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/**
* @file llleaplistener.cpp
* @author Nat Goodspeed
* @date 2012-03-16
* @brief Implementation for llleaplistener.
*
* $LicenseInfo:firstyear=2012&license=viewerlgpl$
* Copyright (c) 2012, Linden Research, Inc.
* $/LicenseInfo$
*/
// Precompiled header
#include "linden_common.h"
// associated header
#include "llleaplistener.h"
// STL headers
#include <algorithm> // std::find_if
#include <functional>
#include <map>
#include <set>
// std headers
// external library headers
// other Linden headers
#include "lazyeventapi.h"
#include "llsdutil.h"
#include "lluuid.h"
#include "stringize.h"
/*****************************************************************************
* LEAP FEATURE STRINGS
*****************************************************************************/
/**
* Implement "getFeatures" command. The LLSD map thus obtained is intended to
* be machine-readable (read: easily-parsed, if parsing be necessary) and to
* highlight the differences between this version of the LEAP protocol and
* the baseline version. A client may thus determine whether or not the
* running viewer supports some recent feature of interest.
*
* This method is defined at the top of this implementation file so it's easy
* to find, easy to spot, easy to update as we enhance the LEAP protocol.
*/
/*static*/ LLSD LLLeapListener::getFeatures()
{
static LLSD features;
if (features.isUndefined())
{
features = LLSD::emptyMap();
// This initial implementation IS the baseline LEAP protocol; thus the
// set of differences is empty; thus features is initially empty.
// features["featurename"] = "value";
}
return features;
}
LLLeapListener::LLLeapListener(std::string_view caller, const Callback& callback):
// Each LEAP plugin has an instance of this listener. Make the command
// pump name difficult for other such plugins to guess.
LLEventAPI(LLUUID::generateNewID().asString(),
"Operations relating to the LLSD Event API Plugin (LEAP) protocol"),
mCaller(caller),
mCallback(callback),
// Troubling thought: what if one plugin intentionally messes with
// another plugin? LLEventPump names are in a single global namespace.
// Try to make that more difficult by generating a UUID for the reply-
// pump name -- so it should NOT need tweaking for uniqueness.
mReplyPump(LLUUID::generateNewID().asString()),
mReplyConn(connect(mReplyPump, mCaller))
{
LLSD need_name(LLSDMap("name", LLSD()));
add("newpump",
R"-(Instantiate a new LLEventPump named like ["name"] and listen to it.
["type"] == "LLEventStream", "LLEventMailDrop" et al.
Events sent through new LLEventPump will be decorated with ["pump"]=name.
Returns actual name in ["name"] (may be different if collision).)-",
&LLLeapListener::newpump,
need_name);
LLSD need_source_listener(LLSDMap("source", LLSD())("listener", LLSD()));
add("listen",
R"-(Listen to an existing LLEventPump named ["source"], with listener name
["listener"].
If ["tweak"] is specified as true, tweak listener name for uniqueness.
By default, send events on ["source"] to the plugin, decorated
with ["pump"]=["source"].
If ["dest"] specified, send undecorated events on ["source"] to the
LLEventPump named ["dest"].
Returns ["status"] boolean indicating whether the connection was made,
plus ["listener"] reporting (possibly tweaked) listener name.)-",
&LLLeapListener::listen,
need_source_listener);
add("stoplistening",
R"-(Disconnect a connection previously established by "listen".
Pass same ["source"] and ["listener"] arguments.
Returns ["status"] boolean indicating whether such a listener existed.)-",
&LLLeapListener::stoplistening,
need_source_listener);
add("ping",
"No arguments, just a round-trip sanity check.",
&LLLeapListener::ping);
add("getAPIs",
"Enumerate all LLEventAPI instances by name and description.",
&LLLeapListener::getAPIs);
add("getAPI",
R"-(Get name, description, dispatch key and operations for LLEventAPI ["api"].)-",
&LLLeapListener::getAPI,
LLSD().with("api", LLSD()));
add("getFeatures",
"Return an LLSD map of feature strings (deltas from baseline LEAP protocol)",
static_cast<void (LLLeapListener::*)(const LLSD&) const>(&LLLeapListener::getFeatures));
add("getFeature",
R"-(Return the feature value with key ["feature"])-",
&LLLeapListener::getFeature,
LLSD().with("feature", LLSD()));
}
LLLeapListener::~LLLeapListener()
{
// We'd have stored a map of LLTempBoundListener instances, save that the
// operation of inserting into a std::map necessarily copies the
// value_type, and Bad Things would happen if you copied an
// LLTempBoundListener. (Destruction of the original would disconnect the
// listener, invalidating every stored connection.)
LL_DEBUGS("LLLeapListener") << "~LLLeapListener(\"" << mCaller << "\")" << LL_ENDL;
for (ListenersMap::value_type& pair : mListeners)
{
pair.second.disconnect();
}
}
void LLLeapListener::newpump(const LLSD& request)
{
Response reply(LLSD(), request);
std::string name = request["name"];
std::string type = request["type"];
try
{
// tweak name for uniqueness
LLEventPump& new_pump(LLEventPumps::instance().make(name, true, type));
name = new_pump.getName();
reply["name"] = name;
// Now listen on this new pump with our plugin listener
saveListener(name, mCaller, connect(new_pump, mCaller));
}
catch (const LLEventPumps::BadType& error)
{
reply.error(error.what());
}
}
void LLLeapListener::listen(const LLSD& request)
{
Response reply(LLSD(), request);
std::string source_name = request["source"];
std::string dest_name = request["dest"];
std::string listener_name = request["listener"];
if (request["tweak"].asBoolean())
{
listener_name = LLEventPump::inventName(listener_name);
}
reply["listener"] = listener_name;
LLEventPump & source = LLEventPumps::instance().obtain(source_name);
reply["status"] = false;
if (mListeners.find(ListenersMap::key_type(source_name, listener_name)) == mListeners.end())
{
try
{
if (request["dest"].isDefined())
{
// If we're asked to connect the "source" pump to a
// specific "dest" pump, find dest pump and connect it.
LLEventPump & dest = LLEventPumps::instance().obtain(dest_name);
saveListener(source_name, listener_name,
source.listen(listener_name,
boost::bind(&LLEventPump::post, &dest, _1)));
}
else
{
// "dest" unspecified means to direct events on "source"
// to our plugin listener.
saveListener(source_name, listener_name, connect(source, listener_name));
}
reply["status"] = true;
}
catch (const LLEventPump::DupListenerName &)
{
// pass - status already set to false
}
}
}
void LLLeapListener::stoplistening(const LLSD& request)
{
Response reply(LLSD(), request);
std::string source_name = request["source"];
std::string listener_name = request["listener"];
ListenersMap::iterator finder =
mListeners.find(ListenersMap::key_type(source_name, listener_name));
reply["status"] = false;
if(finder != mListeners.end())
{
reply["status"] = true;
finder->second.disconnect();
mListeners.erase(finder);
}
}
void LLLeapListener::ping(const LLSD& request) const
{
// do nothing, default reply suffices
Response(LLSD(), request);
}
void LLLeapListener::getAPIs(const LLSD& request) const
{
Response reply(LLSD(), request);
// first, traverse existing LLEventAPI instances
std::set<std::string> instances;
for (auto& ea : LLEventAPI::instance_snapshot())
{
// remember which APIs are actually instantiated
instances.insert(ea.getName());
reply[ea.getName()] = llsd::map("desc", ea.getDesc());
}
// supplement that with *potential* instances: that is, instances of
// LazyEventAPI that can each instantiate an LLEventAPI on demand
for (const auto& lea : LL::LazyEventAPIBase::instance_snapshot())
{
// skip any LazyEventAPI that's already instantiated its LLEventAPI
if (instances.find(lea.getName()) == instances.end())
{
reply[lea.getName()] = llsd::map("desc", lea.getDesc());
}
}
}
// Because LazyEventAPI deliberately mimics LLEventAPI's query API, this
// function can be passed either -- even though they're unrelated types.
template <typename API>
void reportAPI(LLEventAPI::Response& reply, const API& api)
{
reply["name"] = api.getName();
reply["desc"] = api.getDesc();
reply["key"] = api.getDispatchKey();
LLSD ops;
for (const auto& namedesc : api)
{
ops.append(api.getMetadata(namedesc.first));
}
reply["ops"] = ops;
}
void LLLeapListener::getAPI(const LLSD& request) const
{
Response reply(LLSD(), request);
// check first among existing LLEventAPI instances
auto foundea = LLEventAPI::getInstance(request["api"]);
if (foundea)
{
reportAPI(reply, *foundea);
}
else
{
// Here the requested LLEventAPI doesn't yet exist, but do we have a
// registered LazyEventAPI for it?
LL::LazyEventAPIBase::instance_snapshot snap;
auto foundlea = std::find_if(snap.begin(), snap.end(),
[api = request["api"].asString()]
(const auto& lea)
{ return (lea.getName() == api); });
if (foundlea != snap.end())
{
reportAPI(reply, *foundlea);
}
}
}
void LLLeapListener::getFeatures(const LLSD& request) const
{
// Merely constructing and destroying a Response object suffices here.
// Giving it a name would only produce fatal 'unreferenced variable'
// warnings.
Response(getFeatures(), request);
}
void LLLeapListener::getFeature(const LLSD& request) const
{
Response reply(LLSD(), request);
LLSD::String feature_name(request["feature"]);
LLSD features(getFeatures());
if (features[feature_name].isDefined())
{
reply["feature"] = features[feature_name];
}
}
LLBoundListener LLLeapListener::connect(LLEventPump& pump, const std::string& listener)
{
// Connect to source pump with an adapter that calls our callback with the
// pump name as well as the event data.
return pump.listen(
listener,
[callback=mCallback, pump=pump.getName()]
(const LLSD& data)
{ return callback(pump, data); });
}
void LLLeapListener::saveListener(const std::string& pump_name,
const std::string& listener_name,
const LLBoundListener& listener)
{
// Don't use insert() or emplace() because, if this (pump_name,
// listener_name) pair is already in mListeners, we *want* to overwrite it.
auto& listener_entry{ mListeners[ListenersMap::key_type(pump_name, listener_name)] };
// If we already stored a connection for this pump and listener name,
// disconnect it before overwriting it. But if this entry was newly
// created, disconnect() will be a no-op.
listener_entry.disconnect();
listener_entry = listener;
}
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