include/ndn-cpp/security/key-chain.hpp - ndn-cxx - Gitiles

 /* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil -*- */
 /**
  * Copyright (C) 2013 Regents of the University of California.
  * @author: Jeff Thompson <jefft0@remap.ucla.edu>
  * See COPYING for copyright and distribution information.
  */

 #ifndef NDN_KEY_CHAIN_HPP
 #define NDN_KEY_CHAIN_HPP

 #include "../data.hpp"
 #include "../face.hpp"
 #include "identity/identity-manager.hpp"
 #include "encryption/encryption-manager.hpp"

 namespace ndn {

 class PolicyManager;

 /**
  * An OnVerified function object is used to pass a callback to verifyData to report a successful verification.
  */
 typedef func_lib::function<void(const ptr_lib::shared_ptr<Data>& data)> OnVerified;

 /**
  * An OnVerifyFailed function object is used to pass a callback to verifyData to report a failed verification.
  */
 typedef func_lib::function<void(const ptr_lib::shared_ptr<Data>& data)> OnVerifyFailed;

 /**
  * Keychain is the main class of the security library.
  *
  * The Keychain class provides a set of interfaces to the security library such as identity management, policy configuration
  * and packet signing and verification.
  */
 class KeyChain {
 public:
   KeyChain
     (const ptr_lib::shared_ptr<IdentityManager>& identityManager, const ptr_lib::shared_ptr<PolicyManager>& policyManager);

   /*****************************************
    *          Identity Management          *
    *****************************************/

   /**
    * Create an identity by creating a pair of Key-Signing-Key (KSK) for this identity and a self-signed certificate of the KSK.
    * @param identityName The name of the identity.
    * @return The key name of the auto-generated KSK of the identity.
    */
   Name
   createIdentity(const Name& identityName)
   {
     return identityManager_->createIdentity(identityName);
   }

   /**
    * Get the default identity.
    * @return The default identity name.
    */
   Name
   getDefaultIdentity()
   {
     return identityManager_->getDefaultIdentity();
   }

   /**
    * Generate a pair of RSA keys for the specified identity.
    * @param identityName The name of the identity.
    * @param isKsk true for generating a Key-Signing-Key (KSK), false for a Data-Signing-Key (KSK).
    * @param keySize The size of the key.
    * @return The generated key name.
    */
   Name
   generateRSAKeyPair(const Name& identityName, bool isKsk = false, int keySize = 2048)
   {
     return identityManager_->generateRSAKeyPair(identityName, isKsk, keySize);
   }

   /**
    * Set a key as the default key of an identity.
    * @param keyName The name of the key.
    * @param identityName the name of the identity. If not specified, the identity name is inferred from the keyName.
    */
   void
   setDefaultKeyForIdentity(const Name& keyName, const Name& identityName = Name())
   {
     return identityManager_->setDefaultKeyForIdentity(keyName, identityName);
   }

   /**
    * Generate a pair of RSA keys for the specified identity and set it as default key for the identity.
    * @param identityName The name of the identity.
    * @param isKsk true for generating a Key-Signing-Key (KSK), false for a Data-Signing-Key (KSK).
    * @param keySize The size of the key.
    * @return The generated key name.
    */
   Name
   generateRSAKeyPairAsDefault(const Name& identityName, bool isKsk = false, int keySize = 2048)
   {
     return identityManager_->generateRSAKeyPairAsDefault(identityName, isKsk, keySize);
   }

   /**
    * Create a public key signing request.
    * @param keyName The name of the key.
    * @returns The signing request data.
    */
   Blob
   createSigningRequest(const Name& keyName)
   {
     return identityManager_->getPublicKey(keyName)->getKeyDer();
   }

   /**
    * Install an identity certificate into the public key identity storage.
    * @param certificate The certificate to to added.
    */
   void
   installIdentityCertificate(const IdentityCertificate& certificate)
   {
     identityManager_->addCertificate(certificate);
   }

   /**
    * Set the certificate as the default for its corresponding key.
    * @param certificateName The name of the certificate.
    */
   void
   setDefaultCertificateForKey(const Name& certificateName)
   {
     identityManager_->setDefaultCertificateForKey(certificateName);
   }

   /**
    * Get a certificate with the specified name.
    * @param certificateName The name of the requested certificate.
    * @return the requested certificate which is valid.
    */
   ptr_lib::shared_ptr<Certificate>
   getCertificate(const Name& certificateName)
   {
     return identityManager_->getCertificate(certificateName);
   }

   /**
    * Get a certificate even if the certificate is not valid anymore.
    * @param certificateName The name of the requested certificate.
    * @return the requested certificate.
    */
   ptr_lib::shared_ptr<Certificate>
   getAnyCertificate(const Name& certificateName)
   {
     return identityManager_->getAnyCertificate(certificateName);
   }

   /**
    * Get an identity certificate with the specified name.
    * @param certificateName The name of the requested certificate.
    * @return the requested certificate which is valid.
    */
   ptr_lib::shared_ptr<IdentityCertificate>
   getIdentityCertificate(const Name& certificateName)
   {
     return identityManager_->getCertificate(certificateName);
   }

   /**
    * Get an identity certificate even if the certificate is not valid anymore.
    * @param certificateName The name of the requested certificate.
    * @return the requested certificate.
    */
   ptr_lib::shared_ptr<IdentityCertificate>
   getAnyIdentityCertificate(const Name& certificateName)
   {
     return identityManager_->getAnyCertificate(certificateName);
   }

   /**
    * Revoke a key
    * @param keyName the name of the key that will be revoked
    */
   void
   revokeKey(const Name & keyName)
   {
     //TODO: Implement
   }

   /**
    * Revoke a certificate
    * @param certificateName the name of the certificate that will be revoked
    */
   void
   revokeCertificate(const Name & certificateName)
   {
     //TODO: Implement
   }

   /*****************************************
    *           Policy Management           *
    *****************************************/

   const ptr_lib::shared_ptr<PolicyManager>&
   getPolicyManager() { return policyManager_; }

   /*****************************************
    *              Sign/Verify              *
    *****************************************/

   /**
    * Wire encode the Data object, sign it and set its signature.
    * Note: the caller must make sure the timestamp is correct, for example with
    * data.getMetaInfo().setTimestampMilliseconds(time(NULL) * 1000.0).
    * @param data The Data object to be signed.  This updates its signature and key locator field and wireEncoding.
    * @param certificateName The certificate name of the key to use for signing.  If omitted, infer the signing identity from the data packet name.
    * @param wireFormat A WireFormat object used to encode the input. If omitted, use WireFormat getDefaultWireFormat().
    */
   void
   sign(Data& data, const Name& certificateName, WireFormat& wireFormat = *WireFormat::getDefaultWireFormat());

   /**
    * Sign the byte array using a certificate name and return a Signature object.
    * @param buffer The byte array to be signed.
    * @param bufferLength the length of buffer.
    * @param certificateName The certificate name used to get the signing key and which will be put into KeyLocator.
    * @return The Signature.
    */
   ptr_lib::shared_ptr<Signature>
   sign(const uint8_t* buffer, size_t bufferLength, const Name& certificateName);

   /**
    * Sign the byte array using a certificate name and return a Signature object.
    * @param buffer The byte array to be signed.
    * @param certificateName The certificate name used to get the signing key and which will be put into KeyLocator.
    * @return The Signature.
    */
   ptr_lib::shared_ptr<Signature>
   sign(const std::vector<uint8_t>& buffer, const Name& certificateName)
   {
     return sign(&buffer[0], buffer.size(), certificateName);
   }

   /**
    * Wire encode the Data object, sign it and set its signature.
    * Note: the caller must make sure the timestamp is correct, for example with
    * data.getMetaInfo().setTimestampMilliseconds(time(NULL) * 1000.0).
    * @param data The Data object to be signed.  This updates its signature and key locator field and wireEncoding.
    * @param identityName The identity name for the key to use for signing.  If omitted, infer the signing identity from the data packet name.
    * @param wireFormat A WireFormat object used to encode the input. If omitted, use WireFormat getDefaultWireFormat().
    */
   void
   signByIdentity(Data& data, const Name& identityName = Name(), WireFormat& wireFormat = *WireFormat::getDefaultWireFormat());

   /**
    * Sign the byte array using an identity name and return a Signature object.
    * @param buffer The byte array to be signed.
    * @param bufferLength the length of buffer.
    * @param identityName The identity name.
    * @return The Signature.
    */
   ptr_lib::shared_ptr<Signature>
   signByIdentity(const uint8_t* buffer, size_t bufferLength, const Name& identityName);

   /**
    * Sign the byte array using an identity name and return a Signature object.
    * @param buffer The byte array to be signed.
    * @param identityName The identity name.
    * @return The Signature.
    */
   ptr_lib::shared_ptr<Signature>
   signByIdentity(const std::vector<uint8_t>& buffer, const Name& identityName)
   {
     return signByIdentity(&buffer[0], buffer.size(), identityName);
   }

   /**
    * Check the signature on the Data object and call either onVerify or onVerifyFailed.
    * We use callback functions because verify may fetch information to check the signature.
    * @param data The Data object with the signature to check. It is an error if data does not have a wireEncoding.
    * To set the wireEncoding, you can call data.wireDecode.
    * @param onVerified If the signature is verified, this calls onVerified(data).
    * @param onVerifyFailed If the signature check fails, this calls onVerifyFailed(data).
    */
   void
   verifyData
     (const ptr_lib::shared_ptr<Data>& data, const OnVerified& onVerified, const OnVerifyFailed& onVerifyFailed, int stepCount = 0);

   /*****************************************
    *           Encrypt/Decrypt             *
    *****************************************/

   /**
    * Generate a symmetric key.
    * @param keyName The name of the generated key.
    * @param keyType The type of the key, e.g. KEY_TYPE_AES
    */
   void
   generateSymmetricKey(const Name& keyName, KeyType keyType)
   {
     encryptionManager_->createSymmetricKey(keyName, keyType);
   }

   /**
    * Encrypt a byte array.
    * @param keyName The name of the encrypting key.
    * @param data The byte array that will be encrypted.
    * @param dataLength The length of data.
    * @param useSymmetric If true then symmetric encryption is used, otherwise asymmetric encryption is used.
    * @param encryptMode the encryption mode
    * @return the encrypted data as an immutable Blob.
    */
   Blob
   encrypt(const Name &keyName, const uint8_t* data, size_t dataLength, bool useSymmetric = true,
           EncryptMode encryptMode = ENCRYPT_MODE_DEFAULT)
   {
     return encryptionManager_->encrypt(keyName, data, dataLength, useSymmetric, encryptMode);
   }

   /**
    * Decrypt a byte array.
    * @param keyName The name of the decrypting key.
    * @param data The byte array that will be decrypted.
    * @param dataLength The length of data.
    * @param useSymmetric If true then symmetric encryption is used, otherwise asymmetric encryption is used.
    * @param encryptMode the encryption mode
    * @return the decrypted data as an immutable Blob.
    */
   Blob
   decrypt(const Name &keyName, const uint8_t* data, size_t dataLength, bool useSymmetric = true,
           EncryptMode encryptMode = ENCRYPT_MODE_DEFAULT)
   {
      return encryptionManager_->decrypt(keyName, data, dataLength, useSymmetric, encryptMode);
   }

   /**
    * Set the Face which will be used to fetch required certificates.
    * @param face A pointer to the Face object.
    */
   void
   setFace(Face* face) { face_ = face; }

 private:
   ptr_lib::shared_ptr<IdentityManager> identityManager_;
   ptr_lib::shared_ptr<PolicyManager> policyManager_;
   ptr_lib::shared_ptr<EncryptionManager> encryptionManager_;
   Face* face_;
   const int maxSteps_;
 };

 }

 #endif
	/* -- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil -- */
	/**
	* Copyright (C) 2013 Regents of the University of California.
	* @author: Jeff Thompson <jefft0@remap.ucla.edu>
	* See COPYING for copyright and distribution information.
	*/

	#ifndef NDN_KEY_CHAIN_HPP
	#define NDN_KEY_CHAIN_HPP

	#include "../data.hpp"
	#include "../face.hpp"
	#include "identity/identity-manager.hpp"
	#include "encryption/encryption-manager.hpp"

	namespace ndn {

	class PolicyManager;

	/**
	* An OnVerified function object is used to pass a callback to verifyData to report a successful verification.
	*/
	typedef func_lib::function<void(const ptr_lib::shared_ptr<Data>& data)> OnVerified;

	/**
	* An OnVerifyFailed function object is used to pass a callback to verifyData to report a failed verification.
	*/
	typedef func_lib::function<void(const ptr_lib::shared_ptr<Data>& data)> OnVerifyFailed;

	/**
	* Keychain is the main class of the security library.
	*
	* The Keychain class provides a set of interfaces to the security library such as identity management, policy configuration
	* and packet signing and verification.
	*/
	class KeyChain {
	public:
	KeyChain
	(const ptr_lib::shared_ptr<IdentityManager>& identityManager, const ptr_lib::shared_ptr<PolicyManager>& policyManager);

	/*****************************************
	* Identity Management *
	*****************************************/

	/**
	* Create an identity by creating a pair of Key-Signing-Key (KSK) for this identity and a self-signed certificate of the KSK.
	* @param identityName The name of the identity.
	* @return The key name of the auto-generated KSK of the identity.
	*/
	Name
	createIdentity(const Name& identityName)
	{
	return identityManager_->createIdentity(identityName);
	}

	/**
	* Get the default identity.
	* @return The default identity name.
	*/
	Name
	getDefaultIdentity()
	{
	return identityManager_->getDefaultIdentity();
	}

	/**
	* Generate a pair of RSA keys for the specified identity.
	* @param identityName The name of the identity.
	* @param isKsk true for generating a Key-Signing-Key (KSK), false for a Data-Signing-Key (KSK).
	* @param keySize The size of the key.
	* @return The generated key name.
	*/
	Name
	generateRSAKeyPair(const Name& identityName, bool isKsk = false, int keySize = 2048)
	{
	return identityManager_->generateRSAKeyPair(identityName, isKsk, keySize);
	}

	/**
	* Set a key as the default key of an identity.
	* @param keyName The name of the key.
	* @param identityName the name of the identity. If not specified, the identity name is inferred from the keyName.
	*/
	void
	setDefaultKeyForIdentity(const Name& keyName, const Name& identityName = Name())
	{
	return identityManager_->setDefaultKeyForIdentity(keyName, identityName);
	}

	/**
	* Generate a pair of RSA keys for the specified identity and set it as default key for the identity.
	* @param identityName The name of the identity.
	* @param isKsk true for generating a Key-Signing-Key (KSK), false for a Data-Signing-Key (KSK).
	* @param keySize The size of the key.
	* @return The generated key name.
	*/
	Name
	generateRSAKeyPairAsDefault(const Name& identityName, bool isKsk = false, int keySize = 2048)
	{
	return identityManager_->generateRSAKeyPairAsDefault(identityName, isKsk, keySize);
	}

	/**
	* Create a public key signing request.
	* @param keyName The name of the key.
	* @returns The signing request data.
	*/
	Blob
	createSigningRequest(const Name& keyName)
	{
	return identityManager_->getPublicKey(keyName)->getKeyDer();
	}

	/**
	* Install an identity certificate into the public key identity storage.
	* @param certificate The certificate to to added.
	*/
	void
	installIdentityCertificate(const IdentityCertificate& certificate)
	{
	identityManager_->addCertificate(certificate);
	}

	/**
	* Set the certificate as the default for its corresponding key.
	* @param certificateName The name of the certificate.
	*/
	void
	setDefaultCertificateForKey(const Name& certificateName)
	{
	identityManager_->setDefaultCertificateForKey(certificateName);
	}

	/**
	* Get a certificate with the specified name.
	* @param certificateName The name of the requested certificate.
	* @return the requested certificate which is valid.
	*/
	ptr_lib::shared_ptr<Certificate>
	getCertificate(const Name& certificateName)
	{
	return identityManager_->getCertificate(certificateName);
	}

	/**
	* Get a certificate even if the certificate is not valid anymore.
	* @param certificateName The name of the requested certificate.
	* @return the requested certificate.
	*/
	ptr_lib::shared_ptr<Certificate>
	getAnyCertificate(const Name& certificateName)
	{
	return identityManager_->getAnyCertificate(certificateName);
	}

	/**
	* Get an identity certificate with the specified name.
	* @param certificateName The name of the requested certificate.
	* @return the requested certificate which is valid.
	*/
	ptr_lib::shared_ptr<IdentityCertificate>
	getIdentityCertificate(const Name& certificateName)
	{
	return identityManager_->getCertificate(certificateName);
	}

	/**
	* Get an identity certificate even if the certificate is not valid anymore.
	* @param certificateName The name of the requested certificate.
	* @return the requested certificate.
	*/
	ptr_lib::shared_ptr<IdentityCertificate>
	getAnyIdentityCertificate(const Name& certificateName)
	{
	return identityManager_->getAnyCertificate(certificateName);
	}

	/**
	* Revoke a key
	* @param keyName the name of the key that will be revoked
	*/
	void
	revokeKey(const Name & keyName)
	{
	//TODO: Implement
	}

	/**
	* Revoke a certificate
	* @param certificateName the name of the certificate that will be revoked
	*/
	void
	revokeCertificate(const Name & certificateName)
	{
	//TODO: Implement
	}

	/*****************************************
	* Policy Management *
	*****************************************/

	const ptr_lib::shared_ptr<PolicyManager>&
	getPolicyManager() { return policyManager_; }

	/*****************************************
	* Sign/Verify *
	*****************************************/

	/**
	* Wire encode the Data object, sign it and set its signature.
	* Note: the caller must make sure the timestamp is correct, for example with
	* data.getMetaInfo().setTimestampMilliseconds(time(NULL) * 1000.0).
	* @param data The Data object to be signed. This updates its signature and key locator field and wireEncoding.
	* @param certificateName The certificate name of the key to use for signing. If omitted, infer the signing identity from the data packet name.
	* @param wireFormat A WireFormat object used to encode the input. If omitted, use WireFormat getDefaultWireFormat().
	*/
	void
	sign(Data& data, const Name& certificateName, WireFormat& wireFormat = *WireFormat::getDefaultWireFormat());

	/**
	* Sign the byte array using a certificate name and return a Signature object.
	* @param buffer The byte array to be signed.
	* @param bufferLength the length of buffer.
	* @param certificateName The certificate name used to get the signing key and which will be put into KeyLocator.
	* @return The Signature.
	*/
	ptr_lib::shared_ptr<Signature>
	sign(const uint8_t* buffer, size_t bufferLength, const Name& certificateName);

	/**
	* Sign the byte array using a certificate name and return a Signature object.
	* @param buffer The byte array to be signed.
	* @param certificateName The certificate name used to get the signing key and which will be put into KeyLocator.
	* @return The Signature.
	*/
	ptr_lib::shared_ptr<Signature>
	sign(const std::vector<uint8_t>& buffer, const Name& certificateName)
	{
	return sign(&buffer[0], buffer.size(), certificateName);
	}

	/**
	* Wire encode the Data object, sign it and set its signature.
	* Note: the caller must make sure the timestamp is correct, for example with
	* data.getMetaInfo().setTimestampMilliseconds(time(NULL) * 1000.0).
	* @param data The Data object to be signed. This updates its signature and key locator field and wireEncoding.
	* @param identityName The identity name for the key to use for signing. If omitted, infer the signing identity from the data packet name.
	* @param wireFormat A WireFormat object used to encode the input. If omitted, use WireFormat getDefaultWireFormat().
	*/
	void
	signByIdentity(Data& data, const Name& identityName = Name(), WireFormat& wireFormat = *WireFormat::getDefaultWireFormat());

	/**
	* Sign the byte array using an identity name and return a Signature object.
	* @param buffer The byte array to be signed.
	* @param bufferLength the length of buffer.
	* @param identityName The identity name.
	* @return The Signature.
	*/
	ptr_lib::shared_ptr<Signature>
	signByIdentity(const uint8_t* buffer, size_t bufferLength, const Name& identityName);

	/**
	* Sign the byte array using an identity name and return a Signature object.
	* @param buffer The byte array to be signed.
	* @param identityName The identity name.
	* @return The Signature.
	*/
	ptr_lib::shared_ptr<Signature>
	signByIdentity(const std::vector<uint8_t>& buffer, const Name& identityName)
	{
	return signByIdentity(&buffer[0], buffer.size(), identityName);
	}

	/**
	* Check the signature on the Data object and call either onVerify or onVerifyFailed.
	* We use callback functions because verify may fetch information to check the signature.
	* @param data The Data object with the signature to check. It is an error if data does not have a wireEncoding.
	* To set the wireEncoding, you can call data.wireDecode.
	* @param onVerified If the signature is verified, this calls onVerified(data).
	* @param onVerifyFailed If the signature check fails, this calls onVerifyFailed(data).
	*/
	void
	verifyData
	(const ptr_lib::shared_ptr<Data>& data, const OnVerified& onVerified, const OnVerifyFailed& onVerifyFailed, int stepCount = 0);

	/*****************************************
	* Encrypt/Decrypt *
	*****************************************/

	/**
	* Generate a symmetric key.
	* @param keyName The name of the generated key.
	* @param keyType The type of the key, e.g. KEY_TYPE_AES
	*/
	void
	generateSymmetricKey(const Name& keyName, KeyType keyType)
	{
	encryptionManager_->createSymmetricKey(keyName, keyType);
	}

	/**
	* Encrypt a byte array.
	* @param keyName The name of the encrypting key.
	* @param data The byte array that will be encrypted.
	* @param dataLength The length of data.
	* @param useSymmetric If true then symmetric encryption is used, otherwise asymmetric encryption is used.
	* @param encryptMode the encryption mode
	* @return the encrypted data as an immutable Blob.
	*/
	Blob
	encrypt(const Name &keyName, const uint8_t* data, size_t dataLength, bool useSymmetric = true,
	EncryptMode encryptMode = ENCRYPT_MODE_DEFAULT)
	{
	return encryptionManager_->encrypt(keyName, data, dataLength, useSymmetric, encryptMode);
	}

	/**
	* Decrypt a byte array.
	* @param keyName The name of the decrypting key.
	* @param data The byte array that will be decrypted.
	* @param dataLength The length of data.
	* @param useSymmetric If true then symmetric encryption is used, otherwise asymmetric encryption is used.
	* @param encryptMode the encryption mode
	* @return the decrypted data as an immutable Blob.
	*/
	Blob
	decrypt(const Name &keyName, const uint8_t* data, size_t dataLength, bool useSymmetric = true,
	EncryptMode encryptMode = ENCRYPT_MODE_DEFAULT)
	{
	return encryptionManager_->decrypt(keyName, data, dataLength, useSymmetric, encryptMode);
	}

	/**
	* Set the Face which will be used to fetch required certificates.
	* @param face A pointer to the Face object.
	*/
	void
	setFace(Face* face) { face_ = face; }

	private:
	ptr_lib::shared_ptr<IdentityManager> identityManager_;
	ptr_lib::shared_ptr<PolicyManager> policyManager_;
	ptr_lib::shared_ptr<EncryptionManager> encryptionManager_;
	Face* face_;
	const int maxSteps_;
	};

	}

	#endif