// 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., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA // db_purge options // // purge workunit and result records that are no longer needed. // Specifically, purges WUs for which file_delete_state=DONE; // this occurs only when it has been assimilated // and all results have server_state=OVER. // Purging a WU means writing it and all its results // to XML-format archive files, then deleting it and its results from the DB. // // The XML files have names of the form // wu_archive_TIME and result_archive_TIME // where TIME is the time it was created. // In addition there are index files associating each WU and result ID // with the timestamp of the file it's in. // // Options: // // -min_age_days n purge WUs with mod_time at least N days in the past // -max n purge at most N WUs // -one_pass go until nothing left to purge, then exit // default: keep scanning indefinitely // -max_wu_per_file n write at most N WUs to an archive file // The file is then closed and another file is opened. // This can be used to get a series of small files // instead of one huge file. // -zip // compress output files using zip. If used with // -max_wu_per_file then the files get compressed after // being closed. In any case the files are compressed // when db_purge exits on a signal. // -gzip // compress output files using gzip. If used with // -max_wu_per_file then the files get compressed after // being closed. In any case the files are compressed // when db_purge exits on a signal. // -sleep N // when done with a pass of purging the DB, sleep // for N seconds before the next pass. Default // value is 600 seconds. #include "config.h" #include #include #include #include #include #include #include #include #include #include using namespace std; #include "boinc_db.h" #include "util.h" #include "filesys.h" #include "parse.h" #include "sched_config.h" #include "sched_util.h" #include "sched_msgs.h" #include "error_numbers.h" #define WU_FILENAME_PREFIX "wu_archive" #define RESULT_FILENAME_PREFIX "result_archive" #define WU_INDEX_FILENAME_PREFIX "wu_index" #define RESULT_INDEX_FILENAME_PREFIX "result_index" #define DB_QUERY_LIMIT 1000 #define COMPRESSION_NONE 0 #define COMPRESSION_GZIP 1 #define COMPRESSION_ZIP 2 SCHED_CONFIG config; FILE *wu_stream=NULL; FILE *re_stream=NULL; FILE *wu_index_stream=NULL; FILE *re_index_stream=NULL; int time_int=0; int min_age_days=0; bool no_archive = false; int purged_workunits= 0; // used if limiting the total number of workunits to eliminate int max_number_workunits_to_purge=0; // If nonzero, maximum number of workunits to purge. // Since all results associated with a purged workunit are also purged, // this also limits the number of purged results. const char *suffix[3]={"", ".gz", ".zip"}; // subscripts MUST be in agreement with defines above int compression_type=COMPRESSION_NONE; int max_wu_per_file=0; // set on command line if archive files should be closed and re-opened // after getting some max no of WU in the file int wu_stored_in_file=0; // keep track of how many WU archived in file so far bool time_to_quit() { if (max_number_workunits_to_purge) { if (purged_workunits >= max_number_workunits_to_purge) return true; } return false; } // Open an archive. Only subtle thing is that if the user has // asked for compression, then we popen(2) a pipe to gzip or zip. // This does 'in place' compression. // void open_archive(const char* filename_prefix, FILE*& f){ char path[256]; char command[512]; // append appropriate suffix for file type sprintf(path, "../archives/%s_%d.xml", filename_prefix, time_int); strcat(path, suffix[compression_type]); // and construct appropriate command if needed if (compression_type==COMPRESSION_GZIP) { sprintf(command, "gzip - > %s", path); } if (compression_type==COMPRESSION_ZIP) { sprintf(command, "zip %s -", path); } log_messages.printf(SCHED_MSG_LOG::MSG_NORMAL, "Opening archive %s\n", path ); // in the case with no compression, just open the file, else open // a pipe to the compression executable. // if (compression_type==COMPRESSION_NONE) { if (!(f = fopen( path,"w"))) { log_messages.printf( SCHED_MSG_LOG::MSG_CRITICAL,"Can't open archive file %s %s\n", path, errno?strerror(errno):"" ); exit(3); } } else if (!(f = popen(command,"w"))) { log_messages.printf( SCHED_MSG_LOG::MSG_CRITICAL,"Can't open pipe %s %s\n", command, errno?strerror(errno):"" ); exit(4); } // set buffering to line buffered, since we are outputing XML on a // line-by-line basis. // setlinebuf(f); return; } void close_archive(const char *filename, FILE*& fp){ char path[256]; // Set file pointer to NULL after closing file to indicate that it's closed. // if (!fp) return; // In case of errors, carry on anyway. This is deliberate, not lazy // if (compression_type==COMPRESSION_NONE) { fclose(fp); } else { pclose(fp); } fp = NULL; // append appropriate file type sprintf(path, "../archives/%s_%d.xml", filename, time_int); strcat(path, suffix[compression_type]); log_messages.printf(SCHED_MSG_LOG::MSG_NORMAL, "Closed archive file %s containing records of %d workunits\n", path, wu_stored_in_file ); return; } // opens the various archive files. Guarantees that the timestamp // does not equal the previous timestamp // void open_all_archives() { int old_time=time_int; // make sure we get a NEW value of the file timestamp! // while (old_time == (time_int = (int)time(0))) { sleep(1); } // open all the archives. open_archive(WU_FILENAME_PREFIX, wu_stream); open_archive(RESULT_FILENAME_PREFIX, re_stream); open_archive(RESULT_INDEX_FILENAME_PREFIX, re_index_stream); open_archive(WU_INDEX_FILENAME_PREFIX, wu_index_stream); fprintf(wu_stream, "\n"); fprintf(re_stream, "\n"); return; } // closes (and optionally compresses) the archive files. Clears file // pointers to indicate that files are not open. // void close_all_archives() { if (wu_stream) fprintf(wu_stream, "\n"); if (re_stream) fprintf(re_stream, "\n"); close_archive(WU_FILENAME_PREFIX, wu_stream); close_archive(RESULT_FILENAME_PREFIX, re_stream); close_archive(RESULT_INDEX_FILENAME_PREFIX, re_index_stream); close_archive(WU_INDEX_FILENAME_PREFIX, wu_index_stream); log_messages.printf(SCHED_MSG_LOG::MSG_NORMAL, "Closed archive files with %d workunits\n", wu_stored_in_file ); return; } // The exit handler always calls this at the end to be sure that the // database is closed cleanly. // void close_db_exit_handler() { boinc_db.close(); return; } int archive_result(DB_RESULT& result) { fprintf(re_stream, "\n" " %d\n", result.id ); // xml_escape can increase size by factor of 6, e.g. x -> &#NNN; // char buf[LARGE_BLOB_SIZE*6]; xml_escape(result.stderr_out, buf); fprintf( re_stream, " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %s\n" " %.15e\n" " %s\n" " %s\n" " %s\n" " %d\n" " %d\n" " %d\n" " %.15e\n" " %.15e\n" " %f\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %s\n", result.create_time, result.workunitid, result.server_state, result.outcome, result.client_state, result.hostid, result.userid, result.report_deadline, result.sent_time, result.received_time, result.name, result.cpu_time, result.xml_doc_in, result.xml_doc_out, buf, result.batch, result.file_delete_state, result.validate_state, result.claimed_credit, result.granted_credit, result.opaque, result.random, result.app_version_num, result.appid, result.exit_status, result.teamid, result.priority, result.mod_time ); fprintf(re_stream, "\n" ); fprintf(re_index_stream, "%d %d\n", result.id, time_int ); return 0; } int archive_wu(DB_WORKUNIT& wu) { fprintf(wu_stream, "\n" " %d\n", wu.id ); fprintf(wu_stream, " %d\n" " %d\n" " %s\n" " %s\n" " %d\n" " %.15e\n" " %.15e\n" " %.15e\n" " %.15e\n" " %d\n" " %d\n" " %.15e\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %f\n" " %d\n" " %d\n" " %d\n" " %d\n" " %d\n" " %s\n" " %d\n" " %s\n", wu.create_time, wu.appid, wu.name, wu.xml_doc, wu.batch, wu.rsc_fpops_est, wu.rsc_fpops_bound, wu.rsc_memory_bound, wu.rsc_disk_bound, wu.need_validate, wu.canonical_resultid, wu.canonical_credit, wu.transition_time, wu.delay_bound, wu.error_mask, wu.file_delete_state, wu.assimilate_state, wu.hr_class, wu.opaque, wu.min_quorum, wu.target_nresults, wu.max_error_results, wu.max_total_results, wu.max_success_results, wu.result_template_file, wu.priority, wu.mod_time ); fprintf(wu_stream, "\n" ); fprintf(wu_index_stream, "%d %d\n", wu.id, time_int ); return 0; } int purge_and_archive_results(DB_WORKUNIT& wu, int& number_results) { int retval= 0; DB_RESULT result; char buf[256]; number_results=0; sprintf(buf, "where workunitid=%d", wu.id); while (!result.enumerate(buf)) { if (!no_archive) { retval= archive_result(result); if (retval) return retval; log_messages.printf( SCHED_MSG_LOG::MSG_DEBUG, "Archived result [%d] to a file\n", result.id ); } retval= result.delete_from_db(); if (retval) return retval; log_messages.printf( SCHED_MSG_LOG::MSG_DEBUG, "Purged result [%d] from database\n", result.id ); number_results++; } return 0; } // return true if did anything // bool do_pass() { int retval= 0; // The number of workunits/results purged in a single pass of do_pass(). // Since do_pass() may be invoked multiple times, // corresponding global variables store global totals. // int do_pass_purged_workunits = 0; int do_pass_purged_results = 0; // check to see if we got a stop signal. // Note that if we do catch a stop signal here, // we call an exit handler that closes [and optionally compresses] files // before returning to the OS. // check_stop_daemons(); bool did_something = false; DB_WORKUNIT wu; char buf[256]; if (min_age_days) { char timestamp[15]; mysql_timestamp(dtime()-min_age_days*86400, timestamp); sprintf(buf, "where file_delete_state=%d and mod_time<'%s' limit %d", FILE_DELETE_DONE, timestamp, DB_QUERY_LIMIT ); } else { sprintf(buf, "where file_delete_state=%d limit %d", FILE_DELETE_DONE, DB_QUERY_LIMIT ); } int n=0; while (!wu.enumerate(buf)) { if (strstr(wu.name, "nodelete")) continue; did_something = true; // if archives have not already been opened, then open them. // if (!no_archive && !wu_stream) { open_all_archives(); } retval = purge_and_archive_results(wu, n); do_pass_purged_results += n; if (!no_archive) { retval= archive_wu(wu); if (retval) { log_messages.printf(SCHED_MSG_LOG::MSG_CRITICAL, "Failed to write to XML file workunit:%d\n", wu.id ); exit(5); } log_messages.printf(SCHED_MSG_LOG::MSG_DEBUG, "Archived workunit [%d] to a file\n", wu.id ); } // purge workunit from DB // retval= wu.delete_from_db(); if (retval) { log_messages.printf(SCHED_MSG_LOG::MSG_CRITICAL, "Can't delete workunit [%d] from database:%d\n", wu.id, retval ); exit(6); } log_messages.printf(SCHED_MSG_LOG::MSG_DEBUG, "Purged workunit [%d] from database\n", wu.id ); purged_workunits++; do_pass_purged_workunits++; wu_stored_in_file++; if (!no_archive) { fflush(NULL); // if file has got max # of workunits, close and compress it. // This sets file pointers to NULL // if (max_wu_per_file && wu_stored_in_file>=max_wu_per_file) { close_all_archives(); wu_stored_in_file=0; } } if (time_to_quit()) { break; } } if (do_pass_purged_workunits) { log_messages.printf(SCHED_MSG_LOG::MSG_NORMAL, "Archived %d workunits and %d results\n", do_pass_purged_workunits, do_pass_purged_results ); } if (did_something && wu_stored_in_file>0) { log_messages.printf(SCHED_MSG_LOG::MSG_DEBUG, "Currently open archive files contain %d workunits\n", wu_stored_in_file ); } if (do_pass_purged_workunits > DB_QUERY_LIMIT/2) { return true; } else { return false; } } int main(int argc, char** argv) { int retval; bool one_pass = false; int i; int sleep_sec = 600; check_stop_daemons(); for (i=1; i 86400) { log_messages.printf(SCHED_MSG_LOG::MSG_CRITICAL, "Unreasonable value of sleep interval: %d seconds\n", sleep_sec ); exit(1); } } else { log_messages.printf(SCHED_MSG_LOG::MSG_CRITICAL, "Unrecognized arg: %s\n", argv[i] ); exit(1); } } retval = config.parse_file(".."); if (retval) { log_messages.printf(SCHED_MSG_LOG::MSG_CRITICAL, "Can't parse config file\n" ); exit(1); } log_messages.printf(SCHED_MSG_LOG::MSG_NORMAL, "Starting\n"); retval = boinc_db.open( config.db_name, config.db_host, config.db_user, config.db_passwd ); if (retval) { log_messages.printf(SCHED_MSG_LOG::MSG_CRITICAL, "Can't open DB\n"); exit(2); } install_stop_signal_handler(); boinc_mkdir("../archives"); // on exit, either via the check_stop_daemons signal handler, or // through a regular call to exit, these functions will be called // in the opposite order of registration. // atexit(close_db_exit_handler); atexit(close_all_archives); while (1) { if (time_to_quit()) { break; } if (!do_pass()) { if (one_pass) break; log_messages.printf(SCHED_MSG_LOG::MSG_NORMAL, "Sleeping....\n" ); sleep(sleep_sec); } } // files and database are closed by exit handler exit(0); } const char *BOINC_RCSID_0c1c4336f1 = "$Id$";