/* * 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 . */ #pragma once #include #include "erpt_srv_formatter.hpp" #include "erpt_srv_keys.hpp" namespace ams::erpt::srv { class Cipher : private Formatter { private: static constexpr u32 RsaKeySize = 0x100; static constexpr u32 SaltSize = 0x20; static u8 s_key[crypto::Aes128CtrEncryptor::KeySize + crypto::Aes128CtrEncryptor::IvSize + crypto::Aes128CtrEncryptor::BlockSize]; static bool s_need_to_store_cipher; struct Header { u32 magic; u32 field_type; u32 element_count; u32 reserved; u8 data[0]; }; static_assert(sizeof(Header) == 0x10); static constexpr u32 HeaderMagic = util::FourCC<'C', 'R', 'P', 'T'>::Code; private: template static Result EncryptArray(Report *report, FieldId field_id, T *arr, u32 arr_size) { const u32 data_size = util::AlignUp(arr_size * sizeof(T), crypto::Aes128CtrEncryptor::BlockSize); Header *hdr = reinterpret_cast
(AllocateWithAlign(sizeof(Header) + data_size, crypto::Aes128CtrEncryptor::BlockSize)); R_UNLESS(hdr != nullptr, erpt::ResultOutOfMemory()); ON_SCOPE_EXIT { Deallocate(hdr); }; hdr->magic = HeaderMagic; hdr->field_type = static_cast(ConvertFieldToType(field_id)); hdr->element_count = arr_size; hdr->reserved = 0; std::memset(hdr->data, 0, data_size); std::memcpy(hdr->data, arr, arr_size * sizeof(T)); crypto::EncryptAes128Ctr(hdr->data, data_size, s_key, crypto::Aes128CtrEncryptor::KeySize, s_key + crypto::Aes128CtrEncryptor::KeySize, crypto::Aes128CtrEncryptor::IvSize, hdr->data, data_size); ON_SCOPE_EXIT { std::memset(hdr, 0, sizeof(hdr) + data_size); s_need_to_store_cipher = true; }; R_RETURN(Formatter::AddField(report, field_id, reinterpret_cast(hdr), sizeof(hdr) + data_size)); } public: static Result Begin(Report *report, u32 record_count) { s_need_to_store_cipher = false; crypto::GenerateCryptographicallyRandomBytes(s_key, sizeof(s_key)); R_RETURN(Formatter::Begin(report, record_count + 1)); } static Result End(Report *report) { u8 cipher[RsaKeySize] = {}; if (s_need_to_store_cipher) { u8 salt[SaltSize]; crypto::RsaOaepEncryptor oaep; crypto::GenerateCryptographicallyRandomBytes(salt, sizeof(salt)); oaep.Initialize(GetPublicKeyModulus(), GetPublicKeyModulusSize(), GetPublicKeyExponent(), GetPublicKeyExponentSize()); oaep.Encrypt(cipher, sizeof(cipher), s_key, sizeof(s_key), salt, sizeof(salt)); } Formatter::AddField(report, ERPT_FIELD_ID(CipherKey), cipher, sizeof(cipher)); std::memset(s_key, 0, sizeof(s_key)); R_RETURN(Formatter::End(report)); } static Result AddField(Report *report, FieldId field_id, bool value) { R_RETURN(Formatter::AddField(report, field_id, value)); } template static Result AddField(Report *report, FieldId field_id, T value) { R_RETURN(Formatter::AddField(report, field_id, value)); } static Result AddField(Report *report, FieldId field_id, char *str, u32 len) { if (ConvertFieldToFlag(field_id) == FieldFlag_Encrypt) { R_RETURN(EncryptArray(report, field_id, str, len)); } else { R_RETURN(Formatter::AddField(report, field_id, str, len)); } } static Result AddField(Report *report, FieldId field_id, u8 *bin, u32 len) { if (ConvertFieldToFlag(field_id) == FieldFlag_Encrypt) { R_RETURN(EncryptArray(report, field_id, bin, len)); } else { R_RETURN(Formatter::AddField(report, field_id, bin, len)); } } template static Result AddField(Report *report, FieldId field_id, T *arr, u32 len) { if (ConvertFieldToFlag(field_id) == FieldFlag_Encrypt) { R_RETURN(EncryptArray(report, field_id, arr, len)); } else { R_RETURN(Formatter::AddField(report, field_id, arr, len)); } } }; }