man.bsd.lv manual page server

DESCRIPTION

DTLSv1_listen() is currently implemented as a macro.

Datagram based protocols can be susceptible to Denial of Service attacks. A DTLS attacker could, for example, submit a series of handshake initiation requests that cause the server to allocate state (and possibly perform cryptographic operations) thus consuming server resources. The attacker could also (with UDP) quite simply forge the source IP address in such an attack.

As a counter measure to that DTLS includes a stateless cookie mechanism. The idea is that when a client attempts to connect to a server it sends a ClientHello message. The server responds with a HelloVerifyRequest which contains a unique cookie. The client then resends the ClientHello, but this time includes the cookie in the message thus proving that the client is capable of receiving messages sent to that address. All of this can be done by the server without allocating any state, and thus without consuming expensive resources.

OpenSSL implements this capability via the DTLSv1_listen() function. The ssl parameter should be a newly allocated SSL object with its read and write BIOs set, in the same way as might be done for a call to SSL_accept(3). Typically the read BIO will be in an "unconnected" state and thus capable of receiving messages from any peer.

When a ClientHello is received that contains a cookie that has been verified, then DTLSv1_listen() will return with the ssl parameter updated into a state where the handshake can be continued by a call to (for example) SSL_accept(3). Additionally the struct sockaddr pointed to by peer will be filled in with details of the peer that sent the ClientHello. It is the calling code's responsibility to ensure that the peer location is sufficiently large to accommodate the addressing scheme in use. For example this might be done by allocating space for a struct sockaddr_storage and casting the pointer to it to a struct sockaddr * for the call to DTLSv1_listen(). Typically user code is expected to "connect" the underlying socket to the peer and continue the handshake in a connected state.

Prior to calling DTLSv1_listen() user code must ensure that cookie generation and verification callbacks have been set up using SSL_CTX_set_cookie_generate_cb() and SSL_CTX_set_cookie_verify_cb() respectively.

Since DTLSv1_listen() operates entirely statelessly whilst processing incoming ClientHellos, it is unable to process fragmented messages (since this would require the allocation of state). An implication of this is that DTLSv1_listen() only supports ClientHellos that fit inside a single datagram.