/* * Copyright (c) 1983, 1993 * The Regents of the University of California. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #ifndef lint static const char copyright[] = "@(#) Copyright (c) 1983, 1993\n\ The Regents of the University of California. All rights reserved.\n"; #endif /* not lint */ #ifndef lint #if 0 static char sccsid[] = "@(#)gprof.c 8.1 (Berkeley) 6/6/93"; #endif static const char rcsid[] = "$FreeBSD$"; #endif /* not lint */ #include #include #include #include "gprof.h" static int valcmp(const void *, const void *); static struct gmonhdr gmonhdr; static int lflag; static int Lflag; main(argc, argv) int argc; char **argv; { char **sp; nltype **timesortnlp; char **defaultEs; --argc; argv++; debug = 0; bflag = TRUE; while ( *argv != 0 && **argv == '-' ) { (*argv)++; switch ( **argv ) { case 'a': aflag = TRUE; break; case 'b': bflag = FALSE; break; case 'C': Cflag = TRUE; cyclethreshold = atoi( *++argv ); break; case 'c': #if defined(vax) || defined(tahoe) cflag = TRUE; #else errx(1, "-c isn't supported on this architecture yet"); #endif break; case 'd': dflag = TRUE; setlinebuf(stdout); debug |= atoi( *++argv ); debug |= ANYDEBUG; # ifdef DEBUG printf("[main] debug = %d\n", debug); # else not DEBUG printf("gprof: -d ignored\n"); # endif DEBUG break; case 'E': ++argv; addlist( Elist , *argv ); Eflag = TRUE; addlist( elist , *argv ); eflag = TRUE; break; case 'e': addlist( elist , *++argv ); eflag = TRUE; break; case 'F': ++argv; addlist( Flist , *argv ); Fflag = TRUE; addlist( flist , *argv ); fflag = TRUE; break; case 'f': addlist( flist , *++argv ); fflag = TRUE; break; case 'k': addlist( kfromlist , *++argv ); addlist( ktolist , *++argv ); kflag = TRUE; break; case 'K': Kflag = TRUE; break; case 'l': lflag = 1; Lflag = 0; break; case 'L': Lflag = 1; lflag = 0; break; case 's': sflag = TRUE; break; case 'u': uflag = TRUE; break; case 'z': zflag = TRUE; break; } argv++; } if ( *argv != 0 ) { a_outname = *argv; argv++; } else { a_outname = A_OUTNAME; } if ( *argv != 0 ) { gmonname = *argv; argv++; } else { gmonname = (char *) malloc(strlen(a_outname)+6); strcpy(gmonname, a_outname); strcat(gmonname, ".gmon"); } /* * get information from the executable file. */ if ((Kflag && kernel_getnfile(a_outname, &defaultEs) == -1) || (elf_getnfile(a_outname, &defaultEs) == -1 && aout_getnfile(a_outname, &defaultEs) == -1)) errx(1, "%s: bad format", a_outname); /* * sort symbol table. */ qsort(nl, nname, sizeof(nltype), valcmp); /* * turn off default functions */ for ( sp = defaultEs ; *sp ; sp++ ) { Eflag = TRUE; addlist( Elist , *sp ); eflag = TRUE; addlist( elist , *sp ); } /* * get information about mon.out file(s). */ do { getpfile( gmonname ); if ( *argv != 0 ) { gmonname = *argv; } } while ( *argv++ != 0 ); /* * how many ticks per second? * if we can't tell, report time in ticks. */ if (hz == 0) { hz = 1; fprintf(stderr, "time is in ticks, not seconds\n"); } /* * dump out a gmon.sum file if requested */ if ( sflag ) { dumpsum( GMONSUM ); } /* * assign samples to procedures */ asgnsamples(); /* * assemble the dynamic profile */ timesortnlp = doarcs(); /* * print the dynamic profile */ if(!lflag) { printgprof( timesortnlp ); } /* * print the flat profile */ if(!Lflag) { printprof(); } /* * print the index */ printindex(); done(); } /* * information from a gmon.out file is in two parts: * an array of sampling hits within pc ranges, * and the arcs. */ getpfile(filename) char *filename; { FILE *pfile; FILE *openpfile(); struct rawarc arc; pfile = openpfile(filename); readsamples(pfile); /* * the rest of the file consists of * a bunch of tuples. */ while ( fread( &arc , sizeof arc , 1 , pfile ) == 1 ) { # ifdef DEBUG if ( debug & SAMPLEDEBUG ) { printf( "[getpfile] frompc 0x%lx selfpc 0x%lx count %ld\n" , arc.raw_frompc , arc.raw_selfpc , arc.raw_count ); } # endif DEBUG /* * add this arc */ tally( &arc ); } fclose(pfile); } FILE * openpfile(filename) char *filename; { struct gmonhdr tmp; FILE *pfile; int size; int rate; if((pfile = fopen(filename, "r")) == NULL) { perror(filename); done(); } fread(&tmp, sizeof(struct gmonhdr), 1, pfile); if ( s_highpc != 0 && ( tmp.lpc != gmonhdr.lpc || tmp.hpc != gmonhdr.hpc || tmp.ncnt != gmonhdr.ncnt ) ) { warnx("%s: incompatible with first gmon file", filename); done(); } gmonhdr = tmp; if ( gmonhdr.version == GMONVERSION ) { rate = gmonhdr.profrate; size = sizeof(struct gmonhdr); } else { fseek(pfile, sizeof(struct ophdr), SEEK_SET); size = sizeof(struct ophdr); gmonhdr.profrate = rate = hertz(); gmonhdr.version = GMONVERSION; } if (hz == 0) { hz = rate; } else if (hz != rate) { fprintf(stderr, "%s: profile clock rate (%d) %s (%ld) in first gmon file\n", filename, rate, "incompatible with clock rate", hz); done(); } if ( gmonhdr.histcounter_type == 0 ) { /* Historical case. The type was u_short (2 bytes in practice). */ histcounter_type = 16; histcounter_size = 2; } else { histcounter_type = gmonhdr.histcounter_type; histcounter_size = abs(histcounter_type) / CHAR_BIT; } s_lowpc = (unsigned long) gmonhdr.lpc; s_highpc = (unsigned long) gmonhdr.hpc; lowpc = (unsigned long)gmonhdr.lpc / HISTORICAL_SCALE_2; highpc = (unsigned long)gmonhdr.hpc / HISTORICAL_SCALE_2; sampbytes = gmonhdr.ncnt - size; nsamples = sampbytes / histcounter_size; # ifdef DEBUG if ( debug & SAMPLEDEBUG ) { printf( "[openpfile] hdr.lpc 0x%lx hdr.hpc 0x%lx hdr.ncnt %d\n", gmonhdr.lpc , gmonhdr.hpc , gmonhdr.ncnt ); printf( "[openpfile] s_lowpc 0x%lx s_highpc 0x%lx\n" , s_lowpc , s_highpc ); printf( "[openpfile] lowpc 0x%lx highpc 0x%lx\n" , lowpc , highpc ); printf( "[openpfile] sampbytes %d nsamples %d\n" , sampbytes , nsamples ); printf( "[openpfile] sample rate %ld\n" , hz ); } # endif DEBUG return(pfile); } tally( rawp ) struct rawarc *rawp; { nltype *parentp; nltype *childp; parentp = nllookup( rawp -> raw_frompc ); childp = nllookup( rawp -> raw_selfpc ); if ( parentp == 0 || childp == 0 ) return; if ( kflag && onlist( kfromlist , parentp -> name ) && onlist( ktolist , childp -> name ) ) { return; } childp -> ncall += rawp -> raw_count; # ifdef DEBUG if ( debug & TALLYDEBUG ) { printf( "[tally] arc from %s to %s traversed %ld times\n" , parentp -> name , childp -> name , rawp -> raw_count ); } # endif DEBUG addarc( parentp , childp , rawp -> raw_count ); } /* * dump out the gmon.sum file */ dumpsum( sumfile ) char *sumfile; { register nltype *nlp; register arctype *arcp; struct rawarc arc; FILE *sfile; if ( ( sfile = fopen ( sumfile , "w" ) ) == NULL ) { perror( sumfile ); done(); } /* * dump the header; use the last header read in */ if ( fwrite( &gmonhdr , sizeof gmonhdr , 1 , sfile ) != 1 ) { perror( sumfile ); done(); } /* * dump the samples */ if (fwrite(samples, histcounter_size, nsamples, sfile) != nsamples) { perror( sumfile ); done(); } /* * dump the normalized raw arc information */ for ( nlp = nl ; nlp < npe ; nlp++ ) { for ( arcp = nlp -> children ; arcp ; arcp = arcp -> arc_childlist ) { arc.raw_frompc = arcp -> arc_parentp -> value; arc.raw_selfpc = arcp -> arc_childp -> value; arc.raw_count = arcp -> arc_count; if ( fwrite ( &arc , sizeof arc , 1 , sfile ) != 1 ) { perror( sumfile ); done(); } # ifdef DEBUG if ( debug & SAMPLEDEBUG ) { printf( "[dumpsum] frompc 0x%lx selfpc 0x%lx count %ld\n" , arc.raw_frompc , arc.raw_selfpc , arc.raw_count ); } # endif DEBUG } } fclose( sfile ); } static int valcmp(v1, v2) const void *v1; const void *v2; { const nltype *p1 = (const nltype *)v1; const nltype *p2 = (const nltype *)v2; if ( p1 -> value < p2 -> value ) { return LESSTHAN; } if ( p1 -> value > p2 -> value ) { return GREATERTHAN; } return EQUALTO; } readsamples(pfile) FILE *pfile; { register i; intmax_t sample; if (samples == 0) { samples = (double *) calloc(nsamples, sizeof(double)); if (samples == 0) { warnx("no room for %d sample pc's", nsamples); done(); } } for (i = 0; i < nsamples; i++) { fread(&sample, histcounter_size, 1, pfile); if (feof(pfile)) break; switch ( histcounter_type ) { case -8: samples[i] += *(int8_t *)&sample; break; case 8: samples[i] += *(u_int8_t *)&sample; break; case -16: samples[i] += *(int16_t *)&sample; break; case 16: samples[i] += *(u_int16_t *)&sample; break; case -32: samples[i] += *(int32_t *)&sample; break; case 32: samples[i] += *(u_int32_t *)&sample; break; case -64: samples[i] += *(int64_t *)&sample; break; case 64: samples[i] += *(u_int64_t *)&sample; break; default: err(1, "unsupported histogram counter type %d", histcounter_type); } } if (i != nsamples) { warnx("unexpected EOF after reading %d/%d samples", --i , nsamples ); done(); } } /* * Assign samples to the procedures to which they belong. * * There are three cases as to where pcl and pch can be * with respect to the routine entry addresses svalue0 and svalue1 * as shown in the following diagram. overlap computes the * distance between the arrows, the fraction of the sample * that is to be credited to the routine which starts at svalue0. * * svalue0 svalue1 * | | * v v * * +-----------------------------------------------+ * | | * | ->| |<- ->| |<- ->| |<- | * | | | | | | * +---------+ +---------+ +---------+ * * ^ ^ ^ ^ ^ ^ * | | | | | | * pcl pch pcl pch pcl pch * * For the vax we assert that samples will never fall in the first * two bytes of any routine, since that is the entry mask, * thus we give call alignentries() to adjust the entry points if * the entry mask falls in one bucket but the code for the routine * doesn't start until the next bucket. In conjunction with the * alignment of routine addresses, this should allow us to have * only one sample for every four bytes of text space and never * have any overlap (the two end cases, above). */ asgnsamples() { register int j; double ccnt; double time; unsigned long pcl, pch; register int i; unsigned long overlap; unsigned long svalue0, svalue1; /* read samples and assign to namelist symbols */ scale = highpc - lowpc; scale /= nsamples; alignentries(); for (i = 0, j = 1; i < nsamples; i++) { ccnt = samples[i]; if (ccnt == 0) continue; pcl = lowpc + (unsigned long)(scale * i); pch = lowpc + (unsigned long)(scale * (i + 1)); time = ccnt; # ifdef DEBUG if ( debug & SAMPLEDEBUG ) { printf( "[asgnsamples] pcl 0x%lx pch 0x%lx ccnt %.0f\n" , pcl , pch , ccnt ); } # endif DEBUG totime += time; for (j = j - 1; j < nname; j++) { svalue0 = nl[j].svalue; svalue1 = nl[j+1].svalue; /* * if high end of tick is below entry address, * go for next tick. */ if (pch < svalue0) break; /* * if low end of tick into next routine, * go for next routine. */ if (pcl >= svalue1) continue; overlap = min(pch, svalue1) - max(pcl, svalue0); if (overlap > 0) { # ifdef DEBUG if (debug & SAMPLEDEBUG) { printf("[asgnsamples] (0x%lx->0x%lx-0x%lx) %s gets %f ticks %lu overlap\n", nl[j].value / HISTORICAL_SCALE_2, svalue0, svalue1, nl[j].name, overlap * time / scale, overlap); } # endif DEBUG nl[j].time += overlap * time / scale; } } } # ifdef DEBUG if (debug & SAMPLEDEBUG) { printf("[asgnsamples] totime %f\n", totime); } # endif DEBUG } unsigned long min(a, b) unsigned long a,b; { if (ab) return(a); return(b); } /* * calculate scaled entry point addresses (to save time in asgnsamples), * and possibly push the scaled entry points over the entry mask, * if it turns out that the entry point is in one bucket and the code * for a routine is in the next bucket. */ alignentries() { register struct nl *nlp; unsigned long bucket_of_entry; unsigned long bucket_of_code; for (nlp = nl; nlp < npe; nlp++) { nlp -> svalue = nlp -> value / HISTORICAL_SCALE_2; bucket_of_entry = (nlp->svalue - lowpc) / scale; bucket_of_code = (nlp->svalue + OFFSET_OF_CODE / HISTORICAL_SCALE_2 - lowpc) / scale; if (bucket_of_entry < bucket_of_code) { # ifdef DEBUG if (debug & SAMPLEDEBUG) { printf("[alignentries] pushing svalue 0x%lx to 0x%lx\n", nlp->svalue, nlp->svalue + OFFSET_OF_CODE / HISTORICAL_SCALE_2); } # endif DEBUG nlp->svalue += OFFSET_OF_CODE / HISTORICAL_SCALE_2; } } } done() { exit(0); }