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9013cb60fb
So it looks like sed added a '\r' between the closing paren and the semi. Grepping for '^;' failed because the '\r' was considered part of the previous line, so it showed no hits. I finally had to write a C program to properly identify and fix those damn stray semicolons.
725 lines
32 KiB
C++
725 lines
32 KiB
C++
// strciphr.h - originally written and placed in the public domain by Wei Dai
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/// \file strciphr.h
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/// \brief Classes for implementing stream ciphers
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/// \details This file contains helper classes for implementing stream ciphers.
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/// All this infrastructure may look very complex compared to what's in Crypto++ 4.x,
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/// but stream ciphers implementations now support a lot of new functionality,
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/// including better performance (minimizing copying), resetting of keys and IVs, and
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/// methods to query which features are supported by a cipher.
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/// \details Here's an explanation of these classes. The word "policy" is used here to
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/// mean a class with a set of methods that must be implemented by individual stream
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/// cipher implementations. This is usually much simpler than the full stream cipher
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/// API, which is implemented by either AdditiveCipherTemplate or CFB_CipherTemplate
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/// using the policy. So for example, an implementation of SEAL only needs to implement
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/// the AdditiveCipherAbstractPolicy interface (since it's an additive cipher, i.e., it
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/// xors a keystream into the plaintext). See this line in seal.h:
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/// <pre>
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/// typedef SymmetricCipherFinal\<ConcretePolicyHolder\<SEAL_Policy\<B\>, AdditiveCipherTemplate\<\> \> \> Encryption;
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/// </pre>
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/// \details AdditiveCipherTemplate and CFB_CipherTemplate are designed so that they don't
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/// need to take a policy class as a template parameter (although this is allowed), so
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/// that their code is not duplicated for each new cipher. Instead they each get a
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/// reference to an abstract policy interface by calling AccessPolicy() on itself, so
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/// AccessPolicy() must be overridden to return the actual policy reference. This is done
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/// by the ConceretePolicyHolder class. Finally, SymmetricCipherFinal implements the
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/// constructors and other functions that must be implemented by the most derived class.
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#ifndef CRYPTOPP_STRCIPHR_H
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#define CRYPTOPP_STRCIPHR_H
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#include "config.h"
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#if CRYPTOPP_MSC_VERSION
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# pragma warning(push)
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# pragma warning(disable: 4127 4189 4231 4275)
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#endif
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#include "cryptlib.h"
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#include "seckey.h"
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#include "secblock.h"
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#include "argnames.h"
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NAMESPACE_BEGIN(CryptoPP)
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/// \brief Access a stream cipher policy object
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/// \tparam POLICY_INTERFACE class implementing AbstractPolicyHolder
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/// \tparam BASE class or type to use as a base class
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template <class POLICY_INTERFACE, class BASE = Empty>
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class CRYPTOPP_NO_VTABLE AbstractPolicyHolder : public BASE
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{
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public:
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typedef POLICY_INTERFACE PolicyInterface;
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virtual ~AbstractPolicyHolder() {}
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protected:
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virtual const POLICY_INTERFACE & GetPolicy() const =0;
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virtual POLICY_INTERFACE & AccessPolicy() =0;
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};
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/// \brief Stream cipher policy object
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/// \tparam POLICY class implementing AbstractPolicyHolder
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/// \tparam BASE class or type to use as a base class
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template <class POLICY, class BASE, class POLICY_INTERFACE = typename BASE::PolicyInterface>
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class ConcretePolicyHolder : public BASE, protected POLICY
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{
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public:
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virtual ~ConcretePolicyHolder() {}
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protected:
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const POLICY_INTERFACE & GetPolicy() const {return *this;}
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POLICY_INTERFACE & AccessPolicy() {return *this;}
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};
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/// \brief Keystream operation flags
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/// \sa AdditiveCipherAbstractPolicy::GetBytesPerIteration(), AdditiveCipherAbstractPolicy::GetOptimalBlockSize()
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/// and AdditiveCipherAbstractPolicy::GetAlignment()
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enum KeystreamOperationFlags {
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/// \brief Output buffer is aligned
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OUTPUT_ALIGNED=1,
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/// \brief Input buffer is aligned
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INPUT_ALIGNED=2,
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/// \brief Input buffer is NULL
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INPUT_NULL = 4
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};
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/// \brief Keystream operation flags
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/// \sa AdditiveCipherAbstractPolicy::GetBytesPerIteration(), AdditiveCipherAbstractPolicy::GetOptimalBlockSize()
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/// and AdditiveCipherAbstractPolicy::GetAlignment()
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enum KeystreamOperation {
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/// \brief Wirte the keystream to the output buffer, input is NULL
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WRITE_KEYSTREAM = INPUT_NULL,
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/// \brief Wirte the keystream to the aligned output buffer, input is NULL
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WRITE_KEYSTREAM_ALIGNED = INPUT_NULL | OUTPUT_ALIGNED,
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/// \brief XOR the input buffer and keystream, write to the output buffer
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XOR_KEYSTREAM = 0,
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/// \brief XOR the aligned input buffer and keystream, write to the output buffer
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XOR_KEYSTREAM_INPUT_ALIGNED = INPUT_ALIGNED,
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/// \brief XOR the input buffer and keystream, write to the aligned output buffer
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XOR_KEYSTREAM_OUTPUT_ALIGNED= OUTPUT_ALIGNED,
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/// \brief XOR the aligned input buffer and keystream, write to the aligned output buffer
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XOR_KEYSTREAM_BOTH_ALIGNED = OUTPUT_ALIGNED | INPUT_ALIGNED
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};
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/// \brief Policy object for additive stream ciphers
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struct CRYPTOPP_DLL CRYPTOPP_NO_VTABLE AdditiveCipherAbstractPolicy
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{
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virtual ~AdditiveCipherAbstractPolicy() {}
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/// \brief Provides data alignment requirements
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/// \returns data alignment requirements, in bytes
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/// \details Internally, the default implementation returns 1. If the stream cipher is implemented
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/// using an SSE2 ASM or intrinsics, then the value returned is usually 16.
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virtual unsigned int GetAlignment() const {return 1;}
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/// \brief Provides number of bytes operated upon during an iteration
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/// \returns bytes operated upon during an iteration, in bytes
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/// \sa GetOptimalBlockSize()
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virtual unsigned int GetBytesPerIteration() const =0;
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/// \brief Provides number of ideal bytes to process
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/// \returns the ideal number of bytes to process
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/// \details Internally, the default implementation returns GetBytesPerIteration()
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/// \sa GetBytesPerIteration()
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virtual unsigned int GetOptimalBlockSize() const {return GetBytesPerIteration();}
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/// \brief Provides buffer size based on iterations
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/// \returns the buffer size based on iterations, in bytes
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virtual unsigned int GetIterationsToBuffer() const =0;
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/// \brief Generate the keystream
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/// \param keystream the key stream
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/// \param iterationCount the number of iterations to generate the key stream
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/// \sa CanOperateKeystream(), OperateKeystream(), WriteKeystream()
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virtual void WriteKeystream(byte *keystream, size_t iterationCount)
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{OperateKeystream(KeystreamOperation(INPUT_NULL | static_cast<KeystreamOperationFlags>(IsAlignedOn(keystream, GetAlignment()))), keystream, NULLPTR, iterationCount);}
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/// \brief Flag indicating
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/// \returns true if the stream can be generated independent of the transformation input, false otherwise
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/// \sa CanOperateKeystream(), OperateKeystream(), WriteKeystream()
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virtual bool CanOperateKeystream() const {return false;}
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/// \brief Operates the keystream
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/// \param operation the operation with additional flags
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/// \param output the output buffer
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/// \param input the input buffer
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/// \param iterationCount the number of iterations to perform on the input
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/// \details OperateKeystream() will attempt to operate upon GetOptimalBlockSize() buffer,
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/// which will be derived from GetBytesPerIteration().
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/// \sa CanOperateKeystream(), OperateKeystream(), WriteKeystream(), KeystreamOperation()
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virtual void OperateKeystream(KeystreamOperation operation, byte *output, const byte *input, size_t iterationCount)
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{CRYPTOPP_UNUSED(operation); CRYPTOPP_UNUSED(output); CRYPTOPP_UNUSED(input);
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CRYPTOPP_UNUSED(iterationCount); CRYPTOPP_ASSERT(false);}
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/// \brief Key the cipher
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/// \param params set of NameValuePairs use to initialize this object
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/// \param key a byte array used to key the cipher
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/// \param length the size of the key array
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virtual void CipherSetKey(const NameValuePairs ¶ms, const byte *key, size_t length) =0;
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/// \brief Resynchronize the cipher
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/// \param keystreamBuffer the keystream buffer
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/// \param iv a byte array used to resynchronize the cipher
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/// \param length the size of the IV array
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virtual void CipherResynchronize(byte *keystreamBuffer, const byte *iv, size_t length)
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{CRYPTOPP_UNUSED(keystreamBuffer); CRYPTOPP_UNUSED(iv); CRYPTOPP_UNUSED(length);
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throw NotImplemented("SimpleKeyingInterface: this object doesn't support resynchronization");}
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/// \brief Flag indicating random access
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/// \returns true if the cipher is seekable, false otherwise
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/// \sa SeekToIteration()
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virtual bool CipherIsRandomAccess() const =0;
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/// \brief Seeks to a random position in the stream
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/// \sa CipherIsRandomAccess()
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virtual void SeekToIteration(lword iterationCount)
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{CRYPTOPP_UNUSED(iterationCount); CRYPTOPP_ASSERT(!CipherIsRandomAccess());
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throw NotImplemented("StreamTransformation: this object doesn't support random access");}
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/// \brief Retrieve the provider of this algorithm
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/// \return the algorithm provider
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/// \details The algorithm provider can be a name like "C++", "SSE", "NEON", "AESNI",
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/// "ARMv8" and "Power8". C++ is standard C++ code. Other labels, like SSE,
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/// usually indicate a specialized implementation using instructions from a higher
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/// instruction set architecture (ISA). Future labels may include external hardware
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/// like a hardware security module (HSM).
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/// \details Generally speaking Wei Dai's original IA-32 ASM code falls under "SSE2".
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/// Labels like "SSSE3" and "SSE4.1" follow after Wei's code and use intrinsics
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/// instead of ASM.
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/// \details Algorithms which combine different instructions or ISAs provide the
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/// dominant one. For example on x86 <tt>AES/GCM</tt> returns "AESNI" rather than
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/// "CLMUL" or "AES+SSE4.1" or "AES+CLMUL" or "AES+SSE4.1+CLMUL".
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/// \note Provider is not universally implemented yet.
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virtual std::string AlgorithmProvider() const { return "C++"; }
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};
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/// \brief Base class for additive stream ciphers
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/// \tparam WT word type
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/// \tparam W count of words
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/// \tparam X bytes per iteration count
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/// \tparam BASE AdditiveCipherAbstractPolicy derived base class
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template <typename WT, unsigned int W, unsigned int X = 1, class BASE = AdditiveCipherAbstractPolicy>
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struct CRYPTOPP_NO_VTABLE AdditiveCipherConcretePolicy : public BASE
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{
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/// \brief Word type for the cipher
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typedef WT WordType;
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/// \brief Number of bytes for an iteration
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/// \details BYTES_PER_ITERATION is the product <tt>sizeof(WordType) * W</tt>.
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/// For example, ChaCha uses 16 each <tt>word32</tt>, and the value of
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/// BYTES_PER_ITERATION is 64. Each invocation of the ChaCha block function
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/// produces 64 bytes of keystream.
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CRYPTOPP_CONSTANT(BYTES_PER_ITERATION = sizeof(WordType) * W);
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virtual ~AdditiveCipherConcretePolicy() {}
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#if !(CRYPTOPP_BOOL_X86 || CRYPTOPP_BOOL_X64)
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/// \brief Provides data alignment requirements
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/// \returns data alignment requirements, in bytes
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/// \details Internally, the default implementation returns 1. If the stream
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/// cipher is implemented using an SSE2 ASM or intrinsics, then the value
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/// returned is usually 16.
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unsigned int GetAlignment() const {return GetAlignmentOf<WordType>();}
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#endif
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/// \brief Provides number of bytes operated upon during an iteration
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/// \returns bytes operated upon during an iteration, in bytes
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/// \sa GetOptimalBlockSize()
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unsigned int GetBytesPerIteration() const {return BYTES_PER_ITERATION;}
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/// \brief Provides buffer size based on iterations
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/// \returns the buffer size based on iterations, in bytes
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unsigned int GetIterationsToBuffer() const {return X;}
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/// \brief Flag indicating
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/// \returns true if the stream can be generated independent of the
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/// transformation input, false otherwise
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/// \sa CanOperateKeystream(), OperateKeystream(), WriteKeystream()
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bool CanOperateKeystream() const {return true;}
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/// \brief Operates the keystream
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/// \param operation the operation with additional flags
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/// \param output the output buffer
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/// \param input the input buffer
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/// \param iterationCount the number of iterations to perform on the input
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/// \details OperateKeystream() will attempt to operate upon GetOptimalBlockSize() buffer,
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/// which will be derived from GetBytesPerIteration().
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/// \sa CanOperateKeystream(), OperateKeystream(), WriteKeystream(), KeystreamOperation()
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virtual void OperateKeystream(KeystreamOperation operation, byte *output, const byte *input, size_t iterationCount) =0;
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};
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/// \brief Helper macro to implement OperateKeystream
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/// \param x KeystreamOperation mask
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/// \param b Endian order
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/// \param i index in output buffer
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/// \param a value to output
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#define CRYPTOPP_KEYSTREAM_OUTPUT_WORD(x, b, i, a) \
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PutWord(bool(x & OUTPUT_ALIGNED), b, output+i*sizeof(WordType), (x & INPUT_NULL) ? (a) : (a) ^ GetWord<WordType>(bool(x & INPUT_ALIGNED), b, input+i*sizeof(WordType)));
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/// \brief Helper macro to implement OperateKeystream
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/// \param x KeystreamOperation mask
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/// \param i index in output buffer
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/// \param a value to output
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#define CRYPTOPP_KEYSTREAM_OUTPUT_XMM(x, i, a) {\
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__m128i t = (x & INPUT_NULL) ? a : _mm_xor_si128(a, (x & INPUT_ALIGNED) ? _mm_load_si128((__m128i *)input+i) : _mm_loadu_si128((__m128i *)input+i));\
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if (x & OUTPUT_ALIGNED) _mm_store_si128((__m128i *)output+i, t);\
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else _mm_storeu_si128((__m128i *)output+i, t);}
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/// \brief Helper macro to implement OperateKeystream
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#define CRYPTOPP_KEYSTREAM_OUTPUT_SWITCH(x, y) \
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switch (operation) \
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{ \
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case WRITE_KEYSTREAM: \
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x(WRITE_KEYSTREAM) \
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break; \
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case XOR_KEYSTREAM: \
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x(XOR_KEYSTREAM) \
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input += y; \
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break; \
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case XOR_KEYSTREAM_INPUT_ALIGNED: \
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x(XOR_KEYSTREAM_INPUT_ALIGNED) \
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input += y; \
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break; \
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case XOR_KEYSTREAM_OUTPUT_ALIGNED: \
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x(XOR_KEYSTREAM_OUTPUT_ALIGNED) \
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input += y; \
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break; \
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case WRITE_KEYSTREAM_ALIGNED: \
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x(WRITE_KEYSTREAM_ALIGNED) \
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break; \
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case XOR_KEYSTREAM_BOTH_ALIGNED: \
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x(XOR_KEYSTREAM_BOTH_ALIGNED) \
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input += y; \
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break; \
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} \
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output += y;
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/// \brief Base class for additive stream ciphers with SymmetricCipher interface
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/// \tparam BASE AbstractPolicyHolder base class
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template <class BASE = AbstractPolicyHolder<AdditiveCipherAbstractPolicy, SymmetricCipher> >
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class CRYPTOPP_NO_VTABLE AdditiveCipherTemplate : public BASE, public RandomNumberGenerator
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{
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public:
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virtual ~AdditiveCipherTemplate() {}
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AdditiveCipherTemplate() : m_leftOver(0) {}
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/// \brief Generate random array of bytes
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/// \param output the byte buffer
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/// \param size the length of the buffer, in bytes
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/// \details All generated values are uniformly distributed over the range specified
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/// within the constraints of a particular generator.
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void GenerateBlock(byte *output, size_t size);
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/// \brief Apply keystream to data
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/// \param outString a buffer to write the transformed data
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/// \param inString a buffer to read the data
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/// \param length the size fo the buffers, in bytes
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/// \details This is the primary method to operate a stream cipher. For example:
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/// <pre>
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/// size_t size = 30;
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/// byte plain[size] = "Do or do not; there is no try";
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/// byte cipher[size];
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/// ...
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/// ChaCha20 chacha(key, keySize);
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/// chacha.ProcessData(cipher, plain, size);
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/// </pre>
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void ProcessData(byte *outString, const byte *inString, size_t length);
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/// \brief Resynchronize the cipher
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/// \param iv a byte array used to resynchronize the cipher
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/// \param length the size of the IV array
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void Resynchronize(const byte *iv, int length=-1);
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/// \brief Provides number of ideal bytes to process
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/// \returns the ideal number of bytes to process
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/// \details Internally, the default implementation returns GetBytesPerIteration()
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/// \sa GetBytesPerIteration() and GetOptimalNextBlockSize()
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unsigned int OptimalBlockSize() const {return this->GetPolicy().GetOptimalBlockSize();}
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/// \brief Provides number of ideal bytes to process
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/// \returns the ideal number of bytes to process
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/// \details Internally, the default implementation returns remaining unprocessed bytes
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/// \sa GetBytesPerIteration() and OptimalBlockSize()
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unsigned int GetOptimalNextBlockSize() const {return (unsigned int)this->m_leftOver;}
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/// \brief Provides number of ideal data alignment
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/// \returns the ideal data alignment, in bytes
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/// \sa GetAlignment() and OptimalBlockSize()
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unsigned int OptimalDataAlignment() const {return this->GetPolicy().GetAlignment();}
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/// \brief Determines if the cipher is self inverting
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/// \returns true if the stream cipher is self inverting, false otherwise
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bool IsSelfInverting() const {return true;}
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/// \brief Determines if the cipher is a forward transformation
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/// \returns true if the stream cipher is a forward transformation, false otherwise
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bool IsForwardTransformation() const {return true;}
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/// \brief Flag indicating random access
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/// \returns true if the cipher is seekable, false otherwise
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/// \sa Seek()
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bool IsRandomAccess() const {return this->GetPolicy().CipherIsRandomAccess();}
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/// \brief Seeks to a random position in the stream
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/// \param position the absolute position in the stream
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/// \sa IsRandomAccess()
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void Seek(lword position);
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/// \brief Retrieve the provider of this algorithm
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/// \return the algorithm provider
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/// \details The algorithm provider can be a name like "C++", "SSE", "NEON", "AESNI",
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/// "ARMv8" and "Power8". C++ is standard C++ code. Other labels, like SSE,
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/// usually indicate a specialized implementation using instructions from a higher
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/// instruction set architecture (ISA). Future labels may include external hardware
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/// like a hardware security module (HSM).
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/// \details Generally speaking Wei Dai's original IA-32 ASM code falls under "SSE2".
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/// Labels like "SSSE3" and "SSE4.1" follow after Wei's code and use intrinsics
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/// instead of ASM.
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/// \details Algorithms which combine different instructions or ISAs provide the
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/// dominant one. For example on x86 <tt>AES/GCM</tt> returns "AESNI" rather than
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/// "CLMUL" or "AES+SSE4.1" or "AES+CLMUL" or "AES+SSE4.1+CLMUL".
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/// \note Provider is not universally implemented yet.
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std::string AlgorithmProvider() const { return this->GetPolicy().AlgorithmProvider(); }
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typedef typename BASE::PolicyInterface PolicyInterface;
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protected:
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void UncheckedSetKey(const byte *key, unsigned int length, const NameValuePairs ¶ms);
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unsigned int GetBufferByteSize(const PolicyInterface &policy) const {return policy.GetBytesPerIteration() * policy.GetIterationsToBuffer();}
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inline byte * KeystreamBufferBegin() {return this->m_buffer.data();}
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inline byte * KeystreamBufferEnd() {return (PtrAdd(this->m_buffer.data(), this->m_buffer.size()));}
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AlignedSecByteBlock m_buffer;
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size_t m_leftOver;
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};
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/// \brief Policy object for feeback based stream ciphers
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class CRYPTOPP_DLL CRYPTOPP_NO_VTABLE CFB_CipherAbstractPolicy
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{
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public:
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virtual ~CFB_CipherAbstractPolicy() {}
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/// \brief Provides data alignment requirements
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/// \returns data alignment requirements, in bytes
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/// \details Internally, the default implementation returns 1. If the stream cipher is implemented
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/// using an SSE2 ASM or intrinsics, then the value returned is usually 16.
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virtual unsigned int GetAlignment() const =0;
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/// \brief Provides number of bytes operated upon during an iteration
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/// \returns bytes operated upon during an iteration, in bytes
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/// \sa GetOptimalBlockSize()
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virtual unsigned int GetBytesPerIteration() const =0;
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/// \brief Access the feedback register
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/// \returns pointer to the first byte of the feedback register
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virtual byte * GetRegisterBegin() =0;
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/// \brief TODO
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virtual void TransformRegister() =0;
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/// \brief Flag indicating iteration support
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/// \returns true if the cipher supports iteration, false otherwise
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virtual bool CanIterate() const {return false;}
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/// \brief Iterate the cipher
|
|
/// \param output the output buffer
|
|
/// \param input the input buffer
|
|
/// \param dir the direction of the cipher
|
|
/// \param iterationCount the number of iterations to perform on the input
|
|
/// \sa IsSelfInverting() and IsForwardTransformation()
|
|
virtual void Iterate(byte *output, const byte *input, CipherDir dir, size_t iterationCount)
|
|
{CRYPTOPP_UNUSED(output); CRYPTOPP_UNUSED(input); CRYPTOPP_UNUSED(dir);
|
|
CRYPTOPP_UNUSED(iterationCount); CRYPTOPP_ASSERT(false);
|
|
throw Exception(Exception::OTHER_ERROR, "SimpleKeyingInterface: unexpected error");}
|
|
|
|
/// \brief Key the cipher
|
|
/// \param params set of NameValuePairs use to initialize this object
|
|
/// \param key a byte array used to key the cipher
|
|
/// \param length the size of the key array
|
|
virtual void CipherSetKey(const NameValuePairs ¶ms, const byte *key, size_t length) =0;
|
|
|
|
/// \brief Resynchronize the cipher
|
|
/// \param iv a byte array used to resynchronize the cipher
|
|
/// \param length the size of the IV array
|
|
virtual void CipherResynchronize(const byte *iv, size_t length)
|
|
{CRYPTOPP_UNUSED(iv); CRYPTOPP_UNUSED(length);
|
|
throw NotImplemented("SimpleKeyingInterface: this object doesn't support resynchronization");}
|
|
|
|
/// \brief Retrieve the provider of this algorithm
|
|
/// \return the algorithm provider
|
|
/// \details The algorithm provider can be a name like "C++", "SSE", "NEON", "AESNI",
|
|
/// "ARMv8" and "Power8". C++ is standard C++ code. Other labels, like SSE,
|
|
/// usually indicate a specialized implementation using instructions from a higher
|
|
/// instruction set architecture (ISA). Future labels may include external hardware
|
|
/// like a hardware security module (HSM).
|
|
/// \details Generally speaking Wei Dai's original IA-32 ASM code falls under "SSE2".
|
|
/// Labels like "SSSE3" and "SSE4.1" follow after Wei's code and use intrinsics
|
|
/// instead of ASM.
|
|
/// \details Algorithms which combine different instructions or ISAs provide the
|
|
/// dominant one. For example on x86 <tt>AES/GCM</tt> returns "AESNI" rather than
|
|
/// "CLMUL" or "AES+SSE4.1" or "AES+CLMUL" or "AES+SSE4.1+CLMUL".
|
|
/// \note Provider is not universally implemented yet.
|
|
virtual std::string AlgorithmProvider() const { return "C++"; }
|
|
};
|
|
|
|
/// \brief Base class for feedback based stream ciphers
|
|
/// \tparam WT word type
|
|
/// \tparam W count of words
|
|
/// \tparam BASE CFB_CipherAbstractPolicy derived base class
|
|
template <typename WT, unsigned int W, class BASE = CFB_CipherAbstractPolicy>
|
|
struct CRYPTOPP_NO_VTABLE CFB_CipherConcretePolicy : public BASE
|
|
{
|
|
typedef WT WordType;
|
|
|
|
virtual ~CFB_CipherConcretePolicy() {}
|
|
|
|
/// \brief Provides data alignment requirements
|
|
/// \returns data alignment requirements, in bytes
|
|
/// \details Internally, the default implementation returns 1. If the stream cipher is implemented
|
|
/// using an SSE2 ASM or intrinsics, then the value returned is usually 16.
|
|
unsigned int GetAlignment() const {return sizeof(WordType);}
|
|
|
|
/// \brief Provides number of bytes operated upon during an iteration
|
|
/// \returns bytes operated upon during an iteration, in bytes
|
|
/// \sa GetOptimalBlockSize()
|
|
unsigned int GetBytesPerIteration() const {return sizeof(WordType) * W;}
|
|
|
|
/// \brief Flag indicating iteration support
|
|
/// \returns true if the cipher supports iteration, false otherwise
|
|
bool CanIterate() const {return true;}
|
|
|
|
/// \brief Perform one iteration in the forward direction
|
|
void TransformRegister() {this->Iterate(NULLPTR, NULLPTR, ENCRYPTION, 1);}
|
|
|
|
/// \brief Provides alternate access to a feedback register
|
|
/// \tparam B enumeration indicating endianness
|
|
/// \details RegisterOutput() provides alternate access to the feedback register. The
|
|
/// enumeration B is BigEndian or LittleEndian. Repeatedly applying operator()
|
|
/// results in advancing in the register.
|
|
template <class B>
|
|
struct RegisterOutput
|
|
{
|
|
RegisterOutput(byte *output, const byte *input, CipherDir dir)
|
|
: m_output(output), m_input(input), m_dir(dir) {}
|
|
|
|
/// \brief XOR feedback register with data
|
|
/// \param registerWord data represented as a word type
|
|
/// \returns reference to the next feedback register word
|
|
inline RegisterOutput& operator()(WordType ®isterWord)
|
|
{
|
|
//CRYPTOPP_ASSERT(IsAligned<WordType>(m_output));
|
|
//CRYPTOPP_ASSERT(IsAligned<WordType>(m_input));
|
|
|
|
if (!NativeByteOrderIs(B::ToEnum()))
|
|
registerWord = ByteReverse(registerWord);
|
|
|
|
if (m_dir == ENCRYPTION)
|
|
{
|
|
if (m_input == NULLPTR)
|
|
{
|
|
CRYPTOPP_ASSERT(m_output == NULLPTR);
|
|
}
|
|
else
|
|
{
|
|
// WordType ct = *(const WordType *)m_input ^ registerWord;
|
|
WordType ct = GetWord<WordType>(false, NativeByteOrder::ToEnum(), m_input) ^ registerWord;
|
|
registerWord = ct;
|
|
|
|
// *(WordType*)m_output = ct;
|
|
PutWord<WordType>(false, NativeByteOrder::ToEnum(), m_output, ct);
|
|
|
|
m_input += sizeof(WordType);
|
|
m_output += sizeof(WordType);
|
|
}
|
|
}
|
|
else
|
|
{
|
|
// WordType ct = *(const WordType *)m_input;
|
|
WordType ct = GetWord<WordType>(false, NativeByteOrder::ToEnum(), m_input);
|
|
|
|
// *(WordType*)m_output = registerWord ^ ct;
|
|
PutWord<WordType>(false, NativeByteOrder::ToEnum(), m_output, registerWord ^ ct);
|
|
registerWord = ct;
|
|
|
|
m_input += sizeof(WordType);
|
|
m_output += sizeof(WordType);
|
|
}
|
|
|
|
// registerWord is left unreversed so it can be xor-ed with further input
|
|
|
|
return *this;
|
|
}
|
|
|
|
byte *m_output;
|
|
const byte *m_input;
|
|
CipherDir m_dir;
|
|
};
|
|
};
|
|
|
|
/// \brief Base class for feedback based stream ciphers with SymmetricCipher interface
|
|
/// \tparam BASE AbstractPolicyHolder base class
|
|
template <class BASE>
|
|
class CRYPTOPP_NO_VTABLE CFB_CipherTemplate : public BASE
|
|
{
|
|
public:
|
|
virtual ~CFB_CipherTemplate() {}
|
|
CFB_CipherTemplate() : m_leftOver(0) {}
|
|
|
|
/// \brief Apply keystream to data
|
|
/// \param outString a buffer to write the transformed data
|
|
/// \param inString a buffer to read the data
|
|
/// \param length the size fo the buffers, in bytes
|
|
/// \details This is the primary method to operate a stream cipher. For example:
|
|
/// <pre>
|
|
/// size_t size = 30;
|
|
/// byte plain[size] = "Do or do not; there is no try";
|
|
/// byte cipher[size];
|
|
/// ...
|
|
/// ChaCha20 chacha(key, keySize);
|
|
/// chacha.ProcessData(cipher, plain, size);
|
|
/// </pre>
|
|
void ProcessData(byte *outString, const byte *inString, size_t length);
|
|
|
|
/// \brief Resynchronize the cipher
|
|
/// \param iv a byte array used to resynchronize the cipher
|
|
/// \param length the size of the IV array
|
|
void Resynchronize(const byte *iv, int length=-1);
|
|
|
|
/// \brief Provides number of ideal bytes to process
|
|
/// \returns the ideal number of bytes to process
|
|
/// \details Internally, the default implementation returns GetBytesPerIteration()
|
|
/// \sa GetBytesPerIteration() and GetOptimalNextBlockSize()
|
|
unsigned int OptimalBlockSize() const {return this->GetPolicy().GetBytesPerIteration();}
|
|
|
|
/// \brief Provides number of ideal bytes to process
|
|
/// \returns the ideal number of bytes to process
|
|
/// \details Internally, the default implementation returns remaining unprocessed bytes
|
|
/// \sa GetBytesPerIteration() and OptimalBlockSize()
|
|
unsigned int GetOptimalNextBlockSize() const {return (unsigned int)m_leftOver;}
|
|
|
|
/// \brief Provides number of ideal data alignment
|
|
/// \returns the ideal data alignment, in bytes
|
|
/// \sa GetAlignment() and OptimalBlockSize()
|
|
unsigned int OptimalDataAlignment() const {return this->GetPolicy().GetAlignment();}
|
|
|
|
/// \brief Flag indicating random access
|
|
/// \returns true if the cipher is seekable, false otherwise
|
|
/// \sa Seek()
|
|
bool IsRandomAccess() const {return false;}
|
|
|
|
/// \brief Determines if the cipher is self inverting
|
|
/// \returns true if the stream cipher is self inverting, false otherwise
|
|
bool IsSelfInverting() const {return false;}
|
|
|
|
/// \brief Retrieve the provider of this algorithm
|
|
/// \return the algorithm provider
|
|
/// \details The algorithm provider can be a name like "C++", "SSE", "NEON", "AESNI",
|
|
/// "ARMv8" and "Power8". C++ is standard C++ code. Other labels, like SSE,
|
|
/// usually indicate a specialized implementation using instructions from a higher
|
|
/// instruction set architecture (ISA). Future labels may include external hardware
|
|
/// like a hardware security module (HSM).
|
|
/// \details Generally speaking Wei Dai's original IA-32 ASM code falls under "SSE2".
|
|
/// Labels like "SSSE3" and "SSE4.1" follow after Wei's code and use intrinsics
|
|
/// instead of ASM.
|
|
/// \details Algorithms which combine different instructions or ISAs provide the
|
|
/// dominant one. For example on x86 <tt>AES/GCM</tt> returns "AESNI" rather than
|
|
/// "CLMUL" or "AES+SSE4.1" or "AES+CLMUL" or "AES+SSE4.1+CLMUL".
|
|
/// \note Provider is not universally implemented yet.
|
|
std::string AlgorithmProvider() const { return this->GetPolicy().AlgorithmProvider(); }
|
|
|
|
typedef typename BASE::PolicyInterface PolicyInterface;
|
|
|
|
protected:
|
|
virtual void CombineMessageAndShiftRegister(byte *output, byte *reg, const byte *message, size_t length) =0;
|
|
|
|
void UncheckedSetKey(const byte *key, unsigned int length, const NameValuePairs ¶ms);
|
|
|
|
size_t m_leftOver;
|
|
};
|
|
|
|
/// \brief Base class for feedback based stream ciphers in the forward direction with SymmetricCipher interface
|
|
/// \tparam BASE AbstractPolicyHolder base class
|
|
template <class BASE = AbstractPolicyHolder<CFB_CipherAbstractPolicy, SymmetricCipher> >
|
|
class CRYPTOPP_NO_VTABLE CFB_EncryptionTemplate : public CFB_CipherTemplate<BASE>
|
|
{
|
|
bool IsForwardTransformation() const {return true;}
|
|
void CombineMessageAndShiftRegister(byte *output, byte *reg, const byte *message, size_t length);
|
|
};
|
|
|
|
/// \brief Base class for feedback based stream ciphers in the reverse direction with SymmetricCipher interface
|
|
/// \tparam BASE AbstractPolicyHolder base class
|
|
template <class BASE = AbstractPolicyHolder<CFB_CipherAbstractPolicy, SymmetricCipher> >
|
|
class CRYPTOPP_NO_VTABLE CFB_DecryptionTemplate : public CFB_CipherTemplate<BASE>
|
|
{
|
|
bool IsForwardTransformation() const {return false;}
|
|
void CombineMessageAndShiftRegister(byte *output, byte *reg, const byte *message, size_t length);
|
|
};
|
|
|
|
/// \brief Base class for feedback based stream ciphers with a mandatory block size
|
|
/// \tparam BASE CFB_EncryptionTemplate or CFB_DecryptionTemplate base class
|
|
template <class BASE>
|
|
class CFB_RequireFullDataBlocks : public BASE
|
|
{
|
|
public:
|
|
unsigned int MandatoryBlockSize() const {return this->OptimalBlockSize();}
|
|
};
|
|
|
|
/// \brief SymmetricCipher implementation
|
|
/// \tparam BASE AbstractPolicyHolder derived base class
|
|
/// \tparam INFO AbstractPolicyHolder derived information class
|
|
/// \sa Weak::ARC4, ChaCha8, ChaCha12, ChaCha20, Salsa20, SEAL, Sosemanuk, WAKE
|
|
template <class BASE, class INFO = BASE>
|
|
class SymmetricCipherFinal : public AlgorithmImpl<SimpleKeyingInterfaceImpl<BASE, INFO>, INFO>
|
|
{
|
|
public:
|
|
virtual ~SymmetricCipherFinal() {}
|
|
|
|
/// \brief Construct a stream cipher
|
|
SymmetricCipherFinal() {}
|
|
|
|
/// \brief Construct a stream cipher
|
|
/// \param key a byte array used to key the cipher
|
|
/// \details This overload uses DEFAULT_KEYLENGTH
|
|
SymmetricCipherFinal(const byte *key)
|
|
{this->SetKey(key, this->DEFAULT_KEYLENGTH);}
|
|
|
|
/// \brief Construct a stream cipher
|
|
/// \param key a byte array used to key the cipher
|
|
/// \param length the size of the key array
|
|
SymmetricCipherFinal(const byte *key, size_t length)
|
|
{this->SetKey(key, length);}
|
|
|
|
/// \brief Construct a stream cipher
|
|
/// \param key a byte array used to key the cipher
|
|
/// \param length the size of the key array
|
|
/// \param iv a byte array used as an initialization vector
|
|
SymmetricCipherFinal(const byte *key, size_t length, const byte *iv)
|
|
{this->SetKeyWithIV(key, length, iv);}
|
|
|
|
/// \brief Clone a SymmetricCipher
|
|
/// \returns a new SymmetricCipher based on this object
|
|
Clonable * Clone() const {return static_cast<SymmetricCipher *>(new SymmetricCipherFinal<BASE, INFO>(*this));}
|
|
};
|
|
|
|
NAMESPACE_END
|
|
|
|
#ifdef CRYPTOPP_MANUALLY_INSTANTIATE_TEMPLATES
|
|
#include "strciphr.cpp"
|
|
#endif
|
|
|
|
NAMESPACE_BEGIN(CryptoPP)
|
|
CRYPTOPP_DLL_TEMPLATE_CLASS AbstractPolicyHolder<AdditiveCipherAbstractPolicy, SymmetricCipher>;
|
|
CRYPTOPP_DLL_TEMPLATE_CLASS AdditiveCipherTemplate<AbstractPolicyHolder<AdditiveCipherAbstractPolicy, SymmetricCipher> >;
|
|
CRYPTOPP_DLL_TEMPLATE_CLASS CFB_CipherTemplate<AbstractPolicyHolder<CFB_CipherAbstractPolicy, SymmetricCipher> >;
|
|
CRYPTOPP_DLL_TEMPLATE_CLASS CFB_EncryptionTemplate<AbstractPolicyHolder<CFB_CipherAbstractPolicy, SymmetricCipher> >;
|
|
CRYPTOPP_DLL_TEMPLATE_CLASS CFB_DecryptionTemplate<AbstractPolicyHolder<CFB_CipherAbstractPolicy, SymmetricCipher> >;
|
|
|
|
NAMESPACE_END
|
|
|
|
#if CRYPTOPP_MSC_VERSION
|
|
# pragma warning(pop)
|
|
#endif
|
|
|
|
#endif
|