citra/src/core/file_sys/layered_fs.cpp

// Copyright 2020 Citra Emulator Project
// Licensed under GPLv2 or any later version
// Refer to the license.txt file included.

#include <algorithm>
#include <cstring>
#include "common/alignment.h"
#include "common/assert.h"
#include "common/common_paths.h"
#include "common/file_util.h"
#include "common/string_util.h"
#include "common/swap.h"
#include "core/file_sys/layered_fs.h"
#include "core/file_sys/patch.h"

namespace FileSys {

struct FileRelocationInfo {
    int type;                      // 0 - none, 1 - replaced / created, 2 - patched, 3 - removed
    u64 original_offset;           // Type 0. Offset is absolute
    FileUtil::IOFile replace_file; // Type 1
    std::vector<u8> patched_file;  // Type 2
    u64 size;                      // Relocated file size
};
struct LayeredFS::File {
    std::string name;
    std::string path;
    FileRelocationInfo relocation{};
    Directory* parent;
};

struct DirectoryMetadata {
    u32_le parent_directory_offset;
    u32_le next_sibling_offset;
    u32_le first_child_directory_offset;
    u32_le first_file_offset;
    u32_le hash_bucket_next;
    u32_le name_length;
    // Followed by a name of name length (aligned up to 4)
};
static_assert(sizeof(DirectoryMetadata) == 0x18, "Size of DirectoryMetadata is not correct");

struct FileMetadata {
    u32_le parent_directory_offset;
    u32_le next_sibling_offset;
    u64_le file_data_offset;
    u64_le file_data_length;
    u32_le hash_bucket_next;
    u32_le name_length;
    // Followed by a name of name length (aligned up to 4)
};
static_assert(sizeof(FileMetadata) == 0x20, "Size of FileMetadata is not correct");

LayeredFS::LayeredFS(std::shared_ptr<RomFSReader> romfs_, std::string patch_path_,
                     std::string patch_ext_path_)
    : romfs(std::move(romfs_)), patch_path(std::move(patch_path_)),
      patch_ext_path(std::move(patch_ext_path_)) {

    romfs->ReadFile(0, sizeof(header), reinterpret_cast<u8*>(&header));

    ASSERT_MSG(header.header_length == sizeof(header), "Header size is incorrect");

    // TODO: is root always the first directory in table?
    root.parent = &root;
    LoadDirectory(root, 0);

    LoadRelocations();
    LoadExtRelocations();

    RebuildMetadata();
}

LayeredFS::~LayeredFS() = default;

void LayeredFS::LoadDirectory(Directory& current, u32 offset) {
    DirectoryMetadata metadata;
    romfs->ReadFile(header.directory_metadata_table.offset + offset, sizeof(metadata),
                    reinterpret_cast<u8*>(&metadata));

    current.name = ReadName(header.directory_metadata_table.offset + offset + sizeof(metadata),
                            metadata.name_length);
    current.path = current.parent->path + current.name + DIR_SEP;
    directory_path_map.emplace(current.path, &current);

    if (metadata.first_file_offset != 0xFFFFFFFF) {
        LoadFile(current, metadata.first_file_offset);
    }

    if (metadata.first_child_directory_offset != 0xFFFFFFFF) {
        auto child = std::make_unique<Directory>();
        auto& directory = *child;
        directory.parent = &current;
        current.directories.emplace_back(std::move(child));
        LoadDirectory(directory, metadata.first_child_directory_offset);
    }

    if (metadata.next_sibling_offset != 0xFFFFFFFF) {
        auto sibling = std::make_unique<Directory>();
        auto& directory = *sibling;
        directory.parent = current.parent;
        current.parent->directories.emplace_back(std::move(sibling));
        LoadDirectory(directory, metadata.next_sibling_offset);
    }
}

void LayeredFS::LoadFile(Directory& parent, u32 offset) {
    FileMetadata metadata;
    romfs->ReadFile(header.file_metadata_table.offset + offset, sizeof(metadata),
                    reinterpret_cast<u8*>(&metadata));

    auto file = std::make_unique<File>();
    file->name = ReadName(header.file_metadata_table.offset + offset + sizeof(metadata),
                          metadata.name_length);
    file->path = parent.path + file->name;
    file->relocation.original_offset = header.file_data_offset + metadata.file_data_offset;
    file->relocation.size = metadata.file_data_length;
    file->parent = &parent;

    file_path_map.emplace(file->path, file.get());
    parent.files.emplace_back(std::move(file));

    if (metadata.next_sibling_offset != 0xFFFFFFFF) {
        LoadFile(parent, metadata.next_sibling_offset);
    }
}

std::string LayeredFS::ReadName(u32 offset, u32 name_length) {
    std::vector<u16_le> buffer(name_length / sizeof(u16_le));
    romfs->ReadFile(offset, name_length, reinterpret_cast<u8*>(buffer.data()));

    std::u16string name(buffer.size(), 0);
    std::transform(buffer.begin(), buffer.end(), name.begin(), [](u16_le character) {
        return static_cast<char16_t>(static_cast<u16>(character));
    });
    return Common::UTF16ToUTF8(name);
}

void LayeredFS::LoadRelocations() {
    if (!FileUtil::Exists(patch_path)) {
        return;
    }

    const FileUtil::DirectoryEntryCallable callback = [this,
                                                       &callback](u64* /*num_entries_out*/,
                                                                  const std::string& directory,
                                                                  const std::string& virtual_name) {
        auto* parent = directory_path_map.at(directory.substr(patch_path.size() - 1));

        if (FileUtil::IsDirectory(directory + virtual_name + DIR_SEP)) {
            const auto path = (directory + virtual_name + DIR_SEP).substr(patch_path.size() - 1);
            if (!directory_path_map.count(path)) { // Add this directory
                auto directory = std::make_unique<Directory>();
                directory->name = virtual_name;
                directory->path = path;
                directory->parent = parent;
                directory_path_map.emplace(path, directory.get());
                parent->directories.emplace_back(std::move(directory));
                LOG_INFO(Service_FS, "LayeredFS created directory {}", path);
            }
            return FileUtil::ForeachDirectoryEntry(nullptr, directory + virtual_name + DIR_SEP,
                                                   callback);
        }

        const auto path = (directory + virtual_name).substr(patch_path.size() - 1);
        if (!file_path_map.count(path)) { // Newly created file
            auto file = std::make_unique<File>();
            file->name = virtual_name;
            file->path = path;
            file->parent = parent;
            file_path_map.emplace(path, file.get());
            parent->files.emplace_back(std::move(file));
            LOG_INFO(Service_FS, "LayeredFS created file {}", path);
        }

        auto* file = file_path_map.at(path);
        file->relocation.replace_file = FileUtil::IOFile(directory + virtual_name, "rb");
        if (file->relocation.replace_file) {
            file->relocation.type = 1;
            file->relocation.size = file->relocation.replace_file.GetSize();
            LOG_INFO(Service_FS, "LayeredFS replacement file in use for {}", path);
        } else {
            LOG_ERROR(Service_FS, "Could not open replacement file for {}", path);
        }
        return true;
    };

    FileUtil::ForeachDirectoryEntry(nullptr, patch_path, callback);
}

void LayeredFS::LoadExtRelocations() {
    if (!FileUtil::Exists(patch_ext_path)) {
        return;
    }

    if (patch_ext_path.back() == '/' || patch_ext_path.back() == '\\') {
        // ScanDirectoryTree expects a path without trailing '/'
        patch_ext_path.erase(patch_ext_path.size() - 1, 1);
    }

    FileUtil::FSTEntry result;
    FileUtil::ScanDirectoryTree(patch_ext_path, result, 256);

    for (const auto& entry : result.children) {
        if (FileUtil::IsDirectory(entry.physicalName)) {
            continue;
        }

        const auto path = entry.physicalName.substr(patch_ext_path.size());
        if (path.size() >= 5 && path.substr(path.size() - 5) == ".stub") {
            // Remove the corresponding file if exists
            const auto file_path = path.substr(0, path.size() - 5);
            if (file_path_map.count(file_path)) {
                auto& file = *file_path_map[file_path];
                file.relocation.type = 3;
                file.relocation.size = 0;
                file_path_map.erase(file_path);
                LOG_INFO(Service_FS, "LayeredFS removed file {}", file_path);
            } else {
                LOG_WARNING(Service_FS, "LayeredFS file for stub {} not found", path);
            }
        } else if (path.size() >= 4) {
            const auto extension = path.substr(path.size() - 4);
            if (extension != ".ips" && extension != ".bps") {
                LOG_WARNING(Service_FS, "LayeredFS unknown ext file {}", path);
            }

            const auto file_path = path.substr(0, path.size() - 4);
            if (!file_path_map.count(file_path)) {
                LOG_WARNING(Service_FS, "LayeredFS original file for patch {} not found", path);
                continue;
            }

            FileUtil::IOFile patch_file(entry.physicalName, "rb");
            if (!patch_file) {
                LOG_ERROR(Service_FS, "LayeredFS Could not open file {}", entry.physicalName);
                continue;
            }

            const auto size = patch_file.GetSize();
            std::vector<u8> patch(size);
            if (patch_file.ReadBytes(patch.data(), size) != size) {
                LOG_ERROR(Service_FS, "LayeredFS Could not read file {}", entry.physicalName);
                continue;
            }

            auto& file = *file_path_map[file_path];
            std::vector<u8> buffer(file.relocation.size); // Original size
            romfs->ReadFile(file.relocation.original_offset, buffer.size(), buffer.data());

            bool ret = false;
            if (extension == ".ips") {
                ret = Patch::ApplyIpsPatch(patch, buffer);
            } else {
                ret = Patch::ApplyBpsPatch(patch, buffer);
            }

            if (ret) {
                LOG_INFO(Service_FS, "LayeredFS patched file {}", file_path);

                file.relocation.type = 2;
                file.relocation.size = buffer.size();
                file.relocation.patched_file = std::move(buffer);
            } else {
                LOG_ERROR(Service_FS, "LayeredFS failed to patch file {}", file_path);
            }
        } else {
            LOG_WARNING(Service_FS, "LayeredFS unknown ext file {}", path);
        }
    }
}

std::size_t GetNameSize(const std::string& name) {
    std::u16string u16name = Common::UTF8ToUTF16(name);
    return Common::AlignUp(u16name.size() * 2, 4);
}

void LayeredFS::PrepareBuildDirectory(Directory& current) {
    directory_metadata_offset_map.emplace(&current, current_directory_offset);
    directory_list.emplace_back(&current);
    current_directory_offset += sizeof(DirectoryMetadata) + GetNameSize(current.name);
}

void LayeredFS::PrepareBuildFile(File& current) {
    if (current.relocation.type == 3) { // Deleted files are not counted
        return;
    }
    file_metadata_offset_map.emplace(&current, current_file_offset);
    file_list.emplace_back(&current);
    current_file_offset += sizeof(FileMetadata) + GetNameSize(current.name);
}

void LayeredFS::PrepareBuild(Directory& current) {
    for (const auto& child : current.files) {
        PrepareBuildFile(*child);
    }

    for (const auto& child : current.directories) {
        PrepareBuildDirectory(*child);
    }

    for (const auto& child : current.directories) {
        PrepareBuild(*child);
    }
}

// Implementation from 3dbrew
u32 CalcHash(const std::string& name, u32 parent_offset) {
    u32 hash = parent_offset ^ 123456789;

    std::u16string u16name = Common::UTF8ToUTF16(name);
    std::vector<u16_le> tmp_buffer(u16name.size());
    std::transform(u16name.begin(), u16name.end(), tmp_buffer.begin(), [](char16_t character) {
        return static_cast<u16_le>(static_cast<u16>(character));
    });

    std::vector<u8> buffer(tmp_buffer.size() * 2);
    std::memcpy(buffer.data(), tmp_buffer.data(), buffer.size());
    for (std::size_t i = 0; i < buffer.size(); i += 2) {
        hash = (hash >> 5) | (hash << 27);
        hash ^= static_cast<u16>((buffer[i]) | (buffer[i + 1] << 8));
    }
    return hash;
}

std::size_t WriteName(u8* dest, std::u16string name) {
    const auto buffer_size = Common::AlignUp(name.size() * 2, 4);
    std::vector<u16_le> buffer(buffer_size / 2);
    std::transform(name.begin(), name.end(), buffer.begin(), [](char16_t character) {
        return static_cast<u16_le>(static_cast<u16>(character));
    });
    std::memcpy(dest, buffer.data(), buffer_size);

    return buffer_size;
}

void LayeredFS::BuildDirectories() {
    directory_metadata_table.resize(current_directory_offset, 0xFF);

    std::size_t written = 0;
    for (const auto& directory : directory_list) {
        DirectoryMetadata metadata;
        std::memset(&metadata, 0xFF, sizeof(metadata));
        metadata.parent_directory_offset = directory_metadata_offset_map.at(directory->parent);

        if (directory->parent != directory) {
            bool flag = false;
            for (const auto& sibling : directory->parent->directories) {
                if (flag) {
                    metadata.next_sibling_offset = directory_metadata_offset_map.at(sibling.get());
                    break;
                } else if (sibling.get() == directory) {
                    flag = true;
                }
            }
        }

        if (!directory->directories.empty()) {
            metadata.first_child_directory_offset =
                directory_metadata_offset_map.at(directory->directories.front().get());
        }

        if (!directory->files.empty()) {
            metadata.first_file_offset =
                file_metadata_offset_map.at(directory->files.front().get());
        }

        const auto bucket = CalcHash(directory->name, metadata.parent_directory_offset) %
                            directory_hash_table.size();
        metadata.hash_bucket_next = directory_hash_table[bucket];
        directory_hash_table[bucket] = directory_metadata_offset_map.at(directory);

        // Write metadata and name
        std::u16string u16name = Common::UTF8ToUTF16(directory->name);
        metadata.name_length = u16name.size() * 2;

        std::memcpy(directory_metadata_table.data() + written, &metadata, sizeof(metadata));
        written += sizeof(metadata);

        written += WriteName(directory_metadata_table.data() + written, u16name);
    }

    ASSERT_MSG(written == directory_metadata_table.size(),
               "Calculated size for directory metadata table is wrong");
}

void LayeredFS::BuildFiles() {
    file_metadata_table.resize(current_file_offset, 0xFF);

    std::size_t written = 0;
    for (const auto& file : file_list) {
        FileMetadata metadata;
        std::memset(&metadata, 0xFF, sizeof(metadata));

        metadata.parent_directory_offset = directory_metadata_offset_map.at(file->parent);

        bool flag = false;
        for (const auto& sibling : file->parent->files) {
            if (sibling->relocation.type == 3) { // removed file
                continue;
            }
            if (flag) {
                metadata.next_sibling_offset = file_metadata_offset_map.at(sibling.get());
                break;
            } else if (sibling.get() == file) {
                flag = true;
            }
        }

        metadata.file_data_offset = current_data_offset;
        metadata.file_data_length = file->relocation.size;
        current_data_offset += Common::AlignUp(metadata.file_data_length, 16);
        if (metadata.file_data_length != 0) {
            data_offset_map.emplace(metadata.file_data_offset, file);
        }

        const auto bucket =
            CalcHash(file->name, metadata.parent_directory_offset) % file_hash_table.size();
        metadata.hash_bucket_next = file_hash_table[bucket];
        file_hash_table[bucket] = file_metadata_offset_map.at(file);

        // Write metadata and name
        std::u16string u16name = Common::UTF8ToUTF16(file->name);
        metadata.name_length = u16name.size() * 2;

        std::memcpy(file_metadata_table.data() + written, &metadata, sizeof(metadata));
        written += sizeof(metadata);

        written += WriteName(file_metadata_table.data() + written, u16name);
    }

    ASSERT_MSG(written == file_metadata_table.size(),
               "Calculated size for file metadata table is wrong");
}

// Implementation from 3dbrew
std::size_t GetHashTableSize(std::size_t entry_count) {
    if (entry_count < 3) {
        return 3;
    } else if (entry_count < 19) {
        return entry_count | 1;
    } else {
        std::size_t count = entry_count;
        while (count % 2 == 0 || count % 3 == 0 || count % 5 == 0 || count % 7 == 0 ||
               count % 11 == 0 || count % 13 == 0 || count % 17 == 0) {
            count++;
        }
        return count;
    }
}

void LayeredFS::RebuildMetadata() {
    PrepareBuildDirectory(root);
    PrepareBuild(root);

    directory_hash_table.resize(GetHashTableSize(directory_list.size()), 0xFFFFFFFF);
    file_hash_table.resize(GetHashTableSize(file_list.size()), 0xFFFFFFFF);

    BuildDirectories();
    BuildFiles();

    // Create header
    RomFSHeader header;
    header.header_length = sizeof(header);
    header.directory_hash_table = {
        /*offset*/ sizeof(header),
        /*length*/ static_cast<u32_le>(directory_hash_table.size() * sizeof(u32_le))};
    header.directory_metadata_table = {
        /*offset*/
        header.directory_hash_table.offset + header.directory_hash_table.length,
        /*length*/ static_cast<u32_le>(directory_metadata_table.size())};
    header.file_hash_table = {
        /*offset*/
        header.directory_metadata_table.offset + header.directory_metadata_table.length,
        /*length*/ static_cast<u32_le>(file_hash_table.size() * sizeof(u32_le))};
    header.file_metadata_table = {/*offset*/ header.file_hash_table.offset +
                                      header.file_hash_table.length,
                                  /*length*/ static_cast<u32_le>(file_metadata_table.size())};
    header.file_data_offset =
        Common::AlignUp(header.file_metadata_table.offset + header.file_metadata_table.length, 16);

    // Write hash table and metadata table
    metadata.resize(header.file_data_offset);
    std::memcpy(metadata.data(), &header, header.header_length);
    std::memcpy(metadata.data() + header.directory_hash_table.offset, directory_hash_table.data(),
                header.directory_hash_table.length);
    std::memcpy(metadata.data() + header.directory_metadata_table.offset,
                directory_metadata_table.data(), header.directory_metadata_table.length);
    std::memcpy(metadata.data() + header.file_hash_table.offset, file_hash_table.data(),
                header.file_hash_table.length);
    std::memcpy(metadata.data() + header.file_metadata_table.offset, file_metadata_table.data(),
                header.file_metadata_table.length);
}

std::size_t LayeredFS::GetSize() const {
    return metadata.size() + current_data_offset;
}

std::size_t LayeredFS::ReadFile(std::size_t offset, std::size_t length, u8* buffer) {
    ASSERT_MSG(offset + length <= GetSize(), "Out of bound");

    std::size_t read_size = 0;
    if (offset < metadata.size()) {
        // First read the metadata
        const auto to_read = std::min(metadata.size() - offset, length);
        std::memcpy(buffer, metadata.data() + offset, to_read);
        read_size += to_read;
        offset = 0;
    } else {
        offset -= metadata.size();
    }

    // Read files
    auto current = (--data_offset_map.upper_bound(offset));
    while (read_size < length) {
        const auto relative_offset = offset - current->first;
        std::size_t to_read{};
        if (current->second->relocation.size > relative_offset) {
            to_read =
                std::min(current->second->relocation.size - relative_offset, length - read_size);
        }
        const auto alignment =
            std::min(Common::AlignUp(current->second->relocation.size, 16) - relative_offset,
                     length - read_size) -
            to_read;

        // Read the file in different ways depending on relocation type
        auto& relocation = current->second->relocation;
        if (relocation.type == 0) { // none
            romfs->ReadFile(relocation.original_offset + relative_offset, to_read,
                            buffer + read_size);
        } else if (relocation.type == 1) { // replace
            relocation.replace_file.Seek(relative_offset, SEEK_SET);
            relocation.replace_file.ReadBytes(buffer + read_size, to_read);
        } else if (relocation.type == 2) { // patch
            std::memcpy(buffer + read_size, relocation.patched_file.data() + relative_offset,
                        to_read);
        } else {
            UNREACHABLE();
        }

        std::memset(buffer + read_size + to_read, 0, alignment);

        read_size += to_read + alignment;
        offset += to_read + alignment;
        current++;
    }

    return read_size;
}

} // namespace FileSys
core/file_sys: LayeredFS implementation This implementation is different from Luma3DS's which directly hooks the SDK functions. Instead, we read the RomFS's metadata and figure out the directory and file structure. Then, relocations (i.e. replacements/deletions/patches) are applied. Afterwards, we rebuild the metadata, and assign 'fake' data offsets to the files. When we want to read file data from this rebuilt RomFS, we use binary search to find the last data offset smaller or equal to the given offset and read from that file (either from the original RomFS, or from replacement files, or from buffered data with patches applied) and any later files when length is not enough. The code that rebuilds the metadata is pretty complex and uses quite a few variables to keep track of necessary information like metadata offsets. According to my tests, it is able to build RomFS-es identical to the original (but without trailing garbage data) when no relocations are applied. 2020-02-07 04:54:07 +00:00			`// Copyright 2020 Citra Emulator Project`
			`// Licensed under GPLv2 or any later version`
			`// Refer to the license.txt file included.`

			`#include <algorithm>`
			`#include <cstring>`
			`#include "common/alignment.h"`
			`#include "common/assert.h"`
			`#include "common/common_paths.h"`
			`#include "common/file_util.h"`
			`#include "common/string_util.h"`
			`#include "common/swap.h"`
			`#include "core/file_sys/layered_fs.h"`
			`#include "core/file_sys/patch.h"`

			`namespace FileSys {`

			`struct FileRelocationInfo {`
			`int type; // 0 - none, 1 - replaced / created, 2 - patched, 3 - removed`
			`u64 original_offset; // Type 0. Offset is absolute`
			`FileUtil::IOFile replace_file; // Type 1`
			`std::vector<u8> patched_file; // Type 2`
			`u64 size; // Relocated file size`
			`};`
			`struct LayeredFS::File {`
			`std::string name;`
			`std::string path;`
			`FileRelocationInfo relocation{};`
			`Directory* parent;`
			`};`

			`struct DirectoryMetadata {`
			`u32_le parent_directory_offset;`
			`u32_le next_sibling_offset;`
			`u32_le first_child_directory_offset;`
			`u32_le first_file_offset;`
			`u32_le hash_bucket_next;`
			`u32_le name_length;`
			`// Followed by a name of name length (aligned up to 4)`
			`};`
			`static_assert(sizeof(DirectoryMetadata) == 0x18, "Size of DirectoryMetadata is not correct");`

			`struct FileMetadata {`
			`u32_le parent_directory_offset;`
			`u32_le next_sibling_offset;`
			`u64_le file_data_offset;`
			`u64_le file_data_length;`
			`u32_le hash_bucket_next;`
			`u32_le name_length;`
			`// Followed by a name of name length (aligned up to 4)`
			`};`
			`static_assert(sizeof(FileMetadata) == 0x20, "Size of FileMetadata is not correct");`

			`LayeredFS::LayeredFS(std::shared_ptr<RomFSReader> romfs_, std::string patch_path_,`
			`std::string patch_ext_path_)`
			`: romfs(std::move(romfs_)), patch_path(std::move(patch_path_)),`
			`patch_ext_path(std::move(patch_ext_path_)) {`

			`romfs->ReadFile(0, sizeof(header), reinterpret_cast<u8*>(&header));`

			`ASSERT_MSG(header.header_length == sizeof(header), "Header size is incorrect");`

			`// TODO: is root always the first directory in table?`
			`root.parent = &root;`
			`LoadDirectory(root, 0);`

			`LoadRelocations();`
			`LoadExtRelocations();`

			`RebuildMetadata();`
			`}`

			`LayeredFS::~LayeredFS() = default;`

			`void LayeredFS::LoadDirectory(Directory& current, u32 offset) {`
			`DirectoryMetadata metadata;`
			`romfs->ReadFile(header.directory_metadata_table.offset + offset, sizeof(metadata),`
			`reinterpret_cast<u8*>(&metadata));`

			`current.name = ReadName(header.directory_metadata_table.offset + offset + sizeof(metadata),`
			`metadata.name_length);`
			`current.path = current.parent->path + current.name + DIR_SEP;`
			`directory_path_map.emplace(current.path, &current);`

			`if (metadata.first_file_offset != 0xFFFFFFFF) {`
			`LoadFile(current, metadata.first_file_offset);`
			`}`

			`if (metadata.first_child_directory_offset != 0xFFFFFFFF) {`
			`auto child = std::make_unique<Directory>();`
			`auto& directory = *child;`
			`directory.parent = &current;`
			`current.directories.emplace_back(std::move(child));`
			`LoadDirectory(directory, metadata.first_child_directory_offset);`
			`}`

			`if (metadata.next_sibling_offset != 0xFFFFFFFF) {`
			`auto sibling = std::make_unique<Directory>();`
			`auto& directory = *sibling;`
			`directory.parent = current.parent;`
			`current.parent->directories.emplace_back(std::move(sibling));`
			`LoadDirectory(directory, metadata.next_sibling_offset);`
			`}`
			`}`

			`void LayeredFS::LoadFile(Directory& parent, u32 offset) {`
			`FileMetadata metadata;`
			`romfs->ReadFile(header.file_metadata_table.offset + offset, sizeof(metadata),`
			`reinterpret_cast<u8*>(&metadata));`

			`auto file = std::make_unique<File>();`
			`file->name = ReadName(header.file_metadata_table.offset + offset + sizeof(metadata),`
			`metadata.name_length);`
			`file->path = parent.path + file->name;`
			`file->relocation.original_offset = header.file_data_offset + metadata.file_data_offset;`
			`file->relocation.size = metadata.file_data_length;`
			`file->parent = &parent;`

			`file_path_map.emplace(file->path, file.get());`
			`parent.files.emplace_back(std::move(file));`

			`if (metadata.next_sibling_offset != 0xFFFFFFFF) {`
			`LoadFile(parent, metadata.next_sibling_offset);`
			`}`
			`}`

			`std::string LayeredFS::ReadName(u32 offset, u32 name_length) {`
			`std::vector<u16_le> buffer(name_length / sizeof(u16_le));`
			`romfs->ReadFile(offset, name_length, reinterpret_cast<u8*>(buffer.data()));`

			`std::u16string name(buffer.size(), 0);`
			`std::transform(buffer.begin(), buffer.end(), name.begin(), [](u16_le character) {`
			`return static_cast<char16_t>(static_cast<u16>(character));`
			`});`
			`return Common::UTF16ToUTF8(name);`
			`}`

			`void LayeredFS::LoadRelocations() {`
			`if (!FileUtil::Exists(patch_path)) {`
			`return;`
			`}`

			`const FileUtil::DirectoryEntryCallable callback = [this,`
			`&callback](u64* /num_entries_out/,`
			`const std::string& directory,`
			`const std::string& virtual_name) {`
			`auto* parent = directory_path_map.at(directory.substr(patch_path.size() - 1));`

			`if (FileUtil::IsDirectory(directory + virtual_name + DIR_SEP)) {`
			`const auto path = (directory + virtual_name + DIR_SEP).substr(patch_path.size() - 1);`
			`if (!directory_path_map.count(path)) { // Add this directory`
			`auto directory = std::make_unique<Directory>();`
			`directory->name = virtual_name;`
			`directory->path = path;`
			`directory->parent = parent;`
			`directory_path_map.emplace(path, directory.get());`
			`parent->directories.emplace_back(std::move(directory));`
			`LOG_INFO(Service_FS, "LayeredFS created directory {}", path);`
			`}`
			`return FileUtil::ForeachDirectoryEntry(nullptr, directory + virtual_name + DIR_SEP,`
			`callback);`
			`}`

			`const auto path = (directory + virtual_name).substr(patch_path.size() - 1);`
			`if (!file_path_map.count(path)) { // Newly created file`
			`auto file = std::make_unique<File>();`
			`file->name = virtual_name;`
			`file->path = path;`
			`file->parent = parent;`
			`file_path_map.emplace(path, file.get());`
			`parent->files.emplace_back(std::move(file));`
			`LOG_INFO(Service_FS, "LayeredFS created file {}", path);`
			`}`

			`auto* file = file_path_map.at(path);`
			`file->relocation.replace_file = FileUtil::IOFile(directory + virtual_name, "rb");`
			`if (file->relocation.replace_file) {`
			`file->relocation.type = 1;`
			`file->relocation.size = file->relocation.replace_file.GetSize();`
			`LOG_INFO(Service_FS, "LayeredFS replacement file in use for {}", path);`
			`} else {`
			`LOG_ERROR(Service_FS, "Could not open replacement file for {}", path);`
			`}`
			`return true;`
			`};`

			`FileUtil::ForeachDirectoryEntry(nullptr, patch_path, callback);`
			`}`

			`void LayeredFS::LoadExtRelocations() {`
			`if (!FileUtil::Exists(patch_ext_path)) {`
			`return;`
			`}`

			`if (patch_ext_path.back() == '/' \|\| patch_ext_path.back() == '\\') {`
			`// ScanDirectoryTree expects a path without trailing '/'`
			`patch_ext_path.erase(patch_ext_path.size() - 1, 1);`
			`}`

			`FileUtil::FSTEntry result;`
			`FileUtil::ScanDirectoryTree(patch_ext_path, result, 256);`

			`for (const auto& entry : result.children) {`
			`if (FileUtil::IsDirectory(entry.physicalName)) {`
			`continue;`
			`}`

			`const auto path = entry.physicalName.substr(patch_ext_path.size());`
			`if (path.size() >= 5 && path.substr(path.size() - 5) == ".stub") {`
			`// Remove the corresponding file if exists`
			`const auto file_path = path.substr(0, path.size() - 5);`
			`if (file_path_map.count(file_path)) {`
			`auto& file = *file_path_map[file_path];`
			`file.relocation.type = 3;`
			`file.relocation.size = 0;`
			`file_path_map.erase(file_path);`
			`LOG_INFO(Service_FS, "LayeredFS removed file {}", file_path);`
			`} else {`
			`LOG_WARNING(Service_FS, "LayeredFS file for stub {} not found", path);`
			`}`
			`} else if (path.size() >= 4) {`
			`const auto extension = path.substr(path.size() - 4);`
			`if (extension != ".ips" && extension != ".bps") {`
			`LOG_WARNING(Service_FS, "LayeredFS unknown ext file {}", path);`
			`}`

			`const auto file_path = path.substr(0, path.size() - 4);`
			`if (!file_path_map.count(file_path)) {`
			`LOG_WARNING(Service_FS, "LayeredFS original file for patch {} not found", path);`
			`continue;`
			`}`

			`FileUtil::IOFile patch_file(entry.physicalName, "rb");`
			`if (!patch_file) {`
			`LOG_ERROR(Service_FS, "LayeredFS Could not open file {}", entry.physicalName);`
			`continue;`
			`}`

			`const auto size = patch_file.GetSize();`
			`std::vector<u8> patch(size);`
			`if (patch_file.ReadBytes(patch.data(), size) != size) {`
			`LOG_ERROR(Service_FS, "LayeredFS Could not read file {}", entry.physicalName);`
			`continue;`
			`}`

			`auto& file = *file_path_map[file_path];`
			`std::vector<u8> buffer(file.relocation.size); // Original size`
			`romfs->ReadFile(file.relocation.original_offset, buffer.size(), buffer.data());`

			`bool ret = false;`
			`if (extension == ".ips") {`
			`ret = Patch::ApplyIpsPatch(patch, buffer);`
			`} else {`
			`ret = Patch::ApplyBpsPatch(patch, buffer);`
			`}`

			`if (ret) {`
			`LOG_INFO(Service_FS, "LayeredFS patched file {}", file_path);`

			`file.relocation.type = 2;`
			`file.relocation.size = buffer.size();`
			`file.relocation.patched_file = std::move(buffer);`
			`} else {`
			`LOG_ERROR(Service_FS, "LayeredFS failed to patch file {}", file_path);`
			`}`
			`} else {`
			`LOG_WARNING(Service_FS, "LayeredFS unknown ext file {}", path);`
			`}`
			`}`
			`}`

			`std::size_t GetNameSize(const std::string& name) {`
			`std::u16string u16name = Common::UTF8ToUTF16(name);`
			`return Common::AlignUp(u16name.size() * 2, 4);`
			`}`

			`void LayeredFS::PrepareBuildDirectory(Directory& current) {`
			`directory_metadata_offset_map.emplace(&current, current_directory_offset);`
			`directory_list.emplace_back(&current);`
			`current_directory_offset += sizeof(DirectoryMetadata) + GetNameSize(current.name);`
			`}`

			`void LayeredFS::PrepareBuildFile(File& current) {`
			`if (current.relocation.type == 3) { // Deleted files are not counted`
			`return;`
			`}`
			`file_metadata_offset_map.emplace(&current, current_file_offset);`
			`file_list.emplace_back(&current);`
			`current_file_offset += sizeof(FileMetadata) + GetNameSize(current.name);`
			`}`

			`void LayeredFS::PrepareBuild(Directory& current) {`
			`for (const auto& child : current.files) {`
			`PrepareBuildFile(*child);`
			`}`

			`for (const auto& child : current.directories) {`
			`PrepareBuildDirectory(*child);`
			`}`

			`for (const auto& child : current.directories) {`
			`PrepareBuild(*child);`
			`}`
			`}`

			`// Implementation from 3dbrew`
			`u32 CalcHash(const std::string& name, u32 parent_offset) {`
			`u32 hash = parent_offset ^ 123456789;`

			`std::u16string u16name = Common::UTF8ToUTF16(name);`
			`std::vector<u16_le> tmp_buffer(u16name.size());`
			`std::transform(u16name.begin(), u16name.end(), tmp_buffer.begin(), [](char16_t character) {`
			`return static_cast<u16_le>(static_cast<u16>(character));`
			`});`

			`std::vector<u8> buffer(tmp_buffer.size() * 2);`
			`std::memcpy(buffer.data(), tmp_buffer.data(), buffer.size());`
			`for (std::size_t i = 0; i < buffer.size(); i += 2) {`
			`hash = (hash >> 5) \| (hash << 27);`
			`hash ^= static_cast<u16>((buffer[i]) \| (buffer[i + 1] << 8));`
			`}`
			`return hash;`
			`}`

			`std::size_t WriteName(u8* dest, std::u16string name) {`
			`const auto buffer_size = Common::AlignUp(name.size() * 2, 4);`
			`std::vector<u16_le> buffer(buffer_size / 2);`
			`std::transform(name.begin(), name.end(), buffer.begin(), [](char16_t character) {`
			`return static_cast<u16_le>(static_cast<u16>(character));`
			`});`
			`std::memcpy(dest, buffer.data(), buffer_size);`

			`return buffer_size;`
			`}`

			`void LayeredFS::BuildDirectories() {`
			`directory_metadata_table.resize(current_directory_offset, 0xFF);`

			`std::size_t written = 0;`
			`for (const auto& directory : directory_list) {`
			`DirectoryMetadata metadata;`
			`std::memset(&metadata, 0xFF, sizeof(metadata));`
			`metadata.parent_directory_offset = directory_metadata_offset_map.at(directory->parent);`

			`if (directory->parent != directory) {`
			`bool flag = false;`
			`for (const auto& sibling : directory->parent->directories) {`
			`if (flag) {`
			`metadata.next_sibling_offset = directory_metadata_offset_map.at(sibling.get());`
			`break;`
			`} else if (sibling.get() == directory) {`
			`flag = true;`
			`}`
			`}`
			`}`

			`if (!directory->directories.empty()) {`
			`metadata.first_child_directory_offset =`
			`directory_metadata_offset_map.at(directory->directories.front().get());`
			`}`

			`if (!directory->files.empty()) {`
			`metadata.first_file_offset =`
			`file_metadata_offset_map.at(directory->files.front().get());`
			`}`

			`const auto bucket = CalcHash(directory->name, metadata.parent_directory_offset) %`
			`directory_hash_table.size();`
			`metadata.hash_bucket_next = directory_hash_table[bucket];`
			`directory_hash_table[bucket] = directory_metadata_offset_map.at(directory);`

			`// Write metadata and name`
			`std::u16string u16name = Common::UTF8ToUTF16(directory->name);`
			`metadata.name_length = u16name.size() * 2;`

			`std::memcpy(directory_metadata_table.data() + written, &metadata, sizeof(metadata));`
			`written += sizeof(metadata);`

			`written += WriteName(directory_metadata_table.data() + written, u16name);`
			`}`

			`ASSERT_MSG(written == directory_metadata_table.size(),`
			`"Calculated size for directory metadata table is wrong");`
			`}`

			`void LayeredFS::BuildFiles() {`
			`file_metadata_table.resize(current_file_offset, 0xFF);`

			`std::size_t written = 0;`
			`for (const auto& file : file_list) {`
			`FileMetadata metadata;`
			`std::memset(&metadata, 0xFF, sizeof(metadata));`

			`metadata.parent_directory_offset = directory_metadata_offset_map.at(file->parent);`

			`bool flag = false;`
			`for (const auto& sibling : file->parent->files) {`
			`if (sibling->relocation.type == 3) { // removed file`
			`continue;`
			`}`
			`if (flag) {`
			`metadata.next_sibling_offset = file_metadata_offset_map.at(sibling.get());`
			`break;`
			`} else if (sibling.get() == file) {`
			`flag = true;`
			`}`
			`}`

			`metadata.file_data_offset = current_data_offset;`
			`metadata.file_data_length = file->relocation.size;`
			`current_data_offset += Common::AlignUp(metadata.file_data_length, 16);`
			`if (metadata.file_data_length != 0) {`
			`data_offset_map.emplace(metadata.file_data_offset, file);`
			`}`

			`const auto bucket =`
			`CalcHash(file->name, metadata.parent_directory_offset) % file_hash_table.size();`
			`metadata.hash_bucket_next = file_hash_table[bucket];`
			`file_hash_table[bucket] = file_metadata_offset_map.at(file);`

			`// Write metadata and name`
			`std::u16string u16name = Common::UTF8ToUTF16(file->name);`
			`metadata.name_length = u16name.size() * 2;`

			`std::memcpy(file_metadata_table.data() + written, &metadata, sizeof(metadata));`
			`written += sizeof(metadata);`

			`written += WriteName(file_metadata_table.data() + written, u16name);`
			`}`

			`ASSERT_MSG(written == file_metadata_table.size(),`
			`"Calculated size for file metadata table is wrong");`
			`}`

			`// Implementation from 3dbrew`
			`std::size_t GetHashTableSize(std::size_t entry_count) {`
			`if (entry_count < 3) {`
			`return 3;`
			`} else if (entry_count < 19) {`
			`return entry_count \| 1;`
			`} else {`
			`std::size_t count = entry_count;`
			`while (count % 2 == 0 \|\| count % 3 == 0 \|\| count % 5 == 0 \|\| count % 7 == 0 \|\|`
			`count % 11 == 0 \|\| count % 13 == 0 \|\| count % 17 == 0) {`
			`count++;`
			`}`
			`return count;`
			`}`
			`}`

			`void LayeredFS::RebuildMetadata() {`
			`PrepareBuildDirectory(root);`
			`PrepareBuild(root);`

			`directory_hash_table.resize(GetHashTableSize(directory_list.size()), 0xFFFFFFFF);`
			`file_hash_table.resize(GetHashTableSize(file_list.size()), 0xFFFFFFFF);`

			`BuildDirectories();`
			`BuildFiles();`

			`// Create header`
			`RomFSHeader header;`
			`header.header_length = sizeof(header);`
			`header.directory_hash_table = {`
			`/offset/ sizeof(header),`
			`/length/ static_cast<u32_le>(directory_hash_table.size() * sizeof(u32_le))};`
			`header.directory_metadata_table = {`
			`/offset/`
			`header.directory_hash_table.offset + header.directory_hash_table.length,`
			`/length/ static_cast<u32_le>(directory_metadata_table.size())};`
			`header.file_hash_table = {`
			`/offset/`
			`header.directory_metadata_table.offset + header.directory_metadata_table.length,`
			`/length/ static_cast<u32_le>(file_hash_table.size() * sizeof(u32_le))};`
			`header.file_metadata_table = {/offset/ header.file_hash_table.offset +`
			`header.file_hash_table.length,`
			`/length/ static_cast<u32_le>(file_metadata_table.size())};`
			`header.file_data_offset =`
			`Common::AlignUp(header.file_metadata_table.offset + header.file_metadata_table.length, 16);`

			`// Write hash table and metadata table`
			`metadata.resize(header.file_data_offset);`
			`std::memcpy(metadata.data(), &header, header.header_length);`
			`std::memcpy(metadata.data() + header.directory_hash_table.offset, directory_hash_table.data(),`
			`header.directory_hash_table.length);`
			`std::memcpy(metadata.data() + header.directory_metadata_table.offset,`
			`directory_metadata_table.data(), header.directory_metadata_table.length);`
			`std::memcpy(metadata.data() + header.file_hash_table.offset, file_hash_table.data(),`
			`header.file_hash_table.length);`
			`std::memcpy(metadata.data() + header.file_metadata_table.offset, file_metadata_table.data(),`
			`header.file_metadata_table.length);`
			`}`

			`std::size_t LayeredFS::GetSize() const {`
			`return metadata.size() + current_data_offset;`
			`}`

			`std::size_t LayeredFS::ReadFile(std::size_t offset, std::size_t length, u8* buffer) {`
			`ASSERT_MSG(offset + length <= GetSize(), "Out of bound");`

			`std::size_t read_size = 0;`
			`if (offset < metadata.size()) {`
			`// First read the metadata`
			`const auto to_read = std::min(metadata.size() - offset, length);`
			`std::memcpy(buffer, metadata.data() + offset, to_read);`
			`read_size += to_read;`
			`offset = 0;`
			`} else {`
			`offset -= metadata.size();`
			`}`

			`// Read files`
			`auto current = (--data_offset_map.upper_bound(offset));`
			`while (read_size < length) {`
			`const auto relative_offset = offset - current->first;`
			`std::size_t to_read{};`
			`if (current->second->relocation.size > relative_offset) {`
			`to_read =`
			`std::min(current->second->relocation.size - relative_offset, length - read_size);`
			`}`
			`const auto alignment =`
			`std::min(Common::AlignUp(current->second->relocation.size, 16) - relative_offset,`
			`length - read_size) -`
			`to_read;`

			`// Read the file in different ways depending on relocation type`
			`auto& relocation = current->second->relocation;`
			`if (relocation.type == 0) { // none`
			`romfs->ReadFile(relocation.original_offset + relative_offset, to_read,`
			`buffer + read_size);`
			`} else if (relocation.type == 1) { // replace`
			`relocation.replace_file.Seek(relative_offset, SEEK_SET);`
			`relocation.replace_file.ReadBytes(buffer + read_size, to_read);`
			`} else if (relocation.type == 2) { // patch`
			`std::memcpy(buffer + read_size, relocation.patched_file.data() + relative_offset,`
			`to_read);`
			`} else {`
			`UNREACHABLE();`
			`}`

			`std::memset(buffer + read_size + to_read, 0, alignment);`

			`read_size += to_read + alignment;`
			`offset += to_read + alignment;`
			`current++;`
			`}`

			`return read_size;`
			`}`

			`} // namespace FileSys`