// Copyright (c) 2014-2017 Thomas Fussell // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, WRISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN // THE SOFTWARE // // @license: http://www.opensource.org/licenses/mit-license.php // @author: see AUTHORS file #include #include #include #include #include #include #include #include #include #include #include #include #include namespace { using xlnt::detail::encryption_info; encryption_info generate_encryption_info(const std::u16string &/*password*/) { encryption_info result; result.is_agile = true; result.agile = encryption_info::agile_encryption_info(); result.agile.key_data.block_size = 16; result.agile.key_data.cipher_algorithm = "AES"; result.agile.key_data.cipher_chaining = "ChainingModeCBC"; result.agile.key_data.hash_algorithm = "SHA512"; result.agile.key_data.hash_size = 64; result.agile.key_data.key_bits = 256; result.agile.key_data.salt_size = 16; result.agile.key_data.salt_value = { { 40, 183, 193, 64, 115, 97, 10, 177, 122, 50, 243, 123, 229, 145, 162, 247 } }; result.agile.data_integrity.hmac_key = { { 90, 206, 203, 147, 102, 81, 82, 14, 118, 94, 168, 38, 200, 79, 13, 147, 60, 123, 167, 220, 17, 165, 124, 188, 206, 74, 98, 33, 156, 63, 220, 152, 180, 201, 167, 183, 141, 252, 182, 55, 90, 189, 187, 167, 230, 186, 61, 239, 80, 49, 54, 208, 52, 133, 232, 187, 117, 136, 213, 48, 133, 15, 7, 126 } }; result.agile.data_integrity.hmac_value = { { 49, 128, 174, 178, 161, 48, 1, 82, 241, 103, 72, 223, 103, 111, 204, 73, 210, 70, 254, 43, 12, 134, 180, 201, 124, 153, 214, 115, 82, 184, 78, 2, 166, 106, 69, 18, 173, 177, 40, 238, 243, 240, 3, 86, 145, 218, 223, 177, 36, 34, 44, 159, 104, 163, 217, 42, 203, 135, 173, 14, 218, 172, 72, 224 } }; result.agile.key_encryptor.spin_count = 100000; result.agile.key_encryptor.block_size = 16; result.agile.key_encryptor.cipher_algorithm = "AES"; result.agile.key_encryptor.cipher_chaining = "ChainingModeCBC"; result.agile.key_encryptor.hash = xlnt::detail::hash_algorithm::sha512; result.agile.key_encryptor.hash_size = 64; result.agile.key_encryptor.key_bits = 256; result.agile.key_encryptor.salt_size = 16; result.agile.key_encryptor.salt_value = { { 98, 169, 85, 224, 173, 253, 2, 52, 199, 108, 195, 73, 116, 112, 72, 165 } }; result.agile.key_encryptor.verifier_hash_input = { { 179, 105, 118, 193, 217, 180, 248, 7, 174, 45, 186, 17, 202, 101, 178, 12 } }; result.agile.key_encryptor.verifier_hash_value = { { 82, 190, 235, 102, 30, 33, 103, 191, 3, 160, 153, 30, 127, 117, 8, 195, 65, 245, 77, 219, 85, 28, 206, 236, 55, 86, 243, 49, 104, 128, 243, 138, 227, 113, 82, 88, 88, 73, 243, 108, 193, 11, 84, 162, 235, 189, 9, 137, 151, 97, 43, 137, 197, 72, 164, 192, 65, 252, 253, 227, 236, 242, 252, 179 } }; result.agile.key_encryptor.encrypted_key_value = { { 220, 6, 106, 218, 31, 210, 9, 75, 28, 154, 173, 232, 190, 109, 112, 203, 25, 5, 45, 152,75, 131, 122, 17, 166, 95, 117, 124, 121, 123, 32, 133 } }; return result; } void write_agile_encryption_info( const encryption_info &info, std::ostream &info_stream) { const auto version_major = std::uint16_t(4); const auto version_minor = std::uint16_t(4); const auto encryption_flags = std::uint32_t(0x40); info_stream.write(reinterpret_cast(&version_major), sizeof(std::uint16_t)); info_stream.write(reinterpret_cast(&version_minor), sizeof(std::uint16_t)); info_stream.write(reinterpret_cast(&encryption_flags), sizeof(std::uint32_t)); static const auto &xmlns = xlnt::constants::ns("encryption"); static const auto &xmlns_p = xlnt::constants::ns("encryption-password"); xml::serializer serializer(info_stream, "EncryptionInfo"); serializer.start_element(xmlns, "encryption"); const auto key_data = info.agile.key_data; serializer.start_element(xmlns, "keyData"); serializer.attribute("saltSize", key_data.salt_size); serializer.attribute("blockSize", key_data.block_size); serializer.attribute("keyBits", key_data.key_bits); serializer.attribute("hashSize", key_data.hash_size); serializer.attribute("cipherAlgorithm", key_data.cipher_algorithm); serializer.attribute("cipherChaining", key_data.cipher_chaining); serializer.attribute("hashAlgorithm", key_data.hash_algorithm); serializer.attribute("saltValue", xlnt::detail::encode_base64(key_data.salt_value)); serializer.end_element(xmlns, "keyData"); const auto data_integrity = info.agile.data_integrity; serializer.start_element(xmlns, "dataIntegrity"); serializer.attribute("encryptedHmacKey", xlnt::detail::encode_base64(data_integrity.hmac_key)); serializer.attribute("encryptedHmacValue", xlnt::detail::encode_base64(data_integrity.hmac_value)); serializer.end_element(xmlns, "dataIntegrity"); const auto key_encryptor = info.agile.key_encryptor; serializer.start_element(xmlns, "keyEncryptors"); serializer.start_element(xmlns, "keyEncryptor"); serializer.attribute("uri", ""); serializer.start_element(xmlns_p, "encryptedKey"); serializer.attribute("spinCount", key_encryptor.spin_count); serializer.attribute("saltSize", key_encryptor.salt_size); serializer.attribute("blockSize", key_encryptor.block_size); serializer.attribute("keyBits", key_encryptor.key_bits); serializer.attribute("hashSize", key_encryptor.hash_size); serializer.attribute("cipherAlgorithm", key_encryptor.cipher_algorithm); serializer.attribute("cipherChaining", key_encryptor.cipher_chaining); serializer.attribute("hashAlgorithm", key_encryptor.hash); serializer.attribute("saltValue", xlnt::detail::encode_base64(key_encryptor.salt_value)); serializer.attribute("encryptedVerifierHashInput", xlnt::detail::encode_base64(key_encryptor.verifier_hash_input)); serializer.attribute("encryptedVerifierHashValue", xlnt::detail::encode_base64(key_encryptor.verifier_hash_value)); serializer.attribute("encryptedKeyValue", xlnt::detail::encode_base64(key_encryptor.encrypted_key_value)); serializer.end_element(xmlns_p, "encryptedKey"); serializer.end_element(xmlns, "keyEncryptor"); serializer.end_element(xmlns, "keyEncryptors"); serializer.end_element(xmlns, "encryption"); } void write_standard_encryption_info(const encryption_info &info, std::ostream &info_stream) { auto result = std::vector(); auto writer = xlnt::detail::binary_writer(result); const auto version_major = std::uint16_t(4); const auto version_minor = std::uint16_t(2); const auto encryption_flags = std::uint32_t(0b00010000 & 0b00100000); writer.write(version_major); writer.write(version_minor); writer.write(encryption_flags); const auto header_length = std::uint32_t(32); // calculate this! writer.write(header_length); writer.write(std::uint32_t(0)); // skip_flags writer.write(std::uint32_t(0)); // size_extra writer.write(std::uint32_t(0x0000660E)); writer.write(std::uint32_t(0x00008004)); writer.write(std::uint32_t(info.standard.key_bits)); writer.write(std::uint32_t(0x00000018)); writer.write(std::uint32_t(0)); writer.write(std::uint32_t(0)); const auto provider = std::u16string(u"Microsoft Enhanced RSA and AES Cryptographic Provider"); writer.append(xlnt::detail::string_to_bytes(provider)); writer.write(std::uint32_t(info.standard.salt.size())); writer.append(info.standard.salt); writer.append(info.standard.encrypted_verifier); writer.write(std::uint32_t(20)); writer.append(info.standard.encrypted_verifier_hash); info_stream.write(reinterpret_cast(result.data()), static_cast(result.size())); } void encrypt_xlsx_agile( const encryption_info &info, const std::vector &plaintext, std::ostream &ciphertext_stream) { const auto length = static_cast(plaintext.size()); ciphertext_stream.write(reinterpret_cast(&length), sizeof(std::uint64_t)); auto key = info.calculate_key(); auto salt_size = info.agile.key_data.salt_size; auto salt_with_block_key = info.agile.key_data.salt_value; salt_with_block_key.resize(salt_size + sizeof(std::uint32_t), 0); auto &segment_index = *reinterpret_cast(salt_with_block_key.data() + salt_size); auto segment = std::vector(4096, 0); for (auto i = std::size_t(0); i < length; i += 4096) { auto iv = hash(info.agile.key_encryptor.hash, salt_with_block_key); iv.resize(16); auto start = plaintext.begin() + static_cast(i); auto bytes = std::min(std::size_t(length - i), std::size_t(4096)); std::copy(start, start + static_cast(bytes), segment.begin()); auto encrypted_segment = xlnt::detail::aes_cbc_encrypt(segment, key, iv); ciphertext_stream.write(reinterpret_cast(encrypted_segment.data()), static_cast(bytes)); ++segment_index; } } void encrypt_xlsx_standard( const encryption_info &info, const std::vector &plaintext, std::ostream &ciphertext_stream) { const auto length = static_cast(plaintext.size()); ciphertext_stream.write(reinterpret_cast(&length), sizeof(std::uint64_t)); auto key = info.calculate_key(); auto segment = std::vector(4096, 0); for (auto i = std::size_t(0); i < length; ++i) { auto start = plaintext.begin() + static_cast(i); auto bytes = std::min(std::size_t(length - i), std::size_t(4096)); std::copy(start, start + static_cast(bytes), segment.begin()); auto encrypted_segment = xlnt::detail::aes_ecb_encrypt(segment, key); ciphertext_stream.write(reinterpret_cast(encrypted_segment.data()), static_cast(bytes)); } } std::vector encrypt_xlsx( const std::vector &plaintext, const std::u16string &password) { auto encryption_info = generate_encryption_info(password); encryption_info.password = u"secret"; auto ciphertext = std::vector(); xlnt::detail::vector_ostreambuf buffer(ciphertext); std::ostream stream(&buffer); xlnt::detail::compound_document document(stream); if (encryption_info.is_agile) { write_agile_encryption_info(encryption_info, document.open_write_stream("/EncryptionInfo")); encrypt_xlsx_agile(encryption_info, plaintext, document.open_write_stream("/EncryptedPackage")); } else { write_standard_encryption_info(encryption_info, document.open_write_stream("/EncryptionInfo")); encrypt_xlsx_standard(encryption_info, plaintext, document.open_write_stream("/EncryptedPackage")); } return ciphertext; } } // namespace namespace xlnt { namespace detail { std::vector XLNT_API encrypt_xlsx( const std::vector &plaintext, const std::string &password) { return ::encrypt_xlsx(plaintext, utf8_to_utf16(password)); } void xlsx_producer::write(std::ostream &destination, const std::string &password) { std::vector plaintext; vector_ostreambuf plaintext_buffer(plaintext); std::ostream decrypted_stream(&plaintext_buffer); write(decrypted_stream); archive_.reset(); const auto ciphertext = ::encrypt_xlsx(plaintext, utf8_to_utf16(password)); vector_istreambuf encrypted_buffer(ciphertext); destination << &encrypted_buffer; } } // namespace detail } // namespace xlnt