home
***
CD-ROM
|
disk
|
FTP
|
other
***
search
/
Fresh Fish 7
/
FreshFishVol7.bin
/
bbs
/
gnu
/
binutils-1.8.x-src.lha
/
GNU
/
src
/
amiga
/
binutils-1.8.x
/
gprof.c
< prev
next >
Wrap
C/C++ Source or Header
|
1993-09-22
|
80KB
|
2,739 lines
/* `gprof', analyze gmon.out and print a profile.
Copyright (C) 1988 Free Software Foundation, Inc.
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 1, 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, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */
/* GNU gprof was written mainly by Jay Fenlason. */
#include <assert.h>
#include "getopt.h"
#ifdef __STDC__
#ifdef WYSE
#include <sys/types.h>
#else
#include "stddef.h"
#include "stdarg.h"
#endif /* WYSE */
#ifdef __GNUC__
#define alloca __builtin_alloca
#endif
#else /* no __STDC__ */
#ifdef sparc
#include "alloca.h"
#endif /* sparc */
#include "varargs.h"
#define const
typedef unsigned int size_t;
#endif /* no __STDC__ */
#undef NULL
#include <stdio.h>
#undef NULL
#define NULL 0
#if !defined(A_OUT) && !defined(MACH_O)
#define A_OUT
#endif
#ifdef A_OUT
#ifdef COFF_ENCAPSULATE
#include "a.out.encap.h"
#else
#include <a.out.h>
#endif
#endif
#ifdef MACH_O
#ifndef A_OUT
#include <nlist.h>
#ifndef N_TEXT
#define N_TEXT 0x04
#endif
#endif
#include <sys/loader.h>
#endif
#include "gmon.h"
/* #include <nlist.h> */
#ifdef USG
#define index strchr
#define bzero(s, n) (memset((s), 0, (n)))
#define bcopy(from, to, n) (memcpy ((to), (from), (n)))
#endif
/* Special macros designed to remove some __STDC__ ugliness from my source
files. Instead, I use these (which may be just as ugly. Instead of using
extern foo();
or
extern foo(int,double);
I use
extern foo FUN2(int, double);
which is expanded to the right thing depending on whether you're using an
ANSI cc or not.
Also, instead of saying
type
foo(x,y)
int x;
double y;
or
type
foo(int x, double y)
I use
type
foo FUN2(int, x, double, y)
Which is also expanded into the right thing. . .
*/
#ifdef __STDC__
#define var_start(x,y) va_start(x,y)
/* These macros expand into ANSI prototypes */
#define FUN0() (void)
#define EXT0() (void)
#define FUN1(t1,a1) (t1 a1)
#define EXT1(t1) (t1)
#define FUN1N(t1,a1) (t1 a1, ...)
#define EXT1N(t1) (t1, ...)
#define FUN2(t1,a1,t2,a2) (t1 a1,t2 a2)
#define EXT2(t1, t2) (t1, t2)
#define FUN2N(t1,a1,t2,a2) (t1 a1,t2 a2, ...)
#define EXT2N(t1, t2) (t1, t2, ...)
#define FUN3(t1,a1,t2,a2,t3,a3) (t1 a1, t2 a2, t3 a3)
#define EXT3(t1, t2, t3) (t1, t2, t3)
#define FUN3N(t1,a1,t2,a2,t3,a3)(t1 a1, t2 a2, t3 a3, ...)
#define EXT3N(t1, t2, t3) (t1, t2, t3, ...)
#define FUN4(t1,a1,t2,a2,t3,a3,t4,a4) (t1 a1, t2 a2, t3 a3, t4 a4)
#define EXT4(t1, t2, t3, t4) (t1, t2, t3, t4)
#define FUN5(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5) (t1 a1, t2 a2, t3 a3, t4 a4, t5 a5)
#define EXT5(t1, t2, t3, t4, t5) (t1, t2, t3, t4, t5)
#define FUN6(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6) (t1 a1, t2 a2, t3 a3, t4 a4, t5 a5, t6 a6)
#define EXT6(t1, t2, t3, t4, t5, t6) (t1, t2, t3, t4, t5, t6)
#define FUN7(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7) (t1 a1, t2 a2, t3 a3, t4 a4, t5 a5, t6 a6, t7 a7)
#define EXT7(t1, t2, t3, t4, t5, t6, t7) (t1, t2, t3, t4, t5, t6, t7)
#define FUN8(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8) (t1 a1, t2 a2, t3 a3, t4 a4, t5 a5, t6 a6, t7 a7, t8 a8)
#define EXT8(t1, t2, t3, t4, t5, t6, t7, t8) (t1, t2, t3, t4, t5, t6, t7, t8)
#define FUN9(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9) (t1 a1, t2 a2, t3 a3, t4 a4, t5 a5, t6 a6, t7 a7, t8 a8, t9 a9)
#define EXT9(t1, t2, t3, t4, t5, t6, t7, t8, t9) (t1, t2, t3, t4, t5, t6, t7, t8, t9)
#define FUN10(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9,t10,a10) (t1 a1, t2 a2, t3 a3, t4 a4, t5 a5, t6 a6, t7 a7, t8 a8, t9 a9, t10 a10)
#define EXT10(t1, t2, t3, t4, t5, t6, t7, t8, t9, t10) (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10)
#define FUN11(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9,t10,a10,t11,a11) (t1 a1, t2 a2, t3 a3, t4 a4, t5 a5, t6 a6, t7 a7, t8 a8, t9 a9, t10 a10, t11 a11)
#define EXT11(t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11) (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11)
#define FUN12(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9,t10,a10,t11,a11,t12,a12) (t1 a1, t2 a2, t3 a3, t4 a4, t5 a5, t6 a6, t7 a7, t8 a8, t9 a9, t10 a10, t11 a11, t12 a12)
#define EXT12(t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12) (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12)
#define FUN13(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9,t10,a10,t11,a11,t12,a12,t13,a13) (t1 a1, t2 a2, t3 a3, t4 a4, t5 a5, t6 a6, t7 a7, t8 a8, t9 a9, t10 a10, t11 a11, t12 a12, t13 a13)
#define EXT13(t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13) (t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13)
#else
/* Non-ANSI */
#define var_start(x,y) va_start(x)
/* These macros expand into old-style function definitions */
#define FUN0() ()
#define EXT0() ()
#define FUN1(t1,a1) (a1) t1 a1;
#define EXT1(t1) ()
#define FUN1N(t1,a1) (a1,va_alist) t1 a1; va_dcl
#define EXT1N(t1) ()
#define FUN2(t1,a1,t2,a2) (a1, a2) t1 a1; t2 a2;
#define EXT2(t1, t2) ()
#define FUN2N(t1,a1,t2,a2,va_alist) (a1, a2) t1 a1; t2 a2; va_dcl
#define EXT2N(t1, t2) ()
#define FUN3(t1,a1,t2,a2,t3,a3) (a1, a2, a3) t1 a1; t2 a2; t3 a3;
#define EXT3(t1, t2, t3) ()
#define FUN3N(t1,a1,t2,a2,t3,a3) (a1, a2, a3, va_alist) t1 a1; t2 a2; t3 a3; va_dcl
#define EXT3N(t1, t2, t3) ()
#define FUN4(t1,a1,t2,a2,t3,a3,t4,a4) (a1, a2, a3, a4) t1 a1; t2 a2; t3 a3; t4 a4;
#define EXT4(t1, t2, t3, t4) ()
#define FUN5(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5) (a1, a2, a3, a4, a5) t1 a1; t2 a2; t3 a3; t4 a4; t5 a5;
#define EXT5(t1, t2, t3, t4, t5) ()
#define FUN6(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6) (a1, a2, a3, a4, a5, a6) t1 a1; t2 a2; t3 a3; t4 a4; t5 a5; t6 a6;
#define EXT6(t1, t2, t3, t4, t5, t6) ()
#define FUN7(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7) (a1, a2, a3, a4, a5, a6, a7) t1 a1; t2 a2; t3 a3; t4 a4; t5 a5; t6 a6; t7 a7;
#define EXT7(t1, t2, t3, t4, t5, t6, t7) ()
#define FUN8(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8) (a1, a2, a3, a4, a5, a6, a7, a8) t1 a1; t2 a2; t3 a3; t4 a4; t5 a5; t6 a6; t7 a7; t8 a8;
#define EXT8(t1, t2, t3, t4, t5, t6, t7, t8) ()
#define FUN9(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9) (a1, a2, a3, a4, a5, a6, a7, a8, a9) t1 a1; t2 a2; t3 a3; t4 a4; t5 a5; t6 a6; t7 a7; t8 a8; t9 a9;
#define EXT9(t1, t2, t3, t4, t5, t6, t7, t8, t9) ()
#define FUN10(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9,t10,a10) (a1, a2, a3, a4, a5, a6, a7, a8, a9, a10) t1 a1; t2 a2; t3 a3; t4 a4; t5 a5; t6 a6; t7 a7; t8 a8; t9 a9; t10 a10;
#define EXT10(t1, t2, t3, t4, t5, t6, t7, t8, t9, t10) ()
#define FUN11(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9,t10,a10,t11,a11) (a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11) t1 a1; t2 a2; t3 a3; t4 a4; t5 a5; t6 a6; t7 a7; t8 a8; t9 a9; t10 a10; t11 a11;
#define EXT11(t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11) ()
#define FUN12(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9,t10,a10,t11,a11,t12,a12) (a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11, a12) t1 a1; t2 a2; t3 a3; t4 a4; t5 a5; t6 a6; t7 a7; t8 a8; t9 a9; t10 a10; t11 a11; t12 a12;
#define EXT12(t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12) ()
#define FUN13(t1,a1,t2,a2,t3,a3,t4,a4,t5,a5,t6,a6,t7,a7,t8,a8,t9,a9,t10,a10,t11,a11,t12,a12,t13,a13) (a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11, a12, a13) t1 a1; t2 a2; t3 a3; t4 a4; t5 a5; t6 a6; t7 a7; t8 a8; t9 a9; t10 a10; t11 a11; t12 a12; t13 a13;
#define EXT13(t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11, t12, t13) ()
#endif
#if !defined HAVE_VPRINTF
/* The following will work for some systems. */
#define vfprintf(stream, format, ap) _doprnt (format, ap, stream)
int
vsprintf FUN3(char *, into, char *, s, va_list, ap)
{
int ret;
auto FILE f;
f._cnt = 32767;
/* taking address and dereferencing deals with the fact that
f._ptr can be either a char * or an unsigned char *. */
*(char **)&f._ptr = into;
f._flag = _IOWRT+_IOSTRG;
ret = _doprnt(s, ap, &f);
*f._ptr = 0;
return (ret);
}
#endif
/* Names or default names for various files. */
#define OBJ_NAM "a.out"
#define MON_NAM "gmon.out"
#define SUM_NAM "gmon.sum"
/* Debugging stuff */
#define DEBUG
/* A mask of flags defined below. */
long debug=0;
/* Print obnoxious msgs about the a.out file, and the amusing values therein */
#define DB_AFILE (1<<0) /* a.out file */
/* Describe in detail the rending and tearing of the gmon.out file */
#define DB_GFILE (1<<1) /* gmon.out file */
/* Describe in detail the writing out of the gmon.sum file */
#define DB_SUM (1<<2) /* gmon.sum file */
/* Print neeto messages as we deal with -e -E -f and -F options */
#define DB_OPT (1<<3) /* Options */
/* Print msgs whenever the ring buffer is used */
/* This probably doesn't work since the ring buffer code was
moved into the utilities file */
#define DB_RB (1<<4) /* Ring buffer */
/* Print msgs about cycles */
#define DB_CYC (1<<5)
/* Print msgs about assigning the histogram entries to functions */
#define DB_HISTO (1<<6)
/* Print obnoxious msgs here and there as we do our stuff */
#define DB_MISC (1<<31) /* misc stuff */
#ifdef DEBUG
#define PRINT_OBNOXIOUS_DEBUG_MESSAGE(x, msg) if (debug&x) dbgprintf msg
#else
#define PRINT_OBNOXIOUS_DEBUG_MESSAGE(x, msg)
#endif
/* LessThan EQual GreaterThan */
/* These get returned by the various comparison functions */
#define LT (-1)
#define EQ (0)
#define GT (1)
/* Note since *ALL* non-zero values are true, do *NOT* say
if (x==TRUE)
These values are here only for saying
return TRUE;
and things like that. */
#define TRUE (1)
#define FALSE (0)
/* The floating point datatype to use for storing
propagated info. Float should be big enough */
#define FLOAT double
/* Used when creating a gmon.sum file */
/* #define FUDGE_FACTOR (sizeof (CHUNK)) */
#define FUDGE_FACTOR 0
/* Description of one symbol in gprof's internal symbol table.
There is one of these for each function and one for each cycle.
NAME is the name of the function or cycle.
VALUE is the address of the start of the function.
CALLS and CALLED are chains of edges for calls into and out of
this function. These constitute the call graph.
NCALLS is the total number
of times this function called other functions,
NCALLED is the total number of times this function was called.
Note that if NCALLED is zero, but NCALLS is nozero, this function
must have been started magically. It happens. (Signals, etc.)
RECURSIVE is the total number of times this function was called
recursively.
HISTO is the total number of histogram counts for this function.
SUB_HISTO is the total number of histogram counts for this function
plus time propagated from the children.
CYCNUM is the number of the cycle this function is in,
or the number of this cycle is this entry is for a cycle.
-1 means the function isn't in any cycles. 0 means the
cycle-ness of the function hasn't been determined yet.
NUMINDEX is the index number assigned to this function
for the call graph.
If FLAG is non-zero, this function is in the process of being
saved from the oblivion caused by the -f or -F options. */
struct mesym {
char *name;
unsigned long value;
struct symlist *calls;
unsigned ncalls;
struct symlist *called;
unsigned ncalled;
unsigned recursive;
unsigned histo;
FLOAT sub_histo;
int cycnum;
int numindex;
int flag;
};
/* Vector of `struct mesym' for all functions,
sorted in ascending order by VALUE field for binary search. */
struct mesym *syms;
int nsym=0; /* Length of vector */
/* Vector of `struct mesym' for all cycles so far identified. */
struct mesym **cycles;
int number_of_cycles = 0; /* Length of vector */
/* Structure for an edges of the call graph.
Each edge--each pair of functions A and B such that A called B--
is represented by one of these structures. It appears in
A's `calls' chain and in B's `called' chain.
Meanwhile, the structure describes its meaning with the
SYM_FROM and SYM_TO fields, which point to the symbol entries
for A and B.
Basically, if you got here from a mesym's calls
pointer, SYM_FROM points back to that symbol, NEXT_FROM is irrevelant,
SYM_TO points to the symbol it called, and NEXT_TO points to the
next one in the list.
If you got here from a mesym's called pointer, SYM_FROM points to
the symbol that called it, NEXT_FROM points to the next one in the
list, SYM_TO points back to the symbol, and NEXT_TO is irrelevant.
NCALLS is the number of times SYM_FROM called SYM_TO,
PROP_TIME is the amount of time in SYM_TO itself propagated to SYM_FROM,
CHILD_TIME is the amount of time
propagated from SYM_TO's children to SYM_FROM. */
struct symlist {
struct mesym *sym_from;
struct symlist *next_from;
struct mesym *sym_to;
struct symlist *next_to;
unsigned ncalls;
FLOAT prop_time;
FLOAT child_time;
};
/* argv[0], here for the sake of error messages. */
char *myname = 0;
/* Name of the executable file. */
char *exec_file_name;
/* The string table of the executable file.
Each symbol entry in the file contains an index in the string table.
When the symbols are in core, we relocate them to point to their names,
which remain inside the string table. */
char *strs;
/* Header of the first gmon.out file we read. This is used to (try to)
make sure all the rest of the gmon.out files agree with the first one
(and the executable.) */
struct gm_header hdr;
/* Number of clock ticks per second. Read from the kernel's memory,
this number tells us how long an interval a single stab in the
histogram represents. */
long ticks;
/* This is an array of pointers to symbols. These are the functions that
we'll have to print out in the flat graph. */
struct mesym **flat_profile_functions;
int number_of_flat_profile_functions = 0; /* Size of vector */
/* This is an array of pointers to symbols. These are the functions that
we should mention in the call tree. */
struct mesym **functions_in_call_tree;
int number_of_functions_in_call_tree= 0;
struct mesym **f_end;
/* Number of slots in the histogram. */
int nhist;
/* Total number of counts in the histogram. */
unsigned long tothist = 0;
/* Pointer to the histogram itself. */
unsigned CHUNK *histo; /* Stabs */
/* Now that I've re-written the ring_buffer code, we need this */
void *ring_buffer;
/* Record the specified options. */
/* If the -a option is given, static (private) functions are not read into
the symbol table. This means that time spent in them, calls to them, etc,
are instead added to whatever function was loaded next to it in the a.out
file. This is compatable with UN*X gprof. (Bleh.) The right thing to do
is keep track of time spent in static functions, and forget about it,
instead of adding it to another hapless function. Rms disagrees with me.
I think its evil to add histogram time to a function simply because it
happend to be loaded in memory just before a function we don't want to print. */
int no_locals = 0; /* -a flag */
/* The -b option tells gprof to not print out the obnoxious blurbs telling
what all the fields of the output mean. This is useful if you've seen
the blurbs a gzillion times and you only want to look at your numbers. */
int no_blurbs = 0; /* -b flag */
/* If the -s option is given, gprof will write out a 'sum file' gmon.sum
which is a gmon.out file that contains the profile info from all the
gmon.out files that gprof read in. */
int write_sum_file = 0; /* -s option */
/* The -z option tells gprof to include functions with zero usage (never called,
and used no time) in the output. Usually, such functions are considered
boring, and aren't printed. */
int print_zeros = 0; /* -z option */
/* The -e option takes a function name, and suppress the printing of that
function and its descendents from the call graph profile. (If its
descendents are called from elswhere, well. . .) (Currently, they're
printed, and the -e'd function is shown under the list of parents so
you can see where the child's time is disappearing to. . .)
The -E option takes a function name, and not only -e's it, but
removes the time spent in the function from the total time. (Its as if
that function never existed (unless it calls something that is also
called from somewhere else, in which case. . . (Currently it works
as described for -e above.))
-f prints only the call tree for its argument.
-F is like -f, but it uses only the time in the function and its
descendents for computing total time.
*/
enum option_type { SMALL_E, BIG_E, SMALL_F, BIG_F,
/* Like BIG_E except don't print a warning if the
function doesn't exist. */
REMOVE_TIME_IF_THERE };
struct filter {
char *name;
enum option_type type;
};
/* Vector with an element for each -e, -E, -f or -F option specified. */
struct filter *filters;
/* Length of the vector. */
int nfilters;
/* These values are stored in the flag field of a struct mesym so we can know
what we're doing to that function */
/* This one is being saved by a -f or -F flag */
#define SAVE_ME 01
/* This one is being killed by a -e or -E flag */
#define KILL_ME 02
/* Blurbs that are copied verbatim into the output file
to explain the data in the tables.
If your compiler can't stand this, split this up into a vector
of strings, and print them one after another. */
char *first_blurb = "\n\
The above table shows how much time was spent directly in each\n\
function. The table was sorted by the amount of time the computer\n\
spent in each function.\n\n\
% time This is the percentage of the total execution time\n\
the program spent in this function. These should all add\n\
up to 100%.\n\n\
seconds This is the total number of seconds the computer spent\n\
executing this function.\n\n\
cumsec This is the cumulative total number of seconds the\n\
computer spent executing this functions, plus the time spent\n\
in all the functions above this one in this table.\n\n\
calls This is the total number of times the function was called.\n\
If there isn't a number here, the function wasn't compiled with\n\
the profiler enabled, and further information about this function\n\
is limited. In particular, all information about where this \n\
function was called from has been lost.\n\n\
function This is the name of the function.\n\
\f";
char *second_blurb = "\n\
This table describes the call tree of the program, and was sorted by\n\
the total amount of time spent in each function and its children.\n\n\
Each entry in this table consists of several lines. The line with the\n\
index number at the left hand margin lists the current function.\n\
The lines above it list the functions that called this function,\n\
and the lines below it list the functions this one called.\n\
This line lists:\n\
index A unique number given to each element of the table.\n\
Index numbers are sorted numerically.\n\
The index number is printed next to every function name so\n\
it is easier to look up where the function in the table.\n\n\
% time This is the percentage of the `total' time that was spent\n\
in this function and its children. Note that due to\n\
different viewpoints, functions excluded by options, etc,\n\
these numbers will NOT add up to 100%.\n\n\
self This is the total amount of time spent in this function.\n\n\
children This is the total amount of time propagated into this\n\
function by its children.\n\n\
called This is the number of times the function was called.\n\
If the function called itself recursively, the number\n\
only includes non-recursive calls, and is followed by\n\
a `+' and the number of recursive calls.\n\n\
name The name of the current function. The index number is\n\
printed after it. If the function is a member of a\n\
cycle, the cycle number is printed between the\n\
function's name and the index number.\n\n\n\
For the function's parents, the fields have the following meanings:\n\n\
self This is the amount of time that was propagated directly\n\
from the function into this parent.\n\n\
children This is the amount of time that was propagated from\n\
the function's children into this parent.\n\n\
called This is the number of times this parent called the\n\
function `/' the total number of times the function\n\
was called. Recursive calls to the function are not\n\
included in the number after the `/'.\n\n\
name This is the name of the parent. The parent's index\n\
number is printed after it. If the parent is a\n\
member of a cycle, the cycle number is printed between\n\
the name and the index number.\n\n\
If the parents of the function cannot be determined, the word\n\
`<spontaneous>' is printed in the `name' field, and all the other\n\
fields are blank.\n\n\
For the function's children, the fields have the following meanings:\n\n\
self This is the amount of time that was propagated directly\n\
from the child into the function.\n\n\
children This is the amount of time that was propagated from the\n\
child's children to the function.\n\n\
called This is the number of times the function called\n\
this child `/' the total number of times the child\n\
was called. Recursive calls by the child are not\n\
listed in the number after the `/'.\n\n\
name This is the name of the child. The child's index\n\
number is printed after it. If the child is a\n\
member of a cycle, the cycle number is printed\n\
between the name and the index number.\n\n\
If there are any cycles (circles) in the call graph, there is an\n\
entry for the cycle-as-a-whole. This entry shows who called the\n\
cycle (as parents) and the members of the cycle (as children.)\n\
The `+' recursive calls entry shows the number of function calls that\n\
were internal to the cycle, and the calls entry for each member shows,\n\
for that member, how many times it was called from other members of\n\
the cycle.\n\n";
/* Prototypes for all the functions. */
int main EXT2(int, char **);
int read_header_info EXT6 (char *, FILE *, long int *, unsigned int *,
long int *, unsigned int *);
void print_flat_profile EXT0();
void print_call_graph EXT0();
void write_summary EXT0();
void filter_graph EXT0();
FLOAT convert_and_round EXT1(FLOAT);
void add_to_lists EXT3(struct mesym *, struct mesym *, unsigned);
void delete_from_lists EXT2(struct mesym*, struct mesym *);
void flushfuns EXT0();
void findcycles EXT0();
void kill_children EXT2(struct mesym *, int);
void save_the_children EXT2(struct mesym *, int);
void remove_from_call_tree EXT1(struct mesym **);
struct mesym **find_funp_from_name EXT1(char *);
struct mesym **find_funp_from_pointer EXT1(struct mesym *);
void read_syms EXT2(FILE *, int);
struct mesym *val_to_sym EXT1(unsigned long);
int badsym EXT1(struct nlist *);
int symcmp EXT2(const void *, const void *);
int timecmp EXT2(const void *, const void *);
int callcmp EXT2(const void *, const void *);
int treetimecmp EXT2(const void *, const void *);
int listcmp EXT2(const void *, const void *);
void readgm EXT1(char *);
void print_blurb EXT1(char *blurb);
long get_ticks EXT0();
void add_filter EXT2(char *name, int flag);
void print_sorted_list EXT3(int, int, struct symlist *);
void fatal EXT1N(char *);
void fatal_io EXT2(char *, char *);
FILE *ck_fopen EXT2(char *, char *);
void ck_fseek EXT3(FILE *, long, int);
void ck_fread EXT4(void *, size_t, size_t, FILE *);
void ck_fwrite EXT4(void *, size_t, size_t, FILE *);
void ck_fclose EXT1(FILE *);
void *ck_malloc EXT1(size_t);
void *ck_calloc EXT2(size_t, size_t);
void *ck_realloc EXT2(void *, size_t);
char *mk_sprintf EXT1N(char *);
void *init_ring_buffer EXT0();
void push_ring_buffer EXT2(void *, void *);
void *pop_ring_buffer EXT1(void *);
int ring_buffer_isnt_empty EXT1(void *);
void flush_ring_buffer EXT1(void *);
/* C++ demangler stuff. */
char *cplus_demangle EXT1(char *);
void fprint_name EXT2(FILE *, char *);
void fatal EXT1N(char *);
void *malloc EXT1(size_t);
void *realloc EXT2(void *,size_t);
void free EXT1(void *);
/* Since we don't have prototypes for the system funs, we add them
ourselves. . . */
int atoi EXT1(const char *);
long atol EXT1(const char *);
double atof EXT1(const char *);
#ifndef NeXT /* NeXT has a bug in their include files. */
void qsort EXT4(void *, size_t, size_t, int (*)(const void *, const void *));
#endif
void exit EXT1(int);
int strcmp EXT2(const char *, const char *);
char *index EXT2(const char *, int);
int printf EXT1N(const char *);
int fprintf EXT2N(FILE *, const char *);
/* char *sprintf EXT2N(const char *, const char *); */
int puts EXT1(const char *);
int fputs EXT2(const char *, FILE *);
int fputc EXT2(int, FILE *);
size_t fread EXT4(void *, size_t, size_t, FILE *);
int nlist EXT2(const char *, struct nlist *);
#if defined HAVE_VPRINTF
int vfprintf EXT3(FILE *, const char *, va_list);
#endif
void dbgprintf EXT1N(char *);
void dumpsyms EXT0();
void dumpfuns EXT0();
/* And now, the program. */
int
main FUN2(int, ac, char **,av)
{
FILE *fp;
int argc;
char **argv;
int c;
long int syms_offset, strs_offset;
unsigned int syms_size, strs_size;
extern char *optarg;
extern int optind, opterr;
static struct option long_options[] =
{
{"no-static", 0, &no_locals, 1},
{"brief", 0, &no_blurbs, 1},
{"no-prof", 1, 0, 'e'},
{"no-time", 1, 0, 'E'},
{"only-prof", 1, 0, 'f'},
{"only-time", 1, 0, 'F'},
{"sum", 0, &write_sum_file, 1},
{"zeros", 0, &print_zeros, 1},
{NULL, 0, NULL, 0}
};
char *name = '\0';
int ind;
argc=ac;
argv=av;
myname= argv[0];
/* Omit profiling internal functions from call graph. */
#ifdef sparc
#else
add_filter ("mcount", BIG_E);
#endif
/* add_filter ("mcleanup", BIG_E); Seems to have dissappeared? */
/* GCC output doesn't have this function. */
add_filter ("moncontrol", REMOVE_TIME_IF_THERE);
ring_buffer=init_ring_buffer ();
while ((c = getopt_long (argc, argv, "abcdD:e:E:f:F:svz", long_options,
&ind)) !=EOF) {
if (c == 0 && long_options[ind].flag == 0)
c = long_options[ind].val;
switch (c) {
case 0 :
break;
case 'a':
no_locals= TRUE;
break;
case 'b':
no_blurbs = TRUE;
break;
case 'c':
fatal ("The -c option is not supported");
case 'd':
debug= -1;
break;
case 'D':
debug=atoi (optarg);
break;
case 's':
write_sum_file= TRUE;
break;
case 'z':
print_zeros = TRUE;
break;
case 'e':
add_filter (optarg, SMALL_E);
break;
case 'E':
add_filter (optarg, BIG_E);
break;
case 'f':
add_filter (optarg, SMALL_F);
break;
case 'F':
add_filter (optarg, BIG_F);
break;
default:
fprintf (stderr, "\
Usage: %s [-absz] [-e func] [-E func] [-f func] [-F func]\n\
[+no-static] [+brief] [+no-prof func]\n\
[+no-time func] [+only-prof func]\n\
[+only-time func] [+sum] [+zeros] executable gmon.out...\n",
myname);
exit (1);
}
}
if (optind<argc) {
exec_file_name=argv[optind];
optind++;
}
if (!exec_file_name)
exec_file_name=OBJ_NAM;
/* Open the a.out file, and read in selected portions */
fp=ck_fopen (exec_file_name, "r");
/* Make sure its really an a.out file. If it isn't yell and scream
and stamp our feet. */
if (!read_header_info(exec_file_name, fp, &syms_offset, &syms_size, &strs_offset, &strs_size))
fatal ("`%s' is not an executable file", exec_file_name);
/* Read in the string table. */
ck_fseek (fp, strs_offset + sizeof strs_size, 0);
strs=(char *)ck_malloc (strs_size);
ck_fread ((void *)(strs+sizeof (long)), sizeof (char), strs_size-sizeof (long), fp);
/* Read the symbols, and put the interesting ones (sorted) in SYMS. */
ck_fseek (fp, syms_offset, 0);
read_syms (fp, syms_size / sizeof (struct nlist));
ck_fclose (fp);
/* We are done with the a.out file */
/* Read in the gmon.out files; accumulate all histogram data in HISTO
and put all number-of-calls figures into the call graph. */
if (optind>=argc) readgm (MON_NAM);
else {
while (optind<argc) {
readgm (argv[optind]);
optind++;
}
}
/* If a summary output file is wanted,
we can do it straightaway since we have merged the data. */
if (write_sum_file) {
write_summary ();
exit (0);
}
/* Find out how many clock ticks/second our machine puts out */
ticks=get_ticks ();
/* Assign the ticks in the histogram to the functions they represent */
{
int n;
unsigned long pos;
struct mesym *sym;
int incr = (hdr.high - hdr.low) / nhist;
if ((hdr.high - hdr.low) != 4 * nhist)
abort ();
for (n=0, pos=hdr.low, sym= &syms[0]; n<nhist; n++, pos+=incr) {
if (histo[n]) {
/* We've found the right symbol when *sym<=pos && *(sym+1)>pos */
/* This means POS lies between sym and the one after it */
while ((sym+1)->value<=pos)
sym++;
if ((sym+1)->value<(pos+incr))
{
/* Wow! On the edge. Split the time between the symbols */
sym->histo+=(histo[n]+1)/2;
(sym+1)->histo+=(histo[n])/2;
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_HISTO, ("%05lx %02d-> %s (%d) %s (%d)\n", pos, histo[n], sym->name, sym->histo, (sym+1)->name, (sym+1)->histo));
} else {
sym->histo+=histo[n];
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_HISTO, ("%05lx %02d-> %s (%d)\n", pos, histo[n], sym->name, sym->histo));
}
}
}
}
/* Avoid division by zero if there wasn't any time collected! */
if (tothist==0)
tothist=1;
print_flat_profile ();
print_call_graph ();
if (debug&DB_AFILE)
dumpsyms ();
if (debug&DB_AFILE)
dumpfuns ();
exit (0);
}
/* Read various information from the header of an object file.
Return 0 for failure or 1 for success. */
int
read_header_info (name, fp, syms_offset, syms_size, strs_offset, strs_size)
char *name;
FILE *fp;
long int *syms_offset;
unsigned int *syms_size;
long int *strs_offset;
unsigned int *strs_size;
{
#ifdef A_OUT
{
struct exec hdr;
ck_fseek (fp, 0L, 0);
#ifdef HEADER_SEEK
HEADER_SEEK (fp);
#endif
if (fread ((char *) &hdr, sizeof hdr, 1, fp) == 1 && !N_BADMAG(hdr))
{
*syms_offset = N_SYMOFF (hdr);
*syms_size = hdr.a_syms;
*strs_offset = N_STROFF (hdr);
ck_fseek (fp, N_STROFF (hdr), 0);
if (fread ((char *) strs_size, sizeof *strs_size, 1, fp) != 1)
fatal ("error reading string table of `%s'", name);
return 1;
}
}
#endif
#ifdef MACH_O
{
struct mach_header mach_header;
struct load_command *load_command;
struct symtab_command *symtab_command;
char *hdrbuf;
int cmd, symtab_seen;
ck_fseek (fp, 0L, 0);
if (fread ((char *) &mach_header, sizeof mach_header, 1, fp) == 1
&& mach_header.magic == MH_MAGIC)
{
hdrbuf = ck_malloc (mach_header.sizeofcmds);
if (fread (hdrbuf, mach_header.sizeofcmds, 1, fp) != 1)
fatal ("failure reading load commands of file `%s'", name);
load_command = (struct load_command *) hdrbuf;
symtab_seen = 0;
for (cmd = 0; cmd < mach_header.ncmds; ++cmd)
{
if (load_command->cmd == LC_SYMTAB)
{
symtab_seen = 1;
symtab_command = (struct symtab_command *) load_command;
*syms_offset = symtab_command->symoff;
*syms_size = symtab_command->nsyms * sizeof (struct nlist);
*strs_offset = symtab_command->stroff;
*strs_size = symtab_command->strsize;
}
load_command = (struct load_command *) ((char *) load_command + load_command->cmdsize);
}
free (hdrbuf);
if (!symtab_seen)
*syms_offset = *syms_size = *strs_offset = *strs_size = 0;
return 1;
}
}
#endif
return 0;
}
/* Output a summary gmon file containing all our accumulated
histogram and call-graph data. */
void
write_summary FUN0()
{
struct mesym *p;
struct symlist *t;
struct gm_call call_tmp;
FILE *fp;
fp=ck_fopen (SUM_NAM, "w");
hdr.nbytes=sizeof (struct gm_header)+nhist*sizeof (CHUNK);
ck_fwrite ((void *)&hdr, sizeof (hdr), 1, fp);
ck_fwrite ((void *)histo, sizeof (unsigned CHUNK), nhist, fp);
/* for (p= &syms[nsym]; --p>=&syms[0];) { */
if (nsym) {
p= &syms[nsym-1];
do {
for (t=p->calls; t; t=t->next_to) {
/* Since we've forgotten exactly where in FROM we
were called from, we fake it. Since this is only
gonna be fed back into gprof, it doesn't matter */
call_tmp.from=(p->value+FUDGE_FACTOR)-hdr.low;
call_tmp.to=(t->sym_to->value+FUDGE_FACTOR)-hdr.low;
call_tmp.ncalls=t->ncalls;
ck_fwrite ((void *)&call_tmp, sizeof (call_tmp), 1, fp);
}
} while (p-->&syms[0]);
}
ck_fclose (fp);
}
/* Print the flat profile from the symbol table information. */
void
print_flat_profile FUN0()
{
int n;
struct mesym **funp;
/* Scan the symbol table and discover how many functions either had time
spent in them, or had a non-zero call count */
for (n=0; n<nsym; n++) {
if (syms[n].histo || syms[n].ncalled || print_zeros)
number_of_flat_profile_functions++;
}
/* Collect all the interesting functions */
flat_profile_functions
=(struct mesym **)ck_calloc (number_of_flat_profile_functions, sizeof (struct mesym *));
for (n=0, funp=flat_profile_functions; n<nsym; n++) {
if (syms[n].histo || syms[n].ncalled || print_zeros) {
*funp= &syms[n];
funp++;
}
}
/* Sort them */
qsort (flat_profile_functions, number_of_flat_profile_functions,
sizeof (struct mesym *), timecmp);
/* And print them out */
if (no_blurbs)
printf ("\t\tFlat profile\n\n");
else
printf ("\tFlat profile (explanation follows)\n\n");
if (no_blurbs)
printf ("\t\tCall graph is on the following page.\n\n");
else
printf ("\tCall graph is on the following page.\n\n");
printf ("Each sample counts as %g seconds.\n\n", 1.0/ticks);
puts ("% time seconds cumsec calls function");
for (n=0; n<number_of_flat_profile_functions; n++) {
unsigned histo;
static cumhist = 0;
histo=flat_profile_functions[n]->histo;
cumhist+=histo;
printf ("%6.2f ", (FLOAT)(100.0*histo)/(FLOAT)tothist);
printf ("%8.2f ", ((FLOAT)histo)/(FLOAT)ticks);
printf ("%8.2f ", ((FLOAT)cumhist)/(FLOAT)ticks);
if (flat_profile_functions[n]->ncalled)
printf (" %5d ", flat_profile_functions[n]->ncalled);
else fputs (" ", stdout);
fprint_name (stdout, flat_profile_functions[n]->name);
fputs ("\n", stdout);
}
/* RMS says we should print the blurb last, which makes sense to me */
print_blurb (first_blurb);
}
/* Compute the call graph and print it. */
void
print_call_graph FUN0()
{
int n;
int index;
struct mesym **funp;
struct mesym **f;
/* Count the functions that appear in the call tree. */
for (n=0; n<nsym; n++) {
/* If a function calls something else, or is called by
something else, its in the call tree. . . */
if (syms[n].ncalls || syms[n].ncalled)
number_of_functions_in_call_tree++;
}
if (number_of_functions_in_call_tree == 0) {
printf ("\t\tNo call graph information available.\n");
return;
}
/* Allocate a vector of these functions. */
functions_in_call_tree
=(struct mesym **)ck_calloc (number_of_functions_in_call_tree, sizeof (struct mesym *));
for (n=0, funp=functions_in_call_tree; n<nsym; n++) {
if (syms[n].ncalls || syms[n].ncalled) {
*funp= &syms[n];
funp++;
}
}
/* Put all the leaf nodes at the end of the call tree */
qsort (functions_in_call_tree, number_of_functions_in_call_tree, sizeof (struct mesym *), callcmp);
/* Root nodes are now all at the head, and can be easily found
'cuz they have call-counts of zero (Never been called, but
calls something else; that's spontaneous in my book.) */
/* Ordinary nodes are in the middle, (were called, and
called others. Leaf nodes are at the end. */
/* Our mission, should we choose to accept it, is to detect
circles in the call graph. */
/* We do this by keeping a pointer into the call tree called f_end. This
points to the end of the functions that we don't know if they are leaf
nodes or not. When we know something is a leaf node, we move it down
past f_end */
f= &functions_in_call_tree[number_of_functions_in_call_tree-1];
do {
if ((*f)->ncalls!=0)
break;
(*f)->cycnum= -1;
/* Note the neeto side effect here! Is there a better way to do this? */
} while (f-- > &functions_in_call_tree[0]);
/* Note that functions that only call themselves (and nobody else) don't
get marked above. Doesn't matter; they get marked soon. */
if (f== &functions_in_call_tree[0]) {
(*f)->cycnum= -1;
} else {
int found;
f_end=f;
/* Eliminate recursive calls */
do {
struct symlist *t, *u;
for (t= (*f)->calls; t; t=t->next_to) {
if (t->sym_to!= (*f))
continue;
(*f)->recursive+=t->ncalls;
(*f)->ncalls-=t->ncalls;
(*f)->ncalled-=t->ncalls;
/* Delete from linked list */
if (t==(*f)->calls)
(*f)->calls=t->next_to;
else {
for (u=(*f)->calls; u->next_to!=t; u=u->next_to)
;
u->next_to=t->next_to;
}
/* Find and delete from called list too */
if (t==(*f)->called)
(*f)->called=t->next_from;
else {
for (u=(*f)->called; u->next_from!=t; u=u->next_from)
;
u->next_from=t->next_from;
}
free (t);
break;
}
} while (f--!=&functions_in_call_tree[0]);
number_of_cycles = 0;
/* Either there weren't any cycles, or all the cycles live
between f_end and functions_in_call_tree */
/* Mark all functions that are not in any cycle. */
flushfuns ();
/* If we haven't got them all, find the cycle (s). */
if (f_end != &functions_in_call_tree[0])
findcycles ();
}
/* Add entries for the cycles to the vector of all call-graph nodes. */
functions_in_call_tree
=ck_realloc (functions_in_call_tree,
(number_of_cycles+number_of_functions_in_call_tree)*sizeof (struct mesym *));
for (n=0; n<number_of_cycles; n++)
functions_in_call_tree[number_of_functions_in_call_tree++]= cycles[n];
/* Now discard the functions that the filters say should not appear. */
filter_graph ();
/* So by now, the only functions left are the ones we want to print */
qsort (functions_in_call_tree, number_of_functions_in_call_tree, sizeof (struct mesym *), treetimecmp);
/* Assign each function its index number. */
for (n=0; n<number_of_functions_in_call_tree; n++)
functions_in_call_tree[n]->numindex=n+1;
if (no_blurbs)
printf ("\t\t\tCall graph\n\n");
else
printf ("\t\t Call graph (explanation follows)\n\n");
puts ("index % time self children called name");
/* Loop over entries. */
for (index = 0; index <number_of_functions_in_call_tree; index++) {
struct mesym *current = functions_in_call_tree[index];
char tmpstr[40]; /* Can an int have more than 40 digits? I hope not */
/* Print out all the things that called this */
if (current->ncalled==0 && current->called==0)
printf (" <spontaneous>\n");
else {
print_sorted_list (current->ncalled, current->cycnum, current->called);
}
sprintf (tmpstr, "[%d]", current->numindex);
printf ("%-6s %6.2f %7.2f %7.2f ",
tmpstr,
(FLOAT)(100.0*(current->sub_histo+current->histo))/(FLOAT)tothist,
convert_and_round ((FLOAT)current->histo),
convert_and_round ((FLOAT)current->sub_histo));
if (current->recursive) {
printf ("%4d+%-4d ",
current->ncalled,
current->recursive);
fprint_name (stdout, current->name);
} else {
printf ("%4d ", current->ncalled);
fprint_name (stdout, current->name);
}
if (current->cycnum>0 && current->name[0]!='<')
printf (" <cycle %d>", current->cycnum);
printf (" [%d]\n", current->numindex);
/* Now print out the children */
if (current->name[0]=='<')
print_sorted_list (-2, current->cycnum, current->calls);
else
print_sorted_list (-1, current->cycnum, current->calls);
printf ("----------------------------------------\n");
}
print_blurb (second_blurb);
}
/* Scan the call tree for virtual leaf nodes */
/* If we find any, propagate time into them from their children,
mark them as being leaf nodes. Then repeat the process. When
we drop out of here, either we've flushed the entire tree, or
we've found a cycle. */
void
flushfuns FUN0()
{
int found;
struct mesym **f;
do {
found=0;
f=f_end;
do {
struct symlist *t;
assert (f>=functions_in_call_tree);
for (t=(*f)->calls; t; t=t->next_to)
if (t->sym_to->cycnum==0)
break;
/* We've found an virtual leaf node. We shold
propagate time into the node, and move it
past f_end, since we aren't interested in
it anymore */
if (!t) {
found++;
/* If its a member of a cycle, cycnum is positive, and
time propagation has already been dealt with. */
if ((*f)->cycnum==0) {
for (t=(*f)->calls; t; t=t->next_to) {
struct mesym *symP;
if (t->sym_to->name[0]=='<')
continue;
if (t->sym_to->cycnum==-1)
symP= t->sym_to;
else
symP= cycles[t->sym_to->cycnum-1];
t->prop_time= (FLOAT)t->ncalls*(FLOAT)symP->histo/(FLOAT)symP->ncalled;
t->child_time=(FLOAT)t->ncalls* symP->sub_histo /(FLOAT)symP->ncalled;
(*f)->sub_histo+=t->prop_time+t->child_time;
}
(*f)->cycnum= -1;
}
/* move this node past f_end, since we don't care
about it anymore */
if (f_end!=functions_in_call_tree) {
/* move this function to the end */
if (f!=f_end) {
struct mesym *tmp;
tmp= *f;
*f= *f_end;
*f_end=tmp;
}
--f_end;
}
assert (f_end>=functions_in_call_tree);
}
} while (f-->&functions_in_call_tree[0]);
} while (found && f_end>&functions_in_call_tree[0]);
}
void
findcycles FUN0()
{
struct mesym **f;
struct mesym *ptr;
struct symlist *tmp;
struct cy {
struct mesym *memb1;
struct mesym *memb2;
struct mesym **others;
int width;
int deepest;
int shallowest;
};
struct cy *cy;
int ncy = 0;
int n;
int bigdepth = 0;
int curdepth;
struct mesym *current_cycle_pointer;
struct mesym *cursym;
int tree_depth;
for (f= &functions_in_call_tree[0]; f<=f_end; f++) {
if ((*f)->ncalled==0) {
push_ring_buffer (ring_buffer, *f);
(*f)->flag=0;
}
}
push_ring_buffer (ring_buffer, (void *)0);
tree_depth = 1;
for (;;) {
ptr=pop_ring_buffer (ring_buffer);
if (!ptr) {
if (ring_buffer_isnt_empty (ring_buffer)) {
push_ring_buffer (ring_buffer, (void *)0);
tree_depth ++;
continue;
} else {
break;
}
} else if (ptr->flag==1) {
fprintf (stderr, "Ignoring call to spont function ");
fprint_name (stderr, ptr->name);
fprintf (stderr, "\n");
} else if (ptr->flag!=0) {
/* Save upward edge */
/* printf ("Upward edge detected in function %s\n", ptr->name); */
if (!ncy) {
cy=ck_malloc (sizeof (struct cy));
ncy=1;
} else {
ncy++;
cy=ck_realloc (cy, ncy*sizeof (struct cy));
}
cy[ncy-1].memb1=ptr;
cy[ncy-1].memb2=0;
} else {
ptr->flag=tree_depth;
for (tmp=ptr->calls; tmp; tmp=tmp->next_to)
if (tmp->sym_to->cycnum!=-1)
push_ring_buffer (ring_buffer, tmp->sym_to);
}
}
if (!ncy)
return;
for (n=0; n<ncy; n++) {
struct symlist *s;
struct symlist *u;
cursym=cy[n].memb1;
if (cursym->cycnum)
continue;
number_of_cycles++;
/* for (s=cursym->called; s; s=s->next_from) {
if (s->sym_from->flag>=cursym->flag)
break;
}
if (!s)
abort (); */
if (!cycles)
cycles=(struct mesym **)ck_malloc (sizeof (struct mesym *));
else
cycles=(struct mesym **)ck_realloc ((void *)cycles,
number_of_cycles*sizeof (struct mesym *));
current_cycle_pointer = (struct mesym *)ck_malloc (sizeof (struct mesym));
cycles[number_of_cycles-1] = current_cycle_pointer;
bzero (current_cycle_pointer, sizeof *current_cycle_pointer);
current_cycle_pointer->name=mk_sprintf ("<cycle %d as a whole>", number_of_cycles);
current_cycle_pointer->value= (unsigned long)-1;
current_cycle_pointer->cycnum=number_of_cycles;
cursym=cy[n].memb1;
push_ring_buffer (ring_buffer, cursym);
while (ring_buffer_isnt_empty (ring_buffer)) {
cursym=pop_ring_buffer (ring_buffer);
if (cursym->cycnum==number_of_cycles)
continue;
if (cursym->cycnum!=0)
abort ();
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_CYC, ("adding %s (%d) to cycle", cursym->name, cursym->histo));
current_cycle_pointer->histo+=cursym->histo;
cursym->cycnum=number_of_cycles;
add_to_lists (current_cycle_pointer, cursym, 0);
/* Now queue the subroutines of this function to be scanned
eventually. */
for (u=cursym->calls; u; u=u->next_to)
if (u->sym_to->cycnum==0) {
push_ring_buffer (ring_buffer, (void *)(u->sym_to));
} else if (u->sym_to->name[0] == '<') {
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_CYC, ("Cycle calls %s (%d)", u->sym_to->name, u->ncalls));
add_to_lists (current_cycle_pointer, u->sym_to, u->ncalls);
}
}
/* The cycle's list of children now contains all the members of the cycle.
Occasionally a function creeps in that doesn't belong in the cycle.
Find and remove them. */
{
struct symlist *v;
int found;
do {
found = 0;
for (u=current_cycle_pointer->calls; u; u=u->next_to) {
for (v=u->sym_to->called; v; v=v->next_from)
if (v->sym_from->name[0]!='<' && v->sym_from->cycnum==number_of_cycles)
break;
if (!v) {
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_CYC, ("%s not really in cycle", u->sym_to->name));
/* This 'cycle member' wasn't called by any member of the cycle.
thus, it isn't a cycle member. */
u->sym_to->cycnum=0;
delete_from_lists (current_cycle_pointer, u->sym_to);
found++;
}
}
} while (found);
}
/* The cycle's lists of callers and children are now correct.
Propagate the time through the cycle. */
/* Now we propagate time INTO the
cycle from its children. We could do this in flushfuns,
but its easier to do here, since doing it here guarentees
it only happens once per cycle */
for (u=current_cycle_pointer->calls; u; u=u->next_to) {
struct mesym *symP;
struct symlist *v;
/* We have to remember to not propagate time that's already here. . . */
if (u->sym_to->cycnum!=number_of_cycles) {
current_cycle_pointer->ncalls+=u->ncalls;
if (u->sym_to->cycnum==-1)
symP= u->sym_to;
else /* Propagate time FROM another cycle here */
symP= cycles[u->sym_to->cycnum-1];
u->prop_time= (FLOAT)u->ncalls*(FLOAT)symP->histo/(FLOAT)symP->ncalled;
u->child_time=(FLOAT)u->ncalls* symP->sub_histo /(FLOAT)symP->ncalled;
current_cycle_pointer->sub_histo+=u->prop_time+u->child_time;
for (v=u->sym_to->called; v; v=v->next_from) {
if (v->sym_from->cycnum==number_of_cycles) {
v->prop_time= (FLOAT)v->ncalls*(FLOAT)symP->histo/(FLOAT)symP->ncalled;
v->child_time=(FLOAT)v->ncalls* symP->sub_histo /(FLOAT)symP->ncalled;
}
}
} else {
u->prop_time= u->sym_to->histo;
u->child_time=u->sym_to->sub_histo;
for (v=u->sym_to->calls; v; v=v->next_to) {
if (v->sym_to->cycnum==number_of_cycles) {
add_to_lists (current_cycle_pointer, v->sym_to, v->ncalls);
current_cycle_pointer->recursive+=v->ncalls;
} else {
symP = v->sym_to;
v->prop_time= (FLOAT)v->ncalls*(FLOAT)symP->histo/(FLOAT)symP->ncalled;
v->child_time=(FLOAT)v->ncalls* symP->sub_histo /(FLOAT)symP->ncalled;
}
}
for (v=u->sym_to->called; v; v=v->next_from) {
assert (v->sym_from->cycnum==0 || v->sym_from->cycnum==number_of_cycles);
if (v->sym_from->cycnum==0) {
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_CYC, ("Cycle called by %s (%d)", v->sym_from->name, v->ncalls));
add_to_lists (v->sym_from, current_cycle_pointer, v->ncalls);
}
}
}
}
/* Sum all calls into the cycle, from each caller not in the cycle,
to get the number of calls into the cycle. */
for (u=current_cycle_pointer->called; u; u=u->next_from) {
if (u->sym_from->cycnum!=number_of_cycles)
current_cycle_pointer->ncalled+=u->ncalls;
}
/* Loop over functions in this cycle. */
for (u=current_cycle_pointer->calls; u; u=u->next_to) {
struct symlist *v;
if (u->sym_to->cycnum!=number_of_cycles)
continue;
/* U->sym_to is a function in this cycle. */
/* Find all calls to this function from functions outside the cycle
and add remove them from the count of calls "from the cycle" to this function. */
for (v=u->sym_to->called; v; v=v->next_from) {
if (v->sym_from != current_cycle_pointer
&& v->sym_from->cycnum==number_of_cycles)
u->sym_to->ncalled-=v->ncalls;
}
}
/* Compute amounts of time to propagate out of the cycle
to the callers-in. */
for (u=current_cycle_pointer->called; u; u=u->next_from)
if (u->sym_from->cycnum != number_of_cycles) {
struct symlist *v;
u->prop_time= ((FLOAT)u->ncalls*(FLOAT)current_cycle_pointer->histo /(FLOAT)current_cycle_pointer->ncalled);
u->child_time=((FLOAT)u->ncalls* current_cycle_pointer->sub_histo /(FLOAT)current_cycle_pointer->ncalled);
for (v=u->sym_from->calls; v; v=v->next_to) {
if (v->sym_to->cycnum==number_of_cycles) {
v->prop_time= ((FLOAT)v->ncalls*(FLOAT)current_cycle_pointer->histo /(FLOAT)current_cycle_pointer->ncalled);
v->child_time=((FLOAT)v->ncalls* current_cycle_pointer->sub_histo /(FLOAT)current_cycle_pointer->ncalled);
}
}
}
flushfuns ();
}
}
/* Remove from the call tree all nodes that are rejected by
the -e, -E, -f and -F filters that were specified.
Their nodes are removed from functions_in_call_tree
and their edges are deleted from the lists they are in. */
void
filter_graph FUN0()
{
int n;
int the_bomb_is_falling = 0;
for (n=0; n<nfilters; n++) {
struct mesym **call_tree_pointer;
call_tree_pointer=find_funp_from_name (filters[n].name);
/* Couldn't find it? Skip it! */
if (!call_tree_pointer) {
/* It may have taken time, although it
isn't in the call tree. Seek and
destroy! */
if (filters[n].type==BIG_E
|| filters[n].type == REMOVE_TIME_IF_THERE) {
struct mesym *p;
for (p=syms; p< &syms[nsym]; p++) {
if (!strcmp (p->name, filters[n].name)) {
tothist-=p->histo;
break;
}
}
if (p==&syms[nsym] && filters[n].type != REMOVE_TIME_IF_THERE) {
fprintf (stderr, "Warning: couldn't find function ");
fprint_name (stderr, filters[n].name);
fprintf (stderr, "\n");
}
} else {
fprintf (stderr, "Warning: ");
fprint_name (stderr, filters[n].name);
fprintf (stderr, " is not in the call tree.\n");
}
continue;
}
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_OPT, ("Option %d on %s", filters[n].type, (*call_tree_pointer)->name));
switch (filters[n].type) {
case SMALL_E:
kill_children (*call_tree_pointer, FALSE);
break;
case BIG_E:
case REMOVE_TIME_IF_THERE:
kill_children (*call_tree_pointer, TRUE);
break;
case SMALL_F:
if (!the_bomb_is_falling)
the_bomb_is_falling = 1;
save_the_children (*call_tree_pointer, FALSE);
break;
case BIG_F:
if (!the_bomb_is_falling) {
the_bomb_is_falling = 1;
tothist=0;
}
save_the_children (*call_tree_pointer, TRUE);
break;
default:
abort ();
}
}
/* If we had -e or -E filters, now delete everything that
was not marked to be saved. */
if (the_bomb_is_falling) {
struct mesym **call_tree_pointer;
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_OPT, ("And now we drop the bomb."));
call_tree_pointer=&functions_in_call_tree[number_of_functions_in_call_tree-1];
do {
if (((*call_tree_pointer)->flag&SAVE_ME)==0)
remove_from_call_tree (call_tree_pointer);
} while (call_tree_pointer-->&functions_in_call_tree[0]);
}
}
/* Collect a list of parents/children, sort them, and print them */
/* If CALLED > 0, we print parents,
and the value of CALLED is the total number of times this fn was called.
If CALLED == -2 we print children.
This is used for printing the children of an entire cycle.
If CALLED == -1, we print children and if their cycle number is the
same as CYCLE, we print abbreviated information.
This is used for printing the children of an ordinary function. */
/* LIST is the list of parents/children we want to print */
void
print_sorted_list FUN3(int, called, int, cycle, struct symlist *, list)
{
static struct symlist **sbuf;
static nsbuf, sizsbuf;
struct symlist **sbp, *t;
struct mesym *symP;
if (!sizsbuf) {
sbuf=(struct symlist **)ck_calloc (30, sizeof (struct symlist *));
nsbuf=0;
sizsbuf=30;
}
/* Extract all the symbols in LIST as a vector,
but ignore any which represent entire cycles. */
t=list;
for (sbp= &sbuf[0]; t;) {
symP = (called>=0) ? t->sym_from : t->sym_to;
if (symP && symP->name[0] != '<') {
*sbp=t;
sbp++;
nsbuf++;
if (nsbuf==sizsbuf) {
sizsbuf*=2;
sbuf=(struct symlist **)ck_realloc ((void *)sbuf, sizsbuf*sizeof (struct symlist *));
sbp= &sbuf[nsbuf];
}
} else {
symP++;
}
if (called>=0) t=t->next_from;
else t=t->next_to;
}
/* Sort the vector. */
qsort (sbuf, nsbuf, sizeof (struct symlist *), listcmp);
/* Print the elements of the vector. */
for (sbp= &sbuf[0]; nsbuf>0; nsbuf--, sbp++) {
t= *sbp;
if (called>=0) symP=t->sym_from;
else symP=t->sym_to;
if (cycle>0 && cycle==symP->cycnum) {
if (called==-2) {
printf (" %7.2f %7.2f %4d ",
convert_and_round ((FLOAT)(symP->histo)),
convert_and_round ((FLOAT)(symP->sub_histo)),
t->ncalls);
fprint_name (stdout, symP->name);
} else {
/* For things in the same cycle, we only want to print
the number of calls */
printf ("%30s %4d ", "", t->ncalls);
fprint_name (stdout, symP->name);
}
} else {
printf (" %7.2f %7.2f %4d/%-4d ",
convert_and_round (t->prop_time),
convert_and_round (t->child_time),
t->ncalls,
(called>=0) ? called : symP->ncalled);
fprint_name (stdout, symP->name);
}
if (symP->cycnum>0 && symP->name[0]!='<')
printf (" <cycle %d>", symP->cycnum);
if (symP->numindex)
printf (" [%d]\n", symP->numindex);
else
printf (" [not printed]\n");
}
}
/* Compare two symbols for which should come first among
the callers or subroutines in a single call-graph entry. */
int
listcmp FUN2(const void *, a, const void *, b)
{
struct symlist *aa, *bb;
FLOAT n;
aa= *(struct symlist **)a;
bb= *(struct symlist **)b;
n=(bb->prop_time + bb->child_time - aa->prop_time - aa->child_time);
if (n<0) return -1;
if (n>0) return 1;
return 0;
}
/* Convert a number (IN) from the histogram into seconds, rounding to the
nearest 100th of a second. */
FLOAT
convert_and_round FUN1(FLOAT, in)
{
long int inter;
inter=((in/(FLOAT)(ticks))+.005)*100.0;
return ((FLOAT)(inter)/100.0);
}
/* Given ncalls from fromP to toP, add a symlist element telling about it */
void
add_to_lists FUN3(struct mesym *, fromP, struct mesym *, toP, unsigned, ncalls)
{
struct symlist *tmp;
for (tmp=fromP->calls; tmp; tmp=tmp->next_to)
if (tmp->sym_to==toP) {
tmp->ncalls+=ncalls;
break;
}
if (!tmp) {
tmp=(struct symlist *)ck_malloc (sizeof (struct symlist));
tmp->sym_from=fromP;
tmp->next_from=toP->called;
tmp->sym_to=toP;
tmp->next_to=fromP->calls;
tmp->ncalls=ncalls;
tmp->prop_time = -1;
tmp->child_time = -1;
fromP->calls=tmp;
toP->called=tmp;
}
}
/* The reverse of add_to_lists. Forget that fromP ever called toP */
void
delete_from_lists FUN2(struct mesym *, fromP, struct mesym *, toP)
{
struct symlist *die, *tmp, *old;
if (fromP->calls->sym_to==toP) {
die=fromP->calls;
fromP->calls=fromP->calls->next_to;
} else {
old=0;
for (tmp=fromP->calls; tmp; tmp=tmp->next_to) {
if (tmp->sym_to==toP) {
die=tmp;
old->next_to=tmp->next_to;
}
old=tmp;
}
}
if (toP->called->sym_from==fromP) {
die=toP->called;
toP->called=toP->called->next_from;
} else {
for (tmp=toP->called; tmp; tmp=tmp->next_from) {
old=0;
if (tmp->sym_from==fromP) {
die=tmp;
old->next_from=tmp->next_from;
}
old=tmp;
}
}
free (die);
}
/* Implement the -e or -E option by deleting a certain function
and all its descendents from the call graph.
If FLUSHFLAG is set, remove its histogram time from the total, too. */
void
kill_children FUN2(struct mesym *, p, int, flushflag)
{
struct symlist *t;
push_ring_buffer (ring_buffer, p);
while (ring_buffer_isnt_empty (ring_buffer)) {
p=pop_ring_buffer (ring_buffer);
if (flushflag)
tothist-=p->histo;
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_OPT, ("Flushing %s (%d)", p->name, flushflag ? p->histo : 0));
p->flag|=KILL_ME;
remove_from_call_tree (find_funp_from_pointer (p));
for (t=p->calls; t; t=t->next_to) {
if (t->sym_to->ncalled==t->ncalls
|| (p->cycnum>0 && t->sym_to->cycnum==p->cycnum)) {
push_ring_buffer (ring_buffer, t->sym_to);
} else if (t->sym_to->cycnum>0 && t->sym_to->cycnum!=p->cycnum) {
if (cycles[t->sym_to->cycnum-1]->ncalled==t->ncalls) {
push_ring_buffer (ring_buffer, cycles[t->sym_to->cycnum-1]);
}
} else {
struct symlist *ztmp;
for (ztmp=t->sym_to->called; ztmp; ztmp=ztmp->next_from) {
if ((ztmp->sym_from->flag&KILL_ME)==0)
break;
}
if (!ztmp)
push_ring_buffer (ring_buffer, t->sym_to);
else {
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_OPT, ("Not flushing %s. . . More parents", t->sym_to->name));
/* Do we want to deal with removing FRACTIONS of time from
functions who were called from different places? If so,
code goes here. (F'rinstance, if half of the calls to
function X were made from here, cut its stored time in half */
}
}
}
}
}
/* This is the opposite of kill_children ().
-f or -F has been specified, so all call-graph nodes EXCEPT
the descendents of specified functions will be killed.
Find all these descendents and mark them to be saved
by setting the `flag' fields nonzero.
If TIMEFLAG is set, the histogram-total has
already been nuked, and we should add our histogram time to
it in an attempt at reconstruction. . . */
void
save_the_children FUN2(struct mesym *, p, int, timeflag)
{
struct symlist *t;
push_ring_buffer (ring_buffer, p);
while (ring_buffer_isnt_empty (ring_buffer)) {
p=pop_ring_buffer (ring_buffer);
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_OPT, ("Saving %s (%d)", p->name, p->histo));
p->flag|=SAVE_ME;
if (p->cycnum>0)
cycles[p->cycnum-1]->flag|=SAVE_ME;
if (timeflag)
tothist+=p->histo;
for (t=p->calls; t; t=t->next_to) {
if ((t->sym_to->flag&SAVE_ME)==0)
push_ring_buffer (ring_buffer, t->sym_to);
}
}
}
/* The bomb is falling, and PT has just been hit by severe doses of
radiation. Remove it from the call-tree vector */
void
remove_from_call_tree FUN1(struct mesym **, pt)
{
if (!pt) {
/* Just quietly returning allows us to remove cycles from
the call tree easily. */
/* panic ("Internal Error: trying to remove null from call tree"); */
return;
}
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_OPT, ("Removing %ss from the tree", (*pt)->name));
*pt=functions_in_call_tree[number_of_functions_in_call_tree-1];
number_of_functions_in_call_tree--;
}
/* We want to play with a member of the call tree, but we
only know its name. Try to find the funp. This is slow,
natch, since it uses linear search, but it doesn't get called much */
/* Should be some way to scan rest of symbols so we could delete
mcount/mcleanup histogram ticks. Should be way to disable warning? */
struct mesym **
find_funp_from_name FUN1(char *, name)
{
struct mesym **ret;
ret= &functions_in_call_tree[number_of_functions_in_call_tree-1];
do {
if (strcmp ((*ret)->name, name)==0)
return ret;
} while (ret-->&functions_in_call_tree[0]);
return 0;
}
/* We have the mesym, but we need to know where it lives in the call-tree
This is almost as slow as find_funp_from_name (). */
struct mesym **
find_funp_from_pointer FUN1(struct mesym *, p)
{
struct mesym **ret;
ret= &functions_in_call_tree[number_of_functions_in_call_tree-1];
do {
if (*ret==p)
return ret;
} while (ret-->&functions_in_call_tree[0]);
/* fprintf (stderr, "Warning: Can't find %s in the call tree.\n", p->name); */
return 0;
}
/* Read symbols from a.out file open on FP. There are N of them. Allocate a
vector to store the interesting ones in, and sort it numerically. */
void
read_syms FUN2(FILE *, fp, int, n)
{
struct nlist *tmpsyms;
struct nlist *sym;
int i;
#ifdef __STDC__
char buf[n];
#else
char *buf;
char *alloca ();
buf=alloca (n);
#endif
/* Read the entire symbol table. */
tmpsyms=(struct nlist *)ck_malloc (n*sizeof (struct nlist));
ck_fread (tmpsyms, sizeof (struct nlist), n, fp);
bzero (buf, n);
/* Count the useful symbols.
Also relocate their name-fields to be C string pointers. */
for (sym= &tmpsyms[0], i=0; sym<&tmpsyms[n]; sym++) {
sym->n_un.n_name= strs+sym->n_un.n_strx;
if (!badsym (sym))
buf[sym-tmpsyms] = 1, i++;
}
/* Allocate permanent space and copy useful symbols into it. */
nsym=i;
syms=(struct mesym *)ck_calloc (nsym, sizeof (struct mesym));
for (sym= &tmpsyms[0], i=0; sym<&tmpsyms[n]; sym++) {
if (!badsym (sym)) {
syms[i].name=sym->n_un.n_name;
#ifndef nounderscore
/* Remove the initial _ from the symbol name */
if (*(syms[i].name)=='_')
syms[i].name++;
#endif
syms[i].value=sym->n_value;
i++;
}
else if (buf[sym-tmpsyms])
abort ();
}
if (i != nsym)
abort ();
/* Put symbols in numeric order. */
qsort (syms, nsym, sizeof (struct mesym), symcmp);
free ((void *)tmpsyms);
}
/* Return the symbol which has the largest value less than VAL.
Since the symbol vector is sorted by value, this is done
with a binary search. */
struct mesym *
val_to_sym FUN1(unsigned long, val)
{
struct mesym *m;
int gap=nsym/4;
m= &syms[nsym/2];
for (;;) {
if (m->value>val) {
m-=gap;
gap/=2;
} else if ((m+1)->value<val) {
m+=gap;
gap/=2;
} else
break;
if (m<&syms[0] || m>=&syms[nsym])
abort ();
if (gap<1)
gap=1;
}
return m;
}
/* Return TRUE if the nlist-entry SYM describes a symbol
that gprof should pay attention to. */
int
badsym FUN1(struct nlist *, sym)
{
#ifndef N_SECT
if ((sym->n_type & ~N_EXT) != N_TEXT)
return TRUE;
#else
if ((sym->n_type & ~N_EXT) != N_TEXT && (sym->n_type & ~N_EXT) != N_SECT)
return TRUE;
#endif
if (no_locals && !(sym->n_type&N_EXT))
return TRUE;
/* Filenames or pascal labels should be ignored */
if (index (sym->n_un.n_name, '.') || index (sym->n_un.n_name, '$'))
return TRUE;
return FALSE;
}
/* This is used to qsort () the symbol table into numerical order. */
int
symcmp FUN2(const void *, a, const void *, b)
{
struct mesym *aa, *bb;
aa=(struct mesym *)a;
bb=(struct mesym *)b;
return aa->value - bb->value;
}
/* This is used to sort the vector for the flat profile.
if they used different amounts of time, the one with
the most time goes first. If they used the same amount,
the one that was called most goes first. If they were
called the same #, they are sorted alphabetically */
int
timecmp FUN2(const void *, a, const void *, b)
{
struct mesym *aa, *bb;
int n;
aa= *(struct mesym **)a;
bb= *(struct mesym **)b;
n = bb->histo - aa->histo;
if (n==0) n=bb->ncalled - aa->ncalled;
if (n==0) n=strcmp (aa->name, bb->name);
return n;
}
/* This is used to sort the functions_in_call_tree[] vector
so the leaf nodes are at the end, and the root nodes
are at the beginning. This bit about useless nodes could
probably be taken out now, since they shouldn't make it
into the vector in the first place */
int
callcmp FUN2(const void *, a, const void *, b)
{
struct mesym *aa, *bb;
aa= *(struct mesym **)a;
bb= *(struct mesym **)b;
/* Send useless symbols to the end */
if (aa->ncalls==0 && aa->ncalled==0) {
if (bb->ncalls==0 && bb->ncalled==0)
return EQ;
return GT;
}
if (bb->ncalled==0 && bb->ncalls==0)
return LT;
/* send root nodes to the front; */
/* Functions that were called 0 times
are spontaneous */
if (aa->ncalled==0) {
if (bb->ncalled==0)
return EQ;
return LT;
}
if (bb->ncalled==0)
return GT;
/* Send leaf nodes to the end */
if (aa->ncalls==0) {
if (bb->ncalls==0)
return EQ;
return GT;
}
if (bb->ncalls==0)
return LT;
/* And keep the rest the same */
return EQ;
}
/* This is used to sort functions_in_call_tree[] before printing.
To print, we want
A: the ones with the most time first
a: (If one was never called, put it first, 'cuz it
was invoked by GOD, else the one called the most
# of times first)
1: the one with the lower name (strcmp ()) first
*/
int
treetimecmp FUN2(const void *, a, const void *, b)
{
struct mesym *aa, *bb;
int n;
aa= *(struct mesym **)a;
bb= *(struct mesym **)b;
n = (bb->histo+bb->sub_histo) - (aa->histo+aa->sub_histo);
if (n==0) {
/* Just to be bizarre: If one was never called,
put it first, else put the one who was called
the most first. Confused yet? */
if (aa->ncalled==0)
return LT;
if (bb->ncalled==0)
return GT;
n=bb->ncalled - aa->ncalled;
if (n==0)
n=strcmp (aa->name, bb->name);
}
return n;
}
/* Read in a gmon.out file named NAME and deal with the stuff inside it. */
void
readgm FUN1(char *, name)
{
FILE *fp;
struct gm_header tmp;
unsigned CHUNK *p;
int n;
struct gm_call calltmp;
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_GFILE, ("gmon from `%s'", name));
fp=ck_fopen (name, "r");
/* Read in the gmon file header and check that histogram is
compatible with the other gmon files already read. */
ck_fread ((void *)&tmp, sizeof (tmp), 1, fp);
if (hdr.low) {
if (hdr.low!=tmp.low || hdr.high!=tmp.high)
fatal ("file `%s' is incompatable with previous gmon.out file", name);
} else
hdr=tmp;
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_GFILE, ("lowpc=%ld hipc=%ld nbytes= %ld", hdr.low, hdr.high, hdr.nbytes));
/* Allocate the total histogram if we haven't yet done so. */
if (!histo) {
nhist=(hdr.nbytes-sizeof (struct gm_header))/sizeof (CHUNK);
histo=(unsigned CHUNK *)ck_calloc (nhist, sizeof (unsigned CHUNK));
}
/* Read this file's histogram and merge it into the total one. */
p=(unsigned CHUNK *)ck_malloc (nhist*sizeof (unsigned CHUNK));
ck_fread ((void *)p, sizeof (unsigned CHUNK), nhist, fp);
for (n=0; n<nhist; n++) {
tothist+=p[n];
histo[n]+=p[n];
if (debug&DB_GFILE) {
static ncol;
if (n==0) ncol=0;
if (histo[n]) {
fprintf (stderr, "s[%05d]=%-3d", n, histo[n]);
if (ncol++%10==9) fputc ('\n', stderr);
}
}
}
free ((void *)p);
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_GFILE, (""));
/* We've read in the histogram, now read in the function call data.
Loop, reading one call-graph edge from the file
and recording the edge in the graph. */
while (fread ((void *)&calltmp, sizeof (calltmp), 1, fp)==1) {
struct symlist *tmp;
struct mesym *s_fm, *s_to;
/* Find the calling and called functions's symbol entries. */
s_fm=val_to_sym (calltmp.from);
s_to=val_to_sym (calltmp.to);
if (!s_fm || !s_to) {
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_GFILE, ("unknown call %#lx to %#lx %d times.", calltmp.from, calltmp.to, calltmp.ncalls));
continue;
}
/* Updated total numbers of calls from this caller and to this callee. */
s_to->ncalled+=calltmp.ncalls;
s_fm->ncalls+=calltmp.ncalls;
/* Add these calls to the edge between them. */
add_to_lists (s_fm, s_to, calltmp.ncalls);
PRINT_OBNOXIOUS_DEBUG_MESSAGE
(DB_GFILE, ("call %s (%#lx) to %s (%#lx) %ld times", s_fm->name,
calltmp.from, s_to->name, calltmp.to, calltmp.ncalls));
}
ck_fclose (fp);
}
/* Print one of those obnoxious and vaguely informative blurbs that we know
and love so well. Used to be, we'd print them out of a file, but nowaday
the blurb is encoded direcly into the program. Makes printing them
much faster. Also means bozo syswiz can't accidentally delete/move/etc the
blurb file on us. */
void
print_blurb FUN1(char *, blurb)
{
if (! no_blurbs)
fputs (blurb, stdout);
}
/* Find the number of clock ticks/second by reading the kernel's memory.
This means that if /dev/kmem isn't readable, this program will have to run
set[ug]id to someone who can read the kernel. setgid is probably best. */
long
get_ticks FUN0()
{
static struct nlist nl[2];
long ret;
FILE *fp;
#ifdef USG
#include <sys/types.h>
#include <sys/param.h>
ret = HZ;
#else
nl[0].n_un.n_name="_hz";
nlist ("/vmunix", &nl[0]);
if (nl[0].n_type==0)
fatal ("Can't find `%s' in namelist of /vmunix", nl[0].n_un.n_name);
fp=ck_fopen ("/dev/kmem", "r");
ck_fseek (fp, (long)nl[0].n_value, 0);
ck_fread ((void *)&ret, sizeof (ret), 1, fp);
ck_fclose (fp);
#endif
PRINT_OBNOXIOUS_DEBUG_MESSAGE (DB_MISC, ("get_ticks ()=%ld", ret));
return ret;
}
/* Record one -e, -E, -f or -F option in `filters', and check for conflicts.
All these options are recorded there for processing later
once the call-graph has been constructed. */
void
add_filter FUN2(char *, name, int, type)
{
if (!filters) {
filters=(struct filter *)ck_malloc (sizeof (struct filter));
nfilters=1;
} else {
int n;
for (n=0; n<nfilters; n++) {
if (filters[n].name==name || !strcmp (filters[n].name, name))
fatal ("Conflicting options for function `%s'", name);
}
nfilters++;
filters=(struct filter *)ck_realloc ((void *)filters, sizeof (struct filter)*nfilters);
}
filters[nfilters-1].name=name;
filters[nfilters-1].type=type;
}
/* Data base associating stdio streams with the file names that are open. */
struct file_to_name {
FILE *stream; /* A stdio stream */
char *name; /* The file name (malloc'd specially for this list) */
struct file_to_name *next;
};
struct file_to_name *files_to_names;
/* Given a stdio stream, look it up in the data base and return
the file name. */
char *
stream_name FUN1(FILE *, stream)
{
struct file_to_name *tail;
for (tail = files_to_names; tail; tail = tail->next)
if (tail->stream == stream)
return tail->name;
return "unknown file";
}
/* Open a file like `fopen', but report a fatal error if it fails;
if it succeeds, record the stream and filename in the data base of such. */
FILE *
ck_fopen FUN2(char *, name, char *, mode)
{
FILE *stream;
int n;
struct file_to_name *new;
stream=fopen (name, mode);
if (stream==(FILE *)0)
fatal_io ("Couldn't open", name);
new = ck_malloc (sizeof (struct file_to_name));
new->name = ck_malloc (strlen (name) + 1);
strcpy (new->name, name);
new->stream = stream;
new->next = files_to_names;
files_to_names = new;
return stream;
}
/* Interfaces to various functions of stdio
which use the stream/filename database to print an error message
if the function gets an error. */
void
ck_fseek FUN3(FILE *, stream, long, i, int, w)
{
if (fseek (stream, i, w)==-1)
fatal_io ("Couldn't lseek", stream_name (stream));
}
void
ck_fread FUN4(void *, ptr, size_t, size, size_t, nmemb, FILE *, stream)
{
if (fread (ptr, size, nmemb, stream)!=nmemb)
fatal_io ("Couldn't read", stream_name (stream));
}
void
ck_fwrite FUN4(void *, ptr, size_t, size, size_t, nmemb, FILE *, stream)
{
if (fwrite (ptr, size, nmemb, stream)!=nmemb)
fatal_io ("Couldn't write", stream_name (stream));
}
void
ck_fclose FUN1(FILE *, stream)
{
struct file_to_name *tail;
if(stream->_flag & _IOWRT)
fflush (stream);
if (ferror (stream))
fatal ("I/O error on `%s'", stream_name (stream));
if (fclose (stream)==EOF)
fatal_io ("Couldn't close", stream_name (stream));
if (files_to_names && files_to_names->stream == stream)
files_to_names = files_to_names->next;
else
for (tail = files_to_names; tail->next; tail = tail->next)
if (tail->next->stream == stream)
{
struct file_to_name *loser = tail->next;
tail->next = tail->next->next;
free (loser->name);
free (loser);
return;
}
}
/* Report a fatal error doing I/O, and exit.
PROBLEM is "Couldn't whatever" and NAME is the file name. */
void
fatal_io FUN2(char *, problem, char *, name)
{
fprintf (stderr, "%s: %s %s:", myname, problem, name);
perror (0);
exit (1);
}
/* Report a fatal error and exit. Arguments like `printf'. */
void
fatal FUN1N(char *, s)
{
va_list iggy;
var_start (iggy, s);
fprintf (stderr, "%s: ", myname);
vfprintf (stderr, s, iggy);
/* _doprnt (s, iggy, stderr); */
putc ('\n', stderr);
va_end (iggy);
exit (1);
}
/* Memory allocation functions. */
/* This function is called just like `printf'
except that the output is put into a new string
allocated with `malloc'.
Returns the address of the string. The caller must free the string. */
char *
mk_sprintf FUN1N(char *, str)
{
char tmpbuf[2048];
char *ret;
va_list iggy;
var_start (iggy, str);
vsprintf (tmpbuf, str, iggy);
va_end (iggy);
ret=ck_malloc (strlen (tmpbuf)+1);
strcpy (ret, tmpbuf);
return ret;
}
/* Encapsulations of `malloc', `calloc' and `realloc'
that cause fatal errors if there is not enough memory. */
void *
ck_malloc FUN1(size_t, size)
{
void *ret;
void *malloc ();
ret=malloc (size);
if (ret==(void *)0)
fatal ("Virtual memory exhausted");
return ret;
}
void *
ck_calloc FUN2(size_t, nmemb, size_t, size)
{
void *ret;
void *calloc ();
ret=calloc (nmemb, size);
if (ret==(void *)0)
fatal ("Virtual memory exhausted");
return ret;
}
void *
ck_realloc FUN2(void *, ptr, size_t, size)
{
void *ret;
void *realloc ();
ret=realloc (ptr, size);
if (ret==(void *)0)
fatal ("Virtual memory exhausted");
return ret;
}
/* Implement an expandable fifo buffer of pointers
(we don't care what they point to)
which is used for conducting breadth-first tree walks in the call graph.
The fifo is implemented as a ring buffer. */
struct ring_buf
{
void **buf;
int size;
void **push_to_here;
void **pop_frm_here;
};
void *
init_ring_buffer FUN0()
{
struct ring_buf *ret;
ret=ck_malloc (sizeof (struct ring_buf));
ret->size=40;
ret->buf=(void **)ck_calloc (ret->size, sizeof (void **));
ret->push_to_here=ret->buf;
ret->pop_frm_here=ret->buf;
return ret;
}
void
push_ring_buffer FUN2(void *, b, void *, n)
{
struct ring_buf *buf;
buf=(struct ring_buf *)b;
if (buf->push_to_here+1==buf->pop_frm_here
|| (buf->pop_frm_here==buf->buf
&& buf->push_to_here==buf->buf+(buf->size-1))) {
int f, t, from_num;
f=buf->pop_frm_here-buf->buf;
t=buf->push_to_here-buf->buf;
from_num=buf->size-f;
buf->size*=2;
buf->buf=ck_realloc ((void *)buf->buf, buf->size*sizeof (void **));
if (t==0) {
buf->push_to_here=buf->buf+f+from_num;
buf->pop_frm_here=buf->buf+f;
} else if (t>f) {
buf->push_to_here=buf->buf+t;
buf->pop_frm_here=buf->buf+f;
} else {
buf->push_to_here=buf->buf+t;
buf->pop_frm_here=buf->buf+(buf->size-from_num);
if (from_num)
bcopy (buf->buf+f,
buf->pop_frm_here,
from_num*sizeof (void **));
}
}
*(buf->push_to_here)=n;
buf->push_to_here++;
if (buf->push_to_here==buf->buf+buf->size)
buf->push_to_here=buf->buf;
}
void *
pop_ring_buffer FUN1(void *, b)
{
struct ring_buf *buf;
void *ret;
buf=(struct ring_buf *)b;
ret= *(buf->pop_frm_here);
buf->pop_frm_here++;
if (buf->pop_frm_here==buf->buf+buf->size)
buf->pop_frm_here=buf->buf;
return ret;
}
int
ring_buffer_isnt_empty FUN1(void *, b)
{
struct ring_buf *buf;
buf=(struct ring_buf *)b;
return buf->pop_frm_here!=buf->push_to_here;
}
void
flush_ring_buffer FUN1(void *, b)
{
struct ring_buf *buf;
buf=(struct ring_buf *)b;
free (buf->buf);
free (buf);
}
/* Functions to print debugging messages. */
/* Like vprintf but print an extra newline at the end. */
void
dbgprintf FUN1N(char *, s)
{
va_list iggy;
var_start (iggy, s);
vfprintf (stderr, s, iggy);
putc ('\n', stderr);
va_end (iggy);
}
/* Print out the entire symbol table */
void
dumpsyms FUN0()
{
struct mesym *np, *endp;
struct symlist *sy;
int n;
char buf[80];
n=0;
for (np=syms, endp= &syms[nsym]; np<endp; np++) {
char *demangled = cplus_demangle (np->name);
char *name = demangled == NULL ? np->name : demangled;
sprintf (buf, "%-15s %#6lx %d %2d.%2d[%d]",
name, np->value, np->histo, np->ncalled, np->ncalls, np->cycnum);
if (demangled != NULL)
free (demangled);
if (n==0) {
printf ("%-35s", buf);
n++;
} else {
printf ("%s\n", buf);
n=0;
}
}
putchar ('\n');
if (n==0) putchar ('\n');
}
/* Print out the call tree vector */
void
dumpfuns FUN0()
{
struct mesym *np;
struct symlist *sy;
int n;
for (n=0; n<number_of_functions_in_call_tree; n++) {
np=functions_in_call_tree[n];
fprint_name (stdout, np->name);
printf ("{%d}[%d] ", np->cycnum, np->ncalls);
/* for (sy=np->called; sy; sy=sy->next)
printf ("%s{%d}(%d) ", sy->sym->name, sy->sym->cycnum, sy->ncalls);
putchar ('\n'); */
}
}
/* JF someone put this stuff in the file before all the prototyes et all.
I moved them here where they belong */
/* Like malloc but abort if out of memory. */
void *
xmalloc FUN1(size_t, size)
{
return ck_malloc(size);
}
/* Like realloc but abort if out of memory. */
void *
xrealloc FUN2(void *, p, size_t, size)
{
return ck_realloc(p,size);
}
/* Print NAME on STREAM, demangling if necessary. */
void
fprint_name FUN2(FILE *, stream, char *, name)
{
char *demangled = cplus_demangle (name);
if (demangled == NULL)
fputs (name, stream);
else
{
fputs (demangled, stream);
free (demangled);
}
}