mirror of
https://github.com/dolphin-emu/dolphin.git
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58743416bb
These disc images are only used on dev units and not retail units. There are two important differences compared to normal Wii disc images: - The data starts 0x8000 bytes into each partition instead of 0x20000 - The data of a partition is stored unencrypted and contains no hashes Our old implementation was just guesswork and doesn't work at all. According to testing by GerbilSoft, this commit's implementation is able to read and extract files in the filesystem correctly, but the tested game still isn't able to boot. (It's thanks to their info about unencrypted disc images that I was able to make this commit.)
460 lines
14 KiB
C++
460 lines
14 KiB
C++
// Copyright 2008 Dolphin Emulator Project
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// Licensed under GPLv2+
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// Refer to the license.txt file included.
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#include "DiscIO/VolumeWii.h"
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#include <algorithm>
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#include <array>
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#include <cstddef>
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#include <cstring>
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#include <map>
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#include <mbedtls/aes.h>
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#include <mbedtls/sha1.h>
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#include <memory>
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#include <optional>
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#include <string>
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#include <utility>
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#include <vector>
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#include "Common/Assert.h"
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#include "Common/CommonTypes.h"
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#include "Common/Logging/Log.h"
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#include "Common/MsgHandler.h"
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#include "Common/Swap.h"
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#include "DiscIO/Blob.h"
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#include "DiscIO/DiscExtractor.h"
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#include "DiscIO/Enums.h"
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#include "DiscIO/FileSystemGCWii.h"
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#include "DiscIO/Filesystem.h"
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#include "DiscIO/Volume.h"
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#include "DiscIO/WiiSaveBanner.h"
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namespace DiscIO
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{
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VolumeWii::VolumeWii(std::unique_ptr<BlobReader> reader)
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: m_pReader(std::move(reader)), m_game_partition(PARTITION_NONE),
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m_last_decrypted_block(UINT64_MAX)
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{
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ASSERT(m_pReader);
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m_encrypted = m_pReader->ReadSwapped<u32>(0x60) == u32(0);
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for (u32 partition_group = 0; partition_group < 4; ++partition_group)
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{
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const std::optional<u32> number_of_partitions =
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m_pReader->ReadSwapped<u32>(0x40000 + (partition_group * 8));
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if (!number_of_partitions)
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continue;
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const std::optional<u64> partition_table_offset =
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ReadSwappedAndShifted(0x40000 + (partition_group * 8) + 4, PARTITION_NONE);
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if (!partition_table_offset)
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continue;
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for (u32 i = 0; i < number_of_partitions; i++)
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{
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const std::optional<u64> partition_offset =
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ReadSwappedAndShifted(*partition_table_offset + (i * 8), PARTITION_NONE);
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if (!partition_offset)
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continue;
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const Partition partition(*partition_offset);
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const std::optional<u32> partition_type =
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m_pReader->ReadSwapped<u32>(*partition_table_offset + (i * 8) + 4);
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if (!partition_type)
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continue;
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// If this is the game partition, set m_game_partition
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if (m_game_partition == PARTITION_NONE && *partition_type == 0)
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m_game_partition = partition;
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auto get_ticket = [this, partition]() -> IOS::ES::TicketReader {
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std::vector<u8> ticket_buffer(sizeof(IOS::ES::Ticket));
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if (!m_pReader->Read(partition.offset, ticket_buffer.size(), ticket_buffer.data()))
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return INVALID_TICKET;
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return IOS::ES::TicketReader{std::move(ticket_buffer)};
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};
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auto get_tmd = [this, partition]() -> IOS::ES::TMDReader {
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const std::optional<u32> tmd_size = m_pReader->ReadSwapped<u32>(partition.offset + 0x2a4);
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const std::optional<u64> tmd_address =
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ReadSwappedAndShifted(partition.offset + 0x2a8, PARTITION_NONE);
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if (!tmd_size || !tmd_address)
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return INVALID_TMD;
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if (!IOS::ES::IsValidTMDSize(*tmd_size))
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{
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// This check is normally done by ES in ES_DiVerify, but that would happen too late
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// (after allocating the buffer), so we do the check here.
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PanicAlert("Invalid TMD size");
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return INVALID_TMD;
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}
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std::vector<u8> tmd_buffer(*tmd_size);
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if (!m_pReader->Read(partition.offset + *tmd_address, *tmd_size, tmd_buffer.data()))
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return INVALID_TMD;
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return IOS::ES::TMDReader{std::move(tmd_buffer)};
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};
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auto get_key = [this, partition]() -> std::unique_ptr<mbedtls_aes_context> {
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const IOS::ES::TicketReader& ticket = *m_partitions[partition].ticket;
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if (!ticket.IsValid())
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return nullptr;
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const std::array<u8, 16> key = ticket.GetTitleKey();
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std::unique_ptr<mbedtls_aes_context> aes_context = std::make_unique<mbedtls_aes_context>();
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mbedtls_aes_setkey_dec(aes_context.get(), key.data(), 128);
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return aes_context;
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};
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auto get_file_system = [this, partition]() -> std::unique_ptr<FileSystem> {
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auto file_system = std::make_unique<FileSystemGCWii>(this, partition);
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return file_system->IsValid() ? std::move(file_system) : nullptr;
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};
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auto get_data_offset = [this, partition]() -> u64 {
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return ReadSwappedAndShifted(partition.offset + 0x2b8, PARTITION_NONE).value_or(0);
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};
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m_partitions.emplace(
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partition, PartitionDetails{Common::Lazy<std::unique_ptr<mbedtls_aes_context>>(get_key),
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Common::Lazy<IOS::ES::TicketReader>(get_ticket),
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Common::Lazy<IOS::ES::TMDReader>(get_tmd),
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Common::Lazy<std::unique_ptr<FileSystem>>(get_file_system),
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Common::Lazy<u64>(get_data_offset), *partition_type});
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}
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}
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}
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VolumeWii::~VolumeWii()
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{
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}
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bool VolumeWii::Read(u64 _ReadOffset, u64 _Length, u8* _pBuffer, const Partition& partition) const
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{
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if (partition == PARTITION_NONE)
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return m_pReader->Read(_ReadOffset, _Length, _pBuffer);
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auto it = m_partitions.find(partition);
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if (it == m_partitions.end())
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return false;
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const PartitionDetails& partition_details = it->second;
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if (!m_encrypted)
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{
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return m_pReader->Read(partition.offset + *partition_details.data_offset + _ReadOffset, _Length,
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_pBuffer);
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}
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if (m_pReader->SupportsReadWiiDecrypted())
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return m_pReader->ReadWiiDecrypted(_ReadOffset, _Length, _pBuffer, partition.offset);
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mbedtls_aes_context* aes_context = partition_details.key->get();
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if (!aes_context)
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return false;
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std::vector<u8> read_buffer(BLOCK_TOTAL_SIZE);
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while (_Length > 0)
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{
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// Calculate offsets
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u64 block_offset_on_disc = partition.offset + *partition_details.data_offset +
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_ReadOffset / BLOCK_DATA_SIZE * BLOCK_TOTAL_SIZE;
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u64 data_offset_in_block = _ReadOffset % BLOCK_DATA_SIZE;
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if (m_last_decrypted_block != block_offset_on_disc)
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{
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// Read the current block
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if (!m_pReader->Read(block_offset_on_disc, BLOCK_TOTAL_SIZE, read_buffer.data()))
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return false;
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// Decrypt the block's data.
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// 0x3D0 - 0x3DF in read_buffer will be overwritten,
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// but that won't affect anything, because we won't
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// use the content of read_buffer anymore after this
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mbedtls_aes_crypt_cbc(aes_context, MBEDTLS_AES_DECRYPT, BLOCK_DATA_SIZE, &read_buffer[0x3D0],
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&read_buffer[BLOCK_HEADER_SIZE], m_last_decrypted_block_data);
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m_last_decrypted_block = block_offset_on_disc;
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// The only thing we currently use from the 0x000 - 0x3FF part
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// of the block is the IV (at 0x3D0), but it also contains SHA-1
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// hashes that IOS uses to check that discs aren't tampered with.
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// http://wiibrew.org/wiki/Wii_Disc#Encrypted
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}
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// Copy the decrypted data
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u64 copy_size = std::min(_Length, BLOCK_DATA_SIZE - data_offset_in_block);
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memcpy(_pBuffer, &m_last_decrypted_block_data[data_offset_in_block],
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static_cast<size_t>(copy_size));
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// Update offsets
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_Length -= copy_size;
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_pBuffer += copy_size;
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_ReadOffset += copy_size;
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}
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return true;
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}
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bool VolumeWii::IsEncryptedAndHashed() const
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{
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return m_encrypted;
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}
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std::vector<Partition> VolumeWii::GetPartitions() const
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{
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std::vector<Partition> partitions;
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for (const auto& pair : m_partitions)
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partitions.push_back(pair.first);
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return partitions;
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}
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Partition VolumeWii::GetGamePartition() const
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{
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return m_game_partition;
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}
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std::optional<u32> VolumeWii::GetPartitionType(const Partition& partition) const
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{
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auto it = m_partitions.find(partition);
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return it != m_partitions.end() ? it->second.type : std::optional<u32>();
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}
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std::optional<u64> VolumeWii::GetTitleID(const Partition& partition) const
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{
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const IOS::ES::TicketReader& ticket = GetTicket(partition);
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if (!ticket.IsValid())
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return {};
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return ticket.GetTitleId();
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}
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const IOS::ES::TicketReader& VolumeWii::GetTicket(const Partition& partition) const
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{
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auto it = m_partitions.find(partition);
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return it != m_partitions.end() ? *it->second.ticket : INVALID_TICKET;
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}
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const IOS::ES::TMDReader& VolumeWii::GetTMD(const Partition& partition) const
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{
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auto it = m_partitions.find(partition);
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return it != m_partitions.end() ? *it->second.tmd : INVALID_TMD;
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}
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const FileSystem* VolumeWii::GetFileSystem(const Partition& partition) const
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{
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auto it = m_partitions.find(partition);
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return it != m_partitions.end() ? it->second.file_system->get() : nullptr;
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}
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u64 VolumeWii::EncryptedPartitionOffsetToRawOffset(u64 offset, const Partition& partition,
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u64 partition_data_offset)
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{
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if (partition == PARTITION_NONE)
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return offset;
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return partition.offset + partition_data_offset + (offset / BLOCK_DATA_SIZE * BLOCK_TOTAL_SIZE) +
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(offset % BLOCK_DATA_SIZE);
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}
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u64 VolumeWii::PartitionOffsetToRawOffset(u64 offset, const Partition& partition) const
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{
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auto it = m_partitions.find(partition);
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if (it == m_partitions.end())
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return offset;
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const u64 data_offset = *it->second.data_offset;
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if (!m_encrypted)
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return partition.offset + data_offset + offset;
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return EncryptedPartitionOffsetToRawOffset(offset, partition, data_offset);
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}
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std::string VolumeWii::GetGameID(const Partition& partition) const
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{
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char ID[6];
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if (!Read(0, 6, (u8*)ID, partition))
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return std::string();
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return DecodeString(ID);
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}
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Region VolumeWii::GetRegion() const
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{
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const std::optional<u32> region_code = m_pReader->ReadSwapped<u32>(0x4E000);
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if (!region_code)
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return Region::Unknown;
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const Region region = static_cast<Region>(*region_code);
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return region <= Region::NTSC_K ? region : Region::Unknown;
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}
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Country VolumeWii::GetCountry(const Partition& partition) const
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{
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// The 0 that we use as a default value is mapped to Country::Unknown and Region::Unknown
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u8 country_byte = ReadSwapped<u8>(3, partition).value_or(0);
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const Region region = GetRegion();
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if (RegionSwitchWii(country_byte) != region)
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return TypicalCountryForRegion(region);
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return CountrySwitch(country_byte);
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}
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std::string VolumeWii::GetMakerID(const Partition& partition) const
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{
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char makerID[2];
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if (!Read(0x4, 0x2, (u8*)&makerID, partition))
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return std::string();
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return DecodeString(makerID);
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}
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std::optional<u16> VolumeWii::GetRevision(const Partition& partition) const
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{
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std::optional<u8> revision = ReadSwapped<u8>(7, partition);
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return revision ? *revision : std::optional<u16>();
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}
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std::string VolumeWii::GetInternalName(const Partition& partition) const
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{
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char name_buffer[0x60];
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if (Read(0x20, 0x60, (u8*)&name_buffer, partition))
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return DecodeString(name_buffer);
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return "";
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}
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std::map<Language, std::string> VolumeWii::GetLongNames() const
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{
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std::vector<char16_t> names(NAMES_TOTAL_CHARS);
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names.resize(ReadFile(*this, GetGamePartition(), "opening.bnr",
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reinterpret_cast<u8*>(names.data()), NAMES_TOTAL_BYTES, 0x5C));
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return ReadWiiNames(names);
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}
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std::vector<u32> VolumeWii::GetBanner(u32* width, u32* height) const
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{
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*width = 0;
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*height = 0;
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const std::optional<u64> title_id = GetTitleID(GetGamePartition());
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if (!title_id)
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return std::vector<u32>();
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return WiiSaveBanner(*title_id).GetBanner(width, height);
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}
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std::string VolumeWii::GetApploaderDate(const Partition& partition) const
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{
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char date[16];
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if (!Read(0x2440, 0x10, (u8*)&date, partition))
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return std::string();
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return DecodeString(date);
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}
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Platform VolumeWii::GetVolumeType() const
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{
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return Platform::WiiDisc;
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}
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std::optional<u8> VolumeWii::GetDiscNumber(const Partition& partition) const
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{
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return ReadSwapped<u8>(6, partition);
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}
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BlobType VolumeWii::GetBlobType() const
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{
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return m_pReader->GetBlobType();
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}
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u64 VolumeWii::GetSize() const
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{
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return m_pReader->GetDataSize();
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}
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u64 VolumeWii::GetRawSize() const
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{
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return m_pReader->GetRawSize();
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}
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bool VolumeWii::CheckIntegrity(const Partition& partition) const
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{
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if (!m_encrypted)
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return false;
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// Get the decryption key for the partition
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auto it = m_partitions.find(partition);
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if (it == m_partitions.end())
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return false;
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const PartitionDetails& partition_details = it->second;
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mbedtls_aes_context* aes_context = partition_details.key->get();
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if (!aes_context)
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return false;
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// Get partition data size
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u32 partSizeDiv4;
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m_pReader->Read(partition.offset + 0x2BC, 4, (u8*)&partSizeDiv4);
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u64 partDataSize = (u64)Common::swap32(partSizeDiv4) * 4;
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u32 nClusters = (u32)(partDataSize / 0x8000);
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for (u32 clusterID = 0; clusterID < nClusters; ++clusterID)
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{
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u64 clusterOff = partition.offset + *partition_details.data_offset + (u64)clusterID * 0x8000;
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// Read and decrypt the cluster metadata
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u8 clusterMDCrypted[0x400];
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u8 clusterMD[0x400];
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u8 IV[16] = {0};
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if (!m_pReader->Read(clusterOff, 0x400, clusterMDCrypted))
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{
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WARN_LOG(DISCIO, "Integrity Check: fail at cluster %d: could not read metadata", clusterID);
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return false;
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}
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mbedtls_aes_crypt_cbc(aes_context, MBEDTLS_AES_DECRYPT, 0x400, IV, clusterMDCrypted, clusterMD);
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// Some clusters have invalid data and metadata because they aren't
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// meant to be read by the game (for example, holes between files). To
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// try to avoid reporting errors because of these clusters, we check
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// the 0x00 paddings in the metadata.
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//
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// This may cause some false negatives though: some bad clusters may be
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// skipped because they are *too* bad and are not even recognized as
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// valid clusters. To be improved.
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bool meaningless = false;
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for (u32 idx = 0x26C; idx < 0x280; ++idx)
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if (clusterMD[idx] != 0)
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meaningless = true;
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if (meaningless)
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continue;
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u8 clusterData[0x7C00];
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if (!Read((u64)clusterID * 0x7C00, 0x7C00, clusterData, partition))
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{
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WARN_LOG(DISCIO, "Integrity Check: fail at cluster %d: could not read data", clusterID);
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return false;
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}
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for (u32 hashID = 0; hashID < 31; ++hashID)
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{
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u8 hash[20];
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mbedtls_sha1(clusterData + hashID * 0x400, 0x400, hash);
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// Note that we do not use strncmp here
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if (memcmp(hash, clusterMD + hashID * 20, 20))
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{
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WARN_LOG(DISCIO, "Integrity Check: fail at cluster %d: hash %d is invalid", clusterID,
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hashID);
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return false;
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}
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}
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}
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return true;
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}
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} // namespace
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