/* Derived from source code of TrueCrypt 7.1a, which is Copyright (c) 2008-2012 TrueCrypt Developers Association and which is governed by the TrueCrypt License 3.0. Modifications and additions to the original source code (contained in this file) and all other portions of this file are Copyright (c) 2013-2017 IDRIX and are governed by the Apache License 2.0 the full text of which is contained in the file License.txt included in VeraCrypt binary and source code distribution packages. */ #include "Crc32.h" #include "EncryptionModeXTS.h" #include "Pkcs5Kdf.h" #include "Pkcs5Kdf.h" #include "VolumeHeader.h" #include "VolumeException.h" #include "Common/Crypto.h" namespace VeraCrypt { VolumeHeader::VolumeHeader (uint32 size) { Init(); HeaderSize = size; EncryptedHeaderDataSize = size - EncryptedHeaderDataOffset; } VolumeHeader::~VolumeHeader () { Init(); } void VolumeHeader::Init () { VolumeKeyAreaCrc32 = 0; VolumeCreationTime = 0; HeaderCreationTime = 0; mVolumeType = VolumeType::Unknown; HiddenVolumeDataSize = 0; VolumeDataSize = 0; EncryptedAreaStart = 0; EncryptedAreaLength = 0; Flags = 0; SectorSize = 0; } void VolumeHeader::Create (const BufferPtr &headerBuffer, VolumeHeaderCreationOptions &options) { if (options.DataKey.Size() != options.EA->GetKeySize() * 2 || options.Salt.Size() != GetSaltSize()) throw ParameterIncorrect (SRC_POS); headerBuffer.Zero(); HeaderVersion = CurrentHeaderVersion; RequiredMinProgramVersion = CurrentRequiredMinProgramVersion; DataAreaKey.Zero(); DataAreaKey.CopyFrom (options.DataKey); VolumeCreationTime = 0; HiddenVolumeDataSize = (options.Type == VolumeType::Hidden ? options.VolumeDataSize : 0); VolumeDataSize = options.VolumeDataSize; EncryptedAreaStart = options.VolumeDataStart; EncryptedAreaLength = options.VolumeDataSize; SectorSize = options.SectorSize; if (SectorSize < TC_MIN_VOLUME_SECTOR_SIZE || SectorSize > TC_MAX_VOLUME_SECTOR_SIZE || SectorSize % ENCRYPTION_DATA_UNIT_SIZE != 0) { throw ParameterIncorrect (SRC_POS); } EA = options.EA; shared_ptr mode (new EncryptionModeXTS ()); EA->SetMode (mode); EncryptNew (headerBuffer, options.Salt, options.HeaderKey, options.Kdf); } bool VolumeHeader::Decrypt (const ConstBufferPtr &encryptedData, const VolumePassword &password, int pim, shared_ptr kdf, bool truecryptMode, const Pkcs5KdfList &keyDerivationFunctions, const EncryptionAlgorithmList &encryptionAlgorithms, const EncryptionModeList &encryptionModes) { if (password.Size() < 1) throw PasswordEmpty (SRC_POS); ConstBufferPtr salt (encryptedData.GetRange (SaltOffset, SaltSize)); SecureBuffer header (EncryptedHeaderDataSize); SecureBuffer headerKey (GetLargestSerializedKeySize()); foreach (shared_ptr pkcs5, keyDerivationFunctions) { if (kdf && (kdf->GetName() != pkcs5->GetName())) continue; pkcs5->DeriveKey (headerKey, password, pim, salt); foreach (shared_ptr mode, encryptionModes) { if (typeid (*mode) != typeid (EncryptionModeXTS)) mode->SetKey (headerKey.GetRange (0, mode->GetKeySize())); foreach (shared_ptr ea, encryptionAlgorithms) { if (!ea->IsModeSupported (mode)) continue; if (typeid (*mode) == typeid (EncryptionModeXTS)) { ea->SetKey (headerKey.GetRange (0, ea->GetKeySize())); mode = mode->GetNew(); mode->SetKey (headerKey.GetRange (ea->GetKeySize(), ea->GetKeySize())); } else { ea->SetKey (headerKey.GetRange (LegacyEncryptionModeKeyAreaSize, ea->GetKeySize())); } ea->SetMode (mode); header.CopyFrom (encryptedData.GetRange (EncryptedHeaderDataOffset, EncryptedHeaderDataSize)); ea->Decrypt (header); if (Deserialize (header, ea, mode, truecryptMode)) { EA = ea; Pkcs5 = pkcs5; return true; } } } } return false; } bool VolumeHeader::Deserialize (const ConstBufferPtr &header, shared_ptr &ea, shared_ptr &mode, bool truecryptMode) { if (header.Size() != EncryptedHeaderDataSize) throw ParameterIncorrect (SRC_POS); if (truecryptMode && (header[0] != 'T' || header[1] != 'R' || header[2] != 'U' || header[3] != 'E')) return false; if (!truecryptMode && (header[0] != 'V' || header[1] != 'E' || header[2] != 'R' || header[3] != 'A')) return false; size_t offset = 4; HeaderVersion = DeserializeEntry (header, offset); if (HeaderVersion < MinAllowedHeaderVersion) return false; if (HeaderVersion > CurrentHeaderVersion) throw HigherVersionRequired (SRC_POS); if (HeaderVersion >= 4 && Crc32::ProcessBuffer (header.GetRange (0, TC_HEADER_OFFSET_HEADER_CRC - TC_HEADER_OFFSET_MAGIC)) != DeserializeEntryAt (header, TC_HEADER_OFFSET_HEADER_CRC - TC_HEADER_OFFSET_MAGIC)) { return false; } RequiredMinProgramVersion = DeserializeEntry (header, offset); if (!truecryptMode && (RequiredMinProgramVersion > Version::Number())) throw HigherVersionRequired (SRC_POS); if (truecryptMode) { if (RequiredMinProgramVersion < 0x600 || RequiredMinProgramVersion > 0x71a) throw UnsupportedTrueCryptFormat (SRC_POS); RequiredMinProgramVersion = CurrentRequiredMinProgramVersion; } VolumeKeyAreaCrc32 = DeserializeEntry (header, offset); VolumeCreationTime = DeserializeEntry (header, offset); HeaderCreationTime = DeserializeEntry (header, offset); HiddenVolumeDataSize = DeserializeEntry (header, offset); mVolumeType = (HiddenVolumeDataSize != 0 ? VolumeType::Hidden : VolumeType::Normal); VolumeDataSize = DeserializeEntry (header, offset); EncryptedAreaStart = DeserializeEntry (header, offset); EncryptedAreaLength = DeserializeEntry (header, offset); Flags = DeserializeEntry (header, offset); SectorSize = DeserializeEntry (header, offset); if (HeaderVersion < 5) SectorSize = TC_SECTOR_SIZE_LEGACY; if (SectorSize < TC_MIN_VOLUME_SECTOR_SIZE || SectorSize > TC_MAX_VOLUME_SECTOR_SIZE || SectorSize % ENCRYPTION_DATA_UNIT_SIZE != 0) { throw ParameterIncorrect (SRC_POS); } #if !(defined (TC_WINDOWS) || defined (TC_LINUX) || defined (TC_MACOSX)) if (SectorSize != TC_SECTOR_SIZE_LEGACY) throw UnsupportedSectorSize (SRC_POS); #endif offset = DataAreaKeyOffset; if (VolumeKeyAreaCrc32 != Crc32::ProcessBuffer (header.GetRange (offset, DataKeyAreaMaxSize))) return false; DataAreaKey.CopyFrom (header.GetRange (offset, DataKeyAreaMaxSize)); ea = ea->GetNew(); mode = mode->GetNew(); if (typeid (*mode) == typeid (EncryptionModeXTS)) { ea->SetKey (header.GetRange (offset, ea->GetKeySize())); mode->SetKey (header.GetRange (offset + ea->GetKeySize(), ea->GetKeySize())); } else { mode->SetKey (header.GetRange (offset, mode->GetKeySize())); ea->SetKey (header.GetRange (offset + LegacyEncryptionModeKeyAreaSize, ea->GetKeySize())); } ea->SetMode (mode); return true; } template T VolumeHeader::DeserializeEntry (const ConstBufferPtr &header, size_t &offset) const { offset += sizeof (T); if (offset > header.Size()) throw ParameterIncorrect (SRC_POS); return Endian::Big (*reinterpret_cast (header.Get() + offset - sizeof (T))); } template T VolumeHeader::DeserializeEntryAt (const ConstBufferPtr &header, const size_t &offset) const { if (offset > header.Size()) throw ParameterIncorrect (SRC_POS); return Endian::Big (*reinterpret_cast (header.Get() + offset)); } void VolumeHeader::EncryptNew (const BufferPtr &newHeaderBuffer, const ConstBufferPtr &newSalt, const ConstBufferPtr &newHeaderKey, shared_ptr newPkcs5Kdf) { if (newHeaderBuffer.Size() != HeaderSize || newSalt.Size() != SaltSize) throw ParameterIncorrect (SRC_POS); shared_ptr mode = EA->GetMode()->GetNew(); shared_ptr ea = EA->GetNew(); if (typeid (*mode) == typeid (EncryptionModeXTS)) { mode->SetKey (newHeaderKey.GetRange (EA->GetKeySize(), EA->GetKeySize())); ea->SetKey (newHeaderKey.GetRange (0, ea->GetKeySize())); } else { mode->SetKey (newHeaderKey.GetRange (0, mode->GetKeySize())); ea->SetKey (newHeaderKey.GetRange (LegacyEncryptionModeKeyAreaSize, ea->GetKeySize())); } ea->SetMode (mode); newHeaderBuffer.CopyFrom (newSalt); BufferPtr headerData = newHeaderBuffer.GetRange (EncryptedHeaderDataOffset, EncryptedHeaderDataSize); Serialize (headerData); ea->Encrypt (headerData); if (newPkcs5Kdf) Pkcs5 = newPkcs5Kdf; } size_t VolumeHeader::GetLargestSerializedKeySize () { size_t largestKey = EncryptionAlgorithm::GetLargestKeySize (EncryptionAlgorithm::GetAvailableAlgorithms()); // XTS mode requires the same key size as the encryption algorithm. // Legacy modes may require larger key than XTS. if (LegacyEncryptionModeKeyAreaSize + largestKey > largestKey * 2) return LegacyEncryptionModeKeyAreaSize + largestKey; return largestKey * 2; } void VolumeHeader::Serialize (const BufferPtr &header) const { if (header.Size() != EncryptedHeaderDataSize) throw ParameterIncorrect (SRC_POS); header.Zero(); header[0] = 'V'; header[1] = 'E'; header[2] = 'R'; header[3] = 'A'; size_t offset = 4; header.GetRange (DataAreaKeyOffset, DataAreaKey.Size()).CopyFrom (DataAreaKey); uint16 headerVersion = CurrentHeaderVersion; SerializeEntry (headerVersion, header, offset); SerializeEntry (RequiredMinProgramVersion, header, offset); SerializeEntry (Crc32::ProcessBuffer (header.GetRange (DataAreaKeyOffset, DataKeyAreaMaxSize)), header, offset); uint64 reserved64 = 0; SerializeEntry (reserved64, header, offset); SerializeEntry (reserved64, header, offset); SerializeEntry (HiddenVolumeDataSize, header, offset); SerializeEntry (VolumeDataSize, header, offset); SerializeEntry (EncryptedAreaStart, header, offset); SerializeEntry (EncryptedAreaLength, header, offset); SerializeEntry (Flags, header, offset); if (SectorSize < TC_MIN_VOLUME_SECTOR_SIZE || SectorSize > TC_MAX_VOLUME_SECTOR_SIZE || SectorSize % ENCRYPTION_DATA_UNIT_SIZE != 0) { throw ParameterIncorrect (SRC_POS); } SerializeEntry (SectorSize, header, offset); offset = TC_HEADER_OFFSET_HEADER_CRC - TC_HEADER_OFFSET_MAGIC; SerializeEntry (Crc32::ProcessBuffer (header.GetRange (0, TC_HEADER_OFFSET_HEADER_CRC - TC_HEADER_OFFSET_MAGIC)), header, offset); } template void VolumeHeader::SerializeEntry (const T &entry, const BufferPtr &header, size_t &offset) const { offset += sizeof (T); if (offset > header.Size()) throw ParameterIncorrect (SRC_POS); *reinterpret_cast (header.Get() + offset - sizeof (T)) = Endian::Big (entry); } void VolumeHeader::SetSize (uint32 headerSize) { HeaderSize = headerSize; EncryptedHeaderDataSize = HeaderSize - EncryptedHeaderDataOffset; } } ef='#n234'>234 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263 264 265 266 267 268 269 270 271 272 273 274 275 276 277 278 279 280 281 282 283 284 285 286 287 288 289 290 291 292 293 294 295 296 297 298 299 300 301 302 303 304 305 306 307 308 309 310 311 312 313 314 315 316 317 318 319 320 321 322 323 324 325 326 327 328 329 330 331 332 333 334 335 336 337 338 339 340 341 342 343 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 359 360 361 362 363 364 365 366 367 368 369 370 371 372 373 374 375 376 377 378 379 380 381 382 383 384 385 386 387 388 389 390 391 392 393 394 395 396 397 398 399 400 401 402 403 404 405 406 407 408 409 410 411 412 413 414 415 416 417 418 419 420 421 422 423 424 425 426 427 428 429 430 431 432 433 434 435 436 437 438 439 440 441 442 443 444 445 446 447 448 449 450 451 452 453 454 455 456 457 458 459 460 461 462 463 464 465 466 467 468 469 470 471 472 473 474 475 476 477 478 479 480 481 482 483 484 485 486 487 488 489 490 491 492 493 494 495 496 497 498 499 500 501 502 503 504 505 506 507 508 509 510 511 512 513 514 
/*
 Derived from source code of TrueCrypt 7.1a, which is
 Copyright (c) 2008-2012 TrueCrypt Developers Association and which is governed
 by the TrueCrypt License 3.0.

 Modifications and additions to the original source code (contained in this file)
 and all other portions of this file are Copyright (c) 2013-2017 IDRIX
 and are governed by the Apache License 2.0 the full text of which is
 contained in the file License.txt included in VeraCrypt binary and source
 code distribution packages.
*/

#include "Platform/Platform.h"
#include "Cipher.h"
#include "Crypto/Aes.h"
#include "Crypto/SerpentFast.h"
#include "Crypto/Twofish.h"
#include "Crypto/Camellia.h"
#include "Crypto/GostCipher.h"
#include "Crypto/kuznyechik.h"

#ifdef TC_AES_HW_CPU
#	include "Crypto/Aes_hw_cpu.h"
#endif
#include "Crypto/cpu.h"

extern "C" int IsAesHwCpuSupported ()
{
#ifdef TC_AES_HW_CPU
	static bool state = false;
	static bool stateValid = false;

	if (!stateValid)
	{
		state = g_hasAESNI ? true : false;
		stateValid = true;
	}
	return state && VeraCrypt::Cipher::IsHwSupportEnabled();
#else
	return false;
#endif
}

namespace VeraCrypt
{
	Cipher::Cipher () : Initialized (false)
	{
	}

	Cipher::~Cipher ()
	{
	}

	void Cipher::DecryptBlock (byte *data) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

		Decrypt (data);
	}

	void Cipher::DecryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

		while (blockCount-- > 0)
		{
			Decrypt (data);
			data += GetBlockSize();
		}
	}

	void Cipher::EncryptBlock (byte *data) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

		Encrypt (data);
	}

	void Cipher::EncryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

		while (blockCount-- > 0)
		{
			Encrypt (data);
			data += GetBlockSize();
		}
	}

	CipherList Cipher::GetAvailableCiphers ()
	{
		CipherList l;

		l.push_back (shared_ptr <Cipher> (new CipherAES ()));
		l.push_back (shared_ptr <Cipher> (new CipherSerpent ()));
		l.push_back (shared_ptr <Cipher> (new CipherTwofish ()));
		l.push_back (shared_ptr <Cipher> (new CipherCamellia ()));
		l.push_back (shared_ptr <Cipher> (new CipherGost89 ()));
		l.push_back (shared_ptr <Cipher> (new CipherKuznyechik ()));

		return l;
	}

	void Cipher::SetKey (const ConstBufferPtr &key)
	{
		if (key.Size() != GetKeySize ())
			throw ParameterIncorrect (SRC_POS);

		if (!Initialized)
			ScheduledKey.Allocate (GetScheduledKeySize ());

		SetCipherKey (key);
		Key.CopyFrom (key);
		Initialized = true;
	}

#define TC_EXCEPTION(TYPE) TC_SERIALIZER_FACTORY_ADD(TYPE)
#undef TC_EXCEPTION_NODECL
#define TC_EXCEPTION_NODECL(TYPE) TC_SERIALIZER_FACTORY_ADD(TYPE)

	TC_SERIALIZER_FACTORY_ADD_EXCEPTION_SET (CipherException);


	// AES
	void CipherAES::Decrypt (byte *data) const
	{
#ifdef TC_AES_HW_CPU
		if (IsHwSupportAvailable())
			aes_hw_cpu_decrypt (ScheduledKey.Ptr() + sizeof (aes_encrypt_ctx), data);
		else
#endif
			aes_decrypt (data, data, (aes_decrypt_ctx *) (ScheduledKey.Ptr() + sizeof (aes_encrypt_ctx)));
	}

	void CipherAES::DecryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#ifdef TC_AES_HW_CPU
		if ((blockCount & (32 - 1)) == 0
			&& IsHwSupportAvailable())
		{
			while (blockCount > 0)
			{
				aes_hw_cpu_decrypt_32_blocks (ScheduledKey.Ptr() + sizeof (aes_encrypt_ctx), data);

				data += 32 * GetBlockSize();
				blockCount -= 32;
			}
		}
		else
#endif
			Cipher::DecryptBlocks (data, blockCount);
	}

	void CipherAES::Encrypt (byte *data) const
	{
#ifdef TC_AES_HW_CPU
		if (IsHwSupportAvailable())
			aes_hw_cpu_encrypt (ScheduledKey.Ptr(), data);
		else
#endif
			aes_encrypt (data, data, (aes_encrypt_ctx *) ScheduledKey.Ptr());
	}

	void CipherAES::EncryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#ifdef TC_AES_HW_CPU
		if ((blockCount & (32 - 1)) == 0
			&& IsHwSupportAvailable())
		{
			while (blockCount > 0)
			{
				aes_hw_cpu_encrypt_32_blocks (ScheduledKey.Ptr(), data);

				data += 32 * GetBlockSize();
				blockCount -= 32;
			}
		}
		else
#endif
			Cipher::EncryptBlocks (data, blockCount);
	}

	size_t CipherAES::GetScheduledKeySize () const
	{
		return sizeof(aes_encrypt_ctx) + sizeof(aes_decrypt_ctx);
	}

	bool CipherAES::IsHwSupportAvailable () const
	{
#ifdef TC_AES_HW_CPU
		static bool state = false;
		static bool stateValid = false;

		if (!stateValid)
		{
			state = g_hasAESNI ? true : false;
			stateValid = true;
		}
		return state && HwSupportEnabled;
#else
		return false;
#endif
	}

	void CipherAES::SetCipherKey (const byte *key)
	{
		if (aes_encrypt_key256 (key, (aes_encrypt_ctx *) ScheduledKey.Ptr()) != EXIT_SUCCESS)
			throw CipherInitError (SRC_POS);

		if (aes_decrypt_key256 (key, (aes_decrypt_ctx *) (ScheduledKey.Ptr() + sizeof (aes_encrypt_ctx))) != EXIT_SUCCESS)
			throw CipherInitError (SRC_POS);
	}

	// Serpent
	void CipherSerpent::Decrypt (byte *data) const
	{
		serpent_decrypt (data, data, ScheduledKey);
	}

	void CipherSerpent::Encrypt (byte *data) const
	{
		serpent_encrypt (data, data, ScheduledKey);
	}

	size_t CipherSerpent::GetScheduledKeySize () const
	{
		return 140*4;
	}

	void CipherSerpent::SetCipherKey (const byte *key)
	{
		serpent_set_key (key, ScheduledKey);
	}
	
	void CipherSerpent::EncryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#if CRYPTOPP_BOOL_SSE2_INTRINSICS_AVAILABLE && !defined(CRYPTOPP_DISABLE_ASM)
		if ((blockCount >= 4)
			&& IsHwSupportAvailable())
		{
			serpent_encrypt_blocks (data, data, blockCount, ScheduledKey.Ptr());
		}
		else
#endif
			Cipher::EncryptBlocks (data, blockCount);
	}
	
	void CipherSerpent::DecryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#if CRYPTOPP_BOOL_SSE2_INTRINSICS_AVAILABLE && !defined(CRYPTOPP_DISABLE_ASM)
		if ((blockCount >= 4)
			&& IsHwSupportAvailable())
		{
			serpent_decrypt_blocks (data, data, blockCount, ScheduledKey.Ptr());
		}
		else
#endif
			Cipher::DecryptBlocks (data, blockCount);
	}
	
	bool CipherSerpent::IsHwSupportAvailable () const
	{
#if CRYPTOPP_BOOL_SSE2_INTRINSICS_AVAILABLE
		static bool state = false;
		static bool stateValid = false;

		if (!stateValid)
		{
			state = HasSSE2() ? true : false;
			stateValid = true;
		}
		return state;
#else
		return false;
#endif
	}


	// Twofish
	void CipherTwofish::Decrypt (byte *data) const
	{
		twofish_decrypt ((TwofishInstance *) ScheduledKey.Ptr(), (unsigned int *)data, (unsigned int *)data);
	}

	void CipherTwofish::Encrypt (byte *data) const
	{
		twofish_encrypt ((TwofishInstance *) ScheduledKey.Ptr(), (unsigned int *)data, (unsigned int *)data);
	}

	size_t CipherTwofish::GetScheduledKeySize () const
	{
		return TWOFISH_KS;
	}

	void CipherTwofish::SetCipherKey (const byte *key)
	{
		twofish_set_key ((TwofishInstance *) ScheduledKey.Ptr(), (unsigned int *) key);
	}
	
	void CipherTwofish::EncryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#if CRYPTOPP_BOOL_X64 && !defined(CRYPTOPP_DISABLE_ASM)
		twofish_encrypt_blocks ( (TwofishInstance *) ScheduledKey.Ptr(), data, data, blockCount);
#else
		Cipher::EncryptBlocks (data, blockCount);
#endif
	}
	
	void CipherTwofish::DecryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#if CRYPTOPP_BOOL_X64 && !defined(CRYPTOPP_DISABLE_ASM)
		twofish_decrypt_blocks ( (TwofishInstance *) ScheduledKey.Ptr(), data, data, blockCount);
#else
		Cipher::DecryptBlocks (data, blockCount);
#endif
	}
	
	bool CipherTwofish::IsHwSupportAvailable () const
	{
#if CRYPTOPP_BOOL_X64 && !defined(CRYPTOPP_DISABLE_ASM)
		return true;
#else
		return false;
#endif
	}
	
	// Camellia
	void CipherCamellia::Decrypt (byte *data) const
	{
		camellia_decrypt (data, data, ScheduledKey.Ptr());
	}

	void CipherCamellia::Encrypt (byte *data) const
	{
		camellia_encrypt (data, data, ScheduledKey.Ptr());
	}

	size_t CipherCamellia::GetScheduledKeySize () const
	{
		return CAMELLIA_KS;
	}

	void CipherCamellia::SetCipherKey (const byte *key)
	{
		camellia_set_key (key, ScheduledKey.Ptr());
	}
	
	void CipherCamellia::EncryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#if CRYPTOPP_BOOL_X64 && !defined(CRYPTOPP_DISABLE_ASM)
		camellia_encrypt_blocks ( ScheduledKey.Ptr(), data, data, blockCount);
#else
		Cipher::EncryptBlocks (data, blockCount);
#endif
	}
	
	void CipherCamellia::DecryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#if CRYPTOPP_BOOL_X64 && !defined(CRYPTOPP_DISABLE_ASM)
		camellia_decrypt_blocks ( ScheduledKey.Ptr(), data, data, blockCount);
#else
		Cipher::DecryptBlocks (data, blockCount);
#endif
	}
	
	bool CipherCamellia::IsHwSupportAvailable () const
	{
#if CRYPTOPP_BOOL_X64 && !defined(CRYPTOPP_DISABLE_ASM)
		return true;
#else
		return false;
#endif
	}

	// GOST89
	void CipherGost89::Decrypt (byte *data) const
	{
		gost_decrypt (data, data, (gost_kds *) ScheduledKey.Ptr(), 1);
	}

	void CipherGost89::Encrypt (byte *data) const
	{
		gost_encrypt (data, data, (gost_kds *) ScheduledKey.Ptr(), 1);
	}

	size_t CipherGost89::GetScheduledKeySize () const
	{
		return GOST_KS;
	}

	void CipherGost89::SetCipherKey (const byte *key)
	{
		gost_set_key (key, (gost_kds *) ScheduledKey.Ptr(), 1);
	}
	
	// GOST89 with static SBOX
	void CipherGost89StaticSBOX::Decrypt (byte *data) const
	{
		gost_decrypt (data, data, (gost_kds *) ScheduledKey.Ptr(), 1);
	}

	void CipherGost89StaticSBOX::Encrypt (byte *data) const
	{
		gost_encrypt (data, data, (gost_kds *) ScheduledKey.Ptr(), 1);
	}

	size_t CipherGost89StaticSBOX::GetScheduledKeySize () const
	{
		return GOST_KS;
	}

	void CipherGost89StaticSBOX::SetCipherKey (const byte *key)
	{
		gost_set_key (key, (gost_kds *) ScheduledKey.Ptr(), 0);
	}

	// Kuznyechik
	void CipherKuznyechik::Decrypt (byte *data) const
	{
		kuznyechik_decrypt_block (data, data, (kuznyechik_kds *) ScheduledKey.Ptr());
	}

	void CipherKuznyechik::Encrypt (byte *data) const
	{
		kuznyechik_encrypt_block (data, data, (kuznyechik_kds *) ScheduledKey.Ptr());
	}

	size_t CipherKuznyechik::GetScheduledKeySize () const
	{
		return KUZNYECHIK_KS;
	}

	void CipherKuznyechik::SetCipherKey (const byte *key)
	{
		kuznyechik_set_key (key, (kuznyechik_kds *) ScheduledKey.Ptr());
	}
	void CipherKuznyechik::EncryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#if CRYPTOPP_BOOL_SSE2_INTRINSICS_AVAILABLE
		if ((blockCount >= 4)
			&& IsHwSupportAvailable())
		{
			kuznyechik_encrypt_blocks (data, data, blockCount, (kuznyechik_kds *) ScheduledKey.Ptr());
		}
		else
#endif
			Cipher::EncryptBlocks (data, blockCount);
	}
	
	void CipherKuznyechik::DecryptBlocks (byte *data, size_t blockCount) const
	{
		if (!Initialized)
			throw NotInitialized (SRC_POS);

#if CRYPTOPP_BOOL_SSE2_INTRINSICS_AVAILABLE
		if ((blockCount >= 4)
			&& IsHwSupportAvailable())
		{
			kuznyechik_decrypt_blocks (data, data, blockCount, (kuznyechik_kds *) ScheduledKey.Ptr());
		}
		else
#endif
			Cipher::DecryptBlocks (data, blockCount);
	}
	
	bool CipherKuznyechik::IsHwSupportAvailable () const
	{
#if CRYPTOPP_BOOL_SSE2_INTRINSICS_AVAILABLE
		static bool state = false;
		static bool stateValid = false;

		if (!stateValid)
		{
			state = HasSSE2() ? true : false;
			stateValid = true;
		}
		return state;
#else
		return false;
#endif
	}
	bool Cipher::HwSupportEnabled = true;
}