/usr/include/xsec/enc/OpenSSL/OpenSSLCryptoSymmetricKey.hpp is in libxml-security-c-dev 1.7.3-1.
This file is owned by root:root, with mode 0o644.
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* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF licenses this file
* to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance
* with the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing,
* software distributed under the License is distributed on an
* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
* KIND, either express or implied. See the License for the
* specific language governing permissions and limitations
* under the License.
*/
/*
* XSEC
*
* XSECCryptoSymmetricKey := Bulk encryption algorithms should all be
* implemented via this interface
*
* Author(s): Berin Lautenbach
*
* $Id: OpenSSLCryptoSymmetricKey.hpp 1352680 2012-06-21 20:58:07Z scantor $
*
*/
#ifndef OPENSSLCRYPTOSYMMETRICKEY_INCLUDE
#define OPENSSLCRYPTOSYMMETRICKEY_INCLUDE
#include <xsec/framework/XSECDefs.hpp>
#include <xsec/enc/XSECCryptoSymmetricKey.hpp>
#if defined (XSEC_HAVE_OPENSSL)
// OpenSSL Includes
#include <openssl/evp.h>
#define MAX_BLOCK_SIZE 32
/**
* \ingroup opensslcrypto
*/
/**
* \brief Base interface definition for symmetric key material.
*
* This is the implementation for a wrapper of OpenSSL symmetric
* crypto functions.
*/
class DSIG_EXPORT OpenSSLCryptoSymmetricKey : public XSECCryptoSymmetricKey {
public :
/** @name Constructors and Destructors */
//@{
/**
* \brief Constructor
*
* Can only construct a Symmetric key if we know what type it is
**/
OpenSSLCryptoSymmetricKey(XSECCryptoSymmetricKey::SymmetricKeyType type);
/**
* \brief Destructor
*
* Implementations must ensure that the held key is properly destroyed
* (overwritten) when key objects are deleted.
*/
virtual ~OpenSSLCryptoSymmetricKey();
//@}
/** @name Basic CryptoKey Interface methods */
//@{
/**
* \brief Returns a string that identifies the crypto owner of this library.
*/
virtual const XMLCh * getProviderName() const;
/**
* \brief Clone the key
*
* All keys need to be able to copy themselves and return
* a pointer to the copy. This allows the library to
* duplicate keys.
*/
virtual XSECCryptoKey * clone() const;
//@}
/** @name Symmetric key interface methods */
//@{
/**
* \brief What type of symmetric key is this?
*
* There are a number of different types of symmetric key.
* This method allows callers to determine the type of this
* particular key
*/
SymmetricKeyType getSymmetricKeyType(void) const;
/**
* \brief Set the key from the provided bytes
*
* Symmetric keys can all be loaded from a buffer containing a series
* of bytes.
*
* @param key The buffer containing the key bytes
* @param keyLen The number of key bytes in the buffer
*
*/
void setKey(const unsigned char * key, unsigned int keyLen);
/**
* \brief Initialise an decryption process
*
* Setup the key to get ready for a decryption session.
* Callers can pass in an IV. If one is not provided,
* but the algorithm requires one (e.g. 3DES_CBC), then
* implementations should assume that the start of the
* cipher text stream will in fact be the IV.
*
* @param doPad By default, we perform padding for last block
* @param mode mode selection (Currently ECB or CBC mode only)
* @param iv Initialisation Vector to be used. NULL if one is
* not required, or if IV will be set from data stream
* @param tag Authentication tag to be used for AEAD ciphers
* @param taglen length of Authentication Tag
* @returns true if the initialisation succeeded.
*/
virtual bool decryptInit(bool doPad = true,
SymmetricKeyMode mode = MODE_CBC,
const unsigned char * iv = NULL,
const unsigned char* tag = NULL,
unsigned int taglen = NULL);
/**
* \brief Continue an decrypt operation using this key.
*
* Decryption must have been set up using an encryptInit
* call. Takes the inBuf and continues a decryption operation,
* writing the output to outBuf.
*
* This function does not have to guarantee that all input
* will be decrypted. In cases where the input is not a length
* of the block size, the implementation will need to hold back
* cipher-text to be handles during the next operation.
*
* @note While maxOutLength is defined, the OpenSSL libraries will
* not read the value, so the onus is on the caller to ensure the
* buffer is long enough to hold the output!
*
* @param inBuf Octets to be decrypted
* @param plainBuf Buffer to place output in
* @param inLength Number of bytes to decrypt
* @param maxOutLength Maximum number of bytes to place in output
* buffer
* @returns Bytes placed in output Buffer
*/
virtual unsigned int decrypt(const unsigned char * inBuf,
unsigned char * plainBuf,
unsigned int inLength,
unsigned int maxOutLength);
/**
* \brief Finish a decryption operation
*
* Complete a decryption process. No cipher text is passed in,
* as this should simply be removing any remaining text from
* the plain storage buffer.
*
* May throw an exception if there is some stored cipher text
* that is not the length of the block size for block algorithms.
*
* @note While maxOutLength is defined, the OpenSSL libraries will
* not read the value, so the onus is on the caller to ensure the
* buffer is long enough to hold the output!
*
* @param plainBuf Buffer to place any remaining plain text in
* @param maxOutLength Maximum number of bytes to pace in output
* @returns Bytes placed in output buffer
*/
virtual unsigned int decryptFinish(unsigned char * plainBuf,
unsigned int maxOutLength);
/**
* \brief Initialise an encryption process
*
* Setup the key to get ready for a decryption session.
* Callers can pass in an IV. If one is not provided,
* but the algorithm requires one (e.g. 3DES_CBC), then
* implementations are required to generate one.
*
* @param doPad By default, we perform padding for last block
* @param mode What mode to handle blocks (Currently CBC or ECB)
* @param iv Initialisation Vector to be used. NULL if one is
* not required, or if IV is to be generated
* @returns true if the initialisation succeeded.
*/
virtual bool encryptInit(bool doPad = true,
SymmetricKeyMode mode = MODE_CBC,
const unsigned char * iv = NULL);
/**
* \brief Continue an encryption operation using this key.
*
* Encryption must have been set up using an encryptInit
* call. Takes the inBuf and continues a encryption operation,
* writing the output to outBuf.
*
* This function does not have to guarantee that all input
* will be encrypted. In cases where the input is not a length
* of the block size, the implementation will need to hold back
* plain-text to be handled during the next operation.
*
* @param inBuf Octets to be encrypted
* @param cipherBuf Buffer to place output in
* @param inLength Number of bytes to encrypt
* @param maxOutLength Maximum number of bytes to place in output
* buffer
* @returns Bytes placed in output Buffer
*/
virtual unsigned int encrypt(const unsigned char * inBuf,
unsigned char * cipherBuf,
unsigned int inLength,
unsigned int maxOutLength);
/**
* \brief Finish a encryption operation
*
* Complete a encryption process. No plain text is passed in,
* as this should simply be removing any remaining text from
* the plain storage buffer and creating a final padded block.
*
* Padding is performed by taking the remaining block, and
* setting the last byte to equal the number of bytes of
* padding. If the plain was an exact multiple of the block size,
* then an extra block of padding will be used. For example, if
* the block size is 8 bytes, and there were three remaining plain
* text bytes (0x01, 0x02 and 0x03), the final block will be :
*
* 0x010203????????05
*
* @param plainBuf Buffer to place final block of cipher text in
* @param maxOutLength Maximum number of bytes to pace in output
* @param taglen length of Authentication Tag
* @returns Bytes placed in output buffer
*/
virtual unsigned int encryptFinish(unsigned char * plainBuf,
unsigned int maxOutLength,
unsigned int taglen = 0);
//@}
/** @name OpenSSL Library Specific functions */
//@{
/**
* \brief Get OpenSSL cipher context structure
*/
EVP_CIPHER_CTX * getOpenSSLEVP_CIPHER_CTX(void) {return &m_ctx;}
/**
* \brief Get OpenSSL cipher context structure
*/
const EVP_CIPHER_CTX * getOpenSSLEVP_CIPHER_CTX(void) const {return &m_ctx;}
//@}
private:
// Unimplemented constructors
OpenSSLCryptoSymmetricKey();
OpenSSLCryptoSymmetricKey(const OpenSSLCryptoSymmetricKey &);
OpenSSLCryptoSymmetricKey & operator= (const OpenSSLCryptoSymmetricKey &);
// Private functions
int decryptCtxInit(const unsigned char* iv, const unsigned char* tag, unsigned int taglen);
// Private variables
SymmetricKeyType m_keyType;
SymmetricKeyMode m_keyMode;
EVP_CIPHER_CTX m_ctx; // OpenSSL Cipher Context structure
safeBuffer m_keyBuf; // Holder of the key
safeBuffer m_tagBuf; // Holder of authentication tag
unsigned int m_keyLen;
bool m_initialised; // Is the context ready to work?
unsigned char m_lastBlock[MAX_BLOCK_SIZE];
int m_blockSize;
int m_ivSize;
int m_bytesInLastBlock;
bool m_ivSent; // Has the IV been put in the stream
bool m_doPad; // Do we pad last block?
};
#endif /* XSEC_HAVE_OPENSSL */
#endif /* OPENSSLCRYPTOSYMMETRICKEY_INCLUDE */
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