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5091aadc22
Because the quicserver utility supports expressly listening in ipv4/6 mode, its possible/likely that the server will listen on an ipv4 address, while the clients will connect via ipv6, leading to connection failures. Augment quic demo clients to afford them the same -6 option that the server has so that connection family can be co-ordinated Reviewed-by: Nicola Tuveri <nic.tuv@gmail.com> Reviewed-by: Hugo Landau <hlandau@openssl.org> Reviewed-by: Matt Caswell <matt@openssl.org> Reviewed-by: Richard Levitte <levitte@openssl.org> (Merged from https://github.com/openssl/openssl/pull/22577)
382 lines
16 KiB
Plaintext
382 lines
16 KiB
Plaintext
=pod
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=begin comment
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NB: Changes to the source code samples in this file should also be reflected in
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demos/guide/quic-client-block.c
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=end comment
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=head1 NAME
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ossl-guide-quic-client-block
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- OpenSSL Guide: Writing a simple blocking QUIC client
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=head1 SIMPLE BLOCKING QUIC CLIENT EXAMPLE
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This page will present various source code samples demonstrating how to write
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a simple blocking QUIC client application which connects to a server, sends an
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HTTP/1.0 request to it, and reads back the response. Note that HTTP/1.0 over
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QUIC is non-standard and will not be supported by real world servers. This is
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for demonstration purposes only.
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We assume that you already have OpenSSL installed on your system; that you
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already have some fundamental understanding of OpenSSL concepts, TLS and QUIC
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(see L<ossl-guide-libraries-introduction(7)>, L<ossl-guide-tls-introduction(7)>
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and L<ossl-guide-quic-introduction(7)>); and that you know how to
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write and build C code and link it against the libcrypto and libssl libraries
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that are provided by OpenSSL. It also assumes that you have a basic
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understanding of UDP/IP and sockets. The example code that we build in this
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tutorial will amend the blocking TLS client example that is covered in
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L<ossl-guide-tls-client-block(7)>. Only the differences between that client and
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this one will be discussed so we also assume that you have run through and
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understand that tutorial.
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For this tutorial our client will be using a single QUIC stream. A subsequent
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tutorial will discuss how to write a multi-stream client (see
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L<ossl-guide-quic-multi-stream(7)>).
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The complete source code for this example blocking QUIC client is available in
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the C<demos/guide> directory of the OpenSSL source distribution in the file
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C<quic-client-block.c>. It is also available online at
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L<https://github.com/openssl/openssl/blob/master/demos/guide/quic-client-block.c>.
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=head2 Creating the SSL_CTX and SSL objects
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In the TLS tutorial (L<ossl-guide-tls-client-block(7)>) we created an B<SSL_CTX>
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object for our client and used it to create an B<SSL> object to represent the
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TLS connection. A QUIC connection works in exactly the same way. We first create
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an B<SSL_CTX> object and then use it to create an B<SSL> object to represent the
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QUIC connection.
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As in the TLS example the first step is to create an B<SSL_CTX> object for our
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client. This is done in the same way as before except that we use a different
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"method". OpenSSL offers two different QUIC client methods, i.e.
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L<OSSL_QUIC_client_method(3)> and L<OSSL_QUIC_client_thread_method(3)>.
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The first one is the equivalent of L<TLS_client_method(3)> but for the QUIC
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protocol. The second one is the same, but it will additionally create a
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background thread for handling time based events (known as "thread assisted
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mode", see L<ossl-guide-quic-introduction(7)>). For this tutorial we will be
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using L<OSSL_QUIC_client_method(3)> because we will not be leaving the QUIC
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connection idle in our application and so thread assisted mode is not needed.
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/*
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* Create an SSL_CTX which we can use to create SSL objects from. We
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* want an SSL_CTX for creating clients so we use OSSL_QUIC_client_method()
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* here.
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*/
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ctx = SSL_CTX_new(OSSL_QUIC_client_method());
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if (ctx == NULL) {
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printf("Failed to create the SSL_CTX\n");
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goto end;
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}
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The other setup steps that we applied to the B<SSL_CTX> for TLS also apply to
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QUIC except for restricting the TLS versions that we are willing to accept. The
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QUIC protocol implementation in OpenSSL currently only supports TLSv1.3. There
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is no need to call L<SSL_CTX_set_min_proto_version(3)> or
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L<SSL_CTX_set_max_proto_version(3)> in an OpenSSL QUIC application, and any such
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call will be ignored.
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Once the B<SSL_CTX> is created, the B<SSL> object is constructed in exactly the
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same way as for the TLS application.
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=head2 Creating the socket and BIO
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A major difference between TLS and QUIC is the underlying transport protocol.
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TLS uses TCP while QUIC uses UDP. The way that the QUIC socket is created in our
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example code is much the same as for TLS. We use the L<BIO_lookup_ex(3)> and
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L<BIO_socket(3)> helper functions as we did in the previous tutorial except that
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we pass B<SOCK_DGRAM> as an argument to indicate UDP (instead of B<SOCK_STREAM>
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for TCP).
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/*
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* Lookup IP address info for the server.
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*/
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if (!BIO_lookup_ex(hostname, port, BIO_LOOKUP_CLIENT, family, SOCK_DGRAM, 0,
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&res))
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return NULL;
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/*
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* Loop through all the possible addresses for the server and find one
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* we can connect to.
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*/
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for (ai = res; ai != NULL; ai = BIO_ADDRINFO_next(ai)) {
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/*
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* Create a TCP socket. We could equally use non-OpenSSL calls such
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* as "socket" here for this and the subsequent connect and close
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* functions. But for portability reasons and also so that we get
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* errors on the OpenSSL stack in the event of a failure we use
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* OpenSSL's versions of these functions.
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*/
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sock = BIO_socket(BIO_ADDRINFO_family(ai), SOCK_DGRAM, 0, 0);
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if (sock == -1)
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continue;
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/* Connect the socket to the server's address */
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if (!BIO_connect(sock, BIO_ADDRINFO_address(ai), 0)) {
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BIO_closesocket(sock);
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sock = -1;
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continue;
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}
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/* Set to nonblocking mode */
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if (!BIO_socket_nbio(sock, 1)) {
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BIO_closesocket(sock);
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sock = -1;
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continue;
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}
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break;
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}
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if (sock != -1) {
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*peer_addr = BIO_ADDR_dup(BIO_ADDRINFO_address(ai));
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if (*peer_addr == NULL) {
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BIO_closesocket(sock);
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return NULL;
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}
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}
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/* Free the address information resources we allocated earlier */
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BIO_ADDRINFO_free(res);
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You may notice a couple of other differences between this code and the version
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that we used for TLS.
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Firstly, we set the socket into nonblocking mode. This must always be done for
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an OpenSSL QUIC application. This may be surprising considering that we are
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trying to write a blocking client. Despite this the B<SSL> object will still
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have blocking behaviour. See L<ossl-guide-quic-introduction(7)> for further
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information on this.
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Secondly, we take note of the IP address of the peer that we are connecting to.
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We store that information away. We will need it later.
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See L<BIO_lookup_ex(3)>, L<BIO_socket(3)>, L<BIO_connect(3)>,
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L<BIO_closesocket(3)>, L<BIO_ADDRINFO_next(3)>, L<BIO_ADDRINFO_address(3)>,
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L<BIO_ADDRINFO_free(3)> and L<BIO_ADDR_dup(3)> for further information on the
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functions used here. In the above example code the B<hostname> and B<port>
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variables are strings, e.g. "www.example.com" and "443".
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As for our TLS client, once the socket has been created and connected we need to
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associate it with a BIO object:
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BIO *bio;
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/* Create a BIO to wrap the socket */
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bio = BIO_new(BIO_s_datagram());
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if (bio == NULL) {
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BIO_closesocket(sock);
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return NULL;
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}
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/*
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* Associate the newly created BIO with the underlying socket. By
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* passing BIO_CLOSE here the socket will be automatically closed when
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* the BIO is freed. Alternatively you can use BIO_NOCLOSE, in which
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* case you must close the socket explicitly when it is no longer
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* needed.
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*/
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BIO_set_fd(bio, sock, BIO_CLOSE);
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Note the use of L<BIO_s_datagram(3)> here as opposed to L<BIO_s_socket(3)> that
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we used for our TLS client. This is again due to the fact that QUIC uses UDP
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instead of TCP for its transport layer. See L<BIO_new(3)>, L<BIO_s_datagram(3)>
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and L<BIO_set_fd(3)> for further information on these functions.
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=head2 Setting the server's hostname
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As in the TLS tutorial we need to set the server's hostname both for SNI (Server
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Name Indication) and for certificate validation purposes. The steps for this are
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identical to the TLS tutorial and won't be repeated here.
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=head2 Setting the ALPN
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ALPN (Application-Layer Protocol Negotiation) is a feature of TLS that enables
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the application to negotiate which protocol will be used over the connection.
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For example, if you intend to use HTTP/3 over the connection then the ALPN value
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for that is "h3" (see
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L<https://www.iana.org/assignments/tls-extensiontype-values/tls-extensiontype-values.xml#alpn-protocol-ids>).
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OpenSSL provides the ability for a client to specify the ALPN to use via the
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L<SSL_set_alpn_protos(3)> function. This is optional for a TLS client and so our
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simple client that we developed in L<ossl-guide-tls-client-block(7)> did not use
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it. However QUIC mandates that the TLS handshake used in establishing a QUIC
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connection must use ALPN.
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unsigned char alpn[] = { 8, 'h', 't', 't', 'p', '/', '1', '.', '0' };
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/* SSL_set_alpn_protos returns 0 for success! */
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if (SSL_set_alpn_protos(ssl, alpn, sizeof(alpn)) != 0) {
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printf("Failed to set the ALPN for the connection\n");
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goto end;
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}
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The ALPN is specified using a length prefixed array of unsigned chars (it is not
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a NUL terminated string). Our original TLS blocking client demo was using
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HTTP/1.0. We will use the same for this example. Unlike most OpenSSL functions
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L<SSL_set_alpn_protos(3)> returns zero for success and nonzero for failure.
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=head2 Setting the peer address
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An OpenSSL QUIC application must specify the target address of the server that
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is being connected to. In L</Creating the socket and BIO> above we saved that
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address away for future use. Now we need to use it via the
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L<SSL_set1_initial_peer_addr(3)> function.
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/* Set the IP address of the remote peer */
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if (!SSL_set1_initial_peer_addr(ssl, peer_addr)) {
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printf("Failed to set the initial peer address\n");
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goto end;
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}
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Note that we will need to free the B<peer_addr> value that we allocated via
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L<BIO_ADDR_dup(3)> earlier:
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BIO_ADDR_free(peer_addr);
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=head2 The handshake and application data transfer
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Once initial setup of the B<SSL> object is complete then we perform the
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handshake via L<SSL_connect(3)> in exactly the same way as we did for the TLS
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client, so we won't repeat it here.
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We can also perform data transfer using a default QUIC stream that is
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automatically associated with the B<SSL> object for us. We can transmit data
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using L<SSL_write_ex(3)>, and receive data using L<SSL_read_ex(3)> in the same
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way as for TLS. The main difference is that we have to account for failures
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slightly differently. With QUIC the stream can be reset by the peer (which is
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fatal for that stream), but the underlying connection itself may still be
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healthy.
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/*
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* Get up to sizeof(buf) bytes of the response. We keep reading until the
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* server closes the connection.
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*/
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while (SSL_read_ex(ssl, buf, sizeof(buf), &readbytes)) {
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/*
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* OpenSSL does not guarantee that the returned data is a string or
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* that it is NUL terminated so we use fwrite() to write the exact
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* number of bytes that we read. The data could be non-printable or
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* have NUL characters in the middle of it. For this simple example
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* we're going to print it to stdout anyway.
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*/
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fwrite(buf, 1, readbytes, stdout);
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}
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/* In case the response didn't finish with a newline we add one now */
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printf("\n");
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/*
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* Check whether we finished the while loop above normally or as the
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* result of an error. The 0 argument to SSL_get_error() is the return
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* code we received from the SSL_read_ex() call. It must be 0 in order
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* to get here. Normal completion is indicated by SSL_ERROR_ZERO_RETURN. In
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* QUIC terms this means that the peer has sent FIN on the stream to
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* indicate that no further data will be sent.
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*/
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switch (SSL_get_error(ssl, 0)) {
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case SSL_ERROR_ZERO_RETURN:
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/* Normal completion of the stream */
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break;
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case SSL_ERROR_SSL:
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/*
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* Some stream fatal error occurred. This could be because of a stream
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* reset - or some failure occurred on the underlying connection.
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*/
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switch (SSL_get_stream_read_state(ssl)) {
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case SSL_STREAM_STATE_RESET_REMOTE:
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printf("Stream reset occurred\n");
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/* The stream has been reset but the connection is still healthy. */
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break;
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case SSL_STREAM_STATE_CONN_CLOSED:
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printf("Connection closed\n");
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/* Connection is already closed. Skip SSL_shutdown() */
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goto end;
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default:
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printf("Unknown stream failure\n");
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break;
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}
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break;
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default:
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/* Some other unexpected error occurred */
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printf ("Failed reading remaining data\n");
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break;
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}
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In the above code example you can see that B<SSL_ERROR_SSL> indicates a stream
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fatal error. We can use L<SSL_get_stream_read_state(3)> to determine whether the
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stream has been reset, or if some other fatal error has occurred.
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=head2 Shutting down the connection
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In the TLS tutorial we knew that the server had finished sending data because
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L<SSL_read_ex(3)> returned 0, and L<SSL_get_error(3)> returned
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B<SSL_ERROR_ZERO_RETURN>. The same is true with QUIC except that
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B<SSL_ERROR_ZERO_RETURN> should be interpreted slightly differently. With TLS
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we knew that this meant that the server had sent a "close_notify" alert. No
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more data will be sent from the server on that connection.
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With QUIC it means that the server has indicated "FIN" on the stream, meaning
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that it will no longer send any more data on that stream. However this only
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gives us information about the stream itself and does not tell us anything about
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the underlying connection. More data could still be sent from the server on some
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other stream. Additionally, although the server will not send any more data to
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the client, it does not prevent the client from sending more data to the server.
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In this tutorial, once we have finished reading data from the server on the one
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stream that we are using, we will close the connection down. As before we do
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this via the L<SSL_shutdown(3)> function. This example for QUIC is very similar
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to the TLS version. However the L<SSL_shutdown(3)> function will need to be
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called more than once:
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/*
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* Repeatedly call SSL_shutdown() until the connection is fully
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* closed.
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*/
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do {
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ret = SSL_shutdown(ssl);
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if (ret < 0) {
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printf("Error shutting down: %d\n", ret);
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goto end;
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}
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} while (ret != 1);
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The shutdown process is in two stages. In the first stage we wait until all the
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data we have buffered for sending on any stream has been successfully sent and
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acknowledged by the peer, and then we send a CONNECTION_CLOSE to the peer to
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indicate that the connection is no longer usable. This immediately closes the
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connection and no more data can be sent or received. L<SSL_shutdown(3)> returns
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0 once the first stage has been completed.
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In the second stage the connection enters a "closing" state. Application data
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cannot be sent or received in this state, but late arriving packets coming from
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the peer will be handled appropriately. Once this stage has completed
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successfully L<SSL_shutdown(3)> will return 1 to indicate success.
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=head1 FURTHER READING
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See L<ossl-guide-quic-multi-stream(7)> to read a tutorial on how to modify the
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client developed on this page to support multiple streams.
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=head1 SEE ALSO
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L<ossl-guide-introduction(7)>, L<ossl-guide-libraries-introduction(7)>,
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L<ossl-guide-libssl-introduction(7)>, L<ossl-guide-tls-introduction(7)>,
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L<ossl-guide-tls-client-block(7)>, L<ossl-guide-quic-introduction(7)>
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=head1 COPYRIGHT
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Copyright 2023 The OpenSSL Project Authors. All Rights Reserved.
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Licensed under the Apache License 2.0 (the "License"). You may not use
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this file except in compliance with the License. You can obtain a copy
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in the file LICENSE in the source distribution or at
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L<https://www.openssl.org/source/license.html>.
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=cut
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