boinc/client/cs_data.C

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// 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):
//
// Includes the methods required for managing saved data on the client
// utilized by the client to managed its deletion policy and communicate with
// the user and the server what the status of the data storage is
//
// Uhhhh... what exactly does the above say????
//
#include "cpp.h"
#ifdef _WIN32
#include "boinc_win.h"
#endif
#ifndef _WIN32
#include <sys/stat.h>
#include <sys/types.h>
#endif
#include "filesys.h"
#include "client_msgs.h"
#include "client_types.h"
#include "client_state.h"
using std::vector;
#if 0
// This gets called when the client doesn't have enough disk space to continue
// running active tasks.
// Notify user which project is the greatest offender
// of their data share
//
void data_overflow_notify(PROJECT* project) {
if (project == NULL) {
msg_printf(NULL, MSG_ERROR,
"BOINC has run out of disk space.\n"
"Please change your General Preferences to allocate more space.\n"
);
} else {
msg_printf(project, MSG_ERROR,
"BOINC has run out of disk space for %s.\n"
"Please change your General Preferences to allocate more space.\n",
project->project_name
);
}
}
// Polling function called in do_something()
//
// Makes sure the disk bounds have not been drastically violated
// Returns true if something has been violated and tries to correct
// the problem
// TODO: notify the user of corrections made?
//
bool CLIENT_STATE::data_manager_poll() {
double tdu, adu;
static int counter=0;
if (++counter < 10000) {
return false;
}
counter = 0;
total_disk_usage(tdu);
allowed_disk_usage(adu);
// delete files from offenders only
//
if (tdu > adu) {
if (size_overflow || !projects.size()) {
return false;
}
return fix_data_overflow(tdu, adu);
}
if (size_overflow) {
calc_all_proj_size();
size_overflow = false;
}
return false;
}
bool CLIENT_STATE::fix_data_overflow(double tdu, double adu) {
double space_needed, deleted_space;
unsigned int i;
int priority;
bool deleted;
bool tentative;
PROJECT* p;
// Check if any projects are tentative
// could have new prefs in RPC
//
for (i=0; i<projects.size(); i++) {
if (projects[i]->tentative) return false;
}
// get accurate sizes as of right now
//
calc_all_proj_size();
// delete files from offenders only
space_needed = tdu - adu;
get_more_disk_space(NULL, space_needed);
total_disk_usage(tdu);
i=0;
priority = P_LOW;
deleted = false;
while (tdu > adu) {
// there is an offender that doesn't want to give up its files
// try deleting files from other projects first
//
if (i >= projects.size()) {
if (!deleted){
if (priority >= P_HIGH) {
break;
} else {
priority++;
}
}
deleted = false;
i=0;
}
p = projects[i];
deleted_space = select_delete(p, 1, priority);
if (deleted_space != 0) deleted = true;
tdu -= deleted_space;
i++;
}
i=0;
deleted = false;
tentative = false;
while (tdu > adu) {
// still not enough space, projects give up non-active WUs
//
if (i >= projects.size()) {
if (!deleted) {
size_overflow = true;
data_overflow_notify(NULL);
return true;
}
i=0;
deleted = false;
}
p = projects[i];
deleted_space = delete_results(p, 1);
if (deleted_space != 0) deleted = true;
tdu -= deleted_space;
i++;
}
return false;
}
// calculate the size of all the projects
// use after any deletions to ensure accurate number for size
//
int CLIENT_STATE::calc_all_proj_size() {
for (unsigned int i=0; i<projects.size(); ++i) {
calc_proj_size(projects[i]);
}
return 0;
}
// recalculates the total size of the project directory
// and any associated active task directories
//
int CLIENT_STATE::calc_proj_size(PROJECT* p) {
p->size = 0;
project_disk_usage(p, p->size);
compute_share_disk_size(p);
return 0;
}
// Any space that is unallocated, returns number of bytes
//
int CLIENT_STATE::anything_free(double& size) {
double total_size = 0;
double disk_available;
for (unsigned int i=0; i<projects.size(); ++i) {
total_size += projects[i]->size;
}
allowed_project_disk_usage(disk_available);
size = disk_available - total_size;
if (size > 0) {
return 0;
} else {
size = 0;
return 1;
}
}
// Tries to get more disk space for a project. Takes some percentage
// of the disk space that is not utilzed by a project and awards the
// space to the project to be used. Returns true if this was successful,
// false if it was not. It will be uncessful if all the projects are at their
// limits and the currect project is trying to exceed theirs.
//
// This function will try its best to allow a project to grow in size
// It will delete files from all projects that have a larger gap than
// the current project.
//
bool CLIENT_STATE::get_more_disk_space(PROJECT *p, double space_needed) {
PROJECT * other_p = NULL;
double total_space = 0;
double free_space;
double offend_size;
int priority = 0;
// check to see if there is enough extra space floating around
// such will be the case after calling this after a deletion
//
if (!anything_free(free_space)) {
total_space += free_space;
if (total_space > space_needed) {
return true;
}
}
// If the function has not exited with true, this means that all available
// space is being used by some combination of projects
// Check if one of the projects is over its resource share and give the space
// to the requesting project
reset_checks();
priority = P_LOW;
while (total_space < space_needed) {
other_p = greatest_offender();
if (other_p == NULL || (other_p == p)) {
if (priority > P_HIGH) {
return false;
} else {
priority++;
reset_checks();
continue;
}
}
other_p->checked = true;
offend_size = offender(other_p);
if (space_needed - total_space > offend_size) {
total_space += select_delete(other_p, offend_size, priority);
} else {
total_space += select_delete(other_p, (space_needed - total_space), priority);
}
}
return true;
}
// try and delete this many bytes of data from the greatest offender
// return the amount of disk space that was actually freed by the delete
//
double CLIENT_STATE::select_delete(PROJECT* p, double space_to_delete, int priority) {
double deleted_space = 0;
double total_space = 0;
garbage_collect();
// if not, then it must start selecting and deleting files
// until enough space is freed up
while (total_space < space_to_delete) {
deleted_space = delete_next_file(p, priority);
if (deleted_space == 0) break;
total_space += deleted_space;
}
// delete all files that you can after reflagging stickys
garbage_collect();
// calculate the size of the project after the deletion
calc_proj_size(p);
return total_space;
}
// Tries to delete everything but files associated with the active task
// If this function exits with 0 and there is still not enough space,
// the active task needs to be suspended and not restarted until there is
// enough space to run that project.
double CLIENT_STATE::delete_results(PROJECT *p, double space_to_delete) {
double deleted_space = 0;
double oldsize = p->size;
while (deleted_space < space_to_delete) {
if (delete_inactive_results(p)) {
break;
}
calc_proj_size(p);
deleted_space += oldsize - p->size;
}
return deleted_space;
}
// Returns the next file based on the deletion policy of the project.
// Returns true if a file that can be deleted was found,
// false otherwise
//
double CLIENT_STATE::delete_next_file(PROJECT* p, int priority) {
FILE_INFO* retval = NULL;
double space_freed = 0;
if (p->deletion_policy_expire) {
space_freed = delete_expired(p);
}
if (space_freed == 0) {
retval = get_priority_or_lru(p, priority);
if (retval != NULL) {
retval->sticky = false;
space_freed = retval->nbytes;
}
}
return space_freed;
}
// Returns the file_info from the project that has the lowest priority
//
FILE_INFO* CLIENT_STATE::get_priority_or_lru(PROJECT* p, int priority) {
FILE_INFO* fip;
unsigned int i;
double lowest_p = 0;
FILE_INFO* lowest = NULL;
for (i=0; i<file_infos.size(); i++) {
fip = file_infos[i];
// files that have no wu's or results and are permenant
if (fip->ref_cnt==0 && fip->project == p
&& fip->sticky && fip->priority <= priority) {
if (lowest == NULL) {
lowest = fip;
lowest_p = fip->priority;
} else if (fip->priority < lowest_p) {
lowest = file_infos[i];
lowest_p = lowest->priority;
} else if (fip->priority == lowest_p) {
if (p->deletion_policy_expire && fip->exp_date < lowest->exp_date) {
lowest = file_infos[i];
} else if (fip->time_last_used < lowest->time_last_used) {
lowest = file_infos[i];
}
}
}
}
return lowest;
}
// Deletes all expired file_infos
// Returns the amount of bytes freed
//
double CLIENT_STATE::delete_expired(PROJECT* p) {
FILE_INFO* fip;
double time_now = dtime();
double space_expired = 0;
unsigned int i;
for (i=0; i<file_infos.size(); i++) {
fip = file_infos[i];
// files that have no wu's or results and are permenant
if (fip->ref_cnt==0 && fip->project == p && fip->sticky) {
if (fip->exp_date > time_now) {
fip->sticky = false;
space_expired += fip->nbytes;
}
}
}
return space_expired;
}
// Delete any files that associated with inactive results
// by marking their results to acknowledged
//
int CLIENT_STATE::delete_inactive_results(PROJECT *p) {
bool deleted = false;
RESULT* result;
unsigned int i;
for (i=0; i<results.size(); i++) {
result = results[i];
if (!result->is_active && result->state < RESULT_COMPUTE_DONE) {
result->got_server_ack = true;
unstick_result_files(result);
deleted = true;
}
}
if (deleted) {
garbage_collect();
return 0;
} else {
return 1;
}
}
// should be called after forcebly deleting any result
// ensures any files that were supposed to by permanent are
// deleted as well, as we are already low on disk space
//
int CLIENT_STATE::unstick_result_files(RESULT *rp) {
WORKUNIT* wup;
int retval = 1;
unsigned int i;
for (i=0; i<rp->output_files.size(); i++) {
retval = 0;
rp->output_files[i].file_info->sticky = false;
}
wup = rp->wup;
for (i=0; i<wup->input_files.size(); i++) {
retval = 0;
wup->input_files[i].file_info->sticky = false;
}
return retval;
}
// returns the number of bytes the greatest offender is over his usual resource share
// the argument is returned with the number of bytes and the offending
// project is returned
//
PROJECT* CLIENT_STATE::greatest_offender() {
PROJECT* g_offender = NULL;
PROJECT* current_suspect;
double max_offense = 0;
for (unsigned int i=0; i<projects.size(); ++i) {
if (!projects[i]->checked){
current_suspect = projects[i];
if (offender(current_suspect) > max_offense) {
g_offender = current_suspect;
max_offense = offender(current_suspect);
}
}
}
return g_offender;
}
// returns the number of bytes the project is offending by
// will be negative if it is not an offender
//
double CLIENT_STATE::offender(PROJECT* p) {
if (p->share_size == 0) {
calc_all_proj_size();
}
return (p->size - p->share_size);
}
// Computes the percentage of the actual resource share that
// has been awarded to this project when compared with the totals
// from all other projects
//
double CLIENT_STATE::compute_resource_share(PROJECT *p) {
double total_resource_share = 0;
for (unsigned int i=0; i<projects.size(); ++i) {
total_resource_share += projects[i]->resource_share;
}
return p->resource_share/total_resource_share;
}
// Computes the size of the allowed disk share in number of bytes.
// This number may be smaller than the actual disk usage of the project
// since projects are allowed to grow outside of their disk bounds if there
// is space not utilzed by other projects
//
int CLIENT_STATE::compute_share_disk_size(PROJECT *p) {
double disk_available;
allowed_project_disk_usage(disk_available);
p->share_size = disk_available * compute_resource_share(p);
return 0;
}
// resets the checked flag for all projects in gstate to false;
//
int CLIENT_STATE::reset_checks() {
unsigned int i;
for (i=0; i<projects.size(); ++i) {
projects[i]->checked = false;
}
return 0;
}
int CLIENT_STATE::total_potential_offender(PROJECT* p, double& tps) {
PROJECT* other_p;
unsigned int i;
garbage_collect();
anything_free(tps);
for (i=0; i<projects.size(); i++) {
other_p = projects[i];
if (other_p != p) {
tps += proj_potentially_free(other_p);
}
}
if (tps > 0) {
return 0;
} else {
tps = 0;
return 1;
}
}
int CLIENT_STATE::total_potential_self(PROJECT* p, double& tps) {
FILE_INFO* fip;
unsigned int i;
total_potential_offender(p, tps);
for (i=0; i<file_infos.size(); i++) {
fip = file_infos[i];
if (fip->ref_cnt == 0 && fip->project == p && fip->sticky) {
if (!p->deletion_policy_expire) {
tps += fip->nbytes;
} else if (p->deletion_policy_expire && (fip->exp_date > dtime())) {
tps += fip->nbytes;
}
}
}
if (tps > 0) {
return 0;
} else {
tps = 0;
return 1;
}
}
double CLIENT_STATE::proj_potentially_free(PROJECT* p) {
double offend_share = offender(p);
double tps = 0;
FILE_INFO* fip;
unsigned int i;
if (offend_share <= 0) {
return 0;
}
for (i=0; i<file_infos.size(); i++) {
if (tps > offend_share) break;
fip = file_infos[i];
if (fip->ref_cnt==0 && fip->project == p && fip->sticky) {
if (!p->deletion_policy_expire) {
tps += fip->nbytes;
} else if (p->deletion_policy_expire && (fip->exp_date > dtime())) {
tps += fip->nbytes;
}
}
}
return tps;
}
#endif
#ifdef __GNUC__
static volatile const char __attribute__((unused)) *BOINCrcsid="$Id$";
#else
static volatile const char *BOINCrcsid="$Id$";
#endif