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freebsd_amp_hwpstate/usr.sbin/pmcstat/pmcstat_log.c

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/*-
* Copyright (c) 2005-2007, Joseph Koshy
* Copyright (c) 2007 The FreeBSD Foundation
* All rights reserved.
*
* Portions of this software were developed by A. Joseph Koshy under
* sponsorship from the FreeBSD Foundation and Google, Inc.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
/*
* Transform a hwpmc(4) log into human readable form, and into
* gprof(1) compatible profiles.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/param.h>
#include <sys/endian.h>
#include <sys/gmon.h>
#include <sys/imgact_aout.h>
#include <sys/imgact_elf.h>
#include <sys/mman.h>
#include <sys/pmc.h>
#include <sys/queue.h>
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/wait.h>
#include <netinet/in.h>
#include <assert.h>
#include <err.h>
#include <errno.h>
#include <fcntl.h>
#include <gelf.h>
#include <libgen.h>
#include <limits.h>
#include <netdb.h>
#include <pmc.h>
#include <pmclog.h>
#include <sysexits.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include "pmcstat.h"
#define min(A,B) ((A) < (B) ? (A) : (B))
#define max(A,B) ((A) > (B) ? (A) : (B))
#define PMCSTAT_ALLOCATE 1
/*
* PUBLIC INTERFACES
*
* pmcstat_initialize_logging() initialize this module, called first
* pmcstat_shutdown_logging() orderly shutdown, called last
* pmcstat_open_log() open an eventlog for processing
* pmcstat_process_log() print/convert an event log
* pmcstat_close_log() finish processing an event log
*
* IMPLEMENTATION NOTES
*
* We correlate each 'callchain' or 'sample' entry seen in the event
* log back to an executable object in the system. Executable objects
* include:
* - program executables,
* - shared libraries loaded by the runtime loader,
* - dlopen()'ed objects loaded by the program,
* - the runtime loader itself,
* - the kernel and kernel modules.
*
* Each process that we know about is treated as a set of regions that
* map to executable objects. Processes are described by
* 'pmcstat_process' structures. Executable objects are tracked by
* 'pmcstat_image' structures. The kernel and kernel modules are
* common to all processes (they reside at the same virtual addresses
* for all processes). Individual processes can have their text
* segments and shared libraries loaded at process-specific locations.
*
* A given executable object can be in use by multiple processes
* (e.g., libc.so) and loaded at a different address in each.
* pmcstat_pcmap structures track per-image mappings.
*
* The sample log could have samples from multiple PMCs; we
* generate one 'gmon.out' profile per PMC.
*
* IMPLEMENTATION OF GMON OUTPUT
*
* Each executable object gets one 'gmon.out' profile, per PMC in
* use. Creation of 'gmon.out' profiles is done lazily. The
* 'gmon.out' profiles generated for a given sampling PMC are
* aggregates of all the samples for that particular executable
* object.
*
* IMPLEMENTATION OF SYSTEM-WIDE CALLGRAPH OUTPUT
*
* Each active pmcid has its own callgraph structure, described by a
* 'struct pmcstat_callgraph'. Given a process id and a list of pc
* values, we map each pc value to a tuple (image, symbol), where
* 'image' denotes an executable object and 'symbol' is the closest
* symbol that precedes the pc value. Each pc value in the list is
* also given a 'rank' that reflects its depth in the call stack.
*/
typedef const void *pmcstat_interned_string;
/*
* 'pmcstat_pmcrecord' is a mapping from PMC ids to human-readable
* names.
*/
struct pmcstat_pmcrecord {
LIST_ENTRY(pmcstat_pmcrecord) pr_next;
pmc_id_t pr_pmcid;
pmcstat_interned_string pr_pmcname;
};
static LIST_HEAD(,pmcstat_pmcrecord) pmcstat_pmcs =
LIST_HEAD_INITIALIZER(&pmcstat_pmcs);
/*
* struct pmcstat_gmonfile tracks a given 'gmon.out' file. These
* files are mmap()'ed in as needed.
*/
struct pmcstat_gmonfile {
LIST_ENTRY(pmcstat_gmonfile) pgf_next; /* list of entries */
int pgf_overflow; /* whether a count overflowed */
pmc_id_t pgf_pmcid; /* id of the associated pmc */
size_t pgf_nbuckets; /* #buckets in this gmon.out */
unsigned int pgf_nsamples; /* #samples in this gmon.out */
pmcstat_interned_string pgf_name; /* pathname of gmon.out file */
size_t pgf_ndatabytes; /* number of bytes mapped */
void *pgf_gmondata; /* pointer to mmap'ed data */
FILE *pgf_file; /* used when writing gmon arcs */
};
/*
* A 'pmcstat_image' structure describes an executable program on
* disk. 'pi_execpath' is a cookie representing the pathname of
* the executable. 'pi_start' and 'pi_end' are the least and greatest
* virtual addresses for the text segments in the executable.
* 'pi_gmonlist' contains a linked list of gmon.out files associated
* with this image.
*/
enum pmcstat_image_type {
PMCSTAT_IMAGE_UNKNOWN = 0, /* never looked at the image */
PMCSTAT_IMAGE_INDETERMINABLE, /* can't tell what the image is */
PMCSTAT_IMAGE_ELF32, /* ELF 32 bit object */
PMCSTAT_IMAGE_ELF64, /* ELF 64 bit object */
PMCSTAT_IMAGE_AOUT /* AOUT object */
};
struct pmcstat_image {
LIST_ENTRY(pmcstat_image) pi_next; /* hash link */
TAILQ_ENTRY(pmcstat_image) pi_lru; /* LRU list */
pmcstat_interned_string pi_execpath; /* cookie */
pmcstat_interned_string pi_samplename; /* sample path name */
pmcstat_interned_string pi_fullpath; /* path to FS object */
enum pmcstat_image_type pi_type; /* executable type */
/*
* Executables have pi_start and pi_end; these are zero
* for shared libraries.
*/
uintfptr_t pi_start; /* start address (inclusive) */
uintfptr_t pi_end; /* end address (exclusive) */
uintfptr_t pi_entry; /* entry address */
uintfptr_t pi_vaddr; /* virtual address where loaded */
int pi_isdynamic; /* whether a dynamic object */
int pi_iskernelmodule;
pmcstat_interned_string pi_dynlinkerpath; /* path in .interp */
/* All symbols associated with this object. */
struct pmcstat_symbol *pi_symbols;
size_t pi_symcount;
/*
* An image can be associated with one or more gmon.out files;
* one per PMC.
*/
LIST_HEAD(,pmcstat_gmonfile) pi_gmlist;
};
/*
* All image descriptors are kept in a hash table.
*/
static LIST_HEAD(,pmcstat_image) pmcstat_image_hash[PMCSTAT_NHASH];
/*
* A 'pmcstat_pcmap' structure maps a virtual address range to an
* underlying 'pmcstat_image' descriptor.
*/
struct pmcstat_pcmap {
TAILQ_ENTRY(pmcstat_pcmap) ppm_next;
uintfptr_t ppm_lowpc;
uintfptr_t ppm_highpc;
struct pmcstat_image *ppm_image;
};
/*
* A 'pmcstat_process' structure models processes. Each process is
* associated with a set of pmcstat_pcmap structures that map
* addresses inside it to executable objects. This set is implemented
* as a list, kept sorted in ascending order of mapped addresses.
*
* 'pp_pid' holds the pid of the process. When a process exits, the
* 'pp_isactive' field is set to zero, but the process structure is
* not immediately reclaimed because there may still be samples in the
* log for this process.
*/
struct pmcstat_process {
LIST_ENTRY(pmcstat_process) pp_next; /* hash-next */
pid_t pp_pid; /* associated pid */
int pp_isactive; /* whether active */
uintfptr_t pp_entryaddr; /* entry address */
TAILQ_HEAD(,pmcstat_pcmap) pp_map; /* address range map */
};
/*
* All process descriptors are kept in a hash table.
*/
static LIST_HEAD(,pmcstat_process) pmcstat_process_hash[PMCSTAT_NHASH];
static struct pmcstat_process *pmcstat_kernproc; /* kernel 'process' */
/*
* Each function symbol tracked by pmcstat(8).
*/
struct pmcstat_symbol {
pmcstat_interned_string ps_name;
uint64_t ps_start;
uint64_t ps_end;
};
/*
* Each call graph node is tracked by a pmcstat_cgnode struct.
*/
struct pmcstat_cgnode {
struct pmcstat_image *pcg_image;
uintfptr_t pcg_func;
uint32_t pcg_count;
uint32_t pcg_nchildren;
LIST_ENTRY(pmcstat_cgnode) pcg_sibling;
LIST_HEAD(,pmcstat_cgnode) pcg_children;
};
struct pmcstat_cgnode_hash {
struct pmcstat_cgnode *pch_cgnode;
uint32_t pch_pmcid;
LIST_ENTRY(pmcstat_cgnode_hash) pch_next;
};
static int pmcstat_cgnode_hash_count;
static pmcstat_interned_string pmcstat_previous_filename_printed;
/*
* The toplevel CG nodes (i.e., with rank == 0) are placed in a hash table.
*/
static LIST_HEAD(,pmcstat_cgnode_hash) pmcstat_cgnode_hash[PMCSTAT_NHASH];
/* Misc. statistics */
static struct pmcstat_stats {
int ps_exec_aout; /* # a.out executables seen */
int ps_exec_elf; /* # elf executables seen */
int ps_exec_errors; /* # errors processing executables */
int ps_exec_indeterminable; /* # unknown executables seen */
int ps_samples_total; /* total number of samples processed */
int ps_samples_skipped; /* #samples filtered out for any reason */
int ps_samples_unknown_offset; /* #samples of rank 0 not in a map */
int ps_samples_indeterminable; /* #samples in indeterminable images */
int ps_callchain_dubious_frames;/* #dubious frame pointers seen */
} pmcstat_stats;
/*
* Prototypes
*/
static void pmcstat_gmon_create_file(struct pmcstat_gmonfile *_pgf,
struct pmcstat_image *_image);
static pmcstat_interned_string pmcstat_gmon_create_name(const char *_sd,
struct pmcstat_image *_img, pmc_id_t _pmcid);
static void pmcstat_gmon_map_file(struct pmcstat_gmonfile *_pgf);
static void pmcstat_gmon_unmap_file(struct pmcstat_gmonfile *_pgf);
static void pmcstat_image_determine_type(struct pmcstat_image *_image,
struct pmcstat_args *_a);
static struct pmcstat_gmonfile *pmcstat_image_find_gmonfile(struct
pmcstat_image *_i, pmc_id_t _id);
static struct pmcstat_image *pmcstat_image_from_path(pmcstat_interned_string
_path, int _iskernelmodule);
static void pmcstat_image_get_aout_params(struct pmcstat_image *_image,
struct pmcstat_args *_a);
static void pmcstat_image_get_elf_params(struct pmcstat_image *_image,
struct pmcstat_args *_a);
static void pmcstat_image_increment_bucket(struct pmcstat_pcmap *_pcm,
uintfptr_t _pc, pmc_id_t _pmcid, struct pmcstat_args *_a);
static void pmcstat_image_link(struct pmcstat_process *_pp,
struct pmcstat_image *_i, uintfptr_t _lpc);
static void pmcstat_pmcid_add(pmc_id_t _pmcid,
pmcstat_interned_string _name, struct pmcstat_args *_a);
static const char *pmcstat_pmcid_to_name(pmc_id_t _pmcid);
static void pmcstat_process_aout_exec(struct pmcstat_process *_pp,
struct pmcstat_image *_image, uintfptr_t _entryaddr,
struct pmcstat_args *_a);
static void pmcstat_process_elf_exec(struct pmcstat_process *_pp,
struct pmcstat_image *_image, uintfptr_t _entryaddr,
struct pmcstat_args *_a);
static void pmcstat_process_exec(struct pmcstat_process *_pp,
pmcstat_interned_string _path, uintfptr_t _entryaddr,
struct pmcstat_args *_ao);
static struct pmcstat_process *pmcstat_process_lookup(pid_t _pid,
int _allocate);
static struct pmcstat_pcmap *pmcstat_process_find_map(
struct pmcstat_process *_p, uintfptr_t _pc);
static int pmcstat_string_compute_hash(const char *_string);
static void pmcstat_string_initialize(void);
static pmcstat_interned_string pmcstat_string_intern(const char *_s);
static pmcstat_interned_string pmcstat_string_lookup(const char *_s);
static int pmcstat_string_lookup_hash(pmcstat_interned_string _is);
static void pmcstat_string_shutdown(void);
static const char *pmcstat_string_unintern(pmcstat_interned_string _is);
/*
* A simple implementation of interned strings. Each interned string
* is assigned a unique address, so that subsequent string compares
* can be done by a simple pointer comparision instead of using
* strcmp(). This speeds up hash table lookups and saves memory if
* duplicate strings are the norm.
*/
struct pmcstat_string {
LIST_ENTRY(pmcstat_string) ps_next; /* hash link */
int ps_len;
int ps_hash;
char *ps_string;
};
static LIST_HEAD(,pmcstat_string) pmcstat_string_hash[PMCSTAT_NHASH];
/*
* Compute a 'hash' value for a string.
*/
static int
pmcstat_string_compute_hash(const char *s)
{
int hash;
for (hash = 0; *s; s++)
hash ^= *s;
return (hash & PMCSTAT_HASH_MASK);
}
/*
* Intern a copy of string 's', and return a pointer to the
* interned structure.
*/
static pmcstat_interned_string
pmcstat_string_intern(const char *s)
{
struct pmcstat_string *ps;
const struct pmcstat_string *cps;
int hash, len;
if ((cps = pmcstat_string_lookup(s)) != NULL)
return (cps);
hash = pmcstat_string_compute_hash(s);
len = strlen(s);
if ((ps = malloc(sizeof(*ps))) == NULL)
err(EX_OSERR, "ERROR: Could not intern string");
ps->ps_len = len;
ps->ps_hash = hash;
ps->ps_string = strdup(s);
LIST_INSERT_HEAD(&pmcstat_string_hash[hash], ps, ps_next);
return ((pmcstat_interned_string) ps);
}
static const char *
pmcstat_string_unintern(pmcstat_interned_string str)
{
const char *s;
s = ((const struct pmcstat_string *) str)->ps_string;
return (s);
}
static pmcstat_interned_string
pmcstat_string_lookup(const char *s)
{
struct pmcstat_string *ps;
int hash, len;
hash = pmcstat_string_compute_hash(s);
len = strlen(s);
LIST_FOREACH(ps, &pmcstat_string_hash[hash], ps_next)
if (ps->ps_len == len && ps->ps_hash == hash &&
strcmp(ps->ps_string, s) == 0)
return (ps);
return (NULL);
}
static int
pmcstat_string_lookup_hash(pmcstat_interned_string s)
{
const struct pmcstat_string *ps;
ps = (const struct pmcstat_string *) s;
return (ps->ps_hash);
}
/*
* Initialize the string interning facility.
*/
static void
pmcstat_string_initialize(void)
{
int i;
for (i = 0; i < PMCSTAT_NHASH; i++)
LIST_INIT(&pmcstat_string_hash[i]);
}
/*
* Destroy the string table, free'ing up space.
*/
static void
pmcstat_string_shutdown(void)
{
int i;
struct pmcstat_string *ps, *pstmp;
for (i = 0; i < PMCSTAT_NHASH; i++)
LIST_FOREACH_SAFE(ps, &pmcstat_string_hash[i], ps_next,
pstmp) {
LIST_REMOVE(ps, ps_next);
free(ps->ps_string);
free(ps);
}
}
/*
* Create a gmon.out file and size it.
*/
static void
pmcstat_gmon_create_file(struct pmcstat_gmonfile *pgf,
struct pmcstat_image *image)
{
int fd;
size_t count;
struct gmonhdr gm;
const char *pathname;
char buffer[DEFAULT_BUFFER_SIZE];
pathname = pmcstat_string_unintern(pgf->pgf_name);
if ((fd = open(pathname, O_RDWR|O_NOFOLLOW|O_CREAT,
S_IRUSR|S_IWUSR|S_IRGRP|S_IROTH)) < 0)
err(EX_OSERR, "ERROR: Cannot open \"%s\"", pathname);
gm.lpc = image->pi_start;
gm.hpc = image->pi_end;
gm.ncnt = (pgf->pgf_nbuckets * sizeof(HISTCOUNTER)) +
sizeof(struct gmonhdr);
gm.version = GMONVERSION;
gm.profrate = 0; /* use ticks */
gm.histcounter_type = 0; /* compatibility with moncontrol() */
gm.spare[0] = gm.spare[1] = 0;
/* Write out the gmon header */
if (write(fd, &gm, sizeof(gm)) < 0)
goto error;
/* Zero fill the samples[] array */
(void) memset(buffer, 0, sizeof(buffer));
count = pgf->pgf_ndatabytes - sizeof(struct gmonhdr);
while (count > sizeof(buffer)) {
if (write(fd, &buffer, sizeof(buffer)) < 0)
goto error;
count -= sizeof(buffer);
}
if (write(fd, &buffer, count) < 0)
goto error;
(void) close(fd);
return;
error:
err(EX_OSERR, "ERROR: Cannot write \"%s\"", pathname);
}
/*
* Determine the full pathname of a gmon.out file for a given
* (image,pmcid) combination. Return the interned string.
*/
pmcstat_interned_string
pmcstat_gmon_create_name(const char *samplesdir, struct pmcstat_image *image,
pmc_id_t pmcid)
{
const char *pmcname;
char fullpath[PATH_MAX];
pmcname = pmcstat_pmcid_to_name(pmcid);
(void) snprintf(fullpath, sizeof(fullpath),
"%s/%s/%s", samplesdir, pmcname,
pmcstat_string_unintern(image->pi_samplename));
return (pmcstat_string_intern(fullpath));
}
/*
* Mmap in a gmon.out file for processing.
*/
static void
pmcstat_gmon_map_file(struct pmcstat_gmonfile *pgf)
{
int fd;
const char *pathname;
pathname = pmcstat_string_unintern(pgf->pgf_name);
/* the gmon.out file must already exist */
if ((fd = open(pathname, O_RDWR | O_NOFOLLOW, 0)) < 0)
err(EX_OSERR, "ERROR: cannot open \"%s\"", pathname);
pgf->pgf_gmondata = mmap(NULL, pgf->pgf_ndatabytes,
PROT_READ|PROT_WRITE, MAP_NOSYNC|MAP_SHARED, fd, 0);
if (pgf->pgf_gmondata == MAP_FAILED)
err(EX_OSERR, "ERROR: cannot map \"%s\"", pathname);
(void) close(fd);
}
/*
* Unmap a gmon.out file after sync'ing its data to disk.
*/
static void
pmcstat_gmon_unmap_file(struct pmcstat_gmonfile *pgf)
{
(void) msync(pgf->pgf_gmondata, pgf->pgf_ndatabytes,
MS_SYNC);
(void) munmap(pgf->pgf_gmondata, pgf->pgf_ndatabytes);
pgf->pgf_gmondata = NULL;
}
static void
pmcstat_gmon_append_arc(struct pmcstat_image *image, pmc_id_t pmcid,
uintptr_t rawfrom, uintptr_t rawto, uint32_t count)
{
struct rawarc arc; /* from <sys/gmon.h> */
const char *pathname;
struct pmcstat_gmonfile *pgf;
if ((pgf = pmcstat_image_find_gmonfile(image, pmcid)) == NULL)
return;
if (pgf->pgf_file == NULL) {
pathname = pmcstat_string_unintern(pgf->pgf_name);
if ((pgf->pgf_file = fopen(pathname, "a")) == NULL)
return;
}
arc.raw_frompc = rawfrom + image->pi_vaddr;
arc.raw_selfpc = rawto + image->pi_vaddr;
arc.raw_count = count;
(void) fwrite(&arc, sizeof(arc), 1, pgf->pgf_file);
}
static struct pmcstat_gmonfile *
pmcstat_image_find_gmonfile(struct pmcstat_image *image, pmc_id_t pmcid)
{
struct pmcstat_gmonfile *pgf;
LIST_FOREACH(pgf, &image->pi_gmlist, pgf_next)
if (pgf->pgf_pmcid == pmcid)
return (pgf);
return (NULL);
}
/*
* Determine whether a given executable image is an A.OUT object, and
* if so, fill in its parameters from the text file.
* Sets image->pi_type.
*/
static void
pmcstat_image_get_aout_params(struct pmcstat_image *image,
struct pmcstat_args *a)
{
int fd;
ssize_t nbytes;
struct exec ex;
const char *path;
char buffer[PATH_MAX];
path = pmcstat_string_unintern(image->pi_execpath);
assert(path != NULL);
if (image->pi_iskernelmodule)
errx(EX_SOFTWARE, "ERROR: a.out kernel modules are "
"unsupported \"%s\"", path);
(void) snprintf(buffer, sizeof(buffer), "%s%s",
a->pa_fsroot, path);
if ((fd = open(buffer, O_RDONLY, 0)) < 0 ||
(nbytes = read(fd, &ex, sizeof(ex))) < 0) {
warn("WARNING: Cannot determine type of \"%s\"", path);
image->pi_type = PMCSTAT_IMAGE_INDETERMINABLE;
if (fd != -1)
(void) close(fd);
return;
}
(void) close(fd);
if ((unsigned) nbytes != sizeof(ex) ||
N_BADMAG(ex))
return;
image->pi_type = PMCSTAT_IMAGE_AOUT;
/* TODO: the rest of a.out processing */
return;
}
/*
* Helper function.
*/
static int
pmcstat_symbol_compare(const void *a, const void *b)
{
const struct pmcstat_symbol *sym1, *sym2;
sym1 = (const struct pmcstat_symbol *) a;
sym2 = (const struct pmcstat_symbol *) b;
if (sym1->ps_end <= sym2->ps_start)
return (-1);
if (sym1->ps_start >= sym2->ps_end)
return (1);
return (0);
}
/*
* Map an address to a symbol in an image.
*/
static struct pmcstat_symbol *
pmcstat_symbol_search(struct pmcstat_image *image, uintfptr_t addr)
{
struct pmcstat_symbol sym;
if (image->pi_symbols == NULL)
return (NULL);
sym.ps_name = NULL;
sym.ps_start = addr;
sym.ps_end = addr + 1;
return (bsearch((void *) &sym, image->pi_symbols,
image->pi_symcount, sizeof(struct pmcstat_symbol),
pmcstat_symbol_compare));
}
/*
* Add the list of symbols in the given section to the list associated
* with the object.
*/
static void
pmcstat_image_add_symbols(struct pmcstat_image *image, Elf *e,
Elf_Scn *scn, GElf_Shdr *sh)
{
int firsttime;
size_t n, newsyms, nshsyms, nfuncsyms;
struct pmcstat_symbol *symptr;
char *fnname;
GElf_Sym sym;
Elf_Data *data;
if ((data = elf_getdata(scn, NULL)) == NULL)
return;
/*
* Determine the number of functions named in this
* section.
*/
nshsyms = sh->sh_size / sh->sh_entsize;
for (n = nfuncsyms = 0; n < nshsyms; n++) {
if (gelf_getsym(data, (int) n, &sym) != &sym)
return;
if (GELF_ST_TYPE(sym.st_info) == STT_FUNC)
nfuncsyms++;
}
if (nfuncsyms == 0)
return;
/*
* Allocate space for the new entries.
*/
firsttime = image->pi_symbols == NULL;
symptr = realloc(image->pi_symbols,
sizeof(*symptr) * (image->pi_symcount + nfuncsyms));
if (symptr == image->pi_symbols) /* realloc() failed. */
return;
image->pi_symbols = symptr;
/*
* Append new symbols to the end of the current table.
*/
symptr += image->pi_symcount;
for (n = newsyms = 0; n < nshsyms; n++) {
if (gelf_getsym(data, (int) n, &sym) != &sym)
return;
if (GELF_ST_TYPE(sym.st_info) != STT_FUNC)
continue;
if (!firsttime && pmcstat_symbol_search(image, sym.st_value))
continue; /* We've seen this symbol already. */
if ((fnname = elf_strptr(e, sh->sh_link, sym.st_name))
== NULL)
continue;
symptr->ps_name = pmcstat_string_intern(fnname);
symptr->ps_start = sym.st_value - image->pi_vaddr;
symptr->ps_end = symptr->ps_start + sym.st_size;
symptr++;
newsyms++;
}
image->pi_symcount += newsyms;
assert(newsyms <= nfuncsyms);
/*
* Return space to the system if there were duplicates.
*/
if (newsyms < nfuncsyms)
image->pi_symbols = realloc(image->pi_symbols,
sizeof(*symptr) * image->pi_symcount);
/*
* Keep the list of symbols sorted.
*/
qsort(image->pi_symbols, image->pi_symcount, sizeof(*symptr),
pmcstat_symbol_compare);
/*
* Deal with function symbols that have a size of 'zero' by
* making them extend to the next higher address. These
* symbols are usually defined in assembly code.
*/
for (symptr = image->pi_symbols;
symptr < image->pi_symbols + (image->pi_symcount - 1);
symptr++)
if (symptr->ps_start == symptr->ps_end)
symptr->ps_end = (symptr+1)->ps_start;
}
/*
* Examine an ELF file to determine the size of its text segment.
* Sets image->pi_type if anything conclusive can be determined about
* this image.
*/
static void
pmcstat_image_get_elf_params(struct pmcstat_image *image,
struct pmcstat_args *a)
{
int fd;
size_t i, nph, nsh;
const char *path, *elfbase;
uintfptr_t minva, maxva;
Elf *e;
Elf_Scn *scn;
GElf_Ehdr eh;
GElf_Phdr ph;
GElf_Shdr sh;
enum pmcstat_image_type image_type;
char buffer[PATH_MAX];
assert(image->pi_type == PMCSTAT_IMAGE_UNKNOWN);
image->pi_start = minva = ~(uintfptr_t) 0;
image->pi_end = maxva = (uintfptr_t) 0;
image->pi_type = image_type = PMCSTAT_IMAGE_INDETERMINABLE;
image->pi_isdynamic = 0;
image->pi_dynlinkerpath = NULL;
image->pi_vaddr = 0;
path = pmcstat_string_unintern(image->pi_execpath);
assert(path != NULL);
/*
* Look for kernel modules under FSROOT/KERNELPATH/NAME,
* and user mode executable objects under FSROOT/PATHNAME.
*/
if (image->pi_iskernelmodule)
(void) snprintf(buffer, sizeof(buffer), "%s%s/%s",
a->pa_fsroot, a->pa_kernel, path);
else
(void) snprintf(buffer, sizeof(buffer), "%s%s",
a->pa_fsroot, path);
e = NULL;
if ((fd = open(buffer, O_RDONLY, 0)) < 0 ||
(e = elf_begin(fd, ELF_C_READ, NULL)) == NULL ||
(elf_kind(e) != ELF_K_ELF)) {
warnx("WARNING: Cannot determine the type of \"%s\".",
buffer);
goto done;
}
if (gelf_getehdr(e, &eh) != &eh) {
warnx("WARNING: Cannot retrieve the ELF Header for "
"\"%s\": %s.", buffer, elf_errmsg(-1));
goto done;
}
if (eh.e_type != ET_EXEC && eh.e_type != ET_DYN &&
!(image->pi_iskernelmodule && eh.e_type == ET_REL)) {
warnx("WARNING: \"%s\" is of an unsupported ELF type.",
buffer);
goto done;
}
image_type = eh.e_ident[EI_CLASS] == ELFCLASS32 ?
PMCSTAT_IMAGE_ELF32 : PMCSTAT_IMAGE_ELF64;
/*
* Determine the virtual address where an executable would be
* loaded. Additionally, for dynamically linked executables,
* save the pathname to the runtime linker.
*/
if (eh.e_type == ET_EXEC) {
if (elf_getphnum(e, &nph) == 0) {
warnx("WARNING: Could not determine the number of "
"program headers in \"%s\": %s.", buffer,
elf_errmsg(-1));
goto done;
}
for (i = 0; i < eh.e_phnum; i++) {
if (gelf_getphdr(e, i, &ph) != &ph) {
warnx("WARNING: Retrieval of PHDR entry #%ju "
"in \"%s\" failed: %s.", (uintmax_t) i,
buffer, elf_errmsg(-1));
goto done;
}
switch (ph.p_type) {
case PT_DYNAMIC:
image->pi_isdynamic = 1;
break;
case PT_INTERP:
if ((elfbase = elf_rawfile(e, NULL)) == NULL) {
warnx("WARNING: Cannot retrieve the "
"interpreter for \"%s\": %s.",
buffer, elf_errmsg(-1));
goto done;
}
image->pi_dynlinkerpath =
pmcstat_string_intern(elfbase +
ph.p_offset);
break;
case PT_LOAD:
if (ph.p_offset == 0)
image->pi_vaddr = ph.p_vaddr;
break;
}
}
}
/*
* Get the min and max VA associated with this ELF object.
*/
if (elf_getshnum(e, &nsh) == 0) {
warnx("WARNING: Could not determine the number of sections "
"for \"%s\": %s.", buffer, elf_errmsg(-1));
goto done;
}
for (i = 0; i < nsh; i++) {
if ((scn = elf_getscn(e, i)) == NULL ||
gelf_getshdr(scn, &sh) != &sh) {
warnx("WARNING: Could not retrieve section header "
"#%ju in \"%s\": %s.", (uintmax_t) i, buffer,
elf_errmsg(-1));
goto done;
}
if (sh.sh_flags & SHF_EXECINSTR) {
minva = min(minva, sh.sh_addr);
maxva = max(maxva, sh.sh_addr + sh.sh_size);
}
if (sh.sh_type == SHT_SYMTAB || sh.sh_type == SHT_DYNSYM)
pmcstat_image_add_symbols(image, e, scn, &sh);
}
image->pi_start = minva;
image->pi_end = maxva;
image->pi_type = image_type;
image->pi_fullpath = pmcstat_string_intern(buffer);
done:
(void) elf_end(e);
if (fd >= 0)
(void) close(fd);
return;
}
/*
* Given an image descriptor, determine whether it is an ELF, or AOUT.
* If no handler claims the image, set its type to 'INDETERMINABLE'.
*/
static void
pmcstat_image_determine_type(struct pmcstat_image *image,
struct pmcstat_args *a)
{
assert(image->pi_type == PMCSTAT_IMAGE_UNKNOWN);
/* Try each kind of handler in turn */
if (image->pi_type == PMCSTAT_IMAGE_UNKNOWN)
pmcstat_image_get_elf_params(image, a);
if (image->pi_type == PMCSTAT_IMAGE_UNKNOWN)
pmcstat_image_get_aout_params(image, a);
/*
* Otherwise, remember that we tried to determine
* the object's type and had failed.
*/
if (image->pi_type == PMCSTAT_IMAGE_UNKNOWN)
image->pi_type = PMCSTAT_IMAGE_INDETERMINABLE;
}
/*
* Locate an image descriptor given an interned path, adding a fresh
* descriptor to the cache if necessary. This function also finds a
* suitable name for this image's sample file.
*
* We defer filling in the file format specific parts of the image
* structure till the time we actually see a sample that would fall
* into this image.
*/
static struct pmcstat_image *
pmcstat_image_from_path(pmcstat_interned_string internedpath,
int iskernelmodule)
{
int count, hash, nlen;
struct pmcstat_image *pi;
char *sn;
char name[NAME_MAX];
hash = pmcstat_string_lookup_hash(internedpath);
/* First, look for an existing entry. */
LIST_FOREACH(pi, &pmcstat_image_hash[hash], pi_next)
if (pi->pi_execpath == internedpath &&
pi->pi_iskernelmodule == iskernelmodule)
return (pi);
/*
* Allocate a new entry and place it at the head of the hash
* and LRU lists.
*/
pi = malloc(sizeof(*pi));
if (pi == NULL)
return (NULL);
pi->pi_type = PMCSTAT_IMAGE_UNKNOWN;
pi->pi_execpath = internedpath;
pi->pi_start = ~0;
pi->pi_end = 0;
pi->pi_entry = 0;
pi->pi_vaddr = 0;
pi->pi_isdynamic = 0;
pi->pi_iskernelmodule = iskernelmodule;
pi->pi_dynlinkerpath = NULL;
pi->pi_symbols = NULL;
pi->pi_symcount = 0;
/*
* Look for a suitable name for the sample files associated
* with this image: if `basename(path)`+".gmon" is available,
* we use that, otherwise we try iterating through
* `basename(path)`+ "~" + NNN + ".gmon" till we get a free
* entry.
*/
if ((sn = basename(pmcstat_string_unintern(internedpath))) == NULL)
err(EX_OSERR, "ERROR: Cannot process \"%s\"",
pmcstat_string_unintern(internedpath));
nlen = strlen(sn);
nlen = min(nlen, (int) (sizeof(name) - sizeof(".gmon")));
snprintf(name, sizeof(name), "%.*s.gmon", nlen, sn);
/* try use the unabridged name first */
if (pmcstat_string_lookup(name) == NULL)
pi->pi_samplename = pmcstat_string_intern(name);
else {
/*
* Otherwise use a prefix from the original name and
* upto 3 digits.
*/
nlen = strlen(sn);
nlen = min(nlen, (int) (sizeof(name)-sizeof("~NNN.gmon")));
count = 0;
do {
if (++count > 999)
errx(EX_CANTCREAT, "ERROR: cannot create a "
"gmon file for \"%s\"", name);
snprintf(name, sizeof(name), "%.*s~%3.3d.gmon",
nlen, sn, count);
if (pmcstat_string_lookup(name) == NULL) {
pi->pi_samplename =
pmcstat_string_intern(name);
count = 0;
}
} while (count > 0);
}
LIST_INIT(&pi->pi_gmlist);
LIST_INSERT_HEAD(&pmcstat_image_hash[hash], pi, pi_next);
return (pi);
}
/*
* Increment the bucket in the gmon.out file corresponding to 'pmcid'
* and 'pc'.
*/
static void
pmcstat_image_increment_bucket(struct pmcstat_pcmap *map, uintfptr_t pc,
pmc_id_t pmcid, struct pmcstat_args *a)
{
struct pmcstat_image *image;
struct pmcstat_gmonfile *pgf;
uintfptr_t bucket;
HISTCOUNTER *hc;
assert(pc >= map->ppm_lowpc && pc < map->ppm_highpc);
image = map->ppm_image;
/*
* If this is the first time we are seeing a sample for
* this executable image, try determine its parameters.
*/
if (image->pi_type == PMCSTAT_IMAGE_UNKNOWN)
pmcstat_image_determine_type(image, a);
assert(image->pi_type != PMCSTAT_IMAGE_UNKNOWN);
/* Ignore samples in images that we know nothing about. */
if (image->pi_type == PMCSTAT_IMAGE_INDETERMINABLE) {
pmcstat_stats.ps_samples_indeterminable++;
return;
}
/*
* Find the gmon file corresponding to 'pmcid', creating it if
* needed.
*/
pgf = pmcstat_image_find_gmonfile(image, pmcid);
if (pgf == NULL) {
if ((pgf = calloc(1, sizeof(*pgf))) == NULL)
err(EX_OSERR, "ERROR:");
pgf->pgf_gmondata = NULL; /* mark as unmapped */
pgf->pgf_name = pmcstat_gmon_create_name(a->pa_samplesdir,
image, pmcid);
pgf->pgf_pmcid = pmcid;
assert(image->pi_end > image->pi_start);
pgf->pgf_nbuckets = (image->pi_end - image->pi_start) /
FUNCTION_ALIGNMENT; /* see <machine/profile.h> */
pgf->pgf_ndatabytes = sizeof(struct gmonhdr) +
pgf->pgf_nbuckets * sizeof(HISTCOUNTER);
pgf->pgf_nsamples = 0;
pgf->pgf_file = NULL;
pmcstat_gmon_create_file(pgf, image);
LIST_INSERT_HEAD(&image->pi_gmlist, pgf, pgf_next);
}
/*
* Map the gmon file in if needed. It may have been mapped
* out under memory pressure.
*/
if (pgf->pgf_gmondata == NULL)
pmcstat_gmon_map_file(pgf);
assert(pgf->pgf_gmondata != NULL);
/*
*
*/
bucket = (pc - map->ppm_lowpc) / FUNCTION_ALIGNMENT;
assert(bucket < pgf->pgf_nbuckets);
hc = (HISTCOUNTER *) ((uintptr_t) pgf->pgf_gmondata +
sizeof(struct gmonhdr));
/* saturating add */
if (hc[bucket] < 0xFFFFU) /* XXX tie this to sizeof(HISTCOUNTER) */
hc[bucket]++;
else /* mark that an overflow occurred */
pgf->pgf_overflow = 1;
pgf->pgf_nsamples++;
}
/*
* Record the fact that PC values from 'start' to 'end' come from
* image 'image'.
*/
static void
pmcstat_image_link(struct pmcstat_process *pp, struct pmcstat_image *image,
uintfptr_t start)
{
struct pmcstat_pcmap *pcm, *pcmnew;
uintfptr_t offset;
assert(image->pi_type != PMCSTAT_IMAGE_UNKNOWN &&
image->pi_type != PMCSTAT_IMAGE_INDETERMINABLE);
if ((pcmnew = malloc(sizeof(*pcmnew))) == NULL)
err(EX_OSERR, "ERROR: Cannot create a map entry");
/*
* Adjust the map entry to only cover the text portion
* of the object.
*/
offset = start - image->pi_vaddr;
pcmnew->ppm_lowpc = image->pi_start + offset;
pcmnew->ppm_highpc = image->pi_end + offset;
pcmnew->ppm_image = image;
assert(pcmnew->ppm_lowpc < pcmnew->ppm_highpc);
/* Overlapped mmap()'s are assumed to never occur. */
TAILQ_FOREACH(pcm, &pp->pp_map, ppm_next)
if (pcm->ppm_lowpc >= pcmnew->ppm_highpc)
break;
if (pcm == NULL)
TAILQ_INSERT_TAIL(&pp->pp_map, pcmnew, ppm_next);
else
TAILQ_INSERT_BEFORE(pcm, pcmnew, ppm_next);
}
/*
* Unmap images in the range [start..end) associated with process
* 'pp'.
*/
static void
pmcstat_image_unmap(struct pmcstat_process *pp, uintfptr_t start,
uintfptr_t end)
{
struct pmcstat_pcmap *pcm, *pcmtmp, *pcmnew;
assert(pp != NULL);
assert(start < end);
/*
* Cases:
* - we could have the range completely in the middle of an
* existing pcmap; in this case we have to split the pcmap
* structure into two (i.e., generate a 'hole').
* - we could have the range covering multiple pcmaps; these
* will have to be removed.
* - we could have either 'start' or 'end' falling in the
* middle of a pcmap; in this case shorten the entry.
*/
TAILQ_FOREACH_SAFE(pcm, &pp->pp_map, ppm_next, pcmtmp) {
assert(pcm->ppm_lowpc < pcm->ppm_highpc);
if (pcm->ppm_highpc <= start)
continue;
if (pcm->ppm_lowpc >= end)
return;
if (pcm->ppm_lowpc >= start && pcm->ppm_highpc <= end) {
/*
* The current pcmap is completely inside the
* unmapped range: remove it entirely.
*/
TAILQ_REMOVE(&pp->pp_map, pcm, ppm_next);
free(pcm);
} else if (pcm->ppm_lowpc < start && pcm->ppm_highpc > end) {
/*
* Split this pcmap into two; curtail the
* current map to end at [start-1], and start
* the new one at [end].
*/
if ((pcmnew = malloc(sizeof(*pcmnew))) == NULL)
err(EX_OSERR, "ERROR: Cannot split a map "
"entry");
pcmnew->ppm_image = pcm->ppm_image;
pcmnew->ppm_lowpc = end;
pcmnew->ppm_highpc = pcm->ppm_highpc;
pcm->ppm_highpc = start;
TAILQ_INSERT_AFTER(&pp->pp_map, pcm, pcmnew, ppm_next);
return;
} else if (pcm->ppm_lowpc < start && pcm->ppm_highpc <= end)
pcm->ppm_highpc = start;
else if (pcm->ppm_lowpc >= start && pcm->ppm_highpc > end)
pcm->ppm_lowpc = end;
else
assert(0);
}
}
/*
* Add a {pmcid,name} mapping.
*/
static void
pmcstat_pmcid_add(pmc_id_t pmcid, pmcstat_interned_string ps,
struct pmcstat_args *a)
{
struct pmcstat_pmcrecord *pr;
struct stat st;
char fullpath[PATH_MAX];
/* Replace an existing name for the PMC. */
LIST_FOREACH(pr, &pmcstat_pmcs, pr_next)
if (pr->pr_pmcid == pmcid) {
pr->pr_pmcname = ps;
return;
}
/*
* Otherwise, allocate a new descriptor and create the
* appropriate directory to hold gmon.out files.
*/
if ((pr = malloc(sizeof(*pr))) == NULL)
err(EX_OSERR, "ERROR: Cannot allocate pmc record");
pr->pr_pmcid = pmcid;
pr->pr_pmcname = ps;
LIST_INSERT_HEAD(&pmcstat_pmcs, pr, pr_next);
(void) snprintf(fullpath, sizeof(fullpath), "%s/%s", a->pa_samplesdir,
pmcstat_string_unintern(ps));
/* If the path name exists, it should be a directory */
if (stat(fullpath, &st) == 0 && S_ISDIR(st.st_mode))
return;
if (mkdir(fullpath, S_IRWXU|S_IRGRP|S_IXGRP|S_IROTH|S_IXOTH) < 0)
err(EX_OSERR, "ERROR: Cannot create directory \"%s\"",
fullpath);
}
/*
* Given a pmcid in use, find its human-readable name.
*/
static const char *
pmcstat_pmcid_to_name(pmc_id_t pmcid)
{
struct pmcstat_pmcrecord *pr;
char fullpath[PATH_MAX];
LIST_FOREACH(pr, &pmcstat_pmcs, pr_next)
if (pr->pr_pmcid == pmcid)
return (pmcstat_string_unintern(pr->pr_pmcname));
/* create a default name and add this entry */
if ((pr = malloc(sizeof(*pr))) == NULL)
err(EX_OSERR, "ERROR: ");
pr->pr_pmcid = pmcid;
(void) snprintf(fullpath, sizeof(fullpath), "%X", (unsigned int) pmcid);
pr->pr_pmcname = pmcstat_string_intern(fullpath);
LIST_INSERT_HEAD(&pmcstat_pmcs, pr, pr_next);
return (pmcstat_string_unintern(pr->pr_pmcname));
}
/*
* Associate an AOUT image with a process.
*/
static void
pmcstat_process_aout_exec(struct pmcstat_process *pp,
struct pmcstat_image *image, uintfptr_t entryaddr,
struct pmcstat_args *a)
{
(void) pp;
(void) image;
(void) entryaddr;
(void) a;
/* TODO Implement a.out handling */
}
/*
* Associate an ELF image with a process.
*/
static void
pmcstat_process_elf_exec(struct pmcstat_process *pp,
struct pmcstat_image *image, uintfptr_t entryaddr,
struct pmcstat_args *a)
{
uintmax_t libstart;
struct pmcstat_image *rtldimage;
assert(image->pi_type == PMCSTAT_IMAGE_ELF32 ||
image->pi_type == PMCSTAT_IMAGE_ELF64);
/* Create a map entry for the base executable. */
pmcstat_image_link(pp, image, image->pi_vaddr);
/*
* For dynamically linked executables we need to determine
* where the dynamic linker was mapped to for this process,
* Subsequent executable objects that are mapped in by the
* dynamic linker will be tracked by log events of type
* PMCLOG_TYPE_MAP_IN.
*/
if (image->pi_isdynamic) {
/*
* The runtime loader gets loaded just after the maximum
* possible heap address. Like so:
*
* [ TEXT DATA BSS HEAP -->*RTLD SHLIBS <--STACK]
* ^ ^
* 0 VM_MAXUSER_ADDRESS
*
* The exact address where the loader gets mapped in
* will vary according to the size of the executable
* and the limits on the size of the process'es data
* segment at the time of exec(). The entry address
* recorded at process exec time corresponds to the
* 'start' address inside the dynamic linker. From
* this we can figure out the address where the
* runtime loader's file object had been mapped to.
*/
rtldimage = pmcstat_image_from_path(image->pi_dynlinkerpath,
0);
if (rtldimage == NULL) {
warnx("WARNING: Cannot find image for \"%s\".",
pmcstat_string_unintern(image->pi_dynlinkerpath));
pmcstat_stats.ps_exec_errors++;
return;
}
if (rtldimage->pi_type == PMCSTAT_IMAGE_UNKNOWN)
pmcstat_image_get_elf_params(rtldimage, a);
if (rtldimage->pi_type != PMCSTAT_IMAGE_ELF32 &&
rtldimage->pi_type != PMCSTAT_IMAGE_ELF64) {
warnx("WARNING: rtld not an ELF object \"%s\".",
pmcstat_string_unintern(image->pi_dynlinkerpath));
return;
}
libstart = entryaddr - rtldimage->pi_entry;
pmcstat_image_link(pp, rtldimage, libstart);
}
}
/*
* Find the process descriptor corresponding to a PID. If 'allocate'
* is zero, we return a NULL if a pid descriptor could not be found or
* a process descriptor process. If 'allocate' is non-zero, then we
* will attempt to allocate a fresh process descriptor. Zombie
* process descriptors are only removed if a fresh allocation for the
* same PID is requested.
*/
static struct pmcstat_process *
pmcstat_process_lookup(pid_t pid, int allocate)
{
uint32_t hash;
struct pmcstat_pcmap *ppm, *ppmtmp;
struct pmcstat_process *pp, *pptmp;
hash = (uint32_t) pid & PMCSTAT_HASH_MASK; /* simplicity wins */
LIST_FOREACH_SAFE(pp, &pmcstat_process_hash[hash], pp_next, pptmp)
if (pp->pp_pid == pid) {
/* Found a descriptor, check and process zombies */
if (allocate && pp->pp_isactive == 0) {
/* remove maps */
TAILQ_FOREACH_SAFE(ppm, &pp->pp_map, ppm_next,
ppmtmp) {
TAILQ_REMOVE(&pp->pp_map, ppm, ppm_next);
free(ppm);
}
/* remove process entry */
LIST_REMOVE(pp, pp_next);
free(pp);
break;
}
return (pp);
}
if (!allocate)
return (NULL);
if ((pp = malloc(sizeof(*pp))) == NULL)
err(EX_OSERR, "ERROR: Cannot allocate pid descriptor");
pp->pp_pid = pid;
pp->pp_isactive = 1;
TAILQ_INIT(&pp->pp_map);
LIST_INSERT_HEAD(&pmcstat_process_hash[hash], pp, pp_next);
return (pp);
}
/*
* Associate an image and a process.
*/
static void
pmcstat_process_exec(struct pmcstat_process *pp,
pmcstat_interned_string path, uintfptr_t entryaddr,
struct pmcstat_args *a)
{
struct pmcstat_image *image;
if ((image = pmcstat_image_from_path(path, 0)) == NULL) {
pmcstat_stats.ps_exec_errors++;
return;
}
if (image->pi_type == PMCSTAT_IMAGE_UNKNOWN)
pmcstat_image_determine_type(image, a);
assert(image->pi_type != PMCSTAT_IMAGE_UNKNOWN);
switch (image->pi_type) {
case PMCSTAT_IMAGE_ELF32:
case PMCSTAT_IMAGE_ELF64:
pmcstat_stats.ps_exec_elf++;
pmcstat_process_elf_exec(pp, image, entryaddr, a);
break;
case PMCSTAT_IMAGE_AOUT:
pmcstat_stats.ps_exec_aout++;
pmcstat_process_aout_exec(pp, image, entryaddr, a);
break;
case PMCSTAT_IMAGE_INDETERMINABLE:
pmcstat_stats.ps_exec_indeterminable++;
break;
default:
err(EX_SOFTWARE, "ERROR: Unsupported executable type for "
"\"%s\"", pmcstat_string_unintern(path));
}
}
/*
* Find the map entry associated with process 'p' at PC value 'pc'.
*/
static struct pmcstat_pcmap *
pmcstat_process_find_map(struct pmcstat_process *p, uintfptr_t pc)
{
struct pmcstat_pcmap *ppm;
TAILQ_FOREACH(ppm, &p->pp_map, ppm_next) {
if (pc >= ppm->ppm_lowpc && pc < ppm->ppm_highpc)
return (ppm);
if (pc < ppm->ppm_lowpc)
return (NULL);
}
return (NULL);
}
static struct pmcstat_cgnode *
pmcstat_cgnode_allocate(struct pmcstat_image *image, uintfptr_t pc)
{
struct pmcstat_cgnode *cg;
if ((cg = malloc(sizeof(*cg))) == NULL)
err(EX_OSERR, "ERROR: Cannot allocate callgraph node");
cg->pcg_image = image;
cg->pcg_func = pc;
cg->pcg_count = 0;
cg->pcg_nchildren = 0;
LIST_INIT(&cg->pcg_children);
return (cg);
}
/*
* Free a node and its children.
*/
static void
pmcstat_cgnode_free(struct pmcstat_cgnode *cg)
{
struct pmcstat_cgnode *cgc, *cgtmp;
LIST_FOREACH_SAFE(cgc, &cg->pcg_children, pcg_sibling, cgtmp)
pmcstat_cgnode_free(cgc);
free(cg);
}
/*
* Look for a callgraph node associated with pmc `pmcid' in the global
* hash table that corresponds to the given `pc' value in the process
* `pp'.
*/
static struct pmcstat_cgnode *
pmcstat_cgnode_hash_lookup_pc(struct pmcstat_process *pp, uint32_t pmcid,
uintfptr_t pc, int usermode)
{
struct pmcstat_pcmap *ppm;
struct pmcstat_symbol *sym;
struct pmcstat_image *image;
struct pmcstat_cgnode *cg;
struct pmcstat_cgnode_hash *h;
uintfptr_t loadaddress;
unsigned int i, hash;
ppm = pmcstat_process_find_map(usermode ? pp : pmcstat_kernproc, pc);
if (ppm == NULL)
return (NULL);
image = ppm->ppm_image;
loadaddress = ppm->ppm_lowpc + image->pi_vaddr - image->pi_start;
pc -= loadaddress; /* Convert to an offset in the image. */
/*
* Try determine the function at this offset. If we can't
* find a function round leave the `pc' value alone.
*/
if ((sym = pmcstat_symbol_search(image, pc)) != NULL)
pc = sym->ps_start;
for (hash = i = 0; i < sizeof(uintfptr_t); i++)
hash += (pc >> i) & 0xFF;
hash &= PMCSTAT_HASH_MASK;
cg = NULL;
LIST_FOREACH(h, &pmcstat_cgnode_hash[hash], pch_next)
{
if (h->pch_pmcid != pmcid)
continue;
cg = h->pch_cgnode;
assert(cg != NULL);
if (cg->pcg_image == image && cg->pcg_func == pc)
return (cg);
}
/*
* We haven't seen this (pmcid, pc) tuple yet, so allocate a
* new callgraph node and a new hash table entry for it.
*/
cg = pmcstat_cgnode_allocate(image, pc);
if ((h = malloc(sizeof(*h))) == NULL)
err(EX_OSERR, "ERROR: Could not allocate callgraph node");
h->pch_pmcid = pmcid;
h->pch_cgnode = cg;
LIST_INSERT_HEAD(&pmcstat_cgnode_hash[hash], h, pch_next);
pmcstat_cgnode_hash_count++;
return (cg);
}
/*
* Compare two callgraph nodes for sorting.
*/
static int
pmcstat_cgnode_compare(const void *a, const void *b)
{
const struct pmcstat_cgnode *const *pcg1, *const *pcg2, *cg1, *cg2;
pcg1 = (const struct pmcstat_cgnode *const *) a;
cg1 = *pcg1;
pcg2 = (const struct pmcstat_cgnode *const *) b;
cg2 = *pcg2;
/* Sort in reverse order */
if (cg1->pcg_count < cg2->pcg_count)
return (1);
if (cg1->pcg_count > cg2->pcg_count)
return (-1);
return (0);
}
/*
* Find (allocating if a needed) a callgraph node in the given
* parent with the same (image, pcoffset) pair.
*/
static struct pmcstat_cgnode *
pmcstat_cgnode_find(struct pmcstat_cgnode *parent, struct pmcstat_image *image,
uintfptr_t pcoffset)
{
struct pmcstat_cgnode *child;
LIST_FOREACH(child, &parent->pcg_children, pcg_sibling) {
if (child->pcg_image == image &&
child->pcg_func == pcoffset)
return (child);
}
/*
* Allocate a new structure.
*/
child = pmcstat_cgnode_allocate(image, pcoffset);
/*
* Link it into the parent.
*/
LIST_INSERT_HEAD(&parent->pcg_children, child, pcg_sibling);
parent->pcg_nchildren++;
return (child);
}
/*
* Print one callgraph node. The output format is:
*
* indentation %(parent's samples) #nsamples function@object
*/
static void
pmcstat_cgnode_print(struct pmcstat_args *a, struct pmcstat_cgnode *cg,
int depth, uint32_t total)
{
uint32_t n;
const char *space;
struct pmcstat_symbol *sym;
struct pmcstat_cgnode **sortbuffer, **cgn, *pcg;
space = " ";
if (depth > 0)
(void) fprintf(a->pa_graphfile, "%*s", depth, space);
if (cg->pcg_count == total)
(void) fprintf(a->pa_graphfile, "100.0%% ");
else
(void) fprintf(a->pa_graphfile, "%05.2f%% ",
100.0 * cg->pcg_count / total);
n = fprintf(a->pa_graphfile, " [%u] ", cg->pcg_count);
/* #samples is a 12 character wide field. */
if (n < 12)
(void) fprintf(a->pa_graphfile, "%*s", 12 - n, space);
if (depth > 0)
(void) fprintf(a->pa_graphfile, "%*s", depth, space);
sym = pmcstat_symbol_search(cg->pcg_image, cg->pcg_func);
if (sym)
(void) fprintf(a->pa_graphfile, "%s",
pmcstat_string_unintern(sym->ps_name));
else
(void) fprintf(a->pa_graphfile, "%p",
(void *) (cg->pcg_image->pi_vaddr + cg->pcg_func));
if (pmcstat_previous_filename_printed !=
cg->pcg_image->pi_fullpath) {
pmcstat_previous_filename_printed = cg->pcg_image->pi_fullpath;
(void) fprintf(a->pa_graphfile, " @ %s\n",
pmcstat_string_unintern(
pmcstat_previous_filename_printed));
} else
(void) fprintf(a->pa_graphfile, "\n");
if (cg->pcg_nchildren == 0)
return;
if ((sortbuffer = (struct pmcstat_cgnode **)
malloc(sizeof(struct pmcstat_cgnode *) *
cg->pcg_nchildren)) == NULL)
err(EX_OSERR, "ERROR: Cannot print callgraph");
cgn = sortbuffer;
LIST_FOREACH(pcg, &cg->pcg_children, pcg_sibling)
*cgn++ = pcg;
assert(cgn - sortbuffer == (int) cg->pcg_nchildren);
qsort(sortbuffer, cg->pcg_nchildren, sizeof(struct pmcstat_cgnode *),
pmcstat_cgnode_compare);
for (cgn = sortbuffer, n = 0; n < cg->pcg_nchildren; n++, cgn++)
pmcstat_cgnode_print(a, *cgn, depth+1, cg->pcg_count);
free(sortbuffer);
}
/*
* Record a callchain.
*/
static void
pmcstat_record_callchain(struct pmcstat_process *pp, uint32_t pmcid,
uint32_t nsamples, uintfptr_t *cc, int usermode, struct pmcstat_args *a)
{
uintfptr_t pc, loadaddress;
uint32_t n;
struct pmcstat_image *image;
struct pmcstat_pcmap *ppm;
struct pmcstat_symbol *sym;
struct pmcstat_cgnode *parent, *child;
/*
* Find the callgraph node recorded in the global hash table
* for this (pmcid, pc).
*/
pc = cc[0];
parent = pmcstat_cgnode_hash_lookup_pc(pp, pmcid, pc, usermode);
if (parent == NULL) {
pmcstat_stats.ps_callchain_dubious_frames++;
return;
}
parent->pcg_count++;
/*
* For each return address in the call chain record, subject
* to the maximum depth desired.
* - Find the image associated with the sample. Stop if there
* there is no valid image at that address.
* - Find the function that overlaps the return address.
* - If found: use the start address of the function.
* If not found (say an object's symbol table is not present or
* is incomplete), round down to th gprof bucket granularity.
* - Convert return virtual address to an offset in the image.
* - Look for a child with the same {offset,image} tuple,
* inserting one if needed.
* - Increment the count of occurrences of the child.
*/
for (n = 1; n < (uint32_t) a->pa_graphdepth && n < nsamples; n++,
parent = child) {
pc = cc[n];
ppm = pmcstat_process_find_map(usermode ? pp :
pmcstat_kernproc, pc);
if (ppm == NULL)
return;
image = ppm->ppm_image;
loadaddress = ppm->ppm_lowpc + image->pi_vaddr -
image->pi_start;
pc -= loadaddress;
if ((sym = pmcstat_symbol_search(image, pc)) != NULL)
pc = sym->ps_start;
child = pmcstat_cgnode_find(parent, image, pc);
child->pcg_count++;
}
}
/*
* Printing a callgraph for a PMC.
*/
static void
pmcstat_callgraph_print_for_pmcid(struct pmcstat_args *a,
struct pmcstat_pmcrecord *pmcr)
{
int n, nentries;
uint32_t nsamples, pmcid;
struct pmcstat_cgnode **sortbuffer, **cgn;
struct pmcstat_cgnode_hash *pch;
/*
* We pull out all callgraph nodes in the top-level hash table
* with a matching PMC id. We then sort these based on the
* frequency of occurrence. Each callgraph node is then
* printed.
*/
nsamples = 0;
pmcid = pmcr->pr_pmcid;
if ((sortbuffer = (struct pmcstat_cgnode **)
malloc(sizeof(struct pmcstat_cgnode *) *
pmcstat_cgnode_hash_count)) == NULL)
err(EX_OSERR, "ERROR: Cannot sort callgraph");
cgn = sortbuffer;
memset(sortbuffer, 0xFF, pmcstat_cgnode_hash_count *
sizeof(struct pmcstat_cgnode **));
for (n = 0; n < PMCSTAT_NHASH; n++)
LIST_FOREACH(pch, &pmcstat_cgnode_hash[n], pch_next)
if (pch->pch_pmcid == pmcid) {
nsamples += pch->pch_cgnode->pcg_count;
*cgn++ = pch->pch_cgnode;
}
nentries = cgn - sortbuffer;
assert(nentries <= pmcstat_cgnode_hash_count);
if (nentries == 0)
return;
qsort(sortbuffer, nentries, sizeof(struct pmcstat_cgnode *),
pmcstat_cgnode_compare);
(void) fprintf(a->pa_graphfile,
"@ %s [%u samples]\n\n",
pmcstat_string_unintern(pmcr->pr_pmcname),
nsamples);
for (cgn = sortbuffer, n = 0; n < nentries; n++, cgn++) {
pmcstat_previous_filename_printed = NULL;
pmcstat_cgnode_print(a, *cgn, 0, nsamples);
(void) fprintf(a->pa_graphfile, "\n");
}
free(sortbuffer);
}
/*
* Print out callgraphs.
*/
static void
pmcstat_callgraph_print(struct pmcstat_args *a)
{
struct pmcstat_pmcrecord *pmcr;
LIST_FOREACH(pmcr, &pmcstat_pmcs, pr_next)
pmcstat_callgraph_print_for_pmcid(a, pmcr);
}
static void
pmcstat_cgnode_do_gmon_arcs(struct pmcstat_cgnode *cg, pmc_id_t pmcid)
{
struct pmcstat_cgnode *cgc;
/*
* Look for child nodes that belong to the same image.
*/
LIST_FOREACH(cgc, &cg->pcg_children, pcg_sibling) {
if (cgc->pcg_image == cg->pcg_image)
pmcstat_gmon_append_arc(cg->pcg_image, pmcid,
cgc->pcg_func, cg->pcg_func, cgc->pcg_count);
if (cgc->pcg_nchildren > 0)
pmcstat_cgnode_do_gmon_arcs(cgc, pmcid);
}
}
static void
pmcstat_callgraph_do_gmon_arcs_for_pmcid(pmc_id_t pmcid)
{
int n;
struct pmcstat_cgnode_hash *pch;
for (n = 0; n < PMCSTAT_NHASH; n++)
LIST_FOREACH(pch, &pmcstat_cgnode_hash[n], pch_next)
if (pch->pch_pmcid == pmcid &&
pch->pch_cgnode->pcg_nchildren > 1)
pmcstat_cgnode_do_gmon_arcs(pch->pch_cgnode,
pmcid);
}
static void
pmcstat_callgraph_do_gmon_arcs(void)
{
struct pmcstat_pmcrecord *pmcr;
LIST_FOREACH(pmcr, &pmcstat_pmcs, pr_next)
pmcstat_callgraph_do_gmon_arcs_for_pmcid(pmcr->pr_pmcid);
}
/*
* Convert a hwpmc(4) log to profile information. A system-wide
* callgraph is generated if FLAG_DO_CALLGRAPHS is set. gmon.out
* files usable by gprof(1) are created if FLAG_DO_GPROF is set.
*/
static int
pmcstat_analyze_log(struct pmcstat_args *a)
{
uint32_t cpu, cpuflags;
uintfptr_t pc;
pid_t pid;
struct pmcstat_image *image;
struct pmcstat_process *pp, *ppnew;
struct pmcstat_pcmap *ppm, *ppmtmp;
struct pmclog_ev ev;
pmcstat_interned_string image_path;
assert(a->pa_flags & FLAG_DO_ANALYSIS);
if (elf_version(EV_CURRENT) == EV_NONE)
err(EX_UNAVAILABLE, "Elf library intialization failed");
while (pmclog_read(a->pa_logparser, &ev) == 0) {
assert(ev.pl_state == PMCLOG_OK);
switch (ev.pl_type) {
case PMCLOG_TYPE_INITIALIZE:
if ((ev.pl_u.pl_i.pl_version & 0xFF000000) !=
PMC_VERSION_MAJOR << 24 && a->pa_verbosity > 0)
warnx("WARNING: Log version 0x%x does not "
"match compiled version 0x%x.",
ev.pl_u.pl_i.pl_version,
PMC_VERSION_MAJOR);
break;
case PMCLOG_TYPE_MAP_IN:
/*
* Introduce an address range mapping for a
* userland process or the kernel (pid == -1).
*
* We always allocate a process descriptor so
* that subsequent samples seen for this
* address range are mapped to the current
* object being mapped in.
*/
pid = ev.pl_u.pl_mi.pl_pid;
if (pid == -1)
pp = pmcstat_kernproc;
else
pp = pmcstat_process_lookup(pid,
PMCSTAT_ALLOCATE);
assert(pp != NULL);
image_path = pmcstat_string_intern(ev.pl_u.pl_mi.
pl_pathname);
image = pmcstat_image_from_path(image_path, pid == -1);
if (image->pi_type == PMCSTAT_IMAGE_UNKNOWN)
pmcstat_image_determine_type(image, a);
if (image->pi_type != PMCSTAT_IMAGE_INDETERMINABLE)
pmcstat_image_link(pp, image,
ev.pl_u.pl_mi.pl_start);
break;
case PMCLOG_TYPE_MAP_OUT:
/*
* Remove an address map.
*/
pid = ev.pl_u.pl_mo.pl_pid;
if (pid == -1)
pp = pmcstat_kernproc;
else
pp = pmcstat_process_lookup(pid, 0);
if (pp == NULL) /* unknown process */
break;
pmcstat_image_unmap(pp, ev.pl_u.pl_mo.pl_start,
ev.pl_u.pl_mo.pl_end);
break;
case PMCLOG_TYPE_PCSAMPLE:
/*
* Note: the `PCSAMPLE' log entry is not
* generated by hpwmc(4) after version 2.
*/
/*
* We bring in the gmon file for the image
* currently associated with the PMC & pid
* pair and increment the appropriate entry
* bin inside this.
*/
pmcstat_stats.ps_samples_total++;
pc = ev.pl_u.pl_s.pl_pc;
pp = pmcstat_process_lookup(ev.pl_u.pl_s.pl_pid,
PMCSTAT_ALLOCATE);
if ((ppm = pmcstat_process_find_map(pp, pc)) == NULL &&
(ppm = pmcstat_process_find_map(pmcstat_kernproc,
pc)) == NULL) { /* unknown process,offset pair */
pmcstat_stats.ps_samples_unknown_offset++;
break;
}
pmcstat_image_increment_bucket(ppm, pc,
ev.pl_u.pl_s.pl_pmcid, a);
break;
case PMCLOG_TYPE_CALLCHAIN:
pmcstat_stats.ps_samples_total++;
cpuflags = ev.pl_u.pl_cc.pl_cpuflags;
cpu = PMC_CALLCHAIN_CPUFLAGS_TO_CPU(cpuflags);
/* Filter on the CPU id. */
if ((a->pa_cpumask & (1 << cpu)) == 0) {
pmcstat_stats.ps_samples_skipped++;
break;
}
pp = pmcstat_process_lookup(ev.pl_u.pl_cc.pl_pid,
PMCSTAT_ALLOCATE);
pmcstat_record_callchain(pp,
ev.pl_u.pl_cc.pl_pmcid, ev.pl_u.pl_cc.pl_npc,
ev.pl_u.pl_cc.pl_pc,
PMC_CALLCHAIN_CPUFLAGS_TO_USERMODE(cpuflags), a);
if ((a->pa_flags & FLAG_DO_GPROF) == 0)
break;
pc = ev.pl_u.pl_cc.pl_pc[0];
if ((ppm = pmcstat_process_find_map(pp, pc)) == NULL &&
(ppm = pmcstat_process_find_map(pmcstat_kernproc,
pc)) == NULL) { /* unknown offset */
pmcstat_stats.ps_samples_unknown_offset++;
break;
}
pmcstat_image_increment_bucket(ppm, pc,
ev.pl_u.pl_cc.pl_pmcid, a);
break;
case PMCLOG_TYPE_PMCALLOCATE:
/*
* Record the association pmc id between this
* PMC and its name.
*/
pmcstat_pmcid_add(ev.pl_u.pl_a.pl_pmcid,
pmcstat_string_intern(ev.pl_u.pl_a.pl_evname), a);
break;
case PMCLOG_TYPE_PROCEXEC:
/*
* Change the executable image associated with
* a process.
*/
pp = pmcstat_process_lookup(ev.pl_u.pl_x.pl_pid,
PMCSTAT_ALLOCATE);
/* delete the current process map */
TAILQ_FOREACH_SAFE(ppm, &pp->pp_map, ppm_next, ppmtmp) {
TAILQ_REMOVE(&pp->pp_map, ppm, ppm_next);
free(ppm);
}
/* associate this process image */
image_path = pmcstat_string_intern(
ev.pl_u.pl_x.pl_pathname);
assert(image_path != NULL);
pmcstat_process_exec(pp, image_path,
ev.pl_u.pl_x.pl_entryaddr, a);
break;
case PMCLOG_TYPE_PROCEXIT:
/*
* Due to the way the log is generated, the
* last few samples corresponding to a process
* may appear in the log after the process
* exit event is recorded. Thus we keep the
* process' descriptor and associated data
* structures around, but mark the process as
* having exited.
*/
pp = pmcstat_process_lookup(ev.pl_u.pl_e.pl_pid, 0);
if (pp == NULL)
break;
pp->pp_isactive = 0; /* mark as a zombie */
break;
case PMCLOG_TYPE_SYSEXIT:
pp = pmcstat_process_lookup(ev.pl_u.pl_se.pl_pid, 0);
if (pp == NULL)
break;
pp->pp_isactive = 0; /* make a zombie */
break;
case PMCLOG_TYPE_PROCFORK:
/*
* Allocate a process descriptor for the new
* (child) process.
*/
ppnew =
pmcstat_process_lookup(ev.pl_u.pl_f.pl_newpid,
PMCSTAT_ALLOCATE);
/*
* If we had been tracking the parent, clone
* its address maps.
*/
pp = pmcstat_process_lookup(ev.pl_u.pl_f.pl_oldpid, 0);
if (pp == NULL)
break;
TAILQ_FOREACH(ppm, &pp->pp_map, ppm_next)
pmcstat_image_link(ppnew, ppm->ppm_image,
ppm->ppm_lowpc);
break;
default: /* other types of entries are not relevant */
break;
}
}
if (ev.pl_state == PMCLOG_EOF)
return (PMCSTAT_FINISHED);
else if (ev.pl_state == PMCLOG_REQUIRE_DATA)
return (PMCSTAT_RUNNING);
err(EX_DATAERR, "ERROR: event parsing failed (record %jd, "
"offset 0x%jx)", (uintmax_t) ev.pl_count + 1, ev.pl_offset);
}
/*
* Print log entries as text.
*/
static int
pmcstat_print_log(struct pmcstat_args *a)
{
struct pmclog_ev ev;
uint32_t npc;
while (pmclog_read(a->pa_logparser, &ev) == 0) {
assert(ev.pl_state == PMCLOG_OK);
switch (ev.pl_type) {
case PMCLOG_TYPE_CALLCHAIN:
PMCSTAT_PRINT_ENTRY(a, "callchain",
"%d 0x%x %d %d %c", ev.pl_u.pl_cc.pl_pid,
ev.pl_u.pl_cc.pl_pmcid,
PMC_CALLCHAIN_CPUFLAGS_TO_CPU(ev.pl_u.pl_cc. \
pl_cpuflags), ev.pl_u.pl_cc.pl_npc,
PMC_CALLCHAIN_CPUFLAGS_TO_USERMODE(ev.pl_u.pl_cc.\
pl_cpuflags) ? 'u' : 's');
for (npc = 0; npc < ev.pl_u.pl_cc.pl_npc; npc++)
PMCSTAT_PRINT_ENTRY(a, "...", "%p",
(void *) ev.pl_u.pl_cc.pl_pc[npc]);
break;
case PMCLOG_TYPE_CLOSELOG:
PMCSTAT_PRINT_ENTRY(a,"closelog",);
break;
case PMCLOG_TYPE_DROPNOTIFY:
PMCSTAT_PRINT_ENTRY(a,"drop",);
break;
case PMCLOG_TYPE_INITIALIZE:
PMCSTAT_PRINT_ENTRY(a,"initlog","0x%x \"%s\"",
ev.pl_u.pl_i.pl_version,
pmc_name_of_cputype(ev.pl_u.pl_i.pl_arch));
if ((ev.pl_u.pl_i.pl_version & 0xFF000000) !=
PMC_VERSION_MAJOR << 24 && a->pa_verbosity > 0)
warnx("WARNING: Log version 0x%x != expected "
"version 0x%x.", ev.pl_u.pl_i.pl_version,
PMC_VERSION);
break;
case PMCLOG_TYPE_MAP_IN:
PMCSTAT_PRINT_ENTRY(a,"map-in","%d %p \"%s\"",
ev.pl_u.pl_mi.pl_pid,
(void *) ev.pl_u.pl_mi.pl_start,
ev.pl_u.pl_mi.pl_pathname);
break;
case PMCLOG_TYPE_MAP_OUT:
PMCSTAT_PRINT_ENTRY(a,"map-out","%d %p %p",
ev.pl_u.pl_mo.pl_pid,
(void *) ev.pl_u.pl_mo.pl_start,
(void *) ev.pl_u.pl_mo.pl_end);
break;
case PMCLOG_TYPE_PCSAMPLE:
PMCSTAT_PRINT_ENTRY(a,"sample","0x%x %d %p %c",
ev.pl_u.pl_s.pl_pmcid,
ev.pl_u.pl_s.pl_pid,
(void *) ev.pl_u.pl_s.pl_pc,
ev.pl_u.pl_s.pl_usermode ? 'u' : 's');
break;
case PMCLOG_TYPE_PMCALLOCATE:
PMCSTAT_PRINT_ENTRY(a,"allocate","0x%x \"%s\" 0x%x",
ev.pl_u.pl_a.pl_pmcid,
ev.pl_u.pl_a.pl_evname,
ev.pl_u.pl_a.pl_flags);
break;
case PMCLOG_TYPE_PMCATTACH:
PMCSTAT_PRINT_ENTRY(a,"attach","0x%x %d \"%s\"",
ev.pl_u.pl_t.pl_pmcid,
ev.pl_u.pl_t.pl_pid,
ev.pl_u.pl_t.pl_pathname);
break;
case PMCLOG_TYPE_PMCDETACH:
PMCSTAT_PRINT_ENTRY(a,"detach","0x%x %d",
ev.pl_u.pl_d.pl_pmcid,
ev.pl_u.pl_d.pl_pid);
break;
case PMCLOG_TYPE_PROCCSW:
PMCSTAT_PRINT_ENTRY(a,"cswval","0x%x %d %jd",
ev.pl_u.pl_c.pl_pmcid,
ev.pl_u.pl_c.pl_pid,
ev.pl_u.pl_c.pl_value);
break;
case PMCLOG_TYPE_PROCEXEC:
PMCSTAT_PRINT_ENTRY(a,"exec","0x%x %d %p \"%s\"",
ev.pl_u.pl_x.pl_pmcid,
ev.pl_u.pl_x.pl_pid,
(void *) ev.pl_u.pl_x.pl_entryaddr,
ev.pl_u.pl_x.pl_pathname);
break;
case PMCLOG_TYPE_PROCEXIT:
PMCSTAT_PRINT_ENTRY(a,"exitval","0x%x %d %jd",
ev.pl_u.pl_e.pl_pmcid,
ev.pl_u.pl_e.pl_pid,
ev.pl_u.pl_e.pl_value);
break;
case PMCLOG_TYPE_PROCFORK:
PMCSTAT_PRINT_ENTRY(a,"fork","%d %d",
ev.pl_u.pl_f.pl_oldpid,
ev.pl_u.pl_f.pl_newpid);
break;
case PMCLOG_TYPE_USERDATA:
PMCSTAT_PRINT_ENTRY(a,"userdata","0x%x",
ev.pl_u.pl_u.pl_userdata);
break;
case PMCLOG_TYPE_SYSEXIT:
PMCSTAT_PRINT_ENTRY(a,"exit","%d",
ev.pl_u.pl_se.pl_pid);
break;
default:
fprintf(a->pa_printfile, "unknown event (type %d).\n",
ev.pl_type);
}
}
if (ev.pl_state == PMCLOG_EOF)
return (PMCSTAT_FINISHED);
else if (ev.pl_state == PMCLOG_REQUIRE_DATA)
return (PMCSTAT_RUNNING);
errx(EX_DATAERR, "ERROR: event parsing failed "
"(record %jd, offset 0x%jx).",
(uintmax_t) ev.pl_count + 1, ev.pl_offset);
/*NOTREACHED*/
}
/*
* Public Interfaces.
*/
/*
* Close a logfile, after first flushing all in-module queued data.
*/
int
pmcstat_close_log(struct pmcstat_args *a)
{
if (pmc_flush_logfile() < 0 ||
pmc_configure_logfile(-1) < 0)
err(EX_OSERR, "ERROR: logging failed");
a->pa_flags &= ~(FLAG_HAS_OUTPUT_LOGFILE | FLAG_HAS_PIPE);
return (a->pa_flags & FLAG_HAS_PIPE ? PMCSTAT_EXITING :
PMCSTAT_FINISHED);
}
/*
* Open a log file, for reading or writing.
*
* The function returns the fd of a successfully opened log or -1 in
* case of failure.
*/
int
pmcstat_open_log(const char *path, int mode)
{
int error, fd;
size_t hlen;
const char *p, *errstr;
struct addrinfo hints, *res, *res0;
char hostname[MAXHOSTNAMELEN];
errstr = NULL;
fd = -1;
/*
* If 'path' is "-" then open one of stdin or stdout depending
* on the value of 'mode'.
*
* If 'path' contains a ':' and does not start with a '/' or '.',
* and is being opened for writing, treat it as a "host:port"
* specification and open a network socket.
*
* Otherwise, treat 'path' as a file name and open that.
*/
if (path[0] == '-' && path[1] == '\0')
fd = (mode == PMCSTAT_OPEN_FOR_READ) ? 0 : 1;
else if (mode == PMCSTAT_OPEN_FOR_WRITE && path[0] != '/' &&
path[0] != '.' && strchr(path, ':') != NULL) {
p = strrchr(path, ':');
hlen = p - path;
if (p == path || hlen >= sizeof(hostname)) {
errstr = strerror(EINVAL);
goto done;
}
assert(hlen < sizeof(hostname));
(void) strncpy(hostname, path, hlen);
hostname[hlen] = '\0';
(void) memset(&hints, 0, sizeof(hints));
hints.ai_family = AF_UNSPEC;
hints.ai_socktype = SOCK_STREAM;
if ((error = getaddrinfo(hostname, p+1, &hints, &res0)) != 0) {
errstr = gai_strerror(error);
goto done;
}
fd = -1;
for (res = res0; res; res = res->ai_next) {
if ((fd = socket(res->ai_family, res->ai_socktype,
res->ai_protocol)) < 0) {
errstr = strerror(errno);
continue;
}
if (connect(fd, res->ai_addr, res->ai_addrlen) < 0) {
errstr = strerror(errno);
(void) close(fd);
fd = -1;
continue;
}
errstr = NULL;
break;
}
freeaddrinfo(res0);
} else if ((fd = open(path, mode == PMCSTAT_OPEN_FOR_READ ?
O_RDONLY : (O_WRONLY|O_CREAT|O_TRUNC),
S_IRUSR|S_IWUSR|S_IRGRP|S_IROTH)) < 0)
errstr = strerror(errno);
done:
if (errstr)
errx(EX_OSERR, "ERROR: Cannot open \"%s\" for %s: %s.", path,
(mode == PMCSTAT_OPEN_FOR_READ ? "reading" : "writing"),
errstr);
return (fd);
}
/*
* Process a log file in offline analysis mode.
*/
int
pmcstat_process_log(struct pmcstat_args *a)
{
/*
* If analysis has not been asked for, just print the log to
* the current output file.
*/
if (a->pa_flags & FLAG_DO_PRINT)
return (pmcstat_print_log(a));
else
return (pmcstat_analyze_log(a));
}
/*
* Initialize module.
*/
void
pmcstat_initialize_logging(struct pmcstat_args *a)
{
int i;
(void) a;
/* use a convenient format for 'ldd' output */
if (setenv("LD_TRACE_LOADED_OBJECTS_FMT1","%o \"%p\" %x\n",1) != 0)
err(EX_OSERR, "ERROR: Cannot setenv");
/* Initialize hash tables */
pmcstat_string_initialize();
for (i = 0; i < PMCSTAT_NHASH; i++) {
LIST_INIT(&pmcstat_image_hash[i]);
LIST_INIT(&pmcstat_process_hash[i]);
}
/*
* Create a fake 'process' entry for the kernel with pid -1.
* hwpmc(4) will subsequently inform us about where the kernel
* and any loaded kernel modules are mapped.
*/
if ((pmcstat_kernproc = pmcstat_process_lookup((pid_t) -1,
PMCSTAT_ALLOCATE)) == NULL)
err(EX_OSERR, "ERROR: Cannot initialize logging");
}
/*
* Shutdown module.
*/
void
pmcstat_shutdown_logging(struct pmcstat_args *a)
{
int i;
FILE *mf;
struct pmcstat_gmonfile *pgf, *pgftmp;
struct pmcstat_image *pi, *pitmp;
struct pmcstat_process *pp, *pptmp;
struct pmcstat_cgnode_hash *pch, *pchtmp;
/* determine where to send the map file */
mf = NULL;
if (a->pa_mapfilename != NULL)
mf = (strcmp(a->pa_mapfilename, "-") == 0) ?
a->pa_printfile : fopen(a->pa_mapfilename, "w");
if (mf == NULL && a->pa_flags & FLAG_DO_GPROF &&
a->pa_verbosity >= 2)
mf = a->pa_printfile;
if (mf)
(void) fprintf(mf, "MAP:\n");
if (a->pa_flags & FLAG_DO_CALLGRAPHS)
pmcstat_callgraph_print(a);
/*
* Sync back all gprof flat profile data.
*/
for (i = 0; i < PMCSTAT_NHASH; i++) {
LIST_FOREACH(pi, &pmcstat_image_hash[i], pi_next) {
if (mf)
(void) fprintf(mf, " \"%s\" => \"%s\"",
pmcstat_string_unintern(pi->pi_execpath),
pmcstat_string_unintern(
pi->pi_samplename));
/* flush gmon.out data to disk */
LIST_FOREACH(pgf, &pi->pi_gmlist, pgf_next) {
pmcstat_gmon_unmap_file(pgf);
if (mf)
(void) fprintf(mf, " %s/%d",
pmcstat_pmcid_to_name(
pgf->pgf_pmcid),
pgf->pgf_nsamples);
if (pgf->pgf_overflow && a->pa_verbosity >= 1)
warnx("WARNING: profile \"%s\" "
"overflowed.",
pmcstat_string_unintern(
pgf->pgf_name));
}
if (mf)
(void) fprintf(mf, "\n");
}
}
/*
* Compute arcs and add these to the gprof files.
*/
if (a->pa_flags & FLAG_DO_GPROF && a->pa_graphdepth > 1)
pmcstat_callgraph_do_gmon_arcs();
/*
* Free memory.
*/
for (i = 0; i < PMCSTAT_NHASH; i++) {
LIST_FOREACH_SAFE(pch, &pmcstat_cgnode_hash[i], pch_next,
pchtmp) {
pmcstat_cgnode_free(pch->pch_cgnode);
free(pch);
}
}
for (i = 0; i < PMCSTAT_NHASH; i++) {
LIST_FOREACH_SAFE(pi, &pmcstat_image_hash[i], pi_next, pitmp)
{
LIST_FOREACH_SAFE(pgf, &pi->pi_gmlist, pgf_next,
pgftmp) {
if (pgf->pgf_file)
(void) fclose(pgf->pgf_file);
LIST_REMOVE(pgf, pgf_next);
free(pgf);
}
if (pi->pi_symbols)
free(pi->pi_symbols);
LIST_REMOVE(pi, pi_next);
free(pi);
}
LIST_FOREACH_SAFE(pp, &pmcstat_process_hash[i], pp_next,
pptmp) {
LIST_REMOVE(pp, pp_next);
free(pp);
}
}
pmcstat_string_shutdown();
/*
* Print errors unless -q was specified. Print all statistics
* if verbosity > 1.
*/
#define PRINT(N,V,A) do { \
if (pmcstat_stats.ps_##V || (A)->pa_verbosity >= 2) \
(void) fprintf((A)->pa_printfile, " %-40s %d\n",\
N, pmcstat_stats.ps_##V); \
} while (0)
if (a->pa_verbosity >= 1 && a->pa_flags & FLAG_DO_GPROF) {
(void) fprintf(a->pa_printfile, "CONVERSION STATISTICS:\n");
PRINT("#exec/a.out", exec_aout, a);
PRINT("#exec/elf", exec_elf, a);
PRINT("#exec/unknown", exec_indeterminable, a);
PRINT("#exec handling errors", exec_errors, a);
PRINT("#samples/total", samples_total, a);
PRINT("#samples/unclaimed", samples_unknown_offset, a);
PRINT("#samples/unknown-object", samples_indeterminable, a);
PRINT("#callchain/dubious-frames", callchain_dubious_frames,
a);
}
if (mf)
(void) fclose(mf);
}
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