int ACE_SSL_SOCK_Acceptor::ssl_accept (ACE_SSL_SOCK_Stream &new_stream) const { if (SSL_is_init_finished (new_stream.ssl ())) return 0; if (!SSL_in_accept_init (new_stream.ssl ())) ::SSL_set_accept_state (new_stream.ssl ()); int status = ::SSL_accept (new_stream.ssl ()); switch (::SSL_get_error (new_stream.ssl (), status)) { case SSL_ERROR_NONE: 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. (void) new_stream.close (); return -1; default: ACE_SSL_Context::report_error (); return -1; } return 0; }
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); // Register an event handler to complete the non-blocking SSL // accept. A specialized event handler is necessary since since // the ACE Acceptor strategies are not designed for protocols // that require additional handshakes after the initial accept. ACE_SSL_Accept_Handler eh (new_stream); const ACE_Reactor_Mask reactor_mask = ACE_Event_Handler::READ_MASK | ACE_Event_Handler::WRITE_MASK; // In case a thread other than the one running the Reactor event // loop performs the passive SSL connection establishment, transfer // ownership of the Reactor to the current thread. Control will be // passed back to the previous owner when accepting or rejecting the // passive SSL connection. ACE_thread_t old_owner; if (this->reactor_->owner (ACE_Thread::self (), &old_owner) != 0) return -1; // Failed to transfer ownership! Should never happen! if (this->reactor_->register_handler ( new_stream.get_handle (), &eh, reactor_mask) == -1) return -1; // Have the Reactor complete the SSL passive connection. Run the // event loop until the passive connection is completed. Since // the Reactor is used, this isn't a busy wait. while (!SSL_is_init_finished (ssl)) { // Before blocking in the Reactor, do an SSL_accept() in case // OpenSSL buffered additional data sent within an SSL record // during session negotiation. The buffered data must be // handled prior to entering the Reactor event loop since the // Reactor may end up waiting indefinitely for data that has // already arrived. int status = ::SSL_accept (ssl); switch (::SSL_get_error (ssl, status)) { case SSL_ERROR_NONE: break; case SSL_ERROR_WANT_WRITE: case SSL_ERROR_WANT_READ: // No data buffered by OpenSSL, so wait for data in the // Reactor. if (this->reactor_->handle_events (timeout) == -1 || new_stream.get_handle () == ACE_INVALID_HANDLE) { (void) this->reactor_->remove_handler (&eh, reactor_mask); (void) this->reactor_->owner (old_owner); return -1; } 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. // // Removing the event handler from the Reactor causes the // SSL stream to be shutdown. (void) this->reactor_->remove_handler (&eh, reactor_mask); (void) this->reactor_->owner (old_owner); return -1; case SSL_ERROR_SYSCALL: // On some platforms (e.g. MS Windows) OpenSSL does not // store the last error in errno so explicitly do so. ACE_OS::set_errno_to_last_error (); default: ACE_SSL_Context::report_error (); (void) this->reactor_->remove_handler (&eh, reactor_mask); (void) this->reactor_->owner (old_owner); return -1; } } // SSL passive connection was completed. Deregister the event // handler from the Reactor, but don't close it. (void) this->reactor_->remove_handler (&eh, reactor_mask | ACE_Event_Handler::DONT_CALL); // Transfer control of the Reactor to the previous owner. return this->reactor_->owner (old_owner); }
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); }