/* * Copyright (c) 1983 Regents of the University of California. * All rights reserved. * * Redistribution and use in source and binary forms are permitted * provided that the above copyright notice and this paragraph are * duplicated in all such forms and that any documentation, * advertising materials, and other materials related to such * distribution and use acknowledge that the software was developed * by the University of California, Berkeley. The name of the * University may not be used to endorse or promote products derived * from this software without specific prior written permission. * THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED * WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR A PARTICULAR PURPOSE. */ #ifndef lint static char sccsid[] = "@(#)printgprof.c 5.5 (Berkeley) 6/29/88"; #endif /* not lint */ #include "gprof.h" printprof() { register nltype *np; nltype **sortednlp; int index, timecmp(); actime = 0.0; printf( "\f\n" ); flatprofheader(); /* * Sort the symbol table in by time */ sortednlp = (nltype **) calloc( nname , sizeof(nltype *) ); if ( sortednlp == (nltype **) 0 ) { fprintf( stderr , "[printprof] ran out of memory for time sorting\n" ); } for ( index = 0 ; index < nname ; index += 1 ) { sortednlp[ index ] = &nl[ index ]; } qsort( sortednlp , nname , sizeof(nltype *) , timecmp ); for ( index = 0 ; index < nname ; index += 1 ) { np = sortednlp[ index ]; flatprofline( np ); } actime = 0.0; cfree( sortednlp ); } timecmp( npp1 , npp2 ) nltype **npp1, **npp2; { double timediff; long calldiff; timediff = (*npp2) -> time - (*npp1) -> time; if ( timediff > 0.0 ) return 1 ; if ( timediff < 0.0 ) return -1; calldiff = (*npp2) -> ncall - (*npp1) -> ncall; if ( calldiff > 0 ) return 1; if ( calldiff < 0 ) return -1; return( strcmp( (*npp1) -> name , (*npp2) -> name ) ); } /* * header for flatprofline */ flatprofheader() { if ( bflag ) { printblurb( FLAT_BLURB ); } printf( "\ngranularity: each sample hit covers %d byte(s)" , (long) scale * sizeof(UNIT) ); if ( totime > 0.0 ) { printf( " for %.2f%% of %.2f seconds\n\n" , 100.0/totime , totime / hz ); } else { printf( " no time accumulated\n\n" ); /* * this doesn't hurt sinc eall the numerators will be zero. */ totime = 1.0; } printf( "%5.5s %10.10s %8.8s %8.8s %8.8s %8.8s %-8.8s\n" , "% " , "cumulative" , "self " , "" , "self " , "total " , "" ); printf( "%5.5s %10.10s %8.8s %8.8s %8.8s %8.8s %-8.8s\n" , "time" , "seconds " , "seconds" , "calls" , "ms/call" , "ms/call" , "name" ); } flatprofline( np ) register nltype *np; { if ( zflag == 0 && np -> ncall == 0 && np -> time == 0 ) { return; } actime += np -> time; printf( "%5.1f %10.2f %8.2f" , 100 * np -> time / totime , actime / hz , np -> time / hz ); if ( np -> ncall != 0 ) { printf( " %8d %8.2f %8.2f " , np -> ncall , 1000 * np -> time / hz / np -> ncall , 1000 * ( np -> time + np -> childtime ) / hz / np -> ncall ); } else { printf( " %8.8s %8.8s %8.8s " , "" , "" , "" ); } printname( np ); printf( "\n" ); } gprofheader() { if ( bflag ) { printblurb( CALLG_BLURB ); } printf( "\ngranularity: each sample hit covers %d byte(s)" , (long) scale * sizeof(UNIT) ); if ( printtime > 0.0 ) { printf( " for %.2f%% of %.2f seconds\n\n" , 100.0/printtime , printtime / hz ); } else { printf( " no time propagated\n\n" ); /* * this doesn't hurt, since all the numerators will be 0.0 */ printtime = 1.0; } printf( "%6.6s %5.5s %7.7s %11.11s %7.7s/%-7.7s %-8.8s\n" , "" , "" , "" , "" , "called" , "total" , "parents"); printf( "%-6.6s %5.5s %7.7s %11.11s %7.7s+%-7.7s %-8.8s\t%5.5s\n" , "index" , "%time" , "self" , "descendents" , "called" , "self" , "name" , "index" ); printf( "%6.6s %5.5s %7.7s %11.11s %7.7s/%-7.7s %-8.8s\n" , "" , "" , "" , "" , "called" , "total" , "children"); printf( "\n" ); } gprofline( np ) register nltype *np; { char kirkbuffer[ BUFSIZ ]; sprintf( kirkbuffer , "[%d]" , np -> index ); printf( "%-6.6s %5.1f %7.2f %11.2f" , kirkbuffer , 100 * ( np -> propself + np -> propchild ) / printtime , np -> propself / hz , np -> propchild / hz ); if ( ( np -> ncall + np -> selfcalls ) != 0 ) { printf( " %7d" , np -> ncall ); if ( np -> selfcalls != 0 ) { printf( "+%-7d " , np -> selfcalls ); } else { printf( " %7.7s " , "" ); } } else { printf( " %7.7s %7.7s " , "" , "" ); } printname( np ); printf( "\n" ); } printgprof(timesortnlp) nltype **timesortnlp; { int index; nltype *parentp; /* * Print out the structured profiling list */ gprofheader(); for ( index = 0 ; index < nname + ncycle ; index ++ ) { parentp = timesortnlp[ index ]; if ( zflag == 0 && parentp -> ncall == 0 && parentp -> selfcalls == 0 && parentp -> propself == 0 && parentp -> propchild == 0 ) { continue; } if ( ! parentp -> printflag ) { continue; } if ( parentp -> name == 0 && parentp -> cycleno != 0 ) { /* * cycle header */ printcycle( parentp ); printmembers( parentp ); } else { printparents( parentp ); gprofline( parentp ); printchildren( parentp ); } printf( "\n" ); printf( "-----------------------------------------------\n" ); printf( "\n" ); } cfree( timesortnlp ); } /* * sort by decreasing propagated time * if times are equal, but one is a cycle header, * say that's first (e.g. less, i.e. -1). * if one's name doesn't have an underscore and the other does, * say the one is first. * all else being equal, sort by names. */ int totalcmp( npp1 , npp2 ) nltype **npp1; nltype **npp2; { register nltype *np1 = *npp1; register nltype *np2 = *npp2; double diff; diff = ( np1 -> propself + np1 -> propchild ) - ( np2 -> propself + np2 -> propchild ); if ( diff < 0.0 ) return 1; if ( diff > 0.0 ) return -1; if ( np1 -> name == 0 && np1 -> cycleno != 0 ) return -1; if ( np2 -> name == 0 && np2 -> cycleno != 0 ) return 1; if ( np1 -> name == 0 ) return -1; if ( np2 -> name == 0 ) return 1; if ( *(np1 -> name) != '_' && *(np2 -> name) == '_' ) return -1; if ( *(np1 -> name) == '_' && *(np2 -> name) != '_' ) return 1; if ( np1 -> ncall > np2 -> ncall ) return -1; if ( np1 -> ncall < np2 -> ncall ) return 1; return strcmp( np1 -> name , np2 -> name ); } printparents( childp ) nltype *childp; { nltype *parentp; arctype *arcp; nltype *cycleheadp; if ( childp -> cyclehead != 0 ) { cycleheadp = childp -> cyclehead; } else { cycleheadp = childp; } if ( childp -> parents == 0 ) { printf( "%6.6s %5.5s %7.7s %11.11s %7.7s %7.7s <spontaneous>\n" , "" , "" , "" , "" , "" , "" ); return; } sortparents( childp ); for ( arcp = childp -> parents ; arcp ; arcp = arcp -> arc_parentlist ) { parentp = arcp -> arc_parentp; if ( childp == parentp || ( childp->cycleno != 0 && parentp->cycleno == childp->cycleno ) ) { /* * selfcall or call among siblings */ printf( "%6.6s %5.5s %7.7s %11.11s %7d %7.7s " , "" , "" , "" , "" , arcp -> arc_count , "" ); printname( parentp ); printf( "\n" ); } else { /* * regular parent of child */ printf( "%6.6s %5.5s %7.2f %11.2f %7d/%-7d " , "" , "" , arcp -> arc_time / hz , arcp -> arc_childtime / hz , arcp -> arc_count , cycleheadp -> ncall ); printname( parentp ); printf( "\n" ); } } } printchildren( parentp ) nltype *parentp; { nltype *childp; arctype *arcp; sortchildren( parentp ); arcp = parentp -> children; for ( arcp = parentp -> children ; arcp ; arcp = arcp -> arc_childlist ) { childp = arcp -> arc_childp; if ( childp == parentp || ( childp->cycleno != 0 && childp->cycleno == parentp->cycleno ) ) { /* * self call or call to sibling */ printf( "%6.6s %5.5s %7.7s %11.11s %7d %7.7s " , "" , "" , "" , "" , arcp -> arc_count , "" ); printname( childp ); printf( "\n" ); } else { /* * regular child of parent */ printf( "%6.6s %5.5s %7.2f %11.2f %7d/%-7d " , "" , "" , arcp -> arc_time / hz , arcp -> arc_childtime / hz , arcp -> arc_count , childp -> cyclehead -> ncall ); printname( childp ); printf( "\n" ); } } } printname( selfp ) nltype *selfp; { if ( selfp -> name != 0 ) { printf( "%s" , selfp -> name ); # ifdef DEBUG if ( debug & DFNDEBUG ) { printf( "{%d} " , selfp -> toporder ); } if ( debug & PROPDEBUG ) { printf( "%5.2f%% " , selfp -> propfraction ); } # endif DEBUG } if ( selfp -> cycleno != 0 ) { printf( " <cycle %d>" , selfp -> cycleno ); } if ( selfp -> index != 0 ) { if ( selfp -> printflag ) { printf( " [%d]" , selfp -> index ); } else { printf( " (%d)" , selfp -> index ); } } } sortchildren( parentp ) nltype *parentp; { arctype *arcp; arctype *detachedp; arctype sorted; arctype *prevp; /* * unlink children from parent, * then insertion sort back on to sorted's children. * *arcp the arc you have detached and are inserting. * *detachedp the rest of the arcs to be sorted. * sorted arc list onto which you insertion sort. * *prevp arc before the arc you are comparing. */ sorted.arc_childlist = 0; for ( (arcp = parentp -> children)&&(detachedp = arcp -> arc_childlist); arcp ; (arcp = detachedp)&&(detachedp = detachedp -> arc_childlist)) { /* * consider *arcp as disconnected * insert it into sorted */ for ( prevp = &sorted ; prevp -> arc_childlist ; prevp = prevp -> arc_childlist ) { if ( arccmp( arcp , prevp -> arc_childlist ) != LESSTHAN ) { break; } } arcp -> arc_childlist = prevp -> arc_childlist; prevp -> arc_childlist = arcp; } /* * reattach sorted children to parent */ parentp -> children = sorted.arc_childlist; } sortparents( childp ) nltype *childp; { arctype *arcp; arctype *detachedp; arctype sorted; arctype *prevp; /* * unlink parents from child, * then insertion sort back on to sorted's parents. * *arcp the arc you have detached and are inserting. * *detachedp the rest of the arcs to be sorted. * sorted arc list onto which you insertion sort. * *prevp arc before the arc you are comparing. */ sorted.arc_parentlist = 0; for ( (arcp = childp -> parents)&&(detachedp = arcp -> arc_parentlist); arcp ; (arcp = detachedp)&&(detachedp = detachedp -> arc_parentlist)) { /* * consider *arcp as disconnected * insert it into sorted */ for ( prevp = &sorted ; prevp -> arc_parentlist ; prevp = prevp -> arc_parentlist ) { if ( arccmp( arcp , prevp -> arc_parentlist ) != GREATERTHAN ) { break; } } arcp -> arc_parentlist = prevp -> arc_parentlist; prevp -> arc_parentlist = arcp; } /* * reattach sorted arcs to child */ childp -> parents = sorted.arc_parentlist; } /* * print a cycle header */ printcycle( cyclep ) nltype *cyclep; { char kirkbuffer[ BUFSIZ ]; sprintf( kirkbuffer , "[%d]" , cyclep -> index ); printf( "%-6.6s %5.1f %7.2f %11.2f %7d" , kirkbuffer , 100 * ( cyclep -> propself + cyclep -> propchild ) / printtime , cyclep -> propself / hz , cyclep -> propchild / hz , cyclep -> ncall ); if ( cyclep -> selfcalls != 0 ) { printf( "+%-7d" , cyclep -> selfcalls ); } else { printf( " %7.7s" , "" ); } printf( " <cycle %d as a whole>\t[%d]\n" , cyclep -> cycleno , cyclep -> index ); } /* * print the members of a cycle */ printmembers( cyclep ) nltype *cyclep; { nltype *memberp; sortmembers( cyclep ); for ( memberp = cyclep -> cnext ; memberp ; memberp = memberp -> cnext ) { printf( "%6.6s %5.5s %7.2f %11.2f %7d" , "" , "" , memberp -> propself / hz , memberp -> propchild / hz , memberp -> ncall ); if ( memberp -> selfcalls != 0 ) { printf( "+%-7d" , memberp -> selfcalls ); } else { printf( " %7.7s" , "" ); } printf( " " ); printname( memberp ); printf( "\n" ); } } /* * sort members of a cycle */ sortmembers( cyclep ) nltype *cyclep; { nltype *todo; nltype *doing; nltype *prev; /* * detach cycle members from cyclehead, * and insertion sort them back on. */ todo = cyclep -> cnext; cyclep -> cnext = 0; for ( (doing = todo)&&(todo = doing -> cnext); doing ; (doing = todo )&&(todo = doing -> cnext )){ for ( prev = cyclep ; prev -> cnext ; prev = prev -> cnext ) { if ( membercmp( doing , prev -> cnext ) == GREATERTHAN ) { break; } } doing -> cnext = prev -> cnext; prev -> cnext = doing; } } /* * major sort is on propself + propchild, * next is sort on ncalls + selfcalls. */ int membercmp( this , that ) nltype *this; nltype *that; { double thistime = this -> propself + this -> propchild; double thattime = that -> propself + that -> propchild; long thiscalls = this -> ncall + this -> selfcalls; long thatcalls = that -> ncall + that -> selfcalls; if ( thistime > thattime ) { return GREATERTHAN; } if ( thistime < thattime ) { return LESSTHAN; } if ( thiscalls > thatcalls ) { return GREATERTHAN; } if ( thiscalls < thatcalls ) { return LESSTHAN; } return EQUALTO; } /* * compare two arcs to/from the same child/parent. * - if one arc is a self arc, it's least. * - if one arc is within a cycle, it's less than. * - if both arcs are within a cycle, compare arc counts. * - if neither arc is within a cycle, compare with * arc_time + arc_childtime as major key * arc count as minor key */ int arccmp( thisp , thatp ) arctype *thisp; arctype *thatp; { nltype *thisparentp = thisp -> arc_parentp; nltype *thischildp = thisp -> arc_childp; nltype *thatparentp = thatp -> arc_parentp; nltype *thatchildp = thatp -> arc_childp; double thistime; double thattime; # ifdef DEBUG if ( debug & TIMEDEBUG ) { printf( "[arccmp] " ); printname( thisparentp ); printf( " calls " ); printname ( thischildp ); printf( " %f + %f %d/%d\n" , thisp -> arc_time , thisp -> arc_childtime , thisp -> arc_count , thischildp -> ncall ); printf( "[arccmp] " ); printname( thatparentp ); printf( " calls " ); printname( thatchildp ); printf( " %f + %f %d/%d\n" , thatp -> arc_time , thatp -> arc_childtime , thatp -> arc_count , thatchildp -> ncall ); printf( "\n" ); } # endif DEBUG if ( thisparentp == thischildp ) { /* this is a self call */ return LESSTHAN; } if ( thatparentp == thatchildp ) { /* that is a self call */ return GREATERTHAN; } if ( thisparentp -> cycleno != 0 && thischildp -> cycleno != 0 && thisparentp -> cycleno == thischildp -> cycleno ) { /* this is a call within a cycle */ if ( thatparentp -> cycleno != 0 && thatchildp -> cycleno != 0 && thatparentp -> cycleno == thatchildp -> cycleno ) { /* that is a call within the cycle, too */ if ( thisp -> arc_count < thatp -> arc_count ) { return LESSTHAN; } if ( thisp -> arc_count > thatp -> arc_count ) { return GREATERTHAN; } return EQUALTO; } else { /* that isn't a call within the cycle */ return LESSTHAN; } } else { /* this isn't a call within a cycle */ if ( thatparentp -> cycleno != 0 && thatchildp -> cycleno != 0 && thatparentp -> cycleno == thatchildp -> cycleno ) { /* that is a call within a cycle */ return GREATERTHAN; } else { /* neither is a call within a cycle */ thistime = thisp -> arc_time + thisp -> arc_childtime; thattime = thatp -> arc_time + thatp -> arc_childtime; if ( thistime < thattime ) return LESSTHAN; if ( thistime > thattime ) return GREATERTHAN; if ( thisp -> arc_count < thatp -> arc_count ) return LESSTHAN; if ( thisp -> arc_count > thatp -> arc_count ) return GREATERTHAN; return EQUALTO; } } } printblurb( blurbname ) char *blurbname; { FILE *blurbfile; int input; blurbfile = fopen( blurbname , "r" ); if ( blurbfile == NULL ) { perror( blurbname ); return; } while ( ( input = getc( blurbfile ) ) != EOF ) { putchar( input ); } fclose( blurbfile ); } int namecmp( npp1 , npp2 ) nltype **npp1, **npp2; { return( strcmp( (*npp1) -> name , (*npp2) -> name ) ); } printindex() { nltype **namesortnlp; register nltype *nlp; int index, nnames, todo, i, j; char peterbuffer[ BUFSIZ ]; /* * Now, sort regular function name alphbetically * to create an index. */ namesortnlp = (nltype **) calloc( nname + ncycle , sizeof(nltype *) ); if ( namesortnlp == (nltype **) 0 ) { fprintf( stderr , "%s: ran out of memory for sorting\n" , whoami ); } for ( index = 0 , nnames = 0 ; index < nname ; index++ ) { if ( zflag == 0 && nl[index].ncall == 0 && nl[index].time == 0 ) continue; namesortnlp[nnames++] = &nl[index]; } qsort( namesortnlp , nnames , sizeof(nltype *) , namecmp ); for ( index = 1 , todo = nnames ; index <= ncycle ; index++ ) { namesortnlp[todo++] = &cyclenl[index]; } printf( "\f\nIndex by function name\n\n" ); index = ( todo + 2 ) / 3; for ( i = 0; i < index ; i++ ) { for ( j = i; j < todo ; j += index ) { nlp = namesortnlp[ j ]; if ( nlp -> printflag ) { sprintf( peterbuffer , "[%d]" , nlp -> index ); } else { sprintf( peterbuffer , "(%d)" , nlp -> index ); } if ( j < nnames ) { printf( "%6.6s %-19.19s" , peterbuffer , nlp -> name ); } else { printf( "%6.6s " , peterbuffer ); sprintf( peterbuffer , "<cycle %d>" , nlp -> cycleno ); printf( "%-19.19s" , peterbuffer ); } } printf( "\n" ); } cfree( namesortnlp ); }