// 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., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA // scheduler code related to sending work #include "config.h" #include #include #include #include #include using namespace std; #include #include "error_numbers.h" #include "parse.h" #include "server_types.h" #include "sched_shmem.h" #include "sched_config.h" #include "sched_util.h" #include "main.h" #include "sched_array.h" #include "sched_msgs.h" #include "sched_send.h" #include "sched_locality.h" #include "sched_timezone.h" #ifdef _USING_FCGI_ #include "fcgi_stdio.h" #else #define FCGI_ToFILE(x) (x) #endif const int MIN_SECONDS_TO_SEND = 0; const int MAX_SECONDS_TO_SEND = (28*SECONDS_IN_DAY); const double MIN_POSSIBLE_RAM = 64000000; bool anonymous(PLATFORM& platform) { return (!strcmp(platform.name, "anonymous")); } bool SCHEDULER_REQUEST::has_version(APP& app) { unsigned int i; for (i=0; i= app.min_version) { return true; } } return false; } // Find the app and app_version for the client's platform. // int get_app_version( WORKUNIT& wu, APP* &app, APP_VERSION* &avp, SCHEDULER_REQUEST& sreq, SCHEDULER_REPLY& reply, PLATFORM& platform, SCHED_SHMEM& ss ) { bool found; if (anonymous(platform)) { app = ss.lookup_app(wu.appid); found = sreq.has_version(*app); if (!found) { log_messages.printf(SCHED_MSG_LOG::MSG_DEBUG, "Didn't find anonymous app\n" ); return ERR_NO_APP_VERSION; } avp = NULL; } else { found = find_app_version(reply.wreq, wu, platform, ss, app, avp); if (!found) { log_messages.printf(SCHED_MSG_LOG::MSG_DEBUG, "Didn't find app version\n"); return ERR_NO_APP_VERSION; } // see if the core client is too old. // if (!app_core_compatible(reply.wreq, *avp)) { log_messages.printf(SCHED_MSG_LOG::MSG_DEBUG, "Didn't find app version: core client too old\n"); return ERR_NO_APP_VERSION; } } return 0; } // Compute the max additional disk usage we can impose on the host. // Depending on the client version, it can either send us // - d_total and d_free (pre 4 oct 2005) // - the above plus d_boinc_used_total and d_boinc_used_project // double max_allowable_disk(SCHEDULER_REQUEST& req, SCHEDULER_REPLY& reply) { HOST host = req.host; GLOBAL_PREFS prefs = req.global_prefs; double x1, x2, x3, x; // fill in default values for missing prefs // if (prefs.disk_max_used_gb == 0) prefs.disk_max_used_gb = 100.0; // 100 GB if (prefs.disk_max_used_pct == 0) prefs.disk_max_used_pct = 50; // 50% // Always leave at least 1MB free! if (prefs.disk_min_free_gb < 0.001) prefs.disk_min_free_gb = 0.001; // 1MB // no defaults for total/free disk space (host.d_total, d_free) // if they're zero, client will get no work. // if (host.d_boinc_used_total) { // The post 4 oct 2005 case. // Compute the max allowable additional disk usage based on prefs // x1 = prefs.disk_max_used_gb*1e9 - host.d_boinc_used_total; x2 = host.d_total*prefs.disk_max_used_pct/100. - host.d_boinc_used_total; x3 = host.d_free - prefs.disk_min_free_gb*1e9; // may be negative x = min(x1, min(x2, x3)); // see which bound is the most stringent // if (x==x1) { reply.disk_limits.max_used = x; } else if (x==x2) { reply.disk_limits.max_frac = x; } else { reply.disk_limits.min_free = x; } } else { // here we don't know how much space BOINC is using. // so we're kinda screwed. // All we can do is assume that BOINC is using zero space. // We can't honor the max_used for max_used_pct preferences. // We can only honor the min_free pref. // x = host.d_free - prefs.disk_min_free_gb*1e9; // may be negative reply.disk_limits.min_free = x; x1 = x2 = x3 = 0; } //if (true) { if (x < 0) { log_messages.printf( SCHED_MSG_LOG::MSG_NORMAL, "disk_max_used_gb %f disk_max_used_pct %f disk_min_free_gb %f\n", prefs.disk_max_used_gb, prefs.disk_max_used_pct, prefs.disk_min_free_gb ); log_messages.printf( SCHED_MSG_LOG::MSG_NORMAL, "host.d_total %f host.d_free %f host.d_boinc_used_total %f\n", host.d_total, host.d_free, host.d_boinc_used_total ); log_messages.printf( SCHED_MSG_LOG::MSG_NORMAL, "x1 %f x2 %f x3 %f x %f\n", x1, x2, x3, x ); } return x; } // if a host has active_frac < 0.1, assume 0.1 so we don't deprive it of work. // const double HOST_ACTIVE_FRAC_MIN = 0.1; // estimate the number of CPU seconds that a workunit requires // running on this host. // double estimate_cpu_duration(WORKUNIT& wu, SCHEDULER_REPLY& reply) { double p_fpops = reply.host.p_fpops; if (p_fpops <= 0) p_fpops = 1e9; double rsc_fpops_est = wu.rsc_fpops_est; if (rsc_fpops_est <= 0) rsc_fpops_est = 1e12; return rsc_fpops_est/p_fpops; } // estimate the amount of real time to complete this WU, // taking into account active_frac etc. // Note: don't factor in resource_share_fraction. // The core client no longer necessarily does round-robin // across all projects. // static double estimate_wallclock_duration( WORKUNIT& wu, SCHEDULER_REQUEST& request, SCHEDULER_REPLY& reply ) { double running_frac; if (reply.wreq.core_client_version<=419) { running_frac = reply.host.on_frac; } else { running_frac = reply.host.active_frac * reply.host.on_frac; } if (running_frac < HOST_ACTIVE_FRAC_MIN) { running_frac = HOST_ACTIVE_FRAC_MIN; } if (running_frac > 1) running_frac = 1; double ecd = estimate_cpu_duration(wu, reply); double ewd = ecd/running_frac; if (reply.host.duration_correction_factor) { ewd *= reply.host.duration_correction_factor; } if (reply.host.cpu_efficiency) { ewd /= reply.host.cpu_efficiency; } #ifdef EINSTEIN_AT_HOME log_messages.printf( SCHED_MSG_LOG::MSG_DEBUG, "est cpu dur %f; running_frac %f; rsf %f; est %f\n", ecd, running_frac, request.resource_share_fraction, ewd ); #endif return ewd; } // if the WU can't be executed on the host, return a bitmap of reasons why. // Reasons include: // 1) the host doesn't have enough memory; // 2) the host doesn't have enough disk space; // 3) based on CPU speed, resource share and estimated delay, // the host probably won't get the result done within the delay bound // // NOTE: This is a "fast" check; no DB access allowed. // In particular it doesn't enforce the one-result-per-user-per-wu rule // int wu_is_infeasible( WORKUNIT& wu, SCHEDULER_REQUEST& request, SCHEDULER_REPLY& reply ) { int reason = 0; double m_nbytes = reply.host.m_nbytes; if (m_nbytes < MIN_POSSIBLE_RAM) m_nbytes = MIN_POSSIBLE_RAM; if (wu.rsc_memory_bound > m_nbytes) { log_messages.printf( SCHED_MSG_LOG::MSG_DEBUG, "[WU#%d %s] needs %f mem; [HOST#%d] has %f\n", wu.id, wu.name, wu.rsc_memory_bound, reply.host.id, m_nbytes ); char explanation[256]; if (!reply.wreq.insufficient_mem) { // only add message once // sprintf(explanation, "Your computer has only %.0f bytes of memory; workunit requires %.0f more bytes", m_nbytes, wu.rsc_memory_bound-m_nbytes ); USER_MESSAGE um(explanation, "high"); reply.insert_message(um); } reply.wreq.insufficient_mem = true; reason |= INFEASIBLE_MEM; reply.set_delay(24*3600); } if (wu.rsc_disk_bound > reply.wreq.disk_available) { reply.wreq.insufficient_disk = true; reason |= INFEASIBLE_DISK; } // skip delay check if host currently doesn't have any work // (i.e. everyone gets one result, no matter how slow they are) // if (!config.ignore_delay_bound && request.estimated_delay>0) { double ewd = estimate_wallclock_duration(wu, request, reply); if (request.estimated_delay + ewd > wu.delay_bound) { log_messages.printf( SCHED_MSG_LOG::MSG_DEBUG, "[WU#%d %s] needs %d seconds on [HOST#%d]; delay_bound is %d (request.estimated_delay is %f)\n", wu.id, wu.name, (int)ewd, reply.host.id, wu.delay_bound, request.estimated_delay ); reply.set_delay(0.2*request.estimated_delay); reply.wreq.insufficient_speed = true; reason |= INFEASIBLE_CPU; } } return reason; } // insert "text" right after "after" in the given buffer // int insert_after(char* buffer, const char* after, const char* text) { char* p; char temp[LARGE_BLOB_SIZE]; if (strlen(buffer) + strlen(text) > LARGE_BLOB_SIZE-1) { log_messages.printf(SCHED_MSG_LOG::MSG_NORMAL, "insert_after: overflow\n" ); return ERR_BUFFER_OVERFLOW; } p = strstr(buffer, after); if (!p) { log_messages.printf(SCHED_MSG_LOG::MSG_CRITICAL, "insert_after: %s not found in %s\n", after, buffer ); return ERR_NULL; } p += strlen(after); strcpy(temp, p); strcpy(p, text); strcat(p, temp); return 0; } // add elements to WU's xml_doc, // in preparation for sending it to a client // int insert_wu_tags(WORKUNIT& wu, APP& app) { char buf[LARGE_BLOB_SIZE]; sprintf(buf, " %f\n" " %f\n" " %f\n" " %f\n" " %s\n" " %s\n", wu.rsc_fpops_est, wu.rsc_fpops_bound, wu.rsc_memory_bound, wu.rsc_disk_bound, wu.name, app.name ); return insert_after(wu.xml_doc, "\n", buf); } // return the APP and APP_VERSION for the given WU, for the given platform. // return false if none // bool find_app_version( WORK_REQ& wreq, WORKUNIT& wu, PLATFORM& platform, SCHED_SHMEM& ss, APP*& app, APP_VERSION*& avp ) { app = ss.lookup_app(wu.appid); if (!app) { log_messages.printf( SCHED_MSG_LOG::MSG_CRITICAL, "Can't find APP#%d\n", wu.appid ); return false; } avp = ss.lookup_app_version(app->id, platform.id, app->min_version); if (!avp) { log_messages.printf( SCHED_MSG_LOG::MSG_DEBUG, "no app version available: APP#%d PLATFORM#%d min_version %d\n", app->id, platform.id, app->min_version ); wreq.no_app_version = true; return false; } return true; } // verify that the given APP_VERSION will work with the core client // bool app_core_compatible(WORK_REQ& wreq, APP_VERSION& av) { if (wreq.core_client_version < av.min_core_version) { #if 0 log_messages.printf( SCHED_MSG_LOG::MSG_DEBUG, "Outdated core version: wanted %d, got %d\n", av.min_core_version, wreq.core_client_version ); #endif wreq.outdated_core = true; return false; } return true; } // add the given workunit to a reply. // look up its app, and make sure there's a version for this platform. // Add the app and app_version to the reply also. // int add_wu_to_reply( WORKUNIT& wu, SCHEDULER_REPLY& reply, PLATFORM& platform, APP* app, APP_VERSION* avp ) { int retval; WORKUNIT wu2, wu3; // add the app, app_version, and workunit to the reply, // but only if they aren't already there // if (avp) { APP_VERSION av2=*avp, *avp2=&av2; if (config.choose_download_url_by_timezone) { process_av_timezone(reply, avp, av2); } reply.insert_app_unique(*app); reply.insert_app_version_unique(*avp2); log_messages.printf( SCHED_MSG_LOG::MSG_DEBUG, "[HOST#%d] Sending app_version %s %s %d\n", reply.host.id, app->name, platform.name, avp2->version_num ); } // add time estimate to reply // wu2 = wu; // make copy since we're going to modify its XML field retval = insert_wu_tags(wu2, *app); if (retval) { log_messages.printf(SCHED_MSG_LOG::MSG_NORMAL, "insert_wu_tags failed\n"); return retval; } wu3=wu2; if (config.choose_download_url_by_timezone) { process_wu_timezone(reply, wu2, wu3); } reply.insert_workunit_unique(wu3); // switch to tighter policy for estimating delay // return 0; } int insert_name_tags(RESULT& result, WORKUNIT const& wu) { char buf[256]; int retval; sprintf(buf, "%s\n", result.name); retval = insert_after(result.xml_doc_in, "\n", buf); if (retval) return retval; sprintf(buf, "%s\n", wu.name); retval = insert_after(result.xml_doc_in, "\n", buf); if (retval) return retval; return 0; } int insert_deadline_tag(RESULT& result) { char buf[256]; sprintf(buf, "%d\n", result.report_deadline); int retval = insert_after(result.xml_doc_in, "\n", buf); if (retval) return retval; return 0; } int update_wu_transition_time(WORKUNIT wu, time_t x) { DB_WORKUNIT dbwu; char buf[256]; dbwu.id = wu.id; // SQL note: can't use min() here // sprintf(buf, "transition_time=if(transition_time<%d, transition_time, %d)", (int)x, (int)x ); return dbwu.update_field(buf); } // return true iff a result for same WU is already being sent // bool wu_already_in_reply(WORKUNIT& wu, SCHEDULER_REPLY& reply) { unsigned int i; for (i=0; i= config.max_wus_to_send) return false; // config.daily_result_quota is PER CPU (up to max of four CPUs) // host.max_results_day is between 1 and config.daily_result_quota inclusive // wreq.daily_result_quota is between ncpus and ncpus*host.max_results_day inclusive if (config.daily_result_quota) { if (host.max_results_day <= 0 || host.max_results_day>config.daily_result_quota) { host.max_results_day = config.daily_result_quota; } // scale daily quota by #CPUs, up to a limit of 4 // int ncpus = host.p_ncpus; if (ncpus > 4) ncpus = 4; if (ncpus < 1) ncpus = 1; wreq.daily_result_quota = ncpus*host.max_results_day; if (host.nresults_today >= wreq.daily_result_quota) { wreq.daily_result_quota_exceeded = true; return false; } } return true; } void SCHEDULER_REPLY::got_good_result() { host.max_results_day *= 2; if (host.max_results_day > config.daily_result_quota) { host.max_results_day = config.daily_result_quota; } } void SCHEDULER_REPLY::got_bad_result() { host.max_results_day -= 1; if (host.max_results_day < 1) { host.max_results_day = 1; } } int add_result_to_reply( DB_RESULT& result, WORKUNIT& wu, SCHEDULER_REQUEST& request, SCHEDULER_REPLY& reply, PLATFORM& platform, APP* app, APP_VERSION* avp ) { int retval; double wu_seconds_filled; bool resent_result = false; retval = add_wu_to_reply(wu, reply, platform, app, avp); if (retval) return retval; // in the scheduling locality case, // reduce the available space by LESS than the workunit rsc_disk_bound, // IF the host already has the file OR the file was not already sent. // if (!config.locality_scheduling || decrement_disk_space_locality(wu, request, reply) ) { reply.wreq.disk_available -= wu.rsc_disk_bound; } // update the result in DB // result.hostid = reply.host.id; result.userid = reply.user.id; result.sent_time = time(0); if (result.server_state != RESULT_SERVER_STATE_IN_PROGRESS) { // We are sending this result for the first time // result.report_deadline = result.sent_time + wu.delay_bound; result.server_state = RESULT_SERVER_STATE_IN_PROGRESS; } else { // Result was ALREADY sent to this host but never arrived. // So we are resending it. // result.report_deadline and time_sent // have already been updated before this function was called. // resent_result = true; if (result.report_deadline < result.sent_time) { result.report_deadline = result.sent_time + 10; } if (result.report_deadline > result.sent_time + wu.delay_bound) { result.report_deadline = result.sent_time + wu.delay_bound; } log_messages.printf( SCHED_MSG_LOG::MSG_DEBUG, "[RESULT#%d] [HOST#%d] (resend lost work)\n", result.id, reply.host.id ); } retval = result.update_subset(); if (retval) { log_messages.printf( SCHED_MSG_LOG::MSG_CRITICAL, "add_result_to_reply: can't update result: %d\n", retval ); return retval; } wu_seconds_filled = estimate_wallclock_duration(wu, request, reply); log_messages.printf( SCHED_MSG_LOG::MSG_NORMAL, "[HOST#%d] Sending [RESULT#%d %s] (fills %.2f seconds)\n", reply.host.id, result.id, result.name, wu_seconds_filled ); retval = update_wu_transition_time(wu, result.report_deadline); if (retval) { log_messages.printf( SCHED_MSG_LOG::MSG_CRITICAL, "add_result_to_reply: can't update WU transition time: %d\n", retval ); return retval; } // The following overwrites the result's xml_doc field. // But that's OK cuz we're done with DB updates // retval = insert_name_tags(result, wu); if (retval) { log_messages.printf( SCHED_MSG_LOG::MSG_CRITICAL, "send_work: can't insert name tags: %d\n", retval ); return retval; } retval = insert_deadline_tag(result); if (retval) { log_messages.printf( SCHED_MSG_LOG::MSG_CRITICAL, "send_work: can't insert deadline tag: %d\n", retval ); return retval; } reply.insert_result(result); reply.wreq.seconds_to_fill -= wu_seconds_filled; request.estimated_delay += wu_seconds_filled/reply.host.p_ncpus; reply.wreq.nresults++; if (!resent_result) reply.host.nresults_today++; return 0; } int send_work( SCHEDULER_REQUEST& sreq, SCHEDULER_REPLY& reply, PLATFORM& platform, SCHED_SHMEM& ss ) { #if 1 reply.wreq.disk_available = max_allowable_disk(sreq, reply); #else reply.wreq.disk_available = sreq.project_disk_free; #endif reply.wreq.insufficient_disk = false; reply.wreq.insufficient_mem = false; reply.wreq.insufficient_speed = false; reply.wreq.excessive_work_buf = false; reply.wreq.no_app_version = false; reply.wreq.hr_reject_temp = false; reply.wreq.hr_reject_perm = false; reply.wreq.daily_result_quota_exceeded = false; reply.wreq.core_client_version = sreq.core_client_major_version*100 + sreq.core_client_minor_version; reply.wreq.nresults = 0; log_messages.printf( SCHED_MSG_LOG::MSG_NORMAL, "[HOST#%d] got request for %f seconds of work; available disk %f GB\n", reply.host.id, sreq.work_req_seconds, reply.wreq.disk_available/1e9 ); if (sreq.work_req_seconds <= 0) return 0; reply.wreq.seconds_to_fill = sreq.work_req_seconds; if (reply.wreq.seconds_to_fill > MAX_SECONDS_TO_SEND) { reply.wreq.seconds_to_fill = MAX_SECONDS_TO_SEND; } if (reply.wreq.seconds_to_fill < MIN_SECONDS_TO_SEND) { reply.wreq.seconds_to_fill = MIN_SECONDS_TO_SEND; } // TODO: add code to send results that were sent earlier but not reported. // Cautions (from John McLeod): // - make sure the result is still needed // - don't send if the project has been reset since first send, // since result may have been cause of the reset // (need to pass reset time?) // - make sure can complete by deadline // - don't send if project is suspended or "no more work" on client // (need to pass these) if (config.locality_scheduling) { reply.wreq.infeasible_only = false; send_work_locality(sreq, reply, platform, ss); } else { // give priority to results that were infeasible for some other host // reply.wreq.infeasible_only = true; scan_work_array(sreq, reply, platform, ss); reply.wreq.infeasible_only = false; scan_work_array(sreq, reply, platform, ss); } log_messages.printf( SCHED_MSG_LOG::MSG_NORMAL, "[HOST#%d] Sent %d results [scheduler ran %f seconds]\n", reply.host.id, reply.wreq.nresults, elapsed_wallclock_time() ); if (reply.wreq.nresults == 0) { reply.set_delay(3600); USER_MESSAGE um2("No work sent", "high"); reply.insert_message(um2); if (reply.wreq.no_app_version) { USER_MESSAGE um("(there was work for other platforms)", "high"); reply.insert_message(um); reply.set_delay(3600*24); } if (reply.wreq.insufficient_disk) { USER_MESSAGE um( "(there was work but you don't have enough disk space allocated)", "high" ); reply.insert_message(um); } if (reply.wreq.insufficient_mem) { USER_MESSAGE um( "(there was work but your computer doesn't have enough memory)", "high" ); reply.set_delay(24*3600); reply.insert_message(um); } if (reply.wreq.insufficient_speed) { char helpful[512]; if (reply.wreq.core_client_version>419) { sprintf(helpful, "(won't finish in time) " "Computer on %.1f%% of time, BOINC on %.1f%% of that, this project gets %.1f%% of that", 100.0*reply.host.on_frac, 100.0*reply.host.active_frac, 100.0*sreq.resource_share_fraction ); } else { sprintf(helpful, "(won't finish in time) " "Computer available %.1f%% of time, this project gets %.1f%% of that", 100.0*reply.host.on_frac, 100.0*sreq.resource_share_fraction ); } USER_MESSAGE um(helpful, "high"); reply.insert_message(um); } if (reply.wreq.hr_reject_temp) { USER_MESSAGE um( "(there was work but it was committed to other platforms)", "high" ); reply.insert_message(um); } if (reply.wreq.hr_reject_perm) { USER_MESSAGE um( "(your platform is not supported by this project)", "high" ); reply.insert_message(um); } if (reply.wreq.outdated_core) { USER_MESSAGE um( " (your core client is out of date - please upgrade)", "high" ); reply.insert_message(um); reply.set_delay(3600*24); log_messages.printf( SCHED_MSG_LOG::MSG_NORMAL, "Not sending work because core client is outdated\n" ); } if (reply.wreq.excessive_work_buf) { USER_MESSAGE um( "(Your network connection interval is longer than WU deadline)", "high" ); reply.insert_message(um); } if (reply.wreq.daily_result_quota_exceeded) { char helpful[256]; struct tm *rpc_time_tm; int delay_time; sprintf(helpful, "(reached daily quota of %d results)", reply.wreq.daily_result_quota); USER_MESSAGE um(helpful, "high"); reply.insert_message(um); log_messages.printf( SCHED_MSG_LOG::MSG_NORMAL, "Daily result quota exceeded for host %d\n", reply.host.id ); // set delay so host won't return until a random time in // the first hour of 'the next day'. This is to prevent a // lot of hosts from flooding the scheduler with requests // at the same time of day. rpc_time_tm = localtime((const time_t*)&reply.host.rpc_time); delay_time = (23 - rpc_time_tm->tm_hour) * 3600 + (59 - rpc_time_tm->tm_min) * 60 + (60 - rpc_time_tm->tm_sec) + (int)(3600*(double)rand()/(double)RAND_MAX); reply.set_delay(delay_time); } } return 0; } const char *BOINC_RCSID_32dcd335e7 = "$Id$";