/* ----------------------------------------------------------------------------- * * (c) The GHC Team, 1998-2002 * * Main function for a standalone Haskell program. * * ---------------------------------------------------------------------------*/ // PAPI uses caddr_t, which is not POSIX #ifndef USE_PAPI #include "PosixSource.h" #endif #include "Rts.h" #include "RtsAPI.h" #include "HsFFI.h" #include "sm/Storage.h" #include "RtsFlags.h" #include "RtsUtils.h" #include "Prelude.h" #include "Schedule.h" /* initScheduler */ #include "Stats.h" /* initStats */ #include "STM.h" /* initSTM */ #include "RtsSignals.h" #include "Weak.h" #include "Ticky.h" #include "StgRun.h" #include "Prelude.h" /* fixupRTStoPreludeRefs */ #include "ThreadLabels.h" #include "sm/BlockAlloc.h" #include "Trace.h" #include "Stable.h" #include "Hash.h" #include "Profiling.h" #include "Timer.h" #include "Globals.h" #include "FileLock.h" #include "LinkerInternals.h" #if defined(PROFILING) # include "ProfHeap.h" # include "RetainerProfile.h" #endif #if defined(mingw32_HOST_OS) && !defined(THREADED_RTS) #include "win32/AsyncIO.h" #endif #if !defined(mingw32_HOST_OS) #include "posix/TTY.h" #endif #ifdef HAVE_UNISTD_H #include #endif #ifdef HAVE_LOCALE_H #include #endif #if USE_PAPI #include "Papi.h" #endif // Count of how many outstanding hs_init()s there have been. static int hs_init_count = 0; static void flushStdHandles(void); const RtsConfig defaultRtsConfig = { .rts_opts_enabled = RtsOptsSafeOnly, .rts_opts = NULL, .rts_hs_main = rtsFalse }; /* ----------------------------------------------------------------------------- Initialise floating point unit on x86 (currently disabled; See Note [x86 Floating point precision] in compiler/nativeGen/X86/Instr.hs) -------------------------------------------------------------------------- */ #define X86_INIT_FPU 0 #if X86_INIT_FPU static void x86_init_fpu ( void ) { __volatile unsigned short int fpu_cw; // Grab the control word __asm __volatile ("fnstcw %0" : "=m" (fpu_cw)); #if 0 printf("fpu_cw: %x\n", fpu_cw); #endif // Set bits 8-9 to 10 (64-bit precision). fpu_cw = (fpu_cw & 0xfcff) | 0x0200; // Store the new control word back __asm __volatile ("fldcw %0" : : "m" (fpu_cw)); } #endif /* ----------------------------------------------------------------------------- Starting up the RTS -------------------------------------------------------------------------- */ void hs_init(int *argc, char **argv[]) { hs_init_ghc(argc, argv, defaultRtsConfig); } void hs_init_with_rtsopts(int *argc, char **argv[]) { RtsConfig rts_opts = defaultRtsConfig; /* by value */ rts_opts.rts_opts_enabled = RtsOptsAll; hs_init_ghc(argc, argv, rts_opts); } void hs_init_ghc(int *argc, char **argv[], RtsConfig rts_config) { hs_init_count++; if (hs_init_count > 1) { // second and subsequent inits are ignored return; } setlocale(LC_CTYPE,""); /* Initialise the stats department, phase 0 */ initStats0(); /* Initialize system timer before starting to collect stats */ initializeTimer(); /* Next we do is grab the start time...just in case we're * collecting timing statistics. */ stat_startInit(); /* Set the RTS flags to default values. */ initRtsFlagsDefaults(); /* Call the user hook to reset defaults, if present */ defaultsHook(); /* Parse the flags, separating the RTS flags from the programs args */ if (argc == NULL || argv == NULL) { // Use a default for argc & argv if either is not supplied int my_argc = 1; char *my_argv[] = { "", NULL }; setFullProgArgv(my_argc,my_argv); setupRtsFlags(&my_argc, my_argv, rts_config.rts_opts_enabled, rts_config.rts_opts, rts_config.rts_hs_main); } else { setFullProgArgv(*argc,*argv); setupRtsFlags(argc, *argv, rts_config.rts_opts_enabled, rts_config.rts_opts, rts_config.rts_hs_main); } /* Initialise the stats department, phase 1 */ initStats1(); #ifdef USE_PAPI papi_init(); #endif /* initTracing must be after setupRtsFlags() */ #ifdef TRACING initTracing(); #endif /* Trace the startup event */ traceEventStartup(); /* initialise scheduler data structures (needs to be done before * initStorage()). */ initScheduler(); /* Trace some basic information about the process */ traceWallClockTime(); traceOSProcessInfo(); /* initialize the storage manager */ initStorage(); /* initialise the stable pointer table */ initStableTables(); /* Add some GC roots for things in the base package that the RTS * knows about. We don't know whether these turn out to be CAFs * or refer to CAFs, but we have to assume that they might. */ getStablePtr((StgPtr)runIO_closure); getStablePtr((StgPtr)runNonIO_closure); getStablePtr((StgPtr)flushStdHandles_closure); getStablePtr((StgPtr)runFinalizerBatch_closure); getStablePtr((StgPtr)stackOverflow_closure); getStablePtr((StgPtr)heapOverflow_closure); getStablePtr((StgPtr)unpackCString_closure); getStablePtr((StgPtr)blockedIndefinitelyOnMVar_closure); getStablePtr((StgPtr)nonTermination_closure); getStablePtr((StgPtr)blockedIndefinitelyOnSTM_closure); getStablePtr((StgPtr)nestedAtomically_closure); getStablePtr((StgPtr)runSparks_closure); getStablePtr((StgPtr)ensureIOManagerIsRunning_closure); getStablePtr((StgPtr)ioManagerCapabilitiesChanged_closure); #ifndef mingw32_HOST_OS getStablePtr((StgPtr)blockedOnBadFD_closure); getStablePtr((StgPtr)runHandlers_closure); #endif /* initialise the shared Typeable store */ initGlobalStore(); /* initialise file locking, if necessary */ initFileLocking(); #if defined(DEBUG) /* initialise thread label table (tso->char*) */ initThreadLabelTable(); #endif initProfiling1(); /* start the virtual timer 'subsystem'. */ initTimer(); startTimer(); #if defined(RTS_USER_SIGNALS) if (RtsFlags.MiscFlags.install_signal_handlers) { /* Initialise the user signal handler set */ initUserSignals(); /* Set up handler to run on SIGINT, etc. */ initDefaultHandlers(); } #endif #if defined(mingw32_HOST_OS) && !defined(THREADED_RTS) startupAsyncIO(); #endif #if X86_INIT_FPU x86_init_fpu(); #endif startupHpc(); // This must be done after module initialisation. // ToDo: make this work in the presence of multiple hs_add_root()s. initProfiling2(); // ditto. #if defined(THREADED_RTS) ioManagerStart(); #endif /* Record initialization times */ stat_endInit(); } // Compatibility interface void startupHaskell(int argc, char *argv[], void (*init_root)(void) STG_UNUSED) { hs_init(&argc, &argv); } /* ----------------------------------------------------------------------------- hs_add_root: backwards compatibility. (see #3252) -------------------------------------------------------------------------- */ void hs_add_root(void (*init_root)(void) STG_UNUSED) { /* nothing */ } /* ---------------------------------------------------------------------------- * Shutting down the RTS * * The wait_foreign parameter means: * True ==> wait for any threads doing foreign calls now. * False ==> threads doing foreign calls may return in the * future, but will immediately block on a mutex. * (capability->lock). * * If this RTS is a DLL that we're about to unload, then you want * safe=True, otherwise the thread might return to code that has been * unloaded. If this is a standalone program that is about to exit, * then you can get away with safe=False, which is better because we * won't hang on exit if there is a blocked foreign call outstanding. * ------------------------------------------------------------------------- */ static void hs_exit_(rtsBool wait_foreign) { nat g, i; if (hs_init_count <= 0) { errorBelch("warning: too many hs_exit()s"); return; } hs_init_count--; if (hs_init_count > 0) { // ignore until it's the last one return; } /* start timing the shutdown */ stat_startExit(); OnExitHook(); flushStdHandles(); // sanity check #if defined(DEBUG) checkFPUStack(); #endif #if defined(THREADED_RTS) ioManagerDie(); #endif /* stop all running tasks */ exitScheduler(wait_foreign); /* run C finalizers for all active weak pointers */ for (i = 0; i < n_capabilities; i++) { runAllCFinalizers(capabilities[i]->weak_ptr_list_hd); } for (g = 0; g < RtsFlags.GcFlags.generations; g++) { runAllCFinalizers(generations[g].weak_ptr_list); } #if defined(RTS_USER_SIGNALS) if (RtsFlags.MiscFlags.install_signal_handlers) { freeSignalHandlers(); } #endif /* stop the ticker */ stopTimer(); exitTimer(wait_foreign); // set the terminal settings back to what they were #if !defined(mingw32_HOST_OS) resetTerminalSettings(); #endif #if defined(RTS_USER_SIGNALS) if (RtsFlags.MiscFlags.install_signal_handlers) { // uninstall signal handlers resetDefaultHandlers(); } #endif /* stop timing the shutdown, we're about to print stats */ stat_endExit(); /* shutdown the hpc support (if needed) */ exitHpc(); // clean up things from the storage manager's point of view. // also outputs the stats (+RTS -s) info. exitStorage(); /* free the tasks */ freeScheduler(); /* free shared Typeable store */ exitGlobalStore(); /* free linker data */ exitLinker(); /* free file locking tables, if necessary */ freeFileLocking(); /* free the stable pointer table */ exitStableTables(); #if defined(DEBUG) /* free the thread label table */ freeThreadLabelTable(); #endif #if defined(PROFILING) reportCCSProfiling(); #endif endProfiling(); freeProfiling(); #ifdef PROFILING // Originally, this was in report_ccs_profiling(). Now, retainer // profiling might tack some extra stuff on to the end of this file // during endProfiling(). if (prof_file != NULL) fclose(prof_file); #endif #ifdef TRACING endTracing(); freeTracing(); #endif #if defined(TICKY_TICKY) if (RtsFlags.TickyFlags.showTickyStats) PrintTickyInfo(); #endif #if defined(mingw32_HOST_OS) && !defined(THREADED_RTS) shutdownAsyncIO(wait_foreign); #endif /* free hash table storage */ exitHashTable(); // Finally, free all our storage. However, we only free the heap // memory if we have waited for foreign calls to complete; // otherwise a foreign call in progress may still be referencing // heap memory (e.g. by being passed a ByteArray#). freeStorage(wait_foreign); // Free the various argvs freeRtsArgs(); } // Flush stdout and stderr. We do this during shutdown so that it // happens even when the RTS is being used as a library, without a // main (#5594) static void flushStdHandles(void) { Capability *cap; cap = rts_lock(); rts_evalIO(&cap, flushStdHandles_closure, NULL); rts_unlock(cap); } // The real hs_exit(): void hs_exit(void) { hs_exit_(rtsTrue); // be safe; this might be a DLL } // Compatibility interfaces void shutdownHaskell(void) { hs_exit(); } void shutdownHaskellAndExit(int n, int fastExit) { if (!fastExit) { // even if hs_init_count > 1, we still want to shut down the RTS // and exit immediately (see #5402) hs_init_count = 1; // we're about to exit(), no need to wait for foreign calls to return. hs_exit_(rtsFalse); } stg_exit(n); } #ifndef mingw32_HOST_OS static void exitBySignal(int sig) GNUC3_ATTRIBUTE(__noreturn__); void shutdownHaskellAndSignal(int sig, int fastExit) { if (!fastExit) { hs_exit_(rtsFalse); } exitBySignal(sig); } void exitBySignal(int sig) { // We're trying to kill ourselves with a given signal. // That's easier said that done because: // - signals can be ignored have handlers set for them // - signals can be masked // - signals default action can do things other than terminate: // + can do nothing // + can do weirder things: stop/continue the process struct sigaction dfl; sigset_t sigset; // So first of all, we reset the signal to use the default action. (void)sigemptyset(&dfl.sa_mask); dfl.sa_flags = 0; dfl.sa_handler = SIG_DFL; (void)sigaction(sig, &dfl, NULL); // Then we unblock the signal so we can deliver it to ourselves sigemptyset(&sigset); sigaddset(&sigset, sig); sigprocmask(SIG_UNBLOCK, &sigset, NULL); switch (sig) { case SIGSTOP: case SIGTSTP: case SIGTTIN: case SIGTTOU: case SIGCONT: // These signals stop (or continue) the process, so are no good for // exiting. exit(0xff); default: kill(getpid(),sig); // But it's possible the signal is one where the default action is to // ignore, in which case we'll still be alive... so just exit. exit(0xff); } } #endif /* * called from STG-land to exit the program */ void (*exitFn)(int) = 0; void stg_exit(int n) { if (exitFn) (*exitFn)(n); exit(n); }