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Diffstat (limited to 'indra/llcommon/lazyeventapi.h')
-rw-r--r-- | indra/llcommon/lazyeventapi.h | 205 |
1 files changed, 205 insertions, 0 deletions
diff --git a/indra/llcommon/lazyeventapi.h b/indra/llcommon/lazyeventapi.h new file mode 100644 index 0000000000..e36831270b --- /dev/null +++ b/indra/llcommon/lazyeventapi.h @@ -0,0 +1,205 @@ +/** + * @file lazyeventapi.h + * @author Nat Goodspeed + * @date 2022-06-16 + * @brief Declaring a static module-scope LazyEventAPI registers a specific + * LLEventAPI for future on-demand instantiation. + * + * $LicenseInfo:firstyear=2022&license=viewerlgpl$ + * Copyright (c) 2022, Linden Research, Inc. + * $/LicenseInfo$ + */ + +#if ! defined(LL_LAZYEVENTAPI_H) +#define LL_LAZYEVENTAPI_H + +#include "apply.h" +#include "lleventapi.h" +#include "llinstancetracker.h" +#include <boost/signals2/signal.hpp> +#include <string> +#include <tuple> +#include <utility> // std::pair +#include <vector> + +namespace LL +{ + /** + * Bundle params we want to pass to LLEventAPI's protected constructor. We + * package them this way so a subclass constructor can simply forward an + * opaque reference to the LLEventAPI constructor. + */ + // This is a class instead of a plain struct mostly so when we forward- + // declare it we don't have to remember the distinction. + class LazyEventAPIParams + { + public: + // package the parameters used by the normal LLEventAPI constructor + std::string name, desc, field; + // bundle LLEventAPI::add() calls collected by LazyEventAPI::add(), so + // the special LLEventAPI constructor we engage can "play back" those + // add() calls + boost::signals2::signal<void(LLEventAPI*)> init; + }; + + /** + * LazyEventAPIBase implements most of the functionality of LazyEventAPI + * (q.v.), but we need the LazyEventAPI template subclass so we can accept + * the specific LLEventAPI subclass type. + */ + // No LLInstanceTracker key: we don't need to find a specific instance, + // LLLeapListener just needs to be able to enumerate all instances. + class LazyEventAPIBase: public LLInstanceTracker<LazyEventAPIBase> + { + public: + LazyEventAPIBase(const std::string& name, const std::string& desc, + const std::string& field); + virtual ~LazyEventAPIBase(); + + // Do not copy or move: once constructed, LazyEventAPIBase must stay + // put: we bind its instance pointer into a callback. + LazyEventAPIBase(const LazyEventAPIBase&) = delete; + LazyEventAPIBase(LazyEventAPIBase&&) = delete; + LazyEventAPIBase& operator=(const LazyEventAPIBase&) = delete; + LazyEventAPIBase& operator=(LazyEventAPIBase&&) = delete; + + // capture add() calls we want to play back on LLEventAPI construction + template <typename... ARGS> + void add(const std::string& name, const std::string& desc, ARGS&&... rest) + { + // capture the metadata separately + mOperations.push_back(std::make_pair(name, desc)); + // Use connect_extended() so the lambda is passed its own + // connection. + + // apply() can't accept a template per se; it needs a particular + // specialization. Specialize out here to work around a clang bug: + // https://github.com/llvm/llvm-project/issues/41999 + auto func{ &LazyEventAPIBase::add_trampoline + <const std::string&, const std::string&, ARGS...> }; + // We can't bind an unexpanded parameter pack into a lambda -- + // shame really. Instead, capture all our args as a std::tuple and + // then, in the lambda, use apply() to pass to add_trampoline(). + auto args{ std::make_tuple(name, desc, std::forward<ARGS>(rest)...) }; + + mParams.init.connect_extended( + [func, args] + (const boost::signals2::connection& conn, LLEventAPI* instance) + { + // we only need this connection once + conn.disconnect(); + // apply() expects a tuple specifying ALL the arguments, + // so prepend instance. + apply(func, std::tuple_cat(std::make_tuple(instance), args)); + }); + } + + // The following queries mimic the LLEventAPI / LLEventDispatcher + // query API. + + // Get the string name of the subject LLEventAPI + std::string getName() const { return mParams.name; } + // Get the documentation string + std::string getDesc() const { return mParams.desc; } + // Retrieve the LLSD key we use for dispatching + std::string getDispatchKey() const { return mParams.field; } + + // operations + using NameDesc = std::pair<std::string, std::string>; + + private: + // metadata that might be queried by LLLeapListener + std::vector<NameDesc> mOperations; + + public: + using const_iterator = decltype(mOperations)::const_iterator; + const_iterator begin() const { return mOperations.begin(); } + const_iterator end() const { return mOperations.end(); } + LLSD getMetadata(const std::string& name) const; + + protected: + // Params with which to instantiate the companion LLEventAPI subclass + LazyEventAPIParams mParams; + + private: + // true if we successfully registered our LLEventAPI on construction + bool mRegistered; + + // actually instantiate the companion LLEventAPI subclass + virtual LLEventPump* construct(const std::string& name) = 0; + + // Passing an overloaded function to any function that accepts an + // arbitrary callable is a PITB because you have to specify the + // correct overload. What we want is for the compiler to select the + // correct overload, based on the carefully-wrought enable_ifs in + // LLEventDispatcher. This (one and only) add_trampoline() method + // exists solely to pass to LL::apply(). Once add_trampoline() is + // called with the expanded arguments, we hope the compiler will Do + // The Right Thing in selecting the correct LLEventAPI::add() + // overload. + template <typename... ARGS> + static + void add_trampoline(LLEventAPI* instance, ARGS&&... args) + { + instance->add(std::forward<ARGS>(args)...); + } + }; + + /** + * LazyEventAPI provides a way to register a particular LLEventAPI to be + * instantiated on demand, that is, when its name is passed to + * LLEventPumps::obtain(). + * + * Derive your listener from LLEventAPI as usual, with its various + * operation methods, but code your constructor to accept + * <tt>(const LL::LazyEventAPIParams& params)</tt> + * and forward that reference to (the protected) + * <tt>LLEventAPI(const LL::LazyEventAPIParams&)</tt> constructor. + * + * Then derive your listener registrar from + * <tt>LazyEventAPI<your LLEventAPI subclass></tt>. The constructor should + * look very like a traditional LLEventAPI constructor: + * + * * pass (name, desc [, field]) to LazyEventAPI's constructor + * * in the body, make a series of add() calls referencing your LLEventAPI + * subclass methods. + * + * You may use any LLEventAPI::add() methods, that is, any + * LLEventDispatcher::add() methods. But the target methods you pass to + * add() must belong to your LLEventAPI subclass, not the LazyEventAPI + * subclass. + * + * Declare a static instance of your LazyEventAPI listener registrar + * class. When it's constructed at static initialization time, it will + * register your LLEventAPI subclass with LLEventPumps. It will also + * collect metadata for the LLEventAPI and its operations to provide to + * LLLeapListener's introspection queries. + * + * When someone later calls LLEventPumps::obtain() to post an event to + * your LLEventAPI subclass, obtain() will instantiate it using + * LazyEventAPI's name, desc, field and add() calls. + */ + template <class EVENTAPI> + class LazyEventAPI: public LazyEventAPIBase + { + public: + // for subclass constructor to reference handler methods + using listener = EVENTAPI; + + LazyEventAPI(const std::string& name, const std::string& desc, + const std::string& field="op"): + // Forward ctor params to LazyEventAPIBase + LazyEventAPIBase(name, desc, field) + {} + + private: + LLEventPump* construct(const std::string& /*name*/) override + { + // base class has carefully assembled LazyEventAPIParams embedded + // in this instance, just pass to LLEventAPI subclass constructor + return new EVENTAPI(mParams); + } + }; +} // namespace LL + +#endif /* ! defined(LL_LAZYEVENTAPI_H) */ |