/* * 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 "amsmitm_fs_utils.hpp" #include "amsmitm_prodinfo_utils.hpp" namespace ams::mitm { namespace { constexpr inline u16 Crc16InitialValue = 0x55AA; constexpr inline u16 Crc16Table[] = { 0x0000, 0xCC01, 0xD801, 0x1400, 0xF001, 0x3C00, 0x2800, 0xE401, 0xA001, 0x6C00, 0x7800, 0xB401, 0x5000, 0x9C01, 0x8801, 0x4400, }; u16 GetCrc16(const void *data, size_t size) { AMS_ASSERT(data != nullptr); AMS_ASSERT(size > 0); const u8 *src = static_cast(data); u16 crc = Crc16InitialValue; u16 tmp = 0; while ((size--) > 0) { tmp = Crc16Table[crc & 0xF]; crc = ((crc >> 4) & 0x0FFF) ^ tmp ^ Crc16Table[*src & 0xF]; tmp = Crc16Table[crc & 0xF]; crc = ((crc >> 4) & 0x0FFF) ^ tmp ^ Crc16Table[(*(src++) >> 4) & 0xF]; } return crc; } bool IsBlank(const void *data, size_t size) { AMS_ASSERT(data != nullptr); AMS_ASSERT(size > 0); const u8 *src = static_cast(data); while ((size--) > 0) { if (*(src++) != 0) { return false; } } return true; } constexpr inline u32 CalibrationMagic = util::FourCC<'C','A','L','0'>::Code; struct Sha256Hash { u8 data[crypto::Sha256Generator::HashSize]; }; struct CalibrationInfoHeader { u32 magic; u32 version; u32 body_size; u16 model; u16 update_count; u8 pad[0xE]; u16 crc; Sha256Hash body_hash; }; static_assert(sizeof(CalibrationInfoHeader) == 0x40); constexpr inline size_t CalibrationInfoBodySizeMax = CalibrationBinarySize - sizeof(CalibrationInfoHeader); struct CalibrationInfo { CalibrationInfoHeader header; u8 body[CalibrationInfoBodySizeMax]; /* TODO: CalibrationInfoBody body; */ template Block &GetBlock() { static_assert(Block::Offset >= sizeof(CalibrationInfoHeader)); static_assert(Block::Offset < sizeof(CalibrationInfo)); static_assert(Block::Offset + Block::Size <= sizeof(CalibrationInfo)); return *static_cast(static_cast(std::addressof(this->body[Block::Offset - sizeof(this->header)]))); } template const Block &GetBlock() const { static_assert(Block::Offset >= sizeof(CalibrationInfoHeader)); static_assert(Block::Offset < sizeof(CalibrationInfo)); static_assert(Block::Offset + Block::Size <= sizeof(CalibrationInfo)); return *static_cast(static_cast(std::addressof(this->body[Block::Offset - sizeof(this->header)]))); } }; static_assert(sizeof(CalibrationInfo) == CalibrationBinarySize); struct SecureCalibrationInfoBackup { CalibrationInfo info; Sha256Hash hash; u8 pad[SecureCalibrationBinaryBackupSize - sizeof(info) - sizeof(hash)]; }; static_assert(sizeof(SecureCalibrationInfoBackup) == SecureCalibrationBinaryBackupSize); bool IsValidSha256Hash(const Sha256Hash &hash, const void *data, size_t data_size) { Sha256Hash calc_hash; ON_SCOPE_EXIT { ::ams::crypto::ClearMemory(std::addressof(calc_hash), sizeof(calc_hash)); }; ::ams::crypto::GenerateSha256Hash(std::addressof(calc_hash), sizeof(calc_hash), data, data_size); return ::ams::crypto::IsSameBytes(std::addressof(calc_hash), std::addressof(hash), sizeof(Sha256Hash)); } bool IsValid(const CalibrationInfoHeader &header) { return header.magic == CalibrationMagic && GetCrc16(std::addressof(header), AMS_OFFSETOF(CalibrationInfoHeader, crc)) == header.crc; } bool IsValid(const CalibrationInfoHeader &header, const void *body) { return IsValid(header) && IsValidSha256Hash(header.body_hash, body, header.body_size); } #define DEFINE_CALIBRATION_CRC_BLOCK(_TypeName, _Offset, _Size, _Decl, _MemberName) \ struct _TypeName { \ static constexpr size_t Offset = _Offset; \ static constexpr size_t Size = _Size; \ static constexpr bool IsCrcBlock = true; \ static constexpr bool IsShaBlock = false; \ _Decl; \ static_assert(Size >= sizeof(_MemberName) + sizeof(u16)); \ u8 pad[Size - sizeof(_MemberName) - sizeof(u16)]; \ u16 crc; \ }; \ static_assert(sizeof(_TypeName) == _TypeName::Size) #define DEFINE_CALIBRATION_SHA_BLOCK(_TypeName, _Offset, _Size, _Decl, _MemberName) \ struct _TypeName { \ static constexpr size_t Offset = _Offset; \ static constexpr size_t Size = _Size; \ static constexpr bool IsCrcBlock = false; \ static constexpr bool IsShaBlock = true; \ _Decl; \ static_assert(Size == sizeof(_MemberName) + sizeof(Sha256Hash)); \ Sha256Hash sha256_hash; \ }; \ static_assert(sizeof(_TypeName) == _TypeName::Size) DEFINE_CALIBRATION_CRC_BLOCK(SerialNumberBlock, 0x0250, 0x020, ::ams::settings::factory::SerialNumber serial_number, serial_number); DEFINE_CALIBRATION_CRC_BLOCK(EccB233DeviceCertificateBlock, 0x0480, 0x190, ::ams::settings::factory::EccB233DeviceCertificate device_certificate, device_certificate); DEFINE_CALIBRATION_CRC_BLOCK(SslKeyBlock, 0x09B0, 0x120, u8 ssl_key[0x110], ssl_key); DEFINE_CALIBRATION_CRC_BLOCK(SslCertificateSizeBlock, 0x0AD0, 0x010, u64 ssl_certificate_size, ssl_certificate_size); DEFINE_CALIBRATION_SHA_BLOCK(SslCertificateBlock, 0x0AE0, 0x820, u8 ssl_certificate[0x800], ssl_certificate); DEFINE_CALIBRATION_CRC_BLOCK(EcqvEcdsaAmiiboRootCertificateBlock, 0x35A0, 0x080, u8 data[0x70], data); DEFINE_CALIBRATION_CRC_BLOCK(EcqvBlsAmiiboRootCertificateBlock, 0x36A0, 0x0A0, u8 data[0x90], data); DEFINE_CALIBRATION_CRC_BLOCK(ExtendedSslKeyBlock, 0x3AE0, 0x140, u8 ssl_key[0x134], ssl_key); DEFINE_CALIBRATION_CRC_BLOCK(Rsa2048DeviceKeyBlock, 0x3D70, 0x250, u8 device_key[0x240], device_key); DEFINE_CALIBRATION_CRC_BLOCK(Rsa2048DeviceCertificateBlock, 0x3FC0, 0x250, ::ams::settings::factory::Rsa2048DeviceCertificate device_certificate, device_certificate); #undef DEFINE_CALIBRATION_CRC_BLOCK #undef DEFINE_CALIBRATION_SHA_BLOCK constexpr inline const char BlankSerialNumberString[] = "XAW00000000000"; template void Blank(Block &block) { if constexpr (std::is_same::value) { static_assert(sizeof(BlankSerialNumberString) <= sizeof(SerialNumberBlock::serial_number)); std::memset(std::addressof(block), 0, Block::Size - sizeof(block.crc)); std::memcpy(block.serial_number.str, BlankSerialNumberString, sizeof(BlankSerialNumberString)); block.crc = GetCrc16(std::addressof(block), Block::Size - sizeof(block.crc)); } else if constexpr (std::is_same::value) { std::memset(std::addressof(block), 0, sizeof(block.ssl_certificate)); } else if constexpr (Block::IsCrcBlock) { std::memset(std::addressof(block), 0, Block::Size - sizeof(block.crc)); block.crc = GetCrc16(std::addressof(block), Block::Size - sizeof(block.crc)); } else { static_assert(Block::IsShaBlock); std::memset(std::addressof(block), 0, Block::Size); ::ams::crypto::GenerateSha256Hash(std::addressof(block.sha256_hash), sizeof(block.sha256_hash), std::addressof(block), Block::Size - sizeof(block.sha256_hash)); } } template bool IsBlank(const Block &block) { if constexpr (std::is_same::value) { static_assert(sizeof(BlankSerialNumberString) <= sizeof(SerialNumberBlock::serial_number)); return std::memcmp(block.serial_number.str, BlankSerialNumberString, sizeof(BlankSerialNumberString) - 1) == 0 || IsBlank(std::addressof(block), Block::Size - sizeof(block.crc)); } else if constexpr (Block::IsCrcBlock) { return IsBlank(std::addressof(block), Block::Size - sizeof(block.crc)); } else { return IsBlank(std::addressof(block), Block::Size - sizeof(block.sha256_hash)); } } template bool IsValid(const Block &block, size_t size = 0) { if constexpr (Block::IsCrcBlock) { return GetCrc16(std::addressof(block), Block::Size - sizeof(block.crc)) == block.crc; } else { static_assert(Block::IsShaBlock); return IsValidSha256Hash(block.sha256_hash, std::addressof(block), size != 0 ? size : Block::Size - sizeof(block.sha256_hash)); } } void Blank(CalibrationInfo &info) { /* Set header. */ info.header.magic = CalibrationMagic; info.header.body_size = sizeof(info.body); info.header.crc = GetCrc16(std::addressof(info.header), AMS_OFFSETOF(CalibrationInfoHeader, crc)); /* Set blocks. */ Blank(info.GetBlock()); Blank(info.GetBlock()); Blank(info.GetBlock()); Blank(info.GetBlock()); Blank(info.GetBlock()); Blank(info.GetBlock()); /* Set header hash. */ crypto::GenerateSha256Hash(std::addressof(info.header.body_hash), sizeof(info.header.body_hash), std::addressof(info.body), sizeof(info.body)); } bool IsValidHeader(const CalibrationInfo &cal) { return IsValid(cal.header) && cal.header.body_size <= CalibrationInfoBodySizeMax && IsValid(cal.header, cal.body); } bool IsValidSerialNumber(const char *sn) { for (size_t i = 0; i < std::strlen(sn); i++) { if (!std::isalnum(static_cast(sn[i]))) { return false; } } return true; } void GetSerialNumber(char *dst, const CalibrationInfo &info) { std::memcpy(dst, std::addressof(info.GetBlock()), sizeof(info.GetBlock().serial_number)); dst[sizeof(info.GetBlock().serial_number) + 1] = '\x00'; } bool IsValidSerialNumber(const CalibrationInfo &cal) { char sn[0x20] = {}; ON_SCOPE_EXIT { std::memset(sn, 0, sizeof(sn)); }; GetSerialNumber(sn, cal); return IsValidSerialNumber(sn); } bool IsValid(const CalibrationInfo &cal) { return IsValidHeader(cal) && IsValid(cal.GetBlock()) && IsValid(cal.GetBlock()) && IsValid(cal.GetBlock()) && IsValid(cal.GetBlock()) && cal.GetBlock().ssl_certificate_size <= sizeof(cal.GetBlock().ssl_certificate) && IsValid(cal.GetBlock(), cal.GetBlock().ssl_certificate_size) && IsValid(cal.GetBlock()) && IsValid(cal.GetBlock()) && IsValid(cal.GetBlock()) && IsValidSerialNumber(cal); } bool ContainsCorrectDeviceId(const EccB233DeviceCertificateBlock &block, u64 device_id) { static constexpr size_t DeviceIdOffset = 0xC6; char found_device_id_str[sizeof("0011223344556677")] = {}; ON_SCOPE_EXIT { std::memset(found_device_id_str, 0, sizeof(found_device_id_str)); }; std::memcpy(found_device_id_str, std::addressof(block.device_certificate.data[DeviceIdOffset]), sizeof(found_device_id_str) - 1); static constexpr u64 DeviceIdLowMask = 0x00FFFFFFFFFFFFFFul; return (std::strtoul(found_device_id_str, nullptr, 16) & DeviceIdLowMask) == (device_id & DeviceIdLowMask); } bool ContainsCorrectDeviceId(const CalibrationInfo &cal) { return ContainsCorrectDeviceId(cal.GetBlock(), exosphere::GetDeviceId()); } bool IsValidForSecureBackup(const CalibrationInfo &cal) { return IsValid(cal) && ContainsCorrectDeviceId(cal); } bool IsBlank(const CalibrationInfo &cal) { return IsBlank(cal.GetBlock()) || IsBlank(cal.GetBlock()) || IsBlank(cal.GetBlock()) || IsBlank(cal.GetBlock()) || IsBlank(cal.GetBlock()) || IsBlank(cal.GetBlock()); } void ReadStorageCalibrationBinary(CalibrationInfo *out) { FsStorage calibration_binary_storage; R_ABORT_UNLESS(fsOpenBisStorage(std::addressof(calibration_binary_storage), FsBisPartitionId_CalibrationBinary)); ON_SCOPE_EXIT { fsStorageClose(std::addressof(calibration_binary_storage)); }; R_ABORT_UNLESS(fsStorageRead(std::addressof(calibration_binary_storage), 0, out, sizeof(*out))); } constexpr inline const u8 SecureCalibrationBinaryBackupIv[crypto::Aes128CtrDecryptor::IvSize] = {}; void ReadStorageEncryptedSecureCalibrationBinaryBackupUnsafe(SecureCalibrationInfoBackup *out) { FsStorage calibration_binary_storage; R_ABORT_UNLESS(fsOpenBisStorage(std::addressof(calibration_binary_storage), FsBisPartitionId_CalibrationBinary)); ON_SCOPE_EXIT { fsStorageClose(std::addressof(calibration_binary_storage)); }; R_ABORT_UNLESS(fsStorageRead(std::addressof(calibration_binary_storage), SecureCalibrationInfoBackupOffset, out, sizeof(*out))); } void WriteStorageEncryptedSecureCalibrationBinaryBackupUnsafe(const SecureCalibrationInfoBackup *src) { FsStorage calibration_binary_storage; R_ABORT_UNLESS(fsOpenBisStorage(std::addressof(calibration_binary_storage), FsBisPartitionId_CalibrationBinary)); ON_SCOPE_EXIT { fsStorageClose(std::addressof(calibration_binary_storage)); }; R_ABORT_UNLESS(fsStorageWrite(std::addressof(calibration_binary_storage), SecureCalibrationInfoBackupOffset, src, sizeof(*src))); } void GenerateSecureCalibrationBinaryBackupKey(void *dst, size_t dst_size) { static constexpr const u8 SecureCalibrationBinaryBackupKeySource[crypto::Aes128CtrDecryptor::KeySize] = { '|', '-', 'A', 'M', 'S', '-', 'C', 'A', 'L', '0', '-', 'K', 'E', 'Y', '-', '|' }; spl::AccessKey access_key; ON_SCOPE_EXIT { crypto::ClearMemory(std::addressof(access_key), sizeof(access_key)); }; /* Generate a personalized kek. */ R_ABORT_UNLESS(spl::GenerateAesKek(std::addressof(access_key), SecureCalibrationBinaryBackupKeySource, sizeof(SecureCalibrationBinaryBackupKeySource), 0, 1)); /* Generate a personalized key. */ R_ABORT_UNLESS(spl::GenerateAesKey(dst, dst_size, access_key, SecureCalibrationBinaryBackupKeySource, sizeof(SecureCalibrationBinaryBackupKeySource))); } bool ReadStorageSecureCalibrationBinaryBackup(SecureCalibrationInfoBackup *out) { /* Read the data. */ ReadStorageEncryptedSecureCalibrationBinaryBackupUnsafe(out); /* Don't leak any data unless we validate. */ auto clear_guard = SCOPE_GUARD { std::memset(out, 0, sizeof(*out)); }; { /* Create a buffer to hold our key. */ u8 key[crypto::Aes128CtrDecryptor::KeySize]; ON_SCOPE_EXIT { crypto::ClearMemory(key, sizeof(key)); }; /* Generate the key. */ GenerateSecureCalibrationBinaryBackupKey(key, sizeof(key)); /* Decrypt the data in place. */ crypto::DecryptAes128Ctr(out, sizeof(*out), key, sizeof(key), SecureCalibrationBinaryBackupIv, sizeof(SecureCalibrationBinaryBackupIv), out, sizeof(*out)); } /* Generate a hash for the data. */ if (!IsValidSha256Hash(out->hash, std::addressof(out->info), sizeof(out->info))) { return false; } /* Validate the backup. */ if (!IsValidForSecureBackup(out->info)) { return false; } /* Our backup is valid. */ clear_guard.Cancel(); return true; } void WriteStorageSecureCalibrationBinaryBackup(SecureCalibrationInfoBackup *src) { /* Clear the input once we've written it. */ ON_SCOPE_EXIT { std::memset(src, 0, sizeof(*src)); }; /* Ensure that the input is valid. */ AMS_ABORT_UNLESS(IsValidForSecureBackup(src->info)); /* Set the Sha256 hash. */ crypto::GenerateSha256Hash(std::addressof(src->hash), sizeof(src->hash), std::addressof(src->info), sizeof(src->info)); /* Validate the hash. */ AMS_ABORT_UNLESS(IsValidSha256Hash(src->hash, std::addressof(src->info), sizeof(src->info))); /* Encrypt the data. */ { /* Create a buffer to hold our key. */ u8 key[crypto::Aes128CtrDecryptor::KeySize]; ON_SCOPE_EXIT { crypto::ClearMemory(key, sizeof(key)); }; /* Generate the key. */ GenerateSecureCalibrationBinaryBackupKey(key, sizeof(key)); /* Encrypt the data in place. */ crypto::EncryptAes128Ctr(src, sizeof(*src), key, sizeof(key), SecureCalibrationBinaryBackupIv, sizeof(SecureCalibrationBinaryBackupIv), src, sizeof(*src)); } /* Write the encrypted data. */ WriteStorageEncryptedSecureCalibrationBinaryBackupUnsafe(src); } void GetBackupFileName(char *dst, size_t dst_size, const CalibrationInfo &info) { char sn[0x20] = {}; ON_SCOPE_EXIT { std::memset(sn, 0, sizeof(sn)); }; if (IsValidForSecureBackup(info)) { GetSerialNumber(sn, info); util::SNPrintf(dst, dst_size, "automatic_backups/%s_PRODINFO.bin", sn); } else { Sha256Hash hash; crypto::GenerateSha256Hash(std::addressof(hash), sizeof(hash), std::addressof(info), sizeof(info)); ON_SCOPE_EXIT { crypto::ClearMemory(std::addressof(hash), sizeof(hash)); }; if (IsValid(info)) { if (IsBlank(info)) { util::SNPrintf(dst, dst_size, "automatic_backups/BLANK_PRODINFO_%02X%02X%02X%02X.bin", hash.data[0], hash.data[1], hash.data[2], hash.data[3]); } else { GetSerialNumber(sn, info); util::SNPrintf(dst, dst_size, "automatic_backups/%s_PRODINFO_%02X%02X%02X%02X.bin", sn, hash.data[0], hash.data[1], hash.data[2], hash.data[3]); } } else { util::SNPrintf(dst, dst_size, "automatic_backups/INVALID_PRODINFO_%02X%02X%02X%02X.bin", hash.data[0], hash.data[1], hash.data[2], hash.data[3]); } } } void SafeRead(ams::fs::fsa::IFile *file, s64 offset, void *dst, size_t size) { size_t read_size = 0; R_ABORT_UNLESS(file->Read(std::addressof(read_size), offset, dst, size)); AMS_ABORT_UNLESS(read_size == size); } alignas(os::MemoryPageSize) CalibrationInfo g_temp_calibration_info = {}; void SaveProdInfoBackup(util::optional *dst, const CalibrationInfo &info) { char backup_fn[0x100]; GetBackupFileName(backup_fn, sizeof(backup_fn), info); /* Create the file, in case it does not exist. */ mitm::fs::CreateAtmosphereSdFile(backup_fn, sizeof(CalibrationInfo), ams::fs::CreateOption_None); /* Open the file. */ FsFile libnx_file; R_ABORT_UNLESS(mitm::fs::OpenAtmosphereSdFile(std::addressof(libnx_file), backup_fn, ams::fs::OpenMode_ReadWrite)); /* Create our accessor. */ std::unique_ptr file = std::make_unique(libnx_file); AMS_ABORT_UNLESS(file != nullptr); /* Check if we're valid already. */ bool valid = false; s64 size; R_ABORT_UNLESS(file->GetSize(std::addressof(size))); if (size == sizeof(CalibrationInfo)) { SafeRead(file.get(), 0, std::addressof(g_temp_calibration_info), sizeof(g_temp_calibration_info)); ON_SCOPE_EXIT { std::memset(std::addressof(g_temp_calibration_info), 0, sizeof(g_temp_calibration_info)); }; if (std::memcmp(std::addressof(info), std::addressof(g_temp_calibration_info), sizeof(CalibrationInfo)) == 0) { valid = true; } } /* If we're not valid, we need to save. */ if (!valid) { R_ABORT_UNLESS(file->Write(0, std::addressof(info), sizeof(info), ams::fs::WriteOption::Flush)); } /* Save our storage to output. */ if (dst != nullptr) { dst->emplace(std::move(file)); } } void GetRandomEntropy(Sha256Hash *dst) { AMS_ASSERT(dst != nullptr); u64 data_buffer[3] = {}; ON_SCOPE_EXIT { crypto::ClearMemory(data_buffer, sizeof(data_buffer)); }; data_buffer[0] = os::GetSystemTick().GetInt64Value(); R_ABORT_UNLESS(svc::GetInfo(data_buffer + 1, svc::InfoType_AliasRegionAddress, svc::PseudoHandle::CurrentProcess, 0)); if (hos::GetVersion() >= hos::Version_2_0_0) { R_ABORT_UNLESS(svc::GetInfo(data_buffer + 2, svc::InfoType_RandomEntropy, svc::InvalidHandle, (data_buffer[0] ^ (data_buffer[1] >> 24)) & 3)); } else { data_buffer[2] = os::GetSystemTick().GetInt64Value(); } return crypto::GenerateSha256Hash(dst, sizeof(*dst), data_buffer, sizeof(data_buffer)); } void FillWithGarbage(void *dst, size_t dst_size) { /* Get random entropy. */ Sha256Hash entropy; ON_SCOPE_EXIT { crypto::ClearMemory(std::addressof(entropy), sizeof(entropy)); }; GetRandomEntropy(std::addressof(entropy)); /* Clear dst. */ std::memset(dst, 0xCC, dst_size); /* Encrypt dst. */ static_assert(sizeof(entropy) == crypto::Aes128CtrEncryptor::KeySize + crypto::Aes128CtrEncryptor::IvSize); crypto::EncryptAes128Ctr(dst, dst_size, entropy.data, crypto::Aes128CtrEncryptor::KeySize, entropy.data + crypto::Aes128CtrEncryptor::KeySize, crypto::Aes128CtrEncryptor::IvSize, dst, dst_size); } alignas(os::MemoryPageSize) constinit CalibrationInfo g_calibration_info = {}; alignas(os::MemoryPageSize) constinit CalibrationInfo g_blank_calibration_info = {}; alignas(os::MemoryPageSize) constinit SecureCalibrationInfoBackup g_secure_calibration_info_backup = {}; constinit util::optional g_prodinfo_backup_file; constinit util::optional g_blank_prodinfo_storage; constinit util::optional g_fake_secure_backup_storage; constinit bool g_allow_writes = false; constinit bool g_has_secure_backup = false; constinit os::SdkMutex g_prodinfo_management_lock; } void InitializeProdInfoManagement() { std::scoped_lock lk(g_prodinfo_management_lock); /* First, get our options. */ const bool should_blank = exosphere::ShouldBlankProdInfo(); bool allow_writes = exosphere::ShouldAllowWritesToProdInfo(); /* Next, read our prodinfo. */ ReadStorageCalibrationBinary(std::addressof(g_calibration_info)); /* Next, check if we have a secure backup. */ bool has_secure_backup = ReadStorageSecureCalibrationBinaryBackup(std::addressof(g_secure_calibration_info_backup)); /* Only allow writes if we have a secure backup. */ if (allow_writes && !has_secure_backup) { /* If we can make a secure backup, great. */ if (IsValidForSecureBackup(g_calibration_info)) { g_secure_calibration_info_backup.info = g_calibration_info; WriteStorageSecureCalibrationBinaryBackup(std::addressof(g_secure_calibration_info_backup)); g_secure_calibration_info_backup.info = g_calibration_info; has_secure_backup = true; } else { /* Don't allow writes if we can't make a secure backup. */ allow_writes = false; } } /* Ensure our preconditions are met. */ AMS_ABORT_UNLESS(!allow_writes || has_secure_backup); /* Set globals. */ g_allow_writes = allow_writes; g_has_secure_backup = has_secure_backup; /* If we should blank, do so. */ if (should_blank) { g_blank_calibration_info = g_calibration_info; Blank(g_blank_calibration_info); g_blank_prodinfo_storage.emplace(std::addressof(g_blank_calibration_info), sizeof(g_blank_calibration_info)); } /* Ensure that we have a blank file only if we need one. */ AMS_ABORT_UNLESS(should_blank == static_cast(g_blank_prodinfo_storage)); } void SaveProdInfoBackupsAndWipeMemory(char *out_name, size_t out_name_size) { std::scoped_lock lk(g_prodinfo_management_lock); ON_SCOPE_EXIT { FillWithGarbage(std::addressof(g_calibration_info), sizeof(g_calibration_info)); FillWithGarbage(std::addressof(g_secure_calibration_info_backup), sizeof(g_secure_calibration_info_backup)); }; /* Save our backup. We always prefer to save a secure copy of data over a non-secure one. */ if (g_has_secure_backup) { GetSerialNumber(out_name, g_secure_calibration_info_backup.info); SaveProdInfoBackup(std::addressof(g_prodinfo_backup_file), g_secure_calibration_info_backup.info); } else { if (IsValid(g_calibration_info) && !IsBlank(g_calibration_info)) { GetSerialNumber(out_name, g_calibration_info); } else { Sha256Hash hash; ON_SCOPE_EXIT { crypto::ClearMemory(std::addressof(hash), sizeof(hash)); }; crypto::GenerateSha256Hash(std::addressof(hash), sizeof(hash), std::addressof(g_calibration_info), sizeof(g_calibration_info)); util::SNPrintf(out_name, out_name_size, "%02X%02X%02X%02X", hash.data[0], hash.data[1], hash.data[2], hash.data[3]); } SaveProdInfoBackup(std::addressof(g_prodinfo_backup_file), g_calibration_info); } /* Ensure we made our backup. */ AMS_ABORT_UNLESS(g_prodinfo_backup_file); /* Setup our memory storage. */ g_fake_secure_backup_storage.emplace(std::addressof(g_secure_calibration_info_backup), sizeof(g_secure_calibration_info_backup)); /* Ensure that we have a fake storage. */ AMS_ABORT_UNLESS(static_cast(g_fake_secure_backup_storage)); } bool ShouldReadBlankCalibrationBinary() { std::scoped_lock lk(g_prodinfo_management_lock); return static_cast(g_blank_prodinfo_storage); } bool IsWriteToCalibrationBinaryAllowed() { std::scoped_lock lk(g_prodinfo_management_lock); return g_allow_writes; } void ReadFromBlankCalibrationBinary(s64 offset, void *dst, size_t size) { AMS_ABORT_UNLESS(ShouldReadBlankCalibrationBinary()); std::scoped_lock lk(g_prodinfo_management_lock); R_ABORT_UNLESS(g_blank_prodinfo_storage->Read(offset, dst, size)); } void WriteToBlankCalibrationBinary(s64 offset, const void *src, size_t size) { AMS_ABORT_UNLESS(ShouldReadBlankCalibrationBinary()); std::scoped_lock lk(g_prodinfo_management_lock); R_ABORT_UNLESS(g_blank_prodinfo_storage->Write(offset, src, size)); } void ReadFromFakeSecureBackupStorage(s64 offset, void *dst, size_t size) { AMS_ABORT_UNLESS(IsWriteToCalibrationBinaryAllowed()); std::scoped_lock lk(g_prodinfo_management_lock); R_ABORT_UNLESS(g_fake_secure_backup_storage->Read(offset, dst, size)); } void WriteToFakeSecureBackupStorage(s64 offset, const void *src, size_t size) { AMS_ABORT_UNLESS(IsWriteToCalibrationBinaryAllowed()); std::scoped_lock lk(g_prodinfo_management_lock); R_ABORT_UNLESS(g_fake_secure_backup_storage->Write(offset, src, size)); } }