Current Path : /compat/linux/proc/self/root/usr/src/usr.sbin/pmcstat/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //compat/linux/proc/self/root/usr/src/usr.sbin/pmcstat/pmcstat_log.c |
/*- * 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: release/9.1.0/usr.sbin/pmcstat/pmcstat_log.c 237970 2012-07-02 07:18:27Z obrien $"); #include <sys/param.h> #include <sys/endian.h> #include <sys/cpuset.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 <curses.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" #include "pmcstat_log.h" #include "pmcstat_top.h" #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_display_log() top mode display for the 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. */ struct pmcstat_pmcs pmcstat_pmcs = LIST_HEAD_INITIALIZER(pmcstat_pmcs); /* * All image descriptors are kept in a hash table. */ struct pmcstat_image_hash_list pmcstat_image_hash[PMCSTAT_NHASH]; /* * All process descriptors are kept in a hash table. */ struct pmcstat_process_hash_list pmcstat_process_hash[PMCSTAT_NHASH]; struct pmcstat_stats pmcstat_stats; /* statistics */ int ps_samples_period; /* samples count between top refresh. */ struct pmcstat_process *pmcstat_kernproc; /* kernel 'process' */ #include "pmcpl_gprof.h" #include "pmcpl_callgraph.h" #include "pmcpl_annotate.h" #include "pmcpl_calltree.h" struct pmc_plugins { const char *pl_name; /* name */ /* configure */ int (*pl_configure)(char *opt); /* init and shutdown */ int (*pl_init)(void); void (*pl_shutdown)(FILE *mf); /* sample processing */ void (*pl_process)(struct pmcstat_process *pp, struct pmcstat_pmcrecord *pmcr, uint32_t nsamples, uintfptr_t *cc, int usermode, uint32_t cpu); /* image */ void (*pl_initimage)(struct pmcstat_image *pi); void (*pl_shutdownimage)(struct pmcstat_image *pi); /* pmc */ void (*pl_newpmc)(pmcstat_interned_string ps, struct pmcstat_pmcrecord *pr); /* top display */ void (*pl_topdisplay)(void); /* top keypress */ int (*pl_topkeypress)(int c, WINDOW *w); } plugins[] = { { .pl_name = "none", }, { .pl_name = "callgraph", .pl_init = pmcpl_cg_init, .pl_shutdown = pmcpl_cg_shutdown, .pl_process = pmcpl_cg_process, .pl_topkeypress = pmcpl_cg_topkeypress, .pl_topdisplay = pmcpl_cg_topdisplay }, { .pl_name = "gprof", .pl_shutdown = pmcpl_gmon_shutdown, .pl_process = pmcpl_gmon_process, .pl_initimage = pmcpl_gmon_initimage, .pl_shutdownimage = pmcpl_gmon_shutdownimage, .pl_newpmc = pmcpl_gmon_newpmc }, { .pl_name = "annotate", .pl_process = pmcpl_annotate_process }, { .pl_name = "calltree", .pl_configure = pmcpl_ct_configure, .pl_init = pmcpl_ct_init, .pl_shutdown = pmcpl_ct_shutdown, .pl_process = pmcpl_ct_process, .pl_topkeypress = pmcpl_ct_topkeypress, .pl_topdisplay = pmcpl_ct_topdisplay }, { .pl_name = NULL } }; int pmcstat_mergepmc; int pmcstat_pmcinfilter = 0; /* PMC filter for top mode. */ float pmcstat_threshold = 0.5; /* Cost filter for top mode. */ /* * Prototypes */ 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); static void pmcstat_image_get_elf_params(struct pmcstat_image *_image); 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); static void pmcstat_process_aout_exec(struct pmcstat_process *_pp, struct pmcstat_image *_image, uintfptr_t _entryaddr); static void pmcstat_process_elf_exec(struct pmcstat_process *_pp, struct pmcstat_image *_image, uintfptr_t _entryaddr); static void pmcstat_process_exec(struct pmcstat_process *_pp, pmcstat_interned_string _path, uintfptr_t _entryaddr); static struct pmcstat_process *pmcstat_process_lookup(pid_t _pid, int _allocate); static int pmcstat_string_compute_hash(const char *_string); static void pmcstat_string_initialize(void); static int pmcstat_string_lookup_hash(pmcstat_interned_string _is); static void pmcstat_string_shutdown(void); static void pmcstat_stats_reset(int _reset_global); /* * 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]; /* * PMC count. */ int pmcstat_npmcs; /* * PMC Top mode pause state. */ int pmcstat_pause; static void pmcstat_stats_reset(int reset_global) { struct pmcstat_pmcrecord *pr; /* Flush PMCs stats. */ LIST_FOREACH(pr, &pmcstat_pmcs, pr_next) { pr->pr_samples = 0; pr->pr_dubious_frames = 0; } ps_samples_period = 0; /* Flush global stats. */ if (reset_global) bzero(&pmcstat_stats, sizeof(struct pmcstat_stats)); } /* * 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. */ 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); } const char * pmcstat_string_unintern(pmcstat_interned_string str) { const char *s; s = ((const struct pmcstat_string *) str)->ps_string; return (s); } 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); } } /* * 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) { 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", args.pa_fsroot, path); if ((fd = open(buffer, O_RDONLY, 0)) < 0 || (nbytes = read(fd, &ex, sizeof(ex))) < 0) { if (args.pa_verbosity >= 2) 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. */ 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 (sym.st_shndx == STN_UNDEF) 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; #ifdef __arm__ /* Remove spurious ARM function name. */ if (fnname[0] == '$' && (fnname[1] == 'a' || fnname[1] == 't' || fnname[1] == 'd') && fnname[2] == '\0') continue; #endif 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) { int fd; size_t i, nph, nsh; const char *path, *elfbase; char *p, *endp; 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", args.pa_fsroot, args.pa_kernel, path); else (void) snprintf(buffer, sizeof(buffer), "%s%s", args.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)) { if (args.pa_verbosity >= 2) 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); /* Build display name */ endp = buffer; for (p = buffer; *p; p++) if (*p == '/') endp = p+1; image->pi_name = pmcstat_string_intern(endp); 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'. */ void pmcstat_image_determine_type(struct pmcstat_image *image) { 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); if (image->pi_type == PMCSTAT_IMAGE_UNKNOWN) pmcstat_image_get_aout_params(image); /* * 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 hash; struct pmcstat_image *pi; 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; pi->pi_addr2line = NULL; if (plugins[args.pa_pplugin].pl_initimage != NULL) plugins[args.pa_pplugin].pl_initimage(pi); if (plugins[args.pa_plugin].pl_initimage != NULL) plugins[args.pa_plugin].pl_initimage(pi); LIST_INSERT_HEAD(&pmcstat_image_hash[hash], pi, pi_next); return (pi); } /* * 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); } } /* * Resolve file name and line number for the given address. */ int pmcstat_image_addr2line(struct pmcstat_image *image, uintfptr_t addr, char *sourcefile, size_t sourcefile_len, unsigned *sourceline, char *funcname, size_t funcname_len) { static int addr2line_warn = 0; unsigned l; char *sep, cmdline[PATH_MAX], imagepath[PATH_MAX]; int fd; if (image->pi_addr2line == NULL) { snprintf(imagepath, sizeof(imagepath), "%s%s.symbols", args.pa_fsroot, pmcstat_string_unintern(image->pi_fullpath)); fd = open(imagepath, O_RDONLY); if (fd < 0) { snprintf(imagepath, sizeof(imagepath), "%s%s", args.pa_fsroot, pmcstat_string_unintern(image->pi_fullpath)); } else close(fd); /* * New addr2line support recursive inline function with -i * but the format does not add a marker when no more entries * are available. */ snprintf(cmdline, sizeof(cmdline), "addr2line -Cfe \"%s\"", imagepath); image->pi_addr2line = popen(cmdline, "r+"); if (image->pi_addr2line == NULL) { if (!addr2line_warn) { addr2line_warn = 1; warnx( "WARNING: addr2line is needed for source code information." ); } return (0); } } if (feof(image->pi_addr2line) || ferror(image->pi_addr2line)) { warnx("WARNING: addr2line pipe error"); pclose(image->pi_addr2line); image->pi_addr2line = NULL; return (0); } fprintf(image->pi_addr2line, "%p\n", (void *)addr); if (fgets(funcname, funcname_len, image->pi_addr2line) == NULL) { warnx("WARNING: addr2line function name read error"); return (0); } sep = strchr(funcname, '\n'); if (sep != NULL) *sep = '\0'; if (fgets(sourcefile, sourcefile_len, image->pi_addr2line) == NULL) { warnx("WARNING: addr2line source file read error"); return (0); } sep = strchr(sourcefile, ':'); if (sep == NULL) { warnx("WARNING: addr2line source line separator missing"); return (0); } *sep = '\0'; l = atoi(sep+1); if (l == 0) return (0); *sourceline = l; return (1); } /* * Add a {pmcid,name} mapping. */ static void pmcstat_pmcid_add(pmc_id_t pmcid, pmcstat_interned_string ps) { struct pmcstat_pmcrecord *pr, *prm; /* Replace an existing name for the PMC. */ prm = NULL; LIST_FOREACH(pr, &pmcstat_pmcs, pr_next) if (pr->pr_pmcid == pmcid) { pr->pr_pmcname = ps; return; } else if (pr->pr_pmcname == ps) prm = pr; /* * Otherwise, allocate a new descriptor and call the * plugins hook. */ if ((pr = malloc(sizeof(*pr))) == NULL) err(EX_OSERR, "ERROR: Cannot allocate pmc record"); pr->pr_pmcid = pmcid; pr->pr_pmcname = ps; pr->pr_pmcin = pmcstat_npmcs++; pr->pr_samples = 0; pr->pr_dubious_frames = 0; pr->pr_merge = prm == NULL ? pr : prm; LIST_INSERT_HEAD(&pmcstat_pmcs, pr, pr_next); if (plugins[args.pa_pplugin].pl_newpmc != NULL) plugins[args.pa_pplugin].pl_newpmc(ps, pr); if (plugins[args.pa_plugin].pl_newpmc != NULL) plugins[args.pa_plugin].pl_newpmc(ps, pr); } /* * Given a pmcid in use, find its human-readable name. */ const char * pmcstat_pmcid_to_name(pmc_id_t pmcid) { struct pmcstat_pmcrecord *pr; LIST_FOREACH(pr, &pmcstat_pmcs, pr_next) if (pr->pr_pmcid == pmcid) return (pmcstat_string_unintern(pr->pr_pmcname)); return NULL; } /* * Convert PMC index to name. */ const char * pmcstat_pmcindex_to_name(int pmcin) { struct pmcstat_pmcrecord *pr; LIST_FOREACH(pr, &pmcstat_pmcs, pr_next) if (pr->pr_pmcin == pmcin) return pmcstat_string_unintern(pr->pr_pmcname); return NULL; } /* * Return PMC record with given index. */ struct pmcstat_pmcrecord * pmcstat_pmcindex_to_pmcr(int pmcin) { struct pmcstat_pmcrecord *pr; LIST_FOREACH(pr, &pmcstat_pmcs, pr_next) if (pr->pr_pmcin == pmcin) return pr; return NULL; } /* * Get PMC record by id, apply merge policy. */ static struct pmcstat_pmcrecord * pmcstat_lookup_pmcid(pmc_id_t pmcid) { struct pmcstat_pmcrecord *pr; LIST_FOREACH(pr, &pmcstat_pmcs, pr_next) { if (pr->pr_pmcid == pmcid) { if (pmcstat_mergepmc) return pr->pr_merge; return pr; } } return NULL; } /* * Associate an AOUT image with a process. */ static void pmcstat_process_aout_exec(struct pmcstat_process *pp, struct pmcstat_image *image, uintfptr_t entryaddr) { (void) pp; (void) image; (void) entryaddr; /* 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) { 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); 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_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); 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); break; case PMCSTAT_IMAGE_AOUT: pmcstat_stats.ps_exec_aout++; pmcstat_process_aout_exec(pp, image, entryaddr); 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'. */ 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); } /* * 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(void) { 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; struct pmcstat_pmcrecord *pmcr; pmcstat_interned_string image_path; assert(args.pa_flags & FLAG_DO_ANALYSIS); if (elf_version(EV_CURRENT) == EV_NONE) err(EX_UNAVAILABLE, "Elf library intialization failed"); while (pmclog_read(args.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 && args.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); 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++; ps_samples_period++; pc = ev.pl_u.pl_s.pl_pc; pp = pmcstat_process_lookup(ev.pl_u.pl_s.pl_pid, PMCSTAT_ALLOCATE); /* Get PMC record. */ pmcr = pmcstat_lookup_pmcid(ev.pl_u.pl_s.pl_pmcid); assert(pmcr != NULL); pmcr->pr_samples++; /* * Call the plugins processing * TODO: move pmcstat_process_find_map inside plugins */ if (plugins[args.pa_pplugin].pl_process != NULL) plugins[args.pa_pplugin].pl_process( pp, pmcr, 1, &pc, pmcstat_process_find_map(pp, pc) != NULL, 0); plugins[args.pa_plugin].pl_process( pp, pmcr, 1, &pc, pmcstat_process_find_map(pp, pc) != NULL, 0); break; case PMCLOG_TYPE_CALLCHAIN: pmcstat_stats.ps_samples_total++; ps_samples_period++; cpuflags = ev.pl_u.pl_cc.pl_cpuflags; cpu = PMC_CALLCHAIN_CPUFLAGS_TO_CPU(cpuflags); /* Filter on the CPU id. */ if (!CPU_ISSET(cpu, &(args.pa_cpumask))) { pmcstat_stats.ps_samples_skipped++; break; } pp = pmcstat_process_lookup(ev.pl_u.pl_cc.pl_pid, PMCSTAT_ALLOCATE); /* Get PMC record. */ pmcr = pmcstat_lookup_pmcid(ev.pl_u.pl_cc.pl_pmcid); assert(pmcr != NULL); pmcr->pr_samples++; /* * Call the plugins processing */ if (plugins[args.pa_pplugin].pl_process != NULL) plugins[args.pa_pplugin].pl_process( pp, pmcr, ev.pl_u.pl_cc.pl_npc, ev.pl_u.pl_cc.pl_pc, PMC_CALLCHAIN_CPUFLAGS_TO_USERMODE(cpuflags), cpu); plugins[args.pa_plugin].pl_process( pp, pmcr, ev.pl_u.pl_cc.pl_npc, ev.pl_u.pl_cc.pl_pc, PMC_CALLCHAIN_CPUFLAGS_TO_USERMODE(cpuflags), cpu); 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)); break; case PMCLOG_TYPE_PMCALLOCATEDYN: /* * Record the association pmc id between this * PMC and its name. */ pmcstat_pmcid_add(ev.pl_u.pl_ad.pl_pmcid, pmcstat_string_intern(ev.pl_u.pl_ad.pl_evname)); 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); 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(void) { struct pmclog_ev ev; uint32_t npc; while (pmclog_read(args.pa_logparser, &ev) == 0) { assert(ev.pl_state == PMCLOG_OK); switch (ev.pl_type) { case PMCLOG_TYPE_CALLCHAIN: PMCSTAT_PRINT_ENTRY("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("...", "%p", (void *) ev.pl_u.pl_cc.pl_pc[npc]); break; case PMCLOG_TYPE_CLOSELOG: PMCSTAT_PRINT_ENTRY("closelog",); break; case PMCLOG_TYPE_DROPNOTIFY: PMCSTAT_PRINT_ENTRY("drop",); break; case PMCLOG_TYPE_INITIALIZE: PMCSTAT_PRINT_ENTRY("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 && args.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("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("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("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("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_PMCALLOCATEDYN: PMCSTAT_PRINT_ENTRY("allocatedyn","0x%x \"%s\" 0x%x", ev.pl_u.pl_ad.pl_pmcid, ev.pl_u.pl_ad.pl_evname, ev.pl_u.pl_ad.pl_flags); break; case PMCLOG_TYPE_PMCATTACH: PMCSTAT_PRINT_ENTRY("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("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("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("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("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("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("userdata","0x%x", ev.pl_u.pl_u.pl_userdata); break; case PMCLOG_TYPE_SYSEXIT: PMCSTAT_PRINT_ENTRY("exit","%d", ev.pl_u.pl_se.pl_pid); break; default: fprintf(args.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(void) { /* If a local logfile is configured ask the kernel to stop * and flush data. Kernel will close the file when data is flushed * so keep the status to EXITING. */ if (args.pa_logfd != -1) { if (pmc_close_logfile() < 0) err(EX_OSERR, "ERROR: logging failed"); } return (args.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, cfd; 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 (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 (mode == PMCSTAT_OPEN_FOR_READ) { if (bind(fd, res->ai_addr, res->ai_addrlen) < 0) { errstr = strerror(errno); (void) close(fd); fd = -1; continue; } listen(fd, 1); cfd = accept(fd, NULL, NULL); (void) close(fd); if (cfd < 0) { errstr = strerror(errno); fd = -1; break; } fd = cfd; } else { 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(void) { /* * If analysis has not been asked for, just print the log to * the current output file. */ if (args.pa_flags & FLAG_DO_PRINT) return (pmcstat_print_log()); else return (pmcstat_analyze_log()); } /* * Refresh top display. */ static void pmcstat_refresh_top(void) { int v_attrs; float v; char pmcname[40]; struct pmcstat_pmcrecord *pmcpr; /* If in pause mode do not refresh display. */ if (pmcstat_pause) return; /* Wait until PMC pop in the log. */ pmcpr = pmcstat_pmcindex_to_pmcr(pmcstat_pmcinfilter); if (pmcpr == NULL) return; /* Format PMC name. */ if (pmcstat_mergepmc) snprintf(pmcname, sizeof(pmcname), "[%s]", pmcstat_string_unintern(pmcpr->pr_pmcname)); else snprintf(pmcname, sizeof(pmcname), "%s.%d", pmcstat_string_unintern(pmcpr->pr_pmcname), pmcstat_pmcinfilter); /* Format samples count. */ if (ps_samples_period > 0) v = (pmcpr->pr_samples * 100.0) / ps_samples_period; else v = 0.; v_attrs = PMCSTAT_ATTRPERCENT(v); PMCSTAT_PRINTBEGIN(); PMCSTAT_PRINTW("PMC: %s Samples: %u ", pmcname, pmcpr->pr_samples); PMCSTAT_ATTRON(v_attrs); PMCSTAT_PRINTW("(%.1f%%) ", v); PMCSTAT_ATTROFF(v_attrs); PMCSTAT_PRINTW(", %u unresolved\n\n", pmcpr->pr_dubious_frames); if (plugins[args.pa_plugin].pl_topdisplay != NULL) plugins[args.pa_plugin].pl_topdisplay(); PMCSTAT_PRINTEND(); } /* * Find the next pmc index to display. */ static void pmcstat_changefilter(void) { int pmcin; struct pmcstat_pmcrecord *pmcr; /* * Find the next merge target. */ if (pmcstat_mergepmc) { pmcin = pmcstat_pmcinfilter; do { pmcr = pmcstat_pmcindex_to_pmcr(pmcstat_pmcinfilter); if (pmcr == NULL || pmcr == pmcr->pr_merge) break; pmcstat_pmcinfilter++; if (pmcstat_pmcinfilter >= pmcstat_npmcs) pmcstat_pmcinfilter = 0; } while (pmcstat_pmcinfilter != pmcin); } } /* * Top mode keypress. */ int pmcstat_keypress_log(void) { int c, ret = 0; WINDOW *w; w = newwin(1, 0, 1, 0); c = wgetch(w); wprintw(w, "Key: %c => ", c); switch (c) { case 'c': wprintw(w, "enter mode 'd' or 'a' => "); c = wgetch(w); if (c == 'd') { args.pa_topmode = PMCSTAT_TOP_DELTA; wprintw(w, "switching to delta mode"); } else { args.pa_topmode = PMCSTAT_TOP_ACCUM; wprintw(w, "switching to accumulation mode"); } break; case 'm': pmcstat_mergepmc = !pmcstat_mergepmc; /* * Changing merge state require data reset. */ if (plugins[args.pa_plugin].pl_shutdown != NULL) plugins[args.pa_plugin].pl_shutdown(NULL); pmcstat_stats_reset(0); if (plugins[args.pa_plugin].pl_init != NULL) plugins[args.pa_plugin].pl_init(); /* Update filter to be on a merge target. */ pmcstat_changefilter(); wprintw(w, "merge PMC %s", pmcstat_mergepmc ? "on" : "off"); break; case 'n': /* Close current plugin. */ if (plugins[args.pa_plugin].pl_shutdown != NULL) plugins[args.pa_plugin].pl_shutdown(NULL); /* Find next top display available. */ do { args.pa_plugin++; if (plugins[args.pa_plugin].pl_name == NULL) args.pa_plugin = 0; } while (plugins[args.pa_plugin].pl_topdisplay == NULL); /* Open new plugin. */ pmcstat_stats_reset(0); if (plugins[args.pa_plugin].pl_init != NULL) plugins[args.pa_plugin].pl_init(); wprintw(w, "switching to plugin %s", plugins[args.pa_plugin].pl_name); break; case 'p': pmcstat_pmcinfilter++; if (pmcstat_pmcinfilter >= pmcstat_npmcs) pmcstat_pmcinfilter = 0; pmcstat_changefilter(); wprintw(w, "switching to PMC %s.%d", pmcstat_pmcindex_to_name(pmcstat_pmcinfilter), pmcstat_pmcinfilter); break; case ' ': pmcstat_pause = !pmcstat_pause; if (pmcstat_pause) wprintw(w, "pause => press space again to continue"); break; case 'q': wprintw(w, "exiting..."); ret = 1; break; default: if (plugins[args.pa_plugin].pl_topkeypress != NULL) if (plugins[args.pa_plugin].pl_topkeypress(c, w)) ret = 1; } wrefresh(w); delwin(w); return ret; } /* * Top mode display. */ void pmcstat_display_log(void) { pmcstat_refresh_top(); /* Reset everythings if delta mode. */ if (args.pa_topmode == PMCSTAT_TOP_DELTA) { if (plugins[args.pa_plugin].pl_shutdown != NULL) plugins[args.pa_plugin].pl_shutdown(NULL); pmcstat_stats_reset(0); if (plugins[args.pa_plugin].pl_init != NULL) plugins[args.pa_plugin].pl_init(); } } /* * Configure a plugins. */ void pmcstat_pluginconfigure_log(char *opt) { if (strncmp(opt, "threshold=", 10) == 0) { pmcstat_threshold = atof(opt+10); } else { if (plugins[args.pa_plugin].pl_configure != NULL) { if (!plugins[args.pa_plugin].pl_configure(opt)) err(EX_USAGE, "ERROR: unknown option <%s>.", opt); } } } /* * Initialize module. */ void pmcstat_initialize_logging(void) { int i; /* 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"); /* PMC count. */ pmcstat_npmcs = 0; /* Merge PMC with same name. */ pmcstat_mergepmc = args.pa_mergepmc; /* * Initialize plugins */ if (plugins[args.pa_pplugin].pl_init != NULL) plugins[args.pa_pplugin].pl_init(); if (plugins[args.pa_plugin].pl_init != NULL) plugins[args.pa_plugin].pl_init(); } /* * Shutdown module. */ void pmcstat_shutdown_logging(void) { int i; FILE *mf; struct pmcstat_image *pi, *pitmp; struct pmcstat_process *pp, *pptmp; struct pmcstat_pcmap *ppm, *ppmtmp; /* determine where to send the map file */ mf = NULL; if (args.pa_mapfilename != NULL) mf = (strcmp(args.pa_mapfilename, "-") == 0) ? args.pa_printfile : fopen(args.pa_mapfilename, "w"); if (mf == NULL && args.pa_flags & FLAG_DO_GPROF && args.pa_verbosity >= 2) mf = args.pa_printfile; if (mf) (void) fprintf(mf, "MAP:\n"); /* * Shutdown the plugins */ if (plugins[args.pa_plugin].pl_shutdown != NULL) plugins[args.pa_plugin].pl_shutdown(mf); if (plugins[args.pa_pplugin].pl_shutdown != NULL) plugins[args.pa_pplugin].pl_shutdown(mf); for (i = 0; i < PMCSTAT_NHASH; i++) { LIST_FOREACH_SAFE(pi, &pmcstat_image_hash[i], pi_next, pitmp) { if (plugins[args.pa_plugin].pl_shutdownimage != NULL) plugins[args.pa_plugin].pl_shutdownimage(pi); if (plugins[args.pa_pplugin].pl_shutdownimage != NULL) plugins[args.pa_pplugin].pl_shutdownimage(pi); free(pi->pi_symbols); if (pi->pi_addr2line != NULL) pclose(pi->pi_addr2line); LIST_REMOVE(pi, pi_next); free(pi); } LIST_FOREACH_SAFE(pp, &pmcstat_process_hash[i], pp_next, pptmp) { TAILQ_FOREACH_SAFE(ppm, &pp->pp_map, ppm_next, ppmtmp) { TAILQ_REMOVE(&pp->pp_map, ppm, ppm_next); free(ppm); } 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) do { \ if (pmcstat_stats.ps_##V || args.pa_verbosity >= 2) \ (void) fprintf(args.pa_printfile, " %-40s %d\n",\ N, pmcstat_stats.ps_##V); \ } while (0) if (args.pa_verbosity >= 1 && (args.pa_flags & FLAG_DO_ANALYSIS)) { (void) fprintf(args.pa_printfile, "CONVERSION STATISTICS:\n"); PRINT("#exec/a.out", exec_aout); PRINT("#exec/elf", exec_elf); PRINT("#exec/unknown", exec_indeterminable); PRINT("#exec handling errors", exec_errors); PRINT("#samples/total", samples_total); PRINT("#samples/unclaimed", samples_unknown_offset); PRINT("#samples/unknown-object", samples_indeterminable); PRINT("#samples/unknown-function", samples_unknown_function); PRINT("#callchain/dubious-frames", callchain_dubious_frames); } if (mf) (void) fclose(mf); }