// Berkeley Open Infrastructure for Network Computing // http://boinc.berkeley.edu // Copyright (C) 2005 University of California // // This 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; // either version 2.1 of the License, or (at your option) any later version. // // This software 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. // // To view the GNU Lesser General Public License visit // http://www.gnu.org/copyleft/lesser.html // or write to the Free Software Foundation, Inc., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA #if defined(_WIN32) && !defined(__STDWX_H__) && !defined(_BOINC_WIN_) && !defined(_AFX_STDAFX_H_) #include "boinc_win.h" #endif #ifdef _WIN32 #include "version.h" #else #include "config.h" #include #include #include #include #include #include #include #include #include #include #ifndef __EMX__ #include #endif using namespace std; #endif #include "diagnostics.h" #include "parse.h" #include "shmem.h" #include "util.h" #include "str_util.h" #include "filesys.h" #include "mem_usage.h" #include "error_numbers.h" #include "common_defs.h" #include "app_ipc.h" #include "boinc_api.h" #ifdef __APPLE__ #include "mac_backtrace.h" #define GETRUSAGE_IN_TIMER_THREAD // call getrusage() in the timer thread, // rather than in the worker thread's signal handler // (which can cause crashes on Mac) // If you want, you can set this for Linux too: // CPPFLAGS=-DGETRUSAGE_IN_TIMER_THREAD #endif // Implementation notes: // 1) Thread structure, Unix: // getting CPU time and suspend/resume have to be done // in the worker thread, so we use a SIGALRM signal handler. // However, many library functions and system calls // are not "asynch signal safe": see, e.g. // http://www.opengroup.org/onlinepubs/009695399/functions/xsh_chap02_04.html#tag_02_04_03 // (e.g. sprintf() in a signal handler hangs Mac OS X) // so we do as little as possible in the signal handler, // and do the rest in a separate "timer thread". // 2) All variables that are accessed by two threads (i.e. worker and timer) // MUST be declared volatile. // 3) For compatibility with C, we use int instead of bool various places // Terminology: // The processing of a result can be divided // into multiple "episodes" (executions of the app), // each of which resumes from the checkpointed state of the previous episode. // Unless otherwise noted, "CPU time" refers to the sum over all episodes // (not counting the part after the last checkpoint in an episode). const char* api_version="API_VERSION_"PACKAGE_VERSION; static APP_INIT_DATA aid; static FILE_LOCK file_lock; APP_CLIENT_SHM* app_client_shm = 0; static volatile int time_until_checkpoint; // time until enable checkpoint // time until report fraction done to core client static volatile double fraction_done; static volatile double last_checkpoint_cpu_time; static volatile bool ready_to_checkpoint = false; static volatile int in_critical_section=0; static volatile double last_wu_cpu_time; static volatile bool standalone = false; static volatile double initial_wu_cpu_time; static volatile bool have_new_trickle_up = false; static volatile bool have_trickle_down = true; // on first call, scan slot dir for msgs static volatile int heartbeat_giveup_time; // interrupt count value at which to give up on core client #ifdef _WIN32 static volatile int nrunning_ticks = 0; #endif static volatile int interrupt_count = 0; // number of timer interrupts // used to measure elapsed time in a way that's // not affected by user changing system clock, // and doesn't have big jump after hibernation static double fpops_per_cpu_sec = 0; static double fpops_cumulative = 0; static double intops_per_cpu_sec = 0; static double intops_cumulative = 0; static int want_network = 0; static int have_network = 1; bool g_sleep = false; // simulate unresponsive app by setting to true (debugging) static FUNC_PTR timer_callback = 0; #define TIMER_PERIOD 0.1 // period of worker-thread timer interrupts. // Determines rate of handlling messages from client. #define TIMERS_PER_SEC 10 // This determines the resolution of fraction done and CPU time reporting // to the core client, and of checkpoint enabling. // It doesn't influence graphics, so 1 sec is enough. #define HEARTBEAT_GIVEUP_COUNT ((int)(30/TIMER_PERIOD)) // quit if no heartbeat from core in this #interrupts #define LOCKFILE_TIMEOUT_PERIOD 35 // quit if we cannot aquire slot lock file in this #secs after startup #ifdef _WIN32 static HANDLE hSharedMem; HANDLE worker_thread_handle; // used to suspend worker thread, and to measure its CPU time #else static volatile bool worker_thread_exit_flag = false; static volatile int worker_thread_exit_status; // the above are used by the timer thread to tell // the worker thread to exit static pthread_t timer_thread_handle; #ifndef GETRUSAGE_IN_TIMER_THREAD static struct rusage worker_thread_ru; #endif #endif static BOINC_OPTIONS options; static volatile BOINC_STATUS boinc_status; // vars related to intermediate file upload struct UPLOAD_FILE_STATUS { std::string name; int status; }; static bool have_new_upload_file; static std::vector upload_file_status; static void graphics_cleanup(); //static int suspend_activities(); //static int resume_activities(); //static void boinc_exit(int); static void block_sigalrm(); static int start_worker_signals(); static int setup_shared_mem() { if (standalone) { fprintf(stderr, "Standalone mode, so not using shared memory.\n"); return 0; } app_client_shm = new APP_CLIENT_SHM; #ifdef _WIN32 char buf[256]; sprintf(buf, "%s%s", SHM_PREFIX, aid.shmem_seg_name); hSharedMem = attach_shmem(buf, (void**)&app_client_shm->shm); if (hSharedMem == NULL) { delete app_client_shm; app_client_shm = NULL; } #else if (aid.shmem_seg_name == -1) { // Version 6 Unix/Linux/Mac client if (attach_shmem_mmap(MMAPPED_FILE_NAME, (void**)&app_client_shm->shm)) { delete app_client_shm; app_client_shm = NULL; } } else { // EMX or version 5 Unix/Linux/Mac client if (attach_shmem(aid.shmem_seg_name, (void**)&app_client_shm->shm)) { delete app_client_shm; app_client_shm = NULL; } } #endif // ! _WIN32 if (app_client_shm == NULL) return -1; return 0; } // Return CPU time of process. // double boinc_worker_thread_cpu_time() { double cpu; #ifdef _WIN32 int retval; retval = boinc_process_cpu_time(cpu); if (retval) { cpu = nrunning_ticks * TIMER_PERIOD; // for Win9x } #else #ifdef GETRUSAGE_IN_TIMER_THREAD struct rusage worker_thread_ru; getrusage(RUSAGE_SELF, &worker_thread_ru); #endif cpu = (double)worker_thread_ru.ru_utime.tv_sec + (((double)worker_thread_ru.ru_utime.tv_usec)/1000000.0); cpu += (double)worker_thread_ru.ru_stime.tv_sec + (((double)worker_thread_ru.ru_stime.tv_usec)/1000000.0); #endif #if 0 // The following paranoia is (I hope) not needed anymore. // In any case, the check for CPU incrementing faster than real time // is misguided - it assumes no multi-threading. // static double last_cpu=0; // last value returned by this func static time_t last_time=0; // when it was returned time_t now = time(0); double time_diff = (double)(now - last_time); if (!finite(cpu)) { fprintf(stderr, "CPU time infinite or NaN\n"); last_time = now; return last_cpu; } double cpu_diff = cpu - last_cpu; if (cpu_diff < 0) { fprintf(stderr, "Negative CPU time change\n"); last_time = now; return last_cpu; } if (cpu_diff>(time_diff + 1)) { fprintf(stderr, "CPU time incrementing faster than real time. Correcting.\n"); cpu = last_cpu + time_diff + 1; // allow catch-up } last_cpu = cpu; last_time = now; #endif return cpu; } // Communicate to the core client (via shared mem) // the current CPU time and fraction done. // NOTE: various bugs could cause some of these FP numbers to be enormous, // possibly overflowing the buffer. // So use strlcat() instead of strcat() // // This is called only from the timer thread (so no need for synch) // static bool update_app_progress(double cpu_t, double cp_cpu_t) { char msg_buf[MSG_CHANNEL_SIZE], buf[256]; if (standalone) return true; sprintf(msg_buf, "%e\n" "%e\n", cpu_t, cp_cpu_t ); if (want_network) { strlcat(msg_buf, "1\n", MSG_CHANNEL_SIZE); } if (fraction_done >= 0) { double range = aid.fraction_done_end - aid.fraction_done_start; double fdone = aid.fraction_done_start + fraction_done*range; sprintf(buf, "%e\n", fdone); strlcat(msg_buf, buf, MSG_CHANNEL_SIZE); } if (fpops_per_cpu_sec) { sprintf(buf, "%e\n", fpops_per_cpu_sec); strlcat(msg_buf, buf, MSG_CHANNEL_SIZE); } if (fpops_cumulative) { sprintf(buf, "%e\n", fpops_cumulative); strlcat(msg_buf, buf, MSG_CHANNEL_SIZE); } if (intops_per_cpu_sec) { sprintf(buf, "%e\n", intops_per_cpu_sec); strlcat(msg_buf, buf, MSG_CHANNEL_SIZE); } if (intops_cumulative) { sprintf(buf, "%e\n", intops_cumulative); strlcat(msg_buf, buf, MSG_CHANNEL_SIZE); } return app_client_shm->shm->app_status.send_msg(msg_buf); } int boinc_init() { int retval; if (!diagnostics_is_initialized()) { retval = boinc_init_diagnostics(BOINC_DIAG_DEFAULTS); if (retval) return retval; } boinc_options_defaults(options); return boinc_init_options(&options); } int boinc_init_options(BOINC_OPTIONS* opt) { int retval; if (!diagnostics_is_initialized()) { retval = boinc_init_diagnostics(BOINC_DIAG_DEFAULTS); if (retval) return retval; } retval = boinc_init_options_general(*opt); if (retval) return retval; retval = start_timer_thread(); if (retval) return retval; #ifndef _WIN32 retval = start_worker_signals(); if (retval) return retval; #endif return 0; } int boinc_init_options_general(BOINC_OPTIONS& opt) { int retval; options = opt; boinc_status.no_heartbeat = false; boinc_status.suspended = false; boinc_status.quit_request = false; boinc_status.abort_request = false; if (options.main_program) { // make sure we're the only app running in this slot // retval = file_lock.lock(LOCKFILE); if (retval) { // give any previous occupant a chance to timeout and exit // boinc_sleep(LOCKFILE_TIMEOUT_PERIOD); retval = file_lock.lock(LOCKFILE); } if (retval) { fprintf(stderr, "Can't acquire lockfile - exiting\n"); boinc_exit(0); // not un-recoverable ==> status=0 } } retval = boinc_parse_init_data_file(); if (retval) { standalone = true; } else { retval = setup_shared_mem(); if (retval) { fprintf(stderr, "Can't set up shared mem: %d\n" "Will run in standalone mode.\n", retval ); standalone = true; } } // copy the WU CPU time to a separate var, // since we may reread the structure again later. // initial_wu_cpu_time = aid.wu_cpu_time; fraction_done = -1; time_until_checkpoint = (int)aid.checkpoint_period; last_checkpoint_cpu_time = aid.wu_cpu_time; last_wu_cpu_time = aid.wu_cpu_time; if (standalone) { options.check_heartbeat = false; } heartbeat_giveup_time = interrupt_count + HEARTBEAT_GIVEUP_COUNT; return 0; } int boinc_get_status(BOINC_STATUS *s) { s->no_heartbeat = boinc_status.no_heartbeat; s->suspended = boinc_status.suspended; s->quit_request = boinc_status.quit_request; s->reread_init_data_file = boinc_status.reread_init_data_file; s->abort_request = boinc_status.abort_request; s->working_set_size = boinc_status.working_set_size; s->max_working_set_size = boinc_status.max_working_set_size; return 0; } // if we have any new trickle-ups or file upload requests, // send a message describing them // static void send_trickle_up_msg() { char buf[MSG_CHANNEL_SIZE]; BOINCINFO("Sending Trickle Up Message"); strcpy(buf, ""); if (have_new_trickle_up) { strcat(buf, "\n"); } if (have_new_upload_file) { strcat(buf, "\n"); } if (strlen(buf)) { if (app_client_shm->shm->trickle_up.send_msg(buf)) { have_new_trickle_up = false; have_new_upload_file = false; } } } // NOTE: a non-zero status tells the core client that we're exiting with // an "unrecoverable error", which will be reported back to server. // A zero exit-status tells the client we've successfully finished the result. // int boinc_finish(int status) { fraction_done = 1; fprintf(stderr, "called boinc_finish\n"); boinc_sleep(2.0); // let the timer thread send final messages g_sleep = true; // then disable it if (options.main_program && status==0) { FILE* f = fopen(BOINC_FINISH_CALLED_FILE, "w"); if (f) fclose(f); } if (options.send_status_msgs) { aid.wu_cpu_time = last_checkpoint_cpu_time; boinc_write_init_data_file(aid); } boinc_exit(status); return 0; // never reached } // unlock the lockfile and call the appropriate exit function // Unix: called only from the worker thread. // Win: called from the worker or timer thread. // // make static eventually void boinc_exit(int status) { if (options.backwards_compatible_graphics) { graphics_cleanup(); } file_lock.unlock(LOCKFILE); fflush(NULL); boinc_finish_diag(); // various platforms have problems shutting down a process // while other threads are still executing, // or triggering endless exit()/atexit() loops. // BOINCINFO("Exit Status: %d", status); #if defined(_WIN32) // Halts all the threads and then cleans up. TerminateProcess(GetCurrentProcess(), status); #elif defined(__APPLE_CC__) // stops endless exit()/atexit() loops. _exit(status); #else // arrange to exit with given status even if errors happen // in atexit() functions // set_signal_exit_code(status); exit(status); #endif } int boinc_is_standalone() { if (standalone) return 1; return 0; } static void exit_from_timer_thread(int status) { #ifdef _WIN32 // this seems to work OK on Windows // boinc_exit(status); #else // but on Unix there are synchronization problems; // set a flag telling the worker thread to exit // worker_thread_exit_status = status; worker_thread_exit_flag = true; pthread_exit(NULL); #endif } // parse the init data file. // This is done at startup, and also if a "reread prefs" message is received // int boinc_parse_init_data_file() { FILE* f; int retval; // in principle should free project_preferences here if it's nonzero memset(&aid, 0, sizeof(aid)); strcpy(aid.user_name, ""); strcpy(aid.team_name, ""); aid.wu_cpu_time = 0; aid.user_total_credit = 0; aid.user_expavg_credit = 0; aid.host_total_credit = 0; aid.host_expavg_credit = 0; aid.checkpoint_period = DEFAULT_CHECKPOINT_PERIOD; if (!boinc_file_exists(INIT_DATA_FILE)) { fprintf(stderr, "Can't open init data file - running in standalone mode\n" ); return ERR_FOPEN; } f = boinc_fopen(INIT_DATA_FILE, "r"); retval = parse_init_data_file(f, aid); fclose(f); if (retval) { fprintf(stderr, "Can't parse init data file - running in standalone mode\n" ); return retval; } return 0; } int boinc_write_init_data_file(APP_INIT_DATA& x) { FILE* f = boinc_fopen(INIT_DATA_FILE, "w"); if (!f) return ERR_FOPEN; int retval = write_init_data_file(f, x); fclose(f); return retval; } int boinc_report_app_status( double cpu_time, double checkpoint_cpu_time, double _fraction_done ) { char msg_buf[MSG_CHANNEL_SIZE]; if (standalone) return 0; sprintf(msg_buf, "%10.4f\n" "%.15e\n" "%2.8f\n", cpu_time, checkpoint_cpu_time, _fraction_done ); app_client_shm->shm->app_status.send_msg(msg_buf); return 0; } int boinc_get_init_data_p(APP_INIT_DATA* app_init_data) { *app_init_data = aid; return 0; } int boinc_get_init_data(APP_INIT_DATA& app_init_data) { app_init_data = aid; return 0; } int boinc_wu_cpu_time(double& cpu_t) { cpu_t = last_wu_cpu_time; return 0; } // make static eventually int suspend_activities() { BOINCINFO("Received Suspend Message"); #ifdef _WIN32 if (options.direct_process_action) { SuspendThread(worker_thread_handle); } #endif return 0; } // make static eventually int resume_activities() { BOINCINFO("Received Resume Message"); #ifdef _WIN32 if (options.direct_process_action) { ResumeThread(worker_thread_handle); } #endif return 0; } int restore_activities() { int retval; if (boinc_status.suspended) { retval = suspend_activities(); } else { retval = resume_activities(); } return retval; } static void handle_heartbeat_msg() { char buf[MSG_CHANNEL_SIZE]; double dtemp; if (app_client_shm->shm->heartbeat.get_msg(buf)) { if (match_tag(buf, "")) { heartbeat_giveup_time = interrupt_count + HEARTBEAT_GIVEUP_COUNT; } if (parse_double(buf, "", dtemp)) { boinc_status.working_set_size = dtemp; } if (parse_double(buf, "", dtemp)) { boinc_status.max_working_set_size = dtemp; } } } static void handle_upload_file_status() { char path[256], buf[256], log_name[256], *p; std::string filename; int status; relative_to_absolute("", path); DirScanner dirscan(path); while (dirscan.scan(filename)) { strcpy(buf, filename.c_str()); if (strstr(buf, UPLOAD_FILE_STATUS_PREFIX) != buf) continue; strcpy(log_name, buf+strlen(UPLOAD_FILE_STATUS_PREFIX)); FILE* f = boinc_fopen(filename.c_str(), "r"); if (!f) { fprintf(stderr, "handle_file_upload_status: can't open %s\n", filename.c_str()); continue; } p = fgets(buf, 256, f); fclose(f); if (p && parse_int(buf, "", status)) { UPLOAD_FILE_STATUS uf; uf.name = std::string(log_name); uf.status = status; upload_file_status.push_back(uf); } else { fprintf(stderr, "handle_upload_file_status: can't parse %s\n", buf); } } } // handle trickle and file upload messages // static void handle_trickle_down_msg() { char buf[MSG_CHANNEL_SIZE]; if (app_client_shm->shm->trickle_down.get_msg(buf)) { BOINCINFO("Received Trickle Down Message"); if (match_tag(buf, "")) { have_trickle_down = true; } if (match_tag(buf, "")) { handle_upload_file_status(); } } } // runs in timer thread // static void handle_process_control_msg() { char buf[MSG_CHANNEL_SIZE]; if (app_client_shm->shm->process_control_request.get_msg(buf)) { //fprintf(stderr, "%f: got %s\n", dtime(), buf); if (match_tag(buf, "")) { boinc_status.suspended = true; suspend_activities(); } if (match_tag(buf, "")) { boinc_status.suspended = false; resume_activities(); } if (match_tag(buf, "")) { BOINCINFO("Received quit message"); boinc_status.quit_request = true; if (options.direct_process_action) { exit_from_timer_thread(0); } } if (match_tag(buf, "")) { BOINCINFO("Received abort message"); boinc_status.abort_request = true; if (options.direct_process_action) { diagnostics_set_aborted_via_gui(); #if defined(_WIN32) // Cause a controlled assert and dump the callstacks. DebugBreak(); #elif defined(__APPLE__) PrintBacktrace(); #endif exit_from_timer_thread(EXIT_ABORTED_BY_CLIENT); } } if (match_tag(buf, "")) { boinc_status.reread_init_data_file = true; } if (match_tag(buf, "")) { have_network = 1; } } } // The following is used by V6 apps so that graphics // will work with pre-V6 clients. // If we get a graphics message, run/kill the (separate) graphics app // // struct GRAPHICS_APP { bool fullscreen; #ifdef _WIN32 HANDLE pid; #else int pid; #endif GRAPHICS_APP(bool f) {fullscreen=f;} void run(char* path) { int argc; char* argv[4]; char abspath[1024]; #ifdef _WIN32 GetFullPathName(path, 1024, abspath, NULL); #else strcpy(abspath, path); #endif argv[0] = GRAPHICS_APP_FILENAME; if (fullscreen) { argv[1] = "--fullscreen"; argv[2] = 0; argc = 2; } else { argv[1] = 0; argc = 1; } int retval = run_program(0, abspath, argc, argv, 0, pid); if (retval) { pid = 0; } } bool is_running() { if (pid && process_exists(pid)) return true; pid = 0; return false; } void kill() { if (pid) { kill_program(pid); pid = 0; } } }; static GRAPHICS_APP ga_win(false), ga_full(true); static bool have_graphics_app; // The following is for backwards compatibility with version 5 clients. // static inline void handle_graphics_messages() { static char graphics_app_path[1024]; char buf[MSG_CHANNEL_SIZE]; GRAPHICS_MSG m; static bool first=true; if (first) { first = false; boinc_resolve_filename( GRAPHICS_APP_FILENAME, graphics_app_path, sizeof(graphics_app_path) ); // if the above returns "graphics_app", there was no link file, // so there's no graphics app // if (!strcmp(graphics_app_path, GRAPHICS_APP_FILENAME)) { have_graphics_app = false; } else { have_graphics_app = true; app_client_shm->shm->graphics_reply.send_msg( xml_graphics_modes[MODE_HIDE_GRAPHICS] ); } } if (!have_graphics_app) return; if (app_client_shm->shm->graphics_request.get_msg(buf)) { app_client_shm->decode_graphics_msg(buf, m); switch (m.mode) { case MODE_HIDE_GRAPHICS: if (ga_full.is_running()) { ga_full.kill(); } else if (ga_win.is_running()) { ga_win.kill(); } break; case MODE_WINDOW: if (!ga_win.is_running()) ga_win.run(graphics_app_path); break; case MODE_FULLSCREEN: if (!ga_full.is_running()) ga_full.run(graphics_app_path); break; case MODE_BLANKSCREEN: // we can't actually blank the screen; just kill the app // if (ga_full.is_running()) { ga_full.kill(); } break; } app_client_shm->shm->graphics_reply.send_msg( xml_graphics_modes[m.mode] ); } } static void graphics_cleanup() { if (!have_graphics_app) return; if (ga_full.is_running()) ga_full.kill(); if (ga_win.is_running()) ga_win.kill(); } // timer handler; runs in the timer thread // static void timer_handler() { if (g_sleep) return; interrupt_count++; // handle messages from the core client // if (app_client_shm) { if (options.check_heartbeat) { handle_heartbeat_msg(); } if (options.handle_trickle_downs) { handle_trickle_down_msg(); } if (in_critical_section==0 && options.handle_process_control) { handle_process_control_msg(); } if (options.backwards_compatible_graphics) { handle_graphics_messages(); } } if (interrupt_count % TIMERS_PER_SEC) return; // here it we're at a one-second boundary; do slow stuff // if (!ready_to_checkpoint) { time_until_checkpoint -= 1; if (time_until_checkpoint <= 0) { ready_to_checkpoint = true; } } // see if the core client has died, which means we need to die too // (unless we're in a critical section) // if (in_critical_section==0 && options.check_heartbeat) { if (heartbeat_giveup_time < interrupt_count) { fprintf(stderr, "No heartbeat from core client for 30 sec - exiting\n" ); if (options.direct_process_action) { exit_from_timer_thread(0); } else { boinc_status.no_heartbeat = true; } } } // don't bother reporting CPU time etc. if we're suspended // if (options.send_status_msgs && !boinc_status.suspended) { double cur_cpu = boinc_worker_thread_cpu_time(); last_wu_cpu_time = cur_cpu + initial_wu_cpu_time; update_app_progress(last_wu_cpu_time, last_checkpoint_cpu_time); } // If running under V5 client, notify the client if the graphics app exits // (e.g., if user clicked in the graphics window's close box.) // if (ga_win.pid) { if (! ga_win.is_running()) { app_client_shm->shm->graphics_reply.send_msg( xml_graphics_modes[MODE_HIDE_GRAPHICS] ); } } if (options.handle_trickle_ups) { send_trickle_up_msg(); } if (timer_callback) { timer_callback(); } } #ifdef _WIN32 DWORD WINAPI timer_thread(void *) { while (1) { Sleep((int)(TIMER_PERIOD*1000)); timer_handler(); // poor man's CPU time accounting for Win9x // if (!boinc_status.suspended) { nrunning_ticks++; } } return 0; } #else static void* timer_thread(void*) { block_sigalrm(); while(1) { boinc_sleep(TIMER_PERIOD); timer_handler(); } return 0; } // This SIGALRM handler gets handled only by the worker thread. // It gets CPU time and implements sleeping. // It must call only signal-safe functions, and must not do FP math // static void worker_signal_handler(int) { #ifndef GETRUSAGE_IN_TIMER_THREAD getrusage(RUSAGE_SELF, &worker_thread_ru); #endif if (worker_thread_exit_flag) { boinc_exit(worker_thread_exit_status); } if (options.direct_process_action) { while (boinc_status.suspended && in_critical_section==0) { sleep(1); // don't use boinc_sleep() because it does FP math } } } #endif // Called from the worker thread; create the timer thread // int start_timer_thread() { int retval=0; #ifdef _WIN32 // get the worker thread handle // DuplicateHandle( GetCurrentProcess(), GetCurrentThread(), GetCurrentProcess(), &worker_thread_handle, 0, FALSE, DUPLICATE_SAME_ACCESS ); // Create the timer thread // DWORD id; if (!CreateThread(NULL, 0, timer_thread, 0, 0, &id)) { fprintf(stderr, "start_timer_thread(): CreateThread() failed, errno %d\n", errno); return errno; } // lower our (worker thread) priority // SetThreadPriority(worker_thread_handle, THREAD_PRIORITY_IDLE); #else pthread_attr_t thread_attrs; pthread_attr_init(&thread_attrs); pthread_attr_setstacksize(&thread_attrs, 16384); retval = pthread_create(&timer_thread_handle, &thread_attrs, timer_thread, NULL); if (retval) { fprintf(stderr, "start_timer_thread(): pthread_create(): %d", retval); return retval; } #endif return 0; } #ifndef _WIN32 // set up a periodic SIGALRM, to be handled by the worker thread // static int start_worker_signals() { int retval; struct sigaction sa; itimerval value; sa.sa_handler = worker_signal_handler; sa.sa_flags = SA_RESTART; sigemptyset(&sa.sa_mask); retval = sigaction(SIGALRM, &sa, NULL); if (retval) { perror("boinc start_timer_thread() sigaction"); return retval; } value.it_value.tv_sec = 0; value.it_value.tv_usec = (int)(TIMER_PERIOD*1e6); value.it_interval = value.it_value; retval = setitimer(ITIMER_REAL, &value, NULL); if (retval) { perror("boinc start_timer_thread() setitimer"); return retval; } return 0; } #endif int boinc_send_trickle_up(char* variety, char* p) { if (!options.handle_trickle_ups) return ERR_NO_OPTION; FILE* f = boinc_fopen(TRICKLE_UP_FILENAME, "wb"); if (!f) return ERR_FOPEN; fprintf(f, "%s\n", variety); size_t n = fwrite(p, strlen(p), 1, f); fclose(f); if (n != 1) return ERR_WRITE; have_new_trickle_up = true; return 0; } int boinc_time_to_checkpoint() { if (ready_to_checkpoint) { boinc_begin_critical_section(); return 1; } return 0; } int boinc_checkpoint_completed() { double cur_cpu; cur_cpu = boinc_worker_thread_cpu_time(); last_wu_cpu_time = cur_cpu + aid.wu_cpu_time; last_checkpoint_cpu_time = last_wu_cpu_time; time_until_checkpoint = (int)aid.checkpoint_period; boinc_end_critical_section(); ready_to_checkpoint = false; return 0; } void boinc_begin_critical_section() { in_critical_section++; } void boinc_end_critical_section() { in_critical_section--; if (in_critical_section < 0) { in_critical_section = 0; // just in case } } int boinc_fraction_done(double x) { fraction_done = x; return 0; } int boinc_receive_trickle_down(char* buf, int len) { std::string filename; char path[256]; if (!options.handle_trickle_downs) return false; if (have_trickle_down) { relative_to_absolute("", path); DirScanner dirscan(path); while (dirscan.scan(filename)) { fprintf(stderr, "scan: %s\n", filename.c_str()); if (strstr(filename.c_str(), "trickle_down")) { strncpy(buf, filename.c_str(), len); return true; } } have_trickle_down = false; } return false; } int boinc_upload_file(std::string& name) { char buf[256]; std::string pname; int retval; retval = boinc_resolve_filename_s(name.c_str(), pname); if (retval) return retval; sprintf(buf, "%s%s", UPLOAD_FILE_REQ_PREFIX, name.c_str()); FILE* f = boinc_fopen(buf, "w"); if (!f) return ERR_FOPEN; have_new_upload_file = true; fclose(f); return 0; } int boinc_upload_status(std::string& name) { for (unsigned int i=0; i