/* * Carla Pipe Utilities * Copyright (C) 2013-2019 Filipe Coelho * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation; either version 2 of * the License, or any later version. * * This program 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 General Public License for more details. * * For a full copy of the GNU General Public License see the doc/GPL.txt file. */ #include "CarlaPipeUtils.hpp" #include "CarlaProcessUtils.hpp" #include "CarlaString.hpp" #include "CarlaMIDI.h" // needed for atom-util #ifndef nullptr # undef NULL # define NULL nullptr #endif #ifdef BUILDING_CARLA # include "lv2/atom-util.h" #else # include "lv2/lv2plug.in/ns/ext/atom/util.h" #endif #include #include "water/misc/Time.h" #include "water/text/String.h" #ifdef CARLA_OS_WIN # include #else # include # include # include # ifdef CARLA_OS_LINUX # include # ifndef F_SETPIPE_SZ # define F_SETPIPE_SZ 1031 # endif # endif #endif #ifdef CARLA_OS_WIN # define INVALID_PIPE_VALUE INVALID_HANDLE_VALUE #else # define INVALID_PIPE_VALUE -1 #endif #ifdef CARLA_OS_WIN // ----------------------------------------------------------------------- // win32 stuff static inline bool waitForAsyncObject(const HANDLE object, const HANDLE process = INVALID_HANDLE_VALUE) { DWORD dw, dw2; MSG msg; // we give it a max for (int i=20000; --i>=0;) { if (process != INVALID_HANDLE_VALUE) { switch (::WaitForSingleObject(process, 0)) { case WAIT_OBJECT_0: case WAIT_FAILED: carla_stderr("waitForAsyncObject process has stopped"); return false; } } carla_debug("waitForAsyncObject loop start"); dw = ::MsgWaitForMultipleObjectsEx(1, &object, INFINITE, QS_POSTMESSAGE|QS_TIMER, 0); carla_debug("waitForAsyncObject initial code is: %u", dw); if (dw == WAIT_OBJECT_0) { carla_debug("waitForAsyncObject WAIT_OBJECT_0"); return true; } dw2 = ::GetLastError(); if (dw == WAIT_OBJECT_0 + 1) { carla_debug("waitForAsyncObject loop +1"); while (::PeekMessage(&msg, nullptr, 0, 0, PM_REMOVE)) ::DispatchMessage(&msg); continue; } if (dw2 == 0) { carla_debug("waitForAsyncObject loop stop"); return true; } carla_stderr2("waitForAsyncObject loop end reached, error was: %u", dw2); carla_msleep(5); } carla_stderr2("waitForAsyncObject reached the end, this should not happen"); return false; } static inline ssize_t ReadFileWin32(const HANDLE pipeh, const HANDLE event, void* const buf, const std::size_t numBytes) { DWORD dw, dsize = numBytes; DWORD available = 0; if (::PeekNamedPipe(pipeh, nullptr, 0, nullptr, &available, nullptr) == FALSE || available == 0) return -1; OVERLAPPED ov; carla_zeroStruct(ov); ov.hEvent = event; if (::ReadFile(pipeh, buf, dsize, nullptr, &ov)) { if (! ::GetOverlappedResult(pipeh, &ov, &dw, FALSE)) { carla_stderr("ReadFileWin32 GetOverlappedResult failed, error was: %u", ::GetLastError()); return -1; } return static_cast(dsize); } dw = ::GetLastError(); if (dw == ERROR_IO_PENDING) { if (! waitForAsyncObject(event)) { carla_stderr("ReadFileWin32 waitForAsyncObject failed, error was: %u", ::GetLastError()); return -1; } if (! ::GetOverlappedResult(pipeh, &ov, &dw, FALSE)) { carla_stderr("ReadFileWin32 GetOverlappedResult of pending failed, error was: %u", ::GetLastError()); return -1; } return static_cast(dsize); } carla_stderr("ReadFileWin32 failed, error was: %u", dw); return -1; } static inline ssize_t WriteFileWin32(const HANDLE pipeh, const HANDLE event, const void* const buf, const std::size_t numBytes) { DWORD dw, dsize = numBytes; OVERLAPPED ov; carla_zeroStruct(ov); ov.hEvent = event; if (::WriteFile(pipeh, buf, dsize, nullptr, &ov)) { if (! ::GetOverlappedResult(pipeh, &ov, &dw, FALSE)) { carla_stderr("WriteFileWin32 GetOverlappedResult failed, error was: %u", ::GetLastError()); return -1; } return static_cast(dsize); } dw = ::GetLastError(); if (dw == ERROR_IO_PENDING) { if (! waitForAsyncObject(event)) { carla_stderr("WriteFileWin32 waitForAsyncObject failed, error was: %u", ::GetLastError()); return -1; } if (! ::GetOverlappedResult(pipeh, &ov, &dw, FALSE)) { carla_stderr("WriteFileWin32 GetOverlappedResult of pending failed, error was: %u", ::GetLastError()); return -1; } return static_cast(dsize); } if (dw == ERROR_PIPE_NOT_CONNECTED) { carla_stdout("WriteFileWin32 failed, client has closed"); return -2; } carla_stderr("WriteFileWin32 failed, error was: %u", dw); return -1; } #endif // CARLA_OS_WIN // ----------------------------------------------------------------------- // startProcess #ifdef CARLA_OS_WIN static inline bool startProcess(const char* const argv[], PROCESS_INFORMATION* const processInfo) { CARLA_SAFE_ASSERT_RETURN(processInfo != nullptr, false); using water::String; String command; for (int i=0; argv[i] != nullptr; ++i) { String arg(argv[i]); // If there are spaces, surround it with quotes. If there are quotes, // replace them with \" so that CommandLineToArgv will correctly parse them. if (arg.containsAnyOf("\" ")) arg = arg.replace("\"", "\\\"").quoted(); command << arg << ' '; } command = command.trim(); STARTUPINFO startupInfo; carla_zeroStruct(startupInfo); startupInfo.cb = sizeof(startupInfo); if (::CreateProcessA(nullptr, const_cast(command.toRawUTF8()), nullptr, nullptr, TRUE, CREATE_NO_WINDOW | CREATE_UNICODE_ENVIRONMENT, nullptr, nullptr, &startupInfo, processInfo) != FALSE) return true; carla_stderr2("startProcess failed, error was: %u", ::GetLastError()); return false; } static inline bool waitForClientConnect(const HANDLE pipe, const HANDLE event, const HANDLE process, const uint32_t timeOutMilliseconds) noexcept { CARLA_SAFE_ASSERT_RETURN(pipe != INVALID_PIPE_VALUE, false); CARLA_SAFE_ASSERT_RETURN(timeOutMilliseconds > 0, false); DWORD dw; OVERLAPPED ov; carla_zeroStruct(ov); ov.hEvent = event; const uint32_t timeoutEnd(water::Time::getMillisecondCounter() + timeOutMilliseconds); for (;;) { if (::ConnectNamedPipe(pipe, &ov)) { if (! ::GetOverlappedResult(pipe, &ov, &dw, FALSE)) { carla_stderr2("ConnectNamedPipe GetOverlappedResult failed, error was: %u", ::GetLastError()); return false; } return true; } const DWORD err = ::GetLastError(); switch (err) { case ERROR_PIPE_CONNECTED: return true; case ERROR_IO_PENDING: if (! waitForAsyncObject(event, process)) { carla_stderr2("ConnectNamedPipe waitForAsyncObject failed, error was: %u", ::GetLastError()); return false; } if (! ::GetOverlappedResult(pipe, &ov, &dw, FALSE)) { carla_stderr2("ConnectNamedPipe GetOverlappedResult of pending failed, error was: %u", ::GetLastError()); return false; } return true; case ERROR_PIPE_LISTENING: if (water::Time::getMillisecondCounter() < timeoutEnd) { carla_msleep(5); continue; } carla_stderr2("ConnectNamedPipe listening timed out"); return false; default: carla_stderr2("ConnectNamedPipe failed, error was: %u", err); return false; } } return true; } #else static inline bool startProcess(const char* const argv[], pid_t& pidinst) noexcept { const CarlaScopedEnvVar sev1("LD_LIBRARY_PATH", nullptr); const CarlaScopedEnvVar sev2("LD_PRELOAD", nullptr); const pid_t ret = pidinst = vfork(); switch (ret) { case 0: { // child process execvp(argv[0], const_cast(argv)); CarlaString error(std::strerror(errno)); carla_stderr2("exec failed: %s", error.buffer()); _exit(1); // this is not noexcept safe but doesn't matter anyway } break; case -1: { // error CarlaString error(std::strerror(errno)); carla_stderr2("vfork() failed: %s", error.buffer()); } break; } return (ret > 0); } #endif // ----------------------------------------------------------------------- // waitForClientFirstMessage template static inline bool waitForClientFirstMessage(const P& pipe, void* const ovRecv, void* const process, const uint32_t timeOutMilliseconds) noexcept { CARLA_SAFE_ASSERT_RETURN(pipe != INVALID_PIPE_VALUE, false); CARLA_SAFE_ASSERT_RETURN(timeOutMilliseconds > 0, false); char c; ssize_t ret; const uint32_t timeoutEnd(water::Time::getMillisecondCounter() + timeOutMilliseconds); #ifdef CARLA_OS_WIN if (! waitForClientConnect(pipe, (HANDLE)ovRecv, (HANDLE)process, timeOutMilliseconds)) return false; #endif for (;;) { try { #ifdef CARLA_OS_WIN ret = ReadFileWin32(pipe, (HANDLE)ovRecv, &c, 1); #else ret = ::read(pipe, &c, 1); #endif } CARLA_SAFE_EXCEPTION_RETURN("read pipe", false); switch (ret) { case 1: if (c == '\n') return true; carla_stderr("waitForClientFirstMessage() - read has wrong first char '%c'", c);return false; return false; case -1: // failed to read #ifdef CARLA_OS_WIN if (::GetLastError() == ERROR_NO_DATA) #else if (errno == EAGAIN) #endif { if (water::Time::getMillisecondCounter() < timeoutEnd) { carla_msleep(5); continue; } carla_stderr("waitForClientFirstMessage() - read timed out"); } else { #ifdef CARLA_OS_WIN carla_stderr("waitForClientFirstMessage() - read failed"); #else CarlaString error(std::strerror(errno)); carla_stderr("waitForClientFirstMessage() - read failed: %s", error.buffer()); #endif } return false; default: // ??? carla_stderr("waitForClientFirstMessage() - read returned %i", int(ret)); return false; } } // maybe unused (void)ovRecv; (void)process; } // ----------------------------------------------------------------------- // waitForChildToStop / waitForProcessToStop #ifdef CARLA_OS_WIN static inline bool waitForProcessToStop(const HANDLE process, const uint32_t timeOutMilliseconds, bool sendTerminate) noexcept { CARLA_SAFE_ASSERT_RETURN(process != INVALID_HANDLE_VALUE, false); CARLA_SAFE_ASSERT_RETURN(timeOutMilliseconds > 0, false); const uint32_t timeoutEnd(water::Time::getMillisecondCounter() + timeOutMilliseconds); for (;;) { switch (::WaitForSingleObject(process, 0)) { case WAIT_OBJECT_0: case WAIT_FAILED: return true; } if (sendTerminate) { sendTerminate = false; ::TerminateProcess(process, 15); } if (water::Time::getMillisecondCounter() >= timeoutEnd) break; carla_msleep(5); } return false; } static inline void waitForProcessToStopOrKillIt(const HANDLE process, const uint32_t timeOutMilliseconds) noexcept { CARLA_SAFE_ASSERT_RETURN(process != INVALID_HANDLE_VALUE,); CARLA_SAFE_ASSERT_RETURN(timeOutMilliseconds > 0,); if (! waitForProcessToStop(process, timeOutMilliseconds, true)) { carla_stderr("waitForProcessToStopOrKillIt() - process didn't stop, force termination"); if (::TerminateProcess(process, 9) != FALSE) { // wait for process to stop waitForProcessToStop(process, timeOutMilliseconds, false); } } } #else static inline bool waitForChildToStop(const pid_t pid, const uint32_t timeOutMilliseconds, bool sendTerminate) noexcept { CARLA_SAFE_ASSERT_RETURN(pid > 0, false); CARLA_SAFE_ASSERT_RETURN(timeOutMilliseconds > 0, false); pid_t ret; const uint32_t timeoutEnd(water::Time::getMillisecondCounter() + timeOutMilliseconds); for (;;) { try { ret = ::waitpid(pid, nullptr, WNOHANG); } CARLA_SAFE_EXCEPTION_BREAK("waitpid"); switch (ret) { case -1: if (errno == ECHILD) { // success, child doesn't exist return true; } else { CarlaString error(std::strerror(errno)); carla_stderr("waitForChildToStop() - waitpid failed: %s", error.buffer()); return false; } break; case 0: if (sendTerminate) { sendTerminate = false; ::kill(pid, SIGTERM); } if (water::Time::getMillisecondCounter() < timeoutEnd) { carla_msleep(5); continue; } carla_stderr("waitForChildToStop() - timed out"); break; default: if (ret == pid) { // success return true; } else { carla_stderr("waitForChildToStop() - got wrong pid %i (requested was %i)", int(ret), int(pid)); return false; } } break; } return false; } static inline void waitForChildToStopOrKillIt(pid_t& pid, const uint32_t timeOutMilliseconds) noexcept { CARLA_SAFE_ASSERT_RETURN(pid > 0,); CARLA_SAFE_ASSERT_RETURN(timeOutMilliseconds > 0,); if (! waitForChildToStop(pid, timeOutMilliseconds, true)) { carla_stderr("waitForChildToStopOrKillIt() - process didn't stop, force killing"); if (::kill(pid, SIGKILL) != -1) { // wait for killing to take place waitForChildToStop(pid, timeOutMilliseconds, false); } else { CarlaString error(std::strerror(errno)); carla_stderr("waitForChildToStopOrKillIt() - kill failed: %s", error.buffer()); } } } #endif // ----------------------------------------------------------------------- struct CarlaPipeCommon::PrivateData { // pipes #ifdef CARLA_OS_WIN PROCESS_INFORMATION processInfo; HANDLE pipeRecv; HANDLE pipeSend; HANDLE ovRecv; HANDLE ovSend; #else pid_t pid; int pipeRecv; int pipeSend; #endif // read functions must only be called in context of idlePipe() bool isReading; // the client side is closing down, only waiting for response from server bool clientClosingDown; // other side of pipe has closed bool pipeClosed; // print error only once bool lastMessageFailed; // for debugging bool isServer; // common write lock CarlaMutex writeLock; // temporary buffers for _readline() mutable char tmpBuf[0xffff]; mutable CarlaString tmpStr; PrivateData() noexcept #ifdef CARLA_OS_WIN : processInfo(), #else : pid(-1), #endif pipeRecv(INVALID_PIPE_VALUE), pipeSend(INVALID_PIPE_VALUE), isReading(false), clientClosingDown(false), pipeClosed(true), lastMessageFailed(false), isServer(false), writeLock(), tmpBuf(), tmpStr() { #ifdef CARLA_OS_WIN carla_zeroStruct(processInfo); processInfo.hProcess = INVALID_HANDLE_VALUE; processInfo.hThread = INVALID_HANDLE_VALUE; ovRecv = ::CreateEvent(nullptr, FALSE, FALSE, nullptr); ovSend = ::CreateEvent(nullptr, FALSE, FALSE, nullptr); #endif carla_zeroChars(tmpBuf, 0xffff); } CARLA_DECLARE_NON_COPY_STRUCT(PrivateData) }; // ----------------------------------------------------------------------- CarlaPipeCommon::CarlaPipeCommon() noexcept : pData(new PrivateData()) { carla_debug("CarlaPipeCommon::CarlaPipeCommon()"); } CarlaPipeCommon::~CarlaPipeCommon() /*noexcept*/ { carla_debug("CarlaPipeCommon::~CarlaPipeCommon()"); delete pData; } // ------------------------------------------------------------------- bool CarlaPipeCommon::isPipeRunning() const noexcept { return (pData->pipeRecv != INVALID_PIPE_VALUE && pData->pipeSend != INVALID_PIPE_VALUE && ! pData->pipeClosed); } void CarlaPipeCommon::idlePipe(const bool onlyOnce) noexcept { bool readSucess; for (;;) { readSucess = false; const char* const msg = _readline(true, 0, readSucess); if (! readSucess) break; if (msg == nullptr) continue; pData->isReading = true; if (std::strcmp(msg, "__carla-quit__") == 0) { pData->pipeClosed = true; } else if (! pData->clientClosingDown) { try { msgReceived(msg); } CARLA_SAFE_EXCEPTION("msgReceived"); } pData->isReading = false; delete[] msg; if (onlyOnce || pData->pipeRecv == INVALID_PIPE_VALUE) break; } } // ------------------------------------------------------------------- void CarlaPipeCommon::lockPipe() const noexcept { pData->writeLock.lock(); } bool CarlaPipeCommon::tryLockPipe() const noexcept { return pData->writeLock.tryLock(); } void CarlaPipeCommon::unlockPipe() const noexcept { pData->writeLock.unlock(); } CarlaMutex& CarlaPipeCommon::getPipeLock() const noexcept { return pData->writeLock; } // ------------------------------------------------------------------- bool CarlaPipeCommon::readNextLineAsBool(bool& value) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->isReading, false); if (const char* const msg = _readlineblock(false)) { value = (std::strcmp(msg, "true") == 0); return true; } return false; } bool CarlaPipeCommon::readNextLineAsByte(uint8_t& value) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->isReading, false); if (const char* const msg = _readlineblock(false)) { const int asint = std::atoi(msg); if (asint >= 0 && asint <= 0xFF) { value = static_cast(asint); return true; } } return false; } bool CarlaPipeCommon::readNextLineAsInt(int32_t& value) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->isReading, false); if (const char* const msg = _readlineblock(false)) { value = std::atoi(msg); return true; } return false; } bool CarlaPipeCommon::readNextLineAsUInt(uint32_t& value) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->isReading, false); if (const char* const msg = _readlineblock(false)) { #if (defined(__WORDSIZE) && __WORDSIZE < 64) || (defined(__SIZE_WIDTH__) && __SIZE_WIDTH__ < 64) || \ defined(CARLA_OS_WIN) || defined(CARLA_OS_MAC) const long long aslong = std::atoll(msg); #else const long aslong = std::atol(msg); #endif if (aslong >= 0) { value = static_cast(aslong); return true; } } return false; } bool CarlaPipeCommon::readNextLineAsLong(int64_t& value) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->isReading, false); if (const char* const msg = _readlineblock(false)) { value = std::atol(msg); return true; } return false; } bool CarlaPipeCommon::readNextLineAsULong(uint64_t& value) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->isReading, false); if (const char* const msg = _readlineblock(false)) { const int64_t asint64 = std::atol(msg); if (asint64 >= 0) { value = static_cast(asint64); return true; } } return false; } bool CarlaPipeCommon::readNextLineAsFloat(float& value) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->isReading, false); if (const char* const msg = _readlineblock(false)) { { const CarlaScopedLocale csl; value = static_cast(std::atof(msg)); } return true; } return false; } bool CarlaPipeCommon::readNextLineAsDouble(double& value) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->isReading, false); if (const char* const msg = _readlineblock(false)) { { const CarlaScopedLocale csl; value = std::atof(msg); } return true; } return false; } bool CarlaPipeCommon::readNextLineAsString(const char*& value, const bool allocateString, uint32_t size) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->isReading, false); if (size >= 0xffff) size = 0; if (const char* const msg = _readlineblock(allocateString, static_cast(size))) { value = msg; return true; } return false; } // ------------------------------------------------------------------- // must be locked before calling bool CarlaPipeCommon::writeMessage(const char* const msg) const noexcept { CARLA_SAFE_ASSERT_RETURN(msg != nullptr && msg[0] != '\0', false); if (pData->pipeClosed) return false; const std::size_t size(std::strlen(msg)); CARLA_SAFE_ASSERT_RETURN(size > 0, false); CARLA_SAFE_ASSERT_RETURN(msg[size-1] == '\n', false); return _writeMsgBuffer(msg, size); } bool CarlaPipeCommon::writeMessage(const char* const msg, std::size_t size) const noexcept { CARLA_SAFE_ASSERT_RETURN(msg != nullptr && msg[0] != '\0', false); CARLA_SAFE_ASSERT_RETURN(size > 0, false); CARLA_SAFE_ASSERT_RETURN(msg[size-1] == '\n', false); if (pData->pipeClosed) return false; return _writeMsgBuffer(msg, size); } bool CarlaPipeCommon::writeAndFixMessage(const char* const msg) const noexcept { CARLA_SAFE_ASSERT_RETURN(msg != nullptr, false); if (pData->pipeClosed) return false; const std::size_t size(std::strlen(msg)); char fixedMsg[size+2]; if (size > 0) { std::strcpy(fixedMsg, msg); for (std::size_t i=0; ipipeClosed) return false; return _writeMsgBuffer("\n", 1); } bool CarlaPipeCommon::flushMessages() const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->pipeSend != INVALID_PIPE_VALUE, false); #if defined(CARLA_OS_LINUX) || defined(CARLA_OS_GNU_HURD) # if defined(__GLIBC__) && (__GLIBC__ * 1000 + __GLIBC_MINOR__) >= 2014 // the only call that seems to do something return ::syncfs(pData->pipeSend) == 0; # endif #elif 0 // defined(CARLA_OS_WIN) // FIXME causes issues try { return (::FlushFileBuffers(pData->pipeSend) != FALSE); } CARLA_SAFE_EXCEPTION_RETURN("CarlaPipeCommon::writeMsgBuffer", false); #endif return true; } // ------------------------------------------------------------------- bool CarlaPipeCommon::writeErrorMessage(const char* const error) const noexcept { CARLA_SAFE_ASSERT_RETURN(error != nullptr && error[0] != '\0', false); const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("error\n", 6)) return false; if (! writeAndFixMessage(error)) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeControlMessage(const uint32_t index, const float value, const bool withWriteLock) const noexcept { if (withWriteLock) { const CarlaMutexLocker cml(pData->writeLock); return writeControlMessage(index, value, false); } char tmpBuf[0xff]; tmpBuf[0xfe] = '\0'; if (! _writeMsgBuffer("control\n", 8)) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", index); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; { const CarlaScopedLocale csl; std::snprintf(tmpBuf, 0xfe, "%.12g\n", static_cast(value)); } if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeConfigureMessage(const char* const key, const char* const value) const noexcept { CARLA_SAFE_ASSERT_RETURN(key != nullptr && key[0] != '\0', false); CARLA_SAFE_ASSERT_RETURN(value != nullptr, false); const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("configure\n", 10)) return false; if (! writeAndFixMessage(key)) return false; if (! writeAndFixMessage(value)) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeProgramMessage(const uint32_t index) const noexcept { char tmpBuf[0xff]; tmpBuf[0xfe] = '\0'; const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("program\n", 8)) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", index); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeProgramMessage(const uint8_t channel, const uint32_t bank, const uint32_t program) const noexcept { char tmpBuf[0xff]; tmpBuf[0xfe] = '\0'; const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("program\n", 8)) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", channel); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", bank); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", program); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeMidiProgramMessage(const uint32_t bank, const uint32_t program) const noexcept { char tmpBuf[0xff]; tmpBuf[0xfe] = '\0'; const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("midiprogram\n", 12)) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", bank); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", program); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeReloadProgramsMessage(const int32_t index) const noexcept { char tmpBuf[0xff]; tmpBuf[0xfe] = '\0'; const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("reloadprograms\n", 15)) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", index); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeMidiNoteMessage(const bool onOff, const uint8_t channel, const uint8_t note, const uint8_t velocity) const noexcept { CARLA_SAFE_ASSERT_RETURN(channel < MAX_MIDI_CHANNELS, false); CARLA_SAFE_ASSERT_RETURN(note < MAX_MIDI_NOTE, false); CARLA_SAFE_ASSERT_RETURN(velocity < MAX_MIDI_VALUE, false); char tmpBuf[0xff]; tmpBuf[0xfe] = '\0'; const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("note\n", 5)) return false; std::snprintf(tmpBuf, 0xfe, "%s\n", bool2str(onOff)); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", channel); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", note); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", velocity); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeLv2AtomMessage(const uint32_t index, const LV2_Atom* const atom) const noexcept { CARLA_SAFE_ASSERT_RETURN(atom != nullptr, false); char tmpBuf[0xff]; tmpBuf[0xfe] = '\0'; const uint32_t atomTotalSize(lv2_atom_total_size(atom)); CarlaString base64atom(CarlaString::asBase64(atom, atomTotalSize)); const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("atom\n", 5)) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", index); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", atomTotalSize); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; std::snprintf(tmpBuf, 0xfe, "%lu\n", static_cast(base64atom.length())); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; if (! writeAndFixMessage(base64atom.buffer())) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeLv2ParameterMessage(const char* const uri, const float value, const bool withWriteLock) const noexcept { if (withWriteLock) { const CarlaMutexLocker cml(pData->writeLock); return writeLv2ParameterMessage(uri, value, false); } char tmpBuf[0xff]; tmpBuf[0xfe] = '\0'; if (! _writeMsgBuffer("parameter\n", 10)) return false; if (! writeAndFixMessage(uri)) return false; { const CarlaScopedLocale csl; std::snprintf(tmpBuf, 0xfe, "%.12g\n", static_cast(value)); } if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; flushMessages(); return true; } bool CarlaPipeCommon::writeLv2UridMessage(const uint32_t urid, const char* const uri) const noexcept { CARLA_SAFE_ASSERT_RETURN(urid != 0, false); CARLA_SAFE_ASSERT_RETURN(uri != nullptr && uri[0] != '\0', false); char tmpBuf[0xff]; tmpBuf[0xfe] = '\0'; const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("urid\n", 5)) return false; std::snprintf(tmpBuf, 0xfe, "%i\n", urid); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; std::snprintf(tmpBuf, 0xfe, "%lu\n", static_cast(std::strlen(uri))); if (! _writeMsgBuffer(tmpBuf, std::strlen(tmpBuf))) return false; if (! writeAndFixMessage(uri)) return false; flushMessages(); return true; } // ------------------------------------------------------------------- // internal const char* CarlaPipeCommon::_readline(const bool allocReturn, const uint16_t size, bool& readSucess) const noexcept { CARLA_SAFE_ASSERT_RETURN(pData->pipeRecv != INVALID_PIPE_VALUE, nullptr); char c; char* ptr = pData->tmpBuf; ssize_t ret = -1; bool tooBig = false; pData->tmpStr.clear(); if (size == 0 || size == 1) { for (int i=0; i<0xfffe; ++i) { try { #ifdef CARLA_OS_WIN ret = ReadFileWin32(pData->pipeRecv, pData->ovRecv, &c, 1); #else ret = ::read(pData->pipeRecv, &c, 1); #endif } CARLA_SAFE_EXCEPTION_BREAK("CarlaPipeCommon::readline() - read"); if (ret != 1) break; if (c == '\n') { *ptr = '\0'; break; } if (c == '\r') c = '\n'; *ptr++ = c; if (i+1 == 0xfffe) { i = 0; *ptr = '\0'; tooBig = true; pData->tmpStr += pData->tmpBuf; ptr = pData->tmpBuf; } } } else { uint16_t remaining = size; readSucess = false; for (;;) { try { #ifdef CARLA_OS_WIN ret = ReadFileWin32(pData->pipeRecv, pData->ovRecv, ptr, remaining); #else ret = ::read(pData->pipeRecv, ptr, remaining); #endif } CARLA_SAFE_EXCEPTION_RETURN("CarlaPipeCommon::readline() - read", nullptr); if (ret == -1 && errno == EAGAIN) continue; CARLA_SAFE_ASSERT_INT2_RETURN(ret > 0, ret, remaining, nullptr); CARLA_SAFE_ASSERT_INT2_RETURN(ret <= (ssize_t)remaining, ret, remaining, nullptr); for (ssize_t i=0; i(remaining - ret); if (remaining != 0) continue; readSucess = true; if (allocReturn) { pData->tmpStr = pData->tmpBuf; return pData->tmpStr.releaseBufferPointer(); } return pData->tmpBuf; } } if (ptr != pData->tmpBuf) { *ptr = '\0'; if (! allocReturn && ! tooBig) { readSucess = true; return pData->tmpBuf; } pData->tmpStr += pData->tmpBuf; } else if (pData->tmpStr.isEmpty() && ret != 1) { // some error return nullptr; } readSucess = true; if (! allocReturn && ! tooBig) return pData->tmpBuf; return allocReturn ? pData->tmpStr.releaseBufferPointer() : pData->tmpStr.buffer(); } const char* CarlaPipeCommon::_readlineblock(const bool allocReturn, const uint16_t size, const uint32_t timeOutMilliseconds) const noexcept { const uint32_t timeoutEnd = water::Time::getMillisecondCounter() + timeOutMilliseconds; bool readSucess; for (;;) { readSucess = false; const char* const msg = _readline(allocReturn, size, readSucess); if (readSucess) return msg; if (water::Time::getMillisecondCounter() >= timeoutEnd) break; carla_msleep(5); } static const bool testingForValgrind = std::getenv("CARLA_VALGRIND_TEST") != nullptr; if (testingForValgrind) { const uint32_t timeoutEnd2 = water::Time::getMillisecondCounter() + 1000; for (;;) { readSucess = false; const char* const msg = _readline(allocReturn, size, readSucess); if (readSucess) return msg; if (water::Time::getMillisecondCounter() >= timeoutEnd2) break; carla_msleep(100); } } carla_stderr("readlineblock timed out"); return nullptr; } bool CarlaPipeCommon::_writeMsgBuffer(const char* const msg, const std::size_t size) const noexcept { if (pData->pipeClosed) return false; if (pData->pipeSend == INVALID_PIPE_VALUE) { carla_stderr2("CarlaPipe write error, isServer:%s, message was:\n%s", bool2str(pData->isServer), msg); return false; } ssize_t ret; try { #ifdef CARLA_OS_WIN ret = WriteFileWin32(pData->pipeSend, pData->ovSend, msg, size); #else ret = ::write(pData->pipeSend, msg, size); #endif } CARLA_SAFE_EXCEPTION_RETURN("CarlaPipeCommon::writeMsgBuffer", false); #ifdef CARLA_OS_WIN if (ret == -2) { pData->pipeClosed = true; return false; } #endif if (ret == static_cast(size)) { if (pData->lastMessageFailed) pData->lastMessageFailed = false; return true; } if (! pData->lastMessageFailed) { pData->lastMessageFailed = true; fprintf(stderr, "CarlaPipeCommon::_writeMsgBuffer(..., " P_SIZE ") - failed with " P_SSIZE " (%s), message was:\n%s", size, ret, bool2str(pData->isServer), msg); } return false; } // ----------------------------------------------------------------------- CarlaPipeServer::CarlaPipeServer() noexcept : CarlaPipeCommon() { carla_debug("CarlaPipeServer::CarlaPipeServer()"); pData->isServer = true; } CarlaPipeServer::~CarlaPipeServer() /*noexcept*/ { carla_debug("CarlaPipeServer::~CarlaPipeServer()"); stopPipeServer(5*1000); } uintptr_t CarlaPipeServer::getPID() const noexcept { #ifndef CARLA_OS_WIN return static_cast(pData->pid); #else return 0; #endif } // -------------------------------------------------------------------------------------------------------------------- bool CarlaPipeServer::startPipeServer(const char* const filename, const char* const arg1, const char* const arg2, const int size) noexcept { CARLA_SAFE_ASSERT_RETURN(pData->pipeRecv == INVALID_PIPE_VALUE, false); CARLA_SAFE_ASSERT_RETURN(pData->pipeSend == INVALID_PIPE_VALUE, false); #ifdef CARLA_OS_WIN CARLA_SAFE_ASSERT_RETURN(pData->processInfo.hThread == INVALID_HANDLE_VALUE, false); CARLA_SAFE_ASSERT_RETURN(pData->processInfo.hProcess == INVALID_HANDLE_VALUE, false); #else CARLA_SAFE_ASSERT_RETURN(pData->pid == -1, false); #endif CARLA_SAFE_ASSERT_RETURN(filename != nullptr && filename[0] != '\0', false); CARLA_SAFE_ASSERT_RETURN(arg1 != nullptr, false); CARLA_SAFE_ASSERT_RETURN(arg2 != nullptr, false); carla_debug("CarlaPipeServer::startPipeServer(\"%s\", \"%s\", \"%s\")", filename, arg1, arg2); char pipeRecvServerStr[100+1]; char pipeSendServerStr[100+1]; char pipeRecvClientStr[100+1]; char pipeSendClientStr[100+1]; pipeRecvServerStr[100] = '\0'; pipeSendServerStr[100] = '\0'; pipeRecvClientStr[100] = '\0'; pipeSendClientStr[100] = '\0'; const CarlaMutexLocker cml(pData->writeLock); //----------------------------------------------------------------------------------------------------------------- // create pipes #ifdef CARLA_OS_WIN HANDLE pipe1, pipe2; std::srand(static_cast(std::time(nullptr))); static ulong sCounter = 0; ++sCounter; const int randint = std::rand(); std::snprintf(pipeRecvServerStr, 100, "\\\\.\\pipe\\carla-pipe1-%i-%li", randint, sCounter); std::snprintf(pipeSendServerStr, 100, "\\\\.\\pipe\\carla-pipe2-%i-%li", randint, sCounter); std::snprintf(pipeRecvClientStr, 100, "ignored"); std::snprintf(pipeSendClientStr, 100, "ignored"); SECURITY_ATTRIBUTES sa; carla_zeroStruct(sa); sa.nLength = sizeof(sa); sa.bInheritHandle = TRUE; pipe1 = ::CreateNamedPipeA(pipeRecvServerStr, PIPE_ACCESS_DUPLEX|FILE_FLAG_FIRST_PIPE_INSTANCE|FILE_FLAG_OVERLAPPED, PIPE_TYPE_BYTE|PIPE_READMODE_BYTE, 1, size, size, 0, &sa); if (pipe1 == INVALID_HANDLE_VALUE) { fail("pipe creation failed"); return false; } pipe2 = ::CreateNamedPipeA(pipeSendServerStr, PIPE_ACCESS_DUPLEX|FILE_FLAG_FIRST_PIPE_INSTANCE|FILE_FLAG_OVERLAPPED, PIPE_TYPE_BYTE|PIPE_READMODE_BYTE, 1, size, size, 0, &sa); if (pipe2 == INVALID_HANDLE_VALUE) { try { ::CloseHandle(pipe1); } CARLA_SAFE_EXCEPTION("CloseHandle(pipe1)"); fail("pipe creation failed"); return false; } const HANDLE pipeRecvClient = pipe2; const HANDLE pipeSendClient = pipe1; #else int pipe1[2]; // read by server, written by client int pipe2[2]; // read by client, written by server if (::pipe(pipe1) != 0) { fail("pipe1 creation failed"); return false; } if (::pipe(pipe2) != 0) { try { ::close(pipe1[0]); } CARLA_SAFE_EXCEPTION("close(pipe1[0])"); try { ::close(pipe1[1]); } CARLA_SAFE_EXCEPTION("close(pipe1[1])"); fail("pipe2 creation failed"); return false; } /* */ int pipeRecvServer = pipe1[0]; /* */ int pipeSendServer = pipe2[1]; const int pipeRecvClient = pipe2[0]; const int pipeSendClient = pipe1[1]; std::snprintf(pipeRecvServerStr, 100, "%i", pipeRecvServer); std::snprintf(pipeSendServerStr, 100, "%i", pipeSendServer); std::snprintf(pipeRecvClientStr, 100, "%i", pipeRecvClient); std::snprintf(pipeSendClientStr, 100, "%i", pipeSendClient); //----------------------------------------------------------------------------------------------------------------- // set size, non-fatal # ifdef CARLA_OS_LINUX try { ::fcntl(pipeRecvClient, F_SETPIPE_SZ, size); } CARLA_SAFE_EXCEPTION("Set pipe size"); try { ::fcntl(pipeRecvServer, F_SETPIPE_SZ, size); } CARLA_SAFE_EXCEPTION("Set pipe size"); # endif //----------------------------------------------------------------------------------------------------------------- // set non-block int ret; try { ret = ::fcntl(pipeRecvClient, F_SETFL, ::fcntl(pipeRecvClient, F_GETFL) | O_NONBLOCK); } catch (...) { ret = -1; fail("failed to set pipe as non-block"); } if (ret == 0) { try { ret = ::fcntl(pipeRecvServer, F_SETFL, ::fcntl(pipeRecvServer, F_GETFL) | O_NONBLOCK); } catch (...) { ret = -1; fail("failed to set pipe as non-block"); } } if (ret < 0) { try { ::close(pipe1[0]); } CARLA_SAFE_EXCEPTION("close(pipe1[0])"); try { ::close(pipe1[1]); } CARLA_SAFE_EXCEPTION("close(pipe1[1])"); try { ::close(pipe2[0]); } CARLA_SAFE_EXCEPTION("close(pipe2[0])"); try { ::close(pipe2[1]); } CARLA_SAFE_EXCEPTION("close(pipe2[1])"); return false; } #endif //----------------------------------------------------------------------------------------------------------------- // set arguments const char* argv[8]; //----------------------------------------------------------------------------------------------------------------- // argv[0] => filename argv[0] = filename; //----------------------------------------------------------------------------------------------------------------- // argv[1-2] => args argv[1] = arg1; argv[2] = arg2; //----------------------------------------------------------------------------------------------------------------- // argv[3-6] => pipes argv[3] = pipeRecvServerStr; argv[4] = pipeSendServerStr; argv[5] = pipeRecvClientStr; argv[6] = pipeSendClientStr; //----------------------------------------------------------------------------------------------------------------- // argv[7] => null argv[7] = nullptr; //----------------------------------------------------------------------------------------------------------------- // start process #ifdef CARLA_OS_WIN if (! startProcess(argv, &pData->processInfo)) { carla_zeroStruct(pData->processInfo); pData->processInfo.hProcess = INVALID_HANDLE_VALUE; pData->processInfo.hThread = INVALID_HANDLE_VALUE; try { ::CloseHandle(pipe1); } CARLA_SAFE_EXCEPTION("CloseHandle(pipe1)"); try { ::CloseHandle(pipe2); } CARLA_SAFE_EXCEPTION("CloseHandle(pipe2)"); return false; } // just to make sure CARLA_SAFE_ASSERT(pData->processInfo.hThread != INVALID_HANDLE_VALUE); CARLA_SAFE_ASSERT(pData->processInfo.hProcess != INVALID_HANDLE_VALUE); #else if (! startProcess(argv, pData->pid)) { pData->pid = -1; try { ::close(pipe1[0]); } CARLA_SAFE_EXCEPTION("close(pipe1[0])"); try { ::close(pipe1[1]); } CARLA_SAFE_EXCEPTION("close(pipe1[1])"); try { ::close(pipe2[0]); } CARLA_SAFE_EXCEPTION("close(pipe2[0])"); try { ::close(pipe2[1]); } CARLA_SAFE_EXCEPTION("close(pipe2[1])"); fail("startProcess() failed"); return false; } //----------------------------------------------------------------------------------------------------------------- // close duplicated handles used by the client try { ::close(pipeRecvServer); } CARLA_SAFE_EXCEPTION("close(pipeRecvServer)"); try { ::close(pipeSendServer); } CARLA_SAFE_EXCEPTION("close(pipeSendServer)"); #endif //----------------------------------------------------------------------------------------------------------------- // wait for client to say something #ifdef CARLA_OS_WIN void* const ovRecv = pData->ovRecv; void* const process = pData->processInfo.hProcess; #else void* const ovRecv = nullptr; void* const process = nullptr; #endif if (waitForClientFirstMessage(pipeRecvClient, ovRecv, process, 10*1000 /* 10 secs */)) { pData->pipeRecv = pipeRecvClient; pData->pipeSend = pipeSendClient; pData->pipeClosed = false; carla_stdout("ALL OK!"); return true; } //----------------------------------------------------------------------------------------------------------------- // failed to set non-block or get first child message, cannot continue #ifdef CARLA_OS_WIN if (::TerminateProcess(pData->processInfo.hProcess, 9) != FALSE) { // wait for process to stop waitForProcessToStop(pData->processInfo.hProcess, 2*1000, false); } // clear pData->processInfo try { ::CloseHandle(pData->processInfo.hThread); } CARLA_SAFE_EXCEPTION("CloseHandle(pData->processInfo.hThread)"); try { ::CloseHandle(pData->processInfo.hProcess); } CARLA_SAFE_EXCEPTION("CloseHandle(pData->processInfo.hProcess)"); carla_zeroStruct(pData->processInfo); pData->processInfo.hProcess = INVALID_HANDLE_VALUE; pData->processInfo.hThread = INVALID_HANDLE_VALUE; #else if (::kill(pData->pid, SIGKILL) != -1) { // wait for killing to take place waitForChildToStop(pData->pid, 2*1000, false); } pData->pid = -1; #endif //----------------------------------------------------------------------------------------------------------------- // close pipes #ifdef CARLA_OS_WIN try { ::CloseHandle(pipeRecvClient); } CARLA_SAFE_EXCEPTION("CloseHandle(pipeRecvClient)"); try { ::CloseHandle(pipeSendClient); } CARLA_SAFE_EXCEPTION("CloseHandle(pipeSendClient)"); #else try { ::close (pipeRecvClient); } CARLA_SAFE_EXCEPTION("close(pipeRecvClient)"); try { ::close (pipeSendClient); } CARLA_SAFE_EXCEPTION("close(pipeSendClient)"); #endif return false; // maybe unused (void)size; (void)ovRecv; (void)process; } void CarlaPipeServer::stopPipeServer(const uint32_t timeOutMilliseconds) noexcept { carla_debug("CarlaPipeServer::stopPipeServer(%i)", timeOutMilliseconds); #ifdef CARLA_OS_WIN if (pData->processInfo.hThread != INVALID_HANDLE_VALUE || pData->processInfo.hProcess != INVALID_HANDLE_VALUE) { const CarlaMutexLocker cml(pData->writeLock); if (pData->pipeSend != INVALID_PIPE_VALUE && ! pData->pipeClosed) { if (_writeMsgBuffer("__carla-quit__\n", 15)) flushMessages(); } waitForProcessToStopOrKillIt(pData->processInfo.hProcess, timeOutMilliseconds); try { ::CloseHandle(pData->processInfo.hThread); } CARLA_SAFE_EXCEPTION("CloseHandle(pData->processInfo.hThread)"); try { ::CloseHandle(pData->processInfo.hProcess); } CARLA_SAFE_EXCEPTION("CloseHandle(pData->processInfo.hProcess)"); carla_zeroStruct(pData->processInfo); pData->processInfo.hProcess = INVALID_HANDLE_VALUE; pData->processInfo.hThread = INVALID_HANDLE_VALUE; } #else if (pData->pid != -1) { const CarlaMutexLocker cml(pData->writeLock); if (pData->pipeSend != INVALID_PIPE_VALUE && ! pData->pipeClosed) { if (_writeMsgBuffer("__carla-quit__\n", 15)) flushMessages(); } waitForChildToStopOrKillIt(pData->pid, timeOutMilliseconds); pData->pid = -1; } #endif closePipeServer(); } void CarlaPipeServer::closePipeServer() noexcept { carla_debug("CarlaPipeServer::closePipeServer()"); pData->pipeClosed = true; const CarlaMutexLocker cml(pData->writeLock); if (pData->pipeRecv != INVALID_PIPE_VALUE) { #ifdef CARLA_OS_WIN DisconnectNamedPipe(pData->pipeRecv); try { ::CloseHandle(pData->pipeRecv); } CARLA_SAFE_EXCEPTION("CloseHandle(pData->pipeRecv)"); #else try { ::close (pData->pipeRecv); } CARLA_SAFE_EXCEPTION("close(pData->pipeRecv)"); #endif pData->pipeRecv = INVALID_PIPE_VALUE; } if (pData->pipeSend != INVALID_PIPE_VALUE) { #ifdef CARLA_OS_WIN DisconnectNamedPipe(pData->pipeSend); try { ::CloseHandle(pData->pipeSend); } CARLA_SAFE_EXCEPTION("CloseHandle(pData->pipeSend)"); #else try { ::close (pData->pipeSend); } CARLA_SAFE_EXCEPTION("close(pData->pipeSend)"); #endif pData->pipeSend = INVALID_PIPE_VALUE; } } void CarlaPipeServer::writeShowMessage() const noexcept { const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("show\n", 5)) return; flushMessages(); } void CarlaPipeServer::writeFocusMessage() const noexcept { const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("focus\n", 6)) return; flushMessages(); } void CarlaPipeServer::writeHideMessage() const noexcept { const CarlaMutexLocker cml(pData->writeLock); if (! _writeMsgBuffer("show\n", 5)) return; flushMessages(); } // ----------------------------------------------------------------------- CarlaPipeClient::CarlaPipeClient() noexcept : CarlaPipeCommon() { carla_debug("CarlaPipeClient::CarlaPipeClient()"); } CarlaPipeClient::~CarlaPipeClient() /*noexcept*/ { carla_debug("CarlaPipeClient::~CarlaPipeClient()"); closePipeClient(); } bool CarlaPipeClient::initPipeClient(const char* argv[]) noexcept { CARLA_SAFE_ASSERT_RETURN(pData->pipeRecv == INVALID_PIPE_VALUE, false); CARLA_SAFE_ASSERT_RETURN(pData->pipeSend == INVALID_PIPE_VALUE, false); carla_debug("CarlaPipeClient::initPipeClient(%p)", argv); const CarlaMutexLocker cml(pData->writeLock); //---------------------------------------------------------------- // read arguments #ifdef CARLA_OS_WIN const char* const pipeRecvServerStr = argv[3]; const char* const pipeSendServerStr = argv[4]; HANDLE pipeRecvServer = ::CreateFileA(pipeRecvServerStr, GENERIC_READ, 0x0, nullptr, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, nullptr); HANDLE pipeSendServer = ::CreateFileA(pipeSendServerStr, GENERIC_WRITE, 0x0, nullptr, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, nullptr); CARLA_SAFE_ASSERT_RETURN(pipeRecvServer != INVALID_HANDLE_VALUE, false); CARLA_SAFE_ASSERT_RETURN(pipeSendServer != INVALID_HANDLE_VALUE, false); #else const int pipeRecvServer = std::atoi(argv[3]); const int pipeSendServer = std::atoi(argv[4]); /* */ int pipeRecvClient = std::atoi(argv[5]); /* */ int pipeSendClient = std::atoi(argv[6]); CARLA_SAFE_ASSERT_RETURN(pipeRecvServer > 0, false); CARLA_SAFE_ASSERT_RETURN(pipeSendServer > 0, false); CARLA_SAFE_ASSERT_RETURN(pipeRecvClient > 0, false); CARLA_SAFE_ASSERT_RETURN(pipeSendClient > 0, false); //---------------------------------------------------------------- // close duplicated handles used by the client try { ::close(pipeRecvClient); } CARLA_SAFE_EXCEPTION("close(pipeRecvClient)"); try { ::close(pipeSendClient); } CARLA_SAFE_EXCEPTION("close(pipeSendClient)"); //---------------------------------------------------------------- // kill ourselves if parent dies carla_terminateProcessOnParentExit(false); #endif //---------------------------------------------------------------- // done pData->pipeRecv = pipeRecvServer; pData->pipeSend = pipeSendServer; pData->pipeClosed = false; pData->clientClosingDown = false; if (writeMessage("\n", 1)) flushMessages(); return true; } void CarlaPipeClient::closePipeClient() noexcept { carla_debug("CarlaPipeClient::closePipeClient()"); pData->pipeClosed = true; const CarlaMutexLocker cml(pData->writeLock); if (pData->pipeRecv != INVALID_PIPE_VALUE) { #ifdef CARLA_OS_WIN try { ::CloseHandle(pData->pipeRecv); } CARLA_SAFE_EXCEPTION("CloseHandle(pData->pipeRecv)"); #else try { ::close (pData->pipeRecv); } CARLA_SAFE_EXCEPTION("close(pData->pipeRecv)"); #endif pData->pipeRecv = INVALID_PIPE_VALUE; } if (pData->pipeSend != INVALID_PIPE_VALUE) { #ifdef CARLA_OS_WIN try { ::CloseHandle(pData->pipeSend); } CARLA_SAFE_EXCEPTION("CloseHandle(pData->pipeSend)"); #else try { ::close (pData->pipeSend); } CARLA_SAFE_EXCEPTION("close(pData->pipeSend)"); #endif pData->pipeSend = INVALID_PIPE_VALUE; } } void CarlaPipeClient::writeExitingMessageAndWait() noexcept { { const CarlaMutexLocker cml(pData->writeLock); if (_writeMsgBuffer("exiting\n", 8)) flushMessages(); } // NOTE: no more messages are handled after this point pData->clientClosingDown = true; for (int i=0; i < 100 && ! pData->pipeClosed; ++i) { carla_msleep(50); idlePipe(true); } if (! pData->pipeClosed) carla_stderr2("writeExitingMessageAndWait pipe is still running!"); } // ----------------------------------------------------------------------- #undef INVALID_PIPE_VALUE