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Atmosphere/stratosphere/pm/source/impl/pm_process_manager.cpp
SciresM f2ee44da74
romfs/ams.mitm/pm: refactor to dynamically steal heap for certain games. (#2122) 
* fs.mitm: skeleton the use of special allocation in romfs build

* pm: add api for ams.mitm to steal application memory

* pm/mitm: okay, that api won't work, try a different one

* romfs: revert memory usage increases; we'll handle torture games case-by-case.

* pm/romfs: first (broken?) pass at dynamic heap.

I cannot wait to figure out all the ways this is wrong.

* Release the dynamic heap a little more eagerly

* romfs: animal crossing is also not a nice game

* romfs: fix issues in close-during-build

* romfs: zelda is a blight upon this earth
2023-05-14 03:06:52 -07:00

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/*
* Copyright (c) Atmosphère-NX
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stratosphere.hpp>
#include "pm_process_manager.hpp"
#include "pm_resource_manager.hpp"
#include "pm_process_info.hpp"
namespace ams::pm::impl {
namespace {
/* Types. */
enum HookType {
HookType_ProgramId = (1 << 0),
HookType_Application = (1 << 1),
};
struct LaunchProcessArgs {
os::ProcessId *out_process_id;
ncm::ProgramLocation location;
u32 flags;
};
#define GET_FLAG_MASK(flag) (hos_version >= hos::Version_5_0_0 ? static_cast<u32>(LaunchFlags_##flag) : static_cast<u32>(LaunchFlagsDeprecated_##flag))
inline bool ShouldSignalOnExit(u32 launch_flags) {
const auto hos_version = hos::GetVersion();
return launch_flags & GET_FLAG_MASK(SignalOnExit);
}
inline bool ShouldSignalOnStart(u32 launch_flags) {
const auto hos_version = hos::GetVersion();
if (hos_version < hos::Version_2_0_0) {
return false;
}
return launch_flags & GET_FLAG_MASK(SignalOnStart);
}
inline bool ShouldSignalOnException(u32 launch_flags) {
const auto hos_version = hos::GetVersion();
return launch_flags & GET_FLAG_MASK(SignalOnException);
}
inline bool ShouldSignalOnDebugEvent(u32 launch_flags) {
const auto hos_version = hos::GetVersion();
return launch_flags & GET_FLAG_MASK(SignalOnDebugEvent);
}
inline bool ShouldStartSuspended(u32 launch_flags) {
const auto hos_version = hos::GetVersion();
return launch_flags & GET_FLAG_MASK(StartSuspended);
}
inline bool ShouldDisableAslr(u32 launch_flags) {
const auto hos_version = hos::GetVersion();
return launch_flags & GET_FLAG_MASK(DisableAslr);
}
#undef GET_FLAG_MASK
template<size_t MaxProcessInfos>
class ProcessInfoAllocator {
NON_COPYABLE(ProcessInfoAllocator);
NON_MOVEABLE(ProcessInfoAllocator);
static_assert(MaxProcessInfos >= 0x40, "MaxProcessInfos is too small.");
private:
util::TypedStorage<ProcessInfo> m_process_info_storages[MaxProcessInfos]{};
bool m_process_info_allocated[MaxProcessInfos]{};
os::SdkMutex m_lock{};
private:
constexpr inline size_t GetProcessInfoIndex(ProcessInfo *process_info) const {
return process_info - GetPointer(m_process_info_storages[0]);
}
public:
constexpr ProcessInfoAllocator() = default;
template<typename... Args>
ProcessInfo *AllocateProcessInfo(Args &&... args) {
std::scoped_lock lk(m_lock);
for (size_t i = 0; i < MaxProcessInfos; i++) {
if (!m_process_info_allocated[i]) {
m_process_info_allocated[i] = true;
std::memset(m_process_info_storages + i, 0, sizeof(m_process_info_storages[i]));
return util::ConstructAt(m_process_info_storages[i], std::forward<Args>(args)...);
}
}
return nullptr;
}
void FreeProcessInfo(ProcessInfo *process_info) {
std::scoped_lock lk(m_lock);
const size_t index = this->GetProcessInfoIndex(process_info);
AMS_ABORT_UNLESS(index < MaxProcessInfos);
AMS_ABORT_UNLESS(m_process_info_allocated[index]);
util::DestroyAt(m_process_info_storages[index]);
m_process_info_allocated[index] = false;
}
};
/* Process Tracking globals. */
void ProcessTrackingMain(void *);
constinit os::ThreadType g_process_track_thread;
alignas(os::ThreadStackAlignment) constinit u8 g_process_track_thread_stack[16_KB];
/* Process lists. */
constinit ProcessList g_process_list;
constinit ProcessList g_dead_process_list;
/* Process Info Allocation. */
/* Note: The kernel slabheap is size 0x50 -- we allow slightly larger to account for the dead process list. */
constexpr size_t MaxProcessCount = 0x60;
constinit ProcessInfoAllocator<MaxProcessCount> g_process_info_allocator;
/* Global events. */
constinit os::SystemEventType g_process_event;
constinit os::SystemEventType g_hook_to_create_process_event;
constinit os::SystemEventType g_hook_to_create_application_process_event;
constinit os::SystemEventType g_boot_finished_event;
/* Process Launch synchronization globals. */
constinit os::SdkMutex g_launch_program_lock;
os::Event g_process_launch_start_event(os::EventClearMode_AutoClear);
os::Event g_process_launch_finish_event(os::EventClearMode_AutoClear);
constinit Result g_process_launch_result = ResultSuccess();
constinit LaunchProcessArgs g_process_launch_args = {};
/* Hook globals. */
constinit std::atomic<ncm::ProgramId> g_program_id_hook;
constinit std::atomic<bool> g_application_hook;
/* Forward declarations. */
Result LaunchProcess(os::MultiWaitType &multi_wait, const LaunchProcessArgs &args);
void OnProcessSignaled(ProcessListAccessor &list, ProcessInfo *process_info);
/* Helpers. */
void ProcessTrackingMain(void *) {
/* This is the main loop of the process tracking thread. */
/* Setup multi wait/holders. */
os::MultiWaitType process_multi_wait;
os::MultiWaitHolderType start_event_holder;
os::InitializeMultiWait(std::addressof(process_multi_wait));
os::InitializeMultiWaitHolder(std::addressof(start_event_holder), g_process_launch_start_event.GetBase());
os::LinkMultiWaitHolder(std::addressof(process_multi_wait), std::addressof(start_event_holder));
while (true) {
auto signaled_holder = os::WaitAny(std::addressof(process_multi_wait));
if (signaled_holder == std::addressof(start_event_holder)) {
/* Launch start event signaled. */
/* TryWait will clear signaled, preventing duplicate notifications. */
if (g_process_launch_start_event.TryWait()) {
g_process_launch_result = LaunchProcess(process_multi_wait, g_process_launch_args);
g_process_launch_finish_event.Signal();
}
} else {
/* Some process was signaled. */
ProcessListAccessor list(g_process_list);
OnProcessSignaled(list, reinterpret_cast<ProcessInfo *>(os::GetMultiWaitHolderUserData(signaled_holder)));
}
}
}
inline u32 GetLoaderCreateProcessFlags(u32 launch_flags) {
u32 ldr_flags = 0;
if (ShouldSignalOnException(launch_flags) || (hos::GetVersion() >= hos::Version_2_0_0 && !ShouldStartSuspended(launch_flags))) {
ldr_flags |= ldr::CreateProcessFlag_EnableDebug;
}
if (ShouldDisableAslr(launch_flags)) {
ldr_flags |= ldr::CreateProcessFlag_DisableAslr;
}
return ldr_flags;
}
bool HasApplicationProcess() {
ProcessListAccessor list(g_process_list);
for (auto &process : *list) {
if (process.IsApplication()) {
return true;
}
}
return false;
}
Result StartProcess(ProcessInfo *process_info, const ldr::ProgramInfo *program_info) {
R_TRY(svc::StartProcess(process_info->GetHandle(), program_info->main_thread_priority, program_info->default_cpu_id, program_info->main_thread_stack_size));
process_info->SetState(svc::ProcessState_Running);
R_SUCCEED();
}
void CleanupProcessInfo(ProcessListAccessor &list, ProcessInfo *process_info) {
/* Remove the process from the list. */
list->Remove(process_info);
/* Delete the process. */
g_process_info_allocator.FreeProcessInfo(process_info);
}
Result LaunchProcess(os::MultiWaitType &multi_wait, const LaunchProcessArgs &args) {
/* Get Program Info. */
ldr::ProgramInfo program_info;
cfg::OverrideStatus override_status;
R_TRY(ldr::pm::AtmosphereGetProgramInfo(std::addressof(program_info), std::addressof(override_status), args.location));
const bool is_application = (program_info.flags & ldr::ProgramInfoFlag_ApplicationTypeMask) == ldr::ProgramInfoFlag_Application;
const bool allow_debug = (program_info.flags & ldr::ProgramInfoFlag_AllowDebug) || hos::GetVersion() < hos::Version_2_0_0;
/* Ensure we only try to run one application. */
R_UNLESS(!is_application || !HasApplicationProcess(), pm::ResultApplicationRunning());
/* Fix the program location to use the right program id. */
const ncm::ProgramLocation location = ncm::ProgramLocation::Make(program_info.program_id, static_cast<ncm::StorageId>(args.location.storage_id));
/* Pin and create the process. */
os::NativeHandle process_handle;
ldr::PinId pin_id;
{
/* Pin the program with loader. */
R_TRY(ldr::pm::AtmospherePinProgram(std::addressof(pin_id), location, override_status));
/* If we fail after now, unpin. */
ON_RESULT_FAILURE { ldr::pm::UnpinProgram(pin_id); };
/* Ensure we can talk to mitm services. */
{
AMS_FUNCTION_LOCAL_STATIC_CONSTINIT(bool, s_initialized_mitm, false);
if (!s_initialized_mitm) {
mitm::pm::Initialize();
s_initialized_mitm = true;
}
}
/* Determine boost size for mitm. */
u64 mitm_boost_size = 0;
R_TRY(mitm::pm::PrepareLaunchProgram(std::addressof(mitm_boost_size), program_info.program_id, override_status, is_application));
if (mitm_boost_size > 0 || is_application) {
R_ABORT_UNLESS(BoostSystemMemoryResourceLimitForMitm(mitm_boost_size));
}
ON_RESULT_FAILURE_2 { if (mitm_boost_size > 0 || is_application) { R_ABORT_UNLESS(BoostSystemMemoryResourceLimitForMitm(0)); } };
/* Ensure resources are available. */
resource::WaitResourceAvailable(std::addressof(program_info));
/* Actually create the process. */
R_TRY(ldr::pm::CreateProcess(std::addressof(process_handle), pin_id, GetLoaderCreateProcessFlags(args.flags), resource::GetResourceLimitHandle(std::addressof(program_info))));
}
/* Get the process id. */
os::ProcessId process_id = os::GetProcessId(process_handle);
/* Make new process info. */
ProcessInfo *process_info = g_process_info_allocator.AllocateProcessInfo(process_handle, process_id, pin_id, location, override_status);
AMS_ABORT_UNLESS(process_info != nullptr);
/* Link new process info. */
{
ProcessListAccessor list(g_process_list);
list->push_back(*process_info);
process_info->LinkToMultiWait(multi_wait);
}
/* Prevent resource leakage if register fails. */
ON_RESULT_FAILURE {
ProcessListAccessor list(g_process_list);
process_info->Cleanup();
CleanupProcessInfo(list, process_info);
};
const u8 *acid_sac = program_info.ac_buffer;
const u8 *aci_sac = acid_sac + program_info.acid_sac_size;
const u8 *acid_fac = aci_sac + program_info.aci_sac_size;
const u8 *aci_fah = acid_fac + program_info.acid_fac_size;
/* Register with FS and SM. */
R_TRY(fsprRegisterProgram(static_cast<u64>(process_id), static_cast<u64>(location.program_id), static_cast<NcmStorageId>(location.storage_id), aci_fah, program_info.aci_fah_size, acid_fac, program_info.acid_fac_size));
R_TRY(sm::manager::RegisterProcess(process_id, location.program_id, override_status, acid_sac, program_info.acid_sac_size, aci_sac, program_info.aci_sac_size));
/* Set flags. */
if (is_application) {
process_info->SetApplication();
}
if (ShouldSignalOnStart(args.flags) && allow_debug) {
process_info->SetSignalOnStart();
}
if (ShouldSignalOnExit(args.flags)) {
process_info->SetSignalOnExit();
}
if (ShouldSignalOnDebugEvent(args.flags) && allow_debug) {
process_info->SetSignalOnDebugEvent();
}
/* Process hooks/signaling. */
if (location.program_id == g_program_id_hook) {
os::SignalSystemEvent(std::addressof(g_hook_to_create_process_event));
g_program_id_hook = ncm::InvalidProgramId;
} else if (is_application && g_application_hook) {
os::SignalSystemEvent(std::addressof(g_hook_to_create_application_process_event));
g_application_hook = false;
} else if (!ShouldStartSuspended(args.flags)) {
R_TRY(StartProcess(process_info, std::addressof(program_info)));
}
*args.out_process_id = process_id;
R_SUCCEED();
}
void OnProcessSignaled(ProcessListAccessor &list, ProcessInfo *process_info) {
/* Reset the process's signal. */
svc::ResetSignal(process_info->GetHandle());
/* Update the process's state. */
const svc::ProcessState old_state = process_info->GetState();
{
s64 tmp = 0;
R_ABORT_UNLESS(svc::GetProcessInfo(std::addressof(tmp), process_info->GetHandle(), svc::ProcessInfoType_ProcessState));
process_info->SetState(static_cast<svc::ProcessState>(tmp));
}
const svc::ProcessState new_state = process_info->GetState();
/* If we're transitioning away from crashed, clear waiting attached. */
if (old_state == svc::ProcessState_Crashed && new_state != svc::ProcessState_Crashed) {
process_info->ClearExceptionWaitingAttach();
}
switch (new_state) {
case svc::ProcessState_Created:
case svc::ProcessState_CreatedAttached:
case svc::ProcessState_Terminating:
break;
case svc::ProcessState_Running:
if (process_info->ShouldSignalOnDebugEvent()) {
process_info->ClearSuspended();
process_info->SetSuspendedStateChanged();
os::SignalSystemEvent(std::addressof(g_process_event));
} else if (hos::GetVersion() >= hos::Version_2_0_0 && process_info->ShouldSignalOnStart()) {
process_info->SetStartedStateChanged();
process_info->ClearSignalOnStart();
os::SignalSystemEvent(std::addressof(g_process_event));
}
process_info->ClearUnhandledException();
break;
case svc::ProcessState_Crashed:
if (!process_info->HasUnhandledException()) {
process_info->SetExceptionOccurred();
os::SignalSystemEvent(std::addressof(g_process_event));
}
process_info->SetExceptionWaitingAttach();
break;
case svc::ProcessState_RunningAttached:
if (process_info->ShouldSignalOnDebugEvent()) {
process_info->ClearSuspended();
process_info->SetSuspendedStateChanged();
os::SignalSystemEvent(std::addressof(g_process_event));
}
process_info->ClearUnhandledException();
break;
case svc::ProcessState_Terminated:
/* Free process resources, unlink from multi wait. */
process_info->Cleanup();
if (hos::GetVersion() < hos::Version_5_0_0 && process_info->ShouldSignalOnExit()) {
os::SignalSystemEvent(std::addressof(g_process_event));
} else {
/* Handle the case where we need to keep the process alive some time longer. */
if (hos::GetVersion() >= hos::Version_5_0_0 && process_info->ShouldSignalOnExit()) {
/* Remove from the living list. */
list->Remove(process_info);
/* Add the process to the list of dead processes. */
{
ProcessListAccessor dead_list(g_dead_process_list);
dead_list->push_back(*process_info);
}
/* Signal. */
os::SignalSystemEvent(std::addressof(g_process_event));
} else {
/* Actually delete process. */
CleanupProcessInfo(list, process_info);
}
}
break;
case svc::ProcessState_DebugBreak:
if (process_info->ShouldSignalOnDebugEvent()) {
process_info->SetSuspended();
process_info->SetSuspendedStateChanged();
os::SignalSystemEvent(std::addressof(g_process_event));
}
break;
}
}
}
/* Initialization. */
Result InitializeProcessManager() {
/* Create events. */
R_ABORT_UNLESS(os::CreateSystemEvent(std::addressof(g_process_event), os::EventClearMode_AutoClear, true));
R_ABORT_UNLESS(os::CreateSystemEvent(std::addressof(g_hook_to_create_process_event), os::EventClearMode_AutoClear, true));
R_ABORT_UNLESS(os::CreateSystemEvent(std::addressof(g_hook_to_create_application_process_event), os::EventClearMode_AutoClear, true));
R_ABORT_UNLESS(os::CreateSystemEvent(std::addressof(g_boot_finished_event), os::EventClearMode_AutoClear, true));
/* Initialize resource limits. */
R_TRY(resource::InitializeResourceManager());
/* Create thread. */
R_ABORT_UNLESS(os::CreateThread(std::addressof(g_process_track_thread), ProcessTrackingMain, nullptr, g_process_track_thread_stack, sizeof(g_process_track_thread_stack), AMS_GET_SYSTEM_THREAD_PRIORITY(pm, ProcessTrack)));
os::SetThreadNamePointer(std::addressof(g_process_track_thread), AMS_GET_SYSTEM_THREAD_NAME(pm, ProcessTrack));
/* Start thread. */
os::StartThread(std::addressof(g_process_track_thread));
R_SUCCEED();
}
/* Process Management. */
Result LaunchProgram(os::ProcessId *out_process_id, const ncm::ProgramLocation &loc, u32 flags) {
/* Ensure we only try to launch one program at a time. */
std::scoped_lock lk(g_launch_program_lock);
/* Set global arguments, signal, wait. */
g_process_launch_args = {
.out_process_id = out_process_id,
.location = loc,
.flags = flags,
};
g_process_launch_start_event.Signal();
g_process_launch_finish_event.Wait();
R_RETURN(g_process_launch_result);
}
Result StartProcess(os::ProcessId process_id) {
ProcessListAccessor list(g_process_list);
auto process_info = list->Find(process_id);
R_UNLESS(process_info != nullptr, pm::ResultProcessNotFound());
R_UNLESS(!process_info->HasStarted(), pm::ResultAlreadyStarted());
ldr::ProgramInfo program_info;
R_TRY(ldr::pm::GetProgramInfo(std::addressof(program_info), process_info->GetProgramLocation()));
R_RETURN(StartProcess(process_info, std::addressof(program_info)));
}
Result TerminateProcess(os::ProcessId process_id) {
ProcessListAccessor list(g_process_list);
auto process_info = list->Find(process_id);
R_UNLESS(process_info != nullptr, pm::ResultProcessNotFound());
R_RETURN(svc::TerminateProcess(process_info->GetHandle()));
}
Result TerminateProgram(ncm::ProgramId program_id) {
ProcessListAccessor list(g_process_list);
auto process_info = list->Find(program_id);
R_UNLESS(process_info != nullptr, pm::ResultProcessNotFound());
R_RETURN(svc::TerminateProcess(process_info->GetHandle()));
}
Result GetProcessEventHandle(os::NativeHandle *out) {
*out = os::GetReadableHandleOfSystemEvent(std::addressof(g_process_event));
R_SUCCEED();
}
Result GetProcessEventInfo(ProcessEventInfo *out) {
/* Check for event from current process. */
{
ProcessListAccessor list(g_process_list);
for (auto &process : *list) {
if (process.HasStarted() && process.HasStartedStateChanged()) {
process.ClearStartedStateChanged();
out->event = GetProcessEventValue(ProcessEvent::Started);
out->process_id = process.GetProcessId();
R_SUCCEED();
}
if (process.HasSuspendedStateChanged()) {
process.ClearSuspendedStateChanged();
if (process.IsSuspended()) {
out->event = GetProcessEventValue(ProcessEvent::DebugBreak);
} else {
out->event = GetProcessEventValue(ProcessEvent::DebugRunning);
}
out->process_id = process.GetProcessId();
R_SUCCEED();
}
if (process.HasExceptionOccurred()) {
process.ClearExceptionOccurred();
out->event = GetProcessEventValue(ProcessEvent::Exception);
out->process_id = process.GetProcessId();
R_SUCCEED();
}
if (hos::GetVersion() < hos::Version_5_0_0 && process.ShouldSignalOnExit() && process.HasTerminated()) {
out->event = GetProcessEventValue(ProcessEvent::Exited);
out->process_id = process.GetProcessId();
R_SUCCEED();
}
}
}
/* Check for event from exited process. */
if (hos::GetVersion() >= hos::Version_5_0_0) {
ProcessListAccessor dead_list(g_dead_process_list);
if (!dead_list->empty()) {
auto &process_info = dead_list->front();
out->event = GetProcessEventValue(ProcessEvent::Exited);
out->process_id = process_info.GetProcessId();
CleanupProcessInfo(dead_list, std::addressof(process_info));
R_SUCCEED();
}
}
out->process_id = os::ProcessId{};
out->event = GetProcessEventValue(ProcessEvent::None);
R_SUCCEED();
}
Result CleanupProcess(os::ProcessId process_id) {
ProcessListAccessor list(g_process_list);
auto process_info = list->Find(process_id);
R_UNLESS(process_info != nullptr, pm::ResultProcessNotFound());
R_UNLESS(process_info->HasTerminated(), pm::ResultNotTerminated());
CleanupProcessInfo(list, process_info);
R_SUCCEED();
}
Result ClearExceptionOccurred(os::ProcessId process_id) {
ProcessListAccessor list(g_process_list);
auto process_info = list->Find(process_id);
R_UNLESS(process_info != nullptr, pm::ResultProcessNotFound());
process_info->ClearExceptionOccurred();
R_SUCCEED();
}
/* Information Getters. */
Result GetModuleIdList(u32 *out_count, u8 *out_buf, size_t max_out_count, u64 unused) {
/* This function was always stubbed... */
AMS_UNUSED(out_buf, max_out_count, unused);
*out_count = 0;
R_SUCCEED();
}
Result GetExceptionProcessIdList(u32 *out_count, os::ProcessId *out_process_ids, size_t max_out_count) {
ProcessListAccessor list(g_process_list);
size_t count = 0;
if (max_out_count > 0) {
for (auto &process : *list) {
if (process.HasExceptionWaitingAttach()) {
out_process_ids[count++] = process.GetProcessId();
if (count >= max_out_count) {
break;
}
}
}
}
*out_count = static_cast<u32>(count);
R_SUCCEED();
}
Result GetProcessId(os::ProcessId *out, ncm::ProgramId program_id) {
ProcessListAccessor list(g_process_list);
auto process_info = list->Find(program_id);
R_UNLESS(process_info != nullptr, pm::ResultProcessNotFound());
*out = process_info->GetProcessId();
R_SUCCEED();
}
Result GetProgramId(ncm::ProgramId *out, os::ProcessId process_id) {
ProcessListAccessor list(g_process_list);
auto process_info = list->Find(process_id);
R_UNLESS(process_info != nullptr, pm::ResultProcessNotFound());
*out = process_info->GetProgramLocation().program_id;
R_SUCCEED();
}
Result GetApplicationProcessId(os::ProcessId *out_process_id) {
ProcessListAccessor list(g_process_list);
for (auto &process : *list) {
if (process.IsApplication()) {
*out_process_id = process.GetProcessId();
R_SUCCEED();
}
}
R_THROW(pm::ResultProcessNotFound());
}
Result AtmosphereGetProcessInfo(os::NativeHandle *out_process_handle, ncm::ProgramLocation *out_loc, cfg::OverrideStatus *out_status, os::ProcessId process_id) {
ProcessListAccessor list(g_process_list);
auto process_info = list->Find(process_id);
R_UNLESS(process_info != nullptr, pm::ResultProcessNotFound());
*out_process_handle = process_info->GetHandle();
*out_loc = process_info->GetProgramLocation();
*out_status = process_info->GetOverrideStatus();
R_SUCCEED();
}
/* Hook API. */
Result HookToCreateProcess(os::NativeHandle *out_hook, ncm::ProgramId program_id) {
*out_hook = os::InvalidNativeHandle;
{
ncm::ProgramId old_value = ncm::InvalidProgramId;
R_UNLESS(g_program_id_hook.compare_exchange_strong(old_value, program_id), pm::ResultDebugHookInUse());
}
*out_hook = os::GetReadableHandleOfSystemEvent(std::addressof(g_hook_to_create_process_event));
R_SUCCEED();
}
Result HookToCreateApplicationProcess(os::NativeHandle *out_hook) {
*out_hook = os::InvalidNativeHandle;
{
bool old_value = false;
R_UNLESS(g_application_hook.compare_exchange_strong(old_value, true), pm::ResultDebugHookInUse());
}
*out_hook = os::GetReadableHandleOfSystemEvent(std::addressof(g_hook_to_create_application_process_event));
R_SUCCEED();
}
Result ClearHook(u32 which) {
if (which & HookType_ProgramId) {
g_program_id_hook = ncm::InvalidProgramId;
}
if (which & HookType_Application) {
g_application_hook = false;
}
R_SUCCEED();
}
/* Boot API. */
Result NotifyBootFinished() {
AMS_FUNCTION_LOCAL_STATIC_CONSTINIT(bool, s_has_boot_finished, false);
if (!s_has_boot_finished) {
/* Set program verification disabled, if we should. */
/* NOTE: Nintendo does not check the result of this. */
if (spl::IsDisabledProgramVerification()) {
if (hos::GetVersion() >= hos::Version_10_0_0) {
ldr::pm::SetEnabledProgramVerification(false);
} else {
fsprSetEnabledProgramVerification(false);
}
}
boot2::LaunchPreSdCardBootProgramsAndBoot2();
s_has_boot_finished = true;
os::SignalSystemEvent(std::addressof(g_boot_finished_event));
}
R_SUCCEED();
}
Result GetBootFinishedEventHandle(os::NativeHandle *out) {
/* In 8.0.0, Nintendo added this command, which signals that the boot sysmodule has finished. */
/* Nintendo only signals it in safe mode FIRM, and this function aborts on normal FIRM. */
/* We will signal it always, but only allow this function to succeed on safe mode. */
AMS_ABORT_UNLESS(spl::IsRecoveryBoot());
*out = os::GetReadableHandleOfSystemEvent(std::addressof(g_boot_finished_event));
R_SUCCEED();
}
/* Resource Limit API. */
Result BoostSystemMemoryResourceLimit(u64 boost_size) {
R_RETURN(resource::BoostSystemMemoryResourceLimit(boost_size));
}
Result BoostApplicationThreadResourceLimit() {
R_RETURN(resource::BoostApplicationThreadResourceLimit());
}
Result BoostSystemThreadResourceLimit() {
R_RETURN(resource::BoostSystemThreadResourceLimit());
}
Result GetAppletCurrentResourceLimitValues(pm::ResourceLimitValues *out) {
R_RETURN(resource::GetCurrentResourceLimitValues(ResourceLimitGroup_Applet, out));
}
Result GetAppletPeakResourceLimitValues(pm::ResourceLimitValues *out) {
R_RETURN(resource::GetPeakResourceLimitValues(ResourceLimitGroup_Applet, out));
}
Result AtmosphereGetCurrentLimitInfo(s64 *out_cur_val, s64 *out_lim_val, u32 group, u32 resource) {
R_RETURN(resource::GetResourceLimitValues(out_cur_val, out_lim_val, static_cast<ResourceLimitGroup>(group), static_cast<svc::LimitableResource>(resource)));
}
Result BoostSystemMemoryResourceLimitForMitm(u64 boost_size) {
R_RETURN(resource::BoostSystemMemoryResourceLimitForMitm(boost_size));
}
}
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