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542 lines
23 KiB
Plaintext
542 lines
23 KiB
Plaintext
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Public Key Cryptography
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=================================
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Public key cryptography (also called assymmetric cryptography) is a collection
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of techniques allowing for encryption, signatures, and key agreement.
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Key Objects
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----------------------------------------
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Public and private keys are represented by classes ``Public_Key`` and it's
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subclass ``Private_Key``. The use of inheritence here means that a
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``Private_Key`` can be converted into a reference to a public key.
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None of the functions on ``Public_Key`` and ``Private_Key`` itself are
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particularly useful for users of the library, because 'bare' public key
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operations are *very insecure*. The only purpose of these functions is to
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provide a clean interface that higher level operations can be built on. So
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really the only thing you need to know is that when a function takes a
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reference to a ``Public_Key``, it can take any public key or private key, and
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similiarly for ``Private_Key``.
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Types of ``Public_Key`` include ``RSA_PublicKey``, ``DSA_PublicKey``,
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``ECDSA_PublicKey``, ``DH_PublicKey``, ``ECDH_PublicKey``, ``RW_PublicKey``,
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``NR_PublicKey``,, and ``GOST_3410_PublicKey``. There are cooresponding
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``Private_Key`` classes for each of these algorithms.
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.. _creating_new_private_keys:
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Creating New Private Keys
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----------------------------------------
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Creating a new private key requires two things: a source of random numbers
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(see :ref:`random_number_generators`) and some algorithm specific parameters
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that define the *security level* of the resulting key. For instance, the
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security level of an RSA key is (at least in part) defined by the length of
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the public key modulus in bits. So to create a new RSA private key, you would
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call
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.. cpp:function:: RSA_PrivateKey::RSA_PrivateKey(RandomNumberGenerator& rng, size_t bits)
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A constructor that creates a new random RSA private key with a modulus
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of length *bits*.
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Algorithms based on the discrete-logarithm problem uses what is called a
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*group*; a group can safely be used with many keys, and for some operations,
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like key agreement, the two keys *must* use the same group. There are
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currently two kinds of discrete logarithm groups supported in botan: the
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integers modulo a prime, represented by :ref:`dl_group`, and elliptic curves
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in GF(p), represented by :ref:`ec_group`. A rough generalization is that the
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larger the group is, the more secure the algorithm is, but coorespondingly the
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slower the operations will be.
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Given a ``DL_Group``, you can create new DSA, Diffie-Hellman, and
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Nyberg-Rueppel key pairs with
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.. cpp:function:: DSA_PrivateKey::DSA_PrivateKey(RandomNumberGenerator& rng, \
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const DL_Group& group, const BigInt& x = 0)
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.. cpp:function:: DH_PrivateKey::DH_PrivateKey(RandomNumberGenerator& rng, \
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const DL_Group& group, const BigInt& x = 0)
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.. cpp:function:: NR_PrivateKey::NR_PrivateKey(RandomNumberGenerator& rng, \
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const DL_Group& group, const BigInt& x = 0)
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.. cpp:function:: ElGamal_PrivateKey::ElGamal_PrivateKey(RandomNumberGenerator& rng, \
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const DL_Group& group, const BigInt& x = 0)
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The optional *x* parameter to each of these contructors is a private key
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value. This allows you to create keys where the private key is formed by
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some special technique; for instance you can use the hash of a password (see
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:ref:`pbkdf` for how to do that) as a private key value. Normally, you would
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leave the value as zero, letting the class generate a new random key.
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Finally, given an ``EC_Group`` object, you can create a new ECDSA,
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ECDH, or GOST 34.10-2001 private key with
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.. cpp:function:: ECDSA_PrivateKey::ECDSA_PrivateKey(RandomNumberGenerator& rng, \
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const EC_Group& domain, const BigInt& x = 0)
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.. cpp:function:: ECDH_PrivateKey::ECDH_PrivateKey(RandomNumberGenerator& rng, \
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const EC_Group& domain, const BigInt& x = 0)
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.. cpp:function:: GOST_3410_PrivateKey::GOST_3410_PrivateKey(RandomNumberGenerator& rng, \
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const EC_Group& domain, const BigInt& x = 0)
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Generating RSA keys
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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This example will generate an RSA key of a specified bitlength, and put it
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into a pair of key files. One is the public key in X.509 format (PEM encoded),
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the private key is in PKCS #8 format (also PEM encoded), either encrypted or
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unencrypted depending on if a password was given.
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.. literalinclude:: examples/rsa_kgen.cpp
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Generate DSA keys
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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This example generates a 2048 bit DSA key
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.. literalinclude:: examples/dsa_kgen.cpp
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.. _serializing_private_keys:
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Serializing Private Keys Using PKCS #8
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----------------------------------------
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The standard format for serializing a private key is PKCS #8, the operations
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for which are defined in ``pkcs8.h``. It supports both unencrypted and
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encrypted storage.
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.. cpp:function:: SecureVector<byte> PKCS8::BER_encode(const Private_Key& key, \
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RandomNumberGenerator& rng, const std::string& password, const std::string& pbe_algo = "")
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Takes any private key object, serializes it, encrypts it using
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*password*, and returns a binary structure representing the private
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key.
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The final (optional) argument, *pbe_algo*, specifies a particular
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password based encryption (or PBE) algorithm. If you don't specify a
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PBE, a sensible default will be used.
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.. cpp:function:: std::string PKCS8::PEM_encode(const Private_Key& key, \
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RandomNumberGenerator& rng, const std::string& pass, const std::string& pbe_algo = "")
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This formats the key in the same manner as ``BER_encode``, but additionally
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encodes it into a text format with identifying headers. Using PEM encoding
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is *highly* recommended for many reasons, including compatibility with other
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software, for transmission over 8-bit unclean channels, because it can be
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identified by a human without special tools, and because it sometimes allows
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more sane behavior of tools that process the data.
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Unencrypted serialization is also supported.
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.. warning::
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In most situations, using unecrypted private key storage is a bad idea,
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because anyone can come along and grab the private key without having to
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know any passwords or other secrets. Unless you have very particular
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security requirements, always use the versions that encrypt the key based on
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a passphrase, described above.
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.. cpp:function:: SecureVector<byte> PKCS8::BER_encode(const Private_Key& key)
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Serializes the private key and returns the result.
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.. cpp:function:: std::string PKCS8::PEM_encode(const Private_Key& key)
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Serializes the private key, base64 encodes it, and returns the
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result.
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Last but not least, there are some functions that will load (and
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decrypt, if necessary) a PKCS #8 private key:
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.. cpp:function:: Private_Key* PKCS8::load_key(DataSource& in, \
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RandomNumberGenerator& rng, const User_Interface& ui)
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.. cpp:function:: Private_Key* PKCS8::load_key(DataSource& in, \
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RandomNumberGenerator& rng, std::string passphrase = "")
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.. cpp:function:: Private_Key* PKCS8::load_key(const std::string& filename, \
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RandomNumberGenerator& rng, const User_Interface& ui)
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.. cpp:function:: Private_Key* PKCS8::load_key(const std::string& filename, \
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RandomNumberGenerator& rng, const std::string& passphrase = "")
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These functions will return an object allocated key object based on the data
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from whatever source it is using (assuming, of course, the source is in fact
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storing a representation of a private key, and the decryption was
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sucessful). The encoding used (PEM or BER) need not be specified; the format
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will be detected automatically. The key is allocated with ``new``, and should
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be released with ``delete`` when you are done with it. The first takes a
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generic ``DataSource`` that you have to create - the other is a simple wrapper
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functions that take either a filename or a memory buffer and create the
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appropriate ``DataSource``.
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The versions taking a ``std::string`` attempt to decrypt using the password
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given (if the key is encrypted; if it is not, the passphase value will be
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ignored). If the passphrase does not decrypt the key, an exception will be
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thrown.
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The ones taking a ``User_Interface`` provide a simple callback interface which
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makes handling incorrect passphrases and such a bit simpler. A
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``User_Interface`` has very little to do with talking to users; it's just a
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way to glue together Botan and whatever user interface you happen to be using.
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.. note::
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In a future version, it is likely that ``User_Interface`` will be
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replaced by a simple callback using ``std::function``.
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To use ``User_Interface``, derive a subclass and implement:
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.. cpp:function:: std::string User_Interface::get_passphrase(const std::string& what, \
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const std::string& source, UI_Result& result) const
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The ``what`` argument specifies what the passphrase is needed for (for
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example, PKCS #8 key loading passes ``what`` as "PKCS #8 private key"). This
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lets you provide the user with some indication of *why* your application is
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asking for a passphrase; feel free to pass the string through ``gettext(3)``
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or moral equivalent for i18n purposes. Similarly, ``source`` specifies where
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the data in question came from, if available (for example, a file name). If
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the source is not available for whatever reason, then ``source`` will be an
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empty string; be sure to account for this possibility.
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The function returns the passphrase as the return value, and a status code
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in ``result`` (either ``OK`` or ``CANCEL_ACTION``). If ``CANCEL_ACTION`` is
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returned in ``result``, then the return value will be ignored, and the
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caller will take whatever action is necessary (typically, throwing an
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exception stating that the passphrase couldn't be determined). In the
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specific case of PKCS #8 key decryption, a ``Decoding_Error`` exception will
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be thrown; your UI should assume this can happen, and provide appropriate
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error handling (such as putting up a dialog box informing the user of the
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situation, and canceling the operation in progress).
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.. _serializing_public_keys:
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Serializing Public Keys
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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To import and export public keys, use:
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.. cpp:function:: MemoryVector<byte> X509::BER_encode(const Public_Key& key)
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.. cpp:function:: std::string X509::PEM_encode(const Public_Key& key)
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.. cpp:function:: Public_Key* X509::load_key(DataSource& in)
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.. cpp:function:: Public_Key* X509::load_key(const SecureVector<byte>& buffer)
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.. cpp:function:: Public_Key* X509::load_key(const std::string& filename)
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These functions operate in the same way as the ones described in
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:ref:`serializing_private_keys`, except that no encryption option is
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availabe.
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.. _dl_group:
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DL_Group
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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As described in :ref:`creating_new_private_keys`, a discrete logarithm group
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can be shared among many keys, even keys created by users who do not trust
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each other. However, it is necessary to trust the entity who created the
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group; that is why organization like NIST use algorithms which generate groups
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in a deterministic way such that creating a bogus group would require breaking
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some trusted cryptographic primitive like SHA-2.
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Instantiating a ``DL_Group`` simply requires calling
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.. cpp:function:: DL_Group::DL_Group(const std::string& name)
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The *name* parameter is a specially formatted string that consists of three
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things, the type of the group ("modp" or "dsa"), the creator of the group,
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and the size of the group in bits, all delimited by '/' characters.
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Currently all "modp" groups included in botan are ones defined by the
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Internet Engineering Task Force, so the provider is "ietf", and the strings
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look like "modp/ietf/N" where N can be any of 768, 1024, 1536, 2048, 3072,
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4096, 6144, or 8192. This group type is used for Diffie-Hellman and ElGamal
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algorithms.
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The other type, "dsa" is used for DSA and Nyberg-Rueppel keys. They can
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also be used with Diffie-Hellman and ElGamal, but this is less common. The
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currently available groups are "dsa/jce/N" for N in 512, 768, or 1024, and
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"dsa/botan/N" with N being 2048 or 3072. The "jce" groups are the standard
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DSA groups used in the Java Cryptography Extensions, while the "botan"
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groups were randomly generated using the FIPS 186-3 algorithm by the library
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maintainers.
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You can generate a new random group using
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.. cpp:function:: DL_Group::DL_Group(RandomNumberGenerator& rng, \
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PrimeType type, size_t pbits, size_t qbits = 0)
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The *type* can be either ``Strong``, ``Prime_Subgroup``, or
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``DSA_Kosherizer``. *pbits* specifies the size of the prime in
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bits. If the *type* is ``Prime_Subgroup`` or ``DSA_Kosherizer``,
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then *qbits* specifies the size of the subgroup.
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You can serialize a ``DL_Group`` using
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.. cpp:function:: SecureVector<byte> DL_Group::DER_Encode(Format format)
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or
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.. cpp:function:: std::string DL_Group::PEM_encode(Format format)
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where *format* is any of
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* ``ANSI_X9_42`` (or ``DH_PARAMETERS``) for modp groups
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* ``ANSI_X9_57`` (or ``DSA_PARAMETERS``) for DSA-style groups
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* ``PKCS_3`` is an older format for modp groups; it should only
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be used for backwards compatability.
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You can reload a serialized group using
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.. cpp:function:: void DL_Group::BER_decode(DataSource& source, Format format)
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.. cpp:function:: void DL_Group::PEM_decode(DataSource& source)
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.. _ec_group:
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EC_Group
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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An ``EC_Group`` is initialized by passing the name of the
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group to be used to the constructor. These groups have
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semi-standardized names like "secp256r1" and "brainpool512r1".
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Key Checking
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---------------------------------
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Most public key algorithms have limitations or restrictions on their
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parameters. For example RSA requires an odd exponent, and algorithms
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based on the discrete logarithm problem need a generator $> 1$.
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Each public key type has a function
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.. cpp:function:: bool Public_Key::check_key(RandomNumberGenerator& rng, bool strong)
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This function performs a number of algorithm-specific tests that the key
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seems to be mathematically valid and consistent, and returns true if all of
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the tests pass.
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It does not have anything to do with the validity of the key for any
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particular use, nor does it have anything to do with certificates that link
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a key (which, after all, is just some numbers) with a user or other
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entity. If *strong* is ``true``, then it does "strong" checking, which
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includes expensive operations like primality checking.
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Encryption
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---------------------------------
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Safe public key encryption requires the use of a padding scheme which hides
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the underlying mathematical properties of the algorithm. Additionally, they
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will add randomness, so encrypting the same plaintext twice produces two
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different ciphertexts.
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The primary interface for encryption is
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.. cpp:class:: PK_Encryptor
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.. cpp:function:: SecureVector<byte> encrypt( \
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const byte* in, size_t length, RandomNumberGenerator& rng) const
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.. cpp:function:: SecureVector<byte> encrypt( \
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const MemoryRegion<byte>& in, RandomNumberGenerator& rng) const
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These encrypt a message, returning the ciphertext.
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.. cpp:function:: size_t maximum_input_size() const
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Returns the maximum size of the message that can be processed, in
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bytes. If you call :cpp:func:`PK_Encryptor::encrypt` with a value larger
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than this the operation will fail with an exception.
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:cpp:class:`PK_Encryptor` is only an interface - to actually encrypt you have
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to create an implementation, of which there are currently two available in the
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library, :cpp:class:`PK_Encryptor_EME` and :cpp:class:`DLIES_Encryptor`. DLIES
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is a standard method (from IEEE 1363) that uses a key agreement technique such
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as DH or ECDH to perform message encryption. Normally, public key encryption
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is done using algorithms which support it directly, such as RSA or ElGamal;
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these use the EME class:
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.. cpp:class:: PK_Encryptor_EME
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.. cpp:function:: PK_Encryptor_EME(const Public_Key& key, std::string eme)
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With *key* being the key you want to encrypt messages to. The padding
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method to use is specified in *eme*.
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The recommended values for *eme* is "EME1(SHA-1)" or "EME1(SHA-256)". If
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you need compatability with protocols using the PKCS #1 v1.5 standard,
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you can also use "EME-PKCS1-v1_5".
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.. cpp:class:: DLIES_Encryptor
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Available in the header ``dlies.h``
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.. cpp:function:: DLIES_Encryptor(const PK_Key_Agreement_Key& key, \
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KDF* kdf, MessageAuthenticationCode* mac, size_t mac_key_len = 20)
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Where *kdf* is a key derivation function (see
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||
|
:ref:`key_derivation_function`) and *mac* is a
|
||
|
MessageAuthenticationCode.
|
||
|
|
||
|
The decryption classes are named ``PK_Decryptor``, ``PK_Decryptor_EME``, and
|
||
|
``DLIES_Decryptor``. They are created in the exact same way, except they take
|
||
|
the private key, and the processing function is named ``decrypt``.
|
||
|
|
||
|
|
||
|
Signatures
|
||
|
---------------------------------
|
||
|
|
||
|
Signature generation is performed using
|
||
|
|
||
|
.. cpp:class:: PK_Signer
|
||
|
|
||
|
.. cpp:function:: PK_Signer(const Private_Key& key, \
|
||
|
const std::string& emsa, \
|
||
|
Signature_Format format = IEEE_1363)
|
||
|
|
||
|
Constructs a new signer object for the private key *key* using the
|
||
|
signature format *emsa*. The key must support signature operations. In
|
||
|
the current version of the library, this includes RSA, DSA, ECDSA, GOST
|
||
|
34.10-2001, Nyberg-Rueppel, and Rabin-Williams. Other signature schemes
|
||
|
may be supported in the future.
|
||
|
|
||
|
Currently available values for *emsa* include EMSA1, EMSA2, EMSA3, EMSA4,
|
||
|
and Raw. All of them, except Raw, take a parameter naming a message
|
||
|
digest function to hash the message with. The Raw encoding signs the
|
||
|
input directly; if the message is too big, the signing operation will
|
||
|
fail. Raw is not useful except in very specialized applications. Examples
|
||
|
are "EMSA1(SHA-1)" and "EMSA4(SHA-256)".
|
||
|
|
||
|
For RSA, use EMSA4 (also called PSS) unless you need compatability with
|
||
|
software that uses the older PKCS #1 v1.5 standard, in which case use
|
||
|
EMSA3 (also called "EMSA-PKCS1-v1_5"). For DSA, ECDSA, GOST 34.10-2001,
|
||
|
and Nyberg-Rueppel, you should use EMSA1.
|
||
|
|
||
|
The *format* defaults to ``IEEE_1363`` which is the only available
|
||
|
format for RSA. For DSA and ECDSA, you can also use
|
||
|
``DER_SEQUENCE``, which will format the signature as an ASN.1
|
||
|
SEQUENCE value.
|
||
|
|
||
|
.. cpp:function:: void update(const byte* in, size_t length)
|
||
|
.. cpp:function:: void update(const MemoryRegion<byte>& in)
|
||
|
.. cpp:function:: void update(byte in)
|
||
|
|
||
|
These add more data to be included in the signature
|
||
|
computation. Typically, the input will be provided directly to a
|
||
|
hash function.
|
||
|
|
||
|
.. cpp:function:: SecureVector<byte> signature(RandomNumberGenerator& rng)
|
||
|
|
||
|
Creates the signature and returns it
|
||
|
|
||
|
.. cpp:function:: SecureVector<byte> sign_message( \
|
||
|
const byte* in, size_t length, RandomNumberGenerator& rng)
|
||
|
|
||
|
.. cpp:function:: SecureVector<byte> sign_message( \
|
||
|
const MemoryRegion<byte>& in, RandomNumberGenerator& rng)
|
||
|
|
||
|
These functions are equivalent to calling
|
||
|
:cpp:func:`PK_Signer::update` and then
|
||
|
:cpp:func:`PK_Signer::signature`. Any data previously provided
|
||
|
using ``update`` will be included.
|
||
|
|
||
|
Signatures are verified using
|
||
|
|
||
|
.. cpp:class:: PK_Verifier
|
||
|
|
||
|
.. cpp:function:: PK_Verifier(const Public_Key& pub_key, \
|
||
|
const std::string& emsa, Signature_Format format = IEEE_1363)
|
||
|
|
||
|
Construct a new verifier for signatures assicated with public
|
||
|
key *pub_key*. The *emsa* and *format* should be the same as
|
||
|
that used by the signer.
|
||
|
|
||
|
.. cpp:function:: void update(const byte* in, size_t length)
|
||
|
.. cpp:function:: void update(const MemoryRegion<byte>& in)
|
||
|
.. cpp:function:: void update(byte in)
|
||
|
|
||
|
Add further message data that is purportedly assocated with the
|
||
|
signature that will be checked.
|
||
|
|
||
|
.. cpp:function:: bool check_signature(const byte* sig, size_t length)
|
||
|
.. cpp:function:: bool check_signature(const MemoryRegion<byte>& sig)
|
||
|
|
||
|
Check to see if *sig* is a valid signature for the message data
|
||
|
that was written in. Return true if so. This function clears the
|
||
|
internal message state, so after this call you can call
|
||
|
:cpp:func:`PK_Verifier::update` to start verifying another
|
||
|
message.
|
||
|
|
||
|
.. cpp:function:: bool verify_message(const byte* msg, size_t msg_length, \
|
||
|
const byte* sig, size_t sig_length)
|
||
|
|
||
|
.. cpp:function:: bool verify_message(const MemoryRegion<byte>& msg, \
|
||
|
const MemoryRegion<byte>& sig)
|
||
|
|
||
|
These are equivalent to calling :cpp:func:`PK_Verifier::update`
|
||
|
on *msg* and then calling :cpp:func:`PK_Verifier::check_signature`
|
||
|
on *sig*.
|
||
|
|
||
|
Here is an example of DSA signature generation
|
||
|
|
||
|
.. literalinclude:: examples/dsa_sign.cpp
|
||
|
|
||
|
Here is an example that verifies DSA signatures
|
||
|
|
||
|
.. literalinclude:: examples/dsa_ver.cpp
|
||
|
|
||
|
Key Agreement
|
||
|
---------------------------------
|
||
|
|
||
|
You can get a hold of a ``PK_Key_Agreement_Scheme`` object by calling
|
||
|
``get_pk_kas`` with a key that is of a type that supports key
|
||
|
agreement (such as a Diffie-Hellman key stored in a ``DH_PrivateKey``
|
||
|
object), and the name of a key derivation function. This can be "Raw",
|
||
|
meaning the output of the primitive itself is returned as the key, or
|
||
|
"KDF1(hash)" or "KDF2(hash)" where "hash" is any string you happen to
|
||
|
like (hopefully you like strings like "SHA-256" or "RIPEMD-160"), or
|
||
|
"X9.42-PRF(keywrap)", which uses the PRF specified in ANSI X9.42. It
|
||
|
takes the name or OID of the key wrap algorithm that will be used to
|
||
|
encrypt a content encryption key.
|
||
|
|
||
|
How key agreement works is that you trade public values with some
|
||
|
other party, and then each of you runs a computation with the other's
|
||
|
value and your key (this should return the same result to both
|
||
|
parties). This computation can be called by using
|
||
|
``derive_key`` with either a byte array/length pair, or a
|
||
|
``SecureVector<byte>`` than holds the public value of the other
|
||
|
party. The last argument to either call is a number that specifies how
|
||
|
long a key you want.
|
||
|
|
||
|
Depending on the KDF you're using, you *might not* get back a key
|
||
|
of the size you requested. In particular "Raw" will return a number
|
||
|
about the size of the Diffie-Hellman modulus, and KDF1 can only return
|
||
|
a key that is the same size as the output of the hash. KDF2, on the
|
||
|
other hand, will always give you a key exactly as long as you request,
|
||
|
regardless of the underlying hash used with it. The key returned is a
|
||
|
``SymmetricKey``, ready to pass to a block cipher, MAC, or other
|
||
|
symmetric algorithm.
|
||
|
|
||
|
The public value that should be used can be obtained by calling
|
||
|
``public_data``, which exists for any key that is associated with a
|
||
|
key agreement algorithm. It returns a ``SecureVector<byte>``.
|
||
|
|
||
|
"KDF2(SHA-256)" is by far the preferred algorithm for key derivation
|
||
|
in new applications. The X9.42 algorithm may be useful in some
|
||
|
circumstances, but unless you need X9.42 compatibility, KDF2 is easier
|
||
|
to use.
|
||
|
|
||
|
An example of using Diffie-Hellman:
|
||
|
|
||
|
.. literalinclude:: examples/dh.cpp
|