/* * Copyright (c) 2018 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 . */ #include #include #include "dmnt_cheat_manager.hpp" #include "dmnt_cheat_vm.hpp" #include "dmnt_config.hpp" #include "pm_shim.h" static HosMutex g_cheat_lock; static HosThread g_detect_thread, g_vm_thread; static IEvent *g_cheat_process_event; static DmntCheatVm *g_cheat_vm; static CheatProcessMetadata g_cheat_process_metadata = {0}; static Handle g_cheat_process_debug_hnd = 0; /* Global cheat entry storage. */ static CheatEntry g_cheat_entries[DmntCheatManager::MaxCheatCount]; /* Global frozen address storage. */ static std::map g_frozen_addresses_map; void DmntCheatManager::CloseActiveCheatProcess() { if (g_cheat_process_debug_hnd != 0) { /* Close process resources. */ svcCloseHandle(g_cheat_process_debug_hnd); g_cheat_process_debug_hnd = 0; g_cheat_process_metadata = (CheatProcessMetadata){0}; /* Clear cheat list. */ ResetAllCheatEntries(); /* Clear frozen addresses. */ ResetFrozenAddresses(); /* Signal to our fans. */ g_cheat_process_event->Signal(); } } bool DmntCheatManager::HasActiveCheatProcess() { u64 tmp; bool has_cheat_process = g_cheat_process_debug_hnd != 0; if (has_cheat_process) { has_cheat_process &= R_SUCCEEDED(svcGetProcessId(&tmp, g_cheat_process_debug_hnd)); } if (has_cheat_process) { has_cheat_process &= R_SUCCEEDED(pmdmntGetApplicationPid(&tmp)); } if (has_cheat_process) { has_cheat_process &= tmp == g_cheat_process_metadata.process_id; } if (!has_cheat_process) { CloseActiveCheatProcess(); } return has_cheat_process; } void DmntCheatManager::ContinueCheatProcess() { if (HasActiveCheatProcess()) { /* Loop getting debug events. */ u64 debug_event_buf[0x50]; while (R_SUCCEEDED(svcGetDebugEvent((u8 *)debug_event_buf, g_cheat_process_debug_hnd))) { /* ... */ } /* Continue the process. */ if (kernelAbove300()) { svcContinueDebugEvent(g_cheat_process_debug_hnd, 5, nullptr, 0); } else { svcLegacyContinueDebugEvent(g_cheat_process_debug_hnd, 5, 0); } } } Result DmntCheatManager::ReadCheatProcessMemoryForVm(u64 proc_addr, void *out_data, size_t size) { if (HasActiveCheatProcess()) { return svcReadDebugProcessMemory(out_data, g_cheat_process_debug_hnd, proc_addr, size); } return ResultDmntCheatNotAttached; } Result DmntCheatManager::WriteCheatProcessMemoryForVm(u64 proc_addr, const void *data, size_t size) { if (HasActiveCheatProcess()) { Result rc = svcWriteDebugProcessMemory(g_cheat_process_debug_hnd, data, proc_addr, size); /* We might have a frozen address. Update it if we do! */ if (R_SUCCEEDED(rc)) { for (auto & [address, value] : g_frozen_addresses_map) { /* Map is in order, so break here. */ if (address >= proc_addr + size) { break; } /* Check if we need to write. */ if (proc_addr <= address) { const size_t offset = (address - proc_addr); const size_t size_to_copy = size - offset; memcpy(&value.value, (void *)((uintptr_t)data + offset), size_to_copy < sizeof(value.value) ? size_to_copy : sizeof(value.value)); } } } return rc; } return ResultDmntCheatNotAttached; } Result DmntCheatManager::GetCheatProcessMappingCount(u64 *out_count) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } MemoryInfo mem_info; u64 address = 0; *out_count = 0; do { mem_info.perm = 0; u32 tmp; if (R_FAILED(svcQueryDebugProcessMemory(&mem_info, &tmp, g_cheat_process_debug_hnd, address))) { break; } if (mem_info.perm != 0) { *out_count += 1; } address = mem_info.addr + mem_info.size; } while (address != 0); return 0; } Result DmntCheatManager::GetCheatProcessMappings(MemoryInfo *mappings, size_t max_count, u64 *out_count, u64 offset) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } MemoryInfo mem_info; u64 address = 0; u64 count = 0; *out_count = 0; do { mem_info.perm = 0; u32 tmp; if (R_FAILED(svcQueryDebugProcessMemory(&mem_info, &tmp, g_cheat_process_debug_hnd, address))) { break; } if (mem_info.perm != 0) { count++; if (count > offset) { mappings[(*out_count)++] = mem_info; } } address = mem_info.addr + mem_info.size; } while (address != 0 && *out_count < max_count); return 0; } Result DmntCheatManager::ReadCheatProcessMemory(u64 proc_addr, void *out_data, size_t size) { std::scoped_lock lk(g_cheat_lock); return ReadCheatProcessMemoryForVm(proc_addr, out_data, size); } Result DmntCheatManager::WriteCheatProcessMemory(u64 proc_addr, const void *data, size_t size) { std::scoped_lock lk(g_cheat_lock); return WriteCheatProcessMemoryForVm(proc_addr, data, size); } Result DmntCheatManager::QueryCheatProcessMemory(MemoryInfo *mapping, u64 address) { std::scoped_lock lk(g_cheat_lock); if (HasActiveCheatProcess()) { u32 tmp; return svcQueryDebugProcessMemory(mapping, &tmp, g_cheat_process_debug_hnd, address); } return ResultDmntCheatNotAttached; } void DmntCheatManager::ResetFrozenAddresses() { /* Just clear the map. */ g_frozen_addresses_map.clear(); } void DmntCheatManager::ResetCheatEntry(size_t i) { if (i < DmntCheatManager::MaxCheatCount) { g_cheat_entries[i].enabled = false; g_cheat_entries[i].cheat_id = i; g_cheat_entries[i].definition = {0}; } } void DmntCheatManager::ResetAllCheatEntries() { for (size_t i = 0; i < DmntCheatManager::MaxCheatCount; i++) { ResetCheatEntry(i); } } CheatEntry *DmntCheatManager::GetFreeCheatEntry() { /* Check all non-master cheats for availability. */ for (size_t i = 1; i < DmntCheatManager::MaxCheatCount; i++) { if (g_cheat_entries[i].definition.num_opcodes == 0) { return &g_cheat_entries[i]; } } return nullptr; } CheatEntry *DmntCheatManager::GetCheatEntryById(size_t i) { if (i < DmntCheatManager::MaxCheatCount) { return &g_cheat_entries[i]; } return nullptr; } bool DmntCheatManager::ParseCheats(const char *s, size_t len) { size_t i = 0; CheatEntry *cur_entry = NULL; while (i < len) { if (isspace(s[i])) { /* Just ignore space. */ i++; } else if (s[i] == '[') { /* Parse a readable cheat name. */ cur_entry = GetFreeCheatEntry(); if (cur_entry == NULL) { return false; } /* Extract name bounds. */ size_t j = i + 1; while (s[j] != ']') { j++; if (j >= len || (j - i - 1) >= sizeof(cur_entry->definition.readable_name)) { return false; } } /* s[i+1:j] is cheat name. */ const size_t cheat_name_len = (j - i - 1); memcpy(cur_entry->definition.readable_name, &s[i+1], cheat_name_len); cur_entry->definition.readable_name[cheat_name_len] = 0; /* Skip onwards. */ i = j + 1; } else if (s[i] == '{') { /* We're parsing a master cheat. */ cur_entry = &g_cheat_entries[0]; /* There can only be one master cheat. */ if (cur_entry->definition.num_opcodes > 0) { return false; } /* Extract name bounds */ size_t j = i + 1; while (s[j] != '}') { j++; if (j >= len || (j - i - 1) >= sizeof(cur_entry->definition.readable_name)) { return false; } } /* s[i+1:j] is cheat name. */ const size_t cheat_name_len = (j - i - 1); memcpy(cur_entry->definition.readable_name, &s[i+1], cheat_name_len); cur_entry->definition.readable_name[cheat_name_len] = 0; /* Skip onwards. */ i = j + 1; } else if (isxdigit(s[i])) { /* Make sure that we have a cheat open. */ if (cur_entry == NULL) { return false; } /* Bounds check the opcode count. */ if (cur_entry->definition.num_opcodes >= sizeof(cur_entry->definition.opcodes)/sizeof(cur_entry->definition.opcodes[0])) { return false; } /* We're parsing an instruction, so validate it's 8 hex digits. */ for (size_t j = 1; j < 8; j++) { /* Validate 8 hex chars. */ if (i + j >= len || !isxdigit(s[i+j])) { return false; } } /* Parse the new opcode. */ char hex_str[9] = {0}; memcpy(hex_str, &s[i], 8); cur_entry->definition.opcodes[cur_entry->definition.num_opcodes++] = strtoul(hex_str, NULL, 16); /* Skip onwards. */ i += 8; } else { /* Unexpected character encountered. */ return false; } } /* Enable all entries we parsed. */ for (size_t i = 0; i < DmntCheatManager::MaxCheatCount; i++) { if (g_cheat_entries[i].definition.num_opcodes > 0) { g_cheat_entries[i].enabled = true; } } return true; } bool DmntCheatManager::LoadCheats(u64 title_id, const u8 *build_id) { /* Reset existing entries. */ ResetAllCheatEntries(); FILE *f_cht = NULL; /* Open the file for title/build_id. */ { char path[FS_MAX_PATH+1] = {0}; snprintf(path, FS_MAX_PATH, "sdmc:/atmosphere/titles/%016lx/cheats/%02x%02x%02x%02x%02x%02x%02x%02x.txt", title_id, build_id[0], build_id[1], build_id[2], build_id[3], build_id[4], build_id[5], build_id[6], build_id[7]); f_cht = fopen(path, "rb"); } /* Check for NULL */ if (f_cht == NULL) { return false; } ON_SCOPE_EXIT { fclose(f_cht); }; /* Get file size. */ fseek(f_cht, 0L, SEEK_END); const size_t cht_sz = ftell(f_cht); fseek(f_cht, 0L, SEEK_SET); /* Allocate cheat txt buffer. */ char *cht_txt = (char *)malloc(cht_sz + 1); if (cht_txt == NULL) { return false; } ON_SCOPE_EXIT { free(cht_txt); }; /* Read cheats into buffer. */ if (fread(cht_txt, 1, cht_sz, f_cht) != cht_sz) { return false; } cht_txt[cht_sz] = 0; /* Parse cheat buffer. */ return ParseCheats(cht_txt, strlen(cht_txt)); } Result DmntCheatManager::GetCheatCount(u64 *out_count) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } *out_count = 0; for (size_t i = 0; i < DmntCheatManager::MaxCheatCount; i++) { if (g_cheat_entries[i].definition.num_opcodes > 0) { *out_count += 1; } } return 0; } Result DmntCheatManager::GetCheats(CheatEntry *cheats, size_t max_count, u64 *out_count, u64 offset) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } u64 count = 0; *out_count = 0; for (size_t i = 0; i < DmntCheatManager::MaxCheatCount && (*out_count) < max_count; i++) { if (g_cheat_entries[i].definition.num_opcodes > 0) { count++; if (count > offset) { cheats[(*out_count)++] = g_cheat_entries[i]; } } } return 0; } Result DmntCheatManager::GetCheatById(CheatEntry *out_cheat, u32 cheat_id) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } const CheatEntry *entry = GetCheatEntryById(cheat_id); if (entry == nullptr || entry->definition.num_opcodes == 0) { return ResultDmntCheatUnknownChtId; } *out_cheat = *entry; return 0; } Result DmntCheatManager::ToggleCheat(u32 cheat_id) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } CheatEntry *entry = GetCheatEntryById(cheat_id); if (entry == nullptr || entry->definition.num_opcodes == 0) { return ResultDmntCheatUnknownChtId; } entry->enabled = !entry->enabled; return 0; } Result DmntCheatManager::AddCheat(u32 *out_id, CheatDefinition *def, bool enabled) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } if (def->num_opcodes == 0 || def->num_opcodes > sizeof(def->opcodes)/sizeof(def->opcodes[0])) { return ResultDmntCheatInvalidCheat; } CheatEntry *new_entry = GetFreeCheatEntry(); if (new_entry == nullptr) { return ResultDmntCheatOutOfCheats; } new_entry->enabled = enabled; new_entry->definition = *def; return 0; } Result DmntCheatManager::RemoveCheat(u32 cheat_id) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } if (cheat_id >= DmntCheatManager::MaxCheatCount) { return ResultDmntCheatUnknownChtId; } ResetCheatEntry(cheat_id); return 0; } Result DmntCheatManager::GetFrozenAddressCount(u64 *out_count) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } *out_count = g_frozen_addresses_map.size(); return 0; } Result DmntCheatManager::GetFrozenAddresses(FrozenAddressEntry *frz_addrs, size_t max_count, u64 *out_count, u64 offset) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } u64 count = 0; *out_count = 0; for (auto const& [address, value] : g_frozen_addresses_map) { if ((*out_count) >= max_count) { break; } count++; if (count > offset) { const u64 cur_ind = (*out_count)++; frz_addrs[cur_ind].address = address; frz_addrs[cur_ind].value = value; } } return 0; } Result DmntCheatManager::GetFrozenAddress(FrozenAddressEntry *frz_addr, u64 address) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } const auto it = g_frozen_addresses_map.find(address); if (it == g_frozen_addresses_map.end()) { return ResultDmntCheatAddressNotFrozen; } frz_addr->address = it->first; frz_addr->value = it->second; return 0; } Result DmntCheatManager::EnableFrozenAddress(u64 *out_value, u64 address, u64 width) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } if (g_frozen_addresses_map.size() >= DmntCheatManager::MaxFrozenAddressCount) { return ResultDmntCheatTooManyFrozenAddresses; } const auto it = g_frozen_addresses_map.find(address); if (it != g_frozen_addresses_map.end()) { return ResultDmntCheatAddressAlreadyFrozen; } Result rc; FrozenAddressValue value = {0}; value.width = width; if (R_FAILED((rc = ReadCheatProcessMemoryForVm(address, &value.value, width)))) { return rc; } g_frozen_addresses_map[address] = value; *out_value = value.value; return 0; } Result DmntCheatManager::DisableFrozenAddress(u64 address) { std::scoped_lock lk(g_cheat_lock); if (!HasActiveCheatProcess()) { return ResultDmntCheatNotAttached; } const auto it = g_frozen_addresses_map.find(address); if (it == g_frozen_addresses_map.end()) { return ResultDmntCheatAddressNotFrozen; } g_frozen_addresses_map.erase(address); return 0; } Handle DmntCheatManager::PrepareDebugNextApplication() { Result rc; Handle event_h; if (R_FAILED((rc = pmdmntEnableDebugForApplication(&event_h)))) { fatalSimple(rc); } return event_h; } static void PopulateMemoryExtents(MemoryRegionExtents *extents, Handle p_h, u64 id_base, u64 id_size) { Result rc; /* Get base extent. */ if (R_FAILED((rc = svcGetInfo(&extents->base, id_base, p_h, 0)))) { fatalSimple(rc); } /* Get size extent. */ if (R_FAILED((rc = svcGetInfo(&extents->size, id_size, p_h, 0)))) { fatalSimple(rc); } } static void StartDebugProcess(u64 pid) { Result rc = pmdmntStartProcess(pid); if (R_FAILED(rc)) { fatalSimple(rc); } } Result DmntCheatManager::ForceOpenCheatProcess() { std::scoped_lock lk(g_cheat_lock); Result rc; if (HasActiveCheatProcess()) { return 0; } /* Get the current application process ID. */ if (R_FAILED((rc = pmdmntGetApplicationPid(&g_cheat_process_metadata.process_id)))) { return rc; } ON_SCOPE_EXIT { if (R_FAILED(rc)) { g_cheat_process_metadata.process_id = 0; } }; /* Get process handle, use it to learn memory extents. */ { Handle proc_h = 0; ON_SCOPE_EXIT { if (proc_h != 0) { svcCloseHandle(proc_h); } }; if (R_FAILED((rc = pmdmntAtmosphereGetProcessInfo(&proc_h, &g_cheat_process_metadata.title_id, nullptr, g_cheat_process_metadata.process_id)))) { return rc; } /* Get memory extents. */ PopulateMemoryExtents(&g_cheat_process_metadata.heap_extents, proc_h, 4, 5); PopulateMemoryExtents(&g_cheat_process_metadata.alias_extents, proc_h, 2, 3); if (kernelAbove200()) { PopulateMemoryExtents(&g_cheat_process_metadata.address_space_extents, proc_h, 12, 13); } else { g_cheat_process_metadata.address_space_extents.base = 0x08000000UL; g_cheat_process_metadata.address_space_extents.size = 0x78000000UL; } } /* Get module information from Loader. */ { LoaderModuleInfo proc_modules[2]; u32 num_modules; if (R_FAILED((rc = ldrDmntGetModuleInfos(g_cheat_process_metadata.process_id, proc_modules, sizeof(proc_modules), &num_modules)))) { return rc; } /* All applications must have two modules. */ /* However, this is a force-open, so we will accept one module. */ /* Poor HBL, I guess... */ LoaderModuleInfo *proc_module; if (num_modules == 2) { proc_module = &proc_modules[1]; } else if (num_modules == 1) { proc_module = &proc_modules[0]; } else { rc = ResultDmntCheatNotAttached; return rc; } g_cheat_process_metadata.main_nso_extents.base = proc_module->base_address; g_cheat_process_metadata.main_nso_extents.size = proc_module->size; memcpy(g_cheat_process_metadata.main_nso_build_id, proc_module->build_id, sizeof(g_cheat_process_metadata.main_nso_build_id)); } /* Read cheats off the SD. */ /* This is allowed to fail. We may not have any cheats. */ LoadCheats(g_cheat_process_metadata.title_id, g_cheat_process_metadata.main_nso_build_id); /* Open a debug handle. */ if (R_FAILED((rc = svcDebugActiveProcess(&g_cheat_process_debug_hnd, g_cheat_process_metadata.process_id)))) { return rc; } /* Continue debug events, etc. */ ContinueCheatProcess(); /* Signal to our fans. */ g_cheat_process_event->Signal(); return rc; } void DmntCheatManager::OnNewApplicationLaunch() { std::scoped_lock lk(g_cheat_lock); Result rc; /* Close the current application, if it's open. */ CloseActiveCheatProcess(); /* Get the new application's process ID. */ if (R_FAILED((rc = pmdmntGetApplicationPid(&g_cheat_process_metadata.process_id)))) { fatalSimple(rc); } /* Get process handle, use it to learn memory extents. */ { Handle proc_h = 0; ON_SCOPE_EXIT { if (proc_h != 0) { svcCloseHandle(proc_h); } }; if (R_FAILED((rc = pmdmntAtmosphereGetProcessInfo(&proc_h, &g_cheat_process_metadata.title_id, nullptr, g_cheat_process_metadata.process_id)))) { fatalSimple(rc); } /* Get memory extents. */ PopulateMemoryExtents(&g_cheat_process_metadata.heap_extents, proc_h, 4, 5); PopulateMemoryExtents(&g_cheat_process_metadata.alias_extents, proc_h, 2, 3); if (kernelAbove200()) { PopulateMemoryExtents(&g_cheat_process_metadata.address_space_extents, proc_h, 12, 13); } else { g_cheat_process_metadata.address_space_extents.base = 0x08000000UL; g_cheat_process_metadata.address_space_extents.size = 0x78000000UL; } } /* Check if we should skip based on keys down. */ if (!DmntConfigManager::HasCheatEnableButton(g_cheat_process_metadata.title_id)) { StartDebugProcess(g_cheat_process_metadata.process_id); g_cheat_process_metadata.process_id = 0; return; } /* Get module information from Loader. */ { LoaderModuleInfo proc_modules[2]; u32 num_modules; if (R_FAILED((rc = ldrDmntGetModuleInfos(g_cheat_process_metadata.process_id, proc_modules, sizeof(proc_modules), &num_modules)))) { fatalSimple(rc); } /* All applications must have two modules. */ /* If we only have one, we must be e.g. mitming HBL. */ /* We don't want to fuck with HBL. */ if (num_modules != 2) { StartDebugProcess(g_cheat_process_metadata.process_id); g_cheat_process_metadata.process_id = 0; return; } g_cheat_process_metadata.main_nso_extents.base = proc_modules[1].base_address; g_cheat_process_metadata.main_nso_extents.size = proc_modules[1].size; memcpy(g_cheat_process_metadata.main_nso_build_id, proc_modules[1].build_id, sizeof(g_cheat_process_metadata.main_nso_build_id)); } /* Read cheats off the SD. */ if (!LoadCheats(g_cheat_process_metadata.title_id, g_cheat_process_metadata.main_nso_build_id)) { /* If we don't have cheats, or cheats are malformed, don't attach. */ StartDebugProcess(g_cheat_process_metadata.process_id); g_cheat_process_metadata.process_id = 0; return; } /* Open a debug handle. */ if (R_FAILED((rc = svcDebugActiveProcess(&g_cheat_process_debug_hnd, g_cheat_process_metadata.process_id)))) { fatalSimple(rc); } /* Start the process. */ StartDebugProcess(g_cheat_process_metadata.process_id); /* Continue debug events, etc. */ ContinueCheatProcess(); /* Signal to our fans. */ g_cheat_process_event->Signal(); } void DmntCheatManager::DetectThread(void *arg) { auto waiter = new WaitableManager(1); waiter->AddWaitable(LoadReadOnlySystemEvent(PrepareDebugNextApplication(), [](u64 timeout) { /* Process stuff for new application. */ DmntCheatManager::OnNewApplicationLaunch(); /* Setup detection for the next application, and close the duplicate handle. */ svcCloseHandle(PrepareDebugNextApplication()); return 0x0; }, true)); waiter->Process(); delete waiter; } void DmntCheatManager::VmThread(void *arg) { while (true) { /* Execute Cheat VM. */ { /* Acquire lock. */ std::scoped_lock lk(g_cheat_lock); if (HasActiveCheatProcess()) { /* Handle any pending debug events. */ ContinueCheatProcess(); /* Execute VM. */ if (g_cheat_vm->LoadProgram(g_cheat_entries, DmntCheatManager::MaxCheatCount)) { if (g_cheat_vm->GetProgramSize() != 0) { g_cheat_vm->Execute(&g_cheat_process_metadata); } } /* Apply frozen addresses. */ for (auto const& [address, value] : g_frozen_addresses_map) { WriteCheatProcessMemoryForVm(address, &value.value, value.width); } } } svcSleepThread(0x5000000ul); } } bool DmntCheatManager::GetHasActiveCheatProcess() { std::scoped_lock lk(g_cheat_lock); return HasActiveCheatProcess(); } Handle DmntCheatManager::GetCheatProcessEventHandle() { return g_cheat_process_event->GetHandle(); } Result DmntCheatManager::GetCheatProcessMetadata(CheatProcessMetadata *out) { std::scoped_lock lk(g_cheat_lock); if (HasActiveCheatProcess()) { *out = g_cheat_process_metadata; return 0; } return ResultDmntCheatNotAttached; } void DmntCheatManager::InitializeCheatManager() { /* Create cheat process detection event. */ g_cheat_process_event = CreateWriteOnlySystemEvent(); /* Create cheat vm. */ g_cheat_vm = new DmntCheatVm(); /* Spawn application detection thread, spawn cheat vm thread. */ if (R_FAILED(g_detect_thread.Initialize(&DmntCheatManager::DetectThread, nullptr, 0x4000, 28))) { std::abort(); } if (R_FAILED(g_vm_thread.Initialize(&DmntCheatManager::VmThread, nullptr, 0x4000, 28))) { std::abort(); } /* Start threads. */ if (R_FAILED(g_detect_thread.Start()) || R_FAILED(g_vm_thread.Start())) { std::abort(); } }