// strciphr.cpp - originally written and placed in the public domain by Wei Dai. #include "pch.h" #ifndef CRYPTOPP_IMPORTS #include "strciphr.h" // Squash MS LNK4221 and libtool warnings #ifndef CRYPTOPP_MANUALLY_INSTANTIATE_TEMPLATES extern const char STRCIPHER_FNAME[] = __FILE__; #endif NAMESPACE_BEGIN(CryptoPP) template void AdditiveCipherTemplate::UncheckedSetKey(const byte *key, unsigned int length, const NameValuePairs ¶ms) { PolicyInterface &policy = this->AccessPolicy(); policy.CipherSetKey(params, key, length); m_leftOver = 0; unsigned int bufferByteSize = policy.CanOperateKeystream() ? GetBufferByteSize(policy) : RoundUpToMultipleOf(1024U, GetBufferByteSize(policy)); m_buffer.New(bufferByteSize); if (this->IsResynchronizable()) { size_t ivLength; const byte *iv = this->GetIVAndThrowIfInvalid(params, ivLength); policy.CipherResynchronize(m_buffer, iv, ivLength); } } template void AdditiveCipherTemplate::GenerateBlock(byte *outString, size_t length) { if (m_leftOver > 0) { const size_t len = STDMIN(m_leftOver, length); std::memcpy(outString, PtrSub(KeystreamBufferEnd(), m_leftOver), len); length -= len; m_leftOver -= len; outString = PtrAdd(outString, len); if (!length) {return;} } PolicyInterface &policy = this->AccessPolicy(); size_t bytesPerIteration = policy.GetBytesPerIteration(); if (length >= bytesPerIteration) { const size_t iterations = length / bytesPerIteration; policy.WriteKeystream(outString, iterations); length -= iterations * bytesPerIteration; outString = PtrAdd(outString, iterations * bytesPerIteration); } if (length > 0) { size_t bufferByteSize = RoundUpToMultipleOf(length, bytesPerIteration); size_t bufferIterations = bufferByteSize / bytesPerIteration; policy.WriteKeystream(PtrSub(KeystreamBufferEnd(), bufferByteSize), bufferIterations); std::memcpy(outString, PtrSub(KeystreamBufferEnd(), bufferByteSize), length); m_leftOver = bufferByteSize - length; } } template void AdditiveCipherTemplate::ProcessData(byte *outString, const byte *inString, size_t length) { CRYPTOPP_ASSERT(outString); CRYPTOPP_ASSERT(inString); CRYPTOPP_ASSERT(length % this->MandatoryBlockSize() == 0); PolicyInterface &policy = this->AccessPolicy(); size_t bytesPerIteration = policy.GetBytesPerIteration(); if (m_leftOver > 0) { const size_t len = STDMIN(m_leftOver, length); xorbuf(outString, inString, PtrSub(KeystreamBufferEnd(), m_leftOver), len); inString = PtrAdd(inString, len); outString = PtrAdd(outString, len); length -= len; m_leftOver -= len; } if (!length) { return; } const word32 alignment = policy.GetAlignment(); const bool inAligned = IsAlignedOn(inString, alignment); const bool outAligned = IsAlignedOn(outString, alignment); CRYPTOPP_UNUSED(inAligned); CRYPTOPP_UNUSED(outAligned); if (policy.CanOperateKeystream() && length >= bytesPerIteration) { const size_t iterations = length / bytesPerIteration; KeystreamOperationFlags flags = static_cast( (inAligned ? EnumToInt(INPUT_ALIGNED) : 0) | (outAligned ? EnumToInt(OUTPUT_ALIGNED) : 0)); KeystreamOperation operation = KeystreamOperation(flags); policy.OperateKeystream(operation, outString, inString, iterations); inString = PtrAdd(inString, iterations * bytesPerIteration); outString = PtrAdd(outString, iterations * bytesPerIteration); length -= iterations * bytesPerIteration; } size_t bufferByteSize = m_buffer.size(); size_t bufferIterations = bufferByteSize / bytesPerIteration; while (length >= bufferByteSize) { policy.WriteKeystream(m_buffer, bufferIterations); xorbuf(outString, inString, KeystreamBufferBegin(), bufferByteSize); inString = PtrAdd(inString, bufferByteSize); outString = PtrAdd(outString, bufferByteSize); length -= bufferByteSize; } if (length > 0) { bufferByteSize = RoundUpToMultipleOf(length, bytesPerIteration); bufferIterations = bufferByteSize / bytesPerIteration; policy.WriteKeystream(PtrSub(KeystreamBufferEnd(), bufferByteSize), bufferIterations); xorbuf(outString, inString, PtrSub(KeystreamBufferEnd(), bufferByteSize), length); m_leftOver = bufferByteSize - length; } } template void AdditiveCipherTemplate::Resynchronize(const byte *iv, int length) { PolicyInterface &policy = this->AccessPolicy(); m_leftOver = 0; m_buffer.New(GetBufferByteSize(policy)); policy.CipherResynchronize(m_buffer, iv, this->ThrowIfInvalidIVLength(length)); } template void AdditiveCipherTemplate::Seek(lword position) { PolicyInterface &policy = this->AccessPolicy(); unsigned int bytesPerIteration = policy.GetBytesPerIteration(); policy.SeekToIteration(position / bytesPerIteration); position %= bytesPerIteration; if (position > 0) { policy.WriteKeystream(PtrSub(KeystreamBufferEnd(), bytesPerIteration), 1); m_leftOver = bytesPerIteration - static_cast(position); } else m_leftOver = 0; } template void CFB_CipherTemplate::UncheckedSetKey(const byte *key, unsigned int length, const NameValuePairs ¶ms) { PolicyInterface &policy = this->AccessPolicy(); policy.CipherSetKey(params, key, length); if (this->IsResynchronizable()) { size_t ivLength; const byte *iv = this->GetIVAndThrowIfInvalid(params, ivLength); policy.CipherResynchronize(iv, ivLength); } m_leftOver = policy.GetBytesPerIteration(); } template void CFB_CipherTemplate::Resynchronize(const byte *iv, int length) { PolicyInterface &policy = this->AccessPolicy(); policy.CipherResynchronize(iv, this->ThrowIfInvalidIVLength(length)); m_leftOver = policy.GetBytesPerIteration(); } template void CFB_CipherTemplate::ProcessData(byte *outString, const byte *inString, size_t length) { CRYPTOPP_ASSERT(outString); CRYPTOPP_ASSERT(inString); CRYPTOPP_ASSERT(length % this->MandatoryBlockSize() == 0); PolicyInterface &policy = this->AccessPolicy(); unsigned int bytesPerIteration = policy.GetBytesPerIteration(); byte *reg = policy.GetRegisterBegin(); if (m_leftOver) { const size_t len = STDMIN(m_leftOver, length); CombineMessageAndShiftRegister(outString, PtrAdd(reg, bytesPerIteration - m_leftOver), inString, len); inString = PtrAdd(inString, len); outString = PtrAdd(outString, len); m_leftOver -= len; length -= len; } if (!length) { return; } const word32 alignment = policy.GetAlignment(); const bool inAligned = IsAlignedOn(inString, alignment); const bool outAligned = IsAlignedOn(outString, alignment); CRYPTOPP_UNUSED(inAligned); CRYPTOPP_UNUSED(outAligned); if (policy.CanIterate() && length >= bytesPerIteration && outAligned) { CipherDir cipherDir = GetCipherDir(*this); policy.Iterate(outString, inString, cipherDir, length / bytesPerIteration); const size_t remainder = length % bytesPerIteration; inString = PtrAdd(inString, length - remainder); outString = PtrAdd(outString, length - remainder); length = remainder; } while (length >= bytesPerIteration) { policy.TransformRegister(); CombineMessageAndShiftRegister(outString, reg, inString, bytesPerIteration); inString = PtrAdd(inString, bytesPerIteration); outString = PtrAdd(outString, bytesPerIteration); length -= bytesPerIteration; } if (length > 0) { policy.TransformRegister(); CombineMessageAndShiftRegister(outString, reg, inString, length); m_leftOver = bytesPerIteration - length; } } template void CFB_EncryptionTemplate::CombineMessageAndShiftRegister(byte *output, byte *reg, const byte *message, size_t length) { xorbuf(reg, message, length); std::memcpy(output, reg, length); } template void CFB_DecryptionTemplate::CombineMessageAndShiftRegister(byte *output, byte *reg, const byte *message, size_t length) { for (size_t i=0; i