/** * @file llleap.cpp * @author Nat Goodspeed * @date 2012-02-20 * @brief Implementation for llleap. * * $LicenseInfo:firstyear=2012&license=viewerlgpl$ * Copyright (c) 2012, Linden Research, Inc. * $/LicenseInfo$ */ // Precompiled header #include "linden_common.h" // associated header #include "llleap.h" // STL headers #include #include #include // std headers // external library headers // other Linden headers #include "llerror.h" #include "llstring.h" #include "llprocess.h" #include "llevents.h" #include "stringize.h" #include "llsdutil.h" #include "llsdserialize.h" #include "llerrorcontrol.h" #include "lltimer.h" #include "lluuid.h" #include "llleaplistener.h" #include "llexception.h" #if LL_MSVC #pragma warning (disable : 4355) // 'this' used in initializer list: yes, intentionally #endif LLLeap::LLLeap() {} LLLeap::~LLLeap() {} class LLLeapImpl: public LLLeap { LOG_CLASS(LLLeap); public: // Called only by LLLeap::create() LLLeapImpl(const LLProcess::Params& cparams): // We might reassign mDesc in the constructor body if it's empty here. mDesc(cparams.desc), // We expect multiple LLLeapImpl instances. Definitely tweak // mDonePump's name for uniqueness. mDonePump("LLLeap", true), mExpect(0), // Instantiate a distinct LLLeapListener for this plugin. (Every // plugin will want its own collection of managed listeners, etc.) // Pass it our wstdin() method as its callback, so it can send events // from a particular LLEventPump to the plugin without having to know // this class or method name. mListener( new LLLeapListener( "LLLeap", // Serialize any reply event to our child's stdin, suitably // enriched with the pump name on which it was received. [this](const std::string& pump, const LLSD& data) { return wstdin(pump, data); })) { // Rule out unpopulated Params block if (! cparams.executable.isProvided()) { LLTHROW(Error("no plugin command")); } // Don't leave desc empty either, but in this case, if we weren't // given one, we'll fake one. if (mDesc.empty()) { mDesc = LLProcess::basename(cparams.executable); // how about a toLower() variant that returns the transformed string?! std::string desclower(mDesc); LLStringUtil::toLower(desclower); // If we're running a Python script, use the script name for the // desc instead of just 'python'. Arguably we should check for // more different interpreters as well, but there's a reason to // notice Python specially: we provide Python LLSD serialization // support, so there's a pretty good reason to implement plugins // in that language. if (cparams.args.size() && (desclower == "python" || desclower == "python3" || desclower == "python.exe")) { mDesc = LLProcess::basename(cparams.args()[0]); } } // Listen for child "termination" right away to catch launch errors. mDonePump.listen("LLLeap", [this](const LLSD& data){ return bad_launch(data); }); // Okay, launch child. // Get a modifiable copy of params block to set files and postend. LLProcess::Params params(cparams); // copy our deduced mDesc back into the params block params.desc = mDesc; params.files.add(LLProcess::FileParam("pipe")); // stdin params.files.add(LLProcess::FileParam("pipe")); // stdout params.files.add(LLProcess::FileParam("pipe")); // stderr params.postend = mDonePump.getName(); mChild = LLProcess::create(params); // If that didn't work, no point in keeping this LLLeap object. if (! mChild) { LLTHROW(Error(STRINGIZE("failed to run " << mDesc))); } // Okay, launch apparently worked. Change our mDonePump listener. mDonePump.stopListening("LLLeap"); mDonePump.listen("LLLeap", [this](const LLSD& data){ return done(data); }); // Child might pump large volumes of data through either stdout or // stderr. Don't bother copying all that data into notification event. LLProcess::ReadPipe &childout(mChild->getReadPipe(LLProcess::STDOUT)), &childerr(mChild->getReadPipe(LLProcess::STDERR)); childout.setLimit(20); childerr.setLimit(20); // Listening on stdout is stateful. In general, we're either waiting // for the length prefix or waiting for the specified length of data. mReadPrefix = true; mStdoutConnection = childout.getPump() .listen("LLLeap", [this](const LLSD& data){ return rstdout(data); }); // Log anything sent up through stderr. When a typical program // encounters an error, it writes its error message to stderr and // terminates with nonzero exit code. In particular, the Python // interpreter behaves that way. More generally, though, a plugin // author can log whatever s/he wants to the viewer log using stderr. mStderrConnection = childerr.getPump() .listen("LLLeap", [this](const LLSD& data){ return rstderr(data); }); // For our lifespan, intercept any LL_ERRS so we can notify plugin mRecorder = LLError::addGenericRecorder( [this](LLError::ELevel level, const std::string& message) { onError(level, message); }); // Send child a preliminary event reporting our own reply-pump name -- // which would otherwise be pretty tricky to guess! wstdin(mListener->getReplyPump().getName(), LLSDMap ("command", mListener->getName()) // Include LLLeap features -- this may be important for child to // construct (or recognize) current protocol. ("features", LLLeapListener::getFeatures())); } // Normally we'd expect to arrive here only via done() virtual ~LLLeapImpl() { LL_DEBUGS("LLLeap") << "destroying LLLeap(\"" << mDesc << "\")" << LL_ENDL; LLError::removeRecorder(mRecorder); } // Listener for failed launch attempt bool bad_launch(const LLSD& data) { LL_WARNS("LLLeap") << data["string"].asString() << LL_ENDL; return false; } // Listener for child-process termination bool done(const LLSD& data) { // Log the termination LL_INFOS("LLLeap") << data["string"].asString() << LL_ENDL; // Any leftover data at this moment are because protocol was not // satisfied. Possibly the child was interrupted in the middle of // sending a message, possibly the child didn't flush stdout before // terminating, possibly it's just garbage. Log its existence but // discard it. LLProcess::ReadPipe& childout(mChild->getReadPipe(LLProcess::STDOUT)); if (childout.size()) { LLProcess::ReadPipe::size_type peeklen((std::min)(LLProcess::ReadPipe::size_type(50), childout.size())); LL_WARNS("LLLeap") << "Discarding final " << childout.size() << " bytes: " << childout.peek(0, peeklen) << "..." << LL_ENDL; } // Kill this instance. MUST BE LAST before return! delete this; return false; } // Listener for reply events: send to child stdin bool wstdin(const std::string& pump, const LLSD& data) { LLSD packet(LLSDMap("pump", pump)("data", data)); std::ostringstream buffer; // SL-18330: for large data blocks, it's much faster to parse binary // LLSD than notation LLSD. Use serialize(LLSD_BINARY) rather than // directly calling LLSDBinaryFormatter because, unlike the latter, // serialize() prepends the relevant header, needed by a general- // purpose LLSD parser to distinguish binary from notation. LLSDSerialize::serialize(packet, buffer, LLSDSerialize::LLSD_BINARY, LLSDFormatter::OPTIONS_NONE); /*==========================================================================*| // DEBUGGING ONLY: don't copy str() if we can avoid it. std::string strdata(buffer.str()); if (std::size_t(buffer.tellp()) != strdata.length()) { LL_ERRS("LLLeap") << "tellp() -> " << static_cast(buffer.tellp()) << " != " << "str().length() -> " << strdata.length() << LL_ENDL; } // DEBUGGING ONLY: reading back is terribly inefficient. std::istringstream readback(strdata); LLSD echo; bool parse_status(LLSDSerialize::deserialize(echo, readback, strdata.length())); if (! parse_status) { LL_ERRS("LLLeap") << "LLSDSerialize::deserialize() cannot parse output of " << "LLSDSerialize::serialize(LLSD_BINARY)" << LL_ENDL; } if (! llsd_equals(echo, packet)) { LL_ERRS("LLLeap") << "LLSDSerialize::deserialize() returned different LLSD " << "than passed to LLSDSerialize::serialize()" << LL_ENDL; } |*==========================================================================*/ LL_DEBUGS("EventHost") << "Sending: " << static_cast(buffer.tellp()) << ':'; llssize truncate(80); if (buffer.tellp() <= truncate) { LL_CONT << buffer.str(); } else { LL_CONT << buffer.str().substr(0, truncate) << "..."; } LL_CONT << LL_ENDL; LLProcess::WritePipe& childin(mChild->getWritePipe(LLProcess::STDIN)); childin.get_ostream() << static_cast(buffer.tellp()) << ':' << buffer.str() << std::flush; return false; } // Stateful listening on child stdout: // wait for a length prefix, followed by ':'. bool rstdout(const LLSD&) { LLProcess::ReadPipe& childout(mChild->getReadPipe(LLProcess::STDOUT)); while (childout.size()) { /*----------------- waiting for length prefix ------------------*/ if (mReadPrefix) { // It's possible we got notified of a couple digit characters without // seeing the ':' -- unlikely, but still. Until we see ':', keep // waiting. if (! childout.contains(':')) { if (childout.contains('\n')) { // Since this is the initial listening state, this is where we'd // arrive if the child isn't following protocol at all -- say // because the user specified 'ls' or some darn thing. bad_protocol(childout.getline()); } // Either way, stop looping. break; } // Saw ':', read length prefix and store in mExpect. std::istream& childstream(childout.get_istream()); size_t expect; childstream >> expect; int colon(childstream.get()); if (colon != ':') { // Protocol failure. Clear out the rest of the pending data in // childout (well, up to a max length) to log what was wrong. LLProcess::ReadPipe::size_type readlen((std::min)(childout.size(), LLProcess::ReadPipe::size_type(80))); bad_protocol(stringize(expect, char(colon), childout.read(readlen))); break; } else { // Saw length prefix, saw colon, life is good. Now wait for // that length of data to arrive. mExpect = expect; LL_DEBUGS("LLLeap") << "got length, waiting for " << mExpect << " bytes of data" << LL_ENDL; // Transition to "read data" mode and loop back to check // if we've already received all the advertised data. mReadPrefix = false; continue; } } /*----------------- saw prefix, wait for data ------------------*/ else { // Until we've accumulated the promised length of data, keep waiting. if (childout.size() < mExpect) { break; } // We have the data we were told to expect! Ready to rock and roll. LL_DEBUGS("LLLeap") << "needed " << mExpect << " bytes, got " << childout.size() << ", parsing LLSD" << LL_ENDL; LLSD data; #if 1 // specifically require notation LLSD from child LLPointer parser(new LLSDNotationParser()); S32 parse_status(parser->parse(childout.get_istream(), data, mExpect)); if (parse_status == LLSDParser::PARSE_FAILURE) #else // SL-18330: accept any valid LLSD serialization format from child // Unfortunately this runs into trouble we have not yet debugged. bool parse_status(LLSDSerialize::deserialize(data, childout.get_istream(), mExpect)); if (! parse_status) #endif { bad_protocol("unparseable LLSD data"); break; } else if (! (data.isMap() && data["pump"].isString() && data.has("data"))) { // we got an LLSD object, but it lacks required keys bad_protocol("missing 'pump' or 'data'"); break; } else { try { // The LLSD object we got from our stream contains the // keys we need. LLEventPumps::instance().post(data["pump"], data["data"]); } catch (const std::exception& err) { // No plugin should be allowed to crash the viewer by // driving an exception -- intentionally or not. LOG_UNHANDLED_EXCEPTION(stringize("handling request ", data)); // Whether or not the plugin added a "reply" key to the // request, send a reply. We happen to know who originated // this request, and the reply LLEventPump of interest. // Not our problem if the plugin ignores the reply event. data["reply"] = mListener->getReplyPump().getName(); sendReply(llsd::map("error", stringize(LLError::Log::classname(err), ": ", err.what())), data); } // Transition to "read prefix" mode and go check for any // more pending events in the buffer. mReadPrefix = true; continue; } } } return false; } void bad_protocol(const std::string& data) { LL_WARNS("LLLeap") << mDesc << ": invalid protocol: " << data << LL_ENDL; // No point in continuing to run this child. mChild->kill(); } // Listen on child stderr and log everything that arrives bool rstderr(const LLSD& data) { LLProcess::ReadPipe& childerr(mChild->getReadPipe(LLProcess::STDERR)); // We might have gotten a notification involving only a partial line // -- or multiple lines. Read all complete lines; stop when there's // only a partial line left. while (childerr.contains('\n')) { // DO NOT make calls with side effects in a logging statement! If // that log level is suppressed, your side effects WON'T HAPPEN. std::string line(childerr.getline()); // Log the received line. Prefix it with the desc so we know which // plugin it's from. This method name rstderr() is intentionally // chosen to further qualify the log output. LL_INFOS("LLLeap") << mDesc << ": " << line << LL_ENDL; } // What if child writes a final partial line to stderr? if (data["eof"].asBoolean() && childerr.size()) { std::string rest(childerr.read(childerr.size())); // Read all remaining bytes and log. LL_INFOS("LLLeap") << mDesc << ": " << rest << LL_ENDL; } /*--------------------------- diagnostic ---------------------------*/ else if (data["eof"].asBoolean()) { LL_DEBUGS("LLLeap") << mDesc << " ended, no partial line" << LL_ENDL; } else { LL_DEBUGS("LLLeap") << mDesc << " (still running, " << childerr.size() << " bytes pending)" << LL_ENDL; } /*------------------------- end diagnostic -------------------------*/ return false; } void onError(LLError::ELevel level, const std::string& error) { if (level == LLError::LEVEL_ERROR) { // Notify plugin LLSD event; event["type"] = "error"; event["error"] = error; mListener->getReplyPump().post(event); // All the above really accomplished was to buffer the serialized // event in our WritePipe. Have to pump mainloop a couple times to // really write it out there... but time out in case we can't write. LLProcess::WritePipe& childin(mChild->getWritePipe(LLProcess::STDIN)); LLEventPump& mainloop(LLEventPumps::instance().obtain("mainloop")); LLSD nop; F64 until = (LLTimer::getElapsedSeconds() + 2).value(); while (childin.size() && LLTimer::getElapsedSeconds() < until) { mainloop.post(nop); } } } private: std::string mDesc; LLEventStream mDonePump; LLProcessPtr mChild; LLTempBoundListener mStdoutConnection, mStderrConnection; LLProcess::ReadPipe::size_type mExpect; LLError::RecorderPtr mRecorder; std::unique_ptr mListener; bool mReadPrefix; }; // These must follow the declaration of LLLeapImpl, so they may as well be last. LLLeap* LLLeap::create(const LLProcess::Params& params, bool exc) { // If caller is willing to permit exceptions, just instantiate. if (exc) return new LLLeapImpl(params); // Caller insists on suppressing LLLeap::Error. Very well, catch it. try { return new LLLeapImpl(params); } catch (const LLLeap::Error&) { return NULL; } } LLLeap* LLLeap::create(const std::string& desc, const std::vector& plugin, bool exc) { LLProcess::Params params; params.desc = desc; std::vector::const_iterator pi(plugin.begin()), pend(plugin.end()); // could validate here, but let's rely on LLLeapImpl's constructor if (pi != pend) { params.executable = *pi++; } for ( ; pi != pend; ++pi) { params.args.add(*pi); } return create(params, exc); } LLLeap* LLLeap::create(const std::string& desc, const std::string& plugin, bool exc) { // Use LLStringUtil::getTokens() to parse the command line return create(desc, LLStringUtil::getTokens(plugin, " \t\r\n", // drop_delims "", // no keep_delims "\"'", // either kind of quotes "\\"), // backslash escape exc); }