sprof.c source code [glibc/elf/sprof.c]

1	/ Read and display shared object profiling data.*
2	Copyright (C) 1997-2022 Free Software Foundation, Inc.
3	This file is part of the GNU C Library.
4
5	The GNU C Library is free software; you can redistribute it and/or
6	modify it under the terms of the GNU Lesser General Public
7	License as published by the Free Software Foundation; either
8	version 2.1 of the License, or (at your option) any later version.
9
10	The GNU C Library is distributed in the hope that it will be useful,
11	but WITHOUT ANY WARRANTY; without even the implied warranty of
12	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
13	Lesser General Public License for more details.
14
15	You should have received a copy of the GNU Lesser General Public
16	License along with the GNU C Library; if not, see
17	<https://www.gnu.org/licenses/>. /*
18
19	#include <argp.h>
20	#include <dlfcn.h>
21	#include <elf.h>
22	#include <error.h>
23	#include <fcntl.h>
24	#include <inttypes.h>
25	#include <libintl.h>
26	#include <locale.h>
27	#include <obstack.h>
28	#include <search.h>
29	#include <stdbool.h>
30	#include <stdio.h>
31	#include <stdlib.h>
32	#include <string.h>
33	#include <unistd.h>
34	#include <stdint.h>
35	#include <ldsodefs.h>
36	#include <sys/gmon.h>
37	#include <sys/gmon_out.h>
38	#include <sys/mman.h>
39	#include <sys/param.h>
40	#include <sys/stat.h>
41
42	/ Get libc version number. /
43	#include "../version.h"
44
45	#define PACKAGE _libc_intl_domainname
46
47
48	#include <endian.h>
49	#if BYTE_ORDER == BIG_ENDIAN
50	# define byteorder ELFDATA2MSB
51	# define byteorder_name "big-endian"
52	#elif BYTE_ORDER == LITTLE_ENDIAN
53	# define byteorder ELFDATA2LSB
54	# define byteorder_name "little-endian"
55	#else
56	# error "Unknown BYTE_ORDER " BYTE_ORDER
57	# define byteorder ELFDATANONE
58	#endif
59
60	#ifndef PATH_MAX
61	# define PATH_MAX 1024
62	#endif
63
64
65	extern int __profile_frequency (void);
66
67	/ Name and version of program. /
68	static void print_version (FILE stream, struct* argp_state *state);
69	void (argp_program_version_hook) (FILE , struct argp_state *) = print_version;
70
71	#define OPT_TEST 1
72
73	/ Definitions of arguments for argp functions. /
74	static const struct argp_option options[] =
75	{
76	{ NULL, `0`, NULL, `0`, N_("Output selection:") },
77	{ "call-pairs", `'c'`, NULL, `0`,
78	N_("print list of count paths and their number of use") },
79	{ "flat-profile", `'p'`, NULL, `0`,
80	N_("generate flat profile with counts and ticks") },
81	{ "graph", `'q'`, NULL, `0`, N_("generate call graph") },
82
83	{ "test", OPT_TEST, NULL, OPTION_HIDDEN, NULL },
84	{ NULL, `0`, NULL, `0`, NULL }
85	};
86
87	/ Short description of program. /
88	static const char doc[] = N_("Read and display shared object profiling data.");
89	//For bug reporting instructions, please see:\n
90	//<https://www.gnu.org/software/libc/bugs.html>.\n");
91
92	/ Strings for arguments in help texts. /
93	static const char args_doc[] = N_("SHOBJ [PROFDATA]");
94
95	/ Prototype for option handler. /
96	static error_t parse_opt (int key, char arg, struct* argp_state *state);
97
98	/ Function to print some extra text in the help message. /
99	static char more_help (int* key, const char text, void* *input);
100
101	/ Data structure to communicate with argp functions. /
102	static struct argp argp =
103	{
104	options, parse_opt, args_doc, doc, NULL, more_help
105	};
106
107
108	/ Operation modes. /
109	static enum
110	{
111	NONE = `0`,
112	FLAT_MODE = `1` << `0`,
113	CALL_GRAPH_MODE = `1` << `1`,
114	CALL_PAIRS = `1` << `2`,
115
116	DEFAULT_MODE = FLAT_MODE \| CALL_GRAPH_MODE
117	} mode;
118
119	/ Nozero for testing. /
120	static int do_test;
121
122	/ Strcuture describing calls. /
123	struct here_fromstruct
124	{
125	struct here_cg_arc_record volatile *here;
126	uint16_t link;
127	};
128
129	/ We define a special type to address the elements of the arc table.*
130	This is basically the `gmon_cg_arc_record' format but it includes
131	the room for the tag and it uses real types. /*
132	struct here_cg_arc_record
133	{
134	uintptr_t from_pc;
135	uintptr_t self_pc;
136	uint32_t count;
137	} __attribute__ ((packed));
138
139
140	struct known_symbol;
141	struct arc_list
142	{
143	size_t idx;
144	uintmax_t count;
145
146	struct arc_list *next;
147	};
148
149	static struct obstack ob_list;
150
151
152	struct known_symbol
153	{
154	const char *name;
155	uintptr_t addr;
156	size_t size;
157	bool weak;
158	bool hidden;
159
160	uintmax_t ticks;
161	uintmax_t calls;
162
163	struct arc_list *froms;
164	struct arc_list *tos;
165	};
166
167
168	struct shobj
169	{
170	const char name; /* User-provided name. /
171
172	struct link_map *map;
173	const char dynstrtab; /* Dynamic string table of shared object. /
174	const char soname; /* Soname of shared object. /
175
176	uintptr_t lowpc;
177	uintptr_t highpc;
178	unsigned long int kcountsize;
179	size_t expected_size; / Expected size of profiling file. /
180	size_t tossize;
181	size_t fromssize;
182	size_t fromlimit;
183	unsigned int hashfraction;
184	int s_scale;
185
186	void *symbol_map;
187	size_t symbol_mapsize;
188	const ElfW(Sym) *symtab;
189	size_t symtab_size;
190	const char *strtab;
191
192	struct obstack ob_str;
193	struct obstack ob_sym;
194	};
195
196
197	struct real_gmon_hist_hdr
198	{
199	char *low_pc;
200	char *high_pc;
201	int32_t hist_size;
202	int32_t prof_rate;
203	char dimen[`15`];
204	char dimen_abbrev;
205	};
206
207
208	struct profdata
209	{
210	void *addr;
211	off_t size;
212
213	char *hist;
214	struct real_gmon_hist_hdr *hist_hdr;
215	uint16_t *kcount;
216	uint32_t narcs; / Number of arcs in toset. /
217	struct here_cg_arc_record *data;
218	uint16_t *tos;
219	struct here_fromstruct *froms;
220	};
221
222	/ Search tree for symbols. /
223	static void *symroot;
224	static struct known_symbol **sortsym;
225	static size_t symidx;
226	static uintmax_t total_ticks;
227
228	/ Prototypes for local functions. /
229	static struct shobj load_shobj (const* char *name);
230	static void unload_shobj (struct shobj *shobj);
231	static struct profdata load_profdata (const* char name, struct* shobj *shobj);
232	static void unload_profdata (struct profdata *profdata);
233	static void count_total_ticks (struct shobj shobj, struct* profdata *profdata);
234	static void count_calls (struct shobj shobj, struct* profdata *profdata);
235	static void read_symbols (struct shobj *shobj);
236	static void add_arcs (struct profdata *profdata);
237	static void generate_flat_profile (struct profdata *profdata);
238	static void generate_call_graph (struct profdata *profdata);
239	static void generate_call_pair_list (struct profdata *profdata);
240
241
242	int
243	main (int argc, char *argv[])
244	{
245	const char *shobj;
246	const char *profdata;
247	struct shobj *shobj_handle;
248	struct profdata *profdata_handle;
249	int remaining;
250
251	setlocale (LC_ALL, locale: "");
252
253	/ Initialize the message catalog. /
254	textdomain (domainname: _libc_intl_domainname);
255
256	/ Parse and process arguments. /
257	argp_parse (argp: &argp, argc: argc, argv: argv, flags: `0`, arg_index: &remaining, NULL);
258
259	if (argc - remaining == `0` \|\| argc - remaining > `2`)
260	{
261	/ We need exactly two non-option parameter. /
262	argp_help (argp: &argp, stdout, ARGP_HELP_SEE \| ARGP_HELP_EXIT_ERR,
263	name: program_invocation_short_name);
264	exit (status: `1`);
265	}
266
267	/ Get parameters. /
268	shobj = argv[remaining];
269	if (argc - remaining == `2`)
270	profdata = argv[remaining + `1`];
271	else
272	/ No filename for the profiling data given. We will determine it*
273	from the soname of the shobj, later. /*
274	profdata = NULL;
275
276	/ First see whether we can load the shared object. /
277	shobj_handle = load_shobj (name: shobj);
278	if (shobj_handle == NULL)
279	exit (status: `1`);
280
281	/ We can now determine the filename for the profiling data, if*
282	nececessary. /*
283	if (profdata == NULL)
284	{
285	char *newp;
286	const char *soname;
287	size_t soname_len;
288
289	soname = shobj_handle->soname ?: basename (filename: shobj);
290	soname_len = strlen (s: soname);
291	newp = (char ) alloca (soname_len + sizeof* ".profile");
292	stpcpy (mempcpy (newp, soname, soname_len), ".profile");
293	profdata = newp;
294	}
295
296	/ Now see whether the profiling data file matches the given object. /
297	profdata_handle = load_profdata (name: profdata, shobj: shobj_handle);
298	if (profdata_handle == NULL)
299	{
300	unload_shobj (shobj: shobj_handle);
301
302	exit (status: `1`);
303	}
304
305	read_symbols (shobj: shobj_handle);
306
307	/ Count the ticks. /
308	count_total_ticks (shobj: shobj_handle, profdata: profdata_handle);
309
310	/ Count the calls. /
311	count_calls (shobj: shobj_handle, profdata: profdata_handle);
312
313	/ Add the arc information. /
314	add_arcs (profdata: profdata_handle);
315
316	/ If no mode is specified fall back to the default mode. /
317	if (mode == NONE)
318	mode = DEFAULT_MODE;
319
320	/ Do some work. /
321	if (mode & FLAT_MODE)
322	generate_flat_profile (profdata: profdata_handle);
323
324	if (mode & CALL_GRAPH_MODE)
325	generate_call_graph (profdata: profdata_handle);
326
327	if (mode & CALL_PAIRS)
328	generate_call_pair_list (profdata: profdata_handle);
329
330	/ Free the resources. /
331	unload_shobj (shobj: shobj_handle);
332	unload_profdata (profdata: profdata_handle);
333
334	return `0`;
335	}
336
337
338	/ Handle program arguments. /
339	static error_t
340	parse_opt (int key, char arg, struct* argp_state *state)
341	{
342	switch (key)
343	{
344	case `'c'`:
345	mode \|= CALL_PAIRS;
346	break;
347	case `'p'`:
348	mode \|= FLAT_MODE;
349	break;
350	case `'q'`:
351	mode \|= CALL_GRAPH_MODE;
352	break;
353	case OPT_TEST:
354	do_test = `1`;
355	break;
356	default:
357	return ARGP_ERR_UNKNOWN;
358	}
359	return `0`;
360	}
361
362
363	static char *
364	more_help (int key, const char text, void* *input)
365	{
366	char *tp = NULL;
367	switch (key)
368	{
369	case ARGP_KEY_HELP_EXTRA:
370	/ We print some extra information. /
371	if (asprintf (ptr: &tp, gettext ("\
372	For bug reporting instructions, please see:\n\
373	%s.\n"), REPORT_BUGS_TO) < `0`)
374	return NULL;
375	return tp;
376	default:
377	break;
378	}
379	return (char *) text;
380	}
381
382
383	/ Print the version information. /
384	static void
385	print_version (FILE stream, struct* argp_state *state)
386	{
387	fprintf (stream: stream, format: "sprof %s%s\n", PKGVERSION, VERSION);
388	fprintf (stream: stream, gettext ("\
389	Copyright (C) %s Free Software Foundation, Inc.\n\
390	This is free software; see the source for copying conditions. There is NO\n\
391	warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.\n\
392	"),
393	"2022");
394	fprintf (stream: stream, gettext ("Written by %s.\n"), "Ulrich Drepper");
395	}
396
397
398	/ Note that we must not use `dlopen' etc. The shobj object must not*
399	be loaded for use. /*
400	static struct shobj *
401	load_shobj (const char *name)
402	{
403	struct link_map *map = NULL;
404	struct shobj *result;
405	ElfW(Addr) mapstart = ~((ElfW(Addr)) `0`);
406	ElfW(Addr) mapend = `0`;
407	const ElfW(Phdr) *ph;
408	size_t textsize;
409	ElfW(Ehdr) *ehdr;
410	int fd;
411	ElfW(Shdr) *shdr;
412	size_t pagesize = getpagesize ();
413
414	/ Since we use dlopen() we must be prepared to work around the sometimes*
415	strange lookup rules for the shared objects. If we have a file foo.so
416	in the current directory and the user specfies foo.so on the command
417	line (without specifying a directory) we should load the file in the
418	current directory even if a normal dlopen() call would read the other
419	file. We do this by adding a directory portion to the name. /*
420	if (strchr (s: name, c: `'/'`) == NULL)
421	{
422	char load_name = (char* *) alloca (strlen (name) + `3`);
423	stpcpy (stpcpy (load_name, "./"), name);
424
425	map = (struct link_map *) dlopen (file: load_name, RTLD_LAZY \| __RTLD_SPROF);
426	}
427	if (map == NULL)
428	{
429	map = (struct link_map *) dlopen (file: name, RTLD_LAZY \| __RTLD_SPROF);
430	if (map == NULL)
431	{
432	error (status: `0`, errno, _("failed to load shared object `%s'"), name);
433	return NULL;
434	}
435	}
436
437	/ Prepare the result. /
438	result = (struct shobj ) calloc (nmemb: `1`, size: sizeof* (struct shobj));
439	if (result == NULL)
440	{
441	error (status: `0`, errno, _("cannot create internal descriptor"));
442	dlclose (handle: map);
443	return NULL;
444	}
445	result->name = name;
446	result->map = map;
447
448	/ Compute the size of the sections which contain program code.*
449	This must match the code in dl-profile.c (_dl_start_profile). /*
450	for (ph = map->l_phdr; ph < &map->l_phdr[map->l_phnum]; ++ph)
451	if (ph->p_type == PT_LOAD && (ph->p_flags & PF_X))
452	{
453	ElfW(Addr) start = (ph->p_vaddr & ~(pagesize - `1`));
454	ElfW(Addr) end = ((ph->p_vaddr + ph->p_memsz + pagesize - `1`)
455	& ~(pagesize - `1`));
456
457	if (start < mapstart)
458	mapstart = start;
459	if (end > mapend)
460	mapend = end;
461	}
462
463	result->lowpc = ROUNDDOWN ((uintptr_t) (mapstart + map->l_addr),
464	HISTFRACTION * sizeof (HISTCOUNTER));
465	result->highpc = ROUNDUP ((uintptr_t) (mapend + map->l_addr),
466	HISTFRACTION * sizeof (HISTCOUNTER));
467	if (do_test)
468	printf (format: "load addr: %0#*" PRIxPTR "\n"
469	"lower bound PC: %0#*" PRIxPTR "\n"
470	"upper bound PC: %0#*" PRIxPTR "\n",
471	__ELF_NATIVE_CLASS == `32` ? `10` : `18`, map->l_addr,
472	__ELF_NATIVE_CLASS == `32` ? `10` : `18`, result->lowpc,
473	__ELF_NATIVE_CLASS == `32` ? `10` : `18`, result->highpc);
474
475	textsize = result->highpc - result->lowpc;
476	result->kcountsize = textsize / HISTFRACTION;
477	result->hashfraction = HASHFRACTION;
478	if (do_test)
479	printf (format: "hashfraction = %d\ndivider = %Zu\n",
480	result->hashfraction,
481	result->hashfraction * sizeof (struct here_fromstruct));
482	result->tossize = textsize / HASHFRACTION;
483	result->fromlimit = textsize * ARCDENSITY / `100`;
484	if (result->fromlimit < MINARCS)
485	result->fromlimit = MINARCS;
486	if (result->fromlimit > MAXARCS)
487	result->fromlimit = MAXARCS;
488	result->fromssize = result->fromlimit * sizeof (struct here_fromstruct);
489
490	result->expected_size = (sizeof (struct gmon_hdr)
491	+ `4` + sizeof (struct gmon_hist_hdr)
492	+ result->kcountsize
493	+ `4` + `4`
494	+ (result->fromssize
495	* sizeof (struct here_cg_arc_record)));
496
497	if (do_test)
498	printf (format: "expected size: %Zd\n", result->expected_size);
499
500	#define SCALE_1_TO_1 0x10000L
501
502	if (result->kcountsize < result->highpc - result->lowpc)
503	{
504	size_t range = result->highpc - result->lowpc;
505	size_t quot = range / result->kcountsize;
506
507	if (quot >= SCALE_1_TO_1)
508	result->s_scale = `1`;
509	else if (quot >= SCALE_1_TO_1 / `256`)
510	result->s_scale = SCALE_1_TO_1 / quot;
511	else if (range > ULONG_MAX / `256`)
512	result->s_scale = ((SCALE_1_TO_1 * `256`)
513	/ (range / (result->kcountsize / `256`)));
514	else
515	result->s_scale = ((SCALE_1_TO_1 * `256`)
516	/ ((range * `256`) / result->kcountsize));
517	}
518	else
519	result->s_scale = SCALE_1_TO_1;
520
521	if (do_test)
522	printf (format: "s_scale: %d\n", result->s_scale);
523
524	/ Determine the dynamic string table. /
525	if (map->l_info[DT_STRTAB] == NULL)
526	result->dynstrtab = NULL;
527	else
528	result->dynstrtab = (const char *) D_PTR (map, l_info[DT_STRTAB]);
529	if (do_test)
530	printf (format: "string table: %p\n", result->dynstrtab);
531
532	/ Determine the soname. /
533	if (map->l_info[DT_SONAME] == NULL)
534	result->soname = NULL;
535	else
536	result->soname = result->dynstrtab + map->l_info[DT_SONAME]->d_un.d_val;
537	if (do_test && result->soname != NULL)
538	printf (format: "soname: %s\n", result->soname);
539
540	/ Now we have to load the symbol table.*
541
542	First load the section header table. /*
543	ehdr = (ElfW(Ehdr) *) map->l_map_start;
544
545	/ Make sure we are on the right party. /
546	if (ehdr->e_shentsize != sizeof (ElfW(Shdr)))
547	abort ();
548
549	/ And we need the shared object file descriptor again. /
550	fd = open (file: map->l_name, O_RDONLY);
551	if (fd == -`1`)
552	/ Dooh, this really shouldn't happen. We know the file is available. /
553	error (EXIT_FAILURE, errno, _("Reopening shared object `%s' failed"),
554	map->l_name);
555
556	/ Map the section header. /
557	size_t size = ehdr->e_shnum * sizeof (ElfW(Shdr));
558	shdr = (ElfW(Shdr) *) alloca (size);
559	if (pread (fd: fd, buf: shdr, nbytes: size, offset: ehdr->e_shoff) != size)
560	error (EXIT_FAILURE, errno, _("reading of section headers failed"));
561
562	/ Get the section header string table. /
563	char shstrtab = (char* *) alloca (shdr[ehdr->e_shstrndx].sh_size);
564	if (pread (fd: fd, buf: shstrtab, nbytes: shdr[ehdr->e_shstrndx].sh_size,
565	offset: shdr[ehdr->e_shstrndx].sh_offset)
566	!= shdr[ehdr->e_shstrndx].sh_size)
567	error (EXIT_FAILURE, errno,
568	_("reading of section header string table failed"));
569
570	/ Search for the ".symtab" section. /
571	ElfW(Shdr) *symtab_entry = NULL;
572	ElfW(Shdr) *debuglink_entry = NULL;
573	for (int idx = `0`; idx < ehdr->e_shnum; ++idx)
574	if (shdr[idx].sh_type == SHT_SYMTAB
575	&& strcmp (s1: shstrtab + shdr[idx].sh_name, s2: ".symtab") == `0`)
576	{
577	symtab_entry = &shdr[idx];
578	break;
579	}
580	else if (shdr[idx].sh_type == SHT_PROGBITS
581	&& strcmp (s1: shstrtab + shdr[idx].sh_name, s2: ".gnu_debuglink") == `0`)
582	debuglink_entry = &shdr[idx];
583
584	/ Get the file name of the debuginfo file if necessary. /
585	int symfd = fd;
586	if (symtab_entry == NULL && debuglink_entry != NULL)
587	{
588	size_t size = debuglink_entry->sh_size;
589	char debuginfo_fname = (char* *) alloca (size + `1`);
590	debuginfo_fname[size] = `'\0'`;
591	if (pread (fd: fd, buf: debuginfo_fname, nbytes: size, offset: debuglink_entry->sh_offset)
592	!= size)
593	{
594	fprintf (stderr, _("*** Cannot read debuginfo file name: %m\n"));
595	goto no_debuginfo;
596	}
597
598	static const char procpath[] = "/proc/self/fd/%d";
599	char origprocname[sizeof (procpath) + sizeof (int) * `3`];
600	snprintf (s: origprocname, maxlen: sizeof (origprocname), format: procpath, fd);
601	char origlink = (char* *) alloca (PATH_MAX);
602	ssize_t n = readlink (path: origprocname, buf: origlink, PATH_MAX - `1`);
603	if (n == -`1`)
604	goto no_debuginfo;
605	origlink[n] = `'\0'`;
606
607	/ Try to find the actual file. There are three places:*
608	1. the same directory the DSO is in
609	2. in a subdir named .debug of the directory the DSO is in
610	3. in /usr/lib/debug/PATH-OF-DSO
611	*/
612	char *realname = canonicalize_file_name (name: origlink);
613	char *cp = NULL;
614	if (realname == NULL \|\| (cp = strrchr (s: realname, c: `'/'`)) == NULL)
615	error (EXIT_FAILURE, errno, _("cannot determine file name"));
616
617	/ Leave the last slash in place. /
618	*++cp = `'\0'`;
619
620	/ First add the debuginfo file name only. /
621	static const char usrlibdebug[]= "/usr/lib/debug/";
622	char workbuf = (char* ) alloca (sizeof* (usrlibdebug)
623	+ (cp - realname)
624	+ strlen (debuginfo_fname));
625	strcpy (dest: stpcpy (workbuf, realname), src: debuginfo_fname);
626
627	int fd2 = open (file: workbuf, O_RDONLY);
628	if (fd2 == -`1`)
629	{
630	strcpy (dest: stpcpy (stpcpy (workbuf, realname), ".debug/"),
631	src: debuginfo_fname);
632	fd2 = open (file: workbuf, O_RDONLY);
633	if (fd2 == -`1`)
634	{
635	strcpy (dest: stpcpy (stpcpy (workbuf, usrlibdebug), realname),
636	src: debuginfo_fname);
637	fd2 = open (file: workbuf, O_RDONLY);
638	}
639	}
640
641	if (fd2 != -`1`)
642	{
643	ElfW(Ehdr) ehdr2;
644
645	/ Read the ELF header. /
646	if (pread (fd: fd2, buf: &ehdr2, nbytes: sizeof (ehdr2), offset: `0`) != sizeof (ehdr2))
647	error (EXIT_FAILURE, errno,
648	_("reading of ELF header failed"));
649
650	/ Map the section header. /
651	size_t size = ehdr2.e_shnum * sizeof (ElfW(Shdr));
652	ElfW(Shdr) shdr2 = (ElfW(Shdr) ) alloca (size);
653	if (pread (fd: fd2, buf: shdr2, nbytes: size, offset: ehdr2.e_shoff) != size)
654	error (EXIT_FAILURE, errno,
655	_("reading of section headers failed"));
656
657	/ Get the section header string table. /
658	shstrtab = (char *) alloca (shdr2[ehdr2.e_shstrndx].sh_size);
659	if (pread (fd: fd2, buf: shstrtab, nbytes: shdr2[ehdr2.e_shstrndx].sh_size,
660	offset: shdr2[ehdr2.e_shstrndx].sh_offset)
661	!= shdr2[ehdr2.e_shstrndx].sh_size)
662	error (EXIT_FAILURE, errno,
663	_("reading of section header string table failed"));
664
665	/ Search for the ".symtab" section. /
666	for (int idx = `0`; idx < ehdr2.e_shnum; ++idx)
667	if (shdr2[idx].sh_type == SHT_SYMTAB
668	&& strcmp (s1: shstrtab + shdr2[idx].sh_name, s2: ".symtab") == `0`)
669	{
670	symtab_entry = &shdr2[idx];
671	shdr = shdr2;
672	symfd = fd2;
673	break;
674	}
675
676	if (fd2 != symfd)
677	close (fd: fd2);
678	}
679	}
680
681	no_debuginfo:
682	if (symtab_entry == NULL)
683	{
684	fprintf (stderr, _("\
685	*** The file `%s' is stripped: no detailed analysis possible\n"),
686	name);
687	result->symtab = NULL;
688	result->strtab = NULL;
689	}
690	else
691	{
692	ElfW(Off) min_offset, max_offset;
693	ElfW(Shdr) *strtab_entry;
694
695	strtab_entry = &shdr[symtab_entry->sh_link];
696
697	/ Find the minimum and maximum offsets that include both the symbol*
698	table and the string table. /*
699	if (symtab_entry->sh_offset < strtab_entry->sh_offset)
700	{
701	min_offset = symtab_entry->sh_offset & ~(pagesize - `1`);
702	max_offset = strtab_entry->sh_offset + strtab_entry->sh_size;
703	}
704	else
705	{
706	min_offset = strtab_entry->sh_offset & ~(pagesize - `1`);
707	max_offset = symtab_entry->sh_offset + symtab_entry->sh_size;
708	}
709
710	result->symbol_map = mmap (NULL, len: max_offset - min_offset,
711	PROT_READ, MAP_SHARED\|MAP_FILE, fd: symfd,
712	offset: min_offset);
713	if (result->symbol_map == MAP_FAILED)
714	error (EXIT_FAILURE, errno, _("failed to load symbol data"));
715
716	result->symtab
717	= (const ElfW(Sym) ) ((const* char *) result->symbol_map
718	+ (symtab_entry->sh_offset - min_offset));
719	result->symtab_size = symtab_entry->sh_size;
720	result->strtab = ((const char *) result->symbol_map
721	+ (strtab_entry->sh_offset - min_offset));
722	result->symbol_mapsize = max_offset - min_offset;
723	}
724
725	/ Free the descriptor for the shared object. /
726	close (fd: fd);
727	if (symfd != fd)
728	close (fd: symfd);
729
730	return result;
731	}
732
733
734	static void
735	unload_shobj (struct shobj *shobj)
736	{
737	munmap (addr: shobj->symbol_map, len: shobj->symbol_mapsize);
738	dlclose (handle: shobj->map);
739	}
740
741
742	static struct profdata *
743	load_profdata (const char name, struct* shobj *shobj)
744	{
745	struct profdata *result;
746	int fd;
747	struct stat64 st;
748	void *addr;
749	uint32_t *narcsp;
750	size_t fromlimit;
751	struct here_cg_arc_record *data;
752	struct here_fromstruct *froms;
753	uint16_t *tos;
754	size_t fromidx;
755	size_t idx;
756
757	fd = open (file: name, O_RDONLY);
758	if (fd == -`1`)
759	{
760	char *ext_name;
761
762	if (errno != ENOENT \|\| strchr (s: name, c: `'/'`) != NULL)
763	/ The file exists but we are not allowed to read it or the*
764	file does not exist and the name includes a path
765	specification.. /*
766	return NULL;
767
768	/ A file with the given name does not exist in the current*
769	directory, try it in the default location where the profiling
770	files are created. /*
771	ext_name = (char ) alloca (strlen (name) + sizeof* "/var/tmp/");
772	stpcpy (stpcpy (ext_name, "/var/tmp/"), name);
773	name = ext_name;
774
775	fd = open (file: ext_name, O_RDONLY);
776	if (fd == -`1`)
777	{
778	/ Even this file does not exist. /
779	error (status: `0`, errno, _("cannot load profiling data"));
780	return NULL;
781	}
782	}
783
784	/ We have found the file, now make sure it is the right one for the*
785	data file. /*
786	if (fstat64 (fd: fd, buf: &st) < `0`)
787	{
788	error (status: `0`, errno, _("while stat'ing profiling data file"));
789	close (fd: fd);
790	return NULL;
791	}
792
793	if ((size_t) st.st_size != shobj->expected_size)
794	{
795	error (status: `0`, errnum: `0`,
796	_("profiling data file `%s' does not match shared object `%s'"),
797	name, shobj->name);
798	close (fd: fd);
799	return NULL;
800	}
801
802	/ The data file is most probably the right one for our shared*
803	object. Map it now. /*
804	addr = mmap (NULL, len: st.st_size, PROT_READ, MAP_SHARED\|MAP_FILE, fd: fd, offset: `0`);
805	if (addr == MAP_FAILED)
806	{
807	error (status: `0`, errno, _("failed to mmap the profiling data file"));
808	close (fd: fd);
809	return NULL;
810	}
811
812	/ We don't need the file desriptor anymore. /
813	if (close (fd: fd) < `0`)
814	{
815	error (status: `0`, errno, _("error while closing the profiling data file"));
816	munmap (addr: addr, len: st.st_size);
817	return NULL;
818	}
819
820	/ Prepare the result. /
821	result = (struct profdata ) calloc (nmemb: `1`, size: sizeof* (struct profdata));
822	if (result == NULL)
823	{
824	error (status: `0`, errno, _("cannot create internal descriptor"));
825	munmap (addr: addr, len: st.st_size);
826	return NULL;
827	}
828
829	/ Store the address and size so that we can later free the resources. /
830	result->addr = addr;
831	result->size = st.st_size;
832
833	/ Pointer to data after the header. /
834	result->hist = (char ) ((struct* gmon_hdr *) addr + `1`);
835	result->hist_hdr = (struct real_gmon_hist_hdr ) ((char* *) result->hist
836	+ sizeof (uint32_t));
837	result->kcount = (uint16_t ) ((char* ) result->hist + sizeof* (uint32_t)
838	+ sizeof (struct real_gmon_hist_hdr));
839
840	/ Compute pointer to array of the arc information. /
841	narcsp = (uint32_t ) ((char* *) result->kcount + shobj->kcountsize
842	+ sizeof (uint32_t));
843	result->narcs = *narcsp;
844	result->data = (struct here_cg_arc_record ) ((char* *) narcsp
845	+ sizeof (uint32_t));
846
847	/ Create the gmon_hdr we expect or write. /
848	struct real_gmon_hdr
849	{
850	char cookie[`4`];
851	int32_t version;
852	char spare[`3` * `4`];
853	} gmon_hdr;
854	if (sizeof (gmon_hdr) != sizeof (struct gmon_hdr)
855	\|\| (offsetof (struct real_gmon_hdr, cookie)
856	!= offsetof (struct gmon_hdr, cookie))
857	\|\| (offsetof (struct real_gmon_hdr, version)
858	!= offsetof (struct gmon_hdr, version)))
859	abort ();
860
861	memcpy (dest: &gmon_hdr.cookie[`0`], GMON_MAGIC, n: sizeof (gmon_hdr.cookie));
862	gmon_hdr.version = GMON_SHOBJ_VERSION;
863	memset (s: gmon_hdr.spare, c: `'\0'`, n: sizeof (gmon_hdr.spare));
864
865	/ Create the hist_hdr we expect or write. /
866	struct real_gmon_hist_hdr hist_hdr;
867	if (sizeof (hist_hdr) != sizeof (struct gmon_hist_hdr)
868	\|\| (offsetof (struct real_gmon_hist_hdr, low_pc)
869	!= offsetof (struct gmon_hist_hdr, low_pc))
870	\|\| (offsetof (struct real_gmon_hist_hdr, high_pc)
871	!= offsetof (struct gmon_hist_hdr, high_pc))
872	\|\| (offsetof (struct real_gmon_hist_hdr, hist_size)
873	!= offsetof (struct gmon_hist_hdr, hist_size))
874	\|\| (offsetof (struct real_gmon_hist_hdr, prof_rate)
875	!= offsetof (struct gmon_hist_hdr, prof_rate))
876	\|\| (offsetof (struct real_gmon_hist_hdr, dimen)
877	!= offsetof (struct gmon_hist_hdr, dimen))
878	\|\| (offsetof (struct real_gmon_hist_hdr, dimen_abbrev)
879	!= offsetof (struct gmon_hist_hdr, dimen_abbrev)))
880	abort ();
881
882	hist_hdr.low_pc = (char *) shobj->lowpc - shobj->map->l_addr;
883	hist_hdr.high_pc = (char *) shobj->highpc - shobj->map->l_addr;
884	if (do_test)
885	printf (format: "low_pc = %p\nhigh_pc = %p\n", hist_hdr.low_pc, hist_hdr.high_pc);
886	hist_hdr.hist_size = shobj->kcountsize / sizeof (HISTCOUNTER);
887	hist_hdr.prof_rate = __profile_frequency ();
888	strncpy (dest: hist_hdr.dimen, src: "seconds", n: sizeof (hist_hdr.dimen));
889	hist_hdr.dimen_abbrev = `'s'`;
890
891	/ Test whether the header of the profiling data is ok. /
892	if (memcmp (s1: addr, s2: &gmon_hdr, n: sizeof (struct gmon_hdr)) != `0`
893	\|\| (uint32_t ) result->hist != GMON_TAG_TIME_HIST
894	\|\| memcmp (s1: result->hist_hdr, s2: &hist_hdr,
895	n: sizeof (struct gmon_hist_hdr)) != `0`
896	\|\| narcsp[-`1`] != GMON_TAG_CG_ARC)
897	{
898	error (status: `0`, errnum: `0`, _("`%s' is no correct profile data file for `%s'"),
899	name, shobj->name);
900	if (do_test)
901	{
902	if (memcmp (s1: addr, s2: &gmon_hdr, n: sizeof (struct gmon_hdr)) != `0`)
903	puts (s: "gmon_hdr differs");
904	if ((uint32_t ) result->hist != GMON_TAG_TIME_HIST)
905	puts (s: "result->hist differs");
906	if (memcmp (s1: result->hist_hdr, s2: &hist_hdr,
907	n: sizeof (struct gmon_hist_hdr)) != `0`)
908	puts (s: "hist_hdr differs");
909	if (narcsp[-`1`] != GMON_TAG_CG_ARC)
910	puts (s: "narcsp[-1] differs");
911	}
912	free (ptr: result);
913	munmap (addr: addr, len: st.st_size);
914	return NULL;
915	}
916
917	/ We are pretty sure now that this is a correct input file. Set up*
918	the remaining information in the result structure and return. /*
919	result->tos = (uint16_t *) calloc (nmemb: shobj->tossize + shobj->fromssize, size: `1`);
920	if (result->tos == NULL)
921	{
922	error (status: `0`, errno, _("cannot create internal descriptor"));
923	munmap (addr: addr, len: st.st_size);
924	free (ptr: result);
925	return NULL;
926	}
927
928	result->froms = (struct here_fromstruct ) ((char* *) result->tos
929	+ shobj->tossize);
930	fromidx = `0`;
931
932	/ Now we have to process all the arc count entries. /
933	fromlimit = shobj->fromlimit;
934	data = result->data;
935	froms = result->froms;
936	tos = result->tos;
937	for (idx = `0`; idx < MIN (*narcsp, fromlimit); ++idx)
938	{
939	size_t to_index;
940	size_t newfromidx;
941	to_index = (data[idx].self_pc / (shobj->hashfraction * sizeof (*tos)));
942	newfromidx = fromidx++;
943	froms[newfromidx].here = &data[idx];
944	froms[newfromidx].link = tos[to_index];
945	tos[to_index] = newfromidx;
946	}
947
948	return result;
949	}
950
951
952	static void
953	unload_profdata (struct profdata *profdata)
954	{
955	free (ptr: profdata->tos);
956	munmap (addr: profdata->addr, len: profdata->size);
957	free (ptr: profdata);
958	}
959
960
961	static void
962	count_total_ticks (struct shobj shobj, struct* profdata *profdata)
963	{
964	volatile uint16_t *kcount = profdata->kcount;
965	size_t maxkidx = shobj->kcountsize;
966	size_t factor = `2` * (`65536` / shobj->s_scale);
967	size_t kidx = `0`;
968	size_t sidx = `0`;
969
970	while (sidx < symidx)
971	{
972	uintptr_t start = sortsym[sidx]->addr;
973	uintptr_t end = start + sortsym[sidx]->size;
974
975	while (kidx < maxkidx && factor * kidx < start)
976	++kidx;
977	if (kidx == maxkidx)
978	break;
979
980	while (kidx < maxkidx && factor * kidx < end)
981	sortsym[sidx]->ticks += kcount[kidx++];
982	if (kidx == maxkidx)
983	break;
984
985	total_ticks += sortsym[sidx++]->ticks;
986	}
987	}
988
989
990	static size_t
991	find_symbol (uintptr_t addr)
992	{
993	size_t sidx = `0`;
994
995	while (sidx < symidx)
996	{
997	uintptr_t start = sortsym[sidx]->addr;
998	uintptr_t end = start + sortsym[sidx]->size;
999
1000	if (addr >= start && addr < end)
1001	return sidx;
1002
1003	if (addr < start)
1004	break;
1005
1006	++sidx;
1007	}
1008
1009	return (size_t) -`1l`;
1010	}
1011
1012
1013	static void
1014	count_calls (struct shobj shobj, struct* profdata *profdata)
1015	{
1016	struct here_cg_arc_record *data = profdata->data;
1017	uint32_t narcs = profdata->narcs;
1018	uint32_t cnt;
1019
1020	for (cnt = `0`; cnt < narcs; ++cnt)
1021	{
1022	uintptr_t here = data[cnt].self_pc;
1023	size_t symbol_idx;
1024
1025	/ Find the symbol for this address. /
1026	symbol_idx = find_symbol (addr: here);
1027	if (symbol_idx != (size_t) -`1l`)
1028	sortsym[symbol_idx]->calls += data[cnt].count;
1029	}
1030	}
1031
1032
1033	static int
1034	symorder (const void o1, const* void *o2)
1035	{
1036	const struct known_symbol p1 = (const* struct known_symbol *) o1;
1037	const struct known_symbol p2 = (const* struct known_symbol *) o2;
1038
1039	return p1->addr - p2->addr;
1040	}
1041
1042
1043	static void
1044	printsym (const void node, VISIT value, int* level)
1045	{
1046	if (value == leaf \|\| value == postorder)
1047	sortsym[symidx++] = (struct* known_symbol **) node;
1048	}
1049
1050
1051	static void
1052	read_symbols (struct shobj *shobj)
1053	{
1054	int n = `0`;
1055
1056	/ Initialize the obstacks. /
1057	#define obstack_chunk_alloc malloc
1058	#define obstack_chunk_free free
1059	obstack_init (&shobj->ob_str);
1060	obstack_init (&shobj->ob_sym);
1061	obstack_init (&ob_list);
1062
1063	/ Process the symbols. /
1064	if (shobj->symtab != NULL)
1065	{
1066	const ElfW(Sym) *sym = shobj->symtab;
1067	const ElfW(Sym) *sym_end
1068	= (const ElfW(Sym) ) ((const* char *) sym + shobj->symtab_size);
1069	for (; sym < sym_end; sym++)
1070	if ((ELFW(ST_TYPE) (sym->st_info) == STT_FUNC
1071	\|\| ELFW(ST_TYPE) (sym->st_info) == STT_NOTYPE)
1072	&& sym->st_size != `0`)
1073	{
1074	struct known_symbol **existp;
1075	struct known_symbol *newsym
1076	= (struct known_symbol *) obstack_alloc (&shobj->ob_sym,
1077	sizeof (*newsym));
1078	if (newsym == NULL)
1079	error (EXIT_FAILURE, errno, _("cannot allocate symbol data"));
1080
1081	newsym->name = &shobj->strtab[sym->st_name];
1082	newsym->addr = sym->st_value;
1083	newsym->size = sym->st_size;
1084	newsym->weak = ELFW(ST_BIND) (sym->st_info) == STB_WEAK;
1085	newsym->hidden = (ELFW(ST_VISIBILITY) (sym->st_other)
1086	!= STV_DEFAULT);
1087	newsym->ticks = `0`;
1088	newsym->calls = `0`;
1089
1090	existp = tfind (key: newsym, rootp: &symroot, compar: symorder);
1091	if (existp == NULL)
1092	{
1093	/ New function. /
1094	tsearch (key: newsym, rootp: &symroot, compar: symorder);
1095	++n;
1096	}
1097	else
1098	{
1099	/ The function is already defined. See whether we have*
1100	a better name here. /*
1101	if (((*existp)->hidden && !newsym->hidden)
1102	\|\| ((*existp)->name[`0`] == `'_'` && newsym->name[`0`] != `'_'`)
1103	\|\| ((*existp)->name[`0`] != `'_'` && newsym->name[`0`] != `'_'`
1104	&& ((*existp)->weak && !newsym->weak)))
1105	*existp = newsym;
1106	else
1107	/ We don't need the allocated memory. /
1108	obstack_free (&shobj->ob_sym, newsym);
1109	}
1110	}
1111	}
1112	else
1113	{
1114	/ Blarg, the binary is stripped. We have to rely on the*
1115	information contained in the dynamic section of the object. /*
1116	const ElfW(Sym) symtab = (ElfW(Sym) ) D_PTR (shobj->map,
1117	l_info[DT_SYMTAB]);
1118	const char strtab = (const* char *) D_PTR (shobj->map,
1119	l_info[DT_STRTAB]);
1120
1121	/ We assume that the string table follows the symbol table,*
1122	because there is no way in ELF to know the size of the
1123	dynamic symbol table without looking at the section headers. /*
1124	while ((void ) symtab < (void* *) strtab)
1125	{
1126	if ((ELFW(ST_TYPE)(symtab->st_info) == STT_FUNC
1127	\|\| ELFW(ST_TYPE)(symtab->st_info) == STT_NOTYPE)
1128	&& symtab->st_size != `0`)
1129	{
1130	struct known_symbol *newsym;
1131	struct known_symbol **existp;
1132
1133	newsym =
1134	(struct known_symbol *) obstack_alloc (&shobj->ob_sym,
1135	sizeof (*newsym));
1136	if (newsym == NULL)
1137	error (EXIT_FAILURE, errno, _("cannot allocate symbol data"));
1138
1139	newsym->name = &strtab[symtab->st_name];
1140	newsym->addr = symtab->st_value;
1141	newsym->size = symtab->st_size;
1142	newsym->weak = ELFW(ST_BIND) (symtab->st_info) == STB_WEAK;
1143	newsym->hidden = (ELFW(ST_VISIBILITY) (symtab->st_other)
1144	!= STV_DEFAULT);
1145	newsym->ticks = `0`;
1146	newsym->froms = NULL;
1147	newsym->tos = NULL;
1148
1149	existp = tfind (key: newsym, rootp: &symroot, compar: symorder);
1150	if (existp == NULL)
1151	{
1152	/ New function. /
1153	tsearch (key: newsym, rootp: &symroot, compar: symorder);
1154	++n;
1155	}
1156	else
1157	{
1158	/ The function is already defined. See whether we have*
1159	a better name here. /*
1160	if (((*existp)->hidden && !newsym->hidden)
1161	\|\| ((*existp)->name[`0`] == `'_'` && newsym->name[`0`] != `'_'`)
1162	\|\| ((*existp)->name[`0`] != `'_'` && newsym->name[`0`] != `'_'`
1163	&& ((*existp)->weak && !newsym->weak)))
1164	*existp = newsym;
1165	else
1166	/ We don't need the allocated memory. /
1167	obstack_free (&shobj->ob_sym, newsym);
1168	}
1169	}
1170
1171	++symtab;
1172	}
1173	}
1174
1175	sortsym = malloc (size: n * sizeof (struct known_symbol *));
1176	if (sortsym == NULL)
1177	abort ();
1178
1179	twalk (root: symroot, action: printsym);
1180	}
1181
1182
1183	static void
1184	add_arcs (struct profdata *profdata)
1185	{
1186	uint32_t narcs = profdata->narcs;
1187	struct here_cg_arc_record *data = profdata->data;
1188	uint32_t cnt;
1189
1190	for (cnt = `0`; cnt < narcs; ++cnt)
1191	{
1192	/ First add the incoming arc. /
1193	size_t sym_idx = find_symbol (addr: data[cnt].self_pc);
1194
1195	if (sym_idx != (size_t) -`1l`)
1196	{
1197	struct known_symbol *sym = sortsym[sym_idx];
1198	struct arc_list *runp = sym->froms;
1199
1200	while (runp != NULL
1201	&& ((data[cnt].from_pc == `0` && runp->idx != (size_t) -`1l`)
1202	\|\| (data[cnt].from_pc != `0`
1203	&& (runp->idx == (size_t) -`1l`
1204	\|\| data[cnt].from_pc < sortsym[runp->idx]->addr
1205	\|\| (data[cnt].from_pc
1206	>= (sortsym[runp->idx]->addr
1207	+ sortsym[runp->idx]->size))))))
1208	runp = runp->next;
1209
1210	if (runp == NULL)
1211	{
1212	/ We need a new entry. /
1213	struct arc_list newp = (struct* arc_list *)
1214	obstack_alloc (&ob_list, sizeof (struct arc_list));
1215
1216	if (data[cnt].from_pc == `0`)
1217	newp->idx = (size_t) -`1l`;
1218	else
1219	newp->idx = find_symbol (addr: data[cnt].from_pc);
1220	newp->count = data[cnt].count;
1221	newp->next = sym->froms;
1222	sym->froms = newp;
1223	}
1224	else
1225	/ Increment the counter for the found entry. /
1226	runp->count += data[cnt].count;
1227	}
1228
1229	/ Now add it to the appropriate outgoing list. /
1230	sym_idx = find_symbol (addr: data[cnt].from_pc);
1231	if (sym_idx != (size_t) -`1l`)
1232	{
1233	struct known_symbol *sym = sortsym[sym_idx];
1234	struct arc_list *runp = sym->tos;
1235
1236	while (runp != NULL
1237	&& (runp->idx == (size_t) -`1l`
1238	\|\| data[cnt].self_pc < sortsym[runp->idx]->addr
1239	\|\| data[cnt].self_pc >= (sortsym[runp->idx]->addr
1240	+ sortsym[runp->idx]->size)))
1241	runp = runp->next;
1242
1243	if (runp == NULL)
1244	{
1245	/ We need a new entry. /
1246	struct arc_list newp = (struct* arc_list *)
1247	obstack_alloc (&ob_list, sizeof (struct arc_list));
1248
1249	newp->idx = find_symbol (addr: data[cnt].self_pc);
1250	newp->count = data[cnt].count;
1251	newp->next = sym->tos;
1252	sym->tos = newp;
1253	}
1254	else
1255	/ Increment the counter for the found entry. /
1256	runp->count += data[cnt].count;
1257	}
1258	}
1259	}
1260
1261
1262	static int
1263	countorder (const void p1, const* void *p2)
1264	{
1265	struct known_symbol s1 = (struct* known_symbol *) p1;
1266	struct known_symbol s2 = (struct* known_symbol *) p2;
1267
1268	if (s1->ticks != s2->ticks)
1269	return (int) (s2->ticks - s1->ticks);
1270
1271	if (s1->calls != s2->calls)
1272	return (int) (s2->calls - s1->calls);
1273
1274	return strcmp (s1: s1->name, s2: s2->name);
1275	}
1276
1277
1278	static double tick_unit;
1279	static uintmax_t cumu_ticks;
1280
1281	static void
1282	printflat (const void node, VISIT value, int* level)
1283	{
1284	if (value == leaf \|\| value == postorder)
1285	{
1286	struct known_symbol s = (struct known_symbol **) node;
1287
1288	cumu_ticks += s->ticks;
1289
1290	printf (format: "%6.2f%10.2f%9.2f%9" PRIdMAX "%9.2f %s\n",
1291	total_ticks ? (`100.0` * s->ticks) / total_ticks : `0.0`,
1292	tick_unit * cumu_ticks,
1293	tick_unit * s->ticks,
1294	s->calls,
1295	s->calls ? (s->ticks * `1000000`) * tick_unit / s->calls : `0`,
1296	/ FIXME: don't know about called functions. /
1297	s->name);
1298	}
1299	}
1300
1301
1302	/ ARGUSED /
1303	static void
1304	freenoop (void *p)
1305	{
1306	}
1307
1308
1309	static void
1310	generate_flat_profile (struct profdata *profdata)
1311	{
1312	size_t n;
1313	void *data = NULL;
1314
1315	tick_unit = `1.0` / profdata->hist_hdr->prof_rate;
1316
1317	printf (format: "Flat profile:\n\n"
1318	"Each sample counts as %g %s.\n",
1319	tick_unit, profdata->hist_hdr->dimen);
1320	fputs (s: " % cumulative self self total\n"
1321	" time seconds seconds calls us/call us/call name\n",
1322	stdout);
1323
1324	for (n = `0`; n < symidx; ++n)
1325	if (sortsym[n]->calls != `0` \|\| sortsym[n]->ticks != `0`)
1326	tsearch (key: sortsym[n], rootp: &data, compar: countorder);
1327
1328	twalk (root: data, action: printflat);
1329
1330	tdestroy (root: data, freefct: freenoop);
1331	}
1332
1333
1334	static void
1335	generate_call_graph (struct profdata *profdata)
1336	{
1337	size_t cnt;
1338
1339	puts (s: "\nindex % time self children called name\n");
1340
1341	for (cnt = `0`; cnt < symidx; ++cnt)
1342	if (sortsym[cnt]->froms != NULL \|\| sortsym[cnt]->tos != NULL)
1343	{
1344	struct arc_list *runp;
1345	size_t n;
1346
1347	/ First print the from-information. /
1348	runp = sortsym[cnt]->froms;
1349	while (runp != NULL)
1350	{
1351	printf (format: " %8.2f%8.2f%9" PRIdMAX "/%-9" PRIdMAX " %s",
1352	(runp->idx != (size_t) -`1l`
1353	? sortsym[runp->idx]->ticks * tick_unit : `0.0`),
1354	`0.0`, / FIXME: what's time for the children, recursive /
1355	runp->count, sortsym[cnt]->calls,
1356	(runp->idx != (size_t) -`1l`
1357	? sortsym[runp->idx]->name : "<UNKNOWN>"));
1358
1359	if (runp->idx != (size_t) -`1l`)
1360	printf (format: " [%Zd]", runp->idx);
1361	putchar_unlocked (c: `'\n'`);
1362
1363	runp = runp->next;
1364	}
1365
1366	/ Info about the function itself. /
1367	n = printf (format: "[%Zu]", cnt);
1368	printf (format: "%*s%5.1f%8.2f%8.2f%9" PRIdMAX " %s [%Zd]\n",
1369	(int) (`7` - n), " ",
1370	total_ticks ? (`100.0` * sortsym[cnt]->ticks) / total_ticks : `0`,
1371	sortsym[cnt]->ticks * tick_unit,
1372	`0.0`, / FIXME: what's time for the children, recursive /
1373	sortsym[cnt]->calls,
1374	sortsym[cnt]->name, cnt);
1375
1376	/ Info about the functions this function calls. /
1377	runp = sortsym[cnt]->tos;
1378	while (runp != NULL)
1379	{
1380	printf (format: " %8.2f%8.2f%9" PRIdMAX "/",
1381	(runp->idx != (size_t) -`1l`
1382	? sortsym[runp->idx]->ticks * tick_unit : `0.0`),
1383	`0.0`, / FIXME: what's time for the children, recursive /
1384	runp->count);
1385
1386	if (runp->idx != (size_t) -`1l`)
1387	printf (format: "%-9" PRIdMAX " %s [%Zd]\n",
1388	sortsym[runp->idx]->calls,
1389	sortsym[runp->idx]->name,
1390	runp->idx);
1391	else
1392	fputs (s: "??? <UNKNOWN>\n\n", stdout);
1393
1394	runp = runp->next;
1395	}
1396
1397	fputs (s: "-----------------------------------------------\n", stdout);
1398	}
1399	}
1400
1401
1402	static void
1403	generate_call_pair_list (struct profdata *profdata)
1404	{
1405	size_t cnt;
1406
1407	for (cnt = `0`; cnt < symidx; ++cnt)
1408	if (sortsym[cnt]->froms != NULL \|\| sortsym[cnt]->tos != NULL)
1409	{
1410	struct arc_list *runp;
1411
1412	/ First print the incoming arcs. /
1413	runp = sortsym[cnt]->froms;
1414	while (runp != NULL)
1415	{
1416	if (runp->idx == (size_t) -`1l`)
1417	printf (format: "\
1418	<UNKNOWN> %-34s %9" PRIdMAX "\n",
1419	sortsym[cnt]->name, runp->count);
1420	runp = runp->next;
1421	}
1422
1423	/ Next the outgoing arcs. /
1424	runp = sortsym[cnt]->tos;
1425	while (runp != NULL)
1426	{
1427	printf (format: "%-34s %-34s %9" PRIdMAX "\n",
1428	sortsym[cnt]->name,
1429	(runp->idx != (size_t) -`1l`
1430	? sortsym[runp->idx]->name : "<UNKNOWN>"),
1431	runp->count);
1432	runp = runp->next;
1433	}
1434	}
1435	}
1436

source code of glibc/elf/sprof.c