// SPDX-License-Identifier: (LGPL-2.1 OR BSD-2-Clause) /* Copyright (c) 2018 Facebook */ #include #include #include #include #include #include #include #include #include #include "btf.h" #include "bpf.h" #include "libbpf.h" #include "libbpf_internal.h" #include "hashmap.h" #define BTF_MAX_NR_TYPES 0x7fffffff #define BTF_MAX_STR_OFFSET 0x7fffffff static struct btf_type btf_void; struct btf { union { struct btf_header *hdr; void *data; }; struct btf_type **types; const char *strings; void *nohdr_data; __u32 nr_types; __u32 types_size; __u32 data_size; int fd; }; static inline __u64 ptr_to_u64(const void *ptr) { return (__u64) (unsigned long) ptr; } static int btf_add_type(struct btf *btf, struct btf_type *t) { if (btf->types_size - btf->nr_types < 2) { struct btf_type **new_types; __u32 expand_by, new_size; if (btf->types_size == BTF_MAX_NR_TYPES) return -E2BIG; expand_by = max(btf->types_size >> 2, 16); new_size = min(BTF_MAX_NR_TYPES, btf->types_size + expand_by); new_types = realloc(btf->types, sizeof(*new_types) * new_size); if (!new_types) return -ENOMEM; if (btf->nr_types == 0) new_types[0] = &btf_void; btf->types = new_types; btf->types_size = new_size; } btf->types[++(btf->nr_types)] = t; return 0; } static int btf_parse_hdr(struct btf *btf) { const struct btf_header *hdr = btf->hdr; __u32 meta_left; if (btf->data_size < sizeof(struct btf_header)) { pr_debug("BTF header not found\n"); return -EINVAL; } if (hdr->magic != BTF_MAGIC) { pr_debug("Invalid BTF magic:%x\n", hdr->magic); return -EINVAL; } if (hdr->version != BTF_VERSION) { pr_debug("Unsupported BTF version:%u\n", hdr->version); return -ENOTSUP; } if (hdr->flags) { pr_debug("Unsupported BTF flags:%x\n", hdr->flags); return -ENOTSUP; } meta_left = btf->data_size - sizeof(*hdr); if (!meta_left) { pr_debug("BTF has no data\n"); return -EINVAL; } if (meta_left < hdr->type_off) { pr_debug("Invalid BTF type section offset:%u\n", hdr->type_off); return -EINVAL; } if (meta_left < hdr->str_off) { pr_debug("Invalid BTF string section offset:%u\n", hdr->str_off); return -EINVAL; } if (hdr->type_off >= hdr->str_off) { pr_debug("BTF type section offset >= string section offset. No type?\n"); return -EINVAL; } if (hdr->type_off & 0x02) { pr_debug("BTF type section is not aligned to 4 bytes\n"); return -EINVAL; } btf->nohdr_data = btf->hdr + 1; return 0; } static int btf_parse_str_sec(struct btf *btf) { const struct btf_header *hdr = btf->hdr; const char *start = btf->nohdr_data + hdr->str_off; const char *end = start + btf->hdr->str_len; if (!hdr->str_len || hdr->str_len - 1 > BTF_MAX_STR_OFFSET || start[0] || end[-1]) { pr_debug("Invalid BTF string section\n"); return -EINVAL; } btf->strings = start; return 0; } static int btf_type_size(struct btf_type *t) { int base_size = sizeof(struct btf_type); __u16 vlen = btf_vlen(t); switch (btf_kind(t)) { case BTF_KIND_FWD: case BTF_KIND_CONST: case BTF_KIND_VOLATILE: case BTF_KIND_RESTRICT: case BTF_KIND_PTR: case BTF_KIND_TYPEDEF: case BTF_KIND_FUNC: return base_size; case BTF_KIND_INT: return base_size + sizeof(__u32); case BTF_KIND_ENUM: return base_size + vlen * sizeof(struct btf_enum); case BTF_KIND_ARRAY: return base_size + sizeof(struct btf_array); case BTF_KIND_STRUCT: case BTF_KIND_UNION: return base_size + vlen * sizeof(struct btf_member); case BTF_KIND_FUNC_PROTO: return base_size + vlen * sizeof(struct btf_param); case BTF_KIND_VAR: return base_size + sizeof(struct btf_var); case BTF_KIND_DATASEC: return base_size + vlen * sizeof(struct btf_var_secinfo); default: pr_debug("Unsupported BTF_KIND:%u\n", btf_kind(t)); return -EINVAL; } } static int btf_parse_type_sec(struct btf *btf) { struct btf_header *hdr = btf->hdr; void *nohdr_data = btf->nohdr_data; void *next_type = nohdr_data + hdr->type_off; void *end_type = nohdr_data + hdr->str_off; while (next_type < end_type) { struct btf_type *t = next_type; int type_size; int err; type_size = btf_type_size(t); if (type_size < 0) return type_size; next_type += type_size; err = btf_add_type(btf, t); if (err) return err; } return 0; } __u32 btf__get_nr_types(const struct btf *btf) { return btf->nr_types; } const struct btf_type *btf__type_by_id(const struct btf *btf, __u32 type_id) { if (type_id > btf->nr_types) return NULL; return btf->types[type_id]; } static bool btf_type_is_void(const struct btf_type *t) { return t == &btf_void || btf_is_fwd(t); } static bool btf_type_is_void_or_null(const struct btf_type *t) { return !t || btf_type_is_void(t); } #define MAX_RESOLVE_DEPTH 32 __s64 btf__resolve_size(const struct btf *btf, __u32 type_id) { const struct btf_array *array; const struct btf_type *t; __u32 nelems = 1; __s64 size = -1; int i; t = btf__type_by_id(btf, type_id); for (i = 0; i < MAX_RESOLVE_DEPTH && !btf_type_is_void_or_null(t); i++) { switch (btf_kind(t)) { case BTF_KIND_INT: case BTF_KIND_STRUCT: case BTF_KIND_UNION: case BTF_KIND_ENUM: case BTF_KIND_DATASEC: size = t->size; goto done; case BTF_KIND_PTR: size = sizeof(void *); goto done; case BTF_KIND_TYPEDEF: case BTF_KIND_VOLATILE: case BTF_KIND_CONST: case BTF_KIND_RESTRICT: case BTF_KIND_VAR: type_id = t->type; break; case BTF_KIND_ARRAY: array = btf_array(t); if (nelems && array->nelems > UINT32_MAX / nelems) return -E2BIG; nelems *= array->nelems; type_id = array->type; break; default: return -EINVAL; } t = btf__type_by_id(btf, type_id); } if (size < 0) return -EINVAL; done: if (nelems && size > UINT32_MAX / nelems) return -E2BIG; return nelems * size; } int btf__resolve_type(const struct btf *btf, __u32 type_id) { const struct btf_type *t; int depth = 0; t = btf__type_by_id(btf, type_id); while (depth < MAX_RESOLVE_DEPTH && !btf_type_is_void_or_null(t) && (btf_is_mod(t) || btf_is_typedef(t) || btf_is_var(t))) { type_id = t->type; t = btf__type_by_id(btf, type_id); depth++; } if (depth == MAX_RESOLVE_DEPTH || btf_type_is_void_or_null(t)) return -EINVAL; return type_id; } __s32 btf__find_by_name(const struct btf *btf, const char *type_name) { __u32 i; if (!strcmp(type_name, "void")) return 0; for (i = 1; i <= btf->nr_types; i++) { const struct btf_type *t = btf->types[i]; const char *name = btf__name_by_offset(btf, t->name_off); if (name && !strcmp(type_name, name)) return i; } return -ENOENT; } void btf__free(struct btf *btf) { if (!btf) return; if (btf->fd != -1) close(btf->fd); free(btf->data); free(btf->types); free(btf); } struct btf *btf__new(__u8 *data, __u32 size) { struct btf *btf; int err; btf = calloc(1, sizeof(struct btf)); if (!btf) return ERR_PTR(-ENOMEM); btf->fd = -1; btf->data = malloc(size); if (!btf->data) { err = -ENOMEM; goto done; } memcpy(btf->data, data, size); btf->data_size = size; err = btf_parse_hdr(btf); if (err) goto done; err = btf_parse_str_sec(btf); if (err) goto done; err = btf_parse_type_sec(btf); done: if (err) { btf__free(btf); return ERR_PTR(err); } return btf; } static bool btf_check_endianness(const GElf_Ehdr *ehdr) { #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ return ehdr->e_ident[EI_DATA] == ELFDATA2LSB; #elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ return ehdr->e_ident[EI_DATA] == ELFDATA2MSB; #else # error "Unrecognized __BYTE_ORDER__" #endif } struct btf *btf__parse_elf(const char *path, struct btf_ext **btf_ext) { Elf_Data *btf_data = NULL, *btf_ext_data = NULL; int err = 0, fd = -1, idx = 0; struct btf *btf = NULL; Elf_Scn *scn = NULL; Elf *elf = NULL; GElf_Ehdr ehdr; if (elf_version(EV_CURRENT) == EV_NONE) { pr_warning("failed to init libelf for %s\n", path); return ERR_PTR(-LIBBPF_ERRNO__LIBELF); } fd = open(path, O_RDONLY); if (fd < 0) { err = -errno; pr_warning("failed to open %s: %s\n", path, strerror(errno)); return ERR_PTR(err); } err = -LIBBPF_ERRNO__FORMAT; elf = elf_begin(fd, ELF_C_READ, NULL); if (!elf) { pr_warning("failed to open %s as ELF file\n", path); goto done; } if (!gelf_getehdr(elf, &ehdr)) { pr_warning("failed to get EHDR from %s\n", path); goto done; } if (!btf_check_endianness(&ehdr)) { pr_warning("non-native ELF endianness is not supported\n"); goto done; } if (!elf_rawdata(elf_getscn(elf, ehdr.e_shstrndx), NULL)) { pr_warning("failed to get e_shstrndx from %s\n", path); goto done; } while ((scn = elf_nextscn(elf, scn)) != NULL) { GElf_Shdr sh; char *name; idx++; if (gelf_getshdr(scn, &sh) != &sh) { pr_warning("failed to get section(%d) header from %s\n", idx, path); goto done; } name = elf_strptr(elf, ehdr.e_shstrndx, sh.sh_name); if (!name) { pr_warning("failed to get section(%d) name from %s\n", idx, path); goto done; } if (strcmp(name, BTF_ELF_SEC) == 0) { btf_data = elf_getdata(scn, 0); if (!btf_data) { pr_warning("failed to get section(%d, %s) data from %s\n", idx, name, path); goto done; } continue; } else if (btf_ext && strcmp(name, BTF_EXT_ELF_SEC) == 0) { btf_ext_data = elf_getdata(scn, 0); if (!btf_ext_data) { pr_warning("failed to get section(%d, %s) data from %s\n", idx, name, path); goto done; } continue; } } err = 0; if (!btf_data) { err = -ENOENT; goto done; } btf = btf__new(btf_data->d_buf, btf_data->d_size); if (IS_ERR(btf)) goto done; if (btf_ext && btf_ext_data) { *btf_ext = btf_ext__new(btf_ext_data->d_buf, btf_ext_data->d_size); if (IS_ERR(*btf_ext)) goto done; } else if (btf_ext) { *btf_ext = NULL; } done: if (elf) elf_end(elf); close(fd); if (err) return ERR_PTR(err); /* * btf is always parsed before btf_ext, so no need to clean up * btf_ext, if btf loading failed */ if (IS_ERR(btf)) return btf; if (btf_ext && IS_ERR(*btf_ext)) { btf__free(btf); err = PTR_ERR(*btf_ext); return ERR_PTR(err); } return btf; } static int compare_vsi_off(const void *_a, const void *_b) { const struct btf_var_secinfo *a = _a; const struct btf_var_secinfo *b = _b; return a->offset - b->offset; } static int btf_fixup_datasec(struct bpf_object *obj, struct btf *btf, struct btf_type *t) { __u32 size = 0, off = 0, i, vars = btf_vlen(t); const char *name = btf__name_by_offset(btf, t->name_off); const struct btf_type *t_var; struct btf_var_secinfo *vsi; const struct btf_var *var; int ret; if (!name) { pr_debug("No name found in string section for DATASEC kind.\n"); return -ENOENT; } ret = bpf_object__section_size(obj, name, &size); if (ret || !size || (t->size && t->size != size)) { pr_debug("Invalid size for section %s: %u bytes\n", name, size); return -ENOENT; } t->size = size; for (i = 0, vsi = btf_var_secinfos(t); i < vars; i++, vsi++) { t_var = btf__type_by_id(btf, vsi->type); var = btf_var(t_var); if (!btf_is_var(t_var)) { pr_debug("Non-VAR type seen in section %s\n", name); return -EINVAL; } if (var->linkage == BTF_VAR_STATIC) continue; name = btf__name_by_offset(btf, t_var->name_off); if (!name) { pr_debug("No name found in string section for VAR kind\n"); return -ENOENT; } ret = bpf_object__variable_offset(obj, name, &off); if (ret) { pr_debug("No offset found in symbol table for VAR %s\n", name); return -ENOENT; } vsi->offset = off; } qsort(t + 1, vars, sizeof(*vsi), compare_vsi_off); return 0; } int btf__finalize_data(struct bpf_object *obj, struct btf *btf) { int err = 0; __u32 i; for (i = 1; i <= btf->nr_types; i++) { struct btf_type *t = btf->types[i]; /* Loader needs to fix up some of the things compiler * couldn't get its hands on while emitting BTF. This * is section size and global variable offset. We use * the info from the ELF itself for this purpose. */ if (btf_is_datasec(t)) { err = btf_fixup_datasec(obj, btf, t); if (err) break; } } return err; } int btf__load(struct btf *btf) { __u32 log_buf_size = BPF_LOG_BUF_SIZE; char *log_buf = NULL; int err = 0; if (btf->fd >= 0) return -EEXIST; log_buf = malloc(log_buf_size); if (!log_buf) return -ENOMEM; *log_buf = 0; btf->fd = bpf_load_btf(btf->data, btf->data_size, log_buf, log_buf_size, false); if (btf->fd < 0) { err = -errno; pr_warning("Error loading BTF: %s(%d)\n", strerror(errno), errno); if (*log_buf) pr_warning("%s\n", log_buf); goto done; } done: free(log_buf); return err; } int btf__fd(const struct btf *btf) { return btf->fd; } const void *btf__get_raw_data(const struct btf *btf, __u32 *size) { *size = btf->data_size; return btf->data; } const char *btf__name_by_offset(const struct btf *btf, __u32 offset) { if (offset < btf->hdr->str_len) return &btf->strings[offset]; else return NULL; } int btf__get_from_id(__u32 id, struct btf **btf) { struct bpf_btf_info btf_info = { 0 }; __u32 len = sizeof(btf_info); __u32 last_size; int btf_fd; void *ptr; int err; err = 0; *btf = NULL; btf_fd = bpf_btf_get_fd_by_id(id); if (btf_fd < 0) return 0; /* we won't know btf_size until we call bpf_obj_get_info_by_fd(). so * let's start with a sane default - 4KiB here - and resize it only if * bpf_obj_get_info_by_fd() needs a bigger buffer. */ btf_info.btf_size = 4096; last_size = btf_info.btf_size; ptr = malloc(last_size); if (!ptr) { err = -ENOMEM; goto exit_free; } memset(ptr, 0, last_size); btf_info.btf = ptr_to_u64(ptr); err = bpf_obj_get_info_by_fd(btf_fd, &btf_info, &len); if (!err && btf_info.btf_size > last_size) { void *temp_ptr; last_size = btf_info.btf_size; temp_ptr = realloc(ptr, last_size); if (!temp_ptr) { err = -ENOMEM; goto exit_free; } ptr = temp_ptr; memset(ptr, 0, last_size); btf_info.btf = ptr_to_u64(ptr); err = bpf_obj_get_info_by_fd(btf_fd, &btf_info, &len); } if (err || btf_info.btf_size > last_size) { err = errno; goto exit_free; } *btf = btf__new((__u8 *)(long)btf_info.btf, btf_info.btf_size); if (IS_ERR(*btf)) { err = PTR_ERR(*btf); *btf = NULL; } exit_free: close(btf_fd); free(ptr); return err; } int btf__get_map_kv_tids(const struct btf *btf, const char *map_name, __u32 expected_key_size, __u32 expected_value_size, __u32 *key_type_id, __u32 *value_type_id) { const struct btf_type *container_type; const struct btf_member *key, *value; const size_t max_name = 256; char container_name[max_name]; __s64 key_size, value_size; __s32 container_id; if (snprintf(container_name, max_name, "____btf_map_%s", map_name) == max_name) { pr_warning("map:%s length of '____btf_map_%s' is too long\n", map_name, map_name); return -EINVAL; } container_id = btf__find_by_name(btf, container_name); if (container_id < 0) { pr_debug("map:%s container_name:%s cannot be found in BTF. Missing BPF_ANNOTATE_KV_PAIR?\n", map_name, container_name); return container_id; } container_type = btf__type_by_id(btf, container_id); if (!container_type) { pr_warning("map:%s cannot find BTF type for container_id:%u\n", map_name, container_id); return -EINVAL; } if (!btf_is_struct(container_type) || btf_vlen(container_type) < 2) { pr_warning("map:%s container_name:%s is an invalid container struct\n", map_name, container_name); return -EINVAL; } key = btf_members(container_type); value = key + 1; key_size = btf__resolve_size(btf, key->type); if (key_size < 0) { pr_warning("map:%s invalid BTF key_type_size\n", map_name); return key_size; } if (expected_key_size != key_size) { pr_warning("map:%s btf_key_type_size:%u != map_def_key_size:%u\n", map_name, (__u32)key_size, expected_key_size); return -EINVAL; } value_size = btf__resolve_size(btf, value->type); if (value_size < 0) { pr_warning("map:%s invalid BTF value_type_size\n", map_name); return value_size; } if (expected_value_size != value_size) { pr_warning("map:%s btf_value_type_size:%u != map_def_value_size:%u\n", map_name, (__u32)value_size, expected_value_size); return -EINVAL; } *key_type_id = key->type; *value_type_id = value->type; return 0; } struct btf_ext_sec_setup_param { __u32 off; __u32 len; __u32 min_rec_size; struct btf_ext_info *ext_info; const char *desc; }; static int btf_ext_setup_info(struct btf_ext *btf_ext, struct btf_ext_sec_setup_param *ext_sec) { const struct btf_ext_info_sec *sinfo; struct btf_ext_info *ext_info; __u32 info_left, record_size; /* The start of the info sec (including the __u32 record_size). */ void *info; if (ext_sec->len == 0) return 0; if (ext_sec->off & 0x03) { pr_debug(".BTF.ext %s section is not aligned to 4 bytes\n", ext_sec->desc); return -EINVAL; } info = btf_ext->data + btf_ext->hdr->hdr_len + ext_sec->off; info_left = ext_sec->len; if (btf_ext->data + btf_ext->data_size < info + ext_sec->len) { pr_debug("%s section (off:%u len:%u) is beyond the end of the ELF section .BTF.ext\n", ext_sec->desc, ext_sec->off, ext_sec->len); return -EINVAL; } /* At least a record size */ if (info_left < sizeof(__u32)) { pr_debug(".BTF.ext %s record size not found\n", ext_sec->desc); return -EINVAL; } /* The record size needs to meet the minimum standard */ record_size = *(__u32 *)info; if (record_size < ext_sec->min_rec_size || record_size & 0x03) { pr_debug("%s section in .BTF.ext has invalid record size %u\n", ext_sec->desc, record_size); return -EINVAL; } sinfo = info + sizeof(__u32); info_left -= sizeof(__u32); /* If no records, return failure now so .BTF.ext won't be used. */ if (!info_left) { pr_debug("%s section in .BTF.ext has no records", ext_sec->desc); return -EINVAL; } while (info_left) { unsigned int sec_hdrlen = sizeof(struct btf_ext_info_sec); __u64 total_record_size; __u32 num_records; if (info_left < sec_hdrlen) { pr_debug("%s section header is not found in .BTF.ext\n", ext_sec->desc); return -EINVAL; } num_records = sinfo->num_info; if (num_records == 0) { pr_debug("%s section has incorrect num_records in .BTF.ext\n", ext_sec->desc); return -EINVAL; } total_record_size = sec_hdrlen + (__u64)num_records * record_size; if (info_left < total_record_size) { pr_debug("%s section has incorrect num_records in .BTF.ext\n", ext_sec->desc); return -EINVAL; } info_left -= total_record_size; sinfo = (void *)sinfo + total_record_size; } ext_info = ext_sec->ext_info; ext_info->len = ext_sec->len - sizeof(__u32); ext_info->rec_size = record_size; ext_info->info = info + sizeof(__u32); return 0; } static int btf_ext_setup_func_info(struct btf_ext *btf_ext) { struct btf_ext_sec_setup_param param = { .off = btf_ext->hdr->func_info_off, .len = btf_ext->hdr->func_info_len, .min_rec_size = sizeof(struct bpf_func_info_min), .ext_info = &btf_ext->func_info, .desc = "func_info" }; return btf_ext_setup_info(btf_ext, ¶m); } static int btf_ext_setup_line_info(struct btf_ext *btf_ext) { struct btf_ext_sec_setup_param param = { .off = btf_ext->hdr->line_info_off, .len = btf_ext->hdr->line_info_len, .min_rec_size = sizeof(struct bpf_line_info_min), .ext_info = &btf_ext->line_info, .desc = "line_info", }; return btf_ext_setup_info(btf_ext, ¶m); } static int btf_ext_setup_offset_reloc(struct btf_ext *btf_ext) { struct btf_ext_sec_setup_param param = { .off = btf_ext->hdr->offset_reloc_off, .len = btf_ext->hdr->offset_reloc_len, .min_rec_size = sizeof(struct bpf_offset_reloc), .ext_info = &btf_ext->offset_reloc_info, .desc = "offset_reloc", }; return btf_ext_setup_info(btf_ext, ¶m); } static int btf_ext_parse_hdr(__u8 *data, __u32 data_size) { const struct btf_ext_header *hdr = (struct btf_ext_header *)data; if (data_size < offsetofend(struct btf_ext_header, hdr_len) || data_size < hdr->hdr_len) { pr_debug("BTF.ext header not found"); return -EINVAL; } if (hdr->magic != BTF_MAGIC) { pr_debug("Invalid BTF.ext magic:%x\n", hdr->magic); return -EINVAL; } if (hdr->version != BTF_VERSION) { pr_debug("Unsupported BTF.ext version:%u\n", hdr->version); return -ENOTSUP; } if (hdr->flags) { pr_debug("Unsupported BTF.ext flags:%x\n", hdr->flags); return -ENOTSUP; } if (data_size == hdr->hdr_len) { pr_debug("BTF.ext has no data\n"); return -EINVAL; } return 0; } void btf_ext__free(struct btf_ext *btf_ext) { if (!btf_ext) return; free(btf_ext->data); free(btf_ext); } struct btf_ext *btf_ext__new(__u8 *data, __u32 size) { struct btf_ext *btf_ext; int err; err = btf_ext_parse_hdr(data, size); if (err) return ERR_PTR(err); btf_ext = calloc(1, sizeof(struct btf_ext)); if (!btf_ext) return ERR_PTR(-ENOMEM); btf_ext->data_size = size; btf_ext->data = malloc(size); if (!btf_ext->data) { err = -ENOMEM; goto done; } memcpy(btf_ext->data, data, size); if (btf_ext->hdr->hdr_len < offsetofend(struct btf_ext_header, line_info_len)) goto done; err = btf_ext_setup_func_info(btf_ext); if (err) goto done; err = btf_ext_setup_line_info(btf_ext); if (err) goto done; if (btf_ext->hdr->hdr_len < offsetofend(struct btf_ext_header, offset_reloc_len)) goto done; err = btf_ext_setup_offset_reloc(btf_ext); if (err) goto done; done: if (err) { btf_ext__free(btf_ext); return ERR_PTR(err); } return btf_ext; } const void *btf_ext__get_raw_data(const struct btf_ext *btf_ext, __u32 *size) { *size = btf_ext->data_size; return btf_ext->data; } static int btf_ext_reloc_info(const struct btf *btf, const struct btf_ext_info *ext_info, const char *sec_name, __u32 insns_cnt, void **info, __u32 *cnt) { __u32 sec_hdrlen = sizeof(struct btf_ext_info_sec); __u32 i, record_size, existing_len, records_len; struct btf_ext_info_sec *sinfo; const char *info_sec_name; __u64 remain_len; void *data; record_size = ext_info->rec_size; sinfo = ext_info->info; remain_len = ext_info->len; while (remain_len > 0) { records_len = sinfo->num_info * record_size; info_sec_name = btf__name_by_offset(btf, sinfo->sec_name_off); if (strcmp(info_sec_name, sec_name)) { remain_len -= sec_hdrlen + records_len; sinfo = (void *)sinfo + sec_hdrlen + records_len; continue; } existing_len = (*cnt) * record_size; data = realloc(*info, existing_len + records_len); if (!data) return -ENOMEM; memcpy(data + existing_len, sinfo->data, records_len); /* adjust insn_off only, the rest data will be passed * to the kernel. */ for (i = 0; i < sinfo->num_info; i++) { __u32 *insn_off; insn_off = data + existing_len + (i * record_size); *insn_off = *insn_off / sizeof(struct bpf_insn) + insns_cnt; } *info = data; *cnt += sinfo->num_info; return 0; } return -ENOENT; } int btf_ext__reloc_func_info(const struct btf *btf, const struct btf_ext *btf_ext, const char *sec_name, __u32 insns_cnt, void **func_info, __u32 *cnt) { return btf_ext_reloc_info(btf, &btf_ext->func_info, sec_name, insns_cnt, func_info, cnt); } int btf_ext__reloc_line_info(const struct btf *btf, const struct btf_ext *btf_ext, const char *sec_name, __u32 insns_cnt, void **line_info, __u32 *cnt) { return btf_ext_reloc_info(btf, &btf_ext->line_info, sec_name, insns_cnt, line_info, cnt); } __u32 btf_ext__func_info_rec_size(const struct btf_ext *btf_ext) { return btf_ext->func_info.rec_size; } __u32 btf_ext__line_info_rec_size(const struct btf_ext *btf_ext) { return btf_ext->line_info.rec_size; } struct btf_dedup; static struct btf_dedup *btf_dedup_new(struct btf *btf, struct btf_ext *btf_ext, const struct btf_dedup_opts *opts); static void btf_dedup_free(struct btf_dedup *d); static int btf_dedup_strings(struct btf_dedup *d); static int btf_dedup_prim_types(struct btf_dedup *d); static int btf_dedup_struct_types(struct btf_dedup *d); static int btf_dedup_ref_types(struct btf_dedup *d); static int btf_dedup_compact_types(struct btf_dedup *d); static int btf_dedup_remap_types(struct btf_dedup *d); /* * Deduplicate BTF types and strings. * * BTF dedup algorithm takes as an input `struct btf` representing `.BTF` ELF * section with all BTF type descriptors and string data. It overwrites that * memory in-place with deduplicated types and strings without any loss of * information. If optional `struct btf_ext` representing '.BTF.ext' ELF section * is provided, all the strings referenced from .BTF.ext section are honored * and updated to point to the right offsets after deduplication. * * If function returns with error, type/string data might be garbled and should * be discarded. * * More verbose and detailed description of both problem btf_dedup is solving, * as well as solution could be found at: * https://facebookmicrosites.github.io/bpf/blog/2018/11/14/btf-enhancement.html * * Problem description and justification * ===================================== * * BTF type information is typically emitted either as a result of conversion * from DWARF to BTF or directly by compiler. In both cases, each compilation * unit contains information about a subset of all the types that are used * in an application. These subsets are frequently overlapping and contain a lot * of duplicated information when later concatenated together into a single * binary. This algorithm ensures that each unique type is represented by single * BTF type descriptor, greatly reducing resulting size of BTF data. * * Compilation unit isolation and subsequent duplication of data is not the only * problem. The same type hierarchy (e.g., struct and all the type that struct * references) in different compilation units can be represented in BTF to * various degrees of completeness (or, rather, incompleteness) due to * struct/union forward declarations. * * Let's take a look at an example, that we'll use to better understand the * problem (and solution). Suppose we have two compilation units, each using * same `struct S`, but each of them having incomplete type information about * struct's fields: * * // CU #1: * struct S; * struct A { * int a; * struct A* self; * struct S* parent; * }; * struct B; * struct S { * struct A* a_ptr; * struct B* b_ptr; * }; * * // CU #2: * struct S; * struct A; * struct B { * int b; * struct B* self; * struct S* parent; * }; * struct S { * struct A* a_ptr; * struct B* b_ptr; * }; * * In case of CU #1, BTF data will know only that `struct B` exist (but no * more), but will know the complete type information about `struct A`. While * for CU #2, it will know full type information about `struct B`, but will * only know about forward declaration of `struct A` (in BTF terms, it will * have `BTF_KIND_FWD` type descriptor with name `B`). * * This compilation unit isolation means that it's possible that there is no * single CU with complete type information describing structs `S`, `A`, and * `B`. Also, we might get tons of duplicated and redundant type information. * * Additional complication we need to keep in mind comes from the fact that * types, in general, can form graphs containing cycles, not just DAGs. * * While algorithm does deduplication, it also merges and resolves type * information (unless disabled throught `struct btf_opts`), whenever possible. * E.g., in the example above with two compilation units having partial type * information for structs `A` and `B`, the output of algorithm will emit * a single copy of each BTF type that describes structs `A`, `B`, and `S` * (as well as type information for `int` and pointers), as if they were defined * in a single compilation unit as: * * struct A { * int a; * struct A* self; * struct S* parent; * }; * struct B { * int b; * struct B* self; * struct S* parent; * }; * struct S { * struct A* a_ptr; * struct B* b_ptr; * }; * * Algorithm summary * ================= * * Algorithm completes its work in 6 separate passes: * * 1. Strings deduplication. * 2. Primitive types deduplication (int, enum, fwd). * 3. Struct/union types deduplication. * 4. Reference types deduplication (pointers, typedefs, arrays, funcs, func * protos, and const/volatile/restrict modifiers). * 5. Types compaction. * 6. Types remapping. * * Algorithm determines canonical type descriptor, which is a single * representative type for each truly unique type. This canonical type is the * one that will go into final deduplicated BTF type information. For * struct/unions, it is also the type that algorithm will merge additional type * information into (while resolving FWDs), as it discovers it from data in * other CUs. Each input BTF type eventually gets either mapped to itself, if * that type is canonical, or to some other type, if that type is equivalent * and was chosen as canonical representative. This mapping is stored in * `btf_dedup->map` array. This map is also used to record STRUCT/UNION that * FWD type got resolved to. * * To facilitate fast discovery of canonical types, we also maintain canonical * index (`btf_dedup->dedup_table`), which maps type descriptor's signature hash * (i.e., hashed kind, name, size, fields, etc) into a list of canonical types * that match that signature. With sufficiently good choice of type signature * hashing function, we can limit number of canonical types for each unique type * signature to a very small number, allowing to find canonical type for any * duplicated type very quickly. * * Struct/union deduplication is the most critical part and algorithm for * deduplicating structs/unions is described in greater details in comments for * `btf_dedup_is_equiv` function. */ int btf__dedup(struct btf *btf, struct btf_ext *btf_ext, const struct btf_dedup_opts *opts) { struct btf_dedup *d = btf_dedup_new(btf, btf_ext, opts); int err; if (IS_ERR(d)) { pr_debug("btf_dedup_new failed: %ld", PTR_ERR(d)); return -EINVAL; } err = btf_dedup_strings(d); if (err < 0) { pr_debug("btf_dedup_strings failed:%d\n", err); goto done; } err = btf_dedup_prim_types(d); if (err < 0) { pr_debug("btf_dedup_prim_types failed:%d\n", err); goto done; } err = btf_dedup_struct_types(d); if (err < 0) { pr_debug("btf_dedup_struct_types failed:%d\n", err); goto done; } err = btf_dedup_ref_types(d); if (err < 0) { pr_debug("btf_dedup_ref_types failed:%d\n", err); goto done; } err = btf_dedup_compact_types(d); if (err < 0) { pr_debug("btf_dedup_compact_types failed:%d\n", err); goto done; } err = btf_dedup_remap_types(d); if (err < 0) { pr_debug("btf_dedup_remap_types failed:%d\n", err); goto done; } done: btf_dedup_free(d); return err; } #define BTF_UNPROCESSED_ID ((__u32)-1) #define BTF_IN_PROGRESS_ID ((__u32)-2) struct btf_dedup { /* .BTF section to be deduped in-place */ struct btf *btf; /* * Optional .BTF.ext section. When provided, any strings referenced * from it will be taken into account when deduping strings */ struct btf_ext *btf_ext; /* * This is a map from any type's signature hash to a list of possible * canonical representative type candidates. Hash collisions are * ignored, so even types of various kinds can share same list of * candidates, which is fine because we rely on subsequent * btf_xxx_equal() checks to authoritatively verify type equality. */ struct hashmap *dedup_table; /* Canonical types map */ __u32 *map; /* Hypothetical mapping, used during type graph equivalence checks */ __u32 *hypot_map; __u32 *hypot_list; size_t hypot_cnt; size_t hypot_cap; /* Various option modifying behavior of algorithm */ struct btf_dedup_opts opts; }; struct btf_str_ptr { const char *str; __u32 new_off; bool used; }; struct btf_str_ptrs { struct btf_str_ptr *ptrs; const char *data; __u32 cnt; __u32 cap; }; static long hash_combine(long h, long value) { return h * 31 + value; } #define for_each_dedup_cand(d, node, hash) \ hashmap__for_each_key_entry(d->dedup_table, node, (void *)hash) static int btf_dedup_table_add(struct btf_dedup *d, long hash, __u32 type_id) { return hashmap__append(d->dedup_table, (void *)hash, (void *)(long)type_id); } static int btf_dedup_hypot_map_add(struct btf_dedup *d, __u32 from_id, __u32 to_id) { if (d->hypot_cnt == d->hypot_cap) { __u32 *new_list; d->hypot_cap += max(16, d->hypot_cap / 2); new_list = realloc(d->hypot_list, sizeof(__u32) * d->hypot_cap); if (!new_list) return -ENOMEM; d->hypot_list = new_list; } d->hypot_list[d->hypot_cnt++] = from_id; d->hypot_map[from_id] = to_id; return 0; } static void btf_dedup_clear_hypot_map(struct btf_dedup *d) { int i; for (i = 0; i < d->hypot_cnt; i++) d->hypot_map[d->hypot_list[i]] = BTF_UNPROCESSED_ID; d->hypot_cnt = 0; } static void btf_dedup_free(struct btf_dedup *d) { hashmap__free(d->dedup_table); d->dedup_table = NULL; free(d->map); d->map = NULL; free(d->hypot_map); d->hypot_map = NULL; free(d->hypot_list); d->hypot_list = NULL; free(d); } static size_t btf_dedup_identity_hash_fn(const void *key, void *ctx) { return (size_t)key; } static size_t btf_dedup_collision_hash_fn(const void *key, void *ctx) { return 0; } static bool btf_dedup_equal_fn(const void *k1, const void *k2, void *ctx) { return k1 == k2; } static struct btf_dedup *btf_dedup_new(struct btf *btf, struct btf_ext *btf_ext, const struct btf_dedup_opts *opts) { struct btf_dedup *d = calloc(1, sizeof(struct btf_dedup)); hashmap_hash_fn hash_fn = btf_dedup_identity_hash_fn; int i, err = 0; if (!d) return ERR_PTR(-ENOMEM); d->opts.dont_resolve_fwds = opts && opts->dont_resolve_fwds; /* dedup_table_size is now used only to force collisions in tests */ if (opts && opts->dedup_table_size == 1) hash_fn = btf_dedup_collision_hash_fn; d->btf = btf; d->btf_ext = btf_ext; d->dedup_table = hashmap__new(hash_fn, btf_dedup_equal_fn, NULL); if (IS_ERR(d->dedup_table)) { err = PTR_ERR(d->dedup_table); d->dedup_table = NULL; goto done; } d->map = malloc(sizeof(__u32) * (1 + btf->nr_types)); if (!d->map) { err = -ENOMEM; goto done; } /* special BTF "void" type is made canonical immediately */ d->map[0] = 0; for (i = 1; i <= btf->nr_types; i++) { struct btf_type *t = d->btf->types[i]; /* VAR and DATASEC are never deduped and are self-canonical */ if (btf_is_var(t) || btf_is_datasec(t)) d->map[i] = i; else d->map[i] = BTF_UNPROCESSED_ID; } d->hypot_map = malloc(sizeof(__u32) * (1 + btf->nr_types)); if (!d->hypot_map) { err = -ENOMEM; goto done; } for (i = 0; i <= btf->nr_types; i++) d->hypot_map[i] = BTF_UNPROCESSED_ID; done: if (err) { btf_dedup_free(d); return ERR_PTR(err); } return d; } typedef int (*str_off_fn_t)(__u32 *str_off_ptr, void *ctx); /* * Iterate over all possible places in .BTF and .BTF.ext that can reference * string and pass pointer to it to a provided callback `fn`. */ static int btf_for_each_str_off(struct btf_dedup *d, str_off_fn_t fn, void *ctx) { void *line_data_cur, *line_data_end; int i, j, r, rec_size; struct btf_type *t; for (i = 1; i <= d->btf->nr_types; i++) { t = d->btf->types[i]; r = fn(&t->name_off, ctx); if (r) return r; switch (btf_kind(t)) { case BTF_KIND_STRUCT: case BTF_KIND_UNION: { struct btf_member *m = btf_members(t); __u16 vlen = btf_vlen(t); for (j = 0; j < vlen; j++) { r = fn(&m->name_off, ctx); if (r) return r; m++; } break; } case BTF_KIND_ENUM: { struct btf_enum *m = btf_enum(t); __u16 vlen = btf_vlen(t); for (j = 0; j < vlen; j++) { r = fn(&m->name_off, ctx); if (r) return r; m++; } break; } case BTF_KIND_FUNC_PROTO: { struct btf_param *m = btf_params(t); __u16 vlen = btf_vlen(t); for (j = 0; j < vlen; j++) { r = fn(&m->name_off, ctx); if (r) return r; m++; } break; } default: break; } } if (!d->btf_ext) return 0; line_data_cur = d->btf_ext->line_info.info; line_data_end = d->btf_ext->line_info.info + d->btf_ext->line_info.len; rec_size = d->btf_ext->line_info.rec_size; while (line_data_cur < line_data_end) { struct btf_ext_info_sec *sec = line_data_cur; struct bpf_line_info_min *line_info; __u32 num_info = sec->num_info; r = fn(&sec->sec_name_off, ctx); if (r) return r; line_data_cur += sizeof(struct btf_ext_info_sec); for (i = 0; i < num_info; i++) { line_info = line_data_cur; r = fn(&line_info->file_name_off, ctx); if (r) return r; r = fn(&line_info->line_off, ctx); if (r) return r; line_data_cur += rec_size; } } return 0; } static int str_sort_by_content(const void *a1, const void *a2) { const struct btf_str_ptr *p1 = a1; const struct btf_str_ptr *p2 = a2; return strcmp(p1->str, p2->str); } static int str_sort_by_offset(const void *a1, const void *a2) { const struct btf_str_ptr *p1 = a1; const struct btf_str_ptr *p2 = a2; if (p1->str != p2->str) return p1->str < p2->str ? -1 : 1; return 0; } static int btf_dedup_str_ptr_cmp(const void *str_ptr, const void *pelem) { const struct btf_str_ptr *p = pelem; if (str_ptr != p->str) return (const char *)str_ptr < p->str ? -1 : 1; return 0; } static int btf_str_mark_as_used(__u32 *str_off_ptr, void *ctx) { struct btf_str_ptrs *strs; struct btf_str_ptr *s; if (*str_off_ptr == 0) return 0; strs = ctx; s = bsearch(strs->data + *str_off_ptr, strs->ptrs, strs->cnt, sizeof(struct btf_str_ptr), btf_dedup_str_ptr_cmp); if (!s) return -EINVAL; s->used = true; return 0; } static int btf_str_remap_offset(__u32 *str_off_ptr, void *ctx) { struct btf_str_ptrs *strs; struct btf_str_ptr *s; if (*str_off_ptr == 0) return 0; strs = ctx; s = bsearch(strs->data + *str_off_ptr, strs->ptrs, strs->cnt, sizeof(struct btf_str_ptr), btf_dedup_str_ptr_cmp); if (!s) return -EINVAL; *str_off_ptr = s->new_off; return 0; } /* * Dedup string and filter out those that are not referenced from either .BTF * or .BTF.ext (if provided) sections. * * This is done by building index of all strings in BTF's string section, * then iterating over all entities that can reference strings (e.g., type * names, struct field names, .BTF.ext line info, etc) and marking corresponding * strings as used. After that all used strings are deduped and compacted into * sequential blob of memory and new offsets are calculated. Then all the string * references are iterated again and rewritten using new offsets. */ static int btf_dedup_strings(struct btf_dedup *d) { const struct btf_header *hdr = d->btf->hdr; char *start = (char *)d->btf->nohdr_data + hdr->str_off; char *end = start + d->btf->hdr->str_len; char *p = start, *tmp_strs = NULL; struct btf_str_ptrs strs = { .cnt = 0, .cap = 0, .ptrs = NULL, .data = start, }; int i, j, err = 0, grp_idx; bool grp_used; /* build index of all strings */ while (p < end) { if (strs.cnt + 1 > strs.cap) { struct btf_str_ptr *new_ptrs; strs.cap += max(strs.cnt / 2, 16); new_ptrs = realloc(strs.ptrs, sizeof(strs.ptrs[0]) * strs.cap); if (!new_ptrs) { err = -ENOMEM; goto done; } strs.ptrs = new_ptrs; } strs.ptrs[strs.cnt].str = p; strs.ptrs[strs.cnt].used = false; p += strlen(p) + 1; strs.cnt++; } /* temporary storage for deduplicated strings */ tmp_strs = malloc(d->btf->hdr->str_len); if (!tmp_strs) { err = -ENOMEM; goto done; } /* mark all used strings */ strs.ptrs[0].used = true; err = btf_for_each_str_off(d, btf_str_mark_as_used, &strs); if (err) goto done; /* sort strings by context, so that we can identify duplicates */ qsort(strs.ptrs, strs.cnt, sizeof(strs.ptrs[0]), str_sort_by_content); /* * iterate groups of equal strings and if any instance in a group was * referenced, emit single instance and remember new offset */ p = tmp_strs; grp_idx = 0; grp_used = strs.ptrs[0].used; /* iterate past end to avoid code duplication after loop */ for (i = 1; i <= strs.cnt; i++) { /* * when i == strs.cnt, we want to skip string comparison and go * straight to handling last group of strings (otherwise we'd * need to handle last group after the loop w/ duplicated code) */ if (i < strs.cnt && !strcmp(strs.ptrs[i].str, strs.ptrs[grp_idx].str)) { grp_used = grp_used || strs.ptrs[i].used; continue; } /* * this check would have been required after the loop to handle * last group of strings, but due to <= condition in a loop * we avoid that duplication */ if (grp_used) { int new_off = p - tmp_strs; __u32 len = strlen(strs.ptrs[grp_idx].str); memmove(p, strs.ptrs[grp_idx].str, len + 1); for (j = grp_idx; j < i; j++) strs.ptrs[j].new_off = new_off; p += len + 1; } if (i < strs.cnt) { grp_idx = i; grp_used = strs.ptrs[i].used; } } /* replace original strings with deduped ones */ d->btf->hdr->str_len = p - tmp_strs; memmove(start, tmp_strs, d->btf->hdr->str_len); end = start + d->btf->hdr->str_len; /* restore original order for further binary search lookups */ qsort(strs.ptrs, strs.cnt, sizeof(strs.ptrs[0]), str_sort_by_offset); /* remap string offsets */ err = btf_for_each_str_off(d, btf_str_remap_offset, &strs); if (err) goto done; d->btf->hdr->str_len = end - start; done: free(tmp_strs); free(strs.ptrs); return err; } static long btf_hash_common(struct btf_type *t) { long h; h = hash_combine(0, t->name_off); h = hash_combine(h, t->info); h = hash_combine(h, t->size); return h; } static bool btf_equal_common(struct btf_type *t1, struct btf_type *t2) { return t1->name_off == t2->name_off && t1->info == t2->info && t1->size == t2->size; } /* Calculate type signature hash of INT. */ static long btf_hash_int(struct btf_type *t) { __u32 info = *(__u32 *)(t + 1); long h; h = btf_hash_common(t); h = hash_combine(h, info); return h; } /* Check structural equality of two INTs. */ static bool btf_equal_int(struct btf_type *t1, struct btf_type *t2) { __u32 info1, info2; if (!btf_equal_common(t1, t2)) return false; info1 = *(__u32 *)(t1 + 1); info2 = *(__u32 *)(t2 + 1); return info1 == info2; } /* Calculate type signature hash of ENUM. */ static long btf_hash_enum(struct btf_type *t) { long h; /* don't hash vlen and enum members to support enum fwd resolving */ h = hash_combine(0, t->name_off); h = hash_combine(h, t->info & ~0xffff); h = hash_combine(h, t->size); return h; } /* Check structural equality of two ENUMs. */ static bool btf_equal_enum(struct btf_type *t1, struct btf_type *t2) { const struct btf_enum *m1, *m2; __u16 vlen; int i; if (!btf_equal_common(t1, t2)) return false; vlen = btf_vlen(t1); m1 = btf_enum(t1); m2 = btf_enum(t2); for (i = 0; i < vlen; i++) { if (m1->name_off != m2->name_off || m1->val != m2->val) return false; m1++; m2++; } return true; } static inline bool btf_is_enum_fwd(struct btf_type *t) { return btf_is_enum(t) && btf_vlen(t) == 0; } static bool btf_compat_enum(struct btf_type *t1, struct btf_type *t2) { if (!btf_is_enum_fwd(t1) && !btf_is_enum_fwd(t2)) return btf_equal_enum(t1, t2); /* ignore vlen when comparing */ return t1->name_off == t2->name_off && (t1->info & ~0xffff) == (t2->info & ~0xffff) && t1->size == t2->size; } /* * Calculate type signature hash of STRUCT/UNION, ignoring referenced type IDs, * as referenced type IDs equivalence is established separately during type * graph equivalence check algorithm. */ static long btf_hash_struct(struct btf_type *t) { const struct btf_member *member = btf_members(t); __u32 vlen = btf_vlen(t); long h = btf_hash_common(t); int i; for (i = 0; i < vlen; i++) { h = hash_combine(h, member->name_off); h = hash_combine(h, member->offset); /* no hashing of referenced type ID, it can be unresolved yet */ member++; } return h; } /* * Check structural compatibility of two FUNC_PROTOs, ignoring referenced type * IDs. This check is performed during type graph equivalence check and * referenced types equivalence is checked separately. */ static bool btf_shallow_equal_struct(struct btf_type *t1, struct btf_type *t2) { const struct btf_member *m1, *m2; __u16 vlen; int i; if (!btf_equal_common(t1, t2)) return false; vlen = btf_vlen(t1); m1 = btf_members(t1); m2 = btf_members(t2); for (i = 0; i < vlen; i++) { if (m1->name_off != m2->name_off || m1->offset != m2->offset) return false; m1++; m2++; } return true; } /* * Calculate type signature hash of ARRAY, including referenced type IDs, * under assumption that they were already resolved to canonical type IDs and * are not going to change. */ static long btf_hash_array(struct btf_type *t) { const struct btf_array *info = btf_array(t); long h = btf_hash_common(t); h = hash_combine(h, info->type); h = hash_combine(h, info->index_type); h = hash_combine(h, info->nelems); return h; } /* * Check exact equality of two ARRAYs, taking into account referenced * type IDs, under assumption that they were already resolved to canonical * type IDs and are not going to change. * This function is called during reference types deduplication to compare * ARRAY to potential canonical representative. */ static bool btf_equal_array(struct btf_type *t1, struct btf_type *t2) { const struct btf_array *info1, *info2; if (!btf_equal_common(t1, t2)) return false; info1 = btf_array(t1); info2 = btf_array(t2); return info1->type == info2->type && info1->index_type == info2->index_type && info1->nelems == info2->nelems; } /* * Check structural compatibility of two ARRAYs, ignoring referenced type * IDs. This check is performed during type graph equivalence check and * referenced types equivalence is checked separately. */ static bool btf_compat_array(struct btf_type *t1, struct btf_type *t2) { if (!btf_equal_common(t1, t2)) return false; return btf_array(t1)->nelems == btf_array(t2)->nelems; } /* * Calculate type signature hash of FUNC_PROTO, including referenced type IDs, * under assumption that they were already resolved to canonical type IDs and * are not going to change. */ static long btf_hash_fnproto(struct btf_type *t) { const struct btf_param *member = btf_params(t); __u16 vlen = btf_vlen(t); long h = btf_hash_common(t); int i; for (i = 0; i < vlen; i++) { h = hash_combine(h, member->name_off); h = hash_combine(h, member->type); member++; } return h; } /* * Check exact equality of two FUNC_PROTOs, taking into account referenced * type IDs, under assumption that they were already resolved to canonical * type IDs and are not going to change. * This function is called during reference types deduplication to compare * FUNC_PROTO to potential canonical representative. */ static bool btf_equal_fnproto(struct btf_type *t1, struct btf_type *t2) { const struct btf_param *m1, *m2; __u16 vlen; int i; if (!btf_equal_common(t1, t2)) return false; vlen = btf_vlen(t1); m1 = btf_params(t1); m2 = btf_params(t2); for (i = 0; i < vlen; i++) { if (m1->name_off != m2->name_off || m1->type != m2->type) return false; m1++; m2++; } return true; } /* * Check structural compatibility of two FUNC_PROTOs, ignoring referenced type * IDs. This check is performed during type graph equivalence check and * referenced types equivalence is checked separately. */ static bool btf_compat_fnproto(struct btf_type *t1, struct btf_type *t2) { const struct btf_param *m1, *m2; __u16 vlen; int i; /* skip return type ID */ if (t1->name_off != t2->name_off || t1->info != t2->info) return false; vlen = btf_vlen(t1); m1 = btf_params(t1); m2 = btf_params(t2); for (i = 0; i < vlen; i++) { if (m1->name_off != m2->name_off) return false; m1++; m2++; } return true; } /* * Deduplicate primitive types, that can't reference other types, by calculating * their type signature hash and comparing them with any possible canonical * candidate. If no canonical candidate matches, type itself is marked as * canonical and is added into `btf_dedup->dedup_table` as another candidate. */ static int btf_dedup_prim_type(struct btf_dedup *d, __u32 type_id) { struct btf_type *t = d->btf->types[type_id]; struct hashmap_entry *hash_entry; struct btf_type *cand; /* if we don't find equivalent type, then we are canonical */ __u32 new_id = type_id; __u32 cand_id; long h; switch (btf_kind(t)) { case BTF_KIND_CONST: case BTF_KIND_VOLATILE: case BTF_KIND_RESTRICT: case BTF_KIND_PTR: case BTF_KIND_TYPEDEF: case BTF_KIND_ARRAY: case BTF_KIND_STRUCT: case BTF_KIND_UNION: case BTF_KIND_FUNC: case BTF_KIND_FUNC_PROTO: case BTF_KIND_VAR: case BTF_KIND_DATASEC: return 0; case BTF_KIND_INT: h = btf_hash_int(t); for_each_dedup_cand(d, hash_entry, h) { cand_id = (__u32)(long)hash_entry->value; cand = d->btf->types[cand_id]; if (btf_equal_int(t, cand)) { new_id = cand_id; break; } } break; case BTF_KIND_ENUM: h = btf_hash_enum(t); for_each_dedup_cand(d, hash_entry, h) { cand_id = (__u32)(long)hash_entry->value; cand = d->btf->types[cand_id]; if (btf_equal_enum(t, cand)) { new_id = cand_id; break; } if (d->opts.dont_resolve_fwds) continue; if (btf_compat_enum(t, cand)) { if (btf_is_enum_fwd(t)) { /* resolve fwd to full enum */ new_id = cand_id; break; } /* resolve canonical enum fwd to full enum */ d->map[cand_id] = type_id; } } break; case BTF_KIND_FWD: h = btf_hash_common(t); for_each_dedup_cand(d, hash_entry, h) { cand_id = (__u32)(long)hash_entry->value; cand = d->btf->types[cand_id]; if (btf_equal_common(t, cand)) { new_id = cand_id; break; } } break; default: return -EINVAL; } d->map[type_id] = new_id; if (type_id == new_id && btf_dedup_table_add(d, h, type_id)) return -ENOMEM; return 0; } static int btf_dedup_prim_types(struct btf_dedup *d) { int i, err; for (i = 1; i <= d->btf->nr_types; i++) { err = btf_dedup_prim_type(d, i); if (err) return err; } return 0; } /* * Check whether type is already mapped into canonical one (could be to itself). */ static inline bool is_type_mapped(struct btf_dedup *d, uint32_t type_id) { return d->map[type_id] <= BTF_MAX_NR_TYPES; } /* * Resolve type ID into its canonical type ID, if any; otherwise return original * type ID. If type is FWD and is resolved into STRUCT/UNION already, follow * STRUCT/UNION link and resolve it into canonical type ID as well. */ static inline __u32 resolve_type_id(struct btf_dedup *d, __u32 type_id) { while (is_type_mapped(d, type_id) && d->map[type_id] != type_id) type_id = d->map[type_id]; return type_id; } /* * Resolve FWD to underlying STRUCT/UNION, if any; otherwise return original * type ID. */ static uint32_t resolve_fwd_id(struct btf_dedup *d, uint32_t type_id) { __u32 orig_type_id = type_id; if (!btf_is_fwd(d->btf->types[type_id])) return type_id; while (is_type_mapped(d, type_id) && d->map[type_id] != type_id) type_id = d->map[type_id]; if (!btf_is_fwd(d->btf->types[type_id])) return type_id; return orig_type_id; } static inline __u16 btf_fwd_kind(struct btf_type *t) { return btf_kflag(t) ? BTF_KIND_UNION : BTF_KIND_STRUCT; } /* * Check equivalence of BTF type graph formed by candidate struct/union (we'll * call it "candidate graph" in this description for brevity) to a type graph * formed by (potential) canonical struct/union ("canonical graph" for brevity * here, though keep in mind that not all types in canonical graph are * necessarily canonical representatives themselves, some of them might be * duplicates or its uniqueness might not have been established yet). * Returns: * - >0, if type graphs are equivalent; * - 0, if not equivalent; * - <0, on error. * * Algorithm performs side-by-side DFS traversal of both type graphs and checks * equivalence of BTF types at each step. If at any point BTF types in candidate * and canonical graphs are not compatible structurally, whole graphs are * incompatible. If types are structurally equivalent (i.e., all information * except referenced type IDs is exactly the same), a mapping from `canon_id` to * a `cand_id` is recored in hypothetical mapping (`btf_dedup->hypot_map`). * If a type references other types, then those referenced types are checked * for equivalence recursively. * * During DFS traversal, if we find that for current `canon_id` type we * already have some mapping in hypothetical map, we check for two possible * situations: * - `canon_id` is mapped to exactly the same type as `cand_id`. This will * happen when type graphs have cycles. In this case we assume those two * types are equivalent. * - `canon_id` is mapped to different type. This is contradiction in our * hypothetical mapping, because same graph in canonical graph corresponds * to two different types in candidate graph, which for equivalent type * graphs shouldn't happen. This condition terminates equivalence check * with negative result. * * If type graphs traversal exhausts types to check and find no contradiction, * then type graphs are equivalent. * * When checking types for equivalence, there is one special case: FWD types. * If FWD type resolution is allowed and one of the types (either from canonical * or candidate graph) is FWD and other is STRUCT/UNION (depending on FWD's kind * flag) and their names match, hypothetical mapping is updated to point from * FWD to STRUCT/UNION. If graphs will be determined as equivalent successfully, * this mapping will be used to record FWD -> STRUCT/UNION mapping permanently. * * Technically, this could lead to incorrect FWD to STRUCT/UNION resolution, * if there are two exactly named (or anonymous) structs/unions that are * compatible structurally, one of which has FWD field, while other is concrete * STRUCT/UNION, but according to C sources they are different structs/unions * that are referencing different types with the same name. This is extremely * unlikely to happen, but btf_dedup API allows to disable FWD resolution if * this logic is causing problems. * * Doing FWD resolution means that both candidate and/or canonical graphs can * consists of portions of the graph that come from multiple compilation units. * This is due to the fact that types within single compilation unit are always * deduplicated and FWDs are already resolved, if referenced struct/union * definiton is available. So, if we had unresolved FWD and found corresponding * STRUCT/UNION, they will be from different compilation units. This * consequently means that when we "link" FWD to corresponding STRUCT/UNION, * type graph will likely have at least two different BTF types that describe * same type (e.g., most probably there will be two different BTF types for the * same 'int' primitive type) and could even have "overlapping" parts of type * graph that describe same subset of types. * * This in turn means that our assumption that each type in canonical graph * must correspond to exactly one type in candidate graph might not hold * anymore and will make it harder to detect contradictions using hypothetical * map. To handle this problem, we allow to follow FWD -> STRUCT/UNION * resolution only in canonical graph. FWDs in candidate graphs are never * resolved. To see why it's OK, let's check all possible situations w.r.t. FWDs * that can occur: * - Both types in canonical and candidate graphs are FWDs. If they are * structurally equivalent, then they can either be both resolved to the * same STRUCT/UNION or not resolved at all. In both cases they are * equivalent and there is no need to resolve FWD on candidate side. * - Both types in canonical and candidate graphs are concrete STRUCT/UNION, * so nothing to resolve as well, algorithm will check equivalence anyway. * - Type in canonical graph is FWD, while type in candidate is concrete * STRUCT/UNION. In this case candidate graph comes from single compilation * unit, so there is exactly one BTF type for each unique C type. After * resolving FWD into STRUCT/UNION, there might be more than one BTF type * in canonical graph mapping to single BTF type in candidate graph, but * because hypothetical mapping maps from canonical to candidate types, it's * alright, and we still maintain the property of having single `canon_id` * mapping to single `cand_id` (there could be two different `canon_id` * mapped to the same `cand_id`, but it's not contradictory). * - Type in canonical graph is concrete STRUCT/UNION, while type in candidate * graph is FWD. In this case we are just going to check compatibility of * STRUCT/UNION and corresponding FWD, and if they are compatible, we'll * assume that whatever STRUCT/UNION FWD resolves to must be equivalent to * a concrete STRUCT/UNION from canonical graph. If the rest of type graphs * turn out equivalent, we'll re-resolve FWD to concrete STRUCT/UNION from * canonical graph. */ static int btf_dedup_is_equiv(struct btf_dedup *d, __u32 cand_id, __u32 canon_id) { struct btf_type *cand_type; struct btf_type *canon_type; __u32 hypot_type_id; __u16 cand_kind; __u16 canon_kind; int i, eq; /* if both resolve to the same canonical, they must be equivalent */ if (resolve_type_id(d, cand_id) == resolve_type_id(d, canon_id)) return 1; canon_id = resolve_fwd_id(d, canon_id); hypot_type_id = d->hypot_map[canon_id]; if (hypot_type_id <= BTF_MAX_NR_TYPES) return hypot_type_id == cand_id; if (btf_dedup_hypot_map_add(d, canon_id, cand_id)) return -ENOMEM; cand_type = d->btf->types[cand_id]; canon_type = d->btf->types[canon_id]; cand_kind = btf_kind(cand_type); canon_kind = btf_kind(canon_type); if (cand_type->name_off != canon_type->name_off) return 0; /* FWD <--> STRUCT/UNION equivalence check, if enabled */ if (!d->opts.dont_resolve_fwds && (cand_kind == BTF_KIND_FWD || canon_kind == BTF_KIND_FWD) && cand_kind != canon_kind) { __u16 real_kind; __u16 fwd_kind; if (cand_kind == BTF_KIND_FWD) { real_kind = canon_kind; fwd_kind = btf_fwd_kind(cand_type); } else { real_kind = cand_kind; fwd_kind = btf_fwd_kind(canon_type); } return fwd_kind == real_kind; } if (cand_kind != canon_kind) return 0; switch (cand_kind) { case BTF_KIND_INT: return btf_equal_int(cand_type, canon_type); case BTF_KIND_ENUM: if (d->opts.dont_resolve_fwds) return btf_equal_enum(cand_type, canon_type); else return btf_compat_enum(cand_type, canon_type); case BTF_KIND_FWD: return btf_equal_common(cand_type, canon_type); case BTF_KIND_CONST: case BTF_KIND_VOLATILE: case BTF_KIND_RESTRICT: case BTF_KIND_PTR: case BTF_KIND_TYPEDEF: case BTF_KIND_FUNC: if (cand_type->info != canon_type->info) return 0; return btf_dedup_is_equiv(d, cand_type->type, canon_type->type); case BTF_KIND_ARRAY: { const struct btf_array *cand_arr, *canon_arr; if (!btf_compat_array(cand_type, canon_type)) return 0; cand_arr = btf_array(cand_type); canon_arr = btf_array(canon_type); eq = btf_dedup_is_equiv(d, cand_arr->index_type, canon_arr->index_type); if (eq <= 0) return eq; return btf_dedup_is_equiv(d, cand_arr->type, canon_arr->type); } case BTF_KIND_STRUCT: case BTF_KIND_UNION: { const struct btf_member *cand_m, *canon_m; __u16 vlen; if (!btf_shallow_equal_struct(cand_type, canon_type)) return 0; vlen = btf_vlen(cand_type); cand_m = btf_members(cand_type); canon_m = btf_members(canon_type); for (i = 0; i < vlen; i++) { eq = btf_dedup_is_equiv(d, cand_m->type, canon_m->type); if (eq <= 0) return eq; cand_m++; canon_m++; } return 1; } case BTF_KIND_FUNC_PROTO: { const struct btf_param *cand_p, *canon_p; __u16 vlen; if (!btf_compat_fnproto(cand_type, canon_type)) return 0; eq = btf_dedup_is_equiv(d, cand_type->type, canon_type->type); if (eq <= 0) return eq; vlen = btf_vlen(cand_type); cand_p = btf_params(cand_type); canon_p = btf_params(canon_type); for (i = 0; i < vlen; i++) { eq = btf_dedup_is_equiv(d, cand_p->type, canon_p->type); if (eq <= 0) return eq; cand_p++; canon_p++; } return 1; } default: return -EINVAL; } return 0; } /* * Use hypothetical mapping, produced by successful type graph equivalence * check, to augment existing struct/union canonical mapping, where possible. * * If BTF_KIND_FWD resolution is allowed, this mapping is also used to record * FWD -> STRUCT/UNION correspondence as well. FWD resolution is bidirectional: * it doesn't matter if FWD type was part of canonical graph or candidate one, * we are recording the mapping anyway. As opposed to carefulness required * for struct/union correspondence mapping (described below), for FWD resolution * it's not important, as by the time that FWD type (reference type) will be * deduplicated all structs/unions will be deduped already anyway. * * Recording STRUCT/UNION mapping is purely a performance optimization and is * not required for correctness. It needs to be done carefully to ensure that * struct/union from candidate's type graph is not mapped into corresponding * struct/union from canonical type graph that itself hasn't been resolved into * canonical representative. The only guarantee we have is that canonical * struct/union was determined as canonical and that won't change. But any * types referenced through that struct/union fields could have been not yet * resolved, so in case like that it's too early to establish any kind of * correspondence between structs/unions. * * No canonical correspondence is derived for primitive types (they are already * deduplicated completely already anyway) or reference types (they rely on * stability of struct/union canonical relationship for equivalence checks). */ static void btf_dedup_merge_hypot_map(struct btf_dedup *d) { __u32 cand_type_id, targ_type_id; __u16 t_kind, c_kind; __u32 t_id, c_id; int i; for (i = 0; i < d->hypot_cnt; i++) { cand_type_id = d->hypot_list[i]; targ_type_id = d->hypot_map[cand_type_id]; t_id = resolve_type_id(d, targ_type_id); c_id = resolve_type_id(d, cand_type_id); t_kind = btf_kind(d->btf->types[t_id]); c_kind = btf_kind(d->btf->types[c_id]); /* * Resolve FWD into STRUCT/UNION. * It's ok to resolve FWD into STRUCT/UNION that's not yet * mapped to canonical representative (as opposed to * STRUCT/UNION <--> STRUCT/UNION mapping logic below), because * eventually that struct is going to be mapped and all resolved * FWDs will automatically resolve to correct canonical * representative. This will happen before ref type deduping, * which critically depends on stability of these mapping. This * stability is not a requirement for STRUCT/UNION equivalence * checks, though. */ if (t_kind != BTF_KIND_FWD && c_kind == BTF_KIND_FWD) d->map[c_id] = t_id; else if (t_kind == BTF_KIND_FWD && c_kind != BTF_KIND_FWD) d->map[t_id] = c_id; if ((t_kind == BTF_KIND_STRUCT || t_kind == BTF_KIND_UNION) && c_kind != BTF_KIND_FWD && is_type_mapped(d, c_id) && !is_type_mapped(d, t_id)) { /* * as a perf optimization, we can map struct/union * that's part of type graph we just verified for * equivalence. We can do that for struct/union that has * canonical representative only, though. */ d->map[t_id] = c_id; } } } /* * Deduplicate struct/union types. * * For each struct/union type its type signature hash is calculated, taking * into account type's name, size, number, order and names of fields, but * ignoring type ID's referenced from fields, because they might not be deduped * completely until after reference types deduplication phase. This type hash * is used to iterate over all potential canonical types, sharing same hash. * For each canonical candidate we check whether type graphs that they form * (through referenced types in fields and so on) are equivalent using algorithm * implemented in `btf_dedup_is_equiv`. If such equivalence is found and * BTF_KIND_FWD resolution is allowed, then hypothetical mapping * (btf_dedup->hypot_map) produced by aforementioned type graph equivalence * algorithm is used to record FWD -> STRUCT/UNION mapping. It's also used to * potentially map other structs/unions to their canonical representatives, * if such relationship hasn't yet been established. This speeds up algorithm * by eliminating some of the duplicate work. * * If no matching canonical representative was found, struct/union is marked * as canonical for itself and is added into btf_dedup->dedup_table hash map * for further look ups. */ static int btf_dedup_struct_type(struct btf_dedup *d, __u32 type_id) { struct btf_type *cand_type, *t; struct hashmap_entry *hash_entry; /* if we don't find equivalent type, then we are canonical */ __u32 new_id = type_id; __u16 kind; long h; /* already deduped or is in process of deduping (loop detected) */ if (d->map[type_id] <= BTF_MAX_NR_TYPES) return 0; t = d->btf->types[type_id]; kind = btf_kind(t); if (kind != BTF_KIND_STRUCT && kind != BTF_KIND_UNION) return 0; h = btf_hash_struct(t); for_each_dedup_cand(d, hash_entry, h) { __u32 cand_id = (__u32)(long)hash_entry->value; int eq; /* * Even though btf_dedup_is_equiv() checks for * btf_shallow_equal_struct() internally when checking two * structs (unions) for equivalence, we need to guard here * from picking matching FWD type as a dedup candidate. * This can happen due to hash collision. In such case just * relying on btf_dedup_is_equiv() would lead to potentially * creating a loop (FWD -> STRUCT and STRUCT -> FWD), because * FWD and compatible STRUCT/UNION are considered equivalent. */ cand_type = d->btf->types[cand_id]; if (!btf_shallow_equal_struct(t, cand_type)) continue; btf_dedup_clear_hypot_map(d); eq = btf_dedup_is_equiv(d, type_id, cand_id); if (eq < 0) return eq; if (!eq) continue; new_id = cand_id; btf_dedup_merge_hypot_map(d); break; } d->map[type_id] = new_id; if (type_id == new_id && btf_dedup_table_add(d, h, type_id)) return -ENOMEM; return 0; } static int btf_dedup_struct_types(struct btf_dedup *d) { int i, err; for (i = 1; i <= d->btf->nr_types; i++) { err = btf_dedup_struct_type(d, i); if (err) return err; } return 0; } /* * Deduplicate reference type. * * Once all primitive and struct/union types got deduplicated, we can easily * deduplicate all other (reference) BTF types. This is done in two steps: * * 1. Resolve all referenced type IDs into their canonical type IDs. This * resolution can be done either immediately for primitive or struct/union types * (because they were deduped in previous two phases) or recursively for * reference types. Recursion will always terminate at either primitive or * struct/union type, at which point we can "unwind" chain of reference types * one by one. There is no danger of encountering cycles because in C type * system the only way to form type cycle is through struct/union, so any chain * of reference types, even those taking part in a type cycle, will inevitably * reach struct/union at some point. * * 2. Once all referenced type IDs are resolved into canonical ones, BTF type * becomes "stable", in the sense that no further deduplication will cause * any changes to it. With that, it's now possible to calculate type's signature * hash (this time taking into account referenced type IDs) and loop over all * potential canonical representatives. If no match was found, current type * will become canonical representative of itself and will be added into * btf_dedup->dedup_table as another possible canonical representative. */ static int btf_dedup_ref_type(struct btf_dedup *d, __u32 type_id) { struct hashmap_entry *hash_entry; __u32 new_id = type_id, cand_id; struct btf_type *t, *cand; /* if we don't find equivalent type, then we are representative type */ int ref_type_id; long h; if (d->map[type_id] == BTF_IN_PROGRESS_ID) return -ELOOP; if (d->map[type_id] <= BTF_MAX_NR_TYPES) return resolve_type_id(d, type_id); t = d->btf->types[type_id]; d->map[type_id] = BTF_IN_PROGRESS_ID; switch (btf_kind(t)) { case BTF_KIND_CONST: case BTF_KIND_VOLATILE: case BTF_KIND_RESTRICT: case BTF_KIND_PTR: case BTF_KIND_TYPEDEF: case BTF_KIND_FUNC: ref_type_id = btf_dedup_ref_type(d, t->type); if (ref_type_id < 0) return ref_type_id; t->type = ref_type_id; h = btf_hash_common(t); for_each_dedup_cand(d, hash_entry, h) { cand_id = (__u32)(long)hash_entry->value; cand = d->btf->types[cand_id]; if (btf_equal_common(t, cand)) { new_id = cand_id; break; } } break; case BTF_KIND_ARRAY: { struct btf_array *info = btf_array(t); ref_type_id = btf_dedup_ref_type(d, info->type); if (ref_type_id < 0) return ref_type_id; info->type = ref_type_id; ref_type_id = btf_dedup_ref_type(d, info->index_type); if (ref_type_id < 0) return ref_type_id; info->index_type = ref_type_id; h = btf_hash_array(t); for_each_dedup_cand(d, hash_entry, h) { cand_id = (__u32)(long)hash_entry->value; cand = d->btf->types[cand_id]; if (btf_equal_array(t, cand)) { new_id = cand_id; break; } } break; } case BTF_KIND_FUNC_PROTO: { struct btf_param *param; __u16 vlen; int i; ref_type_id = btf_dedup_ref_type(d, t->type); if (ref_type_id < 0) return ref_type_id; t->type = ref_type_id; vlen = btf_vlen(t); param = btf_params(t); for (i = 0; i < vlen; i++) { ref_type_id = btf_dedup_ref_type(d, param->type); if (ref_type_id < 0) return ref_type_id; param->type = ref_type_id; param++; } h = btf_hash_fnproto(t); for_each_dedup_cand(d, hash_entry, h) { cand_id = (__u32)(long)hash_entry->value; cand = d->btf->types[cand_id]; if (btf_equal_fnproto(t, cand)) { new_id = cand_id; break; } } break; } default: return -EINVAL; } d->map[type_id] = new_id; if (type_id == new_id && btf_dedup_table_add(d, h, type_id)) return -ENOMEM; return new_id; } static int btf_dedup_ref_types(struct btf_dedup *d) { int i, err; for (i = 1; i <= d->btf->nr_types; i++) { err = btf_dedup_ref_type(d, i); if (err < 0) return err; } /* we won't need d->dedup_table anymore */ hashmap__free(d->dedup_table); d->dedup_table = NULL; return 0; } /* * Compact types. * * After we established for each type its corresponding canonical representative * type, we now can eliminate types that are not canonical and leave only * canonical ones layed out sequentially in memory by copying them over * duplicates. During compaction btf_dedup->hypot_map array is reused to store * a map from original type ID to a new compacted type ID, which will be used * during next phase to "fix up" type IDs, referenced from struct/union and * reference types. */ static int btf_dedup_compact_types(struct btf_dedup *d) { struct btf_type **new_types; __u32 next_type_id = 1; char *types_start, *p; int i, len; /* we are going to reuse hypot_map to store compaction remapping */ d->hypot_map[0] = 0; for (i = 1; i <= d->btf->nr_types; i++) d->hypot_map[i] = BTF_UNPROCESSED_ID; types_start = d->btf->nohdr_data + d->btf->hdr->type_off; p = types_start; for (i = 1; i <= d->btf->nr_types; i++) { if (d->map[i] != i) continue; len = btf_type_size(d->btf->types[i]); if (len < 0) return len; memmove(p, d->btf->types[i], len); d->hypot_map[i] = next_type_id; d->btf->types[next_type_id] = (struct btf_type *)p; p += len; next_type_id++; } /* shrink struct btf's internal types index and update btf_header */ d->btf->nr_types = next_type_id - 1; d->btf->types_size = d->btf->nr_types; d->btf->hdr->type_len = p - types_start; new_types = realloc(d->btf->types, (1 + d->btf->nr_types) * sizeof(struct btf_type *)); if (!new_types) return -ENOMEM; d->btf->types = new_types; /* make sure string section follows type information without gaps */ d->btf->hdr->str_off = p - (char *)d->btf->nohdr_data; memmove(p, d->btf->strings, d->btf->hdr->str_len); d->btf->strings = p; p += d->btf->hdr->str_len; d->btf->data_size = p - (char *)d->btf->data; return 0; } /* * Figure out final (deduplicated and compacted) type ID for provided original * `type_id` by first resolving it into corresponding canonical type ID and * then mapping it to a deduplicated type ID, stored in btf_dedup->hypot_map, * which is populated during compaction phase. */ static int btf_dedup_remap_type_id(struct btf_dedup *d, __u32 type_id) { __u32 resolved_type_id, new_type_id; resolved_type_id = resolve_type_id(d, type_id); new_type_id = d->hypot_map[resolved_type_id]; if (new_type_id > BTF_MAX_NR_TYPES) return -EINVAL; return new_type_id; } /* * Remap referenced type IDs into deduped type IDs. * * After BTF types are deduplicated and compacted, their final type IDs may * differ from original ones. The map from original to a corresponding * deduped type ID is stored in btf_dedup->hypot_map and is populated during * compaction phase. During remapping phase we are rewriting all type IDs * referenced from any BTF type (e.g., struct fields, func proto args, etc) to * their final deduped type IDs. */ static int btf_dedup_remap_type(struct btf_dedup *d, __u32 type_id) { struct btf_type *t = d->btf->types[type_id]; int i, r; switch (btf_kind(t)) { case BTF_KIND_INT: case BTF_KIND_ENUM: break; case BTF_KIND_FWD: case BTF_KIND_CONST: case BTF_KIND_VOLATILE: case BTF_KIND_RESTRICT: case BTF_KIND_PTR: case BTF_KIND_TYPEDEF: case BTF_KIND_FUNC: case BTF_KIND_VAR: r = btf_dedup_remap_type_id(d, t->type); if (r < 0) return r; t->type = r; break; case BTF_KIND_ARRAY: { struct btf_array *arr_info = btf_array(t); r = btf_dedup_remap_type_id(d, arr_info->type); if (r < 0) return r; arr_info->type = r; r = btf_dedup_remap_type_id(d, arr_info->index_type); if (r < 0) return r; arr_info->index_type = r; break; } case BTF_KIND_STRUCT: case BTF_KIND_UNION: { struct btf_member *member = btf_members(t); __u16 vlen = btf_vlen(t); for (i = 0; i < vlen; i++) { r = btf_dedup_remap_type_id(d, member->type); if (r < 0) return r; member->type = r; member++; } break; } case BTF_KIND_FUNC_PROTO: { struct btf_param *param = btf_params(t); __u16 vlen = btf_vlen(t); r = btf_dedup_remap_type_id(d, t->type); if (r < 0) return r; t->type = r; for (i = 0; i < vlen; i++) { r = btf_dedup_remap_type_id(d, param->type); if (r < 0) return r; param->type = r; param++; } break; } case BTF_KIND_DATASEC: { struct btf_var_secinfo *var = btf_var_secinfos(t); __u16 vlen = btf_vlen(t); for (i = 0; i < vlen; i++) { r = btf_dedup_remap_type_id(d, var->type); if (r < 0) return r; var->type = r; var++; } break; } default: return -EINVAL; } return 0; } static int btf_dedup_remap_types(struct btf_dedup *d) { int i, r; for (i = 1; i <= d->btf->nr_types; i++) { r = btf_dedup_remap_type(d, i); if (r < 0) return r; } return 0; }