// ********************************************************************** // // Copyright (c) 2001 // MutableRealms, Inc. // Huntsville, AL, USA // // All Rights Reserved // // ********************************************************************** #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace std; using namespace Ice; using namespace IceInternal; void IceInternal::incRef(Endpoint* p) { p->__incRef(); } void IceInternal::decRef(Endpoint* p) { p->__decRef(); } EndpointPtr IceInternal::Endpoint::endpointFromString(const InstancePtr& instance, const string& str) { const string delim = " \t\n\r"; string::size_type beg = str.find_first_not_of(delim); if (beg == string::npos) { throw EndpointParseException(__FILE__, __LINE__); } string::size_type end = str.find_first_of(delim, beg); if (end == string::npos) { end = str.length(); } string protocol = str.substr(beg, end - beg); if (protocol == "default") { protocol = instance->defaultProtocol(); } if (protocol == "tcp") { return new TcpEndpoint(instance, str.substr(end)); } if (protocol == "ssl") { return new SslEndpoint(instance, str.substr(end)); } if (protocol == "udp") { return new UdpEndpoint(instance, str.substr(end)); } if (protocol == "sudp") { return new SUdpEndpoint(instance, str.substr(end)); } throw EndpointParseException(__FILE__, __LINE__); } void IceInternal::Endpoint::streamRead(BasicStream* s, EndpointPtr& v) { Short type; s->read(type); switch (type) { case TcpEndpointType: { v = new TcpEndpoint(s); break; } case SslEndpointType: { v = new SslEndpoint(s); break; } case UdpEndpointType: { v = new UdpEndpoint(s); break; } case SUdpEndpointType: { v = new SUdpEndpoint(s); break; } default: { v = new UnknownEndpoint(s); break; } } } IceInternal::UnknownEndpoint::UnknownEndpoint(BasicStream* s) : _instance(s->instance()) { s->read(const_cast&>(_rawBytes)); } void IceInternal::UnknownEndpoint::streamWrite(BasicStream* s) const { s->write(UnknownEndpointType); s->write(_rawBytes); } string IceInternal::UnknownEndpoint::toString() const { return string(); } Short IceInternal::UnknownEndpoint::type() const { return UnknownEndpointType; } Int IceInternal::UnknownEndpoint::timeout() const { return -1; } EndpointPtr IceInternal::UnknownEndpoint::timeout(Int) const { return const_cast(this); } bool IceInternal::UnknownEndpoint::datagram() const { return false; } bool IceInternal::UnknownEndpoint::secure() const { return false; } TransceiverPtr IceInternal::UnknownEndpoint::clientTransceiver() const { return 0; } TransceiverPtr IceInternal::UnknownEndpoint::serverTransceiver(EndpointPtr& endp) const { endp = const_cast(this); return 0; } ConnectorPtr IceInternal::UnknownEndpoint::connector() const { return 0; } AcceptorPtr IceInternal::UnknownEndpoint::acceptor(EndpointPtr& endp) const { endp = const_cast(this); return 0; } bool IceInternal::UnknownEndpoint::equivalent(const TransceiverPtr&) const { return false; } bool IceInternal::UnknownEndpoint::equivalent(const AcceptorPtr&) const { return false; } bool IceInternal::UnknownEndpoint::operator==(const Endpoint& r) const { const UnknownEndpoint* p = dynamic_cast(&r); if (!p) { return false; } if (this == p) { return true; } if (_rawBytes != p->_rawBytes) { return false; } return true; } bool IceInternal::UnknownEndpoint::operator!=(const Endpoint& r) const { return !operator==(r); } bool IceInternal::UnknownEndpoint::operator<(const Endpoint& r) const { const UnknownEndpoint* p = dynamic_cast(&r); if (!p) { return true; // unknown is "less than" every other protocol } if (this == p) { return false; } if (_rawBytes < p->_rawBytes) { return true; } else if (p->_rawBytes < _rawBytes) { return false; } return false; } IceInternal::TcpEndpoint::TcpEndpoint(const InstancePtr& instance, const string& ho, Int po, Int ti) : _instance(instance), _host(ho), _port(po), _timeout(ti) { } IceInternal::TcpEndpoint::TcpEndpoint(const InstancePtr& instance, const string& str) : _instance(instance), _port(0), _timeout(-1) { const string delim = " \t\n\r"; string::size_type beg; string::size_type end = 0; while (true) { beg = str.find_first_not_of(delim, end); if (beg == string::npos) { break; } end = str.find_first_of(delim, beg); if (end == string::npos) { end = str.length(); } string option = str.substr(beg, end - beg); if (option.length() != 2 || option[0] != '-') { throw EndpointParseException(__FILE__, __LINE__); } string argument; string::size_type argumentBeg = str.find_first_not_of(delim, end); if (argumentBeg != string::npos && str[argumentBeg] != '-') { beg = argumentBeg; end = str.find_first_of(delim, beg); if (end == string::npos) { end = str.length(); } argument = str.substr(beg, end - beg); } switch (option[1]) { case 'h': { if (argument.empty()) { throw EndpointParseException(__FILE__, __LINE__); } const_cast(_host) = argument; break; } case 'p': { if (argument.empty()) { throw EndpointParseException(__FILE__, __LINE__); } const_cast(_port) = atoi(argument.c_str()); break; } case 't': { if (argument.empty()) { throw EndpointParseException(__FILE__, __LINE__); } const_cast(_timeout) = atoi(argument.c_str()); break; } default: { throw EndpointParseException(__FILE__, __LINE__); } } } if (_host.empty()) { const_cast(_host) = _instance->defaultHost(); } } IceInternal::TcpEndpoint::TcpEndpoint(BasicStream* s) : _instance(s->instance()), _port(0), _timeout(-1) { s->startReadEncaps(); s->read(const_cast(_host)); s->read(const_cast(_port)); s->read(const_cast(_timeout)); s->endReadEncaps(); } void IceInternal::TcpEndpoint::streamWrite(BasicStream* s) const { s->write(TcpEndpointType); s->startWriteEncaps(); s->write(_host); s->write(_port); s->write(_timeout); s->endWriteEncaps(); } string IceInternal::TcpEndpoint::toString() const { ostringstream s; s << "tcp -h " << _host << " -p " << _port << " -t " << _timeout; return s.str(); } Short IceInternal::TcpEndpoint::type() const { return TcpEndpointType; } Int IceInternal::TcpEndpoint::timeout() const { return _timeout; } EndpointPtr IceInternal::TcpEndpoint::timeout(Int timeout) const { if (timeout == _timeout) { return const_cast(this); } else { return new TcpEndpoint(_instance, _host, _port, timeout); } } bool IceInternal::TcpEndpoint::datagram() const { return false; } bool IceInternal::TcpEndpoint::secure() const { return false; } TransceiverPtr IceInternal::TcpEndpoint::clientTransceiver() const { return 0; } TransceiverPtr IceInternal::TcpEndpoint::serverTransceiver(EndpointPtr& endp) const { endp = const_cast(this); return 0; } ConnectorPtr IceInternal::TcpEndpoint::connector() const { return new TcpConnector(_instance, _host, _port); } AcceptorPtr IceInternal::TcpEndpoint::acceptor(EndpointPtr& endp) const { TcpAcceptor* p = new TcpAcceptor(_instance, _port); endp = new TcpEndpoint(_instance, _host, p->effectivePort(), _timeout); return p; } bool IceInternal::TcpEndpoint::equivalent(const TransceiverPtr&) const { return false; } bool IceInternal::TcpEndpoint::equivalent(const AcceptorPtr& acceptor) const { const TcpAcceptor* tcpAcceptor = dynamic_cast(acceptor.get()); if (!tcpAcceptor) { return false; } return tcpAcceptor->equivalent(_host, _port); } bool IceInternal::TcpEndpoint::operator==(const Endpoint& r) const { const TcpEndpoint* p = dynamic_cast(&r); if (!p) { return false; } if (this == p) { return true; } if (_port != p->_port) { return false; } if (_timeout != p->_timeout) { return false; } struct sockaddr_in laddr; struct sockaddr_in raddr; getAddress(_host.c_str(), _port, laddr); getAddress(p->_host.c_str(), p->_port, raddr); if (memcmp(&laddr, &raddr, sizeof(struct sockaddr_in)) != 0) { return false; } return true; } bool IceInternal::TcpEndpoint::operator!=(const Endpoint& r) const { return !operator==(r); } bool IceInternal::TcpEndpoint::operator<(const Endpoint& r) const { const TcpEndpoint* p = dynamic_cast(&r); if (!p) { if (dynamic_cast(&r)) { return false; // tcp is not "less than" ssl } if (dynamic_cast(&r)) { return false; // tcp is not "less than" udp } if (dynamic_cast(&r)) { return false; // tcp is not "less than" sudp } if (dynamic_cast(&r)) { return false; // tcp is not "less than" unknown } assert(false); } if (this == p) { return false; } struct sockaddr_in laddr; struct sockaddr_in raddr; getAddress(_host.c_str(), _port, laddr); getAddress(p->_host.c_str(), p->_port, raddr); if (laddr.sin_addr.s_addr < raddr.sin_addr.s_addr) { return true; } else if (raddr.sin_addr.s_addr < laddr.sin_addr.s_addr) { return false; } if (_port < p->_port) { return true; } else if (p->_port < _port) { return false; } if (_timeout < p->_timeout) { return true; } else if (p->_timeout < _timeout) { return false; } return false; } IceInternal::SslEndpoint::SslEndpoint(const InstancePtr& instance, const string& ho, Int po, Int ti) : _instance(instance), _host(ho), _port(po), _timeout(ti) { } IceInternal::SslEndpoint::SslEndpoint(const InstancePtr& instance, const string& str) : _instance(instance), _port(0), _timeout(-1) { const string delim = " \t\n\r"; string::size_type beg; string::size_type end = 0; while (true) { beg = str.find_first_not_of(delim, end); if (beg == string::npos) { break; } end = str.find_first_of(delim, beg); if (end == string::npos) { end = str.length(); } string option = str.substr(beg, end - beg); if (option.length() != 2 || option[0] != '-') { throw EndpointParseException(__FILE__, __LINE__); } beg = str.find_first_not_of(delim, end); if (beg == string::npos) { throw EndpointParseException(__FILE__, __LINE__); } end = str.find_first_of(delim, beg); if (end == string::npos) { end = str.length(); } string argument = str.substr(beg, end - beg); switch (option[1]) { case 'h': { const_cast(_host) = argument; break; } case 'p': { const_cast(_port) = atoi(argument.c_str()); break; } case 't': { const_cast(_timeout) = atoi(argument.c_str()); break; } default: { throw EndpointParseException(__FILE__, __LINE__); } } } if (_host.empty()) { const_cast(_host) = _instance->defaultHost(); } } IceInternal::SslEndpoint::SslEndpoint(BasicStream* s) : _instance(s->instance()), _port(0), _timeout(-1) { s->startReadEncaps(); s->read(const_cast(_host)); s->read(const_cast(_port)); s->read(const_cast(_timeout)); s->endReadEncaps(); } void IceInternal::SslEndpoint::streamWrite(BasicStream* s) const { s->write(SslEndpointType); s->startWriteEncaps(); s->write(_host); s->write(_port); s->write(_timeout); s->endWriteEncaps(); } string IceInternal::SslEndpoint::toString() const { ostringstream s; s << "ssl -h " << _host << " -p " << _port << " -t " << _timeout; return s.str(); } Short IceInternal::SslEndpoint::type() const { return SslEndpointType; } Int IceInternal::SslEndpoint::timeout() const { return _timeout; } EndpointPtr IceInternal::SslEndpoint::timeout(Int timeout) const { if (timeout == _timeout) { return const_cast(this); } else { return new SslEndpoint(_instance, _host, _port, timeout); } } bool IceInternal::SslEndpoint::datagram() const { return false; } bool IceInternal::SslEndpoint::secure() const { return true; } TransceiverPtr IceInternal::SslEndpoint::clientTransceiver() const { return 0; } TransceiverPtr IceInternal::SslEndpoint::serverTransceiver(EndpointPtr& endp) const { endp = const_cast(this); return 0; } ConnectorPtr IceInternal::SslEndpoint::connector() const { return new SslConnector(_instance, _host, _port); } AcceptorPtr IceInternal::SslEndpoint::acceptor(EndpointPtr& endp) const { SslAcceptor* p = new SslAcceptor(_instance, _port); endp = new SslEndpoint(_instance, _host, p->effectivePort(), _timeout); return p; } bool IceInternal::SslEndpoint::equivalent(const TransceiverPtr&) const { return false; } bool IceInternal::SslEndpoint::equivalent(const AcceptorPtr& acceptor) const { const SslAcceptor* sslAcceptor = dynamic_cast(acceptor.get()); if (!sslAcceptor) { return false; } return sslAcceptor->equivalent(_host, _port); } bool IceInternal::SslEndpoint::operator==(const Endpoint& r) const { const SslEndpoint* p = dynamic_cast(&r); if (!p) { return false; } if (this == p) { return true; } if (_port != p->_port) { return false; } if (_timeout != p->_timeout) { return false; } struct sockaddr_in laddr; struct sockaddr_in raddr; getAddress(_host.c_str(), _port, laddr); getAddress(p->_host.c_str(), p->_port, raddr); if (memcmp(&laddr, &raddr, sizeof(struct sockaddr_in)) != 0) { return false; } return true; } bool IceInternal::SslEndpoint::operator!=(const Endpoint& r) const { return !operator==(r); } bool IceInternal::SslEndpoint::operator<(const Endpoint& r) const { const SslEndpoint* p = dynamic_cast(&r); if (!p) { if (dynamic_cast(&r)) { return true; // ssl is "less than" tcp } if (dynamic_cast(&r)) { return false; // ssl is not "less than" udp } if (dynamic_cast(&r)) { return false; // ssl is not "less than" sudp } if (dynamic_cast(&r)) { return false; // ssl is not "less than" unknown } assert(false); } if (this == p) { return false; } struct sockaddr_in laddr; struct sockaddr_in raddr; getAddress(_host.c_str(), _port, laddr); getAddress(p->_host.c_str(), p->_port, raddr); if (laddr.sin_addr.s_addr < raddr.sin_addr.s_addr) { return true; } else if (raddr.sin_addr.s_addr < laddr.sin_addr.s_addr) { return false; } if (_port < p->_port) { return true; } else if (p->_port < _port) { return false; } if (_timeout < p->_timeout) { return true; } else if (p->_timeout < _timeout) { return false; } return false; } IceInternal::UdpEndpoint::UdpEndpoint(const InstancePtr& instance, const string& ho, Int po) : _instance(instance), _host(ho), _port(po) { } IceInternal::UdpEndpoint::UdpEndpoint(const InstancePtr& instance, const string& str) : _instance(instance), _port(0) { const string delim = " \t\n\r"; string::size_type beg; string::size_type end = 0; while (true) { beg = str.find_first_not_of(delim, end); if (beg == string::npos) { break; } end = str.find_first_of(delim, beg); if (end == string::npos) { end = str.length(); } string option = str.substr(beg, end - beg); if (option.length() != 2 || option[0] != '-') { throw EndpointParseException(__FILE__, __LINE__); } beg = str.find_first_not_of(delim, end); if (beg == string::npos) { throw EndpointParseException(__FILE__, __LINE__); } end = str.find_first_of(delim, beg); if (end == string::npos) { end = str.length(); } string argument = str.substr(beg, end - beg); switch (option[1]) { case 'h': { const_cast(_host) = argument; break; } case 'p': { const_cast(_port) = atoi(argument.c_str()); break; } default: { throw EndpointParseException(__FILE__, __LINE__); } } } if (_host.empty()) { const_cast(_host) = _instance->defaultHost(); } } IceInternal::UdpEndpoint::UdpEndpoint(BasicStream* s) : _instance(s->instance()), _port(0) { s->startReadEncaps(); s->read(const_cast(_host)); s->read(const_cast(_port)); s->endReadEncaps(); } void IceInternal::UdpEndpoint::streamWrite(BasicStream* s) const { s->write(UdpEndpointType); s->startWriteEncaps(); s->write(_host); s->write(_port); s->endWriteEncaps(); } string IceInternal::UdpEndpoint::toString() const { ostringstream s; s << "udp -h " << _host << " -p " << _port; return s.str(); } Short IceInternal::UdpEndpoint::type() const { return UdpEndpointType; } Int IceInternal::UdpEndpoint::timeout() const { return -1; } EndpointPtr IceInternal::UdpEndpoint::timeout(Int) const { return const_cast(this); } bool IceInternal::UdpEndpoint::datagram() const { return true; } bool IceInternal::UdpEndpoint::secure() const { return false; } TransceiverPtr IceInternal::UdpEndpoint::clientTransceiver() const { return new UdpTransceiver(_instance, _host, _port); } TransceiverPtr IceInternal::UdpEndpoint::serverTransceiver(EndpointPtr& endp) const { UdpTransceiver* p = new UdpTransceiver(_instance, _port); endp = new UdpEndpoint(_instance, _host, p->effectivePort()); return p; } ConnectorPtr IceInternal::UdpEndpoint::connector() const { return 0; } AcceptorPtr IceInternal::UdpEndpoint::acceptor(EndpointPtr& endp) const { endp = const_cast(this); return 0; } bool IceInternal::UdpEndpoint::equivalent(const TransceiverPtr& transceiver) const { const UdpTransceiver* udpTransceiver = dynamic_cast(transceiver.get()); if (!udpTransceiver) { return false; } return udpTransceiver->equivalent(_host, _port); } bool IceInternal::UdpEndpoint::equivalent(const AcceptorPtr&) const { return false; } bool IceInternal::UdpEndpoint::operator==(const Endpoint& r) const { const UdpEndpoint* p = dynamic_cast(&r); if (!p) { return false; } if (this == p) { return true; } if (_port != p->_port) { return false; } struct sockaddr_in laddr; struct sockaddr_in raddr; getAddress(_host.c_str(), _port, laddr); getAddress(p->_host.c_str(), p->_port, raddr); if (memcmp(&laddr, &raddr, sizeof(struct sockaddr_in)) != 0) { return false; } return true; } bool IceInternal::UdpEndpoint::operator!=(const Endpoint& r) const { return !operator==(r); } bool IceInternal::UdpEndpoint::operator<(const Endpoint& r) const { const UdpEndpoint* p = dynamic_cast(&r); if (!p) { if (dynamic_cast(&r)) { return true; // udp is "less than" ssl } if (dynamic_cast(&r)) { return true; // udp is "less than" tcp } if (dynamic_cast(&r)) { return false; // udp is not "less than" sudp } if (dynamic_cast(&r)) { return false; // udp is not "less than" unknown } assert(false); } if (this == p) { return false; } struct sockaddr_in laddr; struct sockaddr_in raddr; getAddress(_host.c_str(), _port, laddr); getAddress(p->_host.c_str(), p->_port, raddr); if (laddr.sin_addr.s_addr < raddr.sin_addr.s_addr) { return true; } else if (raddr.sin_addr.s_addr < laddr.sin_addr.s_addr) { return false; } if (_port < p->_port) { return true; } else if (p->_port < _port) { return false; } return false; } /////////////////////////////////////// IceInternal::SUdpEndpoint::SUdpEndpoint(const InstancePtr& instance, const string& ho, Int po) : _instance(instance), _host(ho), _port(po) { } IceInternal::SUdpEndpoint::SUdpEndpoint(const InstancePtr& instance, const string& str) : _instance(instance), _port(0) { const string delim = " \t\n\r"; string::size_type beg; string::size_type end = 0; while (true) { beg = str.find_first_not_of(delim, end); if (beg == string::npos) { break; } end = str.find_first_of(delim, beg); if (end == string::npos) { end = str.length(); } string option = str.substr(beg, end - beg); if (option.length() != 2 || option[0] != '-') { throw EndpointParseException(__FILE__, __LINE__); } beg = str.find_first_not_of(delim, end); if (beg == string::npos) { throw EndpointParseException(__FILE__, __LINE__); } end = str.find_first_of(delim, beg); if (end == string::npos) { end = str.length(); } string argument = str.substr(beg, end - beg); switch (option[1]) { case 'h': { const_cast(_host) = argument; break; } case 'p': { const_cast(_port) = atoi(argument.c_str()); break; } default: { throw EndpointParseException(__FILE__, __LINE__); } } } if (_host.empty()) { const_cast(_host) = _instance->defaultHost(); } } IceInternal::SUdpEndpoint::SUdpEndpoint(BasicStream* s) : _instance(s->instance()), _port(0) { s->startReadEncaps(); s->read(const_cast(_host)); s->read(const_cast(_port)); s->endReadEncaps(); } void IceInternal::SUdpEndpoint::streamWrite(BasicStream* s) const { s->write(SUdpEndpointType); s->startWriteEncaps(); s->write(_host); s->write(_port); s->endWriteEncaps(); } string IceInternal::SUdpEndpoint::toString() const { ostringstream s; s << "sudp -h " << _host << " -p " << _port; return s.str(); } Short IceInternal::SUdpEndpoint::type() const { return SUdpEndpointType; } Int IceInternal::SUdpEndpoint::timeout() const { return -1; } EndpointPtr IceInternal::SUdpEndpoint::timeout(Int) const { return const_cast(this); } bool IceInternal::SUdpEndpoint::datagram() const { return true; } bool IceInternal::SUdpEndpoint::secure() const { return true; } TransceiverPtr IceInternal::SUdpEndpoint::clientTransceiver() const { return new SUdpTransceiver(_instance, _host, _port); } TransceiverPtr IceInternal::SUdpEndpoint::serverTransceiver(EndpointPtr& endp) const { SUdpTransceiver* p = new SUdpTransceiver(_instance, _port); endp = new SUdpEndpoint(_instance, _host, p->effectivePort()); return p; } ConnectorPtr IceInternal::SUdpEndpoint::connector() const { return 0; } AcceptorPtr IceInternal::SUdpEndpoint::acceptor(EndpointPtr& endp) const { endp = const_cast(this); return 0; } bool IceInternal::SUdpEndpoint::equivalent(const TransceiverPtr& transceiver) const { const SUdpTransceiver* sudpTransceiver = dynamic_cast(transceiver.get()); if (!sudpTransceiver) { return false; } return sudpTransceiver->equivalent(_host, _port); } bool IceInternal::SUdpEndpoint::equivalent(const AcceptorPtr&) const { return false; } bool IceInternal::SUdpEndpoint::operator==(const Endpoint& r) const { const SUdpEndpoint* p = dynamic_cast(&r); if (!p) { return false; } if (this == p) { return true; } if (_port != p->_port) { return false; } struct sockaddr_in laddr; struct sockaddr_in raddr; getAddress(_host.c_str(), _port, laddr); getAddress(p->_host.c_str(), p->_port, raddr); if (memcmp(&laddr, &raddr, sizeof(struct sockaddr_in)) != 0) { return false; } return true; } bool IceInternal::SUdpEndpoint::operator!=(const Endpoint& r) const { return !operator==(r); } bool IceInternal::SUdpEndpoint::operator<(const Endpoint& r) const { const SUdpEndpoint* p = dynamic_cast(&r); if (!p) { if (dynamic_cast(&r)) { return true; // sudp is "less than" ssl } if (dynamic_cast(&r)) { return true; // sudp is "less than" tcp } if (dynamic_cast(&r)) { return true; // sudp is "less than" udp } if (dynamic_cast(&r)) { return false; // sudp is not "less than" unknown } assert(false); } if (this == p) { return false; } struct sockaddr_in laddr; struct sockaddr_in raddr; getAddress(_host.c_str(), _port, laddr); getAddress(p->_host.c_str(), p->_port, raddr); if (laddr.sin_addr.s_addr < raddr.sin_addr.s_addr) { return true; } else if (raddr.sin_addr.s_addr < laddr.sin_addr.s_addr) { return false; } if (_port < p->_port) { return true; } else if (p->_port < _port) { return false; } return false; }