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boring2/openssl/src/ssl/tests/mod.rs

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#![allow(unused_imports)]
use std::fs::File;
use std::io::prelude::*;
use std::io::{self, BufReader};
use std::iter;
use std::mem;
use std::net::{TcpStream, TcpListener, SocketAddr};
use std::path::Path;
use std::process::{Command, Child, Stdio, ChildStdin};
use std::thread;
use std::time::Duration;
use net2::TcpStreamExt;
use crypto::hash::Type::SHA256;
use ssl;
use ssl::SSL_VERIFY_PEER;
use ssl::SslMethod::Sslv23;
use ssl::SslMethod;
use ssl::error::NonblockingSslError;
use ssl::{SslContext, SslStream, VerifyCallback, NonblockingSslStream};
use x509::X509StoreContext;
use x509::X509FileType;
use x509::X509;
use crypto::pkey::PKey;
#[cfg(feature="dtlsv1")]
use std::net::UdpSocket;
#[cfg(feature="dtlsv1")]
use ssl::SslMethod::Dtlsv1;
#[cfg(feature="sslv2")]
use ssl::SslMethod::Sslv2;
#[cfg(feature="dtlsv1")]
use net2::UdpSocketExt;
mod select;
fn next_addr() -> SocketAddr {
use std::sync::atomic::{AtomicUsize, ATOMIC_USIZE_INIT, Ordering};
static PORT: AtomicUsize = ATOMIC_USIZE_INIT;
let port = 15411 + PORT.fetch_add(1, Ordering::SeqCst);
format!("127.0.0.1:{}", port).parse().unwrap()
}
struct Server {
p: Child,
}
impl Server {
fn spawn(args: &[&str], input: Option<Box<FnMut(ChildStdin) + Send>>) -> (Server, SocketAddr) {
let addr = next_addr();
let mut child = Command::new("openssl")
.arg("s_server")
.arg("-accept")
.arg(addr.port().to_string())
.args(args)
.arg("-cert")
.arg("cert.pem")
.arg("-key")
.arg("key.pem")
.arg("-no_dhe")
.current_dir("test")
.stdout(Stdio::null())
.stderr(Stdio::null())
.stdin(Stdio::piped())
.spawn()
.unwrap();
let stdin = child.stdin.take().unwrap();
if let Some(mut input) = input {
thread::spawn(move || input(stdin));
}
(Server { p: child }, addr)
}
fn new_tcp(args: &[&str]) -> (Server, TcpStream) {
let (server, addr) = Server::spawn(args, None);
for _ in 0..20 {
match TcpStream::connect(&addr) {
Ok(s) => return (server, s),
Err(ref e) if e.kind() == io::ErrorKind::ConnectionRefused => {
thread::sleep(Duration::from_millis(100));
}
Err(e) => panic!("wut: {}", e),
}
}
panic!("server never came online");
}
fn new() -> (Server, TcpStream) {
Server::new_tcp(&["-www"])
}
#[cfg(any(feature = "alpn", feature = "npn"))]
fn new_alpn() -> (Server, TcpStream) {
Server::new_tcp(&["-www",
"-nextprotoneg",
"http/1.1,spdy/3.1",
"-alpn",
"http/1.1,spdy/3.1"])
}
#[cfg(feature = "dtlsv1")]
fn new_dtlsv1<I>(input: I) -> (Server, UdpConnected)
where I: IntoIterator<Item = &'static str>,
I::IntoIter: Send + 'static
{
let mut input = input.into_iter();
let (s, addr) = Server::spawn(&["-dtls1"],
Some(Box::new(move |mut io| {
for s in input.by_ref() {
if io.write_all(s.as_bytes()).is_err() {
break;
}
}
})));
// Need to wait for the UDP socket to get bound in our child process,
// but don't currently have a great way to do that so just wait for a
// bit.
thread::sleep(Duration::from_millis(100));
let socket = UdpSocket::bind(next_addr()).unwrap();
socket.connect(&addr).unwrap();
(s, UdpConnected(socket))
}
}
impl Drop for Server {
fn drop(&mut self) {
let _ = self.p.kill();
let _ = self.p.wait();
}
}
#[cfg(feature = "dtlsv1")]
struct UdpConnected(UdpSocket);
#[cfg(feature = "dtlsv1")]
impl Read for UdpConnected {
fn read(&mut self, buf: &mut [u8]) -> io::Result<usize> {
self.0.recv_from(buf).map(|(s, _)| s)
}
}
#[cfg(feature = "dtlsv1")]
impl Write for UdpConnected {
#[cfg(unix)]
fn write(&mut self, buf: &[u8]) -> io::Result<usize> {
use std::os::unix::prelude::*;
use libc;
let n = unsafe {
libc::send(self.0.as_raw_fd(),
buf.as_ptr() as *const _,
buf.len() as libc::size_t,
0)
};
if n < 0 {
Err(io::Error::last_os_error())
} else {
Ok(n as usize)
}
}
#[cfg(windows)]
fn write(&mut self, buf: &[u8]) -> io::Result<usize> {
use std::os::windows::prelude::*;
use libc;
let n = unsafe {
libc::send(self.0.as_raw_socket(),
buf.as_ptr() as *const _,
buf.len() as libc::c_int,
0)
};
if n < 0 {
Err(io::Error::last_os_error())
} else {
Ok(n as usize)
}
}
fn flush(&mut self) -> io::Result<()> {
Ok(())
}
}
macro_rules! run_test(
($module:ident, $blk:expr) => (
#[cfg(test)]
mod $module {
use std::io;
use std::io::prelude::*;
use std::path::Path;
use std::net::UdpSocket;
use std::net::TcpStream;
use ssl;
use ssl::SslMethod;
use ssl::{SslContext, Ssl, SslStream, VerifyCallback};
use ssl::SSL_VERIFY_PEER;
use crypto::hash::Type::SHA256;
use x509::X509StoreContext;
use serialize::hex::FromHex;
use super::Server;
#[test]
fn sslv23() {
let (_s, stream) = Server::new();
$blk(SslMethod::Sslv23, stream);
}
#[test]
#[cfg(feature="dtlsv1")]
fn dtlsv1() {
let (_s, stream) = Server::new_dtlsv1(Some("hello"));
$blk(SslMethod::Dtlsv1, stream);
}
}
);
);
run_test!(new_ctx, |method, _| {
SslContext::new(method).unwrap();
});
run_test!(new_sslstream, |method, stream| {
SslStream::connect_generic(&SslContext::new(method).unwrap(), stream).unwrap();
});
run_test!(get_ssl_method, |method, _| {
let ssl = Ssl::new(&SslContext::new(method).unwrap()).unwrap();
assert_eq!(ssl.get_ssl_method(), Some(method));
});
run_test!(verify_untrusted, |method, stream| {
let mut ctx = SslContext::new(method).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
match SslStream::connect_generic(&ctx, stream) {
Ok(_) => panic!("expected failure"),
Err(err) => println!("error {:?}", err)
}
});
run_test!(verify_trusted, |method, stream| {
let mut ctx = SslContext::new(method).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err)
}
match SslStream::connect_generic(&ctx, stream) {
Ok(_) => (),
Err(err) => panic!("Expected success, got {:?}", err)
}
});
run_test!(verify_untrusted_callback_override_ok, |method, stream| {
fn callback(_preverify_ok: bool, _x509_ctx: &X509StoreContext) -> bool {
true
}
let mut ctx = SslContext::new(method).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, Some(callback as VerifyCallback));
match SslStream::connect_generic(&ctx, stream) {
Ok(_) => (),
Err(err) => panic!("Expected success, got {:?}", err)
}
});
run_test!(verify_untrusted_callback_override_bad, |method, stream| {
fn callback(_preverify_ok: bool, _x509_ctx: &X509StoreContext) -> bool {
false
}
let mut ctx = SslContext::new(method).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, Some(callback as VerifyCallback));
assert!(SslStream::connect_generic(&ctx, stream).is_err());
});
run_test!(verify_trusted_callback_override_ok, |method, stream| {
fn callback(_preverify_ok: bool, _x509_ctx: &X509StoreContext) -> bool {
true
}
let mut ctx = SslContext::new(method).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, Some(callback as VerifyCallback));
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err)
}
match SslStream::connect_generic(&ctx, stream) {
Ok(_) => (),
Err(err) => panic!("Expected success, got {:?}", err)
}
});
run_test!(verify_trusted_callback_override_bad, |method, stream| {
fn callback(_preverify_ok: bool, _x509_ctx: &X509StoreContext) -> bool {
false
}
let mut ctx = SslContext::new(method).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, Some(callback as VerifyCallback));
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err)
}
assert!(SslStream::connect_generic(&ctx, stream).is_err());
});
run_test!(verify_callback_load_certs, |method, stream| {
fn callback(_preverify_ok: bool, x509_ctx: &X509StoreContext) -> bool {
assert!(x509_ctx.get_current_cert().is_some());
true
}
let mut ctx = SslContext::new(method).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, Some(callback as VerifyCallback));
assert!(SslStream::connect_generic(&ctx, stream).is_ok());
});
run_test!(verify_trusted_get_error_ok, |method, stream| {
fn callback(_preverify_ok: bool, x509_ctx: &X509StoreContext) -> bool {
assert!(x509_ctx.get_error().is_none());
true
}
let mut ctx = SslContext::new(method).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, Some(callback as VerifyCallback));
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err)
}
assert!(SslStream::connect_generic(&ctx, stream).is_ok());
});
run_test!(verify_trusted_get_error_err, |method, stream| {
fn callback(_preverify_ok: bool, x509_ctx: &X509StoreContext) -> bool {
assert!(x509_ctx.get_error().is_some());
false
}
let mut ctx = SslContext::new(method).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, Some(callback as VerifyCallback));
assert!(SslStream::connect_generic(&ctx, stream).is_err());
});
run_test!(verify_callback_data, |method, stream| {
fn callback(_preverify_ok: bool, x509_ctx: &X509StoreContext,
node_id: &Vec<u8>) -> bool {
let cert = x509_ctx.get_current_cert();
match cert {
None => false,
Some(cert) => {
let fingerprint = cert.fingerprint(SHA256).unwrap();
&fingerprint == node_id
}
}
}
let mut ctx = SslContext::new(method).unwrap();
// Node id was generated as SHA256 hash of certificate "test/cert.pem"
// in DER format.
// Command: openssl x509 -in test/cert.pem -outform DER | openssl dgst -sha256
// Please update if "test/cert.pem" will ever change
let node_hash_str = "db400bb62f1b1f29c3b8f323b8f7d9dea724fdcd67104ef549c772ae3749655b";
let node_id = node_hash_str.from_hex().unwrap();
ctx.set_verify_with_data(SSL_VERIFY_PEER, callback, node_id);
ctx.set_verify_depth(1);
match SslStream::connect_generic(&ctx, stream) {
Ok(_) => (),
Err(err) => panic!("Expected success, got {:?}", err)
}
});
// Make sure every write call translates to a write call to the underlying socket.
#[test]
fn test_write_hits_stream() {
let listener = TcpListener::bind(next_addr()).unwrap();
let addr = listener.local_addr().unwrap();
let guard = thread::spawn(move || {
let ctx = SslContext::new(Sslv23).unwrap();
let stream = TcpStream::connect(addr).unwrap();
let mut stream = SslStream::connect_generic(&ctx, stream).unwrap();
stream.write_all(b"hello").unwrap();
stream
});
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_certificate_file(&Path::new("test/cert.pem"), X509FileType::PEM).unwrap();
ctx.set_private_key_file(&Path::new("test/key.pem"), X509FileType::PEM).unwrap();
let stream = listener.accept().unwrap().0;
let mut stream = SslStream::accept(&ctx, stream).unwrap();
let mut buf = [0; 5];
assert_eq!(5, stream.read(&mut buf).unwrap());
assert_eq!(&b"hello"[..], &buf[..]);
guard.join().unwrap();
}
#[test]
fn test_set_certificate_and_private_key() {
let key_path = Path::new("test/key.pem");
let cert_path = Path::new("test/cert.pem");
let mut key_file = File::open(&key_path)
.ok()
.expect("Failed to open `test/key.pem`");
let mut cert_file = File::open(&cert_path)
.ok()
.expect("Failed to open `test/cert.pem`");
let key = PKey::private_key_from_pem(&mut key_file).unwrap();
let cert = X509::from_pem(&mut cert_file).unwrap();
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_private_key(&key).unwrap();
ctx.set_certificate(&cert).unwrap();
assert!(ctx.check_private_key().is_ok());
}
run_test!(get_ctx_options, |method, _| {
let mut ctx = SslContext::new(method).unwrap();
ctx.get_options();
});
run_test!(set_ctx_options, |method, _| {
let mut ctx = SslContext::new(method).unwrap();
let opts = ctx.set_options(ssl::SSL_OP_NO_TICKET);
assert!(opts.contains(ssl::SSL_OP_NO_TICKET));
});
run_test!(clear_ctx_options, |method, _| {
let mut ctx = SslContext::new(method).unwrap();
ctx.set_options(ssl::SSL_OP_ALL);
let opts = ctx.clear_options(ssl::SSL_OP_ALL);
assert!(!opts.contains(ssl::SSL_OP_ALL));
});
#[test]
fn test_write() {
let (_s, stream) = Server::new();
let mut stream = SslStream::connect_generic(&SslContext::new(Sslv23).unwrap(), stream).unwrap();
stream.write_all("hello".as_bytes()).unwrap();
stream.flush().unwrap();
stream.write_all(" there".as_bytes()).unwrap();
stream.flush().unwrap();
}
#[test]
fn test_write_direct() {
let (_s, stream) = Server::new();
let mut stream = SslStream::connect(&SslContext::new(Sslv23).unwrap(), stream).unwrap();
stream.write_all("hello".as_bytes()).unwrap();
stream.flush().unwrap();
stream.write_all(" there".as_bytes()).unwrap();
stream.flush().unwrap();
}
run_test!(get_peer_certificate, |method, stream| {
let stream = SslStream::connect_generic(&SslContext::new(method).unwrap(),
stream).unwrap();
let cert = stream.ssl().peer_certificate().unwrap();
let fingerprint = cert.fingerprint(SHA256).unwrap();
let node_hash_str = "db400bb62f1b1f29c3b8f323b8f7d9dea724fdcd67104ef549c772ae3749655b";
let node_id = node_hash_str.from_hex().unwrap();
assert_eq!(node_id, fingerprint)
});
#[test]
#[cfg(feature = "dtlsv1")]
fn test_write_dtlsv1() {
let (_s, stream) = Server::new_dtlsv1(iter::repeat("y\n"));
let mut stream = SslStream::connect_generic(&SslContext::new(Dtlsv1).unwrap(), stream).unwrap();
stream.write_all(b"hello").unwrap();
stream.flush().unwrap();
stream.write_all(b" there").unwrap();
stream.flush().unwrap();
}
#[test]
fn test_read() {
let (_s, tcp) = Server::new();
let mut stream = SslStream::connect_generic(&SslContext::new(Sslv23).unwrap(), tcp).unwrap();
stream.write_all("GET /\r\n\r\n".as_bytes()).unwrap();
stream.flush().unwrap();
io::copy(&mut stream, &mut io::sink()).ok().expect("read error");
}
#[test]
fn test_read_direct() {
let (_s, tcp) = Server::new();
let mut stream = SslStream::connect(&SslContext::new(Sslv23).unwrap(), tcp).unwrap();
stream.write_all("GET /\r\n\r\n".as_bytes()).unwrap();
stream.flush().unwrap();
io::copy(&mut stream, &mut io::sink()).ok().expect("read error");
}
#[test]
fn test_pending() {
let (_s, tcp) = Server::new();
let mut stream = SslStream::connect_generic(&SslContext::new(Sslv23).unwrap(), tcp).unwrap();
stream.write_all("GET /\r\n\r\n".as_bytes()).unwrap();
stream.flush().unwrap();
// wait for the response and read first byte...
let mut buf = [0u8; 16 * 1024];
stream.read(&mut buf[..1]).unwrap();
let pending = stream.ssl().pending();
let len = stream.read(&mut buf[1..]).unwrap();
assert_eq!(pending, len);
stream.read(&mut buf[..1]).unwrap();
let pending = stream.ssl().pending();
let len = stream.read(&mut buf[1..]).unwrap();
assert_eq!(pending, len);
}
#[test]
fn test_state() {
let (_s, tcp) = Server::new();
let stream = SslStream::connect_generic(&SslContext::new(Sslv23).unwrap(), tcp).unwrap();
assert_eq!(stream.ssl().state_string(), "SSLOK ");
assert_eq!(stream.ssl().state_string_long(),
"SSL negotiation finished successfully");
}
/// Tests that connecting with the client using ALPN, but the server not does not
/// break the existing connection behavior.
#[test]
#[cfg(feature = "alpn")]
fn test_connect_with_unilateral_alpn() {
let (_s, stream) = Server::new();
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_alpn_protocols(&[b"http/1.1", b"spdy/3.1"]);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err),
}
let stream = match SslStream::connect(&ctx, stream) {
Ok(stream) => stream,
Err(err) => panic!("Expected success, got {:?}", err),
};
// Since the socket to which we connected is not configured to use ALPN,
// there should be no selected protocol...
assert!(stream.ssl().selected_alpn_protocol().is_none());
}
/// Tests that connecting with the client using NPN, but the server not does not
/// break the existing connection behavior.
#[test]
#[cfg(feature = "npn")]
fn test_connect_with_unilateral_npn() {
let (_s, stream) = Server::new();
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_npn_protocols(&[b"http/1.1", b"spdy/3.1"]);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err),
}
let stream = match SslStream::connect_generic(&ctx, stream) {
Ok(stream) => stream,
Err(err) => panic!("Expected success, got {:?}", err),
};
// Since the socket to which we connected is not configured to use NPN,
// there should be no selected protocol...
assert!(stream.ssl().selected_npn_protocol().is_none());
}
/// Tests that when both the client as well as the server use ALPN and their
/// lists of supported protocols have an overlap, the correct protocol is chosen.
#[test]
#[cfg(feature = "alpn")]
fn test_connect_with_alpn_successful_multiple_matching() {
let (_s, stream) = Server::new_alpn();
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_alpn_protocols(&[b"spdy/3.1", b"http/1.1"]);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err),
}
let stream = match SslStream::connect(&ctx, stream) {
Ok(stream) => stream,
Err(err) => panic!("Expected success, got {:?}", err),
};
// The server prefers "http/1.1", so that is chosen, even though the client
// would prefer "spdy/3.1"
assert_eq!(b"http/1.1", stream.ssl().selected_alpn_protocol().unwrap());
}
/// Tests that when both the client as well as the server use NPN and their
/// lists of supported protocols have an overlap, the correct protocol is chosen.
#[test]
#[cfg(feature = "npn")]
fn test_connect_with_npn_successful_multiple_matching() {
let (_s, stream) = Server::new_alpn();
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_npn_protocols(&[b"spdy/3.1", b"http/1.1"]);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err),
}
let stream = match SslStream::connect_generic(&ctx, stream) {
Ok(stream) => stream,
Err(err) => panic!("Expected success, got {:?}", err),
};
// The server prefers "http/1.1", so that is chosen, even though the client
// would prefer "spdy/3.1"
assert_eq!(b"http/1.1", stream.ssl().selected_npn_protocol().unwrap());
}
/// Tests that when both the client as well as the server use ALPN and their
/// lists of supported protocols have an overlap -- with only ONE protocol
/// being valid for both.
#[test]
#[cfg(feature = "alpn")]
fn test_connect_with_alpn_successful_single_match() {
let (_s, stream) = Server::new_alpn();
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_alpn_protocols(&[b"spdy/3.1"]);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err),
}
let stream = match SslStream::connect(&ctx, stream) {
Ok(stream) => stream,
Err(err) => panic!("Expected success, got {:?}", err),
};
// The client now only supports one of the server's protocols, so that one
// is used.
assert_eq!(b"spdy/3.1", stream.ssl().selected_alpn_protocol().unwrap());
}
/// Tests that when both the client as well as the server use NPN and their
/// lists of supported protocols have an overlap -- with only ONE protocol
/// being valid for both.
#[test]
#[cfg(feature = "npn")]
fn test_connect_with_npn_successful_single_match() {
let (_s, stream) = Server::new_alpn();
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_npn_protocols(&[b"spdy/3.1"]);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err),
}
let stream = match SslStream::connect_generic(&ctx, stream) {
Ok(stream) => stream,
Err(err) => panic!("Expected success, got {:?}", err),
};
// The client now only supports one of the server's protocols, so that one
// is used.
assert_eq!(b"spdy/3.1", stream.ssl().selected_npn_protocol().unwrap());
}
/// Tests that when the `SslStream` is created as a server stream, the protocols
/// are correctly advertised to the client.
#[test]
#[cfg(feature = "npn")]
fn test_npn_server_advertise_multiple() {
let listener = TcpListener::bind(next_addr()).unwrap();
let localhost = listener.local_addr().unwrap();
// We create a different context instance for the server...
let listener_ctx = {
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_npn_protocols(&[b"http/1.1", b"spdy/3.1"]);
assert!(ctx.set_certificate_file(&Path::new("test/cert.pem"), X509FileType::PEM)
.is_ok());
ctx.set_private_key_file(&Path::new("test/key.pem"), X509FileType::PEM)
.unwrap();
ctx
};
// Have the listener wait on the connection in a different thread.
thread::spawn(move || {
let (stream, _) = listener.accept().unwrap();
let _ = SslStream::accept(&listener_ctx, stream).unwrap();
});
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_npn_protocols(&[b"spdy/3.1"]);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err),
}
// Now connect to the socket and make sure the protocol negotiation works...
let stream = TcpStream::connect(localhost).unwrap();
let stream = match SslStream::connect_generic(&ctx, stream) {
Ok(stream) => stream,
Err(err) => panic!("Expected success, got {:?}", err),
};
// SPDY is selected since that's the only thing the client supports.
assert_eq!(b"spdy/3.1", stream.ssl().selected_npn_protocol().unwrap());
}
/// Tests that when the `SslStream` is created as a server stream, the protocols
/// are correctly advertised to the client.
#[test]
#[cfg(feature = "alpn")]
fn test_alpn_server_advertise_multiple() {
let listener = TcpListener::bind(next_addr()).unwrap();
let localhost = listener.local_addr().unwrap();
// We create a different context instance for the server...
let listener_ctx = {
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_alpn_protocols(&[b"http/1.1", b"spdy/3.1"]);
assert!(ctx.set_certificate_file(&Path::new("test/cert.pem"), X509FileType::PEM)
.is_ok());
ctx.set_private_key_file(&Path::new("test/key.pem"), X509FileType::PEM)
.unwrap();
ctx
};
// Have the listener wait on the connection in a different thread.
thread::spawn(move || {
let (stream, _) = listener.accept().unwrap();
let _ = SslStream::accept(&listener_ctx, stream).unwrap();
});
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_alpn_protocols(&[b"spdy/3.1"]);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err),
}
// Now connect to the socket and make sure the protocol negotiation works...
let stream = TcpStream::connect(localhost).unwrap();
let stream = match SslStream::connect(&ctx, stream) {
Ok(stream) => stream,
Err(err) => panic!("Expected success, got {:?}", err),
};
// SPDY is selected since that's the only thing the client supports.
assert_eq!(b"spdy/3.1", stream.ssl().selected_alpn_protocol().unwrap());
}
/// Test that Servers supporting ALPN don't report a protocol when none of their protocols match
/// the client's reported protocol.
#[test]
#[cfg(feature = "alpn")]
fn test_alpn_server_select_none() {
let listener = TcpListener::bind(next_addr()).unwrap();
let localhost = listener.local_addr().unwrap();
// We create a different context instance for the server...
let listener_ctx = {
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_alpn_protocols(&[b"http/1.1", b"spdy/3.1"]);
assert!(ctx.set_certificate_file(&Path::new("test/cert.pem"), X509FileType::PEM)
.is_ok());
ctx.set_private_key_file(&Path::new("test/key.pem"), X509FileType::PEM)
.unwrap();
ctx
};
// Have the listener wait on the connection in a different thread.
thread::spawn(move || {
let (stream, _) = listener.accept().unwrap();
let _ = SslStream::accept(&listener_ctx, stream).unwrap();
});
let mut ctx = SslContext::new(Sslv23).unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
ctx.set_alpn_protocols(&[b"http/2"]);
match ctx.set_CA_file(&Path::new("test/cert.pem")) {
Ok(_) => {}
Err(err) => panic!("Unexpected error {:?}", err),
}
// Now connect to the socket and make sure the protocol negotiation works...
let stream = TcpStream::connect(localhost).unwrap();
let stream = match SslStream::connect(&ctx, stream) {
Ok(stream) => stream,
Err(err) => panic!("Expected success, got {:?}", err),
};
// Since the protocols from the server and client don't overlap at all, no protocol is selected
assert_eq!(None, stream.ssl().selected_alpn_protocol());
}
#[cfg(feature="dtlsv1")]
#[cfg(test)]
mod dtlsv1 {
use serialize::hex::FromHex;
use std::net::TcpStream;
use std::thread;
use crypto::hash::Type::SHA256;
use ssl::SslMethod;
use ssl::SslMethod::Dtlsv1;
use ssl::{SslContext, SslStream, VerifyCallback};
use ssl::SSL_VERIFY_PEER;
use x509::X509StoreContext;
const PROTOCOL: SslMethod = Dtlsv1;
#[test]
fn test_new_ctx() {
SslContext::new(PROTOCOL).unwrap();
}
}
#[test]
#[cfg(feature = "dtlsv1")]
fn test_read_dtlsv1() {
let (_s, stream) = Server::new_dtlsv1(Some("hello"));
let mut stream = SslStream::connect_generic(&SslContext::new(Dtlsv1).unwrap(), stream).unwrap();
let mut buf = [0u8; 100];
assert!(stream.read(&mut buf).is_ok());
}
#[test]
#[cfg(feature = "sslv2")]
fn test_sslv2_connect_failure() {
let (_s, tcp) = Server::new_tcp(&["-no_ssl2", "-www"]);
SslStream::connect_generic(&SslContext::new(Sslv2).unwrap(), tcp)
.err()
.unwrap();
}
fn wait_io(stream: &NonblockingSslStream<TcpStream>, read: bool, timeout_ms: u32) -> bool {
unsafe {
let mut set: select::fd_set = mem::zeroed();
select::fd_set(&mut set, stream.get_ref());
let write = if read {
0 as *mut _
} else {
&mut set as *mut _
};
let read = if !read {
0 as *mut _
} else {
&mut set as *mut _
};
select::select(stream.get_ref(), read, write, 0 as *mut _, timeout_ms).unwrap()
}
}
#[test]
fn test_write_nonblocking() {
let (_s, stream) = Server::new();
stream.set_nonblocking(true).unwrap();
let cx = SslContext::new(Sslv23).unwrap();
let mut stream = NonblockingSslStream::connect(&cx, stream).unwrap();
let mut iterations = 0;
loop {
iterations += 1;
if iterations > 7 {
// Probably a safe assumption for the foreseeable future of
// openssl.
panic!("Too many read/write round trips in handshake!!");
}
let result = stream.write(b"hello");
match result {
Ok(_) => {
break;
}
Err(NonblockingSslError::WantRead) => {
assert!(wait_io(&stream, true, 1000));
}
Err(NonblockingSslError::WantWrite) => {
assert!(wait_io(&stream, false, 1000));
}
Err(other) => {
panic!("Unexpected SSL Error: {:?}", other);
}
}
}
// Second write should succeed immediately--plenty of space in kernel
// buffer, and handshake just completed.
stream.write(" there".as_bytes()).unwrap();
}
#[test]
fn test_read_nonblocking() {
let (_s, stream) = Server::new();
stream.set_nonblocking(true).unwrap();
let cx = SslContext::new(Sslv23).unwrap();
let mut stream = NonblockingSslStream::connect(&cx, stream).unwrap();
let mut iterations = 0;
loop {
iterations += 1;
if iterations > 7 {
// Probably a safe assumption for the foreseeable future of
// openssl.
panic!("Too many read/write round trips in handshake!!");
}
let result = stream.write(b"GET /\r\n\r\n");
match result {
Ok(n) => {
assert_eq!(n, 9);
break;
}
Err(NonblockingSslError::WantRead) => {
assert!(wait_io(&stream, true, 1000));
}
Err(NonblockingSslError::WantWrite) => {
assert!(wait_io(&stream, false, 1000));
}
Err(other) => {
panic!("Unexpected SSL Error: {:?}", other);
}
}
}
let mut input_buffer = [0u8; 1500];
let result = stream.read(&mut input_buffer);
let bytes_read = match result {
Ok(n) => {
// This branch is unlikely, but on an overloaded VM with
// unlucky context switching, the response could actually
// be in the receive buffer before we issue the read() syscall...
n
}
Err(NonblockingSslError::WantRead) => {
assert!(wait_io(&stream, true, 3000));
// Second read should return application data.
stream.read(&mut input_buffer).unwrap()
}
Err(other) => {
panic!("Unexpected SSL Error: {:?}", other);
}
};
assert!(bytes_read >= 5);
assert_eq!(&input_buffer[..5], b"HTTP/");
}
#[test]
fn broken_try_clone_doesnt_crash() {
let context = SslContext::new(SslMethod::Sslv23).unwrap();
let inner = TcpStream::connect("example.com:443").unwrap();
let stream1 = SslStream::connect(&context, inner).unwrap();
let _stream2 = stream1.try_clone().unwrap();
}
#[test]
#[should_panic(expected = "blammo")]
#[cfg(feature = "nightly")]
fn write_panic() {
struct ExplodingStream(TcpStream);
impl Read for ExplodingStream {
fn read(&mut self, buf: &mut [u8]) -> io::Result<usize> {
self.0.read(buf)
}
}
impl Write for ExplodingStream {
fn write(&mut self, _: &[u8]) -> io::Result<usize> {
panic!("blammo");
}
fn flush(&mut self) -> io::Result<()> {
self.0.flush()
}
}
let (_s, stream) = Server::new();
let stream = ExplodingStream(stream);
let ctx = SslContext::new(SslMethod::Sslv23).unwrap();
let _ = SslStream::connect(&ctx, stream);
}
#[test]
#[should_panic(expected = "blammo")]
#[cfg(feature = "nightly")]
fn read_panic() {
struct ExplodingStream(TcpStream);
impl Read for ExplodingStream {
fn read(&mut self, _: &mut [u8]) -> io::Result<usize> {
panic!("blammo");
}
}
impl Write for ExplodingStream {
fn write(&mut self, buf: &[u8]) -> io::Result<usize> {
self.0.write(buf)
}
fn flush(&mut self) -> io::Result<()> {
self.0.flush()
}
}
let (_s, stream) = Server::new();
let stream = ExplodingStream(stream);
let ctx = SslContext::new(SslMethod::Sslv23).unwrap();
let _ = SslStream::connect(&ctx, stream);
}
#[test]
#[should_panic(expected = "blammo")]
#[cfg(feature = "nightly")]
fn flush_panic() {
struct ExplodingStream(TcpStream);
impl Read for ExplodingStream {
fn read(&mut self, buf: &mut [u8]) -> io::Result<usize> {
self.0.read(buf)
}
}
impl Write for ExplodingStream {
fn write(&mut self, buf: &[u8]) -> io::Result<usize> {
self.0.write(buf)
}
fn flush(&mut self) -> io::Result<()> {
panic!("blammo");
}
}
let (_s, stream) = Server::new();
let stream = ExplodingStream(stream);
let ctx = SslContext::new(SslMethod::Sslv23).unwrap();
let mut stream = SslStream::connect(&ctx, stream).unwrap();
let _ = stream.flush();
}
#[test]
fn refcount_ssl_context() {
let ssl = {
let ctx = SslContext::new(SslMethod::Sslv23).unwrap();
ssl::Ssl::new(&ctx).unwrap()
};
{
let new_ctx_a = SslContext::new(SslMethod::Sslv23).unwrap();
let _new_ctx_b = ssl.set_ssl_context(&new_ctx_a);
}
}
#[test]
#[cfg_attr(windows, ignore)] // don't have a trusted CA list easily available :(
fn default_verify_paths() {
let mut ctx = SslContext::new(SslMethod::Sslv23).unwrap();
ctx.set_default_verify_paths().unwrap();
ctx.set_verify(SSL_VERIFY_PEER, None);
let s = TcpStream::connect("google.com:443").unwrap();
let mut socket = SslStream::connect(&ctx, s).unwrap();
socket.write_all(b"GET / HTTP/1.0\r\n\r\n").unwrap();
let mut result = vec![];
socket.read_to_end(&mut result).unwrap();
println!("{}", String::from_utf8_lossy(&result));
assert!(result.starts_with(b"HTTP/1.0"));
assert!(result.ends_with(b"</HTML>\r\n") || result.ends_with(b"</html>"));
}
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