/* * 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 . */ #include namespace ams::fs { namespace { Result ConvertNcaCorruptedResult(Result res) { AMS_ASSERT(fs::ResultNcaCorrupted::Includes(res)); R_TRY_CATCH(res) { R_CONVERT(fs::ResultInvalidNcaFileSystemType, fs::ResultInvalidRomNcaFileSystemType()) R_CONVERT(fs::ResultInvalidAcidFileSize, fs::ResultInvalidRomAcidFileSize()) R_CONVERT(fs::ResultInvalidAcidSize, fs::ResultInvalidRomAcidSize()) R_CONVERT(fs::ResultInvalidAcid, fs::ResultInvalidRomAcid()) R_CONVERT(fs::ResultAcidVerificationFailed, fs::ResultRomAcidVerificationFailed()) R_CONVERT(fs::ResultInvalidNcaSignature, fs::ResultInvalidRomNcaSignature()) R_CONVERT(fs::ResultNcaHeaderSignature1VerificationFailed, fs::ResultRomNcaHeaderSignature1VerificationFailed()) R_CONVERT(fs::ResultNcaHeaderSignature2VerificationFailed, fs::ResultRomNcaHeaderSignature2VerificationFailed()) R_CONVERT(fs::ResultNcaFsHeaderHashVerificationFailed, fs::ResultRomNcaFsHeaderHashVerificationFailed()) R_CONVERT(fs::ResultInvalidNcaKeyIndex, fs::ResultInvalidRomNcaKeyIndex()) R_CONVERT(fs::ResultInvalidNcaFsHeaderHashType, fs::ResultInvalidRomNcaFsHeaderHashType()) R_CONVERT(fs::ResultInvalidNcaFsHeaderEncryptionType, fs::ResultInvalidRomNcaFsHeaderEncryptionType()) R_CONVERT(fs::ResultInvalidHierarchicalSha256BlockSize, fs::ResultInvalidRomHierarchicalSha256BlockSize()) R_CONVERT(fs::ResultInvalidHierarchicalSha256LayerCount, fs::ResultInvalidRomHierarchicalSha256LayerCount()) R_CONVERT(fs::ResultHierarchicalSha256BaseStorageTooLarge, fs::ResultRomHierarchicalSha256BaseStorageTooLarge()) R_CONVERT(fs::ResultHierarchicalSha256HashVerificationFailed, fs::ResultRomHierarchicalSha256HashVerificationFailed()) R_CATCH_ALL() { /* ... */ } } R_END_TRY_CATCH; AMS_ASSERT(false); R_THROW(fs::ResultNcaCorrupted()); } Result ConvertIntegrityVerificationStorageCorruptedResult(Result res) { AMS_ASSERT(fs::ResultIntegrityVerificationStorageCorrupted::Includes(res)); R_TRY_CATCH(res) { R_CONVERT(fs::ResultIncorrectIntegrityVerificationMagic, fs::ResultIncorrectRomIntegrityVerificationMagic()) R_CONVERT(fs::ResultInvalidZeroHash, fs::ResultInvalidRomZeroHash()) R_CONVERT(fs::ResultNonRealDataVerificationFailed, fs::ResultRomNonRealDataVerificationFailed()) R_CONVERT(fs::ResultInvalidHierarchicalIntegrityVerificationLayerCount, fs::ResultInvalidRomHierarchicalIntegrityVerificationLayerCount()) R_CONVERT(fs::ResultClearedRealDataVerificationFailed, fs::ResultClearedRomRealDataVerificationFailed()) R_CONVERT(fs::ResultUnclearedRealDataVerificationFailed, fs::ResultUnclearedRomRealDataVerificationFailed()) R_CATCH_ALL() { /* ... */ } } R_END_TRY_CATCH; AMS_ASSERT(false); R_THROW(fs::ResultIntegrityVerificationStorageCorrupted()); } Result ConvertBuiltInStorageCorruptedResult(Result res) { AMS_ASSERT(fs::ResultBuiltInStorageCorrupted::Includes(res)); R_TRY_CATCH(res) { R_CONVERT(fs::ResultGptHeaderVerificationFailed, fs::ResultRomGptHeaderVerificationFailed()) R_CATCH_ALL() { /* ... */ } } R_END_TRY_CATCH; AMS_ASSERT(false); R_THROW(fs::ResultBuiltInStorageCorrupted()); } Result ConvertPartitionFileSystemCorruptedResult(Result res) { AMS_ASSERT(fs::ResultPartitionFileSystemCorrupted::Includes(res)); R_TRY_CATCH(res) { R_CONVERT(fs::ResultInvalidSha256PartitionHashTarget, fs::ResultInvalidRomSha256PartitionHashTarget()) R_CONVERT(fs::ResultSha256PartitionHashVerificationFailed, fs::ResultRomSha256PartitionHashVerificationFailed()) R_CONVERT(fs::ResultPartitionSignatureVerificationFailed, fs::ResultRomPartitionSignatureVerificationFailed()) R_CONVERT(fs::ResultSha256PartitionSignatureVerificationFailed, fs::ResultRomSha256PartitionSignatureVerificationFailed()) R_CONVERT(fs::ResultInvalidPartitionEntryOffset, fs::ResultInvalidRomPartitionEntryOffset()) R_CONVERT(fs::ResultInvalidSha256PartitionMetaDataSize, fs::ResultInvalidRomSha256PartitionMetaDataSize()) R_CATCH_ALL() { /* ... */ } } R_END_TRY_CATCH; AMS_ASSERT(false); R_THROW(fs::ResultPartitionFileSystemCorrupted()); } Result ConvertFatFileSystemCorruptedResult(Result res) { AMS_ASSERT(fs::ResultFatFileSystemCorrupted::Includes(res)); R_RETURN(res); } Result ConvertHostFileSystemCorruptedResult(Result res) { AMS_ASSERT(fs::ResultHostFileSystemCorrupted::Includes(res)); R_TRY_CATCH(res) { R_CONVERT(fs::ResultHostEntryCorrupted, fs::ResultRomHostEntryCorrupted()) R_CONVERT(fs::ResultHostFileDataCorrupted, fs::ResultRomHostFileDataCorrupted()) R_CONVERT(fs::ResultHostFileCorrupted, fs::ResultRomHostFileCorrupted()) R_CONVERT(fs::ResultInvalidHostHandle, fs::ResultInvalidRomHostHandle()) R_CATCH_ALL() { /* ... */ } } R_END_TRY_CATCH; AMS_ASSERT(false); R_THROW(fs::ResultHostFileSystemCorrupted()); } Result ConvertDatabaseCorruptedResult(Result res) { AMS_ASSERT(fs::ResultDatabaseCorrupted::Includes(res)); R_TRY_CATCH(res) { R_CONVERT(fs::ResultInvalidAllocationTableBlock, fs::ResultInvalidRomAllocationTableBlock()) R_CONVERT(fs::ResultInvalidKeyValueListElementIndex, fs::ResultInvalidRomKeyValueListElementIndex()) R_CATCH_ALL() { /* ... */ } } R_END_TRY_CATCH; AMS_ASSERT(false); R_THROW(fs::ResultDatabaseCorrupted()); } Result ConvertRomFsResult(Result res) { R_TRY_CATCH(res) { R_CONVERT(fs::ResultUnsupportedVersion, fs::ResultUnsupportedRomVersion()) R_CONVERT(fs::ResultNcaCorrupted, ConvertNcaCorruptedResult(res)) R_CONVERT(fs::ResultIntegrityVerificationStorageCorrupted, ConvertIntegrityVerificationStorageCorruptedResult(res)) R_CONVERT(fs::ResultBuiltInStorageCorrupted, ConvertBuiltInStorageCorruptedResult(res)) R_CONVERT(fs::ResultPartitionFileSystemCorrupted, ConvertPartitionFileSystemCorruptedResult(res)) R_CONVERT(fs::ResultFatFileSystemCorrupted, ConvertFatFileSystemCorruptedResult(res)) R_CONVERT(fs::ResultHostFileSystemCorrupted, ConvertHostFileSystemCorruptedResult(res)) R_CONVERT(fs::ResultDatabaseCorrupted, ConvertDatabaseCorruptedResult(res)) R_CONVERT(fs::ResultNotFound, fs::ResultPathNotFound()) R_CONVERT(fs::ResultPermissionDenied, fs::ResultTargetLocked()) R_CONVERT(fs::ResultIncompatiblePath, fs::ResultPathNotFound()) } R_END_TRY_CATCH; R_SUCCEED(); } Result ReadFile(IStorage *storage, s64 offset, void *buffer, size_t size) { AMS_ASSERT(storage != nullptr); AMS_ASSERT(offset >= 0); AMS_ASSERT(buffer != nullptr || size == 0); R_RETURN(ConvertRomFsResult(storage->Read(offset, buffer, size))); } Result ReadFileHeader(IStorage *storage, RomFileSystemInformation *out) { AMS_ASSERT(storage != nullptr); AMS_ASSERT(out != nullptr); R_RETURN(ReadFile(storage, 0, out, sizeof(*out))); } constexpr size_t CalculateRequiredWorkingMemorySize(const RomFileSystemInformation &header) { const size_t needed_size = header.directory_bucket_size + header.directory_entry_size + header.file_bucket_size + header.file_entry_size; return util::AlignUp(needed_size, 8); } class RomFsFile : public fsa::IFile, public impl::Newable { private: RomFsFileSystem *m_parent; s64 m_start; s64 m_end; public: RomFsFile(RomFsFileSystem *p, s64 s, s64 e) : m_parent(p), m_start(s), m_end(e) { /* ... */ } virtual ~RomFsFile() { /* ... */ } Result VerifyArguments(size_t *out, s64 offset, void *buf, size_t size, const fs::ReadOption &option) { R_TRY(DryRead(out, offset, size, option, fs::OpenMode_Read)); AMS_ASSERT(this->GetStorage() != nullptr); AMS_ASSERT(offset >= 0); AMS_ASSERT(buf != nullptr || size == 0); AMS_UNUSED(buf); R_SUCCEED(); } Result ConvertResult(Result res) const { R_RETURN(ConvertRomFsResult(res)); } s64 GetOffset() const { return m_start; } s64 GetSize() const { return m_end - m_start; } IStorage *GetStorage() { return m_parent->GetBaseStorage(); } public: virtual Result DoRead(size_t *out, s64 offset, void *buffer, size_t size, const fs::ReadOption &option) override { size_t read_size = 0; R_TRY(this->VerifyArguments(std::addressof(read_size), offset, buffer, size, option)); R_TRY(this->ConvertResult(this->GetStorage()->Read(offset + m_start, buffer, size))); *out = read_size; R_SUCCEED(); } virtual Result DoGetSize(s64 *out) override { *out = this->GetSize(); R_SUCCEED(); } virtual Result DoFlush() override { R_SUCCEED(); } virtual Result DoWrite(s64 offset, const void *buffer, size_t size, const fs::WriteOption &option) override { AMS_UNUSED(offset, buffer, size, option); R_THROW(fs::ResultUnsupportedWriteForRomFsFile()); } virtual Result DoSetSize(s64 size) override { AMS_UNUSED(size); R_THROW(fs::ResultUnsupportedWriteForRomFsFile()); } virtual Result DoOperateRange(void *dst, size_t dst_size, fs::OperationId op_id, s64 offset, s64 size, const void *src, size_t src_size) override { switch (op_id) { case OperationId::Invalidate: R_RETURN(this->GetStorage()->OperateRange(fs::OperationId::Invalidate, 0, std::numeric_limits::max())); case OperationId::QueryRange: { R_UNLESS(offset >= 0, fs::ResultInvalidOffset()); R_UNLESS(this->GetSize() >= offset, fs::ResultOutOfRange()); auto operate_size = size; if (offset + operate_size > this->GetSize() || offset + operate_size < offset) { operate_size = this->GetSize() - offset; } R_RETURN(this->GetStorage()->OperateRange(dst, dst_size, op_id, m_start + offset, operate_size, src, src_size)); } default: R_THROW(fs::ResultUnsupportedOperateRangeForRomFsFile()); } } public: virtual sf::cmif::DomainObjectId GetDomainObjectId() const override { AMS_ABORT(); } }; class RomFsDirectory : public fsa::IDirectory, public impl::Newable { private: using FindPosition = RomFsFileSystem::RomFileTable::FindPosition; private: RomFsFileSystem *m_parent; FindPosition m_current_find; FindPosition m_first_find; fs::OpenDirectoryMode m_mode; public: RomFsDirectory(RomFsFileSystem *p, const FindPosition &f, fs::OpenDirectoryMode m) : m_parent(p), m_current_find(f), m_first_find(f), m_mode(m) { /* ... */ } virtual ~RomFsDirectory() override { /* ... */ } public: virtual Result DoRead(s64 *out_count, DirectoryEntry *out_entries, s64 max_entries) override { R_RETURN(this->ReadInternal(out_count, std::addressof(m_current_find), out_entries, max_entries)); } virtual Result DoGetEntryCount(s64 *out) override { FindPosition find = m_first_find; R_RETURN(this->ReadInternal(out, std::addressof(find), nullptr, 0)); } private: Result ReadInternal(s64 *out_count, FindPosition *find, DirectoryEntry *out_entries, s64 max_entries) { AMS_ASSERT(out_count != nullptr); AMS_ASSERT(find != nullptr); constexpr size_t NameBufferSize = fs::EntryNameLengthMax + 1; char *name_buf = static_cast(::ams::fs::impl::Allocate(NameBufferSize)); R_UNLESS(name_buf != nullptr, fs::ResultAllocationMemoryFailedInRomFsFileSystemE()); ON_SCOPE_EXIT { ::ams::fs::impl::Deallocate(name_buf, NameBufferSize); }; s32 i = 0; if (m_mode & fs::OpenDirectoryMode_Directory) { while (i < max_entries || out_entries == nullptr) { R_TRY_CATCH(m_parent->GetRomFileTable()->FindNextDirectory(name_buf, find, NameBufferSize)) { R_CATCH(fs::ResultDbmFindFinished) { break; } } R_END_TRY_CATCH; if (out_entries) { const size_t name_len = util::Strnlen(name_buf, NameBufferSize); R_UNLESS(name_len < NameBufferSize, fs::ResultTooLongPath()); std::memcpy(out_entries[i].name, name_buf, name_len); out_entries[i].name[name_len] = '\x00'; out_entries[i].type = fs::DirectoryEntryType_Directory; out_entries[i].file_size = 0; } i++; } } if (m_mode & fs::OpenDirectoryMode_File) { while (i < max_entries || out_entries == nullptr) { auto file_pos = find->next_file; R_TRY_CATCH(m_parent->GetRomFileTable()->FindNextFile(name_buf, find, NameBufferSize)) { R_CATCH(fs::ResultDbmFindFinished) { break; } } R_END_TRY_CATCH; if (out_entries) { const size_t name_len = util::Strnlen(name_buf, NameBufferSize); R_UNLESS(name_len < NameBufferSize, fs::ResultTooLongPath()); std::memcpy(out_entries[i].name, name_buf, name_len); out_entries[i].name[name_len] = '\x00'; out_entries[i].type = fs::DirectoryEntryType_File; RomFsFileSystem::RomFileTable::FileInfo file_info; R_TRY(m_parent->GetRomFileTable()->OpenFile(std::addressof(file_info), m_parent->GetRomFileTable()->PositionToFileId(file_pos))); out_entries[i].file_size = file_info.size.Get(); } i++; } } *out_count = i; R_SUCCEED(); } public: virtual sf::cmif::DomainObjectId GetDomainObjectId() const override { AMS_ABORT(); } }; } RomFsFileSystem::RomFsFileSystem() : m_base_storage() { /* ... */ } RomFsFileSystem::~RomFsFileSystem() { /* ... */ } Result RomFsFileSystem::GetRequiredWorkingMemorySize(size_t *out, IStorage *storage) { RomFileSystemInformation header; R_TRY(ReadFileHeader(storage, std::addressof(header))); *out = CalculateRequiredWorkingMemorySize(header); R_SUCCEED(); } Result RomFsFileSystem::Initialize(IStorage *base, void *work, size_t work_size, bool use_cache) { AMS_ABORT_UNLESS(!use_cache || work != nullptr); AMS_ABORT_UNLESS(base != nullptr); /* Read the header. */ RomFileSystemInformation header; R_TRY(ReadFileHeader(base, std::addressof(header))); /* Set up our storages. */ if (use_cache) { const size_t needed_size = CalculateRequiredWorkingMemorySize(header); R_UNLESS(work_size >= needed_size, fs::ResultPreconditionViolation()); u8 *buf = static_cast(work); auto dir_bucket_buf = buf; buf += header.directory_bucket_size; auto dir_entry_buf = buf; buf += header.directory_entry_size; auto file_bucket_buf = buf; buf += header.file_bucket_size; auto file_entry_buf = buf; buf += header.file_entry_size; R_TRY(ReadFile(base, header.directory_bucket_offset, dir_bucket_buf, header.directory_bucket_size)); R_TRY(ReadFile(base, header.directory_entry_offset, dir_entry_buf, header.directory_entry_size)); R_TRY(ReadFile(base, header.file_bucket_offset, file_bucket_buf, header.file_bucket_size)); R_TRY(ReadFile(base, header.file_entry_offset, file_entry_buf, header.file_entry_size)); m_dir_bucket_storage.reset(new MemoryStorage(dir_bucket_buf, header.directory_bucket_size)); m_dir_entry_storage.reset(new MemoryStorage(dir_entry_buf, header.directory_entry_size)); m_file_bucket_storage.reset(new MemoryStorage(file_bucket_buf, header.file_bucket_size)); m_file_entry_storage.reset(new MemoryStorage(file_entry_buf, header.file_entry_size)); } else { m_dir_bucket_storage.reset(new SubStorage(base, header.directory_bucket_offset, header.directory_bucket_size)); m_dir_entry_storage.reset(new SubStorage(base, header.directory_entry_offset, header.directory_entry_size)); m_file_bucket_storage.reset(new SubStorage(base, header.file_bucket_offset, header.file_bucket_size)); m_file_entry_storage.reset(new SubStorage(base, header.file_entry_offset, header.file_entry_size)); } /* Ensure we allocated storages successfully. */ R_UNLESS(m_dir_bucket_storage != nullptr, fs::ResultAllocationMemoryFailedInRomFsFileSystemA()); R_UNLESS(m_dir_entry_storage != nullptr, fs::ResultAllocationMemoryFailedInRomFsFileSystemA()); R_UNLESS(m_file_bucket_storage != nullptr, fs::ResultAllocationMemoryFailedInRomFsFileSystemA()); R_UNLESS(m_file_entry_storage != nullptr, fs::ResultAllocationMemoryFailedInRomFsFileSystemA()); /* Initialize the rom table. */ { SubStorage db(m_dir_bucket_storage.get(), 0, header.directory_bucket_size); SubStorage de(m_dir_entry_storage.get(), 0, header.directory_entry_size); SubStorage fb(m_file_bucket_storage.get(), 0, header.file_bucket_size); SubStorage fe(m_file_entry_storage.get(), 0, header.file_entry_size); R_TRY(m_rom_file_table.Initialize(db, de, fb, fe)); } /* Set members. */ m_entry_size = header.body_offset; m_base_storage = base; R_SUCCEED(); } Result RomFsFileSystem::Initialize(std::unique_ptr&& base, void *work, size_t work_size, bool use_cache) { m_unique_storage = std::move(base); R_RETURN(this->Initialize(m_unique_storage.get(), work, work_size, use_cache)); } Result RomFsFileSystem::GetFileInfo(RomFileTable::FileInfo *out, const char *path) { R_TRY_CATCH(m_rom_file_table.OpenFile(out, path)) { R_CONVERT(fs::ResultDbmNotFound, fs::ResultPathNotFound()); R_CONVERT(fs::ResultDbmInvalidOperation, fs::ResultPathNotFound()); } R_END_TRY_CATCH; R_SUCCEED(); } IStorage *RomFsFileSystem::GetBaseStorage() { return m_base_storage; } RomFsFileSystem::RomFileTable *RomFsFileSystem::GetRomFileTable() { return std::addressof(m_rom_file_table); } Result RomFsFileSystem::GetFileBaseOffset(s64 *out, const char *path) { AMS_ABORT_UNLESS(out != nullptr); AMS_ABORT_UNLESS(path != nullptr); RomFileTable::FileInfo info; R_TRY(this->GetFileInfo(std::addressof(info), path)); *out = m_entry_size + info.offset.Get(); R_SUCCEED(); } Result RomFsFileSystem::DoCreateFile(const fs::Path &path, s64 size, int flags) { AMS_UNUSED(path, size, flags); R_THROW(fs::ResultUnsupportedWriteForRomFsFileSystem()); } Result RomFsFileSystem::DoDeleteFile(const fs::Path &path) { AMS_UNUSED(path); R_THROW(fs::ResultUnsupportedWriteForRomFsFileSystem()); } Result RomFsFileSystem::DoCreateDirectory(const fs::Path &path) { AMS_UNUSED(path); R_THROW(fs::ResultUnsupportedWriteForRomFsFileSystem()); } Result RomFsFileSystem::DoDeleteDirectory(const fs::Path &path) { AMS_UNUSED(path); R_THROW(fs::ResultUnsupportedWriteForRomFsFileSystem()); } Result RomFsFileSystem::DoDeleteDirectoryRecursively(const fs::Path &path) { AMS_UNUSED(path); R_THROW(fs::ResultUnsupportedWriteForRomFsFileSystem()); } Result RomFsFileSystem::DoRenameFile(const fs::Path &old_path, const fs::Path &new_path) { AMS_UNUSED(old_path, new_path); R_THROW(fs::ResultUnsupportedWriteForRomFsFileSystem()); } Result RomFsFileSystem::DoRenameDirectory(const fs::Path &old_path, const fs::Path &new_path) { AMS_UNUSED(old_path, new_path); R_THROW(fs::ResultUnsupportedWriteForRomFsFileSystem()); } Result RomFsFileSystem::DoGetEntryType(fs::DirectoryEntryType *out, const fs::Path &path) { RomDirectoryInfo dir_info; R_TRY_CATCH(m_rom_file_table.GetDirectoryInformation(std::addressof(dir_info), path.GetString())) { R_CONVERT(fs::ResultDbmNotFound, fs::ResultPathNotFound()) R_CATCH(fs::ResultDbmInvalidOperation) { RomFileTable::FileInfo file_info; R_TRY(this->GetFileInfo(std::addressof(file_info), path.GetString())); *out = fs::DirectoryEntryType_File; R_SUCCEED(); } } R_END_TRY_CATCH; *out = fs::DirectoryEntryType_Directory; R_SUCCEED(); } Result RomFsFileSystem::DoOpenFile(std::unique_ptr *out_file, const fs::Path &path, fs::OpenMode mode) { AMS_ASSERT(out_file != nullptr); R_UNLESS((mode & fs::OpenMode_All) == fs::OpenMode_Read, fs::ResultInvalidOpenMode()); RomFileTable::FileInfo file_info; R_TRY(this->GetFileInfo(std::addressof(file_info), path.GetString())); auto file = std::make_unique(this, m_entry_size + file_info.offset.Get(), m_entry_size + file_info.offset.Get() + file_info.size.Get()); R_UNLESS(file != nullptr, fs::ResultAllocationMemoryFailedInRomFsFileSystemB()); *out_file = std::move(file); R_SUCCEED(); } Result RomFsFileSystem::DoOpenDirectory(std::unique_ptr *out_dir, const fs::Path &path, fs::OpenDirectoryMode mode) { AMS_ASSERT(out_dir != nullptr); RomFileTable::FindPosition find; R_TRY_CATCH(m_rom_file_table.FindOpen(std::addressof(find), path.GetString())) { R_CONVERT(fs::ResultDbmNotFound, fs::ResultPathNotFound()) R_CONVERT(fs::ResultDbmInvalidOperation, fs::ResultPathNotFound()) } R_END_TRY_CATCH; auto dir = std::make_unique(this, find, mode); R_UNLESS(dir != nullptr, fs::ResultAllocationMemoryFailedInRomFsFileSystemC()); *out_dir = std::move(dir); R_SUCCEED(); } Result RomFsFileSystem::DoCommit() { R_SUCCEED(); } Result RomFsFileSystem::DoGetFreeSpaceSize(s64 *out, const fs::Path &path) { AMS_UNUSED(path); *out = 0; R_SUCCEED(); } Result RomFsFileSystem::DoGetTotalSpaceSize(s64 *out, const fs::Path &path) { AMS_UNUSED(out, path); R_THROW(fs::ResultUnsupportedGetTotalSpaceSizeForRomFsFileSystem()); } Result RomFsFileSystem::DoCleanDirectoryRecursively(const fs::Path &path) { AMS_UNUSED(path); R_THROW(fs::ResultUnsupportedWriteForRomFsFileSystem()); } Result RomFsFileSystem::DoCommitProvisionally(s64 counter) { AMS_UNUSED(counter); R_THROW(fs::ResultUnsupportedCommitProvisionallyForRomFsFileSystem()); } Result RomFsFileSystem::DoRollback() { R_SUCCEED(); } }