early-access version 4000

This commit is contained in:
pineappleEA 2023-11-30 17:36:34 +01:00
parent 1996a32f94
commit 49f8c57d33
18 changed files with 680 additions and 72 deletions

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@ -1,7 +1,7 @@
yuzu emulator early access yuzu emulator early access
============= =============
This is the source code for early-access 3999. This is the source code for early-access 4000.
## Legal Notice ## Legal Notice

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@ -193,7 +193,7 @@ if (ANDROID)
endif() endif()
endif() endif()
if (CMAKE_SYSTEM_NAME STREQUAL "Linux") if (UNIX AND NOT APPLE)
add_subdirectory(gamemode) add_subdirectory(gamemode)
endif() endif()

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@ -182,7 +182,7 @@ if(ANDROID)
) )
endif() endif()
if (CMAKE_SYSTEM_NAME STREQUAL "Linux") if (UNIX AND NOT APPLE)
target_sources(common PRIVATE target_sources(common PRIVATE
linux/gamemode.cpp linux/gamemode.cpp
linux/gamemode.h linux/gamemode.h

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@ -935,8 +935,8 @@ if (HAS_NCE)
arm/nce/arm_nce.h arm/nce/arm_nce.h
arm/nce/arm_nce.s arm/nce/arm_nce.s
arm/nce/guest_context.h arm/nce/guest_context.h
arm/nce/patch.cpp arm/nce/patcher.cpp
arm/nce/patch.h arm/nce/patcher.h
arm/nce/instructions.h arm/nce/instructions.h
) )
target_link_libraries(core PRIVATE merry::oaknut) target_link_libraries(core PRIVATE merry::oaknut)

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@ -6,7 +6,7 @@
#include "common/signal_chain.h" #include "common/signal_chain.h"
#include "core/arm/nce/arm_nce.h" #include "core/arm/nce/arm_nce.h"
#include "core/arm/nce/patch.h" #include "core/arm/nce/patcher.h"
#include "core/core.h" #include "core/core.h"
#include "core/memory.h" #include "core/memory.h"

474
src/core/arm/nce/patcher.cpp Executable file
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@ -0,0 +1,474 @@
// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#include "common/arm64/native_clock.h"
#include "common/bit_cast.h"
#include "common/literals.h"
#include "core/arm/nce/arm_nce.h"
#include "core/arm/nce/guest_context.h"
#include "core/arm/nce/instructions.h"
#include "core/arm/nce/patcher.h"
#include "core/core.h"
#include "core/core_timing.h"
#include "core/hle/kernel/svc.h"
namespace Core::NCE {
using namespace Common::Literals;
using namespace oaknut::util;
using NativeExecutionParameters = Kernel::KThread::NativeExecutionParameters;
constexpr size_t MaxRelativeBranch = 128_MiB;
constexpr u32 ModuleCodeIndex = 0x24 / sizeof(u32);
Patcher::Patcher() : c(m_patch_instructions) {}
Patcher::~Patcher() = default;
void Patcher::PatchText(const Kernel::PhysicalMemory& program_image,
const Kernel::CodeSet::Segment& code) {
// Write save context helper function.
c.l(m_save_context);
WriteSaveContext();
// Write load context helper function.
c.l(m_load_context);
WriteLoadContext();
// Retrieve text segment data.
const auto text = std::span{program_image}.subspan(code.offset, code.size);
const auto text_words =
std::span<const u32>{reinterpret_cast<const u32*>(text.data()), text.size() / sizeof(u32)};
// Loop through instructions, patching as needed.
for (u32 i = ModuleCodeIndex; i < static_cast<u32>(text_words.size()); i++) {
const u32 inst = text_words[i];
const auto AddRelocations = [&] {
const uintptr_t this_offset = i * sizeof(u32);
const uintptr_t next_offset = this_offset + sizeof(u32);
// Relocate from here to patch.
this->BranchToPatch(this_offset);
// Relocate from patch to next instruction.
return next_offset;
};
// SVC
if (auto svc = SVC{inst}; svc.Verify()) {
WriteSvcTrampoline(AddRelocations(), svc.GetValue());
continue;
}
// MRS Xn, TPIDR_EL0
// MRS Xn, TPIDRRO_EL0
if (auto mrs = MRS{inst};
mrs.Verify() && (mrs.GetSystemReg() == TpidrroEl0 || mrs.GetSystemReg() == TpidrEl0)) {
const auto src_reg = mrs.GetSystemReg() == TpidrroEl0 ? oaknut::SystemReg::TPIDRRO_EL0
: oaknut::SystemReg::TPIDR_EL0;
const auto dest_reg = oaknut::XReg{static_cast<int>(mrs.GetRt())};
WriteMrsHandler(AddRelocations(), dest_reg, src_reg);
continue;
}
// MRS Xn, CNTPCT_EL0
if (auto mrs = MRS{inst}; mrs.Verify() && mrs.GetSystemReg() == CntpctEl0) {
WriteCntpctHandler(AddRelocations(), oaknut::XReg{static_cast<int>(mrs.GetRt())});
continue;
}
// MRS Xn, CNTFRQ_EL0
if (auto mrs = MRS{inst}; mrs.Verify() && mrs.GetSystemReg() == CntfrqEl0) {
UNREACHABLE();
}
// MSR TPIDR_EL0, Xn
if (auto msr = MSR{inst}; msr.Verify() && msr.GetSystemReg() == TpidrEl0) {
WriteMsrHandler(AddRelocations(), oaknut::XReg{static_cast<int>(msr.GetRt())});
continue;
}
if (auto exclusive = Exclusive{inst}; exclusive.Verify()) {
m_exclusives.push_back(i);
}
}
// Determine patching mode for the final relocation step
const size_t image_size = program_image.size();
this->mode = image_size > MaxRelativeBranch ? PatchMode::PreText : PatchMode::PostData;
}
void Patcher::RelocateAndCopy(Common::ProcessAddress load_base,
const Kernel::CodeSet::Segment& code,
Kernel::PhysicalMemory& program_image,
EntryTrampolines* out_trampolines) {
const size_t patch_size = GetSectionSize();
const size_t image_size = program_image.size();
// Retrieve text segment data.
const auto text = std::span{program_image}.subspan(code.offset, code.size);
const auto text_words =
std::span<u32>{reinterpret_cast<u32*>(text.data()), text.size() / sizeof(u32)};
const auto ApplyBranchToPatchRelocation = [&](u32* target, const Relocation& rel) {
oaknut::CodeGenerator rc{target};
if (mode == PatchMode::PreText) {
rc.B(rel.patch_offset - patch_size - rel.module_offset);
} else {
rc.B(image_size - rel.module_offset + rel.patch_offset);
}
};
const auto ApplyBranchToModuleRelocation = [&](u32* target, const Relocation& rel) {
oaknut::CodeGenerator rc{target};
if (mode == PatchMode::PreText) {
rc.B(patch_size - rel.patch_offset + rel.module_offset);
} else {
rc.B(rel.module_offset - image_size - rel.patch_offset);
}
};
const auto RebasePatch = [&](ptrdiff_t patch_offset) {
if (mode == PatchMode::PreText) {
return GetInteger(load_base) + patch_offset;
} else {
return GetInteger(load_base) + image_size + patch_offset;
}
};
const auto RebasePc = [&](uintptr_t module_offset) {
if (mode == PatchMode::PreText) {
return GetInteger(load_base) + patch_size + module_offset;
} else {
return GetInteger(load_base) + module_offset;
}
};
// We are now ready to relocate!
for (const Relocation& rel : m_branch_to_patch_relocations) {
ApplyBranchToPatchRelocation(text_words.data() + rel.module_offset / sizeof(u32), rel);
}
for (const Relocation& rel : m_branch_to_module_relocations) {
ApplyBranchToModuleRelocation(m_patch_instructions.data() + rel.patch_offset / sizeof(u32),
rel);
}
// Rewrite PC constants and record post trampolines
for (const Relocation& rel : m_write_module_pc_relocations) {
oaknut::CodeGenerator rc{m_patch_instructions.data() + rel.patch_offset / sizeof(u32)};
rc.dx(RebasePc(rel.module_offset));
}
for (const Trampoline& rel : m_trampolines) {
out_trampolines->insert({RebasePc(rel.module_offset), RebasePatch(rel.patch_offset)});
}
// Cortex-A57 seems to treat all exclusives as ordered, but newer processors do not.
// Convert to ordered to preserve this assumption.
for (const ModuleTextAddress i : m_exclusives) {
auto exclusive = Exclusive{text_words[i]};
text_words[i] = exclusive.AsOrdered();
}
// Copy to program image
if (this->mode == PatchMode::PreText) {
std::memcpy(program_image.data(), m_patch_instructions.data(),
m_patch_instructions.size() * sizeof(u32));
} else {
program_image.resize(image_size + patch_size);
std::memcpy(program_image.data() + image_size, m_patch_instructions.data(),
m_patch_instructions.size() * sizeof(u32));
}
}
size_t Patcher::GetSectionSize() const noexcept {
return Common::AlignUp(m_patch_instructions.size() * sizeof(u32), Core::Memory::YUZU_PAGESIZE);
}
void Patcher::WriteLoadContext() {
// This function was called, which modifies X30, so use that as a scratch register.
// SP contains the guest X30, so save our return X30 to SP + 8, since we have allocated 16 bytes
// of stack.
c.STR(X30, SP, 8);
c.MRS(X30, oaknut::SystemReg::TPIDR_EL0);
c.LDR(X30, X30, offsetof(NativeExecutionParameters, native_context));
// Load system registers.
c.LDR(W0, X30, offsetof(GuestContext, fpsr));
c.MSR(oaknut::SystemReg::FPSR, X0);
c.LDR(W0, X30, offsetof(GuestContext, fpcr));
c.MSR(oaknut::SystemReg::FPCR, X0);
c.LDR(W0, X30, offsetof(GuestContext, nzcv));
c.MSR(oaknut::SystemReg::NZCV, X0);
// Load all vector registers.
static constexpr size_t VEC_OFF = offsetof(GuestContext, vector_registers);
for (int i = 0; i <= 30; i += 2) {
c.LDP(oaknut::QReg{i}, oaknut::QReg{i + 1}, X30, VEC_OFF + 16 * i);
}
// Load all general-purpose registers except X30.
for (int i = 0; i <= 28; i += 2) {
c.LDP(oaknut::XReg{i}, oaknut::XReg{i + 1}, X30, 8 * i);
}
// Reload our return X30 from the stack and return.
// The patch code will reload the guest X30 for us.
c.LDR(X30, SP, 8);
c.RET();
}
void Patcher::WriteSaveContext() {
// This function was called, which modifies X30, so use that as a scratch register.
// SP contains the guest X30, so save our X30 to SP + 8, since we have allocated 16 bytes of
// stack.
c.STR(X30, SP, 8);
c.MRS(X30, oaknut::SystemReg::TPIDR_EL0);
c.LDR(X30, X30, offsetof(NativeExecutionParameters, native_context));
// Store all general-purpose registers except X30.
for (int i = 0; i <= 28; i += 2) {
c.STP(oaknut::XReg{i}, oaknut::XReg{i + 1}, X30, 8 * i);
}
// Store all vector registers.
static constexpr size_t VEC_OFF = offsetof(GuestContext, vector_registers);
for (int i = 0; i <= 30; i += 2) {
c.STP(oaknut::QReg{i}, oaknut::QReg{i + 1}, X30, VEC_OFF + 16 * i);
}
// Store guest system registers, X30 and SP, using X0 as a scratch register.
c.STR(X0, SP, PRE_INDEXED, -16);
c.LDR(X0, SP, 16);
c.STR(X0, X30, 8 * 30);
c.ADD(X0, SP, 32);
c.STR(X0, X30, offsetof(GuestContext, sp));
c.MRS(X0, oaknut::SystemReg::FPSR);
c.STR(W0, X30, offsetof(GuestContext, fpsr));
c.MRS(X0, oaknut::SystemReg::FPCR);
c.STR(W0, X30, offsetof(GuestContext, fpcr));
c.MRS(X0, oaknut::SystemReg::NZCV);
c.STR(W0, X30, offsetof(GuestContext, nzcv));
c.LDR(X0, SP, POST_INDEXED, 16);
// Reload our return X30 from the stack, and return.
c.LDR(X30, SP, 8);
c.RET();
}
void Patcher::WriteSvcTrampoline(ModuleDestLabel module_dest, u32 svc_id) {
// We are about to start saving state, so we need to lock the context.
this->LockContext();
// Store guest X30 to the stack. Then, save the context and restore the stack.
// This will save all registers except PC, but we know PC at patch time.
c.STR(X30, SP, PRE_INDEXED, -16);
c.BL(m_save_context);
c.LDR(X30, SP, POST_INDEXED, 16);
// Now that we've saved all registers, we can use any registers as scratch.
// Store PC + 4 to arm interface, since we know the instruction offset from the entry point.
oaknut::Label pc_after_svc;
c.MRS(X1, oaknut::SystemReg::TPIDR_EL0);
c.LDR(X1, X1, offsetof(NativeExecutionParameters, native_context));
c.LDR(X2, pc_after_svc);
c.STR(X2, X1, offsetof(GuestContext, pc));
// Store SVC number to execute when we return
c.MOV(X2, svc_id);
c.STR(W2, X1, offsetof(GuestContext, svc_swi));
// We are calling a SVC. Clear esr_el1 and return it.
static_assert(std::is_same_v<std::underlying_type_t<HaltReason>, u64>);
oaknut::Label retry;
c.ADD(X2, X1, offsetof(GuestContext, esr_el1));
c.l(retry);
c.LDAXR(X0, X2);
c.STLXR(W3, XZR, X2);
c.CBNZ(W3, retry);
// Add "calling SVC" flag. Since this is X0, this is now our return value.
c.ORR(X0, X0, static_cast<u64>(HaltReason::SupervisorCall));
// Offset the GuestContext pointer to the HostContext member.
// STP has limited range of [-512, 504] which we can't reach otherwise
// NB: Due to this all offsets below are from the start of HostContext.
c.ADD(X1, X1, offsetof(GuestContext, host_ctx));
// Reload host TPIDR_EL0 and SP.
static_assert(offsetof(HostContext, host_sp) + 8 == offsetof(HostContext, host_tpidr_el0));
c.LDP(X2, X3, X1, offsetof(HostContext, host_sp));
c.MOV(SP, X2);
c.MSR(oaknut::SystemReg::TPIDR_EL0, X3);
// Load callee-saved host registers and return to host.
static constexpr size_t HOST_REGS_OFF = offsetof(HostContext, host_saved_regs);
static constexpr size_t HOST_VREGS_OFF = offsetof(HostContext, host_saved_vregs);
c.LDP(X19, X20, X1, HOST_REGS_OFF);
c.LDP(X21, X22, X1, HOST_REGS_OFF + 2 * sizeof(u64));
c.LDP(X23, X24, X1, HOST_REGS_OFF + 4 * sizeof(u64));
c.LDP(X25, X26, X1, HOST_REGS_OFF + 6 * sizeof(u64));
c.LDP(X27, X28, X1, HOST_REGS_OFF + 8 * sizeof(u64));
c.LDP(X29, X30, X1, HOST_REGS_OFF + 10 * sizeof(u64));
c.LDP(Q8, Q9, X1, HOST_VREGS_OFF);
c.LDP(Q10, Q11, X1, HOST_VREGS_OFF + 2 * sizeof(u128));
c.LDP(Q12, Q13, X1, HOST_VREGS_OFF + 4 * sizeof(u128));
c.LDP(Q14, Q15, X1, HOST_VREGS_OFF + 6 * sizeof(u128));
c.RET();
// Write the post-SVC trampoline address, which will jump back to the guest after restoring its
// state.
m_trampolines.push_back({c.offset(), module_dest});
// Host called this location. Save the return address so we can
// unwind the stack properly when jumping back.
c.MRS(X2, oaknut::SystemReg::TPIDR_EL0);
c.LDR(X2, X2, offsetof(NativeExecutionParameters, native_context));
c.ADD(X0, X2, offsetof(GuestContext, host_ctx));
c.STR(X30, X0, offsetof(HostContext, host_saved_regs) + 11 * sizeof(u64));
// Reload all guest registers except X30 and PC.
// The function also expects 16 bytes of stack already allocated.
c.STR(X30, SP, PRE_INDEXED, -16);
c.BL(m_load_context);
c.LDR(X30, SP, POST_INDEXED, 16);
// Use X1 as a scratch register to restore X30.
c.STR(X1, SP, PRE_INDEXED, -16);
c.MRS(X1, oaknut::SystemReg::TPIDR_EL0);
c.LDR(X1, X1, offsetof(NativeExecutionParameters, native_context));
c.LDR(X30, X1, offsetof(GuestContext, cpu_registers) + sizeof(u64) * 30);
c.LDR(X1, SP, POST_INDEXED, 16);
// Unlock the context.
this->UnlockContext();
// Jump back to the instruction after the emulated SVC.
this->BranchToModule(module_dest);
// Store PC after call.
c.l(pc_after_svc);
this->WriteModulePc(module_dest);
}
void Patcher::WriteMrsHandler(ModuleDestLabel module_dest, oaknut::XReg dest_reg,
oaknut::SystemReg src_reg) {
// Retrieve emulated TLS register from GuestContext.
c.MRS(dest_reg, oaknut::SystemReg::TPIDR_EL0);
if (src_reg == oaknut::SystemReg::TPIDRRO_EL0) {
c.LDR(dest_reg, dest_reg, offsetof(NativeExecutionParameters, tpidrro_el0));
} else {
c.LDR(dest_reg, dest_reg, offsetof(NativeExecutionParameters, tpidr_el0));
}
// Jump back to the instruction after the emulated MRS.
this->BranchToModule(module_dest);
}
void Patcher::WriteMsrHandler(ModuleDestLabel module_dest, oaknut::XReg src_reg) {
const auto scratch_reg = src_reg.index() == 0 ? X1 : X0;
c.STR(scratch_reg, SP, PRE_INDEXED, -16);
// Save guest value to NativeExecutionParameters::tpidr_el0.
c.MRS(scratch_reg, oaknut::SystemReg::TPIDR_EL0);
c.STR(src_reg, scratch_reg, offsetof(NativeExecutionParameters, tpidr_el0));
// Restore scratch register.
c.LDR(scratch_reg, SP, POST_INDEXED, 16);
// Jump back to the instruction after the emulated MSR.
this->BranchToModule(module_dest);
}
void Patcher::WriteCntpctHandler(ModuleDestLabel module_dest, oaknut::XReg dest_reg) {
static Common::Arm64::NativeClock clock{};
const auto factor = clock.GetGuestCNTFRQFactor();
const auto raw_factor = Common::BitCast<std::array<u64, 2>>(factor);
const auto use_x2_x3 = dest_reg.index() == 0 || dest_reg.index() == 1;
oaknut::XReg scratch0 = use_x2_x3 ? X2 : X0;
oaknut::XReg scratch1 = use_x2_x3 ? X3 : X1;
oaknut::Label factorlo;
oaknut::Label factorhi;
// Save scratches.
c.STP(scratch0, scratch1, SP, PRE_INDEXED, -16);
// Load counter value.
c.MRS(dest_reg, oaknut::SystemReg::CNTVCT_EL0);
// Load scaling factor.
c.LDR(scratch0, factorlo);
c.LDR(scratch1, factorhi);
// Multiply low bits and get result.
c.UMULH(scratch0, dest_reg, scratch0);
// Multiply high bits and add low bit result.
c.MADD(dest_reg, dest_reg, scratch1, scratch0);
// Reload scratches.
c.LDP(scratch0, scratch1, SP, POST_INDEXED, 16);
// Jump back to the instruction after the emulated MRS.
this->BranchToModule(module_dest);
// Scaling factor constant values.
c.l(factorlo);
c.dx(raw_factor[0]);
c.l(factorhi);
c.dx(raw_factor[1]);
}
void Patcher::LockContext() {
oaknut::Label retry;
// Save scratches.
c.STP(X0, X1, SP, PRE_INDEXED, -16);
// Reload lock pointer.
c.l(retry);
c.CLREX();
c.MRS(X0, oaknut::SystemReg::TPIDR_EL0);
c.ADD(X0, X0, offsetof(NativeExecutionParameters, lock));
static_assert(SpinLockLocked == 0);
// Load-linked with acquire ordering.
c.LDAXR(W1, X0);
// If the value was SpinLockLocked, clear monitor and retry.
c.CBZ(W1, retry);
// Store-conditional SpinLockLocked with relaxed ordering.
c.STXR(W1, WZR, X0);
// If we failed to store, retry.
c.CBNZ(W1, retry);
// We succeeded! Reload scratches.
c.LDP(X0, X1, SP, POST_INDEXED, 16);
}
void Patcher::UnlockContext() {
// Save scratches.
c.STP(X0, X1, SP, PRE_INDEXED, -16);
// Load lock pointer.
c.MRS(X0, oaknut::SystemReg::TPIDR_EL0);
c.ADD(X0, X0, offsetof(NativeExecutionParameters, lock));
// Load SpinLockUnlocked.
c.MOV(W1, SpinLockUnlocked);
// Store value with release ordering.
c.STLR(W1, X0);
// Load scratches.
c.LDP(X0, X1, SP, POST_INDEXED, 16);
}
} // namespace Core::NCE

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// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#pragma once
#include <span>
#include <unordered_map>
#include <vector>
#include <oaknut/code_block.hpp>
#include <oaknut/oaknut.hpp>
#include "common/common_types.h"
#include "core/hle/kernel/code_set.h"
#include "core/hle/kernel/k_typed_address.h"
#include "core/hle/kernel/physical_memory.h"
namespace Core::NCE {
enum class PatchMode : u32 {
None,
PreText, ///< Patch section is inserted before .text
PostData, ///< Patch section is inserted after .data
};
using ModuleTextAddress = u64;
using PatchTextAddress = u64;
using EntryTrampolines = std::unordered_map<ModuleTextAddress, PatchTextAddress>;
class Patcher {
public:
explicit Patcher();
~Patcher();
void PatchText(const Kernel::PhysicalMemory& program_image,
const Kernel::CodeSet::Segment& code);
void RelocateAndCopy(Common::ProcessAddress load_base, const Kernel::CodeSet::Segment& code,
Kernel::PhysicalMemory& program_image, EntryTrampolines* out_trampolines);
size_t GetSectionSize() const noexcept;
[[nodiscard]] PatchMode GetPatchMode() const noexcept {
return mode;
}
private:
using ModuleDestLabel = uintptr_t;
struct Trampoline {
ptrdiff_t patch_offset;
uintptr_t module_offset;
};
void WriteLoadContext();
void WriteSaveContext();
void LockContext();
void UnlockContext();
void WriteSvcTrampoline(ModuleDestLabel module_dest, u32 svc_id);
void WriteMrsHandler(ModuleDestLabel module_dest, oaknut::XReg dest_reg,
oaknut::SystemReg src_reg);
void WriteMsrHandler(ModuleDestLabel module_dest, oaknut::XReg src_reg);
void WriteCntpctHandler(ModuleDestLabel module_dest, oaknut::XReg dest_reg);
private:
void BranchToPatch(uintptr_t module_dest) {
m_branch_to_patch_relocations.push_back({c.offset(), module_dest});
}
void BranchToModule(uintptr_t module_dest) {
m_branch_to_module_relocations.push_back({c.offset(), module_dest});
c.dw(0);
}
void WriteModulePc(uintptr_t module_dest) {
m_write_module_pc_relocations.push_back({c.offset(), module_dest});
c.dx(0);
}
private:
// List of patch instructions we have generated.
std::vector<u32> m_patch_instructions{};
// Relocation type for relative branch from module to patch.
struct Relocation {
ptrdiff_t patch_offset; ///< Offset in bytes from the start of the patch section.
uintptr_t module_offset; ///< Offset in bytes from the start of the text section.
};
oaknut::VectorCodeGenerator c;
std::vector<Trampoline> m_trampolines;
std::vector<Relocation> m_branch_to_patch_relocations{};
std::vector<Relocation> m_branch_to_module_relocations{};
std::vector<Relocation> m_write_module_pc_relocations{};
std::vector<ModuleTextAddress> m_exclusives{};
oaknut::Label m_save_context{};
oaknut::Label m_load_context{};
PatchMode mode{PatchMode::None};
};
} // namespace Core::NCE

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@ -16,7 +16,7 @@
#include "core/loader/nso.h" #include "core/loader/nso.h"
#ifdef HAS_NCE #ifdef HAS_NCE
#include "core/arm/nce/patch.h" #include "core/arm/nce/patcher.h"
#endif #endif
namespace Loader { namespace Loader {

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@ -23,7 +23,7 @@
#include "core/memory.h" #include "core/memory.h"
#ifdef HAS_NCE #ifdef HAS_NCE
#include "core/arm/nce/patch.h" #include "core/arm/nce/patcher.h"
#endif #endif
namespace Loader { namespace Loader {

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@ -21,7 +21,7 @@
#include "core/memory.h" #include "core/memory.h"
#ifdef HAS_NCE #ifdef HAS_NCE
#include "core/arm/nce/patch.h" #include "core/arm/nce/patcher.h"
#endif #endif
namespace Loader { namespace Loader {

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@ -146,8 +146,12 @@ StagingBufferMap BufferCacheRuntime::UploadStagingBuffer(size_t size) {
return staging_buffer_pool.RequestUploadBuffer(size); return staging_buffer_pool.RequestUploadBuffer(size);
} }
StagingBufferMap BufferCacheRuntime::DownloadStagingBuffer(size_t size) { StagingBufferMap BufferCacheRuntime::DownloadStagingBuffer(size_t size, bool deferred) {
return staging_buffer_pool.RequestDownloadBuffer(size); return staging_buffer_pool.RequestDownloadBuffer(size, deferred);
}
void BufferCacheRuntime::FreeDeferredStagingBuffer(StagingBufferMap& buffer) {
staging_buffer_pool.FreeDeferredStagingBuffer(buffer);
} }
u64 BufferCacheRuntime::GetDeviceMemoryUsage() const { u64 BufferCacheRuntime::GetDeviceMemoryUsage() const {

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@ -66,7 +66,9 @@ public:
[[nodiscard]] StagingBufferMap UploadStagingBuffer(size_t size); [[nodiscard]] StagingBufferMap UploadStagingBuffer(size_t size);
[[nodiscard]] StagingBufferMap DownloadStagingBuffer(size_t size); [[nodiscard]] StagingBufferMap DownloadStagingBuffer(size_t size, bool deferred = false);
void FreeDeferredStagingBuffer(StagingBufferMap& buffer);
bool CanReorderUpload(const Buffer&, std::span<const VideoCommon::BufferCopy>) { bool CanReorderUpload(const Buffer&, std::span<const VideoCommon::BufferCopy>) {
return false; return false;
@ -246,7 +248,7 @@ struct BufferCacheParams {
static constexpr bool NEEDS_BIND_STORAGE_INDEX = true; static constexpr bool NEEDS_BIND_STORAGE_INDEX = true;
static constexpr bool USE_MEMORY_MAPS = true; static constexpr bool USE_MEMORY_MAPS = true;
static constexpr bool SEPARATE_IMAGE_BUFFER_BINDINGS = true; static constexpr bool SEPARATE_IMAGE_BUFFER_BINDINGS = true;
static constexpr bool IMPLEMENTS_ASYNC_DOWNLOADS = false; static constexpr bool IMPLEMENTS_ASYNC_DOWNLOADS = true;
// TODO: Investigate why OpenGL seems to perform worse with persistently mapped buffer uploads // TODO: Investigate why OpenGL seems to perform worse with persistently mapped buffer uploads
static constexpr bool USE_MEMORY_MAPS_FOR_UPLOADS = false; static constexpr bool USE_MEMORY_MAPS_FOR_UPLOADS = false;

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@ -28,63 +28,69 @@ StagingBuffers::StagingBuffers(GLenum storage_flags_, GLenum map_flags_)
StagingBuffers::~StagingBuffers() = default; StagingBuffers::~StagingBuffers() = default;
StagingBufferMap StagingBuffers::RequestMap(size_t requested_size, bool insert_fence) { StagingBufferMap StagingBuffers::RequestMap(size_t requested_size, bool insert_fence,
bool deferred) {
MICROPROFILE_SCOPE(OpenGL_BufferRequest); MICROPROFILE_SCOPE(OpenGL_BufferRequest);
const size_t index = RequestBuffer(requested_size); const size_t index = RequestBuffer(requested_size);
OGLSync* const sync = insert_fence ? &syncs[index] : nullptr; OGLSync* const sync = insert_fence ? &allocs[index].sync : nullptr;
sync_indices[index] = insert_fence ? ++current_sync_index : 0; allocs[index].sync_index = insert_fence ? ++current_sync_index : 0;
allocs[index].deferred = deferred;
return StagingBufferMap{ return StagingBufferMap{
.mapped_span = std::span(maps[index], requested_size), .mapped_span = std::span(allocs[index].map, requested_size),
.sync = sync, .sync = sync,
.buffer = buffers[index].handle, .buffer = allocs[index].buffer.handle,
.index = index,
}; };
} }
void StagingBuffers::FreeDeferredStagingBuffer(size_t index) {
ASSERT(allocs[index].deferred);
allocs[index].deferred = false;
}
size_t StagingBuffers::RequestBuffer(size_t requested_size) { size_t StagingBuffers::RequestBuffer(size_t requested_size) {
if (const std::optional<size_t> index = FindBuffer(requested_size); index) { if (const std::optional<size_t> index = FindBuffer(requested_size); index) {
return *index; return *index;
} }
StagingBufferAlloc alloc;
OGLBuffer& buffer = buffers.emplace_back(); alloc.buffer.Create();
buffer.Create();
const auto next_pow2_size = Common::NextPow2(requested_size); const auto next_pow2_size = Common::NextPow2(requested_size);
glNamedBufferStorage(buffer.handle, next_pow2_size, nullptr, glNamedBufferStorage(alloc.buffer.handle, next_pow2_size, nullptr,
storage_flags | GL_MAP_PERSISTENT_BIT); storage_flags | GL_MAP_PERSISTENT_BIT);
maps.push_back(static_cast<u8*>(glMapNamedBufferRange(buffer.handle, 0, next_pow2_size, alloc.map = static_cast<u8*>(glMapNamedBufferRange(alloc.buffer.handle, 0, next_pow2_size,
map_flags | GL_MAP_PERSISTENT_BIT))); map_flags | GL_MAP_PERSISTENT_BIT));
syncs.emplace_back(); alloc.size = next_pow2_size;
sync_indices.emplace_back(); allocs.emplace_back(std::move(alloc));
sizes.push_back(next_pow2_size); return allocs.size() - 1;
ASSERT(syncs.size() == buffers.size() && buffers.size() == maps.size() &&
maps.size() == sizes.size());
return buffers.size() - 1;
} }
std::optional<size_t> StagingBuffers::FindBuffer(size_t requested_size) { std::optional<size_t> StagingBuffers::FindBuffer(size_t requested_size) {
size_t known_unsignaled_index = current_sync_index + 1; size_t known_unsignaled_index = current_sync_index + 1;
size_t smallest_buffer = std::numeric_limits<size_t>::max(); size_t smallest_buffer = std::numeric_limits<size_t>::max();
std::optional<size_t> found; std::optional<size_t> found;
const size_t num_buffers = sizes.size(); const size_t num_buffers = allocs.size();
for (size_t index = 0; index < num_buffers; ++index) { for (size_t index = 0; index < num_buffers; ++index) {
const size_t buffer_size = sizes[index]; StagingBufferAlloc& alloc = allocs[index];
const size_t buffer_size = alloc.size;
if (buffer_size < requested_size || buffer_size >= smallest_buffer) { if (buffer_size < requested_size || buffer_size >= smallest_buffer) {
continue; continue;
} }
if (syncs[index].handle != 0) { if (alloc.deferred) {
if (sync_indices[index] >= known_unsignaled_index) { continue;
}
if (alloc.sync.handle != 0) {
if (alloc.sync_index >= known_unsignaled_index) {
// This fence is later than a fence that is known to not be signaled // This fence is later than a fence that is known to not be signaled
continue; continue;
} }
if (!syncs[index].IsSignaled()) { if (!alloc.sync.IsSignaled()) {
// Since this fence hasn't been signaled, it's safe to assume all later // Since this fence hasn't been signaled, it's safe to assume all later
// fences haven't been signaled either // fences haven't been signaled either
known_unsignaled_index = std::min(known_unsignaled_index, sync_indices[index]); known_unsignaled_index = std::min(known_unsignaled_index, alloc.sync_index);
continue; continue;
} }
syncs[index].Release(); alloc.sync.Release();
} }
smallest_buffer = buffer_size; smallest_buffer = buffer_size;
found = index; found = index;
@ -143,8 +149,12 @@ StagingBufferMap StagingBufferPool::RequestUploadBuffer(size_t size) {
return upload_buffers.RequestMap(size, true); return upload_buffers.RequestMap(size, true);
} }
StagingBufferMap StagingBufferPool::RequestDownloadBuffer(size_t size) { StagingBufferMap StagingBufferPool::RequestDownloadBuffer(size_t size, bool deferred) {
return download_buffers.RequestMap(size, false); return download_buffers.RequestMap(size, false, deferred);
}
void StagingBufferPool::FreeDeferredStagingBuffer(StagingBufferMap& buffer) {
download_buffers.FreeDeferredStagingBuffer(buffer.index);
} }
} // namespace OpenGL } // namespace OpenGL

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@ -26,23 +26,30 @@ struct StagingBufferMap {
size_t offset = 0; size_t offset = 0;
OGLSync* sync; OGLSync* sync;
GLuint buffer; GLuint buffer;
size_t index;
}; };
struct StagingBuffers { struct StagingBuffers {
explicit StagingBuffers(GLenum storage_flags_, GLenum map_flags_); explicit StagingBuffers(GLenum storage_flags_, GLenum map_flags_);
~StagingBuffers(); ~StagingBuffers();
StagingBufferMap RequestMap(size_t requested_size, bool insert_fence); StagingBufferMap RequestMap(size_t requested_size, bool insert_fence, bool deferred = false);
void FreeDeferredStagingBuffer(size_t index);
size_t RequestBuffer(size_t requested_size); size_t RequestBuffer(size_t requested_size);
std::optional<size_t> FindBuffer(size_t requested_size); std::optional<size_t> FindBuffer(size_t requested_size);
std::vector<OGLSync> syncs; struct StagingBufferAlloc {
std::vector<OGLBuffer> buffers; OGLSync sync;
std::vector<u8*> maps; OGLBuffer buffer;
std::vector<size_t> sizes; u8* map;
std::vector<size_t> sync_indices; size_t size;
size_t sync_index;
bool deferred;
};
std::vector<StagingBufferAlloc> allocs;
GLenum storage_flags; GLenum storage_flags;
GLenum map_flags; GLenum map_flags;
size_t current_sync_index = 0; size_t current_sync_index = 0;
@ -85,7 +92,8 @@ public:
~StagingBufferPool() = default; ~StagingBufferPool() = default;
StagingBufferMap RequestUploadBuffer(size_t size); StagingBufferMap RequestUploadBuffer(size_t size);
StagingBufferMap RequestDownloadBuffer(size_t size); StagingBufferMap RequestDownloadBuffer(size_t size, bool deferred = false);
void FreeDeferredStagingBuffer(StagingBufferMap& buffer);
private: private:
StagingBuffers upload_buffers{GL_MAP_WRITE_BIT, GL_MAP_WRITE_BIT | GL_MAP_FLUSH_EXPLICIT_BIT}; StagingBuffers upload_buffers{GL_MAP_WRITE_BIT, GL_MAP_WRITE_BIT | GL_MAP_FLUSH_EXPLICIT_BIT};

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@ -557,8 +557,12 @@ StagingBufferMap TextureCacheRuntime::UploadStagingBuffer(size_t size) {
return staging_buffer_pool.RequestUploadBuffer(size); return staging_buffer_pool.RequestUploadBuffer(size);
} }
StagingBufferMap TextureCacheRuntime::DownloadStagingBuffer(size_t size) { StagingBufferMap TextureCacheRuntime::DownloadStagingBuffer(size_t size, bool deferred) {
return staging_buffer_pool.RequestDownloadBuffer(size); return staging_buffer_pool.RequestDownloadBuffer(size, deferred);
}
void TextureCacheRuntime::FreeDeferredStagingBuffer(StagingBufferMap& buffer) {
staging_buffer_pool.FreeDeferredStagingBuffer(buffer);
} }
u64 TextureCacheRuntime::GetDeviceMemoryUsage() const { u64 TextureCacheRuntime::GetDeviceMemoryUsage() const {

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@ -74,7 +74,9 @@ public:
StagingBufferMap UploadStagingBuffer(size_t size); StagingBufferMap UploadStagingBuffer(size_t size);
StagingBufferMap DownloadStagingBuffer(size_t size); StagingBufferMap DownloadStagingBuffer(size_t size, bool deferred = false);
void FreeDeferredStagingBuffer(StagingBufferMap& buffer);
u64 GetDeviceLocalMemory() const { u64 GetDeviceLocalMemory() const {
return device_access_memory; return device_access_memory;
@ -359,7 +361,7 @@ struct TextureCacheParams {
static constexpr bool FRAMEBUFFER_BLITS = true; static constexpr bool FRAMEBUFFER_BLITS = true;
static constexpr bool HAS_EMULATED_COPIES = true; static constexpr bool HAS_EMULATED_COPIES = true;
static constexpr bool HAS_DEVICE_MEMORY_INFO = true; static constexpr bool HAS_DEVICE_MEMORY_INFO = true;
static constexpr bool IMPLEMENTS_ASYNC_DOWNLOADS = false; static constexpr bool IMPLEMENTS_ASYNC_DOWNLOADS = true;
using Runtime = OpenGL::TextureCacheRuntime; using Runtime = OpenGL::TextureCacheRuntime;
using Image = OpenGL::Image; using Image = OpenGL::Image;
@ -367,7 +369,7 @@ struct TextureCacheParams {
using ImageView = OpenGL::ImageView; using ImageView = OpenGL::ImageView;
using Sampler = OpenGL::Sampler; using Sampler = OpenGL::Sampler;
using Framebuffer = OpenGL::Framebuffer; using Framebuffer = OpenGL::Framebuffer;
using AsyncBuffer = u32; using AsyncBuffer = OpenGL::StagingBufferMap;
using BufferType = GLuint; using BufferType = GLuint;
}; };

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@ -892,10 +892,6 @@ void RasterizerVulkan::UpdateDynamicStates() {
UpdateFrontFace(regs); UpdateFrontFace(regs);
UpdateStencilOp(regs); UpdateStencilOp(regs);
if (device.IsExtVertexInputDynamicStateSupported()) {
UpdateVertexInput(regs);
}
if (state_tracker.TouchStateEnable()) { if (state_tracker.TouchStateEnable()) {
UpdateDepthBoundsTestEnable(regs); UpdateDepthBoundsTestEnable(regs);
UpdateDepthTestEnable(regs); UpdateDepthTestEnable(regs);
@ -918,6 +914,9 @@ void RasterizerVulkan::UpdateDynamicStates() {
UpdateBlending(regs); UpdateBlending(regs);
} }
} }
if (device.IsExtVertexInputDynamicStateSupported()) {
UpdateVertexInput(regs);
}
} }
void RasterizerVulkan::HandleTransformFeedback() { void RasterizerVulkan::HandleTransformFeedback() {

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@ -519,10 +519,6 @@ Device::Device(VkInstance instance_, vk::PhysicalDevice physical_, VkSurfaceKHR
LOG_WARNING(Render_Vulkan, "ARM drivers have broken VK_EXT_extended_dynamic_state"); LOG_WARNING(Render_Vulkan, "ARM drivers have broken VK_EXT_extended_dynamic_state");
RemoveExtensionFeature(extensions.extended_dynamic_state, features.extended_dynamic_state, RemoveExtensionFeature(extensions.extended_dynamic_state, features.extended_dynamic_state,
VK_EXT_EXTENDED_DYNAMIC_STATE_EXTENSION_NAME); VK_EXT_EXTENDED_DYNAMIC_STATE_EXTENSION_NAME);
LOG_WARNING(Render_Vulkan, "ARM drivers have broken VK_EXT_extended_dynamic_state2");
RemoveExtensionFeature(extensions.extended_dynamic_state2, features.extended_dynamic_state2,
VK_EXT_EXTENDED_DYNAMIC_STATE_2_EXTENSION_NAME);
} }
if (is_nvidia) { if (is_nvidia) {
@ -611,17 +607,12 @@ Device::Device(VkInstance instance_, vk::PhysicalDevice physical_, VkSurfaceKHR
} }
} }
if (extensions.vertex_input_dynamic_state && is_qualcomm) { if (extensions.vertex_input_dynamic_state && is_qualcomm) {
const u32 version = (properties.properties.driverVersion << 3) >> 3; // Qualcomm drivers do not properly support vertex_input_dynamic_state.
if (version >= VK_MAKE_API_VERSION(0, 0, 676, 0) && LOG_WARNING(Render_Vulkan,
version < VK_MAKE_API_VERSION(0, 0, 680, 0)) { "Qualcomm drivers have broken VK_EXT_vertex_input_dynamic_state");
// Qualcomm Adreno 7xx drivers do not properly support vertex_input_dynamic_state. RemoveExtensionFeature(extensions.vertex_input_dynamic_state,
LOG_WARNING( features.vertex_input_dynamic_state,
Render_Vulkan, VK_EXT_VERTEX_INPUT_DYNAMIC_STATE_EXTENSION_NAME);
"Qualcomm Adreno 7xx drivers have broken VK_EXT_vertex_input_dynamic_state");
RemoveExtensionFeature(extensions.vertex_input_dynamic_state,
features.vertex_input_dynamic_state,
VK_EXT_VERTEX_INPUT_DYNAMIC_STATE_EXTENSION_NAME);
}
} }
sets_per_pool = 64; sets_per_pool = 64;
@ -704,6 +695,22 @@ Device::Device(VkInstance instance_, vk::PhysicalDevice physical_, VkSurfaceKHR
std::min(properties.properties.limits.maxVertexInputBindings, 16U); std::min(properties.properties.limits.maxVertexInputBindings, 16U);
} }
if (!extensions.extended_dynamic_state && extensions.extended_dynamic_state2) {
LOG_INFO(Render_Vulkan,
"Removing extendedDynamicState2 due to missing extendedDynamicState");
RemoveExtensionFeature(extensions.extended_dynamic_state2, features.extended_dynamic_state2,
VK_EXT_EXTENDED_DYNAMIC_STATE_2_EXTENSION_NAME);
}
if (!extensions.extended_dynamic_state2 && extensions.extended_dynamic_state3) {
LOG_INFO(Render_Vulkan,
"Removing extendedDynamicState3 due to missing extendedDynamicState2");
RemoveExtensionFeature(extensions.extended_dynamic_state3, features.extended_dynamic_state3,
VK_EXT_EXTENDED_DYNAMIC_STATE_3_EXTENSION_NAME);
dynamic_state3_blending = false;
dynamic_state3_enables = false;
}
logical = vk::Device::Create(physical, queue_cis, ExtensionListForVulkan(loaded_extensions), logical = vk::Device::Create(physical, queue_cis, ExtensionListForVulkan(loaded_extensions),
first_next, dld); first_next, dld);