// ********************************************************************** // // Copyright (c) 2003-2005 ZeroC, Inc. All rights reserved. // // This copy of Ice-E is licensed to you under the terms described in the // ICEE_LICENSE file included in this distribution. // // ********************************************************************** #include #include #include #include #include using namespace std; using namespace Ice; using namespace IceInternal; IceInternal::NonRepeatable::NonRepeatable(const NonRepeatable& ex) { _ex.reset(dynamic_cast(ex.get()->ice_clone())); } IceInternal::NonRepeatable::NonRepeatable(const ::Ice::LocalException& ex) { _ex.reset(dynamic_cast(ex.ice_clone())); } const ::Ice::LocalException* IceInternal::NonRepeatable::get() const { assert(_ex.get()); return _ex.get(); } IceInternal::Outgoing::Outgoing(Connection* connection, Reference* ref, const string& operation, OperationMode mode, const Context& context) : _connection(connection), _reference(ref), _state(StateUnsent), _is(ref->getInstance().get()), _os(ref->getInstance().get()) { switch(_reference->getMode()) { case Reference::ModeTwoway: case Reference::ModeOneway: { _connection->prepareRequest(&_os); break; } case Reference::ModeBatchOneway: #ifdef ICEE_HAS_BATCH { _connection->prepareBatchRequest(&_os); break; } #endif case Reference::ModeDatagram: case Reference::ModeBatchDatagram: { assert(false); break; } } _reference->getIdentity().__write(&_os); // // For compatibility with the old FacetPath. // if(_reference->getFacet().empty()) { _os.write(static_cast(0), static_cast(0)); } else { string facet = _reference->getFacet(); _os.write(&facet, &facet + 1); } _os.write(operation); _os.write(static_cast(mode)); _os.writeSize(Int(context.size())); Context::const_iterator p; for(p = context.begin(); p != context.end(); ++p) { _os.write(p->first); _os.write(p->second); } // // Input and output parameters are always sent in an // encapsulation, which makes it possible to forward requests as // blobs. // _os.startWriteEncaps(); } bool IceInternal::Outgoing::invoke() { #ifdef ICEE_BLOCKING_CLIENT assert(_state == StateUnsent); _os.endWriteEncaps(); switch(_reference->getMode()) { case Reference::ModeTwoway: { // // For blocking sends the reply is written directly // into the incoming stream. // try { _connection->sendBlockingRequest(&_os, &_is, this); finishedInternal(); } catch(const LocalException& ex) { _state = StateLocalException; _exception.reset(dynamic_cast(ex.ice_clone())); } if(_exception.get()) { // // A CloseConnectionException indicates graceful // server shutdown, and is therefore always repeatable // without violating "at-most-once". That's because by // sending a close connection message, the server // guarantees that all outstanding requests can safely // be repeated. // // An ObjectNotExistException can always be retried as // well without violating "at-most-once". // if(dynamic_cast(_exception.get()) || dynamic_cast(_exception.get())) { _exception->ice_throw(); } // // Throw the exception wrapped in a NonRepeatable, to // indicate that the request cannot be resent without // potentially violating the "at-most-once" principle. // throw NonRepeatable(*_exception.get()); } if(_state == StateUserException) { return false; } assert(_state == StateOK); break; } case Reference::ModeOneway: { // // For oneway requests, the connection object // never calls back on this object. Therefore we don't // need to lock the mutex or save exceptions. We simply // let all exceptions from sending propagate to the // caller, because such exceptions can be retried without // violating "at-most-once". // _state = StateInProgress; _connection->sendBlockingRequest(&_os, 0, 0); break; } case Reference::ModeBatchOneway: #ifdef ICEE_HAS_BATCH { // // For batch oneways, the same rules as for // regular oneways (see comment above) // apply. // _state = StateInProgress; _connection->finishBatchRequest(&_os); break; } #endif case Reference::ModeDatagram: case Reference::ModeBatchDatagram: { assert(false); return false; } } return true; #else assert(false); return false; #endif } void IceInternal::Outgoing::abort(const LocalException& ex) { assert(_state == StateUnsent); // // If we didn't finish a batch oneway request, we must // notify the connection about that we give up ownership of the // batch stream. // #ifdef ICEE_HAS_BATCH if(_reference->getMode() == Reference::ModeBatchOneway) { _connection->abortBatchRequest(); // // If we abort a batch requests, we cannot retry, because not // only the batch request that caused the problem will be // aborted, but all other requests in the batch as well. // throw NonRepeatable(ex); } #endif ex.ice_throw(); } void IceInternal::Outgoing::finishedInternal() { Byte status; _is.read(status); switch(static_cast(status)) { case DispatchOK: { // // Input and output parameters are always sent in an // encapsulation, which makes it possible to forward // oneway requests as blobs. // _is.startReadEncaps(); _state = StateOK; // The state must be set last, in case there is an exception. break; } case DispatchUserException: { // // Input and output parameters are always sent in an // encapsulation, which makes it possible to forward // oneway requests as blobs. // _is.startReadEncaps(); _state = StateUserException; // The state must be set last, in case there is an exception. break; } case DispatchObjectNotExist: case DispatchFacetNotExist: case DispatchOperationNotExist: { // // Don't read the exception members directly into the // exception. Otherwise if reading fails and raises an // exception, you will have a memory leak. // Identity ident; ident.__read(&_is); // // For compatibility with the old FacetPath. // vector facetPath; _is.read(facetPath); string facet; if(!facetPath.empty()) { if(facetPath.size() > 1) { throw MarshalException(__FILE__, __LINE__); } facet.swap(facetPath[0]); } string operation; _is.read(operation); RequestFailedException* ex; switch(static_cast(status)) { case DispatchObjectNotExist: { ex = new ObjectNotExistException(__FILE__, __LINE__); break; } case DispatchFacetNotExist: { ex = new FacetNotExistException(__FILE__, __LINE__); break; } case DispatchOperationNotExist: { ex = new OperationNotExistException(__FILE__, __LINE__); break; } default: { ex = 0; // To keep the compiler from complaining. assert(false); break; } } ex->id = ident; ex->facet = facet; ex->operation = operation; _exception.reset(ex); _state = StateLocalException; // The state must be set last, in case there is an exception. break; } case DispatchUnknownException: case DispatchUnknownLocalException: case DispatchUnknownUserException: { // // Don't read the exception members directly into the // exception. Otherwise if reading fails and raises an // exception, you will have a memory leak. // string unknown; _is.read(unknown); UnknownException* ex; switch(static_cast(status)) { case DispatchUnknownException: { ex = new UnknownException(__FILE__, __LINE__); break; } case DispatchUnknownLocalException: { ex = new UnknownLocalException(__FILE__, __LINE__); break; } case DispatchUnknownUserException: { ex = new UnknownUserException(__FILE__, __LINE__); break; } default: { ex = 0; // To keep the compiler from complaining. assert(false); break; } } ex->unknown = unknown; _exception.reset(ex); _state = StateLocalException; // The state must be set last, in case there is an exception. break; } default: { _exception.reset(new UnknownReplyStatusException(__FILE__, __LINE__)); _state = StateLocalException; break; } } }