/* $OpenBSD: db_ctf.c,v 1.35 2024/11/07 16:02:29 miod Exp $ */ /* * Copyright (c) 2016-2017 Martin Pieuchot * Copyright (c) 2016 Jasper Lievisse Adriaanse * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include extern db_symtab_t db_symtab; struct ddb_ctf { struct ctf_header *cth; const char *rawctf; /* raw .SUNW_ctf section */ size_t rawctflen; /* raw .SUNW_ctf section size */ const char *data; /* decompressed CTF data */ size_t dlen; /* decompressed CTF data size */ const char *strtab; /* ELF string table */ uint32_t ctf_found; }; struct ddb_ctf db_ctf; static const char *db_ctf_off2name(uint32_t); static Elf_Sym *db_ctf_idx2sym(size_t *, uint8_t); static char *db_ctf_decompress(const char *, size_t, size_t); uint32_t db_ctf_type_len(const struct ctf_type *); size_t db_ctf_type_size(const struct ctf_type *); const struct ctf_type *db_ctf_type_by_name(const char *, unsigned int); const struct ctf_type *db_ctf_type_by_symbol(Elf_Sym *); const struct ctf_type *db_ctf_type_by_index(uint16_t); void db_ctf_pprint(const struct ctf_type *, vaddr_t); void db_ctf_pprint_struct(const struct ctf_type *, vaddr_t); void db_ctf_pprint_enum(const struct ctf_type *, vaddr_t); void db_ctf_pprint_ptr(const struct ctf_type *, vaddr_t); /* * Entrypoint to verify CTF presence, initialize the header, decompress * the data, etc. */ void db_ctf_init(void) { db_symtab_t *stab = &db_symtab; size_t rawctflen; /* Assume nothing was correct found until proven otherwise. */ db_ctf.ctf_found = 0; if (stab->private == NULL) return; db_ctf.strtab = db_elf_find_strtab(stab); if (db_ctf.strtab == NULL) return; db_ctf.rawctf = db_elf_find_section(stab, &rawctflen, ELF_CTF); if (db_ctf.rawctf == NULL) return; db_ctf.rawctflen = rawctflen; db_ctf.cth = (struct ctf_header *)db_ctf.rawctf; db_ctf.dlen = db_ctf.cth->cth_stroff + db_ctf.cth->cth_strlen; if ((db_ctf.cth->cth_flags & CTF_F_COMPRESS) == 0) { db_printf("unsupported non-compressed CTF section\n"); return; } /* Now decompress the section, take into account to skip the header */ db_ctf.data = db_ctf_decompress(db_ctf.rawctf + sizeof(*db_ctf.cth), db_ctf.rawctflen - sizeof(*db_ctf.cth), db_ctf.dlen); if (db_ctf.data == NULL) return; /* We made it this far, everything seems fine. */ db_ctf.ctf_found = 1; } /* * Convert an index to a symbol name while ensuring the type is matched. * It must be noted this only works if the CTF table has the same order * as the symbol table. */ Elf_Sym * db_ctf_idx2sym(size_t *idx, uint8_t type) { Elf_Sym *symp, *symtab_start, *symtab_end; size_t i = *idx + 1; symtab_start = STAB_TO_SYMSTART(&db_symtab); symtab_end = STAB_TO_SYMEND(&db_symtab); for (symp = &symtab_start[i]; symp < symtab_end; i++, symp++) { if (ELF_ST_TYPE(symp->st_info) != type) continue; *idx = i; return symp; } return NULL; } /* * For a given function name, return the number of arguments. */ int db_ctf_func_numargs(Elf_Sym *st) { Elf_Sym *symp; uint16_t *fstart, *fend; uint16_t *fsp, kind, vlen; size_t i, idx = 0; if (!db_ctf.ctf_found || st == NULL) return -1; fstart = (uint16_t *)(db_ctf.data + db_ctf.cth->cth_funcoff); fend = (uint16_t *)(db_ctf.data + db_ctf.cth->cth_typeoff); fsp = fstart; while (fsp < fend) { symp = db_ctf_idx2sym(&idx, STT_FUNC); if (symp == NULL) break; kind = CTF_INFO_KIND(*fsp); vlen = CTF_INFO_VLEN(*fsp); fsp++; if (kind == CTF_K_UNKNOWN && vlen == 0) continue; /* Skip return type */ fsp++; /* Skip argument types */ for (i = 0; i < vlen; i++) fsp++; if (symp == st) return vlen; } return 0; } /* * Return the length of the type record in the CTF section. */ uint32_t db_ctf_type_len(const struct ctf_type *ctt) { uint16_t kind, vlen, i; uint32_t tlen; uint64_t size; kind = CTF_INFO_KIND(ctt->ctt_info); vlen = CTF_INFO_VLEN(ctt->ctt_info); if (ctt->ctt_size <= CTF_MAX_SIZE) { size = ctt->ctt_size; tlen = sizeof(struct ctf_stype); } else { size = CTF_TYPE_LSIZE(ctt); tlen = sizeof(struct ctf_type); } switch (kind) { case CTF_K_UNKNOWN: case CTF_K_FORWARD: break; case CTF_K_INTEGER: tlen += sizeof(uint32_t); break; case CTF_K_FLOAT: tlen += sizeof(uint32_t); break; case CTF_K_ARRAY: tlen += sizeof(struct ctf_array); break; case CTF_K_FUNCTION: tlen += (vlen + (vlen & 1)) * sizeof(uint16_t); break; case CTF_K_STRUCT: case CTF_K_UNION: if (size < CTF_LSTRUCT_THRESH) { for (i = 0; i < vlen; i++) { tlen += sizeof(struct ctf_member); } } else { for (i = 0; i < vlen; i++) { tlen += sizeof(struct ctf_lmember); } } break; case CTF_K_ENUM: for (i = 0; i < vlen; i++) { tlen += sizeof(struct ctf_enum); } break; case CTF_K_POINTER: case CTF_K_TYPEDEF: case CTF_K_VOLATILE: case CTF_K_CONST: case CTF_K_RESTRICT: break; default: return 0; } return tlen; } /* * Return the size of the type. */ size_t db_ctf_type_size(const struct ctf_type *ctt) { vaddr_t taddr = (vaddr_t)ctt; const struct ctf_type *ref; const struct ctf_array *arr; size_t tlen = 0; uint16_t kind; uint32_t toff; uint64_t size; kind = CTF_INFO_KIND(ctt->ctt_info); if (ctt->ctt_size <= CTF_MAX_SIZE) { size = ctt->ctt_size; toff = sizeof(struct ctf_stype); } else { size = CTF_TYPE_LSIZE(ctt); toff = sizeof(struct ctf_type); } switch (kind) { case CTF_K_UNKNOWN: case CTF_K_FORWARD: break; case CTF_K_INTEGER: case CTF_K_FLOAT: tlen = size; break; case CTF_K_ARRAY: arr = (struct ctf_array *)(taddr + toff); ref = db_ctf_type_by_index(arr->cta_contents); tlen = arr->cta_nelems * db_ctf_type_size(ref); break; case CTF_K_FUNCTION: tlen = 0; break; case CTF_K_STRUCT: case CTF_K_UNION: case CTF_K_ENUM: tlen = size; break; case CTF_K_POINTER: tlen = sizeof(void *); break; case CTF_K_TYPEDEF: case CTF_K_VOLATILE: case CTF_K_CONST: case CTF_K_RESTRICT: ref = db_ctf_type_by_index(ctt->ctt_type); tlen = db_ctf_type_size(ref); break; default: return 0; } return tlen; } /* * Return the CTF type associated to an ELF symbol. */ const struct ctf_type * db_ctf_type_by_symbol(Elf_Sym *st) { Elf_Sym *symp; uint32_t objtoff; uint16_t *dsp; size_t idx = 0; if (!db_ctf.ctf_found || st == NULL) return NULL; objtoff = db_ctf.cth->cth_objtoff; while (objtoff < db_ctf.cth->cth_funcoff) { dsp = (uint16_t *)(db_ctf.data + objtoff); symp = db_ctf_idx2sym(&idx, STT_OBJECT); if (symp == NULL) break; if (symp == st) return db_ctf_type_by_index(*dsp); objtoff += sizeof(*dsp); } return NULL; } const struct ctf_type * db_ctf_type_by_name(const char *name, unsigned int kind) { struct ctf_header *cth; const struct ctf_type *ctt; const char *tname; uint32_t off, toff; if (!db_ctf.ctf_found) return (NULL); cth = db_ctf.cth; for (off = cth->cth_typeoff; off < cth->cth_stroff; off += toff) { ctt = (struct ctf_type *)(db_ctf.data + off); toff = db_ctf_type_len(ctt); if (toff == 0) { db_printf("incorrect type at offset %u", off); break; } if (CTF_INFO_KIND(ctt->ctt_info) != kind) continue; tname = db_ctf_off2name(ctt->ctt_name); if (tname == NULL) continue; if (strcmp(name, tname) == 0) return (ctt); } return (NULL); } /* * Return the CTF type corresponding to a given index in the type section. */ const struct ctf_type * db_ctf_type_by_index(uint16_t index) { uint32_t offset = db_ctf.cth->cth_typeoff; uint16_t idx = 1; if (!db_ctf.ctf_found) return NULL; while (offset < db_ctf.cth->cth_stroff) { const struct ctf_type *ctt; uint32_t toff; ctt = (struct ctf_type *)(db_ctf.data + offset); if (idx == index) return ctt; toff = db_ctf_type_len(ctt); if (toff == 0) { db_printf("incorrect type at offset %u", offset); break; } offset += toff; idx++; } return NULL; } /* * Pretty print `addr'. */ void db_ctf_pprint(const struct ctf_type *ctt, vaddr_t addr) { vaddr_t taddr = (vaddr_t)ctt; const struct ctf_type *ref; const struct ctf_array *arr; uint16_t kind; uint32_t eob, toff, i; db_expr_t val; size_t elm_size; if (ctt == NULL) return; kind = CTF_INFO_KIND(ctt->ctt_info); if (ctt->ctt_size <= CTF_MAX_SIZE) toff = sizeof(struct ctf_stype); else toff = sizeof(struct ctf_type); switch (kind) { case CTF_K_ARRAY: arr = (struct ctf_array *)(taddr + toff); ref = db_ctf_type_by_index(arr->cta_contents); elm_size = db_ctf_type_size(ref); db_printf("["); for (i = 0; i < arr->cta_nelems; i++) { db_ctf_pprint(ref, addr + i * elm_size); if (i + 1 < arr->cta_nelems) db_printf(","); } db_printf("]"); break; case CTF_K_ENUM: db_ctf_pprint_enum(ctt, addr); break; case CTF_K_FLOAT: case CTF_K_FUNCTION: val = db_get_value(addr, sizeof(val), 0); db_printf("%lx", (unsigned long)val); break; case CTF_K_INTEGER: eob = db_get_value((taddr + toff), sizeof(eob), 0); switch (CTF_INT_BITS(eob)) { #ifndef __LP64__ case 64: { uint64_t val64; #if BYTE_ORDER == LITTLE_ENDIAN val64 = db_get_value(addr + 4, CTF_INT_BITS(eob) / 8, CTF_INT_ENCODING(eob) & CTF_INT_SIGNED); val64 <<= 32; val64 |= db_get_value(addr, CTF_INT_BITS(eob) / 8, 0); #else val64 = db_get_value(addr, CTF_INT_BITS(eob) / 8, CTF_INT_ENCODING(eob) & CTF_INT_SIGNED); val64 <<= 32; val64 |= db_get_value(addr + 4, CTF_INT_BITS(eob) / 8, 0); #endif if (CTF_INT_ENCODING(eob) & CTF_INT_SIGNED) db_printf("%lld", val64); else db_printf("%llu", val64); break; } #endif default: val = db_get_value(addr, CTF_INT_BITS(eob) / 8, CTF_INT_ENCODING(eob) & CTF_INT_SIGNED); if (CTF_INT_ENCODING(eob) & CTF_INT_SIGNED) db_printf("%ld", val); else db_printf("%lu", val); break; } break; case CTF_K_STRUCT: case CTF_K_UNION: db_ctf_pprint_struct(ctt, addr); break; case CTF_K_POINTER: db_ctf_pprint_ptr(ctt, addr); break; case CTF_K_TYPEDEF: case CTF_K_VOLATILE: case CTF_K_CONST: case CTF_K_RESTRICT: ref = db_ctf_type_by_index(ctt->ctt_type); db_ctf_pprint(ref, addr); break; case CTF_K_UNKNOWN: case CTF_K_FORWARD: default: break; } } void db_ctf_pprint_struct(const struct ctf_type *ctt, vaddr_t addr) { const char *name, *p = (const char *)ctt; const struct ctf_type *ref; uint32_t toff; uint64_t size; uint16_t i, vlen; vlen = CTF_INFO_VLEN(ctt->ctt_info); if (ctt->ctt_size <= CTF_MAX_SIZE) { size = ctt->ctt_size; toff = sizeof(struct ctf_stype); } else { size = CTF_TYPE_LSIZE(ctt); toff = sizeof(struct ctf_type); } db_printf("{"); if (size < CTF_LSTRUCT_THRESH) { for (i = 0; i < vlen; i++) { struct ctf_member *ctm; ctm = (struct ctf_member *)(p + toff); toff += sizeof(struct ctf_member); name = db_ctf_off2name(ctm->ctm_name); if (name != NULL) db_printf("%s = ", name); ref = db_ctf_type_by_index(ctm->ctm_type); db_ctf_pprint(ref, addr + ctm->ctm_offset / 8); if (i < vlen - 1) db_printf(", "); } } else { for (i = 0; i < vlen; i++) { struct ctf_lmember *ctlm; ctlm = (struct ctf_lmember *)(p + toff); toff += sizeof(struct ctf_lmember); name = db_ctf_off2name(ctlm->ctlm_name); if (name != NULL) db_printf("%s = ", name); ref = db_ctf_type_by_index(ctlm->ctlm_type); db_ctf_pprint(ref, addr + CTF_LMEM_OFFSET(ctlm) / 8); if (i < vlen - 1) db_printf(", "); } } db_printf("}"); } void db_ctf_pprint_enum(const struct ctf_type *ctt, vaddr_t addr) { const char *name = NULL, *p = (const char *)ctt; struct ctf_enum *cte; uint32_t toff; int32_t val; uint16_t i, vlen; vlen = CTF_INFO_VLEN(ctt->ctt_info); toff = sizeof(struct ctf_stype); val = (int32_t)db_get_value(addr, sizeof(val), 1); for (i = 0; i < vlen; i++) { cte = (struct ctf_enum *)(p + toff); toff += sizeof(*cte); if (val == cte->cte_value) { name = db_ctf_off2name(cte->cte_name); break; } } if (name != NULL) db_printf("%s", name); else db_printf("#%d", val); } void db_ctf_pprint_ptr(const struct ctf_type *ctt, vaddr_t addr) { const char *name, *modif = ""; const struct ctf_type *ref; uint16_t kind; unsigned long ptr; ref = db_ctf_type_by_index(ctt->ctt_type); kind = CTF_INFO_KIND(ref->ctt_info); switch (kind) { case CTF_K_VOLATILE: modif = "volatile "; ref = db_ctf_type_by_index(ref->ctt_type); break; case CTF_K_CONST: modif = "const "; ref = db_ctf_type_by_index(ref->ctt_type); break; case CTF_K_STRUCT: modif = "struct "; break; case CTF_K_UNION: modif = "union "; break; default: break; } name = db_ctf_off2name(ref->ctt_name); if (name != NULL) db_printf("(%s%s *)", modif, name); ptr = (unsigned long)db_get_value(addr, sizeof(ptr), 0); db_printf("0x%lx", ptr); } static const char * db_ctf_off2name(uint32_t offset) { const char *name; if (!db_ctf.ctf_found) return NULL; if (CTF_NAME_STID(offset) != CTF_STRTAB_0) return "external"; if (CTF_NAME_OFFSET(offset) >= db_ctf.cth->cth_strlen) return "exceeds strlab"; if (db_ctf.cth->cth_stroff + CTF_NAME_OFFSET(offset) >= db_ctf.dlen) return "invalid"; name = db_ctf.data + db_ctf.cth->cth_stroff + CTF_NAME_OFFSET(offset); if (*name == '\0') return NULL; return name; } static char * db_ctf_decompress(const char *buf, size_t size, size_t len) { z_stream stream; char *data; int error; data = malloc(len, M_TEMP, M_WAITOK|M_ZERO|M_CANFAIL); if (data == NULL) return NULL; memset(&stream, 0, sizeof(stream)); stream.next_in = (void *)buf; stream.avail_in = size; stream.next_out = data; stream.avail_out = len; if ((error = inflateInit(&stream)) != Z_OK) { db_printf("zlib inflateInit failed: %s", zError(error)); goto exit; } if ((error = inflate(&stream, Z_FINISH)) != Z_STREAM_END) { db_printf("zlib inflate failed: %s", zError(error)); inflateEnd(&stream); goto exit; } if ((error = inflateEnd(&stream)) != Z_OK) { db_printf("zlib inflateEnd failed: %s", zError(error)); goto exit; } if (stream.total_out != len) { db_printf("decompression failed: %lu != %zu", stream.total_out, len); goto exit; } return data; exit: free(data, M_DEVBUF, len); return NULL; } /* * pprint */ void db_ctf_pprint_cmd(db_expr_t addr, int have_addr, db_expr_t count, char *modif) { Elf_Sym *st; const struct ctf_type *ctt; int t; if (!db_ctf.ctf_found) { db_printf("No CTF data found\n"); db_flush_lex(); return; } /* * Read the struct name from the debugger input. */ t = db_read_token(); if (t != tIDENT) { db_printf("Bad symbol name\n"); db_flush_lex(); return; } if ((st = db_symbol_by_name(db_tok_string, &addr)) == NULL) { db_printf("Symbol not found %s\n", db_tok_string); db_flush_lex(); return; } if ((ctt = db_ctf_type_by_symbol(st)) == NULL) { modif[0] = '\0'; db_print_cmd(addr, 0, 0, modif); db_flush_lex(); return; } db_printf("%s:\t", db_tok_string); db_ctf_pprint(ctt, addr); db_printf("\n"); } /* * show struct [addr]: displays the data starting at addr * (`dot' if unspecified) as a struct of the given type. */ void db_ctf_show_struct(db_expr_t addr, int have_addr, db_expr_t count, char *modifiers) { const struct ctf_type *ctt; const char *name; uint64_t sz; int t; /* * Read the struct name from the debugger input. */ t = db_read_token(); if (t != tIDENT) { db_printf("Bad struct name\n"); db_flush_lex(); return; } name = db_tok_string; ctt = db_ctf_type_by_name(name, CTF_K_STRUCT); if (ctt == NULL) { db_printf("unknown struct %s\n", name); db_flush_lex(); return; } /* * Read the address, if any, from the debugger input. * In that case, update `dot' value. */ if (db_expression(&addr)) { db_dot = (vaddr_t)addr; db_last_addr = db_dot; } else addr = (db_expr_t)db_dot; db_skip_to_eol(); /* * Display the structure contents. */ sz = (ctt->ctt_size <= CTF_MAX_SIZE) ? ctt->ctt_size : CTF_TYPE_LSIZE(ctt); db_printf("struct %s at %p (%llu bytes) ", name, (void *)addr, sz); db_ctf_pprint_struct(ctt, addr); }