int
ACE_TP_Reactor::handle_events (ACE_Time_Value *max_wait_time)
{
ACE_TRACE ("ACE_TP_Reactor::handle_events");
// Stash the current time -- the destructor of this object will
// automatically compute how much time elapsed since this method was
// called.
ACE_Countdown_Time countdown (max_wait_time);
//
// The order of these events is very subtle, modify with care.
//
// Instantiate the token guard which will try grabbing the token for
// this thread.
ACE_TP_Token_Guard guard (this->token_);
int const result = guard.acquire_read_token (max_wait_time);
// If the guard is NOT the owner just return the retval
if (!guard.is_owner ())
return result;
// After getting the lock just just for deactivation..
if (this->deactivated_)
return -1;
// Update the countdown to reflect time waiting for the token.
countdown.update ();
return this->dispatch_i (max_wait_time, guard);
}
int
ACE_SSL_SOCK_Acceptor::accept (ACE_SSL_SOCK_Stream &new_stream,
ACE_Accept_QoS_Params qos_params,
ACE_Addr *remote_addr,
ACE_Time_Value *timeout,
int restart,
int reset_new_handle) const
{
ACE_TRACE ("ACE_SSL_SOCK_Acceptor::accept");
// Take into account the time to complete the basic TCP handshake
// and the SSL handshake.
ACE_Countdown_Time countdown (timeout);
ACE_SOCK_Stream temp_stream;
if (-1 == this->acceptor_.accept (temp_stream,
qos_params,
remote_addr,
timeout,
restart,
reset_new_handle))
return -1;
(void) countdown.update ();
new_stream.set_handle (temp_stream.get_handle ());
temp_stream.set_handle (ACE_INVALID_HANDLE);
if (this->ssl_accept (new_stream, timeout) == -1)
{
new_stream.close ();
new_stream.set_handle (ACE_INVALID_HANDLE);
return -1;
}
return 0;
}
ssize_t
ACE_SSL_SOCK_Stream::sendv (const iovec iov[],
size_t n,
const ACE_Time_Value *max_wait_time) const
{
ACE_TRACE ("ACE_SSL_SOCK_Stream::sendv");
// There is subtle problem in this method that occurs when using
// non-blocking IO. The semantics of a non-blocking scatter write
// (sendv()) are not possible to retain with the emulation in this
// method.
ssize_t bytes_sent = 0;
ACE_Time_Value t;
ACE_Time_Value *timeout = const_cast<ACE_Time_Value *> (max_wait_time);
if (max_wait_time != 0)
{
// Make a copy since ACE_Countdown_Time modifies the
// ACE_Time_Value.
t = *max_wait_time;
timeout = &t;
}
// Take into account the time between each send.
ACE_Countdown_Time countdown (timeout);
for (size_t i = 0; i < n; ++i)
{
ssize_t const result = this->send (iov[i].iov_base,
iov[i].iov_len,
timeout);
if (result == -1)
{
// There is a subtle difference in behaviour depending on
// whether or not any data was sent. If no data was sent,
// then always return -1. Otherwise return bytes_sent.
// This gives the caller an opportunity to keep track of
if (bytes_sent > 0)
break;
else
return -1;
}
else
{
bytes_sent += result;
// Do not continue on to the next loop iteration if the
// amount of data sent was less than the amount data given.
// This avoids a subtle problem where "holes" in the data
// stream would occur if partial sends of a given buffer in
// the iovec array occured.
if (static_cast<size_t> (result) < static_cast<size_t> (iov[i].iov_len))
break;
}
(void) countdown.update ();
}
return bytes_sent;
}
int
ACE_SSL_SOCK_Acceptor::ssl_accept (ACE_SSL_SOCK_Stream &new_stream,
ACE_Time_Value *timeout) const
{
SSL *ssl = new_stream.ssl ();
if (SSL_is_init_finished (ssl))
return 0;
if (!SSL_in_accept_init (ssl))
::SSL_set_accept_state (ssl);
ACE_HANDLE handle = new_stream.get_handle ();
// We're going to call SSL_accept, optionally doing ACE::select and
// retrying the SSL_accept, until the SSL handshake is done or
// it fails.
// To get the timeout affect, set the socket to nonblocking mode
// before beginning if there is a timeout specified. If the timeout
// is 0 (wait as long as it takes) then don't worry about the blocking
// status; we'll block in SSL_accept if the socket is blocking, and
// block in ACE::select if not.
int reset_blocking_mode = 0;
if (timeout != 0)
{
reset_blocking_mode = ACE_BIT_DISABLED (ACE::get_flags (handle),
ACE_NONBLOCK);
// Set the handle into non-blocking mode if it's not already
// in it.
if (reset_blocking_mode
&& ACE::set_flags (handle,
ACE_NONBLOCK) == -1)
return -1;
}
// Take into account the time between each select() call below.
ACE_Countdown_Time countdown (timeout);
int status;
do
{
// These handle sets are used to set up for whatever SSL_accept
// says it wants next. They're reset on each pass around the loop.
ACE_Handle_Set rd_handle;
ACE_Handle_Set wr_handle;
status = ::SSL_accept (ssl);
switch (::SSL_get_error (ssl, status))
{
case SSL_ERROR_NONE:
status = 0; // To tell caller about success
break; // Done
case SSL_ERROR_WANT_WRITE:
wr_handle.set_bit (handle);
status = 1; // Wait for more activity
break;
case SSL_ERROR_WANT_READ:
rd_handle.set_bit (handle);
status = 1; // Wait for more activity
break;
case SSL_ERROR_ZERO_RETURN:
// The peer has notified us that it is shutting down via
// the SSL "close_notify" message so we need to
// shutdown, too.
status = -1;
break;
case SSL_ERROR_SYSCALL:
// On some platforms (e.g. MS Windows) OpenSSL does not
// store the last error in errno so explicitly do so.
//
// Explicitly check for EWOULDBLOCK since it doesn't get
// converted to an SSL_ERROR_WANT_{READ,WRITE} on some
// platforms. If SSL_accept failed outright, though, don't
// bother checking more. This can happen if the socket gets
// closed during the handshake.
if (ACE_OS::set_errno_to_last_error () == EWOULDBLOCK &&
status == -1)
{
// Although the SSL_ERROR_WANT_READ/WRITE isn't getting
// set correctly, the read/write state should be valid.
// Use that to decide what to do.
status = 1; // Wait for more activity
if (SSL_want_write (ssl))
wr_handle.set_bit (handle);
else if (SSL_want_read (ssl))
rd_handle.set_bit (handle);
else
status = -1; // Doesn't want anything - bail out
}
else
status = -1;
break;
default:
ACE_SSL_Context::report_error ();
status = -1;
break;
}
if (status == 1)
{
// Must have at least one handle to wait for at this point.
ACE_ASSERT (rd_handle.num_set() == 1 || wr_handle.num_set () == 1);
status = ACE::select (int (handle) + 1,
&rd_handle,
&wr_handle,
0,
timeout);
(void) countdown.update ();
// 0 is timeout, so we're done.
// -1 is error, so we're done.
// Could be both handles set (same handle in both masks) so
// set to 1.
if (status >= 1)
status = 1;
else // Timeout or failure
status = -1;
}
} while (status == 1 && !SSL_is_init_finished (ssl));
if (reset_blocking_mode)
{
ACE_Errno_Guard eguard (errno);
ACE::clr_flags (handle, ACE_NONBLOCK);
}
return (status == -1 ? -1 : 0);
}