/* * 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 "fusee_emummc.hpp" #include "fusee_mmc.hpp" #include "fusee_sd_card.hpp" #include "fusee_fatal.hpp" #include "fusee_malloc.hpp" #include "fs/fusee_fs_api.hpp" #include "fs/fusee_fs_storage.hpp" namespace ams::nxboot { namespace { class SdCardStorage : public fs::IStorage { public: virtual Result Read(s64 offset, void *buffer, size_t size) override { if (!util::IsAligned(offset, sdmmc::SectorSize) || !util::IsAligned(size, sdmmc::SectorSize)) { ShowFatalError("SdCard: unaligned access to %" PRIx64 ", size=%" PRIx64"\n", static_cast(offset), static_cast(size)); } return ReadSdCard(buffer, size, offset / sdmmc::SectorSize, size / sdmmc::SectorSize); } virtual Result Flush() override { R_SUCCEED(); } virtual Result GetSize(s64 *out) override { u32 num_sectors; R_TRY(GetSdCardMemoryCapacity(std::addressof(num_sectors))); *out = static_cast(num_sectors) * static_cast(sdmmc::SectorSize); R_SUCCEED(); } virtual Result Write(s64 offset, const void *buffer, size_t size) override { R_THROW(fs::ResultUnsupportedOperation()); } virtual Result SetSize(s64 size) override { R_THROW(fs::ResultUnsupportedOperation()); } }; template class MmcPartitionStorage : public fs::IStorage { public: constexpr MmcPartitionStorage() { /* ... */ } virtual Result Read(s64 offset, void *buffer, size_t size) override { if (!util::IsAligned(offset, sdmmc::SectorSize) || !util::IsAligned(size, sdmmc::SectorSize)) { ShowFatalError("SdCard: unaligned access to %" PRIx64 ", size=%" PRIx64"\n", static_cast(offset), static_cast(size)); } return ReadMmc(buffer, size, Partition, offset / sdmmc::SectorSize, size / sdmmc::SectorSize); } virtual Result Flush() override { R_SUCCEED(); } virtual Result GetSize(s64 *out) override { u32 num_sectors; R_TRY(GetMmcMemoryCapacity(std::addressof(num_sectors), Partition)); *out = num_sectors * sdmmc::SectorSize; R_SUCCEED(); } virtual Result Write(s64 offset, const void *buffer, size_t size) override { R_THROW(fs::ResultUnsupportedOperation()); } virtual Result SetSize(s64 size) override { R_THROW(fs::ResultUnsupportedOperation()); } }; using MmcBoot0Storage = MmcPartitionStorage; using MmcUserStorage = MmcPartitionStorage; constinit char g_emummc_path[0x300]; class EmummcFileStorage : public fs::IStorage { private: s64 m_file_size; fs::FileHandle m_handles[64]; bool m_open[64]; int m_file_path_ofs; private: void EnsureFile(int id) { if (!m_open[id]) { /* Update path. */ g_emummc_path[m_file_path_ofs + 1] = '0' + (id % 10); g_emummc_path[m_file_path_ofs + 0] = '0' + (id / 10); /* Open new file. */ const Result result = fs::OpenFile(m_handles + id, g_emummc_path, fs::OpenMode_Read); if (R_FAILED(result)) { ShowFatalError("Failed to open emummc user %02d file: 0x%08" PRIx32 "!\n", id, result.GetValue()); } m_open[id] = true; } } public: EmummcFileStorage(fs::FileHandle user00, int ofs) : m_file_path_ofs(ofs) { const Result result = fs::GetFileSize(std::addressof(m_file_size), user00); if (R_FAILED(result)) { ShowFatalError("Failed to get emummc file size: 0x%08" PRIx32 "!\n", result.GetValue()); } for (size_t i = 0; i < util::size(m_handles); ++i) { m_open[i] = false; } m_handles[0] = user00; m_open[0] = true; } virtual Result Read(s64 offset, void *buffer, size_t size) override { int file = offset / m_file_size; s64 subofs = offset % m_file_size; u8 *cur_dst = static_cast(buffer); for (/* ... */; size > 0; ++file) { /* Ensure the current file is open. */ EnsureFile(file); /* Perform the current read. */ const size_t cur_size = std::min(m_file_size - subofs, size); R_TRY(fs::ReadFile(m_handles[file], subofs, cur_dst, cur_size)); /* Advance. */ cur_dst += cur_size; size -= cur_size; subofs = 0; } R_SUCCEED(); } virtual Result Flush() override { R_THROW(fs::ResultUnsupportedOperation()); } virtual Result GetSize(s64 *out) override { R_THROW(fs::ResultUnsupportedOperation()); } virtual Result Write(s64 offset, const void *buffer, size_t size) override { R_THROW(fs::ResultUnsupportedOperation()); } virtual Result SetSize(s64 size) override { R_THROW(fs::ResultUnsupportedOperation()); } }; constinit SdCardStorage g_sd_card_storage; constinit MmcBoot0Storage g_mmc_boot0_storage; constinit MmcUserStorage g_mmc_user_storage; constinit fs::IStorage *g_boot0_storage = nullptr; constinit fs::IStorage *g_user_storage = nullptr; constinit fs::SubStorage *g_package2_storage = nullptr; struct Guid { u32 data1; u16 data2; u16 data3; u8 data4[8]; }; static_assert(sizeof(Guid) == 0x10); struct GptHeader { char signature[8]; u32 revision; u32 header_size; u32 header_crc32; u32 reserved0; u64 my_lba; u64 alt_lba; u64 first_usable_lba; u64 last_usable_lba; Guid disk_guid; u64 partition_entry_lba; u32 number_of_partition_entries; u32 size_of_partition_entry; u32 partition_entry_array_crc32; u32 reserved1; }; static_assert(sizeof(GptHeader) == 0x60); struct GptPartitionEntry { Guid partition_type_guid; Guid unique_partition_guid; u64 starting_lba; u64 ending_lba; u64 attributes; char partition_name[0x48]; }; static_assert(sizeof(GptPartitionEntry) == 0x80); struct Gpt { GptHeader header; u8 padding[0x1A0]; GptPartitionEntry entries[128]; }; static_assert(sizeof(Gpt) == 16_KB + 0x200); constexpr const u16 Package2PartitionName[] = { 'B', 'C', 'P', 'K', 'G', '2', '-', '1', '-', 'N', 'o', 'r', 'm', 'a', 'l', '-', 'M', 'a', 'i', 'n', 0 }; } void InitializeEmummc(bool emummc_enabled, const secmon::EmummcConfiguration &emummc_cfg) { Result result; if (emummc_enabled) { /* Get sd card size. */ s64 sd_card_size; if (R_FAILED((result = g_sd_card_storage.GetSize(std::addressof(sd_card_size))))) { ShowFatalError("Failed to get sd card size: 0x%08" PRIx32 "!\n", result.GetValue()); } if (emummc_cfg.base_cfg.type == secmon::EmummcType_Partition) { const s64 partition_start = emummc_cfg.partition_cfg.start_sector * sdmmc::SectorSize; g_boot0_storage = AllocateObject(g_sd_card_storage, partition_start, 4_MB); g_user_storage = AllocateObject(g_sd_card_storage, partition_start + 8_MB, sd_card_size - (partition_start + 8_MB)); } else if (emummc_cfg.base_cfg.type == secmon::EmummcType_File) { /* Get the base emummc path. */ std::memcpy(g_emummc_path, emummc_cfg.file_cfg.path.str, sizeof(emummc_cfg.file_cfg.path.str)); /* Get path length. */ auto len = std::strlen(g_emummc_path); /* Append emmc. */ std::memcpy(g_emummc_path + len, "/eMMC", 6); len += 5; /* Open boot0. */ fs::FileHandle boot0_file; std::memcpy(g_emummc_path + len, "/boot0", 7); if (R_FAILED((result = fs::OpenFile(std::addressof(boot0_file), g_emummc_path, fs::OpenMode_Read)))) { ShowFatalError("Failed to open emummc boot0 file: 0x%08" PRIx32 "!\n", result.GetValue()); } /* Open boot1. */ g_emummc_path[len + 5] = '1'; { fs::DirectoryEntryType entry_type; bool is_archive; if (R_FAILED((result = fs::GetEntryType(std::addressof(entry_type), std::addressof(is_archive), g_emummc_path)))) { ShowFatalError("Failed to find emummc boot1 file: 0x%08" PRIx32 "!\n", result.GetValue()); } if (entry_type != fs::DirectoryEntryType_File) { ShowFatalError("emummc boot1 file is not a file!\n"); } } /* Open userdata. */ std::memcpy(g_emummc_path + len, "/00", 4); fs::FileHandle user00_file; if (R_FAILED((result = fs::OpenFile(std::addressof(user00_file), g_emummc_path, fs::OpenMode_Read)))) { ShowFatalError("Failed to open emummc user %02d file: 0x%08" PRIx32 "!\n", 0, result.GetValue()); } /* Create partitions. */ g_boot0_storage = AllocateObject(boot0_file); g_user_storage = AllocateObject(user00_file, len + 1); } else { ShowFatalError("Unknown emummc type %d\n", static_cast(emummc_cfg.base_cfg.type)); } } else { /* Initialize access to mmc. */ { const Result result = InitializeMmc(); if (R_FAILED(result)) { ShowFatalError("Failed to initialize mmc: 0x%08" PRIx32 "\n", result.GetValue()); } } /* Create storages. */ g_boot0_storage = std::addressof(g_mmc_boot0_storage); g_user_storage = std::addressof(g_mmc_user_storage); } if (g_boot0_storage == nullptr) { ShowFatalError("Failed to initialize BOOT0\n"); } if (g_user_storage == nullptr) { ShowFatalError("Failed to initialize Raw EMMC\n"); } /* Read the GPT. */ Gpt *gpt = static_cast(AllocateAligned(sizeof(Gpt), 0x200)); { const Result result = g_user_storage->Read(0x200, gpt, sizeof(*gpt)); if (R_FAILED(result)) { ShowFatalError("Failed to read GPT: 0x%08" PRIx32 "\n", result.GetValue()); } } /* Check the GPT. */ if (std::memcmp(gpt->header.signature, "EFI PART", 8) != 0) { ShowFatalError("Invalid GPT signature\n"); } if (gpt->header.number_of_partition_entries > util::size(gpt->entries)) { ShowFatalError("Too many GPT entries\n"); } /* Create system storage. */ for (u32 i = 0; i < gpt->header.number_of_partition_entries; ++i) { if (gpt->entries[i].starting_lba < gpt->header.first_usable_lba) { continue; } const s64 offset = INT64_C(0x200) * gpt->entries[i].starting_lba; const u64 size = UINT64_C(0x200) * (gpt->entries[i].ending_lba + 1 - gpt->entries[i].starting_lba); if (std::memcmp(gpt->entries[i].partition_name, Package2PartitionName, sizeof(Package2PartitionName)) == 0) { g_package2_storage = AllocateObject(*g_user_storage, offset, size); } } /* Check that we created package2 storage. */ if (g_package2_storage == nullptr) { ShowFatalError("Failed to initialize Package2\n"); } } Result ReadBoot0(s64 offset, void *dst, size_t size) { return g_boot0_storage->Read(offset, dst, size); } Result ReadPackage2(s64 offset, void *dst, size_t size) { return g_package2_storage->Read(offset, dst, size); } }