mirror of
https://github.com/openssl/openssl.git
synced 2024-12-27 06:21:43 +08:00
7deb2b433a
Reviewed-by: Paul Yang <kaishen.yy@antfin.com> Reviewed-by: Tomas Mraz <tomas@openssl.org> (Merged from https://github.com/openssl/openssl/pull/23131)
586 lines
24 KiB
Plaintext
586 lines
24 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/tls-client-block.c
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=end comment
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=head1 NAME
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ossl-guide-tls-client-block
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- OpenSSL Guide: Writing a simple blocking TLS client
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=head1 SIMPLE BLOCKING TLS CLIENT EXAMPLE
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This page will present various source code samples demonstrating how to write
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a simple TLS client application which connects to a server, sends an HTTP/1.0
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request to it, and reads back the response.
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We use a blocking socket for the purposes of this example. This means that
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attempting to read data from a socket that has no data available on it to read
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will block (and the function will not return), until data becomes available.
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For example, this can happen if we have sent our request, but we are still
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waiting for the server's response. Similarly any attempts to write to a socket
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that is not able to write at the moment will block until writing is possible.
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This blocking behaviour simplifies the implementation of a client because you do
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not have to worry about what happens if data is not yet available. The
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application will simply wait until it is available.
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The complete source code for this example blocking TLS client is available in
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the B<demos/guide> directory of the OpenSSL source distribution in the file
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B<tls-client-block.c>. It is also available online at
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L<https://github.com/openssl/openssl/blob/master/demos/guide/tls-client-block.c>.
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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 and TLS (see
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L<ossl-guide-libraries-introduction(7)> and L<ossl-guide-tls-introduction(7)>);
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and that you know how to write and build C code and link it against the
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libcrypto and libssl libraries that are provided by OpenSSL. It also assumes
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that you have a basic understanding of TCP/IP and sockets.
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=head2 Creating the SSL_CTX and SSL objects
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The first step is to create an B<SSL_CTX> object for our client. We use the
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L<SSL_CTX_new(3)> function for this purpose. We could alternatively use
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L<SSL_CTX_new_ex(3)> if we want to associate the B<SSL_CTX> with a particular
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B<OSSL_LIB_CTX> (see L<ossl-guide-libraries-introduction(7)> to learn about
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B<OSSL_LIB_CTX>). We pass as an argument the return value of the function
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L<TLS_client_method(3)>. You should use this method whenever you are writing a
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TLS client. This method will automatically use TLS version negotiation to select
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the highest version of the protocol that is mutually supported by both the
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client and the server.
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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 TLS_client_method()
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* here.
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*/
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ctx = SSL_CTX_new(TLS_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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Since we are writing a client we must ensure that we verify the server's
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certificate. We do this by calling the L<SSL_CTX_set_verify(3)> function and
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pass the B<SSL_VERIFY_PEER> value to it. The final argument to this function
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is a callback that you can optionally supply to override the default handling
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for certificate verification. Most applications do not need to do this so this
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can safely be set to NULL to get the default handling.
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/*
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* Configure the client to abort the handshake if certificate
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* verification fails. Virtually all clients should do this unless you
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* really know what you are doing.
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*/
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SSL_CTX_set_verify(ctx, SSL_VERIFY_PEER, NULL);
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In order for certificate verification to be successful you must have configured
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where the trusted certificate store to be used is located (see
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L<ossl-guide-tls-introduction(7)>). In most cases you just want to use the
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default store so we call L<SSL_CTX_set_default_verify_paths(3)>.
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/* Use the default trusted certificate store */
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if (!SSL_CTX_set_default_verify_paths(ctx)) {
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printf("Failed to set the default trusted certificate store\n");
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goto end;
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}
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We would also like to restrict the TLS versions that we are willing to accept to
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TLSv1.2 or above. TLS protocol versions earlier than that are generally to be
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avoided where possible. We can do that using
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L<SSL_CTX_set_min_proto_version(3)>:
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/*
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* TLSv1.1 or earlier are deprecated by IETF and are generally to be
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* avoided if possible. We require a minimum TLS version of TLSv1.2.
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*/
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if (!SSL_CTX_set_min_proto_version(ctx, TLS1_2_VERSION)) {
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printf("Failed to set the minimum TLS protocol version\n");
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goto end;
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}
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That is all the setup that we need to do for the B<SSL_CTX>, so next we need to
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create an B<SSL> object to represent the TLS connection. In a real application
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we might expect to be creating more than one TLS connection over time. In that
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case we would expect to reuse the B<SSL_CTX> that we already created each time.
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There is no need to repeat those steps. In fact it is best not to since certain
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internal resources are cached in the B<SSL_CTX>. You will get better performance
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by reusing an existing B<SSL_CTX> instead of creating a new one each time.
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Creating the B<SSL> object is a simple matter of calling the B<SSL_new(3)>
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function and passing the B<SSL_CTX> we created as an argument.
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/* Create an SSL object to represent the TLS connection */
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ssl = SSL_new(ctx);
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if (ssl == NULL) {
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printf("Failed to create the SSL object\n");
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goto end;
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}
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=head2 Creating the socket and BIO
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TLS data is transmitted over an underlying transport layer. Normally a TCP
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socket. It is the application's responsibility for ensuring that the socket is
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created and associated with an SSL object (via a BIO).
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Socket creation for use by a client is typically a 2 step process, i.e.
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constructing the socket; and connecting the socket.
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How to construct a socket is platform specific - but most platforms (including
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Windows) provide a POSIX compatible interface via the I<socket> function, e.g.
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to create an IPv4 TCP socket:
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int sock;
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sock = socket(AF_INET, SOCK_STREAM, 0);
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if (sock == -1)
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return NULL;
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Once the socket is constructed it must be connected to the remote server. Again
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the details are platform specific but most platforms (including Windows)
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provide the POSIX compatible I<connect> function. For example:
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struct sockaddr_in serveraddr;
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struct hostent *server;
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server = gethostbyname("www.openssl.org");
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if (server == NULL) {
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close(sock);
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return NULL;
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}
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memset(&serveraddr, 0, sizeof(serveraddr));
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serveraddr.sin_family = server->h_addrtype;
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serveraddr.sin_port = htons(443);
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memcpy(&serveraddr.sin_addr.s_addr, server->h_addr, server->h_length);
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if (connect(sock, (struct sockaddr *)&serveraddr,
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sizeof(serveraddr)) == -1) {
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close(sock);
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return NULL;
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}
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OpenSSL provides portable helper functions to do these tasks which also
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integrate into the OpenSSL error system to log error data, e.g.
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int sock = -1;
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BIO_ADDRINFO *res;
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const BIO_ADDRINFO *ai = NULL;
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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_STREAM, 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_STREAM, 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), BIO_SOCK_NODELAY)) {
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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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/* We have a connected socket so break out of the loop */
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break;
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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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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)> and
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L<BIO_ADDRINFO_free(3)> for further information on the functions used here. In
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the above example code the B<hostname> and B<port> variables are strings, e.g.
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"www.example.com" and "443". Note also the use of the family variable, which
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can take the values of AF_INET or AF_INET6 based on the command line -6 option,
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to allow specific connections to an ipv4 or ipv6 enabled host.
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Sockets created using the methods described above will automatically be blocking
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sockets - which is exactly what we want for this example.
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Once the socket has been created and connected we need to associate it with a
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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_socket());
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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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See L<BIO_new(3)>, L<BIO_s_socket(3)> and L<BIO_set_fd(3)> for further
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information on these functions.
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Finally we associate the B<SSL> object we created earlier with the B<BIO> using
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the L<SSL_set_bio(3)> function. Note that this passes ownership of the B<BIO>
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object to the B<SSL> object. Once ownership is passed the SSL object is
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responsible for its management and will free it automatically when the B<SSL> is
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freed. So, once L<SSL_set_bio(3)> has been been called, you should not call
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L<BIO_free(3)> on the B<BIO>.
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SSL_set_bio(ssl, bio, bio);
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=head2 Setting the server's hostname
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We have already connected our underlying socket to the server, but the client
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still needs to know the server's hostname. It uses this information for 2 key
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purposes and we need to set the hostname for each one.
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Firstly, the server's hostname is included in the initial ClientHello message
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sent by the client. This is known as the Server Name Indication (SNI). This is
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important because it is common for multiple hostnames to be fronted by a single
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server that handles requests for all of them. In other words a single server may
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have multiple hostnames associated with it and it is important to indicate which
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one we want to connect to. Without this information we may get a handshake
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failure, or we may get connected to the "default" server which may not be the
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one we were expecting.
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To set the SNI hostname data we call the L<SSL_set_tlsext_host_name(3)> function
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like this:
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/*
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* Tell the server during the handshake which hostname we are attempting
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* to connect to in case the server supports multiple hosts.
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*/
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if (!SSL_set_tlsext_host_name(ssl, hostname)) {
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printf("Failed to set the SNI hostname\n");
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goto end;
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}
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Here the C<hostname> argument is a string representing the hostname of the
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server, e.g. "www.example.com".
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Secondly, we need to tell OpenSSL what hostname we expect to see in the
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certificate coming back from the server. This is almost always the same one that
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we asked for in the original request. This is important because, without this,
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we do not verify that the hostname in the certificate is what we expect it to be
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and any certificate is acceptable unless your application explicitly checks this
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itself. We do this via the L<SSL_set1_host(3)> function:
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/*
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* Ensure we check during certificate verification that the server has
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* supplied a certificate for the hostname that we were expecting.
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* Virtually all clients should do this unless you really know what you
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* are doing.
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*/
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if (!SSL_set1_host(ssl, hostname)) {
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printf("Failed to set the certificate verification hostname");
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goto end;
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}
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All of the above steps must happen before we attempt to perform the handshake
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otherwise they will have no effect.
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=head2 Performing the handshake
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Before we can start sending or receiving application data over a TLS connection
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the TLS handshake must be performed. We can do this explicitly via the
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L<SSL_connect(3)> function.
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/* Do the handshake with the server */
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if (SSL_connect(ssl) < 1) {
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printf("Failed to connect to the server\n");
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/*
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* If the failure is due to a verification error we can get more
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* information about it from SSL_get_verify_result().
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*/
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if (SSL_get_verify_result(ssl) != X509_V_OK)
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printf("Verify error: %s\n",
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X509_verify_cert_error_string(SSL_get_verify_result(ssl)));
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goto end;
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}
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The L<SSL_connect(3)> function can return 1, 0 or less than 0. Only a return
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value of 1 is considered a success. For a simple blocking client we only need
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to concern ourselves with whether the call was successful or not. Anything else
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indicates that we have failed to connect to the server.
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A common cause of failures at this stage is due to a problem verifying the
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server's certificate. For example if the certificate has expired, or it is not
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signed by a CA in our trusted certificate store. We can use the
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L<SSL_get_verify_result(3)> function to find out more information about the
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verification failure. A return value of B<X509_V_OK> indicates that the
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verification was successful (so the connection error must be due to some other
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cause). Otherwise we use the L<X509_verify_cert_error_string(3)> function to get
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a human readable error message.
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=head2 Sending and receiving data
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Once the handshake is complete we are able to send and receive application data.
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Exactly what data is sent and in what order is usually controlled by some
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application level protocol. In this example we are using HTTP 1.0 which is a
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very simple request and response protocol. The client sends a request to the
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server. The server sends the response data and then immediately closes down the
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connection.
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To send data to the server we use the L<SSL_write_ex(3)> function and to receive
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data from the server we use the L<SSL_read_ex(3)> function. In HTTP 1.0 the
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client always writes data first. Our HTTP request will include the hostname that
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we are connecting to. For simplicity, we write the HTTP request in three
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chunks. First we write the start of the request. Secondly we write the hostname
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we are sending the request to. Finally we send the end of the request.
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size_t written;
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const char *request_start = "GET / HTTP/1.0\r\nConnection: close\r\nHost: ";
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const char *request_end = "\r\n\r\n";
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/* Write an HTTP GET request to the peer */
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if (!SSL_write_ex(ssl, request_start, strlen(request_start), &written)) {
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printf("Failed to write start of HTTP request\n");
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goto end;
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}
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if (!SSL_write_ex(ssl, hostname, strlen(hostname), &written)) {
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printf("Failed to write hostname in HTTP request\n");
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goto end;
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}
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if (!SSL_write_ex(ssl, request_end, strlen(request_end), &written)) {
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printf("Failed to write end of HTTP request\n");
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goto end;
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}
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The L<SSL_write_ex(3)> function returns 0 if it fails and 1 if it is successful.
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If it is successful then we can proceed to waiting for a response from the
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server.
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size_t readbytes;
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char buf[160];
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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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We use the L<SSL_read_ex(3)> function to read the response. We don't know
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exactly how much data we are going to receive back so we enter a loop reading
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blocks of data from the server and printing each block that we receive to the
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screen. The loop ends as soon as L<SSL_read_ex(3)> returns 0 - meaning that it
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failed to read any data.
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A failure to read data could mean that there has been some error, or it could
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simply mean that server has sent all the data that it wants to send and has
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indicated that it has finished by sending a "close_notify" alert. This alert is
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a TLS protocol level message indicating that the endpoint has finished sending
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all of its data and it will not send any more. Both of these conditions result
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in a 0 return value from L<SSL_read_ex(3)> and we need to use the function
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L<SSL_get_error(3)> to determine the cause of the 0 return value.
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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.
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*/
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if (SSL_get_error(ssl, 0) != SSL_ERROR_ZERO_RETURN) {
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/*
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* Some error occurred other than a graceful close down by the
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* peer
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*/
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printf ("Failed reading remaining data\n");
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goto end;
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}
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If L<SSL_get_error(3)> returns B<SSL_ERROR_ZERO_RETURN> then we know that the
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server has finished sending its data. Otherwise an error has occurred.
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=head2 Shutting down the connection
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Once we have finished reading data from the server then we are ready to close
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the connection down. We do this via the L<SSL_shutdown(3)> function which has
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the effect of sending a TLS protocol level message (a "close_notify" alert) to
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the server saying that we have finished writing data:
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/*
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* The peer already shutdown gracefully (we know this because of the
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* SSL_ERROR_ZERO_RETURN above). We should do the same back.
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*/
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ret = SSL_shutdown(ssl);
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if (ret < 1) {
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/*
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* ret < 0 indicates an error. ret == 0 would be unexpected here
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* because that means "we've sent a close_notify and we're waiting
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* for one back". But we already know we got one from the peer
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* because of the SSL_ERROR_ZERO_RETURN above.
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*/
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printf("Error shutting down\n");
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goto end;
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}
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The L<SSL_shutdown(3)> function will either return 1, 0, or less than 0. A
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return value of 1 is a success, and a return value less than 0 is an error. More
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precisely a return value of 1 means that we have sent a "close_notify" alert to
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the server, and that we have also received one back. A return value of 0 means
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|
that we have sent a "close_notify" alert to the server, but we have not yet
|
|
received one back. Usually in this scenario you would call L<SSL_shutdown(3)>
|
|
again which (with a blocking socket) would block until the "close_notify" is
|
|
received. However in this case we already know that the server has sent us a
|
|
"close_notify" because of the SSL_ERROR_ZERO_RETURN that we received from the
|
|
call to L<SSL_read_ex(3)>. So this scenario should never happen in practice. We
|
|
just treat it as an error in this example.
|
|
|
|
=head2 Final clean up
|
|
|
|
Before the application exits we have to clean up some memory that we allocated.
|
|
If we are exiting due to an error we might also want to display further
|
|
information about that error if it is available to the user:
|
|
|
|
/* Success! */
|
|
res = EXIT_SUCCESS;
|
|
end:
|
|
/*
|
|
* If something bad happened then we will dump the contents of the
|
|
* OpenSSL error stack to stderr. There might be some useful diagnostic
|
|
* information there.
|
|
*/
|
|
if (res == EXIT_FAILURE)
|
|
ERR_print_errors_fp(stderr);
|
|
|
|
/*
|
|
* Free the resources we allocated. We do not free the BIO object here
|
|
* because ownership of it was immediately transferred to the SSL object
|
|
* via SSL_set_bio(). The BIO will be freed when we free the SSL object.
|
|
*/
|
|
SSL_free(ssl);
|
|
SSL_CTX_free(ctx);
|
|
return res;
|
|
|
|
To display errors we make use of the L<ERR_print_errors_fp(3)> function which
|
|
simply dumps out the contents of any errors on the OpenSSL error stack to the
|
|
specified location (in this case I<stderr>).
|
|
|
|
We need to free up the B<SSL> object that we created for the connection via the
|
|
L<SSL_free(3)> function. Also, since we are not going to be creating any more
|
|
TLS connections we must also free up the B<SSL_CTX> via a call to
|
|
L<SSL_CTX_free(3)>.
|
|
|
|
=head1 TROUBLESHOOTING
|
|
|
|
There are a number of things that might go wrong when running the demo
|
|
application. This section describes some common things you might encounter.
|
|
|
|
=head2 Failure to connect the underlying socket
|
|
|
|
This could occur for numerous reasons. For example if there is a problem in the
|
|
network route between the client and the server; or a firewall is blocking the
|
|
communication; or the server is not in DNS. Check the network configuration.
|
|
|
|
=head2 Verification failure of the server certificate
|
|
|
|
A verification failure of the server certificate would result in a failure when
|
|
running the L<SSL_connect(3)> function. L<ERR_print_errors_fp(3)> would display
|
|
an error which would look something like this:
|
|
|
|
Verify error: unable to get local issuer certificate
|
|
40E74AF1F47F0000:error:0A000086:SSL routines:tls_post_process_server_certificate:certificate verify failed:ssl/statem/statem_clnt.c:2069:
|
|
|
|
A server certificate verification failure could be caused for a number of
|
|
reasons. For example
|
|
|
|
=over 4
|
|
|
|
=item Failure to correctly setup the trusted certificate store
|
|
|
|
See the page L<ossl-guide-tls-introduction(7)> and check that your trusted
|
|
certificate store is correctly configured
|
|
|
|
=item Unrecognised CA
|
|
|
|
If the CA used by the server's certificate is not in the trusted certificate
|
|
store for the client then this will cause a verification failure during
|
|
connection. Often this can occur if the server is using a self-signed
|
|
certificate (i.e. a test certificate that has not been signed by a CA at all).
|
|
|
|
=item Missing intermediate CAs
|
|
|
|
This is a server misconfiguration where the client has the relevant root CA in
|
|
its trust store, but the server has not supplied all of the intermediate CA
|
|
certificates between that root CA and the server's own certificate. Therefore
|
|
a trust chain cannot be established.
|
|
|
|
=item Mismatched hostname
|
|
|
|
If for some reason the hostname of the server that the client is expecting does
|
|
not match the hostname in the certificate then this will cause verification to
|
|
fail.
|
|
|
|
=item Expired certificate
|
|
|
|
The date that the server's certificate is valid to has passed.
|
|
|
|
=back
|
|
|
|
The "unable to get local issuer certificate" we saw in the example above means
|
|
that we have been unable to find the issuer of the server's certificate (or one
|
|
of its intermediate CA certificates) in our trusted certificate store (e.g.
|
|
because the trusted certificate store is misconfigured, or there are missing
|
|
intermediate CAs, or the issuer is simply unrecognised).
|
|
|
|
=head1 FURTHER READING
|
|
|
|
See L<ossl-guide-tls-client-non-block(7)> to read a tutorial on how to modify
|
|
the client developed on this page to support a nonblocking socket.
|
|
|
|
See L<ossl-guide-quic-client-block(7)> to read a tutorial on how to modify the
|
|
client developed on this page to support QUIC instead of TLS.
|
|
|
|
=head1 SEE ALSO
|
|
|
|
L<ossl-guide-introduction(7)>, L<ossl-guide-libraries-introduction(7)>,
|
|
L<ossl-guide-libssl-introduction(7)>, L<ossl-guide-tls-introduction(7)>,
|
|
L<ossl-guide-tls-client-non-block(7)>, L<ossl-guide-quic-client-block(7)>
|
|
|
|
=head1 COPYRIGHT
|
|
|
|
Copyright 2023 The OpenSSL Project Authors. All Rights Reserved.
|
|
|
|
Licensed under the Apache License 2.0 (the "License"). You may not use
|
|
this file except in compliance with the License. You can obtain a copy
|
|
in the file LICENSE in the source distribution or at
|
|
L<https://www.openssl.org/source/license.html>.
|
|
|
|
=cut
|