/* Copyright (C) 2000,2004,2005 Silicon Graphics, Inc. All Rights Reserved. Portions Copyright (C) 2007-2012 David Anderson. All Rights Reserved. Portions Copyright (C) 2011-2012 SN Systems Ltd. All Rights Reserved This program is free software; you can redistribute it and/or modify it under the terms of version 2 of the GNU General Public License as published by the Free Software Foundation. This program is distributed in the hope that it would be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. Further, this software is distributed without any warranty that it is free of the rightful claim of any third person regarding infringement or the like. Any license provided herein, whether implied or otherwise, applies only to this software file. Patent licenses, if any, provided herein do not apply to combinations of this program with other software, or any other product whatsoever. You should have received a copy of the GNU General Public License along with this program; if not, write the Free Software Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston MA 02110-1301, USA. */ #include "globals.h" #define DWARF_RELOC_MIPS #define DWARF_RELOC_PPC #define DWARF_RELOC_PPC64 #define DWARF_RELOC_ARM #define DWARF_RELOC_X86_64 #define DWARF_RELOC_386 #include "print_reloc.h" #include "section_bitmaps.h" #include "esb.h" /* Include Section type, to be able to deal with all the Elf32_Rel, Elf32_Rela, Elf64_Rel, Elf64_Rela relocation types print_error does not return, so the following esb_destructor() call is unnecessary but reads well :-) */ #define SECT_DATA_SET(x,t,n,sout,r2) { \ data = elf_getdata(scn, 0); \ if (!data || !data->d_size) { \ struct esb_s data_disaster; \ esb_constructor(&data_disaster); \ esb_append(&data_disaster,(n)); \ esb_append(&data_disaster," null"); \ print_error(dbg,esb_get_string(&data_disaster),DW_DLV_OK, err); \ esb_destructor(&data_disaster); \ } \ sout[(r2)] = sect_data[(x)]; \ sout[(r2)].buf = data->d_buf; \ sout[(r2)].size = data->d_size; \ sout[(r2)].type = (t); \ sout[(r2)].name = (n); \ } /* Record the relocation table name information */ static const char **reloc_type_names = NULL; static Dwarf_Small number_of_reloc_type_names = 0; /* Set the relocation names based on the machine type */ static void set_relocation_table_names(Dwarf_Small machine_type) { reloc_type_names = 0; number_of_reloc_type_names = 0; switch (machine_type) { case EM_MIPS: #ifdef DWARF_RELOC_MIPS reloc_type_names = reloc_type_names_MIPS; number_of_reloc_type_names = sizeof(reloc_type_names_MIPS) / sizeof(char *); #endif /* DWARF_RELOC_MIPS */ break; case EM_PPC: #ifdef DWARF_RELOC_PPC reloc_type_names = reloc_type_names_PPC; number_of_reloc_type_names = sizeof(reloc_type_names_PPC) / sizeof(char *); #endif /* DWARF_RELOC_PPC */ break; case EM_PPC64: #ifdef DWARF_RELOC_PPC64 reloc_type_names = reloc_type_names_PPC64; number_of_reloc_type_names = sizeof(reloc_type_names_PPC64) / sizeof(char *); #endif /* DWARF_RELOC_PPC64 */ break; case EM_ARM: #ifdef DWARF_RELOC_ARM reloc_type_names = reloc_type_names_ARM; number_of_reloc_type_names = sizeof(reloc_type_names_ARM) / sizeof(char *); #endif /* DWARF_RELOC_ARM */ break; case EM_386: #ifdef DWARF_RELOC_386 reloc_type_names = reloc_type_names_386; number_of_reloc_type_names = sizeof(reloc_type_names_386) / sizeof(char *); #endif /* DWARF_RELOC_X86_64 */ break; case EM_X86_64: #ifdef DWARF_RELOC_X86_64 reloc_type_names = reloc_type_names_X86_64; number_of_reloc_type_names = sizeof(reloc_type_names_X86_64) / sizeof(char *); #endif /* DWARF_RELOC_X86_64 */ break; default: /* We don't have others covered. */ reloc_type_names = 0; number_of_reloc_type_names = 0; break; } } /* Return valid reloc type names. If buf is used, it is static, so beware: it will be overwritten by the next call. */ static const char * get_reloc_type_names(int index) { static char buf[100]; const char *retval = 0; if (index < 0 || index >= number_of_reloc_type_names) { if (number_of_reloc_type_names == 0) { /* No table provided. */ sprintf(buf, "reloc type %d", (int) index); } else { /* Table incomplete? */ sprintf(buf, "reloc type %d unknown", (int) index); } retval = buf; } else { retval = reloc_type_names[index]; } return retval; } #ifndef HAVE_ELF64_GETEHDR #define Elf64_Addr long #define Elf64_Word unsigned long #define Elf64_Xword unsigned long #define Elf64_Sym long #endif struct sect_data_s { Dwarf_Small *buf; Dwarf_Unsigned size; Dwarf_Bool display; /* Display reloc if TRUE */ const char *name; /* Section name */ Elf64_Xword type; /* To cover 32 and 64 records types */ }; static struct sect_data_s sect_data[DW_SECTION_REL_ARRAY_SIZE]; typedef size_t indx_type; typedef struct { indx_type indx; char *name; Elf32_Addr value; Elf32_Word size; int type; int bind; unsigned char other; Elf32_Half shndx; } SYM; typedef struct { indx_type indx; char *name; Elf64_Addr value; Elf64_Xword size; int type; int bind; unsigned char other; unsigned short shndx; } SYM64; static void print_reloc_information_64(int section_no, Dwarf_Small * buf, Dwarf_Unsigned size, Elf64_Xword type, char **scn_names, int scn_names_count); static void print_reloc_information_32(int section_no, Dwarf_Small * buf, Dwarf_Unsigned size, Elf64_Xword type, char **scn_names, int scn_names_count); static SYM *readsyms(Elf32_Sym * data, size_t num, Elf * elf, Elf32_Word link); static SYM64 *read_64_syms(Elf64_Sym * data, size_t num, Elf * elf, Elf64_Word link); static void *get_scndata(Elf_Scn * fd_scn, size_t * scn_size); static void print_relocinfo_64(Dwarf_Debug dbg, Elf * elf); static void print_relocinfo_32(Dwarf_Debug dbg, Elf * elf); static SYM *sym_data; static SYM64 *sym_data_64; static unsigned long sym_data_entry_count; static unsigned long sym_data_64_entry_count; typedef struct { indx_type index; char *name_rel; /* .rel.debug_* names */ char *name_rela; /* .rela.debug_* names */ } REL_INFO; /* If the incoming scn_name is known, record the name in our reloc section names table. For a given (debug) section there can be a .rel or a .rela, not both. The name-to-index in this table is fixed, invariant. */ static REL_INFO rel_info[DW_SECTION_REL_ARRAY_SIZE] = { {0,0,0}, {/*1*/ DW_SECTION_REL_DEBUG_INFO, DW_SECTNAME_REL_DEBUG_INFO, DW_SECTNAME_RELA_DEBUG_INFO}, {/*2*/ DW_SECTION_REL_DEBUG_LINE, DW_SECTNAME_REL_DEBUG_LINE, DW_SECTNAME_RELA_DEBUG_LINE}, {/*3*/ DW_SECTION_REL_DEBUG_PUBNAMES, DW_SECTNAME_REL_DEBUG_PUBNAMES, DW_SECTNAME_RELA_DEBUG_PUBNAMES}, {/*4*/ DW_SECTION_REL_DEBUG_ABBREV, DW_SECTNAME_REL_DEBUG_ABBREV, DW_SECTNAME_RELA_DEBUG_ABBREV}, {/*5*/ DW_SECTION_REL_DEBUG_ARANGES, DW_SECTNAME_REL_DEBUG_ARANGES, DW_SECTNAME_RELA_DEBUG_ARANGES}, {/*6*/ DW_SECTION_REL_DEBUG_FRAME, DW_SECTNAME_REL_DEBUG_FRAME, DW_SECTNAME_RELA_DEBUG_FRAME}, {/*7*/ DW_SECTION_REL_DEBUG_LOC, DW_SECTNAME_REL_DEBUG_LOC, DW_SECTNAME_RELA_DEBUG_LOC}, {/*8*/ DW_SECTION_REL_DEBUG_LOCLISTS, DW_SECTNAME_REL_DEBUG_LOCLISTS, DW_SECTNAME_RELA_DEBUG_LOCLISTS}, {/*9*/ DW_SECTION_REL_DEBUG_RANGES, DW_SECTNAME_REL_DEBUG_RANGES, DW_SECTNAME_RELA_DEBUG_RANGES}, {/*10*/ DW_SECTION_REL_DEBUG_RNGLISTS, DW_SECTNAME_REL_DEBUG_RNGLISTS, DW_SECTNAME_RELA_DEBUG_RNGLISTS}, {/*11*/ DW_SECTION_REL_DEBUG_TYPES, DW_SECTNAME_REL_DEBUG_TYPES, DW_SECTNAME_RELA_DEBUG_TYPES}, {/*12*/ DW_SECTION_REL_DEBUG_STR_OFFSETS, DW_SECTNAME_REL_DEBUG_STR_OFFSETS, DW_SECTNAME_RELA_DEBUG_STR_OFFSETS}, {/*13*/ DW_SECTION_REL_DEBUG_PUBTYPES, DW_SECTNAME_REL_DEBUG_PUBTYPES, DW_SECTNAME_RELA_DEBUG_PUBTYPES}, {/*14*/ DW_SECTION_REL_GDB_INDEX, DW_SECTNAME_REL_GDB_INDEX, DW_SECTNAME_RELA_GDB_INDEX}, {/*15*/ DW_SECTION_REL_EH_FRAME, DW_SECTNAME_REL_EH_FRAME, DW_SECTNAME_RELA_EH_FRAME}, {/*16*/ DW_SECTION_REL_DEBUG_SUP, DW_SECTNAME_REL_DEBUG_SUP, DW_SECTNAME_RELA_DEBUG_SUP}, {/*17*/ DW_SECTION_REL_DEBUG_MACINFO, DW_SECTNAME_REL_DEBUG_MACINFO, DW_SECTNAME_RELA_DEBUG_MACINFO}, {/*18*/ DW_SECTION_REL_DEBUG_MACRO, DW_SECTNAME_REL_DEBUG_MACRO, DW_SECTNAME_RELA_DEBUG_MACRO}, {/*19*/ DW_SECTION_REL_DEBUG_NAMES, DW_SECTNAME_REL_DEBUG_NAMES, DW_SECTNAME_RELA_DEBUG_NAMES}, }; #ifndef SELFTEST static void get_reloc_section(Dwarf_Debug dbg, Elf_Scn *scn, char *scn_name, Elf64_Word sh_type, struct sect_data_s * printable_sect, unsigned sectnum) { Elf_Data *data; int index; /* Check for reloc records we are interested in. */ for (index = 1; index < DW_SECTION_REL_ARRAY_SIZE; ++index) { const char *n = rel_info[index].name_rel; const char *na = rel_info[index].name_rela; Dwarf_Error err = 0; if (strcmp(scn_name, n) == 0) { SECT_DATA_SET(rel_info[index].index,sh_type,n, printable_sect,sectnum) return; } if (strcmp(scn_name, na) == 0) { SECT_DATA_SET(rel_info[index].index,sh_type,na, printable_sect,sectnum) return; } } return; } void print_relocinfo(Dwarf_Debug dbg, char * reloc_map) { Elf *elf; char *endr_ident; int is_64bit; int res; int i; Dwarf_Error err = 0; for (i = 1; i < DW_SECTION_REL_ARRAY_SIZE; i++) { sect_data[i].display = reloc_map[i]; sect_data[i].buf = 0; sect_data[i].size = 0; sect_data[i].type = SHT_NULL; } res = dwarf_get_elf(dbg, &elf, &err); if (res != DW_DLV_OK) { print_error(dbg, "dwarf_get_elf error", res, err); } endr_ident = elf_getident(elf, NULL); if (!endr_ident) { print_error(dbg, "DW_ELF_GETIDENT_ERROR", res, err); } is_64bit = (endr_ident[EI_CLASS] == ELFCLASS64); if (is_64bit) { print_relocinfo_64(dbg, elf); } else { print_relocinfo_32(dbg, elf); } } static void print_relocinfo_64(Dwarf_Debug dbg, Elf * elf) { #ifdef HAVE_ELF64_GETEHDR Elf_Scn *scn = NULL; unsigned sect_number = 0; Elf64_Ehdr *ehdr64 = 0; Elf64_Shdr *shdr64 = 0; char *scn_name = 0; int i = 0; Elf64_Sym *sym_64 = 0; char **scn_names = 0; struct sect_data_s *printable_sects = 0; int scn_names_cnt = 0; Dwarf_Error err = 0; ehdr64 = elf64_getehdr(elf); if (ehdr64 == NULL) { print_error(dbg, "DW_ELF_GETEHDR_ERROR", DW_DLV_OK, err); } /* Make the section name array big enough that we don't need to check for overrun in the loop. */ scn_names_cnt = ehdr64->e_shnum + 1; scn_names = (char **)calloc(scn_names_cnt, sizeof(char *)); if (!scn_names) { print_error(dbg, "Out of malloc space in relocation print names", DW_DLV_OK, err); } printable_sects = (struct sect_data_s *)calloc(scn_names_cnt, sizeof(struct sect_data_s)); if (!printable_sects) { free(scn_names); print_error(dbg, "Out of malloc space in relocation print sects", DW_DLV_OK, err); } /* First nextscn returns section 1 */ while ((scn = elf_nextscn(elf, scn)) != NULL) { ++sect_number; shdr64 = elf64_getshdr(scn); if (shdr64 == NULL) { free(scn_names); free(printable_sects); print_error(dbg, "DW_ELF_GETSHDR_ERROR", DW_DLV_OK, err); } scn_name = elf_strptr(elf, ehdr64->e_shstrndx, shdr64->sh_name); if (scn_name == NULL) { print_error(dbg, "DW_ELF_STRPTR_ERROR", DW_DLV_OK, err); } /* elf_nextscn() skips section with index '0' */ scn_names[sect_number] = scn_name; if (shdr64->sh_type == SHT_SYMTAB) { size_t sym_size = 0; size_t count = 0; sym_64 = (Elf64_Sym *) get_scndata(scn, &sym_size); if (sym_64 == NULL) { free(scn_names); free(printable_sects); print_error(dbg, "no Elf64 symbol table data", DW_DLV_OK, err); } count = sym_size / sizeof(Elf64_Sym); if(sym_size%sizeof(Elf64_Sym)) { print_error(dbg, "Elf64 problem reading .symtab data", DW_DLV_OK, err); } sym_64++; count--; free(sym_data_64); sym_data_64 = 0; sym_data_64 = read_64_syms(sym_64, count, elf, shdr64->sh_link); sym_data_64_entry_count = count; if (sym_data_64 == NULL) { free(scn_names); free(printable_sects); print_error(dbg, "problem reading Elf64 symbol table data", DW_DLV_OK, err); } } else { get_reloc_section(dbg,scn,scn_name,shdr64->sh_type, printable_sects,sect_number); } } /* Set the relocation names based on the machine type */ set_relocation_table_names(ehdr64->e_machine); for (i = 1; i < ehdr64->e_shnum + 1; i++) { if (printable_sects[i].display && printable_sects[i].buf != NULL && printable_sects[i].size > 0) { print_reloc_information_64(i, printable_sects[i].buf, printable_sects[i].size, printable_sects[i].type, scn_names,scn_names_cnt); } } free(printable_sects); free(scn_names); scn_names = 0; scn_names_cnt = 0; #endif } static void print_relocinfo_32(Dwarf_Debug dbg, Elf * elf) { Elf_Scn *scn = NULL; Elf32_Ehdr *ehdr32 = 0; Elf32_Shdr *shdr32 = 0; unsigned sect_number = 0; char *scn_name = 0; int i = 0; Elf32_Sym *sym = 0; char **scn_names = 0; int scn_names_cnt = 0; Dwarf_Error err = 0; struct sect_data_s *printable_sects = 0; ehdr32 = elf32_getehdr(elf); if (ehdr32 == NULL) { print_error(dbg, "DW_ELF_GETEHDR_ERROR", DW_DLV_OK, err); } /* Make the section name array big enough that we don't need to check for overrun in the loop. */ scn_names_cnt = ehdr32->e_shnum + 1; scn_names = (char **)calloc(scn_names_cnt, sizeof(char *)); if (!scn_names) { print_error(dbg, "Out of malloc space in relocation print names", DW_DLV_OK, err); } printable_sects = (struct sect_data_s *)calloc(scn_names_cnt, sizeof(struct sect_data_s)); if (!printable_sects) { free(scn_names); print_error(dbg, "Out of malloc space in relocation print sects", DW_DLV_OK, err); } while ((scn = elf_nextscn(elf, scn)) != NULL) { ++sect_number; shdr32 = elf32_getshdr(scn); if (shdr32 == NULL) { free(printable_sects); free(scn_names); print_error(dbg, "DW_ELF_GETSHDR_ERROR", DW_DLV_OK, err); } scn_name = elf_strptr(elf, ehdr32->e_shstrndx, shdr32->sh_name); if (scn_name == NULL) { free(printable_sects); free(scn_names); print_error(dbg, "DW_ELF_STRPTR_ERROR", DW_DLV_OK, err); } scn_names[sect_number] = scn_name; if (shdr32->sh_type == SHT_SYMTAB) { size_t sym_size = 0; size_t count = 0; sym = (Elf32_Sym *) get_scndata(scn, &sym_size); if (sym == NULL) { free(printable_sects); free(scn_names); print_error(dbg, "No Elf32 symbol table data", DW_DLV_OK, err); } count = sym_size / sizeof(Elf32_Sym); if(sym_size%sizeof(Elf32_Sym)) { print_error(dbg, "Elf32 problem reading .symtab data", DW_DLV_OK, err); } sym++; count--; free(sym_data); sym_data = 0; sym_data = readsyms(sym, count, elf, shdr32->sh_link); sym_data_entry_count = count; if (sym_data == NULL) { free(printable_sects); free(scn_names); print_error(dbg, "problem reading Elf32 symbol table data", DW_DLV_OK, err); } } else { get_reloc_section(dbg,scn,scn_name,shdr32->sh_type, printable_sects,sect_number); } } /* End while. */ /* Set the relocation names based on the machine type */ set_relocation_table_names(ehdr32->e_machine); for (i = 1; i < ehdr32->e_shnum + 1; i++) { if (printable_sects[i].display && printable_sects[i].buf != NULL && printable_sects[i].size > 0) { print_reloc_information_32(i, printable_sects[i].buf, printable_sects[i].size, printable_sects[i].type, scn_names,scn_names_cnt); } } free(printable_sects); free(scn_names); scn_names = 0; scn_names_cnt = 0; } #if HAVE_ELF64_R_INFO #ifndef ELF64_R_TYPE #define ELF64_R_TYPE(x) 0 /* FIXME */ #endif #ifndef ELF64_R_SYM #define ELF64_R_SYM(x) 0 /* FIXME */ #endif #ifndef ELF64_ST_TYPE #define ELF64_ST_TYPE(x) 0 /* FIXME */ #endif #ifndef ELF64_ST_BIND #define ELF64_ST_BIND(x) 0 /* FIXME */ #endif #endif /* HAVE_ELF64_R_INFO */ static void print_reloc_information_64(int section_no, Dwarf_Small * buf, Dwarf_Unsigned size, Elf64_Xword type, char **scn_names,int scn_names_count) { /* Include support for Elf64_Rel and Elf64_Rela */ Dwarf_Unsigned add = 0; Dwarf_Half rel_size = SHT_RELA == type ? sizeof(Elf64_Rela) : sizeof(Elf64_Rel); Dwarf_Unsigned off = 0; struct esb_s tempesb; printf("\n[%3d] %s:\n",section_no, sanitized(scn_names[section_no])); /* Print some headers and change the order for better reading */ printf("Offset Addend %-26s Index Symbol Name\n","Reloc Type"); #if HAVE_ELF64_GETEHDR for (off = 0; off < size; off += rel_size) { #if HAVE_ELF64_R_INFO /* This works for the Elf64_Rel in linux */ Elf64_Rel *p = (Elf64_Rel *) (buf + off); char *name = 0; /* We subtract 1 from sym indexes since we left symtab entry 0 out of the sym_data[_64] array */ if (sym_data ) { size_t index = ELF64_R_SYM(p->r_info) - 1; if (index < sym_data_entry_count) { name = sym_data[index].name; } } else if (sym_data_64) { size_t index = ELF64_R_SYM(p->r_info) - 1; if (index < sym_data_64_entry_count) { name = sym_data_64[index].name; } } /* When the name is not available, use the section name as a reference for the name.*/ if (!name || !name[0]) { size_t index = ELF64_R_SYM(p->r_info) - 1; if (index < sym_data_64_entry_count) { SYM64 *sym_64 = &sym_data_64[index]; if (sym_64->type == STT_SECTION && sym_64->shndx < scn_names_count) { name = scn_names[sym_64->shndx]; } } } if (!name || !name[0]) { name = ""; } if (SHT_RELA == type) { Elf64_Rela *pa = (Elf64_Rela *)p; add = pa->r_addend; } esb_constructor(&tempesb); esb_append(&tempesb,sanitized( get_reloc_type_names(ELF64_R_TYPE(p->r_info)))); /* sanitized uses a static buffer, call just once here */ printf("0x%08lx 0x%08lx %-26s <%5ld> %s\n", (unsigned long int) (p->r_offset), (unsigned long int) (add), esb_get_string(&tempesb), (long)ELF64_R_SYM(p->r_info), sanitized(name)); esb_destructor(&tempesb); #else /* sgi/mips -64 does not have r_info in the 64bit relocations, but seperate fields, with 3 types, actually. Only one of which prints here, as only one really used with dwarf */ Elf64_Rel *p = (Elf64_Rel *) (buf + off); char *name = 0; /* We subtract 1 from sym indexes since we left symtab entry 0 out of the sym_data[_64] array */ if (sym_data ) { size_t index = p->r_sym - 1; if (index < sym_data_entry_count) { name = sym_data[index].name; } } else if (sym_data_64) { size_t index = p->r_sym - 1; if (index < sym_data_64_entry_count) { name = sym_data_64[index].name; } } if (!name || !name[0]) { name = ""; } /* sanitized uses a static buffer, call just once here */ esb_constructor(&tempesb); esb_append(&tempesb, sanitized( get_reloc_type_names(p->r_type))); /* sanitized uses a static buffer, call just once here */ printf("%5" DW_PR_DUu " %-26s <%3ld> %s\n", (Dwarf_Unsigned) (p->r_offset), esb_get_string(&tempesb), (long)p->r_sym, sanitized(name)); esb_destructor(&tempesb); #endif } #endif /* HAVE_ELF64_GETEHDR */ } static void print_reloc_information_32(int section_no, Dwarf_Small * buf, Dwarf_Unsigned size, Elf64_Xword type, char **scn_names, int scn_names_count) { /* Include support for Elf32_Rel and Elf32_Rela */ Dwarf_Unsigned add = 0; Dwarf_Half rel_size = SHT_RELA == type ? sizeof(Elf32_Rela) : sizeof(Elf32_Rel); Dwarf_Unsigned off = 0; struct esb_s tempesb; printf("\n[%3d] %s:\n",section_no, sanitized(scn_names[section_no])); /* Print some headers and change the order for better reading. */ printf("Offset Addend %-26s Index Symbol Name\n","Reloc Type"); for (off = 0; off < size; off += rel_size) { Elf32_Rel *p = (Elf32_Rel *) (buf + off); char *name = 0; /* We subtract 1 from sym indexes since we left symtab entry 0 out of the sym_data[_64] array */ if (sym_data) { size_t index = ELF32_R_SYM(p->r_info) - 1; if (index < sym_data_entry_count) { name = sym_data[index].name; } } /* When the name is not available, use the section name as a reference for the name. */ if (!name || !name[0]) { size_t index = ELF32_R_SYM(p->r_info) - 1; if (index < sym_data_entry_count) { SYM *sym = &sym_data[index]; if (sym->type == STT_SECTION&& sym->shndx < scn_names_count) { name = scn_names[sym->shndx]; } } } if (!name || !name[0]) { name = ""; } if (SHT_RELA == type) { Elf32_Rela *pa = (Elf32_Rela *)p; add = pa->r_addend; } esb_constructor(&tempesb); esb_append(&tempesb,sanitized( get_reloc_type_names(ELF32_R_TYPE(p->r_info)))); printf("0x%08lx 0x%08lx %-26s <%5ld> %s\n", (unsigned long int) (p->r_offset), (unsigned long int) (add), esb_get_string(&tempesb), (long)ELF32_R_SYM(p->r_info), sanitized(name)); esb_destructor(&tempesb); } } /* We are only reading and saving syms 1...num-1. */ static SYM * readsyms(Elf32_Sym * data, size_t num, Elf * elf, Elf32_Word link) { SYM *s = 0; SYM *buf = 0; indx_type i = 0; buf = (SYM *) calloc(num, sizeof(SYM)); if (buf == NULL) { return NULL; } s = buf; /* save pointer to head of array */ for (i = 0; i < num; i++, data++, buf++) { buf->indx = i; buf->name = (char *) elf_strptr(elf, link, data->st_name); buf->value = data->st_value; buf->size = data->st_size; buf->type = ELF32_ST_TYPE(data->st_info); buf->bind = ELF32_ST_BIND(data->st_info); buf->other = data->st_other; buf->shndx = data->st_shndx; } /* end for loop */ return (s); } /* We are only reading and saving syms 1...num-1. */ static SYM64 * read_64_syms(Elf64_Sym * data, size_t num, Elf * elf, Elf64_Word link) { #ifdef HAVE_ELF64_GETEHDR SYM64 *s = 0; SYM64 *buf = 0; indx_type i = 0; buf = (SYM64 *) calloc(num, sizeof(SYM64)); if (buf == NULL) { return NULL; } s = buf; /* save pointer to head of array */ for (i = 0; i < num; i++, data++, buf++) { buf->indx = i; buf->name = (char *) elf_strptr(elf, link, data->st_name); buf->value = data->st_value; buf->size = data->st_size; buf->type = ELF64_ST_TYPE(data->st_info); buf->bind = ELF64_ST_BIND(data->st_info); buf->other = data->st_other; buf->shndx = data->st_shndx; } /* end for loop */ return (s); #else return 0; #endif /* HAVE_ELF64_GETEHDR */ } static void * get_scndata(Elf_Scn * fd_scn, size_t * scn_size) { Elf_Data *p_data; p_data = 0; if ((p_data = elf_getdata(fd_scn, p_data)) == 0 || p_data->d_size == 0) { return NULL; } *scn_size = p_data->d_size; return (p_data->d_buf); } /* Cleanup of malloc space (some of the pointers will be 0 here) so dwarfdump looks 'clean' to a malloc checker. */ void clean_up_syms_malloc_data() { free(sym_data); sym_data = 0; free(sym_data_64); sym_data_64 = 0; sym_data_64_entry_count = 0; sym_data_entry_count = 0; } #endif /* !SELFTEST */ #ifdef SELFTEST /* SELFTEST here is just to check on table internal consistency. */ int main() { int failcount = 0; unsigned long i = 1; for ( ; i < DW_SECTION_REL_ARRAY_SIZE; ++i) { if (rel_info[i].index != i) { printf(" FAIL rel_info check, i = %lu vs %lu\n", i, (unsigned long)rel_info[i].index); ++failcount; } } if(failcount) { printf("FAIL print_reloc selftest\n"); exit(1); } printf("PASS print_reloc selftest\n"); return 0; } #endif /* SELFTEST*/