// The contents of this file are subject to the BOINC Public License // Version 1.0 (the "License"); you may not use this file except in // compliance with the License. You may obtain a copy of the License at // http://boinc.berkeley.edu/license_1.0.txt // // Software distributed under the License is distributed on an "AS IS" // basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See the // License for the specific language governing rights and limitations // under the License. // // The Original Code is the Berkeley Open Infrastructure for Network Computing. // // The Initial Developer of the Original Code is the SETI@home project. // Portions created by the SETI@home project are Copyright (C) 2002 // University of California at Berkeley. All Rights Reserved. // // Contributor(s): // #include "cpp.h" #ifdef _WIN32 #include "stdafx.h" #endif #ifndef _WIN32 #if HAVE_SYS_TYPES_H #include #endif #if HAVE_SYS_WAIT_H #include #endif #if HAVE_SIGNAL_H #include #endif #if HAVE_SYS_SIGNAL_H #include #endif #ifdef HAVE_UNISTD_H #include #endif #include #include #include #include #endif #include "parse.h" #include "util.h" #include "error_numbers.h" #include "filesys.h" #include "file_names.h" #include "hostinfo.h" #include "http.h" #include "log_flags.h" #include "client_msgs.h" #include "client_state.h" CLIENT_STATE gstate; CLIENT_STATE::CLIENT_STATE() { net_xfers = new NET_XFER_SET; http_ops = new HTTP_OP_SET(net_xfers); file_xfers = new FILE_XFER_SET(http_ops); pers_file_xfers = new PERS_FILE_XFER_SET(file_xfers); scheduler_op = new SCHEDULER_OP(http_ops); client_state_dirty = false; exit_when_idle = false; return_results_immediately = false; run_cpu_benchmarks = false; skip_cpu_benchmarks = false; file_xfer_giveup_period = PERS_GIVEUP; contacted_sched_server = false; activities_suspended = false; network_suspended = false; previous_activities_suspended = false; core_client_major_version = MAJOR_VERSION; core_client_minor_version = MINOR_VERSION; platform_name = HOSTTYPE; exit_after_app_start_secs = 0; app_started = 0; exit_before_upload = false; user_idle = true; pi.clear(); show_projects = false; strcpy(detach_project_url, ""); strcpy(host_venue, ""); user_run_request = USER_RUN_REQUEST_AUTO; user_network_request = USER_RUN_REQUEST_AUTO; started_by_screensaver = false; requested_exit = false; master_fetch_period = MASTER_FETCH_PERIOD; retry_base_period = RETRY_BASE_PERIOD; retry_cap = RETRY_CAP; master_fetch_retry_cap = MASTER_FETCH_RETRY_CAP; master_fetch_interval = MASTER_FETCH_INTERVAL; sched_retry_delay_min = SCHED_RETRY_DELAY_MIN; sched_retry_delay_max = SCHED_RETRY_DELAY_MAX; pers_retry_delay_min = PERS_RETRY_DELAY_MIN; pers_retry_delay_max = PERS_RETRY_DELAY_MAX; pers_giveup = PERS_GIVEUP; executing_as_windows_service = false; } #if 0 // Deallocate memory. Can be used to check for memory leaks. // Turned off for now. // void CLIENT_STATE::free_mem() { vector::iterator proj_iter; vector::iterator app_iter; vector::iterator fi_iter; vector::iterator av_iter; vector::iterator wu_iter; vector::iterator res_iter; PROJECT *proj; APP *app; FILE_INFO *fi; APP_VERSION *av; WORKUNIT *wu; RESULT *res; proj_iter = projects.begin(); while (proj_iter != projects.end()) { proj = projects[0]; proj_iter = projects.erase(proj_iter); delete proj; } app_iter = apps.begin(); while (app_iter != apps.end()) { app = apps[0]; app_iter = apps.erase(app_iter); delete app; } fi_iter = file_infos.begin(); while (fi_iter != file_infos.end()) { fi = file_infos[0]; fi_iter = file_infos.erase(fi_iter); delete fi; } av_iter = app_versions.begin(); while (av_iter != app_versions.end()) { av = app_versions[0]; av_iter = app_versions.erase(av_iter); delete av; } wu_iter = workunits.begin(); while (wu_iter != workunits.end()) { wu = workunits[0]; wu_iter = workunits.erase(wu_iter); delete wu; } res_iter = results.begin(); while (res_iter != results.end()) { res = results[0]; res_iter = results.erase(res_iter); delete res; } active_tasks.free_mem(); } #endif int CLIENT_STATE::init() { int retval; unsigned int i; srand(time(NULL)); language.read_language_file(LANGUAGE_FILE_NAME); msg_printf( NULL, MSG_INFO, "Starting BOINC client version %d.%02d for %s", core_client_major_version, core_client_minor_version, platform_name ); // we need the host venue while parsing account files. // Get it from the client state file // parse_venue(); // parse account files. // If there are none, prompt user for project URL and create file // retval = parse_account_files(); if (projects.size() == 0) { retval = add_new_project(); if (retval) { printf("can't get initial project\n"); return retval; } retval = parse_account_files(); if (projects.size() == 0) { if (retval) { printf("can't get initial project\n"); return retval; } } } // check for app_info.xml file in project dirs. // If find, read app info from there, set project.anonymous_platform // check_anonymous(); // Parse the client state file, // ignoring any tags (and associated stuff) // for projects with no account file // host_info.clear_host_info(); parse_state_file(); // scan user prefs; create file records // parse_preferences_for_user_files(); print_summary(); do_cmdline_actions(); if (core_client_major_version != old_major_version) { msg_printf(NULL, MSG_INFO, "State file has different major version (%d.%02d); resetting projects\n", old_major_version, old_minor_version ); for (i=0; ihostid) { msg_printf(p, MSG_INFO, "Host ID is %d", p->hostid); } else { msg_printf(p, MSG_INFO, "Host ID not assigned yet"); } } // Read the global preferences file, if it exists. // Do this after reading the state file so we know our venue // bool found_venue; retval = global_prefs.parse_file( GLOBAL_PREFS_FILE_NAME, host_venue, found_venue ); if (retval) { msg_printf(NULL, MSG_INFO, "No general preferences found - using BOINC defaults" ); } else { show_global_prefs_source(found_venue); } install_global_prefs(); // Getting host info is very fast, so we can do it anytime // host_info.get_host_info(); // running CPU benchmarks is slow, so do it infrequently // if (should_run_cpu_benchmarks()) { start_cpu_benchmarks(); } set_nslots(); // set up the project and slot directories // retval = make_project_dirs(); if (retval) return retval; // Restart any tasks that were running when we last quit the client // restart_tasks(); // Just to be on the safe side; something may have been modified // set_client_state_dirty("init"); #ifndef _WIN32 gui_rpcs.init(); #endif return 0; } // sleep up to x seconds, // but if network I/O becomes possible, // wake up and do as much as limits allow. // If suspended, just sleep x seconds. // This gets called from the Win GUI to allow high network throughput. // NOTE: when a socket is connecting, this gets called repeatedly, // because the NetActivity messages seems to get sent repeatedly. // This is inefficient but not a problem (I guess) // int CLIENT_STATE::net_sleep(double x) { SCOPE_MSG_LOG scope_messages(log_messages, CLIENT_MSG_LOG::DEBUG_NET_XFER); scope_messages.printf("CLIENT_STATE::net_sleep(%f)\n", x); if (activities_suspended || network_suspended) { boinc_sleep(x); return 0; } else { return net_xfers->net_sleep(x); } } #define POLL_ACTION(name, func) \ do { if (func()) { \ ++actions; \ scope_messages.printf("CLIENT_STATE::do_something(): active task: " #name "\n"); \ } } while(0) // do_something polls each of the client's finite-state machine layers, // possibly triggering state transitions. // Returns true if something happened // (in which case should call this again immediately) // bool CLIENT_STATE::do_something() { int actions = 0, reason, retval; SCOPE_MSG_LOG scope_messages(log_messages, CLIENT_MSG_LOG::DEBUG_POLL); check_suspend_activities(reason); if (reason) { if (!activities_suspended) { suspend_activities(reason); } } else { if (activities_suspended) { resume_activities(); } } previous_activities_suspended = activities_suspended; activities_suspended = (reason != 0); // if we're doing CPU benchmarks, don't do anything else // if (reason & SUSPEND_REASON_BENCHMARKS) { cpu_benchmarks_poll(); return false; } check_suspend_network(reason); if (reason) { if (!network_suspended) { suspend_network(reason); } } else { if (network_suspended) { resume_network(); } } network_suspended = (reason != 0); scope_messages.printf("CLIENT_STATE::do_something(): Begin poll:\n"); ++scope_messages; ss_logic.poll(); if (activities_suspended) { scope_messages.printf("CLIENT_STATE::do_something(): activities suspended\n"); POLL_ACTION(net_xfers , net_xfers->poll ); POLL_ACTION(http_ops , http_ops->poll ); POLL_ACTION(scheduler_rpc , scheduler_rpc_poll ); POLL_ACTION(garbage_collect , garbage_collect ); POLL_ACTION(update_results , update_results ); #ifndef _WIN32 POLL_ACTION(gui_rpc , gui_rpcs.poll ); #endif } else if (network_suspended) { scope_messages.printf("CLIENT_STATE::do_something(): network suspended\n"); POLL_ACTION(net_xfers , net_xfers->poll ); POLL_ACTION(http_ops , http_ops->poll ); POLL_ACTION(active_tasks , active_tasks.poll ); POLL_ACTION(start_apps , start_apps ); POLL_ACTION(handle_finished_apps , handle_finished_apps ); POLL_ACTION(scheduler_rpc , scheduler_rpc_poll ); POLL_ACTION(garbage_collect , garbage_collect ); POLL_ACTION(update_results , update_results ); #ifndef _WIN32 POLL_ACTION(gui_rpc , gui_rpcs.poll ); #endif } else { net_stats.poll(*net_xfers); // Call these functions in bottom to top order with // respect to the FSM hierarchy // POLL_ACTION(net_xfers , net_xfers->poll ); POLL_ACTION(http_ops , http_ops->poll ); POLL_ACTION(file_xfers , file_xfers->poll ); POLL_ACTION(active_tasks , active_tasks.poll ); POLL_ACTION(scheduler_rpc , scheduler_rpc_poll ); POLL_ACTION(start_apps , start_apps ); POLL_ACTION(pers_file_xfers , pers_file_xfers->poll ); POLL_ACTION(handle_finished_apps , handle_finished_apps ); POLL_ACTION(handle_pers_file_xfers , handle_pers_file_xfers ); POLL_ACTION(garbage_collect , garbage_collect ); POLL_ACTION(update_results , update_results ); #ifndef _WIN32 POLL_ACTION(gui_rpc , gui_rpcs.poll ); #endif } retval = write_state_file_if_needed(); if (retval) { msg_printf(NULL, MSG_ERROR, "Couldn't write state file: %d", retval); } --log_messages; scope_messages.printf( "CLIENT_STATE::do_something(): End poll: %d tasks active\n", actions ); if (actions > 0) { return true; } else { time_stats.update(true, !activities_suspended); return false; } } // See if the project specified by master_url already exists // in the client state record. Ignore any trailing "/" characters // PROJECT* CLIENT_STATE::lookup_project(const char* master_url) { int len1, len2; char *mu; len1 = strlen(master_url); if (master_url[strlen(master_url)-1] == '/') len1--; for (unsigned int i=0; imaster_url; len2 = strlen(mu); if (mu[strlen(mu)-1] == '/') len2--; if (!strncmp(master_url, projects[i]->master_url, max(len1,len2))) { return projects[i]; } } return 0; } APP* CLIENT_STATE::lookup_app(PROJECT* p, const char* name) { for (unsigned int i=0; iproject == p && !strcmp(name, app->name)) return app; } return 0; } RESULT* CLIENT_STATE::lookup_result(PROJECT* p, const char* name) { for (unsigned int i=0; iproject == p && !strcmp(name, rp->name)) return rp; } return 0; } WORKUNIT* CLIENT_STATE::lookup_workunit(PROJECT* p, const char* name) { for (unsigned int i=0; iproject == p && !strcmp(name, wup->name)) return wup; } return 0; } APP_VERSION* CLIENT_STATE::lookup_app_version(APP* app, int version_num) { for (unsigned int i=0; iapp == app && version_num==avp->version_num) { return avp; } } return 0; } FILE_INFO* CLIENT_STATE::lookup_file_info(PROJECT* p, const char* name) { for (unsigned int i=0; iproject == p && !strcmp(fip->name, name)) { return fip; } } return 0; } // Find the active task for a given result // ACTIVE_TASK* CLIENT_STATE::lookup_active_task_by_result(RESULT* rep) { for (unsigned int i = 0; i < active_tasks.active_tasks.size(); i ++) { if (active_tasks.active_tasks[i]->result == rep) { return active_tasks.active_tasks[i]; } } return NULL; } // functions to create links between state objects // (which, in their XML form, reference one another by name) // Return nonzero if already in client state. // int CLIENT_STATE::link_app(PROJECT* p, APP* app) { if (lookup_app(p, app->name)) return ERR_NOT_UNIQUE; app->project = p; return 0; } int CLIENT_STATE::link_file_info(PROJECT* p, FILE_INFO* fip) { if (lookup_file_info(p, fip->name)) return ERR_NOT_UNIQUE; fip->project = p; return 0; } int CLIENT_STATE::link_app_version(PROJECT* p, APP_VERSION* avp) { APP* app; FILE_INFO* fip; unsigned int i; avp->project = p; app = lookup_app(p, avp->app_name); if (!app) { msg_printf(0, MSG_ERROR, "app_version refers to nonexistent app: %s\n", avp->app_name); return ERR_NOT_FOUND; } avp->app = app; if (lookup_app_version(app, avp->version_num)) return ERR_NOT_UNIQUE; for (i=0; iapp_files.size(); i++) { FILE_REF& file_ref = avp->app_files[i]; fip = lookup_file_info(p, file_ref.file_name); if (!fip) { msg_printf(0, MSG_ERROR, "app_version refers to nonexistent file: %s\n", file_ref.file_name ); return ERR_NOT_FOUND; } // any executable file associated with an app version must be signed // if (fip->executable) { fip->signature_required = true; } file_ref.file_info = fip; } return 0; } int CLIENT_STATE::link_file_ref(PROJECT* p, FILE_REF* file_refp) { FILE_INFO* fip; fip = lookup_file_info(p, file_refp->file_name); if (!fip) { msg_printf(0, MSG_ERROR, "File ref refers to nonexistent file: %s\n", file_refp->file_name); return ERR_NOT_FOUND; } file_refp->file_info = fip; return 0; } int CLIENT_STATE::link_workunit(PROJECT* p, WORKUNIT* wup) { APP* app; APP_VERSION* avp; unsigned int i; int retval; app = lookup_app(p, wup->app_name); if (!app) { msg_printf(0, MSG_ERROR, "WU refers to nonexistent app: %s\n", wup->app_name); return ERR_NOT_FOUND; } avp = lookup_app_version(app, wup->version_num); if (!avp) { msg_printf(0, MSG_ERROR, "WU refers to nonexistent app_version: %s %d\n", wup->app_name, wup->version_num ); return ERR_NOT_FOUND; } wup->project = p; wup->app = app; wup->avp = avp; for (i=0; iinput_files.size(); i++) { retval = link_file_ref(p, &wup->input_files[i]); if (retval) return retval; } return 0; } int CLIENT_STATE::link_result(PROJECT* p, RESULT* rp) { WORKUNIT* wup; unsigned int i; int retval; wup = lookup_workunit(p, rp->wu_name); if (!wup) { fprintf(stderr, "result refers to nonexistent WU: %s\n", rp->wu_name); return ERR_NOT_FOUND; } rp->project = p; rp->wup = wup; rp->app = wup->app; for (i=0; ioutput_files.size(); i++) { retval = link_file_ref(p, &rp->output_files[i]); if (retval) { msg_printf(0, MSG_ERROR, "link_result: link_file_ref failed\n"); return retval; } } return 0; } // Print debugging information about how many projects/files/etc // are currently in the client state record // void CLIENT_STATE::print_summary() { unsigned int i; int t; if (!log_flags.state_debug) return; SCOPE_MSG_LOG scope_messages(log_messages, CLIENT_MSG_LOG::DEBUG_STATE); scope_messages.printf("CLIENT_STATE::print_summary(): Client state summary:\n"); ++log_messages; scope_messages.printf("%d projects:\n", (int)projects.size()); for (i=0; imin_rpc_time; if (t) { scope_messages.printf(" %s min RPC %d seconds from now\n", projects[i]->master_url, (int)(t-time(0))); } else { scope_messages.printf(" %s\n", projects[i]->master_url); } } scope_messages.printf("%d file_infos:\n", (int)file_infos.size()); for (i=0; iname, file_infos[i]->status, file_infos[i]->pers_file_xfer?"active":"inactive"); } scope_messages.printf("%d app_versions\n", (int)app_versions.size()); for (i=0; iapp_name, app_versions[i]->version_num); } scope_messages.printf("%d workunits\n", (int)workunits.size()); for (i=0; iname); } scope_messages.printf("%d results\n", (int)results.size()); for (i=0; iname, results[i]->state); } scope_messages.printf("%d persistent file xfers\n", (int)pers_file_xfers->pers_file_xfers.size()); for (i=0; ipers_file_xfers.size(); i++) { scope_messages.printf(" %s http op state: %d\n", pers_file_xfers->pers_file_xfers[i]->fip->name, (pers_file_xfers->pers_file_xfers[i]->fxp?pers_file_xfers->pers_file_xfers[i]->fxp->http_op_state:-1)); } scope_messages.printf("%d active tasks\n", (int)active_tasks.active_tasks.size()); for (i=0; iresult->name); } --log_messages; } // delete unneeded records and files // bool CLIENT_STATE::garbage_collect() { unsigned int i, j; int failnum; FILE_INFO* fip; RESULT* rp; WORKUNIT* wup; APP_VERSION* avp, *avp2; vector::iterator result_iter; vector::iterator wu_iter; vector::iterator fi_iter; vector::iterator avp_iter; bool action = false, found; string error_msgs; PROJECT* project; SCOPE_MSG_LOG scope_messages(log_messages, CLIENT_MSG_LOG::DEBUG_STATE); // zero references counts on WUs, FILE_INFOs and APP_VERSIONs for (i=0; iref_cnt = 0; } for (i=0; iref_cnt = 0; } for (i=0; iref_cnt = 0; } // reference-count project files // for (i=0; iuser_files.size(); j++) { project->user_files[j].file_info->ref_cnt++; } } // Scan through RESULTs. // delete RESULTs that have been reported and acked. // Check for results whose WUs had download failures // Check for resultw that had upload failures // Reference-count output files // Reference-count WUs // result_iter = results.begin(); while (result_iter != results.end()) { rp = *result_iter; if (rp->got_server_ack) { scope_messages.printf("CLIENT_STATE::garbage_collect(): deleting result %s\n", rp->name); delete rp; result_iter = results.erase(result_iter); action = true; continue; } // See if the files for this result's workunit had // any errors (download failure, MD5, RSA, etc) // and we don't already have an error for this file // if (!rp->ready_to_report && rp->wup->had_failure(failnum)) { rp->wup->get_file_errors(error_msgs); report_result_error(*rp, 0, "file transfer error: %s", error_msgs.c_str()); } for (i=0; ioutput_files.size(); i++) { // If one of the output files had an upload failure, // mark the result as done and report the error. // The result, workunits, and file infos // will be cleaned up after the server is notified // if (rp->output_files[i].file_info->had_failure(failnum)) { if (!rp->ready_to_report) { // had an error uploading a file for this result // switch (failnum) { case ERR_FILE_TOO_BIG: report_result_error(*rp, 0, "Output file exceeded size limit"); break; default: report_result_error(*rp, 0, "Output file error: %d", failnum); } } } rp->output_files[i].file_info->ref_cnt++; } rp->wup->ref_cnt++; result_iter++; } // delete WORKUNITs not referenced by any in-progress result; // reference-count files and APP_VERSIONs referred to by other WUs // wu_iter = workunits.begin(); while (wu_iter != workunits.end()) { wup = *wu_iter; if (wup->ref_cnt == 0) { scope_messages.printf("CLIENT_STATE::garbage_collect(): deleting workunit %s\n", wup->name); delete wup; wu_iter = workunits.erase(wu_iter); action = true; } else { for (i=0; iinput_files.size(); i++) { wup->input_files[i].file_info->ref_cnt++; } wup->avp->ref_cnt++; wu_iter++; } } // go through APP_VERSIONs; // delete any not referenced by any WORKUNIT // and having a more recent version. // avp_iter = app_versions.begin(); while (avp_iter != app_versions.end()) { avp = *avp_iter; if (avp->ref_cnt == 0) { found = false; for (j=0; japp==avp->app && avp2->version_num>avp->version_num) { found = true; break; } } if (found) { delete avp; avp_iter = app_versions.erase(avp_iter); action = true; } else { avp_iter++; } } else { avp_iter++; } } // Then go through remaining APP_VERSIONs, // bumping refcnt of associated files. // for (i=0; iapp_files.size(); j++) { avp->app_files[j].file_info->ref_cnt++; } } // delete FILE_INFOs (and corresponding files) that are not sticky // and are not referenced by any WORKUNIT, RESULT or APP_VERSION // fi_iter = file_infos.begin(); while (fi_iter != file_infos.end()) { fip = *fi_iter; if (fip->ref_cnt==0 && fip->pers_file_xfer==NULL && !fip->sticky) { fip->delete_file(); scope_messages.printf( "CLIENT_STATE::garbage_collect(): deleting file %s\n", fip->name ); delete fip; fi_iter = file_infos.erase(fi_iter); action = true; } else { fi_iter++; } } if (action) { print_summary(); } return action; } // update the state of results // bool CLIENT_STATE::update_results() { RESULT* rp; vector::iterator result_iter; bool action = false; // delete RESULTs that have been finished and reported; // reference-count files referred to by other results // result_iter = results.begin(); while (result_iter != results.end()) { rp = *result_iter; // The result has been acked by the scheduling server. // It will be deleted on the next garbage collection, // which we trigger by setting action to true if (rp->got_server_ack) { action = true; } switch (rp->state) { case RESULT_NEW: rp->state = RESULT_FILES_DOWNLOADING; action = true; break; case RESULT_FILES_DOWNLOADING: if (input_files_available(rp)) { rp->state = RESULT_FILES_DOWNLOADED; action = true; } break; // app_finished() transitions to either RESULT_COMPUTE_DONE or // RESULT_FILES_UPLOADING. RESULT_COMPUTE_DONE is a dead-end state // indicating we had an error at the end of computation. // case RESULT_FILES_DOWNLOADED: // break; // case RESULT_COMPUTE_DONE: // rp->state = RESULT_FILES_UPLOADING; // action = true; // break; case RESULT_FILES_UPLOADING: // Once the computation has been done, check that the necessary // files have been uploaded before moving on // if (rp->is_upload_done()) { rp->ready_to_report = true; rp->state = RESULT_FILES_UPLOADED; action = true; } break; case RESULT_FILES_UPLOADED: break; } result_iter++; } return action; } // Returns true if client should exit because of debugging criteria // (timeout or idle) // bool CLIENT_STATE::time_to_exit() { if (!exit_when_idle && !exit_after_app_start_secs) return false; if (exit_after_app_start_secs && app_started && (difftime(time(0), app_started) >= exit_after_app_start_secs) ) { msg_printf(NULL, MSG_INFO, "exiting because time is up: %d\n", exit_after_app_start_secs); return true; } if (exit_when_idle && (results.size() == 0) && contacted_sched_server) { msg_printf(NULL, MSG_INFO, "exiting because no more results\n"); return true; } return false; } // Call this when a result has a nonrecoverable error. // Append a description of the error to the stderr_out field of the result. // // Go through the input and output files for this result // and generates error messages for upload/download failures. // // This function is called in the following situations: // 1. When the active_task could not start or restart, // in which case err_num is set to an OS-specific error_code. // and err_msg has an OS-supplied string. // 2. when we fail in downloading an input file or uploading an output file, // in which case err_num and err_msg are zero. // 3. When the active_task exits with a non_zero error code // or it gets signaled. // int CLIENT_STATE::report_result_error( RESULT& res, int err_num, const char* format, ... ) { char buf[MAX_BLOB_LEN], err_msg[MAX_BLOB_LEN]; unsigned int i; int failnum; // only do this once per result // if (res.ready_to_report) { return 0; } res.ready_to_report = true; va_list va; va_start(va, format); #ifdef _WIN32 _vsnprintf(err_msg, sizeof(err_msg), format, va); #else vsnprintf(err_msg, sizeof(err_msg), format, va); #endif va_end(va); sprintf(buf, "Unrecoverable error for result %s (%s)", res.name, err_msg); scheduler_op->backoff(res.project, buf); sprintf( buf, "%s\n\n" "%d\n" "%d\n", err_msg, res.active_task_state, res.signal ); res.stderr_out.append(buf); if ((res.state == RESULT_FILES_DOWNLOADED) && err_num) { sprintf(buf,"%d\n", err_num); res.stderr_out.append(buf); } if (res.state == RESULT_NEW) { for (i=0;iinput_files.size();i++) { if (res.wup->input_files[i].file_info->had_failure(failnum)) { sprintf(buf, "\n" " %s\n" " %d\n" "\n", res.wup->input_files[i].file_info->name, failnum ); res.stderr_out.append(buf); } } } if (res.state == RESULT_COMPUTE_DONE) { for (i=0; ihad_failure(failnum)) { sprintf(buf, "\n" " %s\n" " %d\n" "\n", res.output_files[i].file_info->name, failnum ); res.stderr_out.append(buf); } } } res.stderr_out = res.stderr_out.substr(0,MAX_BLOB_LEN-1); return 0; } // "Reset" a project: (clear error conditions) // - stop all active tasks // - stop all file transfers // - stop scheduler RPC if any // - delete all workunits and results // - delete all apps and app_versions // - garbage collect to delete unneeded files // // Note: does NOT delete persistent files or user-supplied files; // does not delete project dir // int CLIENT_STATE::reset_project(PROJECT* project) { unsigned int i; APP_VERSION* avp; APP* app; vector::iterator app_iter; vector::iterator avp_iter; RESULT* rp; PERS_FILE_XFER* pxp; msg_printf(project, MSG_INFO, "Resetting project"); active_tasks.abort_project(project); // TODO: close sockets and open FILEs; delete the various objects // for (i=0; ipers_file_xfers.size(); i++) { pxp = pers_file_xfers->pers_file_xfers[i]; if (pxp->fip->project == project) { if (pxp->fxp) { file_xfers->remove(pxp->fxp); } pers_file_xfers->remove(pxp); i--; } } // if we're in the middle of a scheduler op to the project, abort it // if (scheduler_op->state != SCHEDULER_OP_STATE_IDLE && scheduler_op->project == project ) { http_ops->remove(&scheduler_op->http_op); scheduler_op->state = SCHEDULER_OP_STATE_IDLE; } // mark results as server-acked. // This will cause garbage_collect to delete them, // and in turn their WUs will be deleted // for (i=0; iproject == project) { rp->got_server_ack = true; } } garbage_collect(); // forcibly remove apps and app_versions // (but not if anonymous platform) // if (!project->anonymous_platform) { avp_iter = app_versions.begin(); while (avp_iter != app_versions.end()) { avp = *avp_iter; if (avp->project == project) { avp_iter = app_versions.erase(avp_iter); delete avp; } else { avp_iter++; } } app_iter = apps.begin(); while (app_iter != apps.end()) { app = *app_iter; if (app->project == project) { app_iter = apps.erase(app_iter); delete app; } else { app_iter++; } } garbage_collect(); } write_state_file(); return 0; } // "Detach" a project: // - Reset (see above) // - delete all file infos // - delete account file // - delete account directory // int CLIENT_STATE::detach_project(PROJECT* project) { vector::iterator project_iter; vector::iterator fi_iter; FILE_INFO* fip; PROJECT* p; char path[256]; int retval; reset_project(project); msg_printf(project, MSG_INFO, "Detaching from project"); // delete all FILE_INFOs associated with this project // fi_iter = file_infos.begin(); while (fi_iter != file_infos.end()) { fip = *fi_iter; if (fip->project == project) { file_infos.erase(fi_iter); delete fip; } else { fi_iter++; } } // if global prefs came from this project, delete file and reinit // p = lookup_project(global_prefs.source_project.c_str()); if (p == project) { boinc_delete_file(GLOBAL_PREFS_FILE_NAME); global_prefs.init(); } // find project and remove it from the vector // for (project_iter = projects.begin(); project_iter != projects.end(); project_iter++) { p = *project_iter; if (p == project) { projects.erase(project_iter); break; } } // delete account file // get_account_filename(project->master_url, path); retval = boinc_delete_file(path); // remove project directory and its contents // remove_project_dir(*project); delete project; write_state_file(); return 0; }