// SPDX-License-Identifier: GPL-2.0-or-later /* * probe-event.c : perf-probe definition to probe_events format converter * * Written by Masami Hiramatsu */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "build-id.h" #include "event.h" #include "namespaces.h" #include "strlist.h" #include "strfilter.h" #include "debug.h" #include "dso.h" #include "color.h" #include "map.h" #include "maps.h" #include "symbol.h" #include #include "trace-event.h" /* For __maybe_unused */ #include "probe-event.h" #include "probe-finder.h" #include "probe-file.h" #include "session.h" #include "string2.h" #include "strbuf.h" #include #include #include #ifdef HAVE_DEBUGINFOD_SUPPORT #include #endif #define PERFPROBE_GROUP "probe" bool probe_event_dry_run; /* Dry run flag */ struct probe_conf probe_conf = { .magic_num = DEFAULT_PROBE_MAGIC_NUM }; #define semantic_error(msg ...) pr_err("Semantic error :" msg) int e_snprintf(char *str, size_t size, const char *format, ...) { int ret; va_list ap; va_start(ap, format); ret = vsnprintf(str, size, format, ap); va_end(ap); if (ret >= (int)size) ret = -E2BIG; return ret; } static struct machine *host_machine; /* Initialize symbol maps and path of vmlinux/modules */ int init_probe_symbol_maps(bool user_only) { int ret; symbol_conf.sort_by_name = true; symbol_conf.allow_aliases = true; ret = symbol__init(NULL); if (ret < 0) { pr_debug("Failed to init symbol map.\n"); goto out; } if (host_machine || user_only) /* already initialized */ return 0; if (symbol_conf.vmlinux_name) pr_debug("Use vmlinux: %s\n", symbol_conf.vmlinux_name); host_machine = machine__new_host(); if (!host_machine) { pr_debug("machine__new_host() failed.\n"); symbol__exit(); ret = -1; } out: if (ret < 0) pr_warning("Failed to init vmlinux path.\n"); return ret; } void exit_probe_symbol_maps(void) { machine__delete(host_machine); host_machine = NULL; symbol__exit(); } static struct ref_reloc_sym *kernel_get_ref_reloc_sym(struct map **pmap) { struct kmap *kmap; struct map *map = machine__kernel_map(host_machine); if (map__load(map) < 0) return NULL; kmap = map__kmap(map); if (!kmap) return NULL; if (pmap) *pmap = map; return kmap->ref_reloc_sym; } static int kernel_get_symbol_address_by_name(const char *name, u64 *addr, bool reloc, bool reladdr) { struct ref_reloc_sym *reloc_sym; struct symbol *sym; struct map *map; /* ref_reloc_sym is just a label. Need a special fix*/ reloc_sym = kernel_get_ref_reloc_sym(&map); if (reloc_sym && strcmp(name, reloc_sym->name) == 0) *addr = (!map->reloc || reloc) ? reloc_sym->addr : reloc_sym->unrelocated_addr; else { sym = machine__find_kernel_symbol_by_name(host_machine, name, &map); if (!sym) return -ENOENT; *addr = map->unmap_ip(map, sym->start) - ((reloc) ? 0 : map->reloc) - ((reladdr) ? map->start : 0); } return 0; } static struct map *kernel_get_module_map(const char *module) { struct maps *maps = machine__kernel_maps(host_machine); struct map *pos; /* A file path -- this is an offline module */ if (module && strchr(module, '/')) return dso__new_map(module); if (!module) { pos = machine__kernel_map(host_machine); return map__get(pos); } maps__for_each_entry(maps, pos) { /* short_name is "[module]" */ if (strncmp(pos->dso->short_name + 1, module, pos->dso->short_name_len - 2) == 0 && module[pos->dso->short_name_len - 2] == '\0') { return map__get(pos); } } return NULL; } struct map *get_target_map(const char *target, struct nsinfo *nsi, bool user) { /* Init maps of given executable or kernel */ if (user) { struct map *map; map = dso__new_map(target); if (map && map->dso) { nsinfo__put(map->dso->nsinfo); map->dso->nsinfo = nsinfo__get(nsi); } return map; } else { return kernel_get_module_map(target); } } static int convert_exec_to_group(const char *exec, char **result) { char *ptr1, *ptr2, *exec_copy; char buf[64]; int ret; exec_copy = strdup(exec); if (!exec_copy) return -ENOMEM; ptr1 = basename(exec_copy); if (!ptr1) { ret = -EINVAL; goto out; } for (ptr2 = ptr1; *ptr2 != '\0'; ptr2++) { if (!isalnum(*ptr2) && *ptr2 != '_') { *ptr2 = '\0'; break; } } ret = e_snprintf(buf, 64, "%s_%s", PERFPROBE_GROUP, ptr1); if (ret < 0) goto out; *result = strdup(buf); ret = *result ? 0 : -ENOMEM; out: free(exec_copy); return ret; } static void clear_perf_probe_point(struct perf_probe_point *pp) { zfree(&pp->file); zfree(&pp->function); zfree(&pp->lazy_line); } static void clear_probe_trace_events(struct probe_trace_event *tevs, int ntevs) { int i; for (i = 0; i < ntevs; i++) clear_probe_trace_event(tevs + i); } static bool kprobe_blacklist__listed(u64 address); static bool kprobe_warn_out_range(const char *symbol, u64 address) { struct map *map; bool ret = false; map = kernel_get_module_map(NULL); if (map) { ret = address <= map->start || map->end < address; if (ret) pr_warning("%s is out of .text, skip it.\n", symbol); map__put(map); } if (!ret && kprobe_blacklist__listed(address)) { pr_warning("%s is blacklisted function, skip it.\n", symbol); ret = true; } return ret; } /* * @module can be module name of module file path. In case of path, * inspect elf and find out what is actual module name. * Caller has to free mod_name after using it. */ static char *find_module_name(const char *module) { int fd; Elf *elf; GElf_Ehdr ehdr; GElf_Shdr shdr; Elf_Data *data; Elf_Scn *sec; char *mod_name = NULL; int name_offset; fd = open(module, O_RDONLY); if (fd < 0) return NULL; elf = elf_begin(fd, PERF_ELF_C_READ_MMAP, NULL); if (elf == NULL) goto elf_err; if (gelf_getehdr(elf, &ehdr) == NULL) goto ret_err; sec = elf_section_by_name(elf, &ehdr, &shdr, ".gnu.linkonce.this_module", NULL); if (!sec) goto ret_err; data = elf_getdata(sec, NULL); if (!data || !data->d_buf) goto ret_err; /* * NOTE: * '.gnu.linkonce.this_module' section of kernel module elf directly * maps to 'struct module' from linux/module.h. This section contains * actual module name which will be used by kernel after loading it. * But, we cannot use 'struct module' here since linux/module.h is not * exposed to user-space. Offset of 'name' has remained same from long * time, so hardcoding it here. */ if (ehdr.e_ident[EI_CLASS] == ELFCLASS32) name_offset = 12; else /* expect ELFCLASS64 by default */ name_offset = 24; mod_name = strdup((char *)data->d_buf + name_offset); ret_err: elf_end(elf); elf_err: close(fd); return mod_name; } #ifdef HAVE_DWARF_SUPPORT static int kernel_get_module_dso(const char *module, struct dso **pdso) { struct dso *dso; struct map *map; const char *vmlinux_name; int ret = 0; if (module) { char module_name[128]; snprintf(module_name, sizeof(module_name), "[%s]", module); map = maps__find_by_name(&host_machine->kmaps, module_name); if (map) { dso = map->dso; goto found; } pr_debug("Failed to find module %s.\n", module); return -ENOENT; } map = machine__kernel_map(host_machine); dso = map->dso; if (!dso->has_build_id) dso__read_running_kernel_build_id(dso, host_machine); vmlinux_name = symbol_conf.vmlinux_name; dso->load_errno = 0; if (vmlinux_name) ret = dso__load_vmlinux(dso, map, vmlinux_name, false); else ret = dso__load_vmlinux_path(dso, map); found: *pdso = dso; return ret; } /* * Some binaries like glibc have special symbols which are on the symbol * table, but not in the debuginfo. If we can find the address of the * symbol from map, we can translate the address back to the probe point. */ static int find_alternative_probe_point(struct debuginfo *dinfo, struct perf_probe_point *pp, struct perf_probe_point *result, const char *target, struct nsinfo *nsi, bool uprobes) { struct map *map = NULL; struct symbol *sym; u64 address = 0; int ret = -ENOENT; /* This can work only for function-name based one */ if (!pp->function || pp->file) return -ENOTSUP; map = get_target_map(target, nsi, uprobes); if (!map) return -EINVAL; /* Find the address of given function */ map__for_each_symbol_by_name(map, pp->function, sym) { if (uprobes) { address = sym->start; if (sym->type == STT_GNU_IFUNC) pr_warning("Warning: The probe function (%s) is a GNU indirect function.\n" "Consider identifying the final function used at run time and set the probe directly on that.\n", pp->function); } else address = map->unmap_ip(map, sym->start) - map->reloc; break; } if (!address) { ret = -ENOENT; goto out; } pr_debug("Symbol %s address found : %" PRIx64 "\n", pp->function, address); ret = debuginfo__find_probe_point(dinfo, address, result); if (ret <= 0) ret = (!ret) ? -ENOENT : ret; else { result->offset += pp->offset; result->line += pp->line; result->retprobe = pp->retprobe; ret = 0; } out: map__put(map); return ret; } static int get_alternative_probe_event(struct debuginfo *dinfo, struct perf_probe_event *pev, struct perf_probe_point *tmp) { int ret; memcpy(tmp, &pev->point, sizeof(*tmp)); memset(&pev->point, 0, sizeof(pev->point)); ret = find_alternative_probe_point(dinfo, tmp, &pev->point, pev->target, pev->nsi, pev->uprobes); if (ret < 0) memcpy(&pev->point, tmp, sizeof(*tmp)); return ret; } static int get_alternative_line_range(struct debuginfo *dinfo, struct line_range *lr, const char *target, bool user) { struct perf_probe_point pp = { .function = lr->function, .file = lr->file, .line = lr->start }; struct perf_probe_point result; int ret, len = 0; memset(&result, 0, sizeof(result)); if (lr->end != INT_MAX) len = lr->end - lr->start; ret = find_alternative_probe_point(dinfo, &pp, &result, target, NULL, user); if (!ret) { lr->function = result.function; lr->file = result.file; lr->start = result.line; if (lr->end != INT_MAX) lr->end = lr->start + len; clear_perf_probe_point(&pp); } return ret; } #ifdef HAVE_DEBUGINFOD_SUPPORT static struct debuginfo *open_from_debuginfod(struct dso *dso, struct nsinfo *nsi, bool silent) { debuginfod_client *c = debuginfod_begin(); char sbuild_id[SBUILD_ID_SIZE + 1]; struct debuginfo *ret = NULL; struct nscookie nsc; char *path; int fd; if (!c) return NULL; build_id__sprintf(&dso->bid, sbuild_id); fd = debuginfod_find_debuginfo(c, (const unsigned char *)sbuild_id, 0, &path); if (fd >= 0) close(fd); debuginfod_end(c); if (fd < 0) { if (!silent) pr_debug("Failed to find debuginfo in debuginfod.\n"); return NULL; } if (!silent) pr_debug("Load debuginfo from debuginfod (%s)\n", path); nsinfo__mountns_enter(nsi, &nsc); ret = debuginfo__new((const char *)path); nsinfo__mountns_exit(&nsc); return ret; } #else static inline struct debuginfo *open_from_debuginfod(struct dso *dso __maybe_unused, struct nsinfo *nsi __maybe_unused, bool silent __maybe_unused) { return NULL; } #endif /* Open new debuginfo of given module */ static struct debuginfo *open_debuginfo(const char *module, struct nsinfo *nsi, bool silent) { const char *path = module; char reason[STRERR_BUFSIZE]; struct debuginfo *ret = NULL; struct dso *dso = NULL; struct nscookie nsc; int err; if (!module || !strchr(module, '/')) { err = kernel_get_module_dso(module, &dso); if (err < 0) { if (!dso || dso->load_errno == 0) { if (!str_error_r(-err, reason, STRERR_BUFSIZE)) strcpy(reason, "(unknown)"); } else dso__strerror_load(dso, reason, STRERR_BUFSIZE); if (dso) ret = open_from_debuginfod(dso, nsi, silent); if (ret) return ret; if (!silent) { if (module) pr_err("Module %s is not loaded, please specify its full path name.\n", module); else pr_err("Failed to find the path for the kernel: %s\n", reason); } return NULL; } path = dso->long_name; } nsinfo__mountns_enter(nsi, &nsc); ret = debuginfo__new(path); if (!ret && !silent) { pr_warning("The %s file has no debug information.\n", path); if (!module || !strtailcmp(path, ".ko")) pr_warning("Rebuild with CONFIG_DEBUG_INFO=y, "); else pr_warning("Rebuild with -g, "); pr_warning("or install an appropriate debuginfo package.\n"); } nsinfo__mountns_exit(&nsc); return ret; } /* For caching the last debuginfo */ static struct debuginfo *debuginfo_cache; static char *debuginfo_cache_path; static struct debuginfo *debuginfo_cache__open(const char *module, bool silent) { const char *path = module; /* If the module is NULL, it should be the kernel. */ if (!module) path = "kernel"; if (debuginfo_cache_path && !strcmp(debuginfo_cache_path, path)) goto out; /* Copy module path */ free(debuginfo_cache_path); debuginfo_cache_path = strdup(path); if (!debuginfo_cache_path) { debuginfo__delete(debuginfo_cache); debuginfo_cache = NULL; goto out; } debuginfo_cache = open_debuginfo(module, NULL, silent); if (!debuginfo_cache) zfree(&debuginfo_cache_path); out: return debuginfo_cache; } static void debuginfo_cache__exit(void) { debuginfo__delete(debuginfo_cache); debuginfo_cache = NULL; zfree(&debuginfo_cache_path); } static int get_text_start_address(const char *exec, u64 *address, struct nsinfo *nsi) { Elf *elf; GElf_Ehdr ehdr; GElf_Shdr shdr; int fd, ret = -ENOENT; struct nscookie nsc; nsinfo__mountns_enter(nsi, &nsc); fd = open(exec, O_RDONLY); nsinfo__mountns_exit(&nsc); if (fd < 0) return -errno; elf = elf_begin(fd, PERF_ELF_C_READ_MMAP, NULL); if (elf == NULL) { ret = -EINVAL; goto out_close; } if (gelf_getehdr(elf, &ehdr) == NULL) goto out; if (!elf_section_by_name(elf, &ehdr, &shdr, ".text", NULL)) goto out; *address = shdr.sh_addr - shdr.sh_offset; ret = 0; out: elf_end(elf); out_close: close(fd); return ret; } /* * Convert trace point to probe point with debuginfo */ static int find_perf_probe_point_from_dwarf(struct probe_trace_point *tp, struct perf_probe_point *pp, bool is_kprobe) { struct debuginfo *dinfo = NULL; u64 stext = 0; u64 addr = tp->address; int ret = -ENOENT; /* convert the address to dwarf address */ if (!is_kprobe) { if (!addr) { ret = -EINVAL; goto error; } ret = get_text_start_address(tp->module, &stext, NULL); if (ret < 0) goto error; addr += stext; } else if (tp->symbol) { /* If the module is given, this returns relative address */ ret = kernel_get_symbol_address_by_name(tp->symbol, &addr, false, !!tp->module); if (ret != 0) goto error; addr += tp->offset; } pr_debug("try to find information at %" PRIx64 " in %s\n", addr, tp->module ? : "kernel"); dinfo = debuginfo_cache__open(tp->module, verbose <= 0); if (dinfo) ret = debuginfo__find_probe_point(dinfo, addr, pp); else ret = -ENOENT; if (ret > 0) { pp->retprobe = tp->retprobe; return 0; } error: pr_debug("Failed to find corresponding probes from debuginfo.\n"); return ret ? : -ENOENT; } /* Adjust symbol name and address */ static int post_process_probe_trace_point(struct probe_trace_point *tp, struct map *map, u64 offs) { struct symbol *sym; u64 addr = tp->address - offs; sym = map__find_symbol(map, addr); if (!sym) { /* * If the address is in the inittext section, map can not * find it. Ignore it if we are probing offline kernel. */ return (symbol_conf.ignore_vmlinux_buildid) ? 0 : -ENOENT; } if (strcmp(sym->name, tp->symbol)) { /* If we have no realname, use symbol for it */ if (!tp->realname) tp->realname = tp->symbol; else free(tp->symbol); tp->symbol = strdup(sym->name); if (!tp->symbol) return -ENOMEM; } tp->offset = addr - sym->start; tp->address -= offs; return 0; } /* * Rename DWARF symbols to ELF symbols -- gcc sometimes optimizes functions * and generate new symbols with suffixes such as .constprop.N or .isra.N * etc. Since those symbols are not recorded in DWARF, we have to find * correct generated symbols from offline ELF binary. * For online kernel or uprobes we don't need this because those are * rebased on _text, or already a section relative address. */ static int post_process_offline_probe_trace_events(struct probe_trace_event *tevs, int ntevs, const char *pathname) { struct map *map; u64 stext = 0; int i, ret = 0; /* Prepare a map for offline binary */ map = dso__new_map(pathname); if (!map || get_text_start_address(pathname, &stext, NULL) < 0) { pr_warning("Failed to get ELF symbols for %s\n", pathname); return -EINVAL; } for (i = 0; i < ntevs; i++) { ret = post_process_probe_trace_point(&tevs[i].point, map, stext); if (ret < 0) break; } map__put(map); return ret; } static int add_exec_to_probe_trace_events(struct probe_trace_event *tevs, int ntevs, const char *exec, struct nsinfo *nsi) { int i, ret = 0; u64 stext = 0; if (!exec) return 0; ret = get_text_start_address(exec, &stext, nsi); if (ret < 0) return ret; for (i = 0; i < ntevs && ret >= 0; i++) { /* point.address is the address of point.symbol + point.offset */ tevs[i].point.address -= stext; tevs[i].point.module = strdup(exec); if (!tevs[i].point.module) { ret = -ENOMEM; break; } tevs[i].uprobes = true; } return ret; } static int post_process_module_probe_trace_events(struct probe_trace_event *tevs, int ntevs, const char *module, struct debuginfo *dinfo) { Dwarf_Addr text_offs = 0; int i, ret = 0; char *mod_name = NULL; struct map *map; if (!module) return 0; map = get_target_map(module, NULL, false); if (!map || debuginfo__get_text_offset(dinfo, &text_offs, true) < 0) { pr_warning("Failed to get ELF symbols for %s\n", module); return -EINVAL; } mod_name = find_module_name(module); for (i = 0; i < ntevs; i++) { ret = post_process_probe_trace_point(&tevs[i].point, map, text_offs); if (ret < 0) break; tevs[i].point.module = strdup(mod_name ? mod_name : module); if (!tevs[i].point.module) { ret = -ENOMEM; break; } } free(mod_name); map__put(map); return ret; } static int post_process_kernel_probe_trace_events(struct probe_trace_event *tevs, int ntevs) { struct ref_reloc_sym *reloc_sym; struct map *map; char *tmp; int i, skipped = 0; /* Skip post process if the target is an offline kernel */ if (symbol_conf.ignore_vmlinux_buildid) return post_process_offline_probe_trace_events(tevs, ntevs, symbol_conf.vmlinux_name); reloc_sym = kernel_get_ref_reloc_sym(&map); if (!reloc_sym) { pr_warning("Relocated base symbol is not found! " "Check /proc/sys/kernel/kptr_restrict\n" "and /proc/sys/kernel/perf_event_paranoid. " "Or run as privileged perf user.\n\n"); return -EINVAL; } for (i = 0; i < ntevs; i++) { if (!tevs[i].point.address) continue; if (tevs[i].point.retprobe && !kretprobe_offset_is_supported()) continue; /* * If we found a wrong one, mark it by NULL symbol. * Since addresses in debuginfo is same as objdump, we need * to convert it to addresses on memory. */ if (kprobe_warn_out_range(tevs[i].point.symbol, map__objdump_2mem(map, tevs[i].point.address))) { tmp = NULL; skipped++; } else { tmp = strdup(reloc_sym->name); if (!tmp) return -ENOMEM; } /* If we have no realname, use symbol for it */ if (!tevs[i].point.realname) tevs[i].point.realname = tevs[i].point.symbol; else free(tevs[i].point.symbol); tevs[i].point.symbol = tmp; tevs[i].point.offset = tevs[i].point.address - (map->reloc ? reloc_sym->unrelocated_addr : reloc_sym->addr); } return skipped; } void __weak arch__post_process_probe_trace_events(struct perf_probe_event *pev __maybe_unused, int ntevs __maybe_unused) { } /* Post processing the probe events */ static int post_process_probe_trace_events(struct perf_probe_event *pev, struct probe_trace_event *tevs, int ntevs, const char *module, bool uprobe, struct debuginfo *dinfo) { int ret; if (uprobe) ret = add_exec_to_probe_trace_events(tevs, ntevs, module, pev->nsi); else if (module) /* Currently ref_reloc_sym based probe is not for drivers */ ret = post_process_module_probe_trace_events(tevs, ntevs, module, dinfo); else ret = post_process_kernel_probe_trace_events(tevs, ntevs); if (ret >= 0) arch__post_process_probe_trace_events(pev, ntevs); return ret; } /* Try to find perf_probe_event with debuginfo */ static int try_to_find_probe_trace_events(struct perf_probe_event *pev, struct probe_trace_event **tevs) { bool need_dwarf = perf_probe_event_need_dwarf(pev); struct perf_probe_point tmp; struct debuginfo *dinfo; int ntevs, ret = 0; /* Workaround for gcc #98776 issue. * Perf failed to add kretprobe event with debuginfo of vmlinux which is * compiled by gcc with -fpatchable-function-entry option enabled. The * same issue with kernel module. The retprobe doesn`t need debuginfo. * This workaround solution use map to query the probe function address * for retprobe event. */ if (pev->point.retprobe) return 0; dinfo = open_debuginfo(pev->target, pev->nsi, !need_dwarf); if (!dinfo) { if (need_dwarf) return -ENOENT; pr_debug("Could not open debuginfo. Try to use symbols.\n"); return 0; } pr_debug("Try to find probe point from debuginfo.\n"); /* Searching trace events corresponding to a probe event */ ntevs = debuginfo__find_trace_events(dinfo, pev, tevs); if (ntevs == 0) { /* Not found, retry with an alternative */ ret = get_alternative_probe_event(dinfo, pev, &tmp); if (!ret) { ntevs = debuginfo__find_trace_events(dinfo, pev, tevs); /* * Write back to the original probe_event for * setting appropriate (user given) event name */ clear_perf_probe_point(&pev->point); memcpy(&pev->point, &tmp, sizeof(tmp)); } } if (ntevs > 0) { /* Succeeded to find trace events */ pr_debug("Found %d probe_trace_events.\n", ntevs); ret = post_process_probe_trace_events(pev, *tevs, ntevs, pev->target, pev->uprobes, dinfo); if (ret < 0 || ret == ntevs) { pr_debug("Post processing failed or all events are skipped. (%d)\n", ret); clear_probe_trace_events(*tevs, ntevs); zfree(tevs); ntevs = 0; } } debuginfo__delete(dinfo); if (ntevs == 0) { /* No error but failed to find probe point. */ pr_warning("Probe point '%s' not found.\n", synthesize_perf_probe_point(&pev->point)); return -ENOENT; } else if (ntevs < 0) { /* Error path : ntevs < 0 */ pr_debug("An error occurred in debuginfo analysis (%d).\n", ntevs); if (ntevs == -EBADF) pr_warning("Warning: No dwarf info found in the vmlinux - " "please rebuild kernel with CONFIG_DEBUG_INFO=y.\n"); if (!need_dwarf) { pr_debug("Trying to use symbols.\n"); return 0; } } return ntevs; } #define LINEBUF_SIZE 256 #define NR_ADDITIONAL_LINES 2 static int __show_one_line(FILE *fp, int l, bool skip, bool show_num) { char buf[LINEBUF_SIZE], sbuf[STRERR_BUFSIZE]; const char *color = show_num ? "" : PERF_COLOR_BLUE; const char *prefix = NULL; do { if (fgets(buf, LINEBUF_SIZE, fp) == NULL) goto error; if (skip) continue; if (!prefix) { prefix = show_num ? "%7d " : " "; color_fprintf(stdout, color, prefix, l); } color_fprintf(stdout, color, "%s", buf); } while (strchr(buf, '\n') == NULL); return 1; error: if (ferror(fp)) { pr_warning("File read error: %s\n", str_error_r(errno, sbuf, sizeof(sbuf))); return -1; } return 0; } static int _show_one_line(FILE *fp, int l, bool skip, bool show_num) { int rv = __show_one_line(fp, l, skip, show_num); if (rv == 0) { pr_warning("Source file is shorter than expected.\n"); rv = -1; } return rv; } #define show_one_line_with_num(f,l) _show_one_line(f,l,false,true) #define show_one_line(f,l) _show_one_line(f,l,false,false) #define skip_one_line(f,l) _show_one_line(f,l,true,false) #define show_one_line_or_eof(f,l) __show_one_line(f,l,false,false) /* * Show line-range always requires debuginfo to find source file and * line number. */ static int __show_line_range(struct line_range *lr, const char *module, bool user) { struct build_id bid; int l = 1; struct int_node *ln; struct debuginfo *dinfo; FILE *fp; int ret; char *tmp; char sbuf[STRERR_BUFSIZE]; char sbuild_id[SBUILD_ID_SIZE] = ""; /* Search a line range */ dinfo = open_debuginfo(module, NULL, false); if (!dinfo) return -ENOENT; ret = debuginfo__find_line_range(dinfo, lr); if (!ret) { /* Not found, retry with an alternative */ ret = get_alternative_line_range(dinfo, lr, module, user); if (!ret) ret = debuginfo__find_line_range(dinfo, lr); } if (dinfo->build_id) { build_id__init(&bid, dinfo->build_id, BUILD_ID_SIZE); build_id__sprintf(&bid, sbuild_id); } debuginfo__delete(dinfo); if (ret == 0 || ret == -ENOENT) { pr_warning("Specified source line is not found.\n"); return -ENOENT; } else if (ret < 0) { pr_warning("Debuginfo analysis failed.\n"); return ret; } /* Convert source file path */ tmp = lr->path; ret = find_source_path(tmp, sbuild_id, lr->comp_dir, &lr->path); /* Free old path when new path is assigned */ if (tmp != lr->path) free(tmp); if (ret < 0) { pr_warning("Failed to find source file path.\n"); return ret; } setup_pager(); if (lr->function) fprintf(stdout, "<%s@%s:%d>\n", lr->function, lr->path, lr->start - lr->offset); else fprintf(stdout, "<%s:%d>\n", lr->path, lr->start); fp = fopen(lr->path, "r"); if (fp == NULL) { pr_warning("Failed to open %s: %s\n", lr->path, str_error_r(errno, sbuf, sizeof(sbuf))); return -errno; } /* Skip to starting line number */ while (l < lr->start) { ret = skip_one_line(fp, l++); if (ret < 0) goto end; } intlist__for_each_entry(ln, lr->line_list) { for (; ln->i > (unsigned long)l; l++) { ret = show_one_line(fp, l - lr->offset); if (ret < 0) goto end; } ret = show_one_line_with_num(fp, l++ - lr->offset); if (ret < 0) goto end; } if (lr->end == INT_MAX) lr->end = l + NR_ADDITIONAL_LINES; while (l <= lr->end) { ret = show_one_line_or_eof(fp, l++ - lr->offset); if (ret <= 0) break; } end: fclose(fp); return ret; } int show_line_range(struct line_range *lr, const char *module, struct nsinfo *nsi, bool user) { int ret; struct nscookie nsc; ret = init_probe_symbol_maps(user); if (ret < 0) return ret; nsinfo__mountns_enter(nsi, &nsc); ret = __show_line_range(lr, module, user); nsinfo__mountns_exit(&nsc); exit_probe_symbol_maps(); return ret; } static int show_available_vars_at(struct debuginfo *dinfo, struct perf_probe_event *pev, struct strfilter *_filter) { char *buf; int ret, i, nvars; struct str_node *node; struct variable_list *vls = NULL, *vl; struct perf_probe_point tmp; const char *var; buf = synthesize_perf_probe_point(&pev->point); if (!buf) return -EINVAL; pr_debug("Searching variables at %s\n", buf); ret = debuginfo__find_available_vars_at(dinfo, pev, &vls); if (!ret) { /* Not found, retry with an alternative */ ret = get_alternative_probe_event(dinfo, pev, &tmp); if (!ret) { ret = debuginfo__find_available_vars_at(dinfo, pev, &vls); /* Release the old probe_point */ clear_perf_probe_point(&tmp); } } if (ret <= 0) { if (ret == 0 || ret == -ENOENT) { pr_err("Failed to find the address of %s\n", buf); ret = -ENOENT; } else pr_warning("Debuginfo analysis failed.\n"); goto end; } /* Some variables are found */ fprintf(stdout, "Available variables at %s\n", buf); for (i = 0; i < ret; i++) { vl = &vls[i]; /* * A probe point might be converted to * several trace points. */ fprintf(stdout, "\t@<%s+%lu>\n", vl->point.symbol, vl->point.offset); zfree(&vl->point.symbol); nvars = 0; if (vl->vars) { strlist__for_each_entry(node, vl->vars) { var = strchr(node->s, '\t') + 1; if (strfilter__compare(_filter, var)) { fprintf(stdout, "\t\t%s\n", node->s); nvars++; } } strlist__delete(vl->vars); } if (nvars == 0) fprintf(stdout, "\t\t(No matched variables)\n"); } free(vls); end: free(buf); return ret; } /* Show available variables on given probe point */ int show_available_vars(struct perf_probe_event *pevs, int npevs, struct strfilter *_filter) { int i, ret = 0; struct debuginfo *dinfo; ret = init_probe_symbol_maps(pevs->uprobes); if (ret < 0) return ret; dinfo = open_debuginfo(pevs->target, pevs->nsi, false); if (!dinfo) { ret = -ENOENT; goto out; } setup_pager(); for (i = 0; i < npevs && ret >= 0; i++) ret = show_available_vars_at(dinfo, &pevs[i], _filter); debuginfo__delete(dinfo); out: exit_probe_symbol_maps(); return ret; } #else /* !HAVE_DWARF_SUPPORT */ static void debuginfo_cache__exit(void) { } static int find_perf_probe_point_from_dwarf(struct probe_trace_point *tp __maybe_unused, struct perf_probe_point *pp __maybe_unused, bool is_kprobe __maybe_unused) { return -ENOSYS; } static int try_to_find_probe_trace_events(struct perf_probe_event *pev, struct probe_trace_event **tevs __maybe_unused) { if (perf_probe_event_need_dwarf(pev)) { pr_warning("Debuginfo-analysis is not supported.\n"); return -ENOSYS; } return 0; } int show_line_range(struct line_range *lr __maybe_unused, const char *module __maybe_unused, struct nsinfo *nsi __maybe_unused, bool user __maybe_unused) { pr_warning("Debuginfo-analysis is not supported.\n"); return -ENOSYS; } int show_available_vars(struct perf_probe_event *pevs __maybe_unused, int npevs __maybe_unused, struct strfilter *filter __maybe_unused) { pr_warning("Debuginfo-analysis is not supported.\n"); return -ENOSYS; } #endif void line_range__clear(struct line_range *lr) { zfree(&lr->function); zfree(&lr->file); zfree(&lr->path); zfree(&lr->comp_dir); intlist__delete(lr->line_list); } int line_range__init(struct line_range *lr) { memset(lr, 0, sizeof(*lr)); lr->line_list = intlist__new(NULL); if (!lr->line_list) return -ENOMEM; else return 0; } static int parse_line_num(char **ptr, int *val, const char *what) { const char *start = *ptr; errno = 0; *val = strtol(*ptr, ptr, 0); if (errno || *ptr == start) { semantic_error("'%s' is not a valid number.\n", what); return -EINVAL; } return 0; } /* Check the name is good for event, group or function */ static bool is_c_func_name(const char *name) { if (!isalpha(*name) && *name != '_') return false; while (*++name != '\0') { if (!isalpha(*name) && !isdigit(*name) && *name != '_') return false; } return true; } /* * Stuff 'lr' according to the line range described by 'arg'. * The line range syntax is described by: * * SRC[:SLN[+NUM|-ELN]] * FNC[@SRC][:SLN[+NUM|-ELN]] */ int parse_line_range_desc(const char *arg, struct line_range *lr) { char *range, *file, *name = strdup(arg); int err; if (!name) return -ENOMEM; lr->start = 0; lr->end = INT_MAX; range = strchr(name, ':'); if (range) { *range++ = '\0'; err = parse_line_num(&range, &lr->start, "start line"); if (err) goto err; if (*range == '+' || *range == '-') { const char c = *range++; err = parse_line_num(&range, &lr->end, "end line"); if (err) goto err; if (c == '+') { lr->end += lr->start; /* * Adjust the number of lines here. * If the number of lines == 1, the * the end of line should be equal to * the start of line. */ lr->end--; } } pr_debug("Line range is %d to %d\n", lr->start, lr->end); err = -EINVAL; if (lr->start > lr->end) { semantic_error("Start line must be smaller" " than end line.\n"); goto err; } if (*range != '\0') { semantic_error("Tailing with invalid str '%s'.\n", range); goto err; } } file = strchr(name, '@'); if (file) { *file = '\0'; lr->file = strdup(++file); if (lr->file == NULL) { err = -ENOMEM; goto err; } lr->function = name; } else if (strchr(name, '/') || strchr(name, '.')) lr->file = name; else if (is_c_func_name(name))/* We reuse it for checking funcname */ lr->function = name; else { /* Invalid name */ semantic_error("'%s' is not a valid function name.\n", name); err = -EINVAL; goto err; } return 0; err: free(name); return err; } static int parse_perf_probe_event_name(char **arg, struct perf_probe_event *pev) { char *ptr; ptr = strpbrk_esc(*arg, ":"); if (ptr) { *ptr = '\0'; if (!pev->sdt && !is_c_func_name(*arg)) goto ng_name; pev->group = strdup_esc(*arg); if (!pev->group) return -ENOMEM; *arg = ptr + 1; } else pev->group = NULL; pev->event = strdup_esc(*arg); if (pev->event == NULL) return -ENOMEM; if (!pev->sdt && !is_c_func_name(pev->event)) { zfree(&pev->event); ng_name: zfree(&pev->group); semantic_error("%s is bad for event name -it must " "follow C symbol-naming rule.\n", *arg); return -EINVAL; } return 0; } /* Parse probepoint definition. */ static int parse_perf_probe_point(char *arg, struct perf_probe_event *pev) { struct perf_probe_point *pp = &pev->point; char *ptr, *tmp; char c, nc = 0; bool file_spec = false; int ret; /* * * perf probe [GRP:][EVENT=]SRC[:LN|;PTN] * perf probe [GRP:][EVENT=]FUNC[@SRC][+OFFS|%return|:LN|;PAT] * perf probe %[GRP:]SDT_EVENT */ if (!arg) return -EINVAL; if (is_sdt_event(arg)) { pev->sdt = true; if (arg[0] == '%') arg++; } ptr = strpbrk_esc(arg, ";=@+%"); if (pev->sdt) { if (ptr) { if (*ptr != '@') { semantic_error("%s must be an SDT name.\n", arg); return -EINVAL; } /* This must be a target file name or build id */ tmp = build_id_cache__complement(ptr + 1); if (tmp) { pev->target = build_id_cache__origname(tmp); free(tmp); } else pev->target = strdup_esc(ptr + 1); if (!pev->target) return -ENOMEM; *ptr = '\0'; } ret = parse_perf_probe_event_name(&arg, pev); if (ret == 0) { if (asprintf(&pev->point.function, "%%%s", pev->event) < 0) ret = -errno; } return ret; } if (ptr && *ptr == '=') { /* Event name */ *ptr = '\0'; tmp = ptr + 1; ret = parse_perf_probe_event_name(&arg, pev); if (ret < 0) return ret; arg = tmp; } /* * Check arg is function or file name and copy it. * * We consider arg to be a file spec if and only if it satisfies * all of the below criteria:: * - it does not include any of "+@%", * - it includes one of ":;", and * - it has a period '.' in the name. * * Otherwise, we consider arg to be a function specification. */ if (!strpbrk_esc(arg, "+@%")) { ptr = strpbrk_esc(arg, ";:"); /* This is a file spec if it includes a '.' before ; or : */ if (ptr && memchr(arg, '.', ptr - arg)) file_spec = true; } ptr = strpbrk_esc(arg, ";:+@%"); if (ptr) { nc = *ptr; *ptr++ = '\0'; } if (arg[0] == '\0') tmp = NULL; else { tmp = strdup_esc(arg); if (tmp == NULL) return -ENOMEM; } if (file_spec) pp->file = tmp; else { pp->function = tmp; /* * Keep pp->function even if this is absolute address, * so it can mark whether abs_address is valid. * Which make 'perf probe lib.bin 0x0' possible. * * Note that checking length of tmp is not needed * because when we access tmp[1] we know tmp[0] is '0', * so tmp[1] should always valid (but could be '\0'). */ if (tmp && !strncmp(tmp, "0x", 2)) { pp->abs_address = strtoull(pp->function, &tmp, 0); if (*tmp != '\0') { semantic_error("Invalid absolute address.\n"); return -EINVAL; } } } /* Parse other options */ while (ptr) { arg = ptr; c = nc; if (c == ';') { /* Lazy pattern must be the last part */ pp->lazy_line = strdup(arg); /* let leave escapes */ if (pp->lazy_line == NULL) return -ENOMEM; break; } ptr = strpbrk_esc(arg, ";:+@%"); if (ptr) { nc = *ptr; *ptr++ = '\0'; } switch (c) { case ':': /* Line number */ pp->line = strtoul(arg, &tmp, 0); if (*tmp != '\0') { semantic_error("There is non-digit char" " in line number.\n"); return -EINVAL; } break; case '+': /* Byte offset from a symbol */ pp->offset = strtoul(arg, &tmp, 0); if (*tmp != '\0') { semantic_error("There is non-digit character" " in offset.\n"); return -EINVAL; } break; case '@': /* File name */ if (pp->file) { semantic_error("SRC@SRC is not allowed.\n"); return -EINVAL; } pp->file = strdup_esc(arg); if (pp->file == NULL) return -ENOMEM; break; case '%': /* Probe places */ if (strcmp(arg, "return") == 0) { pp->retprobe = 1; } else { /* Others not supported yet */ semantic_error("%%%s is not supported.\n", arg); return -ENOTSUP; } break; default: /* Buggy case */ pr_err("This program has a bug at %s:%d.\n", __FILE__, __LINE__); return -ENOTSUP; break; } } /* Exclusion check */ if (pp->lazy_line && pp->line) { semantic_error("Lazy pattern can't be used with" " line number.\n"); return -EINVAL; } if (pp->lazy_line && pp->offset) { semantic_error("Lazy pattern can't be used with offset.\n"); return -EINVAL; } if (pp->line && pp->offset) { semantic_error("Offset can't be used with line number.\n"); return -EINVAL; } if (!pp->line && !pp->lazy_line && pp->file && !pp->function) { semantic_error("File always requires line number or " "lazy pattern.\n"); return -EINVAL; } if (pp->offset && !pp->function) { semantic_error("Offset requires an entry function.\n"); return -EINVAL; } if ((pp->offset || pp->line || pp->lazy_line) && pp->retprobe) { semantic_error("Offset/Line/Lazy pattern can't be used with " "return probe.\n"); return -EINVAL; } pr_debug("symbol:%s file:%s line:%d offset:%lu return:%d lazy:%s\n", pp->function, pp->file, pp->line, pp->offset, pp->retprobe, pp->lazy_line); return 0; } /* Parse perf-probe event argument */ static int parse_perf_probe_arg(char *str, struct perf_probe_arg *arg) { char *tmp, *goodname; struct perf_probe_arg_field **fieldp; pr_debug("parsing arg: %s into ", str); tmp = strchr(str, '='); if (tmp) { arg->name = strndup(str, tmp - str); if (arg->name == NULL) return -ENOMEM; pr_debug("name:%s ", arg->name); str = tmp + 1; } tmp = strchr(str, '@'); if (tmp && tmp != str && !strcmp(tmp + 1, "user")) { /* user attr */ if (!user_access_is_supported()) { semantic_error("ftrace does not support user access\n"); return -EINVAL; } *tmp = '\0'; arg->user_access = true; pr_debug("user_access "); } tmp = strchr(str, ':'); if (tmp) { /* Type setting */ *tmp = '\0'; arg->type = strdup(tmp + 1); if (arg->type == NULL) return -ENOMEM; pr_debug("type:%s ", arg->type); } tmp = strpbrk(str, "-.["); if (!is_c_varname(str) || !tmp) { /* A variable, register, symbol or special value */ arg->var = strdup(str); if (arg->var == NULL) return -ENOMEM; pr_debug("%s\n", arg->var); return 0; } /* Structure fields or array element */ arg->var = strndup(str, tmp - str); if (arg->var == NULL) return -ENOMEM; goodname = arg->var; pr_debug("%s, ", arg->var); fieldp = &arg->field; do { *fieldp = zalloc(sizeof(struct perf_probe_arg_field)); if (*fieldp == NULL) return -ENOMEM; if (*tmp == '[') { /* Array */ str = tmp; (*fieldp)->index = strtol(str + 1, &tmp, 0); (*fieldp)->ref = true; if (*tmp != ']' || tmp == str + 1) { semantic_error("Array index must be a" " number.\n"); return -EINVAL; } tmp++; if (*tmp == '\0') tmp = NULL; } else { /* Structure */ if (*tmp == '.') { str = tmp + 1; (*fieldp)->ref = false; } else if (tmp[1] == '>') { str = tmp + 2; (*fieldp)->ref = true; } else { semantic_error("Argument parse error: %s\n", str); return -EINVAL; } tmp = strpbrk(str, "-.["); } if (tmp) { (*fieldp)->name = strndup(str, tmp - str); if ((*fieldp)->name == NULL) return -ENOMEM; if (*str != '[') goodname = (*fieldp)->name; pr_debug("%s(%d), ", (*fieldp)->name, (*fieldp)->ref); fieldp = &(*fieldp)->next; } } while (tmp); (*fieldp)->name = strdup(str); if ((*fieldp)->name == NULL) return -ENOMEM; if (*str != '[') goodname = (*fieldp)->name; pr_debug("%s(%d)\n", (*fieldp)->name, (*fieldp)->ref); /* If no name is specified, set the last field name (not array index)*/ if (!arg->name) { arg->name = strdup(goodname); if (arg->name == NULL) return -ENOMEM; } return 0; } /* Parse perf-probe event command */ int parse_perf_probe_command(const char *cmd, struct perf_probe_event *pev) { char **argv; int argc, i, ret = 0; argv = argv_split(cmd, &argc); if (!argv) { pr_debug("Failed to split arguments.\n"); return -ENOMEM; } if (argc - 1 > MAX_PROBE_ARGS) { semantic_error("Too many probe arguments (%d).\n", argc - 1); ret = -ERANGE; goto out; } /* Parse probe point */ ret = parse_perf_probe_point(argv[0], pev); if (ret < 0) goto out; /* Generate event name if needed */ if (!pev->event && pev->point.function && pev->point.line && !pev->point.lazy_line && !pev->point.offset) { if (asprintf(&pev->event, "%s_L%d", pev->point.function, pev->point.line) < 0) { ret = -ENOMEM; goto out; } } /* Copy arguments and ensure return probe has no C argument */ pev->nargs = argc - 1; pev->args = zalloc(sizeof(struct perf_probe_arg) * pev->nargs); if (pev->args == NULL) { ret = -ENOMEM; goto out; } for (i = 0; i < pev->nargs && ret >= 0; i++) { ret = parse_perf_probe_arg(argv[i + 1], &pev->args[i]); if (ret >= 0 && is_c_varname(pev->args[i].var) && pev->point.retprobe) { semantic_error("You can't specify local variable for" " kretprobe.\n"); ret = -EINVAL; } } out: argv_free(argv); return ret; } /* Returns true if *any* ARG is either C variable, $params or $vars. */ bool perf_probe_with_var(struct perf_probe_event *pev) { int i = 0; for (i = 0; i < pev->nargs; i++) if (is_c_varname(pev->args[i].var) || !strcmp(pev->args[i].var, PROBE_ARG_PARAMS) || !strcmp(pev->args[i].var, PROBE_ARG_VARS)) return true; return false; } /* Return true if this perf_probe_event requires debuginfo */ bool perf_probe_event_need_dwarf(struct perf_probe_event *pev) { if (pev->point.file || pev->point.line || pev->point.lazy_line) return true; if (perf_probe_with_var(pev)) return true; return false; } /* Parse probe_events event into struct probe_point */ int parse_probe_trace_command(const char *cmd, struct probe_trace_event *tev) { struct probe_trace_point *tp = &tev->point; char pr; char *p; char *argv0_str = NULL, *fmt, *fmt1_str, *fmt2_str, *fmt3_str; int ret, i, argc; char **argv; pr_debug("Parsing probe_events: %s\n", cmd); argv = argv_split(cmd, &argc); if (!argv) { pr_debug("Failed to split arguments.\n"); return -ENOMEM; } if (argc < 2) { semantic_error("Too few probe arguments.\n"); ret = -ERANGE; goto out; } /* Scan event and group name. */ argv0_str = strdup(argv[0]); if (argv0_str == NULL) { ret = -ENOMEM; goto out; } fmt1_str = strtok_r(argv0_str, ":", &fmt); fmt2_str = strtok_r(NULL, "/", &fmt); fmt3_str = strtok_r(NULL, " \t", &fmt); if (fmt1_str == NULL || fmt2_str == NULL || fmt3_str == NULL) { semantic_error("Failed to parse event name: %s\n", argv[0]); ret = -EINVAL; goto out; } pr = fmt1_str[0]; tev->group = strdup(fmt2_str); tev->event = strdup(fmt3_str); if (tev->group == NULL || tev->event == NULL) { ret = -ENOMEM; goto out; } pr_debug("Group:%s Event:%s probe:%c\n", tev->group, tev->event, pr); tp->retprobe = (pr == 'r'); /* Scan module name(if there), function name and offset */ p = strchr(argv[1], ':'); if (p) { tp->module = strndup(argv[1], p - argv[1]); if (!tp->module) { ret = -ENOMEM; goto out; } tev->uprobes = (tp->module[0] == '/'); p++; } else p = argv[1]; fmt1_str = strtok_r(p, "+", &fmt); /* only the address started with 0x */ if (fmt1_str[0] == '0') { /* * Fix a special case: * if address == 0, kernel reports something like: * p:probe_libc/abs_0 /lib/libc-2.18.so:0x (null) arg1=%ax * Newer kernel may fix that, but we want to * support old kernel also. */ if (strcmp(fmt1_str, "0x") == 0) { if (!argv[2] || strcmp(argv[2], "(null)")) { ret = -EINVAL; goto out; } tp->address = 0; free(argv[2]); for (i = 2; argv[i + 1] != NULL; i++) argv[i] = argv[i + 1]; argv[i] = NULL; argc -= 1; } else tp->address = strtoull(fmt1_str, NULL, 0); } else { /* Only the symbol-based probe has offset */ tp->symbol = strdup(fmt1_str); if (tp->symbol == NULL) { ret = -ENOMEM; goto out; } fmt2_str = strtok_r(NULL, "", &fmt); if (fmt2_str == NULL) tp->offset = 0; else tp->offset = strtoul(fmt2_str, NULL, 10); } if (tev->uprobes) { fmt2_str = strchr(p, '('); if (fmt2_str) tp->ref_ctr_offset = strtoul(fmt2_str + 1, NULL, 0); } tev->nargs = argc - 2; tev->args = zalloc(sizeof(struct probe_trace_arg) * tev->nargs); if (tev->args == NULL) { ret = -ENOMEM; goto out; } for (i = 0; i < tev->nargs; i++) { p = strchr(argv[i + 2], '='); if (p) /* We don't need which register is assigned. */ *p++ = '\0'; else p = argv[i + 2]; tev->args[i].name = strdup(argv[i + 2]); /* TODO: parse regs and offset */ tev->args[i].value = strdup(p); if (tev->args[i].name == NULL || tev->args[i].value == NULL) { ret = -ENOMEM; goto out; } } ret = 0; out: free(argv0_str); argv_free(argv); return ret; } /* Compose only probe arg */ char *synthesize_perf_probe_arg(struct perf_probe_arg *pa) { struct perf_probe_arg_field *field = pa->field; struct strbuf buf; char *ret = NULL; int err; if (strbuf_init(&buf, 64) < 0) return NULL; if (pa->name && pa->var) err = strbuf_addf(&buf, "%s=%s", pa->name, pa->var); else err = strbuf_addstr(&buf, pa->name ?: pa->var); if (err) goto out; while (field) { if (field->name[0] == '[') err = strbuf_addstr(&buf, field->name); else err = strbuf_addf(&buf, "%s%s", field->ref ? "->" : ".", field->name); field = field->next; if (err) goto out; } if (pa->type) if (strbuf_addf(&buf, ":%s", pa->type) < 0) goto out; ret = strbuf_detach(&buf, NULL); out: strbuf_release(&buf); return ret; } /* Compose only probe point (not argument) */ char *synthesize_perf_probe_point(struct perf_probe_point *pp) { struct strbuf buf; char *tmp, *ret = NULL; int len, err = 0; if (strbuf_init(&buf, 64) < 0) return NULL; if (pp->function) { if (strbuf_addstr(&buf, pp->function) < 0) goto out; if (pp->offset) err = strbuf_addf(&buf, "+%lu", pp->offset); else if (pp->line) err = strbuf_addf(&buf, ":%d", pp->line); else if (pp->retprobe) err = strbuf_addstr(&buf, "%return"); if (err) goto out; } if (pp->file) { tmp = pp->file; len = strlen(tmp); if (len > 30) { tmp = strchr(pp->file + len - 30, '/'); tmp = tmp ? tmp + 1 : pp->file + len - 30; } err = strbuf_addf(&buf, "@%s", tmp); if (!err && !pp->function && pp->line) err = strbuf_addf(&buf, ":%d", pp->line); } if (!err) ret = strbuf_detach(&buf, NULL); out: strbuf_release(&buf); return ret; } char *synthesize_perf_probe_command(struct perf_probe_event *pev) { struct strbuf buf; char *tmp, *ret = NULL; int i; if (strbuf_init(&buf, 64)) return NULL; if (pev->event) if (strbuf_addf(&buf, "%s:%s=", pev->group ?: PERFPROBE_GROUP, pev->event) < 0) goto out; tmp = synthesize_perf_probe_point(&pev->point); if (!tmp || strbuf_addstr(&buf, tmp) < 0) goto out; free(tmp); for (i = 0; i < pev->nargs; i++) { tmp = synthesize_perf_probe_arg(pev->args + i); if (!tmp || strbuf_addf(&buf, " %s", tmp) < 0) goto out; free(tmp); } ret = strbuf_detach(&buf, NULL); out: strbuf_release(&buf); return ret; } static int __synthesize_probe_trace_arg_ref(struct probe_trace_arg_ref *ref, struct strbuf *buf, int depth) { int err; if (ref->next) { depth = __synthesize_probe_trace_arg_ref(ref->next, buf, depth + 1); if (depth < 0) return depth; } if (ref->user_access) err = strbuf_addf(buf, "%s%ld(", "+u", ref->offset); else err = strbuf_addf(buf, "%+ld(", ref->offset); return (err < 0) ? err : depth; } static int synthesize_probe_trace_arg(struct probe_trace_arg *arg, struct strbuf *buf) { struct probe_trace_arg_ref *ref = arg->ref; int depth = 0, err; /* Argument name or separator */ if (arg->name) err = strbuf_addf(buf, " %s=", arg->name); else err = strbuf_addch(buf, ' '); if (err) return err; /* Special case: @XXX */ if (arg->value[0] == '@' && arg->ref) ref = ref->next; /* Dereferencing arguments */ if (ref) { depth = __synthesize_probe_trace_arg_ref(ref, buf, 1); if (depth < 0) return depth; } /* Print argument value */ if (arg->value[0] == '@' && arg->ref) err = strbuf_addf(buf, "%s%+ld", arg->value, arg->ref->offset); else err = strbuf_addstr(buf, arg->value); /* Closing */ while (!err && depth--) err = strbuf_addch(buf, ')'); /* Print argument type */ if (!err && arg->type) err = strbuf_addf(buf, ":%s", arg->type); return err; } static int synthesize_probe_trace_args(struct probe_trace_event *tev, struct strbuf *buf) { int i, ret = 0; for (i = 0; i < tev->nargs && ret >= 0; i++) ret = synthesize_probe_trace_arg(&tev->args[i], buf); return ret; } static int synthesize_uprobe_trace_def(struct probe_trace_point *tp, struct strbuf *buf) { int err; /* Uprobes must have tp->module */ if (!tp->module) return -EINVAL; /* * If tp->address == 0, then this point must be a * absolute address uprobe. * try_to_find_absolute_address() should have made * tp->symbol to "0x0". */ if (!tp->address && (!tp->symbol || strcmp(tp->symbol, "0x0"))) return -EINVAL; /* Use the tp->address for uprobes */ err = strbuf_addf(buf, "%s:0x%" PRIx64, tp->module, tp->address); if (err >= 0 && tp->ref_ctr_offset) { if (!uprobe_ref_ctr_is_supported()) return -EINVAL; err = strbuf_addf(buf, "(0x%lx)", tp->ref_ctr_offset); } return err >= 0 ? 0 : err; } static int synthesize_kprobe_trace_def(struct probe_trace_point *tp, struct strbuf *buf) { if (!strncmp(tp->symbol, "0x", 2)) { /* Absolute address. See try_to_find_absolute_address() */ return strbuf_addf(buf, "%s%s0x%" PRIx64, tp->module ?: "", tp->module ? ":" : "", tp->address); } else { return strbuf_addf(buf, "%s%s%s+%lu", tp->module ?: "", tp->module ? ":" : "", tp->symbol, tp->offset); } } char *synthesize_probe_trace_command(struct probe_trace_event *tev) { struct probe_trace_point *tp = &tev->point; struct strbuf buf; char *ret = NULL; int err; if (strbuf_init(&buf, 32) < 0) return NULL; if (strbuf_addf(&buf, "%c:%s/%s ", tp->retprobe ? 'r' : 'p', tev->group, tev->event) < 0) goto error; if (tev->uprobes) err = synthesize_uprobe_trace_def(tp, &buf); else err = synthesize_kprobe_trace_def(tp, &buf); if (err >= 0) err = synthesize_probe_trace_args(tev, &buf); if (err >= 0) ret = strbuf_detach(&buf, NULL); error: strbuf_release(&buf); return ret; } static int find_perf_probe_point_from_map(struct probe_trace_point *tp, struct perf_probe_point *pp, bool is_kprobe) { struct symbol *sym = NULL; struct map *map = NULL; u64 addr = tp->address; int ret = -ENOENT; if (!is_kprobe) { map = dso__new_map(tp->module); if (!map) goto out; sym = map__find_symbol(map, addr); } else { if (tp->symbol && !addr) { if (kernel_get_symbol_address_by_name(tp->symbol, &addr, true, false) < 0) goto out; } if (addr) { addr += tp->offset; sym = machine__find_kernel_symbol(host_machine, addr, &map); } } if (!sym) goto out; pp->retprobe = tp->retprobe; pp->offset = addr - map->unmap_ip(map, sym->start); pp->function = strdup(sym->name); ret = pp->function ? 0 : -ENOMEM; out: if (map && !is_kprobe) { map__put(map); } return ret; } static int convert_to_perf_probe_point(struct probe_trace_point *tp, struct perf_probe_point *pp, bool is_kprobe) { char buf[128]; int ret; ret = find_perf_probe_point_from_dwarf(tp, pp, is_kprobe); if (!ret) return 0; ret = find_perf_probe_point_from_map(tp, pp, is_kprobe); if (!ret) return 0; pr_debug("Failed to find probe point from both of dwarf and map.\n"); if (tp->symbol) { pp->function = strdup(tp->symbol); pp->offset = tp->offset; } else { ret = e_snprintf(buf, 128, "0x%" PRIx64, tp->address); if (ret < 0) return ret; pp->function = strdup(buf); pp->offset = 0; } if (pp->function == NULL) return -ENOMEM; pp->retprobe = tp->retprobe; return 0; } static int convert_to_perf_probe_event(struct probe_trace_event *tev, struct perf_probe_event *pev, bool is_kprobe) { struct strbuf buf = STRBUF_INIT; int i, ret; /* Convert event/group name */ pev->event = strdup(tev->event); pev->group = strdup(tev->group); if (pev->event == NULL || pev->group == NULL) return -ENOMEM; /* Convert trace_point to probe_point */ ret = convert_to_perf_probe_point(&tev->point, &pev->point, is_kprobe); if (ret < 0) return ret; /* Convert trace_arg to probe_arg */ pev->nargs = tev->nargs; pev->args = zalloc(sizeof(struct perf_probe_arg) * pev->nargs); if (pev->args == NULL) return -ENOMEM; for (i = 0; i < tev->nargs && ret >= 0; i++) { if (tev->args[i].name) pev->args[i].name = strdup(tev->args[i].name); else { if ((ret = strbuf_init(&buf, 32)) < 0) goto error; ret = synthesize_probe_trace_arg(&tev->args[i], &buf); pev->args[i].name = strbuf_detach(&buf, NULL); } if (pev->args[i].name == NULL && ret >= 0) ret = -ENOMEM; } error: if (ret < 0) clear_perf_probe_event(pev); return ret; } void clear_perf_probe_event(struct perf_probe_event *pev) { struct perf_probe_arg_field *field, *next; int i; zfree(&pev->event); zfree(&pev->group); zfree(&pev->target); clear_perf_probe_point(&pev->point); for (i = 0; i < pev->nargs; i++) { zfree(&pev->args[i].name); zfree(&pev->args[i].var); zfree(&pev->args[i].type); field = pev->args[i].field; while (field) { next = field->next; zfree(&field->name); free(field); field = next; } } pev->nargs = 0; zfree(&pev->args); } #define strdup_or_goto(str, label) \ ({ char *__p = NULL; if (str && !(__p = strdup(str))) goto label; __p; }) static int perf_probe_point__copy(struct perf_probe_point *dst, struct perf_probe_point *src) { dst->file = strdup_or_goto(src->file, out_err); dst->function = strdup_or_goto(src->function, out_err); dst->lazy_line = strdup_or_goto(src->lazy_line, out_err); dst->line = src->line; dst->retprobe = src->retprobe; dst->offset = src->offset; return 0; out_err: clear_perf_probe_point(dst); return -ENOMEM; } static int perf_probe_arg__copy(struct perf_probe_arg *dst, struct perf_probe_arg *src) { struct perf_probe_arg_field *field, **ppfield; dst->name = strdup_or_goto(src->name, out_err); dst->var = strdup_or_goto(src->var, out_err); dst->type = strdup_or_goto(src->type, out_err); field = src->field; ppfield = &(dst->field); while (field) { *ppfield = zalloc(sizeof(*field)); if (!*ppfield) goto out_err; (*ppfield)->name = strdup_or_goto(field->name, out_err); (*ppfield)->index = field->index; (*ppfield)->ref = field->ref; field = field->next; ppfield = &((*ppfield)->next); } return 0; out_err: return -ENOMEM; } int perf_probe_event__copy(struct perf_probe_event *dst, struct perf_probe_event *src) { int i; dst->event = strdup_or_goto(src->event, out_err); dst->group = strdup_or_goto(src->group, out_err); dst->target = strdup_or_goto(src->target, out_err); dst->uprobes = src->uprobes; if (perf_probe_point__copy(&dst->point, &src->point) < 0) goto out_err; dst->args = zalloc(sizeof(struct perf_probe_arg) * src->nargs); if (!dst->args) goto out_err; dst->nargs = src->nargs; for (i = 0; i < src->nargs; i++) if (perf_probe_arg__copy(&dst->args[i], &src->args[i]) < 0) goto out_err; return 0; out_err: clear_perf_probe_event(dst); return -ENOMEM; } void clear_probe_trace_event(struct probe_trace_event *tev) { struct probe_trace_arg_ref *ref, *next; int i; zfree(&tev->event); zfree(&tev->group); zfree(&tev->point.symbol); zfree(&tev->point.realname); zfree(&tev->point.module); for (i = 0; i < tev->nargs; i++) { zfree(&tev->args[i].name); zfree(&tev->args[i].value); zfree(&tev->args[i].type); ref = tev->args[i].ref; while (ref) { next = ref->next; free(ref); ref = next; } } zfree(&tev->args); tev->nargs = 0; } struct kprobe_blacklist_node { struct list_head list; u64 start; u64 end; char *symbol; }; static void kprobe_blacklist__delete(struct list_head *blacklist) { struct kprobe_blacklist_node *node; while (!list_empty(blacklist)) { node = list_first_entry(blacklist, struct kprobe_blacklist_node, list); list_del_init(&node->list); zfree(&node->symbol); free(node); } } static int kprobe_blacklist__load(struct list_head *blacklist) { struct kprobe_blacklist_node *node; const char *__debugfs = debugfs__mountpoint(); char buf[PATH_MAX], *p; FILE *fp; int ret; if (__debugfs == NULL) return -ENOTSUP; ret = e_snprintf(buf, PATH_MAX, "%s/kprobes/blacklist", __debugfs); if (ret < 0) return ret; fp = fopen(buf, "r"); if (!fp) return -errno; ret = 0; while (fgets(buf, PATH_MAX, fp)) { node = zalloc(sizeof(*node)); if (!node) { ret = -ENOMEM; break; } INIT_LIST_HEAD(&node->list); list_add_tail(&node->list, blacklist); if (sscanf(buf, "0x%" PRIx64 "-0x%" PRIx64, &node->start, &node->end) != 2) { ret = -EINVAL; break; } p = strchr(buf, '\t'); if (p) { p++; if (p[strlen(p) - 1] == '\n') p[strlen(p) - 1] = '\0'; } else p = (char *)"unknown"; node->symbol = strdup(p); if (!node->symbol) { ret = -ENOMEM; break; } pr_debug2("Blacklist: 0x%" PRIx64 "-0x%" PRIx64 ", %s\n", node->start, node->end, node->symbol); ret++; } if (ret < 0) kprobe_blacklist__delete(blacklist); fclose(fp); return ret; } static struct kprobe_blacklist_node * kprobe_blacklist__find_by_address(struct list_head *blacklist, u64 address) { struct kprobe_blacklist_node *node; list_for_each_entry(node, blacklist, list) { if (node->start <= address && address < node->end) return node; } return NULL; } static LIST_HEAD(kprobe_blacklist); static void kprobe_blacklist__init(void) { if (!list_empty(&kprobe_blacklist)) return; if (kprobe_blacklist__load(&kprobe_blacklist) < 0) pr_debug("No kprobe blacklist support, ignored\n"); } static void kprobe_blacklist__release(void) { kprobe_blacklist__delete(&kprobe_blacklist); } static bool kprobe_blacklist__listed(u64 address) { return !!kprobe_blacklist__find_by_address(&kprobe_blacklist, address); } static int perf_probe_event__sprintf(const char *group, const char *event, struct perf_probe_event *pev, const char *module, struct strbuf *result) { int i, ret; char *buf; if (asprintf(&buf, "%s:%s", group, event) < 0) return -errno; ret = strbuf_addf(result, " %-20s (on ", buf); free(buf); if (ret) return ret; /* Synthesize only event probe point */ buf = synthesize_perf_probe_point(&pev->point); if (!buf) return -ENOMEM; ret = strbuf_addstr(result, buf); free(buf); if (!ret && module) ret = strbuf_addf(result, " in %s", module); if (!ret && pev->nargs > 0) { ret = strbuf_add(result, " with", 5); for (i = 0; !ret && i < pev->nargs; i++) { buf = synthesize_perf_probe_arg(&pev->args[i]); if (!buf) return -ENOMEM; ret = strbuf_addf(result, " %s", buf); free(buf); } } if (!ret) ret = strbuf_addch(result, ')'); return ret; } /* Show an event */ int show_perf_probe_event(const char *group, const char *event, struct perf_probe_event *pev, const char *module, bool use_stdout) { struct strbuf buf = STRBUF_INIT; int ret; ret = perf_probe_event__sprintf(group, event, pev, module, &buf); if (ret >= 0) { if (use_stdout) printf("%s\n", buf.buf); else pr_info("%s\n", buf.buf); } strbuf_release(&buf); return ret; } static bool filter_probe_trace_event(struct probe_trace_event *tev, struct strfilter *filter) { char tmp[128]; /* At first, check the event name itself */ if (strfilter__compare(filter, tev->event)) return true; /* Next, check the combination of name and group */ if (e_snprintf(tmp, 128, "%s:%s", tev->group, tev->event) < 0) return false; return strfilter__compare(filter, tmp); } static int __show_perf_probe_events(int fd, bool is_kprobe, struct strfilter *filter) { int ret = 0; struct probe_trace_event tev; struct perf_probe_event pev; struct strlist *rawlist; struct str_node *ent; memset(&tev, 0, sizeof(tev)); memset(&pev, 0, sizeof(pev)); rawlist = probe_file__get_rawlist(fd); if (!rawlist) return -ENOMEM; strlist__for_each_entry(ent, rawlist) { ret = parse_probe_trace_command(ent->s, &tev); if (ret >= 0) { if (!filter_probe_trace_event(&tev, filter)) goto next; ret = convert_to_perf_probe_event(&tev, &pev, is_kprobe); if (ret < 0) goto next; ret = show_perf_probe_event(pev.group, pev.event, &pev, tev.point.module, true); } next: clear_perf_probe_event(&pev); clear_probe_trace_event(&tev); if (ret < 0) break; } strlist__delete(rawlist); /* Cleanup cached debuginfo if needed */ debuginfo_cache__exit(); return ret; } /* List up current perf-probe events */ int show_perf_probe_events(struct strfilter *filter) { int kp_fd, up_fd, ret; setup_pager(); if (probe_conf.cache) return probe_cache__show_all_caches(filter); ret = init_probe_symbol_maps(false); if (ret < 0) return ret; ret = probe_file__open_both(&kp_fd, &up_fd, 0); if (ret < 0) return ret; if (kp_fd >= 0) ret = __show_perf_probe_events(kp_fd, true, filter); if (up_fd >= 0 && ret >= 0) ret = __show_perf_probe_events(up_fd, false, filter); if (kp_fd > 0) close(kp_fd); if (up_fd > 0) close(up_fd); exit_probe_symbol_maps(); return ret; } static int get_new_event_name(char *buf, size_t len, const char *base, struct strlist *namelist, bool ret_event, bool allow_suffix) { int i, ret; char *p, *nbase; if (*base == '.') base++; nbase = strdup(base); if (!nbase) return -ENOMEM; /* Cut off the dot suffixes (e.g. .const, .isra) and version suffixes */ p = strpbrk(nbase, ".@"); if (p && p != nbase) *p = '\0'; /* Try no suffix number */ ret = e_snprintf(buf, len, "%s%s", nbase, ret_event ? "__return" : ""); if (ret < 0) { pr_debug("snprintf() failed: %d\n", ret); goto out; } if (!strlist__has_entry(namelist, buf)) goto out; if (!allow_suffix) { pr_warning("Error: event \"%s\" already exists.\n" " Hint: Remove existing event by 'perf probe -d'\n" " or force duplicates by 'perf probe -f'\n" " or set 'force=yes' in BPF source.\n", buf); ret = -EEXIST; goto out; } /* Try to add suffix */ for (i = 1; i < MAX_EVENT_INDEX; i++) { ret = e_snprintf(buf, len, "%s_%d", nbase, i); if (ret < 0) { pr_debug("snprintf() failed: %d\n", ret); goto out; } if (!strlist__has_entry(namelist, buf)) break; } if (i == MAX_EVENT_INDEX) { pr_warning("Too many events are on the same function.\n"); ret = -ERANGE; } out: free(nbase); /* Final validation */ if (ret >= 0 && !is_c_func_name(buf)) { pr_warning("Internal error: \"%s\" is an invalid event name.\n", buf); ret = -EINVAL; } return ret; } /* Warn if the current kernel's uprobe implementation is old */ static void warn_uprobe_event_compat(struct probe_trace_event *tev) { int i; char *buf = synthesize_probe_trace_command(tev); struct probe_trace_point *tp = &tev->point; if (tp->ref_ctr_offset && !uprobe_ref_ctr_is_supported()) { pr_warning("A semaphore is associated with %s:%s and " "seems your kernel doesn't support it.\n", tev->group, tev->event); } /* Old uprobe event doesn't support memory dereference */ if (!tev->uprobes || tev->nargs == 0 || !buf) goto out; for (i = 0; i < tev->nargs; i++) if (strglobmatch(tev->args[i].value, "[$@+-]*")) { pr_warning("Please upgrade your kernel to at least " "3.14 to have access to feature %s\n", tev->args[i].value); break; } out: free(buf); } /* Set new name from original perf_probe_event and namelist */ static int probe_trace_event__set_name(struct probe_trace_event *tev, struct perf_probe_event *pev, struct strlist *namelist, bool allow_suffix) { const char *event, *group; char buf[64]; int ret; /* If probe_event or trace_event already have the name, reuse it */ if (pev->event && !pev->sdt) event = pev->event; else if (tev->event) event = tev->event; else { /* Or generate new one from probe point */ if (pev->point.function && (strncmp(pev->point.function, "0x", 2) != 0) && !strisglob(pev->point.function)) event = pev->point.function; else event = tev->point.realname; } if (pev->group && !pev->sdt) group = pev->group; else if (tev->group) group = tev->group; else group = PERFPROBE_GROUP; /* Get an unused new event name */ ret = get_new_event_name(buf, 64, event, namelist, tev->point.retprobe, allow_suffix); if (ret < 0) return ret; event = buf; tev->event = strdup(event); tev->group = strdup(group); if (tev->event == NULL || tev->group == NULL) return -ENOMEM; /* * Add new event name to namelist if multiprobe event is NOT * supported, since we have to use new event name for following * probes in that case. */ if (!multiprobe_event_is_supported()) strlist__add(namelist, event); return 0; } static int __open_probe_file_and_namelist(bool uprobe, struct strlist **namelist) { int fd; fd = probe_file__open(PF_FL_RW | (uprobe ? PF_FL_UPROBE : 0)); if (fd < 0) return fd; /* Get current event names */ *namelist = probe_file__get_namelist(fd); if (!(*namelist)) { pr_debug("Failed to get current event list.\n"); close(fd); return -ENOMEM; } return fd; } static int __add_probe_trace_events(struct perf_probe_event *pev, struct probe_trace_event *tevs, int ntevs, bool allow_suffix) { int i, fd[2] = {-1, -1}, up, ret; struct probe_trace_event *tev = NULL; struct probe_cache *cache = NULL; struct strlist *namelist[2] = {NULL, NULL}; struct nscookie nsc; up = pev->uprobes ? 1 : 0; fd[up] = __open_probe_file_and_namelist(up, &namelist[up]); if (fd[up] < 0) return fd[up]; ret = 0; for (i = 0; i < ntevs; i++) { tev = &tevs[i]; up = tev->uprobes ? 1 : 0; if (fd[up] == -1) { /* Open the kprobe/uprobe_events */ fd[up] = __open_probe_file_and_namelist(up, &namelist[up]); if (fd[up] < 0) goto close_out; } /* Skip if the symbol is out of .text or blacklisted */ if (!tev->point.symbol && !pev->uprobes) continue; /* Set new name for tev (and update namelist) */ ret = probe_trace_event__set_name(tev, pev, namelist[up], allow_suffix); if (ret < 0) break; nsinfo__mountns_enter(pev->nsi, &nsc); ret = probe_file__add_event(fd[up], tev); nsinfo__mountns_exit(&nsc); if (ret < 0) break; /* * Probes after the first probe which comes from same * user input are always allowed to add suffix, because * there might be several addresses corresponding to * one code line. */ allow_suffix = true; } if (ret == -EINVAL && pev->uprobes) warn_uprobe_event_compat(tev); if (ret == 0 && probe_conf.cache) { cache = probe_cache__new(pev->target, pev->nsi); if (!cache || probe_cache__add_entry(cache, pev, tevs, ntevs) < 0 || probe_cache__commit(cache) < 0) pr_warning("Failed to add event to probe cache\n"); probe_cache__delete(cache); } close_out: for (up = 0; up < 2; up++) { strlist__delete(namelist[up]); if (fd[up] >= 0) close(fd[up]); } return ret; } static int find_probe_functions(struct map *map, char *name, struct symbol **syms) { int found = 0; struct symbol *sym; struct rb_node *tmp; const char *norm, *ver; char *buf = NULL; bool cut_version = true; if (map__load(map) < 0) return -EACCES; /* Possible permission error to load symbols */ /* If user gives a version, don't cut off the version from symbols */ if (strchr(name, '@')) cut_version = false; map__for_each_symbol(map, sym, tmp) { norm = arch__normalize_symbol_name(sym->name); if (!norm) continue; if (cut_version) { /* We don't care about default symbol or not */ ver = strchr(norm, '@'); if (ver) { buf = strndup(norm, ver - norm); if (!buf) return -ENOMEM; norm = buf; } } if (strglobmatch(norm, name)) { found++; if (syms && found < probe_conf.max_probes) syms[found - 1] = sym; } if (buf) zfree(&buf); } return found; } void __weak arch__fix_tev_from_maps(struct perf_probe_event *pev __maybe_unused, struct probe_trace_event *tev __maybe_unused, struct map *map __maybe_unused, struct symbol *sym __maybe_unused) { } static void pr_kallsyms_access_error(void) { pr_err("Please ensure you can read the /proc/kallsyms symbol addresses.\n" "If /proc/sys/kernel/kptr_restrict is '2', you can not read\n" "kernel symbol addresses even if you are a superuser. Please change\n" "it to '1'. If kptr_restrict is '1', the superuser can read the\n" "symbol addresses.\n" "In that case, please run this command again with sudo.\n"); } /* * Find probe function addresses from map. * Return an error or the number of found probe_trace_event */ static int find_probe_trace_events_from_map(struct perf_probe_event *pev, struct probe_trace_event **tevs) { struct map *map = NULL; struct ref_reloc_sym *reloc_sym = NULL; struct symbol *sym; struct symbol **syms = NULL; struct probe_trace_event *tev; struct perf_probe_point *pp = &pev->point; struct probe_trace_point *tp; int num_matched_functions; int ret, i, j, skipped = 0; char *mod_name; map = get_target_map(pev->target, pev->nsi, pev->uprobes); if (!map) { ret = -EINVAL; goto out; } syms = malloc(sizeof(struct symbol *) * probe_conf.max_probes); if (!syms) { ret = -ENOMEM; goto out; } /* * Load matched symbols: Since the different local symbols may have * same name but different addresses, this lists all the symbols. */ num_matched_functions = find_probe_functions(map, pp->function, syms); if (num_matched_functions <= 0) { if (num_matched_functions == -EACCES) { pr_err("Failed to load symbols from %s\n", pev->target ?: "/proc/kallsyms"); if (pev->target) pr_err("Please ensure the file is not stripped.\n"); else pr_kallsyms_access_error(); } else pr_err("Failed to find symbol %s in %s\n", pp->function, pev->target ? : "kernel"); ret = -ENOENT; goto out; } else if (num_matched_functions > probe_conf.max_probes) { pr_err("Too many functions matched in %s\n", pev->target ? : "kernel"); ret = -E2BIG; goto out; } /* Note that the symbols in the kmodule are not relocated */ if (!pev->uprobes && !pev->target && (!pp->retprobe || kretprobe_offset_is_supported())) { reloc_sym = kernel_get_ref_reloc_sym(NULL); if (!reloc_sym) { pr_warning("Relocated base symbol is not found! " "Check /proc/sys/kernel/kptr_restrict\n" "and /proc/sys/kernel/perf_event_paranoid. " "Or run as privileged perf user.\n\n"); ret = -EINVAL; goto out; } } /* Setup result trace-probe-events */ *tevs = zalloc(sizeof(*tev) * num_matched_functions); if (!*tevs) { ret = -ENOMEM; goto out; } ret = 0; for (j = 0; j < num_matched_functions; j++) { sym = syms[j]; if (sym->type != STT_FUNC) continue; /* There can be duplicated symbols in the map */ for (i = 0; i < j; i++) if (sym->start == syms[i]->start) { pr_debug("Found duplicated symbol %s @ %" PRIx64 "\n", sym->name, sym->start); break; } if (i != j) continue; tev = (*tevs) + ret; tp = &tev->point; if (ret == num_matched_functions) { pr_warning("Too many symbols are listed. Skip it.\n"); break; } ret++; if (pp->offset > sym->end - sym->start) { pr_warning("Offset %ld is bigger than the size of %s\n", pp->offset, sym->name); ret = -ENOENT; goto err_out; } /* Add one probe point */ tp->address = map->unmap_ip(map, sym->start) + pp->offset; /* Check the kprobe (not in module) is within .text */ if (!pev->uprobes && !pev->target && kprobe_warn_out_range(sym->name, tp->address)) { tp->symbol = NULL; /* Skip it */ skipped++; } else if (reloc_sym) { tp->symbol = strdup_or_goto(reloc_sym->name, nomem_out); tp->offset = tp->address - reloc_sym->addr; } else { tp->symbol = strdup_or_goto(sym->name, nomem_out); tp->offset = pp->offset; } tp->realname = strdup_or_goto(sym->name, nomem_out); tp->retprobe = pp->retprobe; if (pev->target) { if (pev->uprobes) { tev->point.module = strdup_or_goto(pev->target, nomem_out); } else { mod_name = find_module_name(pev->target); tev->point.module = strdup(mod_name ? mod_name : pev->target); free(mod_name); if (!tev->point.module) goto nomem_out; } } tev->uprobes = pev->uprobes; tev->nargs = pev->nargs; if (tev->nargs) { tev->args = zalloc(sizeof(struct probe_trace_arg) * tev->nargs); if (tev->args == NULL) goto nomem_out; } for (i = 0; i < tev->nargs; i++) { if (pev->args[i].name) tev->args[i].name = strdup_or_goto(pev->args[i].name, nomem_out); tev->args[i].value = strdup_or_goto(pev->args[i].var, nomem_out); if (pev->args[i].type) tev->args[i].type = strdup_or_goto(pev->args[i].type, nomem_out); } arch__fix_tev_from_maps(pev, tev, map, sym); } if (ret == skipped) { ret = -ENOENT; goto err_out; } out: map__put(map); free(syms); return ret; nomem_out: ret = -ENOMEM; err_out: clear_probe_trace_events(*tevs, num_matched_functions); zfree(tevs); goto out; } static int try_to_find_absolute_address(struct perf_probe_event *pev, struct probe_trace_event **tevs) { struct perf_probe_point *pp = &pev->point; struct probe_trace_event *tev; struct probe_trace_point *tp; int i, err; if (!(pev->point.function && !strncmp(pev->point.function, "0x", 2))) return -EINVAL; if (perf_probe_event_need_dwarf(pev)) return -EINVAL; /* * This is 'perf probe /lib/libc.so 0xabcd'. Try to probe at * absolute address. * * Only one tev can be generated by this. */ *tevs = zalloc(sizeof(*tev)); if (!*tevs) return -ENOMEM; tev = *tevs; tp = &tev->point; /* * Don't use tp->offset, use address directly, because * in synthesize_probe_trace_command() address cannot be * zero. */ tp->address = pev->point.abs_address; tp->retprobe = pp->retprobe; tev->uprobes = pev->uprobes; err = -ENOMEM; /* * Give it a '0x' leading symbol name. * In __add_probe_trace_events, a NULL symbol is interpreted as * invalid. */ if (asprintf(&tp->symbol, "0x%" PRIx64, tp->address) < 0) goto errout; /* For kprobe, check range */ if ((!tev->uprobes) && (kprobe_warn_out_range(tev->point.symbol, tev->point.address))) { err = -EACCES; goto errout; } if (asprintf(&tp->realname, "abs_%" PRIx64, tp->address) < 0) goto errout; if (pev->target) { tp->module = strdup(pev->target); if (!tp->module) goto errout; } if (tev->group) { tev->group = strdup(pev->group); if (!tev->group) goto errout; } if (pev->event) { tev->event = strdup(pev->event); if (!tev->event) goto errout; } tev->nargs = pev->nargs; tev->args = zalloc(sizeof(struct probe_trace_arg) * tev->nargs); if (!tev->args) goto errout; for (i = 0; i < tev->nargs; i++) copy_to_probe_trace_arg(&tev->args[i], &pev->args[i]); return 1; errout: clear_probe_trace_events(*tevs, 1); *tevs = NULL; return err; } /* Concatenate two arrays */ static void *memcat(void *a, size_t sz_a, void *b, size_t sz_b) { void *ret; ret = malloc(sz_a + sz_b); if (ret) { memcpy(ret, a, sz_a); memcpy(ret + sz_a, b, sz_b); } return ret; } static int concat_probe_trace_events(struct probe_trace_event **tevs, int *ntevs, struct probe_trace_event **tevs2, int ntevs2) { struct probe_trace_event *new_tevs; int ret = 0; if (*ntevs == 0) { *tevs = *tevs2; *ntevs = ntevs2; *tevs2 = NULL; return 0; } if (*ntevs + ntevs2 > probe_conf.max_probes) ret = -E2BIG; else { /* Concatenate the array of probe_trace_event */ new_tevs = memcat(*tevs, (*ntevs) * sizeof(**tevs), *tevs2, ntevs2 * sizeof(**tevs2)); if (!new_tevs) ret = -ENOMEM; else { free(*tevs); *tevs = new_tevs; *ntevs += ntevs2; } } if (ret < 0) clear_probe_trace_events(*tevs2, ntevs2); zfree(tevs2); return ret; } /* * Try to find probe_trace_event from given probe caches. Return the number * of cached events found, if an error occurs return the error. */ static int find_cached_events(struct perf_probe_event *pev, struct probe_trace_event **tevs, const char *target) { struct probe_cache *cache; struct probe_cache_entry *entry; struct probe_trace_event *tmp_tevs = NULL; int ntevs = 0; int ret = 0; cache = probe_cache__new(target, pev->nsi); /* Return 0 ("not found") if the target has no probe cache. */ if (!cache) return 0; for_each_probe_cache_entry(entry, cache) { /* Skip the cache entry which has no name */ if (!entry->pev.event || !entry->pev.group) continue; if ((!pev->group || strglobmatch(entry->pev.group, pev->group)) && strglobmatch(entry->pev.event, pev->event)) { ret = probe_cache_entry__get_event(entry, &tmp_tevs); if (ret > 0) ret = concat_probe_trace_events(tevs, &ntevs, &tmp_tevs, ret); if (ret < 0) break; } } probe_cache__delete(cache); if (ret < 0) { clear_probe_trace_events(*tevs, ntevs); zfree(tevs); } else { ret = ntevs; if (ntevs > 0 && target && target[0] == '/') pev->uprobes = true; } return ret; } /* Try to find probe_trace_event from all probe caches */ static int find_cached_events_all(struct perf_probe_event *pev, struct probe_trace_event **tevs) { struct probe_trace_event *tmp_tevs = NULL; struct strlist *bidlist; struct str_node *nd; char *pathname; int ntevs = 0; int ret; /* Get the buildid list of all valid caches */ bidlist = build_id_cache__list_all(true); if (!bidlist) { ret = -errno; pr_debug("Failed to get buildids: %d\n", ret); return ret; } ret = 0; strlist__for_each_entry(nd, bidlist) { pathname = build_id_cache__origname(nd->s); ret = find_cached_events(pev, &tmp_tevs, pathname); /* In the case of cnt == 0, we just skip it */ if (ret > 0) ret = concat_probe_trace_events(tevs, &ntevs, &tmp_tevs, ret); free(pathname); if (ret < 0) break; } strlist__delete(bidlist); if (ret < 0) { clear_probe_trace_events(*tevs, ntevs); zfree(tevs); } else ret = ntevs; return ret; } static int find_probe_trace_events_from_cache(struct perf_probe_event *pev, struct probe_trace_event **tevs) { struct probe_cache *cache; struct probe_cache_entry *entry; struct probe_trace_event *tev; struct str_node *node; int ret, i; if (pev->sdt) { /* For SDT/cached events, we use special search functions */ if (!pev->target) return find_cached_events_all(pev, tevs); else return find_cached_events(pev, tevs, pev->target); } cache = probe_cache__new(pev->target, pev->nsi); if (!cache) return 0; entry = probe_cache__find(cache, pev); if (!entry) { /* SDT must be in the cache */ ret = pev->sdt ? -ENOENT : 0; goto out; } ret = strlist__nr_entries(entry->tevlist); if (ret > probe_conf.max_probes) { pr_debug("Too many entries matched in the cache of %s\n", pev->target ? : "kernel"); ret = -E2BIG; goto out; } *tevs = zalloc(ret * sizeof(*tev)); if (!*tevs) { ret = -ENOMEM; goto out; } i = 0; strlist__for_each_entry(node, entry->tevlist) { tev = &(*tevs)[i++]; ret = parse_probe_trace_command(node->s, tev); if (ret < 0) goto out; /* Set the uprobes attribute as same as original */ tev->uprobes = pev->uprobes; } ret = i; out: probe_cache__delete(cache); return ret; } static int convert_to_probe_trace_events(struct perf_probe_event *pev, struct probe_trace_event **tevs) { int ret; if (!pev->group && !pev->sdt) { /* Set group name if not given */ if (!pev->uprobes) { pev->group = strdup(PERFPROBE_GROUP); ret = pev->group ? 0 : -ENOMEM; } else ret = convert_exec_to_group(pev->target, &pev->group); if (ret != 0) { pr_warning("Failed to make a group name.\n"); return ret; } } ret = try_to_find_absolute_address(pev, tevs); if (ret > 0) return ret; /* At first, we need to lookup cache entry */ ret = find_probe_trace_events_from_cache(pev, tevs); if (ret > 0 || pev->sdt) /* SDT can be found only in the cache */ return ret == 0 ? -ENOENT : ret; /* Found in probe cache */ /* Convert perf_probe_event with debuginfo */ ret = try_to_find_probe_trace_events(pev, tevs); if (ret != 0) return ret; /* Found in debuginfo or got an error */ return find_probe_trace_events_from_map(pev, tevs); } int convert_perf_probe_events(struct perf_probe_event *pevs, int npevs) { int i, ret; /* Loop 1: convert all events */ for (i = 0; i < npevs; i++) { /* Init kprobe blacklist if needed */ if (!pevs[i].uprobes) kprobe_blacklist__init(); /* Convert with or without debuginfo */ ret = convert_to_probe_trace_events(&pevs[i], &pevs[i].tevs); if (ret < 0) return ret; pevs[i].ntevs = ret; } /* This just release blacklist only if allocated */ kprobe_blacklist__release(); return 0; } static int show_probe_trace_event(struct probe_trace_event *tev) { char *buf = synthesize_probe_trace_command(tev); if (!buf) { pr_debug("Failed to synthesize probe trace event.\n"); return -EINVAL; } /* Showing definition always go stdout */ printf("%s\n", buf); free(buf); return 0; } int show_probe_trace_events(struct perf_probe_event *pevs, int npevs) { struct strlist *namelist = strlist__new(NULL, NULL); struct probe_trace_event *tev; struct perf_probe_event *pev; int i, j, ret = 0; if (!namelist) return -ENOMEM; for (j = 0; j < npevs && !ret; j++) { pev = &pevs[j]; for (i = 0; i < pev->ntevs && !ret; i++) { tev = &pev->tevs[i]; /* Skip if the symbol is out of .text or blacklisted */ if (!tev->point.symbol && !pev->uprobes) continue; /* Set new name for tev (and update namelist) */ ret = probe_trace_event__set_name(tev, pev, namelist, true); if (!ret) ret = show_probe_trace_event(tev); } } strlist__delete(namelist); return ret; } static int show_bootconfig_event(struct probe_trace_event *tev) { struct probe_trace_point *tp = &tev->point; struct strbuf buf; char *ret = NULL; int err; if (strbuf_init(&buf, 32) < 0) return -ENOMEM; err = synthesize_kprobe_trace_def(tp, &buf); if (err >= 0) err = synthesize_probe_trace_args(tev, &buf); if (err >= 0) ret = strbuf_detach(&buf, NULL); strbuf_release(&buf); if (ret) { printf("'%s'", ret); free(ret); } return err; } int show_bootconfig_events(struct perf_probe_event *pevs, int npevs) { struct strlist *namelist = strlist__new(NULL, NULL); struct probe_trace_event *tev; struct perf_probe_event *pev; char *cur_name = NULL; int i, j, ret = 0; if (!namelist) return -ENOMEM; for (j = 0; j < npevs && !ret; j++) { pev = &pevs[j]; if (pev->group && strcmp(pev->group, "probe")) pr_warning("WARN: Group name %s is ignored\n", pev->group); if (pev->uprobes) { pr_warning("ERROR: Bootconfig doesn't support uprobes\n"); ret = -EINVAL; break; } for (i = 0; i < pev->ntevs && !ret; i++) { tev = &pev->tevs[i]; /* Skip if the symbol is out of .text or blacklisted */ if (!tev->point.symbol && !pev->uprobes) continue; /* Set new name for tev (and update namelist) */ ret = probe_trace_event__set_name(tev, pev, namelist, true); if (ret) break; if (!cur_name || strcmp(cur_name, tev->event)) { printf("%sftrace.event.kprobes.%s.probe = ", cur_name ? "\n" : "", tev->event); cur_name = tev->event; } else printf(", "); ret = show_bootconfig_event(tev); } } printf("\n"); strlist__delete(namelist); return ret; } int apply_perf_probe_events(struct perf_probe_event *pevs, int npevs) { int i, ret = 0; /* Loop 2: add all events */ for (i = 0; i < npevs; i++) { ret = __add_probe_trace_events(&pevs[i], pevs[i].tevs, pevs[i].ntevs, probe_conf.force_add); if (ret < 0) break; } return ret; } void cleanup_perf_probe_events(struct perf_probe_event *pevs, int npevs) { int i, j; struct perf_probe_event *pev; /* Loop 3: cleanup and free trace events */ for (i = 0; i < npevs; i++) { pev = &pevs[i]; for (j = 0; j < pevs[i].ntevs; j++) clear_probe_trace_event(&pevs[i].tevs[j]); zfree(&pevs[i].tevs); pevs[i].ntevs = 0; nsinfo__zput(pev->nsi); clear_perf_probe_event(&pevs[i]); } } int add_perf_probe_events(struct perf_probe_event *pevs, int npevs) { int ret; ret = init_probe_symbol_maps(pevs->uprobes); if (ret < 0) return ret; ret = convert_perf_probe_events(pevs, npevs); if (ret == 0) ret = apply_perf_probe_events(pevs, npevs); cleanup_perf_probe_events(pevs, npevs); exit_probe_symbol_maps(); return ret; } int del_perf_probe_events(struct strfilter *filter) { int ret, ret2, ufd = -1, kfd = -1; char *str = strfilter__string(filter); if (!str) return -EINVAL; /* Get current event names */ ret = probe_file__open_both(&kfd, &ufd, PF_FL_RW); if (ret < 0) goto out; ret = probe_file__del_events(kfd, filter); if (ret < 0 && ret != -ENOENT) goto error; ret2 = probe_file__del_events(ufd, filter); if (ret2 < 0 && ret2 != -ENOENT) { ret = ret2; goto error; } ret = 0; error: if (kfd >= 0) close(kfd); if (ufd >= 0) close(ufd); out: free(str); return ret; } int show_available_funcs(const char *target, struct nsinfo *nsi, struct strfilter *_filter, bool user) { struct rb_node *nd; struct map *map; int ret; ret = init_probe_symbol_maps(user); if (ret < 0) return ret; /* Get a symbol map */ map = get_target_map(target, nsi, user); if (!map) { pr_err("Failed to get a map for %s\n", (target) ? : "kernel"); return -EINVAL; } ret = map__load(map); if (ret) { if (ret == -2) { char *str = strfilter__string(_filter); pr_err("Failed to find symbols matched to \"%s\"\n", str); free(str); } else pr_err("Failed to load symbols in %s\n", (target) ? : "kernel"); goto end; } if (!dso__sorted_by_name(map->dso)) dso__sort_by_name(map->dso); /* Show all (filtered) symbols */ setup_pager(); for (nd = rb_first_cached(&map->dso->symbol_names); nd; nd = rb_next(nd)) { struct symbol_name_rb_node *pos = rb_entry(nd, struct symbol_name_rb_node, rb_node); if (strfilter__compare(_filter, pos->sym.name)) printf("%s\n", pos->sym.name); } end: map__put(map); exit_probe_symbol_maps(); return ret; } int copy_to_probe_trace_arg(struct probe_trace_arg *tvar, struct perf_probe_arg *pvar) { tvar->value = strdup(pvar->var); if (tvar->value == NULL) return -ENOMEM; if (pvar->type) { tvar->type = strdup(pvar->type); if (tvar->type == NULL) return -ENOMEM; } if (pvar->name) { tvar->name = strdup(pvar->name); if (tvar->name == NULL) return -ENOMEM; } else tvar->name = NULL; return 0; }