/* * 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 #include "fssystem_read_only_block_cache_storage.hpp" #include "fssystem_hierarchical_sha256_storage.hpp" #include "fssystem_memory_resource_buffer_hold_storage.hpp" namespace ams::fssystem { namespace { constexpr inline s32 AesCtrExTableCacheBlockSize = AesCtrCounterExtendedStorage::NodeSize; constexpr inline s32 AesCtrExTableCacheCount = 8; constexpr inline s32 IndirectTableCacheBlockSize = IndirectStorage::NodeSize; constexpr inline s32 IndirectTableCacheCount = 8; constexpr inline s32 IndirectDataCacheBlockSize = 32_KB; constexpr inline s32 IndirectDataCacheCount = 16; constexpr inline s32 SparseTableCacheBlockSize = SparseStorage::NodeSize; constexpr inline s32 SparseTableCacheCount = 4; //TODO: Better names for these? //constexpr inline s32 CompressedDataBlockSize = 64_KB; //constexpr inline s32 CompressedContinuousReadingSizeMax = 640_KB; //constexpr inline s32 CompressedCacheBlockSize = 16_KB; //constexpr inline s32 CompressedCacheCount = 32; constexpr inline s32 AesCtrStorageCacheBlockSize = 0x200; constexpr inline s32 AesCtrStorageCacheCount = 9; class SharedNcaBodyStorage : public ::ams::fs::IStorage, public ::ams::fs::impl::Newable { NON_COPYABLE(SharedNcaBodyStorage); NON_MOVEABLE(SharedNcaBodyStorage); private: std::shared_ptr m_storage; std::shared_ptr m_nca_reader; public: SharedNcaBodyStorage(std::shared_ptr s, std::shared_ptr r) : m_storage(std::move(s)), m_nca_reader(std::move(r)) { /* ... */ } virtual Result Read(s64 offset, void *buffer, size_t size) override { /* Validate pre-conditions. */ AMS_ASSERT(m_storage != nullptr); /* Read from the base storage. */ return m_storage->Read(offset, buffer, size); } virtual Result GetSize(s64 *out) override { /* Validate pre-conditions. */ AMS_ASSERT(m_storage != nullptr); return m_storage->GetSize(out); } virtual Result Flush() override { /* Validate pre-conditions. */ AMS_ASSERT(m_storage != nullptr); return m_storage->Flush(); } virtual Result Write(s64 offset, const void *buffer, size_t size) override { /* Validate pre-conditions. */ AMS_ASSERT(m_storage != nullptr); /* Read from the base storage. */ return m_storage->Write(offset, buffer, size); } virtual Result SetSize(s64 size) override { /* Validate pre-conditions. */ AMS_ASSERT(m_storage != nullptr); return m_storage->SetSize(size); } virtual Result OperateRange(void *dst, size_t dst_size, fs::OperationId op_id, s64 offset, s64 size, const void *src, size_t src_size) override { /* Validate pre-conditions. */ AMS_ASSERT(m_storage != nullptr); return m_storage->OperateRange(dst, dst_size, op_id, offset, size, src, src_size); } }; class AesCtrStorageExternal : public ::ams::fs::IStorage, public ::ams::fs::impl::Newable { NON_COPYABLE(AesCtrStorageExternal); NON_MOVEABLE(AesCtrStorageExternal); public: static constexpr size_t BlockSize = crypto::Aes128CtrEncryptor::BlockSize; static constexpr size_t KeySize = crypto::Aes128CtrEncryptor::KeySize; static constexpr size_t IvSize = crypto::Aes128CtrEncryptor::IvSize; private: std::shared_ptr m_base_storage; u8 m_iv[IvSize]; DecryptAesCtrFunction m_decrypt_function; s32 m_key_index; u8 m_encrypted_key[KeySize]; public: AesCtrStorageExternal(std::shared_ptr bs, const void *enc_key, size_t enc_key_size, const void *iv, size_t iv_size, DecryptAesCtrFunction df, s32 kidx) : m_base_storage(std::move(bs)), m_decrypt_function(df), m_key_index(kidx) { AMS_ASSERT(bs != nullptr); AMS_ASSERT(enc_key_size == KeySize); AMS_ASSERT(iv != nullptr); AMS_ASSERT(iv_size == IvSize); AMS_UNUSED(iv_size); std::memcpy(m_iv, iv, IvSize); std::memcpy(m_encrypted_key, enc_key, enc_key_size); } virtual Result Read(s64 offset, void *buffer, size_t size) override { /* Allow zero size. */ R_SUCCEED_IF(size == 0); /* Validate arguments. */ /* NOTE: For some reason, Nintendo uses InvalidArgument instead of InvalidOffset/InvalidSize here. */ R_UNLESS(buffer != nullptr, fs::ResultNullptrArgument()); R_UNLESS(util::IsAligned(offset, BlockSize), fs::ResultInvalidArgument()); R_UNLESS(util::IsAligned(size, BlockSize), fs::ResultInvalidArgument()); /* Read the data. */ R_TRY(m_base_storage->Read(offset, buffer, size)); /* Temporarily increase our thread priority. */ ScopedThreadPriorityChanger cp(+1, ScopedThreadPriorityChanger::Mode::Relative); /* Allocate a pooled buffer for decryption. */ PooledBuffer pooled_buffer; pooled_buffer.AllocateParticularlyLarge(size, BlockSize); AMS_ASSERT(pooled_buffer.GetSize() >= BlockSize); /* Setup the counter. */ u8 ctr[IvSize]; std::memcpy(ctr, m_iv, IvSize); AddCounter(ctr, IvSize, offset / BlockSize); /* Setup tracking. */ size_t remaining_size = size; s64 cur_offset = 0; while (remaining_size > 0) { /* Get the current size to process. */ size_t cur_size = std::min(pooled_buffer.GetSize(), remaining_size); char *dst = static_cast(buffer) + cur_offset; /* Decrypt into the temporary buffer */ m_decrypt_function(pooled_buffer.GetBuffer(), cur_size, m_key_index, m_encrypted_key, KeySize, ctr, IvSize, dst, cur_size); /* Copy to the destination. */ std::memcpy(dst, pooled_buffer.GetBuffer(), cur_size); /* Update tracking. */ cur_offset += cur_size; remaining_size -= cur_size; if (remaining_size > 0) { AddCounter(ctr, IvSize, cur_size / BlockSize); } } return ResultSuccess(); } virtual Result OperateRange(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 fs::OperationId::QueryRange: { /* Validate that we have an output range info. */ R_UNLESS(dst != nullptr, fs::ResultNullptrArgument()); R_UNLESS(dst_size == sizeof(fs::QueryRangeInfo), fs::ResultInvalidSize()); /* Operate on our base storage. */ R_TRY(m_base_storage->OperateRange(dst, dst_size, op_id, offset, size, src, src_size)); /* Add in new flags. */ fs::QueryRangeInfo new_info; new_info.Clear(); new_info.aes_ctr_key_type = static_cast(m_key_index >= 0 ? fs::AesCtrKeyTypeFlag::InternalKeyForHardwareAes : fs::AesCtrKeyTypeFlag::ExternalKeyForHardwareAes); /* Merge the new info in. */ reinterpret_cast(dst)->Merge(new_info); return ResultSuccess(); } default: { /* Operate on our base storage. */ R_TRY(m_base_storage->OperateRange(dst, dst_size, op_id, offset, size, src, src_size)); return ResultSuccess(); } } } virtual Result GetSize(s64 *out) override { return m_base_storage->GetSize(out); } virtual Result Flush() override { return ResultSuccess(); } virtual Result Write(s64 offset, const void *buffer, size_t size) override { AMS_UNUSED(offset, buffer, size); return fs::ResultUnsupportedOperationInAesCtrStorageExternalA(); } virtual Result SetSize(s64 size) override { AMS_UNUSED(size); return fs::ResultUnsupportedOperationInAesCtrStorageExternalB(); } }; template class SwitchStorage : public ::ams::fs::IStorage, public ::ams::fs::impl::Newable { NON_COPYABLE(SwitchStorage); NON_MOVEABLE(SwitchStorage); private: std::shared_ptr m_true_storage; std::shared_ptr m_false_storage; F m_truth_function; private: ALWAYS_INLINE std::shared_ptr &SelectStorage() { return m_truth_function() ? m_true_storage : m_false_storage; } public: SwitchStorage(std::shared_ptr t, std::shared_ptr f, F func) : m_true_storage(std::move(t)), m_false_storage(std::move(f)), m_truth_function(func) { /* ... */ } virtual Result Read(s64 offset, void *buffer, size_t size) override { return this->SelectStorage()->Read(offset, buffer, size); } virtual Result OperateRange(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 fs::OperationId::Invalidate: { R_TRY(m_true_storage->OperateRange(dst, dst_size, op_id, offset, size, src, src_size)); R_TRY(m_false_storage->OperateRange(dst, dst_size, op_id, offset, size, src, src_size)); return ResultSuccess(); } case fs::OperationId::QueryRange: { R_TRY(this->SelectStorage()->OperateRange(dst, dst_size, op_id, offset, size, src, src_size)); return ResultSuccess(); } default: return fs::ResultUnsupportedOperationInSwitchStorageA(); } } virtual Result GetSize(s64 *out) override { return this->SelectStorage()->GetSize(out); } virtual Result Flush() override { return this->SelectStorage()->Flush(); } virtual Result Write(s64 offset, const void *buffer, size_t size) override { return this->SelectStorage()->Write(offset, buffer, size); } virtual Result SetSize(s64 size) override { return this->SelectStorage()->SetSize(size); } }; inline s64 GetFsOffset(const NcaReader &reader, s32 fs_index) { return static_cast(reader.GetFsOffset(fs_index)); } inline s64 GetFsEndOffset(const NcaReader &reader, s32 fs_index) { return static_cast(reader.GetFsEndOffset(fs_index)); } inline bool IsUsingHwAesCtrForSpeedEmulation() { auto mode = fssystem::SpeedEmulationConfiguration::GetSpeedEmulationMode(); return mode == fs::SpeedEmulationMode::None || mode == fs::SpeedEmulationMode::Slower; } using Sha256DataRegion = NcaFsHeader::Region; using IntegrityLevelInfo = NcaFsHeader::HashData::IntegrityMetaInfo::LevelHashInfo; using IntegrityDataInfo = IntegrityLevelInfo::HierarchicalIntegrityVerificationLevelInformation; // inline const Sha256DataRegion &GetSha256DataRegion(const NcaFsHeader::HashData &hash_data) { // return hash_data.hierarchical_sha256_data.hash_layer_region[1]; // } // inline const IntegrityDataInfo &GetIntegrityDataInfo(const NcaFsHeader::HashData &hash_data) { // return hash_data.integrity_meta_info.level_hash_info.info[hash_data.integrity_meta_info.level_hash_info.max_layers - 2]; // } } Result NcaFileSystemDriver::OpenStorageWithContext(std::shared_ptr *out, std::shared_ptr *out_splitter, NcaFsHeaderReader *out_header_reader, s32 fs_index, StorageContext *ctx) { /* Open storage. */ R_TRY(this->OpenStorageImpl(out, out_header_reader, fs_index, ctx)); /* If we have a compressed storage, use it as splitter. */ if (ctx->compressed_storage != nullptr) { *out_splitter = std::move(ctx->compressed_storage); } else { /* Otherwise, allocate a default splitter. */ *out_splitter = fssystem::AllocateShared(); R_UNLESS(*out_splitter != nullptr, fs::ResultAllocationFailureInAllocateShared()); } return ResultSuccess(); } Result NcaFileSystemDriver::OpenStorageImpl(std::shared_ptr *out, NcaFsHeaderReader *out_header_reader, s32 fs_index, StorageContext *ctx) { /* Validate preconditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(out_header_reader != nullptr); AMS_ASSERT(0 <= fs_index && fs_index < NcaHeader::FsCountMax); /* Validate the fs index. */ R_UNLESS(m_reader->HasFsInfo(fs_index), fs::ResultPartitionNotFound()); /* Initialize our header reader for the fs index. */ R_TRY(out_header_reader->Initialize(*m_reader, fs_index)); /* Declare the storage we're opening. */ std::shared_ptr storage; /* Process sparse layer. */ s64 fs_data_offset = 0; if (out_header_reader->ExistsSparseLayer()) { /* Create the sparse storage. */ R_TRY(this->CreateSparseStorage(std::addressof(storage), std::addressof(fs_data_offset), ctx != nullptr ? std::addressof(ctx->current_sparse_storage) : nullptr, ctx != nullptr ? std::addressof(ctx->sparse_storage_meta_storage) : nullptr, fs_index, out_header_reader->GetAesCtrUpperIv(), out_header_reader->GetSparseInfo())); } else { /* Get the data offsets. */ fs_data_offset = GetFsOffset(*m_reader, fs_index); const auto fs_end_offset = GetFsEndOffset(*m_reader, fs_index); /* Validate that we're within range. */ const auto data_size = fs_end_offset - fs_data_offset; R_UNLESS(data_size > 0, fs::ResultInvalidNcaHeader()); /* Create the body substorage. */ R_TRY(this->CreateBodySubStorage(std::addressof(storage), fs_data_offset, data_size)); /* Potentially save the body substorage to our context. */ if (ctx != nullptr) { ctx->body_substorage = storage; } } /* Process patch layer. */ const auto &patch_info = out_header_reader->GetPatchInfo(); if (patch_info.HasAesCtrExTable()) { /* Check the encryption type. */ AMS_ASSERT(out_header_reader->GetEncryptionType() == NcaFsHeader::EncryptionType::AesCtrEx); /* Create the ex meta storage. */ std::shared_ptr aes_ctr_ex_storage_meta_storage; R_TRY(this->CreateAesCtrExMetaStorage(std::addressof(aes_ctr_ex_storage_meta_storage), storage, fs_data_offset, out_header_reader->GetAesCtrUpperIv(), patch_info)); /* Create the ex storage. */ std::shared_ptr aes_ctr_ex_storage; R_TRY(this->CreateAesCtrExStorage(std::addressof(aes_ctr_ex_storage), ctx != nullptr ? std::addressof(ctx->aes_ctr_ex_storage) : nullptr, std::move(storage), aes_ctr_ex_storage_meta_storage, fs_data_offset, out_header_reader->GetAesCtrUpperIv(), patch_info)); /* Set the base storage as the ex storage. */ storage = std::move(aes_ctr_ex_storage); /* Potentially save storages to our context. */ if (ctx != nullptr) { ctx->aes_ctr_ex_storage_meta_storage = aes_ctr_ex_storage_meta_storage; ctx->aes_ctr_ex_storage_data_storage = storage; ctx->fs_data_storage = storage; } } else { /* Create the appropriate storage for the encryption type. */ switch (out_header_reader->GetEncryptionType()) { case NcaFsHeader::EncryptionType::None: /* If there's no encryption, use the base storage we made previously. */ break; case NcaFsHeader::EncryptionType::AesXts: R_TRY(this->CreateAesXtsStorage(std::addressof(storage), std::move(storage), fs_data_offset)); break; case NcaFsHeader::EncryptionType::AesCtr: R_TRY(this->CreateAesCtrStorage(std::addressof(storage), std::move(storage), fs_data_offset, out_header_reader->GetAesCtrUpperIv(), AlignmentStorageRequirement_None)); break; default: return fs::ResultInvalidNcaFsHeaderEncryptionType(); } /* Potentially save storages to our context. */ if (ctx != nullptr) { ctx->fs_data_storage = storage; } } /* Process indirect layer. */ if (patch_info.HasIndirectTable()) { /* Create the indirect meta storage */ std::shared_ptr indirect_storage_meta_storage; R_TRY(this->CreateIndirectStorageMetaStorage(std::addressof(indirect_storage_meta_storage), storage, patch_info)); /* Potentially save the indirect meta storage to our context. */ if (ctx != nullptr) { ctx->indirect_storage_meta_storage = indirect_storage_meta_storage; } /* Get the original indirectable storage. */ std::shared_ptr original_indirectable_storage; if (m_original_reader != nullptr && m_original_reader->HasFsInfo(fs_index)) { /* Create a driver for the original. */ NcaFileSystemDriver original_driver(m_original_reader, m_allocator, m_buffer_manager, m_hash_generator_factory_selector); /* Create a header reader for the original. */ NcaFsHeaderReader original_header_reader; R_TRY(original_header_reader.Initialize(*m_original_reader, fs_index)); /* Open original indirectable storage. */ R_TRY(original_driver.OpenIndirectableStorageAsOriginal(std::addressof(original_indirectable_storage), std::addressof(original_header_reader), ctx)); } else if (ctx != nullptr && ctx->external_original_storage != nullptr) { /* Use the external original storage. */ original_indirectable_storage = ctx->external_original_storage; } else { /* Allocate a dummy memory storage as original storage. */ original_indirectable_storage = fssystem::AllocateShared(nullptr, 0); R_UNLESS(original_indirectable_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); } /* Create the indirect storage. */ std::shared_ptr indirect_storage; R_TRY(this->CreateIndirectStorage(std::addressof(indirect_storage), ctx != nullptr ? std::addressof(ctx->indirect_storage) : nullptr, std::move(storage), std::move(original_indirectable_storage), std::move(indirect_storage_meta_storage), patch_info)); /* Set storage as the indirect storage. */ storage = std::move(indirect_storage); } /* Check if we're sparse or requested to skip the integrity layer. */ if (out_header_reader->ExistsSparseLayer() || (ctx != nullptr && ctx->open_raw_storage)) { *out = std::move(storage); return ResultSuccess(); } /* Process hash/integrity layer. */ switch (out_header_reader->GetHashType()) { case NcaFsHeader::HashType::HierarchicalSha256Hash: R_TRY(this->CreateSha256Storage(std::addressof(storage), std::move(storage), out_header_reader->GetHashData().hierarchical_sha256_data)); break; case NcaFsHeader::HashType::HierarchicalIntegrityHash: R_TRY(this->CreateIntegrityVerificationStorage(std::addressof(storage), std::move(storage), out_header_reader->GetHashData().integrity_meta_info)); break; default: return fs::ResultInvalidNcaFsHeaderHashType(); } /* Process compression layer. */ if (out_header_reader->ExistsCompressionLayer()) { R_TRY(this->CreateCompressedStorage(std::addressof(storage), ctx != nullptr ? std::addressof(ctx->compressed_storage) : nullptr, ctx != nullptr ? std::addressof(ctx->compressed_storage_meta_storage) : nullptr, std::move(storage), out_header_reader->GetCompressionInfo())); } /* Set output storage. */ *out = std::move(storage); return ResultSuccess(); } Result NcaFileSystemDriver::OpenIndirectableStorageAsOriginal(std::shared_ptr *out, const NcaFsHeaderReader *header_reader, StorageContext *ctx) { /* Get the fs index. */ const auto fs_index = header_reader->GetFsIndex(); /* Declare the storage we're opening. */ std::shared_ptr storage; /* Process sparse layer. */ s64 fs_data_offset = 0; if (header_reader->ExistsSparseLayer()) { /* Create the sparse storage. */ R_TRY(this->CreateSparseStorage(std::addressof(storage), std::addressof(fs_data_offset), ctx != nullptr ? std::addressof(ctx->original_sparse_storage) : nullptr, ctx != nullptr ? std::addressof(ctx->sparse_storage_meta_storage) : nullptr, fs_index, header_reader->GetAesCtrUpperIv(), header_reader->GetSparseInfo())); } else { /* Get the data offsets. */ fs_data_offset = GetFsOffset(*m_reader, fs_index); const auto fs_end_offset = GetFsEndOffset(*m_reader, fs_index); /* Validate that we're within range. */ const auto data_size = fs_end_offset - fs_data_offset; R_UNLESS(data_size > 0, fs::ResultInvalidNcaHeader()); /* Create the body substorage. */ R_TRY(this->CreateBodySubStorage(std::addressof(storage), fs_data_offset, data_size)); } /* Create the appropriate storage for the encryption type. */ switch (header_reader->GetEncryptionType()) { case NcaFsHeader::EncryptionType::None: /* If there's no encryption, use the base storage we made previously. */ break; case NcaFsHeader::EncryptionType::AesXts: R_TRY(this->CreateAesXtsStorage(std::addressof(storage), std::move(storage), fs_data_offset)); break; case NcaFsHeader::EncryptionType::AesCtr: R_TRY(this->CreateAesCtrStorage(std::addressof(storage), std::move(storage), fs_data_offset, header_reader->GetAesCtrUpperIv(), AlignmentStorageRequirement_CacheBlockSize)); break; default: return fs::ResultInvalidNcaFsHeaderEncryptionType(); } /* Set output storage. */ *out = std::move(storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateBodySubStorage(std::shared_ptr *out, s64 offset, s64 size) { /* Create the body storage. */ auto body_storage = fssystem::AllocateShared(m_reader->GetSharedBodyStorage(), m_reader); R_UNLESS(body_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Get the body storage size. */ s64 body_size = 0; R_TRY(body_storage->GetSize(std::addressof(body_size))); /* Check that we're within range. */ R_UNLESS(offset + size <= body_size, fs::ResultNcaBaseStorageOutOfRangeB()); /* Create substorage. */ auto body_substorage = fssystem::AllocateShared(std::move(body_storage), offset, size); R_UNLESS(body_substorage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Set the output storage. */ *out = std::move(body_substorage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateAesCtrStorage(std::shared_ptr *out, std::shared_ptr base_storage, s64 offset, const NcaAesCtrUpperIv &upper_iv, AlignmentStorageRequirement alignment_storage_requirement) { /* Check pre-conditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); /* Enforce alignment of accesses to base storage. */ switch (alignment_storage_requirement) { case AlignmentStorageRequirement_CacheBlockSize: { /* Get the base storage's size. */ s64 base_size; R_TRY(base_storage->GetSize(std::addressof(base_size))); /* Create buffered storage. */ auto buffered_storage = fssystem::AllocateShared(); R_UNLESS(buffered_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the buffered storage. */ R_TRY(buffered_storage->Initialize(fs::SubStorage(std::move(base_storage), 0, base_size), m_buffer_manager, AesCtrStorageCacheBlockSize, AesCtrStorageCacheCount)); /* Enable bulk read in the buffered storage. */ buffered_storage->EnableBulkRead(); /* Use the buffered storage in place of our base storage. */ base_storage = std::move(buffered_storage); } break; case AlignmentStorageRequirement_None: default: /* No alignment enforcing is required. */ break; } /* Create the iv. */ u8 iv[AesCtrStorageBySharedPointer::IvSize] = {}; AesCtrStorageBySharedPointer::MakeIv(iv, sizeof(iv), upper_iv.value, offset); /* Create the ctr storage. */ std::shared_ptr aes_ctr_storage; if (m_reader->HasExternalDecryptionKey()) { aes_ctr_storage = fssystem::AllocateShared(std::move(base_storage), m_reader->GetExternalDecryptionKey(), AesCtrStorageExternal::KeySize, iv, AesCtrStorageExternal::IvSize, m_reader->GetExternalDecryptAesCtrFunctionForExternalKey(), -1); R_UNLESS(aes_ctr_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); } else { /* Create software decryption storage. */ auto sw_storage = fssystem::AllocateShared(base_storage, m_reader->GetDecryptionKey(NcaHeader::DecryptionKey_AesCtr), AesCtrStorageBySharedPointer::KeySize, iv, AesCtrStorageBySharedPointer::IvSize); R_UNLESS(sw_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* If we have a hardware key and should use it, make the hardware decryption storage. */ if (m_reader->HasInternalDecryptionKeyForAesHw() && !m_reader->IsSoftwareAesPrioritized()) { auto hw_storage = fssystem::AllocateShared(base_storage, m_reader->GetDecryptionKey(NcaHeader::DecryptionKey_AesCtrHw), AesCtrStorageExternal::KeySize, iv, AesCtrStorageExternal::IvSize, m_reader->GetExternalDecryptAesCtrFunction(), GetKeyTypeValue(m_reader->GetKeyIndex(), m_reader->GetKeyGeneration())); R_UNLESS(hw_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Create the selection storage. */ auto switch_storage = fssystem::AllocateShared>(std::move(hw_storage), std::move(sw_storage), IsUsingHwAesCtrForSpeedEmulation); R_UNLESS(switch_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Use the selection storage. */ aes_ctr_storage = std::move(switch_storage); } else { /* Otherwise, just use the software decryption storage. */ aes_ctr_storage = std::move(sw_storage); } } /* Create alignment matching storage. */ auto aligned_storage = fssystem::AllocateShared>(std::move(aes_ctr_storage)); R_UNLESS(aligned_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Set the out storage. */ *out = std::move(aligned_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateAesXtsStorage(std::shared_ptr *out, std::shared_ptr base_storage, s64 offset) { /* Check pre-conditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); /* Create the iv. */ u8 iv[AesXtsStorageBySharedPointer::IvSize] = {}; AesXtsStorageBySharedPointer::MakeAesXtsIv(iv, sizeof(iv), offset, NcaHeader::XtsBlockSize); /* Make the aes xts storage. */ const auto * const key1 = m_reader->GetDecryptionKey(NcaHeader::DecryptionKey_AesXts1); const auto * const key2 = m_reader->GetDecryptionKey(NcaHeader::DecryptionKey_AesXts2); auto xts_storage = fssystem::AllocateShared(std::move(base_storage), key1, key2, AesXtsStorageBySharedPointer::KeySize, iv, AesXtsStorageBySharedPointer::IvSize, NcaHeader::XtsBlockSize); R_UNLESS(xts_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Create alignment matching storage. */ auto aligned_storage = fssystem::AllocateShared>(std::move(xts_storage)); R_UNLESS(aligned_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Set the out storage. */ *out = std::move(aligned_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateSparseStorageMetaStorage(std::shared_ptr *out, std::shared_ptr base_storage, s64 offset, const NcaAesCtrUpperIv &upper_iv, const NcaSparseInfo &sparse_info) { /* Validate preconditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); /* Get the base storage size. */ s64 base_size = 0; R_TRY(base_storage->GetSize(std::addressof(base_size))); /* Get the meta extents. */ const auto meta_offset = sparse_info.bucket.offset; const auto meta_size = sparse_info.bucket.size; R_UNLESS(meta_offset + meta_size - offset <= base_size, fs::ResultNcaBaseStorageOutOfRangeB()); /* Create the encrypted storage. */ auto enc_storage = fssystem::AllocateShared(std::move(base_storage), meta_offset, meta_size); R_UNLESS(enc_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Create the decrypted storage. */ std::shared_ptr decrypted_storage; R_TRY(this->CreateAesCtrStorage(std::addressof(decrypted_storage), std::move(enc_storage), offset + meta_offset, sparse_info.MakeAesCtrUpperIv(upper_iv), AlignmentStorageRequirement_None)); /* Create meta storage. */ auto meta_storage = fssystem::AllocateShared(); R_UNLESS(meta_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the meta storage. */ R_TRY(meta_storage->Initialize(fs::SubStorage(std::move(decrypted_storage), 0, meta_size), m_buffer_manager, SparseTableCacheBlockSize, SparseTableCacheCount)); /* Set the output. */ *out = std::move(meta_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateSparseStorageCore(std::shared_ptr *out, std::shared_ptr base_storage, s64 base_size, std::shared_ptr meta_storage, const NcaSparseInfo &sparse_info, bool external_info) { /* Validate preconditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); AMS_ASSERT(meta_storage != nullptr); /* Read and verify the bucket tree header. */ BucketTree::Header header; std::memcpy(std::addressof(header), sparse_info.bucket.header, sizeof(header)); R_TRY(header.Verify()); /* Determine storage extents. */ const auto node_offset = 0; const auto node_size = SparseStorage::QueryNodeStorageSize(header.entry_count); const auto entry_offset = node_offset + node_size; const auto entry_size = SparseStorage::QueryEntryStorageSize(header.entry_count); /* Create the sparse storage. */ auto sparse_storage = fssystem::AllocateShared(); R_UNLESS(sparse_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Sanity check that we can be doing this. */ AMS_ASSERT(header.entry_count != 0); /* Initialize the sparse storage. */ R_TRY(sparse_storage->Initialize(m_allocator, fs::SubStorage(meta_storage, node_offset, node_size), fs::SubStorage(meta_storage, entry_offset, entry_size), header.entry_count)); /* If not external, set the data storage. */ if (!external_info) { sparse_storage->SetDataStorage(fs::SubStorage(std::move(base_storage), 0, base_size)); } /* Set the output. */ *out = std::move(sparse_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateSparseStorage(std::shared_ptr *out, s64 *out_fs_data_offset, std::shared_ptr *out_sparse_storage, std::shared_ptr *out_meta_storage, s32 index, const NcaAesCtrUpperIv &upper_iv, const NcaSparseInfo &sparse_info) { /* Validate preconditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(out_fs_data_offset != nullptr); /* Check the sparse info generation. */ R_UNLESS(sparse_info.generation != 0, fs::ResultInvalidNcaHeader()); /* Read and verify the bucket tree header. */ BucketTree::Header header; std::memcpy(std::addressof(header), sparse_info.bucket.header, sizeof(header)); R_TRY(header.Verify()); /* Determine the storage extents. */ const auto fs_offset = GetFsOffset(*m_reader, index); const auto fs_end_offset = GetFsEndOffset(*m_reader, index); const auto fs_size = fs_end_offset - fs_offset; /* Create the sparse storage. */ std::shared_ptr sparse_storage; if (header.entry_count != 0) { /* Create the body substorage. */ std::shared_ptr body_substorage; R_TRY(this->CreateBodySubStorage(std::addressof(body_substorage), sparse_info.physical_offset, sparse_info.GetPhysicalSize())); /* Create the meta storage. */ std::shared_ptr meta_storage; R_TRY(this->CreateSparseStorageMetaStorage(std::addressof(meta_storage), body_substorage, sparse_info.physical_offset, upper_iv, sparse_info)); /* Potentially set the output meta storage. */ if (out_meta_storage != nullptr) { *out_meta_storage = meta_storage; } /* Create the sparse storage. */ R_TRY(this->CreateSparseStorageCore(std::addressof(sparse_storage), body_substorage, sparse_info.GetPhysicalSize(), std::move(meta_storage), sparse_info, false)); } else { /* If there are no entries, there's nothing to actually do. */ sparse_storage = fssystem::AllocateShared(); R_UNLESS(sparse_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); sparse_storage->Initialize(fs_size); } /* Potentially set the output sparse storage. */ if (out_sparse_storage != nullptr) { *out_sparse_storage = sparse_storage; } /* Set the output fs data offset. */ *out_fs_data_offset = fs_offset; /* Set the output storage. */ *out = std::move(sparse_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateAesCtrExMetaStorage(std::shared_ptr *out, std::shared_ptr base_storage, s64 offset, const NcaAesCtrUpperIv &upper_iv, const NcaPatchInfo &patch_info) { /* Validate preconditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); AMS_ASSERT(patch_info.HasAesCtrExTable()); /* Validate patch info extents. */ R_UNLESS(patch_info.indirect_size > 0, fs::ResultInvalidNcaPatchInfoIndirectSize()); R_UNLESS(patch_info.aes_ctr_ex_size > 0, fs::ResultInvalidNcaPatchInfoAesCtrExSize()); R_UNLESS(patch_info.indirect_size + patch_info.indirect_offset <= patch_info.aes_ctr_ex_offset, fs::ResultInvalidNcaPatchInfoAesCtrExOffset()); /* Get the base storage size. */ s64 base_size; R_TRY(base_storage->GetSize(std::addressof(base_size))); /* Get and validate the meta extents. */ const s64 meta_offset = patch_info.aes_ctr_ex_offset; const s64 meta_size = util::AlignUp(patch_info.aes_ctr_ex_size, NcaHeader::XtsBlockSize); R_UNLESS(meta_offset + meta_size <= base_size, fs::ResultNcaBaseStorageOutOfRangeB()); /* Create the encrypted storage. */ auto enc_storage = fssystem::AllocateShared(std::move(base_storage), meta_offset, meta_size); R_UNLESS(enc_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Create the decrypted storage. */ std::shared_ptr decrypted_storage; R_TRY(this->CreateAesCtrStorage(std::addressof(decrypted_storage), std::move(enc_storage), offset + meta_offset, upper_iv, AlignmentStorageRequirement_None)); /* Create meta storage. */ auto meta_storage = fssystem::AllocateShared(); R_UNLESS(meta_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the meta storage. */ R_TRY(meta_storage->Initialize(fs::SubStorage(std::move(decrypted_storage), 0, meta_size), m_buffer_manager, AesCtrExTableCacheBlockSize, AesCtrExTableCacheCount)); /* Create an alignment-matching storage. */ using AlignedStorage = AlignmentMatchingStorage; auto aligned_storage = fssystem::AllocateShared(std::move(meta_storage)); R_UNLESS(aligned_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Set the output. */ *out = std::move(aligned_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateAesCtrExStorage(std::shared_ptr *out, std::shared_ptr *out_ext, std::shared_ptr base_storage, std::shared_ptr meta_storage, s64 counter_offset, const NcaAesCtrUpperIv &upper_iv, const NcaPatchInfo &patch_info) { /* Validate pre-conditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); AMS_ASSERT(meta_storage != nullptr); AMS_ASSERT(patch_info.HasAesCtrExTable()); /* Read the bucket tree header. */ BucketTree::Header header; std::memcpy(std::addressof(header), patch_info.aes_ctr_ex_header, sizeof(header)); R_TRY(header.Verify()); /* Determine the bucket extents. */ const auto entry_count = header.entry_count; const s64 data_offset = 0; const s64 data_size = patch_info.aes_ctr_ex_offset; const s64 node_offset = 0; const s64 node_size = AesCtrCounterExtendedStorage::QueryNodeStorageSize(entry_count); const s64 entry_offset = node_offset + node_size; const s64 entry_size = AesCtrCounterExtendedStorage::QueryEntryStorageSize(entry_count); /* Create bucket storages. */ fs::SubStorage data_storage(std::move(base_storage), data_offset, data_size); fs::SubStorage node_storage(meta_storage, node_offset, node_size); fs::SubStorage entry_storage(meta_storage, entry_offset, entry_size); /* Get the secure value. */ const auto secure_value = upper_iv.part.secure_value; /* Create the aes ctr ex storage. */ std::shared_ptr aes_ctr_ex_storage; if (m_reader->HasExternalDecryptionKey()) { /* Create the decryptor. */ std::unique_ptr decryptor; R_TRY(AesCtrCounterExtendedStorage::CreateExternalDecryptor(std::addressof(decryptor), m_reader->GetExternalDecryptAesCtrFunctionForExternalKey(), -1)); /* Create the aes ctr ex storage. */ auto impl_storage = fssystem::AllocateShared(); R_UNLESS(impl_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the aes ctr ex storage. */ R_TRY(impl_storage->Initialize(m_allocator, m_reader->GetExternalDecryptionKey(), AesCtrStorageBySharedPointer::KeySize, secure_value, counter_offset, data_storage, node_storage, entry_storage, entry_count, std::move(decryptor))); /* Potentially set the output implementation storage. */ if (out_ext != nullptr) { *out_ext = impl_storage; } /* Set the implementation storage. */ aes_ctr_ex_storage = std::move(impl_storage); } else { /* Create the software decryptor. */ std::unique_ptr sw_decryptor; R_TRY(AesCtrCounterExtendedStorage::CreateSoftwareDecryptor(std::addressof(sw_decryptor))); /* Make the software storage. */ auto sw_storage = fssystem::AllocateShared(); R_UNLESS(sw_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the software storage. */ R_TRY(sw_storage->Initialize(m_allocator, m_reader->GetDecryptionKey(NcaHeader::DecryptionKey_AesCtr), AesCtrStorageBySharedPointer::KeySize, secure_value, counter_offset, data_storage, node_storage, entry_storage, entry_count, std::move(sw_decryptor))); /* Potentially set the output implementation storage. */ if (out_ext != nullptr) { *out_ext = sw_storage; } /* If we have a hardware key and should use it, make the hardware decryption storage. */ if (m_reader->HasInternalDecryptionKeyForAesHw() && !m_reader->IsSoftwareAesPrioritized()) { /* Create the hardware decryptor. */ std::unique_ptr hw_decryptor; R_TRY(AesCtrCounterExtendedStorage::CreateExternalDecryptor(std::addressof(hw_decryptor), m_reader->GetExternalDecryptAesCtrFunction(), GetKeyTypeValue(m_reader->GetKeyIndex(), m_reader->GetKeyGeneration()))); /* Create the hardware storage. */ auto hw_storage = fssystem::AllocateShared(); R_UNLESS(hw_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the hardware storage. */ R_TRY(hw_storage->Initialize(m_allocator, m_reader->GetDecryptionKey(NcaHeader::DecryptionKey_AesCtrHw), AesCtrStorageBySharedPointer::KeySize, secure_value, counter_offset, data_storage, node_storage, entry_storage, entry_count, std::move(hw_decryptor))); /* Create the selection storage. */ auto switch_storage = fssystem::AllocateShared>(std::move(hw_storage), std::move(sw_storage), IsUsingHwAesCtrForSpeedEmulation); R_UNLESS(switch_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Set the implementation storage. */ aes_ctr_ex_storage = std::move(switch_storage); } else { /* Set the implementation storage. */ aes_ctr_ex_storage = std::move(sw_storage); } } /* Create an alignment-matching storage. */ using AlignedStorage = AlignmentMatchingStorage; auto aligned_storage = fssystem::AllocateShared(std::move(aes_ctr_ex_storage)); R_UNLESS(aligned_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Set the output. */ *out = std::move(aligned_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateIndirectStorageMetaStorage(std::shared_ptr *out, std::shared_ptr base_storage, const NcaPatchInfo &patch_info) { /* Validate preconditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); AMS_ASSERT(patch_info.HasIndirectTable()); /* Get the base storage size. */ s64 base_size = 0; R_TRY(base_storage->GetSize(std::addressof(base_size))); /* Check that we're within range. */ R_UNLESS(patch_info.indirect_offset + patch_info.indirect_size <= base_size, fs::ResultNcaBaseStorageOutOfRangeE()); /* Allocate the meta storage. */ auto meta_storage = fssystem::AllocateShared(); R_UNLESS(meta_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the meta storage. */ R_TRY(meta_storage->Initialize(fs::SubStorage(base_storage, patch_info.indirect_offset, patch_info.indirect_size), m_buffer_manager, IndirectTableCacheBlockSize, IndirectTableCacheCount)); /* Set the output. */ *out = std::move(meta_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateIndirectStorage(std::shared_ptr *out, std::shared_ptr *out_ind, std::shared_ptr base_storage, std::shared_ptr original_data_storage, std::shared_ptr meta_storage, const NcaPatchInfo &patch_info) { /* Validate preconditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); AMS_ASSERT(meta_storage != nullptr); AMS_ASSERT(patch_info.HasIndirectTable()); /* Read the bucket tree header. */ BucketTree::Header header; std::memcpy(std::addressof(header), patch_info.indirect_header, sizeof(header)); R_TRY(header.Verify()); /* Determine the storage sizes. */ const auto node_size = IndirectStorage::QueryNodeStorageSize(header.entry_count); const auto entry_size = IndirectStorage::QueryEntryStorageSize(header.entry_count); R_UNLESS(node_size + entry_size <= patch_info.indirect_size, fs::ResultInvalidIndirectStorageSize()); /* Get the indirect data size. */ const s64 indirect_data_size = patch_info.indirect_offset; AMS_ASSERT(util::IsAligned(indirect_data_size, NcaHeader::XtsBlockSize)); /* Create the indirect data storage. */ auto indirect_data_storage = fssystem::AllocateShared(); R_UNLESS(indirect_data_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the indirect data storage. */ R_TRY(indirect_data_storage->Initialize(fs::SubStorage(base_storage, 0, indirect_data_size), m_buffer_manager, IndirectDataCacheBlockSize, IndirectDataCacheCount)); /* Enable bulk read on the data storage. */ indirect_data_storage->EnableBulkRead(); /* Create the indirect storage. */ auto indirect_storage = fssystem::AllocateShared(); R_UNLESS(indirect_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the indirect storage. */ R_TRY(indirect_storage->Initialize(m_allocator, fs::SubStorage(meta_storage, 0, node_size), fs::SubStorage(meta_storage, node_size, entry_size), header.entry_count)); /* Get the original data size. */ s64 original_data_size; R_TRY(original_data_storage->GetSize(std::addressof(original_data_size))); /* Set the indirect storages. */ indirect_storage->SetStorage(0, fs::SubStorage(original_data_storage, 0, original_data_size)); indirect_storage->SetStorage(1, fs::SubStorage(indirect_data_storage, 0, indirect_data_size)); /* If necessary, set the output indirect storage. */ if (out_ind != nullptr) { *out_ind = indirect_storage; } /* Set the output. */ *out = std::move(indirect_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateSha256Storage(std::shared_ptr *out, std::shared_ptr base_storage, const NcaFsHeader::HashData::HierarchicalSha256Data &hash_data) { /* Validate preconditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); /* Define storage types. */ using VerificationStorage = HierarchicalSha256Storage; using CacheStorage = ReadOnlyBlockCacheStorage; using AlignedStorage = AlignmentMatchingStoragePooledBuffer, 1>; /* Validate the hash data. */ R_UNLESS(util::IsPowerOfTwo(hash_data.hash_block_size), fs::ResultInvalidHierarchicalSha256BlockSize()); R_UNLESS(hash_data.hash_layer_count == VerificationStorage::LayerCount - 1, fs::ResultInvalidHierarchicalSha256LayerCount()); /* Get the regions. */ const auto &hash_region = hash_data.hash_layer_region[0]; const auto &data_region = hash_data.hash_layer_region[1]; /* Determine buffer sizes. */ constexpr s32 CacheBlockCount = 2; const auto hash_buffer_size = static_cast(hash_region.size); const auto cache_buffer_size = CacheBlockCount * hash_data.hash_block_size; const auto total_buffer_size = hash_buffer_size + cache_buffer_size; /* Make a buffer holder storage. */ auto buffer_hold_storage = fssystem::AllocateShared(std::move(base_storage), m_allocator, total_buffer_size); R_UNLESS(buffer_hold_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); R_UNLESS(buffer_hold_storage->IsValid(), fs::ResultAllocationFailureInNcaFileSystemDriverI()); /* Get storage size. */ s64 base_size; R_TRY(buffer_hold_storage->GetSize(std::addressof(base_size))); /* Check that we're within range. */ R_UNLESS(hash_region.offset + hash_region.size <= base_size, fs::ResultNcaBaseStorageOutOfRangeC()); R_UNLESS(data_region.offset + data_region.size <= base_size, fs::ResultNcaBaseStorageOutOfRangeC()); /* Create the master hash storage. */ fs::MemoryStorage master_hash_storage(const_cast(std::addressof(hash_data.fs_data_master_hash)), sizeof(Hash)); /* Make the verification storage. */ auto verification_storage = fssystem::AllocateShared(); R_UNLESS(verification_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Make layer storages. */ fs::SubStorage layer_storages[VerificationStorage::LayerCount] = { fs::SubStorage(std::addressof(master_hash_storage), 0, sizeof(Hash)), fs::SubStorage(buffer_hold_storage.get(), hash_region.offset, hash_region.size), fs::SubStorage(buffer_hold_storage, data_region.offset, data_region.size) }; /* Initialize the verification storage. */ R_TRY(verification_storage->Initialize(layer_storages, util::size(layer_storages), hash_data.hash_block_size, buffer_hold_storage->GetBuffer(), hash_buffer_size, m_hash_generator_factory_selector->GetFactory())); /* Make the cache storage. */ auto cache_storage = fssystem::AllocateShared(std::move(verification_storage), hash_data.hash_block_size, static_cast(buffer_hold_storage->GetBuffer()) + hash_buffer_size, cache_buffer_size, CacheBlockCount); R_UNLESS(cache_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Make the aligned storage. */ auto aligned_storage = fssystem::AllocateShared(std::move(cache_storage), hash_data.hash_block_size); R_UNLESS(aligned_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Set the output. */ *out = std::move(aligned_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateIntegrityVerificationStorage(std::shared_ptr *out, std::shared_ptr base_storage, const NcaFsHeader::HashData::IntegrityMetaInfo &meta_info) { /* Validate preconditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); /* Define storage types. */ using VerificationStorage = save::HierarchicalIntegrityVerificationStorage; using StorageInfo = VerificationStorage::HierarchicalStorageInformation; /* Validate the meta info. */ save::HierarchicalIntegrityVerificationInformation level_hash_info; std::memcpy(std::addressof(level_hash_info), std::addressof(meta_info.level_hash_info), sizeof(level_hash_info)); R_UNLESS(save::IntegrityMinLayerCount <= level_hash_info.max_layers, fs::ResultInvalidHierarchicalIntegrityVerificationLayerCount()); R_UNLESS(level_hash_info.max_layers <= save::IntegrityMaxLayerCount, fs::ResultInvalidHierarchicalIntegrityVerificationLayerCount()); /* Get the base storage size. */ s64 base_storage_size; R_TRY(base_storage->GetSize(std::addressof(base_storage_size))); /* Create storage info. */ StorageInfo storage_info; for (s32 i = 0; i < static_cast(level_hash_info.max_layers - 2); ++i) { const auto &layer_info = level_hash_info.info[i]; R_UNLESS(layer_info.offset + layer_info.size <= base_storage_size, fs::ResultNcaBaseStorageOutOfRangeD()); storage_info[i + 1] = fs::SubStorage(base_storage, layer_info.offset, layer_info.size); } /* Set the last layer info. */ const auto &layer_info = level_hash_info.info[level_hash_info.max_layers - 2]; R_UNLESS(layer_info.offset + layer_info.size <= base_storage_size, fs::ResultNcaBaseStorageOutOfRangeD()); storage_info.SetDataStorage(fs::SubStorage(std::move(base_storage), layer_info.offset, layer_info.size)); /* Make the integrity romfs storage. */ auto integrity_storage = fssystem::AllocateShared(); R_UNLESS(integrity_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the integrity storage. */ R_TRY(integrity_storage->Initialize(level_hash_info, meta_info.master_hash, storage_info, m_buffer_manager, m_hash_generator_factory_selector->GetFactory())); /* Set the output. */ *out = std::move(integrity_storage); return ResultSuccess(); } Result NcaFileSystemDriver::CreateCompressedStorage(std::shared_ptr *out, std::shared_ptr *out_cmp, std::shared_ptr *out_meta, std::shared_ptr base_storage, const NcaCompressionInfo &compression_info) { return this->CreateCompressedStorage(out, out_cmp, out_meta, std::move(base_storage), compression_info, m_reader->GetDecompressor(), m_allocator, m_buffer_manager); } Result NcaFileSystemDriver::CreateCompressedStorage(std::shared_ptr *out, std::shared_ptr *out_cmp, std::shared_ptr *out_meta, std::shared_ptr base_storage, const NcaCompressionInfo &compression_info, GetDecompressorFunction get_decompressor, MemoryResource *allocator, IBufferManager *buffer_manager) { /* Check pre-conditions. */ AMS_ASSERT(out != nullptr); AMS_ASSERT(base_storage != nullptr); AMS_ASSERT(get_decompressor != nullptr); /* Read and verify the bucket tree header. */ BucketTree::Header header; std::memcpy(std::addressof(header), compression_info.bucket.header, sizeof(header)); R_TRY(header.Verify()); /* Determine the storage extents. */ const auto table_offset = compression_info.bucket.offset; const auto table_size = compression_info.bucket.size; const auto node_size = CompressedStorage::QueryNodeStorageSize(header.entry_count); const auto entry_size = CompressedStorage::QueryEntryStorageSize(header.entry_count); R_UNLESS(node_size + entry_size <= table_size, fs::ResultInvalidCompressedStorageSize()); /* If we should, set the output meta storage. */ if (out_meta != nullptr) { auto meta_storage = fssystem::AllocateShared(base_storage, table_offset, table_size); R_UNLESS(meta_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); *out_meta = std::move(meta_storage); } /* Allocate the compressed storage. */ auto compressed_storage = fssystem::AllocateShared(); R_UNLESS(compressed_storage != nullptr, fs::ResultAllocationFailureInAllocateShared()); /* Initialize the compressed storage. */ R_TRY(compressed_storage->Initialize(allocator, buffer_manager, fs::SubStorage(base_storage, 0, table_offset), fs::SubStorage(base_storage, table_offset, node_size), fs::SubStorage(base_storage, table_offset + node_size, entry_size), header.entry_count, 64_KB, 640_KB, get_decompressor, 16_KB, 16_KB, 32)); /* Potentially set the output compressed storage. */ if (out_cmp) { *out_cmp = compressed_storage; } /* Set the output. */ *out = std::move(compressed_storage); return ResultSuccess(); } }