispatch);
rvAsm->Bind(&cont);
}
// jump to dispatcher or next block
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if (force_run_events)
{
rvEmitJmp(rvAsm, CodeCache::g_run_events_and_dispatch);
}
else if (!newpc.has_value())
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{
rvEmitJmp(rvAsm, CodeCache::g_dispatcher);
}
else
{
if (newpc.value() == m_block->pc)
{
// Special case: ourselves! No need to backlink then.
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DEBUG_LOG("Linking block at {:08X} to self", m_block->pc);
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rvEmitJmp(rvAsm, rvAsm->GetBufferPointer(0));
}
else
{
const void* target = CreateBlockLink(m_block, rvAsm->GetCursorPointer(), newpc.value());
rvEmitJmp(rvAsm, target);
}
}
}
const void* CPU::NewRec::RISCV64Compiler::EndCompile(u32* code_size, u32* far_code_size)
{
u8* const code = m_emitter->GetBufferPointer(0);
*code_size = static_cast<u32>(m_emitter->GetCodeBuffer().GetSizeInBytes());
*far_code_size = static_cast<u32>(m_far_emitter->GetCodeBuffer().GetSizeInBytes());
rvAsm = nullptr;
m_far_emitter.reset();
m_emitter.reset();
return code;
}
const char* CPU::NewRec::RISCV64Compiler::GetHostRegName(u32 reg) const
{
static constexpr std::array<const char*, 32> reg64_names = {
{"zero", "ra", "sp", "gp", "tp", "t0", "t1", "t2", "s0", "s1", "a0", "a1", "a2", "a3", "a4", "a5",
"a6", "a7", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "t3", "t4", "t5", "t6"}};
return (reg < reg64_names.size()) ? reg64_names[reg] : "UNKNOWN";
}
void CPU::NewRec::RISCV64Compiler::LoadHostRegWithConstant(u32 reg, u32 val)
{
EmitMov(GPR(reg), val);
}
void CPU::NewRec::RISCV64Compiler::LoadHostRegFromCPUPointer(u32 reg, const void* ptr)
{
rvAsm->LW(GPR(reg), PTR(ptr));
}
void CPU::NewRec::RISCV64Compiler::StoreHostRegToCPUPointer(u32 reg, const void* ptr)
{
rvAsm->SW(GPR(reg), PTR(ptr));
}
void CPU::NewRec::RISCV64Compiler::StoreConstantToCPUPointer(u32 val, const void* ptr)
{
if (val == 0)
{
rvAsm->SW(zero, PTR(ptr));
return;
}
EmitMov(RSCRATCH, val);
rvAsm->SW(RSCRATCH, PTR(ptr));
}
void CPU::NewRec::RISCV64Compiler::CopyHostReg(u32 dst, u32 src)
{
if (src != dst)
rvAsm->MV(GPR(dst), GPR(src));
}
void CPU::NewRec::RISCV64Compiler::AssertRegOrConstS(CompileFlags cf) const
{
DebugAssert(cf.valid_host_s || cf.const_s);
}
void CPU::NewRec::RISCV64Compiler::AssertRegOrConstT(CompileFlags cf) const
{
DebugAssert(cf.valid_host_t || cf.const_t);
}
biscuit::GPR CPU::NewRec::RISCV64Compiler::CFGetSafeRegS(CompileFlags cf, const biscuit::GPR& temp_reg)
{
if (cf.valid_host_s)
{
return GPR(cf.host_s);
}
else if (cf.const_s)
{
if (HasConstantRegValue(cf.MipsS(), 0))
return zero;
EmitMov(temp_reg, GetConstantRegU32(cf.MipsS()));
return temp_reg;
}
else
{
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WARNING_LOG("Hit memory path in CFGetSafeRegS() for {}", GetRegName(cf.MipsS()));
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rvAsm->LW(temp_reg, PTR(&g_state.regs.r[cf.mips_s]));
return temp_reg;
}
}
biscuit::GPR CPU::NewRec::RISCV64Compiler::CFGetSafeRegT(CompileFlags cf, const biscuit::GPR& temp_reg)
{
if (cf.valid_host_t)
{
return GPR(cf.host_t);
}
else if (cf.const_t)
{
if (HasConstantRegValue(cf.MipsT(), 0))
return zero;
EmitMov(temp_reg, GetConstantRegU32(cf.MipsT()));
return temp_reg;
}
else
{
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WARNING_LOG("Hit memory path in CFGetSafeRegT() for {}", GetRegName(cf.MipsT()));
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rvAsm->LW(temp_reg, PTR(&g_state.regs.r[cf.mips_t]));
return temp_reg;
}
}
biscuit::GPR CPU::NewRec::RISCV64Compiler::CFGetRegD(CompileFlags cf) const
{
DebugAssert(cf.valid_host_d);
return GPR(cf.host_d);
}
biscuit::GPR CPU::NewRec::RISCV64Compiler::CFGetRegS(CompileFlags cf) const
{
DebugAssert(cf.valid_host_s);
return GPR(cf.host_s);
}
biscuit::GPR CPU::NewRec::RISCV64Compiler::CFGetRegT(CompileFlags cf) const
{
DebugAssert(cf.valid_host_t);
return GPR(cf.host_t);
}
biscuit::GPR CPU::NewRec::RISCV64Compiler::CFGetRegLO(CompileFlags cf) const
{
DebugAssert(cf.valid_host_lo);
return GPR(cf.host_lo);
}
biscuit::GPR CPU::NewRec::RISCV64Compiler::CFGetRegHI(CompileFlags cf) const
{
DebugAssert(cf.valid_host_hi);
return GPR(cf.host_hi);
}
void CPU::NewRec::RISCV64Compiler::MoveSToReg(const biscuit::GPR& dst, CompileFlags cf)
{
if (cf.valid_host_s)
{
if (cf.host_s != dst.Index())
rvAsm->MV(dst, GPR(cf.host_s));
}
else if (cf.const_s)
{
EmitMov(dst, GetConstantRegU32(cf.MipsS()));
}
else
{
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WARNING_LOG("Hit memory path in MoveSToReg() for {}", GetRegName(cf.MipsS()));
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rvAsm->LW(dst, PTR(&g_state.regs.r[cf.mips_s]));
}
}
void CPU::NewRec::RISCV64Compiler::MoveTToReg(const biscuit::GPR& dst, CompileFlags cf)
{
if (cf.valid_host_t)
{
if (cf.host_t != dst.Index())
rvAsm->MV(dst, GPR(cf.host_t));
}
else if (cf.const_t)
{
EmitMov(dst, GetConstantRegU32(cf.MipsT()));
}
else
{
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WARNING_LOG("Hit memory path in MoveTToReg() for {}", GetRegName(cf.MipsT()));
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rvAsm->LW(dst, PTR(&g_state.regs.r[cf.mips_t]));
}
}
void CPU::NewRec::RISCV64Compiler::MoveMIPSRegToReg(const biscuit::GPR& dst, Reg reg)
{
DebugAssert(reg < Reg::count);
if (const std::optional<u32> hreg = CheckHostReg(0, Compiler::HR_TYPE_CPU_REG, reg))
rvAsm->MV(dst, GPR(hreg.value()));
else if (HasConstantReg(reg))
EmitMov(dst, GetConstantRegU32(reg));
else
rvAsm->LW(dst, PTR(&g_state.regs.r[static_cast<u8>(reg)]));
}
void CPU::NewRec::RISCV64Compiler::GeneratePGXPCallWithMIPSRegs(const void* func, u32 arg1val,
Reg arg2reg /* = Reg::count */,
Reg arg3reg /* = Reg::count */)
{
DebugAssert(g_settings.gpu_pgxp_enable);
Flush(FLUSH_FOR_C_CALL);
if (arg2reg != Reg::count)
MoveMIPSRegToReg(RARG2, arg2reg);
if (arg3reg != Reg::count)
MoveMIPSRegToReg(RARG3, arg3reg);
EmitMov(RARG1, arg1val);
EmitCall(func);
}
void CPU::NewRec::RISCV64Compiler::Flush(u32 flags)
{
Compiler::Flush(flags);
if (flags & FLUSH_PC && m_dirty_pc)
{
StoreConstantToCPUPointer(m_compiler_pc, &g_state.pc);
m_dirty_pc = false;
}
if (flags & FLUSH_INSTRUCTION_BITS)
{
// This sucks, but it's only used for fallbacks.
Panic("Not implemented");
}
if (flags & FLUSH_LOAD_DELAY_FROM_STATE && m_load_delay_dirty)
{
// This sucks :(
// TODO: make it a function?
rvAsm->LBU(RARG1, PTR(&g_state.load_delay_reg));
rvAsm->LW(RARG2, PTR(&g_state.load_delay_value));
rvAsm->SLLI(RARG1, RARG1, 2); // *4
rvAsm->ADD(RARG1, RARG1, RSTATE);
rvAsm->SW(RARG2, OFFSETOF(CPU::State, regs.r[0]), RARG1);
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rvAsm->LI(RSCRATCH, static_cast<u8>(Reg::count));
rvAsm->SB(RSCRATCH, PTR(&g_state.load_delay_reg));
m_load_delay_dirty = false;
}
if (flags & FLUSH_LOAD_DELAY && m_load_delay_register != Reg::count)
{
if (m_load_delay_value_register != NUM_HOST_REGS)
FreeHostReg(m_load_delay_value_register);
EmitMov(RSCRATCH, static_cast<u8>(m_load_delay_register));
rvAsm->SB(RSCRATCH, PTR(&g_state.load_delay_reg));
m_load_delay_register = Reg::count;
m_load_delay_dirty = true;
}
if (flags & FLUSH_GTE_STALL_FROM_STATE && m_dirty_gte_done_cycle)
{
// May as well flush cycles while we're here.
// GTE spanning blocks is very rare, we _could_ disable this for speed.
rvAsm->LW(RARG1, PTR(&g_state.pending_ticks));
rvAsm->LW(RARG2, PTR(&g_state.gte_completion_tick));
if (m_cycles > 0)
{
SafeADDIW(RARG1, RARG1, m_cycles);
m_cycles = 0;
}
Label no_stall;
rvAsm->BGE(RARG1, RARG2, &no_stall);
rvAsm->MV(RARG1, RARG2);
rvAsm->Bind(&no_stall);
rvAsm->SW(RARG1, PTR(&g_state.pending_ticks));
m_dirty_gte_done_cycle = false;
}
if (flags & FLUSH_GTE_DONE_CYCLE && m_gte_done_cycle > m_cycles)
{
rvAsm->LW(RARG1, PTR(&g_state.pending_ticks));
// update cycles at the same time
if (flags & FLUSH_CYCLES && m_cycles > 0)
{
SafeADDIW(RARG1, RARG1, m_cycles);
rvAsm->SW(RARG1, PTR(&g_state.pending_ticks));
m_gte_done_cycle -= m_cycles;
m_cycles = 0;
}
SafeADDIW(RARG1, RARG1, m_gte_done_cycle);
rvAsm->SW(RARG1, PTR(&g_state.gte_completion_tick));
m_gte_done_cycle = 0;
m_dirty_gte_done_cycle = true;
}
if (flags & FLUSH_CYCLES && m_cycles > 0)
{
rvAsm->LW(RARG1, PTR(&g_state.pending_ticks));
SafeADDIW(RARG1, RARG1, m_cycles);
rvAsm->SW(RARG1, PTR(&g_state.pending_ticks));
m_gte_done_cycle = std::max<TickCount>(m_gte_done_cycle - m_cycles, 0);
m_cycles = 0;
}
}
void CPU::NewRec::RISCV64Compiler::Compile_Fallback()
{
WARNING_LOG("Compiling instruction fallback at PC=0x{:08X}, instruction=0x{:08X}", iinfo->pc, inst->bits);
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Flush(FLUSH_FOR_INTERPRETER);
#if 0
cg->call(&CPU::Recompiler::Thunks::InterpretInstruction);
// TODO: make me less garbage
// TODO: this is wrong, it flushes the load delay on the same cycle when we return.
// but nothing should be going through here..
Label no_load_delay;
cg->movzx(RWARG1, cg->byte[PTR(&g_state.next_load_delay_reg)]);
cg->cmp(RWARG1, static_cast<u8>(Reg::count));
cg->je(no_load_delay, CodeGenerator::T_SHORT);
cg->mov(RWARG2, cg->dword[PTR(&g_state.next_load_delay_value)]);
cg->mov(cg->byte[PTR(&g_state.load_delay_reg)], RWARG1);
cg->mov(cg->dword[PTR(&g_state.load_delay_value)], RWARG2);
cg->mov(cg->byte[PTR(&g_state.next_load_delay_reg)], static_cast<u32>(Reg::count));
cg->L(no_load_delay);
m_load_delay_dirty = EMULATE_LOAD_DELAYS;
#else
Panic("Fixme");
#endif
}
void CPU::NewRec::RISCV64Compiler::CheckBranchTarget(const biscuit::GPR& pcreg)
{
if (!g_settings.cpu_recompiler_memory_exceptions)
return;
DebugAssert(pcreg != RSCRATCH);
rvAsm->ANDI(RSCRATCH, pcreg, 0x3);
SwitchToFarCode(true, &Assembler::BEQ, RSCRATCH, zero);
BackupHostState();
EndBlockWithException(Exception::AdEL);
RestoreHostState();
SwitchToNearCode(false);
}
void CPU::NewRec::RISCV64Compiler::Compile_jr(CompileFlags cf)
{
const GPR pcreg = CFGetRegS(cf);
CheckBranchTarget(pcreg);
rvAsm->SW(pcreg, PTR(&g_state.pc));
CompileBranchDelaySlot(false);
EndBlock(std::nullopt, true);
}
void CPU::NewRec::RISCV64Compiler::Compile_jalr(CompileFlags cf)
{
const GPR pcreg = CFGetRegS(cf);
if (MipsD() != Reg::zero)
SetConstantReg(MipsD(), GetBranchReturnAddress(cf));
CheckBranchTarget(pcreg);
rvAsm->SW(pcreg, PTR(&g_state.pc));
CompileBranchDelaySlot(false);
EndBlock(std::nullopt, true);
}
void CPU::NewRec::RISCV64Compiler::Compile_bxx(CompileFlags cf, BranchCondition cond)
{
AssertRegOrConstS(cf);
const u32 taken_pc = GetConditionalBranchTarget(cf);
Flush(FLUSH_FOR_BRANCH);
DebugAssert(cf.valid_host_s);
// MipsT() here should equal zero for zero branches.
DebugAssert(cond == BranchCondition::Equal || cond == BranchCondition::NotEqual || cf.MipsT() == Reg::zero);
Label taken;
const GPR rs = CFGetRegS(cf);
switch (cond)
{
case BranchCondition::Equal:
case BranchCondition::NotEqual:
{
AssertRegOrConstT(cf);
if (cf.const_t && HasConstantRegValue(cf.MipsT(), 0))
{
(cond == BranchCondition::Equal) ? rvAsm->BEQZ(rs, &taken) : rvAsm->BNEZ(rs, &taken);
}
else
{
const GPR rt = cf.valid_host_t ? CFGetRegT(cf) : RARG1;
if (!cf.valid_host_t)
MoveTToReg(RARG1, cf);
if (cond == Compiler::BranchCondition::Equal)
rvAsm->BEQ(rs, rt, &taken);
else
rvAsm->BNE(rs, rt, &taken);
}
}
break;
case BranchCondition::GreaterThanZero:
{
rvAsm->BGTZ(rs, &taken);
}
break;
case BranchCondition::GreaterEqualZero:
{
rvAsm->BGEZ(rs, &taken);
}
break;
case BranchCondition::LessThanZero:
{
rvAsm->BLTZ(rs, &taken);
}
break;
case BranchCondition::LessEqualZero:
{
rvAsm->BLEZ(rs, &taken);
}
break;
}
BackupHostState();
if (!cf.delay_slot_swapped)
CompileBranchDelaySlot();
EndBlock(m_compiler_pc, true);
rvAsm->Bind(&taken);
RestoreHostState();
if (!cf.delay_slot_swapped)
CompileBranchDelaySlot();
EndBlock(taken_pc, true);
}
void CPU::NewRec::RISCV64Compiler::Compile_addi(CompileFlags cf, bool overflow)
{
const GPR rs = CFGetRegS(cf);
const GPR rt = CFGetRegT(cf);
if (const u32 imm = inst->i.imm_sext32(); imm != 0)
{
if (!overflow)
{
SafeADDIW(rt, rs, imm);
}
else
{
SafeADDI(RARG1, rs, imm);
SafeADDIW(rt, rs, imm);
TestOverflow(RARG1, rt, rt);
}
}
else if (rt.Index() != rs.Index())
{
rvAsm->MV(rt, rs);
}
}
void CPU::NewRec::RISCV64Compiler::Compile_addi(CompileFlags cf)
{
Compile_addi(cf, g_settings.cpu_recompiler_memory_exceptions);
}
void CPU::NewRec::RISCV64Compiler::Compile_addiu(CompileFlags cf)
{
Compile_addi(cf, false);
}
void CPU::NewRec::RISCV64Compiler::Compile_slti(CompileFlags cf)
{
Compile_slti(cf, true);
}
void CPU::NewRec::RISCV64Compiler::Compile_sltiu(CompileFlags cf)
{
Compile_slti(cf, false);
}
void CPU::NewRec::RISCV64Compiler::Compile_slti(CompileFlags cf, bool sign)
{
if (sign)
SafeSLTI(CFGetRegT(cf), CFGetRegS(cf), inst->i.imm_sext32());
else
SafeSLTIU(CFGetRegT(cf), CFGetRegS(cf), inst->i.imm_sext32());
}
void CPU::NewRec::RISCV64Compiler::Compile_andi(CompileFlags cf)
{
const GPR rt = CFGetRegT(cf);
if (const u32 imm = inst->i.imm_zext32(); imm != 0)
SafeANDI(rt, CFGetRegS(cf), imm);
else
EmitMov(rt, 0);
}
void CPU::NewRec::RISCV64Compiler::Compile_ori(CompileFlags cf)
{
const GPR rt = CFGetRegT(cf);
const GPR rs = CFGetRegS(cf);
if (const u32 imm = inst->i.imm_zext32(); imm != 0)
SafeORI(rt, rs, imm);
else if (rt.Index() != rs.Index())
rvAsm->MV(rt, rs);
}
void CPU::NewRec::RISCV64Compiler::Compile_xori(CompileFlags cf)
{
const GPR rt = CFGetRegT(cf);
const GPR rs = CFGetRegS(cf);
if (const u32 imm = inst->i.imm_zext32(); imm != 0)
SafeXORI(rt, rs, imm);
else if (rt.Index() != rs.Index())
rvAsm->MV(rt, rs);
}
void CPU::NewRec::RISCV64Compiler::Compile_shift(
CompileFlags cf, void (biscuit::Assembler::*op)(biscuit::GPR, biscuit::GPR, biscuit::GPR),
void (biscuit::Assembler::*op_const)(biscuit::GPR, biscuit::GPR, unsigned))
{
const GPR rd = CFGetRegD(cf);
const GPR rt = CFGetRegT(cf);
if (inst->r.shamt > 0)
(rvAsm->*op_const)(rd, rt, inst->r.shamt);
else if (rd.Index() != rt.Index())
rvAsm->MV(rd, rt);
}
void CPU::NewRec::RISCV64Compiler::Compile_sll(CompileFlags cf)
{
Compile_shift(cf, &Assembler::SLLW, &Assembler::SLLIW);
}
void CPU::NewRec::RISCV64Compiler::Compile_srl(CompileFlags cf)
{
Compile_shift(cf, &Assembler::SRLW, &Assembler::SRLIW);
}
void CPU::NewRec::RISCV64Compiler::Compile_sra(CompileFlags cf)
{
Compile_shift(cf, &Assembler::SRAW, &Assembler::SRAIW);
}
void CPU::NewRec::RISCV64Compiler::Compile_variable_shift(
CompileFlags cf, void (biscuit::Assembler::*op)(biscuit::GPR, biscuit::GPR, biscuit::GPR),
void (biscuit::Assembler::*op_const)(biscuit::GPR, biscuit::GPR, unsigned))
{
const GPR rd = CFGetRegD(cf);
AssertRegOrConstS(cf);
AssertRegOrConstT(cf);
const GPR rt = cf.valid_host_t ? CFGetRegT(cf) : RARG2;
if (!cf.valid_host_t)
MoveTToReg(rt, cf);
if (cf.const_s)
{
if (const u32 shift = GetConstantRegU32(cf.MipsS()); shift != 0)
(rvAsm->*op_const)(rd, rt, shift & 31u);
else if (rd.Index() != rt.Index())
rvAsm->MV(rd, rt);
}
else
{
(rvAsm->*op)(rd, rt, CFGetRegS(cf));
}
}
void CPU::NewRec::RISCV64Compiler::Compile_sllv(CompileFlags cf)
{
Compile_variable_shift(cf, &Assembler::SLLW, &Assembler::SLLIW);
}
void CPU::NewRec::RISCV64Compiler::Compile_srlv(CompileFlags cf)
{
Compile_variable_shift(cf, &Assembler::SRLW, &Assembler::SRLIW);
}
void CPU::NewRec::RISCV64Compiler::Compile_srav(CompileFlags cf)
{
Compile_variable_shift(cf, &Assembler::SRAW, &Assembler::SRAIW);
}
void CPU::NewRec::RISCV64Compiler::Compile_mult(CompileFlags cf, bool sign)
{
const GPR rs = cf.valid_host_s ? CFGetRegS(cf) : RARG1;
if (!cf.valid_host_s)
MoveSToReg(rs, cf);
const GPR rt = cf.valid_host_t ? CFGetRegT(cf) : RARG2;
if (!cf.valid_host_t)
MoveTToReg(rt, cf);
// TODO: if lo/hi gets killed, we can use a 32-bit multiply
const GPR lo = CFGetRegLO(cf);
const GPR hi = CFGetRegHI(cf);
if (sign)
{
rvAsm->MUL(lo, rs, rt);
rvAsm->SRAI64(hi, lo, 32);
EmitDSExtW(lo, lo);
}
else
{
// Need to make it unsigned.
EmitDUExtW(RARG1, rs);
EmitDUExtW(RARG2, rt);
rvAsm->MUL(lo, RARG1, RARG2);
rvAsm->SRAI64(hi, lo, 32);
EmitDSExtW(lo, lo);
}
}
void CPU::NewRec::RISCV64Compiler::Compile_mult(CompileFlags cf)
{
Compile_mult(cf, true);
}
void CPU::NewRec::RISCV64Compiler::Compile_multu(CompileFlags cf)
{
Compile_mult(cf, false);
}
void CPU::NewRec::RISCV64Compiler::Compile_div(CompileFlags cf)
{
// 36 Volume I: RISC-V User-Level ISA V2.2
const GPR rs = cf.valid_host_s ? CFGetRegS(cf) : RARG1;
if (!cf.valid_host_s)
MoveSToReg(rs, cf);
const GPR rt = cf.valid_host_t ? CFGetRegT(cf) : RARG2;
if (!cf.valid_host_t)
MoveTToReg(rt, cf);
const GPR rlo = CFGetRegLO(cf);
const GPR rhi = CFGetRegHI(cf);
Label done;
Label not_divide_by_zero;
rvAsm->BNEZ(rt, &not_divide_by_zero);
rvAsm->MV(rhi, rs); // hi = num
rvAsm->SRAI64(rlo, rs, 63);
rvAsm->ANDI(rlo, rlo, 2);
rvAsm->ADDI(rlo, rlo, -1); // lo = s >= 0 ? -1 : 1
rvAsm->J(&done);
rvAsm->Bind(&not_divide_by_zero);
Label not_unrepresentable;
EmitMov(RSCRATCH, static_cast<u32>(-1));
rvAsm->BNE(rt, RSCRATCH, &not_unrepresentable);
EmitMov(rlo, 0x80000000u);
rvAsm->BNE(rs, rlo, &not_unrepresentable);
EmitMov(rhi, 0);
rvAsm->J(&done);
rvAsm->Bind(&not_unrepresentable);
rvAsm->DIVW(rlo, rs, rt);
rvAsm->REMW(rhi, rs, rt);
rvAsm->Bind(&done);
}
void CPU::NewRec::RISCV64Compiler::Compile_divu(CompileFlags cf)
{
const GPR rs = cf.valid_host_s ? CFGetRegS(cf) : RARG1;
if (!cf.valid_host_s)
MoveSToReg(rs, cf);
const GPR rt = cf.valid_host_t ? CFGetRegT(cf) : RARG2;
if (!cf.valid_host_t)
MoveTToReg(rt, cf);
const GPR rlo = CFGetRegLO(cf);
const GPR rhi = CFGetRegHI(cf);
// Semantics match? :-)
rvAsm->DIVUW(rlo, rs, rt);
rvAsm->REMUW(rhi, rs, rt);
}
void CPU::NewRec::RISCV64Compiler::TestOverflow(const biscuit::GPR& long_res, const biscuit::GPR& res,
const biscuit::GPR& reg_to_discard)
{
SwitchToFarCode(true, &Assembler::BEQ, long_res, res);
BackupHostState();
// toss the result
ClearHostReg(reg_to_discard.Index());
EndBlockWithException(Exception::Ov);
RestoreHostState();
SwitchToNearCode(false);
}
void CPU::NewRec::RISCV64Compiler::Compile_dst_op(
CompileFlags cf, void (biscuit::Assembler::*op)(biscuit::GPR, biscuit::GPR, biscuit::GPR),
void (RISCV64Compiler::*op_const)(const biscuit::GPR& rd, const biscuit::GPR& rs, u32 imm),
void (biscuit::Assembler::*op_long)(biscuit::GPR, biscuit::GPR, biscuit::GPR), bool commutative, bool overflow)
{
AssertRegOrConstS(cf);
AssertRegOrConstT(cf);
const GPR rd = CFGetRegD(cf);
if (overflow)
{
const GPR rs = CFGetSafeRegS(cf, RARG1);
const GPR rt = CFGetSafeRegT(cf, RARG2);
(rvAsm->*op)(RARG3, rs, rt);
(rvAsm->*op_long)(rd, rs, rt);
TestOverflow(RARG3, rd, rd);
return;
}
if (cf.valid_host_s && cf.valid_host_t)
{
(rvAsm->*op)(rd, CFGetRegS(cf), CFGetRegT(cf));
}
else if (commutative && (cf.const_s || cf.const_t))
{
const GPR src = cf.const_s ? CFGetRegT(cf) : CFGetRegS(cf);
if (const u32 cv = GetConstantRegU32(cf.const_s ? cf.MipsS() : cf.MipsT()); cv != 0)
{
(this->*op_const)(rd, src, cv);
}
else
{
if (rd.Index() != src.Index())
rvAsm->MV(rd, src);
overflow = false;
}
}
else if (cf.const_s)
{
if (HasConstantRegValue(cf.MipsS(), 0))
{
(rvAsm->*op)(rd, zero, CFGetRegT(cf));
}
else
{
EmitMov(RSCRATCH, GetConstantRegU32(cf.MipsS()));
(rvAsm->*op)(rd, RSCRATCH, CFGetRegT(cf));
}
}
else if (cf.const_t)
{
const GPR rs = CFGetRegS(cf);
if (const u32 cv = GetConstantRegU32(cf.const_s ? cf.MipsS() : cf.MipsT()); cv != 0)
{
(this->*op_const)(rd, rs, cv);
}
else
{
if (rd.Index() != rs.Index())
rvAsm->MV(rd, rs);
overflow = false;
}
}
}
void CPU::NewRec::RISCV64Compiler::Compile_add(CompileFlags cf)
{
Compile_dst_op(cf, &Assembler::ADDW, &RISCV64Compiler::SafeADDIW, &Assembler::ADD, true,
g_settings.cpu_recompiler_memory_exceptions);
}
void CPU::NewRec::RISCV64Compiler::Compile_addu(CompileFlags cf)
{
Compile_dst_op(cf, &Assembler::ADDW, &RISCV64Compiler::SafeADDIW, &Assembler::ADD, true, false);
}
void CPU::NewRec::RISCV64Compiler::Compile_sub(CompileFlags cf)
{
Compile_dst_op(cf, &Assembler::SUBW, &RISCV64Compiler::SafeSUBIW, &Assembler::SUB, false,
g_settings.cpu_recompiler_memory_exceptions);
}
void CPU::NewRec::RISCV64Compiler::Compile_subu(CompileFlags cf)
{
Compile_dst_op(cf, &Assembler::SUBW, &RISCV64Compiler::SafeSUBIW, &Assembler::SUB, false, false);
}
void CPU::NewRec::RISCV64Compiler::Compile_and(CompileFlags cf)
{
AssertRegOrConstS(cf);
AssertRegOrConstT(cf);
// special cases - and with self -> self, and with 0 -> 0
const GPR regd = CFGetRegD(cf);
if (cf.MipsS() == cf.MipsT())
{
rvAsm->MV(regd, CFGetRegS(cf));
return;
}
else if (HasConstantRegValue(cf.MipsS(), 0) || HasConstantRegValue(cf.MipsT(), 0))
{
EmitMov(regd, 0);
return;
}
Compile_dst_op(cf, &Assembler::AND, &RISCV64Compiler::SafeANDI, &Assembler::AND, true, false);
}
void CPU::NewRec::RISCV64Compiler::Compile_or(CompileFlags cf)
{
AssertRegOrConstS(cf);
AssertRegOrConstT(cf);
// or/nor with 0 -> no effect
const GPR regd = CFGetRegD(cf);
if (HasConstantRegValue(cf.MipsS(), 0) || HasConstantRegValue(cf.MipsT(), 0) || cf.MipsS() == cf.MipsT())
{
cf.const_s ? MoveTToReg(regd, cf) : MoveSToReg(regd, cf);
return;
}
Compile_dst_op(cf, &Assembler::OR, &RISCV64Compiler::SafeORI, &Assembler::OR, true, false);
}
void CPU::NewRec::RISCV64Compiler::Compile_xor(CompileFlags cf)
{
AssertRegOrConstS(cf);
AssertRegOrConstT(cf);
const GPR regd = CFGetRegD(cf);
if (cf.MipsS() == cf.MipsT())
{
// xor with self -> zero
EmitMov(regd, 0);
return;
}
else if (HasConstantRegValue(cf.MipsS(), 0) || HasConstantRegValue(cf.MipsT(), 0))
{
// xor with zero -> no effect
cf.const_s ? MoveTToReg(regd, cf) : MoveSToReg(regd, cf);
return;
}
Compile_dst_op(cf, &Assembler::XOR, &RISCV64Compiler::SafeXORI, &Assembler::XOR, true, false);
}
void CPU::NewRec::RISCV64Compiler::Compile_nor(CompileFlags cf)
{
Compile_or(cf);
rvAsm->NOT(CFGetRegD(cf), CFGetRegD(cf));
}
void CPU::NewRec::RISCV64Compiler::Compile_slt(CompileFlags cf)
{
Compile_slt(cf, true);
}
void CPU::NewRec::RISCV64Compiler::Compile_sltu(CompileFlags cf)
{
Compile_slt(cf, false);
}
void CPU::NewRec::RISCV64Compiler::Compile_slt(CompileFlags cf, bool sign)
{
AssertRegOrConstS(cf);
AssertRegOrConstT(cf);
const GPR rd = CFGetRegD(cf);
const GPR rs = CFGetSafeRegS(cf, RARG1);
if (cf.const_t && rvIsValidSExtITypeImm(GetConstantRegU32(cf.MipsT())))
{
if (sign)
rvAsm->SLTI(rd, rs, GetConstantRegS32(cf.MipsT()));
else
rvAsm->SLTIU(rd, rs, GetConstantRegS32(cf.MipsT()));
}
else
{
const GPR rt = CFGetSafeRegT(cf, RARG2);
if (sign)
rvAsm->SLT(rd, rs, rt);
else
rvAsm->SLTU(rd, rs, rt);
}
}
biscuit::GPR CPU::NewRec::RISCV64Compiler::ComputeLoadStoreAddressArg(
CompileFlags cf, const std::optional<VirtualMemoryAddress>& address, const std::optional<const biscuit::GPR>& reg)
{
const u32 imm = inst->i.imm_sext32();
if (cf.valid_host_s && imm == 0 && !reg.has_value())
return CFGetRegS(cf);
const GPR dst = reg.has_value() ? reg.value() : RARG1;
if (address.has_value())
{
EmitMov(dst, address.value());
}
else if (imm == 0)
{
if (cf.valid_host_s)
{
if (const GPR src = CFGetRegS(cf); src.Index() != dst.Index())
rvAsm->MV(dst, CFGetRegS(cf));
}
else
{
rvAsm->LW(dst, PTR(&g_state.regs.r[cf.mips_s]));
}
}
else
{
if (cf.valid_host_s)
{
SafeADDIW(dst, CFGetRegS(cf), inst->i.imm_sext32());
}
else
{
rvAsm->LW(dst, PTR(&g_state.regs.r[cf.mips_s]));
SafeADDIW(dst, dst, inst->i.imm_sext32());
}
}
return dst;
}
template<typename RegAllocFn>
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biscuit::GPR CPU::NewRec::RISCV64Compiler::GenerateLoad(const biscuit::GPR& addr_reg, MemoryAccessSize size, bool sign,
bool use_fastmem, const RegAllocFn& dst_reg_alloc)
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{
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if (use_fastmem)
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{
m_cycles += Bus::RAM_READ_TICKS;
// TODO: Make this better. If we're loading the address from state, we can use LWU instead, and skip this.
// TODO: LUT fastmem
const GPR dst = dst_reg_alloc();
rvAsm->SLLI64(RSCRATCH, addr_reg, 32);
rvAsm->SRLI64(RSCRATCH, RSCRATCH, 32);
if (g_settings.cpu_fastmem_mode == CPUFastmemMode::LUT)
{
DebugAssert(addr_reg.Index() != RARG3.Index());
rvAsm->SRLI64(RARG3, RSCRATCH, Bus::FASTMEM_LUT_PAGE_SHIFT);
rvAsm->SLLI64(RARG3, RARG3, 8);
rvAsm->ADD(RARG3, RARG3, RMEMBASE);
rvAsm->LD(RARG3, 0, RARG3);
rvAsm->ADD(RSCRATCH, RSCRATCH, RARG3);
}
else
{
rvAsm->ADD(RSCRATCH, RSCRATCH, RMEMBASE);
}
u8* start = m_emitter->GetCursorPointer();
switch (size)
{
case MemoryAccessSize::Byte:
sign ? rvAsm->LB(dst, 0, RSCRATCH) : rvAsm->LBU(dst, 0, RSCRATCH);
break;
case MemoryAccessSize::HalfWord:
sign ? rvAsm->LH(dst, 0, RSCRATCH) : rvAsm->LHU(dst, 0, RSCRATCH);
break;
case MemoryAccessSize::Word:
rvAsm->LW(dst, 0, RSCRATCH);
break;
}
// We need a nop, because the slowmem jump might be more than 1MB away.
rvAsm->NOP();
AddLoadStoreInfo(start, 8, addr_reg.Index(), dst.Index(), size, sign, true);
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return dst;
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}
if (addr_reg.Index() != RARG1.Index())
rvAsm->MV(RARG1, addr_reg);
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const bool checked = g_settings.cpu_recompiler_memory_exceptions;
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switch (size)
{
case MemoryAccessSize::Byte:
{
EmitCall(checked ? reinterpret_cast<const void*>(&Recompiler::Thunks::ReadMemoryByte) :
reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedReadMemoryByte));
}
break;
case MemoryAccessSize::HalfWord:
{
EmitCall(checked ? reinterpret_cast<const void*>(&Recompiler::Thunks::ReadMemoryHalfWord) :
reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedReadMemoryHalfWord));
}
break;
case MemoryAccessSize::Word:
{
EmitCall(checked ? reinterpret_cast<const void*>(&Recompiler::Thunks::ReadMemoryWord) :
reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedReadMemoryWord));
}
break;
}
// TODO: turn this into an asm function instead
if (checked)
{
rvAsm->SRLI64(RSCRATCH, RRET, 63);
SwitchToFarCode(true, &Assembler::BEQ, RSCRATCH, zero);
BackupHostState();
// Need to stash this in a temp because of the flush.
const GPR temp = GPR(AllocateTempHostReg(HR_CALLEE_SAVED));
rvAsm->NEG(temp, RRET);
rvAsm->SLLIW(temp, temp, 2);
Flush(FLUSH_FOR_C_CALL | FLUSH_FLUSH_MIPS_REGISTERS | FLUSH_FOR_EXCEPTION);
// cause_bits = (-result << 2) | BD | cop_n
SafeORI(RARG1, temp,
Cop0Registers::CAUSE::MakeValueForException(
static_cast<Exception>(0), m_current_instruction_branch_delay_slot, false, inst->cop.cop_n));
EmitMov(RARG2, m_current_instruction_pc);
EmitCall(reinterpret_cast<const void*>(static_cast<void (*)(u32, u32)>(&CPU::RaiseException)));
FreeHostReg(temp.Index());
EndBlock(std::nullopt, true);
RestoreHostState();
SwitchToNearCode(false);
}
const GPR dst_reg = dst_reg_alloc();
switch (size)
{
case MemoryAccessSize::Byte:
{
sign ? EmitSExtB(dst_reg, RRET) : EmitUExtB(dst_reg, RRET);
}
break;
case MemoryAccessSize::HalfWord:
{
sign ? EmitSExtH(dst_reg, RRET) : EmitUExtH(dst_reg, RRET);
}
break;
case MemoryAccessSize::Word:
{
// Need to undo the zero-extend.
if (checked)
rvEmitDSExtW(rvAsm, dst_reg, RRET);
else if (dst_reg.Index() != RRET.Index())
rvAsm->MV(dst_reg, RRET);
}
break;
}
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return dst_reg;
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}
void CPU::NewRec::RISCV64Compiler::GenerateStore(const biscuit::GPR& addr_reg, const biscuit::GPR& value_reg,
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MemoryAccessSize size, bool use_fastmem)
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{
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if (use_fastmem)
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{
DebugAssert(value_reg != RSCRATCH);
rvAsm->SLLI64(RSCRATCH, addr_reg, 32);
rvAsm->SRLI64(RSCRATCH, RSCRATCH, 32);
if (g_settings.cpu_fastmem_mode == CPUFastmemMode::LUT)
{
DebugAssert(addr_reg.Index() != RARG3.Index());
rvAsm->SRLI64(RARG3, RSCRATCH, Bus::FASTMEM_LUT_PAGE_SHIFT);
rvAsm->SLLI64(RARG3, RARG3, 8);
rvAsm->ADD(RARG3, RARG3, RMEMBASE);
rvAsm->LD(RARG3, 0, RARG3);
rvAsm->ADD(RSCRATCH, RSCRATCH, RARG3);
}
else
{
rvAsm->ADD(RSCRATCH, RSCRATCH, RMEMBASE);
}
u8* start = m_emitter->GetCursorPointer();
switch (size)
{
case MemoryAccessSize::Byte:
rvAsm->SB(value_reg, 0, RSCRATCH);
break;
case MemoryAccessSize::HalfWord:
rvAsm->SH(value_reg, 0, RSCRATCH);
break;
case MemoryAccessSize::Word:
rvAsm->SW(value_reg, 0, RSCRATCH);
break;
}
// We need a nop, because the slowmem jump might be more than 1MB away.
rvAsm->NOP();
AddLoadStoreInfo(start, 8, addr_reg.Index(), value_reg.Index(), size, false, false);
return;
}
if (addr_reg.Index() != RARG1.Index())
rvAsm->MV(RARG1, addr_reg);
if (value_reg.Index() != RARG2.Index())
rvAsm->MV(RARG2, value_reg);
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const bool checked = g_settings.cpu_recompiler_memory_exceptions;
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switch (size)
{
case MemoryAccessSize::Byte:
{
EmitCall(checked ? reinterpret_cast<const void*>(&Recompiler::Thunks::WriteMemoryByte) :
reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedWriteMemoryByte));
}
break;
case MemoryAccessSize::HalfWord:
{
EmitCall(checked ? reinterpret_cast<const void*>(&Recompiler::Thunks::WriteMemoryHalfWord) :
reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedWriteMemoryHalfWord));
}
break;
case MemoryAccessSize::Word:
{
EmitCall(checked ? reinterpret_cast<const void*>(&Recompiler::Thunks::WriteMemoryWord) :
reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedWriteMemoryWord));
}
break;
}
// TODO: turn this into an asm function instead
if (checked)
{
SwitchToFarCode(true, &Assembler::BEQ, RRET, zero);
BackupHostState();
// Need to stash this in a temp because of the flush.
const GPR temp = GPR(AllocateTempHostReg(HR_CALLEE_SAVED));
rvAsm->SLLIW(temp, RRET, 2);
Flush(FLUSH_FOR_C_CALL | FLUSH_FLUSH_MIPS_REGISTERS | FLUSH_FOR_EXCEPTION);
// cause_bits = (result << 2) | BD | cop_n
SafeORI(RARG1, temp,
Cop0Registers::CAUSE::MakeValueForException(
static_cast<Exception>(0), m_current_instruction_branch_delay_slot, false, inst->cop.cop_n));
EmitMov(RARG2, m_current_instruction_pc);
EmitCall(reinterpret_cast<const void*>(static_cast<void (*)(u32, u32)>(&CPU::RaiseException)));
FreeHostReg(temp.Index());
EndBlock(std::nullopt, true);
RestoreHostState();
SwitchToNearCode(false);
}
}
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void CPU::NewRec::RISCV64Compiler::Compile_lxx(CompileFlags cf, MemoryAccessSize size, bool sign, bool use_fastmem,
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const std::optional<VirtualMemoryAddress>& address)
{
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const std::optional<GPR> addr_reg = (g_settings.gpu_pgxp_enable && cf.MipsT() != Reg::zero) ?
std::optional<GPR>(GPR(AllocateTempHostReg(HR_CALLEE_SAVED))) :
std::optional<GPR>();
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FlushForLoadStore(address, false, use_fastmem);
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const GPR addr = ComputeLoadStoreAddressArg(cf, address, addr_reg);
const GPR data = GenerateLoad(addr, size, sign, use_fastmem, [this, cf]() {
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if (cf.MipsT() == Reg::zero)
return RRET;
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return GPR(AllocateHostReg(GetFlagsForNewLoadDelayedReg(),
EMULATE_LOAD_DELAYS ? HR_TYPE_NEXT_LOAD_DELAY_VALUE : HR_TYPE_CPU_REG, cf.MipsT()));
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});
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if (g_settings.gpu_pgxp_enable && cf.MipsT() != Reg::zero)
{
Flush(FLUSH_FOR_C_CALL);
EmitMov(RARG1, inst->bits);
rvAsm->MV(RARG2, addr);
rvAsm->MV(RARG3, data);
EmitCall(s_pgxp_mem_load_functions[static_cast<u32>(size)][static_cast<u32>(sign)]);
FreeHostReg(addr_reg.value().Index());
}
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}
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void CPU::NewRec::RISCV64Compiler::Compile_lwx(CompileFlags cf, MemoryAccessSize size, bool sign, bool use_fastmem,
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const std::optional<VirtualMemoryAddress>& address)
{
DebugAssert(size == MemoryAccessSize::Word && !sign);
const GPR addr = GPR(AllocateTempHostReg(HR_CALLEE_SAVED));
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FlushForLoadStore(address, false, use_fastmem);
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// TODO: if address is constant, this can be simplified..
// If we're coming from another block, just flush the load delay and hope for the best..
if (m_load_delay_dirty)
UpdateLoadDelay();
// We'd need to be careful here if we weren't overwriting it..
ComputeLoadStoreAddressArg(cf, address, addr);
rvAsm->ANDI(RARG1, addr, ~0x3u);
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GenerateLoad(RARG1, MemoryAccessSize::Word, false, use_fastmem, []() { return RRET; });
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if (inst->r.rt == Reg::zero)
{
FreeHostReg(addr.Index());
return;
}
// lwl/lwr from a load-delayed value takes the new value, but it itself, is load delayed, so the original value is
// never written back. NOTE: can't trust T in cf because of the flush
const Reg rt = inst->r.rt;
GPR value;
if (m_load_delay_register == rt)
{
const u32 existing_ld_rt = (m_load_delay_value_register == NUM_HOST_REGS) ?
AllocateHostReg(HR_MODE_READ, HR_TYPE_LOAD_DELAY_VALUE, rt) :
m_load_delay_value_register;
RenameHostReg(existing_ld_rt, HR_MODE_WRITE, HR_TYPE_NEXT_LOAD_DELAY_VALUE, rt);
value = GPR(existing_ld_rt);
}
else
{
if constexpr (EMULATE_LOAD_DELAYS)
{
value = GPR(AllocateHostReg(HR_MODE_WRITE, HR_TYPE_NEXT_LOAD_DELAY_VALUE, rt));
if (const std::optional<u32> rtreg = CheckHostReg(HR_MODE_READ, HR_TYPE_CPU_REG, rt); rtreg.has_value())
rvAsm->MV(value, GPR(rtreg.value()));
else if (HasConstantReg(rt))
EmitMov(value, GetConstantRegU32(rt));
else
rvAsm->LW(value, PTR(&g_state.regs.r[static_cast<u8>(rt)]));
}
else
{
value = GPR(AllocateHostReg(HR_MODE_READ | HR_MODE_WRITE, HR_TYPE_CPU_REG, rt));
}
}
DebugAssert(value.Index() != RARG2.Index() && value.Index() != RARG3.Index());
rvAsm->ANDI(RARG2, addr, 3);
rvAsm->SLLIW(RARG2, RARG2, 3); // *8
EmitMov(RARG3, 24);
rvAsm->SUBW(RARG3, RARG3, RARG2);
if (inst->op == InstructionOp::lwl)
{
// const u32 mask = UINT32_C(0x00FFFFFF) >> shift;
// new_value = (value & mask) | (RWRET << (24 - shift));
EmitMov(RSCRATCH, 0xFFFFFFu);
rvAsm->SRLW(RSCRATCH, RSCRATCH, RARG2);
rvAsm->AND(value, value, RSCRATCH);
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rvAsm->SLLW(RRET, RRET, RARG3);
rvAsm->OR(value, value, RRET);
}
else
{
// const u32 mask = UINT32_C(0xFFFFFF00) << (24 - shift);
// new_value = (value & mask) | (RWRET >> shift);
rvAsm->SRLW(RRET, RRET, RARG2);
EmitMov(RSCRATCH, 0xFFFFFF00u);
rvAsm->SLLW(RSCRATCH, RSCRATCH, RARG3);
rvAsm->AND(value, value, RSCRATCH);
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rvAsm->OR(value, value, RRET);
}
FreeHostReg(addr.Index());
if (g_settings.gpu_pgxp_enable)
{
Flush(FLUSH_FOR_C_CALL);
rvAsm->MV(RARG3, value);
rvAsm->ANDI(RARG2, addr, ~0x3u);
EmitMov(RARG1, inst->bits);
EmitCall(reinterpret_cast<const void*>(&PGXP::CPU_LW));
}
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}
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void CPU::NewRec::RISCV64Compiler::Compile_lwc2(CompileFlags cf, MemoryAccessSize size, bool sign, bool use_fastmem,
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const std::optional<VirtualMemoryAddress>& address)
{
const u32 index = static_cast<u32>(inst->r.rt.GetValue());
const auto [ptr, action] = GetGTERegisterPointer(index, true);
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const std::optional<GPR> addr_reg =
g_settings.gpu_pgxp_enable ? std::optional<GPR>(GPR(AllocateTempHostReg(HR_CALLEE_SAVED))) : std::optional<GPR>();
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FlushForLoadStore(address, false, use_fastmem);
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const GPR addr = ComputeLoadStoreAddressArg(cf, address, addr_reg);
const GPR value = GenerateLoad(addr, MemoryAccessSize::Word, false, use_fastmem, [this, action = action]() {
return (action == GTERegisterAccessAction::CallHandler && g_settings.gpu_pgxp_enable) ?
GPR(AllocateTempHostReg(HR_CALLEE_SAVED)) :
RRET;
});
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switch (action)
{
case GTERegisterAccessAction::Ignore:
{
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break;
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}
case GTERegisterAccessAction::Direct:
{
rvAsm->SW(value, PTR(ptr));
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break;
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}
case GTERegisterAccessAction::SignExtend16:
{
EmitSExtH(RARG3, value);
rvAsm->SW(RARG3, PTR(ptr));
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break;
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}
case GTERegisterAccessAction::ZeroExtend16:
{
EmitUExtH(RARG3, value);
rvAsm->SW(RARG3, PTR(ptr));
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break;
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}
case GTERegisterAccessAction::CallHandler:
{
Flush(FLUSH_FOR_C_CALL);
rvAsm->MV(RARG2, value);
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EmitMov(RARG1, index);
EmitCall(reinterpret_cast<const void*>(&GTE::WriteRegister));
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break;
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}
case GTERegisterAccessAction::PushFIFO:
{
// SXY0 <- SXY1
// SXY1 <- SXY2
// SXY2 <- SXYP
DebugAssert(value.Index() != RARG2.Index() && value.Index() != RARG3.Index());
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rvAsm->LW(RARG2, PTR(&g_state.gte_regs.SXY1[0]));
rvAsm->LW(RARG3, PTR(&g_state.gte_regs.SXY2[0]));
rvAsm->SW(RARG2, PTR(&g_state.gte_regs.SXY0[0]));
rvAsm->SW(RARG3, PTR(&g_state.gte_regs.SXY1[0]));
rvAsm->SW(value, PTR(&g_state.gte_regs.SXY2[0]));
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break;
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}
default:
{
Panic("Unknown action");
return;
}
}
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if (g_settings.gpu_pgxp_enable)
{
Flush(FLUSH_FOR_C_CALL);
rvAsm->MV(RARG3, value);
if (value.Index() != RRET.Index())
FreeHostReg(value.Index());
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rvAsm->MV(RARG2, addr);
FreeHostReg(addr_reg.value().Index());
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EmitMov(RARG1, inst->bits);
EmitCall(reinterpret_cast<const void*>(&PGXP::CPU_LWC2));
}
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}
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void CPU::NewRec::RISCV64Compiler::Compile_sxx(CompileFlags cf, MemoryAccessSize size, bool sign, bool use_fastmem,
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const std::optional<VirtualMemoryAddress>& address)
{
AssertRegOrConstS(cf);
AssertRegOrConstT(cf);
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const std::optional<GPR> addr_reg =
g_settings.gpu_pgxp_enable ? std::optional<GPR>(GPR(AllocateTempHostReg(HR_CALLEE_SAVED))) : std::optional<GPR>();
FlushForLoadStore(address, true, use_fastmem);
const GPR addr = ComputeLoadStoreAddressArg(cf, address, addr_reg);
const GPR data = cf.valid_host_t ? CFGetRegT(cf) : RARG2;
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if (!cf.valid_host_t)
MoveTToReg(RARG2, cf);
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GenerateStore(addr, data, size, use_fastmem);
if (g_settings.gpu_pgxp_enable)
{
Flush(FLUSH_FOR_C_CALL);
MoveMIPSRegToReg(RARG3, cf.MipsT());
rvAsm->MV(RARG2, addr);
EmitMov(RARG1, inst->bits);
EmitCall(s_pgxp_mem_store_functions[static_cast<u32>(size)]);
FreeHostReg(addr_reg.value().Index());
}
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}
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void CPU::NewRec::RISCV64Compiler::Compile_swx(CompileFlags cf, MemoryAccessSize size, bool sign, bool use_fastmem,
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const std::optional<VirtualMemoryAddress>& address)
{
DebugAssert(size == MemoryAccessSize::Word && !sign);
// TODO: this can take over rt's value if it's no longer needed
// NOTE: can't trust T in cf because of the alloc
const GPR addr = GPR(AllocateTempHostReg(HR_CALLEE_SAVED));
const GPR value = g_settings.gpu_pgxp_enable ? GPR(AllocateTempHostReg(HR_CALLEE_SAVED)) : RARG2;
if (g_settings.gpu_pgxp_enable)
MoveMIPSRegToReg(value, inst->r.rt);
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FlushForLoadStore(address, true, use_fastmem);
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// TODO: if address is constant, this can be simplified..
// We'd need to be careful here if we weren't overwriting it..
ComputeLoadStoreAddressArg(cf, address, addr);
rvAsm->ANDI(RARG1, addr, ~0x3u);
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GenerateLoad(RARG1, MemoryAccessSize::Word, false, use_fastmem, []() { return RRET; });
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rvAsm->ANDI(RSCRATCH, addr, 3);
rvAsm->SLLIW(RSCRATCH, RSCRATCH, 3); // *8
rvAsm->ANDI(addr, addr, ~0x3u);
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// Need to load down here for PGXP-off, because it's in a volatile reg that can get overwritten by flush.
if (!g_settings.gpu_pgxp_enable)
MoveMIPSRegToReg(value, inst->r.rt);
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if (inst->op == InstructionOp::swl)
{
// const u32 mem_mask = UINT32_C(0xFFFFFF00) << shift;
// new_value = (RWRET & mem_mask) | (value >> (24 - shift));
EmitMov(RARG3, 0xFFFFFF00u);
rvAsm->SLLW(RARG3, RARG3, RSCRATCH);
rvAsm->AND(RRET, RRET, RARG3);
EmitMov(RARG3, 24);
rvAsm->SUBW(RARG3, RARG3, RSCRATCH);
rvAsm->SRLW(value, value, RARG3);
rvAsm->OR(value, value, RRET);
}
else
{
// const u32 mem_mask = UINT32_C(0x00FFFFFF) >> (24 - shift);
// new_value = (RWRET & mem_mask) | (value << shift);
rvAsm->SLLW(value, value, RSCRATCH);
EmitMov(RARG3, 24);
rvAsm->SUBW(RARG3, RARG3, RSCRATCH);
EmitMov(RSCRATCH, 0x00FFFFFFu);
rvAsm->SRLW(RSCRATCH, RSCRATCH, RARG3);
rvAsm->AND(RRET, RRET, RSCRATCH);
rvAsm->OR(value, value, RRET);
}
if (!g_settings.gpu_pgxp_enable)
{
GenerateStore(addr, value, MemoryAccessSize::Word, use_fastmem);
FreeHostReg(addr.Index());
}
else
{
GenerateStore(addr, value, MemoryAccessSize::Word, use_fastmem);
Flush(FLUSH_FOR_C_CALL);
rvAsm->MV(RARG3, value);
FreeHostReg(value.Index());
rvAsm->MV(RARG2, addr);
FreeHostReg(addr.Index());
EmitMov(RARG1, inst->bits);
EmitCall(reinterpret_cast<const void*>(&PGXP::CPU_SW));
}
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}
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void CPU::NewRec::RISCV64Compiler::Compile_swc2(CompileFlags cf, MemoryAccessSize size, bool sign, bool use_fastmem,
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const std::optional<VirtualMemoryAddress>& address)
{
const u32 index = static_cast<u32>(inst->r.rt.GetValue());
const auto [ptr, action] = GetGTERegisterPointer(index, false);
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const GPR addr = (g_settings.gpu_pgxp_enable || action == GTERegisterAccessAction::CallHandler) ?
GPR(AllocateTempHostReg(HR_CALLEE_SAVED)) :
RARG1;
const GPR data = g_settings.gpu_pgxp_enable ? GPR(AllocateTempHostReg(HR_CALLEE_SAVED)) : RARG2;
FlushForLoadStore(address, true, use_fastmem);
ComputeLoadStoreAddressArg(cf, address, addr);
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switch (action)
{
case GTERegisterAccessAction::Direct:
{
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rvAsm->LW(data, PTR(ptr));
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}
break;
case GTERegisterAccessAction::CallHandler:
{
// should already be flushed.. except in fastmem case
Flush(FLUSH_FOR_C_CALL);
EmitMov(RARG1, index);
EmitCall(reinterpret_cast<const void*>(&GTE::ReadRegister));
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rvAsm->MV(data, RRET);
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}
break;
default:
{
Panic("Unknown action");
}
break;
}
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GenerateStore(addr, data, size, use_fastmem);
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if (!g_settings.gpu_pgxp_enable)
{
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if (addr.Index() != RARG1.Index())
FreeHostReg(addr.Index());
}
else
{
// TODO: This can be simplified because we don't need to validate in PGXP..
Flush(FLUSH_FOR_C_CALL);
rvAsm->MV(RARG3, data);
FreeHostReg(data.Index());
rvAsm->MV(RARG2, addr);
FreeHostReg(addr.Index());
EmitMov(RARG1, inst->bits);
EmitCall(reinterpret_cast<const void*>(&PGXP::CPU_SWC2));
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}
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}
void CPU::NewRec::RISCV64Compiler::Compile_mtc0(CompileFlags cf)
{
// TODO: we need better constant setting here.. which will need backprop
AssertRegOrConstT(cf);
const Cop0Reg reg = static_cast<Cop0Reg>(MipsD());
const u32* ptr = GetCop0RegPtr(reg);
const u32 mask = GetCop0RegWriteMask(reg);
if (!ptr)
{
Compile_Fallback();
return;
}
if (mask == 0)
{
// if it's a read-only register, ignore
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DEBUG_LOG("Ignoring write to read-only cop0 reg {}", static_cast<u32>(reg));
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return;
}
// for some registers, we need to test certain bits
const bool needs_bit_test = (reg == Cop0Reg::SR);
const GPR new_value = RARG1;
const GPR old_value = RARG2;
const GPR changed_bits = RARG3;
const GPR mask_reg = RSCRATCH;
// Load old value
rvAsm->LW(old_value, PTR(ptr));
// No way we fit this in an immediate..
EmitMov(mask_reg, mask);
// update value
// TODO: This is creating pointless MV instructions.. why?
if (cf.valid_host_t)
rvAsm->AND(new_value, CFGetRegT(cf), mask_reg);
else
EmitMov(new_value, GetConstantRegU32(cf.MipsT()) & mask);
if (needs_bit_test)
rvAsm->XOR(changed_bits, old_value, new_value);
rvAsm->NOT(mask_reg, mask_reg);
rvAsm->AND(old_value, old_value, mask_reg);
rvAsm->OR(new_value, old_value, new_value);
rvAsm->SW(new_value, PTR(ptr));
if (reg == Cop0Reg::SR)
{
// TODO: replace with register backup
// We could just inline the whole thing..
Flush(FLUSH_FOR_C_CALL);
rvAsm->SRLIW(RSCRATCH, changed_bits, 16);
rvAsm->ANDI(RSCRATCH, RSCRATCH, 1);
SwitchToFarCode(true, &Assembler::BEQ, RSCRATCH, zero);
rvAsm->ADDI(sp, sp, -16);
rvAsm->SW(RARG1, 0, sp);
EmitCall(reinterpret_cast<const void*>(&CPU::UpdateMemoryPointers));
rvAsm->LW(RARG1, 0, sp);
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rvAsm->ADDI(sp, sp, 16);
rvAsm->LD(RMEMBASE, PTR(&g_state.fastmem_base));
SwitchToNearCode(true);
TestInterrupts(RARG1);
}
else if (reg == Cop0Reg::CAUSE)
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{
rvAsm->LW(RARG1, PTR(&g_state.cop0_regs.sr.bits));
TestInterrupts(RARG1);
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}
if (reg == Cop0Reg::DCIC && g_settings.cpu_recompiler_memory_exceptions)
{
// TODO: DCIC handling for debug breakpoints
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WARNING_LOG("TODO: DCIC handling for debug breakpoints");
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}
}
void CPU::NewRec::RISCV64Compiler::Compile_rfe(CompileFlags cf)
{
// shift mode bits right two, preserving upper bits
rvAsm->LW(RARG1, PTR(&g_state.cop0_regs.sr.bits));
rvAsm->SRLIW(RSCRATCH, RARG1, 2);
rvAsm->ANDI(RSCRATCH, RSCRATCH, 0xf);
rvAsm->ANDI(RARG1, RARG1, ~0xfu);
rvAsm->OR(RARG1, RARG1, RSCRATCH);
rvAsm->SW(RARG1, PTR(&g_state.cop0_regs.sr.bits));
TestInterrupts(RARG1);
}
void CPU::NewRec::RISCV64Compiler::TestInterrupts(const biscuit::GPR& sr)
{
DebugAssert(sr != RSCRATCH);
// if Iec == 0 then goto no_interrupt
Label no_interrupt;
rvAsm->ANDI(RSCRATCH, sr, 1);
rvAsm->BEQZ(RSCRATCH, &no_interrupt);
// sr & cause
rvAsm->LW(RSCRATCH, PTR(&g_state.cop0_regs.cause.bits));
rvAsm->AND(sr, sr, RSCRATCH);
// ((sr & cause) & 0xff00) == 0 goto no_interrupt
rvAsm->SRLIW(sr, sr, 8);
rvAsm->ANDI(sr, sr, 0xFF);
SwitchToFarCode(true, &Assembler::BEQ, sr, zero);
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BackupHostState();
// Update load delay, this normally happens at the end of an instruction, but we're finishing it early.
UpdateLoadDelay();
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Flush(FLUSH_END_BLOCK | FLUSH_FOR_EXCEPTION | FLUSH_FOR_C_CALL);
// Can't use EndBlockWithException() here, because it'll use the wrong PC.
// Can't use RaiseException() on the fast path if we're the last instruction, because the next PC is unknown.
if (!iinfo->is_last_instruction)
{
EmitMov(RARG1, Cop0Registers::CAUSE::MakeValueForException(Exception::INT, iinfo->is_branch_instruction, false,
(inst + 1)->cop.cop_n));
EmitMov(RARG2, m_compiler_pc);
EmitCall(reinterpret_cast<const void*>(static_cast<void (*)(u32, u32)>(&CPU::RaiseException)));
m_dirty_pc = false;
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EndAndLinkBlock(std::nullopt, true, false);
}
else
{
if (m_dirty_pc)
EmitMov(RARG1, m_compiler_pc);
rvAsm->SW(biscuit::zero, PTR(&g_state.downcount));
if (m_dirty_pc)
rvAsm->SW(RARG1, PTR(&g_state.pc));
m_dirty_pc = false;
EndAndLinkBlock(std::nullopt, false, true);
}
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RestoreHostState();
SwitchToNearCode(false);
rvAsm->Bind(&no_interrupt);
}
void CPU::NewRec::RISCV64Compiler::Compile_mfc2(CompileFlags cf)
{
const u32 index = inst->cop.Cop2Index();
const Reg rt = inst->r.rt;
const auto [ptr, action] = GetGTERegisterPointer(index, false);
if (action == GTERegisterAccessAction::Ignore)
return;
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u32 hreg;
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if (action == GTERegisterAccessAction::Direct)
{
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hreg = AllocateHostReg(GetFlagsForNewLoadDelayedReg(),
EMULATE_LOAD_DELAYS ? HR_TYPE_NEXT_LOAD_DELAY_VALUE : HR_TYPE_CPU_REG, rt);
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rvAsm->LW(GPR(hreg), PTR(ptr));
}
else if (action == GTERegisterAccessAction::CallHandler)
{
Flush(FLUSH_FOR_C_CALL);
EmitMov(RARG1, index);
EmitCall(reinterpret_cast<const void*>(&GTE::ReadRegister));
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hreg = AllocateHostReg(GetFlagsForNewLoadDelayedReg(),
EMULATE_LOAD_DELAYS ? HR_TYPE_NEXT_LOAD_DELAY_VALUE : HR_TYPE_CPU_REG, rt);
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rvAsm->MV(GPR(hreg), RRET);
}
else
{
Panic("Unknown action");
}
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if (g_settings.gpu_pgxp_enable)
{
Flush(FLUSH_FOR_C_CALL);
EmitMov(RARG1, inst->bits);
rvAsm->MV(RARG2, GPR(hreg));
EmitCall(reinterpret_cast<const void*>(&PGXP::CPU_MFC2));
}
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}
void CPU::NewRec::RISCV64Compiler::Compile_mtc2(CompileFlags cf)
{
const u32 index = inst->cop.Cop2Index();
const auto [ptr, action] = GetGTERegisterPointer(index, true);
if (action == GTERegisterAccessAction::Ignore)
return;
if (action == GTERegisterAccessAction::Direct)
{
if (cf.const_t)
StoreConstantToCPUPointer(GetConstantRegU32(cf.MipsT()), ptr);
else
rvAsm->SW(CFGetRegT(cf), PTR(ptr));
}
else if (action == GTERegisterAccessAction::SignExtend16 || action == GTERegisterAccessAction::ZeroExtend16)
{
const bool sign = (action == GTERegisterAccessAction::SignExtend16);
if (cf.valid_host_t)
{
sign ? EmitSExtH(RARG1, CFGetRegT(cf)) : EmitUExtH(RARG1, CFGetRegT(cf));
rvAsm->SW(RARG1, PTR(ptr));
}
else if (cf.const_t)
{
const u16 cv = Truncate16(GetConstantRegU32(cf.MipsT()));
StoreConstantToCPUPointer(sign ? ::SignExtend32(cv) : ::ZeroExtend32(cv), ptr);
}
else
{
Panic("Unsupported setup");
}
}
else if (action == GTERegisterAccessAction::CallHandler)
{
Flush(FLUSH_FOR_C_CALL);
EmitMov(RARG1, index);
MoveTToReg(RARG2, cf);
EmitCall(reinterpret_cast<const void*>(&GTE::WriteRegister));
}
else if (action == GTERegisterAccessAction::PushFIFO)
{
// SXY0 <- SXY1
// SXY1 <- SXY2
// SXY2 <- SXYP
DebugAssert(RRET.Index() != RARG2.Index() && RRET.Index() != RARG3.Index());
rvAsm->LW(RARG2, PTR(&g_state.gte_regs.SXY1[0]));
rvAsm->LW(RARG3, PTR(&g_state.gte_regs.SXY2[0]));
rvAsm->SW(RARG2, PTR(&g_state.gte_regs.SXY0[0]));
rvAsm->SW(RARG3, PTR(&g_state.gte_regs.SXY1[0]));
if (cf.valid_host_t)
rvAsm->SW(CFGetRegT(cf), PTR(&g_state.gte_regs.SXY2[0]));
else if (cf.const_t)
StoreConstantToCPUPointer(GetConstantRegU32(cf.MipsT()), &g_state.gte_regs.SXY2[0]);
else
Panic("Unsupported setup");
}
else
{
Panic("Unknown action");
}
}
void CPU::NewRec::RISCV64Compiler::Compile_cop2(CompileFlags cf)
{
TickCount func_ticks;
GTE::InstructionImpl func = GTE::GetInstructionImpl(inst->bits, &func_ticks);
Flush(FLUSH_FOR_C_CALL);
EmitMov(RARG1, inst->bits & GTE::Instruction::REQUIRED_BITS_MASK);
EmitCall(reinterpret_cast<const void*>(func));
AddGTETicks(func_ticks);
}
u32 CPU::NewRec::CompileLoadStoreThunk(void* thunk_code, u32 thunk_space, void* code_address, u32 code_size,
TickCount cycles_to_add, TickCount cycles_to_remove, u32 gpr_bitmask,
u8 address_register, u8 data_register, MemoryAccessSize size, bool is_signed,
bool is_load)
{
Assembler arm_asm(static_cast<u8*>(thunk_code), thunk_space);
Assembler* rvAsm = &arm_asm;
static constexpr u32 GPR_SIZE = 8;
// save regs
u32 num_gprs = 0;
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
if ((gpr_bitmask & (1u << i)) && rvIsCallerSavedRegister(i) && (!is_load || data_register != i))
num_gprs++;
}
const u32 stack_size = (((num_gprs + 1) & ~1u) * GPR_SIZE);
if (stack_size > 0)
{
rvAsm->ADDI(sp, sp, -static_cast<s32>(stack_size));
u32 stack_offset = 0;
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
if ((gpr_bitmask & (1u << i)) && rvIsCallerSavedRegister(i) && (!is_load || data_register != i))
{
rvAsm->SD(GPR(i), stack_offset, sp);
stack_offset += GPR_SIZE;
}
}
}
if (cycles_to_add != 0)
{
// NOTE: we have to reload here, because memory writes can run DMA, which can screw with cycles
Assert(rvIsValidSExtITypeImm(cycles_to_add));
rvAsm->LW(RSCRATCH, PTR(&g_state.pending_ticks));
rvAsm->ADDIW(RSCRATCH, RSCRATCH, cycles_to_add);
rvAsm->SW(RSCRATCH, PTR(&g_state.pending_ticks));
}
if (address_register != RARG1.Index())
rvAsm->MV(RARG1, GPR(address_register));
if (!is_load)
{
if (data_register != RARG2.Index())
rvAsm->MV(RARG2, GPR(data_register));
}
switch (size)
{
case MemoryAccessSize::Byte:
{
rvEmitCall(rvAsm, is_load ? reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedReadMemoryByte) :
reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedWriteMemoryByte));
}
break;
case MemoryAccessSize::HalfWord:
{
rvEmitCall(rvAsm, is_load ? reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedReadMemoryHalfWord) :
reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedWriteMemoryHalfWord));
}
break;
case MemoryAccessSize::Word:
{
rvEmitCall(rvAsm, is_load ? reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedReadMemoryWord) :
reinterpret_cast<const void*>(&Recompiler::Thunks::UncheckedWriteMemoryWord));
}
break;
}
if (is_load)
{
const GPR dst = GPR(data_register);
switch (size)
{
case MemoryAccessSize::Byte:
{
is_signed ? rvEmitSExtB(rvAsm, dst, RRET) : rvEmitUExtB(rvAsm, dst, RRET);
}
break;
case MemoryAccessSize::HalfWord:
{
is_signed ? rvEmitSExtH(rvAsm, dst, RRET) : rvEmitUExtH(rvAsm, dst, RRET);
}
break;
case MemoryAccessSize::Word:
{
if (dst.Index() != RRET.Index())
rvAsm->MV(dst, RRET);
}
break;
}
}
if (cycles_to_remove != 0)
{
Assert(rvIsValidSExtITypeImm(-cycles_to_remove));
rvAsm->LW(RSCRATCH, PTR(&g_state.pending_ticks));
rvAsm->ADDIW(RSCRATCH, RSCRATCH, -cycles_to_remove);
rvAsm->SW(RSCRATCH, PTR(&g_state.pending_ticks));
}
// restore regs
if (stack_size > 0)
{
u32 stack_offset = 0;
for (u32 i = 0; i < NUM_HOST_REGS; i++)
{
if ((gpr_bitmask & (1u << i)) && rvIsCallerSavedRegister(i) && (!is_load || data_register != i))
{
rvAsm->LD(GPR(i), stack_offset, sp);
stack_offset += GPR_SIZE;
}
}
rvAsm->ADDI(sp, sp, stack_size);
}
rvEmitJmp(rvAsm, static_cast<const u8*>(code_address) + code_size);
return static_cast<u32>(rvAsm->GetCodeBuffer().GetSizeInBytes());
}
#endif // CPU_ARCH_RISCV64