// $Id$ // @ (#)iiopobj.cpp 1.9 95/11/04 // Copyright 1995 by Sun Microsystems Inc. // All Rights Reserved // // XXXX Bridge: CORBA::Object operations // // Some CORBA::Object and other operations are specific to this STUB // based implementation, and can neither be used by other kinds of // objref nor have a default implementation. #include "tao/Stub.h" #include "tao/Sequence.h" #include "tao/Sequence_T.h" #include "tao/Object.h" #include "tao/GIOP.h" #include "tao/NVList.h" #include "tao/Invocation.h" #include "tao/ORB_Core.h" #include "tao/Client_Strategy_Factory.h" #include "ace/Auto_Ptr.h" #if !defined (__ACE_INLINE__) # include "tao/Stub.i" #endif /* ! __ACE_INLINE__ */ #include "tao/Timeprobe.h" ACE_RCSID(tao, TAO_Stub, "$Id$") #if defined (ACE_ENABLE_TIMEPROBES) static const char *TAO_TAO_Stub_Timeprobe_Description[] = { "TAO_Stub::do_static_call - start", "TAO_Stub::do_static_call - end", "TAO_Stub::do_static_call - set_cancel", "TAO_Stub::do_static_call - grab_orb_core", "TAO_Stub::do_static_call - invocation_ctor", "TAO_Stub::do_static_call - invocation_start", "TAO_Stub::do_static_call - put_params" }; enum { // Timeprobe description table start key TAO_STUB_OBJECT_DO_STATIC_CALL_START = 500, TAO_STUB_OBJECT_DO_STATIC_CALL_END, TAO_STUB_OBJECT_DO_STATIC_CALL_SET_CANCEL, TAO_STUB_OBJECT_DO_STATIC_CALL_GRAB_ORB_CORE, TAO_STUB_OBJECT_DO_STATIC_CALL_INVOCATION_CTOR, TAO_STUB_OBJECT_DO_STATIC_CALL_INVOCATION_START, TAO_STUB_OBJECT_DO_STATIC_CALL_PUT_PARAMS }; // Setup Timeprobes ACE_TIMEPROBE_EVENT_DESCRIPTIONS (TAO_TAO_Stub_Timeprobe_Description, TAO_STUB_OBJECT_DO_STATIC_CALL_START); #endif /* ACE_ENABLE_TIMEPROBES */ TAO_Stub::TAO_Stub (char *repository_id, TAO_MProfile &profiles, TAO_ORB_Core* orb_core) : type_id (repository_id), base_profiles_ ((CORBA::ULong) 0), forward_profiles_ (0), profile_in_use_ (0), profile_lock_ptr_ (0), profile_success_ (0), // what about ACE_SYNCH_MUTEX refcount_lock_ refcount_ (1), use_locate_request_ (0), first_locate_request_ (0), orb_core_ (orb_core), policies_ (0) { if (this->orb_core_ == 0) { if (TAO_debug_level > 0) { ACE_DEBUG ((LM_DEBUG, "TAO: (%P|%t) TAO_Stub created with default " "ORB core\n")); } this->orb_core_ = TAO_ORB_Core_instance (); } this->profile_lock_ptr_ = this->orb_core_->client_factory ()->create_iiop_profile_lock (); this->set_base_profiles (&profiles); } TAO_Stub::TAO_Stub (char *repository_id, TAO_MProfile *profiles, TAO_ORB_Core* orb_core) : type_id (repository_id), base_profiles_ ((CORBA::ULong) 0), forward_profiles_ (0), profile_in_use_ (0), profile_lock_ptr_ (0), profile_success_ (0), // what about ACE_SYNCH_MUTEX refcount_lock_ refcount_ (1), use_locate_request_ (0), first_locate_request_ (0), orb_core_ (orb_core) { if (this->orb_core_ == 0) { if (TAO_debug_level > 0) { ACE_DEBUG ((LM_DEBUG, "TAO: (%P|%t) TAO_Stub created with default " "ORB core\n")); } this->orb_core_ = TAO_ORB_Core_instance (); } // @@ does this need to be freed? this->profile_lock_ptr_ = this->orb_core_->client_factory ()->create_iiop_profile_lock (); this->set_base_profiles (profiles); } #if 0 TAO_Stub::TAO_Stub (char *repository_id, TAO_Profile *profile) : type_id (repository_id), base_profiles_ ((CORBA::ULong) 0), forward_profiles_ (0), profile_in_use_ (0), profile_lock_ptr_ (0), profile_success_ (0), // what about ACE_SYNCH_MUTEX refcount_lock_ refcount_ (1), use_locate_request_ (0), first_locate_request_ (0) { // @@ XXX need to verify type and deal with wrong types this->profile_lock_ptr_ = this->orb_core_->client_factory ()->create_iiop_profile_lock (); base_profiles_.set (1); base_profiles_.give_profile (profile); reset_base (); } TAO_Stub::TAO_Stub (char *repository_id) : type_id (repository_id), base_profiles_ ((CORBA::ULong) 0), forward_profiles_ (0), profile_in_use_ (0), profile_lock_ptr_ (0), profile_success_ (0), // what about ACE_SYNCH_MUTEX refcount_lock_ refcount_ (1), use_locate_request_ (0), first_locate_request_ (0) { this->profile_lock_ptr_ = this->orb_core_->client_factory ()->create_iiop_profile_lock (); } #endif /* 0 */ // Quick'n'dirty hash of objref data, for partitioning objrefs into // sets. // // NOTE that this must NOT go across the network! // @@ Use all profiles for hash function!!!!! FRED // can get different values, depending on the profile_in_use!! CORBA::ULong TAO_Stub::hash (CORBA::ULong max, CORBA::Environment &env) { // we rely on the profile object to has it's address info if (profile_in_use_) return profile_in_use_->hash (max, env); ACE_ERROR_RETURN((LM_ERROR, "(%P|%t) hash called on a null profile!\n"), 0); } int operator==(const TAO_opaque& rhs, const TAO_opaque& lhs) { if (rhs.length () != lhs.length ()) return 0; for (CORBA::ULong i = 0; i < rhs.length (); ++i) if (rhs[i] != lhs[i]) return 0; return 1; } int operator!=(const TAO_opaque& rhs, const TAO_opaque& lhs) { return !(rhs == lhs); } // Expensive comparison of objref data, to see if two objrefs // certainly point at the same object. (It's quite OK for this to // return FALSE, and yet have the two objrefs really point to the same // object.) // // NOTE that this must NOT go across the network! // @@ Two object references are the same if any two profiles are the same! CORBA::Boolean TAO_Stub::is_equivalent (CORBA::Object_ptr other_obj, CORBA::Environment &env) { if (CORBA::is_nil (other_obj) == 1) return 0; TAO_Profile *other_profile = other_obj->_stubobj ()->profile_in_use_; TAO_Profile *this_profile = this->profile_in_use_; if (other_profile == 0 || this_profile == 0) return 0; // Compare the profiles return this_profile->is_equivalent (other_profile, env); } // Memory managment CORBA::ULong TAO_Stub::_incr_refcnt (void) { ACE_GUARD_RETURN (ACE_SYNCH_MUTEX, guard, this->refcount_lock_, 0); return this->refcount_++; } CORBA::ULong TAO_Stub::_decr_refcnt (void) { { ACE_GUARD_RETURN (ACE_SYNCH_MUTEX, mon, this->refcount_lock_, 0); this->refcount_--; if (this->refcount_ != 0) return this->refcount_; } delete this; return 0; } // Note that if the repository ID (typeID) is NULL, it will make // narrowing rather expensive, though it does ensure that type-safe // narrowing code gets thoroughly exercised/debugged! Without a // typeID, the _narrow will be required to make an expensive remote // "is_a" call. // THREADING NOTE: Code below this point is of course thread-safe (at // least on supported threaded platforms), so the caller of these // routines need only ensure that the data being passed in is not // being modified by any other thread. // // As an _experiment_ (to estimate the performance cost) remote calls // are currently deemed "cancel-safe". That means that they can be // called by threads when they're in asynchronous cancellation mode. // The only effective way to do this is to disable async cancellation // for the duration of the call. There are numerous rude interactions // with code generators for C++ ... cancellation handlers just do // normal stack unwinding like exceptions, but exceptions are purely // synchronous and sophisticated code generators rely on that to // generate better code, which in some cases may be very hard to // unwind. class TAO_Synchronous_Cancellation_Required // = TITLE // Stick one of these at the beginning of a block that can't // support asynchronous cancellation, and which must be // cancel-safe. // // = EXAMPLE // somefunc() // { // TAO_Synchronous_Cancellation_Required NOT_USED; // ... // } { public: // These should probably be in a separate inline file, but they're // only used within this one file right now, and we always want them // inlined, so here they sit. TAO_Synchronous_Cancellation_Required (void) : old_type_ (0) { #if !defined (VXWORKS) ACE_OS::thr_setcanceltype (THR_CANCEL_DEFERRED, &old_type_); #endif /* ! VXWORKS */ } ~TAO_Synchronous_Cancellation_Required (void) { #if !defined (VXWORKS) int dont_care; ACE_OS::thr_setcanceltype(old_type_, &dont_care); #endif /* ! VXWORKS */ } private: int old_type_; }; // "Stub interpreter" for static stubs. IDL compiler (or human // equivalent thereof :-) should just dump a read-only description of // the call into "calldata" and do varargs calls to this routine, // which does all the work. void TAO_Stub::do_static_call (CORBA::Environment &ACE_TRY_ENV, const TAO_Call_Data *info, void** args) { ACE_FUNCTION_TIMEPROBE (TAO_STUB_OBJECT_DO_STATIC_CALL_START); TAO_Synchronous_Cancellation_Required NOT_USED; ACE_TIMEPROBE (TAO_STUB_OBJECT_DO_STATIC_CALL_SET_CANCEL); ACE_TIMEPROBE (TAO_STUB_OBJECT_DO_STATIC_CALL_GRAB_ORB_CORE); // Do a locate_request if necessary/wanted. // Suspect that you will be forwarded, so be proactive! // strategy for reducing overhead when you think a request will // be forwarded. No standard way now to know. if (this->use_locate_request_ && this->first_locate_request_) { TAO_GIOP_Locate_Request_Invocation call (this, this->orb_core_); // Simply let these exceptions propagate up // (if any of them occurs.) call.start (ACE_TRY_ENV); ACE_CHECK; call.invoke (ACE_TRY_ENV); ACE_CHECK; this->first_locate_request_ = 0; } if (info->is_roundtrip) { TAO_GIOP_Twoway_Invocation call (this, info->opname, this->orb_core_); ACE_TIMEPROBE (TAO_STUB_OBJECT_DO_STATIC_CALL_INVOCATION_CTOR); // We may need to loop through here more than once if we're // forwarded to some other object reference. // // NOTE: A quality-of-service policy may be useful to establish // here, specifically one controlling how many times the call is // reissued before failing the call on the assumption that // something is broken. // // NOTE: something missing is a dynamic way to change the policy // of whether to issue LocateRequest messages or not. This code // uses a simple, fixed policy: never use LocateRequest // messages. // for (;;) { call.start (ACE_TRY_ENV); ACE_CHECK; ACE_TIMEPROBE (TAO_STUB_OBJECT_DO_STATIC_CALL_INVOCATION_START); // Make the call ... blocking for the response. this->put_params (ACE_TRY_ENV, info, call, args); ACE_CHECK; ACE_TIMEPROBE (TAO_STUB_OBJECT_DO_STATIC_CALL_PUT_PARAMS); int status = call.invoke (info->excepts, info->except_count, ACE_TRY_ENV); ACE_CHECK; if (status == TAO_INVOKE_RESTART) continue; if (status == TAO_INVOKE_EXCEPTION) return; // Shouldn't happen if (status != TAO_INVOKE_OK) ACE_THROW (CORBA::UNKNOWN (CORBA::COMPLETED_MAYBE)); // The only case left is status == TAO_INVOKE_OK, exit the // loop. We cannot retry because at this point we either // got a reply or something with an status of // COMPLETED_MAYBE, thus we cannot reissue the request if we // are to satisfy the "at most once" semantics. break; } // Now, get all the "return", "out", and "inout" parameters // from the response message body ... return parameter is // first, the rest are in the order defined in the IDL spec // (which is also the order that DII users are required to // use). const TAO_Param_Data *pdp = info->params; for (void** i = args; i != args + info->param_count; i++, pdp++) { void *ptr = *i; // if it is an inout parameter, it would become // necessary to first release the "in" memory if (pdp->mode == PARAM_INOUT) { // @@ TODO - add others as we test each case // (ASG) will do 03/22/98. // @@ IMHO this should be handled in the stub // (coryan) switch (pdp->tc->kind (TAO_IN_ENV)) { case CORBA::tk_string: { CORBA::string_free (*(char **)ptr); *(char **)ptr = 0; } break; default: break; } } if (pdp->mode == PARAM_RETURN || pdp->mode == PARAM_OUT || pdp->mode == PARAM_INOUT) { // The language mapping's memory allocation // policy says that some data is heap-allocated. // This interpreter is told about the relevant // policy by whoever built the operation // description (e.g. the IDL compiler) so it // doesn't have to know the policy associated // with a particular language binding // (e.g. C/C++ differ, and C++ even has // different policies for different kinds of // structures). if (pdp->value_size == 0) { call.get_value (pdp->tc, ptr, ACE_TRY_ENV); ACE_CHECK; } else { // @@ (ASG) - I think we must completely // get rid of this case because IDL compiler // generated stubs will use this function // and they better allocate all the memory. // assert (value_size == tc->size()); *(void **)ptr = new CORBA::Octet [pdp->value_size]; call.get_value (pdp->tc, *(void **)ptr, ACE_TRY_ENV); ACE_CHECK; } } } } // if (two way) else { TAO_GIOP_Oneway_Invocation call (this, info->opname, this->orb_core_); ACE_TIMEPROBE (TAO_STUB_OBJECT_DO_STATIC_CALL_INVOCATION_CTOR); for (;;) { call.start (ACE_TRY_ENV); ACE_CHECK; this->put_params (ACE_TRY_ENV, info, call, args); ACE_CHECK; ACE_TIMEPROBE (TAO_STUB_OBJECT_DO_STATIC_CALL_PUT_PARAMS); int status = call.invoke (ACE_TRY_ENV); ACE_CHECK; if (status == TAO_INVOKE_RESTART) continue; if (status == TAO_INVOKE_EXCEPTION) return; // Shouldn't happen if (status != TAO_INVOKE_OK) ACE_THROW (CORBA::UNKNOWN (CORBA::COMPLETED_MAYBE)); break; } } } void TAO_Stub::put_params (CORBA::Environment &ACE_TRY_ENV, const TAO_Call_Data *info, TAO_GIOP_Invocation &call, void** args) { // Now, put all "in" and "inout" parameters into the request // message body. // // Some "inout" data have an extra level of indirection, // specified by the language mapping's memory allocation // policies ... the indirection only shows up here when it's // needed later for allocating "out" memory, otherwise there's // just one indirection. const TAO_Param_Data *pdp = info->params; for (void** i = args; i != args + info->param_count; i++, pdp++) { void *ptr = *i; if (pdp->mode == PARAM_IN) { call.put_param (pdp->tc, ptr, ACE_TRY_ENV); } else if (pdp->mode == PARAM_INOUT) { if (pdp->value_size == 0) call.put_param (pdp->tc, ptr, ACE_TRY_ENV); else call.put_param (pdp->tc, *(void **)ptr, ACE_TRY_ENV); } ACE_CHECK; } } #if !defined (TAO_HAS_MINIMUM_CORBA) // DII analogue of the above. void TAO_Stub::do_dynamic_call (const char *opname, CORBA::Boolean is_roundtrip, CORBA::NVList_ptr args, CORBA::NamedValue_ptr result, CORBA::Flags, CORBA::ExceptionList &exceptions, CORBA::Environment &ACE_TRY_ENV) { TAO_Synchronous_Cancellation_Required NOT_USED; // Do a locate_request if necessary/wanted. // Suspect that you will be forwarded, so be proactive! // strategy for reducing overhead when you think a request will // be forwarded. No standard way now to know. if (this->use_locate_request_ && this->first_locate_request_) { TAO_GIOP_Locate_Request_Invocation call (this, this->orb_core_); // Simply let these exceptions propagate up // (if any of them occurs.) call.start (ACE_TRY_ENV); ACE_CHECK; call.invoke (ACE_TRY_ENV); ACE_CHECK; this->first_locate_request_ = 0; } if (is_roundtrip) { TAO_GIOP_Twoway_Invocation call (this, opname, this->orb_core_); // Loop as needed for forwarding; see above. for (;;) { call.start (ACE_TRY_ENV); ACE_CHECK; this->put_params (call, args, ACE_TRY_ENV); ACE_CHECK; // Make the call ... blocking for the response. int status = call.invoke (exceptions, ACE_TRY_ENV); ACE_CHECK; if (status == TAO_INVOKE_RESTART) continue; if (status == TAO_INVOKE_EXCEPTION) return; // Shouldn't happen if (status != TAO_INVOKE_OK) ACE_THROW (CORBA::UNKNOWN (CORBA::COMPLETED_MAYBE)); // The only case left is status == TAO_INVOKE_OK, exit the // loop. We cannot retry because at this point we either // got a reply or something with an status of // COMPLETED_MAYBE, thus we cannot reissue the request if we // are to satisfy the "at most once" semantics. break; } // Now, get all the "return", "out", and "inout" parameters // from the response message body ... return parameter is // first, the rest are in the order defined in the IDL spec // (which is also the order that DII users are required to // use). if (result != 0) { #if 0 // @@ (ASG) I need to look into this OUT_LIST_MEMORY stuff // (4/21/98). // @@ (Carlos) All this code seems bogus, we know that // allocating memory of behalf of the user is and endless // source of trouble (due to vtbls and the such). // If caller didn't set OUT_LIST_MEMORY flag, allocate // memory for return value ... if (!(flags & CORBA::OUT_LIST_MEMORY)) { CORBA::TypeCode_var tcp = result->value ()->type (); size_t size = tcp->size (ACE_TRY_ENV); ACE_CHECK; if (size != 0) { void *ptr = new CORBA::Octet [size]; result->value ()->replace (tcp.in (), ptr, 1, ACE_TRY_ENV); ACE_CHECK; } } #endif if (!result->value ()->value_) { // storage was not allocated. In this case, we // simply grab the portion of the CDR stream // that contained this parameter, The // application should use the appropriate >>= // operator to retrieve the value char *begin, *end; TAO_InputCDR temp (call.inp_stream ()); CORBA::TypeCode::traverse_status retval; CORBA::Any *any = result->value (); begin = call.inp_stream ().rd_ptr (); // skip the parameter to get the ending position retval = temp.skip (any->type_, ACE_TRY_ENV); ACE_CHECK; if (retval == CORBA::TypeCode::TRAVERSE_CONTINUE) { end = temp.rd_ptr (); any->cdr_ = new ACE_Message_Block (end - begin); TAO_OutputCDR out (any->cdr_); retval = out.append (any->type_, &call.inp_stream (), ACE_TRY_ENV); ACE_CHECK; if (retval == CORBA::TypeCode::TRAVERSE_CONTINUE) { any->any_owns_data_ = 1; any->value_ = 0; } } } else { // the application had allocated the top level // storage. We simply retrieve the data call.get_value (result->value ()->type_, result->value ()->value_, ACE_TRY_ENV); ACE_CHECK; } } for (u_int i = 0; i < args->count (); i++) { CORBA::NamedValue_ptr value = args->item (i, ACE_TRY_ENV); ACE_CHECK; CORBA::Any *any = value->value (); if (value->flags () == CORBA::ARG_OUT || value->flags () == CORBA::ARG_INOUT) { #if 0 // @@ (ASG) need to deal with this // If caller didn't set OUT_LIST_MEMORY flag, allocate // memory for this parameter ... if (!(flags & CORBA::OUT_LIST_MEMORY)) { CORBA::TypeCode_var tcp = value->value ()->type (); size_t size = tcp->size (ACE_TRY_ENV); ACE_CHECK; if (size != 0) { CORBA::Octet *ptr = new CORBA::Octet [size]; value->value ()->replace (tcp.in (), ptr, 1, ACE_TRY_ENV); ACE_CHECK; } } #endif if (!any->value_) { // storage was not allocated. In this case, // we simply grab the portion of the CDR // stream that contained this parameter, The // application should use the appropriate // >>= operator to retrieve the value char *begin, *end; TAO_InputCDR temp (call.inp_stream ()); CORBA::TypeCode::traverse_status retval; begin = call.inp_stream ().rd_ptr (); // skip the parameter to get the ending position retval = temp.skip (any->type_, ACE_TRY_ENV); ACE_CHECK; if (retval == CORBA::TypeCode::TRAVERSE_CONTINUE) { end = temp.rd_ptr (); any->cdr_ = new ACE_Message_Block (end - begin); TAO_OutputCDR out (any->cdr_); retval = out.append (any->type_, &call.inp_stream (), ACE_TRY_ENV); ACE_CHECK; if (retval == CORBA::TypeCode::TRAVERSE_CONTINUE) { any->any_owns_data_ = 1; any->value_ = 0; } } } else { // the application had allocated the top level // storage. We simply retrieve the data call.get_value (any->type_, (void *) any->value_, ACE_TRY_ENV); ACE_CHECK; } } } } else { TAO_GIOP_Oneway_Invocation call (this, opname, this->orb_core_); for (;;) { call.start (ACE_TRY_ENV); ACE_CHECK; this->put_params (call, args, ACE_TRY_ENV); ACE_CHECK; int status = call.invoke (ACE_TRY_ENV); ACE_CHECK; if (status == TAO_INVOKE_RESTART) continue; if (status == TAO_INVOKE_EXCEPTION) return; // Shouldn't happen if (status != TAO_INVOKE_OK) ACE_THROW (CORBA::UNKNOWN (CORBA::COMPLETED_MAYBE)); break; } } } void TAO_Stub::put_params (TAO_GIOP_Invocation &call, CORBA::NVList_ptr args, CORBA::Environment &ACE_TRY_ENV) { // Now, put all "in" and "inout" parameters into the request // message body. for (u_int i = 0; i < args->count (); i++) { CORBA::NamedValue_ptr value = args->item (i, ACE_TRY_ENV); ACE_CHECK; if (value->flags () == CORBA::ARG_IN || value->flags () == CORBA::ARG_INOUT) { // If the Any owns the data, then we have allocated space. if (value->value ()->any_owns_data_) { call.put_param (value->value ()->type_, value->value ()->value_, ACE_TRY_ENV); ACE_CHECK; } else { TAO_OutputCDR &cdr = call.out_stream (); TAO_InputCDR in (value->value ()->cdr_, TAO_ENCAP_BYTE_ORDER, this->orb_core_); cdr.append (value->value ()->type_, &in, ACE_TRY_ENV); ACE_CHECK; } } } } #endif /* TAO_HAS_MINIMUM_CORBA */ // **************************************************************** #if defined (TAO_HAS_CORBA_MESSAGING) CORBA::Policy_ptr TAO_Stub::get_policy ( CORBA::PolicyType type, CORBA::Environment &ACE_TRY_ENV) { ACE_GUARD_RETURN (ACE_SYNCH_MUTEX, guard, this->refcount_lock_, CORBA::Policy::_nil ()); if (this->policies_ == 0) return CORBA::Policy::_nil (); return this->policies_->get_policy (type, ACE_TRY_ENV); } CORBA::Policy_ptr TAO_Stub::get_client_policy ( CORBA::PolicyType type, CORBA::Environment &ACE_TRY_ENV) { ACE_GUARD_RETURN (ACE_SYNCH_MUTEX, guard, this->refcount_lock_, CORBA::Policy::_nil ()); CORBA::Policy_var result; if (this->policies_ != 0) { result = this->policies_->get_policy (type, ACE_TRY_ENV); ACE_CHECK_RETURN (CORBA::Policy::_nil ()); } if (CORBA::is_nil (result.in ())) { TAO_Policy_Current *policy_current = this->orb_core_->policy_current (); if (policy_current != 0) { result = policy_current->get_policy (type, ACE_TRY_ENV); ACE_CHECK_RETURN (CORBA::Policy::_nil ()); } } if (CORBA::is_nil (result.in ())) { TAO_Policy_Manager *policy_manager = this->orb_core_->policy_manager (); if (policy_manager != 0) { result = policy_manager->get_policy (type, ACE_TRY_ENV); ACE_CHECK_RETURN (CORBA::Policy::_nil ()); } } if (CORBA::is_nil (result.in ())) { result = this->orb_core_->get_default_policy (type, ACE_TRY_ENV); ACE_CHECK_RETURN (CORBA::Policy::_nil ()); } return result._retn (); } TAO_Stub* TAO_Stub::set_policy_overrides ( const CORBA::PolicyList & policies, CORBA::SetOverrideType set_add, CORBA::Environment &ACE_TRY_ENV) { auto_ptr policy_manager = new TAO_Policy_Manager_Impl; if (set_add == CORBA::SET_OVERRIDE) { policy_manager->set_policy_overrides (policies, set_add, ACE_TRY_ENV); ACE_CHECK_RETURN (0); } else if (this->policies_ == 0) { policy_manager->set_policy_overrides (policies, CORBA::SET_OVERRIDE, ACE_TRY_ENV); ACE_CHECK_RETURN (0); } else { *policy_manager = *this->policies_; policy_manager->set_policy_overrides (policies, set_add, ACE_TRY_ENV); ACE_CHECK_RETURN (0); } TAO_Stub* stub; ACE_NEW_RETURN (stub, TAO_Stub (CORBA::string_dup (this->type_id.in ()), this->get_profiles (), this->orb_core_), 0); stub->policies_ = policy_manager.release (); return stub; } CORBA::PolicyList * TAO_Stub::get_policy_overrides ( const CORBA::PolicyTypeSeq & types, CORBA::Environment &ACE_TRY_ENV) { if (this->policies_ == 0) return 0; return this->policies_->get_policy_overrides (types, ACE_TRY_ENV); } CORBA::Boolean TAO_Stub::validate_connection ( CORBA::PolicyList_out inconsistent_policies, CORBA::Environment &ACE_TRY_ENV) { // @@ What is a good default value to return.... inconsistent_policies = 0; return 0; } #endif /* TAO_HAS_CORBA_MESSAGING */