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// **********************************************************************
//
// Copyright (c) 2003-2018 ZeroC, Inc. All rights reserved.
//
// This copy of Ice is licensed to you under the terms described in the
// ICE_LICENSE file included in this distribution.
//
// **********************************************************************
#include <TestI.h>
#include <Ice/Ice.h>
using namespace std;
using namespace Ice;
TestIntfI::TestIntfI() :
_batchCount(0), _shutdown(false)
{
}
void
TestIntfI::op(const Ice::Current&)
{
}
int
TestIntfI::opWithResult(const Ice::Current&)
{
return 15;
}
void
TestIntfI::opWithUE(const Ice::Current&)
{
throw Test::TestIntfException();
}
int
TestIntfI::opWithResultAndUE(const Ice::Current&)
{
throw Test::TestIntfException();
}
void
TestIntfI::opWithPayload(ICE_IN(Ice::ByteSeq), const Ice::Current&)
{
}
void
TestIntfI::opBatch(const Ice::Current&)
{
IceUtil::Monitor<IceUtil::Mutex>::Lock sync(*this);
++_batchCount;
notify();
}
Ice::Int
TestIntfI::opBatchCount(const Ice::Current&)
{
IceUtil::Monitor<IceUtil::Mutex>::Lock sync(*this);
return _batchCount;
}
void
TestIntfI::opWithArgs(Ice::Int& one, Ice::Int& two, Ice::Int& three, Ice::Int& four, Ice::Int& five, Ice::Int& six,
Ice::Int& seven, Ice::Int& eight, Ice::Int& nine, Ice::Int& ten, Ice::Int& eleven,
const Ice::Current&)
{
one = 1;
two = 2;
three = 3;
four = 4;
five = 5;
six = 6;
seven = 7;
eight = 8;
nine = 9;
ten = 10;
eleven = 11;
}
bool
TestIntfI::waitForBatch(Ice::Int count, const Ice::Current&)
{
IceUtil::Monitor<IceUtil::Mutex>::Lock sync(*this);
while(_batchCount < count)
{
timedWait(IceUtil::Time::milliSeconds(5000));
}
bool result = count == _batchCount;
_batchCount = 0;
return result;
}
void
TestIntfI::close(Test::CloseMode mode, const Ice::Current& current)
{
current.con->close(static_cast<ConnectionClose>(mode));
}
void
TestIntfI::sleep(Ice::Int ms, const Ice::Current& current)
{
IceUtil::Monitor<IceUtil::Mutex>::Lock sync(*this);
timedWait(IceUtil::Time::milliSeconds(ms));
}
#ifdef ICE_CPP11_MAPPING
void
TestIntfI::startDispatchAsync(std::function<void()> response, std::function<void(std::exception_ptr)> ex,
const Ice::Current&)
{
IceUtil::Monitor<IceUtil::Mutex>::Lock sync(*this);
if(_shutdown)
{
response();
return;
}
else if(_pending)
{
_pending();
}
_pending = move(response);
}
#else
void
TestIntfI::startDispatch_async(const Test::AMD_TestIntf_startDispatchPtr& cb, const Ice::Current&)
{
IceUtil::Monitor<IceUtil::Mutex>::Lock sync(*this);
if(_shutdown)
{
// Ignore, this can occur with the forcefull connection close test, shutdown can be dispatch
// before start dispatch.
cb->ice_response();
return;
}
else if(_pending)
{
_pending->ice_response();
}
_pending = cb;
}
#endif
void
TestIntfI::finishDispatch(const Ice::Current& current)
{
IceUtil::Monitor<IceUtil::Mutex>::Lock sync(*this);
if(_shutdown)
{
return;
}
else if(_pending) // Pending might not be set yet if startDispatch is dispatch out-of-order
{
#ifdef ICE_CPP11_MAPPING
_pending();
_pending = nullptr;
#else
_pending->ice_response();
_pending = 0;
#endif
}
}
void
TestIntfI::shutdown(const Ice::Current& current)
{
IceUtil::Monitor<IceUtil::Mutex>::Lock sync(*this);
_shutdown = true;
if(_pending)
{
#ifdef ICE_CPP11_MAPPING
_pending();
_pending = nullptr;
#else
_pending->ice_response();
_pending = 0;
#endif
}
current.adapter->getCommunicator()->shutdown();
}
bool
TestIntfI::supportsAMD(const Ice::Current&)
{
return true;
}
bool
TestIntfI::supportsFunctionalTests(const Ice::Current&)
{
return false;
}
void
TestIntfI::pingBiDir(ICE_IN(Ice::Identity) id, const Ice::Current& current)
{
ICE_UNCHECKED_CAST(Test::PingReplyPrx, current.con->createProxy(id))->reply();
}
void
TestIntfControllerI::holdAdapter(const Ice::Current&)
{
_adapter->hold();
}
void
TestIntfControllerI::resumeAdapter(const Ice::Current&)
{
_adapter->activate();
}
TestIntfControllerI::TestIntfControllerI(const Ice::ObjectAdapterPtr& adapter) : _adapter(adapter)
{
}
Ice::Int
TestIntfII::op(Ice::Int i, Ice::Int& j, const Ice::Current&)
{
j = i;
return i;
}
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