kotatogram-desktop/Telegram/SourceFiles/mtproto/auth_key.h

/*
This file is part of Telegram Desktop,
the official desktop application for the Telegram messaging service.

For license and copyright information please follow this link:
https://github.com/telegramdesktop/tdesktop/blob/master/LEGAL
*/
#pragma once

#include <array>
#include <memory>
#include "base/bytes.h"

namespace MTP {

class AuthKey {
public:
	static constexpr auto kSize = 256; // 2048 bits.
	using Data = std::array<gsl::byte, kSize>;
	using KeyId = uint64;

	enum class Type {
		Generated,
		ReadFromFile,
		Local,
	};
	AuthKey(Type type, DcId dcId, const Data &data) : _type(type), _dcId(dcId), _key(data) {
		countKeyId();
	}
	AuthKey(const Data &data) : _type(Type::Local), _key(data) {
		countKeyId();
	}

	AuthKey(const AuthKey &other) = delete;
	AuthKey &operator=(const AuthKey &other) = delete;

	Type type() const {
		return _type;
	}

	int dcId() const {
		return _dcId;
	}

	KeyId keyId() const {
		return _keyId;
	}

	void prepareAES_oldmtp(const MTPint128 &msgKey, MTPint256 &aesKey, MTPint256 &aesIV, bool send) const;
	void prepareAES(const MTPint128 &msgKey, MTPint256 &aesKey, MTPint256 &aesIV, bool send) const;

	const void *partForMsgKey(bool send) const {
		return _key.data() + 88 + (send ? 0 : 8);
	}

	void write(QDataStream &to) const {
		to.writeRawData(reinterpret_cast<const char*>(_key.data()), _key.size());
	}
	bytes::const_span data() const {
		return _key;
	}

	bool equals(const std::shared_ptr<AuthKey> &other) const {
		return other ? (_key == other->_key) : false;
	}

	static void FillData(Data &authKey, bytes::const_span computedAuthKey) {
		auto computedAuthKeySize = computedAuthKey.size();
		Assert(computedAuthKeySize <= kSize);
		auto authKeyBytes = gsl::make_span(authKey);
		if (computedAuthKeySize < kSize) {
			bytes::set_with_const(authKeyBytes.subspan(0, kSize - computedAuthKeySize), gsl::byte());
			bytes::copy(authKeyBytes.subspan(kSize - computedAuthKeySize), computedAuthKey);
		} else {
			bytes::copy(authKeyBytes, computedAuthKey);
		}
	}

private:
	void countKeyId() {
		auto sha1 = hashSha1(_key.data(), _key.size());

		// Lower 64 bits = 8 bytes of 20 byte SHA1 hash.
		_keyId = *reinterpret_cast<KeyId*>(sha1.data() + 12);
	}

	Type _type = Type::Generated;
	DcId _dcId = 0;
	Data _key = { { gsl::byte{} } };
	KeyId _keyId = 0;

};

using AuthKeyPtr = std::shared_ptr<AuthKey>;
using AuthKeysList = std::vector<AuthKeyPtr>;

void aesIgeEncryptRaw(const void *src, void *dst, uint32 len, const void *key, const void *iv);
void aesIgeDecryptRaw(const void *src, void *dst, uint32 len, const void *key, const void *iv);

inline void aesIgeEncrypt_oldmtp(const void *src, void *dst, uint32 len, const AuthKeyPtr &authKey, const MTPint128 &msgKey) {
	MTPint256 aesKey, aesIV;
	authKey->prepareAES_oldmtp(msgKey, aesKey, aesIV, true);

	return aesIgeEncryptRaw(src, dst, len, static_cast<const void*>(&aesKey), static_cast<const void*>(&aesIV));
}

inline void aesIgeEncrypt(const void *src, void *dst, uint32 len, const AuthKeyPtr &authKey, const MTPint128 &msgKey) {
	MTPint256 aesKey, aesIV;
	authKey->prepareAES(msgKey, aesKey, aesIV, true);

	return aesIgeEncryptRaw(src, dst, len, static_cast<const void*>(&aesKey), static_cast<const void*>(&aesIV));
}

inline void aesEncryptLocal(const void *src, void *dst, uint32 len, const AuthKeyPtr &authKey, const void *key128) {
	MTPint256 aesKey, aesIV;
	authKey->prepareAES_oldmtp(*(const MTPint128*)key128, aesKey, aesIV, false);

	return aesIgeEncryptRaw(src, dst, len, static_cast<const void*>(&aesKey), static_cast<const void*>(&aesIV));
}

inline void aesIgeDecrypt_oldmtp(const void *src, void *dst, uint32 len, const AuthKeyPtr &authKey, const MTPint128 &msgKey) {
	MTPint256 aesKey, aesIV;
	authKey->prepareAES_oldmtp(msgKey, aesKey, aesIV, false);

	return aesIgeDecryptRaw(src, dst, len, static_cast<const void*>(&aesKey), static_cast<const void*>(&aesIV));
}

inline void aesIgeDecrypt(const void *src, void *dst, uint32 len, const AuthKeyPtr &authKey, const MTPint128 &msgKey) {
	MTPint256 aesKey, aesIV;
	authKey->prepareAES(msgKey, aesKey, aesIV, false);

	return aesIgeDecryptRaw(src, dst, len, static_cast<const void*>(&aesKey), static_cast<const void*>(&aesIV));
}

inline void aesDecryptLocal(const void *src, void *dst, uint32 len, const AuthKeyPtr &authKey, const void *key128) {
	MTPint256 aesKey, aesIV;
	authKey->prepareAES_oldmtp(*(const MTPint128*)key128, aesKey, aesIV, false);

	return aesIgeDecryptRaw(src, dst, len, static_cast<const void*>(&aesKey), static_cast<const void*>(&aesIV));
}

// ctr used inplace, encrypt the data and leave it at the same place
struct CTRState {
	static constexpr int KeySize = 32;
	static constexpr int IvecSize = 16;
	static constexpr int EcountSize = 16;

	uchar ivec[IvecSize] = { 0 };
	uint32 num = 0;
	uchar ecount[EcountSize] = { 0 };
};
void aesCtrEncrypt(bytes::span data, const void *key, CTRState *state);

} // namespace MTP