/** * @file lleventdispatcher.cpp * @author Nat Goodspeed * @date 2009-06-18 * @brief Implementation for lleventdispatcher. * * $LicenseInfo:firstyear=2009&license=viewerlgpl$ * Second Life Viewer Source Code * Copyright (C) 2010, Linden Research, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; * version 2.1 of the License only. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA * $/LicenseInfo$ */ #if LL_WINDOWS #pragma warning (disable : 4355) // 'this' used in initializer list: yes, intentionally #endif // Precompiled header #include "linden_common.h" // associated header #include "lleventdispatcher.h" // STL headers // std headers // external library headers // other Linden headers #include "llevents.h" #include "llerror.h" #include "llsdutil.h" #include "stringize.h" #include // std::auto_ptr /***************************************************************************** * LLSDArgsSource *****************************************************************************/ /** * Store an LLSD array, producing its elements one at a time. Die with LL_ERRS * if the consumer requests more elements than the array contains. */ class LL_COMMON_API LLSDArgsSource { public: LLSDArgsSource(const std::string function, const LLSD& args); ~LLSDArgsSource(); LLSD next(); void done() const; private: std::string _function; LLSD _args; LLSD::Integer _index; }; LLSDArgsSource::LLSDArgsSource(const std::string function, const LLSD& args): _function(function), _args(args), _index(0) { if (! (_args.isUndefined() || _args.isArray())) { LL_ERRS("LLSDArgsSource") << _function << " needs an args array instead of " << _args << LL_ENDL; } } LLSDArgsSource::~LLSDArgsSource() { done(); } LLSD LLSDArgsSource::next() { if (_index >= _args.size()) { LL_ERRS("LLSDArgsSource") << _function << " requires more arguments than the " << _args.size() << " provided: " << _args << LL_ENDL; } return _args[_index++]; } void LLSDArgsSource::done() const { if (_index < _args.size()) { LL_WARNS("LLSDArgsSource") << _function << " only consumed " << _index << " of the " << _args.size() << " arguments provided: " << _args << LL_ENDL; } } /***************************************************************************** * LLSDArgsMapper *****************************************************************************/ /** * From a formal parameters description and a map of arguments, construct an * arguments array. * * That is, given: * - an LLSD array of length n containing parameter-name strings, * corresponding to the arguments of a function of interest * - an LLSD collection specifying default parameter values, either: * - an LLSD array of length m <= n, matching the rightmost m params, or * - an LLSD map explicitly stating default name=value pairs * - an LLSD map of parameter names and actual values for a particular * function call * construct an LLSD array of actual argument values for this function call. * * The parameter-names array and the defaults collection describe the function * being called. The map might vary with every call, providing argument values * for the described parameters. * * The array of parameter names must match the number of parameters expected * by the function of interest. * * If you pass a map of default parameter values, it provides default values * as you might expect. It is an error to specify a default value for a name * not listed in the parameters array. * * If you pass an array of default parameter values, it is mapped to the * rightmost m of the n parameter names. It is an error if the default-values * array is longer than the parameter-names array. Consider the following * parameter names: ["a", "b", "c", "d"]. * * - An empty array of default values (or an isUndefined() value) asserts that * every one of the above parameter names is required. * - An array of four default values [1, 2, 3, 4] asserts that every one of * the above parameters is optional. If the current parameter map is empty, * they will be passed to the function as [1, 2, 3, 4]. * - An array of two default values [11, 12] asserts that parameters "a" and * "b" are required, while "c" and "d" are optional, having default values * "c"=11 and "d"=12. * * The arguments array is constructed as follows: * * - Arguments-map keys not found in the parameter-names array are ignored. * - Entries from the map provide values for an improper subset of the * parameters named in the parameter-names array. This results in a * tentative values array with "holes." (size of map) + (number of holes) = * (size of names array) * - Holes are filled with the default values. * - Any remaining holes constitute an error. */ class LL_COMMON_API LLSDArgsMapper { public: /// Accept description of function: function name, param names, param /// default values LLSDArgsMapper(const std::string& function, const LLSD& names, const LLSD& defaults); /// Given arguments map, return LLSD::Array of parameter values, or LL_ERRS. LLSD map(const LLSD& argsmap) const; private: static std::string formatlist(const LLSD&); // The function-name string is purely descriptive. We want error messages // to be able to indicate which function's LLSDArgsMapper has the problem. std::string _function; // Store the names array pretty much as given. LLSD _names; // Though we're handed an array of name strings, it's more useful to us to // store it as a map from name string to position index. Of course that's // easy to generate from the incoming names array, but why do it more than // once? typedef std::map IndexMap; IndexMap _indexes; // Generated array of default values, aligned with the array of param names. LLSD _defaults; // Indicate whether we have a default value for each param. typedef std::vector FilledVector; FilledVector _has_dft; }; LLSDArgsMapper::LLSDArgsMapper(const std::string& function, const LLSD& names, const LLSD& defaults): _function(function), _names(names), _has_dft(names.size()) { if (! (_names.isUndefined() || _names.isArray())) { LL_ERRS("LLSDArgsMapper") << function << " names must be an array, not " << names << LL_ENDL; } LLSD::Integer nparams(_names.size()); // From _names generate _indexes. for (LLSD::Integer ni = 0, nend = _names.size(); ni < nend; ++ni) { _indexes[_names[ni]] = ni; } // Presize _defaults() array so we don't have to resize it more than once. // All entries are initialized to LLSD(); but since _has_dft is still all // 0, they're all "holes" for now. if (nparams) { _defaults[nparams - 1] = LLSD(); } if (defaults.isUndefined() || defaults.isArray()) { LLSD::Integer ndefaults = defaults.size(); // defaults is a (possibly empty) array. Right-align it with names. if (ndefaults > nparams) { LL_ERRS("LLSDArgsMapper") << function << " names array " << names << " shorter than defaults array " << defaults << LL_ENDL; } // Offset by which we slide defaults array right to right-align with // _names array LLSD::Integer offset = nparams - ndefaults; // Fill rightmost _defaults entries from defaults, and mark them as // filled for (LLSD::Integer i = 0, iend = ndefaults; i < iend; ++i) { _defaults[i + offset] = defaults[i]; _has_dft[i + offset] = 1; } } else if (defaults.isMap()) { // defaults is a map. Use it to populate the _defaults array. LLSD bogus; for (LLSD::map_const_iterator mi(defaults.beginMap()), mend(defaults.endMap()); mi != mend; ++mi) { IndexMap::const_iterator ixit(_indexes.find(mi->first)); if (ixit == _indexes.end()) { bogus.append(mi->first); continue; } LLSD::Integer pos = ixit->second; // Store default value at that position in the _defaults array. _defaults[pos] = mi->second; // Don't forget to record the fact that we've filled this // position. _has_dft[pos] = 1; } if (bogus.size()) { LL_ERRS("LLSDArgsMapper") << function << " defaults specified for nonexistent params " << formatlist(bogus) << LL_ENDL; } } else { LL_ERRS("LLSDArgsMapper") << function << " defaults must be a map or an array, not " << defaults << LL_ENDL; } } LLSD LLSDArgsMapper::map(const LLSD& argsmap) const { if (! (argsmap.isUndefined() || argsmap.isMap())) { LL_ERRS("LLSDArgsMapper") << _function << " map() needs a map, not " << argsmap << LL_ENDL; } // Initialize the args array. Indexing a non-const LLSD array grows it // to appropriate size, but we don't want to resize this one on each // new operation. Just make it as big as we need before we start // stuffing values into it. LLSD args(LLSD::emptyArray()); if (_defaults.size() == 0) { // If this function requires no arguments, fast exit. (Don't try to // assign to args[-1].) return args; } args[_defaults.size() - 1] = LLSD(); // Get a vector of chars to indicate holes. It's tempting to just scan // for LLSD::isUndefined() values after filling the args array from // the map, but it's plausible for caller to explicitly pass // isUndefined() as the value of some parameter name. That's legal // since isUndefined() has well-defined conversions (default value) // for LLSD data types. So use a whole separate array for detecting // holes. (Avoid std::vector which is known to be odd -- can we // iterate?) FilledVector filled(args.size()); // Walk the map. for (LLSD::map_const_iterator mi(argsmap.beginMap()), mend(argsmap.endMap()); mi != mend; ++mi) { // mi->first is a parameter-name string, with mi->second its // value. Look up the name's position index in _indexes. IndexMap::const_iterator ixit(_indexes.find(mi->first)); if (ixit == _indexes.end()) { // Allow for a map containing more params than were passed in // our names array. Caller typically receives a map containing // the function name, cruft such as reqid, etc. Ignore keys // not defined in _indexes. LL_DEBUGS("LLSDArgsMapper") << _function << " ignoring " << mi->first << "=" << mi->second << LL_ENDL; continue; } LLSD::Integer pos = ixit->second; // Store the value at that position in the args array. args[pos] = mi->second; // Don't forget to record the fact that we've filled this // position. filled[pos] = 1; } // Fill any remaining holes from _defaults. LLSD unfilled(LLSD::emptyArray()); for (LLSD::Integer i = 0, iend = args.size(); i < iend; ++i) { if (! filled[i]) { // If there's no default value for this parameter, that's an // error. if (! _has_dft[i]) { unfilled.append(_names[i]); } else { args[i] = _defaults[i]; } } } // If any required args -- args without defaults -- were left unfilled // by argsmap, that's a problem. if (unfilled.size()) { LL_ERRS("LLSDArgsMapper") << _function << " missing required arguments " << formatlist(unfilled) << " from " << argsmap << LL_ENDL; } // done return args; } std::string LLSDArgsMapper::formatlist(const LLSD& list) { std::ostringstream out; const char* delim = ""; for (LLSD::array_const_iterator li(list.beginArray()), lend(list.endArray()); li != lend; ++li) { out << delim << li->asString(); delim = ", "; } return out.str(); } LLEventDispatcher::LLEventDispatcher(const std::string& desc, const std::string& key): mDesc(desc), mKey(key) { } LLEventDispatcher::~LLEventDispatcher() { } /** * DispatchEntry subclass used for callables accepting(const LLSD&) */ struct LLEventDispatcher::LLSDDispatchEntry: public LLEventDispatcher::DispatchEntry { LLSDDispatchEntry(const std::string& desc, const Callable& func, const LLSD& required): DispatchEntry(desc), mFunc(func), mRequired(required) {} Callable mFunc; LLSD mRequired; virtual void call(const std::string& desc, const LLSD& event) const { // Validate the syntax of the event itself. std::string mismatch(llsd_matches(mRequired, event)); if (! mismatch.empty()) { LL_ERRS("LLEventDispatcher") << desc << ": bad request: " << mismatch << LL_ENDL; } // Event syntax looks good, go for it! mFunc(event); } virtual LLSD addMetadata(LLSD meta) const { meta["required"] = mRequired; return meta; } }; /** * DispatchEntry subclass for passing LLSD to functions accepting * arbitrary argument types (convertible via LLSDParam) */ struct LLEventDispatcher::ParamsDispatchEntry: public LLEventDispatcher::DispatchEntry { ParamsDispatchEntry(const std::string& desc, const invoker_function& func): DispatchEntry(desc), mInvoker(func) {} invoker_function mInvoker; virtual void call(const std::string& desc, const LLSD& event) const { LLSDArgsSource src(desc, event); mInvoker(boost::bind(&LLSDArgsSource::next, boost::ref(src))); } }; /** * DispatchEntry subclass for dispatching LLSD::Array to functions accepting * arbitrary argument types (convertible via LLSDParam) */ struct LLEventDispatcher::ArrayParamsDispatchEntry: public LLEventDispatcher::ParamsDispatchEntry { ArrayParamsDispatchEntry(const std::string& desc, const invoker_function& func, LLSD::Integer arity): ParamsDispatchEntry(desc, func), mArity(arity) {} LLSD::Integer mArity; virtual LLSD addMetadata(LLSD meta) const { LLSD array(LLSD::emptyArray()); // Resize to number of arguments required if (mArity) array[mArity - 1] = LLSD(); llassert_always(array.size() == mArity); meta["required"] = array; return meta; } }; /** * DispatchEntry subclass for dispatching LLSD::Map to functions accepting * arbitrary argument types (convertible via LLSDParam) */ struct LLEventDispatcher::MapParamsDispatchEntry: public LLEventDispatcher::ParamsDispatchEntry { MapParamsDispatchEntry(const std::string& name, const std::string& desc, const invoker_function& func, const LLSD& params, const LLSD& defaults): ParamsDispatchEntry(desc, func), mMapper(name, params, defaults), mRequired(LLSD::emptyMap()) { // Build the set of all param keys, then delete the ones that are // optional. What's left are the ones that are required. for (LLSD::array_const_iterator pi(params.beginArray()), pend(params.endArray()); pi != pend; ++pi) { mRequired[pi->asString()] = LLSD(); } if (defaults.isArray() || defaults.isUndefined()) { // Right-align the params and defaults arrays. LLSD::Integer offset = params.size() - defaults.size(); // Now the name of every defaults[i] is at params[i + offset]. for (LLSD::Integer i(0), iend(defaults.size()); i < iend; ++i) { // Erase this optional param from mRequired. mRequired.erase(params[i + offset].asString()); // Instead, make an entry in mOptional with the default // param's name and value. mOptional[params[i + offset].asString()] = defaults[i]; } } else if (defaults.isMap()) { // if defaults is already a map, then it's already in the form we // intend to deliver in metadata mOptional = defaults; // Just delete from mRequired every key appearing in mOptional. for (LLSD::map_const_iterator mi(mOptional.beginMap()), mend(mOptional.endMap()); mi != mend; ++mi) { mRequired.erase(mi->first); } } } LLSDArgsMapper mMapper; LLSD mRequired; LLSD mOptional; virtual void call(const std::string& desc, const LLSD& event) const { // Just convert from LLSD::Map to LLSD::Array using mMapper, then pass // to base-class call() method. ParamsDispatchEntry::call(desc, mMapper.map(event)); } virtual LLSD addMetadata(LLSD meta) const { meta["required"] = mRequired; meta["optional"] = mOptional; return meta; } }; void LLEventDispatcher::addArrayParamsDispatchEntry(const std::string& name, const std::string& desc, const invoker_function& invoker, LLSD::Integer arity) { mDispatch.insert( DispatchMap::value_type(name, DispatchMap::mapped_type( new ArrayParamsDispatchEntry(desc, invoker, arity)))); } void LLEventDispatcher::addMapParamsDispatchEntry(const std::string& name, const std::string& desc, const invoker_function& invoker, const LLSD& params, const LLSD& defaults) { mDispatch.insert( DispatchMap::value_type(name, DispatchMap::mapped_type( new MapParamsDispatchEntry(name, desc, invoker, params, defaults)))); } /// Register a callable by name void LLEventDispatcher::add(const std::string& name, const std::string& desc, const Callable& callable, const LLSD& required) { mDispatch.insert( DispatchMap::value_type(name, DispatchMap::mapped_type( new LLSDDispatchEntry(desc, callable, required)))); } void LLEventDispatcher::addFail(const std::string& name, const std::string& classname) const { LL_ERRS("LLEventDispatcher") << "LLEventDispatcher(" << mDesc << ")::add(" << name << "): " << classname << " is not a subclass " << "of LLEventDispatcher" << LL_ENDL; } /// Unregister a callable bool LLEventDispatcher::remove(const std::string& name) { DispatchMap::iterator found = mDispatch.find(name); if (found == mDispatch.end()) { return false; } mDispatch.erase(found); return true; } /// Call a registered callable with an explicitly-specified name. If no /// such callable exists, die with LL_ERRS. void LLEventDispatcher::operator()(const std::string& name, const LLSD& event) const { if (! try_call(name, event)) { LL_ERRS("LLEventDispatcher") << "LLEventDispatcher(" << mDesc << "): '" << name << "' not found" << LL_ENDL; } } /// Extract the @a key value from the incoming @a event, and call the /// callable whose name is specified by that map @a key. If no such /// callable exists, die with LL_ERRS. void LLEventDispatcher::operator()(const LLSD& event) const { // This could/should be implemented in terms of the two-arg overload. // However -- we can produce a more informative error message. std::string name(event[mKey]); if (! try_call(name, event)) { LL_ERRS("LLEventDispatcher") << "LLEventDispatcher(" << mDesc << "): bad " << mKey << " value '" << name << "'" << LL_ENDL; } } bool LLEventDispatcher::try_call(const LLSD& event) const { return try_call(event[mKey], event); } bool LLEventDispatcher::try_call(const std::string& name, const LLSD& event) const { DispatchMap::const_iterator found = mDispatch.find(name); if (found == mDispatch.end()) { return false; } // Found the name, so it's plausible to even attempt the call. found->second->call(STRINGIZE("LLEventDispatcher(" << mDesc << ") calling '" << name << "'"), event); return true; // tell caller we were able to call } LLSD LLEventDispatcher::getMetadata(const std::string& name) const { DispatchMap::const_iterator found = mDispatch.find(name); if (found == mDispatch.end()) { return LLSD(); } LLSD meta; meta["name"] = name; meta["desc"] = found->second->mDesc; return found->second->addMetadata(meta); } LLDispatchListener::LLDispatchListener(const std::string& pumpname, const std::string& key): LLEventDispatcher(pumpname, key), mPump(pumpname, true), // allow tweaking for uniqueness mBoundListener(mPump.listen("self", boost::bind(&LLDispatchListener::process, this, _1))) { } bool LLDispatchListener::process(const LLSD& event) { (*this)(event); return false; } LLEventDispatcher::DispatchEntry::DispatchEntry(const std::string& desc): mDesc(desc) {}