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suyu/src/core/crypto/key_manager.cpp
Morph 99ceb03a1c general: Convert source file copyright comments over to SPDX
This formats all copyright comments according to SPDX formatting guidelines.
Additionally, this resolves the remaining GPLv2 only licensed files by relicensing them to GPLv2.0-or-later.
2022-04-23 05:55:32 -04:00

1325 lines
48 KiB
C++

// SPDX-FileCopyrightText: Copyright 2018 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#include <algorithm>
#include <array>
#include <bitset>
#include <cctype>
#include <fstream>
#include <locale>
#include <map>
#include <sstream>
#include <tuple>
#include <vector>
#include <mbedtls/bignum.h>
#include <mbedtls/cipher.h>
#include <mbedtls/cmac.h>
#include <mbedtls/sha256.h>
#include "common/fs/file.h"
#include "common/fs/fs.h"
#include "common/fs/path_util.h"
#include "common/hex_util.h"
#include "common/logging/log.h"
#include "common/settings.h"
#include "common/string_util.h"
#include "core/crypto/aes_util.h"
#include "core/crypto/key_manager.h"
#include "core/crypto/partition_data_manager.h"
#include "core/file_sys/content_archive.h"
#include "core/file_sys/nca_metadata.h"
#include "core/file_sys/registered_cache.h"
#include "core/hle/service/filesystem/filesystem.h"
#include "core/loader/loader.h"
namespace Core::Crypto {
namespace {
constexpr u64 CURRENT_CRYPTO_REVISION = 0x5;
constexpr u64 FULL_TICKET_SIZE = 0x400;
using Common::AsArray;
// clang-format off
constexpr std::array eticket_source_hashes{
AsArray("B71DB271DC338DF380AA2C4335EF8873B1AFD408E80B3582D8719FC81C5E511C"), // eticket_rsa_kek_source
AsArray("E8965A187D30E57869F562D04383C996DE487BBA5761363D2D4D32391866A85C"), // eticket_rsa_kekek_source
};
// clang-format on
constexpr std::array<std::pair<std::string_view, KeyIndex<S128KeyType>>, 30> s128_file_id{{
{"eticket_rsa_kek", {S128KeyType::ETicketRSAKek, 0, 0}},
{"eticket_rsa_kek_source",
{S128KeyType::Source, static_cast<u64>(SourceKeyType::ETicketKek), 0}},
{"eticket_rsa_kekek_source",
{S128KeyType::Source, static_cast<u64>(SourceKeyType::ETicketKekek), 0}},
{"rsa_kek_mask_0", {S128KeyType::RSAKek, static_cast<u64>(RSAKekType::Mask0), 0}},
{"rsa_kek_seed_3", {S128KeyType::RSAKek, static_cast<u64>(RSAKekType::Seed3), 0}},
{"rsa_oaep_kek_generation_source",
{S128KeyType::Source, static_cast<u64>(SourceKeyType::RSAOaepKekGeneration), 0}},
{"sd_card_kek_source", {S128KeyType::Source, static_cast<u64>(SourceKeyType::SDKek), 0}},
{"aes_kek_generation_source",
{S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKekGeneration), 0}},
{"aes_key_generation_source",
{S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKeyGeneration), 0}},
{"package2_key_source", {S128KeyType::Source, static_cast<u64>(SourceKeyType::Package2), 0}},
{"master_key_source", {S128KeyType::Source, static_cast<u64>(SourceKeyType::Master), 0}},
{"header_kek_source", {S128KeyType::Source, static_cast<u64>(SourceKeyType::HeaderKek), 0}},
{"key_area_key_application_source",
{S128KeyType::Source, static_cast<u64>(SourceKeyType::KeyAreaKey),
static_cast<u64>(KeyAreaKeyType::Application)}},
{"key_area_key_ocean_source",
{S128KeyType::Source, static_cast<u64>(SourceKeyType::KeyAreaKey),
static_cast<u64>(KeyAreaKeyType::Ocean)}},
{"key_area_key_system_source",
{S128KeyType::Source, static_cast<u64>(SourceKeyType::KeyAreaKey),
static_cast<u64>(KeyAreaKeyType::System)}},
{"titlekek_source", {S128KeyType::Source, static_cast<u64>(SourceKeyType::Titlekek), 0}},
{"keyblob_mac_key_source",
{S128KeyType::Source, static_cast<u64>(SourceKeyType::KeyblobMAC), 0}},
{"tsec_key", {S128KeyType::TSEC, 0, 0}},
{"secure_boot_key", {S128KeyType::SecureBoot, 0, 0}},
{"sd_seed", {S128KeyType::SDSeed, 0, 0}},
{"bis_key_0_crypt", {S128KeyType::BIS, 0, static_cast<u64>(BISKeyType::Crypto)}},
{"bis_key_0_tweak", {S128KeyType::BIS, 0, static_cast<u64>(BISKeyType::Tweak)}},
{"bis_key_1_crypt", {S128KeyType::BIS, 1, static_cast<u64>(BISKeyType::Crypto)}},
{"bis_key_1_tweak", {S128KeyType::BIS, 1, static_cast<u64>(BISKeyType::Tweak)}},
{"bis_key_2_crypt", {S128KeyType::BIS, 2, static_cast<u64>(BISKeyType::Crypto)}},
{"bis_key_2_tweak", {S128KeyType::BIS, 2, static_cast<u64>(BISKeyType::Tweak)}},
{"bis_key_3_crypt", {S128KeyType::BIS, 3, static_cast<u64>(BISKeyType::Crypto)}},
{"bis_key_3_tweak", {S128KeyType::BIS, 3, static_cast<u64>(BISKeyType::Tweak)}},
{"header_kek", {S128KeyType::HeaderKek, 0, 0}},
{"sd_card_kek", {S128KeyType::SDKek, 0, 0}},
}};
auto Find128ByName(std::string_view name) {
return std::find_if(s128_file_id.begin(), s128_file_id.end(),
[&name](const auto& pair) { return pair.first == name; });
}
constexpr std::array<std::pair<std::string_view, KeyIndex<S256KeyType>>, 6> s256_file_id{{
{"header_key", {S256KeyType::Header, 0, 0}},
{"sd_card_save_key_source", {S256KeyType::SDKeySource, static_cast<u64>(SDKeyType::Save), 0}},
{"sd_card_nca_key_source", {S256KeyType::SDKeySource, static_cast<u64>(SDKeyType::NCA), 0}},
{"header_key_source", {S256KeyType::HeaderSource, 0, 0}},
{"sd_card_save_key", {S256KeyType::SDKey, static_cast<u64>(SDKeyType::Save), 0}},
{"sd_card_nca_key", {S256KeyType::SDKey, static_cast<u64>(SDKeyType::NCA), 0}},
}};
auto Find256ByName(std::string_view name) {
return std::find_if(s256_file_id.begin(), s256_file_id.end(),
[&name](const auto& pair) { return pair.first == name; });
}
using KeyArray = std::array<std::pair<std::pair<S128KeyType, u64>, std::string_view>, 7>;
constexpr KeyArray KEYS_VARIABLE_LENGTH{{
{{S128KeyType::Master, 0}, "master_key_"},
{{S128KeyType::Package1, 0}, "package1_key_"},
{{S128KeyType::Package2, 0}, "package2_key_"},
{{S128KeyType::Titlekek, 0}, "titlekek_"},
{{S128KeyType::Source, static_cast<u64>(SourceKeyType::Keyblob)}, "keyblob_key_source_"},
{{S128KeyType::Keyblob, 0}, "keyblob_key_"},
{{S128KeyType::KeyblobMAC, 0}, "keyblob_mac_key_"},
}};
template <std::size_t Size>
bool IsAllZeroArray(const std::array<u8, Size>& array) {
return std::all_of(array.begin(), array.end(), [](const auto& elem) { return elem == 0; });
}
} // Anonymous namespace
u64 GetSignatureTypeDataSize(SignatureType type) {
switch (type) {
case SignatureType::RSA_4096_SHA1:
case SignatureType::RSA_4096_SHA256:
return 0x200;
case SignatureType::RSA_2048_SHA1:
case SignatureType::RSA_2048_SHA256:
return 0x100;
case SignatureType::ECDSA_SHA1:
case SignatureType::ECDSA_SHA256:
return 0x3C;
}
UNREACHABLE();
return 0;
}
u64 GetSignatureTypePaddingSize(SignatureType type) {
switch (type) {
case SignatureType::RSA_4096_SHA1:
case SignatureType::RSA_4096_SHA256:
case SignatureType::RSA_2048_SHA1:
case SignatureType::RSA_2048_SHA256:
return 0x3C;
case SignatureType::ECDSA_SHA1:
case SignatureType::ECDSA_SHA256:
return 0x40;
}
UNREACHABLE();
return 0;
}
SignatureType Ticket::GetSignatureType() const {
if (const auto* ticket = std::get_if<RSA4096Ticket>(&data)) {
return ticket->sig_type;
}
if (const auto* ticket = std::get_if<RSA2048Ticket>(&data)) {
return ticket->sig_type;
}
if (const auto* ticket = std::get_if<ECDSATicket>(&data)) {
return ticket->sig_type;
}
throw std::bad_variant_access{};
}
TicketData& Ticket::GetData() {
if (auto* ticket = std::get_if<RSA4096Ticket>(&data)) {
return ticket->data;
}
if (auto* ticket = std::get_if<RSA2048Ticket>(&data)) {
return ticket->data;
}
if (auto* ticket = std::get_if<ECDSATicket>(&data)) {
return ticket->data;
}
throw std::bad_variant_access{};
}
const TicketData& Ticket::GetData() const {
if (const auto* ticket = std::get_if<RSA4096Ticket>(&data)) {
return ticket->data;
}
if (const auto* ticket = std::get_if<RSA2048Ticket>(&data)) {
return ticket->data;
}
if (const auto* ticket = std::get_if<ECDSATicket>(&data)) {
return ticket->data;
}
throw std::bad_variant_access{};
}
u64 Ticket::GetSize() const {
const auto sig_type = GetSignatureType();
return sizeof(SignatureType) + GetSignatureTypeDataSize(sig_type) +
GetSignatureTypePaddingSize(sig_type) + sizeof(TicketData);
}
Ticket Ticket::SynthesizeCommon(Key128 title_key, const std::array<u8, 16>& rights_id) {
RSA2048Ticket out{};
out.sig_type = SignatureType::RSA_2048_SHA256;
out.data.rights_id = rights_id;
out.data.title_key_common = title_key;
return Ticket{out};
}
Key128 GenerateKeyEncryptionKey(Key128 source, Key128 master, Key128 kek_seed, Key128 key_seed) {
Key128 out{};
AESCipher<Key128> cipher1(master, Mode::ECB);
cipher1.Transcode(kek_seed.data(), kek_seed.size(), out.data(), Op::Decrypt);
AESCipher<Key128> cipher2(out, Mode::ECB);
cipher2.Transcode(source.data(), source.size(), out.data(), Op::Decrypt);
if (key_seed != Key128{}) {
AESCipher<Key128> cipher3(out, Mode::ECB);
cipher3.Transcode(key_seed.data(), key_seed.size(), out.data(), Op::Decrypt);
}
return out;
}
Key128 DeriveKeyblobKey(const Key128& sbk, const Key128& tsec, Key128 source) {
AESCipher<Key128> sbk_cipher(sbk, Mode::ECB);
AESCipher<Key128> tsec_cipher(tsec, Mode::ECB);
tsec_cipher.Transcode(source.data(), source.size(), source.data(), Op::Decrypt);
sbk_cipher.Transcode(source.data(), source.size(), source.data(), Op::Decrypt);
return source;
}
Key128 DeriveMasterKey(const std::array<u8, 0x90>& keyblob, const Key128& master_source) {
Key128 master_root;
std::memcpy(master_root.data(), keyblob.data(), sizeof(Key128));
AESCipher<Key128> master_cipher(master_root, Mode::ECB);
Key128 master{};
master_cipher.Transcode(master_source.data(), master_source.size(), master.data(), Op::Decrypt);
return master;
}
std::array<u8, 144> DecryptKeyblob(const std::array<u8, 176>& encrypted_keyblob,
const Key128& key) {
std::array<u8, 0x90> keyblob;
AESCipher<Key128> cipher(key, Mode::CTR);
cipher.SetIV(std::vector<u8>(encrypted_keyblob.data() + 0x10, encrypted_keyblob.data() + 0x20));
cipher.Transcode(encrypted_keyblob.data() + 0x20, keyblob.size(), keyblob.data(), Op::Decrypt);
return keyblob;
}
void KeyManager::DeriveGeneralPurposeKeys(std::size_t crypto_revision) {
const auto kek_generation_source =
GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKekGeneration));
const auto key_generation_source =
GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKeyGeneration));
if (HasKey(S128KeyType::Master, crypto_revision)) {
for (auto kak_type :
{KeyAreaKeyType::Application, KeyAreaKeyType::Ocean, KeyAreaKeyType::System}) {
if (HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::KeyAreaKey),
static_cast<u64>(kak_type))) {
const auto source =
GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::KeyAreaKey),
static_cast<u64>(kak_type));
const auto kek =
GenerateKeyEncryptionKey(source, GetKey(S128KeyType::Master, crypto_revision),
kek_generation_source, key_generation_source);
SetKey(S128KeyType::KeyArea, kek, crypto_revision, static_cast<u64>(kak_type));
}
}
AESCipher<Key128> master_cipher(GetKey(S128KeyType::Master, crypto_revision), Mode::ECB);
for (auto key_type : {SourceKeyType::Titlekek, SourceKeyType::Package2}) {
if (HasKey(S128KeyType::Source, static_cast<u64>(key_type))) {
Key128 key{};
master_cipher.Transcode(
GetKey(S128KeyType::Source, static_cast<u64>(key_type)).data(), key.size(),
key.data(), Op::Decrypt);
SetKey(key_type == SourceKeyType::Titlekek ? S128KeyType::Titlekek
: S128KeyType::Package2,
key, crypto_revision);
}
}
}
}
RSAKeyPair<2048> KeyManager::GetETicketRSAKey() const {
if (IsAllZeroArray(eticket_extended_kek) || !HasKey(S128KeyType::ETicketRSAKek)) {
return {};
}
const auto eticket_final = GetKey(S128KeyType::ETicketRSAKek);
std::vector<u8> extended_iv(eticket_extended_kek.begin(), eticket_extended_kek.begin() + 0x10);
std::array<u8, 0x230> extended_dec{};
AESCipher<Key128> rsa_1(eticket_final, Mode::CTR);
rsa_1.SetIV(extended_iv);
rsa_1.Transcode(eticket_extended_kek.data() + 0x10, eticket_extended_kek.size() - 0x10,
extended_dec.data(), Op::Decrypt);
RSAKeyPair<2048> rsa_key{};
std::memcpy(rsa_key.decryption_key.data(), extended_dec.data(), rsa_key.decryption_key.size());
std::memcpy(rsa_key.modulus.data(), extended_dec.data() + 0x100, rsa_key.modulus.size());
std::memcpy(rsa_key.exponent.data(), extended_dec.data() + 0x200, rsa_key.exponent.size());
return rsa_key;
}
Key128 DeriveKeyblobMACKey(const Key128& keyblob_key, const Key128& mac_source) {
AESCipher<Key128> mac_cipher(keyblob_key, Mode::ECB);
Key128 mac_key{};
mac_cipher.Transcode(mac_source.data(), mac_key.size(), mac_key.data(), Op::Decrypt);
return mac_key;
}
std::optional<Key128> DeriveSDSeed() {
const auto system_save_43_path =
Common::FS::GetYuzuPath(Common::FS::YuzuPath::NANDDir) / "system/save/8000000000000043";
const Common::FS::IOFile save_43{system_save_43_path, Common::FS::FileAccessMode::Read,
Common::FS::FileType::BinaryFile};
if (!save_43.IsOpen()) {
return std::nullopt;
}
const auto sd_private_path =
Common::FS::GetYuzuPath(Common::FS::YuzuPath::SDMCDir) / "Nintendo/Contents/private";
const Common::FS::IOFile sd_private{sd_private_path, Common::FS::FileAccessMode::Read,
Common::FS::FileType::BinaryFile};
if (!sd_private.IsOpen()) {
return std::nullopt;
}
std::array<u8, 0x10> private_seed{};
if (sd_private.Read(private_seed) != private_seed.size()) {
return std::nullopt;
}
std::array<u8, 0x10> buffer{};
s64 offset = 0;
for (; offset + 0x10 < static_cast<s64>(save_43.GetSize()); ++offset) {
if (!save_43.Seek(offset)) {
return std::nullopt;
}
if (save_43.Read(buffer) != buffer.size()) {
return std::nullopt;
}
if (buffer == private_seed) {
break;
}
}
if (!save_43.Seek(offset + 0x10)) {
return std::nullopt;
}
Key128 seed{};
if (save_43.Read(seed) != seed.size()) {
return std::nullopt;
}
return seed;
}
Loader::ResultStatus DeriveSDKeys(std::array<Key256, 2>& sd_keys, KeyManager& keys) {
if (!keys.HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::SDKek))) {
return Loader::ResultStatus::ErrorMissingSDKEKSource;
}
if (!keys.HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKekGeneration))) {
return Loader::ResultStatus::ErrorMissingAESKEKGenerationSource;
}
if (!keys.HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKeyGeneration))) {
return Loader::ResultStatus::ErrorMissingAESKeyGenerationSource;
}
const auto sd_kek_source =
keys.GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::SDKek));
const auto aes_kek_gen =
keys.GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKekGeneration));
const auto aes_key_gen =
keys.GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKeyGeneration));
const auto master_00 = keys.GetKey(S128KeyType::Master);
const auto sd_kek =
GenerateKeyEncryptionKey(sd_kek_source, master_00, aes_kek_gen, aes_key_gen);
keys.SetKey(S128KeyType::SDKek, sd_kek);
if (!keys.HasKey(S128KeyType::SDSeed)) {
return Loader::ResultStatus::ErrorMissingSDSeed;
}
const auto sd_seed = keys.GetKey(S128KeyType::SDSeed);
if (!keys.HasKey(S256KeyType::SDKeySource, static_cast<u64>(SDKeyType::Save))) {
return Loader::ResultStatus::ErrorMissingSDSaveKeySource;
}
if (!keys.HasKey(S256KeyType::SDKeySource, static_cast<u64>(SDKeyType::NCA))) {
return Loader::ResultStatus::ErrorMissingSDNCAKeySource;
}
std::array<Key256, 2> sd_key_sources{
keys.GetKey(S256KeyType::SDKeySource, static_cast<u64>(SDKeyType::Save)),
keys.GetKey(S256KeyType::SDKeySource, static_cast<u64>(SDKeyType::NCA)),
};
// Combine sources and seed
for (auto& source : sd_key_sources) {
for (std::size_t i = 0; i < source.size(); ++i) {
source[i] = static_cast<u8>(source[i] ^ sd_seed[i & 0xF]);
}
}
AESCipher<Key128> cipher(sd_kek, Mode::ECB);
// The transform manipulates sd_keys as part of the Transcode, so the return/output is
// unnecessary. This does not alter sd_keys_sources.
std::transform(sd_key_sources.begin(), sd_key_sources.end(), sd_keys.begin(),
sd_key_sources.begin(), [&cipher](const Key256& source, Key256& out) {
cipher.Transcode(source.data(), source.size(), out.data(), Op::Decrypt);
return source; ///< Return unaltered source to satisfy output requirement.
});
keys.SetKey(S256KeyType::SDKey, sd_keys[0], static_cast<u64>(SDKeyType::Save));
keys.SetKey(S256KeyType::SDKey, sd_keys[1], static_cast<u64>(SDKeyType::NCA));
return Loader::ResultStatus::Success;
}
std::vector<Ticket> GetTicketblob(const Common::FS::IOFile& ticket_save) {
if (!ticket_save.IsOpen()) {
return {};
}
std::vector<u8> buffer(ticket_save.GetSize());
if (ticket_save.Read(buffer) != buffer.size()) {
return {};
}
std::vector<Ticket> out;
for (std::size_t offset = 0; offset + 0x4 < buffer.size(); ++offset) {
if (buffer[offset] == 0x4 && buffer[offset + 1] == 0x0 && buffer[offset + 2] == 0x1 &&
buffer[offset + 3] == 0x0) {
out.emplace_back();
auto& next = out.back();
std::memcpy(&next, buffer.data() + offset, sizeof(Ticket));
offset += FULL_TICKET_SIZE;
}
}
return out;
}
template <size_t size>
static std::array<u8, size> operator^(const std::array<u8, size>& lhs,
const std::array<u8, size>& rhs) {
std::array<u8, size> out;
std::transform(lhs.begin(), lhs.end(), rhs.begin(), out.begin(),
[](u8 lhs_elem, u8 rhs_elem) { return u8(lhs_elem ^ rhs_elem); });
return out;
}
template <size_t target_size, size_t in_size>
static std::array<u8, target_size> MGF1(const std::array<u8, in_size>& seed) {
// Avoids truncation overflow within the loop below.
static_assert(target_size <= 0xFF);
std::array<u8, in_size + 4> seed_exp{};
std::memcpy(seed_exp.data(), seed.data(), in_size);
std::vector<u8> out;
size_t i = 0;
while (out.size() < target_size) {
out.resize(out.size() + 0x20);
seed_exp[in_size + 3] = static_cast<u8>(i);
mbedtls_sha256_ret(seed_exp.data(), seed_exp.size(), out.data() + out.size() - 0x20, 0);
++i;
}
std::array<u8, target_size> target;
std::memcpy(target.data(), out.data(), target_size);
return target;
}
template <size_t size>
static std::optional<u64> FindTicketOffset(const std::array<u8, size>& data) {
u64 offset = 0;
for (size_t i = 0x20; i < data.size() - 0x10; ++i) {
if (data[i] == 0x1) {
offset = i + 1;
break;
} else if (data[i] != 0x0) {
return std::nullopt;
}
}
return offset;
}
std::optional<std::pair<Key128, Key128>> ParseTicket(const Ticket& ticket,
const RSAKeyPair<2048>& key) {
const auto issuer = ticket.GetData().issuer;
if (IsAllZeroArray(issuer)) {
return std::nullopt;
}
if (issuer[0] != 'R' || issuer[1] != 'o' || issuer[2] != 'o' || issuer[3] != 't') {
LOG_INFO(Crypto, "Attempting to parse ticket with non-standard certificate authority.");
}
Key128 rights_id = ticket.GetData().rights_id;
if (rights_id == Key128{}) {
return std::nullopt;
}
if (!std::any_of(ticket.GetData().title_key_common_pad.begin(),
ticket.GetData().title_key_common_pad.end(), [](u8 b) { return b != 0; })) {
return std::make_pair(rights_id, ticket.GetData().title_key_common);
}
mbedtls_mpi D; // RSA Private Exponent
mbedtls_mpi N; // RSA Modulus
mbedtls_mpi S; // Input
mbedtls_mpi M; // Output
mbedtls_mpi_init(&D);
mbedtls_mpi_init(&N);
mbedtls_mpi_init(&S);
mbedtls_mpi_init(&M);
mbedtls_mpi_read_binary(&D, key.decryption_key.data(), key.decryption_key.size());
mbedtls_mpi_read_binary(&N, key.modulus.data(), key.modulus.size());
mbedtls_mpi_read_binary(&S, ticket.GetData().title_key_block.data(), 0x100);
mbedtls_mpi_exp_mod(&M, &S, &D, &N, nullptr);
std::array<u8, 0x100> rsa_step;
mbedtls_mpi_write_binary(&M, rsa_step.data(), rsa_step.size());
u8 m_0 = rsa_step[0];
std::array<u8, 0x20> m_1;
std::memcpy(m_1.data(), rsa_step.data() + 0x01, m_1.size());
std::array<u8, 0xDF> m_2;
std::memcpy(m_2.data(), rsa_step.data() + 0x21, m_2.size());
if (m_0 != 0) {
return std::nullopt;
}
m_1 = m_1 ^ MGF1<0x20>(m_2);
m_2 = m_2 ^ MGF1<0xDF>(m_1);
const auto offset = FindTicketOffset(m_2);
if (!offset) {
return std::nullopt;
}
ASSERT(*offset > 0);
Key128 key_temp{};
std::memcpy(key_temp.data(), m_2.data() + *offset, key_temp.size());
return std::make_pair(rights_id, key_temp);
}
KeyManager::KeyManager() {
// Initialize keys
const auto yuzu_keys_dir = Common::FS::GetYuzuPath(Common::FS::YuzuPath::KeysDir);
if (!Common::FS::CreateDir(yuzu_keys_dir)) {
LOG_ERROR(Core, "Failed to create the keys directory.");
}
if (Settings::values.use_dev_keys) {
dev_mode = true;
LoadFromFile(yuzu_keys_dir / "dev.keys", false);
LoadFromFile(yuzu_keys_dir / "dev.keys_autogenerated", false);
} else {
dev_mode = false;
LoadFromFile(yuzu_keys_dir / "prod.keys", false);
LoadFromFile(yuzu_keys_dir / "prod.keys_autogenerated", false);
}
LoadFromFile(yuzu_keys_dir / "title.keys", true);
LoadFromFile(yuzu_keys_dir / "title.keys_autogenerated", true);
LoadFromFile(yuzu_keys_dir / "console.keys", false);
LoadFromFile(yuzu_keys_dir / "console.keys_autogenerated", false);
}
static bool ValidCryptoRevisionString(std::string_view base, size_t begin, size_t length) {
if (base.size() < begin + length) {
return false;
}
return std::all_of(base.begin() + begin, base.begin() + begin + length,
[](u8 c) { return std::isxdigit(c); });
}
void KeyManager::LoadFromFile(const std::filesystem::path& file_path, bool is_title_keys) {
if (!Common::FS::Exists(file_path)) {
return;
}
std::ifstream file;
Common::FS::OpenFileStream(file, file_path, std::ios_base::in);
if (!file.is_open()) {
return;
}
std::string line;
while (std::getline(file, line)) {
std::vector<std::string> out;
std::stringstream stream(line);
std::string item;
while (std::getline(stream, item, '=')) {
out.push_back(std::move(item));
}
if (out.size() != 2) {
continue;
}
out[0].erase(std::remove(out[0].begin(), out[0].end(), ' '), out[0].end());
out[1].erase(std::remove(out[1].begin(), out[1].end(), ' '), out[1].end());
if (out[0].compare(0, 1, "#") == 0) {
continue;
}
if (is_title_keys) {
auto rights_id_raw = Common::HexStringToArray<16>(out[0]);
u128 rights_id{};
std::memcpy(rights_id.data(), rights_id_raw.data(), rights_id_raw.size());
Key128 key = Common::HexStringToArray<16>(out[1]);
s128_keys[{S128KeyType::Titlekey, rights_id[1], rights_id[0]}] = key;
} else {
out[0] = Common::ToLower(out[0]);
if (const auto iter128 = Find128ByName(out[0]); iter128 != s128_file_id.end()) {
const auto& index = iter128->second;
const Key128 key = Common::HexStringToArray<16>(out[1]);
s128_keys[{index.type, index.field1, index.field2}] = key;
} else if (const auto iter256 = Find256ByName(out[0]); iter256 != s256_file_id.end()) {
const auto& index = iter256->second;
const Key256 key = Common::HexStringToArray<32>(out[1]);
s256_keys[{index.type, index.field1, index.field2}] = key;
} else if (out[0].compare(0, 8, "keyblob_") == 0 &&
out[0].compare(0, 9, "keyblob_k") != 0) {
if (!ValidCryptoRevisionString(out[0], 8, 2)) {
continue;
}
const auto index = std::stoul(out[0].substr(8, 2), nullptr, 16);
keyblobs[index] = Common::HexStringToArray<0x90>(out[1]);
} else if (out[0].compare(0, 18, "encrypted_keyblob_") == 0) {
if (!ValidCryptoRevisionString(out[0], 18, 2)) {
continue;
}
const auto index = std::stoul(out[0].substr(18, 2), nullptr, 16);
encrypted_keyblobs[index] = Common::HexStringToArray<0xB0>(out[1]);
} else if (out[0].compare(0, 20, "eticket_extended_kek") == 0) {
eticket_extended_kek = Common::HexStringToArray<576>(out[1]);
} else {
for (const auto& kv : KEYS_VARIABLE_LENGTH) {
if (!ValidCryptoRevisionString(out[0], kv.second.size(), 2)) {
continue;
}
if (out[0].compare(0, kv.second.size(), kv.second) == 0) {
const auto index =
std::stoul(out[0].substr(kv.second.size(), 2), nullptr, 16);
const auto sub = kv.first.second;
if (sub == 0) {
s128_keys[{kv.first.first, index, 0}] =
Common::HexStringToArray<16>(out[1]);
} else {
s128_keys[{kv.first.first, kv.first.second, index}] =
Common::HexStringToArray<16>(out[1]);
}
break;
}
}
static constexpr std::array<const char*, 3> kak_names = {
"key_area_key_application_", "key_area_key_ocean_", "key_area_key_system_"};
for (size_t j = 0; j < kak_names.size(); ++j) {
const auto& match = kak_names[j];
if (out[0].compare(0, std::strlen(match), match) == 0) {
const auto index =
std::stoul(out[0].substr(std::strlen(match), 2), nullptr, 16);
s128_keys[{S128KeyType::KeyArea, index, j}] =
Common::HexStringToArray<16>(out[1]);
}
}
}
}
}
}
bool KeyManager::BaseDeriveNecessary() const {
const auto check_key_existence = [this](auto key_type, u64 index1 = 0, u64 index2 = 0) {
return !HasKey(key_type, index1, index2);
};
if (check_key_existence(S256KeyType::Header)) {
return true;
}
for (size_t i = 0; i < CURRENT_CRYPTO_REVISION; ++i) {
if (check_key_existence(S128KeyType::Master, i) ||
check_key_existence(S128KeyType::KeyArea, i,
static_cast<u64>(KeyAreaKeyType::Application)) ||
check_key_existence(S128KeyType::KeyArea, i, static_cast<u64>(KeyAreaKeyType::Ocean)) ||
check_key_existence(S128KeyType::KeyArea, i,
static_cast<u64>(KeyAreaKeyType::System)) ||
check_key_existence(S128KeyType::Titlekek, i))
return true;
}
return false;
}
bool KeyManager::HasKey(S128KeyType id, u64 field1, u64 field2) const {
return s128_keys.find({id, field1, field2}) != s128_keys.end();
}
bool KeyManager::HasKey(S256KeyType id, u64 field1, u64 field2) const {
return s256_keys.find({id, field1, field2}) != s256_keys.end();
}
Key128 KeyManager::GetKey(S128KeyType id, u64 field1, u64 field2) const {
if (!HasKey(id, field1, field2)) {
return {};
}
return s128_keys.at({id, field1, field2});
}
Key256 KeyManager::GetKey(S256KeyType id, u64 field1, u64 field2) const {
if (!HasKey(id, field1, field2)) {
return {};
}
return s256_keys.at({id, field1, field2});
}
Key256 KeyManager::GetBISKey(u8 partition_id) const {
Key256 out{};
for (const auto& bis_type : {BISKeyType::Crypto, BISKeyType::Tweak}) {
if (HasKey(S128KeyType::BIS, partition_id, static_cast<u64>(bis_type))) {
std::memcpy(
out.data() + sizeof(Key128) * static_cast<u64>(bis_type),
s128_keys.at({S128KeyType::BIS, partition_id, static_cast<u64>(bis_type)}).data(),
sizeof(Key128));
}
}
return out;
}
template <size_t Size>
void KeyManager::WriteKeyToFile(KeyCategory category, std::string_view keyname,
const std::array<u8, Size>& key) {
const auto yuzu_keys_dir = Common::FS::GetYuzuPath(Common::FS::YuzuPath::KeysDir);
std::string filename = "title.keys_autogenerated";
if (category == KeyCategory::Standard) {
filename = dev_mode ? "dev.keys_autogenerated" : "prod.keys_autogenerated";
} else if (category == KeyCategory::Console) {
filename = "console.keys_autogenerated";
}
const auto path = yuzu_keys_dir / filename;
const auto add_info_text = !Common::FS::Exists(path);
Common::FS::IOFile file{path, Common::FS::FileAccessMode::Append,
Common::FS::FileType::TextFile};
if (!file.IsOpen()) {
return;
}
if (add_info_text) {
void(file.WriteString(
"# This file is autogenerated by Yuzu\n"
"# It serves to store keys that were automatically generated from the normal keys\n"
"# If you are experiencing issues involving keys, it may help to delete this file\n"));
}
void(file.WriteString(fmt::format("\n{} = {}", keyname, Common::HexToString(key))));
LoadFromFile(path, category == KeyCategory::Title);
}
void KeyManager::SetKey(S128KeyType id, Key128 key, u64 field1, u64 field2) {
if (s128_keys.find({id, field1, field2}) != s128_keys.end() || key == Key128{}) {
return;
}
if (id == S128KeyType::Titlekey) {
Key128 rights_id;
std::memcpy(rights_id.data(), &field2, sizeof(u64));
std::memcpy(rights_id.data() + sizeof(u64), &field1, sizeof(u64));
WriteKeyToFile(KeyCategory::Title, Common::HexToString(rights_id), key);
}
auto category = KeyCategory::Standard;
if (id == S128KeyType::Keyblob || id == S128KeyType::KeyblobMAC || id == S128KeyType::TSEC ||
id == S128KeyType::SecureBoot || id == S128KeyType::SDSeed || id == S128KeyType::BIS) {
category = KeyCategory::Console;
}
const auto iter2 = std::find_if(
s128_file_id.begin(), s128_file_id.end(), [&id, &field1, &field2](const auto& elem) {
return std::tie(elem.second.type, elem.second.field1, elem.second.field2) ==
std::tie(id, field1, field2);
});
if (iter2 != s128_file_id.end()) {
WriteKeyToFile(category, iter2->first, key);
}
// Variable cases
if (id == S128KeyType::KeyArea) {
static constexpr std::array<const char*, 3> kak_names = {
"key_area_key_application_{:02X}",
"key_area_key_ocean_{:02X}",
"key_area_key_system_{:02X}",
};
WriteKeyToFile(category, fmt::format(fmt::runtime(kak_names.at(field2)), field1), key);
} else if (id == S128KeyType::Master) {
WriteKeyToFile(category, fmt::format("master_key_{:02X}", field1), key);
} else if (id == S128KeyType::Package1) {
WriteKeyToFile(category, fmt::format("package1_key_{:02X}", field1), key);
} else if (id == S128KeyType::Package2) {
WriteKeyToFile(category, fmt::format("package2_key_{:02X}", field1), key);
} else if (id == S128KeyType::Titlekek) {
WriteKeyToFile(category, fmt::format("titlekek_{:02X}", field1), key);
} else if (id == S128KeyType::Keyblob) {
WriteKeyToFile(category, fmt::format("keyblob_key_{:02X}", field1), key);
} else if (id == S128KeyType::KeyblobMAC) {
WriteKeyToFile(category, fmt::format("keyblob_mac_key_{:02X}", field1), key);
} else if (id == S128KeyType::Source && field1 == static_cast<u64>(SourceKeyType::Keyblob)) {
WriteKeyToFile(category, fmt::format("keyblob_key_source_{:02X}", field2), key);
}
s128_keys[{id, field1, field2}] = key;
}
void KeyManager::SetKey(S256KeyType id, Key256 key, u64 field1, u64 field2) {
if (s256_keys.find({id, field1, field2}) != s256_keys.end() || key == Key256{}) {
return;
}
const auto iter = std::find_if(
s256_file_id.begin(), s256_file_id.end(), [&id, &field1, &field2](const auto& elem) {
return std::tie(elem.second.type, elem.second.field1, elem.second.field2) ==
std::tie(id, field1, field2);
});
if (iter != s256_file_id.end()) {
WriteKeyToFile(KeyCategory::Standard, iter->first, key);
}
s256_keys[{id, field1, field2}] = key;
}
bool KeyManager::KeyFileExists(bool title) {
const auto yuzu_keys_dir = Common::FS::GetYuzuPath(Common::FS::YuzuPath::KeysDir);
if (title) {
return Common::FS::Exists(yuzu_keys_dir / "title.keys");
}
if (Settings::values.use_dev_keys) {
return Common::FS::Exists(yuzu_keys_dir / "dev.keys");
}
return Common::FS::Exists(yuzu_keys_dir / "prod.keys");
}
void KeyManager::DeriveSDSeedLazy() {
if (HasKey(S128KeyType::SDSeed)) {
return;
}
const auto res = DeriveSDSeed();
if (res) {
SetKey(S128KeyType::SDSeed, *res);
}
}
static Key128 CalculateCMAC(const u8* source, size_t size, const Key128& key) {
Key128 out{};
mbedtls_cipher_cmac(mbedtls_cipher_info_from_type(MBEDTLS_CIPHER_AES_128_ECB), key.data(),
key.size() * 8, source, size, out.data());
return out;
}
void KeyManager::DeriveBase() {
if (!BaseDeriveNecessary()) {
return;
}
if (!HasKey(S128KeyType::SecureBoot) || !HasKey(S128KeyType::TSEC)) {
return;
}
const auto has_bis = [this](u64 id) {
return HasKey(S128KeyType::BIS, id, static_cast<u64>(BISKeyType::Crypto)) &&
HasKey(S128KeyType::BIS, id, static_cast<u64>(BISKeyType::Tweak));
};
const auto copy_bis = [this](u64 id_from, u64 id_to) {
SetKey(S128KeyType::BIS,
GetKey(S128KeyType::BIS, id_from, static_cast<u64>(BISKeyType::Crypto)), id_to,
static_cast<u64>(BISKeyType::Crypto));
SetKey(S128KeyType::BIS,
GetKey(S128KeyType::BIS, id_from, static_cast<u64>(BISKeyType::Tweak)), id_to,
static_cast<u64>(BISKeyType::Tweak));
};
if (has_bis(2) && !has_bis(3)) {
copy_bis(2, 3);
} else if (has_bis(3) && !has_bis(2)) {
copy_bis(3, 2);
}
std::bitset<32> revisions(0xFFFFFFFF);
for (size_t i = 0; i < revisions.size(); ++i) {
if (!HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::Keyblob), i) ||
encrypted_keyblobs[i] == std::array<u8, 0xB0>{}) {
revisions.reset(i);
}
}
if (!revisions.any()) {
return;
}
const auto sbk = GetKey(S128KeyType::SecureBoot);
const auto tsec = GetKey(S128KeyType::TSEC);
for (size_t i = 0; i < revisions.size(); ++i) {
if (!revisions[i]) {
continue;
}
// Derive keyblob key
const auto key = DeriveKeyblobKey(
sbk, tsec, GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::Keyblob), i));
SetKey(S128KeyType::Keyblob, key, i);
// Derive keyblob MAC key
if (!HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::KeyblobMAC))) {
continue;
}
const auto mac_key = DeriveKeyblobMACKey(
key, GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::KeyblobMAC)));
SetKey(S128KeyType::KeyblobMAC, mac_key, i);
Key128 cmac = CalculateCMAC(encrypted_keyblobs[i].data() + 0x10, 0xA0, mac_key);
if (std::memcmp(cmac.data(), encrypted_keyblobs[i].data(), cmac.size()) != 0) {
continue;
}
// Decrypt keyblob
if (keyblobs[i] == std::array<u8, 0x90>{}) {
keyblobs[i] = DecryptKeyblob(encrypted_keyblobs[i], key);
WriteKeyToFile<0x90>(KeyCategory::Console, fmt::format("keyblob_{:02X}", i),
keyblobs[i]);
}
Key128 package1;
std::memcpy(package1.data(), keyblobs[i].data() + 0x80, sizeof(Key128));
SetKey(S128KeyType::Package1, package1, i);
// Derive master key
if (HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::Master))) {
SetKey(S128KeyType::Master,
DeriveMasterKey(keyblobs[i], GetKey(S128KeyType::Source,
static_cast<u64>(SourceKeyType::Master))),
i);
}
}
revisions.set();
for (size_t i = 0; i < revisions.size(); ++i) {
if (!HasKey(S128KeyType::Master, i)) {
revisions.reset(i);
}
}
if (!revisions.any()) {
return;
}
for (size_t i = 0; i < revisions.size(); ++i) {
if (!revisions[i]) {
continue;
}
// Derive general purpose keys
DeriveGeneralPurposeKeys(i);
}
if (HasKey(S128KeyType::Master, 0) &&
HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKeyGeneration)) &&
HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKekGeneration)) &&
HasKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::HeaderKek)) &&
HasKey(S256KeyType::HeaderSource)) {
const auto header_kek = GenerateKeyEncryptionKey(
GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::HeaderKek)),
GetKey(S128KeyType::Master, 0),
GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKekGeneration)),
GetKey(S128KeyType::Source, static_cast<u64>(SourceKeyType::AESKeyGeneration)));
SetKey(S128KeyType::HeaderKek, header_kek);
AESCipher<Key128> header_cipher(header_kek, Mode::ECB);
Key256 out = GetKey(S256KeyType::HeaderSource);
header_cipher.Transcode(out.data(), out.size(), out.data(), Op::Decrypt);
SetKey(S256KeyType::Header, out);
}
}
void KeyManager::DeriveETicket(PartitionDataManager& data,
const FileSys::ContentProvider& provider) {
// ETicket keys
const auto es = provider.GetEntry(0x0100000000000033, FileSys::ContentRecordType::Program);
if (es == nullptr) {
return;
}
const auto exefs = es->GetExeFS();
if (exefs == nullptr) {
return;
}
const auto main = exefs->GetFile("main");
if (main == nullptr) {
return;
}
const auto bytes = main->ReadAllBytes();
const auto eticket_kek = FindKeyFromHex16(bytes, eticket_source_hashes[0]);
const auto eticket_kekek = FindKeyFromHex16(bytes, eticket_source_hashes[1]);
const auto seed3 = data.GetRSAKekSeed3();
const auto mask0 = data.GetRSAKekMask0();
if (eticket_kek != Key128{}) {
SetKey(S128KeyType::Source, eticket_kek, static_cast<size_t>(SourceKeyType::ETicketKek));
}
if (eticket_kekek != Key128{}) {
SetKey(S128KeyType::Source, eticket_kekek,
static_cast<size_t>(SourceKeyType::ETicketKekek));
}
if (seed3 != Key128{}) {
SetKey(S128KeyType::RSAKek, seed3, static_cast<size_t>(RSAKekType::Seed3));
}
if (mask0 != Key128{}) {
SetKey(S128KeyType::RSAKek, mask0, static_cast<size_t>(RSAKekType::Mask0));
}
if (eticket_kek == Key128{} || eticket_kekek == Key128{} || seed3 == Key128{} ||
mask0 == Key128{}) {
return;
}
const Key128 rsa_oaep_kek = seed3 ^ mask0;
if (rsa_oaep_kek == Key128{}) {
return;
}
SetKey(S128KeyType::Source, rsa_oaep_kek,
static_cast<u64>(SourceKeyType::RSAOaepKekGeneration));
Key128 temp_kek{};
Key128 temp_kekek{};
Key128 eticket_final{};
// Derive ETicket RSA Kek
AESCipher<Key128> es_master(GetKey(S128KeyType::Master), Mode::ECB);
es_master.Transcode(rsa_oaep_kek.data(), rsa_oaep_kek.size(), temp_kek.data(), Op::Decrypt);
AESCipher<Key128> es_kekek(temp_kek, Mode::ECB);
es_kekek.Transcode(eticket_kekek.data(), eticket_kekek.size(), temp_kekek.data(), Op::Decrypt);
AESCipher<Key128> es_kek(temp_kekek, Mode::ECB);
es_kek.Transcode(eticket_kek.data(), eticket_kek.size(), eticket_final.data(), Op::Decrypt);
if (eticket_final == Key128{}) {
return;
}
SetKey(S128KeyType::ETicketRSAKek, eticket_final);
// Titlekeys
data.DecryptProdInfo(GetBISKey(0));
eticket_extended_kek = data.GetETicketExtendedKek();
WriteKeyToFile(KeyCategory::Console, "eticket_extended_kek", eticket_extended_kek);
PopulateTickets();
}
void KeyManager::PopulateTickets() {
const auto rsa_key = GetETicketRSAKey();
if (rsa_key == RSAKeyPair<2048>{}) {
return;
}
if (!common_tickets.empty() && !personal_tickets.empty()) {
return;
}
const auto system_save_e1_path =
Common::FS::GetYuzuPath(Common::FS::YuzuPath::NANDDir) / "system/save/80000000000000e1";
const Common::FS::IOFile save_e1{system_save_e1_path, Common::FS::FileAccessMode::Read,
Common::FS::FileType::BinaryFile};
const auto system_save_e2_path =
Common::FS::GetYuzuPath(Common::FS::YuzuPath::NANDDir) / "system/save/80000000000000e2";
const Common::FS::IOFile save_e2{system_save_e2_path, Common::FS::FileAccessMode::Read,
Common::FS::FileType::BinaryFile};
const auto blob2 = GetTicketblob(save_e2);
auto res = GetTicketblob(save_e1);
const auto idx = res.size();
res.insert(res.end(), blob2.begin(), blob2.end());
for (std::size_t i = 0; i < res.size(); ++i) {
const auto common = i < idx;
const auto pair = ParseTicket(res[i], rsa_key);
if (!pair) {
continue;
}
const auto& [rid, key] = *pair;
u128 rights_id;
std::memcpy(rights_id.data(), rid.data(), rid.size());
if (common) {
common_tickets[rights_id] = res[i];
} else {
personal_tickets[rights_id] = res[i];
}
SetKey(S128KeyType::Titlekey, key, rights_id[1], rights_id[0]);
}
}
void KeyManager::SynthesizeTickets() {
for (const auto& key : s128_keys) {
if (key.first.type != S128KeyType::Titlekey) {
continue;
}
u128 rights_id{key.first.field1, key.first.field2};
Key128 rights_id_2;
std::memcpy(rights_id_2.data(), rights_id.data(), rights_id_2.size());
const auto ticket = Ticket::SynthesizeCommon(key.second, rights_id_2);
common_tickets.insert_or_assign(rights_id, ticket);
}
}
void KeyManager::SetKeyWrapped(S128KeyType id, Key128 key, u64 field1, u64 field2) {
if (key == Key128{}) {
return;
}
SetKey(id, key, field1, field2);
}
void KeyManager::SetKeyWrapped(S256KeyType id, Key256 key, u64 field1, u64 field2) {
if (key == Key256{}) {
return;
}
SetKey(id, key, field1, field2);
}
void KeyManager::PopulateFromPartitionData(PartitionDataManager& data) {
if (!BaseDeriveNecessary()) {
return;
}
if (!data.HasBoot0()) {
return;
}
for (size_t i = 0; i < encrypted_keyblobs.size(); ++i) {
if (encrypted_keyblobs[i] != std::array<u8, 0xB0>{}) {
continue;
}
encrypted_keyblobs[i] = data.GetEncryptedKeyblob(i);
WriteKeyToFile<0xB0>(KeyCategory::Console, fmt::format("encrypted_keyblob_{:02X}", i),
encrypted_keyblobs[i]);
}
SetKeyWrapped(S128KeyType::Source, data.GetPackage2KeySource(),
static_cast<u64>(SourceKeyType::Package2));
SetKeyWrapped(S128KeyType::Source, data.GetAESKekGenerationSource(),
static_cast<u64>(SourceKeyType::AESKekGeneration));
SetKeyWrapped(S128KeyType::Source, data.GetTitlekekSource(),
static_cast<u64>(SourceKeyType::Titlekek));
SetKeyWrapped(S128KeyType::Source, data.GetMasterKeySource(),
static_cast<u64>(SourceKeyType::Master));
SetKeyWrapped(S128KeyType::Source, data.GetKeyblobMACKeySource(),
static_cast<u64>(SourceKeyType::KeyblobMAC));
for (size_t i = 0; i < PartitionDataManager::MAX_KEYBLOB_SOURCE_HASH; ++i) {
SetKeyWrapped(S128KeyType::Source, data.GetKeyblobKeySource(i),
static_cast<u64>(SourceKeyType::Keyblob), i);
}
if (data.HasFuses()) {
SetKeyWrapped(S128KeyType::SecureBoot, data.GetSecureBootKey());
}
DeriveBase();
Key128 latest_master{};
for (s8 i = 0x1F; i >= 0; --i) {
if (GetKey(S128KeyType::Master, static_cast<u8>(i)) != Key128{}) {
latest_master = GetKey(S128KeyType::Master, static_cast<u8>(i));
break;
}
}
const auto masters = data.GetTZMasterKeys(latest_master);
for (size_t i = 0; i < masters.size(); ++i) {
if (masters[i] != Key128{} && !HasKey(S128KeyType::Master, i)) {
SetKey(S128KeyType::Master, masters[i], i);
}
}
DeriveBase();
if (!data.HasPackage2())
return;
std::array<Key128, 0x20> package2_keys{};
for (size_t i = 0; i < package2_keys.size(); ++i) {
if (HasKey(S128KeyType::Package2, i)) {
package2_keys[i] = GetKey(S128KeyType::Package2, i);
}
}
data.DecryptPackage2(package2_keys, Package2Type::NormalMain);
SetKeyWrapped(S128KeyType::Source, data.GetKeyAreaKeyApplicationSource(),
static_cast<u64>(SourceKeyType::KeyAreaKey),
static_cast<u64>(KeyAreaKeyType::Application));
SetKeyWrapped(S128KeyType::Source, data.GetKeyAreaKeyOceanSource(),
static_cast<u64>(SourceKeyType::KeyAreaKey),
static_cast<u64>(KeyAreaKeyType::Ocean));
SetKeyWrapped(S128KeyType::Source, data.GetKeyAreaKeySystemSource(),
static_cast<u64>(SourceKeyType::KeyAreaKey),
static_cast<u64>(KeyAreaKeyType::System));
SetKeyWrapped(S128KeyType::Source, data.GetSDKekSource(),
static_cast<u64>(SourceKeyType::SDKek));
SetKeyWrapped(S256KeyType::SDKeySource, data.GetSDSaveKeySource(),
static_cast<u64>(SDKeyType::Save));
SetKeyWrapped(S256KeyType::SDKeySource, data.GetSDNCAKeySource(),
static_cast<u64>(SDKeyType::NCA));
SetKeyWrapped(S128KeyType::Source, data.GetHeaderKekSource(),
static_cast<u64>(SourceKeyType::HeaderKek));
SetKeyWrapped(S256KeyType::HeaderSource, data.GetHeaderKeySource());
SetKeyWrapped(S128KeyType::Source, data.GetAESKeyGenerationSource(),
static_cast<u64>(SourceKeyType::AESKeyGeneration));
DeriveBase();
}
const std::map<u128, Ticket>& KeyManager::GetCommonTickets() const {
return common_tickets;
}
const std::map<u128, Ticket>& KeyManager::GetPersonalizedTickets() const {
return personal_tickets;
}
bool KeyManager::AddTicketCommon(Ticket raw) {
const auto rsa_key = GetETicketRSAKey();
if (rsa_key == RSAKeyPair<2048>{}) {
return false;
}
const auto pair = ParseTicket(raw, rsa_key);
if (!pair) {
return false;
}
const auto& [rid, key] = *pair;
u128 rights_id;
std::memcpy(rights_id.data(), rid.data(), rid.size());
common_tickets[rights_id] = raw;
SetKey(S128KeyType::Titlekey, key, rights_id[1], rights_id[0]);
return true;
}
bool KeyManager::AddTicketPersonalized(Ticket raw) {
const auto rsa_key = GetETicketRSAKey();
if (rsa_key == RSAKeyPair<2048>{}) {
return false;
}
const auto pair = ParseTicket(raw, rsa_key);
if (!pair) {
return false;
}
const auto& [rid, key] = *pair;
u128 rights_id;
std::memcpy(rights_id.data(), rid.data(), rid.size());
common_tickets[rights_id] = raw;
SetKey(S128KeyType::Titlekey, key, rights_id[1], rights_id[0]);
return true;
}
} // namespace Core::Crypto