usr.sbin/tprof/tprof_analyze.c

1.3.2.2  pgoyette /*	$NetBSD: tprof_analyze.c,v 1.3.2.2 2018/07/28 04:38:15 pgoyette Exp $	*/
1.3.2.2  pgoyette
1.3.2.2  pgoyette /*
1.3.2.2  pgoyette  * Copyright (c) 2010,2011,2012 YAMAMOTO Takashi,
1.3.2.2  pgoyette  * All rights reserved.
1.3.2.2  pgoyette  *
1.3.2.2  pgoyette  * Redistribution and use in source and binary forms, with or without
1.3.2.2  pgoyette  * modification, are permitted provided that the following conditions
1.3.2.2  pgoyette  * are met:
1.3.2.2  pgoyette  * 1. Redistributions of source code must retain the above copyright
1.3.2.2  pgoyette  *    notice, this list of conditions and the following disclaimer.
1.3.2.2  pgoyette  * 2. Redistributions in binary form must reproduce the above copyright
1.3.2.2  pgoyette  *    notice, this list of conditions and the following disclaimer in the
1.3.2.2  pgoyette  *    documentation and/or other materials provided with the distribution.
1.3.2.2  pgoyette  *
1.3.2.2  pgoyette  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
1.3.2.2  pgoyette  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.3.2.2  pgoyette  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.3.2.2  pgoyette  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
1.3.2.2  pgoyette  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.3.2.2  pgoyette  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.3.2.2  pgoyette  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.3.2.2  pgoyette  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.3.2.2  pgoyette  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.3.2.2  pgoyette  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.3.2.2  pgoyette  * SUCH DAMAGE.
1.3.2.2  pgoyette  */
1.3.2.2  pgoyette
1.3.2.2  pgoyette #include <sys/cdefs.h>
1.3.2.2  pgoyette #ifndef lint
1.3.2.2  pgoyette __RCSID("$NetBSD: tprof_analyze.c,v 1.3.2.2 2018/07/28 04:38:15 pgoyette Exp $");
1.3.2.2  pgoyette #endif /* not lint */
1.3.2.2  pgoyette
1.3.2.2  pgoyette #include <assert.h>
1.3.2.2  pgoyette #include <err.h>
1.3.2.2  pgoyette #include <errno.h>
1.3.2.2  pgoyette #include <fcntl.h>
1.3.2.2  pgoyette #include <gelf.h>
1.3.2.2  pgoyette #include <inttypes.h>
1.3.2.2  pgoyette #include <libelf.h>
1.3.2.2  pgoyette #include <stdbool.h>
1.3.2.2  pgoyette #include <stdlib.h>
1.3.2.2  pgoyette #include <stdio.h>
1.3.2.2  pgoyette #include <unistd.h>
1.3.2.2  pgoyette #include <string.h>
1.3.2.2  pgoyette #include <util.h>
1.3.2.2  pgoyette #include <dev/tprof/tprof_ioctl.h>
1.3.2.2  pgoyette #include "tprof.h"
1.3.2.2  pgoyette
1.3.2.2  pgoyette #define	_PATH_KSYMS	"/dev/ksyms"
1.3.2.2  pgoyette
1.3.2.2  pgoyette #include <sys/rbtree.h>
1.3.2.2  pgoyette
1.3.2.2  pgoyette static bool filter_by_pid;
1.3.2.2  pgoyette static pid_t target_pid;
1.3.2.2  pgoyette static bool per_symbol;
1.3.2.2  pgoyette
1.3.2.2  pgoyette struct addr {
1.3.2.2  pgoyette 	struct rb_node node;
1.3.2.2  pgoyette 	uint64_t addr;		/* address */
1.3.2.2  pgoyette 	uint32_t pid;		/* process id */
1.3.2.2  pgoyette 	uint32_t lwpid;		/* lwp id */
1.3.2.2  pgoyette 	uint32_t cpuid;		/* cpu id */
1.3.2.2  pgoyette 	bool in_kernel;		/* if addr is in the kernel address space */
1.3.2.2  pgoyette 	unsigned int nsamples;	/* number of samples taken for the address */
1.3.2.2  pgoyette };
1.3.2.2  pgoyette
1.3.2.2  pgoyette static rb_tree_t addrtree;
1.3.2.2  pgoyette
1.3.2.2  pgoyette struct sym {
1.3.2.2  pgoyette 	char *name;
1.3.2.2  pgoyette 	uint64_t value;
1.3.2.2  pgoyette 	uint64_t size;
1.3.2.2  pgoyette };
1.3.2.2  pgoyette
1.3.2.2  pgoyette static struct sym **syms = NULL;
1.3.2.2  pgoyette static size_t nsyms = 0;
1.3.2.2  pgoyette
1.3.2.2  pgoyette static int
1.3.2.2  pgoyette compare_value(const void *p1, const void *p2)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const struct sym *s1 = *(const struct sym * const *)p1;
1.3.2.2  pgoyette 	const struct sym *s2 = *(const struct sym * const *)p2;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if (s1->value > s2->value) {
1.3.2.2  pgoyette 		return -1;
1.3.2.2  pgoyette 	} else if (s1->value < s2->value) {
1.3.2.2  pgoyette 		return 1;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	/*
1.3.2.2  pgoyette 	 * to produce a stable result, it's better not to return 0
1.3.2.2  pgoyette 	 * even for __strong_alias.
1.3.2.2  pgoyette 	 */
1.3.2.2  pgoyette 	if (s1->size > s2->size) {
1.3.2.2  pgoyette 		return -1;
1.3.2.2  pgoyette 	} else if (s1->size < s2->size) {
1.3.2.2  pgoyette 		return 1;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return strcmp(s1->name, s2->name);
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette static void
1.3.2.2  pgoyette ksymload(void)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	Elf *e;
1.3.2.2  pgoyette 	Elf_Scn *s;
1.3.2.2  pgoyette 	GElf_Shdr sh_store;
1.3.2.2  pgoyette 	GElf_Shdr *sh;
1.3.2.2  pgoyette 	Elf_Data *d;
1.3.2.2  pgoyette 	int fd;
1.3.2.2  pgoyette 	size_t size, i;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	fd = open(_PATH_KSYMS, O_RDONLY);
1.3.2.2  pgoyette 	if (fd == -1) {
1.3.2.2  pgoyette 		err(EXIT_FAILURE, "open");
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	if (elf_version(EV_CURRENT) == EV_NONE) {
1.3.2.2  pgoyette 		goto elffail;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	e = elf_begin(fd, ELF_C_READ, NULL);
1.3.2.2  pgoyette 	if (e == NULL) {
1.3.2.2  pgoyette 		goto elffail;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	for (s = elf_nextscn(e, NULL); s != NULL; s = elf_nextscn(e, s)) {
1.3.2.2  pgoyette 		sh = gelf_getshdr(s, &sh_store);
1.3.2.2  pgoyette 		if (sh == NULL) {
1.3.2.2  pgoyette 			goto elffail;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		if (sh->sh_type == SHT_SYMTAB) {
1.3.2.2  pgoyette 			break;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	if (s == NULL) {
1.3.2.2  pgoyette 		errx(EXIT_FAILURE, "no symtab");
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	d = elf_getdata(s, NULL);
1.3.2.2  pgoyette 	if (d == NULL) {
1.3.2.2  pgoyette 		goto elffail;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	assert(sh->sh_size == d->d_size);
1.3.2.2  pgoyette 	size = sh->sh_size / sh->sh_entsize;
1.3.2.2  pgoyette 	for (i = 1; i < size; i++) {
1.3.2.2  pgoyette 		GElf_Sym st_store;
1.3.2.2  pgoyette 		GElf_Sym *st;
1.3.2.2  pgoyette 		struct sym *sym;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		st = gelf_getsym(d, (int)i, &st_store);
1.3.2.2  pgoyette 		if (st == NULL) {
1.3.2.2  pgoyette 			goto elffail;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		if (ELF_ST_TYPE(st->st_info) != STT_FUNC) {
1.3.2.2  pgoyette 			continue;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		sym = emalloc(sizeof(*sym));
1.3.2.2  pgoyette 		sym->name = estrdup(elf_strptr(e, sh->sh_link, st->st_name));
1.3.2.2  pgoyette 		sym->value = (uint64_t)st->st_value;
1.3.2.2  pgoyette 		sym->size = st->st_size;
1.3.2.2  pgoyette 		nsyms++;
1.3.2.2  pgoyette 		syms = erealloc(syms, sizeof(*syms) * nsyms);
1.3.2.2  pgoyette 		syms[nsyms - 1] = sym;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	qsort(syms, nsyms, sizeof(*syms), compare_value);
1.3.2.2  pgoyette 	return;
1.3.2.2  pgoyette elffail:
1.3.2.2  pgoyette 	errx(EXIT_FAILURE, "libelf: %s", elf_errmsg(elf_errno()));
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette static const char *
1.3.2.2  pgoyette ksymlookup(uint64_t value, uint64_t *offset)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	size_t hi;
1.3.2.2  pgoyette 	size_t lo;
1.3.2.2  pgoyette 	size_t i;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	/*
1.3.2.2  pgoyette 	 * try to find the smallest i for which syms[i]->value <= value.
1.3.2.2  pgoyette 	 * syms[] is ordered by syms[]->value in the descending order.
1.3.2.2  pgoyette 	 */
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	hi = nsyms - 1;
1.3.2.2  pgoyette 	lo = 0;
1.3.2.2  pgoyette 	while (lo < hi) {
1.3.2.2  pgoyette 		const size_t mid = (lo + hi) / 2;
1.3.2.2  pgoyette 		const struct sym *sym = syms[mid];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		assert(syms[lo]->value >= sym->value);
1.3.2.2  pgoyette 		assert(sym->value >= syms[hi]->value);
1.3.2.2  pgoyette 		if (sym->value <= value) {
1.3.2.2  pgoyette 			hi = mid;
1.3.2.2  pgoyette 			continue;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		lo = mid + 1;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	assert(lo == nsyms - 1 || syms[lo]->value <= value);
1.3.2.2  pgoyette 	assert(lo == 0 || syms[lo - 1]->value > value);
1.3.2.2  pgoyette 	for (i = lo; i < nsyms; i++) {
1.3.2.2  pgoyette 		const struct sym *sym = syms[i];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		if (sym->value <= value &&
1.3.2.2  pgoyette 		    (sym->size == 0 || value - sym->value <= sym->size )) {
1.3.2.2  pgoyette 			*offset = value - sym->value;
1.3.2.2  pgoyette 			return sym->name;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		if (sym->size != 0 && sym->value + sym->size < value) {
1.3.2.2  pgoyette 			break;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return NULL;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette static signed int
1.3.2.2  pgoyette addrtree_compare_key(void *ctx, const void *n1, const void *keyp)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const struct addr *a1 = n1;
1.3.2.2  pgoyette 	const struct addr *a2 = (const struct addr *)keyp;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if (a1->addr > a2->addr) {
1.3.2.2  pgoyette 		return 1;
1.3.2.2  pgoyette 	} else if (a1->addr < a2->addr) {
1.3.2.2  pgoyette 		return -1;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	if (a1->pid > a2->pid) {
1.3.2.2  pgoyette 		return -1;
1.3.2.2  pgoyette 	} else if (a1->pid < a2->pid) {
1.3.2.2  pgoyette 		return 1;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	if (a1->lwpid > a2->lwpid) {
1.3.2.2  pgoyette 		return -1;
1.3.2.2  pgoyette 	} else if (a1->lwpid < a2->lwpid) {
1.3.2.2  pgoyette 		return 1;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	if (a1->cpuid > a2->cpuid) {
1.3.2.2  pgoyette 		return -1;
1.3.2.2  pgoyette 	} else if (a1->cpuid < a2->cpuid) {
1.3.2.2  pgoyette 		return 1;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	if (a1->in_kernel > a2->in_kernel) {
1.3.2.2  pgoyette 		return -1;
1.3.2.2  pgoyette 	} else if (a1->in_kernel < a2->in_kernel) {
1.3.2.2  pgoyette 		return 1;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return 0;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette static signed int
1.3.2.2  pgoyette addrtree_compare_nodes(void *ctx, const void *n1, const void *n2)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const struct addr *a2 = n2;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	return addrtree_compare_key(ctx, n1, a2);
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette static const rb_tree_ops_t addrtree_ops = {
1.3.2.2  pgoyette 	.rbto_compare_nodes = addrtree_compare_nodes,
1.3.2.2  pgoyette 	.rbto_compare_key = addrtree_compare_key,
1.3.2.2  pgoyette };
1.3.2.2  pgoyette
1.3.2.2  pgoyette static int
1.3.2.2  pgoyette compare_nsamples(const void *p1, const void *p2)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const struct addr *a1 = *(const struct addr * const *)p1;
1.3.2.2  pgoyette 	const struct addr *a2 = *(const struct addr * const *)p2;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if (a1->nsamples > a2->nsamples) {
1.3.2.2  pgoyette 		return -1;
1.3.2.2  pgoyette 	} else if (a1->nsamples < a2->nsamples) {
1.3.2.2  pgoyette 		return 1;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return 0;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette void
1.3.2.2  pgoyette tprof_analyze(int argc, char **argv)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	struct addr *a;
1.3.2.2  pgoyette 	struct addr **l;
1.3.2.2  pgoyette 	struct addr **p;
1.3.2.2  pgoyette 	size_t naddrs, nsamples, i;
1.3.2.2  pgoyette 	float perc;
1.3.2.2  pgoyette 	int ch;
1.3.2.2  pgoyette 	bool distinguish_processes = true;
1.3.2.2  pgoyette 	bool distinguish_cpus = true;
1.3.2.2  pgoyette 	bool distinguish_lwps = true;
1.3.2.2  pgoyette 	bool kernel_only = false;
1.3.2.2  pgoyette 	extern char *optarg;
1.3.2.2  pgoyette 	extern int optind;
1.3.2.2  pgoyette 	FILE *f;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	while ((ch = getopt(argc, argv, "CkLPp:s")) != -1) {
1.3.2.2  pgoyette 		uintmax_t val;
1.3.2.2  pgoyette 		char *ep;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		switch (ch) {
1.3.2.2  pgoyette 		case 'C':	/* don't distinguish cpus */
1.3.2.2  pgoyette 			distinguish_cpus = false;
1.3.2.2  pgoyette 			break;
1.3.2.2  pgoyette 		case 'k':	/* kernel only */
1.3.2.2  pgoyette 			kernel_only = true;
1.3.2.2  pgoyette 			break;
1.3.2.2  pgoyette 		case 'L':	/* don't distinguish lwps */
1.3.2.2  pgoyette 			distinguish_lwps = false;
1.3.2.2  pgoyette 			break;
1.3.2.2  pgoyette 		case 'p':	/* only for the process for the given pid */
1.3.2.2  pgoyette 			errno = 0;
1.3.2.2  pgoyette 			val = strtoumax(optarg, &ep, 10);
1.3.2.2  pgoyette 			if (optarg[0] == 0 || *ep != 0 ||
1.3.2.2  pgoyette 			    val > INT32_MAX) {
1.3.2.2  pgoyette 				errx(EXIT_FAILURE, "invalid p option");
1.3.2.2  pgoyette 			}
1.3.2.2  pgoyette 			target_pid = val;
1.3.2.2  pgoyette 			filter_by_pid = true;
1.3.2.2  pgoyette 			break;
1.3.2.2  pgoyette 		case 'P':	/* don't distinguish processes */
1.3.2.2  pgoyette 			distinguish_processes = false;
1.3.2.2  pgoyette 			break;
1.3.2.2  pgoyette 		case 's':	/* per symbol */
1.3.2.2  pgoyette 			per_symbol = true;
1.3.2.2  pgoyette 			break;
1.3.2.2  pgoyette 		default:
1.3.2.2  pgoyette 			exit(EXIT_FAILURE);
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	argc -= optind;
1.3.2.2  pgoyette 	argv += optind;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if (argc == 0) {
1.3.2.2  pgoyette 		errx(EXIT_FAILURE, "missing file name");
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	f = fopen(argv[0], "rb");
1.3.2.2  pgoyette 	if (f == NULL) {
1.3.2.2  pgoyette 		errx(EXIT_FAILURE, "fopen");
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	ksymload();
1.3.2.2  pgoyette 	rb_tree_init(&addrtree, &addrtree_ops);
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	/*
1.3.2.2  pgoyette 	 * read and count samples.
1.3.2.2  pgoyette 	 */
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	naddrs = 0;
1.3.2.2  pgoyette 	nsamples = 0;
1.3.2.2  pgoyette 	while (/*CONSTCOND*/true) {
1.3.2.2  pgoyette 		struct addr *o;
1.3.2.2  pgoyette 		tprof_sample_t sample;
1.3.2.2  pgoyette 		size_t n = fread(&sample, sizeof(sample), 1, f);
1.3.2.2  pgoyette 		bool in_kernel;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		if (n == 0) {
1.3.2.2  pgoyette 			if (feof(f)) {
1.3.2.2  pgoyette 				break;
1.3.2.2  pgoyette 			}
1.3.2.2  pgoyette 			if (ferror(f)) {
1.3.2.2  pgoyette 				err(EXIT_FAILURE, "fread");
1.3.2.2  pgoyette 			}
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		if (filter_by_pid && (pid_t)sample.s_pid != target_pid) {
1.3.2.2  pgoyette 			continue;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		in_kernel = (sample.s_flags & TPROF_SAMPLE_INKERNEL) != 0;
1.3.2.2  pgoyette 		if (kernel_only && !in_kernel) {
1.3.2.2  pgoyette 			continue;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		a = emalloc(sizeof(*a));
1.3.2.2  pgoyette 		a->addr = (uint64_t)sample.s_pc;
1.3.2.2  pgoyette 		if (distinguish_processes) {
1.3.2.2  pgoyette 			a->pid = sample.s_pid;
1.3.2.2  pgoyette 		} else {
1.3.2.2  pgoyette 			a->pid = 0;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		if (distinguish_lwps) {
1.3.2.2  pgoyette 			a->lwpid = sample.s_lwpid;
1.3.2.2  pgoyette 		} else {
1.3.2.2  pgoyette 			a->lwpid = 0;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		if (distinguish_cpus) {
1.3.2.2  pgoyette 			a->cpuid = sample.s_cpuid;
1.3.2.2  pgoyette 		} else {
1.3.2.2  pgoyette 			a->cpuid = 0;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		a->in_kernel = in_kernel;
1.3.2.2  pgoyette 		if (per_symbol) {
1.3.2.2  pgoyette 			const char *name;
1.3.2.2  pgoyette 			uint64_t offset;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 			name = ksymlookup(a->addr, &offset);
1.3.2.2  pgoyette 			if (name != NULL) {
1.3.2.2  pgoyette 				a->addr -= offset;
1.3.2.2  pgoyette 			}
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		a->nsamples = 1;
1.3.2.2  pgoyette 		o = rb_tree_insert_node(&addrtree, a);
1.3.2.2  pgoyette 		if (o != a) {
1.3.2.2  pgoyette 			assert(a->addr == o->addr);
1.3.2.2  pgoyette 			assert(a->pid == o->pid);
1.3.2.2  pgoyette 			assert(a->lwpid == o->lwpid);
1.3.2.2  pgoyette 			assert(a->cpuid == o->cpuid);
1.3.2.2  pgoyette 			assert(a->in_kernel == o->in_kernel);
1.3.2.2  pgoyette 			free(a);
1.3.2.2  pgoyette 			o->nsamples++;
1.3.2.2  pgoyette 		} else {
1.3.2.2  pgoyette 			naddrs++;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		nsamples++;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	/*
1.3.2.2  pgoyette 	 * sort samples by addresses.
1.3.2.2  pgoyette 	 */
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	l = emalloc(naddrs * sizeof(*l));
1.3.2.2  pgoyette 	p = l;
1.3.2.2  pgoyette 	RB_TREE_FOREACH(a, &addrtree) {
1.3.2.2  pgoyette 		*p++ = a;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	assert(l + naddrs == p);
1.3.2.2  pgoyette 	qsort(l, naddrs, sizeof(*l), compare_nsamples);
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	/*
1.3.2.2  pgoyette 	 * print addresses and number of samples, preferably with
1.3.2.2  pgoyette 	 * resolved symbol names.
1.3.2.2  pgoyette 	 */
1.3.2.2  pgoyette 	printf("File: %s\n", argv[0]);
1.3.2.2  pgoyette 	printf("Number of samples: %zu\n\n", nsamples);
1.3.2.2  pgoyette 	printf("percentage   nsamples pid    lwp  cpu  k address          symbol\n");
1.3.2.2  pgoyette 	printf("------------ -------- ------ ---- ---- - ---------------- ------\n");
1.3.2.2  pgoyette 	for (i = 0; i < naddrs; i++) {
1.3.2.2  pgoyette 		const char *name;
1.3.2.2  pgoyette 		char buf[100];
1.3.2.2  pgoyette 		uint64_t offset;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		a = l[i];
1.3.2.2  pgoyette 		if (a->in_kernel) {
1.3.2.2  pgoyette 			name = ksymlookup(a->addr, &offset);
1.3.2.2  pgoyette 		} else {
1.3.2.2  pgoyette 			name = NULL;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		if (name == NULL) {
1.3.2.2  pgoyette 			(void)snprintf(buf, sizeof(buf), "<%016" PRIx64 ">",
1.3.2.2  pgoyette 			    a->addr);
1.3.2.2  pgoyette 			name = buf;
1.3.2.2  pgoyette 		} else if (offset != 0) {
1.3.2.2  pgoyette 			(void)snprintf(buf, sizeof(buf), "%s+0x%" PRIx64, name,
1.3.2.2  pgoyette 			    offset);
1.3.2.2  pgoyette 			name = buf;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		perc = ((float)a->nsamples / (float)nsamples) * 100.0;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		printf("%11f%% %8u %6" PRIu32 " %4" PRIu32 " %4" PRIu32 " %u %016"
1.3.2.2  pgoyette 		    PRIx64 " %s\n",
1.3.2.2  pgoyette 		    perc,
1.3.2.2  pgoyette 		    a->nsamples, a->pid, a->lwpid, a->cpuid, a->in_kernel,
1.3.2.2  pgoyette 		    a->addr, name);
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	fclose(f);
1.3.2.2  pgoyette }