/* ----------------------------------------------------------------------------- * * (c) The GHC Team, 1998-2000 * * Support for profiling * * ---------------------------------------------------------------------------*/ #ifdef PROFILING #include "PosixSource.h" #include "Rts.h" #include "RtsUtils.h" #include "RtsFlags.h" #include "Profiling.h" #include "Storage.h" #include "Proftimer.h" #include "Timer.h" #include "ProfHeap.h" #include "Arena.h" #include "RetainerProfile.h" #include "LdvProfile.h" #include #ifdef DEBUG #include "Trace.h" #endif /* * Profiling allocation arena. */ Arena *prof_arena; /* * Global variables used to assign unique IDs to cc's, ccs's, and * closure_cats */ unsigned int CC_ID; unsigned int CCS_ID; unsigned int HP_ID; /* figures for the profiling report. */ static ullong total_alloc; static lnat total_prof_ticks; /* Globals for opening the profiling log file(s) */ static char *prof_filename; /* prof report file name = .prof */ FILE *prof_file; static char *hp_filename; /* heap profile (hp2ps style) log file */ FILE *hp_file; /* The Current Cost Centre Stack (for attributing costs) */ CostCentreStack *CCCS; /* Linked lists to keep track of cc's and ccs's that haven't * been declared in the log file yet */ CostCentre *CC_LIST; CostCentreStack *CCS_LIST; /* * Built-in cost centres and cost-centre stacks: * * MAIN is the root of the cost-centre stack tree. If there are * no _scc_s in the program, all costs will be attributed * to MAIN. * * SYSTEM is the RTS in general (scheduler, etc.). All costs for * RTS operations apart from garbage collection are attributed * to SYSTEM. * * GC is the storage manager / garbage collector. * * OVERHEAD gets all costs generated by the profiling system * itself. These are costs that would not be incurred * during non-profiled execution of the program. * * SUBSUMED is the one-and-only CCS placed on top-level functions. * It indicates that all costs are to be attributed to the * enclosing cost centre stack. SUBSUMED never accumulates * any costs. The is_caf flag is set on the subsumed cost * centre. * * DONT_CARE is a placeholder cost-centre we assign to static * constructors. It should *never* accumulate any costs. */ CC_DECLARE(CC_MAIN, "MAIN", "MAIN", CC_IS_BORING, ); CC_DECLARE(CC_SYSTEM, "SYSTEM", "MAIN", CC_IS_BORING, ); CC_DECLARE(CC_GC, "GC", "GC", CC_IS_BORING, ); CC_DECLARE(CC_OVERHEAD, "OVERHEAD_of", "PROFILING", CC_IS_CAF, ); CC_DECLARE(CC_SUBSUMED, "SUBSUMED", "MAIN", CC_IS_CAF, ); CC_DECLARE(CC_DONT_CARE, "DONT_CARE", "MAIN", CC_IS_BORING, ); CCS_DECLARE(CCS_MAIN, CC_MAIN, ); CCS_DECLARE(CCS_SYSTEM, CC_SYSTEM, ); CCS_DECLARE(CCS_GC, CC_GC, ); CCS_DECLARE(CCS_OVERHEAD, CC_OVERHEAD, ); CCS_DECLARE(CCS_SUBSUMED, CC_SUBSUMED, ); CCS_DECLARE(CCS_DONT_CARE, CC_DONT_CARE, ); /* * Uniques for the XML log-file format */ #define CC_UQ 1 #define CCS_UQ 2 #define TC_UQ 3 #define HEAP_OBJ_UQ 4 #define TIME_UPD_UQ 5 #define HEAP_UPD_UQ 6 /* * Static Functions */ static CostCentreStack * ActualPush_ ( CostCentreStack *ccs, CostCentre *cc, CostCentreStack *new_ccs ); static rtsBool ccs_to_ignore ( CostCentreStack *ccs ); static void count_ticks ( CostCentreStack *ccs ); static void inherit_costs ( CostCentreStack *ccs ); static void reportCCS ( CostCentreStack *ccs, nat indent ); static void DecCCS ( CostCentreStack *ccs ); static void DecBackEdge ( CostCentreStack *ccs, CostCentreStack *oldccs ); static CostCentreStack * CheckLoop ( CostCentreStack *ccs, CostCentre *cc ); static CostCentreStack * pruneCCSTree ( CostCentreStack *ccs ); static CostCentreStack * ActualPush ( CostCentreStack *, CostCentre * ); static CostCentreStack * IsInIndexTable ( IndexTable *, CostCentre * ); static IndexTable * AddToIndexTable ( IndexTable *, CostCentreStack *, CostCentre *, unsigned int ); static void ccsSetSelected ( CostCentreStack *ccs ); static void initTimeProfiling ( void ); static void initProfilingLogFile( void ); static void reportCCS_XML ( CostCentreStack *ccs ); /* ----------------------------------------------------------------------------- Initialise the profiling environment -------------------------------------------------------------------------- */ void initProfiling1 (void) { // initialise our arena prof_arena = newArena(); /* for the benefit of allocate()... */ CCCS = CCS_SYSTEM; /* Initialize counters for IDs */ CC_ID = 1; CCS_ID = 1; HP_ID = 1; /* Initialize Declaration lists to NULL */ CC_LIST = NULL; CCS_LIST = NULL; /* Register all the cost centres / stacks in the program * CC_MAIN gets link = 0, all others have non-zero link. */ REGISTER_CC(CC_MAIN); REGISTER_CC(CC_SYSTEM); REGISTER_CC(CC_GC); REGISTER_CC(CC_OVERHEAD); REGISTER_CC(CC_SUBSUMED); REGISTER_CC(CC_DONT_CARE); REGISTER_CCS(CCS_MAIN); REGISTER_CCS(CCS_SYSTEM); REGISTER_CCS(CCS_GC); REGISTER_CCS(CCS_OVERHEAD); REGISTER_CCS(CCS_SUBSUMED); REGISTER_CCS(CCS_DONT_CARE); CCCS = CCS_OVERHEAD; /* cost centres are registered by the per-module * initialisation code now... */ } void initProfiling2 (void) { CostCentreStack *ccs, *next; CCCS = CCS_SYSTEM; /* Set up the log file, and dump the header and cost centre * information into it. */ initProfilingLogFile(); /* find all the "special" cost centre stacks, and make them children * of CCS_MAIN. */ ASSERT(CCS_MAIN->prevStack == 0); CCS_MAIN->root = CC_MAIN; ccsSetSelected(CCS_MAIN); DecCCS(CCS_MAIN); for (ccs = CCS_LIST; ccs != CCS_MAIN; ) { next = ccs->prevStack; ccs->prevStack = 0; ActualPush_(CCS_MAIN,ccs->cc,ccs); ccs->root = ccs->cc; ccs = next; } if (RtsFlags.CcFlags.doCostCentres) { initTimeProfiling(); } if (RtsFlags.ProfFlags.doHeapProfile) { initHeapProfiling(); } } // Decide whether closures with this CCS should contribute to the heap // profile. static void ccsSetSelected( CostCentreStack *ccs ) { if (RtsFlags.ProfFlags.modSelector) { if (! strMatchesSelector( ccs->cc->module, RtsFlags.ProfFlags.modSelector ) ) { ccs->selected = 0; return; } } if (RtsFlags.ProfFlags.ccSelector) { if (! strMatchesSelector( ccs->cc->label, RtsFlags.ProfFlags.ccSelector ) ) { ccs->selected = 0; return; } } if (RtsFlags.ProfFlags.ccsSelector) { CostCentreStack *c; for (c = ccs; c != NULL; c = c->prevStack) { if ( strMatchesSelector( c->cc->label, RtsFlags.ProfFlags.ccsSelector )) { break; } } if (c == NULL) { ccs->selected = 0; return; } } ccs->selected = 1; return; } static void initProfilingLogFile(void) { /* Initialise the log file name */ prof_filename = arenaAlloc(prof_arena, strlen(prog_name) + 6); sprintf(prof_filename, "%s.prof", prog_name); /* open the log file */ if ((prof_file = fopen(prof_filename, "w")) == NULL) { debugBelch("Can't open profiling report file %s\n", prof_filename); RtsFlags.CcFlags.doCostCentres = 0; // The following line was added by Sung; retainer/LDV profiling may need // two output files, i.e., .prof/hp. if (RtsFlags.ProfFlags.doHeapProfile == HEAP_BY_RETAINER) RtsFlags.ProfFlags.doHeapProfile = 0; return; } if (RtsFlags.CcFlags.doCostCentres == COST_CENTRES_XML) { /* dump the time, and the profiling interval */ fprintf(prof_file, "\"%s\"\n", time_str()); fprintf(prof_file, "\"%d ms\"\n", RtsFlags.MiscFlags.tickInterval); /* declare all the cost centres */ { CostCentre *cc; for (cc = CC_LIST; cc != NULL; cc = cc->link) { fprintf(prof_file, "%d %ld \"%s\" \"%s\"\n", CC_UQ, cc->ccID, cc->label, cc->module); } } } if (RtsFlags.ProfFlags.doHeapProfile) { /* Initialise the log file name */ hp_filename = arenaAlloc(prof_arena, strlen(prog_name) + 6); sprintf(hp_filename, "%s.hp", prog_name); /* open the log file */ if ((hp_file = fopen(hp_filename, "w")) == NULL) { debugBelch("Can't open profiling report file %s\n", hp_filename); RtsFlags.ProfFlags.doHeapProfile = 0; return; } } } void initTimeProfiling(void) { /* Start ticking */ startProfTimer(); }; void endProfiling ( void ) { if (RtsFlags.CcFlags.doCostCentres) { stopProfTimer(); } if (RtsFlags.ProfFlags.doHeapProfile) { endHeapProfiling(); } } /* ----------------------------------------------------------------------------- Set cost centre stack when entering a function. -------------------------------------------------------------------------- */ rtsBool entering_PAP; void EnterFunCCS ( CostCentreStack *ccsfn ) { /* PAP_entry has already set CCCS for us */ if (entering_PAP) { entering_PAP = rtsFalse; return; } if (ccsfn->root->is_caf == CC_IS_CAF) { CCCS = AppendCCS(CCCS,ccsfn); } else { CCCS = ccsfn; } } /* ----------------------------------------------------------------------------- Cost-centre stack manipulation -------------------------------------------------------------------------- */ #ifdef DEBUG CostCentreStack * _PushCostCentre ( CostCentreStack *ccs, CostCentre *cc ); CostCentreStack * PushCostCentre ( CostCentreStack *ccs, CostCentre *cc ) #define PushCostCentre _PushCostCentre { IF_DEBUG(prof, traceBegin("pushing %s on ", cc->label); debugCCS(ccs); traceEnd();); return PushCostCentre(ccs,cc); } #endif CostCentreStack * PushCostCentre ( CostCentreStack *ccs, CostCentre *cc ) { CostCentreStack *temp_ccs; if (ccs == EMPTY_STACK) return ActualPush(ccs,cc); else { if (ccs->cc == cc) return ccs; else { /* check if we've already memoized this stack */ temp_ccs = IsInIndexTable(ccs->indexTable,cc); if (temp_ccs != EMPTY_STACK) return temp_ccs; else { temp_ccs = CheckLoop(ccs,cc); if (temp_ccs != NULL) { /* we have recursed to an older CCS. Mark this in * the index table, and emit a "back edge" into the * log file. */ ccs->indexTable = AddToIndexTable(ccs->indexTable,temp_ccs,cc,1); DecBackEdge(temp_ccs,ccs); return temp_ccs; } else { return ActualPush(ccs,cc); } } } } } static CostCentreStack * CheckLoop ( CostCentreStack *ccs, CostCentre *cc ) { while (ccs != EMPTY_STACK) { if (ccs->cc == cc) return ccs; ccs = ccs->prevStack; } return NULL; } /* Append ccs1 to ccs2 (ignoring any CAF cost centre at the root of ccs1 */ #ifdef DEBUG CostCentreStack *_AppendCCS ( CostCentreStack *ccs1, CostCentreStack *ccs2 ); CostCentreStack * AppendCCS ( CostCentreStack *ccs1, CostCentreStack *ccs2 ) #define AppendCCS _AppendCCS { IF_DEBUG(prof, if (ccs1 != ccs2) { debugBelch("Appending "); debugCCS(ccs1); debugBelch(" to "); debugCCS(ccs2); debugBelch("\n");}); return AppendCCS(ccs1,ccs2); } #endif CostCentreStack * AppendCCS ( CostCentreStack *ccs1, CostCentreStack *ccs2 ) { CostCentreStack *ccs = NULL; if (ccs1 == ccs2) { return ccs1; } if (ccs2->cc->is_caf == CC_IS_CAF) { return ccs1; } if (ccs2->prevStack != NULL) { ccs = AppendCCS(ccs1, ccs2->prevStack); } return PushCostCentre(ccs,ccs2->cc); } static CostCentreStack * ActualPush ( CostCentreStack *ccs, CostCentre *cc ) { CostCentreStack *new_ccs; /* allocate space for a new CostCentreStack */ new_ccs = (CostCentreStack *) arenaAlloc(prof_arena, sizeof(CostCentreStack)); return ActualPush_(ccs, cc, new_ccs); } static CostCentreStack * ActualPush_ ( CostCentreStack *ccs, CostCentre *cc, CostCentreStack *new_ccs ) { /* assign values to each member of the structure */ new_ccs->ccsID = CCS_ID++; new_ccs->cc = cc; new_ccs->prevStack = ccs; new_ccs->indexTable = EMPTY_TABLE; /* Initialise the various _scc_ counters to zero */ new_ccs->scc_count = 0; /* Initialize all other stats here. There should be a quick way * that's easily used elsewhere too */ new_ccs->time_ticks = 0; new_ccs->mem_alloc = 0; new_ccs->inherited_ticks = 0; new_ccs->inherited_alloc = 0; new_ccs->root = ccs->root; // Set the selected field. ccsSetSelected(new_ccs); /* update the memoization table for the parent stack */ if (ccs != EMPTY_STACK) ccs->indexTable = AddToIndexTable(ccs->indexTable, new_ccs, cc, 0/*not a back edge*/); /* make sure this CC is declared at the next heap/time sample */ DecCCS(new_ccs); /* return a pointer to the new stack */ return new_ccs; } static CostCentreStack * IsInIndexTable(IndexTable *it, CostCentre *cc) { while (it!=EMPTY_TABLE) { if (it->cc==cc) return it->ccs; else it = it->next; } /* otherwise we never found it so return EMPTY_TABLE */ return EMPTY_TABLE; } static IndexTable * AddToIndexTable(IndexTable *it, CostCentreStack *new_ccs, CostCentre *cc, unsigned int back_edge) { IndexTable *new_it; new_it = arenaAlloc(prof_arena, sizeof(IndexTable)); new_it->cc = cc; new_it->ccs = new_ccs; new_it->next = it; new_it->back_edge = back_edge; return new_it; } static void DecCCS(CostCentreStack *ccs) { if (prof_file && RtsFlags.CcFlags.doCostCentres == COST_CENTRES_XML) { if (ccs->prevStack == EMPTY_STACK) fprintf(prof_file, "%d %ld 1 %ld\n", CCS_UQ, ccs->ccsID, ccs->cc->ccID); else fprintf(prof_file, "%d %ld 2 %ld %ld\n", CCS_UQ, ccs->ccsID, ccs->cc->ccID, ccs->prevStack->ccsID); } } static void DecBackEdge( CostCentreStack *ccs, CostCentreStack *oldccs ) { if (prof_file && RtsFlags.CcFlags.doCostCentres == COST_CENTRES_XML) { if (ccs->prevStack == EMPTY_STACK) fprintf(prof_file, "%d %ld 1 %ld\n", CCS_UQ, ccs->ccsID, ccs->cc->ccID); else fprintf(prof_file, "%d %ld 2 %ld %ld\n", CCS_UQ, ccs->ccsID, ccs->cc->ccID, oldccs->ccsID); } } /* ----------------------------------------------------------------------------- Generating a time & allocation profiling report. -------------------------------------------------------------------------- */ /* We omit certain system-related CCs and CCSs from the default * reports, so as not to cause confusion. */ static rtsBool cc_to_ignore (CostCentre *cc) { if ( cc == CC_OVERHEAD || cc == CC_DONT_CARE || cc == CC_GC || cc == CC_SYSTEM) { return rtsTrue; } else { return rtsFalse; } } static rtsBool ccs_to_ignore (CostCentreStack *ccs) { if ( ccs == CCS_OVERHEAD || ccs == CCS_DONT_CARE || ccs == CCS_GC || ccs == CCS_SYSTEM) { return rtsTrue; } else { return rtsFalse; } } /* ----------------------------------------------------------------------------- Generating the aggregated per-cost-centre time/alloc report. -------------------------------------------------------------------------- */ static CostCentre *sorted_cc_list; static void aggregate_cc_costs( CostCentreStack *ccs ) { IndexTable *i; ccs->cc->mem_alloc += ccs->mem_alloc; ccs->cc->time_ticks += ccs->time_ticks; for (i = ccs->indexTable; i != 0; i = i->next) { if (!i->back_edge) { aggregate_cc_costs(i->ccs); } } } static void insert_cc_in_sorted_list( CostCentre *new_cc ) { CostCentre **prev, *cc; prev = &sorted_cc_list; for (cc = sorted_cc_list; cc != NULL; cc = cc->link) { if (new_cc->time_ticks > cc->time_ticks) { new_cc->link = cc; *prev = new_cc; return; } else { prev = &(cc->link); } } new_cc->link = NULL; *prev = new_cc; } static void report_per_cc_costs( void ) { CostCentre *cc, *next; aggregate_cc_costs(CCS_MAIN); sorted_cc_list = NULL; for (cc = CC_LIST; cc != NULL; cc = next) { next = cc->link; if (cc->time_ticks > total_prof_ticks/100 || cc->mem_alloc > total_alloc/100 || RtsFlags.CcFlags.doCostCentres >= COST_CENTRES_ALL) { insert_cc_in_sorted_list(cc); } } fprintf(prof_file, "%-30s %-20s", "COST CENTRE", "MODULE"); fprintf(prof_file, "%6s %6s", "%time", "%alloc"); if (RtsFlags.CcFlags.doCostCentres >= COST_CENTRES_VERBOSE) { fprintf(prof_file, " %5s %9s", "ticks", "bytes"); } fprintf(prof_file, "\n\n"); for (cc = sorted_cc_list; cc != NULL; cc = cc->link) { if (cc_to_ignore(cc)) { continue; } fprintf(prof_file, "%-30s %-20s", cc->label, cc->module); fprintf(prof_file, "%6.1f %6.1f", total_prof_ticks == 0 ? 0.0 : (cc->time_ticks / (StgFloat) total_prof_ticks * 100), total_alloc == 0 ? 0.0 : (cc->mem_alloc / (StgFloat) total_alloc * 100) ); if (RtsFlags.CcFlags.doCostCentres >= COST_CENTRES_VERBOSE) { fprintf(prof_file, " %5" FMT_Word64 " %9" FMT_Word64, (StgWord64)(cc->time_ticks), cc->mem_alloc); } fprintf(prof_file, "\n"); } fprintf(prof_file,"\n\n"); } /* ----------------------------------------------------------------------------- Generate the cost-centre-stack time/alloc report -------------------------------------------------------------------------- */ static void fprint_header( void ) { fprintf(prof_file, "%-24s %-10s individual inherited\n", "", ""); fprintf(prof_file, "%-24s %-50s", "COST CENTRE", "MODULE"); fprintf(prof_file, "%6s %10s %5s %5s %5s %5s", "no.", "entries", "%time", "%alloc", "%time", "%alloc"); if (RtsFlags.CcFlags.doCostCentres >= COST_CENTRES_VERBOSE) { fprintf(prof_file, " %5s %9s", "ticks", "bytes"); #if defined(PROFILING_DETAIL_COUNTS) fprintf(prof_file, " %8s %8s %8s %8s %8s %8s %8s", "closures", "thunks", "funcs", "PAPs", "subfuns", "subcafs", "cafssub"); #endif } fprintf(prof_file, "\n\n"); } void reportCCSProfiling( void ) { nat count; char temp[128]; /* sigh: magic constant */ stopProfTimer(); total_prof_ticks = 0; total_alloc = 0; count_ticks(CCS_MAIN); switch (RtsFlags.CcFlags.doCostCentres) { case 0: return; case COST_CENTRES_XML: gen_XML_logfile(); return; default: break; } fprintf(prof_file, "\t%s Time and Allocation Profiling Report (%s)\n", time_str(), "Final"); fprintf(prof_file, "\n\t "); fprintf(prof_file, " %s", prog_name); fprintf(prof_file, " +RTS"); for (count = 0; rts_argv[count]; count++) fprintf(prof_file, " %s", rts_argv[count]); fprintf(prof_file, " -RTS"); for (count = 1; prog_argv[count]; count++) fprintf(prof_file, " %s", prog_argv[count]); fprintf(prof_file, "\n\n"); fprintf(prof_file, "\ttotal time = %11.2f secs (%lu ticks @ %d ms)\n", (double) total_prof_ticks * (double) RtsFlags.MiscFlags.tickInterval / 1000, (unsigned long) total_prof_ticks, (int) RtsFlags.MiscFlags.tickInterval); fprintf(prof_file, "\ttotal alloc = %11s bytes", ullong_format_string(total_alloc * sizeof(W_), temp, rtsTrue/*commas*/)); #if defined(PROFILING_DETAIL_COUNTS) fprintf(prof_file, " (%lu closures)", total_allocs); #endif fprintf(prof_file, " (excludes profiling overheads)\n\n"); report_per_cc_costs(); inherit_costs(CCS_MAIN); fprint_header(); reportCCS(pruneCCSTree(CCS_MAIN), 0); } static void reportCCS(CostCentreStack *ccs, nat indent) { CostCentre *cc; IndexTable *i; cc = ccs->cc; /* Only print cost centres with non 0 data ! */ if ( RtsFlags.CcFlags.doCostCentres >= COST_CENTRES_ALL || ! ccs_to_ignore(ccs)) /* force printing of *all* cost centres if -P -P */ { fprintf(prof_file, "%-*s%-*s %-50s", indent, "", 24-indent, cc->label, cc->module); fprintf(prof_file, "%6ld %11.0f %5.1f %5.1f %5.1f %5.1f", ccs->ccsID, (double) ccs->scc_count, total_prof_ticks == 0 ? 0.0 : ((double)ccs->time_ticks / (double)total_prof_ticks * 100.0), total_alloc == 0 ? 0.0 : ((double)ccs->mem_alloc / (double)total_alloc * 100.0), total_prof_ticks == 0 ? 0.0 : ((double)ccs->inherited_ticks / (double)total_prof_ticks * 100.0), total_alloc == 0 ? 0.0 : ((double)ccs->inherited_alloc / (double)total_alloc * 100.0) ); if (RtsFlags.CcFlags.doCostCentres >= COST_CENTRES_VERBOSE) { fprintf(prof_file, " %5" FMT_Word64 " %9" FMT_Word64, (StgWord64)(ccs->time_ticks), ccs->mem_alloc*sizeof(W_)); #if defined(PROFILING_DETAIL_COUNTS) fprintf(prof_file, " %8ld %8ld %8ld %8ld %8ld %8ld %8ld", ccs->mem_allocs, ccs->thunk_count, ccs->function_count, ccs->pap_count, ccs->subsumed_fun_count, ccs->subsumed_caf_count, ccs->caffun_subsumed); #endif } fprintf(prof_file, "\n"); } for (i = ccs->indexTable; i != 0; i = i->next) { if (!i->back_edge) { reportCCS(i->ccs, indent+1); } } } /* Traverse the cost centre stack tree and accumulate * ticks/allocations. */ static void count_ticks(CostCentreStack *ccs) { IndexTable *i; if (!ccs_to_ignore(ccs)) { total_alloc += ccs->mem_alloc; total_prof_ticks += ccs->time_ticks; } for (i = ccs->indexTable; i != NULL; i = i->next) if (!i->back_edge) { count_ticks(i->ccs); } } /* Traverse the cost centre stack tree and inherit ticks & allocs. */ static void inherit_costs(CostCentreStack *ccs) { IndexTable *i; if (ccs_to_ignore(ccs)) { return; } ccs->inherited_ticks += ccs->time_ticks; ccs->inherited_alloc += ccs->mem_alloc; for (i = ccs->indexTable; i != NULL; i = i->next) if (!i->back_edge) { inherit_costs(i->ccs); ccs->inherited_ticks += i->ccs->inherited_ticks; ccs->inherited_alloc += i->ccs->inherited_alloc; } return; } static CostCentreStack * pruneCCSTree( CostCentreStack *ccs ) { CostCentreStack *ccs1; IndexTable *i, **prev; prev = &ccs->indexTable; for (i = ccs->indexTable; i != 0; i = i->next) { if (i->back_edge) { continue; } ccs1 = pruneCCSTree(i->ccs); if (ccs1 == NULL) { *prev = i->next; } else { prev = &(i->next); } } if ( (RtsFlags.CcFlags.doCostCentres >= COST_CENTRES_ALL /* force printing of *all* cost centres if -P -P */ ) || ( ccs->indexTable != 0 ) || ( ccs->scc_count || ccs->time_ticks || ccs->mem_alloc ) ) { return ccs; } else { return NULL; } } /* ----------------------------------------------------------------------------- Generate the XML time/allocation profile -------------------------------------------------------------------------- */ void gen_XML_logfile( void ) { fprintf(prof_file, "%d %lu", TIME_UPD_UQ, total_prof_ticks); reportCCS_XML(pruneCCSTree(CCS_MAIN)); fprintf(prof_file, " 0\n"); } static void reportCCS_XML(CostCentreStack *ccs) { CostCentre *cc; IndexTable *i; if (ccs_to_ignore(ccs)) { return; } cc = ccs->cc; fprintf(prof_file, " 1 %ld %" FMT_Word64 " %" FMT_Word64 " %" FMT_Word64, ccs->ccsID, ccs->scc_count, (StgWord64)(ccs->time_ticks), ccs->mem_alloc); for (i = ccs->indexTable; i != 0; i = i->next) { if (!i->back_edge) { reportCCS_XML(i->ccs); } } } void fprintCCS( FILE *f, CostCentreStack *ccs ) { fprintf(f,"<"); for (; ccs && ccs != CCS_MAIN; ccs = ccs->prevStack ) { fprintf(f,"%s.%s", ccs->cc->module, ccs->cc->label); if (ccs->prevStack && ccs->prevStack != CCS_MAIN) { fprintf(f,","); } } fprintf(f,">"); } /* For calling from .cmm code, where we can't reliably refer to stderr */ void fprintCCS_stderr( CostCentreStack *ccs ) { fprintCCS(stderr, ccs); } #ifdef DEBUG void debugCCS( CostCentreStack *ccs ) { debugBelch("<"); for (; ccs && ccs != CCS_MAIN; ccs = ccs->prevStack ) { debugBelch("%s.%s", ccs->cc->module, ccs->cc->label); if (ccs->prevStack && ccs->prevStack != CCS_MAIN) { debugBelch(","); } } debugBelch(">"); } #endif /* DEBUG */ #endif /* PROFILING */