/* Copyright (C) 2021-2024 Free Software Foundation, Inc. Contributed by Oracle. This file is part of GNU Binutils. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */ #include "config.h" #include #include // open, chmod #include #include // open #include #include #include "util.h" #include "Histable.h" #include "DbeSession.h" #include "DbeView.h" #include "BaseMetric.h" #include "CallStack.h" #include "collctrl.h" #include "Command.h" #include "Dbe.h" #include "DbeApplication.h" #include "DefaultMap.h" #include "LoadObject.h" #include "Experiment.h" #include "IndexObject.h" #include "IOActivity.h" #include "PreviewExp.h" #include "Function.h" #include "Hist_data.h" #include "MetricList.h" #include "Module.h" #include "DataSpace.h" #include "MemorySpace.h" #include "DataObject.h" #include "MemObject.h" #include "Filter.h" #include "FilterSet.h" #include "FilterExp.h" #include "Sample.h" #include "Print.h" #include "StringBuilder.h" #include "dbe_types.h" #include "ExpGroup.h" #include "vec.h" #include "UserLabel.h" #include "DbeFile.h" #include "PathTree.h" // Data structures for managing the collector control info for Collection GUI static Coll_Ctrl *col_ctr = NULL; template<> VecType Vector::type () { return VEC_INTEGER; } template<> VecType Vector::type () { return VEC_INTEGER; } template<> VecType Vector::type () { return VEC_CHAR; } template<> VecType Vector::type () { return VEC_BOOL; } template<> VecType Vector::type () { return VEC_DOUBLE; } template<> VecType Vector::type () { return VEC_LLONG; } template<> VecType Vector::type () { return VEC_LLONG; } template<> VecType Vector::type () { return VEC_VOIDARR; } template<> VecType Vector::type () { return VEC_STRING; } template<> VecType Vector*>::type () { return VEC_INTARR; } template<> VecType Vector*>::type () { return VEC_STRINGARR; } template<> VecType Vector*>::type () { return VEC_LLONGARR; } // gcc won't instantiate Vector::type() without it Vector __dummy_unsigned_vector; #define CASE_S(x) case x: return #x static const char * dsp_type_to_string (int t) { switch (t) { CASE_S (DSP_FUNCTION); CASE_S (DSP_LINE); CASE_S (DSP_PC); CASE_S (DSP_SOURCE); CASE_S (DSP_DISASM); CASE_S (DSP_SELF); CASE_S (DSP_CALLER); CASE_S (DSP_CALLEE); CASE_S (DSP_CALLTREE); CASE_S (DSP_TIMELINE); CASE_S (DSP_STATIS); CASE_S (DSP_EXP); CASE_S (DSP_LEAKLIST); CASE_S (DSP_MEMOBJ); CASE_S (DSP_DATAOBJ); CASE_S (DSP_DLAYOUT); CASE_S (DSP_SRC_FILE); CASE_S (DSP_IFREQ); CASE_S (DSP_RACES); CASE_S (DSP_INDXOBJ); CASE_S (DSP_DUALSOURCE); CASE_S (DSP_SOURCE_DISASM); CASE_S (DSP_DEADLOCKS); CASE_S (DSP_SOURCE_V2); CASE_S (DSP_DISASM_V2); CASE_S (DSP_IOACTIVITY); CASE_S (DSP_OVERVIEW); CASE_S (DSP_IOCALLSTACK); CASE_S (DSP_HEAPCALLSTACK); CASE_S (DSP_SAMPLE); default: break; } return NTXT ("ERROR"); } enum { COMPARE_BIT = 1 << 8, MTYPE_MASK = (1 << 8) - 1, GROUP_ID_SHIFT = 16 }; static DbeView * getDbeView (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); return dbev; } Vector * dbeGetInitMessages () { // If any comments from the .rc files, send them to the GUI Emsg *msg = theDbeApplication->fetch_comments (); int size = 0; while (msg != NULL) { size++; msg = msg->next; } // Initialize Java String array Vector *list = new Vector(size); msg = theDbeApplication->fetch_comments (); size = 0; int i = 0; while (msg != NULL) { char *str = msg->get_msg (); list->store (i, dbe_strdup (str)); i++; msg = msg->next; } // now delete the comments theDbeApplication->delete_comments (); return list; } Vector * dbeGetExpPreview (int /*dbevindex*/, char *exp_name) { PreviewExp *preview = new PreviewExp (); preview->experiment_open (exp_name); preview->open_epilogue (); // Initialize Java String array Vector *info = preview->preview_info (); int size = info->size (); Vector *list = new Vector(size); // Get experiment names for (int i = 0; i < size; i++) { char *str = info->fetch (i); if (str == NULL) str = GTXT ("N/A"); list->store (i, dbe_strdup (str)); } delete info; delete preview; return list; } char * dbeGetExpParams (int /*dbevindex*/, char *exp_name) { PreviewExp *preview = new PreviewExp (); preview->experiment_open (exp_name); // Initialize Java String array char *arg_list = dbe_strdup (preview->getArgList ()); delete preview; return arg_list; } /** * Gets File Attributes according to the specified format * Supported formats: * "/bin/ls -dl " - see 'man ls' for details * @param filename * @param format * @return char * attributes */ char * dbeGetFileAttributes (const char *filename, const char *format) { if (format != NULL) { if (!strcmp (format, NTXT ("/bin/ls -dl "))) { // A kind of "/bin/ls -dl " simulation dbe_stat_t sbuf; sbuf.st_mode = 0; dbe_stat (filename, &sbuf); if (S_IREAD & sbuf.st_mode) { // Readable if (S_ISDIR (sbuf.st_mode) != 0) return dbe_sprintf (NTXT ("%s %s\n"), NTXT ("drwxrwxr-x"), filename); else if (S_ISREG (sbuf.st_mode) != 0) return dbe_sprintf (NTXT ("%s %s\n"), NTXT ("-rwxrwxr-x"), filename); } } } return dbe_strdup (NTXT ("")); } /** * Gets list of files for specified directory according to the specified format * Supported formats: * "/bin/ls -a" - see 'man ls' for details * "/bin/ls -aF" - see 'man ls' for details * @param dirname * @param format * @return char * files */ char * dbeGetFiles (const char *dirname, const char *format) { if (format != NULL) return dbe_read_dir (dirname, format); return dbe_strdup (NTXT ("")); } /** * Creates the directory named by this full path name, including any * necessary but nonexistent parent directories. * @param dirname * @return result */ char * dbeCreateDirectories (const char *dirname) { if (dirname != NULL) { char *res = dbe_create_directories (dirname); if (res != NULL) return res; } return dbe_strdup (NTXT ("")); } /** * Deletes the file or the directory named by the specified path name. * If this pathname denotes a directory, then the directory must be empty in order to be deleted. * @param const char *pathname * @return int result */ char * dbeDeleteFile (const char *pathname) { // return unlink(pathname); if (pathname != NULL) { char *res = dbe_delete_file (pathname); if (res != NULL) return res; } return dbe_strdup (NTXT ("")); } /** * Reads the file named by the specified path name. * Temporary limitation: file should be "text only" and its size should be less than the 1 MB limit. * If the operation was successful, the contents is in the first element, and second element is NULL. * If the operation failed, then first element is NULL, and second element contains the error message. * @param const char *pathname * @return Vector *result */ Vector * dbeReadFile (const char *pathname) { Vector *result = new Vector(2); int limit = 1024 * 1024; // Temporary limit: 1 MB char * contents = (char *) xmalloc (limit); StringBuilder sb; if (NULL == contents) { sb.sprintf (NTXT ("\nError: Cannot allocate %d bytes\n"), limit); result->store (0, NULL); result->store (1, sb.toString ()); // failure return result; } int fd = open (pathname, O_RDONLY); if (fd >= 0) { int64_t bytes = read_from_file (fd, contents, limit); close (fd); if (bytes >= limit) { sb.sprintf (NTXT ("\nError: file size is greater than the limit (%d bytes)\n"), limit); result->store (0, NULL); result->store (1, sb.toString ()); // failure } else { contents[bytes] = '\0'; // add string terminator result->store (0, contents); result->store (1, NULL); // success } } else { sb.sprintf (NTXT ("\nError: Cannot open file %s\n"), pathname); result->store (0, NULL); result->store (1, sb.toString ()); // failure free (contents); } return result; } /** * Writes the file named by the specified path name. * Temporary limitation: file should be "text only" and its size should be less than the 1 MB limit. * If the operation failed, then -1 is returned. * @param const char *pathname * @return int result (written bytes) */ int dbeWriteFile (const char *pathname, const char *contents) { int result = -1; // error size_t len = 0; if (NULL != contents) len = strlen (contents); size_t limit = 1024 * 1024; // Temporary limit: 1 MB if (len > limit) return result; unlink (pathname); mode_t mode = S_IRUSR | S_IWUSR; int fd = open (pathname, O_WRONLY | O_CREAT | O_TRUNC, mode); if (fd >= 0) { // replace file contents chmod (pathname, /*S_IRUSR || S_IWUSR*/ 0600); // rw for owner only ssize_t bytes = 0; if (len > 0) bytes = write (fd, contents, len); close (fd); result = (int) bytes; } return result; } /** * Gets list of running processes according to the specified format * Supported formats: * "/bin/ps -ef" - see 'man ps' for details * @param format * @return char * processes */ char * dbeGetRunningProcesses (const char *format) { if (format != NULL) return dbe_get_processes (format); return dbe_strdup (NTXT ("")); } // // Open experiment // char * dbeOpenExperimentList (int /* dbevindex */, Vector*> *groups, bool sessionRestart) { if (sessionRestart) dbeSession->reset (); char *errstr; // Open experiments try { errstr = dbeSession->setExperimentsGroups (groups); } catch (ExperimentLoadCancelException *) { errstr = dbe_strdup (NTXT ("Experiment Load Cancelled")); } return errstr; } // // Drop experiments // char * dbeDropExperiment (int /* dbevindex */, Vector *drop_index) { for (int i = drop_index->size () - 1; i >= 0; i--) { char *ret = dbeSession->drop_experiment (drop_index->fetch (i)); if (ret != NULL) return ret; } return NULL; } /** * Read .er.rc file from the specified location * @param path * @return */ char * dbeReadRCFile (int dbevindex, char* path) { DbeView *dbev = getDbeView (dbevindex); char *err_msg = dbev->get_settings ()->read_rc (path); return err_msg; } char * dbeSetExperimentsGroups (Vector*> *groups) { int cmp_mode = dbeSession->get_settings ()->get_compare_mode (); if (groups->size () < 2) cmp_mode = CMP_DISABLE; else if (cmp_mode == CMP_DISABLE) cmp_mode = CMP_ENABLE; for (int i = 0;; i++) { DbeView *dbev = dbeSession->getView (i); if (dbev == NULL) break; dbev->get_settings ()->set_compare_mode (cmp_mode); } char *err_msg = dbeSession->setExperimentsGroups (groups); // automatically load machine model if applicable dbeDetectLoadMachineModel (0); return err_msg; } Vector*> * dbeGetExperimensGroups () { Vector*> *grops = dbeSession->getExperimensGroups (); return grops; } Vector * dbeGetFounderExpId (Vector *expIds) { Vector *ret = new Vector(expIds->size ()); for (int i = 0; i < expIds->size (); i++) { int expId = expIds->fetch (i); Experiment *exp = dbeSession->get_exp (expId); if (exp != NULL) { int founderExpId = exp->getBaseFounder ()->getExpIdx (); ret->store (i, founderExpId); } else ret->store (i, -1); } return ret; } Vector * dbeGetUserExpId (Vector *expIds) { // returns "User Visible" ids used for EXPID filters and timeline processes Vector *ret = new Vector(expIds->size ()); for (int i = 0; i < expIds->size (); i++) { int expId = expIds->fetch (i); Experiment *exp = dbeSession->get_exp (expId); if (exp != NULL) { int userExpId = exp->getUserExpId (); ret->store (i, userExpId); } else ret->store (i, -1); } return ret; } // // Get experiment groupid // Vector * dbeGetExpGroupId (Vector *expIds) { Vector *ret = new Vector(expIds->size ()); for (int i = 0; i < expIds->size (); i++) { int expId = expIds->fetch (i); Experiment *exp = dbeSession->get_exp (expId); if (exp != NULL) { int gId = exp->groupId; ret->store (i, gId); } else ret->store (i, -1); } return ret; } Vector * dbeGetExpsProperty (const char *prop_name) { long nexps = dbeSession->nexps (); if (prop_name == NULL || nexps == 0) return NULL; Vector *list = new Vector(nexps); StringBuilder sb; int empty = 1; int prop = 99; if (strcasecmp (prop_name, NTXT ("ERRORS")) == 0) prop = 1; else if (strcasecmp (prop_name, NTXT ("WARNINGS")) == 0) prop = 2; if (prop < 3) { for (long i = 0; i < nexps; i++) { Experiment *exp = dbeSession->get_exp (i); char *nm = exp->get_expt_name (); sb.setLength (0); for (Emsg *emsg = (prop == 1) ? exp->fetch_errors () : exp->fetch_warnings (); emsg; emsg = emsg->next) sb.appendf (NTXT ("%s: %s\n"), STR (nm), STR (emsg->get_msg ())); char *s = NULL; if (sb.length () > 0) { s = sb.toString (); empty = 0; } list->append (s); } } if (empty) { delete list; list = NULL; } return list; } // // Get experiment names // Vector * dbeGetExpName (int /*dbevindex*/) { int size = dbeSession->nexps (); if (size == 0) return NULL; // Initialize Java String array Vector *list = new Vector(size); // Get experiment names for (int i = 0; i < size; i++) { Experiment *texp = dbeSession->get_exp (i); char *buf = dbe_sprintf (NTXT ("%s [%s]"), texp->get_expt_name (), texp->utargname != NULL ? texp->utargname : GTXT ("(unknown)")); list->store (i, buf); } return list; } // // Get experiment state // Vector * dbeGetExpState (int /* dbevindex */) { int size = dbeSession->nexps (); if (size == 0) return NULL; // Initialize Java array Vector *state = new Vector(size); // Get experiment state for (int i = 0; i < size; i++) { Experiment *exp = dbeSession->get_exp (i); int set = EXP_SUCCESS; if (exp->get_status () == Experiment::FAILURE) set |= EXP_FAILURE; if (exp->get_status () == Experiment::INCOMPLETE) set |= EXP_INCOMPLETE; if (exp->broken) set |= EXP_BROKEN; if (exp->obsolete) set |= EXP_OBSOLETE; state->store (i, set); } return state; } // // Get enabled experiment indices // Vector * dbeGetExpEnable (int dbevindex) { DbeView *dbev = getDbeView (dbevindex); int size = dbeSession->nexps (); if (dbev == NULL || size == 0) return NULL; // Get enabled experiment Vector *enable = new Vector(size); for (int i = 0; i < size; i++) { bool val = dbev->get_exp_enable (i) && !dbeSession->get_exp (i)->broken; enable->store (i, val); } return enable; } // // Get enabled experiment indices // bool dbeSetExpEnable (int dbevindex, Vector *enable) { DbeView *dbev = getDbeView (dbevindex); bool ret = false; int size = dbeSession->nexps (); if (dbev == NULL || size == 0) return false; // set enable, as per input vector for (int i = 0; i < size; i++) if (!dbeSession->get_exp (i)->broken && dbev->get_exp_enable (i) != enable->fetch (i)) { dbev->set_exp_enable (i, enable->fetch (i)); ret = true; } return ret; } // // Get experiment info // Vector * dbeGetExpInfo (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); int size = dbeSession->nexps (); if (size == 0) return NULL; // Initialize Java String array Vector *list = new Vector(size * 2 + 1); // Get experiment names Vector *text_segments = dbeSession->get_text_segments (); char *msg = pr_load_objects (text_segments, NTXT ("")); delete text_segments; list->store (0, msg); int k = 1; for (int i = 0; i < size; i++) { Experiment *exp = dbeSession->get_exp (i); char *msg0 = pr_mesgs (exp->fetch_notes (), NTXT (""), NTXT ("")); char *msg1 = pr_mesgs (exp->fetch_errors (), GTXT ("No errors\n"), NTXT ("")); char *msg2 = pr_mesgs (exp->fetch_warnings (), GTXT ("No warnings\n"), NTXT ("")); char *msg3 = pr_mesgs (exp->fetch_comments (), NTXT (""), NTXT ("")); char *msg4 = pr_mesgs (exp->fetch_pprocq (), NTXT (""), NTXT ("")); msg = dbe_sprintf (NTXT ("%s%s%s%s"), msg1, msg2, msg3, msg4); list->store (k++, msg0); list->store (k++, msg); free (msg1); free (msg2); free (msg3); free (msg4); } return list; } bool dbeGetViewModeEnable () { return dbeSession->has_ompavail () || dbeSession->has_java (); } bool dbeGetJavaEnable () { return dbeSession->has_java (); } int dbeUpdateNotes (int dbevindex, int exp_id, int type, char* text, bool handle_file) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); int size = dbeSession->nexps (); if (size == 0) return -1; Experiment *exp = dbeSession->get_exp (exp_id); return (type == 0) ? exp->save_notes (text, handle_file) : exp->delete_notes (handle_file); } // // Get load object names // Vector * dbeGetLoadObjectName (int /* dbevindex */) { Vector *lobjs = dbeSession->get_text_segments (); int size = lobjs->size (); // Initialize Java String array Vector *list = new Vector(size); // Get load object names LoadObject *lo; int index; Vec_loop (LoadObject*, lobjs, index, lo) { list->store (index, dbe_strdup (lo->get_name ())); } delete lobjs; return list; } // XXX Will use later when order has to be passed too, // Get complete List of tabs // Vector * dbeGetTabList (int /* dbevindex */) { //DbeView *dbev = getDbeView (dbevindex); //Vector *tabs = dbeSession->get_TabList(); //return tabs; return NULL; } // // Returns list of available tabs // Vector * dbeGetTabListInfo (int dbevindex) { int index; DispTab *dsptab; DbeView *dbev = getDbeView (dbevindex); // make sure the tabs are initialized properly dbev->get_settings ()->proc_tabs (theDbeApplication->rdtMode); Vector *tabs = dbev->get_TabList (); // Get number of available tabs int size = 0; Vec_loop (DispTab*, tabs, index, dsptab) { if (!dsptab->available) continue; size++; } Vector *data = new Vector(2); Vector *typelist = new Vector(size); Vector *cmdlist = new Vector(size); Vector *ordlist = new Vector(size); // Build list of avaliable tabs int i = 0; Vec_loop (DispTab*, tabs, index, dsptab) { if (!dsptab->available) continue; typelist->store (i, dsptab->type); cmdlist->store (i, dbe_strdup (Command::get_cmd_str (dsptab->cmdtoken))); ordlist->store (i, dsptab->order); i++; } data->store (0, typelist); data->store (1, cmdlist); data->store (2, ordlist); return data; } // Return visibility state for all available tabs // Vector * dbeGetTabSelectionState (int dbevindex) { int index; DispTab *dsptab; DbeView *dbev = getDbeView (dbevindex); Vector *tabs = dbev->get_TabList (); // Get number of available tabs int size = 0; Vec_loop (DispTab*, tabs, index, dsptab) { if (!dsptab->available) continue; size++; } Vector *states = new Vector(size); // Get visibility bit for all available tabs int i = 0; Vec_loop (DispTab*, tabs, index, dsptab) { if (!dsptab->available) continue; states->store (i++, dsptab->visible); } return states; } // Set visibility bit for a tab void dbeSetTabSelectionState (int dbevindex, Vector *selected) { int index; DispTab *dsptab; DbeView *dbev = getDbeView (dbevindex); Vector *tabs = dbev->get_TabList (); int i = 0; Vec_loop (DispTab*, tabs, index, dsptab) { if (!dsptab->available) continue; dsptab->visible = selected->fetch (i++); } } // Return visibility state for all available MemObj tabs Vector * dbeGetMemTabSelectionState (int dbevindex) { int index; bool dsptab; DbeView *dbev = getDbeView (dbevindex); Vector *memtabs = dbev->get_MemTabState (); // set the output vector int size = memtabs->size (); Vector *states = new Vector(size); // Get visibility bit for all available tabs int i = 0; Vec_loop (bool, memtabs, index, dsptab) { states->store (i++, dsptab); } return states; } // Set visibility bit for a memory tab // void dbeSetMemTabSelectionState (int dbevindex, Vector *selected) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->set_MemTabState (selected); } // Return visibility state for all available index tabs Vector * dbeGetIndxTabSelectionState (int dbevindex) { int index; bool dsptab; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Vector *indxtabs = dbev->get_IndxTabState (); // set the output vector int size = indxtabs->size (); Vector *states = new Vector(size); // Get visibility bit for all available tabs int i = 0; Vec_loop (bool, indxtabs, index, dsptab) { states->store (i++, dsptab); } return states; } // Set visibility bit for a index tab void dbeSetIndxTabSelectionState (int dbevindex, Vector *selected) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->set_IndxTabState (selected); } // // Get search path // Vector * dbeGetSearchPath (int /*dbevindex*/) { Vector *path = dbeSession->get_search_path (); int size = path->size (); Vector *list = new Vector(size); int index; char *name; Vec_loop (char*, path, index, name) { list->store (index, dbe_strdup (name)); } return list; } // // Set search path // void dbeSetSearchPath (int /*dbevindex*/, Vector *path) { dbeSession->set_search_path (path, true); return; } // // Get pathmaps // Vector * dbeGetPathmaps (int /*dbevindex*/) { int index; pathmap_t *pthmap; Vector *path = dbeSession->get_pathmaps (); int size = path->size (); Vector *data = new Vector(2); Vector *oldlist = new Vector(size); Vector *newlist = new Vector(size); int i = 0; Vec_loop (pathmap_t*, path, index, pthmap) { oldlist->store (i, dbe_strdup (pthmap->old_prefix)); newlist->store (i, dbe_strdup (pthmap->new_prefix)); i++; } data->store (0, oldlist); data->store (1, newlist); return data; } // dbeGetPathmaps char * dbeSetPathmaps (Vector *from, Vector *to) { if (from == NULL || to == NULL || from->size () != to->size ()) return dbe_strdup ("dbeSetPathmaps: size of 'from' does not match for size of 'to'\n"); Vector *newPath = new Vector(from->size ()); for (int i = 0, sz = from->size (); i < sz; i++) { char *err = Settings::add_pathmap (newPath, from->get (i), to->get (i)); if (err) { newPath->destroy (); delete newPath; return err; } } dbeSession->set_pathmaps (newPath); return NULL; } // // Add pathmap char * dbeAddPathmap (int /* dbevindex */, char *from, char *to) { Vector *pmp = dbeSession->get_pathmaps (); char *err = Settings::add_pathmap (pmp, from, to); return err; } // // Get error/warning string of data char * dbeGetMsg (int dbevindex, int type) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); char *msgstr = NULL; if (type == ERROR_MSG) msgstr = dbev->get_error_msg (); else if (type == WARNING_MSG) msgstr = dbev->get_warning_msg (); else if (type == PSTAT_MSG) msgstr = dbev->get_processor_msg (PSTAT_MSG); else if (type == PWARN_MSG) msgstr = dbev->get_processor_msg (PWARN_MSG); return msgstr ? dbe_strdup (msgstr) : NULL; } // Create a DbeView, given new index, and index of view to clone int dbeInitView (int id, int cloneid) { return dbeSession->createView (id, cloneid); } // Delete a DbeView void dbeDeleteView (int dbevindex) { dbeSession->dropView (dbevindex); return; } // dbeDeleteView MetricList * dbeGetMetricListV2 (int dbevindex, MetricType mtype, Vector *type, Vector *subtype, Vector *sort, Vector *vis, Vector *cmd, Vector *expr_spec, Vector *legends) { DbeView *dbev = dbeSession->getView (dbevindex); MetricList *mlist = new MetricList (mtype); for (int i = 0, msize = type->size (); i < msize; i++) { BaseMetric *bm = dbev->register_metric_expr ((BaseMetric::Type) type->fetch (i), cmd->fetch (i), expr_spec->fetch (i)); Metric *m = new Metric (bm, (Metric::SubType) subtype->fetch (i)); m->set_raw_visbits (vis->fetch (i)); if (m->legend == NULL) m->legend = dbe_strdup (legends->fetch (i)); mlist->append (m); if (sort->fetch (i)) { mlist->set_sort_ref_index (i); } } return mlist; } static Vector * dbeGetMetricList (MetricList *mlist) { int clock_val = dbeSession->get_clock (-1); Vector *items = mlist->get_items (); int size = items->size (); Vector *type = new Vector(size); Vector *subtype = new Vector(size); Vector *clock = new Vector(size); Vector *flavors = new Vector(size); Vector *vis = new Vector(size); Vector *sorted = new Vector(size); Vector *value_styles = new Vector(size); Vector *aux = new Vector(size); Vector *name = new Vector(size); Vector *abbr = new Vector(size); Vector *comd = new Vector(size); Vector *unit = new Vector(size); Vector *user_name = new Vector(size); Vector *expr_spec = new Vector(size); Vector *legend = new Vector(size); Vector *valtype = new Vector(size); Vector *data_type_name = new Vector(size); Vector *data_type_uname = new Vector(size); Vector *short_desc = new Vector(size); int sort_index = mlist->get_sort_ref_index (); // Fill metric elements for (int i = 0; i < size; i++) { Metric *m = items->fetch (i); type->append (m->get_type ()); subtype->append (m->get_subtype ()); flavors->append (m->get_flavors ()); abbr->append (dbe_strdup (m->get_abbr ())); char *s = m->get_abbr_unit (); if ((m->get_visbits () & VAL_RATIO) != 0) s = NULL; unit->append (dbe_strdup (s ? s : NTXT (""))); value_styles->append (m->get_value_styles ()); vis->append (m->get_visbits ()); sorted->append (i == sort_index); clock->append (m->get_type () == Metric::HWCNTR ? clock_val : m->get_clock_unit ()); aux->append (dbe_strdup (m->get_aux ())); name->append (dbe_strdup (m->get_name ())); comd->append (dbe_strdup (m->get_cmd ())); user_name->append (dbe_strdup (m->get_username ())); expr_spec->append (dbe_strdup (m->get_expr_spec ())); legend->append (dbe_strdup (m->legend)); valtype->append (m->get_vtype2 ()); char* _data_type_name = NULL; char* _data_type_uname = NULL; int data_type = m->get_packet_type (); if (data_type >= 0 && data_type < DATA_LAST) { _data_type_name = dbe_strdup (get_prof_data_type_name (data_type)); _data_type_uname = dbe_strdup (get_prof_data_type_uname (data_type)); } data_type_name->append (_data_type_name); data_type_uname->append (_data_type_uname); char* _short_desc = NULL; if (m->get_type () == Metric::HWCNTR) { Hwcentry * hwctr = m->get_hw_ctr (); if (hwctr) _short_desc = dbe_strdup (hwctr->short_desc); } short_desc->append (_short_desc); } // Set Java array Vector *data = new Vector(16); data->append (type); data->append (subtype); data->append (clock); data->append (flavors); data->append (value_styles); data->append (user_name); data->append (expr_spec); data->append (aux); data->append (name); data->append (abbr); data->append (comd); data->append (unit); data->append (vis); data->append (sorted); data->append (legend); data->append (valtype); data->append (data_type_name); data->append (data_type_uname); data->append (short_desc); return data; } Vector * dbeGetRefMetricsV2 () { MetricList *mlist = new MetricList (MET_NORMAL); Vector *base_metrics = dbeSession->get_base_reg_metrics (); for (long i = 0, sz = base_metrics->size (); i < sz; i++) { BaseMetric *bm = base_metrics->fetch (i); Metric *m; if (bm->get_flavors () & Metric::EXCLUSIVE) { m = new Metric (bm, Metric::EXCLUSIVE); m->enable_all_visbits (); mlist->append (m); } else if (bm->get_flavors () & BaseMetric::STATIC) { m = new Metric (bm, BaseMetric::STATIC); m->enable_all_visbits (); mlist->append (m); } } Vector *data = dbeGetMetricList (mlist); delete mlist; return data; } Vector * dbeGetCurMetricsV2 (int dbevindex, MetricType mtype) { DbeView *dbev = dbeSession->getView (dbevindex); MetricList *mlist = dbev->get_metric_list (mtype); Vector *data = dbeGetMetricList (mlist); return data; } // YXXX we should refactor Metrics/BaseMetrics so that it no longer uses VAL_VALUE to enable time. static int convert_visbits_to_gui_checkbox_bits (BaseMetric *bm, const int visbits) { // The purpose of this function is to handle the following case: // When bm->get_value_styles() supports VAL_TIMEVAL but not VAL_VALUE // Metric and BaseMetric use (visbits&VAL_VALUE) to enable time. // However, the Overview expects the VAL_TIMEVAL bit to enable time. // Inputs: visbits as returned by BaseMetric->get_default_visbits(); // Returns: valuebits, as used for checks in GUI checkboxes int valuebits = visbits; const int value_styles = bm->get_value_styles (); if ((value_styles & VAL_TIMEVAL) && // supports time !(value_styles & VAL_VALUE)) { // but not value unsigned mask = ~(VAL_VALUE | VAL_TIMEVAL); valuebits = (unsigned) valuebits & mask; // clear bits if (visbits & VAL_VALUE) valuebits |= VAL_TIMEVAL; // set VAL_TIMEVAL if (visbits & VAL_TIMEVAL) valuebits |= VAL_TIMEVAL; // weird, this should never happen. } return valuebits; } static Vector * dbeGetMetricTreeNode (BaseMetricTreeNode* curr, MetricList *mlist, bool include_unregistered, bool has_clock_profiling_data) { Vector *data = new Vector(2); // ----- fields Vector *fields = new Vector(); Vector *name = new Vector(1); Vector *username = new Vector(1); Vector *description = new Vector(1); Vector * flavors = new Vector(1); Vector * vtype = new Vector(1); Vector * vstyles_capable = new Vector(1); // Specifies which default styles should be enabled when a metric is enabled. // Also, specifies if metric should start enabled Vector *vstyles_e_defaults = new Vector(1); Vector *vstyles_i_defaults = new Vector(1); Vector *registered = new Vector(1); Vector *aggregation = new Vector(1); Vector *has_value = new Vector(1); Vector *unit = new Vector(1); Vector *unit_uname = new Vector(1); char *_name = NULL; char *_username = NULL; char *_description = dbe_strdup (curr->get_description ()); // BaseMetric fields int _flavors = 0; // SubType bitmask: (e.g. EXCLUSIVE) int _vtype = 0; // ValueTag: e.g. VT_INT, VT_FLOAT, ... int _vstyles_capable = 0; // ValueType bitmask, e.g. VAL_TIMEVAL int _vstyles_e_default_values = 0; // default visibility settings, exclusive/static int _vstyles_i_derault_values = 0; // default visibility settings, inclusive bool _registered = curr->is_registered () || curr->get_num_registered_descendents () > 0; bool _aggregation = curr->is_composite_metric () && curr->get_num_registered_descendents () > 0; bool _has_value = false; //not used yet; for nodes that don't have metrics char *_unit = NULL; char *_unit_uname = NULL; BaseMetric *bm = curr->get_BaseMetric (); if (bm) { _name = dbe_strdup (bm->get_cmd ()); _username = dbe_strdup (bm->get_username ()); if (!include_unregistered && !curr->is_registered ()) abort (); _flavors = bm->get_flavors (); _vtype = bm->get_vtype (); _vstyles_capable = bm->get_value_styles (); int e_visbits = bm->get_default_visbits (BaseMetric::EXCLUSIVE); int i_visbits = bm->get_default_visbits (BaseMetric::INCLUSIVE); _vstyles_e_default_values = convert_visbits_to_gui_checkbox_bits (bm, e_visbits); _vstyles_i_derault_values = convert_visbits_to_gui_checkbox_bits (bm, i_visbits); // not all metrics shown in er_print cmd line should be selected in the GUI at startup: if (has_clock_profiling_data && bm->get_hw_ctr ()) { bool hide = true; // by default, hide HWCs if (dbe_strcmp (bm->get_hw_ctr ()->name, NTXT ("c_stalls")) == 0 || dbe_strcmp (bm->get_hw_ctr ()->name, NTXT ("K_c_stalls")) == 0) { bool is_time = (bm->get_value_styles () & VAL_TIMEVAL) != 0; if (is_time) // By default, show time variant of c_stalls hide = false; } if (hide) { _vstyles_e_default_values |= VAL_HIDE_ALL; _vstyles_i_derault_values |= VAL_HIDE_ALL; } } } else { // not a base metric _name = dbe_strdup (curr->get_name ()); _username = dbe_strdup (curr->get_user_name ()); if (curr->get_unit ()) { // represents a value _has_value = true; _unit = dbe_strdup (curr->get_unit ()); _unit_uname = dbe_strdup (curr->get_unit_uname ()); } } name->append (_name); // unique id string (dmetrics cmd) username->append (_username); // user-visible name description->append (_description); flavors->append (_flavors); // SubType bitmask: (e.g. EXCLUSIVE) vtype->append (_vtype); // ValueTag: e.g. VT_INT, VT_FLOAT, ... vstyles_capable->append (_vstyles_capable); // ValueType bitmask, e.g. VAL_TIMEVAL vstyles_e_defaults->append (_vstyles_e_default_values); vstyles_i_defaults->append (_vstyles_i_derault_values); registered->append (_registered); // is a "live" metric aggregation->append (_aggregation); // value derived from children nodes has_value->append (_has_value); // value generated from other source unit->append (_unit); // See BaseMetric.h, e.g. UNIT_SECONDS unit_uname->append (_unit_uname); //See BaseMetric.h, fields->append (name); fields->append (username); fields->append (description); fields->append (flavors); fields->append (vtype); fields->append (vstyles_capable); fields->append (vstyles_e_defaults); fields->append (vstyles_i_defaults); fields->append (registered); fields->append (aggregation); fields->append (has_value); fields->append (unit); fields->append (unit_uname); data->append (fields); // ----- children Vector *children = curr->get_children (); int num_children = children->size (); Vector *children_list = new Vector(num_children); BaseMetricTreeNode *child_node; int index; Vec_loop (BaseMetricTreeNode*, children, index, child_node) { if (include_unregistered /* fetch everything */ || child_node->is_registered () || child_node->get_num_registered_descendents () > 0) { //Special case for metrics that aren't registered // but have registered children // Linux example: Total Time is unregistered, CPU Time is registered if (!include_unregistered && /* not fetching everything */ !child_node->is_registered () && (child_node->get_BaseMetric () != NULL || child_node->is_composite_metric ())) { Vector *registered_descendents = new Vector(); child_node->get_nearest_registered_descendents (registered_descendents); int idx2; BaseMetricTreeNode*desc_node; Vec_loop (BaseMetricTreeNode*, registered_descendents, idx2, desc_node) { Vector *desc_data; desc_data = dbeGetMetricTreeNode (desc_node, mlist, include_unregistered, has_clock_profiling_data); children_list->append (desc_data); } delete registered_descendents; continue; } Vector *child_data; child_data = dbeGetMetricTreeNode (child_node, mlist, include_unregistered, has_clock_profiling_data); children_list->append (child_data); } } data->append (children_list); return data; } Vector * dbeGetRefMetricTree (int dbevindex, bool include_unregistered) { DbeView *dbev = dbeSession->getView (dbevindex); MetricList *mlist = dbev->get_metric_list (MET_NORMAL); bool has_clock_profiling_data = false; for (long i = 0, sz = mlist->get_items ()->size (); i < sz; i++) { Metric *m = mlist->get_items ()->fetch (i); if (m->get_packet_type () == DATA_CLOCK) { has_clock_profiling_data = true; break; } } BaseMetricTreeNode *curr = dbeSession->get_reg_metrics_tree (); return dbeGetMetricTreeNode (curr, mlist, include_unregistered, has_clock_profiling_data); } static Vector * dbeGetTableDataV2Data (DbeView *dbev, Hist_data *data); static Vector *dbeGetTableDataOneColumn (Hist_data *data, int met_ind); static Vector * dbeGetTableDataOneColumn (DbeView *dbev, Vector *data, ValueTag vtype, int metricColumnNumber); static hrtime_t dbeCalcGroupDuration (int grInd) { int thisGroupSize = 1; hrtime_t max_time = 0; Experiment *exp; if (dbeSession->expGroups->size () > 0) { ExpGroup *grp = dbeSession->expGroups->fetch (grInd); thisGroupSize = grp->exps->size (); for (int ii = 0; ii < thisGroupSize; ii++) { exp = grp->exps->fetch (ii); Vector *ddscr = exp->getDataDescriptors (); delete ddscr;// getDataDescriptors() forces reading of experiment data if (exp != NULL) { hrtime_t tot_time = exp->getLastEvent () - exp->getStartTime () + exp->getRelativeStartTime (); if (max_time < tot_time) max_time = tot_time; } } } else { exp = dbeSession->get_exp (0); if (exp != NULL) max_time = exp->getLastEvent () - exp->getStartTime (); } return max_time; //nanoseconds } static hrtime_t dbeCalcGroupGCDuration (int grInd) { int thisGroupSize = 1; hrtime_t tot_time = 0; Experiment *exp; if (dbeSession->expGroups->size () > 0) { ExpGroup *grp = dbeSession->expGroups->fetch (grInd); thisGroupSize = grp->exps->size (); for (int ii = 0; ii < thisGroupSize; ii++) { exp = grp->exps->fetch (ii); Vector *ddscr = exp->getDataDescriptors (); delete ddscr; // getDataDescriptors() forces reading of experiment data if (exp != NULL) tot_time += exp->getGCDuration (); } } else { exp = dbeSession->get_exp (0); if (exp != NULL) tot_time = exp->getGCDuration (); } return tot_time; //nanoseconds } Vector * dbeGetRefMetricTreeValues (int dbevindex, Vector *metric_cmds, Vector *non_metric_cmds) { DbeView *dbev = dbeSession->getView (dbevindex); // valueTable will have N "columns" of values, where N is the number of // requested metrics and non-metrics. // Each column will be a vector with M "rows", where M is the number of // compare groups. // highlightTable mirrors the structure of valueTable. Each cell indicates // if the corresponding valueTable cell is "hot" (interesting) int numMetrics = metric_cmds->size (); int numNonMetrics = non_metric_cmds->size (); int totalColumns = numMetrics + numNonMetrics; // Columns Vector *valueTable = new Vector(totalColumns); Vector *highlightTable = new Vector(totalColumns); // the return value consists of the two tables discussed above. Vector *rc = new Vector(2); rc->append (valueTable); rc->append (highlightTable); if (dbeSession->nexps () == 0) { // no experiments are loaded for (int jj = 0; jj < totalColumns; jj++) { Vector *columnData = new Vector(); valueTable->append (columnData); highlightTable->append (columnData); } return rc; } int ngroups = dbeSession->expGroups->size (); // Rows (one per compare group) if (ngroups == 0 || !dbev->comparingExperiments ()) ngroups = 1; Vector *groupTotalTime = new Vector(ngroups); Vector *groupCpuTime = new Vector(ngroups); // initialize highlight table for (int ii = 0; ii < totalColumns; ii++) { // metrics Vector *columnData = new Vector(ngroups); highlightTable->append (columnData); for (int grInd = 0; grInd < ngroups; grInd++) columnData->store (grInd, false); // non-highlight } if (numMetrics > 0) { MetricList *bmlist; // set bmlist to list of requested base metrics BaseMetricTreeNode *root = dbeSession->get_reg_metrics_tree (); int index; char *mcmd; Vector *base_metrics = new Vector(); Vec_loop (char *, metric_cmds, index, mcmd) { BaseMetricTreeNode *bmt_node = root->find (mcmd); if (!bmt_node) abort (); //YXXX weird BaseMetric * baseNetric = bmt_node->get_BaseMetric (); if (!baseNetric) abort (); base_metrics->append (baseNetric); } // MET_INDX will create MetricList of Exclusive metrics bmlist = new MetricList (base_metrics, MET_SRCDIS); // Use the Function List to fetch values // A temporary table, v_totals, stores by group Vector *v_totals = new Vector(ngroups); for (int grInd = 0; grInd < ngroups; grInd++) { MetricList *mlist; if (ngroups > 1) mlist = dbev->get_compare_mlist (bmlist, grInd); else mlist = bmlist; if (mlist->size () != numMetrics) abort (); Hist_data *data; data = dbev->get_hist_data (mlist, Histable::FUNCTION, 0, Hist_data::ALL); Hist_data::HistItem * totals = data->get_totals (); v_totals->append (totals); } // store the Hist_data totals in valueTable { Metric *mitem; int index; Vec_loop (Metric*, bmlist->get_items (), index, mitem) { Vector * columnData = dbeGetTableDataOneColumn (dbev, v_totals, mitem->get_vtype (), index); valueTable->append (columnData); } } // 7207285: hack for hwc profiling cycles conversion: { Metric *mitem; int index; Vec_loop (Metric*, bmlist->get_items (), index, mitem) { if (mitem->is_time_val () && mitem->get_vtype () == VT_ULLONG) { Vector *cycleValues = (Vector *)valueTable->fetch (index); Vector *timeValues = new Vector(ngroups); assert (cycleValues->size () == ngroups); for (int grInd = 0; grInd < ngroups; grInd++) { long long cycles = cycleValues->fetch (grInd); int expId; if (dbeSession->expGroups->size () > 0) { ExpGroup *gr = dbeSession->expGroups->fetch (grInd); Experiment *exp = gr->exps->fetch (0); expId = exp->getExpIdx (); } else expId = -1; int clock = dbeSession->get_clock (expId); double time; if (clock) time = cycles / (1.e+6 * clock); else time = cycles; //weird timeValues->store (grInd, time); } delete cycleValues; valueTable->store (index, timeValues); } } } // Scan metrics for best measure of CPU time int bestCpuTimeIndx = -1; { Metric *mitem; int index; Vec_loop (Metric*, bmlist->get_items (), index, mitem) { BaseMetric::Type type = mitem->get_type (); if (type == BaseMetric::CP_KERNEL_CPU) { bestCpuTimeIndx = index; break; // CP_KERNEL_CPU trumps other measures } if (type == BaseMetric::CP_TOTAL_CPU) { // clock profiling CPU time bestCpuTimeIndx = index; // keep looking in case CP_KERNEL_CPU also exists continue; } bool isTime = ((mitem->get_value_styles () & VAL_TIMEVAL) != 0); bool isHwcCycles = (type == BaseMetric::HWCNTR && (dbe_strcmp (mitem->get_aux (), "cycles") == 0) && isTime); if (isHwcCycles) if (bestCpuTimeIndx < 0) bestCpuTimeIndx = index; } if (bestCpuTimeIndx >= 0) { Vector *timeValues = (Vector *)valueTable->fetch (bestCpuTimeIndx); if (timeValues->type () == VEC_DOUBLE) for (int grInd = 0; grInd < ngroups; grInd++) { double time = timeValues->fetch (grInd); groupCpuTime->append (time); } } } // Scan metrics for Total Thread time { Metric *mitem; int index; Vec_loop (Metric*, bmlist->get_items (), index, mitem) { BaseMetric::Type type = mitem->get_type (); if (type == BaseMetric::CP_TOTAL) { Vector *timeValues = (Vector *)valueTable->fetch (index); if (timeValues->type () != VEC_DOUBLE) continue; // weird for (int grInd = 0; grInd < ngroups; grInd++) { double time = timeValues->fetch (grInd); groupTotalTime->append (time); } break; } } } // highlight metrics based on cpu time #define CPUSEC_PERCENT_THRESHOLD 10.0 #define HWC_OVERFLOWS_PER_CPUSEC_THRESHOLD 15 { Metric *mitem; int index; Vec_loop (Metric*, bmlist->get_items (), index, mitem) { BaseMetric::Type type = mitem->get_type (); Vector * columnHilites = (Vector *)highlightTable->fetch (index); // always highlight the following if (index == bestCpuTimeIndx) { for (int grInd = 0; grInd < ngroups; grInd++) columnHilites->store (grInd, true); continue; } // skip certain types bool typeIsCycles = (type == BaseMetric::HWCNTR && dbe_strcmp (mitem->get_aux (), NTXT ("cycles")) == 0); bool typeIsInsts = (type == BaseMetric::HWCNTR && dbe_strcmp (mitem->get_aux (), NTXT ("insts")) == 0); if (type == BaseMetric::CP_TOTAL || type == BaseMetric::CP_TOTAL_CPU || type == BaseMetric::CP_LMS_USER || type == BaseMetric::CP_LMS_SYSTEM || type == BaseMetric::CP_LMS_TRAP || type == BaseMetric::CP_LMS_USER_LOCK || type == BaseMetric::CP_LMS_SLEEP || type == BaseMetric::CP_KERNEL_CPU || type == BaseMetric::OMP_WORK || typeIsCycles || typeIsInsts // || type == BaseMetric::CP_TOTAL_WAIT ) continue; // types we never highlight // for time values, compare against CPUSEC_PERCENT_THRESHOLD bool isTime = ((mitem->get_value_styles () & VAL_TIMEVAL) != 0); if (isTime) { if (groupCpuTime->size () == 0) continue; // no time to use as reference Vector *timeValues = (Vector *)valueTable->fetch (index); if (timeValues->type () != VEC_DOUBLE) continue; // weird for (int grInd = 0; grInd < ngroups; grInd++) { double thistime = timeValues->fetch (grInd); double usertime = groupCpuTime->fetch (grInd); if (thistime / (CPUSEC_PERCENT_THRESHOLD / 100) > usertime) columnHilites->store (grInd, true); } continue; } // for HWC event counts, look at rate of events if (type == BaseMetric::HWCNTR) { Hwcentry *hwctr = mitem->get_hw_ctr (); if (!hwctr) continue; // weird if (!hwctr->metric) continue; // raw counter if (groupCpuTime->size () == 0) continue; // no time to use as reference if (mitem->get_base_metric ()->get_dependent_bm ()) continue; // has a derived time metric, only flag time version Vector *llValues = (Vector *)valueTable->fetch (index); if (llValues->type () != VEC_LLONG) continue; // weird int overflowVal = hwctr->val; //overflow count if (!overflowVal) continue; // weird if (overflowVal > (4000000)) // cut off events that are very frequent like loads/stores // 4Ghz * (0.01 seconds/event) / (4000000 events/overflow) = 10 cycles continue; // for HWCs we could base it on the overflow rate for (int grInd = 0; grInd < ngroups; grInd++) { double thisVal = llValues->fetch (grInd); thisVal /= overflowVal; double usertime = groupCpuTime->fetch (grInd); if (thisVal > usertime * HWC_OVERFLOWS_PER_CPUSEC_THRESHOLD) columnHilites->store (grInd, true); } continue; } // check for non-zero counts of the following if (type == BaseMetric::DEADLOCKS || type == BaseMetric::RACCESS || type == BaseMetric::HEAP_ALLOC_BYTES || type == BaseMetric::HEAP_LEAK_BYTES) { Vector *llValues = (Vector *)valueTable->fetch (index); if (llValues->type () != VEC_LLONG) continue; // weird for (int grInd = 0; grInd < ngroups; grInd++) { long long thisVal = llValues->fetch (grInd); if (thisVal) columnHilites->store (grInd, true); } continue; } // continue adding cases as needed } } } if (numNonMetrics > 0) { int index; char *mcmd; Vec_loop (char *, non_metric_cmds, index, mcmd) { if (dbe_strcmp (mcmd, NTXT ("YXXX_TOTAL_TIME_PLUS_THREADS")) == 0 && groupCpuTime->size () == ngroups) { Vector *columnData = new Vector(ngroups); for (int grInd = 0; grInd < ngroups; grInd++) { double totaltime = groupTotalTime->fetch (grInd); columnData->append (dbe_sprintf (NTXT ("%0.3f %s"), totaltime, GTXT ("Seconds"))); } valueTable->append (columnData); } else if (dbe_strcmp (mcmd, L1_DURATION) == 0) { Vector *columnData = new Vector(ngroups); for (int grInd = 0; grInd < ngroups; grInd++) { hrtime_t duration = dbeCalcGroupDuration (grInd); double seconds = duration * 1.e-9; columnData->append (seconds); } valueTable->append (columnData); } else if (dbe_strcmp (mcmd, L1_GCDURATION) == 0) { Vector *columnData = new Vector(ngroups); for (int grInd = 0; grInd < ngroups; grInd++) { hrtime_t duration = dbeCalcGroupGCDuration (grInd); double seconds = duration * 1.e-9; columnData->append (seconds); } valueTable->append (columnData); } else { Vector *columnData = new Vector(ngroups); char * valueString = NTXT (""); for (int grInd = 0; grInd < ngroups; grInd++) columnData->append (dbe_strdup (valueString)); valueTable->append (columnData); } } } return rc; } Vector * dbeGetOverviewText (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); Vector *info = new Vector; char *field; int ngroups = dbeSession->expGroups->size (); // Rows (one per compare group) if (ngroups == 0 || !dbev->comparingExperiments ()) ngroups = 1; for (int grInd = 0; grInd < ngroups; grInd++) { int thisGroupSize = 1; Experiment *exp; if (dbeSession->expGroups->size () > 0) { ExpGroup *gr = dbeSession->expGroups->fetch (grInd); exp = gr->exps->fetch (0); thisGroupSize = gr->exps->size (); } else { if (dbeSession->nexps () == 0) return info; exp = dbeSession->get_exp (0); } char * expHeader; if (ngroups == 1) expHeader = dbe_strdup (GTXT ("Experiment :")); else if (grInd == 0) expHeader = dbe_strdup (GTXT ("Base Group : ")); else if (ngroups == 2) expHeader = dbe_strdup (GTXT ("Compare Group : ")); else expHeader = dbe_sprintf (GTXT ("Compare Group %d : "), grInd); if (thisGroupSize == 1) info->append (dbe_sprintf ("%s%s", expHeader, exp->get_expt_name ())); else info->append (dbe_sprintf ("%s%s (plus %d more)", expHeader, exp->get_expt_name (), thisGroupSize - 1)); free (expHeader); field = exp->uarglist; if (field && field[0]) info->append (dbe_sprintf (GTXT (" Target : '%s'"), field)); field = exp->hostname; if (field && field[0]) info->append (dbe_sprintf (GTXT (" Host : %s (%s, %s)"), field, exp->architecture ? exp->architecture : GTXT (""), exp->os_version ? exp->os_version : GTXT (""))); time_t start_sec = (time_t) exp->start_sec; char *p = ctime (&start_sec); hrtime_t tot_time = dbeCalcGroupDuration (grInd); double seconds = tot_time * 1.e-9; info->append (dbe_sprintf ( GTXT (" Start Time : %s Duration : %0.3f Seconds"), p, seconds)); // Number of descendants/processes would be nice info->append (dbe_strdup (NTXT (""))); } return info; } //-------------------------------------------------------------------------- // Set Sort by index // void dbeSetSort (int dbevindex, int sort_index, MetricType mtype, bool reverse) { DbeView *dbev; dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->setSort (sort_index, mtype, reverse); return; } // // Get annotation setting // Vector * dbeGetAnoValue (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Vector *set = new Vector(9); set->store (0, dbev->get_src_compcom ()); set->store (1, dbev->get_dis_compcom ()); set->store (2, dbev->get_thresh_src ()); set->store (3, dbev->get_thresh_src ()); set->store (4, dbev->get_src_visible ()); set->store (5, (int) dbev->get_srcmetric_visible ()); set->store (6, (int) dbev->get_hex_visible ()); set->store (7, (int) dbev->get_cmpline_visible ()); set->store (8, (int) dbev->get_func_scope ()); return set; } // // Set annotation setting // void dbeSetAnoValue (int dbevindex, Vector *set) { DbeView *dbev; dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); if (set->size () != 10) return; dbev->set_src_compcom (set->fetch (0)); dbev->set_dis_compcom (set->fetch (1)); dbev->set_thresh_src (set->fetch (2)); dbev->set_thresh_dis (set->fetch (3)); dbev->set_src_visible (set->fetch (4)); dbev->set_srcmetric_visible ((bool)set->fetch (5)); dbev->set_hex_visible ((bool)set->fetch (6)); dbev->set_cmpline_visible ((bool)set->fetch (7)); dbev->set_func_scope (set->fetch (8)); dbev->set_funcline_visible ((bool)set->fetch (9)); return; } // // Get name formats // int dbeGetNameFormat (int dbevindex) { DbeView *dbev; dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Histable::NameFormat fmt = dbev->get_name_format (); return Histable::fname_fmt (fmt); } bool dbeGetSoName (int dbevindex) { DbeView *dbev; dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Histable::NameFormat fmt = dbev->get_name_format (); return Histable::soname_fmt (fmt); } // // Set name formats // void dbeSetNameFormat (int dbevindex, int nformat, bool soname) { DbeView *dbev; dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->set_name_format (nformat, soname); } // // Get View mode // int dbeGetViewMode (int dbevindex) { DbeView *dbev; dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); return (int) dbev->get_view_mode (); } // Set View mode void dbeSetViewMode (int dbevindex, int nmode) { DbeView *dbev; dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->set_view_mode ((VMode) nmode); return; } // Get timeline setting // Vector * dbeGetTLValue (int dbevindex) { DbeView *dbev; dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Vector *strings = new Vector(); char *tldata_cmd = dbev->get_tldata (); strings->store (0, tldata_cmd); Vector *ints = new Vector(3); int val; val = dbev->get_tlmode (); ints->store (0, val); val = dbev->get_stack_align (); ints->store (1, val); val = dbev->get_stack_depth (); ints->store (2, val); Vector *objs = new Vector(2); objs->store (0, strings); objs->store (1, ints); return objs; } // // Set timeline setting // void dbeSetTLValue (int dbevindex, const char *tldata_cmd, int entitiy_prop_id, int stackalign, int stackdepth) { DbeView *dbev; dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->set_tldata (tldata_cmd); dbev->set_tlmode (entitiy_prop_id); dbev->set_stack_align (stackalign); dbev->set_stack_depth (stackdepth); return; } // // Get founder experiments and their descendants // Vector * dbeGetExpFounderDescendants () { int size = dbeSession->nexps (); if (size == 0) return NULL; Vector *table = new Vector(2); Vector *founderExpIds = new Vector(); Vector *> *subExpIds = new Vector*>(); for (int index = 0; index < size; index++) { Experiment *exp = dbeSession->get_exp (index); if (exp->founder_exp == NULL) { founderExpIds->append (exp->getExpIdx ()); Vector *subExps = new Vector(); for (int i = 0; i < exp->children_exps->size (); i++) { Experiment * subExp = exp->children_exps->fetch (i); subExps->append (subExp->getExpIdx ()); } subExpIds->append (subExps); } } table->store (0, founderExpIds); table->store (1, subExpIds); return table; } // // Get experiment selection // Vector * dbeGetExpSelection (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); int size = dbeSession->nexps (); if (size == 0) return NULL; Vector *table = new Vector(3); Vector *names = new Vector(size); Vector *enable = new Vector(size); Vector *userExpIds = new Vector(size); // Get experiment names for (int index = 0; index < size; index++) { Experiment *exp = dbeSession->get_exp (index); char *buf = dbeGetName (dbevindex, index); names->store (index, buf); bool val; val = dbev->get_exp_enable (index); enable->store (index, val); userExpIds->store (index, exp->getUserExpId ()); } table->store (0, names); table->store (1, enable); table->store (2, userExpIds); return table; } int dbeValidateFilterExpression (char *str_expr) { if (str_expr == NULL) return 0; Expression *expr = dbeSession->ql_parse (str_expr); if (expr == NULL) return 0; delete expr; return 1; } Vector * dbeGetFilterKeywords (int /* dbevindex */) { Vector *kwCategory = new Vector(); Vector *kwCategoryI18N = new Vector(); Vector *kwDataType = new Vector(); Vector *kwKeyword = new Vector(); Vector *kwFormula = new Vector(); Vector *kwDescription = new Vector(); Vector *kwEnumDescs = new Vector(); Vector *res = new Vector(7); res->append (kwCategory); res->append (kwCategoryI18N); res->append (kwDataType); res->append (kwKeyword); res->append (kwFormula); res->append (kwDescription); res->append (kwEnumDescs); char *vtypeNames[] = VTYPE_TYPE_NAMES; // section header for global definitions kwCategory->append (dbe_strdup (NTXT ("FK_SECTION"))); kwCategoryI18N->append (dbe_strdup (GTXT ("Global Definitions"))); kwDataType->append (NULL); kwKeyword->append (NULL); kwFormula->append (NULL); kwDescription->append (NULL); kwEnumDescs->append (NULL); dbeSession->get_filter_keywords (res); MemorySpace::get_filter_keywords (res); // loop thru all founder experiments int nexp = dbeSession->nexps (); for (int ii = 0; ii < nexp; ++ii) { Experiment* fexp = dbeSession->get_exp (ii); if (fexp->founder_exp != NULL) continue; // is a child; should be covered when we get to founder // section header for each founder // section header for founder experiment kwCategory->append (dbe_strdup (NTXT ("FK_SECTION"))); kwCategoryI18N->append (dbe_sprintf (NTXT ("%s [EXPGRID==%d]"), fexp->get_expt_name (), fexp->groupId)); kwDataType->append (NULL); kwKeyword->append (NULL); kwFormula->append (NULL); kwDescription->append (NULL); kwEnumDescs->append (NULL); int nchildren = fexp->children_exps->size (); Experiment *exp; // category header: Experiments { char *propUName = dbeSession->getPropUName (PROP_EXPID); // store list of subexperiments in kwEnumDescs Vector *enumDescs = new Vector(); int jj = 0; exp = fexp; while (1) { char * expBasename = get_basename (exp->get_expt_name ()); char * targetName = exp->utargname ? exp->utargname : (char *) GTXT ("(unknown)"); enumDescs->append (dbe_sprintf (NTXT ("(%d) -> %s [%s, PID %d]"), exp->getUserExpId (), expBasename, targetName, exp->getPID ())); if (jj >= nchildren) break; exp = fexp->children_exps->fetch (jj); jj++; } kwCategory->append (dbe_strdup (NTXT ("FK_EXPLIST"))); kwCategoryI18N->append (dbe_strdup (GTXT ("Experiments"))); kwDataType->append (dbe_strdup (vtypeNames[TYPE_INT32])); kwKeyword->append (dbe_strdup (NTXT ("EXPID"))); kwFormula->append (NULL); kwDescription->append (propUName); kwEnumDescs->append (enumDescs); } // select representative experiment if (nchildren == 0) exp = fexp; // founder else exp = fexp->children_exps->fetch (0); // first child int expIdx = exp->getExpIdx (); Vector *data = dbeGetDataDescriptorsV2 (expIdx); if (data == NULL) continue; Vector *dataId = (Vector*)data->fetch (0); Vector *dataName = (Vector*)data->fetch (1); Vector *dataUName = (Vector*)data->fetch (2); if (dataId == NULL || dataName == NULL) { destroy (data); continue; } // loop thru data descriptors int ndata = dataId->size (); for (int j = 0; j < ndata; ++j) { // category: data name (e.g. Clock Profiling) char * catName = dataName->fetch (j); char * dUname = dataUName ? dataUName->fetch (j) : catName; char * catUname = dUname ? dUname : catName; Vector *props = dbeGetDataPropertiesV2 (expIdx, dataId->fetch (j)); if (props == NULL) continue; Vector *propUName = (Vector*)props->fetch (1); Vector *propTypeId = (Vector *)props->fetch (2); Vector *propType = (Vector*)props->fetch (3); Vector *propName = (Vector*)props->fetch (5); Vector*> *propStateNames = (Vector*> *)props->fetch (6); Vector*> *propStateUNames = (Vector*> *)props->fetch (7); if (propName == NULL || propUName == NULL || propType == NULL || propName->size () <= 0) { destroy (props); continue; } int nprop = propName->size (); for (int k = 0; k < nprop; ++k) { if (propTypeId->fetch (k) == TYPE_OBJ) continue; if (dbe_strcmp (propName->fetch (k), NTXT ("FRINFO")) == 0) continue; // store list of states in kwEnumDescs Vector *enumDescs = new Vector(); Vector* stateNames = propStateNames->fetch (k); Vector* stateUNames = propStateUNames->fetch (k); int nStates = stateNames ? stateNames->size () : 0; for (int kk = 0; kk < nStates; ++kk) { const char *stateName = stateNames->fetch (kk); if (stateName == NULL || strlen (stateName) == 0) continue; const char *stateUName = stateUNames->fetch (kk); if (stateUName == NULL || strlen (stateUName) == 0) stateUName = stateName; enumDescs->append (dbe_sprintf (NTXT ("(%d) -> %s"), kk, stateUName)); } kwCategory->append (dbe_strdup (catName)); kwCategoryI18N->append (dbe_strdup (catUname)); kwDataType->append (dbe_strdup (propType->fetch (k))); kwKeyword->append (dbe_strdup (propName->fetch (k))); kwFormula->append (NULL); kwDescription->append (dbe_strdup (propUName->fetch (k))); kwEnumDescs->append (enumDescs); } destroy (props); } destroy (data); } return (res); } // GetFilters -- returns the list of filters for the indexed experiment // returns false if there's a problem; true otherwise // Vector * dbeGetFilters (int dbevindex, int nexp) { FilterNumeric *filt; int index; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Vector*filters = dbev->get_all_filters (nexp); if (filters == NULL) return NULL; // return an array of filter data for that experiment Vector *findex = new Vector(); // index of the filters Vector *shortname = new Vector(); // short name of filter Vector *i18n_name = new Vector(); // External I18N'd name of filter Vector *pattern = new Vector(); // current setting string Vector *status = new Vector(); // current status of filter (%, range, etc.) Vec_loop (FilterNumeric *, filters, index, filt) { findex->append (index); shortname->append (dbe_strdup (filt->get_cmd ())); i18n_name->append (dbe_strdup (filt->get_name ())); pattern->append (dbe_strdup (filt->get_pattern ())); status->append (dbe_strdup (filt->get_status ())); } Vector *res = new Vector(5); res->store (0, findex); res->store (1, shortname); res->store (2, i18n_name); res->store (3, pattern); res->store (4, status); return (res); } // Set a filter string for a view // Returns NULL if OK, error message if not char * dbeSetFilterStr (int dbevindex, char *filter_str) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->clear_error_msg (); dbev->clear_warning_msg (); char *ret = dbev->set_filter (filter_str); return ret; } // Get the current filter setting for the view char * dbeGetFilterStr (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); char *ret = dbev->get_filter (); return ret; } // Update a filters for a single experiment // Returns true if any filter->set_pattern() returns true, // implying rereading the data is needed (i.e., a filter changed) // bool dbeUpdateFilters (int dbevindex, Vector *selected, Vector *pattern_str) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->clear_error_msg (); dbev->clear_warning_msg (); // Get index of first selected experiment int size = selected->size (); int nselexp = -1; for (int index = 0; index < size; index++) { if (selected->fetch (index) == true) { nselexp = index; break; } } if (nselexp == -1) // No experiment selected return false; bool ret = false; for (int j = 0; j < size; j++) { if (selected->fetch (j) == false) continue; bool error; if (dbev->set_pattern (j, pattern_str, &error)) ret = true; } dbev->update_advanced_filter (); return ret; } char * dbeComposeFilterClause (int dbevindex, int type, int subtype, Vector *selections) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); // ask the cached data to generate the string Hist_data *data; switch (type) { case DSP_FUNCTION: data = dbev->func_data; break; case DSP_DLAYOUT: data = dbev->dlay_data; break; case DSP_DATAOBJ: data = dbev->dobj_data; break; case DSP_MEMOBJ: case DSP_INDXOBJ: data = dbev->get_indxobj_data (subtype); break; case DSP_LINE: data = dbev->line_data; break; case DSP_PC: data = dbev->pc_data; break; case DSP_SOURCE: data = dbev->src_data; break; case DSP_DISASM: data = dbev->dis_data; break; case DSP_IOACTIVITY: data = dbev->iofile_data; break; case DSP_IOVFD: data = dbev->iovfd_data; break; case DSP_IOCALLSTACK: data = dbev->iocs_data; break; case DSP_HEAPCALLSTACK: data = dbev->heapcs_data; break; default: return NULL; } if (data == NULL) return NULL; // Get array of object indices, and compose filter string Vector *obj_ids = data->get_object_indices (selections); if (obj_ids == NULL || obj_ids->size () == 0) return NULL; uint64_t sel; int index; int found = 0; char buf[128]; StringBuilder sb; sb.append ('('); switch (type) { case DSP_LINE: case DSP_PC: case DSP_SOURCE: case DSP_DISASM: case DSP_FUNCTION: sb.append (NTXT ("LEAF IN ")); break; case DSP_MEMOBJ: case DSP_INDXOBJ: sb.append (dbeSession->getIndexSpaceName (subtype)); sb.append (NTXT (" IN ")); break; } Vec_loop (uint64_t, obj_ids, index, sel) { if (found == 0) { found = 1; sb.append ('('); } else sb.append (NTXT (", ")); snprintf (buf, sizeof (buf), NTXT ("%llu"), (long long) sel); sb.append (buf); } if (found == 1) sb.append (')'); switch (type) { case DSP_DLAYOUT: case DSP_DATAOBJ: sb.append (NTXT (" SOME IN DOBJ")); break; } sb.append (')'); return sb.toString (); } // // Get load object states // Vector * dbeGetLoadObjectList (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Vector *lobjs = dbeSession->get_text_segments (); int size = lobjs->size (); // Initialize Java boolean array Vector *names = new Vector(size); Vector *states = new Vector(size); Vector *indices = new Vector(size); Vector *paths = new Vector(size); Vector *isJava = new Vector(size); // Get load object states int index; LoadObject *lo; char *lo_name; // lobjectsNoJava is a trimmed list of indices provided to front-end skipping the Java // classes. lobjectsNoJava preserves the mapping of the index into the complete lobjs // vector. What front-end sees as lobj[i] is really lobj[lobjectsNoJava[i]]; // This list is constructed every time GetLoadObjectList() or GetLoadObjectState() is // called. Possibility of further optimization by making it more persistent. // Only consumer of this list is dbeSetLoadObjectState int new_index = 0; if (dbev->lobjectsNoJava == NULL) dbev->lobjectsNoJava = new Vector(1); else dbev->lobjectsNoJava->reset (); Vec_loop (LoadObject*, lobjs, index, lo) { // Set 0, 1, or 2 for show/hide/api enum LibExpand expand = dbev->get_lo_expand (lo->seg_idx); lo_name = lo->get_name (); if (lo_name != NULL) { size_t len = strlen (lo_name); if (len > 7 && streq (lo_name + len - 7, NTXT (".class>"))) isJava->store (new_index, 1); else isJava->store (new_index, 0); } else isJava->store (new_index, 0); dbev->lobjectsNoJava->append (index); names->store (new_index, dbe_sprintf (NTXT ("%s"), lo_name)); states->store (new_index, (int) expand); indices->store (new_index, (int) lo->seg_idx); paths->store (new_index, dbe_sprintf (NTXT ("%s"), lo->get_pathname ())); new_index++; } Vector *res = new Vector(5); res->store (0, names); res->store (1, states); res->store (2, indices); res->store (3, paths); res->store (4, isJava); delete lobjs; return res; } Vector * dbeGetLoadObjectState (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Vector *lobjs = dbeSession->get_text_segments (); int size = lobjs->size (); // Initialize Java boolean array Vector *states = new Vector(size); char *lo_name; // lobjectsNoJava is a trimmed list of indices provided to front-end skipping the Java // classes. lobjectsNoJava preserves the mapping of the index into the complete lobjs // vector. What front-end sees as lobj[i] is really lobj[lobjectsNoJava[i]]; // This list is constructed every time GetLoadObjectList() or GetLoadObjectState() is // called. Possibility of further optimization by making it more persistent. // Only consumer of this list is dbeSetLoadObjectState int new_index = 0; if (dbev->lobjectsNoJava == NULL) dbev->lobjectsNoJava = new Vector(1); else dbev->lobjectsNoJava->reset (); // Get load object states int index; LoadObject *lo; Vec_loop (LoadObject*, lobjs, index, lo) { // Set 0, 1, or 2 for show/hide/api lo_name = lo->get_name (); if (lo_name != NULL) { size_t len = strlen (lo_name); if (len > 7 && streq (lo_name + len - 7, NTXT (".class>"))) continue; } else dbev->lobjectsNoJava->append (index); enum LibExpand expand = dbev->get_lo_expand (lo->seg_idx); states->store (new_index, (int) expand); new_index++; } delete lobjs; return states; } // Set load object states void dbeSetLoadObjectState (int dbevindex, Vector *selected) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Vector *lobjs = dbeSession->get_text_segments (); int index; bool changed = false; LoadObject *lo; int new_index = 0; dbev->setShowAll (); Vec_loop (LoadObject*, lobjs, index, lo) { if (dbev->lobjectsNoJava != NULL) { // This loadobject is a java class and was skipped if (dbev->lobjectsNoJava->fetch (new_index) != index) continue; } // Get array of settings enum LibExpand expand = (enum LibExpand) selected->fetch (new_index); if (expand == LIBEX_HIDE) { dbev->resetShowAll (); dbeSession->set_lib_visibility_used (); } changed = changed | dbev->set_libexpand (lo->get_pathname (), expand); new_index++; } delete lobjs; if (changed == true) { dbev->setShowHideChanged (); dbev->update_lo_expands (); } return; } // Reset load object states void dbeSetLoadObjectDefaults (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->set_libdefaults (); } // Get Machine model Vector* dbeGetCPUVerMachineModel (int dbevindex) { Vector* table = new Vector(); DbeView *dbev = dbeSession->getView (dbevindex); char * mach_model = dbev->get_settings ()->get_machinemodel (); if (mach_model != NULL) { table->append (mach_model); return table; } int grsize = dbeSession->expGroups->size (); for (int j = 0; j < grsize; j++) { ExpGroup *gr = dbeSession->expGroups->fetch (j); Vector *exps = gr->exps; for (int i = 0, sz = exps->size (); i < sz; i++) { Experiment *exp = exps->fetch (i); char *model = exp->machinemodel; if (model != NULL) table->append (dbe_strdup (model)); } } return table; } // automatically load machine model if applicable void dbeDetectLoadMachineModel (int dbevindex) { if (dbeSession->is_datamode_available ()) { char *model = dbeGetMachineModel (); if (model == NULL) { Vector* models = dbeGetCPUVerMachineModel (dbevindex); char * machineModel = NTXT ("generic"); if (models->size () > 0) { machineModel = models->get (0); for (int i = 1; i < models->size (); i++) { if (strncmp (models->get (i), machineModel, strlen (machineModel)) == 0) { machineModel = NTXT ("generic"); break; } } dbeLoadMachineModel (machineModel); } delete models; } } } // Managing Memory Objects char * dbeDefineMemObj (char *name, char *index_expr, char *machinemodel, char *sdesc, char *ldesc) { return MemorySpace::mobj_define (name, index_expr, machinemodel, sdesc, ldesc); } char * dbeDeleteMemObj (char *name) { return MemorySpace::mobj_delete (name); } Vector * dbeGetMemObjects (int /*dbevindex*/) { Vector *res = MemorySpace::getMemObjects (); return res; } // Managing machine model char * dbeLoadMachineModel (char *name) { return dbeSession->load_mach_model (name); } char * dbeGetMachineModel () { return dbeSession->get_mach_model (); } Vector * dbeListMachineModels () { return dbeSession->list_mach_models (); } // Managing Index Objects char * dbeDefineIndxObj (char *name, char *index_expr, char *sdesc, char *ldesc) { return dbeSession->indxobj_define (name, NULL, index_expr, sdesc, ldesc); } Vector * dbeGetIndxObjDescriptions (int /*dbevindex*/) { Vector *res = dbeSession->getIndxObjDescriptions (); return res; } Vector * dbeGetCustomIndxObjects (int /*dbevindex*/) { Vector *res = dbeSession->getCustomIndxObjects (); return res; } void dbeSetSelObj (int dbevindex, Obj sel_obj_or_ind, int type, int subtype) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Histable *sel_obj; Hist_data *data; int sel_ind = (int) sel_obj_or_ind; switch (type) { case DSP_FUNCTION: data = dbev->func_data; break; case DSP_LINE: data = dbev->line_data; break; case DSP_PC: data = dbev->pc_data; break; case DSP_CALLER: data = dbev->callers; break; case DSP_CALLEE: data = dbev->callees; break; case DSP_SOURCE: data = dbev->src_data; break; case DSP_DISASM: data = dbev->dis_data; break; case DSP_DLAYOUT: data = dbev->dlay_data; if (data == NULL) { dbev->sel_binctx = NULL; return; } if (sel_ind >= 0 && sel_ind < dbev->dlay_data->size ()) dbev->sel_dobj = dbev->dlay_data->fetch (sel_ind)->obj; return; case DSP_DATAOBJ: data = dbev->dobj_data; if (data == NULL) { dbev->sel_binctx = NULL; return; } if (sel_ind >= 0 && sel_ind < dbev->dobj_data->size ()) dbev->sel_dobj = dbev->dobj_data->fetch (sel_ind)->obj; return; case DSP_MEMOBJ: case DSP_INDXOBJ: dbev->set_indxobj_sel (subtype, sel_ind); sel_obj = dbev->get_indxobj_sel (subtype); if (sel_obj && sel_obj->get_type () == Histable::INDEXOBJ) dbev->set_sel_obj (((IndexObject*) sel_obj)->get_obj ()); return; case DSP_SOURCE_V2: case DSP_DISASM_V2: case DSP_TIMELINE: case DSP_LEAKLIST: case DSP_RACES: case DSP_DEADLOCKS: case DSP_DUALSOURCE: case DSP_SOURCE_DISASM: case DSP_IOACTIVITY: case DSP_IOVFD: case DSP_IOCALLSTACK: case DSP_HEAPCALLSTACK: case DSP_MINICALLER: dbev->set_sel_obj ((Histable *) sel_obj_or_ind); return; default: // abort(); return; } if (type != DSP_SOURCE && type != DSP_DISASM && type != DSP_SOURCE_V2 && type != DSP_DISASM_V2) dbev->sel_binctx = NULL; if (data == NULL || data->get_status () != Hist_data::SUCCESS || sel_ind >= data->size ()) return; if (sel_ind >= 0 && sel_ind < data->size ()) dbev->set_sel_obj (data->fetch (sel_ind)->obj); } void dbeSetSelObjV2 (int dbevindex, uint64_t id) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->set_sel_obj (dbeSession->findObjectById (id)); } Obj dbeGetSelObj (int dbevindex, int type, int subtype) { DbeView *dbev = dbeSession->getView (dbevindex); Histable *sel_obj = NULL; switch (type) { case DSP_FUNCTION: sel_obj = dbev->get_sel_obj (Histable::FUNCTION); break; case DSP_LINE: case DSP_SOURCE: case DSP_SOURCE_V2: sel_obj = dbev->get_sel_obj (Histable::LINE); break; case DSP_PC: case DSP_DISASM: case DSP_DISASM_V2: sel_obj = dbev->get_sel_obj (Histable::INSTR); break; case DSP_SRC_FILE: sel_obj = dbev->get_sel_obj (Histable::SOURCEFILE); break; case DSP_DATAOBJ: case DSP_DLAYOUT: if (dbev->sel_dobj) sel_obj = dbev->sel_dobj->convertto (Histable::DOBJECT); break; case DSP_MEMOBJ: case DSP_INDXOBJ: sel_obj = dbev->get_indxobj_sel (subtype); break; default: abort (); } Dprintf (DEBUG_DBE, NTXT ("### dbeGetSelObj: Dbe.cc:%d %s (%d) returns %s\n"), __LINE__, dsp_type_to_string (type), type, sel_obj ? sel_obj->dump () : "NULL"); return (Obj) sel_obj; } Obj dbeConvertSelObj (Obj obj, int type) { Histable *sel_obj = (Histable *) obj; Dprintf (DEBUG_DBE, NTXT ("### dbeConvertSelObj: Dbe.cc:%d %s (%d) sel_obj=%s\n"), __LINE__, dsp_type_to_string (type), type, sel_obj ? sel_obj->dump () : "NULL"); if (sel_obj == NULL) return (Obj) NULL; switch (type) { case DSP_FUNCTION: return (Obj) sel_obj->convertto (Histable::FUNCTION); case DSP_LINE: return (Obj) sel_obj->convertto (Histable::LINE); case DSP_SOURCE: case DSP_SOURCE_V2: { SourceFile* srcCtx = NULL; if (sel_obj->get_type () == Histable::INSTR) { DbeInstr* dbei = (DbeInstr *) sel_obj; srcCtx = (SourceFile*) dbei->convertto (Histable::SOURCEFILE); } else if (sel_obj->get_type () == Histable::LINE) { DbeLine * dbel = (DbeLine *) sel_obj; srcCtx = dbel->sourceFile; } sel_obj = sel_obj->convertto (Histable::LINE, srcCtx); Dprintf (DEBUG_DBE, NTXT ("### dbeConvertSelObj: Dbe.cc:%d %s (%d) returns %s\n"), __LINE__, dsp_type_to_string (type), type, sel_obj ? sel_obj->dump () : "NULL"); if (sel_obj && sel_obj->get_type () == Histable::LINE) { DbeLine * dbel = (DbeLine *) sel_obj; return (Obj) dbel->dbeline_base; } return (Obj) sel_obj->convertto (Histable::LINE, srcCtx); } case DSP_PC: case DSP_DISASM: case DSP_DISASM_V2: return (Obj) sel_obj->convertto (Histable::INSTR); case DSP_SRC_FILE: return (Obj) sel_obj->convertto (Histable::SOURCEFILE); default: abort (); } return (Obj) NULL; } uint64_t dbeGetSelObjV2 (int dbevindex, char *typeStr) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Histable *obj = NULL; if (typeStr != NULL) { if (streq (typeStr, NTXT ("FUNCTION"))) obj = dbev->get_sel_obj (Histable::FUNCTION); else if (streq (typeStr, NTXT ("INSTRUCTION"))) obj = dbev->get_sel_obj (Histable::INSTR); else if (streq (typeStr, NTXT ("SOURCELINE"))) obj = dbev->get_sel_obj (Histable::LINE); else if (streq (typeStr, NTXT ("SOURCEFILE"))) obj = dbev->get_sel_obj (Histable::SOURCEFILE); } Dprintf (DEBUG_DBE, NTXT ("### dbeGetSelObjV2: Dbe.cc:%d %s returns %s\n"), __LINE__, STR (typeStr), obj ? obj->dump () : "NULL"); return obj != NULL ? obj->id : (uint64_t) - 1; } Vector * dbeGetSelObjsIO (int dbevindex, Vector *ids, int type) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Vector *res = NULL; Vector *result = new Vector(); for (int i = 0; i < ids->size (); i++) { res = dbeGetSelObjIO (dbevindex, ids->fetch (i), type); if (res != NULL) { result->addAll (res); delete res; } } return result; } Vector * dbeGetSelObjIO (int dbevindex, uint64_t id, int type) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Histable *obj = NULL; Vector *res = NULL; int size = 0; switch (type) { case DSP_IOACTIVITY: obj = dbev->get_sel_obj_io (id, Histable::IOACTFILE); size = obj != NULL ? ((FileData*) obj)->getVirtualFds ()->size () : 0; if (size) { res = new Vector(); Vector *vfds = ((FileData*) obj)->getVirtualFds (); for (int i = 0; i < size; i++) res->append (vfds->fetch (i)); } break; case DSP_IOVFD: obj = dbev->get_sel_obj_io (id, Histable::IOACTVFD); if (obj) { res = new Vector(); res->append (obj->id); } break; case DSP_IOCALLSTACK: obj = dbev->get_sel_obj_io (id, Histable::IOCALLSTACK); if (obj) { Vector *instrs = dbeGetStackPCs (dbevindex, obj->id); if (instrs == NULL) return NULL; int stsize = instrs->size (); res = new Vector(stsize); for (int i = 0; i < stsize; i++) { Histable *objFunc = (DbeInstr*) (instrs->fetch (i)); if (objFunc->get_type () != Histable::LINE) { objFunc = objFunc->convertto (Histable::FUNCTION); res->insert (0, objFunc->id); } } delete instrs; } break; default: break; } return res; } uint64_t dbeGetSelObjHeapTimestamp (int dbevindex, uint64_t id) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Histable *obj = NULL; uint64_t res = 0; Vector *peakStackIds; Vector *peakTimestamps; // Find and return the timestamp for the peak bool foundPeakId = false; if (id > 0) { obj = dbev->get_sel_obj_heap (0); if (obj != NULL) { peakStackIds = ((HeapData*) obj)->getPeakStackIds (); peakTimestamps = ((HeapData*) obj)->getPeakTimestamps (); for (int i = 0; i < peakStackIds->size (); i++) { if (id == peakStackIds->fetch (i)) { res = peakTimestamps->fetch (i); foundPeakId = true; break; } } } } // Return the first timestamp for the peak // if the callstack id is zero or it // doesn't match with the peak stack id if (id == 0 || !foundPeakId) { obj = dbev->get_sel_obj_heap (0); res = obj != NULL ? ((HeapData*) obj)->getPeakTimestamps ()->fetch (0) : 0; } return res; } int dbeGetSelObjHeapUserExpId (int dbevindex, uint64_t id) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Histable *obj = NULL; int res = 0; obj = dbev->get_sel_obj_heap (id); res = obj != NULL ? ((HeapData*) obj)->getUserExpId () : 0; return res; } // // Get index of selected function/object // int dbeGetSelIndex (int dbevindex, Obj sel_obj, int type, int subtype) { Hist_data *data; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); switch (type) { case DSP_FUNCTION: data = dbev->func_data; break; case DSP_LINE: data = dbev->line_data; break; case DSP_PC: data = dbev->pc_data; break; case DSP_SOURCE: case DSP_SOURCE_V2: data = dbev->src_data; break; case DSP_DISASM: case DSP_DISASM_V2: data = dbev->dis_data; break; case DSP_DLAYOUT: data = dbev->dlay_data; break; case DSP_DATAOBJ: data = dbev->dobj_data; break; case DSP_MEMOBJ: case DSP_INDXOBJ: data = dbev->get_indxobj_data (subtype); break; default: data = NULL; break; } if (data == NULL || data->get_status () != Hist_data::SUCCESS) return -1; Histable *chk_obj = (Histable *) sel_obj; Vector *histItems = data->get_hist_items (); if (histItems == NULL || chk_obj == NULL) return -1; for (int i = 0, sz = histItems->size (); i < sz; i++) { if (histItems->get (i)->obj == chk_obj) return i; if (histItems->get (i)->obj == NULL) continue; if (histItems->get (i)->obj->get_type () == Histable::LINE && chk_obj->get_type () == Histable::LINE) { if (((DbeLine*) histItems->get (i)->obj)->convertto (Histable::FUNCTION) == ((DbeLine*) chk_obj)->convertto (Histable::FUNCTION) && ((DbeLine*) histItems->get (i)->obj)->lineno == ((DbeLine*) chk_obj)->lineno) return i; } else if (histItems->get (i)->obj->get_type () == Histable::INSTR && chk_obj->get_type () == Histable::INSTR) if (((DbeInstr*) histItems->get (i)->obj)->convertto (Histable::FUNCTION) == ((DbeInstr*) chk_obj)->convertto (Histable::FUNCTION) && ((DbeInstr*) histItems->get (i)->obj)->addr == ((DbeInstr*) chk_obj)->addr) return i; } Histable *chk_obj1 = NULL; switch (type) { case DSP_FUNCTION: chk_obj1 = chk_obj->convertto (Histable::FUNCTION); break; case DSP_LINE: case DSP_SOURCE: case DSP_SOURCE_V2: chk_obj1 = chk_obj->convertto (Histable::LINE); break; case DSP_PC: case DSP_DISASM: case DSP_DISASM_V2: chk_obj1 = chk_obj->convertto (Histable::INSTR); break; } if (chk_obj1 && chk_obj != chk_obj1) for (int i = 0, sz = histItems->size (); i < sz; i++) if (histItems->get (i)->obj == chk_obj1) return i; if (type == DSP_LINE) { for (int i = 0, sz = histItems->size (); i < sz; i++) if (histItems->get (i)->obj != NULL && chk_obj->convertto (Histable::FUNCTION) == histItems->get (i)->obj->convertto (Histable::FUNCTION)) return i; } else if (type == DSP_PC) { for (int i = 0, sz = histItems->size (); i < sz; i++) if (histItems->get (i)->obj != NULL && (histItems->get (i)->obj)->convertto (Histable::FUNCTION) == (chk_obj)->convertto (Histable::FUNCTION) && ((DbeLine*) histItems->get (i)->obj->convertto (Histable::LINE))->lineno == ((DbeLine*) chk_obj->convertto (Histable::LINE))->lineno) return i; for (int i = 0, sz = histItems->size (); i < sz; i++) if (histItems->get (i)->obj != NULL && (histItems->get (i)->obj)->convertto (Histable::FUNCTION) == (chk_obj)->convertto (Histable::FUNCTION)) return i; } // If we clicked on an mfunction line in the called-by call mini in user mode for omp // we might not find that function in func data if (dbev->isOmpDisMode () && type == DSP_FUNCTION) { int p = dbeGetSelIndex (dbevindex, sel_obj, DSP_DISASM, subtype); if (p != -1) return p; } return -1; } // Print data // char * dbePrintData (int dbevindex, int type, int subtype, char *printer, char *fname, FILE *outfile) { Histable *current_obj; Function *func; Module *module; MetricList *mlist_orig; bool header; Print_params params; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); // Set print parameters if (printer != NULL) { params.dest = DEST_PRINTER; params.name = printer; } else if (outfile != NULL) { params.dest = DEST_OPEN_FILE; params.openfile = outfile; params.name = NULL; } else { params.dest = DEST_FILE; params.name = fname; if (*(params.name) == '\0') { free (params.name); return dbe_strdup (GTXT ("Please enter the name of the file to which to print")); } } params.ncopies = 1; if (outfile != NULL) header = false; else header = !(type == DSP_SOURCE || type == DSP_SOURCE_V2 || type == DSP_DISASM_V2); params.header = header; // figure out what kind of metrics to use if (type == DSP_SELF || type == DSP_CALLER || type == DSP_CALLEE || type == DSP_CALLTREE) mlist_orig = dbev->get_metric_list (MET_CALL); else if (type == DSP_DATAOBJ || type == DSP_DLAYOUT || type == DSP_MEMOBJ) mlist_orig = dbev->get_metric_list (MET_DATA); else if (type == DSP_INDXOBJ) mlist_orig = dbev->get_metric_list (MET_INDX); else if (type == DSP_IOACTIVITY || type == DSP_IOVFD || type == DSP_IOCALLSTACK) mlist_orig = dbev->get_metric_list (MET_IO); else if (type == DSP_HEAPCALLSTACK) mlist_orig = dbev->get_metric_list (MET_HEAP); else mlist_orig = dbev->get_metric_list (MET_NORMAL); // make a compacted version of the input list // the list will either be moved to the generated data, // or freed below if it wasn't needed MetricList *mlist = new MetricList (mlist_orig); Hist_data *data = NULL; er_print_common_display *cd = NULL; int ix; // Set data switch (type) { case DSP_FUNCTION: case DSP_LINE: case DSP_PC: case DSP_MEMOBJ: case DSP_INDXOBJ: case DSP_DATAOBJ: data = dbev->get_hist_data (mlist, ((type == DSP_FUNCTION) ? Histable::FUNCTION : (type == DSP_LINE) ? Histable::LINE : (type == DSP_PC) ? Histable::INSTR : (type == DSP_INDXOBJ) ? Histable::INDEXOBJ : (type == DSP_MEMOBJ) ? Histable::MEMOBJ : Histable::DOBJECT), subtype, Hist_data::ALL); if (data->get_status () != Hist_data::SUCCESS) return DbeView::status_str (DbeView::DBEVIEW_NO_DATA); // no strdup() cd = new er_print_histogram (dbev, data, mlist, MODE_LIST, dbev->get_limit (), mlist->get_sort_name (), NULL, true, true); break; case DSP_DLAYOUT: { data = dbev->get_hist_data (mlist, Histable::DOBJECT, 0, Hist_data::LAYOUT); if (data->get_status () != Hist_data::SUCCESS) return DbeView::status_str (DbeView::DBEVIEW_NO_DATA); // no strdup() cd = new er_print_histogram (dbev, data, mlist, MODE_ANNOTATED, dbev->get_thresh_dis (), mlist->get_sort_name (), NULL, true, true); break; } // source and disassembly case DSP_SOURCE: case DSP_DISASM: case DSP_SOURCE_V2: case DSP_DISASM_V2: if (dbev->sel_obj == NULL) return NULL; current_obj = dbev->sel_obj->convertto (Histable::FUNCTION); if (current_obj->get_type () != Histable::FUNCTION) return dbe_strdup (GTXT ("Not a real function; no source or disassembly available.")); func = (Function*) current_obj->convertto (Histable::FUNCTION); if (func->flags & FUNC_FLAG_SIMULATED) return dbe_strdup (GTXT ("Not a real function; no source or disassembly available.")); if (func->get_name () == NULL) return dbe_strdup (GTXT ("Source location not recorded in experiment")); module = func->module; if (module == NULL || module->get_name () == NULL) return dbe_strdup (GTXT ("Object name not recorded in experiment")); ix = module->loadobject->seg_idx; if (dbev->get_lo_expand (ix) == LIBEX_HIDE) return dbe_strdup (GTXT ("No source or disassembly available for hidden object")); cd = new er_print_histogram (dbev, dbev->func_data, mlist, MODE_ANNOTATED, type == DSP_DISASM || type == DSP_DISASM_V2, mlist->get_sort_name (), func, false, false); break; // callers-callees case DSP_SELF: case DSP_CALLER: case DSP_CALLEE: if (dbev->sel_obj == NULL) return NULL; current_obj = dbev->sel_obj->convertto (Histable::FUNCTION); cd = new er_print_histogram (dbev, dbev->func_data, mlist, MODE_GPROF, 1, mlist->get_sort_name (), current_obj, false, false); break; // statistics; this won't use the metric list copied above, so delete it case DSP_STATIS: cd = new er_print_experiment (dbev, 0, dbeSession->nexps () - 1, true, true, true, true, false); delete mlist; break; case DSP_EXP: cd = new er_print_experiment (dbev, 0, dbeSession->nexps () - 1, true, true, false, false, false); delete mlist; break; case DSP_LEAKLIST: cd = new er_print_leaklist (dbev, true, true, dbev->get_limit ()); delete mlist; break; case DSP_HEAPCALLSTACK: cd = new er_print_heapactivity (dbev, Histable::HEAPCALLSTACK, false, dbev->get_limit ()); delete mlist; break; case DSP_IOACTIVITY: cd = new er_print_ioactivity (dbev, Histable::IOACTFILE, false, dbev->get_limit ()); delete mlist; break; case DSP_IOVFD: cd = new er_print_ioactivity (dbev, Histable::IOACTVFD, false, dbev->get_limit ()); delete mlist; break; // the io call stack case DSP_IOCALLSTACK: cd = new er_print_ioactivity (dbev, Histable::IOCALLSTACK, false, dbev->get_limit ()); delete mlist; break; // some unknown panel -- return an error string default: delete mlist; return dbe_strdup (GTXT ("Print not available")); } // Start printing char *buf = NULL; // first open the file/device/whatever if (cd->open (¶ms) == 0) { // now call the actual print routine cd->data_dump (); if (params.dest == DEST_PRINTER) { if (streq ((char *) params.name, NTXT ("-"))) { // Special case - return report to the GUI int maxbytes = 2 * 1024 * 1024; // IPC large buffer limit char *report = cd->get_output (maxbytes); delete data; delete cd; return report; // TEMPORARY } } if (cd->print_output () == false) buf = dbe_sprintf (NTXT ("%s: %s"), GTXT ("Unable to submit print request to"), params.name); } else // if unable to set up the print, return an error buf = dbe_sprintf (NTXT ("%s: %s"), GTXT ("Unable to open file"), params.name); // dbe_free((void *) params.name); XXX when should this happen? if (data) if (data->isViewOwned () == false) delete data; delete cd; return buf; } // Set limit for print data // char * dbeSetPrintLimit (int dbevindex, int limit) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); return (dbev->set_limit (limit)); } // get limit for print data int dbeGetPrintLimit (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); int limit = dbev->get_limit (); return limit; } // set printmode for data char * dbeSetPrintMode (int dbevindex, char * pmode) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); char *r = dbev->set_printmode (pmode); return r; } // get printmode for data int dbeGetPrintMode (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); return (dbev->get_printmode ()); } // get printmode for data char * dbeGetPrintModeString (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); return ( dbev->get_printmode_str ()); } // get print delimiter for csv data char dbeGetPrintDelim (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); return (dbev->get_printdelimiter ()); } // Set Source/Object/Load-Object file names static void set_file_names (Function *func, char *names[3]) { Module *module = func->module; LoadObject *loadobject = module->loadobject; if (loadobject == NULL) loadobject = dbeSession->get_Unknown_LoadObject (); free (names[0]); free (names[1]); free (names[2]); SourceFile *sf = func->getDefSrc (); char *src_name = sf->dbeFile->get_location_info (); DbeFile *df = module->dbeFile; if (df == NULL || (df->filetype & DbeFile::F_JAVACLASS) == 0) df = module->loadobject->dbeFile; char *lo_name = df->get_location_info (); char *dot_o_name = lo_name; if (module->dot_o_file) dot_o_name = module->dot_o_file->dbeFile->get_location_info (); names[0] = dbe_sprintf (NTXT ("%s: %s"), GTXT ("Source File"), src_name); names[1] = dbe_sprintf (NTXT ("%s: %s"), GTXT ("Object File"), dot_o_name); names[2] = dbe_sprintf (NTXT ("%s: %s"), GTXT ("Load Object"), lo_name); } // dbeSetFuncData // Master function to generate all Tab data for the analyzer // Returns the index of the selected item in the specified list // // After calling it to set up, the Analyzer calls dbeGetFuncList // to format the generated data and return the table // Most of the data is destined for a JTable // int dbeSetFuncData (int dbevindex, Obj sel_obj, int type, int subtype) { MetricList *_mlist; Histable *org_obj; Hist_data *data = NULL; int index, sel_index; Function *func; char *name; int ix; DbeView *dbev = dbeSession->getView (dbevindex); sel_index = -1; dbev->resetOmpDisMode (); dbev->error_msg = dbev->warning_msg = NULL; // get metric list, make a compact duplicate _mlist = dbev->get_metric_list (MET_NORMAL); MetricList *mlist = new MetricList (_mlist); // Remove old function/obj list data & Get new function/obj list data org_obj = (Histable *) sel_obj; // Figure out which "function" data is being asked for, i.e., // which of the analyzer displays is asking for data switch (type) { // the various tables: functions, lines, PCs, DataObjects, IndexObjects case DSP_FUNCTION: case DSP_LINE: case DSP_PC: case DSP_DATAOBJ: case DSP_MEMOBJ: case DSP_INDXOBJ: switch (type) { case DSP_FUNCTION: if (dbev->func_data) delete dbev->func_data; dbev->func_data = data = dbev->get_hist_data (mlist, Histable::FUNCTION, subtype, Hist_data::ALL); break; case DSP_LINE: if (dbev->line_data) delete dbev->line_data; dbev->line_data = data = dbev->get_hist_data (mlist, Histable::LINE, subtype, Hist_data::ALL); break; case DSP_PC: if (dbev->pc_data) delete dbev->pc_data; dbev->pc_data = data = dbev->get_hist_data (mlist, Histable::INSTR, subtype, Hist_data::ALL); break; case DSP_DATAOBJ: if (dbev->dobj_data) delete dbev->dobj_data; mlist = dbev->get_metric_list (MET_DATA); dbev->dobj_data = data = dbev->get_hist_data (mlist, Histable::DOBJECT, subtype, Hist_data::ALL); break; case DSP_MEMOBJ: mlist = dbev->get_metric_list (MET_DATA); data = dbev->get_hist_data (mlist, Histable::MEMOBJ, subtype, Hist_data::ALL); dbev->indx_data->store (subtype, data); break; case DSP_INDXOBJ: mlist = dbev->get_metric_list (MET_INDX); data = dbev->get_hist_data (mlist, Histable::INDEXOBJ, subtype, Hist_data::ALL); dbev->indx_data->store (subtype, data); break; default: break; } // Set the selection of row item if (data->get_status () == Hist_data::SUCCESS) { // otherwise, look for it sel_index = -1; if (org_obj) { Hist_data::HistItem *hi; Vec_loop (Hist_data::HistItem*, data->get_hist_items (), index, hi) { if (hi->obj == org_obj) { sel_index = index; break; } } if (sel_index == -1 && (type == DSP_LINE || type == DSP_PC)) { Vec_loop (Hist_data::HistItem*, data->get_hist_items (), index, hi) { name = hi->obj->get_name (); if (strcmp (name, NTXT ("")) && strcmp (name, GTXT (""))) { int done = 0; switch (type) { case DSP_LINE: if (org_obj->convertto (Histable::FUNCTION) == hi->obj->convertto (Histable::FUNCTION)) { sel_index = index; done = 1; } break; case DSP_PC: if (hi->obj->convertto (Histable::FUNCTION) == org_obj->convertto (Histable::FUNCTION) && ((DbeLine*) hi->obj->convertto (Histable::LINE))->lineno == ((DbeLine*) org_obj->convertto (Histable::LINE))->lineno) { sel_index = index; done = 1; } break; } if (done) break; } } } if (sel_index == -1 && type == DSP_PC) { Vec_loop (Hist_data::HistItem*, data->get_hist_items (), index, hi) { name = hi->obj->get_name (); if (strcmp (name, NTXT ("")) && strcmp (name, GTXT (""))) { int done = 0; if (hi->obj->convertto (Histable::FUNCTION) == org_obj->convertto (Histable::FUNCTION)) { sel_index = index; done = 1; } if (done) break; } } } } if (sel_index == -1) { Hist_data::HistItem *hi; Vec_loop (Hist_data::HistItem*, data->get_hist_items (), index, hi) { name = hi->obj->get_name (); if (strcmp (name, NTXT ("")) && strcmp (name, GTXT (""))) { sel_index = index; break; } } } } else dbev->error_msg = DbeView::status_str (DbeView::DBEVIEW_NO_DATA); return sel_index; // the end of the code for the regular tables // Data Layout case DSP_DLAYOUT: if (dbev->dlay_data) delete dbev->dlay_data; dbev->marks->reset (); mlist = dbev->get_metric_list (MET_DATA); // initial dobj list ... data = dbev->get_hist_data (mlist, Histable::DOBJECT, subtype, Hist_data::LAYOUT); // .. provides metric data for layout dbev->dlay_data = data = dbev->get_data_space ()->get_layout_data (data, dbev->marks, dbev->get_thresh_dis ()); if (data->get_status () != Hist_data::SUCCESS) dbev->error_msg = DbeView::status_str (DbeView::DBEVIEW_NO_DATA); return sel_index; // Source or disassembly case DSP_SOURCE_V2: case DSP_DISASM_V2: case DSP_SOURCE: case DSP_DISASM: { if (org_obj == NULL) { dbev->error_msg = DbeView::status_str (DbeView::DBEVIEW_NO_SEL_OBJ); return sel_index; } if (org_obj->get_type () != Histable::FUNCTION) { dbev->error_msg = dbe_strdup ( GTXT ("Not a real function; no source or disassembly available.")); return sel_index; } func = (Function *) org_obj; if (func->flags & FUNC_FLAG_SIMULATED) { dbev->error_msg = dbe_strdup ( GTXT ("Not a real function; no source or disassembly available.")); return sel_index; } if (func->get_name () == NULL) { dbev->error_msg = dbe_strdup ( GTXT ("Source location not recorded in experiment")); return sel_index; } Module *module = func->module; if ((module == NULL) || (module->get_name () == NULL)) { dbev->error_msg = dbe_strdup ( GTXT ("Object name not recorded in experiment")); return sel_index; } ix = module->loadobject->seg_idx; if (dbev->get_lo_expand (ix) == LIBEX_HIDE) { dbev->error_msg = dbe_strdup ( GTXT ("No source or disassembly available for hidden object")); return sel_index; } if ((type == DSP_DISASM || type == DSP_DISASM_V2) && dbev->get_view_mode () == VMODE_USER && dbeSession->is_omp_available ()) dbev->setOmpDisMode (); dbev->marks->reset (); SourceFile *srcContext = NULL; switch (dbev->sel_obj->get_type ()) { case Histable::FUNCTION: { Function *f = (Function *) dbev->sel_obj; srcContext = f->getDefSrc (); dbev->sel_binctx = f->module; break; } case Histable::LINE: { DbeLine *dl = (DbeLine *) dbev->sel_obj; srcContext = dl->sourceFile; Function *f = dl->func; if (f) dbev->sel_binctx = f; break; } case Histable::INSTR: { Function *f = (Function *) dbev->sel_obj->convertto (Histable::FUNCTION); if (f) { dbev->sel_binctx = f; srcContext = f->getDefSrc (); } break; } default: break; } mlist = dbev->get_metric_list (MET_SRCDIS); // for source and disassembly the name needs to be invisible, // but that's handled in the module code if (type == DSP_SOURCE) { if (dbev->src_data) delete dbev->src_data; // func_data computation needed for get_totals if (dbev->func_data == NULL) dbev->func_data = data = dbev->get_hist_data (mlist, Histable::FUNCTION, subtype, Hist_data::ALL); dbev->marks2dsrc->reset (); dbev->marks2dsrc_inc->reset (); data = dbev->src_data = module->get_data (dbev, mlist, Histable::LINE, dbev->func_data->get_totals ()->value, srcContext, func, dbev->marks, dbev->get_thresh_src (), dbev->get_src_compcom (), dbev->get_src_visible (), dbev->get_hex_visible (), false, false, dbev->marks2dsrc, dbev->marks2dsrc_inc); set_file_names (func, dbev->names_src); if (srcContext) { free (dbev->names_src[0]); dbev->names_src[0] = dbe_sprintf (GTXT ("Source File: %s"), srcContext->dbeFile->get_location_info ()); } Obj obj = (Obj) func->convertto (Histable::LINE, srcContext); sel_index = dbeGetSelIndex (dbevindex, obj, type, subtype); } else { /* type == DSP_DISASM */ if (dbev->dis_data) delete dbev->dis_data; // func_data computation needed for get_totals if (dbev->func_data == NULL) dbev->func_data = data = dbev->get_hist_data (mlist, Histable::FUNCTION, subtype, Hist_data::ALL); dbev->marks2ddis->reset (); dbev->marks2ddis_inc->reset (); data = dbev->dis_data = module->get_data (dbev, mlist, Histable::INSTR, dbev->func_data->get_totals ()->value, srcContext, func, dbev->marks, dbev->get_thresh_dis (), dbev->get_dis_compcom (), dbev->get_src_visible (), dbev->get_hex_visible (), dbev->get_func_scope (), false, dbev->marks2ddis, dbev->marks2ddis_inc); set_file_names (func, dbev->names_dis); if (srcContext) { free (dbev->names_dis[0]); dbev->names_dis[0] = dbe_sprintf (GTXT ("Source File: %s"), srcContext->dbeFile->get_location_info ()); } Obj obj = (Obj) func->convertto (Histable::INSTR); sel_index = dbeGetSelIndex (dbevindex, obj, type, subtype); } return sel_index; } // the three cases for caller-callee case DSP_SELF: case DSP_CALLER: case DSP_CALLEE: if (org_obj == NULL) { dbev->error_msg = DbeView::status_str (DbeView::DBEVIEW_NO_SEL_OBJ); return sel_index; } // Caller data if (dbev->callers) delete dbev->callers; mlist = dbev->get_metric_list (MET_CALL); dbev->callers = dbev->get_hist_data (mlist, Histable::FUNCTION, subtype, Hist_data::CALLERS, org_obj); if (dbev->callers->get_status () != Hist_data::SUCCESS) { dbev->error_msg = DbeView::status_str (DbeView::DBEVIEW_NO_DATA); return sel_index; } // Callee data if (dbev->callees) delete dbev->callees; dbev->callees = dbev->get_hist_data (mlist, Histable::FUNCTION, subtype, Hist_data::CALLEES, org_obj); if (dbev->callees->get_status () != Hist_data::SUCCESS) { dbev->error_msg = DbeView::status_str (DbeView::DBEVIEW_NO_DATA); return sel_index; } // Center Function item if (dbev->fitem_data) delete dbev->fitem_data; dbev->fitem_data = dbev->get_hist_data (mlist, Histable::FUNCTION, subtype, Hist_data::SELF, org_obj); if (dbev->fitem_data->get_status () != Hist_data::SUCCESS) { dbev->error_msg = DbeView::status_str (DbeView::DBEVIEW_NO_DATA); return sel_index; } return sel_index; default: abort (); } return sel_index; } Vector* dbeGetTotals (int dbevindex, int dsptype, int subtype) { DbeView *dbev = dbeSession->getView (dbevindex); MetricList *mlist = dbev->get_metric_list (dsptype, subtype); Hist_data *data = dbev->get_hist_data (mlist, Histable::FUNCTION, 0, Hist_data::ALL); Hist_data::HistItem *totals = data->get_totals (); Vector *tbl = new Vector(mlist->size ()); for (long i = 0, sz = mlist->size (); i < sz; i++) { Metric *m = mlist->get (i); switch (m->get_vtype ()) { case VT_DOUBLE: { Vector *lst = new Vector(1); lst->append (totals->value[i].d); tbl->append (lst); break; } case VT_INT: { Vector *lst = new Vector(1); lst->append (totals->value[i].i); tbl->append (lst); break; } case VT_LLONG: case VT_ULLONG: case VT_ADDRESS: { Vector *lst = new Vector(1); lst->append (totals->value[i].ll); tbl->append (lst); break; } case VT_LABEL: { Vector *lst = new Vector(1); Histable::NameFormat nfmt = dbev->get_name_format (); lst->append (dbe_strdup (totals->obj->get_name (nfmt))); tbl->append (lst); break; } default: abort (); } } Vector *res = new Vector(2); res->append (dbeGetMetricList (mlist)); res->append (tbl); return res; } Vector* dbeGetHotMarks (int dbevindex, int type) { Vector* table = new Vector(2); Vector* table0 = new Vector (); Vector* table1 = new Vector (); DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) return NULL; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: for (int i = 0; i < dbev->marks2dsrc->size (); i++) { table0->append (dbev->marks2dsrc->fetch (i).index1); table1->append (dbev->marks2dsrc->fetch (i).index2); } break; case DSP_DISASM: case DSP_DISASM_V2: for (int i = 0; i < dbev->marks2ddis->size (); i++) { table0->append (dbev->marks2ddis->fetch (i).index1); table1->append (dbev->marks2ddis->fetch (i).index2); } break; default: break; } table->store (0, table0); table->store (1, table1); return table; } Vector* dbeGetHotMarksInc (int dbevindex, int type) { Vector* table = new Vector(2); Vector* table0 = new Vector (); Vector* table1 = new Vector (); DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) return NULL; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: for (int i = 0; i < dbev->marks2dsrc_inc->size (); i++) { table0->append (dbev->marks2dsrc_inc->fetch (i).index1); table1->append (dbev->marks2dsrc_inc->fetch (i).index2); } break; case DSP_DISASM: case DSP_DISASM_V2: for (int i = 0; i < dbev->marks2ddis_inc->size (); i++) { table0->append (dbev->marks2ddis_inc->fetch (i).index1); table1->append (dbev->marks2ddis_inc->fetch (i).index2); } break; default: break; } table->store (0, table0); table->store (1, table1); return table; } Vector* dbeGetSummaryHotMarks (int dbevindex, Vector *sel_objs, int type) { Vector* table = new Vector(2); Vector* table0 = new Vector (); Vector* table1 = new Vector (); DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) return NULL; if (sel_objs == NULL || sel_objs->size () == 0) return NULL; Hist_data *data; Vector *marks2d; Vector* marks2d_inc; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: data = dbev->src_data; marks2d = dbev->marks2dsrc; marks2d_inc = dbev->marks2dsrc_inc; break; case DSP_DISASM: case DSP_DISASM_V2: data = dbev->dis_data; marks2d = dbev->marks2ddis; marks2d_inc = dbev->marks2ddis_inc; break; default: data = NULL; marks2d = NULL; marks2d_inc = NULL; break; } if (data == NULL || data->get_status () != Hist_data::SUCCESS || marks2d_inc == NULL || marks2d == NULL) return NULL; MetricList *orig_mlist = data->get_metric_list (); MetricList *prop_mlist = new MetricList (dbev->get_metric_ref (MET_NORMAL)); if (prop_mlist && dbev->comparingExperiments ()) prop_mlist = dbev->get_compare_mlist (prop_mlist, 0); Metric *mitem; int index, index2; index2 = 0; Vec_loop (Metric*, prop_mlist->get_items (), index, mitem) { if (mitem->get_subtype () == Metric::STATIC) continue; for (int i = 0; i < marks2d_inc->size (); i++) { int found = 0; for (int j = 0; j < sel_objs->size (); j++) { int sel_index = (int) sel_objs->fetch (j); int marked_index = marks2d_inc->fetch (i).index1; if (sel_index == marked_index) { found = 1; break; } } if (!found) continue; int mindex = marks2d_inc->fetch (i).index2; Metric *orig_metric = orig_mlist->get_items ()->fetch (mindex); if (orig_metric->get_id () == mitem->get_id () && mitem->get_subtype () == Metric::INCLUSIVE) { table0->append (index2); table1->append (1); } } for (int i = 0; i < marks2d->size (); i++) { int found = 0; for (int j = 0; j < sel_objs->size (); j++) { int sel_index = (int) sel_objs->fetch (j); int marked_index = marks2d->fetch (i).index1; if (sel_index == marked_index) { found = 1; break; } } if (!found) continue; int mindex = marks2d->fetch (i).index2; Metric *orig_metric = orig_mlist->get_items ()->fetch (mindex); if (orig_metric->get_id () == mitem->get_id () && mitem->get_subtype () == Metric::EXCLUSIVE) { table0->append (index2); table1->append (0); } } if (!(mitem->get_subtype () == Metric::EXCLUSIVE || mitem->get_subtype () == Metric::DATASPACE)) index2++; } table->store (0, table0); table->store (1, table1); return table; } // Get a vector of function ids of data(begin, begin + length - 1) // Currently only support source/disassembly view Vector* dbeGetFuncId (int dbevindex, int type, int begin, int length) { Vector* table = new Vector (); DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Hist_data *data; Function* given_func = NULL; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: data = dbev->src_data; break; case DSP_DISASM: case DSP_DISASM_V2: data = dbev->dis_data; break; default: data = NULL; abort (); } if (data == NULL || data->get_status () != Hist_data::SUCCESS) return NULL; if (begin < 0 || begin + length > data->size ()) return NULL; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: case DSP_DISASM: case DSP_DISASM_V2: { for (int i = begin; i < begin + length; i++) { given_func = NULL; Histable * sel_obj = data->fetch (i)->obj; if (sel_obj != NULL) given_func = (Function*) (sel_obj)->convertto (Histable::FUNCTION, (Histable*) dbev); if (given_func == NULL) table->append (0); else table->append (given_func->id); } } break; default: abort (); } return table; } Vector* dbeGetFuncCallerInfo (int dbevindex, int type, Vector* idxs, int groupId) { Vector* data = new Vector(); if (type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) { Obj sel_func = dbeGetSelObj (dbevindex, DSP_FUNCTION, 0); if (sel_func == 0) return data; Vector * cmpObjs = dbeGetComparableObjsV2 (dbevindex, sel_func, type); if (cmpObjs == NULL) return data; DbeView *dbev = dbeSession->getView (dbevindex); int mtype = MET_COMMON | COMPARE_BIT | ((groupId + 1) << GROUP_ID_SHIFT); MetricList *mlist = dbev->get_metric_list ((MetricType) (mtype & MTYPE_MASK), (mtype & COMPARE_BIT) != 0, mtype >> GROUP_ID_SHIFT); Histable *selObj = (Histable *) cmpObjs->fetch (groupId); int subtype = 0; Hist_data *hist_data = dbev->get_data (mlist, selObj, type, subtype); if (hist_data == NULL) return data; } for (int i = 0; i < idxs->size (); i++) data->append (dbeGetFuncCallerInfoById (dbevindex, type, idxs->fetch (i))); return data; } // // Get Table of Caller info: // param: idx -- selected AT_FUNC row // return: callsite_id, callsite_name (function: file: line) Vector* dbeGetFuncCallerInfoById (int dbevindex, int type, int idx) { Vector* table = new Vector(3); Vector* table0 = new Vector (); Vector* table1 = new Vector (); Vector* table2 = new Vector(); DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Hist_data *data; Function* given_func = NULL; Vector *instr_info = NULL; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: data = dbev->src_data; break; case DSP_DISASM: case DSP_DISASM_V2: data = dbev->dis_data; break; default: data = NULL; abort (); } if (data == NULL || data->get_status () != Hist_data::SUCCESS) return NULL; if (idx < 0 || idx >= data->size ()) return NULL; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: case DSP_DISASM: case DSP_DISASM_V2: { Histable * sel_obj = data->fetch (idx)->obj; if (sel_obj == NULL) return NULL; given_func = (Function*) (sel_obj)->convertto (Histable::FUNCTION, (Histable*) dbev); if (given_func == NULL) return NULL; PathTree * ptree = dbev->get_path_tree (); if (ptree == NULL) return NULL; instr_info = ptree->get_clr_instr (given_func); DefaultMap * line_seen = new DefaultMap(); for (int j = 0; j < ((Vector*)instr_info)->size (); j++) { Histable *instr = ((Vector*)instr_info)->fetch (j); Function *cur_func = NULL; if (instr->get_type () == Histable::INSTR) cur_func = ((DbeInstr*) instr)->func; else if (instr->get_type () == Histable::LINE) cur_func = ((DbeLine*) instr)->func; if (cur_func == NULL || (cur_func->flags & FUNC_FLAG_SIMULATED)) continue; // skip functions like Histable* line; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: if (cur_func != NULL) { SourceFile *sourceFile = cur_func->getDefSrc (); if (sourceFile == NULL || (sourceFile->flags & SOURCE_FLAG_UNKNOWN) != 0) continue; // skip functions like } line = instr->convertto (Histable::LINE, NULL); break; case DSP_DISASM: case DSP_DISASM_V2: line = instr->convertto (Histable::INSTR, NULL); break; default: abort (); } uint64_t func_id = cur_func->id; uint64_t line_id = instr->id; int is_null = 0; int line_no = -1; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: is_null = (((DbeLine*) line)->func == NULL) ? 1 : 0; if (is_null) ((DbeLine*) line)->func = cur_func; line_no = ((DbeLine*) line)->lineno; if (line_seen->get (line_id) == 0) { line_seen->put (line_id, 1); table0->append (func_id); table1->append (line_no); Histable::NameFormat nfmt = dbev->get_name_format (); table2->append (dbe_strdup (line->get_name (nfmt))); } if (is_null) ((DbeLine*) line)->func = NULL; break; case DSP_DISASM: case DSP_DISASM_V2: is_null = (((DbeInstr*) line)->func == NULL) ? 1 : 0; if (is_null) ((DbeInstr*) line)->func = cur_func; line_no = ((DbeInstr*) line)->addr; if (line_seen->get (line_id) == 0) { line_seen->put (line_id, 1); table0->append (func_id); table1->append (line_no); Histable::NameFormat nfmt = dbev->get_name_format (); table2->append (dbe_strdup (line->get_name (nfmt))); } if (is_null) ((DbeInstr*) line)->func = NULL; break; default: abort (); } } delete line_seen; delete instr_info; } break; default: abort (); } table->store (0, table0); table->store (1, table1); table->store (2, table2); return table; } Vector* dbeGetFuncCalleeInfo (int dbevindex, int type, Vector* idxs, int groupId) { Vector* data = new Vector(); if (type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) { Obj sel_func = dbeGetSelObj (dbevindex, DSP_FUNCTION, 0); if (sel_func == 0) return data; Vector * cmpObjs = dbeGetComparableObjsV2 (dbevindex, sel_func, type); if (cmpObjs == NULL) return data; DbeView *dbev = dbeSession->getView (dbevindex); int mtype = MET_COMMON | COMPARE_BIT | ((groupId + 1) << GROUP_ID_SHIFT); MetricList *mlist = dbev->get_metric_list ((MetricType) (mtype & MTYPE_MASK), (mtype & COMPARE_BIT) != 0, mtype >> GROUP_ID_SHIFT); Histable *selObj = (Histable *) cmpObjs->fetch (groupId); int subtype = 0; Hist_data *hist_data = dbev->get_data (mlist, selObj, type, subtype); if (hist_data == NULL) return data; } for (int i = 0; i < idxs->size (); i++) data->append (dbeGetFuncCalleeInfoById (dbevindex, type, idxs->fetch (i))); return data; } // // Get Table of Callee info: // param: idx -- selected AT_FUNC row // return: callsite_row, callee_id, callee_name // Vector* dbeGetFuncCalleeInfoById (int dbevindex, int type, int idx) { Vector* table = new Vector(3); Vector* table0 = new Vector(); Vector* table1 = new Vector (); Vector* table2 = new Vector(); DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Hist_data *data; Function* given_func = NULL; Vector *instr_info = NULL; Vector *func_info = NULL; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: data = dbev->src_data; break; case DSP_DISASM: case DSP_DISASM_V2: data = dbev->dis_data; break; default: data = NULL; abort (); } if (data == NULL || data->get_status () != Hist_data::SUCCESS) return NULL; if (idx < 0 || idx >= data->size ()) return NULL; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: case DSP_DISASM: case DSP_DISASM_V2: { Histable * sel_obj = data->fetch (idx)->obj; if (sel_obj == NULL) return NULL; given_func = (Function*) (sel_obj)->convertto (Histable::FUNCTION, (Histable*) dbev); if (given_func == NULL) return NULL; PathTree * ptree = dbev->get_path_tree (); if (ptree == NULL) return NULL; Vector *instrs = NULL; Vector *callee_instrs = ptree->get_cle_instr (given_func, instrs); func_info = new Vector(); instr_info = new Vector(); for (long a = 0, sz_a = callee_instrs ? callee_instrs->size () : 0; a < sz_a; a++) { Vector *temp = ((Vector*>*)callee_instrs)->get (a); DefaultMap * func_seen = new DefaultMap(); Histable* instr0 = (Histable*) instrs->fetch (a); for (long b = 0, sz_b = temp ? temp->size () : 0; b < sz_b; b++) { Histable *instr = temp->get (b); if (instr->get_type () == Histable::INSTR) { Function* func1 = ((DbeInstr *) instr)->func; func_seen->put (func1, 1); } else if (instr->get_type () == Histable::LINE) { Function* func1 = ((DbeLine *) instr)->func; func_seen->put (func1, 1); } } Vector *funcs = func_seen->keySet (); delete func_seen; if (funcs->size () > 0) { instr_info->append (instr0); func_info->append (funcs); } } delete instrs; destroy (callee_instrs); DefaultMap* > * instr_idxs = new DefaultMap* >(); DefaultMap * func_idxs = new DefaultMap(); for (long j = 0, sz_j = instr_info ? instr_info->size () : 0; j < sz_j; j++) { Histable *instr = instr_info->get (j); Function *cur_func = NULL; if (instr->get_type () == Histable::INSTR) cur_func = ((DbeInstr*) instr)->func; else if (instr->get_type () == Histable::LINE) cur_func = ((DbeLine*) instr)->func; if (cur_func != NULL && (cur_func->flags & FUNC_FLAG_SIMULATED)) continue; // skip functions like Histable* line; switch (type) { case DSP_SOURCE: case DSP_SOURCE_V2: if (cur_func != NULL) { SourceFile *sourceFile = cur_func->getDefSrc (); if (sourceFile == NULL || (sourceFile->flags & SOURCE_FLAG_UNKNOWN) != 0) // skip functions like continue; } line = instr->convertto (Histable::LINE, NULL); if (type == DSP_SOURCE_V2) line = dbev->get_compare_obj (line); break; case DSP_DISASM: case DSP_DISASM_V2: line = instr; if (type == DSP_DISASM_V2) line = dbev->get_compare_obj (line); break; default: abort (); } if (func_idxs->get (line->id) == 0) { func_idxs->put (line->id, 1); Vector *temp_idx = new Vector(); temp_idx->append (j); instr_idxs->put (line->id, temp_idx); } else { Vector *temp_idx = instr_idxs->get (line->id); temp_idx->append (j); } } for (long i = 0; i < data->size (); i++) { Histable* line = data->fetch (i)->obj; if (line == NULL) continue; Vector * instr_idx = instr_idxs->get (line->id); if (instr_idx == NULL) continue; for (long j = 0; j < instr_idx->size (); j++) { Vector* callee_funcs_vec = (Vector*)func_info; if (callee_funcs_vec->size () == 0) continue; Vector* callee_funcs_value = (Vector*)callee_funcs_vec->fetch (instr_idx->fetch (j)); for (int k = 0; callee_funcs_value != NULL && k < callee_funcs_value->size (); k++) { uint64_t funcobj_id = ((Function*) callee_funcs_value->fetch (k))->id; int old_size = table0->size (); if (old_size > 0 && i == table0->fetch (old_size - 1) && funcobj_id == table1->fetch (old_size - 1)) continue; table0->append (i); table1->append (funcobj_id); table2->append (dbe_strdup (((Function*) callee_funcs_value->fetch (k))->get_name ())); } } } delete instr_idxs; delete func_idxs; destroy (func_info); delete instr_info; } break; default: abort (); } table->store (0, table0); table->store (1, table1); table->store (2, table2); return table; } // // Get Table of Function List data with only total values // Vector * dbeGetFuncListMini (int dbevindex, int type, int /*subtype*/) { Hist_data *data; DbeView *dbev = dbeSession->getView (dbevindex); switch (type) { case DSP_FUNCTION: data = dbev->func_data; break; default: data = NULL; break; } if (data == NULL || data->get_status () != Hist_data::SUCCESS) return NULL; MetricList *mlist = data->get_metric_list (); // Get table size: count visible metrics int nvisible = 0; for (long i = 0, sz = mlist->size (); i < sz; i++) { Metric *m = mlist->get (i); if (m->is_visible () || m->is_tvisible () || m->is_pvisible ()) nvisible++; } Vector *table = new Vector(nvisible + 1); // Fill function list elements Hist_data::HistItem *totals = data->get_totals (); for (long i = 0, sz = mlist->size (); i < sz; i++) { Metric *m = mlist->get (i); if (!m->is_visible () && !m->is_tvisible () && !m->is_pvisible ()) continue; TValue res; TValue *v = data->get_value (&res, i, totals); if ((m->get_visbits () & VAL_RATIO) != 0) { Vector *col = new Vector(1); double d = (v->tag != VT_LABEL) ? v->to_double () : 100.; // NaN col->append (d); table->append (col); continue; } switch (m->get_vtype ()) { case VT_INT: { Vector *col = new Vector(1); col->append (v->i); table->append (col); break; } case VT_ADDRESS: case VT_ULLONG: case VT_LLONG: { Vector *col = new Vector(1); col->append (v->ll); table->append (col); break; } case VT_LABEL: { Vector *col = new Vector(1); col->append (dbe_strdup (v->l)); table->append (col); break; } case VT_DOUBLE: default: { Vector *col = new Vector(1); col->append (v->d); table->append (col); break; } } } table->append (NULL); return table; } // Get Table of Function List data Vector * dbeGetFuncList (int dbevindex, int type, int subtype) { MetricList *mlist; Metric *mitem; int nitems, nvisible; int index, index2, nv; char *cell; Vector *ji_list; Hist_data *data; Hist_data::HistItem *item; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); // fprintf(stderr, NTXT("XXX dbeGetFuncList, FuncListDisp_type = %d\n"), type); switch (type) { case DSP_FUNCTION: data = dbev->func_data; break; case DSP_LINE: data = dbev->line_data; break; case DSP_PC: data = dbev->pc_data; break; case DSP_SOURCE: case DSP_SOURCE_V2: data = dbev->src_data; break; case DSP_DISASM: case DSP_DISASM_V2: data = dbev->dis_data; break; case DSP_SELF: data = dbev->fitem_data; break; case DSP_CALLER: data = dbev->callers; break; case DSP_CALLEE: data = dbev->callees; break; case DSP_DLAYOUT: data = dbev->dlay_data; break; case DSP_DATAOBJ: data = dbev->dobj_data; break; case DSP_MEMOBJ: case DSP_INDXOBJ: data = dbev->get_indxobj_data (subtype); break; default: data = NULL; break; } if (data == NULL || data->get_status () != Hist_data::SUCCESS) return NULL; mlist = data->get_metric_list (); // Get table size: count visible metrics nitems = data->size (); nvisible = 0; Vec_loop (Metric*, mlist->get_items (), index, mitem) { if (mitem->is_visible () || mitem->is_tvisible () || mitem->is_pvisible ()) nvisible++; } // Initialize Java String array Vector *table = new Vector(nvisible + 1); // Mark Hi-value metric items for annotated src/dis/layout if (type == DSP_SOURCE || type == DSP_DISASM || type == DSP_DLAYOUT || type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) { ji_list = new Vector(nitems); if (dbev->marks->size () > 0) index = dbev->marks->fetch (0); else index = -1; int mindex = 0; for (index2 = 0; index2 < nitems; index2++) { item = data->fetch (index2); if (index2 == index) { ji_list->store (index2, -item->type); if (++mindex < dbev->marks->size ()) index = dbev->marks->fetch (mindex); else index = -1; } else ji_list->store (index2, item->type); } table->store (nvisible, ji_list); } else table->store (nvisible, NULL); // Fill function list elements nv = 0; Vec_loop (Metric*, mlist->get_items (), index, mitem) { if (!mitem->is_visible () && !mitem->is_tvisible () && !mitem->is_pvisible ()) continue; // Fill values switch (mitem->get_vtype ()) { case VT_LABEL: { Vector *jobjects = new Vector(nitems); char *buf = NULL; size_t bufsz = 0; int lspace = 0; if (type == DSP_SOURCE || type == DSP_DISASM || type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) { // if this is source or disassembly, where we'll insert // a preface into the output line, figure out how wide // it needs to be // first, scan all the lines, to get the maximum line number bufsz = 1024; buf = (char *) xmalloc (bufsz); int max_lineno = 0; int hidx; Hist_data::HistItem *hitem; Vec_loop (Hist_data::HistItem*, data, hidx, hitem) { if (!hitem->obj) continue; if (hitem->obj->get_type () == Histable::LINE && ((DbeLine*) hitem->obj)->lineno > max_lineno) max_lineno = ((DbeLine*) hitem->obj)->lineno; else if (hitem->obj->get_type () == Histable::INSTR && ((DbeInstr*) hitem->obj)->lineno > max_lineno) max_lineno = ((DbeInstr*) hitem->obj)->lineno; } // we have the maximum integer over all linenumbers in the file // figure out how many digits are needed lspace = snprintf (buf, bufsz, NTXT ("%d"), max_lineno); } for (index2 = 0; index2 < nitems; index2++) { item = data->fetch (index2); if (type == DSP_DLAYOUT) cell = dbe_strdup (((DataObject*) (item->obj))->get_offset_name ()); else if (type == DSP_SOURCE || type == DSP_DISASM || type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) { // This code is duplicated in output.cc, yet it's // intended for presentation purpose and thus is // potentially different for er_print and analyzer. switch (item->type) { case Module::AT_SRC_ONLY: case Module::AT_SRC: if (item->obj == NULL) snprintf (buf, bufsz, NTXT (" %*c. "), lspace, ' '); else snprintf (buf, bufsz, NTXT (" %*d. "), lspace, ((DbeLine*) item->obj)->lineno); break; case Module::AT_FUNC: case Module::AT_QUOTE: snprintf (buf, bufsz, NTXT ("%*c"), lspace + 3, ' '); break; case Module::AT_DIS: case Module::AT_DIS_ONLY: if (item->obj == NULL || ((DbeInstr*) item->obj)->lineno == -1) snprintf (buf, bufsz, NTXT ("%*c[%*s] "), lspace + 3, ' ', lspace, NTXT ("?")); else snprintf (buf, bufsz, NTXT ("%*c[%*d] "), lspace + 3, ' ', lspace, ((DbeInstr*) item->obj)->lineno); break; case Module::AT_COM: case Module::AT_EMPTY: *buf = (char) 0; break; } // get the line's text char *s = item->value[index].l; if (s != NULL) { // copy the string expanding all tabulations // (JTable doesn't render them) char *d = buf + strlen (buf); char c; size_t column = 0; do { c = *s++; if (c == '\t') { do { *d++ = ' '; column++; } while (column & 07); } else { *d++ = c; column++; } if (column + 32 > bufsz) { // Reallocate the buffer size_t curlen = d - buf; bufsz += 1024; char *buf_new = (char *) xmalloc (bufsz); strncpy (buf_new, buf, curlen); buf_new[curlen] = '\0'; free (buf); buf = buf_new; d = buf + curlen; } } while (c != (char) 0); } cell = dbe_strdup (buf); free (item->value[index].l); item->value[index].l = NULL; //YXXX missing from dbeGetFuncListV2 } else { // omazur: why don't we have it as metric value Histable::NameFormat nfmt = dbev->get_name_format (); cell = dbe_strdup (item->obj->get_name (nfmt)); } jobjects->store (index2, cell); } if (type == DSP_SOURCE || type == DSP_DISASM || type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) free (buf); table->store (nv++, jobjects); break; } default: table->store (nv++, dbeGetTableDataOneColumn (data, index)); break; } } return table; } Vector * dbeGetComparableObjsV2 (int /* dbevindex */, Obj sel_obj, int type) { long grsize = dbeSession->expGroups->size (); Vector *res = new Vector (grsize + 1); for (long j = 0; j < grsize; j++) res->append ((Obj) NULL); res->append (sel_obj); Histable *obj = (Histable *) sel_obj; if (obj == NULL) return res; Function *func = (Function *) obj->convertto (Histable::FUNCTION); if (func == NULL) return res; Vector *cmpObjs = func->get_comparable_objs (); if (cmpObjs == NULL || cmpObjs->size () != grsize) return res; Histable::Type conv_type = (type == DSP_SOURCE || type == DSP_SOURCE_V2) ? Histable::LINE : Histable::INSTR; switch (obj->get_type ()) { case Histable::FUNCTION: for (long j = 0; j < grsize; j++) res->store (j, (Obj) cmpObjs->get (j)); return res; case Histable::INSTR: case Histable::LINE: { SourceFile *srcContext = (SourceFile *) obj->convertto (Histable::SOURCEFILE); char *bname = get_basename (srcContext->get_name ()); for (long j = 0; j < grsize; j++) { Function *func1 = (Function *) cmpObjs->get (j); if (func == func1) { if (conv_type == Histable::LINE) res->store (j, (Obj) obj); else res->store (j, (Obj) obj->convertto (conv_type, srcContext)); continue; } if (func1 == NULL) continue; Vector *sources = func1->get_sources (); SourceFile *sf = NULL; for (long j1 = 0, sz1 = sources ? sources->size () : 0; j1 < sz1; j1++) { SourceFile *sf1 = sources->get (j1); if (sf1 == srcContext) { // the same file sf = srcContext; break; } else if (sf == NULL) { char *bname1 = get_basename (sf1->get_name ()); if (dbe_strcmp (bname, bname1) == 0) sf = sf1; } } res->store (j, (Obj) func1->convertto (conv_type, srcContext)); } break; } default: break; } return res; } // Get Table of Function List data Vector * dbeGetFuncListV2 (int dbevindex, int mtype, Obj sel_obj, int type, int subtype) { Metric *mitem; int nitems, nvisible; int index, index2, nv; char *cell; Hist_data::HistItem *item; DbeView *dbev = dbeSession->getView (dbevindex); dbev->error_msg = dbev->warning_msg = NULL; MetricList *mlist = dbev->get_metric_list ((MetricType) (mtype & MTYPE_MASK), (mtype & COMPARE_BIT) != 0, mtype >> GROUP_ID_SHIFT); Histable *selObj = (Histable *) sel_obj; int old_compare_mode = dbev->get_compare_mode (); if ((mtype & COMPARE_BIT) != 0) dbev->reset_compare_mode (CMP_DISABLE); Hist_data *data = dbev->get_data (mlist, selObj, type, subtype); dbev->reset_compare_mode (old_compare_mode); if (data == NULL || data->get_status () != Hist_data::SUCCESS) return NULL; nitems = data->size (); nvisible = mlist->get_items ()->size (); // Initialize Java String array Vector *table = new Vector(nvisible + 3); // Mark Hi-value metric items for annotated src/dis/layout if (type == DSP_SOURCE || type == DSP_DISASM || type == DSP_DLAYOUT || type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) { Vector *types = new Vector(nitems); Vector *ids = new Vector (nitems); if (dbev->marks->size () > 0) index = dbev->marks->fetch (0); else index = -1; int mindex = 0; for (int i = 0; i < nitems; i++) { item = data->fetch (i); ids->store (i, (Obj) item->obj); if (i == index) { types->store (i, -item->type); if (++mindex < dbev->marks->size ()) index = dbev->marks->fetch (mindex); else index = -1; } else types->store (i, item->type); } table->store (nvisible, types); table->store (nvisible + 1, ids); } else { table->store (nvisible, NULL); table->store (nvisible + 1, NULL); } // Fill function list elements nv = 0; Vec_loop (Metric*, mlist->get_items (), index, mitem) { if (!mitem->is_visible () && !mitem->is_tvisible () && !mitem->is_pvisible ()) continue; // Fill values switch (mitem->get_vtype ()) { default: table->store (nv++, dbeGetTableDataOneColumn (data, index)); break; case VT_LABEL: Vector *jobjects = new Vector(nitems); char *buf = NULL; size_t bufsz = 0; int lspace = 0; if (type == DSP_SOURCE || type == DSP_DISASM || type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) { // if this is source or disassembly, where we'll insert // a preface into the output line, figure out how wide // it needs to be // first, scan all the lines, to get the maximum line number bufsz = 1024; buf = (char *) xmalloc (bufsz); int max_lineno = 0; int hidx; Hist_data::HistItem *hitem; Vec_loop (Hist_data::HistItem*, data, hidx, hitem) { if (!hitem->obj) continue; if (hitem->obj->get_type () == Histable::LINE && ((DbeLine*) hitem->obj)->lineno > max_lineno) max_lineno = ((DbeLine*) hitem->obj)->lineno; else if (hitem->obj->get_type () == Histable::INSTR && ((DbeInstr*) hitem->obj)->lineno > max_lineno) max_lineno = ((DbeInstr*) hitem->obj)->lineno; } // we have the maximum integer over all linenumbers in the file // figure out how many digits are needed lspace = snprintf (buf, bufsz, NTXT ("%d"), max_lineno); } for (index2 = 0; index2 < nitems; index2++) { item = data->fetch (index2); if (type == DSP_DLAYOUT) cell = dbe_strdup (((DataObject*) (item->obj))->get_offset_name ()); else if (type == DSP_SOURCE || type == DSP_DISASM || type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) { // This code is duplicated in output.cc, yet it's // intended for presentation purpose and thus is // potentially different for er_print and analyzer. switch (item->type) { case Module::AT_SRC_ONLY: case Module::AT_SRC: if (item->obj == NULL) snprintf (buf, bufsz, NTXT (" %*c. "), lspace, ' '); else snprintf (buf, bufsz, NTXT (" %*d. "), lspace, ((DbeLine*) item->obj)->lineno); break; case Module::AT_FUNC: case Module::AT_QUOTE: snprintf (buf, bufsz, NTXT ("%*c"), lspace + 3, ' '); break; case Module::AT_DIS: case Module::AT_DIS_ONLY: if (item->obj == NULL || ((DbeInstr*) item->obj)->lineno == -1) snprintf (buf, bufsz, NTXT ("%*c[%*s] "), lspace + 3, ' ', lspace, NTXT ("?")); else snprintf (buf, bufsz, NTXT ("%*c[%*d] "), lspace + 3, ' ', lspace, ((DbeInstr*) item->obj)->lineno); break; case Module::AT_COM: case Module::AT_EMPTY: *buf = (char) 0; break; } // get the line's text char *s = item->value[index].l; if (s != NULL) { // copy the string expanding all tabulations // (JTable doesn't render them) char *d = buf + strlen (buf); char c; size_t column = 0; do { c = *s++; if (c == '\t') { do { *d++ = ' '; column++; } while (column & 07); } else { *d++ = c; column++; } if (column + 32 > bufsz) { // Reallocate the buffer size_t curlen = d - buf; bufsz += 1024; char *buf_new = (char *) xmalloc (bufsz); strncpy (buf_new, buf, curlen); buf_new[curlen] = '\0'; free (buf); buf = buf_new; d = buf + curlen; } } while (c != (char) 0); } cell = dbe_strdup (buf); } else { Histable::NameFormat nfmt = dbev->get_name_format (); cell = dbe_strdup (item->obj->get_name (nfmt)); } jobjects->store (index2, cell); } if (type == DSP_SOURCE || type == DSP_DISASM || type == DSP_SOURCE_V2 || type == DSP_DISASM_V2) free (buf); table->store (nv++, jobjects); break; } } table->append (dbeGetMetricList (mlist)); return table; } // dbeGetFuncListV2 // // Get Table DataV2 // Vector * dbeGetTableDataV2 (int dbevindex, char *mlistStr, char *modeStr, char *typeStr, char *subtypeStr, Vector *ids) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); // Process metric list specification if (mlistStr == NULL) return NULL; bool met_call = false; MetricList *mlist = NULL; if (streq (mlistStr, NTXT ("MET_NORMAL"))) mlist = dbev->get_metric_list (MET_NORMAL); else if (streq (mlistStr, NTXT ("MET_CALL"))) { met_call = true; mlist = dbev->get_metric_list (MET_CALL); } else if (streq (mlistStr, NTXT ("MET_CALL_AGR"))) mlist = dbev->get_metric_list (MET_CALL_AGR); else if (streq (mlistStr, NTXT ("MET_DATA"))) mlist = dbev->get_metric_list (MET_DATA); else if (streq (mlistStr, NTXT ("MET_INDX"))) mlist = dbev->get_metric_list (MET_INDX); else if (streq (mlistStr, NTXT ("MET_IO"))) mlist = dbev->get_metric_list (MET_IO); else if (streq (mlistStr, NTXT ("MET_HEAP"))) mlist = dbev->get_metric_list (MET_HEAP); else return NULL; // Process mode specification if (modeStr == NULL) return NULL; Hist_data::Mode mode = (Hist_data::Mode)0; if (streq (modeStr, NTXT ("CALLERS"))) mode = Hist_data::CALLERS; else if (streq (modeStr, NTXT ("CALLEES"))) mode = Hist_data::CALLEES; else if (streq (modeStr, NTXT ("SELF"))) mode = Hist_data::SELF; else if (streq (modeStr, NTXT ("ALL"))) mode = Hist_data::ALL; else return NULL; // Process type specification if (typeStr == NULL) return NULL; Histable::Type type = Histable::OTHER; if (streq (typeStr, NTXT ("FUNCTION"))) type = Histable::FUNCTION; else if (streq (typeStr, NTXT ("INDEXOBJ"))) type = Histable::INDEXOBJ; else if (streq (typeStr, NTXT ("IOACTFILE"))) type = Histable::IOACTFILE; else if (streq (typeStr, NTXT ("IOACTVFD"))) type = Histable::IOACTVFD; else if (streq (typeStr, NTXT ("IOCALLSTACK"))) type = Histable::IOCALLSTACK; else if (streq (typeStr, NTXT ("HEAPCALLSTACK"))) type = Histable::HEAPCALLSTACK; else if (streq (typeStr, NTXT ("LINE"))) type = Histable::LINE; else if (streq (typeStr, NTXT ("INSTR"))) type = Histable::INSTR; else // XXX Accepting objects other than above may require a different // implementation of the id -> Histable mapping below return NULL; // Process subtype specification int subtype = 0; if (subtypeStr != NULL) subtype = atoi (subtypeStr); Vector *hobjs = NULL; if (ids != NULL) { hobjs = new Vector(); for (int i = 0; i < ids->size (); ++i) { Histable::Type obj_type = type; if ((obj_type == Histable::LINE || obj_type == Histable::INSTR) && subtype == 0) obj_type = Histable::FUNCTION; Histable *hobj = dbeSession->findObjectById (obj_type, subtype, ids->fetch (i)); if ((obj_type == Histable::LINE || obj_type == Histable::INSTR) && subtype == 0 && hobj == NULL) return NULL; hobjs->append (hobj); } } PathTree::PtreeComputeOption flag = PathTree::COMPUTEOPT_NONE; if (dbev->isOmpDisMode () && type == Histable::FUNCTION && mode == Hist_data::CALLEES && met_call) flag = PathTree::COMPUTEOPT_OMP_CALLEE; Hist_data *data = dbev->get_hist_data (mlist, type, subtype, mode, hobjs, NULL, NULL, flag); return dbeGetTableDataV2Data (dbev, data); } static Vector * dbeGetTableDataV2Data (DbeView * /*dbev*/, Hist_data *data) { if (data == NULL || data->get_status () != Hist_data::SUCCESS) return NULL; MetricList *mlist; mlist = data->get_metric_list (); int nitems = data->size (); // Initialize Java String array Vector *table = new Vector(mlist->size () + 1); // Fill function list elements for (long i = 0, sz = mlist->size (); i < sz; i++) { Metric *mitem = mlist->get (i); if (!mitem->is_visible () && !mitem->is_tvisible () && !mitem->is_pvisible ()) continue; table->append (dbeGetTableDataOneColumn (data, i)); } // Add an array of Histable IDs Vector *idList = new Vector(nitems); for (int i = 0; i < nitems; ++i) { Hist_data::HistItem *item = data->fetch (i); if (item->obj->get_type () == Histable::LINE || item->obj->get_type () == Histable::INSTR) idList->store (i, (uint64_t) (item->obj)); else idList->store (i, item->obj->id); } table->append (idList); return table; } // dbeGetTableData //YXXX try to use the following to consolidate similar cut/paste code static Vector * dbeGetTableDataOneColumn (Hist_data *data, int met_ind) { // Allocates a vector and fills it with metric values for one column TValue res; Metric *m = data->get_metric_list ()->get (met_ind); if ((m->get_visbits () & VAL_RATIO) != 0) { Vector *col = new Vector(data->size ()); for (long row = 0, sz_row = data->size (); row < sz_row; row++) { TValue *v = data->get_value (&res, met_ind, row); double d = (v->tag != VT_LABEL) ? v->to_double () : 100.; // NaN col->append (d); } return (Vector *) col; } switch (m->get_vtype ()) { case VT_DOUBLE: { Vector *col = new Vector(data->size ()); for (long row = 0, sz_row = data->size (); row < sz_row; row++) { TValue *v = data->get_value (&res, met_ind, row); col->append (v->d); } return (Vector *) col; } case VT_INT: { Vector *col = new Vector(data->size ()); for (long row = 0, sz_row = data->size (); row < sz_row; row++) { TValue *v = data->get_value (&res, met_ind, row); col->append (v->i); } return (Vector *) col; } case VT_ULLONG: case VT_LLONG: { Vector *col = new Vector(data->size ()); for (long row = 0, sz_row = data->size (); row < sz_row; row++) { TValue *v = data->get_value (&res, met_ind, row); col->append (v->ll); } return (Vector *) col; } case VT_ADDRESS: { Vector *col = new Vector(data->size ()); for (long row = 0, sz_row = data->size (); row < sz_row; row++) { TValue *v = data->get_value (&res, met_ind, row); // set the highest bit to mark this jlong as // a VT_ADDRESS (rather than a regular VT_LLONG) col->append (v->ll | 0x8000000000000000ULL); } return (Vector *) col; } case VT_LABEL: { Vector *col = new Vector(data->size ()); for (long row = 0, sz_row = data->size (); row < sz_row; row++) { TValue *v = data->get_value (&res, met_ind, row); col->append (dbe_strdup (v->l)); } return (Vector *) col; } default: return NULL; } } static Vector * dbeGetTableDataOneColumn (DbeView *dbev, Vector *data, ValueTag vtype, int metricColumnNumber) // Allocates a vector and fills it with metric values for one column { Vector *column_data = NULL; int nitems = data->size (); // number of rows int index = metricColumnNumber; switch (vtype) { case VT_DOUBLE: { Vector *jd_list = new Vector(nitems); for (int index2 = 0; index2 < nitems; index2++) { Hist_data::HistItem *item = data->fetch (index2); jd_list->store (index2, item->value[index].d); } column_data = (Vector *)jd_list; break; } case VT_INT: { Vector *ji_list = new Vector(nitems); for (int index2 = 0; index2 < nitems; index2++) { Hist_data::HistItem *item = data->fetch (index2); ji_list->store (index2, item->value[index].i); } column_data = (Vector *)ji_list; break; } case VT_ULLONG: case VT_LLONG: { Vector *jl_list = new Vector(nitems); for (int index2 = 0; index2 < nitems; index2++) { Hist_data::HistItem *item = data->fetch (index2); jl_list->store (index2, item->value[index].ll); } column_data = (Vector *)jl_list; break; } case VT_ADDRESS: { Vector *jl_list = new Vector(nitems); for (int index2 = 0; index2 < nitems; index2++) { Hist_data::HistItem *item = data->fetch (index2); // set the highest bit to mark this jlong as // a VT_ADDRESS (rather than a regular VT_LLONG) uint64_t addr = item->value[index].ll; addr |= 0x8000000000000000ULL; jl_list->store (index2, addr); } column_data = (Vector *)jl_list; break; } case VT_LABEL: { Vector *jobjects = new Vector(nitems); for (int index2 = 0; index2 < nitems; index2++) { Hist_data::HistItem *item = data->fetch (index2); // omazur: why don't we have it as metric value Histable::NameFormat nfmt = dbev->get_name_format (); char *str = dbe_strdup (item->obj->get_name (nfmt)); jobjects->store (index2, str); } column_data = (Vector *)jobjects; break; } default: abort (); } return column_data; } int dbeGetCallTreeNumLevels (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); PathTree * ptree = dbev->get_path_tree (); if (ptree == NULL) return 0; return ptree->get_ftree_depth (); } Vector* dbeGetCallTreeLevel (int dbevindex, char *mcmd, int level) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); PathTree * ptree = dbev->get_path_tree (); if (ptree == NULL) return NULL; if (mcmd == NULL) return NULL; BaseMetric *bm = dbeSession->find_base_reg_metric (mcmd); if (bm == NULL) return NULL; return ptree->get_ftree_level (bm, level); } Vector* dbeGetCallTreeLevels (int dbevindex, char *mcmd) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); PathTree * ptree = dbev->get_path_tree (); if (ptree == NULL) return NULL; if (mcmd == NULL) return NULL; BaseMetric *bm = dbeSession->find_base_reg_metric (mcmd); if (bm == NULL) return NULL; int depth = ptree->get_ftree_depth (); Vector *results = new Vector(depth); for (int ii = 0; ii < depth; ii++) results->append (ptree->get_ftree_level (bm, ii)); return results; } Vector* dbeGetCallTreeLevelFuncs (int dbevindex, int start_level, int end_level) { // (0,-1) -> all levels DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); PathTree * ptree = dbev->get_path_tree (); if (ptree == NULL) return NULL; int depth = ptree->get_ftree_depth (); if (start_level < 0) start_level = 0; if (end_level < 0 || end_level >= depth) end_level = depth - 1; Histable::NameFormat nfmt = dbev->get_name_format (); //YXXX or fixed format? Vector *funcNames = new Vector(); Vector *funcIds = new Vector(); Vector *funcObjs = new Vector(); if (start_level == 0 && end_level == depth - 1) return dbeGetCallTreeFuncs (dbevindex); else { for (int ii = start_level; ii <= end_level; ii++) { Vector *info = ptree->get_ftree_level (NULL, ii); /*no metric*/ if (!info) continue; Vector *fids = (Vector *)info->get (2); if (!fids) continue; int index; long long fid; Vec_loop (long long, fids, index, fid) { funcIds->append (fid); Histable *obj = dbeSession->findObjectById (fid); char * fname = obj ? dbe_strdup (obj->get_name (nfmt)) : NULL; funcNames->append (fname); funcObjs->append ((unsigned long) obj); // avoiding sign extension } destroy (info); } } Vector *results = new Vector(3); results->append (funcIds); results->append (funcNames); results->append (funcObjs); return results; } Vector * dbeGetCallTreeFuncs (int dbevindex) { // does not require ptree->get_ftree_level() to be computed DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); PathTree * ptree = dbev->get_path_tree (); if (ptree == NULL) return 0; Vector* funcs = ptree->get_funcs (); // Unique functions in tree if (funcs == NULL) return NULL; long sz = funcs->size (); Vector *results = new Vector(3); Vector *funcIds = new Vector(sz); Vector *funcNames = new Vector(sz); Vector *funcObjs = new Vector(sz); int index; Function * func; Histable::NameFormat nfmt = dbev->get_name_format (); //YXXX or fixed format? Vec_loop (Function *, funcs, index, func) { funcIds->append (func->id); // do we need IDs? char *fname = dbe_strdup (func->get_name (nfmt)); funcNames->append (fname); funcObjs->append ((unsigned long) func); // avoiding sign extension } results->put (0, funcIds); results->put (1, funcNames); results->put (2, funcObjs); destroy (funcs); return results; } Vector* dbeGetCallTreeChildren (int dbevindex, char *mcmd, Vector*node_idxs) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); if (node_idxs == NULL || node_idxs->size () == 0) return NULL; long sz = node_idxs->size (); PathTree * ptree = dbev->get_path_tree (); if (ptree == NULL) return NULL; if (mcmd == NULL) return NULL; BaseMetric *bm = dbeSession->find_base_reg_metric (mcmd); if (bm == NULL) return NULL; Vector *results = new Vector(sz); for (long ii = 0; ii < sz; ii++) { PathTree::NodeIdx nodeIdx = node_idxs->get (ii); // upcasted from int results->append (ptree->get_ftree_node_children (bm, nodeIdx)); } return results; } Vector * dbeGetGroupIds (int /*dbevindex*/) { Vector *groups = dbeSession->expGroups; int sz = groups->size (); Vector *grIds = new Vector(sz); for (int i = 0; i < sz; i++) grIds->store (i, groups->fetch (i)->groupId); return grIds; } // // Get label for name column // Vector * dbeGetNames (int dbevindex, int type, Obj sel_obj) { char *s0, *s1, *s2; bool need_strdup = true; switch (type) { case DSP_SOURCE_V2: case DSP_DISASM_V2: case DSP_SOURCE: case DSP_DISASM: { if (sel_obj) { Histable *selObj = (Histable*) sel_obj; Function *func = (Function *) selObj->convertto (Histable::FUNCTION); if (func) { char *names[3] = {NULL, NULL, NULL}; set_file_names (func, names); s0 = names[0]; s1 = names[1]; s2 = names[2]; need_strdup = false; break; } } DbeView *dbev = dbeSession->getView (dbevindex); char **names = type == DSP_SOURCE || type == DSP_SOURCE_V2 ? dbev->names_src : dbev->names_dis; s0 = names[0]; s1 = names[1]; s2 = names[2]; break; } case DSP_LINE: s0 = GTXT ("Lines"); s1 = GTXT ("Function, line # in \"sourcefile\""); s2 = NTXT (""); break; case DSP_PC: s0 = GTXT ("PCs"); s1 = GTXT ("Function + offset"); s2 = NTXT (""); break; case DSP_DLAYOUT: s0 = GTXT ("Name"); s1 = GTXT ("* +offset .element"); s2 = NTXT (""); break; default: s0 = GTXT ("Name"); s1 = s2 = NTXT (""); break; } if (need_strdup) { s0 = dbe_strdup (s0); s1 = dbe_strdup (s1); s2 = dbe_strdup (s2); } Vector *table = new Vector(3); table->store (0, s0); table->store (1, s1); table->store (2, s2); return table; } // // Get Total/Maximum element of Function List // Vector * dbeGetTotalMax (int dbevindex, int type, int subtype) { Hist_data *data; int index; Hist_data::HistItem *total_item, *maximum_item; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); switch (type) { case DSP_LINE: data = dbev->line_data; break; case DSP_PC: data = dbev->pc_data; break; case DSP_CALLER: data = dbev->callers; break; case DSP_SELF: case DSP_CALLEE: data = dbev->callees; break; case DSP_DLAYOUT: data = dbev->dlay_data; break; case DSP_DATAOBJ: data = dbev->dobj_data; break; case DSP_MEMOBJ: data = dbev->get_indxobj_data (subtype); break; case DSP_INDXOBJ: data = dbev->get_indxobj_data (subtype); break; case DSP_FUNCTION: // annotated src/dis use func total/max case DSP_SOURCE: case DSP_DISASM: case DSP_SOURCE_V2: case DSP_DISASM_V2: data = dbev->func_data; break; default: abort (); } if (data == NULL || data->get_status () != Hist_data::SUCCESS) return NULL; // Get list size // XXX -- the original list has all items, visible or not; // XXX -- the one from Hist_data has only visible items, // XXX -- and should be the only ones computed // XXX -- Analyzer got confused (yesterday), when we used the shorter list // XXX -- Why can we fetch total/max for metrics never // XXX -- computed without core dumping? MetricList *mlist2 = data->get_metric_list (); int size = mlist2->get_items ()->size (); // Initialize Java array Vector *total_max = new Vector(2); Vector *total = new Vector(size); Vector *maximum = new Vector(size); // Fill total/maximum element total_item = data->get_totals (); maximum_item = data->get_maximums (); for (index = 0; index < size; index++) { total->store (index, total_item->value[index].to_double ()); maximum->store (index, maximum_item->value[index].to_double ()); } total_max->store (0, total); total_max->store (1, maximum); return total_max; } // // Get Table of Overview List Vector * dbeGetStatisOverviewList (int dbevindex) { int size; Ovw_data **data; Ovw_data::Ovw_item labels, *totals; int nitems; int index, index2; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->error_msg = dbev->warning_msg = NULL; size = dbeSession->nexps (); totals = new Ovw_data::Ovw_item[size + 1]; data = new Ovw_data*[size + 1]; data[0] = new Ovw_data (); for (index = 1; index <= size; index++) { data[index] = dbev->get_ovw_data (index - 1); if (data[index] == NULL) { Ovw_data::reset_item (&totals[index]); // set contents to zeros continue; } data[0]->sum (data[index]); totals[index] = data[index]->get_totals (); //shallow copy! } totals[0] = data[0]->get_totals (); // Get table size labels = data[0]->get_labels (); nitems = labels.size + 4; // Initialize Java String array Vector *table = new Vector(size + 4); Vector *jobjects = new Vector(nitems); // Set the label jobjects->store (0, dbe_strdup (GTXT ("Start Time (sec.)"))); jobjects->store (1, dbe_strdup (GTXT ("End Time (sec.)"))); jobjects->store (2, dbe_strdup (GTXT ("Duration (sec.)"))); jobjects->store (3, dbe_strdup (GTXT ("Total Thread Time (sec.)"))); jobjects->store (4, dbe_strdup (GTXT ("Average number of Threads"))); for (index2 = 5; index2 < nitems; index2++) jobjects->store (index2, dbe_strdup (labels.values[index2 - 4].l)); table->store (0, jobjects); // Set the data for (index = 0; index <= size; index++) { Vector *jd_list = new Vector(nitems); jd_list->store (0, tstodouble (totals[index].start)); jd_list->store (1, tstodouble (totals[index].end)); jd_list->store (2, tstodouble (totals[index].duration)); jd_list->store (3, tstodouble (totals[index].tlwp)); jd_list->store (4, totals[index].nlwp); for (index2 = 5; index2 < nitems; index2++) jd_list->store (index2, tstodouble (totals[index].values[index2 - 4].t)); table->store (index + 1, jd_list); } for (index = 0; index <= size; index++) delete data[index]; delete[] data; delete[] totals; return table; } // Get Table of Statistics List Vector * dbeGetStatisList (int dbevindex) { int size; Stats_data **data; int nitems; int index, index2; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); dbev->error_msg = dbev->warning_msg = NULL; if ((size = dbeSession->nexps ()) == 0) return NULL; // Get statistics data data = (Stats_data **) xmalloc ((size + 1) * sizeof (Stats_data *)); data[0] = new Stats_data (); for (index = 1; index <= size; index++) { data[index] = dbev->get_stats_data (index - 1); if (data[index] == NULL) continue; data[0]->sum (data[index]); } // Get table size nitems = data[0]->size (); // Initialize Java String array Vector *table = new Vector(size + 2); Vector *jobjects = new Vector(nitems); // Set the label for (index2 = 0; index2 < nitems; index2++) jobjects->store (index2, dbe_strdup (data[0]->fetch (index2).label)); table->store (0, jobjects); // Set the data for (index = 0; index <= size; index++) { Vector *jd_list = new Vector(nitems); for (index2 = 0; index2 < nitems; index2++) { double val = 0; if (data[index]) val = data[index]->fetch (index2).value.to_double (); jd_list->store (index2, val); } table->store (index + 1, jd_list); } if (data) { for (index = 0; index <= size; index++) delete data[index]; free (data); } return table; } // // Set summary list // static void setSummary (Vector *objs, Vector *saligns, Vector *mnemonic, Vector *jlabels, Vector *jvalues) { char *sname = NULL, *oname = NULL, *lname = NULL, *alias = NULL, *mangle = NULL, *address = NULL, *size = NULL, *name_0 = NULL, *sname_0 = NULL, *oname_0 = NULL, *lname_0 = NULL, *alias_0 = NULL, *mangle_0 = NULL; Function *func, *last_func = NULL; int one_func = 1; // Get the source/object/load-object files & aliases long long ll_size = 0; for (long i = 0; i < objs->size (); i++) { Histable *current_obj = objs->fetch (i); Histable::Type htype = current_obj->get_type (); if (htype == Histable::LOADOBJECT) lname = ((LoadObject *) current_obj)->dbeFile->get_location_info (); else if ((func = (Function*) current_obj->convertto (Histable::FUNCTION)) != NULL) { if (one_func && last_func != NULL && last_func != func) one_func = 0; last_func = func; sname = NULL; DbeLine *dbeline = (DbeLine*) current_obj->convertto (Histable::LINE); if (dbeline) { SourceFile *sf; if (dbeline->lineno == 0 && dbeline->include != NULL) sf = dbeline->include; else if (dbeline->sourceFile != NULL) sf = dbeline->sourceFile; else sf = func->getDefSrc (); if (sf) sname = sf->dbeFile->get_location_info (); } char *func_name = func->get_name (); mangle = func->get_mangled_name (); if (mangle && streq (func_name, mangle)) mangle = NULL; Module *module = func->module; if (module != NULL) { module->read_stabs (); if (sname == NULL || strlen (sname) == 0) { SourceFile *sf = module->getMainSrc (); sname = sf->dbeFile->get_location_info (); } DbeFile *df = module->dbeFile; if (df == NULL || (df->filetype & DbeFile::F_JAVACLASS) == 0) df = module->loadobject->dbeFile; lname = df->get_location_info (); oname = lname; if (module->dot_o_file) oname = module->dot_o_file->dbeFile->get_location_info (); } if (htype == Histable::INSTR && dbeSession->is_datamode_available ()) alias = ((DbeInstr*) current_obj)->get_descriptor (); } char *name = current_obj->get_name (); if (i == 0) { name_0 = name; lname_0 = lname; sname_0 = sname; oname_0 = oname; mangle_0 = mangle; alias_0 = alias; if (objs->size () == 1) { uint64_t addr = current_obj->get_addr (); address = dbe_sprintf (NTXT ("%lld:0x%08llX"), (long long) ADDRESS_SEG (addr), (long long) ADDRESS_OFF (addr)); } } else { if (name_0 != name) name_0 = NULL; if (lname_0 != lname) lname_0 = NULL; if (sname_0 != sname) sname_0 = NULL; if (oname_0 != oname) oname_0 = NULL; if (mangle_0 != mangle) mangle_0 = NULL; if (alias_0 != alias) alias_0 = NULL; } if (current_obj->get_size () == -1) { if (size == NULL) size = dbe_strdup (GTXT ("(Unknown)")); } else ll_size += current_obj->get_size (); } if (size == NULL) size = dbe_sprintf (NTXT ("%lld"), ll_size); if (name_0 == NULL) { if (objs->size () > 1) { char *func_name = last_func == NULL ? NULL : (one_func == 0 ? NULL : last_func->get_name ()); name_0 = dbe_sprintf (NTXT ("%s%s%s (%lld %s)"), func_name == NULL ? "" : func_name, func_name == NULL ? "" : ": ", GTXT ("Multiple Selection"), (long long) objs->size (), GTXT ("objects")); } } else name_0 = dbe_strdup (name_0); // Set the name area saligns->store (0, TEXT_LEFT); mnemonic->store (0, 'N'); jlabels->store (0, dbe_strdup (GTXT ("Name"))); jvalues->store (0, name_0); saligns->store (1, TEXT_LEFT); mnemonic->store (1, 'P'); jlabels->store (1, dbe_strdup (GTXT ("PC Address"))); jvalues->store (1, address); saligns->store (2, TEXT_LEFT); mnemonic->store (2, 'z'); jlabels->store (2, dbe_strdup (GTXT ("Size"))); jvalues->store (2, size); saligns->store (3, TEXT_RIGHT); mnemonic->store (3, 'r'); jlabels->store (3, dbe_strdup (GTXT ("Source File"))); jvalues->store (3, dbe_strdup (sname_0)); saligns->store (4, TEXT_RIGHT); mnemonic->store (4, 'b'); jlabels->store (4, dbe_strdup (GTXT ("Object File"))); jvalues->store (4, dbe_strdup (oname_0)); saligns->store (5, TEXT_LEFT); mnemonic->store (5, 'j'); jlabels->store (5, dbe_strdup (GTXT ("Load Object"))); jvalues->store (5, dbe_strdup (lname_0)); saligns->store (6, TEXT_LEFT); mnemonic->store (6, 'm'); jlabels->store (6, dbe_strdup (GTXT ("Mangled Name"))); jvalues->store (6, dbe_strdup (mangle_0)); saligns->store (7, TEXT_LEFT); mnemonic->store (7, 'A'); jlabels->store (7, dbe_strdup (GTXT ("Aliases"))); jvalues->store (7, dbe_strdup (alias_0)); } // Set memory-object summary list // static void setMemSummary (Vector *objs, Vector *saligns, Vector *mnemonic, Vector *jlabels, Vector *jvalues) { saligns->store (0, TEXT_LEFT); mnemonic->store (0, 'M'); jlabels->store (0, dbe_strdup (GTXT ("Memory Object"))); if (objs->size () == 1) { Histable *current_obj = objs->fetch (0); jvalues->store (0, dbe_strdup (current_obj->get_name ())); } else { char *name = dbe_sprintf (NTXT ("%s (%lld %s)"), GTXT ("Multiple Selection"), (long long) objs->size (), GTXT ("objects")); jvalues->store (0, name); } } // Set index-object summary list // static void setIndxSummary (Vector *objs, Vector *saligns, Vector *mnemonic, Vector *jlabels, Vector *jvalues) { saligns->store (0, TEXT_LEFT); mnemonic->store (0, 'I'); jlabels->store (0, dbe_strdup (GTXT ("Index Object"))); if (objs->size () == 1) { Histable *current_obj = objs->fetch (0); jvalues->store (0, dbe_strdup (current_obj->get_name ())); } else { char *name = dbe_sprintf (NTXT ("%s (%lld %s)"), GTXT ("Multiple Selection"), (long long) objs->size (), GTXT ("objects")); jvalues->store (0, name); } } // Set I/O activity summary list // static void setIOActivitySummary (Vector *objs, Vector *saligns, Vector *mnemonic, Vector *jlabels, Vector *jvalues) { saligns->store (0, TEXT_LEFT); mnemonic->store (0, 'O'); jlabels->store (0, dbe_strdup (GTXT ("I/O Activity"))); if (objs->size () == 1) { Histable *current_obj = objs->fetch (0); jvalues->store (0, dbe_strdup (current_obj->get_name ())); } else { char *name = dbe_sprintf (NTXT ("%s (%lld %s)"), GTXT ("Multiple Selection"), (long long) objs->size (), GTXT ("objects")); jvalues->store (0, name); } } // Set heap activity summary list // static void setHeapActivitySummary (Vector *objs, Vector *saligns, Vector *mnemonic, Vector *jlabels, Vector *jvalues) { saligns->store (0, TEXT_LEFT); mnemonic->store (0, 'O'); jlabels->store (0, dbe_strdup (GTXT ("Heap Activity"))); if (objs->size () == 1) { Histable *current_obj = objs->fetch (0); jvalues->store (0, dbe_strdup (current_obj->get_name ())); } else { char *name = dbe_sprintf (NTXT ("%s (%lld %s)"), GTXT ("Multiple Selection"), (long long) objs->size (), GTXT ("objects")); jvalues->store (0, name); } } // // Set data-object summary list // static void setDataSummary (Vector *objs, Vector *saligns, Vector *mnemonic, Vector *jlabels, Vector *jvalues) { char *name, *type, *member, *elist; DataObject *dobj; Vector *delem; Histable *scope; int index; char *size, *offset, *elements, *scopename; // Get the data object elements member = elist = type = size = offset = elements = scopename = NULL; if (objs->size () == 1) { Histable *current_obj = objs->fetch (0); name = dbe_strdup (current_obj->get_name ()); dobj = (DataObject *) current_obj; type = dobj->get_typename (); scope = dobj->get_scope (); delem = dbeSession->get_dobj_elements (dobj); if (type == NULL) type = GTXT ("(Synthetic)"); if (!scope) scopename = dbe_strdup (GTXT ("(Global)")); else { switch (scope->get_type ()) { case Histable::FUNCTION: scopename = dbe_sprintf (NTXT ("%s(%s)"), ((Function*) scope)->module->get_name (), scope->get_name ()); break; case Histable::LOADOBJECT: case Histable::MODULE: default: scopename = dbe_strdup (scope->get_name ()); break; } } if (dobj->get_offset () != -1) { if (dobj->get_parent ()) member = dbe_strdup (dobj->get_parent ()->get_name ()); offset = dbe_sprintf (NTXT ("%lld"), (long long) dobj->get_offset ()); } size = dbe_sprintf ("%lld", (long long) dobj->get_size ()); if (delem->size () > 0) { elements = dbe_sprintf (NTXT ("%lld"), (long long) delem->size ()); StringBuilder sb_tmp, sb; sb.append (GTXT ("Offset Size Name\n")); for (index = 0; index < delem->size (); index++) { DataObject *ditem = delem->fetch (index); sb_tmp.sprintf (NTXT ("%6lld %5lld %s\n"), (long long) ditem->get_offset (), (long long) ditem->get_size (), ditem->get_name ()); sb.append (&sb_tmp); } if (sb.charAt (sb.length () - 1) == '\n') sb.setLength (sb.length () - 1); elist = sb.toString (); } } else name = dbe_sprintf (NTXT ("%s (%lld %s)"), GTXT ("Multiple Selection"), (long long) objs->size (), GTXT ("objects")); saligns->store (0, TEXT_LEFT); mnemonic->store (0, 'D'); jlabels->store (0, dbe_strdup (GTXT ("Data Object"))); jvalues->store (0, name); saligns->store (1, TEXT_LEFT); mnemonic->store (1, 'S'); jlabels->store (1, dbe_strdup (GTXT ("Scope"))); jvalues->store (1, scopename); saligns->store (2, TEXT_LEFT); mnemonic->store (2, 'T'); jlabels->store (2, dbe_strdup (GTXT ("Type"))); jvalues->store (2, dbe_strdup (type)); saligns->store (3, TEXT_LEFT); mnemonic->store (3, 'M'); jlabels->store (3, dbe_strdup (GTXT ("Member of"))); jvalues->store (3, member); saligns->store (4, TEXT_LEFT); mnemonic->store (4, 'O'); jlabels->store (4, dbe_strdup (GTXT ("Offset"))); jvalues->store (4, offset); saligns->store (5, TEXT_LEFT); mnemonic->store (5, 'z'); jlabels->store (5, dbe_strdup (GTXT ("Size"))); jvalues->store (5, size); saligns->store (6, TEXT_LEFT); mnemonic->store (6, 'E'); jlabels->store (6, dbe_strdup (GTXT ("Elements"))); jvalues->store (6, elements); saligns->store (7, TEXT_LEFT); mnemonic->store (7, 'L'); jlabels->store (7, dbe_strdup (GTXT ("List"))); jvalues->store (7, elist); } #define SUMMARY_NAME 8 #define DSUMMARY_NAME 8 #define LSUMMARY_NAME 7 #define IMSUMMARY_NAME 1 Vector * dbeGetSummaryV2 (int dbevindex, Vector *sel_objs, int type, int subtype) { if (sel_objs == NULL || sel_objs->size () == 0) return NULL; DbeView *dbev = dbeSession->getView (dbevindex); Vector*objs = new Vector(sel_objs->size ()); for (int i = 0; i < sel_objs->size (); i++) { Histable *obj = (Histable *) sel_objs->fetch (i); if (obj == NULL) continue; char *nm = obj->get_name (); if (streq (nm, NTXT (""))) { // Special case for 'Total'. // Multi selection which includes 'Total' is only 'Total' objs->reset (); objs->append (obj); break; } objs->append (obj); } if (objs->size () == 0) return NULL; // Set name area int nname = SUMMARY_NAME; Vector *saligns = new Vector(nname); Vector*mnemonic = new Vector(nname); Vector *jlabels = new Vector(nname); Vector *jvalues = new Vector(nname); Vector *name_objs = new Vector(4); name_objs->store (0, saligns); name_objs->store (1, mnemonic); name_objs->store (2, jlabels); name_objs->store (3, jvalues); setSummary (objs, saligns, mnemonic, jlabels, jvalues); MetricList *prop_mlist = new MetricList (dbev->get_metric_ref (MET_NORMAL)); if (prop_mlist && dbev->comparingExperiments ()) prop_mlist = dbev->get_compare_mlist (prop_mlist, 0); int nitems = prop_mlist->get_items ()->size (); // Set the metrics area jlabels = new Vector(nitems); Vector *clock_list = new Vector(nitems); Vector *excl_list = new Vector(nitems); Vector *ep_list = new Vector(nitems); Vector *incl_list = new Vector(nitems); Vector *ip_list = new Vector(nitems); Vector *vtype = new Vector(nitems); // Initialize Java String array Vector *metric_objs = new Vector(8); metric_objs->store (0, jlabels); metric_objs->store (1, clock_list); metric_objs->store (2, excl_list); metric_objs->store (3, ep_list); metric_objs->store (4, incl_list); metric_objs->store (5, ip_list); metric_objs->store (6, vtype); int last_init = -1; for (int i = 0; i < objs->size (); i++) { Histable *obj = objs->fetch (i); // Get the data to be displayed Hist_data *data = dbev->get_hist_data (prop_mlist, obj->get_type (), subtype, Hist_data::SELF, obj, dbev->sel_binctx, objs); if (data->get_status () != Hist_data::SUCCESS) { if (type != DSP_DLAYOUT) { // For data_layout, rows with zero metrics are OK delete data; continue; } } TValue *values = NULL; if (data->get_status () == Hist_data::SUCCESS) { Hist_data::HistItem *hi = data->fetch (0); if (hi) values = hi->value; } Hist_data::HistItem *total = data->get_totals (); int index2 = 0; char *tstr = GTXT (" Time"); char *estr = GTXT ("Exclusive "); size_t len = strlen (estr); // get the metric list from the data MetricList *mlist = data->get_metric_list (); int index; Metric *mitem; double clock; Vec_loop (Metric*, mlist->get_items (), index, mitem) { if (mitem->get_subtype () == Metric::STATIC) continue; if (last_init < index2) { last_init = index2; jlabels->store (index2, NULL); clock_list->store (index2, 0.0); excl_list->store (index2, 0.0); ep_list->store (index2, 0.0); incl_list->store (index2, 0.0); ip_list->store (index2, 0.0); vtype->store (index2, 0); } double dvalue = (values != NULL) ? values[index].to_double () : 0.0; double dtotal = total->value[index].to_double (); if (mitem->is_time_val ()) clock = 1.e+6 * dbeSession->get_clock (-1); else clock = 0.0; clock_list->store (index2, clock); if ((mitem->get_subtype () == Metric::EXCLUSIVE) || (mitem->get_subtype () == Metric::DATASPACE)) { if (i == 0) { char *sstr = mitem->get_name (); if (!strncmp (sstr, estr, len)) sstr += len; char *buf, *lstr = strstr (sstr, tstr); if (lstr) buf = dbe_strndup (sstr, lstr - sstr); else buf = dbe_strdup (sstr); jlabels->store (index2, buf); vtype->store (index2, mitem->get_vtype ()); } dvalue += excl_list->fetch (index2); double percent = dtotal == 0.0 ? dtotal : (dvalue / dtotal) * 100; excl_list->store (index2, dvalue); ep_list->store (index2, percent); } else { dvalue += incl_list->fetch (index2); if (dvalue > dtotal) dvalue = dtotal; // temporary correction double percent = dtotal == 0.0 ? dtotal : (dvalue / dtotal) * 100; incl_list->store (index2, dvalue); ip_list->store (index2, percent); index2++; } } delete data; } delete prop_mlist; Vector *summary = new Vector(2); summary->store (0, name_objs); summary->store (1, metric_objs); return summary; } // Get Summary List Vector * dbeGetSummary (int dbevindex, Vector *sel_objs, int type, int subtype) { bool is_data, is_mem, is_indx, is_iodata, is_heapdata; Hist_data::HistItem *total; MetricList *prop_mlist; // as passed to get_hist_data MetricList *mlist; // as stored in the data Metric *mitem; int i, nname, nitems, index, index2; TValue *values; double dvalue, clock; Hist_data *data; Vector *percent_scale; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); if (sel_objs == NULL || sel_objs->size () == 0) return NULL; is_mem = false; is_data = false; is_indx = false; is_iodata = false; is_heapdata = false; nname = SUMMARY_NAME; Vector*objs = new Vector(sel_objs->size ()); if (type == DSP_TIMELINE) objs->append ((Histable *) sel_objs->fetch (0)); else { switch (type) { case DSP_FUNCTION: data = dbev->func_data; break; case DSP_LINE: data = dbev->line_data; break; case DSP_PC: data = dbev->pc_data; break; case DSP_SELF: data = dbev->fitem_data; break; case DSP_SOURCE: case DSP_SOURCE_V2: data = dbev->src_data; break; case DSP_DISASM: case DSP_DISASM_V2: data = dbev->dis_data; break; case DSP_DLAYOUT: is_data = true; nname = LSUMMARY_NAME; data = dbev->dlay_data; break; case DSP_DATAOBJ: is_data = true; nname = DSUMMARY_NAME; data = dbev->dobj_data; break; case DSP_MEMOBJ: is_data = true; is_mem = true; nname = IMSUMMARY_NAME; data = dbev->get_indxobj_data (subtype); break; case DSP_INDXOBJ: is_indx = true; nname = IMSUMMARY_NAME; data = dbev->get_indxobj_data (subtype); break; case DSP_IOACTIVITY: is_iodata = true; nname = IMSUMMARY_NAME; data = dbev->iofile_data; break; case DSP_IOVFD: is_iodata = true; nname = IMSUMMARY_NAME; data = dbev->iovfd_data; break; case DSP_IOCALLSTACK: is_iodata = true; nname = IMSUMMARY_NAME; data = dbev->iocs_data; break; case DSP_HEAPCALLSTACK: is_heapdata = true; nname = IMSUMMARY_NAME; data = dbev->heapcs_data; break; default: data = NULL; break; } if (data == NULL || data->get_status () != Hist_data::SUCCESS) return NULL; Hist_data::HistItem *current_item; for (i = 0; i < sel_objs->size (); i++) { int sel_index = (int) sel_objs->fetch (i); if (type != DSP_IOACTIVITY && type != DSP_IOVFD && type != DSP_IOCALLSTACK && type != DSP_HEAPCALLSTACK) { if (sel_index < 0 || sel_index >= data->size ()) continue; current_item = data->fetch (sel_index); if (current_item->obj == NULL) continue; } else { if (sel_index < 0) continue; bool found = false; for (int j = 0; j < data->size (); j++) { current_item = data->fetch (j); if ((current_item->obj != NULL) && (current_item->obj->id == sel_index)) { found = true; break; } } if (!found) continue; } char *nm = current_item->obj->get_name (); if (streq (nm, NTXT (""))) { // Special case for 'Total'. // Multi selection which includes 'Total' is only 'Total' objs->reset (); objs->append (current_item->obj); break; } objs->append (current_item->obj); } } if (objs->size () == 0) return NULL; // Set name area Vector *saligns = new Vector(nname); Vector*mnemonic = new Vector(nname); Vector *jlabels = new Vector(nname); Vector *jvalues = new Vector(nname); Vector *name_objs = new Vector(4); name_objs->store (0, saligns); name_objs->store (1, mnemonic); name_objs->store (2, jlabels); name_objs->store (3, jvalues); if (is_mem) setMemSummary (objs, saligns, mnemonic, jlabels, jvalues); else if (is_indx) setIndxSummary (objs, saligns, mnemonic, jlabels, jvalues); else if (is_data) setDataSummary (objs, saligns, mnemonic, jlabels, jvalues); else if (is_iodata) setIOActivitySummary (objs, saligns, mnemonic, jlabels, jvalues); else if (is_heapdata) setHeapActivitySummary (objs, saligns, mnemonic, jlabels, jvalues); else setSummary (objs, saligns, mnemonic, jlabels, jvalues); // Get the reference metrics if (is_data) prop_mlist = new MetricList (dbev->get_metric_ref (MET_DATA)); else if (is_indx) prop_mlist = new MetricList (dbev->get_metric_ref (MET_INDX)); else if (is_iodata) prop_mlist = new MetricList (dbev->get_metric_ref (MET_IO)); else if (is_heapdata) prop_mlist = new MetricList (dbev->get_metric_ref (MET_HEAP)); else prop_mlist = new MetricList (dbev->get_metric_ref (MET_NORMAL)); // XXXX a workaround to avoid aggregated data for compare mode, only show base experiment data if (prop_mlist && dbev->comparingExperiments ()) prop_mlist = dbev->get_compare_mlist (prop_mlist, 0); nitems = prop_mlist->get_items ()->size (); // Set the metrics area jlabels = new Vector(nitems); Vector *clock_list = new Vector(nitems); Vector *excl_list = new Vector(nitems); Vector *ep_list = new Vector(nitems); Vector *incl_list = new Vector(nitems); Vector *ip_list = new Vector(nitems); Vector *vtype = new Vector(nitems); // Initialize Java String array Vector *metric_objs = new Vector(8); metric_objs->store (0, jlabels); metric_objs->store (1, clock_list); metric_objs->store (2, excl_list); metric_objs->store (3, ep_list); metric_objs->store (4, incl_list); metric_objs->store (5, ip_list); metric_objs->store (6, vtype); percent_scale = new Vector(); int last_init = -1; for (i = 0; i < objs->size (); i++) { Histable *current_obj = objs->fetch (i); // Get the data to be displayed data = dbev->get_hist_data (prop_mlist, current_obj->get_type (), subtype, Hist_data::SELF, current_obj, dbev->sel_binctx, objs); if (data->get_status () != Hist_data::SUCCESS) { if (type != DSP_DLAYOUT) { // For data_layout, rows with zero metrics are OK delete data; continue; } } Hist_data::HistItem *hi = data->fetch (0); values = hi ? hi->value : NULL; total = data->get_totals (); index2 = 0; // get the metric list from the data mlist = data->get_metric_list (); // We loop over the metrics in mlist. // We construct index2, which tells us // the corresponding entry in the metric_objs lists. // We need this mapping multiple times. // So, if you change the looping in any way here, // do so as well in other similar loops. // All such loops are marked so: // See discussion on "mlist-to-index2 mapping". Vec_loop (Metric*, mlist->get_items (), index, mitem) { if (mitem->get_subtype () == Metric::STATIC) continue; if (last_init < index2) { last_init = index2; jlabels->store (index2, NULL); clock_list->store (index2, 0.0); excl_list->store (index2, 0.0); ep_list->store (index2, 0.0); incl_list->store (index2, 0.0); ip_list->store (index2, 0.0); vtype->store (index2, 0); } dvalue = (values != NULL) ? values[index].to_double () : 0.0; double dtotal = total->value[index].to_double (); percent_scale->store (index, dtotal == 0. ? 0. : 100. / dtotal); if (mitem->is_time_val ()) clock = 1.e+6 * dbeSession->get_clock (-1); else clock = 0.0; clock_list->store (index2, clock); if (mitem->get_subtype () == Metric::EXCLUSIVE || mitem->get_subtype () == Metric::DATASPACE) { if (i == 0) { char *sstr = mitem->get_username (); char *buf = dbe_strdup (sstr); jlabels->store (index2, buf); vtype->store (index2, mitem->get_vtype ()); } dvalue += excl_list->fetch (index2); double percent = dvalue * percent_scale->fetch (index); excl_list->store (index2, dvalue); ep_list->store (index2, percent); if (is_data || is_indx || is_iodata || is_heapdata) // move to next row, except if there's inclusive data, too index2++; } else { dvalue += incl_list->fetch (index2); if (dvalue > dtotal && mitem->get_type () != BaseMetric::DERIVED) dvalue = dtotal; // temporary correction double percent = dvalue * percent_scale->fetch (index); incl_list->store (index2, dvalue); ip_list->store (index2, percent); index2++; } } delete data; } // for multi-selection, we have to recompute the derived metrics if (objs->size () > 1 && dbev->get_derived_metrics () != NULL && dbev->get_derived_metrics ()->get_items () != NULL && dbev->get_derived_metrics ()->get_items ()->size () > 0) { // See discussion on "mlist-to-index2 mapping". Vector *mvec = new Vector(nitems); index2 = 0; Vec_loop (Metric*, prop_mlist->get_items (), index, mitem) { if (mitem->get_subtype () == Metric::STATIC) continue; if (mitem->get_subtype () == Metric::EXCLUSIVE || mitem->get_subtype () == Metric::DATASPACE) { mvec->store (index2, mitem); if (is_data || is_indx || is_iodata || is_heapdata) index2++; } else { assert (strcmp (mvec->fetch (index2)->get_cmd (), mitem->get_cmd ()) == 0); index2++; } } int *map = dbev->get_derived_metrics ()->construct_map (mvec, BaseMetric::EXCLUSIVE, mvec->fetch (0)->get_expr_spec ()); if (map != NULL) { int nmetrics = mvec->size (); double *evalues = (double *) xmalloc (nmetrics * sizeof (double)); double *ivalues = (double *) xmalloc (nmetrics * sizeof (double)); for (index2 = 0; index2 < nmetrics; index2++) { evalues[index2] = excl_list->fetch (index2); ivalues[index2] = incl_list->fetch (index2); } // evaluate derived metrics dbev->get_derived_metrics ()->eval (map, evalues); dbev->get_derived_metrics ()->eval (map, ivalues); for (index2 = 0; index2 < nmetrics; index2++) { excl_list->store (index2, evalues[index2]); incl_list->store (index2, ivalues[index2]); } // recompute percentages for derived metrics EUGENE maybe all percentage computations should be moved here // See discussion on "mlist-to-index2 mapping". index2 = 0; Vec_loop (Metric*, prop_mlist->get_items (), index, mitem) { if (mitem->get_subtype () == Metric::STATIC) continue; if (mitem->get_subtype () == Metric::EXCLUSIVE || mitem->get_subtype () == Metric::DATASPACE) { if (mitem->get_type () == BaseMetric::DERIVED) ep_list->store (index2, excl_list->fetch (index2) * percent_scale->fetch (index)); if (is_data || is_indx || is_iodata || is_heapdata) index2++; } else { if (mitem->get_type () == BaseMetric::DERIVED) ip_list->store (index2, incl_list->fetch (index2) * percent_scale->fetch (index)); index2++; } } free (evalues); free (ivalues); free (map); } delete mvec; } delete prop_mlist; Vector *summary = new Vector(2); summary->store (0, name_objs); summary->store (1, metric_objs); delete objs; delete percent_scale; return summary; } char * dbeGetExpName (int /*dbevindex*/, char *dir_name) { char *ret; char *warn; if (col_ctr == NULL) col_ctr = new Coll_Ctrl (1); // Potential race condition? if (dir_name != NULL) { ret = col_ctr->set_directory (dir_name, &warn); // note that the warning and error msgs are written to stderr, not returned to caller if (warn != NULL) fprintf (stderr, NTXT ("%s"), warn); if (ret != NULL) fprintf (stderr, NTXT ("%s"), ret); } return dbe_strdup (col_ctr->get_expt ()); } // === CollectDialog HWC info === Vector*> * dbeGetHwcSets (int /*dbevindex*/, bool forKernel) { Vector*> *list = new Vector*>(2); char * defctrs = hwc_get_default_cntrs2 (forKernel, 1); Vector *i18n = new Vector(1); // User name Vector *name = new Vector(1); // Internal name if (NULL != defctrs) { i18n->store (0, xstrdup (defctrs)); name->store (0, xstrdup (NTXT ("default"))); } list->store (0, i18n); list->store (1, name); return list; } static Vector * dbeGetHwcs (Hwcentry **hwcs) { int sz; for (sz = 0; hwcs && hwcs[sz]; sz++) ; Vector *list = new Vector(9); Vector *i18n = new Vector(sz); Vector *name = new Vector(sz); Vector *int_name = new Vector(sz); Vector *metric = new Vector(sz); Vector *val = new Vector(sz); Vector *timecvt = new Vector(sz); Vector *memop = new Vector(sz); Vector *short_desc = new Vector(sz); Vector*> *reglist_v = new Vector*>(sz); Vector *supportsAttrs = new Vector(sz); Vector *supportsMemspace = new Vector(sz); for (int i = 0; i < sz; i++) { Hwcentry *ctr = hwcs[i]; Vector *registers = new Vector(MAX_PICS); registers->store (0, REGNO_ANY); i18n->store (i, dbe_strdup (hwc_i18n_metric (ctr))); name->store (i, dbe_strdup (ctr->name)); int_name->store (i, dbe_strdup (ctr->int_name)); metric->store (i, dbe_strdup (ctr->metric)); val->store (i, ctr->val); // signed promotion from int timecvt->store (i, ctr->timecvt); memop->store (i, ctr->memop); reglist_v->store (i, registers); short_desc->store (i, dbe_strdup (ctr->short_desc)); supportsAttrs->store (i, true); supportsMemspace->store (i, ABST_MEMSPACE_ENABLED (ctr->memop)); } list->store (0, i18n); list->store (1, name); list->store (2, int_name); list->store (3, metric); list->store (4, val); list->store (5, timecvt); list->store (6, memop); list->store (7, short_desc); list->store (8, reglist_v); list->store (9, supportsAttrs); list->store (10, supportsMemspace); return list; } Vector * dbeGetHwcsAll (int /*dbevindex*/, bool forKernel) { Vector *list = new Vector(2); list->store (0, dbeGetHwcs (hwc_get_std_ctrs (forKernel))); list->store (1, dbeGetHwcs (hwc_get_raw_ctrs (forKernel))); return list; } Vector * dbeGetHwcHelp (int /*dbevindex*/, bool forKernel) { Vector *strings = new Vector(32); FILE *f = tmpfile (); hwc_usage_f (forKernel, f, "", 0, 0, 1); // writes to f fflush (f); fseek (f, 0, SEEK_SET); #define MAX_LINE_LEN 2048 char buff[MAX_LINE_LEN]; int ii = 0; while (fgets (buff, MAX_LINE_LEN, f)) strings->store (ii++, dbe_strdup (buff)); fclose (f); return strings; } Vector * dbeGetHwcAttrList (int /*dbevindex*/, bool forKernel) { char ** attr_list = hwc_get_attrs (forKernel); // Get Attribute list int size; for (size = 0; attr_list && attr_list[size]; size++) ; Vector *name = new Vector(size); for (int i = 0; i < size; i++) name->store (i, dbe_strdup (attr_list[i])); return name; } //Get maximum number of simultaneous counters int dbeGetHwcMaxConcurrent (int /*dbevindex*/, bool forKernel) { return hwc_get_max_concurrent (forKernel); } // === End CollectDialog HWC info === // Instruction-frequency data Vector * dbeGetIfreqData (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); if (!dbeSession->is_ifreq_available ()) return NULL; int size = dbeSession->nexps (); if (size == 0) return NULL; // Initialize Java String array Vector *list = new Vector(); for (int i = 0; i < size; i++) { Experiment *exp = dbeSession->get_exp (i); if (exp->broken || !dbev->get_exp_enable (i) || !exp->ifreqavail) continue; // write a header for the experiment list->append (dbe_sprintf (GTXT ("Instruction frequency data from experiment %s\n\n"), exp->get_expt_name ())); // add its instruction frequency messages char *ifreq = pr_mesgs (exp->fetch_ifreq (), NTXT (""), NTXT ("")); list->append (ifreq); } return list; } // LeakList related methods // Vector * dbeGetLeakListInfo (int dbevindex, bool leakflag) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); MetricList *origmlist = dbev->get_metric_list (MET_NORMAL); MetricList *nmlist = new MetricList (origmlist); if (leakflag) nmlist->set_metrics (NTXT ("e.heapleakbytes:e.heapleakcnt:name"), true, dbev->get_derived_metrics ()); else nmlist->set_metrics (NTXT ("e.heapallocbytes:e.heapalloccnt:name"), true, dbev->get_derived_metrics ()); MetricList *mlist = new MetricList (nmlist); delete nmlist; CStack_data *lam = dbev->get_cstack_data (mlist); if (lam == NULL || lam->size () == 0) { delete lam; delete mlist; return NULL; } Vector*> *evalue = new Vector*>(lam->size ()); Vector*> *pcstack = new Vector*>(lam->size ()); Vector*> *offstack = new Vector*>(lam->size ()); Vector*> *fpcstack = new Vector*>(lam->size ()); Vector*> *sumval = new Vector*>(lam->size ()); int index; CStack_data::CStack_item *lae; Vec_loop (CStack_data::CStack_item*, lam->cstack_items, index, lae) { Vector *jivals = NULL; if (lae != NULL) { jivals = new Vector(4); jivals->store (0, (Obj) (index + 1)); jivals->store (1, (Obj) lae->value[1].ll); jivals->store (2, (Obj) lae->value[0].ll); jivals->store (3, (Obj) (leakflag ? 1 : 2)); } evalue->store (index, jivals); int snum = lae->stack->size (); Vector *jivals1 = new Vector(snum); Vector *jivals2 = new Vector(snum); Vector *jivals3 = new Vector(snum); if (lae->stack != NULL) { for (int i = lae->stack->size () - 1; i >= 0; i--) { DbeInstr *instr = lae->stack->fetch (i); jivals1->store (i, (Obj) instr); jivals2->store (i, (Obj) instr->func); jivals3->store (i, (Obj) instr->addr); } } fpcstack->store (index, jivals1); pcstack->store (index, jivals2); offstack->store (index, jivals3); lae++; } Vector *jivals4 = new Vector(3); jivals4->store (0, (Obj) lam->size ()); jivals4->store (1, (Obj) lam->total->value[1].ll); jivals4->store (2, (Obj) lam->total->value[0].ll); sumval->store (0, jivals4); delete lam; delete mlist; Vector *earray = new Vector(5); earray->store (0, evalue); earray->store (1, pcstack); earray->store (2, offstack); earray->store (3, fpcstack); earray->store (4, sumval); return earray; } // Map timeline address to function instr // Obj dbeGetObject (int dbevindex, Obj sel_func, Obj sel_pc) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); if (sel_pc) return sel_pc; return sel_func; } char * dbeGetName (int /*dbevindex*/, int exp_id) // This function's name is not descriptive enough - it returns a string // containing the full experiment name with path, process name, and PID. // There are various dbe functions that provide experiment name and experiment // details, and they should probably be consolidated/refactored. (TBR) // For another example of similar output formatting, see dbeGetExpName(). { int id = (exp_id < 0) ? 0 : exp_id; Experiment *exp = dbeSession->get_exp (id); if (exp == NULL) return NULL; char *buf = dbe_sprintf (NTXT ("%s [%s, PID %d]"), exp->get_expt_name (), exp->utargname != NULL ? exp->utargname : GTXT ("(unknown)"), exp->getPID ()); return buf; } Vector * dbeGetExpVerboseName (Vector *exp_ids) { int len = exp_ids->size (); Vector *list = new Vector(len); for (int i = 0; i < len; i++) { char * verboseName = dbeGetName (0, exp_ids->fetch (i)); // no strdup() list->store (i, verboseName); } return list; } long long dbeGetStartTime (int /*dbevindex*/, int exp_id) { int id = (exp_id < 0) ? 0 : exp_id; Experiment *exp = dbeSession->get_exp (id); return exp ? exp->getStartTime () : (long long) 0; } long long dbeGetRelativeStartTime (int /*dbevindex*/, int exp_id) { int id = (exp_id < 0) ? 0 : exp_id; Experiment *exp = dbeSession->get_exp (id); return exp ? exp->getRelativeStartTime () : (long long) 0; } long long dbeGetEndTime (int /*dbevindex*/, int exp_id) { int id = (exp_id < 0) ? 0 : exp_id; Experiment *exp = dbeSession->get_exp (id); // Experiment::getEndTime was initially implemented as // returning exp->last_event. To preserve the semantics // new Experiment::getLastEvent() is used here. return exp ? exp->getLastEvent () : (long long) 0; } int dbeGetClock (int /*dbevindex*/, int exp_id) { return dbeSession->get_clock (exp_id); } long long dbeGetWallStartSec (int /*dbevindex*/, int exp_id) { int id = (exp_id < 0) ? 0 : exp_id; Experiment *exp = dbeSession->get_exp (id); return exp ? exp->getWallStartSec () : 0ll; } char * dbeGetHostname (int /*dbevindex*/, int exp_id) { int id = (exp_id < 0) ? 0 : exp_id; Experiment *exp = dbeSession->get_exp (id); return exp ? dbe_strdup (exp->hostname) : NULL; } static DataView * getTimelinePackets (int dbevindex, int exp_id, int data_id, int entity_prop_id) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); const int sortprop_count = 3; const int sortprops[sortprop_count] = { PROP_HWCTAG, // aux entity_prop_id, PROP_TSTAMP }; DataView *packets = dbev->get_filtered_events (exp_id, data_id, sortprops, sortprop_count); return packets; } static long getIdxByVals (DataView * packets, int aux, int entity_prop_val, uint64_t time, DataView::Relation rel) { const int sortprop_count = 3; Datum tval[sortprop_count]; tval[0].setUINT32 (aux); tval[1].setUINT32 (entity_prop_val); //CPUID, LWPID, THRID are downsized to 32 tval[2].setUINT64 (time); long idx = packets->getIdxByVals (tval, rel); return idx; } static bool isValidIdx (DataView * packets, int entity_prop_id, int aux, int entity_prop_val, long idx) { if (idx < 0 || idx >= packets->getSize ()) return false; int pkt_aux = packets->getIntValue (PROP_HWCTAG, idx); if (pkt_aux != aux) return false; if (entity_prop_id == PROP_EXPID) return true; // not a packet property; we know the packet is in this experiment if (entity_prop_id == PROP_NONE) return true; // not a packet property; we know the packet is in this experiment int pkt_ent = packets->getIntValue (entity_prop_id, idx); if (pkt_ent != entity_prop_val) return false; return true; } static bool hasInvisbleTLEvents (Experiment *exp, VMode view_mode) { if (exp->has_java && view_mode == VMODE_USER) return true; return false; } static bool isVisibleTLEvent (Experiment *exp, VMode view_mode, DataView* packets, long idx) { if (hasInvisbleTLEvents (exp, view_mode)) { JThread *jthread = (JThread*) packets->getObjValue (PROP_JTHREAD, idx); if (jthread == JTHREAD_NONE || (jthread != NULL && jthread->is_system ())) return false; } return true; } static long getTLVisibleIdxByStepping (Experiment *exp, VMode view_mode, int entity_prop_id, DataView * packets, int aux, int entity_prop_val, long idx, long move_count, int direction) { assert (move_count >= 0); assert (direction == 1 || direction == -1 || direction == 0); if (direction == 0 /* precise hit required */) move_count = 0; do { if (!isValidIdx (packets, entity_prop_id, aux, entity_prop_val, idx)) return -1; if (isVisibleTLEvent (exp, view_mode, packets, idx)) { if (move_count <= 0) break; move_count--; } if (direction == 0) return -1; idx += direction; } while (1); return idx; } static long getTLVisibleIdxByVals (Experiment *exp, VMode view_mode, int entity_prop_id, DataView * packets, int aux, int entity_prop_val, uint64_t time, DataView::Relation rel) { long idx = getIdxByVals (packets, aux, entity_prop_val, time, rel); if (!hasInvisbleTLEvents (exp, view_mode)) return idx; if (idx < 0) return idx; if (rel == DataView::REL_EQ) return -1; // would require bi-directional search... not supported for now int direction = (rel == DataView::REL_LT || rel == DataView::REL_LTEQ) ? -1 : 1; idx = getTLVisibleIdxByStepping (exp, view_mode, entity_prop_id, packets, aux, entity_prop_val, idx, 0 /* first match */, direction); return idx; } // In thread mode, the entity name for non Java thread should be the 1st func // from the current thread's stack. See #4961315 static char* getThreadRootFuncName (int, int, int, int, VMode) { return NULL; // until we figure out what we want to show... YXXX } Vector * dbeGetEntityProps (int dbevindex) //YXXX TBD, should this be exp-specific? { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Vector *prop_id = new Vector(); Vector *prop_name = new Vector(); Vector *prop_uname = new Vector(); Vector *prop_cname = new Vector(); //must match TLModeCmd vals! prop_id->append (PROP_NONE); prop_name->append (dbe_strdup (GTXT ("NONE"))); prop_uname->append (dbe_strdup (GTXT ("Unknown"))); prop_cname->append (dbe_strdup (NTXT ("unknown"))); prop_id->append (PROP_LWPID); prop_name->append (dbe_strdup (GTXT ("LWPID"))); prop_uname->append (dbe_strdup (GTXT ("LWP"))); prop_cname->append (dbe_strdup (NTXT ("lwp"))); prop_id->append (PROP_THRID); prop_name->append (dbe_strdup (GTXT ("THRID"))); prop_uname->append (dbe_strdup (GTXT ("Thread"))); prop_cname->append (dbe_strdup (NTXT ("thread"))); prop_id->append (PROP_CPUID); prop_name->append (dbe_strdup (GTXT ("CPUID"))); prop_uname->append (dbe_strdup (GTXT ("CPU"))); prop_cname->append (dbe_strdup (NTXT ("cpu"))); prop_id->append (PROP_EXPID); prop_name->append (dbe_strdup (GTXT ("EXPID"))); prop_uname->append (dbe_strdup (GTXT ("Process"))); // placeholder... // ...until we finalize how to expose user-level Experiments, descendents prop_cname->append (dbe_strdup (NTXT ("experiment"))); Vector *darray = new Vector(); darray->store (0, prop_id); darray->store (1, prop_name); darray->store (2, prop_uname); darray->store (3, prop_cname); return darray; } Vector * dbeGetEntities (int dbevindex, int exp_id, int entity_prop_id) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Experiment *exp = dbeSession->get_exp (exp_id); if (exp == NULL) return NULL; // Recognize and skip faketime experiments if (exp->timelineavail == false) return NULL; Vector *tagObjs = exp->getTagObjs ((Prop_type) entity_prop_id); int total_nelem; if (tagObjs) total_nelem = (int) tagObjs->size (); else total_nelem = 0; const VMode view_mode = dbev->get_view_mode (); bool show_java_threadnames = (entity_prop_id == PROP_THRID && view_mode != VMODE_MACHINE); // allocate the structures for the return Vector *entity_prop_vals = new Vector(); Vector *jthr_names = new Vector(); Vector *jthr_g_names = new Vector(); Vector *jthr_p_names = new Vector(); // now walk the tagObjs from the experiment, and check for filtering for (int tagObjsIdx = 0; tagObjsIdx < total_nelem; tagObjsIdx++) { int entity_prop_val = (int) ((Other *) tagObjs->fetch (tagObjsIdx))->tag; entity_prop_vals->append (entity_prop_val); char *jname, *jgname, *jpname; JThread *jthread = NULL; bool has_java_threadnames = false; if (show_java_threadnames) { jthread = exp->get_jthread (entity_prop_val); has_java_threadnames = (jthread != JTHREAD_DEFAULT && jthread != JTHREAD_NONE); } if (!has_java_threadnames) { jname = jgname = jpname = NULL; if (entity_prop_id == PROP_THRID || entity_prop_id == PROP_LWPID) // if non Java thread, set thread name to the 1st func // from the current thread's stack. see #4961315 jname = getThreadRootFuncName (dbevindex, exp_id, entity_prop_id, entity_prop_val, view_mode); } else { jname = dbe_strdup (jthread->name); jgname = dbe_strdup (jthread->group_name); jpname = dbe_strdup (jthread->parent_name); } jthr_names->append (jname); jthr_g_names->append (jgname); jthr_p_names->append (jpname); } Vector *entity_prop_name_v = new Vector(); char* entity_prop_name = dbeSession->getPropName (entity_prop_id); entity_prop_name_v->append (entity_prop_name); Vector *darray = new Vector(5); darray->store (0, entity_prop_vals); darray->store (1, jthr_names); darray->store (2, jthr_g_names); darray->store (3, jthr_p_names); darray->store (4, entity_prop_name_v); // vector only has 1 element return darray; } // TBR: dbeGetEntities() can be set to private now that we have dbeGetEntitiesV2() Vector * dbeGetEntitiesV2 (int dbevindex, Vector *exp_ids, int entity_prop_id) { int sz = exp_ids->size (); Vector *res = new Vector(sz); for (int ii = 0; ii < sz; ii++) { int expIdx = exp_ids->fetch (ii); Vector* ents = dbeGetEntities (dbevindex, expIdx, entity_prop_id); res->store (ii, ents); } return res; } //YXXX old-tl packets still used for details static Vector * getTLDetailValues (int dbevindex, Experiment * exp, int data_id, VMode view_mode, DataView *packets, long idx) { Vector *value = new Vector(15); long i = idx; if (data_id == DATA_SAMPLE || data_id == DATA_GCEVENT) { //YXXX DATA_SAMPLE not handled but could be. } Obj stack = (unsigned long) getStack (view_mode, packets, i); Vector *funcs = stack ? dbeGetStackFunctions (dbevindex, stack) : NULL; Function *func = (Function*) getStackPC (0, view_mode, packets, i)->convertto (Histable::FUNCTION); // Fill common data value->store (0, packets->getIntValue (PROP_LWPID, i)); value->store (1, packets->getIntValue (PROP_THRID, i)); value->store (2, packets->getIntValue (PROP_CPUID, i)); value->store (3, packets->getLongValue (PROP_TSTAMP, i)); value->store (4, (unsigned long) stack); value->store (5, (unsigned long) func); // Fill specific data switch (data_id) { case DATA_CLOCK: value->store (6, packets->getIntValue (PROP_MSTATE, i)); { hrtime_t interval = exp->get_params ()->ptimer_usec * 1000LL // nanoseconds * packets->getLongValue (PROP_NTICK, i); value->store (7, interval); } value->store (8, packets->getIntValue (PROP_OMPSTATE, i)); value->store (9, packets->getLongValue (PROP_EVT_TIME, i)); // visual duration break; case DATA_SYNCH: value->store (6, packets->getLongValue (PROP_EVT_TIME, i)); value->store (7, packets->getLongValue (PROP_SOBJ, i)); break; case DATA_HWC: value->store (6, packets->getLongValue (PROP_HWCINT, i)); value->store (7, packets->getLongValue (PROP_VADDR, i)); // data vaddr value->store (8, packets->getLongValue (PROP_PADDR, i)); // data paddr value->store (9, packets->getLongValue (PROP_VIRTPC, i)); // pc paddr value->store (10, packets->getLongValue (PROP_PHYSPC, i)); // pc vaddr break; case DATA_RACE: value->store (6, packets->getIntValue (PROP_RTYPE, i)); value->store (7, packets->getIntValue (PROP_RID, i)); value->store (8, packets->getLongValue (PROP_RVADDR, i)); break; case DATA_DLCK: value->store (6, packets->getIntValue (PROP_DTYPE, i)); value->store (7, packets->getIntValue (PROP_DLTYPE, i)); value->store (8, packets->getIntValue (PROP_DID, i)); value->store (9, packets->getLongValue (PROP_DVADDR, i)); break; case DATA_HEAP: case DATA_HEAPSZ: value->store (6, packets->getIntValue (PROP_HTYPE, i)); value->store (7, packets->getLongValue (PROP_HSIZE, i)); value->store (8, packets->getLongValue (PROP_HVADDR, i)); value->store (9, packets->getLongValue (PROP_HOVADDR, i)); value->store (10, packets->getLongValue (PROP_HLEAKED, i)); value->store (11, packets->getLongValue (PROP_HFREED, i)); value->store (12, packets->getLongValue (PROP_HCUR_ALLOCS, i)); // signed int64_t value->store (13, packets->getLongValue (PROP_HCUR_LEAKS, i)); break; case DATA_IOTRACE: value->store (6, packets->getIntValue (PROP_IOTYPE, i)); value->store (7, packets->getIntValue (PROP_IOFD, i)); value->store (8, packets->getLongValue (PROP_IONBYTE, i)); value->store (9, packets->getLongValue (PROP_EVT_TIME, i)); value->store (10, packets->getIntValue (PROP_IOVFD, i)); break; } Vector *result = new Vector(5); result->store (0, value); result->store (1, funcs); // Histable::Function* result->store (2, funcs ? dbeGetFuncNames (dbevindex, funcs) : 0); // formatted func names result->store (3, stack ? dbeGetStackPCs (dbevindex, stack) : 0); // Histable::DbeInstr* result->store (4, stack ? dbeGetStackNames (dbevindex, stack) : 0); // formatted pc names return result; } Vector * dbeGetTLDetails (int dbevindex, int exp_id, int data_id, int entity_prop_id, Obj event_id) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Experiment *exp = dbeSession->get_exp (exp_id < 0 ? 0 : exp_id); if (exp == NULL) return NULL; DataView *packets = getTimelinePackets (dbevindex, exp_id, data_id, entity_prop_id); if (!packets) return NULL; VMode view_mode = dbev->get_view_mode (); long idx = (long) event_id; Vector *values = getTLDetailValues (dbevindex, exp, data_id, view_mode, packets, idx); return values; } Vector * dbeGetStackFunctions (int dbevindex, Obj stack) { Vector *instrs = dbeGetStackPCs (dbevindex, stack); if (instrs == NULL) return NULL; int stsize = instrs->size (); Vector *jivals = new Vector(stsize); for (int i = 0; i < stsize; i++) { Histable *obj = (Histable*) instrs->fetch (i); // if ( obj->get_type() != Histable::LINE ) {//YXXX what is this? // Remove the above check: why not do this conversion for lines - // otherwise filtering in timeline by function stack in omp user mode is broken obj = obj->convertto (Histable::FUNCTION); jivals->store (i, (Obj) obj); } delete instrs; return jivals; } Vector * dbeGetStacksFunctions (int dbevindex, Vector *stacks) { long sz = stacks->size (); Vector *res = new Vector(sz); for (int ii = 0; ii < sz; ii++) { Obj stack = stacks->fetch (ii); Vector *jivals = dbeGetStackFunctions (dbevindex, stack); res->store (ii, jivals); } return res; } Vector * dbeGetStackPCs (int dbevindex, Obj stack) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); if (stack == 0) return NULL; bool show_all = dbev->isShowAll (); Vector *instrs = CallStack::getStackPCs ((void *) stack, !show_all); int stsize = instrs->size (); int istart = 0; bool showAll = dbev->isShowAll (); for (int i = 0; i < stsize - 1; i++) { Function *func = (Function*) instrs->fetch (i)->convertto (Histable::FUNCTION); int ix = func->module->loadobject->seg_idx; if (showAll && dbev->get_lo_expand (ix) == LIBEX_API) // truncate stack here: LIBRARY_VISIBILITY if we are using API only but no hide istart = i; } stsize = stsize - istart; Vector *jlvals = new Vector(stsize); for (int i = 0; i < stsize; i++) { Histable *instr = instrs->fetch (i + istart); jlvals->store (i, (Obj) instr); } delete instrs; return jlvals; } Vector * dbeGetStackNames (int dbevindex, Obj stack) { DbeView *dbev = dbeSession->getView (dbevindex); Vector *instrs = dbeGetStackPCs (dbevindex, stack); if (instrs == NULL) return NULL; int stsize = instrs->size (); Vector *list = new Vector(stsize); bool showAll = dbev->isShowAll (); for (int i = 0; i < stsize; i++) { Histable* instr = (Histable*) instrs->fetch (i); if (!showAll) { // LIBRARY_VISIBILITY Function *func = (Function*) instr->convertto (Histable::FUNCTION); LoadObject *lo = ((Function*) func)->module->loadobject; if (dbev->get_lo_expand (lo->seg_idx) == LIBEX_HIDE) { list->store (i, dbe_strdup (lo->get_name ())); continue; } } list->store (i, dbe_strdup (instr->get_name (dbev->get_name_format ()))); } delete instrs; return list; } Vector * dbeGetSamples (int dbevindex, int exp_id, int64_t lo_idx, int64_t hi_idx) { DataView * packets = getTimelinePackets (dbevindex, exp_id, DATA_SAMPLE, PROP_EXPID); if (packets == NULL || packets->getSize () == 0) return NULL; long lo; if (lo_idx < 0) lo = 0; else lo = (long) lo_idx; long long max = packets->getSize () - 1; long hi; if (hi_idx < 0 || hi_idx > max) hi = (long) max; else hi = (long) hi_idx; Vector*> *sarray = new Vector*>; Vector* starts = new Vector; Vector* ends = new Vector; Vector* rtimes = new Vector; Vector *startNames = new Vector; Vector *endNames = new Vector; Vector *sampId = new Vector; for (long index = lo; index <= hi; index++) { Sample *sample = (Sample*) packets->getObjValue (PROP_SMPLOBJ, index); PrUsage *prusage = sample->get_usage (); if (prusage == NULL) prusage = new PrUsage; Vector *states = prusage->getMstateValues (); sarray->append (states); starts->append (sample->get_start_time ()); ends->append (sample->get_end_time ()); rtimes->append (prusage->pr_rtime); startNames->append (dbe_strdup (sample->get_start_label ())); endNames->append (dbe_strdup (sample->get_end_label ())); sampId->append (sample->get_number ()); } Vector *res = new Vector(6); res->store (0, sarray); res->store (1, starts); res->store (2, ends); res->store (3, rtimes); res->store (4, startNames); res->store (5, endNames); res->store (6, sampId); return res; } Vector * dbeGetGCEvents (int dbevindex, int exp_id, int64_t lo_idx, int64_t hi_idx) { DataView *packets = getTimelinePackets (dbevindex, exp_id, DATA_GCEVENT, PROP_EXPID); if (packets == NULL || packets->getSize () == 0) return NULL; long lo; if (lo_idx < 0) lo = 0; else lo = (long) lo_idx; long long max = packets->getSize () - 1; long hi; if (hi_idx < 0 || hi_idx > max) hi = (long) max; else hi = (long) hi_idx; Vector* starts = new Vector; Vector* ends = new Vector; Vector *eventId = new Vector; for (long index = lo; index <= hi; index++) { GCEvent *gcevent = (GCEvent*) packets->getObjValue (PROP_GCEVENTOBJ, index); if (gcevent) { starts->append (gcevent->start); ends->append (gcevent->end); eventId->append (gcevent->id); } } Vector *res = new Vector(3); res->store (0, starts); res->store (1, ends); res->store (2, eventId); return res; } Vector*>* dbeGetIOStatistics (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); Hist_data *hist_data; Hist_data::HistItem *hi; FileData *fDataTotal; hist_data = dbev->iofile_data; if (hist_data == NULL) return NULL; hi = hist_data->fetch (0); fDataTotal = (FileData*) hi->obj; Vector *writeStat = new Vector; Vector *readStat = new Vector; Vector *otherStat = new Vector; Vector *errorStat = new Vector; writeStat->append (dbe_strdup (GTXT ("Write Statistics"))); readStat->append (dbe_strdup (GTXT ("Read Statistics"))); otherStat->append (dbe_strdup (GTXT ("Other I/O Statistics"))); errorStat->append (dbe_strdup (GTXT ("I/O Error Statistics"))); StringBuilder sb; if (fDataTotal->getWriteCnt () > 0) { if (fDataTotal->getW0KB1KBCnt () > 0) { sb.sprintf (GTXT ("0KB - 1KB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW0KB1KBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW1KB8KBCnt () > 0) { sb.sprintf (GTXT ("1KB - 8KB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW1KB8KBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW8KB32KBCnt () > 0) { sb.sprintf (GTXT ("8KB - 32KB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW8KB32KBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW32KB128KBCnt () > 0) { sb.sprintf (GTXT ("32KB - 128KB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW32KB128KBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW128KB256KBCnt () > 0) { sb.sprintf (GTXT ("128KB - 256KB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW128KB256KBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW256KB512KBCnt () > 0) { sb.sprintf (GTXT ("256KB - 512KB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW256KB512KBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW512KB1000KBCnt () > 0) { sb.sprintf (GTXT ("512KB - 1000KB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW512KB1000KBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW1000KB10MBCnt () > 0) { sb.sprintf (GTXT ("1000KB - 10MB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW1000KB10MBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW10MB100MBCnt () > 0) { sb.sprintf (GTXT ("10MB - 100MB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW10MB100MBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW100MB1GBCnt () > 0) { sb.sprintf (GTXT ("100MB - 1GB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW100MB1GBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW1GB10GBCnt () > 0) { sb.sprintf (GTXT ("1GB - 10GB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW1GB10GBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW10GB100GBCnt () > 0) { sb.sprintf (GTXT ("10GB - 100GB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW10GB100GBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW100GB1TBCnt () > 0) { sb.sprintf (GTXT ("100GB - 1TB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW100GB1TBCnt ()); writeStat->append (sb.toString ()); } if (fDataTotal->getW1TB10TBCnt () > 0) { sb.sprintf (GTXT ("1TB - 10TB")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getW1TB10TBCnt ()); writeStat->append (sb.toString ()); } sb.sprintf (GTXT ("Longest write")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%.6f (secs.)"), (double) (fDataTotal->getWSlowestBytes () / (double) NANOSEC)); writeStat->append (sb.toString ()); sb.sprintf (GTXT ("Smallest write bytes")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (fDataTotal->getWSmallestBytes ())); writeStat->append (sb.toString ()); sb.sprintf (GTXT ("Largest write bytes")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (fDataTotal->getWLargestBytes ())); writeStat->append (sb.toString ()); sb.sprintf (GTXT ("Total time")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%.6f (secs.)"), (double) (fDataTotal->getWriteTime () / (double) NANOSEC)); writeStat->append (sb.toString ()); sb.sprintf (GTXT ("Total calls")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (fDataTotal->getWriteCnt ())); writeStat->append (sb.toString ()); sb.sprintf (GTXT ("Total bytes")); writeStat->append (sb.toString ()); sb.sprintf (NTXT ("%lld"), (long long) (fDataTotal->getWriteBytes ())); writeStat->append (sb.toString ()); } if (fDataTotal->getReadCnt () > 0) { if (fDataTotal->getR0KB1KBCnt () > 0) { sb.sprintf (GTXT ("0KB - 1KB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR0KB1KBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR1KB8KBCnt () > 0) { sb.sprintf (GTXT ("1KB - 8KB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR1KB8KBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR8KB32KBCnt () > 0) { sb.sprintf (GTXT ("8KB - 32KB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR8KB32KBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR32KB128KBCnt () > 0) { sb.sprintf (GTXT ("32KB - 128KB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR32KB128KBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR128KB256KBCnt () > 0) { sb.sprintf (GTXT ("128KB - 256KB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR128KB256KBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR256KB512KBCnt () > 0) { sb.sprintf (GTXT ("256KB - 512KB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR256KB512KBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR512KB1000KBCnt () > 0) { sb.sprintf (GTXT ("512KB - 1000KB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR512KB1000KBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR1000KB10MBCnt () > 0) { sb.sprintf (GTXT ("1000KB - 10MB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR1000KB10MBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR10MB100MBCnt () > 0) { sb.sprintf (GTXT ("10MB - 100MB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR10MB100MBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR100MB1GBCnt () > 0) { sb.sprintf (GTXT ("100MB - 1GB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR100MB1GBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR1GB10GBCnt () > 0) { sb.sprintf (GTXT ("1GB - 10GB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR1GB10GBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR10GB100GBCnt () > 0) { sb.sprintf (GTXT ("10GB - 100GB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR10GB100GBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR100GB1TBCnt () > 0) { sb.sprintf (GTXT ("100GB - 1TB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR100GB1TBCnt ()); readStat->append (sb.toString ()); } if (fDataTotal->getR1TB10TBCnt () > 0) { sb.sprintf (GTXT ("1TB - 10TB")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), fDataTotal->getR1TB10TBCnt ()); readStat->append (sb.toString ()); } sb.sprintf (GTXT ("Longest read")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%.6f (secs.)"), (double) (fDataTotal->getRSlowestBytes () / (double) NANOSEC)); readStat->append (sb.toString ()); sb.sprintf (GTXT ("Smallest read bytes")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (fDataTotal->getRSmallestBytes ())); readStat->append (sb.toString ()); sb.sprintf (GTXT ("Largest read bytes")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (fDataTotal->getRLargestBytes ())); readStat->append (sb.toString ()); sb.sprintf (GTXT ("Total time")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%.6f (secs.)"), (double) (fDataTotal->getReadTime () / (double) NANOSEC)); readStat->append (sb.toString ()); sb.sprintf (GTXT ("Total calls")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (fDataTotal->getReadCnt ())); readStat->append (sb.toString ()); sb.sprintf (GTXT ("Total bytes")); readStat->append (sb.toString ()); sb.sprintf (NTXT ("%lld"), (long long) (fDataTotal->getReadBytes ())); readStat->append (sb.toString ()); } if (fDataTotal->getOtherCnt () > 0) { sb.sprintf (GTXT ("Total time")); otherStat->append (sb.toString ()); sb.sprintf (NTXT ("%.6f (secs.)"), (double) (fDataTotal->getOtherTime () / (double) NANOSEC)); otherStat->append (sb.toString ()); sb.sprintf (GTXT ("Total calls")); otherStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (fDataTotal->getOtherCnt ())); otherStat->append (sb.toString ()); } if (fDataTotal->getErrorCnt () > 0) { sb.sprintf (GTXT ("Total time")); errorStat->append (sb.toString ()); sb.sprintf (NTXT ("%.6f (secs.)"), (double) (fDataTotal->getErrorTime () / (double) NANOSEC)); errorStat->append (sb.toString ()); sb.sprintf (GTXT ("Total calls")); errorStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (fDataTotal->getErrorCnt ())); errorStat->append (sb.toString ()); } Vector*>* statisticsData = new Vector*>(4); statisticsData->store (0, writeStat); statisticsData->store (1, readStat); statisticsData->store (2, otherStat); statisticsData->store (3, errorStat); return statisticsData; } Vector*>* dbeGetHeapStatistics (int dbevindex) { DbeView *dbev = dbeSession->getView (dbevindex); Hist_data *hist_data; Hist_data::HistItem *hi; HeapData *hDataTotal; hist_data = dbev->heapcs_data; if (hist_data == NULL) return NULL; hi = hist_data->fetch (0); hDataTotal = (HeapData*) hi->obj; Vector *memoryUsage = new Vector; Vector *allocStat = new Vector; Vector *leakStat = new Vector; memoryUsage->append (dbe_strdup (GTXT ("Process With Highest Peak Memory Usage"))); allocStat->append (dbe_strdup (GTXT ("Memory Allocations Statistics"))); leakStat->append (dbe_strdup (GTXT ("Memory Leaks Statistics"))); StringBuilder sb; if (hDataTotal->getPeakMemUsage () > 0) { sb.sprintf (GTXT ("Heap size bytes")); memoryUsage->append (sb.toString ()); sb.sprintf (NTXT ("%lld"), (long long) (hDataTotal->getPeakMemUsage ())); memoryUsage->append (sb.toString ()); sb.sprintf (GTXT ("Experiment Id")); memoryUsage->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (hDataTotal->getUserExpId ())); memoryUsage->append (sb.toString ()); sb.sprintf (GTXT ("Process Id")); memoryUsage->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (hDataTotal->getPid ())); memoryUsage->append (sb.toString ()); Vector *pTimestamps; pTimestamps = hDataTotal->getPeakTimestamps (); if (pTimestamps != NULL) { for (int i = 0; i < pTimestamps->size (); i++) { sb.sprintf (GTXT ("Time of peak")); memoryUsage->append (sb.toString ()); sb.sprintf (NTXT ("%.3f (secs.)"), (double) (pTimestamps->fetch (i) / (double) NANOSEC)); memoryUsage->append (sb.toString ()); } } } if (hDataTotal->getAllocCnt () > 0) { if (hDataTotal->getA0KB1KBCnt () > 0) { sb.sprintf (GTXT ("0KB - 1KB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA0KB1KBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA1KB8KBCnt () > 0) { sb.sprintf (GTXT ("1KB - 8KB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA1KB8KBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA8KB32KBCnt () > 0) { sb.sprintf (GTXT ("8KB - 32KB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA8KB32KBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA32KB128KBCnt () > 0) { sb.sprintf (GTXT ("32KB - 128KB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA32KB128KBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA128KB256KBCnt () > 0) { sb.sprintf (GTXT ("128KB - 256KB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA128KB256KBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA256KB512KBCnt () > 0) { sb.sprintf (GTXT ("256KB - 512KB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA256KB512KBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA512KB1000KBCnt () > 0) { sb.sprintf (GTXT ("512KB - 1000KB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA512KB1000KBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA1000KB10MBCnt () > 0) { sb.sprintf (GTXT ("1000KB - 10MB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA1000KB10MBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA10MB100MBCnt () > 0) { sb.sprintf (GTXT ("10MB - 100MB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA10MB100MBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA100MB1GBCnt () > 0) { sb.sprintf (GTXT ("100MB - 1GB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA100MB1GBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA1GB10GBCnt () > 0) { sb.sprintf (GTXT ("1GB - 10GB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA1GB10GBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA10GB100GBCnt () > 0) { sb.sprintf (GTXT ("10GB - 100GB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA10GB100GBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA100GB1TBCnt () > 0) { sb.sprintf (GTXT ("100GB - 1TB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA100GB1TBCnt ()); allocStat->append (sb.toString ()); } if (hDataTotal->getA1TB10TBCnt () > 0) { sb.sprintf (GTXT ("1TB - 10TB")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getA1TB10TBCnt ()); allocStat->append (sb.toString ()); } sb.sprintf (GTXT ("Smallest allocation bytes")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (hDataTotal->getASmallestBytes ())); allocStat->append (sb.toString ()); sb.sprintf (GTXT ("Largest allocation bytes")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (hDataTotal->getALargestBytes ())); allocStat->append (sb.toString ()); sb.sprintf (GTXT ("Total allocations")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (hDataTotal->getAllocCnt ())); allocStat->append (sb.toString ()); sb.sprintf (GTXT ("Total bytes")); allocStat->append (sb.toString ()); sb.sprintf (NTXT ("%lld"), (long long) (hDataTotal->getAllocBytes ())); allocStat->append (sb.toString ()); } if (hDataTotal->getLeakCnt () > 0) { if (hDataTotal->getL0KB1KBCnt () > 0) { sb.sprintf (GTXT ("0KB - 1KB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL0KB1KBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL1KB8KBCnt () > 0) { sb.sprintf (GTXT ("1KB - 8KB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL1KB8KBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL8KB32KBCnt () > 0) { sb.sprintf (GTXT ("8KB - 32KB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL8KB32KBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL32KB128KBCnt () > 0) { sb.sprintf (GTXT ("32KB - 128KB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL32KB128KBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL128KB256KBCnt () > 0) { sb.sprintf (GTXT ("128KB - 256KB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL128KB256KBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL256KB512KBCnt () > 0) { sb.sprintf (GTXT ("256KB - 512KB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL256KB512KBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL512KB1000KBCnt () > 0) { sb.sprintf (GTXT ("512KB - 1000KB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL512KB1000KBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL1000KB10MBCnt () > 0) { sb.sprintf (GTXT ("1000KB - 10MB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL1000KB10MBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL10MB100MBCnt () > 0) { sb.sprintf (GTXT ("10MB - 100MB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL10MB100MBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL100MB1GBCnt () > 0) { sb.sprintf (GTXT ("100MB - 1GB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL100MB1GBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL1GB10GBCnt () > 0) { sb.sprintf (GTXT ("1GB - 10GB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL1GB10GBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL10GB100GBCnt () > 0) { sb.sprintf (GTXT ("10GB - 100GB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL10GB100GBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL100GB1TBCnt () > 0) { sb.sprintf (GTXT ("100GB - 1TB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL100GB1TBCnt ()); leakStat->append (sb.toString ()); } if (hDataTotal->getL1TB10TBCnt () > 0) { sb.sprintf (GTXT ("1TB - 10TB")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), hDataTotal->getL1TB10TBCnt ()); leakStat->append (sb.toString ()); } sb.sprintf (GTXT ("Smallest leaked bytes")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (hDataTotal->getLSmallestBytes ())); leakStat->append (sb.toString ()); sb.sprintf (GTXT ("Largest leaked bytes")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (hDataTotal->getLLargestBytes ())); leakStat->append (sb.toString ()); sb.sprintf (GTXT ("Total leaked")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%d"), (int) (hDataTotal->getLeakCnt ())); leakStat->append (sb.toString ()); sb.sprintf (GTXT ("Total bytes")); leakStat->append (sb.toString ()); sb.sprintf (NTXT ("%lld"), (long long) (hDataTotal->getLeakBytes ())); leakStat->append (sb.toString ()); } Vector*>* statisticsData = new Vector*>(3); statisticsData->store (0, memoryUsage); statisticsData->store (1, allocStat); statisticsData->store (2, leakStat); return statisticsData; } Vector * dbeGetFuncNames (int dbevindex, Vector *funcs) { int len = funcs->size (); Vector *list = new Vector(len); for (int i = 0; i < len; i++) list->store (i, dbeGetFuncName (dbevindex, funcs->fetch (i))); // no strdup() return list; } Vector * dbeGetObjNamesV2 (int dbevindex, Vector *ids) { int len = ids->size (); Vector *list = new Vector(len); for (int i = 0; i < len; i++) list->store (i, dbeGetObjNameV2 (dbevindex, ids->fetch (i))); // no strdup() return list; } char * dbeGetFuncName (int dbevindex, Obj func) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); if (func == 0) return NULL; char *fname; fname = ((Histable *) func)->get_name (dbev->get_name_format ()); return fname ? dbe_strdup (fname) : NULL; } Vector * dbeGetFuncIds (int dbevindex, Vector *funcs) { int len = funcs->size (); Vector *list = new Vector(len); for (int i = 0; i < len; i++) list->store (i, dbeGetFuncId (dbevindex, funcs->fetch (i))); return list; } uint64_t dbeGetFuncId (int dbevindex, Obj func) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); if (func == 0) return 0; uint64_t id = ((Histable *) func)->id; return id; } char * dbeGetObjNameV2 (int dbevindex, uint64_t id) { DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Histable *obj = dbeSession->findObjectById (id); if (obj == NULL) return NULL; char *fname = obj->get_name (dbev->get_name_format ()); return fname ? dbe_strdup (fname) : NULL; } char * dbeGetDataspaceTypeDesc (int /*dbevindex*/, Obj stack) { if (stack == 0) return NULL; Histable *hist = CallStack::getStackPC ((void *) stack, 0); DbeInstr *instr; Histable::Type type = hist->get_type (); if (type != Histable::INSTR) return NULL; else instr = (DbeInstr *) hist; char *descriptor = instr->get_descriptor (); return descriptor ? dbe_strdup (descriptor) : NULL; } Vector * dbeGetDataDescriptorsV2 (int exp_id) { Experiment *exp = dbeSession->get_exp (exp_id); if (exp == NULL) return NULL; Vector *dataId = new Vector; Vector *dataName = new Vector; Vector *dataUName = new Vector; Vector *auxProp = new Vector; Vector *ddscr = exp->getDataDescriptors (); for (int i = 0; i < ddscr->size (); i++) { DataDescriptor *dataDscr = ddscr->fetch (i); if (dataDscr->getFlags () & DDFLAG_NOSHOW) continue; int data_id = dataDscr->getId (); int aux_prop_id = (data_id == DATA_HWC) ? PROP_HWCTAG : PROP_NONE; dataId->append (data_id); dataName->append (xstrdup (dataDscr->getName ())); dataUName->append (xstrdup (dataDscr->getUName ())); auxProp->append (aux_prop_id); } delete ddscr; Vector *res = new Vector(3); res->store (0, dataId); res->store (1, dataName); res->store (2, dataUName); res->store (3, auxProp); return res; } Vector * dbeGetDataPropertiesV2 (int exp_id, int data_id) { Experiment *exp = dbeSession->get_exp (exp_id); if (exp == NULL) return NULL; DataDescriptor *dataDscr = exp->get_raw_events (data_id); if (dataDscr == NULL) return NULL; Vector *props = dataDscr->getProps (); Vector *propId = new Vector(props->size ()); Vector *propUName = new Vector(props->size ()); Vector *propTypeId = new Vector(props->size ()); Vector *propTypeName = new Vector(props->size ()); Vector *propFlags = new Vector(props->size ()); Vector *propName = new Vector(props->size ()); Vector *propStateNames = new Vector(props->size ()); Vector *propStateUNames = new Vector(props->size ()); for (int i = 0; i < props->size (); i++) { PropDescr *prop = props->fetch (i); char *pname = prop->name; if (pname == NULL) pname = NTXT (""); char *uname = prop->uname; if (uname == NULL) uname = pname; int vtypeNum = prop->vtype; if (vtypeNum < 0 || vtypeNum >= TYPE_LAST) vtypeNum = TYPE_NONE; const char * vtypeNames[] = VTYPE_TYPE_NAMES; const char *vtype = vtypeNames[prop->vtype]; Vector *stateNames = NULL; Vector *stateUNames = NULL; int nStates = prop->getMaxState (); if (nStates > 0) { stateNames = new Vector(nStates); stateUNames = new Vector(nStates); for (int kk = 0; kk < nStates; kk++) { const char * stateName = prop->getStateName (kk); stateNames->store (kk, dbe_strdup (stateName)); const char * Uname = prop->getStateUName (kk); stateUNames->store (kk, dbe_strdup (Uname)); } } propId->store (i, prop->propID); propUName->store (i, dbe_strdup (uname)); propTypeId->store (i, prop->vtype); propTypeName->store (i, dbe_strdup (vtype)); propFlags->store (i, prop->flags); propName->store (i, dbe_strdup (pname)); propStateNames->store (i, stateNames); propStateUNames->store (i, stateUNames); } Vector *res = new Vector(7); res->store (0, propId); res->store (1, propUName); res->store (2, propTypeId); res->store (3, propTypeName); res->store (4, propFlags); res->store (5, propName); res->store (6, propStateNames); res->store (7, propStateUNames); return res; } Vector * dbeGetExperimentTimeInfo (Vector *exp_ids) { int sz = exp_ids->size (); Vector *offset_time = new Vector (sz); Vector *start_time = new Vector (sz); Vector *end_time = new Vector (sz); Vector *start_wall_sec = new Vector (sz); Vector *hostname = new Vector (sz); Vector *cpu_freq = new Vector (sz); for (int ii = 0; ii < sz; ii++) { int expIdx = exp_ids->fetch (ii); { // update end_time by forcing fetch of experiment data // workaround until dbeGetEndTime() is more robust int id = (expIdx < 0) ? 0 : expIdx; Experiment *exp = dbeSession->get_exp (id); if (exp) { Vector *ddscr = exp->getDataDescriptors (); delete ddscr; } } offset_time->store (ii, dbeGetRelativeStartTime (0, expIdx)); start_time->store (ii, dbeGetStartTime (0, expIdx)); end_time->store (ii, dbeGetEndTime (0, expIdx)); start_wall_sec->store (ii, dbeGetWallStartSec (0, expIdx)); hostname->store (ii, dbeGetHostname (0, expIdx)); cpu_freq->store (ii, dbeGetClock (0, expIdx)); } Vector *res = new Vector(4); res->store (0, offset_time); res->store (1, start_time); res->store (2, end_time); res->store (3, start_wall_sec); res->store (4, hostname); res->store (5, cpu_freq); return res; } Vector * dbeGetExperimentDataDescriptors (Vector *exp_ids) { int sz = exp_ids->size (); Vector *exp_dscr_info = new Vector (sz); Vector *exp_dscr_props = new Vector (sz); for (int ii = 0; ii < sz; ii++) { int expIdx = exp_ids->fetch (ii); Vector *ddscrInfo = dbeGetDataDescriptorsV2 (expIdx); Vector *ddscrProps = new Vector (); // one entry per ddscrInfo if (ddscrInfo) { Vector *dataId = (Vector*)ddscrInfo->fetch (0); if (dataId) { // loop thru data descriptors int ndata = dataId->size (); for (int j = 0; j < ndata; ++j) { Vector *props = dbeGetDataPropertiesV2 (expIdx, dataId->fetch (j)); ddscrProps->store (j, props); } } } exp_dscr_info->store (ii, ddscrInfo); exp_dscr_props->store (ii, ddscrProps); } Vector *res = new Vector(2); res->store (0, exp_dscr_info); res->store (1, exp_dscr_props); return res; } static Vector * dbeGetTLDataRepVals (VMode view_mode, hrtime_t start_ts, hrtime_t delta, int numDeltas, DataView*packets, Vector *representativeEvents, bool showDuration); static bool dbeHasTLData (int dbevindex, int exp_id, int data_id, int entity_prop_id, int entity_prop_value, int aux) { DataView *packets = getTimelinePackets (dbevindex, exp_id, data_id, entity_prop_id); if (!packets || packets->getSize () == 0) return false; long start_ind = getIdxByVals (packets, aux, entity_prop_value, 0, DataView::REL_GTEQ); // time >= 0 if (start_ind < 0) return false; DbeView *dbev = dbeSession->getView (dbevindex); VMode view_mode = dbev->get_view_mode (); Experiment *exp = dbeSession->get_exp (exp_id); if (!hasInvisbleTLEvents (exp, view_mode)) return true; // all events are visible, no further checking required long end_ind = getIdxByVals (packets, aux, entity_prop_value, MAX_TIME, DataView::REL_LTEQ); for (long ii = start_ind; ii <= end_ind; ii++) { if (!isVisibleTLEvent (exp, view_mode, packets, ii)) continue; return true; // first visible packet => has data } return false; } Vector * dbeHasTLData (int dbev_index, Vector *exp_ids, Vector *data_ids, Vector *entity_prop_ids, // LWP,CPU,THR, etc Vector *entity_prop_values, Vector *auxs) { DbeView *dbev = dbeSession->getView (dbev_index); if (!dbev->isShowAll () && (dbev->isShowHideChanged () || dbev->isNewViewMode ())) { // LIBRARY_VISIBILITY dbev->resetAndConstructShowHideStacks (); if (dbev->isNewViewMode ()) dbev->resetNewViewMode (); if (dbev->isShowHideChanged ()) dbev->resetShowHideChanged (); } int sz = exp_ids->size (); Vector *hasVec = new Vector(sz); for (int ii = 0; ii < sz; ii++) { bool hasData = dbeHasTLData (dbev_index, exp_ids->fetch (ii), data_ids->fetch (ii), entity_prop_ids->fetch (ii), entity_prop_values->fetch (ii), auxs->fetch (ii)); hasVec->store (ii, hasData); } return hasVec; } /* * dbeGetTLData implements: * FROM data_id * DURATION >= delta AND ( start_ts <= TSTAMP < start_ts+num*delta OR * start_ts <= TSTAMP-DURATION < start_ts+num*delta ) * OR * FAIR( DURATION < delta AND ( start_ts <= TSTAMP < start_ts+num*delta ) ) * WHERE lfilter */ Vector * dbeGetTLData ( int dbevindex, int exp_id, int data_id, // DATA_* int entity_prop_id, // Show PROP_LWPID, PROP_CPUID, PROP_THRID, PROP_EXPID, or N/A int entity_prop_value, // which LWPID, CPUID, THRID, EXPID for this request int aux, hrtime_t param_start_ts, hrtime_t param_delta, int param_numDeltas, bool getRepresentatives, // fetch TL representatives Vector *chartProps) // calculate sums for these property vals { const hrtime_t start_ts = param_start_ts; const hrtime_t delta = param_delta; const int numDeltas = param_numDeltas; DbeView *dbev = dbeSession->getView (dbevindex); if (dbev == NULL) abort (); Experiment *exp = dbeSession->get_exp (exp_id); if (exp == NULL) return NULL; if (getRepresentatives == false && chartProps == NULL) return NULL; if (delta <= 0) return NULL; hrtime_t tmp_ts = start_ts + delta * numDeltas; if (tmp_ts < start_ts) tmp_ts = MAX_TIME; const hrtime_t end_ts = tmp_ts; if (exp->get_status () == Experiment::INCOMPLETE && exp->getLastEvent () < end_ts) exp->update (); DataView *packets = getTimelinePackets (dbevindex, exp_id, data_id, entity_prop_id); if (packets == NULL) return NULL; // strange, no data view? VMode view_mode = dbev->get_view_mode (); // user, expert, machine //YXXX yuck // storage for calculating timeline representative events Vector *representativeEvents = NULL; // list of representative events to be displayed on TL Vector *binRepIdx = NULL; // for each bin, index of current "best" representativeEvent Vector *representativeVals = NULL; // TL representative packets' values // storage for calculating charts Vector *propIds = NULL; // [propIdx], which prop to measure Vector *propVals = NULL; // [propIdx][bin], prop vals Vector *propNumStates = NULL; // [propIdx], how many states for prop? Vector *propCumulativeChart = NULL; // [propIdx], data represents cumulative totals Vector *propCumulativeRecentBinLastVal = NULL; // [propIdx], most recent value Vector *propCumulativeRecentBinHighVal = NULL; // [propIdx], highest value for propCumulativeRecentBin Vector *propCumulativeRecentBin = NULL; // [propIdx], most recent bin // determine when to show duration of events bool tmp_repsShowDuration = false; bool tmp_statesUseDuration = false; bool tmp_extendMicrostates = false; const hrtime_t ptimerTickDuration = exp->get_params ()->ptimer_usec * 1000LL; // nanoseconds per tick const bool hasDuration = packets->getProp (PROP_EVT_TIME) ? true : false; if (hasDuration) { switch (entity_prop_id) { case PROP_CPUID: tmp_repsShowDuration = false; tmp_statesUseDuration = false; break; case PROP_THRID: case PROP_LWPID: tmp_repsShowDuration = true; tmp_statesUseDuration = true; tmp_extendMicrostates = (DATA_CLOCK == data_id) && (ptimerTickDuration < param_delta); break; case PROP_EXPID: case PROP_NONE: // experiment summary row uses this default: if (DATA_SAMPLE == data_id) { tmp_repsShowDuration = true; tmp_statesUseDuration = true; } else if (DATA_GCEVENT == data_id) { tmp_repsShowDuration = true; tmp_statesUseDuration = true; } else if (DATA_CLOCK == data_id) { tmp_repsShowDuration = false; tmp_statesUseDuration = true; tmp_extendMicrostates = true; } else { tmp_repsShowDuration = false; tmp_statesUseDuration = true; } break; } } const bool repsShowDuration = tmp_repsShowDuration; // show stretched callstacks const bool statesUseDuration = tmp_statesUseDuration; // use duration to calculate state charts const bool extendMicrostates = tmp_extendMicrostates; // we show discrete profiling microstates with // width=(tick-1), but for computing // zoomed-out graphs we need to extend to // account for all ticks, width=(ntick) const bool reverseScan = repsShowDuration || extendMicrostates; // scan packets in reverse // determine range of packet indices (lo_pkt_idx, hi_pkt_idx) long lo_pkt_idx, hi_pkt_idx; if (extendMicrostates && !(entity_prop_id == PROP_THRID || entity_prop_id == PROP_LWPID)) { // merging data from multiple threads, need to scan all packets with timestamp [start_ts, exp end] hrtime_t exp_end_time = exp->getLastEvent () + 1; hi_pkt_idx = getIdxByVals (packets, aux, entity_prop_value, exp_end_time, DataView::REL_LT); // last item } else hi_pkt_idx = getIdxByVals (packets, aux, entity_prop_value, end_ts, DataView::REL_LT); if (repsShowDuration) { // There are two issues to deal with // 1. events that end "off screen" to the right // 2. overlapping events // 1. events that end "off screen" to the right // For now, we only consistently handle the case where events don't overlap. // Note that packet timestamps mark end of duration, not start. // This means that the rightmost event won't be within hi_pkt_idx. // Solution: Check if end+1 packet _started_ in-range // Caveat: because we only look ahead by one packet, if there are // overlapping duration events (e.g. EXPID aggregation)), zoom level // and panning combo may cause events with TSTAMP>end_ts // to appear/disappear. A complete solution would involve // a solution to 2. // 2. overlapping events // For now, we have a simplistic solution that makes "wide" events win. However, // a future solution for deterministically dealing with overlap might look like this: // - find all packets that touch the visible time range // - possibly use two DataViews: one with TSTAMP_HI sort and one with TSTAMP_LO // sort to allow efficient determination of packets with HI and LO endpoints in-range // - create buckets to capture "winning" event for each bin (each pixel, that is) // - sort the new list of packets by TSTAMP_HI (for example) // - looping thru the packets that are in-range, update every bin it touches with it's id // - if there is overlap, earlier packets will be kicked out of bins // - On the GUI side, paint one event at a time, as normal. // - However, for selections, recognize that duration of event may span many bins // long idx; if (hi_pkt_idx >= 0) // a packet was found to the left of the end time idx = hi_pkt_idx + 1; // attempt to go one packet right else idx = getIdxByVals (packets, aux, entity_prop_value, end_ts, DataView::REL_GTEQ); if (isValidIdx (packets, entity_prop_id, aux, entity_prop_value, idx)) { int64_t pkt_ts = packets->getLongValue (PROP_TSTAMP, idx); int64_t duration = packets->getLongValue (PROP_EVT_TIME, idx); pkt_ts -= duration; if (pkt_ts < end_ts) hi_pkt_idx = idx; } } lo_pkt_idx = getIdxByVals (packets, aux, entity_prop_value, start_ts, DataView::REL_GTEQ); // allocate structs that return chart data bool hasCumulativeCharts = false; if (chartProps && chartProps->size () > 0) { int nprops = chartProps->size (); // pre-allocate storage propIds = new Vector (nprops); propVals = new Vector(nprops); propNumStates = new Vector (nprops); propCumulativeChart = new Vector(nprops); propCumulativeRecentBinLastVal = new Vector(nprops); propCumulativeRecentBinHighVal = new Vector(nprops); propCumulativeRecentBin = new Vector(nprops); for (int propNum = 0; propNum < nprops; propNum++) { const char* propStr = chartProps->fetch (propNum); int items_per_prop = 0; int prop_id = PROP_NONE; if (!strcmp (propStr, "EVT_COUNT")) items_per_prop = 1; // use PROP_NONE for counting packets else { int lookup_prop_id = dbeSession->getPropIdByName (propStr); PropDescr *propDscr = packets->getProp (lookup_prop_id); if (propDscr != NULL) { switch (propDscr->vtype) { case TYPE_INT32: case TYPE_UINT32: case TYPE_INT64: case TYPE_UINT64: items_per_prop = propDscr->getMaxState () + 1; // add extra slot to store values with out-of-range idx prop_id = lookup_prop_id; break; case TYPE_DOUBLE: break; // not implemented yet case TYPE_STRING: case TYPE_OBJ: case TYPE_DATE: default: break; } } } void *vals; if (!items_per_prop) vals = NULL; else if (items_per_prop == 1) { Vector *longVals = new Vector (); longVals->store (numDeltas - 1, 0); // initialize all elements vals = longVals; } else { Vector*> *stateVals = new Vector*> (); vals = stateVals; // initialize only on-demand, some may not be needed } bool isCumulativeChart; #define YXXX_HEAP_VS_TIME 1 // YXXX add data meaning to properties? #if YXXX_HEAP_VS_TIME isCumulativeChart = (prop_id == PROP_HCUR_LEAKS || prop_id == PROP_HCUR_ALLOCS); #endif if (isCumulativeChart) hasCumulativeCharts = true; propIds->store (propNum, prop_id); propVals->store (propNum, vals); propNumStates->store (propNum, items_per_prop); propCumulativeRecentBinLastVal->store (propNum, 0); propCumulativeRecentBinHighVal->store (propNum, 0); propCumulativeRecentBin->store (propNum, 0); propCumulativeChart->store (propNum, isCumulativeChart); } } // Adjust idx range for calculating 'cumulative charts' e.g. heap size if (hasCumulativeCharts) { // set initial values if earlier packet exists long lo_idx; if (lo_pkt_idx >= 0) // packet was found to the right of start lo_idx = lo_pkt_idx - 1; // attempt to go left by one event else // no packet was to the right of start, look left of start lo_idx = getIdxByVals (packets, aux, entity_prop_value, start_ts, DataView::REL_LT); if (isValidIdx (packets, entity_prop_id, aux, entity_prop_value, lo_idx)) { // preceding packet found // update initial values int nprops = propCumulativeChart->size (); for (int propNum = 0; propNum < nprops; propNum++) { if (!propCumulativeChart->fetch (propNum)) continue; int propId = propIds->fetch (propNum); long long value = packets->getLongValue (propId, lo_idx); propCumulativeRecentBinLastVal->store (propNum, value); propCumulativeRecentBinHighVal->store (propNum, value); } // update indices used for iterating lo_pkt_idx = lo_idx; if (hi_pkt_idx < lo_pkt_idx) hi_pkt_idx = lo_pkt_idx; } } if (lo_pkt_idx < 0 || hi_pkt_idx < 0) goto dbeGetTLData_done; // no data; return empty vectors, not null // representative events (subset of callstacks to represent on TL) if (getRepresentatives) { representativeEvents = new Vector(numDeltas); // per-bin, longest event's index binRepIdx = new Vector(numDeltas); for (int ii = 0; ii < numDeltas; ++ii) binRepIdx->append (-1); } // While packets are sorted by _end_ timestamp (TSTAMP), // after calculating start times for non-zero durations, // start times are not guaranteed be monotonically increasing. // For packets with duration, we'll scan them in reverse order to // take advantage of the monotonically decreasing _end_ timestamps. long start_idx, idx_inc; if (!reverseScan) { start_idx = lo_pkt_idx; idx_inc = 1; } else { start_idx = hi_pkt_idx; idx_inc = -1; } for (long ii = start_idx; ii >= lo_pkt_idx && ii <= hi_pkt_idx; ii += idx_inc) { if (!isVisibleTLEvent (exp, view_mode, packets, ii) && !hasCumulativeCharts) continue; // determine packet time duration and start bin int tmp_start_bin; // packet start bin int tmp_end_bin; // packet end bin (inclusive) const hrtime_t pkt_end_ts = packets->getLongValue (PROP_TSTAMP, ii); const hrtime_t pkt_dur = packets->getLongValue (PROP_EVT_TIME, ii); const hrtime_t pkt_start_ts = pkt_end_ts - pkt_dur; if (pkt_end_ts < start_ts && !hasCumulativeCharts) continue; // weird, should not happen if (pkt_start_ts >= end_ts) continue; // could happen hrtime_t bin_end_ts = pkt_end_ts; if (bin_end_ts >= end_ts) bin_end_ts = end_ts - 1; tmp_end_bin = (int) ((bin_end_ts - start_ts) / delta); hrtime_t bin_start_ts = pkt_start_ts; if (bin_start_ts < start_ts) bin_start_ts = start_ts; // event truncated to left. tmp_start_bin = (int) ((bin_start_ts - start_ts) / delta); // By definition // (end_ts - start_ts) == delta * numDeltas // and we know // pkt_start < end_ts // therefore // (pkt_start - start_ts) < delta * numDeltas // (pkt_start - start_ts) / delta < numDeltas // bin < numDeltas assert (tmp_end_bin < numDeltas); assert (tmp_start_bin < numDeltas); const bool is_offscreen = tmp_end_bin < 0 ? true : false; if (tmp_end_bin < 0) tmp_end_bin = 0; const int pkt_end_bin = tmp_end_bin; // packet end bin (inclusive) const int pkt_start_bin = tmp_start_bin; if (getRepresentatives && !is_offscreen) { // find best representative // Note: for events with duration, we're scanning packets in order // of decreasing end-timestamp. This means that the first packet // that hits a particular _start_ bin will have the longest duration // of any later packet that might hit that start bin. The // the first packet will be the best (longest) packet. const int bin = reverseScan ? pkt_start_bin : pkt_end_bin; int eventIdx = binRepIdx->fetch (bin); if (eventIdx == -1) { eventIdx = representativeEvents->size (); // append to end representativeEvents->append (ii); binRepIdx->store (bin, eventIdx); } } if (propIds) { // per-bin chart: sum across filtered packets for (int propNum = 0; propNum < propIds->size (); propNum++) { void *thisProp = propVals->fetch (propNum); if (thisProp == NULL) continue; // no valid data if (is_offscreen && !propCumulativeChart->fetch (propNum)) continue; // offscreen events are only processed for cumulative charts int propId = propIds->fetch (propNum); long long val; if (propId == PROP_NONE) val = 1; // count else val = packets->getLongValue (propId, ii); long nitems = propNumStates->fetch (propNum); if (nitems < 1) continue; else if (nitems == 1) { // chart is not based on not multiple states Vector* thisPropVals = (Vector*)thisProp; if (thisPropVals->size () == 0) thisPropVals->store (numDeltas - 1, 0); const int bin = statesUseDuration ? pkt_start_bin : pkt_end_bin; if (!propCumulativeChart->fetch (propNum)) { val += thisPropVals->fetch (bin); thisPropVals->store (bin, val); } else { // propCumulativeChart long long high_value = propCumulativeRecentBinHighVal->fetch (propNum); int last_bin = propCumulativeRecentBin->fetch (propNum); if (last_bin < bin) { // backfill from previous event // last_bin: store largest value (in case of multiple events) thisPropVals->store (last_bin, high_value); // propagate forward the bin's last value long long last_value = propCumulativeRecentBinLastVal->fetch (propNum); for (int kk = last_bin + 1; kk < bin; kk++) thisPropVals->store (kk, last_value); // prepare new bin for current event high_value = 0; // high value of next bin is 0. propCumulativeRecentBinHighVal->store (propNum, high_value); propCumulativeRecentBin->store (propNum, bin); } long long this_value = packets->getLongValue (propId, ii); propCumulativeRecentBinLastVal->store (propNum, this_value); if (high_value < this_value) { // record the max high_value = this_value; propCumulativeRecentBinHighVal->store (propNum, high_value); } if (ii == hi_pkt_idx) { // bin: show largest value (in case of multiple events thisPropVals->store (bin, high_value); //forward fill remaining bins for (int kk = bin + 1; kk < numDeltas; kk++) thisPropVals->store (kk, this_value); } } } else { // means val is actually a state # Vector*>* thisPropStateVals = (Vector*>*)thisProp; if (thisPropStateVals->size () == 0) thisPropStateVals->store (numDeltas - 1, 0); long stateNum; if (val >= 0 && val < nitems) stateNum = (long) val; else stateNum = nitems - 1; // out of range, use last slot hrtime_t graph_pkt_dur = pkt_dur; hrtime_t graph_pkt_start_ts = pkt_start_ts; int tmp2_start_bin = pkt_start_bin; if (propId == PROP_MSTATE) { if (statesUseDuration && extendMicrostates) { // microstate stacks are shown and filtered with width=NTICK-1 // but for microstate graph calcs use width=NTICK. graph_pkt_dur += ptimerTickDuration; graph_pkt_start_ts -= ptimerTickDuration; hrtime_t bin_start_ts = graph_pkt_start_ts; if (bin_start_ts < start_ts) bin_start_ts = start_ts; // event truncated to left. tmp2_start_bin = (int) ((bin_start_ts - start_ts) / delta); } } const int graph_pkt_start_bin = statesUseDuration ? tmp2_start_bin : pkt_end_bin; // We will distribute the state's presence evenly over duration of the event. // When only a 'partial bin' is touched by an event, adjust accordingly. long long value_per_bin; // weight to be applied to each bin { long long weight; if (propId == PROP_MSTATE) // ticks to nanoseconds weight = packets->getLongValue (PROP_NTICK, ii) * ptimerTickDuration; else if (graph_pkt_dur) weight = graph_pkt_dur; // nanoseconds else weight = 1; // no duration; indicate presence if (graph_pkt_start_bin != pkt_end_bin) { // spans multiple bins double nbins = (double) graph_pkt_dur / delta; value_per_bin = weight / nbins; } else value_per_bin = weight; } for (int evtbin = graph_pkt_start_bin; evtbin <= pkt_end_bin; evtbin++) { Vector* stateValues = (Vector*) thisPropStateVals->fetch (evtbin); if (stateValues == NULL) { // on-demand storage stateValues = new Vector(nitems); stateValues->store (nitems - 1, 0); // force memset of full vector thisPropStateVals->store (evtbin, stateValues); } long long new_val = stateValues->fetch (stateNum); if (graph_pkt_start_bin == pkt_end_bin || (evtbin > graph_pkt_start_bin && evtbin < pkt_end_bin)) { new_val += value_per_bin; } else { // partial bin const hrtime_t bin_start = start_ts + evtbin * delta; const hrtime_t bin_end = start_ts + (evtbin + 1) * delta - 1; if (evtbin == graph_pkt_start_bin) { // leftmost bin if (graph_pkt_start_ts < bin_start) new_val += value_per_bin; else { double percent = (double) (bin_end - graph_pkt_start_ts) / delta; new_val += value_per_bin*percent; } } else { // rightmost bin if (pkt_end_ts > bin_end) new_val += value_per_bin; else { double percent = (double) (pkt_end_ts - bin_start) / delta; new_val += value_per_bin*percent; } } } stateValues->store (stateNum, new_val); } } } } } delete binRepIdx; delete propIds; delete propCumulativeChart; delete propCumulativeRecentBinLastVal; delete propCumulativeRecentBinHighVal; delete propCumulativeRecentBin; if (representativeEvents != NULL && reverseScan) { if (repsShowDuration) { //YXXX for now prune here, but in the future, let gui decide what to show // Prune events that are completely obscured long duration events. // Note: representativeEvents is sorted by decreasing _end_ timestamps. Vector *prunedEvents = new Vector(numDeltas); hrtime_t prev_start_ts = MAX_TIME; long repCnt = representativeEvents->size (); for (long kk = 0; kk < repCnt; kk++) { long ii = representativeEvents->fetch (kk); hrtime_t tmp_end_ts = packets->getLongValue (PROP_TSTAMP, ii); hrtime_t tmp_dur = packets->getLongValue (PROP_EVT_TIME, ii); hrtime_t tmp_start_ts = tmp_end_ts - tmp_dur; if (tmp_start_ts >= prev_start_ts) // this event would be completely hidden // (because of sorting, we know tmp_end_ts <= prev_end_ts) continue; prev_start_ts = tmp_start_ts; prunedEvents->append (ii); } // invert order to to get increasing _end_ timestamps representativeEvents->reset (); for (long kk = prunedEvents->size () - 1; kk >= 0; kk--) { long packet_idx = prunedEvents->fetch (kk); representativeEvents->append (packet_idx); } delete prunedEvents; } else { // !repsShowDuration // Note: representativeEvents is sorted by decreasing _end_ timestamps. // Reverse the order: long hi_idx = representativeEvents->size () - 1; long lo_idx = 0; while (hi_idx > lo_idx) { // swap long lo = representativeEvents->fetch (lo_idx); long hi = representativeEvents->fetch (hi_idx); representativeEvents->store (lo_idx, hi); representativeEvents->store (hi_idx, lo); hi_idx--; lo_idx++; } } } dbeGetTLData_done: if (getRepresentatives) { representativeVals = dbeGetTLDataRepVals (view_mode, start_ts, delta, numDeltas, packets, representativeEvents, repsShowDuration); delete representativeEvents; } Vector *results = new Vector (2); results->store (0, representativeVals); results->store (1, propVals); return results; } // add representative events to return buffer static Vector * dbeGetTLDataRepVals (VMode view_mode, hrtime_t start_ts, hrtime_t delta, int numDeltas, DataView*packets, Vector *representativeEvents, bool showDuration) { int numrecs = representativeEvents ? representativeEvents->size () : 0; // allocate storage for results Vector *startBins = new Vector(numrecs); Vector *numBins = new Vector(numrecs); Vector *eventIdxs = new Vector(numrecs); Vector *stackIds = NULL; if (packets->getProp (PROP_FRINFO)) stackIds = new Vector(numrecs); Vector *mstates = NULL; if (packets->getProp (PROP_MSTATE)) mstates = new Vector(numrecs); Vector*> *sampleVals = NULL; if (packets->getProp (PROP_SMPLOBJ)) sampleVals = new Vector*>(numrecs); Vector *timeStart = new Vector(numrecs); Vector *timeEnd = new Vector(numrecs); int prevEndBin = -1; // make sure we don't overlap bins for (int eventIdx = 0; eventIdx < numrecs; eventIdx++) { long packetIdx = representativeEvents->fetch (eventIdx); // long eventId = packets->getIdByIdx( packetIdx ); const hrtime_t pkt_tstamp = packets->getLongValue (PROP_TSTAMP, packetIdx); const hrtime_t pkt_dur = showDuration ? packets->getLongValue (PROP_EVT_TIME, packetIdx) : 0; timeStart->store (eventIdx, pkt_tstamp - pkt_dur); timeEnd->store (eventIdx, pkt_tstamp); // calc startBin int startBin = (int) ((pkt_tstamp - pkt_dur - start_ts) / delta); if (startBin <= prevEndBin) startBin = prevEndBin + 1; // calc binCnt int endBin = (int) ((pkt_tstamp - start_ts) / delta); if (endBin >= numDeltas) endBin = numDeltas - 1; int binCnt = endBin - startBin + 1; prevEndBin = endBin; startBins->store (eventIdx, startBin); numBins->store (eventIdx, binCnt); eventIdxs->store (eventIdx, packetIdx); // store packet's idx if (stackIds != NULL) { void* stackId = getStack (view_mode, packets, packetIdx); stackIds->store (eventIdx, (Obj) (unsigned long) stackId); } if (mstates != NULL) { int mstate = packets->getIntValue (PROP_MSTATE, packetIdx); mstates->store (eventIdx, mstate); } if (sampleVals != NULL) { Sample *sample = (Sample*) packets->getObjValue (PROP_SMPLOBJ, packetIdx); if (sample != NULL) { PrUsage *prusage = sample->get_usage (); if (prusage != NULL) sampleVals->store (eventIdx, prusage->getMstateValues ()); } } } // caller responsible for: delete representativeEvents; Vector *results = new Vector (8); results->store (0, startBins); results->store (1, numBins); results->store (2, eventIdxs); results->store (3, stackIds); results->store (4, mstates); results->store (5, sampleVals); results->store (6, timeStart); results->store (7, timeEnd); return results; } // starting from packet idx, step visible events // return the resulting idx and that packet's center time, or null if no event. Vector * dbeGetTLEventCenterTime (int dbevindex, int exp_id, int data_id, int entity_prop_id, int entity_prop_val, int aux, long long event_id, long long move_count) { DataView *packets = getTimelinePackets (dbevindex, exp_id, data_id, entity_prop_id); if (packets == NULL) return NULL; long idx = (long) event_id; DbeView *dbev = dbeSession->getView (dbevindex); VMode view_mode = dbev->get_view_mode (); Experiment *exp = dbeSession->get_exp (exp_id); int direction; if (move_count == 0) direction = 0; else if (move_count < 0) { move_count = -move_count; direction = -1; } else direction = 1; idx = getTLVisibleIdxByStepping (exp, view_mode, entity_prop_id, packets, aux, entity_prop_val, idx, move_count, direction); if (idx >= 0) { long long ts = packets->getLongValue (PROP_TSTAMP, idx); long long dur = packets->getLongValue (PROP_EVT_TIME, idx); long long center = ts - dur / 2; Vector *results = new Vector (2); results->store (0, idx); // result idx results->store (1, center); // result timestamp return results; } return NULL; } long long dbeGetTLEventIdxNearTime (int dbevindex, int exp_id, int data_id, int entity_prop_id, int entity_prop_val, int aux, int searchDirection, long long tstamp) { DataView *packets = getTimelinePackets (dbevindex, exp_id, data_id, entity_prop_id); if (packets == NULL) return -1; DbeView *dbev = dbeSession->getView (dbevindex); VMode view_mode = dbev->get_view_mode (); Experiment *exp = dbeSession->get_exp (exp_id); if (searchDirection < 0) { int idx = getTLVisibleIdxByVals (exp, view_mode, entity_prop_id, packets, aux, entity_prop_val, tstamp, DataView::REL_LTEQ); if (idx != -1) return idx; searchDirection = 1; // couldn't find to left, try to right } if (searchDirection > 0) { int idx = getTLVisibleIdxByVals (exp, view_mode, entity_prop_id, packets, aux, entity_prop_val, tstamp, DataView::REL_GTEQ); if (idx != -1) return idx; // couldn't find to right, fall through to generic } // search left and right of timestamp long idx1, idx2; idx1 = getTLVisibleIdxByVals (exp, view_mode, entity_prop_id, packets, aux, entity_prop_val, tstamp, DataView::REL_LT); idx2 = getTLVisibleIdxByVals (exp, view_mode, entity_prop_id, packets, aux, entity_prop_val, tstamp, DataView::REL_GTEQ); if (idx1 == -1) return idx2; else if (idx2 == -1) return idx1; // both valid, so need to compare to see which is closer long long t1 = packets->getLongValue (PROP_TSTAMP, idx1); long long t2 = packets->getLongValue (PROP_TSTAMP, idx2); long long t2dur = packets->getLongValue (PROP_EVT_TIME, idx2); long long delta1 = tstamp - t1; // should always be positive long long delta2 = (t2 - t2dur) - tstamp; // if negative, overlaps idx1 if (delta1 > delta2) return idx2; else return idx1; } enum Aggr_type { AGGR_NONE, AGGR_FAIR, AGGR_MAX, AGGR_MIN, AGGR_CNT, AGGR_SUM, AGGR_AVG }; static Aggr_type getAggrFunc (char *aname) { Aggr_type agrfn = AGGR_NONE; if (aname == NULL) return agrfn; if (strcmp (aname, NTXT ("FAIR")) == 0) agrfn = AGGR_FAIR; else if (strcmp (aname, NTXT ("MAX")) == 0) agrfn = AGGR_MAX; else if (strcmp (aname, NTXT ("MIN")) == 0) agrfn = AGGR_MIN; else if (strcmp (aname, NTXT ("CNT")) == 0) agrfn = AGGR_CNT; else if (strcmp (aname, NTXT ("SUM")) == 0) agrfn = AGGR_SUM; else if (strcmp (aname, NTXT ("AVG")) == 0) agrfn = AGGR_AVG; return agrfn; } static long long computeAggrVal (DefaultMap *fval_map, Aggr_type agrfn) { long long aval = 0; long cnt = 0; Vector *fvals = fval_map->values (); long nvals = fvals->size (); for (int i = 0; i < nvals; ++i) { long long val = fvals->fetch (i); switch (agrfn) { case AGGR_FAIR: aval = val; break; case AGGR_MAX: if (aval < val || cnt == 0) aval = val; break; case AGGR_MIN: if (aval > val || cnt == 0) aval = val; break; case AGGR_CNT: aval = cnt + 1; break; case AGGR_SUM: case AGGR_AVG: aval += val; break; case AGGR_NONE: break; } if (agrfn == AGGR_FAIR) break; cnt += 1; } // Finalize aggregation if (agrfn == AGGR_AVG) if (cnt > 0) aval = (aval + cnt / 2) / cnt; delete fvals; return aval; } Vector * dbeGetAggregatedValue (int data_id, // data table id char *lfilter, // local filter char *fexpr, // function expression char *pname_ts, // property name for timestamp hrtime_t start_ts, // start of the first time interval hrtime_t delta, // time interval length int num, // number of time intervals char *pname_key, // property name for aggregation key char *aggr_func) // aggregation function { Vector *res = new Vector; Experiment *exp = dbeSession->get_exp (0); if (exp == NULL) return res; hrtime_t end_ts = start_ts + delta * num; if (end_ts < start_ts) // check overflow end_ts = MAX_TIME; if (exp->get_status () == Experiment::INCOMPLETE && exp->getLastEvent () < end_ts) exp->update (); DataDescriptor *dataDscr = exp->get_raw_events (data_id); if (dataDscr == NULL) return res; // Process timestamp argument int prop_ts = dbeSession->getPropIdByName (pname_ts); if (prop_ts == PROP_NONE) return res; assert (prop_ts == -1); // Parse all expressions Expression *flt_expr = NULL; if (lfilter != NULL) flt_expr = dbeSession->ql_parse (lfilter); Expression *func_expr = NULL; if (fexpr != NULL) func_expr = dbeSession->ql_parse (fexpr); if (func_expr == NULL) // Not specified or malformed return res; // Process aggregation key argument int prop_key = PROP_NONE; Data *data_key = NULL; if (pname_key != NULL) { prop_key = dbeSession->getPropIdByName (pname_key); data_key = dataDscr->getData (prop_key); if (data_key == NULL) // Specified but not found return res; } // Process aggregation function argument Aggr_type agrfn = AGGR_FAIR; if (aggr_func != NULL) { agrfn = getAggrFunc (aggr_func); if (agrfn == AGGR_NONE) // Specified but not recognized return res; } DefaultMap * fval_map = new DefaultMap; // key_val -> func_val Vector *key_set = NULL; assert (key_set != NULL); if (key_set == NULL) { key_set = new Vector; key_set->append (0L); } DefaultMap *key_seen = new DefaultMap; long idx_prev = -1; for (int tidx = 0; tidx < num; ++tidx) { long idx_cur = -1; assert (idx_cur != -1); int left = key_set->size (); key_seen->clear (); for (long idx = idx_cur; idx > idx_prev; --idx) { long id = 0; assert (id != 0); // Pre-create expression context Expression::Context ctx (dbeSession->getView (0), exp, NULL, id); // First use the filter if (flt_expr != NULL) if (flt_expr->eval (&ctx) == 0) continue; // Calculate the key // keys are limited to integral values long long key = 0; if (data_key != NULL) key = data_key->fetchLong (id); // Check if already seen if (key_seen->get (key) == 1) continue; key_seen->put (key, 1); left -= 1; // Calculate function value // function values are limited to integral values long long fval = func_expr->eval (&ctx); fval_map->put (key, fval); if (left == 0) break; } idx_prev = idx_cur; long long aval = computeAggrVal (fval_map, agrfn); res->store (tidx, aval); } delete key_seen; delete fval_map; delete flt_expr; delete func_expr; return res; } Vector * dbeGetLineInfo (Obj pc) { DbeInstr *instr = (DbeInstr*) pc; if (instr == NULL || instr->get_type () != Histable::INSTR) return NULL; DbeLine *dbeline = (DbeLine*) instr->convertto (Histable::LINE); const char *fname = dbeline ? dbeline->sourceFile->get_name () : NTXT (""); char lineno[16]; *lineno = '\0'; if (dbeline != NULL) snprintf (lineno, sizeof (lineno), NTXT ("%d"), dbeline->lineno); Vector *res = new Vector(2); res->store (0, xstrdup (fname)); res->store (1, xstrdup (lineno)); return res; } int dbeSetAlias (char *name, char *uname, char *expr) { char *res = dbeSession->indxobj_define (name, uname, expr, NULL, NULL); return res == NULL ? 0 : 1; } Vector * dbeGetAlias (char *name) { Vector *res = new Vector; int idx = dbeSession->findIndexSpaceByName (name); if (idx >= 0) { char *str = dbeSession->getIndexSpaceDescr (idx); res->append (dbe_strdup (str)); str = dbeSession->getIndexSpaceExprStr (idx); res->append (dbe_strdup (str)); } return res; } static int key_cmp (const void *p1, const void *p2) { long long ll1 = *(long long*) p1; long long ll2 = *(long long*) p2; return ll1 < ll2 ? -1 : ll1 > ll2 ? 1 : 0; } Vector*> * dbeGetXYPlotData ( int data_id, // data table id char *lfilter, // local filter expression char *arg, // name for the argument char *func1, // expression for the first axis (x) char *aggr1, // aggregation function for func1: "SUM","CNT",... char *func2, // expression for the second axis (y) char *aggr2, // aggregation function for func2 char *func3, // expression for the third axis (color) char *aggr3) // aggregation function for func3 { Vector*> *res = new Vector*>; Experiment *exp = dbeSession->get_exp (0); if (exp == NULL) return res; if (exp->get_status () == Experiment::INCOMPLETE) exp->update (); DataDescriptor *dataDscr = exp->get_raw_events (data_id); if (dataDscr == NULL) return res; // Parse all expressions Vector *funcs = new Vector; Vector *aggrs = new Vector; Vector*> *fval_maps = new Vector*>; Vector*> *cnt_maps = new Vector*>; if (func1 != NULL) { Expression *expr = dbeSession->ql_parse (func1); funcs->append (expr); aggrs->append (getAggrFunc (aggr1)); fval_maps->append (new DefaultMap); cnt_maps->append (new DefaultMap); res->append (new Vector); if (func2 != NULL) { expr = dbeSession->ql_parse (func2); funcs->append (expr); aggrs->append (getAggrFunc (aggr2)); fval_maps->append (new DefaultMap); cnt_maps->append (new DefaultMap); res->append (new Vector); if (func3 != NULL) { expr = dbeSession->ql_parse (func3); funcs->append (expr); aggrs->append (getAggrFunc (aggr3)); fval_maps->append (new DefaultMap); cnt_maps->append (new DefaultMap); res->append (new Vector); } } } if (funcs->size () == 0) { funcs->destroy (); delete funcs; fval_maps->destroy (); delete fval_maps; cnt_maps->destroy (); delete cnt_maps; delete aggrs; return res; } Expression *arg_expr = NULL; if (arg != NULL) arg_expr = dbeSession->ql_parse (arg); if (arg_expr == NULL) { funcs->destroy (); delete funcs; fval_maps->destroy (); delete fval_maps; cnt_maps->destroy (); delete cnt_maps; delete aggrs; return res; } Expression *flt_expr = NULL; if (lfilter != NULL) flt_expr = dbeSession->ql_parse (lfilter); Vector *kidx_map = new Vector(); // key_idx -> key_val for (long i = 0; i < dataDscr->getSize (); i++) { Expression::Context ctx (dbeSession->getView (0), exp, NULL, i); // First use the filter if (flt_expr != NULL) if (flt_expr->eval (&ctx) == 0) continue; // Compute the argument long long key = arg_expr->eval (&ctx); if (kidx_map->find (key) == -1) kidx_map->append (key); for (long j = 0; j < funcs->size (); ++j) { Expression *func = funcs->fetch (j); Aggr_type aggr = aggrs->fetch (j); DefaultMap *fval_map = fval_maps->fetch (j); DefaultMap *cnt_map = cnt_maps->fetch (j); long long fval = func->eval (&ctx); long long aval = fval_map->get (key); long cnt = cnt_map->get (key); switch (aggr) { case AGGR_NONE: case AGGR_FAIR: if (cnt == 0) aval = fval; break; case AGGR_MAX: if (aval < fval || cnt == 0) aval = fval; break; case AGGR_MIN: if (aval > fval || cnt == 0) aval = fval; break; case AGGR_CNT: aval = cnt + 1; break; case AGGR_SUM: case AGGR_AVG: aval += fval; break; } cnt_map->put (key, cnt + 1); fval_map->put (key, aval); } } kidx_map->sort (key_cmp); // Finalize aggregation, prepare result for (long j = 0; j < funcs->size (); ++j) { Aggr_type aggr = aggrs->fetch (j); Vector *resj = res->fetch (j); DefaultMap * fval_map = fval_maps->fetch (j); DefaultMap * cnt_map = cnt_maps->fetch (j); for (int kidx = 0; kidx < kidx_map->size (); ++kidx) { long long key = kidx_map->fetch (kidx); long long aval = fval_map->get (key); if (aggr == AGGR_AVG) { long cnt = cnt_map->get (key); if (cnt > 0) aval = (aval + cnt / 2) / cnt; } resj->append (aval); } } delete flt_expr; funcs->destroy (); delete funcs; delete aggrs; delete arg_expr; delete kidx_map; fval_maps->destroy (); delete fval_maps; cnt_maps->destroy (); delete cnt_maps; return res; } /* ********************************************************************* */ /* Routines for use by Collector GUI */ /** * Returns signal value for provided name. Example of name: "SIGUSR1" * @param signal * @return value */ int dbeGetSignalValue (char *signal) { int ret = -1; if (signal == NULL) return ret; if (strcmp (signal, "SIGUSR1") == 0) return (SIGUSR1); if (strcmp (signal, "SIGUSR2") == 0) return (SIGUSR2); if (strcmp (signal, "SIGPROF") == 0) return (SIGPROF); return ret; } char * dbeSendSignal (pid_t p, int signum) { int ret = kill (p, signum); if (p == 0 || p == -1) return (dbe_sprintf (GTXT ("kill of process %d not supported\n"), p)); if (ret == 0) return NULL; char *msg = dbe_sprintf (GTXT ("kill(%d, %d) failed: %s\n"), p, signum, strerror (errno)); return msg; } char * dbeGetCollectorControlValue (char *control) { if (control == NULL) return NULL; if (col_ctr == NULL) col_ctr = new Coll_Ctrl (1); char *msg = col_ctr->get (control); return msg; } char * dbeSetCollectorControlValue (char *control, char * value) { if (control == NULL) return NULL; if (col_ctr == NULL) col_ctr = new Coll_Ctrl (1); char *msg = col_ctr->set (control, value); return msg; } char * dbeUnsetCollectorControlValue (char *control) { if (control == NULL) return NULL; if (col_ctr == NULL) col_ctr = new Coll_Ctrl (1); char *msg = col_ctr->unset (control); return msg; } void dbeSetLocation (const char *fname, const char *location) { Vector *sources = dbeSession->get_sources (); for (long i = 0, sz = sources ? sources->size () : 0; i < sz; i++) { SourceFile *src = sources->get (i); DbeFile *df = src->dbeFile; if (df && (strcmp (fname, df->get_name ()) == 0)) { df->find_file ((char *) location); break; } } } void dbeSetLocations (Vector *fnames, Vector *locations) { if (fnames == NULL || locations == NULL || fnames->size () != locations->size ()) return; for (long i = 0, sz = fnames->size (); i < sz; i++) dbeSetLocation (fnames->get (i), locations->get (i)); } Vector * dbeResolvedWith_setpath (const char *path) { Vector *names = new Vector(); Vector *pathes = new Vector(); Vector *ids = new Vector(); Vector *sources = dbeSession->get_sources (); for (long i = 0, sz = sources ? sources->size () : 0; i < sz; i++) { SourceFile *src = sources->get (i); DbeFile *df = src->dbeFile; if (df == NULL || (df->filetype & DbeFile::F_FICTION) != 0) continue; char *fnm = df->get_name (); if ((df->filetype & (DbeFile::F_JAVACLASS | DbeFile::F_JAVA_SOURCE)) != 0) { char *jnm = dbe_sprintf (NTXT ("%s/%s"), path, fnm); if (df->check_access (jnm) == DbeFile::F_FILE) { names->append (dbe_strdup (fnm)); pathes->append (jnm); ids->append (src->id); continue; } free (jnm); } char *nm = dbe_sprintf (NTXT ("%s/%s"), path, get_basename (fnm)); if (df->check_access (nm) == DbeFile::F_FILE) { names->append (dbe_strdup (fnm)); pathes->append (nm); ids->append (src->id); continue; } free (nm); } if (names->size () != 0) { Vector *data = new Vector(3); data->append (names); data->append (pathes); data->append (ids); return data; } return NULL; } Vector * dbeResolvedWith_pathmap (const char *old_prefix, const char *new_prefix) { size_t len = strlen (old_prefix); Vector *names = new Vector(); Vector *pathes = new Vector(); Vector *ids = new Vector(); Vector *sources = dbeSession->get_sources (); for (long i = 0, sz = sources ? sources->size () : 0; i < sz; i++) { SourceFile *src = sources->get (i); DbeFile *df = src->dbeFile; if (df == NULL || (df->filetype & DbeFile::F_FICTION) != 0) continue; char *fnm = df->get_name (); if (strncmp (old_prefix, fnm, len) == 0 && (fnm[len] == '/' || fnm[len] == '\0')) { char *nm = dbe_sprintf (NTXT ("%s/%s"), new_prefix, fnm + len); if (df->check_access (nm) == DbeFile::F_FILE) { names->append (dbe_strdup (fnm)); pathes->append (nm); ids->append (src->id); continue; } if ((df->filetype & DbeFile::F_JAVA_SOURCE) != 0) { free (nm); nm = dbe_sprintf (NTXT ("%s/%s"), new_prefix, fnm); if (df->check_access (nm) == DbeFile::F_FILE) { names->append (dbe_strdup (fnm)); pathes->append (nm); ids->append (src->id); continue; } } free (nm); } } if (names->size () != 0) { Vector *data = new Vector(3); data->append (names); data->append (pathes); data->append (ids); return data; } return NULL; } void dbe_archive (Vector *ids, Vector *locations) { if (ids == NULL || locations == NULL || ids->size () != locations->size ()) return; Experiment *exp = dbeSession->get_exp (0); if (exp == NULL) return; Vector *sources = dbeSession->get_sources (); for (long i1 = 0, sz1 = ids->size (); i1 < sz1; i1++) { long long id = ids->get (i1); for (long i = 0, sz = sources ? sources->size () : 0; i < sz; i++) { SourceFile *src = sources->get (i); if (src->id == id) { DbeFile *df = src->dbeFile; if (df) { char *fnm = df->find_file ((char *) locations->get (i1)); if (fnm) { char *nm = df->get_name (); char *anm = exp->getNameInArchive (nm, false); exp->copy_file (fnm, anm, true); free (anm); } } } } } } /* ************************************************************************ */ /* Routines to check connection between Remote Analyzer Client and er_print */ char * dbeCheckConnection (char *str) { return dbe_strdup (str); }