Files
KytyPS5/tests/PageManagerTests.cpp
2026-07-16 10:21:41 +02:00

632 lines
26 KiB
C++

#include "graphics/host_gpu/pageManager.h"
#include <atomic>
#include <cstdint>
#include <cstdio>
#include <cstdlib>
#include <cstring>
#include <memory>
#include <string>
#include <thread>
#include <vector>
#if KYTY_PLATFORM == KYTY_PLATFORM_WINDOWS
#ifndef NOMINMAX
#define NOMINMAX
#endif
#include <windows.h>
#undef min
#undef max
#endif
namespace {
using Libs::Graphics::GpuAccess;
using Libs::Graphics::PageFaultAccess;
using Libs::Graphics::PageManager;
void Check(bool value, const char *text) {
if (!value) {
std::fprintf(stderr, "PageManagerTests: failed: %s\n", text);
std::abort();
}
}
#if KYTY_PLATFORM == KYTY_PLATFORM_WINDOWS
bool IsWritable(const void *address) {
MEMORY_BASIC_INFORMATION info{};
Check(VirtualQuery(address, &info, sizeof(info)) != 0, "VirtualQuery failed");
return info.Protect == PAGE_READWRITE;
}
uint32_t Protection(const void *address) {
MEMORY_BASIC_INFORMATION info{};
Check(VirtualQuery(address, &info, sizeof(info)) != 0, "VirtualQuery failed");
return info.Protect;
}
struct FaultContext {
PageManager *manager = nullptr;
bool result = true;
bool reenter = false;
uint64_t reenter_address = 0;
bool block = false;
std::atomic_uint32_t calls{0};
std::atomic_bool entered{false};
std::atomic_bool release{false};
};
std::atomic<PageManager *> g_native_fault_manager{nullptr};
std::atomic_bool g_delay_native_fault{false};
std::atomic_bool g_native_fault_entered{false};
std::atomic_bool g_release_native_fault{false};
LONG CALLBACK NativeFaultHandler(EXCEPTION_POINTERS *exception) {
if (exception == nullptr || exception->ExceptionRecord == nullptr ||
exception->ExceptionRecord->ExceptionCode != EXCEPTION_ACCESS_VIOLATION) {
return EXCEPTION_CONTINUE_SEARCH;
}
const auto operation = exception->ExceptionRecord->ExceptionInformation[0];
const auto access = operation == 0 ? PageFaultAccess::Read
: operation == 1 ? PageFaultAccess::Write
: operation == 8 ? PageFaultAccess::Execute
: PageFaultAccess::Unknown;
auto *manager = g_native_fault_manager.load(std::memory_order_acquire);
if (manager == nullptr) {
return EXCEPTION_CONTINUE_SEARCH;
}
if (g_delay_native_fault.load(std::memory_order_acquire)) {
g_native_fault_entered.store(true, std::memory_order_release);
while (!g_release_native_fault.load(std::memory_order_acquire)) {
std::this_thread::yield();
}
}
return manager->HandleFault(
access, exception->ExceptionRecord->ExceptionInformation[1])
? EXCEPTION_CONTINUE_EXECUTION
: EXCEPTION_CONTINUE_SEARCH;
}
bool InvalidateFault(void *context, Libs::Graphics::PageFaultAccess, uint64_t vaddr, uint64_t size,
Libs::Graphics::PageFaultPhase phase) noexcept {
auto *fault = static_cast<FaultContext *>(context);
Check(fault != nullptr && fault->manager != nullptr, "invalid fault context");
if (phase != Libs::Graphics::PageFaultPhase::Invalidate) {
return true;
}
fault->calls.fetch_add(1, std::memory_order_relaxed);
if (fault->reenter) {
const auto address =
fault->reenter_address != 0 ? fault->reenter_address : vaddr;
(void)fault->manager->HandleFault(PageFaultAccess::Write, address);
}
if (fault->block) {
fault->entered.store(true, std::memory_order_release);
while (!fault->release.load(std::memory_order_acquire)) {
std::this_thread::yield();
}
}
(void)size;
return fault->result;
}
uint8_t *Allocate(uint64_t size, uint32_t protection = PAGE_READWRITE) {
constexpr uintptr_t test_address = 0x0000000200010000ull;
auto *memory = static_cast<uint8_t *>(
VirtualAlloc(reinterpret_cast<void *>(test_address), size,
MEM_RESERVE | MEM_COMMIT, protection));
Check(memory == reinterpret_cast<void *>(test_address),
"fixed low VirtualAlloc failed");
return memory;
}
void TestWatchFaultAndUnwatch() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size * 2);
manager.OnGpuMap(reinterpret_cast<uint64_t>(memory), page_size * 2);
manager.UpdatePageWatchers(true, reinterpret_cast<uint64_t>(memory),
page_size);
Check(manager.IsTracked(reinterpret_cast<uint64_t>(memory)) &&
!IsWritable(memory),
"watch did not protect the page");
Check(manager.HandleFault(PageFaultAccess::Write,
reinterpret_cast<uint64_t>(memory + 32)),
"tracked write fault was not handled");
Check(!manager.IsTracked(reinterpret_cast<uint64_t>(memory)) &&
IsWritable(memory),
"fault invalidation did not remove the watcher");
Check(manager.HandleFault(PageFaultAccess::Write,
reinterpret_cast<uint64_t>(memory)),
"single delayed write fault was not coalesced");
Check(manager.HandleFault(PageFaultAccess::Write,
reinterpret_cast<uint64_t>(memory)),
"second delayed write fault was not coalesced");
manager.OnGpuUnmap(reinterpret_cast<uint64_t>(memory), page_size * 2);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestSharedWatcherFault() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.UpdatePageWatchers(true, address + 8, 32);
manager.UpdatePageWatchers(true, address + 128, 64);
Check(manager.HandleFault(PageFaultAccess::Write, address + 16),
"shared-watcher fault was not handled");
Check(!manager.IsTracked(address) && IsWritable(memory),
"fault callback did not clear every shared watcher");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestReadWriteWatcherFault() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.UpdatePageWatchers(true, address, page_size,
Libs::Graphics::PageWatchMode::Write);
manager.UpdatePageWatchers(true, address, page_size,
Libs::Graphics::PageWatchMode::ReadWrite);
manager.UpdatePageWatchers(false, address, page_size,
Libs::Graphics::PageWatchMode::Write);
Check(Protection(memory) == PAGE_NOACCESS,
"read/write watcher did not install no-access protection");
Check(manager.HandleFault(PageFaultAccess::Read, address + 8),
"tracked read fault was not handled");
Check(Protection(memory) == PAGE_READWRITE && !manager.IsTracked(address),
"read fault did not release every watcher");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestPermittedMappedLateFaultsResume() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.UpdatePageWatchers(true, address, page_size);
manager.UpdatePageWatchers(false, address, page_size);
Check(manager.HandleFault(PageFaultAccess::Write, address),
"first delayed mapped write was not accepted");
Check(manager.HandleFault(PageFaultAccess::Write, address),
"second delayed mapped write was not accepted");
Check(manager.HandleFault(PageFaultAccess::Read, address),
"delayed mapped read was not accepted on readable backing");
DWORD old_protection = 0;
Check(VirtualProtect(memory, page_size, PAGE_READONLY, &old_protection) != 0 &&
old_protection == PAGE_READWRITE,
"failed to prepare intentional read-only protection");
Check(!manager.HandleFault(PageFaultAccess::Write, address),
"intentional read-only mapping accepted a write fault");
Check(VirtualProtect(memory, page_size, PAGE_READWRITE, &old_protection) != 0,
"failed to restore writable protection");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestPartialMappingUnmapPreservesTokens() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.OnGpuMap(address + 8, 16);
manager.UpdatePageWatchers(true, address, page_size,
Libs::Graphics::PageWatchMode::ReadWrite);
manager.UpdatePageWatchers(false, address, page_size,
Libs::Graphics::PageWatchMode::ReadWrite);
manager.OnGpuUnmap(address + 8, 16);
Check(manager.HandleFault(PageFaultAccess::Read, address),
"partial mapping unmap erased delayed read ownership");
Check(manager.HandleFault(PageFaultAccess::Write, address),
"partial mapping unmap erased delayed write ownership");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestNativeDelayedReadAfterModeDowngrade() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
memory[0] = 0x6d;
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.UpdatePageWatchers(true, address, page_size);
manager.UpdatePageWatchers(true, address, page_size,
Libs::Graphics::PageWatchMode::ReadWrite);
manager.UpdatePageWatchers(false, address, page_size);
Check(Protection(memory) == PAGE_NOACCESS,
"read/write ownership did not install no-access protection");
void *handler = AddVectoredExceptionHandler(1, NativeFaultHandler);
Check(handler != nullptr, "AddVectoredExceptionHandler failed");
Check(g_native_fault_manager.exchange(&manager, std::memory_order_acq_rel) ==
nullptr,
"native fault manager already installed");
g_native_fault_entered.store(false, std::memory_order_release);
g_release_native_fault.store(false, std::memory_order_release);
g_delay_native_fault.store(true, std::memory_order_release);
uint8_t value = 0;
std::thread reader(
[&] { value = *static_cast<volatile uint8_t *>(memory); });
while (!g_native_fault_entered.load(std::memory_order_acquire)) {
std::this_thread::yield();
}
manager.UpdatePageWatchers(true, address, page_size);
manager.UpdatePageWatchers(false, address, page_size,
Libs::Graphics::PageWatchMode::ReadWrite);
Check(Protection(memory) == PAGE_READONLY,
"mode downgrade did not restore readable protection");
manager.UpdatePageWatchers(true, address, page_size);
context.block = true;
bool write_handled = false;
std::thread writer([&] {
write_handled = manager.HandleFault(PageFaultAccess::Write, address);
});
while (!context.entered.load(std::memory_order_acquire)) {
std::this_thread::yield();
}
g_release_native_fault.store(true, std::memory_order_release);
reader.join();
context.release.store(true, std::memory_order_release);
writer.join();
g_delay_native_fault.store(false, std::memory_order_release);
Check(g_native_fault_manager.exchange(nullptr, std::memory_order_acq_rel) ==
&manager,
"native fault manager publication changed");
Check(RemoveVectoredExceptionHandler(handler) != 0,
"RemoveVectoredExceptionHandler failed");
Check(value == 0x6d && write_handled &&
context.calls.load(std::memory_order_relaxed) == 1,
"delayed read was not coalesced across write ownership/resolution");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestDelayedFaultAfterExplicitUnwatch() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.UpdatePageWatchers(true, address, page_size);
// Models a store that already raised an AV before another thread published
// explicit CPU dirtiness and removed the watcher.
manager.UpdatePageWatchers(false, address, page_size);
Check(manager.HandleFault(PageFaultAccess::Write, address),
"delayed watched write was not accepted after explicit unwatch");
Check(manager.HandleFault(PageFaultAccess::Write, address) &&
context.calls.load(std::memory_order_relaxed) == 0,
"second explicit-unwatch fault was not coalesced or dispatched invalidation");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestNativeAccessViolation() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.UpdatePageWatchers(true, address, page_size);
void *handler = AddVectoredExceptionHandler(1, NativeFaultHandler);
Check(handler != nullptr, "AddVectoredExceptionHandler failed");
Check(g_native_fault_manager.exchange(&manager, std::memory_order_acq_rel) ==
nullptr,
"native fault manager already installed");
*static_cast<volatile uint8_t *>(memory) = 0x5a;
Check(g_native_fault_manager.exchange(nullptr, std::memory_order_acq_rel) ==
&manager,
"native fault manager publication changed");
Check(RemoveVectoredExceptionHandler(handler) != 0,
"RemoveVectoredExceptionHandler failed");
Check(memory[0] == 0x5a && !manager.IsTracked(address) &&
context.calls.load(std::memory_order_relaxed) == 1,
"native access violation did not invalidate and resume the store");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestInvalidLateWriteTokenIsConsumed() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.UpdatePageWatchers(true, address, page_size);
Check(manager.HandleFault(PageFaultAccess::Write, address),
"initial write fault was not handled");
DWORD old_protection = 0;
Check(VirtualProtect(memory, page_size, PAGE_READONLY, &old_protection) !=
0 &&
old_protection == PAGE_READWRITE,
"failed to create invalid late-write protection state");
Check(!manager.HandleFault(PageFaultAccess::Write, address) &&
!manager.HandleFault(PageFaultAccess::Write, address),
"invalid late-write token was accepted or retained");
Check(VirtualProtect(memory, page_size, PAGE_READWRITE, &old_protection) != 0,
"failed to restore test protection");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestCrossRegionRange() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
constexpr uint64_t region_size = 4ull * 1024ull * 1024ull;
auto *memory = Allocate(region_size * 2);
const auto base = reinterpret_cast<uint64_t>(memory);
const auto boundary = (base + region_size - 1) & ~(region_size - 1);
Check(boundary >= base + page_size &&
boundary + page_size <= base + region_size * 2,
"test allocation does not contain a region boundary");
manager.OnGpuMap(base, region_size * 2);
manager.UpdatePageWatchers(true, boundary - page_size, page_size * 2);
Check(!IsWritable(reinterpret_cast<void *>(boundary - page_size)) &&
!IsWritable(reinterpret_cast<void *>(boundary)),
"cross-region watch did not protect both pages");
manager.UpdatePageWatchers(false, boundary - page_size, page_size * 2);
Check(IsWritable(reinterpret_cast<void *>(boundary - page_size)) &&
IsWritable(reinterpret_cast<void *>(boundary)),
"cross-region unwatch did not restore both pages");
manager.OnGpuUnmap(base, region_size * 2);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
[[noreturn]] void RunDeathCase(const char *name) {
FaultContext context;
auto manager = std::make_unique<PageManager>(InvalidateFault, &context);
context.manager = manager.get();
const auto page_size = manager->GetPageSize();
if (std::strcmp(name, "invalid-range") == 0) {
manager->UpdatePageWatchers(true, (1ull << 40u) - 1, 2);
} else if (std::strcmp(name, "unknown-untrack") == 0) {
manager->UpdatePageWatchers(false, 0x1000, page_size);
} else {
const bool two_pages = std::strcmp(name, "cross-reentrant") == 0;
auto *memory = Allocate(
two_pages ? page_size * 2 : page_size,
std::strcmp(name, "protection") == 0 ? PAGE_READONLY : PAGE_READWRITE);
const auto address = reinterpret_cast<uint64_t>(memory);
manager->OnGpuMap(address, two_pages ? page_size * 2 : page_size);
manager->UpdatePageWatchers(true, address, page_size);
if (two_pages) {
manager->UpdatePageWatchers(true, address + page_size, page_size);
}
if (std::strcmp(name, "destructor-watch") == 0) {
manager.reset();
} else if (std::strcmp(name, "non-write") == 0) {
(void)manager->HandleFault(PageFaultAccess::Read, address);
} else if (std::strcmp(name, "callback-false") == 0) {
context.result = false;
(void)manager->HandleFault(PageFaultAccess::Write, address);
} else if (std::strcmp(name, "reentrant") == 0) {
context.reenter = true;
(void)manager->HandleFault(PageFaultAccess::Write, address);
} else if (std::strcmp(name, "cross-reentrant") == 0) {
context.reenter = true;
context.reenter_address = address + page_size;
(void)manager->HandleFault(PageFaultAccess::Write, address);
} else if (std::strcmp(name, "concurrent-non-write") == 0) {
context.block = true;
std::thread first(
[&] { (void)manager->HandleFault(PageFaultAccess::Write, address); });
while (!context.entered.load(std::memory_order_acquire)) {
std::this_thread::yield();
}
(void)manager->HandleFault(PageFaultAccess::Read, address);
first.join();
} else if (std::strcmp(name, "watched-unmap") == 0) {
manager->OnGpuUnmap(address, page_size);
} else if (std::strcmp(name, "protection") != 0) {
std::_Exit(0x7f);
}
}
std::_Exit(0x7f);
}
void CheckDeathCase(const char *name) {
char path[MAX_PATH]{};
Check(GetModuleFileNameA(nullptr, path, MAX_PATH) != 0,
"GetModuleFileName failed");
std::string command = std::string("\"") + path + "\" --death " + name;
std::vector<char> mutable_command(command.begin(), command.end());
mutable_command.push_back('\0');
STARTUPINFOA startup{sizeof(startup)};
PROCESS_INFORMATION process{};
Check(CreateProcessA(nullptr, mutable_command.data(), nullptr, nullptr, FALSE,
CREATE_NO_WINDOW, nullptr, nullptr, &startup,
&process) != 0,
"CreateProcess failed");
Check(WaitForSingleObject(process.hProcess, 10000) == WAIT_OBJECT_0,
"death test timed out");
DWORD exit_code = 0;
Check(
GetExitCodeProcess(process.hProcess, &exit_code) != 0 &&
(exit_code == 322 || exit_code == EXCEPTION_NONCONTINUABLE_EXCEPTION),
"death case did not use the PageManager fatal exit");
CloseHandle(process.hThread);
CloseHandle(process.hProcess);
}
void TestFatalPaths() {
for (const char *name :
{"invalid-range", "unknown-untrack", "destructor-watch", "non-write",
"callback-false", "reentrant", "cross-reentrant",
"concurrent-non-write", "watched-unmap", "protection"}) {
CheckDeathCase(name);
}
}
void TestConcurrentFault() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
context.block = true;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.UpdatePageWatchers(true, address, page_size);
bool first_result = false;
bool second_result = false;
std::thread first([&] {
first_result = manager.HandleFault(PageFaultAccess::Write, address);
});
while (!context.entered.load(std::memory_order_acquire)) {
std::this_thread::yield();
}
std::thread second([&] {
second_result = manager.HandleFault(PageFaultAccess::Write, address);
});
context.release.store(true, std::memory_order_release);
first.join();
second.join();
Check(first_result && second_result &&
context.calls.load(std::memory_order_relaxed) == 1,
"concurrent faults dispatched invalidation more than once");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestExternalDirtyTransferDuringResolution() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
context.block = true;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
manager.UpdatePageWatchers(true, address, page_size);
bool handled = false;
std::thread fault(
[&] { handled = manager.HandleFault(PageFaultAccess::Write, address); });
while (!context.entered.load(std::memory_order_acquire)) {
std::this_thread::yield();
}
manager.UpdatePageWatchers(false, address, page_size);
context.release.store(true, std::memory_order_release);
fault.join();
Check(handled && !manager.IsTracked(address) && IsWritable(memory),
"external dirty transfer did not satisfy active resolution");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestMappingDoesNotRequireCpuWriteAccess() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
DWORD old_protection = 0;
Check(VirtualProtect(memory, page_size, PAGE_NOACCESS, &old_protection) != 0 &&
old_protection == PAGE_READWRITE,
"failed to prepare CPU-inaccessible mapping");
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size);
Check(manager.IsMapped(address, page_size),
"CPU-inaccessible committed range was not GPU mapped");
manager.OnGpuUnmap(address, page_size);
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
void TestGpuAccessPermissions() {
FaultContext context;
PageManager manager(InvalidateFault, &context);
context.manager = &manager;
const auto page_size = manager.GetPageSize();
auto *memory = Allocate(page_size);
const auto address = reinterpret_cast<uint64_t>(memory);
manager.OnGpuMap(address, page_size, GpuAccess::Read);
Check(manager.HasGpuAccess(address, page_size, GpuAccess::Read) &&
!manager.HasGpuAccess(address, page_size, GpuAccess::Write),
"read-only GPU mapping granted write access");
manager.OnGpuMap(address, page_size, GpuAccess::Write);
Check(manager.HasGpuAccess(address, page_size, GpuAccess::ReadWrite),
"overlapping GPU mappings did not combine permissions");
manager.OnGpuUnmap(address, page_size, GpuAccess::Read);
Check(!manager.HasGpuAccess(address, page_size, GpuAccess::Read) &&
manager.HasGpuAccess(address, page_size, GpuAccess::Write),
"GPU read unmap removed the wrong permission");
manager.OnGpuUnmap(address, page_size, GpuAccess::Write);
Check(!manager.IsMapped(address, page_size),
"GPU permission mappings were not fully balanced");
Check(VirtualFree(memory, 0, MEM_RELEASE) != 0, "VirtualFree failed");
}
#endif
} // namespace
int main(int argc, char **argv) {
#if KYTY_PLATFORM == KYTY_PLATFORM_WINDOWS
if (argc == 3 && std::strcmp(argv[1], "--death") == 0) {
RunDeathCase(argv[2]);
}
TestWatchFaultAndUnwatch();
TestSharedWatcherFault();
TestReadWriteWatcherFault();
TestPermittedMappedLateFaultsResume();
TestPartialMappingUnmapPreservesTokens();
TestNativeDelayedReadAfterModeDowngrade();
TestDelayedFaultAfterExplicitUnwatch();
TestNativeAccessViolation();
TestInvalidLateWriteTokenIsConsumed();
TestCrossRegionRange();
TestConcurrentFault();
TestExternalDirtyTransferDuringResolution();
TestMappingDoesNotRequireCpuWriteAccess();
TestGpuAccessPermissions();
TestFatalPaths();
std::puts("PageManagerTests: all cases passed");
return 0;
#else
(void)argc;
(void)argv;
std::fputs("PageManagerTests: unsupported platform\n", stderr);
return 1;
#endif
}