// default.cpp - written and placed in the public domain by Wei Dai #include "pch.h" #include "default.h" #include "queue.h" #include #include #if GCC_DIAGNOSTIC_AWARE # pragma GCC diagnostic ignored "-Wunused-value" # pragma GCC diagnostic ignored "-Wunused-variable" #endif NAMESPACE_BEGIN(CryptoPP) static const unsigned int MASH_ITERATIONS = 200; static const unsigned int SALTLENGTH = 8; static const unsigned int BLOCKSIZE = Default_BlockCipher::Encryption::BLOCKSIZE; static const unsigned int KEYLENGTH = Default_BlockCipher::Encryption::DEFAULT_KEYLENGTH; // The purpose of this function Mash() is to take an arbitrary length input // string and *deterministicly* produce an arbitrary length output string such // that (1) it looks random, (2) no information about the input is // deducible from it, and (3) it contains as much entropy as it can hold, or // the amount of entropy in the input string, whichever is smaller. static void Mash(const byte *in, size_t inLen, byte *out, size_t outLen, int iterations) { if (BytePrecision(outLen) > 2) throw InvalidArgument("Mash: output legnth too large"); size_t bufSize = RoundUpToMultipleOf(outLen, (size_t)DefaultHashModule::DIGESTSIZE); byte b[2]; SecByteBlock buf(bufSize); SecByteBlock outBuf(bufSize); DefaultHashModule hash; unsigned int i; for(i=0; i> 8); b[1] = (byte) i; hash.Update(b, 2); hash.Update(in, inLen); hash.Final(outBuf+i); } while (iterations-- > 1) { memcpy(buf, outBuf, bufSize); for (i=0; i> 8); b[1] = (byte) i; hash.Update(b, 2); hash.Update(buf, bufSize); hash.Final(outBuf+i); } } memcpy(out, outBuf, outLen); } static void GenerateKeyIV(const byte *passphrase, size_t passphraseLength, const byte *salt, size_t saltLength, byte *key, byte *IV) { SecByteBlock temp(passphraseLength+saltLength); memcpy(temp, passphrase, passphraseLength); memcpy(temp+passphraseLength, salt, saltLength); SecByteBlock keyIV(KEYLENGTH+BLOCKSIZE); Mash(temp, passphraseLength + saltLength, keyIV, KEYLENGTH+BLOCKSIZE, MASH_ITERATIONS); memcpy(key, keyIV, KEYLENGTH); memcpy(IV, keyIV+KEYLENGTH, BLOCKSIZE); } // ******************************************************** DefaultEncryptor::DefaultEncryptor(const char *passphrase, BufferedTransformation *attachment) : ProxyFilter(NULL, 0, 0, attachment), m_passphrase((const byte *)passphrase, strlen(passphrase)) { } DefaultEncryptor::DefaultEncryptor(const byte *passphrase, size_t passphraseLength, BufferedTransformation *attachment) : ProxyFilter(NULL, 0, 0, attachment), m_passphrase(passphrase, passphraseLength) { } void DefaultEncryptor::FirstPut(const byte *) { // VC60 workaround: __LINE__ expansion bug CRYPTOPP_COMPILE_ASSERT_INSTANCE(SALTLENGTH <= DefaultHashModule::DIGESTSIZE, 1); CRYPTOPP_COMPILE_ASSERT_INSTANCE(BLOCKSIZE <= DefaultHashModule::DIGESTSIZE, 2); SecByteBlock salt(DefaultHashModule::DIGESTSIZE), keyCheck(DefaultHashModule::DIGESTSIZE); DefaultHashModule hash; // use hash(passphrase | time | clock) as salt hash.Update(m_passphrase, m_passphrase.size()); time_t t=time(0); hash.Update((byte *)&t, sizeof(t)); clock_t c=clock(); hash.Update((byte *)&c, sizeof(c)); hash.Final(salt); // use hash(passphrase | salt) as key check hash.Update(m_passphrase, m_passphrase.size()); hash.Update(salt, SALTLENGTH); hash.Final(keyCheck); AttachedTransformation()->Put(salt, SALTLENGTH); // mash passphrase and salt together into key and IV SecByteBlock key(KEYLENGTH); SecByteBlock IV(BLOCKSIZE); GenerateKeyIV(m_passphrase, m_passphrase.size(), salt, SALTLENGTH, key, IV); m_cipher.SetKeyWithIV(key, key.size(), IV); SetFilter(new StreamTransformationFilter(m_cipher)); m_filter->Put(keyCheck, BLOCKSIZE); } void DefaultEncryptor::LastPut(const byte *inString, size_t length) { m_filter->MessageEnd(); } // ******************************************************** DefaultDecryptor::DefaultDecryptor(const char *p, BufferedTransformation *attachment, bool throwException) : ProxyFilter(NULL, SALTLENGTH+BLOCKSIZE, 0, attachment) , m_state(WAITING_FOR_KEYCHECK) , m_passphrase((const byte *)p, strlen(p)) , m_throwException(throwException) { } DefaultDecryptor::DefaultDecryptor(const byte *passphrase, size_t passphraseLength, BufferedTransformation *attachment, bool throwException) : ProxyFilter(NULL, SALTLENGTH+BLOCKSIZE, 0, attachment) , m_state(WAITING_FOR_KEYCHECK) , m_passphrase(passphrase, passphraseLength) , m_throwException(throwException) { } void DefaultDecryptor::FirstPut(const byte *inString) { CheckKey(inString, inString+SALTLENGTH); } void DefaultDecryptor::LastPut(const byte *inString, size_t length) { if (m_filter.get() == NULL) { m_state = KEY_BAD; if (m_throwException) throw KeyBadErr(); } else { m_filter->MessageEnd(); m_state = WAITING_FOR_KEYCHECK; } } void DefaultDecryptor::CheckKey(const byte *salt, const byte *keyCheck) { SecByteBlock check(STDMAX((unsigned int)2*BLOCKSIZE, (unsigned int)DefaultHashModule::DIGESTSIZE)); DefaultHashModule hash; hash.Update(m_passphrase, m_passphrase.size()); hash.Update(salt, SALTLENGTH); hash.Final(check); SecByteBlock key(KEYLENGTH); SecByteBlock IV(BLOCKSIZE); GenerateKeyIV(m_passphrase, m_passphrase.size(), salt, SALTLENGTH, key, IV); m_cipher.SetKeyWithIV(key, key.size(), IV); std::auto_ptr decryptor(new StreamTransformationFilter(m_cipher)); decryptor->Put(keyCheck, BLOCKSIZE); decryptor->ForceNextPut(); decryptor->Get(check+BLOCKSIZE, BLOCKSIZE); SetFilter(decryptor.release()); if (!VerifyBufsEqual(check, check+BLOCKSIZE, BLOCKSIZE)) { m_state = KEY_BAD; if (m_throwException) throw KeyBadErr(); } else m_state = KEY_GOOD; } // ******************************************************** static DefaultMAC * NewDefaultEncryptorMAC(const byte *passphrase, size_t passphraseLength) { size_t macKeyLength = DefaultMAC::StaticGetValidKeyLength(16); SecByteBlock macKey(macKeyLength); // since the MAC is encrypted there is no reason to mash the passphrase for many iterations Mash(passphrase, passphraseLength, macKey, macKeyLength, 1); return new DefaultMAC(macKey, macKeyLength); } DefaultEncryptorWithMAC::DefaultEncryptorWithMAC(const char *passphrase, BufferedTransformation *attachment) : ProxyFilter(NULL, 0, 0, attachment) , m_mac(NewDefaultEncryptorMAC((const byte *)passphrase, strlen(passphrase))) { SetFilter(new HashFilter(*m_mac, new DefaultEncryptor(passphrase), true)); } DefaultEncryptorWithMAC::DefaultEncryptorWithMAC(const byte *passphrase, size_t passphraseLength, BufferedTransformation *attachment) : ProxyFilter(NULL, 0, 0, attachment) , m_mac(NewDefaultEncryptorMAC(passphrase, passphraseLength)) { SetFilter(new HashFilter(*m_mac, new DefaultEncryptor(passphrase, passphraseLength), true)); } void DefaultEncryptorWithMAC::LastPut(const byte *inString, size_t length) { m_filter->MessageEnd(); } // ******************************************************** DefaultDecryptorWithMAC::DefaultDecryptorWithMAC(const char *passphrase, BufferedTransformation *attachment, bool throwException) : ProxyFilter(NULL, 0, 0, attachment) , m_mac(NewDefaultEncryptorMAC((const byte *)passphrase, strlen(passphrase))) , m_throwException(throwException) { SetFilter(new DefaultDecryptor(passphrase, m_hashVerifier=new HashVerifier(*m_mac, NULL, HashVerifier::PUT_MESSAGE), throwException)); } DefaultDecryptorWithMAC::DefaultDecryptorWithMAC(const byte *passphrase, size_t passphraseLength, BufferedTransformation *attachment, bool throwException) : ProxyFilter(NULL, 0, 0, attachment) , m_mac(NewDefaultEncryptorMAC(passphrase, passphraseLength)) , m_throwException(throwException) { SetFilter(new DefaultDecryptor(passphrase, passphraseLength, m_hashVerifier=new HashVerifier(*m_mac, NULL, HashVerifier::PUT_MESSAGE), throwException)); } DefaultDecryptor::State DefaultDecryptorWithMAC::CurrentState() const { return static_cast(m_filter.get())->CurrentState(); } bool DefaultDecryptorWithMAC::CheckLastMAC() const { return m_hashVerifier->GetLastResult(); } void DefaultDecryptorWithMAC::LastPut(const byte *inString, size_t length) { m_filter->MessageEnd(); if (m_throwException && !CheckLastMAC()) throw MACBadErr(); } NAMESPACE_END