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.\" ========================================================================
.\"
.IX Title "OSSL-GUIDE-QUIC-CLIENT-BLOCK 7ossl"
.TH OSSL-GUIDE-QUIC-CLIENT-BLOCK 7ossl "2024-10-22" "3.4.0" "OpenSSL"
.\" For nroff, turn off justification. Always turn off hyphenation; it makes
.\" way too many mistakes in technical documents.
.if n .ad l
.nh
.SH "NAME"
ossl\-guide\-quic\-client\-block
\&\- OpenSSL Guide: Writing a simple blocking QUIC client
.SH "SIMPLE BLOCKING QUIC CLIENT EXAMPLE"
.IX Header "SIMPLE BLOCKING QUIC CLIENT EXAMPLE"
This page will present various source code samples demonstrating how to write
a simple blocking \s-1QUIC\s0 client application which connects to a server, sends an
\&\s-1HTTP/1.0\s0 request to it, and reads back the response. Note that \s-1HTTP/1.0\s0 over
\&\s-1QUIC\s0 is non-standard and will not be supported by real world servers. This is
for demonstration purposes only.
.PP
We assume that you already have OpenSSL installed on your system; that you
already have some fundamental understanding of OpenSSL concepts, \s-1TLS\s0 and \s-1QUIC\s0
(see \fBossl\-guide\-libraries\-introduction\fR\|(7), \fBossl\-guide\-tls\-introduction\fR\|(7)
and \fBossl\-guide\-quic\-introduction\fR\|(7)); and that you know how to
write and build C code and link it against the libcrypto and libssl libraries
that are provided by OpenSSL. It also assumes that you have a basic
understanding of \s-1UDP/IP\s0 and sockets. The example code that we build in this
tutorial will amend the blocking \s-1TLS\s0 client example that is covered in
\&\fBossl\-guide\-tls\-client\-block\fR\|(7). Only the differences between that client and
this one will be discussed so we also assume that you have run through and
understand that tutorial.
.PP
For this tutorial our client will be using a single \s-1QUIC\s0 stream. A subsequent
tutorial will discuss how to write a multi-stream client (see
\&\fBossl\-guide\-quic\-multi\-stream\fR\|(7)).
.PP
The complete source code for this example blocking \s-1QUIC\s0 client is available in
the \f(CW\*(C`demos/guide\*(C'\fR directory of the OpenSSL source distribution in the file
\&\f(CW\*(C`quic\-client\-block.c\*(C'\fR. It is also available online at
<https://github.com/openssl/openssl/blob/master/demos/guide/quic\-client\-block.c>.
.SS "Creating the \s-1SSL_CTX\s0 and \s-1SSL\s0 objects"
.IX Subsection "Creating the SSL_CTX and SSL objects"
In the \s-1TLS\s0 tutorial (\fBossl\-guide\-tls\-client\-block\fR\|(7)) we created an \fB\s-1SSL_CTX\s0\fR
object for our client and used it to create an \fB\s-1SSL\s0\fR object to represent the
\&\s-1TLS\s0 connection. A \s-1QUIC\s0 connection works in exactly the same way. We first create
an \fB\s-1SSL_CTX\s0\fR object and then use it to create an \fB\s-1SSL\s0\fR object to represent the
\&\s-1QUIC\s0 connection.
.PP
As in the \s-1TLS\s0 example the first step is to create an \fB\s-1SSL_CTX\s0\fR object for our
client. This is done in the same way as before except that we use a different
\&\*(L"method\*(R". OpenSSL offers two different \s-1QUIC\s0 client methods, i.e.
\&\fBOSSL_QUIC_client_method\fR\|(3) and \fBOSSL_QUIC_client_thread_method\fR\|(3).
.PP
The first one is the equivalent of \fBTLS_client_method\fR\|(3) but for the \s-1QUIC\s0
protocol. The second one is the same, but it will additionally create a
background thread for handling time based events (known as \*(L"thread assisted
mode\*(R", see \fBossl\-guide\-quic\-introduction\fR\|(7)). For this tutorial we will be
using \fBOSSL_QUIC_client_method\fR\|(3) because we will not be leaving the \s-1QUIC\s0
connection idle in our application and so thread assisted mode is not needed.
.PP
.Vb 10
\& /*
\& * Create an SSL_CTX which we can use to create SSL objects from. We
\& * want an SSL_CTX for creating clients so we use OSSL_QUIC_client_method()
\& * here.
\& */
\& ctx = SSL_CTX_new(OSSL_QUIC_client_method());
\& if (ctx == NULL) {
\& printf("Failed to create the SSL_CTX\en");
\& goto end;
\& }
.Ve
.PP
The other setup steps that we applied to the \fB\s-1SSL_CTX\s0\fR for \s-1TLS\s0 also apply to
\&\s-1QUIC\s0 except for restricting the \s-1TLS\s0 versions that we are willing to accept. The
\&\s-1QUIC\s0 protocol implementation in OpenSSL currently only supports TLSv1.3. There
is no need to call \fBSSL_CTX_set_min_proto_version\fR\|(3) or
\&\fBSSL_CTX_set_max_proto_version\fR\|(3) in an OpenSSL \s-1QUIC\s0 application, and any such
call will be ignored.
.PP
Once the \fB\s-1SSL_CTX\s0\fR is created, the \fB\s-1SSL\s0\fR object is constructed in exactly the
same way as for the \s-1TLS\s0 application.
.SS "Creating the socket and \s-1BIO\s0"
.IX Subsection "Creating the socket and BIO"
A major difference between \s-1TLS\s0 and \s-1QUIC\s0 is the underlying transport protocol.
\&\s-1TLS\s0 uses \s-1TCP\s0 while \s-1QUIC\s0 uses \s-1UDP.\s0 The way that the \s-1QUIC\s0 socket is created in our
example code is much the same as for \s-1TLS.\s0 We use the \fBBIO_lookup_ex\fR\|(3) and
\&\fBBIO_socket\fR\|(3) helper functions as we did in the previous tutorial except that
we pass \fB\s-1SOCK_DGRAM\s0\fR as an argument to indicate \s-1UDP\s0 (instead of \fB\s-1SOCK_STREAM\s0\fR
for \s-1TCP\s0).
.PP
.Vb 6
\& /*
\& * Lookup IP address info for the server.
\& */
\& if (!BIO_lookup_ex(hostname, port, BIO_LOOKUP_CLIENT, family, SOCK_DGRAM, 0,
\& &res))
\& return NULL;
\&
\& /*
\& * Loop through all the possible addresses for the server and find one
\& * we can connect to.
\& */
\& for (ai = res; ai != NULL; ai = BIO_ADDRINFO_next(ai)) {
\& /*
\& * Create a TCP socket. We could equally use non\-OpenSSL calls such
\& * as "socket" here for this and the subsequent connect and close
\& * functions. But for portability reasons and also so that we get
\& * errors on the OpenSSL stack in the event of a failure we use
\& * OpenSSL\*(Aqs versions of these functions.
\& */
\& sock = BIO_socket(BIO_ADDRINFO_family(ai), SOCK_DGRAM, 0, 0);
\& if (sock == \-1)
\& continue;
\&
\& /* Connect the socket to the server\*(Aqs address */
\& if (!BIO_connect(sock, BIO_ADDRINFO_address(ai), 0)) {
\& BIO_closesocket(sock);
\& sock = \-1;
\& continue;
\& }
\&
\& /* Set to nonblocking mode */
\& if (!BIO_socket_nbio(sock, 1)) {
\& BIO_closesocket(sock);
\& sock = \-1;
\& continue;
\& }
\&
\& break;
\& }
\&
\& if (sock != \-1) {
\& *peer_addr = BIO_ADDR_dup(BIO_ADDRINFO_address(ai));
\& if (*peer_addr == NULL) {
\& BIO_closesocket(sock);
\& return NULL;
\& }
\& }
\&
\& /* Free the address information resources we allocated earlier */
\& BIO_ADDRINFO_free(res);
.Ve
.PP
You may notice a couple of other differences between this code and the version
that we used for \s-1TLS.\s0
.PP
Firstly, we set the socket into nonblocking mode. This must always be done for
an OpenSSL \s-1QUIC\s0 application. This may be surprising considering that we are
trying to write a blocking client. Despite this the \fB\s-1SSL\s0\fR object will still
have blocking behaviour. See \fBossl\-guide\-quic\-introduction\fR\|(7) for further
information on this.
.PP
Secondly, we take note of the \s-1IP\s0 address of the peer that we are connecting to.
We store that information away. We will need it later.
.PP
See \fBBIO_lookup_ex\fR\|(3), \fBBIO_socket\fR\|(3), \fBBIO_connect\fR\|(3),
\&\fBBIO_closesocket\fR\|(3), \fBBIO_ADDRINFO_next\fR\|(3), \fBBIO_ADDRINFO_address\fR\|(3),
\&\fBBIO_ADDRINFO_free\fR\|(3) and \fBBIO_ADDR_dup\fR\|(3) for further information on the
functions used here. In the above example code the \fBhostname\fR and \fBport\fR
variables are strings, e.g. \*(L"www.example.com\*(R" and \*(L"443\*(R".
.PP
As for our \s-1TLS\s0 client, once the socket has been created and connected we need to
associate it with a \s-1BIO\s0 object:
.PP
.Vb 1
\& BIO *bio;
\&
\& /* Create a BIO to wrap the socket */
\& bio = BIO_new(BIO_s_datagram());
\& if (bio == NULL) {
\& BIO_closesocket(sock);
\& return NULL;
\& }
\&
\& /*
\& * Associate the newly created BIO with the underlying socket. By
\& * passing BIO_CLOSE here the socket will be automatically closed when
\& * the BIO is freed. Alternatively you can use BIO_NOCLOSE, in which
\& * case you must close the socket explicitly when it is no longer
\& * needed.
\& */
\& BIO_set_fd(bio, sock, BIO_CLOSE);
.Ve
.PP
Note the use of \fBBIO_s_datagram\fR\|(3) here as opposed to \fBBIO_s_socket\fR\|(3) that
we used for our \s-1TLS\s0 client. This is again due to the fact that \s-1QUIC\s0 uses \s-1UDP\s0
instead of \s-1TCP\s0 for its transport layer. See \fBBIO_new\fR\|(3), \fBBIO_s_datagram\fR\|(3)
and \fBBIO_set_fd\fR\|(3) for further information on these functions.
.SS "Setting the server's hostname"
.IX Subsection "Setting the server's hostname"
As in the \s-1TLS\s0 tutorial we need to set the server's hostname both for \s-1SNI\s0 (Server
Name Indication) and for certificate validation purposes. The steps for this are
identical to the \s-1TLS\s0 tutorial and won't be repeated here.
.SS "Setting the \s-1ALPN\s0"
.IX Subsection "Setting the ALPN"
\&\s-1ALPN\s0 (Application-Layer Protocol Negotiation) is a feature of \s-1TLS\s0 that enables
the application to negotiate which protocol will be used over the connection.
For example, if you intend to use \s-1HTTP/3\s0 over the connection then the \s-1ALPN\s0 value
for that is \*(L"h3\*(R" (see
<https://www.iana.org/assignments/tls\-extensiontype\-values/tls\-extensiontype\-values.xml#alpn\-protocol\-ids>).
OpenSSL provides the ability for a client to specify the \s-1ALPN\s0 to use via the
\&\fBSSL_set_alpn_protos\fR\|(3) function. This is optional for a \s-1TLS\s0 client and so our
simple client that we developed in \fBossl\-guide\-tls\-client\-block\fR\|(7) did not use
it. However \s-1QUIC\s0 mandates that the \s-1TLS\s0 handshake used in establishing a \s-1QUIC\s0
connection must use \s-1ALPN.\s0
.PP
.Vb 1
\& unsigned char alpn[] = { 8, \*(Aqh\*(Aq, \*(Aqt\*(Aq, \*(Aqt\*(Aq, \*(Aqp\*(Aq, \*(Aq/\*(Aq, \*(Aq1\*(Aq, \*(Aq.\*(Aq, \*(Aq0\*(Aq };
\&
\& /* SSL_set_alpn_protos returns 0 for success! */
\& if (SSL_set_alpn_protos(ssl, alpn, sizeof(alpn)) != 0) {
\& printf("Failed to set the ALPN for the connection\en");
\& goto end;
\& }
.Ve
.PP
The \s-1ALPN\s0 is specified using a length prefixed array of unsigned chars (it is not
a \s-1NUL\s0 terminated string). Our original \s-1TLS\s0 blocking client demo was using
\&\s-1HTTP/1.0.\s0 We will use the same for this example. Unlike most OpenSSL functions
\&\fBSSL_set_alpn_protos\fR\|(3) returns zero for success and nonzero for failure.
.SS "Setting the peer address"
.IX Subsection "Setting the peer address"
An OpenSSL \s-1QUIC\s0 application must specify the target address of the server that
is being connected to. In \*(L"Creating the socket and \s-1BIO\*(R"\s0 above we saved that
address away for future use. Now we need to use it via the
\&\fBSSL_set1_initial_peer_addr\fR\|(3) function.
.PP
.Vb 5
\& /* Set the IP address of the remote peer */
\& if (!SSL_set1_initial_peer_addr(ssl, peer_addr)) {
\& printf("Failed to set the initial peer address\en");
\& goto end;
\& }
.Ve
.PP
Note that we will need to free the \fBpeer_addr\fR value that we allocated via
\&\fBBIO_ADDR_dup\fR\|(3) earlier:
.PP
.Vb 1
\& BIO_ADDR_free(peer_addr);
.Ve
.SS "The handshake and application data transfer"
.IX Subsection "The handshake and application data transfer"
Once initial setup of the \fB\s-1SSL\s0\fR object is complete then we perform the
handshake via \fBSSL_connect\fR\|(3) in exactly the same way as we did for the \s-1TLS\s0
client, so we won't repeat it here.
.PP
We can also perform data transfer using a default \s-1QUIC\s0 stream that is
automatically associated with the \fB\s-1SSL\s0\fR object for us. We can transmit data
using \fBSSL_write_ex\fR\|(3), and receive data using \fBSSL_read_ex\fR\|(3) in the same
way as for \s-1TLS.\s0 The main difference is that we have to account for failures
slightly differently. With \s-1QUIC\s0 the stream can be reset by the peer (which is
fatal for that stream), but the underlying connection itself may still be
healthy.
.PP
.Vb 10
\& /*
\& * Get up to sizeof(buf) bytes of the response. We keep reading until the
\& * server closes the connection.
\& */
\& while (SSL_read_ex(ssl, buf, sizeof(buf), &readbytes)) {
\& /*
\& * OpenSSL does not guarantee that the returned data is a string or
\& * that it is NUL terminated so we use fwrite() to write the exact
\& * number of bytes that we read. The data could be non\-printable or
\& * have NUL characters in the middle of it. For this simple example
\& * we\*(Aqre going to print it to stdout anyway.
\& */
\& fwrite(buf, 1, readbytes, stdout);
\& }
\& /* In case the response didn\*(Aqt finish with a newline we add one now */
\& printf("\en");
\&
\& /*
\& * Check whether we finished the while loop above normally or as the
\& * result of an error. The 0 argument to SSL_get_error() is the return
\& * code we received from the SSL_read_ex() call. It must be 0 in order
\& * to get here. Normal completion is indicated by SSL_ERROR_ZERO_RETURN. In
\& * QUIC terms this means that the peer has sent FIN on the stream to
\& * indicate that no further data will be sent.
\& */
\& switch (SSL_get_error(ssl, 0)) {
\& case SSL_ERROR_ZERO_RETURN:
\& /* Normal completion of the stream */
\& break;
\&
\& case SSL_ERROR_SSL:
\& /*
\& * Some stream fatal error occurred. This could be because of a stream
\& * reset \- or some failure occurred on the underlying connection.
\& */
\& switch (SSL_get_stream_read_state(ssl)) {
\& case SSL_STREAM_STATE_RESET_REMOTE:
\& printf("Stream reset occurred\en");
\& /* The stream has been reset but the connection is still healthy. */
\& break;
\&
\& case SSL_STREAM_STATE_CONN_CLOSED:
\& printf("Connection closed\en");
\& /* Connection is already closed. Skip SSL_shutdown() */
\& goto end;
\&
\& default:
\& printf("Unknown stream failure\en");
\& break;
\& }
\& break;
\&
\& default:
\& /* Some other unexpected error occurred */
\& printf ("Failed reading remaining data\en");
\& break;
\& }
.Ve
.PP
In the above code example you can see that \fB\s-1SSL_ERROR_SSL\s0\fR indicates a stream
fatal error. We can use \fBSSL_get_stream_read_state\fR\|(3) to determine whether the
stream has been reset, or if some other fatal error has occurred.
.SS "Shutting down the connection"
.IX Subsection "Shutting down the connection"
In the \s-1TLS\s0 tutorial we knew that the server had finished sending data because
\&\fBSSL_read_ex\fR\|(3) returned 0, and \fBSSL_get_error\fR\|(3) returned
\&\fB\s-1SSL_ERROR_ZERO_RETURN\s0\fR. The same is true with \s-1QUIC\s0 except that
\&\fB\s-1SSL_ERROR_ZERO_RETURN\s0\fR should be interpreted slightly differently. With \s-1TLS\s0
we knew that this meant that the server had sent a \*(L"close_notify\*(R" alert. No
more data will be sent from the server on that connection.
.PP
With \s-1QUIC\s0 it means that the server has indicated \*(L"\s-1FIN\*(R"\s0 on the stream, meaning
that it will no longer send any more data on that stream. However this only
gives us information about the stream itself and does not tell us anything about
the underlying connection. More data could still be sent from the server on some
other stream. Additionally, although the server will not send any more data to
the client, it does not prevent the client from sending more data to the server.
.PP
In this tutorial, once we have finished reading data from the server on the one
stream that we are using, we will close the connection down. As before we do
this via the \fBSSL_shutdown\fR\|(3) function. This example for \s-1QUIC\s0 is very similar
to the \s-1TLS\s0 version. However the \fBSSL_shutdown\fR\|(3) function will need to be
called more than once:
.PP
.Vb 11
\& /*
\& * Repeatedly call SSL_shutdown() until the connection is fully
\& * closed.
\& */
\& do {
\& ret = SSL_shutdown(ssl);
\& if (ret < 0) {
\& printf("Error shutting down: %d\en", ret);
\& goto end;
\& }
\& } while (ret != 1);
.Ve
.PP
The shutdown process is in two stages. In the first stage we wait until all the
data we have buffered for sending on any stream has been successfully sent and
acknowledged by the peer, and then we send a \s-1CONNECTION_CLOSE\s0 to the peer to
indicate that the connection is no longer usable. This immediately closes the
connection and no more data can be sent or received. \fBSSL_shutdown\fR\|(3) returns
0 once the first stage has been completed.
.PP
In the second stage the connection enters a \*(L"closing\*(R" state. Application data
cannot be sent or received in this state, but late arriving packets coming from
the peer will be handled appropriately. Once this stage has completed
successfully \fBSSL_shutdown\fR\|(3) will return 1 to indicate success.
.SH "FURTHER READING"
.IX Header "FURTHER READING"
See \fBossl\-guide\-quic\-multi\-stream\fR\|(7) to read a tutorial on how to modify the
client developed on this page to support multiple streams.
.SH "SEE ALSO"
.IX Header "SEE ALSO"
\&\fBossl\-guide\-introduction\fR\|(7), \fBossl\-guide\-libraries\-introduction\fR\|(7),
\&\fBossl\-guide\-libssl\-introduction\fR\|(7), \fBossl\-guide\-tls\-introduction\fR\|(7),
\&\fBossl\-guide\-tls\-client\-block\fR\|(7), \fBossl\-guide\-quic\-introduction\fR\|(7)
.SH "COPYRIGHT"
.IX Header "COPYRIGHT"
Copyright 2023 The OpenSSL Project Authors. All Rights Reserved.
.PP
Licensed under the Apache License 2.0 (the \*(L"License\*(R"). You may not use
this file except in compliance with the License. You can obtain a copy
in the file \s-1LICENSE\s0 in the source distribution or at
<https://www.openssl.org/source/license.html>.
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