boinc/client/cs_scheduler.C

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// 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
// High-level logic for communicating with scheduling servers,
// and for merging the result of a scheduler RPC into the client state
// The scheduler RPC mechanism is in scheduler_op.C
#include "cpp.h"
#ifdef _WIN32
#include "boinc_win.h"
#endif
#ifndef _WIN32
#include <stdio.h>
#include <math.h>
#include <time.h>
#include <strings.h>
#include <map>
#include <set>
#endif
#include "crypt.h"
#include "error_numbers.h"
#include "file_names.h"
#include "filesys.h"
#include "parse.h"
#include "util.h"
#include "client_msgs.h"
#include "scheduler_op.h"
#include "client_state.h"
using std::max;
using std::vector;
using std::string;
static double trs;
//#define DEBUG_SCHED 1
// quantities like avg CPU time decay by a factor of e every week
//
#define EXP_DECAY_RATE (1./(SECONDS_PER_DAY*7))
// how often to show user "backing off" messages
//
const int SECONDS_BEFORE_REPORTING_MIN_RPC_TIME_AGAIN = 60*60;
// try to report results this much before their deadline
//
#define REPORT_DEADLINE_CUSHION SECONDS_PER_DAY
// try to maintain no more than this load factor on the CPU.
//
#define MAX_CPU_LOAD_FACTOR 0.8
static int proj_min_results(PROJECT* p, int ncpus) {
return (int)(ceil(ncpus*p->resource_share/trs));
}
void PROJECT::set_min_rpc_time(double future_time) {
if (future_time > min_rpc_time) {
min_rpc_time = future_time;
}
min_report_min_rpc_time = 0;
}
// Return true iff we should not contact the project yet.
// Print a message to the user if we haven't recently
//
bool PROJECT::waiting_until_min_rpc_time(double now) {
if (min_rpc_time > now ) {
if (now >= min_report_min_rpc_time) {
min_report_min_rpc_time = now + SECONDS_BEFORE_REPORTING_MIN_RPC_TIME_AGAIN;
msg_printf(
this, MSG_ERROR,
"Deferring communication with project for %s\n",
timediff_format(min_rpc_time - now).c_str()
);
}
return true;
}
return false;
}
// find a project that needs to have its master file fetched
//
PROJECT* CLIENT_STATE::next_project_master_pending() {
unsigned int i;
PROJECT* p;
double now = dtime();
for (i=0; i<projects.size(); i++) {
p = projects[i];
if (p->waiting_until_min_rpc_time(now)) continue;
if (p->suspended_via_gui) continue;
if (p->master_url_fetch_pending) {
return p;
}
}
return 0;
}
// find a project that needs to contact its scheduling server
//
PROJECT* CLIENT_STATE::next_project_sched_rpc_pending() {
unsigned int i;
double now = dtime();
PROJECT* p;
for (i=0; i<projects.size(); i++) {
p = projects[i];
if (p->waiting_until_min_rpc_time(now)) continue;
if (p->suspended_via_gui) continue;
if (p->sched_rpc_pending) {
return p;
}
}
return 0;
}
// return the next project after "old" that
// 1) is eligible for a scheduler RPC
// 2) has work_request > 0
// 3) has master_url_fetch_pending == false
// 4) has dont_request_more_work == false
//
PROJECT* CLIENT_STATE::next_project_need_work(PROJECT *old) {
PROJECT *p, *p_prospect = NULL;
double work_on_prospect;
double now = dtime();
unsigned int i;
bool found_old = (old == 0);
for (i=0; i<projects.size(); ++i) {
p = projects[i];
double work_on_current = ettprc(p, 0);
if (p == old) {
found_old = true;
continue;
}
if (p->master_url_fetch_pending) continue;
if (p->waiting_until_min_rpc_time(now)) continue;
if (p->suspended_via_gui) continue;
if (p->dont_request_more_work) continue;
if (p->long_term_debt < 0 && !no_work_for_a_cpu()) continue;
if (p_prospect && p->long_term_debt - work_on_current < p_prospect->long_term_debt - work_on_prospect) continue;
if (p->non_cpu_intensive) continue;
if (found_old && p->work_request > 0) {
p_prospect = p;
work_on_prospect = work_on_current;
}
}
return p_prospect;
}
// Write a scheduler request to a disk file
// (later sent to the scheduling server)
//
int CLIENT_STATE::make_scheduler_request(PROJECT* p, double work_req) {
char buf[1024];
get_sched_request_filename(*p, buf);
FILE* f = boinc_fopen(buf, "wb");
MIOFILE mf;
unsigned int i;
RESULT* rp;
int retval;
#if 0
double free, possible;
#endif
trs = total_resource_share();
if (!f) return ERR_FOPEN;
mf.init_file(f);
fprintf(f,
"<scheduler_request>\n"
" <authenticator>%s</authenticator>\n"
" <hostid>%d</hostid>\n"
" <rpc_seqno>%d</rpc_seqno>\n"
" <platform_name>%s</platform_name>\n"
" <core_client_major_version>%d</core_client_major_version>\n"
" <core_client_minor_version>%d</core_client_minor_version>\n"
" <work_req_seconds>%f</work_req_seconds>\n"
" <resource_share_fraction>%f</resource_share_fraction>\n"
" <estimated_delay>%f</estimated_delay>\n",
p->authenticator,
p->hostid,
p->rpc_seqno,
p->anonymous_platform?"anonymous":platform_name,
core_client_major_version,
core_client_minor_version,
work_req,
p->resource_share / trs,
ettprc(p, proj_min_results(p, ncpus)-1)
);
if (p->anonymous_platform) {
fprintf(f, " <app_versions>\n");
for (i=0; i<app_versions.size(); i++) {
APP_VERSION* avp = app_versions[i];
if (avp->project != p) continue;
avp->write(mf);
}
fprintf(f, " </app_versions>\n");
}
#if 0
anything_free(free);
fprintf(f, " <project_disk_free>%f</project_disk_free>\n", free);
total_potential_offender(p, possible);
fprintf(f, " <potentially_free_offender>%f</potentially_free_offender>\n", possible);
total_potential_self(p, possible);
fprintf(f, " <potentially_free_self>%f</potentially_free_self>\n", possible);
#endif
if (strlen(p->code_sign_key)) {
fprintf(f, " <code_sign_key>\n%s</code_sign_key>\n", p->code_sign_key);
}
// insert global preferences if present
//
if (boinc_file_exists(GLOBAL_PREFS_FILE_NAME)) {
FILE* fprefs = fopen(GLOBAL_PREFS_FILE_NAME, "r");
if (fprefs) {
copy_stream(fprefs, f);
fclose(fprefs);
}
PROJECT* pp = lookup_project(global_prefs.source_project);
if (pp && strlen(pp->email_hash)) {
fprintf(f,
"<global_prefs_source_email_hash>%s</global_prefs_source_email_hash>\n",
pp->email_hash
);
}
}
// Of the projects with same email hash as this one,
// send the oldest cross-project ID.
// Use project URL as tie-breaker.
//
PROJECT* winner = p;
for (i=0; i<projects.size(); i++ ) {
PROJECT* project = projects[i];
if (project == p) continue;
if (strcmp(project->email_hash, p->email_hash)) continue;
if (project->user_create_time < winner->user_create_time) {
winner = project;
} else if (project->user_create_time == winner->user_create_time) {
if (strcmp(project->master_url, winner->master_url) < 0) {
winner = project;
}
}
}
fprintf(f,
"<cross_project_id>%s</cross_project_id>\n",
winner->cross_project_id
);
retval = time_stats.write(mf, true);
if (retval) return retval;
retval = net_stats.write(mf);
if (retval) return retval;
retval = host_info.write(mf);
if (retval) return retval;
for (i=0; i<results.size(); i++) {
rp = results[i];
if (rp->project == p && rp->ready_to_report) {
rp->write(mf, true);
}
}
read_trickle_files(p, f);
// report sticky files as needed
//
for (i=0; i<file_infos.size(); i++) {
FILE_INFO* fip = file_infos[i];
if (fip->project != p) continue;
if (!fip->report_on_rpc) continue;
if (fip->marked_for_delete) continue;
fprintf(f,
" <file_info>\n"
" <name>%s</name>\n"
" <nbytes>%f</nbytes>\n"
" <status>%d</status>\n"
" <report_on_rpc/>\n"
" </file_info>\n",
fip->name, fip->nbytes, fip->status
);
}
fprintf(f, "</scheduler_request>\n");
fclose(f);
return 0;
}
// find a project with results that are overdue to report,
// and which we're allowed to contact.
//
PROJECT* CLIENT_STATE::find_project_with_overdue_results() {
unsigned int i;
RESULT* r;
double now = dtime();
for (i=0; i<results.size(); i++) {
r = results[i];
// return the project for this result to report if:
// - we're not backing off a scheduler request for its project
// - we're ready_to_report (compute done; files uploaded)
// - we're almost at the report_deadline
//
PROJECT* p = r->project;
if (p->waiting_until_min_rpc_time(now)) continue;
if (p->suspended_via_gui) continue;
if (!r->ready_to_report) continue;
if (return_results_immediately ||
(r->report_deadline <= (now + REPORT_DEADLINE_CUSHION))
) {
return p;
}
}
return 0;
}
#if 0
// return true if we're allowed to do a scheduler RPC to at least one project
//
bool CLIENT_STATE::some_project_rpc_ok() {
unsigned int i;
double now = dtime();
for (i=0; i<projects.size(); i++) {
if (projects[i]->min_rpc_time < now) return true;
}
return false;
}
#endif
// return the expected number of CPU seconds completed by the client
// for project p in a second of wall-clock time.
// May be > 1 on a multiprocessor.
//
double CLIENT_STATE::avg_proc_rate(PROJECT *p) {
double running_frac = time_stats.on_frac * time_stats.active_frac;
if (running_frac < 0.1) running_frac = 0.1;
if (running_frac > 1) running_frac = 1;
return (p ? (p->resource_share / trs) : 1) * ncpus * running_frac;
}
// "estimated time to project result count"
// return the estimated wall-clock time until the
// number of results for project p will reach k
//
double CLIENT_STATE::ettprc(PROJECT *p, int k) {
int num_results_to_skip = k;
double est = 0;
// total up the estimated time for this project's unstarted
// and partially completed results,
// omitting the last k
//
for (vector<RESULT*>::reverse_iterator iter = results.rbegin();
iter != results.rend(); iter++
) {
RESULT *rp = *iter;
if (rp->project != p
|| rp->state > RESULT_FILES_DOWNLOADED
|| rp->ready_to_report
) continue;
if (num_results_to_skip > 0) {
--num_results_to_skip;
continue;
}
est += rp->estimated_cpu_time_remaining();
}
double apr = avg_proc_rate(p);
return est/apr;
}
// set work_request for each project and return the urgency level for
// requesting more work
// only set non-zero work requests for projects that are allowed to do
// a scheduler RPC
//
int CLIENT_STATE::compute_work_requests() {
int urgency = DONT_NEED_WORK;
unsigned int i;
double work_min_period = global_prefs.work_buf_min_days * SECONDS_PER_DAY;
double now = dtime();
trs = total_resource_share();
// for each project, compute
// min_results = min # of results for project needed by CPU scheduling,
// to avoid "starvation".
// Then estimate how long it's going to be until we have fewer
// than this # of results remaining.
//
for (i=0; i<projects.size(); ++i) {
PROJECT *p = projects[i];
p->work_request = 0;
if (p->min_rpc_time >= now) continue;
if (p->dont_request_more_work) continue;
if (p->suspended_via_gui) continue;
if (p->long_term_debt < 0 && !no_work_for_a_cpu()) continue;
int min_results = proj_min_results(p, ncpus);
double estimated_time_to_starvation = ettprc(p, min_results-1);
// determine urgency
//
if (estimated_time_to_starvation < work_min_period) {
if (estimated_time_to_starvation == 0) {
#if DEBUG_SCHED
msg_printf(p, MSG_INFO, "is starved");
#endif
urgency = NEED_WORK_IMMEDIATELY;
} else {
#if DEBUG_SCHED
msg_printf(p, MSG_INFO, "will starve in %.2f sec",
estimated_time_to_starvation
);
#endif
urgency = max(NEED_WORK, urgency);
}
}
// determine work requests for each project
// NOTE: don't need to divide by active_frac etc.;
// the scheduler does that (see sched/sched_send.C)
//
p->work_request = max(0.0,
//(2*work_min_period - estimated_time_to_starvation)
(work_min_period - estimated_time_to_starvation)
* ncpus
);
#if DEBUG_SCHED
msg_printf(p, MSG_INFO, "work req: %f sec", p->work_request);
#endif
}
if (urgency == DONT_NEED_WORK) {
for (i=0; i<projects.size(); ++i) {
projects[i]->work_request = 0;
}
}
return urgency;
}
// called from the client's polling loop.
// initiate scheduler RPC activity if needed and possible
//
bool CLIENT_STATE::scheduler_rpc_poll(double now) {
int urgency = DONT_NEED_WORK;
PROJECT *p;
bool action=false;
static double last_time=0;
if (now - last_time < 1.0) return false;
last_time = now;
switch(scheduler_op->state) {
case SCHEDULER_OP_STATE_IDLE:
if (network_suspended) break;
if (should_get_work()) {
urgency = compute_work_requests();
}
// highest priority is to report overdue results
//
p = find_project_with_overdue_results();
if (p) {
scheduler_op->init_return_results(p);
action = true;
} else if (!(exit_when_idle && contacted_sched_server) && urgency != DONT_NEED_WORK) {
if (urgency == NEED_WORK) {
msg_printf(NULL, MSG_INFO,
"May run out of work in %.2f days; requesting more",
global_prefs.work_buf_min_days
);
} else if (urgency == NEED_WORK_IMMEDIATELY) {
msg_printf(NULL, MSG_INFO,
"Insufficient work; requesting more"
);
}
scheduler_op->init_get_work(false);
action = true;
} else if ((p=next_project_master_pending())) {
scheduler_op->init_get_work(true);
action = true;
} else if ((p=next_project_sched_rpc_pending())) {
scheduler_op->init_return_results(p);
action = true;
}
break;
default:
scheduler_op->poll();
if (scheduler_op->state == SCHEDULER_OP_STATE_IDLE) {
action = true;
}
break;
}
return action;
}
// Handle the reply from a scheduler
//
int CLIENT_STATE::handle_scheduler_reply(
PROJECT* project, char* scheduler_url, int& nresults
) {
SCHEDULER_REPLY sr;
FILE* f;
int retval;
unsigned int i;
bool signature_valid, update_global_prefs=false, update_project_prefs=false;
char buf[256], filename[256];
nresults = 0;
contacted_sched_server = true;
SCOPE_MSG_LOG scope_messages(log_messages, CLIENT_MSG_LOG::DEBUG_SCHED_OP);
get_sched_reply_filename(*project, filename);
scope_messages.printf_file(filename, "reply: ");
f = fopen(filename, "r");
if (!f) return ERR_FOPEN;
retval = sr.parse(f, project);
fclose(f);
if (retval) return retval;
for (i=0; i<sr.messages.size(); i++) {
USER_MESSAGE& um = sr.messages[i];
sprintf(buf, "Message from server: %s", um.message.c_str());
int prio = (!strcmp(um.priority.c_str(), "high"))?MSG_ERROR:MSG_INFO;
show_message(project, buf, prio);
}
// if project is down, return error (so that we back off)
// and don't do anything else
//
if (sr.project_is_down) {
return ERR_PROJECT_DOWN;
}
// The project returns a hostid only if it has created a new host record.
// In that case we should reset RPC seqno
//
if (sr.hostid) {
project->hostid = sr.hostid;
project->rpc_seqno = 0;
}
// see if we have a new venue from this project
//
if (strlen(sr.host_venue) && strcmp(project->host_venue, sr.host_venue)) {
safe_strcpy(project->host_venue, sr.host_venue);
msg_printf(project, MSG_INFO, "New host venue: %s", sr.host_venue);
update_project_prefs = true;
if (project == global_prefs_source_project()) {
strcpy(main_host_venue, sr.host_venue);
update_global_prefs = true;
}
}
// if the scheduler reply includes global preferences,
// insert extra elements, write to disk, and parse
//
if (sr.global_prefs_xml) {
f = boinc_fopen(GLOBAL_PREFS_FILE_NAME, "w");
if (!f) return ERR_FOPEN;
fprintf(f,
"<global_preferences>\n"
);
// tag with the project and scheduler URL,
// but only if not already tagged
//
if (!strstr(sr.global_prefs_xml, "<source_project>")) {
fprintf(f,
" <source_project>%s</source_project>\n"
" <source_scheduler>%s</source_scheduler>\n",
project->master_url,
scheduler_url
);
}
fprintf(f,
"%s"
"</global_preferences>\n",
sr.global_prefs_xml
);
fclose(f);
update_global_prefs = true;
}
if (update_global_prefs) {
bool found_venue;
retval = global_prefs.parse_file(
GLOBAL_PREFS_FILE_NAME, project->host_venue, found_venue
);
if (retval) {
msg_printf(project, MSG_ERROR, "Can't parse general preferences");
} else {
show_global_prefs_source(found_venue);
install_global_prefs();
}
}
// deal with project preferences (should always be there)
// If they've changed, write to account file,
// then parse to get our venue, and pass to running apps
//
if (sr.project_prefs_xml) {
if (strcmp(project->project_prefs.c_str(), sr.project_prefs_xml)) {
project->project_prefs = string(sr.project_prefs_xml);
update_project_prefs = true;
}
}
if (update_project_prefs) {
retval = project->write_account_file();
if (retval) {
msg_printf(project, MSG_ERROR, "Can't write account file: %d", retval);
return retval;
}
project->parse_account_file();
project->parse_preferences_for_user_files();
active_tasks.request_reread_prefs(project);
}
// if the scheduler reply includes a code-signing key,
// accept it if we don't already have one from the project.
// Otherwise verify its signature, using the key we already have.
//
if (sr.code_sign_key) {
if (!strlen(project->code_sign_key)) {
safe_strcpy(project->code_sign_key, sr.code_sign_key);
} else {
if (sr.code_sign_key_signature) {
retval = verify_string2(
sr.code_sign_key, sr.code_sign_key_signature,
project->code_sign_key, signature_valid
);
if (!retval && signature_valid) {
safe_strcpy(project->code_sign_key, sr.code_sign_key);
} else {
msg_printf(project, MSG_ERROR, "New code signing key doesn't validate");
}
} else {
msg_printf(project, MSG_ERROR, "Missing code sign key signature");
}
}
}
// copy new entities to client state
//
for (i=0; i<sr.apps.size(); i++) {
APP* app = lookup_app(project, sr.apps[i].name);
if (!app) {
app = new APP;
*app = sr.apps[i];
retval = link_app(project, app);
if (retval) {
msg_printf(project, MSG_ERROR,
"Can't link app %s in sched reply", app->name
);
delete app;
} else {
apps.push_back(app);
}
}
}
FILE_INFO* fip;
for (i=0; i<sr.file_infos.size(); i++) {
fip = lookup_file_info(project, sr.file_infos[i].name);
if (fip) {
fip->merge_info(sr.file_infos[i]);
} else {
fip = new FILE_INFO;
*fip = sr.file_infos[i];
retval = link_file_info(project, fip);
if (retval) {
msg_printf(project, MSG_ERROR,
"Can't link file_info %s in sched reply", fip->name
);
delete fip;
} else {
file_infos.push_back(fip);
}
}
}
for (i=0; i<sr.file_deletes.size(); i++) {
fip = lookup_file_info(project, sr.file_deletes[i].c_str());
if (fip) {
msg_printf(project, MSG_INFO, "Got server request to delete file %s\n", fip->name);
fip->marked_for_delete = true;
}
}
for (i=0; i<sr.app_versions.size(); i++) {
APP* app = lookup_app(project, sr.app_versions[i].app_name);
APP_VERSION* avp = lookup_app_version(app, sr.app_versions[i].version_num);
if (avp) {
// if we had download failures, clear them
//
avp->clear_errors();
continue;
}
avp = new APP_VERSION;
*avp = sr.app_versions[i];
retval = link_app_version(project, avp);
if (retval) {
msg_printf(project, MSG_ERROR,
"Can't link app version %s %d in sched reply",
avp->app_name, avp->version_num
);
delete avp;
continue;
}
app_versions.push_back(avp);
}
for (i=0; i<sr.workunits.size(); i++) {
if (lookup_workunit(project, sr.workunits[i].name)) continue;
WORKUNIT* wup = new WORKUNIT;
*wup = sr.workunits[i];
int vnum = choose_version_num(wup->app_name, sr);
if (vnum < 0) {
msg_printf(project, MSG_ERROR,
"Can't find app version for WU %s", wup->name
);
delete wup;
continue;
}
wup->version_num = vnum;
retval = link_workunit(project, wup);
if (retval) {
msg_printf(project, MSG_ERROR,
"Can't link workunit %s in sched reply", wup->name
);
delete wup;
continue;
}
wup->clear_errors();
workunits.push_back(wup);
}
for (i=0; i<sr.results.size(); i++) {
if (lookup_result(project, sr.results[i].name)) {
msg_printf(project, MSG_ERROR,
"Already have result %s\n", sr.results[i].name
);
continue;
}
RESULT* rp = new RESULT;
*rp = sr.results[i];
retval = link_result(project, rp);
if (retval) {
msg_printf(project, MSG_ERROR,
"Can't link result %s in sched reply", rp->name
);
delete rp;
continue;
}
results.push_back(rp);
rp->state = RESULT_NEW;
nresults++;
}
// update records for ack'ed results
//
for (i=0; i<sr.result_acks.size(); i++) {
RESULT* rp = lookup_result(project, sr.result_acks[i].name);
scope_messages.printf(
"CLIENT_STATE::handle_scheduler_reply(): got ack for result %s\n",
sr.result_acks[i].name
);
if (rp) {
rp->got_server_ack = true;
} else {
msg_printf(project, MSG_ERROR,
"Got ack for result %s, can't find", sr.result_acks[i].name
);
}
}
// remove acked trickle files
//
if (sr.message_ack) {
remove_trickle_files(project);
}
if (sr.send_file_list) {
project->send_file_list = true;
}
project->sched_rpc_pending = false;
// handle delay request
//
if (sr.request_delay) {
double x = dtime() + sr.request_delay;
if (x > project->min_rpc_time) project->min_rpc_time = x;
} else {
project->min_rpc_time = 0;
}
set_client_state_dirty("handle_scheduler_reply");
scope_messages.printf("CLIENT_STATE::handle_scheduler_reply(): State after handle_scheduler_reply():\n");
print_summary();
return 0;
}
bool CLIENT_STATE::should_get_work() {
// if there are fewer wus available then CPUS, then we need more work.
if (no_work_for_a_cpu()) return true;
double tot_cpu_time_remaining = 0;
for (unsigned int i = 0; i < results.size();++i) {
tot_cpu_time_remaining += results[i]->estimated_cpu_time_remaining();
}
if (tot_cpu_time_remaining < global_prefs.work_buf_min_days * SECONDS_PER_DAY) return true;
// if the CPU started this time period overloaded,
// let it process for a while to get out of the CPU overload state.
//
if (!work_fetch_no_new_work) {
set_cpu_scheduler_modes();
}
bool ret = !work_fetch_no_new_work;
return ret;
}
// return true iff we don't have enough runnable tasks to keep all CPUs busy
//
bool CLIENT_STATE::no_work_for_a_cpu() {
int count = 0;
for (unsigned int i = 0; i < results.size(); ++i){
if (!results[i]->project->non_cpu_intensive &&
!(RESULT_COMPUTE_ERROR > results[i]->state) &&
!results[i]->suspended_via_gui &&
!results[i]->project->suspended_via_gui
) {
count++;
}
}
return ncpus > count;
}
// decide on the CPU scheduler state
//
void CLIENT_STATE::set_cpu_scheduler_modes() {
std::map<double, RESULT*> results_by_deadline;
std::set<PROJECT*> projects_with_work;
std::vector<RESULT*>::iterator it_u;
for (it_u = results.begin(); it_u != results.end(); ++it_u) {
if (RESULT_COMPUTE_ERROR > (*it_u)->state && !(*it_u)->project->non_cpu_intensive) {
results_by_deadline[(*it_u)->report_deadline] = *it_u;
projects_with_work.insert((*it_u)->project);
}
}
bool should_not_fetch_work = false;
bool use_earliest_deadline_first = false;
double now;
double frac_booked;
std::vector <double> booked_to;
now = dtime();
frac_booked = 0;
for (int i=0; i<ncpus; i++) {
booked_to.push_back(now);
}
std::map<double, RESULT*>::iterator it;
double up_frac = avg_proc_rate(0);
for (
it = results_by_deadline.begin();
it != results_by_deadline.end() && !should_not_fetch_work;
it++
) {
RESULT *r = (*it).second;
if (RESULT_COMPUTE_ERROR > ((*it).second)->state) {
double lowest_book = booked_to[0];
int lowest_booked_cpu = 0;
for (int i=1; i<ncpus; i++) {
if (booked_to[i] < lowest_book) {
lowest_book = booked_to[i];
lowest_booked_cpu = i;
}
}
booked_to[lowest_booked_cpu] += ((*it).second)->estimated_cpu_time_remaining();
// Are the deadlines too tight to meet reliably?
//
if (booked_to[lowest_booked_cpu] - now > (r->report_deadline - now) * MAX_CPU_LOAD_FACTOR * up_frac) {
should_not_fetch_work = true;
use_earliest_deadline_first = true;
if (!cpu_earliest_deadline_first || !work_fetch_no_new_work) {
msg_printf(NULL, MSG_INFO,
"Computer is overcommitted"
);
}
}
// Is the nearest deadline within a day?
//
if (r->report_deadline - now < 60 * 60 * 24) {
use_earliest_deadline_first = true;
if (!cpu_earliest_deadline_first) {
msg_printf(NULL, MSG_INFO,
"Less than 1 day until deadline."
);
}
}
// is there a deadline < twice the users connect period?
//
if (r->report_deadline - now < global_prefs.work_buf_min_days * SECONDS_PER_DAY * 2) {
use_earliest_deadline_first = true;
if (!cpu_earliest_deadline_first) {
msg_printf(NULL, MSG_INFO,
"Deadline is before reconnect time"
);
}
}
frac_booked += r->estimated_cpu_time_remaining() / (r->report_deadline - now);
}
}
if (frac_booked > MAX_CPU_LOAD_FACTOR * up_frac * ncpus) {
should_not_fetch_work = true;
if (!work_fetch_no_new_work) {
msg_printf(NULL, MSG_INFO,
"Nearly overcommitted."
);
}
}
// check for too many projects that have work
//
if (projects_with_work.size() >= (unsigned int)global_prefs.max_projects_on_client) {
should_not_fetch_work = true;
if (!work_fetch_no_new_work) {
msg_printf(NULL, MSG_INFO,
"Too many projects have work."
);
}
}
// display only when the policy changes to avoid once per second
//
if (work_fetch_no_new_work && !should_not_fetch_work) {
msg_printf(NULL, MSG_INFO,
"New work fetch policy: work fetch allowed."
);
}
if (!work_fetch_no_new_work && should_not_fetch_work) {
msg_printf(NULL, MSG_INFO,
"New work fetch policy: no work fetch allowed."
);
}
if (cpu_earliest_deadline_first && !use_earliest_deadline_first) {
msg_printf(NULL, MSG_INFO,
"New CPU scheduler policy: highest debt first."
);
}
if (!cpu_earliest_deadline_first && use_earliest_deadline_first) {
msg_printf(NULL, MSG_INFO,
"New CPU scheduler policy: earliest deadline first."
);
}
work_fetch_no_new_work = should_not_fetch_work;
cpu_earliest_deadline_first = use_earliest_deadline_first;
}
const char *BOINC_RCSID_d35a4a7711 = "$Id$";