jni/libzrtp/sources/zrtp/libzrtpcpp/ZrtpPacketHello.h - jami-client-android - Gitiles

 /*
   Copyright (C) 2006-2013 Werner Dittmann

   This program is free software: you can redistribute it and/or modify
   it under the terms of the GNU Lesser General Public License as published by
   the Free Software Foundation, either version 3 of the License, or
   (at your option) any later version.

   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */

 #ifndef _ZRTPPACKETHELLO_H_
 #define _ZRTPPACKETHELLO_H_

 /**
  * @file ZrtpPacketHello.h
  * @brief The ZRTP Hello message
  *
  * @ingroup GNU_ZRTP
  * @{
  */

 #include <libzrtpcpp/ZrtpPacketBase.h>

 #define HELLO_FIXED_PART_LEN  22

 /**
  * Implement the Hello packet.
  *
  * The ZRTP Hello message. The implementation sends this
  * to start the ZRTP negotiation sequence. The Hello message
  * offers crypto methods and parameters to the other party. The
  * other party selects methods and parameters it can support
  * and uses the Commit message to commit these.
  *
  * @author Werner Dittmann <Werner.Dittmann@t-online.de>
  */

 class __EXPORT ZrtpPacketHello : public ZrtpPacketBase {

  protected:
     Hello_t* helloHeader;   ///< Point to the Hello message part

     int32_t nHash,          ///< number of hash algorithms offered
     nCipher,                ///< number of cipher algorithms offered
     nPubkey,                ///< number of key agreement algorithms offered
     nSas,                   ///< number of SAS algorithms offered
     nAuth;                  ///< number of SRTP authentication algorithms offered

     int32_t oHash,          ///< offsets in bytes to hash algorithm names
     oCipher,                ///< offsets in bytes to cipher algorithm names
     oPubkey,                ///< offsets in bytes to key agreement algorithm names
     oSas,                   ///< offsets in bytes to SAS algorithm names
     oAuth,                  ///< offsets in bytes to SRTP authentication algorithm names
     oHmac;                  ///< offsets in bytes to MAC of Hello message

  public:
     /// Creates a Hello packet with default data
     ZrtpPacketHello();

     /// Creates a Hello packet from received data
     ZrtpPacketHello(uint8_t *data);

     virtual ~ZrtpPacketHello();

     /**
      * Set configure data and populate Hello message data.
      *
      * Fill in the offered Algorithm names and compute all offset to
      * names and MAC. An application must call this method on Hello message
      * objects created with the standard constructor (with default data)
      * before the application can use most of the getter and setter methods.
      *
      * @param config
      *    Pointer to ZrtpConfigure data.
      */
     void configureHello(ZrtpConfigure* config);

     /// Get version number from Hello message, fixed ASCII character array
     uint8_t* getVersion()  { return helloHeader->version; };

      /// Get version number from Hello message as integer, only relvant digits converted
     int32_t getVersionInt();

     /// Get client id from Hello message, fixed ASCII character array
     uint8_t* getClientId() { return helloHeader->clientId; };

     /// Get H3 hash from Hello message, fixed byte array
     uint8_t* getH3()       { return helloHeader->hashH3; };

     /// Get client ZID from Hello message, fixed bytes array
     uint8_t* getZid()      { return helloHeader->zid; };

     /// Set version sting in Hello message, fixed ASCII character array
     void setVersion(const uint8_t *text)     { memcpy(helloHeader->version, text,ZRTP_WORD_SIZE ); }

     /// Set client id in Hello message, fixed ASCII character array
     void setClientId(const uint8_t *t) { memcpy(helloHeader->clientId, t, sizeof(helloHeader->clientId)); }

     /// Set H3 hash in Hello message, fixed byte array
     void setH3(uint8_t *hash)          { memcpy(helloHeader->hashH3, hash, sizeof(helloHeader->hashH3)); }

     /// Set client ZID in Hello message, fixed bytes array
     void setZid(uint8_t *text)         { memcpy(helloHeader->zid, text, sizeof(helloHeader->zid)); }

     /// Check passive mode (mode not implemented)
     bool isPassive()       { return helloHeader->flags & 0x10; };

     /// Check if MitM flag is set
     bool isMitmMode()       { return helloHeader->flags & 0x20; };

     /// Check if SAS sign flag is set
     bool isSasSign()       { return helloHeader->flags & 0x40; };

     /// Get hash algorithm name at position n, fixed ASCII character array
     uint8_t* getHashType(int32_t n)   { return ((uint8_t*)helloHeader)+oHash+(n*ZRTP_WORD_SIZE); }

     /// Get ciper algorithm name at position n, fixed ASCII character array
     uint8_t* getCipherType(int32_t n) { return ((uint8_t*)helloHeader)+oCipher+(n*ZRTP_WORD_SIZE); }

     /// Get SRTP authentication algorithm name at position n, fixed ASCII character array
     uint8_t* getAuthLen(int32_t n)    { return ((uint8_t*)helloHeader)+oAuth+(n*ZRTP_WORD_SIZE); }

     /// Get key agreement algorithm name at position n, fixed ASCII character array
     uint8_t* getPubKeyType(int32_t n) { return ((uint8_t*)helloHeader)+oPubkey+(n*ZRTP_WORD_SIZE); }

     /// Get SAS algorithm name at position n, fixed ASCII character array
     uint8_t* getSasType(int32_t n)    { return ((uint8_t*)helloHeader)+oSas+(n*ZRTP_WORD_SIZE); }

     /// Get Hello MAC, fixed byte array
     uint8_t* getHMAC()                { return ((uint8_t*)helloHeader)+oHmac; }

     /// Set hash algorithm name at position n, fixed ASCII character array
     void setHashType(int32_t n, int8_t* t)
         { memcpy(((uint8_t*)helloHeader)+oHash+(n*ZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

     /// Set ciper algorithm name at position n, fixed ASCII character array
     void setCipherType(int32_t n, int8_t* t)
         { memcpy(((uint8_t*)helloHeader)+oCipher+(n*ZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

     /// Set SRTP authentication algorithm name at position n, fixed ASCII character array
     void setAuthLen(int32_t n, int8_t* t)
         { memcpy(((uint8_t*)helloHeader)+oAuth+(n*ZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

     /// Set key agreement algorithm name at position n, fixed ASCII character array
     void setPubKeyType(int32_t n, int8_t* t)
         { memcpy(((uint8_t*)helloHeader)+oPubkey+(n*ZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

     /// Set SAS algorithm name at position n, fixed ASCII character array
     void setSasType(int32_t n, int8_t* t)
         { memcpy(((uint8_t*)helloHeader)+oSas+(n*ZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

     /// Set Hello MAC, fixed byte array
     void setHMAC(uint8_t* t)
         { memcpy(((uint8_t*)helloHeader)+oHmac, t, 2*ZRTP_WORD_SIZE); }

     /// Get number of offered hash algorithms
     int32_t getNumHashes()   {return nHash; }

     /// Get number of offered cipher algorithms
     int32_t getNumCiphers()  {return nCipher; }

     /// Get number of offered key agreement algorithms
     int32_t getNumPubKeys()  {return nPubkey; }

     /// Get number of offered SAS algorithms
     int32_t getNumSas()      {return nSas; }

     /// Get number of offered SRTP authentication algorithms
     int32_t getNumAuth()     {return nAuth; }

     /// set MitM flag
     void setMitmMode()       {helloHeader->flags |= 0x20; }

     /// set SAS sign flag
     void setSasSign()        {helloHeader->flags |= 0x40; }

     /// Check if packet length matches
     bool isLengthOk()        {return (computedLength == getLength());}

  private:
      uint32_t computedLength;
      // Hello packet is of variable length. It maximum size is 46 words:
      // - 20 words fixed sizze
      // - up to 35 words variable part, depending on number of algorithms
      // leads to a maximum of 4*55=220 bytes.
      uint8_t data[256];       // large enough to hold a full blown Hello packet
 };

 /**
  * @}
  */
 #endif // ZRTPPACKETHELLO
	/*
	Copyright (C) 2006-2013 Werner Dittmann

	This program is free software: you can redistribute it and/or modify
	it under the terms of the GNU Lesser General Public License as published by
	the Free Software Foundation, either version 3 of the License, or
	(at your option) any later version.

	This program is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	GNU General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program. If not, see <http://www.gnu.org/licenses/>.
	*/

	#ifndef _ZRTPPACKETHELLO_H_
	#define _ZRTPPACKETHELLO_H_

	/**
	* @file ZrtpPacketHello.h
	* @brief The ZRTP Hello message
	*
	* @ingroup GNU_ZRTP
	* @{
	*/

	#include <libzrtpcpp/ZrtpPacketBase.h>

	#define HELLO_FIXED_PART_LEN 22

	/**
	* Implement the Hello packet.
	*
	* The ZRTP Hello message. The implementation sends this
	* to start the ZRTP negotiation sequence. The Hello message
	* offers crypto methods and parameters to the other party. The
	* other party selects methods and parameters it can support
	* and uses the Commit message to commit these.
	*
	* @author Werner Dittmann <Werner.Dittmann@t-online.de>
	*/

	class __EXPORT ZrtpPacketHello : public ZrtpPacketBase {

	protected:
	Hello_t* helloHeader; ///< Point to the Hello message part

	int32_t nHash, ///< number of hash algorithms offered
	nCipher, ///< number of cipher algorithms offered
	nPubkey, ///< number of key agreement algorithms offered
	nSas, ///< number of SAS algorithms offered
	nAuth; ///< number of SRTP authentication algorithms offered

	int32_t oHash, ///< offsets in bytes to hash algorithm names
	oCipher, ///< offsets in bytes to cipher algorithm names
	oPubkey, ///< offsets in bytes to key agreement algorithm names
	oSas, ///< offsets in bytes to SAS algorithm names
	oAuth, ///< offsets in bytes to SRTP authentication algorithm names
	oHmac; ///< offsets in bytes to MAC of Hello message

	public:
	/// Creates a Hello packet with default data
	ZrtpPacketHello();

	/// Creates a Hello packet from received data
	ZrtpPacketHello(uint8_t *data);

	virtual ~ZrtpPacketHello();

	/**
	* Set configure data and populate Hello message data.
	*
	* Fill in the offered Algorithm names and compute all offset to
	* names and MAC. An application must call this method on Hello message
	* objects created with the standard constructor (with default data)
	* before the application can use most of the getter and setter methods.
	*
	* @param config
	* Pointer to ZrtpConfigure data.
	*/
	void configureHello(ZrtpConfigure* config);

	/// Get version number from Hello message, fixed ASCII character array
	uint8_t* getVersion() { return helloHeader->version; };

	/// Get version number from Hello message as integer, only relvant digits converted
	int32_t getVersionInt();

	/// Get client id from Hello message, fixed ASCII character array
	uint8_t* getClientId() { return helloHeader->clientId; };

	/// Get H3 hash from Hello message, fixed byte array
	uint8_t* getH3() { return helloHeader->hashH3; };

	/// Get client ZID from Hello message, fixed bytes array
	uint8_t* getZid() { return helloHeader->zid; };

	/// Set version sting in Hello message, fixed ASCII character array
	void setVersion(const uint8_t *text) { memcpy(helloHeader->version, text,ZRTP_WORD_SIZE ); }

	/// Set client id in Hello message, fixed ASCII character array
	void setClientId(const uint8_t *t) { memcpy(helloHeader->clientId, t, sizeof(helloHeader->clientId)); }

	/// Set H3 hash in Hello message, fixed byte array
	void setH3(uint8_t *hash) { memcpy(helloHeader->hashH3, hash, sizeof(helloHeader->hashH3)); }

	/// Set client ZID in Hello message, fixed bytes array
	void setZid(uint8_t *text) { memcpy(helloHeader->zid, text, sizeof(helloHeader->zid)); }

	/// Check passive mode (mode not implemented)
	bool isPassive() { return helloHeader->flags & 0x10; };

	/// Check if MitM flag is set
	bool isMitmMode() { return helloHeader->flags & 0x20; };

	/// Check if SAS sign flag is set
	bool isSasSign() { return helloHeader->flags & 0x40; };

	/// Get hash algorithm name at position n, fixed ASCII character array
	uint8_t* getHashType(int32_t n) { return ((uint8_t)helloHeader)+oHash+(nZRTP_WORD_SIZE); }

	/// Get ciper algorithm name at position n, fixed ASCII character array
	uint8_t* getCipherType(int32_t n) { return ((uint8_t)helloHeader)+oCipher+(nZRTP_WORD_SIZE); }

	/// Get SRTP authentication algorithm name at position n, fixed ASCII character array
	uint8_t* getAuthLen(int32_t n) { return ((uint8_t)helloHeader)+oAuth+(nZRTP_WORD_SIZE); }

	/// Get key agreement algorithm name at position n, fixed ASCII character array
	uint8_t* getPubKeyType(int32_t n) { return ((uint8_t)helloHeader)+oPubkey+(nZRTP_WORD_SIZE); }

	/// Get SAS algorithm name at position n, fixed ASCII character array
	uint8_t* getSasType(int32_t n) { return ((uint8_t)helloHeader)+oSas+(nZRTP_WORD_SIZE); }

	/// Get Hello MAC, fixed byte array
	uint8_t* getHMAC() { return ((uint8_t*)helloHeader)+oHmac; }

	/// Set hash algorithm name at position n, fixed ASCII character array
	void setHashType(int32_t n, int8_t* t)
	{ memcpy(((uint8_t)helloHeader)+oHash+(nZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

	/// Set ciper algorithm name at position n, fixed ASCII character array
	void setCipherType(int32_t n, int8_t* t)
	{ memcpy(((uint8_t)helloHeader)+oCipher+(nZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

	/// Set SRTP authentication algorithm name at position n, fixed ASCII character array
	void setAuthLen(int32_t n, int8_t* t)
	{ memcpy(((uint8_t)helloHeader)+oAuth+(nZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

	/// Set key agreement algorithm name at position n, fixed ASCII character array
	void setPubKeyType(int32_t n, int8_t* t)
	{ memcpy(((uint8_t)helloHeader)+oPubkey+(nZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

	/// Set SAS algorithm name at position n, fixed ASCII character array
	void setSasType(int32_t n, int8_t* t)
	{ memcpy(((uint8_t)helloHeader)+oSas+(nZRTP_WORD_SIZE), t, ZRTP_WORD_SIZE); }

	/// Set Hello MAC, fixed byte array
	void setHMAC(uint8_t* t)
	{ memcpy(((uint8_t)helloHeader)+oHmac, t, 2ZRTP_WORD_SIZE); }

	/// Get number of offered hash algorithms
	int32_t getNumHashes() {return nHash; }

	/// Get number of offered cipher algorithms
	int32_t getNumCiphers() {return nCipher; }

	/// Get number of offered key agreement algorithms
	int32_t getNumPubKeys() {return nPubkey; }

	/// Get number of offered SAS algorithms
	int32_t getNumSas() {return nSas; }

	/// Get number of offered SRTP authentication algorithms
	int32_t getNumAuth() {return nAuth; }

	/// set MitM flag
	void setMitmMode() {helloHeader->flags \|= 0x20; }

	/// set SAS sign flag
	void setSasSign() {helloHeader->flags \|= 0x40; }

	/// Check if packet length matches
	bool isLengthOk() {return (computedLength == getLength());}

	private:
	uint32_t computedLength;
	// Hello packet is of variable length. It maximum size is 46 words:
	// - 20 words fixed sizze
	// - up to 35 words variable part, depending on number of algorithms
	// leads to a maximum of 4*55=220 bytes.
	uint8_t data[256]; // large enough to hold a full blown Hello packet
	};

	/**
	* @}
	*/
	#endif // ZRTPPACKETHELLO