// This file is part of BOINC. // http://boinc.berkeley.edu // Copyright (C) 2008 University of California // // BOINC 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 3 of the License, or (at your option) any later version. // // BOINC 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. // // You should have received a copy of the GNU Lesser General Public License // along with BOINC. If not, see . #include "cpp.h" #ifdef _WIN32 #include "boinc_win.h" #else #include "config.h" #include #include #include #include #if HAVE_SYS_SOCKET_H #include #endif #endif #include "error_numbers.h" #include "filesys.h" #include "parse.h" #include "util.h" #include "client_msgs.h" #include "client_state.h" #include "file_names.h" #include "log_flags.h" #include "network.h" #ifdef SIM #include "sim.h" #endif #include "time_stats.h" #define CONNECTED_STATE_UNINITIALIZED -1 #define CONNECTED_STATE_NOT_CONNECTED 0 #define CONNECTED_STATE_CONNECTED 1 #define CONNECTED_STATE_UNKNOWN 2 #ifndef SIM #if defined(_WIN32) && ( !defined(__MINGW32__) || defined(HAVE_LIBSENSAPI) ) #include int get_connected_state() { DWORD flags; return IsNetworkAlive(&flags)?CONNECTED_STATE_CONNECTED:CONNECTED_STATE_NOT_CONNECTED; } #else // anyone know how to see if this host has physical network connection? // int get_connected_state() { return CONNECTED_STATE_UNKNOWN; } #endif #endif // exponential decay constant. // The last 10 days have a weight of 1/e; // everything before that has a weight of (1-1/e) const float ALPHA = (SECONDS_PER_DAY*10); //const float ALPHA = 60; // for testing // called before the client state file is parsed // void CLIENT_TIME_STATS::init() { // members of TIME_STATS now = 0; on_frac = 1; connected_frac = 1; cpu_and_network_available_frac = 1; active_frac = 1; gpu_active_frac = 1; client_start_time = gstate.now; previous_uptime = 0; session_active_duration = 0; session_gpu_active_duration = 0; total_start_time = 0; total_duration = 0; total_active_duration = 0; total_gpu_active_duration = 0; // members of CLIENT_TIME_STATS first = true; previous_connected_state = CONNECTED_STATE_UNINITIALIZED; last_update = 0; inactive_start = 0; trim_stats_log(); time_stats_log = NULL; } // if log file is over a meg, discard everything older than a year // void CLIENT_TIME_STATS::trim_stats_log() { #ifndef SIM double size; char buf[256]; int retval; double x; retval = file_size(TIME_STATS_LOG, size); if (retval) return; if (size < 1e6) return; FILE* f = fopen(TIME_STATS_LOG, "r"); if (!f) return; FILE* f2 = fopen(TEMP_TIME_STATS_FILE_NAME, "w"); if (!f2) { fclose(f); return; } while (fgets(buf, 256, f)) { int n = sscanf(buf, "%lf", &x); if (n != 1) continue; if (x < gstate.now-86400*365) continue; fputs(buf, f2); } fclose(f); fclose(f2); #endif } void send_log_after(const char* filename, double t, MIOFILE& mf) { char buf[256]; double x; FILE* f = fopen(filename, "r"); if (!f) return; while (fgets(buf, 256, f)) { int n = sscanf(buf, "%lf", &x); if (n != 1) continue; if (x < t) continue; mf.printf("%s", buf); } fclose(f); } // copy the log file after a given time // void CLIENT_TIME_STATS::get_log_after(double t, MIOFILE& mf) { if (time_stats_log) { fclose(time_stats_log); // win: can't open twice } send_log_after(TIME_STATS_LOG, t, mf); time_stats_log = fopen(TIME_STATS_LOG, "a"); } // Update time statistics based on current activities // NOTE: we don't set the state-file dirty flag here, // so these get written to disk only when other activities // cause this to happen. Maybe should change this. // void CLIENT_TIME_STATS::update(int suspend_reason, int _gpu_suspend_reason) { double dt, w1, w2; bool is_active = (suspend_reason == 0) || (suspend_reason == SUSPEND_REASON_CPU_THROTTLE); bool is_gpu_active = is_active && !_gpu_suspend_reason; if (total_start_time == 0) { total_start_time = gstate.now; } if (last_update == 0) { // this is the first time this client has executed. // Assume that everything is active on_frac = 1; connected_frac = 1; active_frac = 1; gpu_active_frac = 1; cpu_and_network_available_frac = 1; first = false; last_update = gstate.now; log_append("power_on", gstate.now); } else { dt = gstate.now - last_update; if (dt <= 10) return; if (dt > 14*86400) { // If dt is large it could be because user is upgrading // from a client version that wasn't updating due to bug. // Or it could be because user wasn't running for a while // and is starting up again. // In either case, don't decay on_frac. // dt = 0; } w1 = 1 - exp(-dt/ALPHA); // weight for recent period w2 = 1 - w1; // weight for everything before that // (close to zero if long gap) int connected_state; #ifdef SIM connected_state = CONNECTED_STATE_NOT_CONNECTED; #else connected_state = get_connected_state(); if (gstate.network_suspend_reason) { connected_state = CONNECTED_STATE_NOT_CONNECTED; } #endif if (first) { // the client has just started; this is the first call. // on_frac *= w2; first = false; log_append("power_off", last_update); char buf[256]; #ifndef SIM snprintf(buf, sizeof(buf), "platform %s", gstate.get_primary_platform() ); log_append(buf, gstate.now); #endif snprintf(buf, sizeof(buf), "version %d.%d.%d", BOINC_MAJOR_VERSION, BOINC_MINOR_VERSION, BOINC_RELEASE ); log_append(buf, gstate.now); log_append("power_on", gstate.now); } else if (dt > 100) { // large dt - the client or host must have been suspended on_frac *= w2; log_append("proc_stop", last_update); if (is_active) { log_append("proc_start", gstate.now); } } else { on_frac = w1 + w2*on_frac; cpu_and_network_available_frac *= w2; if (connected_frac < 0) connected_frac = 0; switch (connected_state) { case CONNECTED_STATE_NOT_CONNECTED: connected_frac *= w2; break; case CONNECTED_STATE_CONNECTED: connected_frac *= w2; connected_frac += w1; if (!gstate.network_suspended && !gstate.tasks_suspended) { cpu_and_network_available_frac += w1; } break; case CONNECTED_STATE_UNKNOWN: connected_frac = -1; if (!gstate.network_suspended && !gstate.tasks_suspended) { cpu_and_network_available_frac += w1; } } if (connected_state != previous_connected_state) { log_append_net(connected_state); previous_connected_state = connected_state; } active_frac *= w2; total_duration += dt; if (is_active) { active_frac += w1; if (inactive_start) { inactive_start = 0; log_append("proc_start", gstate.now); } session_active_duration += dt; total_active_duration += dt; } else if (inactive_start == 0){ inactive_start = gstate.now; log_append("proc_stop", gstate.now); } gpu_active_frac *= w2; if (is_gpu_active) { gpu_active_frac += w1; session_gpu_active_duration += dt; total_gpu_active_duration += dt; } //msg_printf(NULL, MSG_INFO, "is_active %d, active_frac %f", is_active, active_frac); } last_update = gstate.now; if (log_flags.time_debug) { msg_printf(0, MSG_INFO, "[time] dt %f susp_reason %d gpu_susp_reason %d", dt, suspend_reason, _gpu_suspend_reason ); msg_printf(0, MSG_INFO, "[time] w2 %f on %f; active %f; gpu_active %f; conn %f, cpu_and_net_avail %f", w2, on_frac, active_frac, gpu_active_frac, connected_frac, cpu_and_network_available_frac ); } } } // Write time statistics // to_remote means GUI RPC reply; else writing client state file // int CLIENT_TIME_STATS::write(MIOFILE& out, bool to_remote) { out.printf( "\n" " %f\n" " %f\n" " %f\n" " %f\n" " %f\n" " %f\n" " %f\n" " %f\n" " %f\n" " %f\n", on_frac, connected_frac, cpu_and_network_available_frac, active_frac, gpu_active_frac, client_start_time, total_start_time, total_duration, total_active_duration, total_gpu_active_duration ); if (to_remote) { out.printf( " %f\n" " %f\n" " %f\n" " %f\n", gstate.now, previous_uptime, session_active_duration, session_gpu_active_duration ); } else { out.printf( " %f\n" " %f\n", gstate.now - client_start_time, last_update ); } out.printf("\n"); return 0; } // Parse XML based time statistics from client_state.xml // int CLIENT_TIME_STATS::parse(XML_PARSER& xp) { double x; #ifdef SIM // mean unavailability is 1 hour // double on_lambda = 3600, connected_lambda = 3600; double active_lambda = 3600, gpu_active_lambda = 3600; #endif while (!xp.get_tag()) { if (xp.match_tag("/time_stats")) { #ifdef SIM on_proc.init(on_frac, on_lambda); connected_proc.init(connected_frac, connected_lambda); active_proc.init(active_frac, active_lambda); gpu_active_proc.init(gpu_active_frac, gpu_active_lambda); #endif return 0; } #ifdef SIM if (xp.parse_double("on_lambda", on_lambda)) continue; if (xp.parse_double("connected_lambda", connected_lambda)) continue; if (xp.parse_double("active_lambda", active_lambda)) continue; if (xp.parse_double("gpu_active_lambda", gpu_active_lambda)) continue; #endif if (xp.parse_double("last_update", x)) { if (x < 0 || x > gstate.now) { #ifndef SIM msg_printf(0, MSG_INTERNAL_ERROR, "bad value %f of time stats last update; ignoring", x ); #endif } else { last_update = x; } continue; } if (xp.parse_double("on_frac", x)) { if (x <= 0 || x > 1) { msg_printf(0, MSG_INTERNAL_ERROR, "bad value %f of time stats on_frac; ignoring", x ); } else { on_frac = x; } continue; } if (xp.parse_double("connected_frac", x)) { // -1 means undefined; skip check connected_frac = x; continue; } if (xp.parse_double("cpu_and_network_available_frac", x)) { if (x <= 0 || x > 1) { msg_printf(0, MSG_INTERNAL_ERROR, "bad value %f of time stats cpu_and_network_available_frac; ignoring", x ); } else { cpu_and_network_available_frac = x; } continue; } if (xp.parse_double("active_frac", x)) { if (x <= 0 || x > 1) { msg_printf(0, MSG_INTERNAL_ERROR, "bad value %f of time stats active_frac; ignoring", x ); } else { active_frac = x; } continue; } if (xp.parse_double("gpu_active_frac", x)) { if (x <= 0 || x > 1) { msg_printf(0, MSG_INTERNAL_ERROR, "bad value %f of time stats gpu_active_frac; ignoring", x ); } else { gpu_active_frac = x; } continue; } if (xp.parse_double("client_start_time", x)) continue; if (xp.parse_double("previous_uptime", previous_uptime)) continue; if (xp.parse_double("total_start_time", total_start_time)) continue; if (xp.parse_double("total_duration", total_duration)) continue; if (xp.parse_double("total_active_duration", total_active_duration)) continue; if (xp.parse_double("total_gpu_active_duration", total_gpu_active_duration)) continue; if (log_flags.unparsed_xml) { msg_printf(0, MSG_INFO, "[unparsed_xml] TIME_STATS::parse(): unrecognized: %s\n", xp.parsed_tag ); } } return ERR_XML_PARSE; } void CLIENT_TIME_STATS::start() { time_stats_log = fopen(TIME_STATS_LOG, "a"); if (time_stats_log) { setbuf(time_stats_log, 0); } } void CLIENT_TIME_STATS::quit() { log_append("power_off", gstate.now); } #ifdef SIM void CLIENT_TIME_STATS::log_append(const char* , double ) {} #else void CLIENT_TIME_STATS::log_append(const char* msg, double t) { if (!time_stats_log) return; fprintf(time_stats_log, "%f %s\n", t, msg); } #endif void CLIENT_TIME_STATS::log_append_net(int new_state) { switch(new_state) { case CONNECTED_STATE_NOT_CONNECTED: log_append("net_not_connected", gstate.now); break; case CONNECTED_STATE_CONNECTED: log_append("net_connected", gstate.now); break; case CONNECTED_STATE_UNKNOWN: log_append("net_unknown", gstate.now); break; } }