/* Copyright (C) 2000,2004,2006 Silicon Graphics, Inc. All Rights Reserved. Portions Copyright (C) 2007-2019 David Anderson. All Rights Reserved. Portions Copyright 2002-2010 Sun Microsystems, Inc. All rights reserved. Portions Copyright 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 2.1 of the GNU Lesser 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 Lesser 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 "config.h" #include "libdwarfdefs.h" #include #ifdef HAVE_STRING_H #include #endif /* HAVE_STRING_H */ #ifdef HAVE_ELFACCESS_H #include #endif #ifdef HAVE_STDLIB_H #include #endif #ifdef HAVE_MALLOC_H /* Useful include for some Windows compilers. */ #include #endif /* HAVE_MALLOC_H */ #ifdef HAVE_STDDEF_H #include #endif /* HAVE_STDDEF_H */ #include "pro_incl.h" #include "dwarf.h" #include "libdwarf.h" #include "pro_opaque.h" #include "pro_error.h" #include "pro_util.h" #include "pro_encode_nm.h" #include "pro_alloc.h" #include "pro_section.h" #include "pro_line.h" #include "pro_frame.h" #include "pro_die.h" #include "pro_macinfo.h" #include "pro_types.h" #include "pro_dnames.h" #ifndef SHN_UNDEF #define SHN_UNDEF 0 #endif /* SHN_UNDEF */ #ifndef SHF_MIPS_NOSTRIP /* if this is not defined, we probably don't need it: just use 0 */ #define SHF_MIPS_NOSTRIP 0 #endif #ifndef R_MIPS_NONE #define R_MIPS_NONE 0 #endif #ifndef TRUE #define TRUE 1 #endif #ifndef FALSE #define FALSE 0 #endif #ifdef WORDS_BIGENDIAN #define ASNOUT(t,s,l) \ do { \ unsigned sbyte = 0; \ const char *p = 0; \ if (l > sizeof(s)) { \ _dwarf_p_error(dbg, error, DW_DLE_DEBUG_FRAME_LENGTH_BAD);\ return DW_DLV_ERROR; \ } \ sbyte = sizeof(s) - l; \ p = (const char *)(&s); \ dbg->de_copy_word(t,(const void *)(p+sbyte),l);\ } while (0) #else /* LITTLEENDIAN */ #define ASNOUT(t,s,l) \ do { \ const char *p = 0; \ if (l > sizeof(s)) { \ _dwarf_p_error(dbg, error, DW_DLE_DEBUG_FRAME_LENGTH_BAD);\ return DW_DLV_ERROR; \ } \ p = (const char *)(&s); \ dbg->de_copy_word(t,(const void *)p,l); \ } while (0) #endif /* ENDIANNESS */ #define SIZEOFT32 4 struct Dwarf_Sort_Abbrev_s { Dwarf_Unsigned dsa_attr; Dwarf_Unsigned dsa_form; Dwarf_Signed dsa_implicitvalue; Dwarf_P_Attribute dsa_attrp; }; /* Must match up with pro_section.h defines of DEBUG_INFO etc and sectnames (below). REL_SEC_PREFIX is either ".rel" or ".rela" see pro_incl.h */ const char *_dwarf_rel_section_names[] = { REL_SEC_PREFIX ".debug_info", REL_SEC_PREFIX ".debug_line", REL_SEC_PREFIX ".debug_abbrev", /* Nothing here refers to anything. */ REL_SEC_PREFIX ".debug_frame", REL_SEC_PREFIX ".debug_aranges", REL_SEC_PREFIX ".debug_pubnames", REL_SEC_PREFIX ".debug_funcnames", /* sgi extension */ REL_SEC_PREFIX ".debug_typenames", /* sgi extension */ REL_SEC_PREFIX ".debug_varnames", /* sgi extension */ REL_SEC_PREFIX ".debug_weaknames", /* sgi extension */ REL_SEC_PREFIX ".debug_macinfo", REL_SEC_PREFIX ".debug_loc", REL_SEC_PREFIX ".debug_ranges", REL_SEC_PREFIX ".debug_types", /* new in DWARF4 */ REL_SEC_PREFIX ".debug_pubtypes", /* new in DWARF3 */ REL_SEC_PREFIX ".debug_names", /* DWARF5 aka dnames */ REL_SEC_PREFIX ".debug_str", /* Nothing here refers to anything.*/ REL_SEC_PREFIX ".debug_rnglists", /* DWARF5. */ REL_SEC_PREFIX ".debug_line_str", /* DWARF5. Nothing referselsewhere */ REL_SEC_PREFIX ".debug_macro", /* DWARF5. */ REL_SEC_PREFIX ".debug_loclists", /* DWARF5. */ REL_SEC_PREFIX ".debug_rnglists", /* DWARF5. */ }; /* names of sections. Ensure that it matches the defines in pro_section.h, in the same order Must match also _dwarf_rel_section_names above */ const char *_dwarf_sectnames[] = { ".debug_info", ".debug_line", ".debug_abbrev", ".debug_frame", ".debug_aranges", ".debug_pubnames", ".debug_funcnames", /* sgi extension */ ".debug_typenames", /* sgi extension */ ".debug_varnames", /* sgi extension */ ".debug_weaknames", /* sgi extension */ ".debug_macinfo", ".debug_loc", ".debug_ranges", ".debug_types", /* new in DWARF4 */ ".debug_pubtypes", /* new in DWARF3 */ ".debug_names", /* new in DWARF5. aka dnames */ ".debug_str", ".debug_line_str", /* new in DWARF5 */ ".debug_macro", /* new in DWARF5 */ ".debug_loclists", /* new in DWARF5 */ ".debug_rnglists", /* new in DWARF5 */ }; static const Dwarf_Ubyte std_opcode_len[] = { 0, /* DW_LNS_copy */ 1, /* DW_LNS_advance_pc */ 1, /* DW_LNS_advance_line */ 1, /* DW_LNS_set_file */ 1, /* DW_LNS_set_column */ 0, /* DW_LNS_negate_stmt */ 0, /* DW_LNS_set_basic_block */ 0, /* DW_LNS_const_add_pc */ 1, /* DW_LNS_fixed_advance_pc */ /* The following for DWARF3 and DWARF4, though GNU uses these in DWARF2 as well. */ 0, /* DW_LNS_set_prologue_end */ 0, /* DW_LNS_set_epilogue_begin */ 1, /* DW_LNS_set_isa */ }; /* struct to hold relocation entries. Its mantained as a linked list of relocation structs, and will then be written at as a whole into the relocation section. Whether its 32 bit or 64 bit will be obtained from Dwarf_Debug pointer. */ typedef struct Dwarf_P_Rel_s *Dwarf_P_Rel; struct Dwarf_P_Rel_s { Dwarf_P_Rel dr_next; void *dr_rel_datap; }; typedef struct Dwarf_P_Rel_Head_s *Dwarf_P_Rel_Head; struct Dwarf_P_Rel_Head_s { struct Dwarf_P_Rel_s *drh_head; struct Dwarf_P_Rel_s *drh_tail; }; static int _dwarf_pro_generate_debug_line_str(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error); static int _dwarf_pro_generate_debug_names(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error); static int _dwarf_pro_generate_debug_str(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error); static int _dwarf_pro_generate_debugline(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error); static int _dwarf_pro_generate_debugframe(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error); static int _dwarf_pro_generate_debuginfo(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error); #if 0 static void dump_bytes(char * msg,Dwarf_Small * start, long len) { Dwarf_Small *end = start + len; Dwarf_Small *cur = start; printf("%s len %ld ",msg,len); for (; cur < end; cur++) { printf("%02x ", *cur); } printf("\n"); } #endif #if 0 static void print_single_abbrev(Dwarf_P_Abbrev c, unsigned idx) { unsigned j = 0; printf(" %2u idx %2u tag 0x%x attrct %2u\n",idx, (unsigned)c->abb_idx, (unsigned)c->abb_tag, (unsigned)c->abb_n_attr); for ( ; j < (unsigned)c->abb_n_attr; ++j) { printf(" %2u attr 0x%2x form 0x%2x impl val %" DW_PR_DSd "\n", j, (unsigned)c->abb_attrs[j], (unsigned)c->abb_forms[j]); (unsigned)c->abb_implicits[j]); } } static void print_curabbrev(const char *where, Dwarf_P_Abbrev curabbrev) { Dwarf_P_Abbrev ca = 0; unsigned i = 0; for(ca = curabbrev; ca ; ca = ca->abb_next,++i) { printf("ABBREV %u from %s\n",i,where); print_single_abbrev(ca,i); } } #endif /* These macros used as return value for _dwarf_pro_get_opc. */ #define OPC_INCS_ZERO -1 #define OPC_OUT_OF_RANGE -2 #define LINE_OUT_OF_RANGE -3 /* Given address advance and line advance, it gives either special opcode, or a number < 0 FIXME: Check all three negative values. Are any negatives really hard errors? */ static int _dwarf_pro_get_opc( struct Dwarf_P_Line_Inits_s *inits, Dwarf_Unsigned addr_adv, int line_adv) { int line_base = inits->pi_line_base; int line_range =inits->pi_line_range; Dwarf_Unsigned factored_adv = 0; factored_adv = addr_adv / inits->pi_minimum_instruction_length; if (line_adv == 0 && factored_adv == 0) { return OPC_INCS_ZERO; } if (line_adv >= line_base && line_adv < line_base + line_range) { int opc = 0; opc = (line_adv - line_base) + (factored_adv * line_range) + inits->pi_opcode_base; if (opc > 255) { return OPC_OUT_OF_RANGE; } return opc; } return LINE_OUT_OF_RANGE; } /* OFFSET_PLUS_EXTENSION_SIZE is the size of the 'length' field in total. Which may be 4,8, or 12 bytes! 4 is standard DWARF2. 8 is non-standard MIPS-IRIX 64-bit. 12 is standard DWARF3 for 64 bit offsets. Used in various routines: local variable names must match the names here. */ #define OFFSET_PLUS_EXTENSION_SIZE (offset_size + extension_size) /* Return TRUE if we need the section, FALSE otherwise If any of the 'line-data-related' calls were made including file or directory entries, produce .debug_line . */ static int dwarf_need_debug_line_section(Dwarf_P_Debug dbg) { if (dbg->de_output_version > 4) { return FALSE; } if (dbg->de_lines == NULL && dbg->de_file_entries == NULL && dbg->de_inc_dirs == NULL) { return FALSE; } return TRUE; } /* DWARF5 only. */ static int dwarf_need_debug_names_section(Dwarf_P_Debug dbg) { if (dbg->de_output_version < 5) { return FALSE; } if (!dbg->de_dnames) { return FALSE; } if (!dbg->de_dnames->dn_create_section) { return FALSE; } return TRUE; } /* Convert debug information to a format such that it can be written on disk. Called exactly once per execution. This is the traditional interface. Bad interface design. */ Dwarf_Signed dwarf_transform_to_disk_form(Dwarf_P_Debug dbg, Dwarf_Error * error) { Dwarf_Signed count = 0; int res = 0; res = dwarf_transform_to_disk_form_a(dbg, &count,error); if (res == DW_DLV_ERROR) { return DW_DLV_NOCOUNT; } return count; } /* Convert debug information to a format such that it can be written on disk. Called exactly once per execution. This is the interface design used with the consumer interface, so easier for callers to work with. */ int dwarf_transform_to_disk_form_a(Dwarf_P_Debug dbg, Dwarf_Signed *count, Dwarf_Error * error) { /* Section data in written out in a number of buffers. Each _generate_*() function returns a cumulative count of buffers for all the sections. dwarf_get_section_bytes() returns pointers to these buffers one at a time. */ Dwarf_Signed nbufs = 0; int sect = 0; int err = 0; Dwarf_Unsigned du = 0; if (dbg->de_version_magic_number != PRO_VERSION_MAGIC) { DWARF_P_DBG_ERROR(dbg, DW_DLE_IA, DW_DLV_ERROR); } /* Create dwarf section headers */ for (sect = 0; sect < NUM_DEBUG_SECTIONS; sect++) { long flags = 0; switch (sect) { case DEBUG_INFO: if (dbg->de_dies == NULL) { continue; } break; case DEBUG_LINE: if (dwarf_need_debug_line_section(dbg) == FALSE) { continue; } break; case DEBUG_ABBREV: if (dbg->de_dies == NULL) { continue; } break; case DEBUG_FRAME: if (dbg->de_frame_cies == NULL) { continue; } flags = SHF_MIPS_NOSTRIP; break; case DEBUG_ARANGES: if (dbg->de_arange == NULL) { continue; } break; case DEBUG_PUBNAMES: if (dbg->de_simple_name_headers[dwarf_snk_pubname]. sn_head == NULL) { continue; } break; case DEBUG_PUBTYPES: if (dbg->de_simple_name_headers[dwarf_snk_pubtype]. sn_head == NULL) { continue; } break; case DEBUG_STR: if (dbg->de_debug_str->ds_data == NULL) { continue; } break; case DEBUG_FUNCNAMES: if (dbg->de_simple_name_headers[dwarf_snk_funcname]. sn_head == NULL) { continue; } break; case DEBUG_TYPENAMES: if (dbg->de_simple_name_headers[dwarf_snk_typename]. sn_head == NULL) { continue; } break; case DEBUG_VARNAMES: if (dbg->de_simple_name_headers[dwarf_snk_varname]. sn_head == NULL) { continue; } break; case DEBUG_WEAKNAMES: if (dbg->de_simple_name_headers[dwarf_snk_weakname]. sn_head == NULL) { continue; } break; case DEBUG_MACINFO: if (dbg->de_first_macinfo == NULL) { continue; } break; case DEBUG_NAMES: /* DWARF5 */ if (dwarf_need_debug_names_section(dbg) == FALSE) { continue; } break; case DEBUG_LOC: /* Not handled yet. */ continue; case DEBUG_RANGES: /* Not handled yet. */ continue; case DEBUG_TYPES: /* Not handled yet. */ continue; case DEBUG_MACRO: /* Not handled yet. */ continue; case DEBUG_LOCLISTS: /* Not handled yet. */ continue; case DEBUG_RNGLISTS: /* Not handled yet. */ continue; case DEBUG_LINE_STR: if (dwarf_need_debug_line_section(dbg) == FALSE) { continue; } /* Not handled yet. */ continue; default: /* logic error: missing a case */ DWARF_P_DBG_ERROR(dbg, DW_DLE_ELF_SECT_ERR, DW_DLV_ERROR); } { int new_base_elf_sect = 0; if (dbg->de_callback_func) { new_base_elf_sect = dbg->de_callback_func(_dwarf_sectnames[sect], /* rec size */ 1, SECTION_TYPE, flags, SHN_UNDEF, 0, &du, dbg->de_user_data, &err); } if (new_base_elf_sect == -1) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ELF_SECT_ERR, DW_DLV_ERROR); } dbg->de_elf_sects[sect] = new_base_elf_sect; dbg->de_sect_name_idx[sect] = du; } } nbufs = 0; /* Changing the order in which the sections are generated may cause problems because of relocations. */ if (dwarf_need_debug_line_section(dbg) == TRUE) { int res = _dwarf_pro_generate_debugline(dbg,&nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_frame_cies) { int res = _dwarf_pro_generate_debugframe(dbg,&nbufs,error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_first_macinfo) { /* For DWARF 2,3,4 only */ /* Need new code for DWARF5 macro info. FIXME*/ int res = _dwarf_pro_transform_macro_info_to_disk(dbg, &nbufs,error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_dies) { int res= _dwarf_pro_generate_debuginfo(dbg, &nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_debug_str->ds_data) { int res = _dwarf_pro_generate_debug_str(dbg,&nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_debug_line_str->ds_data) { int res = _dwarf_pro_generate_debug_line_str(dbg,&nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_arange) { int res = _dwarf_transform_arange_to_disk(dbg,&nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_output_version < 5) { if (dbg->de_simple_name_headers[dwarf_snk_pubname].sn_head) { int res = _dwarf_transform_simplename_to_disk(dbg, dwarf_snk_pubname, DEBUG_PUBNAMES, &nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_simple_name_headers[dwarf_snk_pubtype].sn_head) { int res = _dwarf_transform_simplename_to_disk(dbg, dwarf_snk_pubtype, DEBUG_PUBTYPES, &nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_simple_name_headers[dwarf_snk_funcname].sn_head) { int res = _dwarf_transform_simplename_to_disk(dbg, dwarf_snk_funcname, DEBUG_FUNCNAMES, &nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_simple_name_headers[dwarf_snk_typename].sn_head) { int res = _dwarf_transform_simplename_to_disk(dbg, dwarf_snk_typename, DEBUG_TYPENAMES, &nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_simple_name_headers[dwarf_snk_varname].sn_head) { int res = _dwarf_transform_simplename_to_disk(dbg, dwarf_snk_varname, DEBUG_VARNAMES, &nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dbg->de_simple_name_headers[dwarf_snk_weakname].sn_head) { int res = _dwarf_transform_simplename_to_disk(dbg, dwarf_snk_weakname, DEBUG_WEAKNAMES, &nbufs, error); if (res == DW_DLV_ERROR) { return res; } } } if (dwarf_need_debug_names_section(dbg) == TRUE) { int res = _dwarf_pro_generate_debug_names(dbg,&nbufs, error); if (res == DW_DLV_ERROR) { return res; } } #if 0 /* FIXME: TODO new sections */ if (dwarf_need_debug_macro_section(dbg) == TRUE) { int res = _dwarf_pro_generate_debug_macro(dbg,&nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dwarf_need_debug_loclists_section(dbg) == TRUE) { int res = _dwarf_pro_generate_debug_loclists(dbg,&nbufs, error); if (res == DW_DLV_ERROR) { return res; } } if (dwarf_need_debug_rnglists_section(dbg) == TRUE) { int res = _dwarf_pro_generate_debug_rnglists(dbg,&nbufs, error); if (res == DW_DLV_ERROR) { return res; } } #endif { Dwarf_Signed new_chunks = 0; int res = 0; res = dbg->de_transform_relocs_to_disk(dbg, &new_chunks); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_RELOCS_ERROR, DW_DLV_ERROR); } nbufs += new_chunks; } *count = nbufs; return DW_DLV_OK; } static int write_fixed_size(Dwarf_Unsigned val, Dwarf_P_Debug dbg, int elfsectno, Dwarf_Unsigned size, unsigned * size_out, Dwarf_Error* error) { unsigned char *data = 0; GET_CHUNK_ERR(dbg, elfsectno, data, size, error); WRITE_UNALIGNED(dbg, (void *) data, (const void *) &val, sizeof(val), size); *size_out = size; return DW_DLV_OK; } static int write_ubyte(unsigned val, Dwarf_P_Debug dbg, int elfsectno, unsigned *len_out, Dwarf_Error* error) { Dwarf_Ubyte db = val; unsigned char *data = 0; unsigned len = sizeof(Dwarf_Ubyte); GET_CHUNK_ERR(dbg, elfsectno, data, len, error); WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), len); *len_out = 1; return DW_DLV_OK;; } static int pretend_write_uval(Dwarf_Unsigned val, Dwarf_P_Debug dbg, unsigned *uval_len_out, Dwarf_Error* error) { char buff1[ENCODE_SPACE_NEEDED]; int nbytes = 0; int res = 0; res = _dwarf_pro_encode_leb128_nm(val, &nbytes, buff1, sizeof(buff1)); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg,DW_DLE_LEB_OUT_ERROR , DW_DLV_ERROR); } *uval_len_out = nbytes; return DW_DLV_OK; } static int write_sval(Dwarf_Signed val, Dwarf_P_Debug dbg, int elfsectno, unsigned *sval_len_out, Dwarf_Error* error) { char buff1[ENCODE_SPACE_NEEDED]; unsigned char *data = 0; int nbytes = 0; int res = _dwarf_pro_encode_signed_leb128_nm(val, &nbytes, buff1, sizeof(buff1)); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_LEB_OUT_ERROR, DW_DLV_ERROR); } GET_CHUNK(dbg, elfsectno, data, nbytes, error); memcpy((void *) data, (const void *) buff1, nbytes); *sval_len_out = nbytes; return DW_DLV_OK; } /* This one does not allocate a chunk, uses an already existing chunk. data points into that existing chunk. */ static int append_uval(Dwarf_Unsigned val, Dwarf_P_Debug dbg, unsigned char *data, unsigned * uval_len_out, Dwarf_Error* error) { char buff1[ENCODE_SPACE_NEEDED]; int nbytes = 0; int res = _dwarf_pro_encode_leb128_nm(val, &nbytes, buff1, sizeof(buff1)); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_LEB_OUT_ERROR, DW_DLV_ERROR); } memcpy((void *) data, (const void *) buff1, nbytes); *uval_len_out = nbytes; return DW_DLV_OK; } static int write_uval(Dwarf_Unsigned val, Dwarf_P_Debug dbg, int elfsectno, unsigned * uval_len_out, Dwarf_Error* error) { char buff1[ENCODE_SPACE_NEEDED]; unsigned char *data = 0; int nbytes = 0; int res = _dwarf_pro_encode_leb128_nm(val, &nbytes, buff1, sizeof(buff1)); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_LEB_OUT_ERROR, DW_DLV_ERROR); } GET_CHUNK_ERR(dbg, elfsectno, data, nbytes, error); memcpy((void *) data, (const void *) buff1, nbytes); *uval_len_out = nbytes; return DW_DLV_OK; } static unsigned write_opcode_uval(int opcode, Dwarf_P_Debug dbg, int elfsectno, Dwarf_Unsigned val, unsigned *len_out, Dwarf_Error* error) { unsigned ublen = 0; int res = 0; unsigned uvlen = 0; res = write_ubyte(opcode,dbg,elfsectno,&ublen,error); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_LEB_OUT_ERROR, DW_DLV_ERROR); } res = write_uval(val,dbg,elfsectno,&uvlen,error); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_LEB_OUT_ERROR, DW_DLV_ERROR); } *len_out = ublen +uvlen; return DW_DLV_OK; } static int determine_form_size(Dwarf_P_Debug dbg, unsigned format_count, struct Dwarf_P_Line_format_s *format, unsigned *size_out, Dwarf_Bool write_out, unsigned char *data, Dwarf_Error *error) { unsigned calculated_size = 0; unsigned n = 0; int res = 0; /* entry format itself */ calculated_size += sizeof_ubyte(dbg); /* Space for the format details. */ for(n = 0; n < format_count; ++n) { struct Dwarf_P_Line_format_s *lf = format+n; unsigned val_len = 0; unsigned val_len2 = 0; if (write_out) { res = append_uval(lf->def_content_type, dbg, data, &val_len,error); } else { res = pretend_write_uval(lf->def_content_type, dbg, &val_len,error); } data += val_len; if(res != DW_DLV_OK) { return res; } if (write_out) { res = append_uval(lf->def_form_code, dbg, data, &val_len2,error); } else { res = pretend_write_uval(lf->def_form_code, dbg, &val_len2,error); } if(res != DW_DLV_OK) { return res; } data += val_len2; calculated_size += val_len + val_len2; } *size_out = calculated_size; return DW_DLV_OK; } static int determine_file_content_size(Dwarf_P_Debug dbg, Dwarf_P_F_Entry entry_list, Dwarf_Unsigned format_count, struct Dwarf_P_Line_format_s *format, unsigned *size_out, Dwarf_Bool write_out, unsigned char *data, Dwarf_Error *error) { unsigned calculated_size = 0; unsigned count_len = 0; Dwarf_P_F_Entry cur = 0; Dwarf_P_F_Entry nxt = 0; unsigned n = 0; int res = 0; Dwarf_Unsigned offset_size = 0; offset_size = dbg->de_dwarf_offset_size; res = pretend_write_uval(format_count,dbg, &count_len,error); if(res != DW_DLV_OK) { return res; } calculated_size += count_len; cur = entry_list; for(n = 0; cur; n++,cur = nxt) { unsigned f = 0; nxt = cur->dfe_next; for( ; f < format_count; f++) { struct Dwarf_P_Line_format_s *lf = format+f; unsigned ctype = lf->def_content_type; unsigned cform = lf->def_form_code; switch (ctype) { case DW_LNCT_path: { switch(cform) { case DW_FORM_string: { unsigned slen = strlen(cur->dfe_name) +1; calculated_size += slen; if (write_out) { strcpy((char *)data, cur->dfe_name); data += slen; } } break; case DW_FORM_strp: { unsigned slen = strlen(cur->dfe_name) +1; if (write_out) { Dwarf_Unsigned stroffset = 0; res = _dwarf_insert_or_find_in_debug_str( dbg, cur->dfe_name, _dwarf_hash_debug_str, slen, &stroffset,error); if (res != DW_DLV_OK) { return res; } WRITE_UNALIGNED(dbg, (void *) data, (const void *) &stroffset, sizeof(stroffset), offset_size); data += offset_size; } calculated_size += offset_size; } break; case DW_FORM_line_strp: { unsigned slen = strlen(cur->dfe_name) +1; if (write_out) { Dwarf_Unsigned stroffset = 0; res = _dwarf_insert_or_find_in_debug_str( dbg, cur->dfe_name, _dwarf_hash_debug_line_str, slen, &stroffset,error); if (res != DW_DLV_OK) { return res; } WRITE_UNALIGNED(dbg, (void *) data, (const void *) &stroffset, sizeof(stroffset), offset_size); data += offset_size; } calculated_size += offset_size; } break; case DW_FORM_strp_sup: /* Following in dwo only. */ case DW_FORM_strx: case DW_FORM_strx1: case DW_FORM_strx2: case DW_FORM_strx3: case DW_FORM_strx4: default: DWARF_P_DBG_ERROR(dbg, DW_DLE_LNCT_FORM_CODE_NOT_HANDLED, DW_DLV_ERROR); break; } } break; case DW_LNCT_directory_index: { switch(cform) { case DW_FORM_data1: calculated_size += 1; if (write_out) { unsigned char ub = cur->dfe_index; *data = ub; data += 1; } break; case DW_FORM_data2: calculated_size += DWARF_HALF_SIZE; if (write_out) { Dwarf_Half uh = cur->dfe_index; memcpy(data,&uh,DWARF_HALF_SIZE); data += DWARF_HALF_SIZE; } break; case DW_FORM_udata: { unsigned val_len = 0; if (write_out) { res = append_uval(cur->dfe_index, dbg, data, &val_len,error); data += val_len; } else { res = pretend_write_uval(cur->dfe_index, dbg, &val_len,error); } if (res != DW_DLV_OK) { return res; } calculated_size += val_len; } break; default: DWARF_P_DBG_ERROR(dbg, DW_DLE_LNCT_FORM_CODE_NOT_HANDLED, DW_DLV_ERROR); } } break; case DW_LNCT_timestamp: { switch(cform) { case DW_FORM_udata: { unsigned val_len = 0; if (write_out) { res = append_uval(cur->dfe_timestamp, dbg, data, &val_len,error); data += val_len; } else { res = pretend_write_uval(cur->dfe_timestamp, dbg, &val_len,error); } if (res != DW_DLV_OK) { return res; } calculated_size += val_len; } break; case DW_FORM_data4: { calculated_size += DWARF_32BIT_SIZE; if (write_out) { ASNOUT(data,cur->dfe_timestamp, DWARF_32BIT_SIZE); data += DWARF_32BIT_SIZE; } } break; case DW_FORM_data8: /* As of 2017 there is no 8 byte timestamp defined, though it does have to happen. before 2038. */ calculated_size += DWARF_64BIT_SIZE; if (write_out) { Dwarf_Unsigned u8 = cur->dfe_index; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &u8, sizeof(u8), DWARF_64BIT_SIZE); data += DWARF_64BIT_SIZE; } break; case DW_FORM_block: default: DWARF_P_DBG_ERROR(dbg, DW_DLE_LNCT_FORM_CODE_NOT_HANDLED, DW_DLV_ERROR); } } break; case DW_LNCT_size: { switch(cform) { case DW_FORM_data1: calculated_size += 1; if (write_out) { unsigned char ub = cur->dfe_index; *data = ub; data += 1; } break; case DW_FORM_data2: calculated_size += DWARF_HALF_SIZE; if (write_out) { Dwarf_Half uh = cur->dfe_index; memcpy(data,&uh,DWARF_HALF_SIZE); } break; case DW_FORM_data4: calculated_size += DWARF_32BIT_SIZE; if (write_out) { ASNOUT(data,cur->dfe_index, DWARF_32BIT_SIZE); data += DWARF_32BIT_SIZE; } break; case DW_FORM_data8: calculated_size += DWARF_64BIT_SIZE; if (write_out) { Dwarf_Unsigned u8 = cur->dfe_index; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &u8, sizeof(u8), DWARF_64BIT_SIZE); data += DWARF_64BIT_SIZE; } break; case DW_FORM_udata: { unsigned val_len = 0; if (write_out) { res = append_uval(cur->dfe_size, dbg, data, &val_len,error); data += val_len; } else { res = pretend_write_uval(cur->dfe_size, dbg, &val_len,error); } if (res != DW_DLV_OK) { return res; } calculated_size += val_len; } break; default: DWARF_P_DBG_ERROR(dbg, DW_DLE_LNCT_FORM_CODE_NOT_HANDLED, DW_DLV_ERROR); } } break; case DW_LNCT_MD5: { switch(cform) { case DW_FORM_data16: if (write_out) { memcpy(data,cur->dfe_md5,sizeof(cur->dfe_md5)); data += 16; } calculated_size += 16; break; default: DWARF_P_DBG_ERROR(dbg, DW_DLE_LNCT_FORM_CODE_NOT_HANDLED, DW_DLV_ERROR); } } break; default: DWARF_P_DBG_ERROR(dbg, DW_DLE_LNCT_CODE_UNKNOWN, DW_DLV_ERROR); } } } *size_out = calculated_size; return DW_DLV_OK; } static int calculate_size_of_line_header5(Dwarf_P_Debug dbg, struct Dwarf_P_Line_Inits_s *inits, unsigned *prolog_size_out, Dwarf_Error *error) { unsigned prolog_size = 0; int offset_size = dbg->de_dwarf_offset_size; int extension_size = dbg->de_64bit_extension ? 4 : 0; int res = 0; prolog_size += OFFSET_PLUS_EXTENSION_SIZE + sizeof_uhalf(dbg) + /* version # */ sizeof_ubyte(dbg) + /* address_size */ sizeof_ubyte(dbg) + /* segment_selector_size */ offset_size + /* header length */ sizeof_ubyte(dbg) + /* min_instr length */ sizeof_ubyte(dbg) + /* maximum_operations_per_instruction */ sizeof_ubyte(dbg) + /* default is_stmt */ sizeof_ubyte(dbg) + /* linebase */ sizeof_ubyte(dbg) + /* linerange */ sizeof_ubyte(dbg); /* opcode base */ /* For maximum_operations_per_instruction. */ prolog_size += sizeof_ubyte(dbg); /* standard_opcode_lengths table len */ prolog_size += inits->pi_opcode_base-1; { unsigned fsize = 0; res = determine_form_size(dbg, inits->pi_directory_entry_format_count, inits->pi_incformats, &fsize,FALSE,0,error); if (res != DW_DLV_OK) { return res; } prolog_size += fsize; } { unsigned dir_count_len = 0; res = determine_file_content_size(dbg, dbg->de_inc_dirs, dbg->de_line_inits.pi_directory_entry_format_count, dbg->de_line_inits.pi_incformats, &dir_count_len, FALSE,0, error); if (res != DW_DLV_OK) { return res; } prolog_size += dir_count_len; } { unsigned fsize = 0; res = determine_form_size(dbg, inits->pi_file_entry_format_count, inits->pi_fileformats, &fsize, FALSE,0, error); if (res != DW_DLV_OK) { return res; } prolog_size += fsize; } { unsigned file_count_len = 0; res = determine_file_content_size(dbg, dbg->de_file_entries, dbg->de_line_inits.pi_file_entry_format_count, dbg->de_line_inits.pi_fileformats, &file_count_len, FALSE,0, error); if (res != DW_DLV_OK) { return res; } prolog_size += file_count_len; } *prolog_size_out = prolog_size; return DW_DLV_OK; } /* For DWARF 2,3,4 */ static int calculate_size_of_line_header4(Dwarf_P_Debug dbg, struct Dwarf_P_Line_Inits_s *inits, unsigned *prolog_size_out, UNUSEDARG Dwarf_Error *error) { Dwarf_P_F_Entry curdir = 0; Dwarf_P_F_Entry curentry = 0; unsigned prolog_size = 0; int offset_size = dbg->de_dwarf_offset_size; int extension_size = dbg->de_64bit_extension ? 4 : 0; prolog_size += OFFSET_PLUS_EXTENSION_SIZE + sizeof_uhalf(dbg) + /* version # */ offset_size + /* header length */ sizeof_ubyte(dbg) + /* min_instr length */ sizeof_ubyte(dbg) + /* default is_stmt */ sizeof_ubyte(dbg) + /* linebase */ sizeof_ubyte(dbg) + /* linerange */ sizeof_ubyte(dbg); /* opcode base */ if (inits->pi_linetable_version == DW_LINE_VERSION4) { /* For maximum_operations_per_instruction. */ prolog_size += sizeof_ubyte(dbg); } /* standard_opcode_lengths table len */ prolog_size += inits->pi_opcode_base-1; /* include directories */ curdir = dbg->de_inc_dirs; while (curdir) { prolog_size += strlen(curdir->dfe_name) + 1; curdir = curdir->dfe_next; } prolog_size++; /* last null following last directory entry. */ /* file entries */ curentry = dbg->de_file_entries; while (curentry) { prolog_size += strlen(curentry->dfe_name) + 1 + curentry->dfe_nbytes; curentry = curentry->dfe_next; } prolog_size++; /* last null byte */ *prolog_size_out = prolog_size; return DW_DLV_OK; } /* Generate debug_line section Dwarf2, dwarf3 headers are the same (DW3 acknowledges 64bit). DWARF4 adds the maximum_operations_per_instruction field. DWARF5 adds address size and address selector size and replaces the entire directories/files list with very different stuff. */ static int _dwarf_pro_generate_debugline(Dwarf_P_Debug dbg, Dwarf_Signed * nbufs, Dwarf_Error * error) { Dwarf_P_F_Entry curdir = 0; Dwarf_P_F_Entry curentry = 0; Dwarf_P_Line curline = 0; Dwarf_P_Line prevline = 0; struct Dwarf_P_Line_Inits_s *inits = 0; /* all data named cur* are used to loop thru linked lists */ int sum_bytes = 0; unsigned prolog_size = 0; unsigned char *data = 0; /* holds disk form data */ int elfsectno = 0; unsigned char *start_line_sec = 0; /* pointer to the buffer at section start */ /* temps for memcpy */ Dwarf_Unsigned du = 0; Dwarf_Ubyte db = 0; Dwarf_Half dh = 0; int res = 0; Dwarf_Half version = dbg->de_output_version; int offset_size = dbg->de_dwarf_offset_size; Dwarf_Ubyte extension_size = dbg->de_64bit_extension ? 4 : 0; Dwarf_Ubyte address_size = dbg->de_pointer_size; sum_bytes = 0; elfsectno = dbg->de_elf_sects[DEBUG_LINE]; inits = &dbg->de_line_inits; if (version < 5) { res = calculate_size_of_line_header4(dbg,inits,&prolog_size, error); } else if (version == 5) { res = calculate_size_of_line_header5(dbg,inits,&prolog_size, error); } else { _dwarf_p_error(dbg, error,DW_DLE_VERSION_STAMP_ERROR ); return DW_DLV_ERROR; } if (res != DW_DLV_OK) { return res; } /* Allocate a chunk, put address in 'data' */ GET_CHUNK_ERR(dbg, elfsectno, data, prolog_size, error); start_line_sec = data; /* Copy the prologue data into 'data' */ /* total_length */ du = 0; if (extension_size) { DISTINGUISHED_VALUE_ARRAY(v4); WRITE_UNALIGNED(dbg, (void *) data, (const void *) &v4[0], SIZEOFT32, extension_size); data += extension_size; } /* We will adjust this later, we do not know the full length of the line_section content for this cu yet. */ WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; dh = inits->pi_linetable_version; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &dh, sizeof(dh), DWARF_HALF_SIZE); data += DWARF_HALF_SIZE; if (version == 5 ) { /* address size, seg sel size now */ db = inits->pi_address_size; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(db)); data += sizeof(db); db = inits->pi_segment_size; /* segment selector size */ WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(db)); data += sizeof(db); } { /* header length (called prolog length in DWARF2) This we do know, we calculated the prolog length already and it is prolog_size so just */ Dwarf_Unsigned sofar = data - start_line_sec; du = prolog_size - sofar - offset_size; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; } db = inits->pi_minimum_instruction_length; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); if (inits->pi_linetable_version == 4 || inits->pi_linetable_version == 5) { db = inits->pi_maximum_operations_per_instruction; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); } db = inits->pi_default_is_stmt; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); db = inits->pi_line_base; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); db = inits->pi_line_range; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); db = inits->pi_opcode_base; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); WRITE_UNALIGNED(dbg, (void *) data, (const void *) std_opcode_len, inits->pi_opcode_base-1, inits->pi_opcode_base-1); data += inits->pi_opcode_base-1; if (version < 5) { /* copy over include directories */ curdir = dbg->de_inc_dirs; while (curdir) { strcpy((char *) data, curdir->dfe_name); data += strlen(curdir->dfe_name) + 1; curdir = curdir->dfe_next; } *data = '\0'; /* last null */ data++; /* copy file entries */ curentry = dbg->de_file_entries; while (curentry) { strcpy((char *) data, curentry->dfe_name); data += strlen(curentry->dfe_name) + 1; /* copies of leb numbers, no endian issues */ memcpy((void *) data, (const void *) curentry->dfe_args, curentry->dfe_nbytes); data += curentry->dfe_nbytes; curentry = curentry->dfe_next; } *data = '\0'; data++; } else if (version == 5) { { unsigned fsize = 0; res = determine_form_size(dbg, inits->pi_directory_entry_format_count, inits->pi_incformats, &fsize, TRUE,data, error); if (res != DW_DLV_OK) { return res; } data += fsize; } { unsigned dir_count_len = 0; res = determine_file_content_size(dbg, dbg->de_inc_dirs, inits->pi_directory_entry_format_count, inits->pi_incformats, &dir_count_len, TRUE,data, error); if (res != DW_DLV_OK) { return res; } data += dir_count_len; } { unsigned fsize = 0; res = determine_form_size(dbg, inits->pi_file_entry_format_count, inits->pi_fileformats, &fsize, TRUE,data, error); if (res != DW_DLV_OK) { return res; } data += fsize; } { unsigned file_count_len = 0; res = determine_file_content_size(dbg, dbg->de_file_entries, dbg->de_line_inits.pi_file_entry_format_count, dbg->de_line_inits.pi_fileformats, &file_count_len, TRUE,data, error); if (res != DW_DLV_OK) { return res; } data += file_count_len; } } { Dwarf_Unsigned sofar = data - start_line_sec; if (sofar != prolog_size) { /* We miscalculated something. */ _dwarf_p_error(dbg, error, DW_DLE_LINE_HEADER_LENGTH_BOTCH); return DW_DLV_ERROR; } sum_bytes += prolog_size; } curline = dbg->de_lines; prevline = (Dwarf_P_Line) _dwarf_p_get_alloc(dbg, sizeof(struct Dwarf_P_Line_s)); if (prevline == NULL) { DWARF_P_DBG_ERROR(dbg, DW_DLE_LINE_ALLOC, DW_DLV_ERROR); } _dwarf_pro_reg_init(dbg,prevline); /* generate opcodes for line numbers */ while (curline) { int opc = 0; int no_lns_copy = 0; /* if lns copy opcode does not need to be generated, if special opcode or end sequence */ Dwarf_Unsigned addr_adv = 0; int line_adv = 0; /* supposed to be a reasonably small number, so the size should not be a problem. ? */ no_lns_copy = 0; if (curline->dpl_opc != 0) { int inst_bytes = 0; /* no of bytes in extended opcode */ unsigned writelen = 0; switch (curline->dpl_opc) { case DW_LNE_end_sequence: /* Advance pc to end of text section. */ addr_adv = curline->dpl_address - prevline->dpl_address; if (addr_adv > 0) { res = write_opcode_uval(DW_LNS_advance_pc,dbg, elfsectno, addr_adv/inits->pi_minimum_instruction_length, &writelen, error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_address = curline->dpl_address; } /* first null byte */ db = 0; res = write_ubyte(db,dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* write length of extended opcode */ inst_bytes = sizeof(Dwarf_Ubyte); res = write_uval(inst_bytes,dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* write extended opcode */ res = write_ubyte(DW_LNE_end_sequence,dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* reset value to original values */ _dwarf_pro_reg_init(dbg,prevline); no_lns_copy = 1; /* this is set only for end_sequence, so that a dw_lns_copy is not generated */ break; case DW_LNE_set_address: /* first null byte */ db = 0; res = write_ubyte(db,dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* write length of extended opcode */ inst_bytes = sizeof(Dwarf_Ubyte) + address_size; res = write_uval(inst_bytes,dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* write extended opcode */ res = write_ubyte(DW_LNE_set_address,dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* reloc for address */ res = dbg->de_relocate_by_name_symbol(dbg, DEBUG_LINE, sum_bytes, /* r_offset */ curline->dpl_r_symidx, dwarf_drt_data_reloc, offset_size); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CHUNK_ALLOC, DW_DLV_ERROR); } /* write offset (address) */ du = curline->dpl_address; res = write_fixed_size(du,dbg,elfsectno, address_size,&writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_address = curline->dpl_address; no_lns_copy = 1; break; case DW_LNE_define_file: /* Not supported, all add-file entries are added via dbg -> de_file_entries, which adds to the line table header. */ no_lns_copy = 1; break; case DW_LNE_set_discriminator: {/* DWARF4 */ unsigned val_len = 0; /* first null byte */ db = 0; res = write_ubyte(db,dbg,elfsectno,&writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* Write len of opcode + value here. */ res = pretend_write_uval(curline->dpl_discriminator, dbg, &val_len,error); if (res != DW_DLV_OK) { return res; } val_len++; res = write_uval(val_len +1,dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* Write opcode */ res = write_ubyte(DW_LNE_set_discriminator, dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* Write the value itself. */ res = write_uval(curline->dpl_discriminator, dbg,elfsectno,&writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; no_lns_copy = 1; } break; } } else { unsigned writelen = 0; if (inits->pi_opcode_base >12) { /* We have the newer standard opcodes DW_LNS_set_prologue_end, DW_LNS_set_epilogue_end, DW_LNS_set_isa, we do not write them if not in the table. DWARF3 and DWARF4 */ /* Should we check if a change? These reset automatically in the line processing/reading engine, so I think no check of prevline is wanted. */ if (curline->dpl_epilogue_begin) { res = write_ubyte(DW_LNS_set_epilogue_begin,dbg, elfsectno,&writelen, error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; } if (curline->dpl_prologue_end) { res = write_ubyte(DW_LNS_set_prologue_end,dbg, elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; } if (curline->dpl_isa != prevline->dpl_isa) { res = write_opcode_uval(DW_LNS_set_isa,dbg, elfsectno, curline->dpl_isa, &writelen ,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; } } if (curline->dpl_file != prevline->dpl_file) { db = DW_LNS_set_file; res = write_opcode_uval(db,dbg, elfsectno, curline->dpl_file,&writelen ,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_file = curline->dpl_file; } if (curline->dpl_column != prevline->dpl_column) { db = DW_LNS_set_column; res = write_opcode_uval(db,dbg, elfsectno, curline->dpl_column , &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_column = curline->dpl_column; } if (curline->dpl_is_stmt != prevline->dpl_is_stmt) { res = write_ubyte(DW_LNS_negate_stmt,dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_is_stmt = curline->dpl_is_stmt; } if (curline->dpl_basic_block == true && prevline->dpl_basic_block == false) { res = write_ubyte(DW_LNS_set_basic_block,dbg, elfsectno,&writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_basic_block = curline->dpl_basic_block; } if (curline->dpl_discriminator) { /* This is dwarf4, but because it is an extended op not a standard op, we allow it without testing version. GNU seems to set this from time to time. */ unsigned val_len = 0; /* first null byte */ db = 0; res = write_ubyte(db,dbg,elfsectno,&writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* Write len of opcode + value here. */ res = pretend_write_uval(curline->dpl_discriminator, dbg, &val_len,error); if (res != DW_DLV_OK) { return res; } val_len ++; res = write_uval(val_len +1,dbg,elfsectno, &writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* Write opcode */ res = write_ubyte(DW_LNE_set_discriminator, dbg,elfsectno,&writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; /* Write the value itself. */ res = write_uval(curline->dpl_discriminator, dbg,elfsectno,&writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; } addr_adv = curline->dpl_address - prevline->dpl_address; line_adv = (int) (curline->dpl_line - prevline->dpl_line); if ((addr_adv % MIN_INST_LENGTH) != 0) { DWARF_P_DBG_ERROR(dbg, DW_DLE_WRONG_ADDRESS, DW_DLV_ERROR); } opc = _dwarf_pro_get_opc(inits,addr_adv, line_adv); if (opc > 0) { /* Use special opcode. */ no_lns_copy = 1; res = write_ubyte(opc,dbg,elfsectno,&writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_basic_block = false; prevline->dpl_address = curline->dpl_address; prevline->dpl_line = curline->dpl_line; } else { /* opc says use standard opcodes. */ if (addr_adv > 0) { db = DW_LNS_advance_pc; res = write_opcode_uval(db,dbg, elfsectno, addr_adv/inits->pi_minimum_instruction_length, &writelen, error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_basic_block = false; prevline->dpl_address = curline->dpl_address; } if (line_adv != 0) { db = DW_LNS_advance_line; res = write_ubyte(db,dbg, elfsectno, &writelen, error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; res = write_sval(line_adv,dbg, elfsectno, &writelen, error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_basic_block = false; prevline->dpl_line = curline->dpl_line; } } } /* ends else for opc <= 0 */ if (no_lns_copy == 0) { /* if not a special or dw_lne_end_seq generate a matrix line */ unsigned writelen = 0; res = write_ubyte(DW_LNS_copy,dbg,elfsectno,&writelen,error); if (res != DW_DLV_OK) { return res; } sum_bytes += writelen; prevline->dpl_basic_block = false; } curline = curline->dpl_next; } /* write total length field */ du = sum_bytes - OFFSET_PLUS_EXTENSION_SIZE; { start_line_sec += extension_size; WRITE_UNALIGNED(dbg, (void *) start_line_sec, (const void *) &du, sizeof(du), offset_size); } *nbufs = dbg->de_n_debug_sect; return DW_DLV_OK; } /* Generate debug_frame section */ static int _dwarf_pro_generate_debugframe(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error) { int elfsectno = 0; int i = 0; int firsttime = 1; Dwarf_P_Cie curcie = 0; Dwarf_P_Fde curfde = 0; unsigned char *data = 0; Dwarf_Unsigned du = 0; Dwarf_Ubyte db = 0; long *cie_offs = 0; /* Holds byte offsets for links to fde's */ unsigned long cie_length = 0; int cie_no = 0; Dwarf_Ubyte offset_size = dbg->de_dwarf_offset_size; Dwarf_Ubyte extension_size = dbg->de_64bit_extension ? 4 : 0; Dwarf_Ubyte address_size = dbg->de_pointer_size; Dwarf_Unsigned cur_off = 0; /* current offset of written data, held for relocation info */ elfsectno = dbg->de_elf_sects[DEBUG_FRAME]; curcie = dbg->de_frame_cies; cie_length = 0; cie_offs = (long *) _dwarf_p_get_alloc(dbg, sizeof(long) * dbg->de_n_cie); if (cie_offs == NULL) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CIE_OFFS_ALLOC, DW_DLV_ERROR); } /* Generate cie number as we go along. This writes all CIEs first before any FDEs, which is rather different from the order a compiler might like (which might be each CIE followed by its FDEs then the next CIE, and so on). */ cie_no = 1; while (curcie) { char *code_al = 0; int codeal_bytes = 0; char *data_al = 0; int data_align_bytes = 0; int pad = 0; /* Pad for padding to align cies and fdes */ int res = 0; char buff1[ENCODE_SPACE_NEEDED]; char buff2[ENCODE_SPACE_NEEDED]; char buff3[ENCODE_SPACE_NEEDED]; char *augmentation = 0; char *augmented_al = 0; long augmented_fields_length = 0; int irix_auglen_v0 = 0; Dwarf_Half version = curcie->cie_version; res = _dwarf_pro_encode_leb128_nm(curcie->cie_code_align, &codeal_bytes, buff1, sizeof(buff1)); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CIE_OFFS_ALLOC, DW_DLV_ERROR); } /* Before April 1999, the following was using an unsigned encode. That worked ok even though the decoder used the correct signed leb read, but doing the encode correctly (according to the dwarf spec) saves space in the output file and is completely compatible. Note the actual stored amount on MIPS was 10 bytes (!) to store the value -4. (hex)fc ffffffff ffffffff 01 The libdwarf consumer consumed all 10 bytes too! old version res = _dwarf_pro_encode_leb128_nm(curcie->cie_data_align, below is corrected signed version. */ res = _dwarf_pro_encode_signed_leb128_nm(curcie->cie_data_align, &data_align_bytes, buff2, sizeof(buff2)); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CIE_OFFS_ALLOC, DW_DLV_ERROR); } code_al = buff1; data_al = buff2; /* get the correct offset */ if (firsttime) { cie_offs[cie_no - 1] = 0; firsttime = 0; } else { cie_offs[cie_no - 1] = cie_offs[cie_no - 2] + (long) cie_length + OFFSET_PLUS_EXTENSION_SIZE; } cie_no++; augmentation = curcie->cie_aug; cie_length = offset_size + /* cie_id */ sizeof(Dwarf_Ubyte) + /* cie version */ strlen(curcie->cie_aug) + 1 + /* augmentation */ codeal_bytes + /* code alignment factor */ data_align_bytes + /* data alignment factor */ sizeof(Dwarf_Ubyte) + /* return reg address */ curcie->cie_inst_bytes; if (dbg->de_irix_exc_augmentation && (strcmp(augmentation, DW_CIE_AUGMENTER_STRING_V0) == 0)) { /* IRIX specific. */ augmented_fields_length = 0; res = _dwarf_pro_encode_leb128_nm(augmented_fields_length, &irix_auglen_v0, buff3, sizeof(buff3)); augmented_al = buff3; if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CIE_OFFS_ALLOC, DW_DLV_ERROR); } cie_length += irix_auglen_v0 ; /* augmentation length */ } if (version >= 4) { /* address size, segment selector size */ cie_length += 1 +1; } pad = (int) PADDING(cie_length, address_size); cie_length += pad; /* Now we have the cie length with padding, allocate a buffer for that plus the header length. */ GET_CHUNK_ERR(dbg, elfsectno, data, cie_length + OFFSET_PLUS_EXTENSION_SIZE, error); if (extension_size) { DISTINGUISHED_VALUE_ARRAY(v4); WRITE_UNALIGNED(dbg, (void *) data, (const void *) &v4[0], SIZEOFT32, extension_size); data += extension_size; } du = cie_length; /* total length of cie */ WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; /* cie-id is a special value. */ du = DW_CIE_ID; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; db = curcie->cie_version; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); strcpy((char *) data, curcie->cie_aug); data += strlen(curcie->cie_aug) + 1; if (curcie->cie_version >= 4) { /* emit address-size, segment selector size */ db = dbg->de_pointer_size; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); db = dbg->de_segment_selector_size; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); } memcpy((void *) data, (const void *) code_al, codeal_bytes); data += codeal_bytes; memcpy((void *) data, (const void *) data_al, data_align_bytes); data += data_align_bytes; db = curcie->cie_ret_reg; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); if (dbg->de_irix_exc_augmentation && strcmp(augmentation, DW_CIE_AUGMENTER_STRING_V0) == 0) { /* IRIX only */ memcpy((void *) data, (const void *) augmented_al, irix_auglen_v0); data += irix_auglen_v0; } memcpy((void *) data, (const void *) curcie->cie_inst, curcie->cie_inst_bytes); data += curcie->cie_inst_bytes; for (i = 0; i < pad; i++) { *data = DW_CFA_nop; data++; } curcie = curcie->cie_next; } /* calculate current offset */ cur_off = cie_offs[cie_no - 2] + cie_length + OFFSET_PLUS_EXTENSION_SIZE; /* write out fde's */ curfde = dbg->de_frame_fdes; while (curfde) { Dwarf_P_Frame_Pgm curinst = 0; long fde_length = 0; int pad2 = 0; Dwarf_P_Cie cie_ptr = 0; Dwarf_Unsigned cie_index = 0; /* index is a global in string.h, so don't name anything index. */ Dwarf_Unsigned indx = 0; int oet_length = 0; int afl_length = 0; int res = 0; int v0_augmentation = 0; char afl_buff[ENCODE_SPACE_NEEDED]; /* Find the CIE associated with this fde. */ cie_ptr = dbg->de_frame_cies; cie_index = curfde->fde_cie; indx = 1; /* The cie_index of the first cie is 1, not 0. */ while (cie_ptr && indx < cie_index) { cie_ptr = cie_ptr->cie_next; indx++; } if (cie_ptr == NULL) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CIE_NULL, DW_DLV_ERROR); } fde_length = curfde->fde_n_bytes + OFFSET_PLUS_EXTENSION_SIZE + /* cie pointer */ address_size + /* initial loc */ address_size; /* address range */ if (dbg->de_irix_exc_augmentation && strcmp(cie_ptr->cie_aug, DW_CIE_AUGMENTER_STRING_V0) == 0) { v0_augmentation = 1; oet_length = DWARF_32BIT_SIZE; /* encode the length of augmented fields. */ res = _dwarf_pro_encode_leb128_nm(oet_length, &afl_length, afl_buff, sizeof(afl_buff)); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CIE_OFFS_ALLOC, DW_DLV_ERROR); } fde_length += afl_length + /* augmented field length */ oet_length; /* exception_table offset */ } if (curfde->fde_die) { /* IRIX/MIPS extension: Using fde offset, generate DW_AT_MIPS_fde attribute for the die corresponding to this fde. */ res = _dwarf_pro_add_AT_fde(dbg, curfde->fde_die, cur_off, error); if (res != DW_DLV_OK) { return res; } } /* store relocation for cie pointer */ res = dbg->de_relocate_by_name_symbol(dbg, DEBUG_FRAME, cur_off + OFFSET_PLUS_EXTENSION_SIZE /* r_offset */, dbg->de_sect_name_idx[DEBUG_FRAME], dwarf_drt_data_reloc, offset_size); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CHUNK_ALLOC, res ); } /* store relocation information for initial location */ res = dbg->de_relocate_by_name_symbol(dbg, DEBUG_FRAME, cur_off + OFFSET_PLUS_EXTENSION_SIZE + address_size /* r_offset */, curfde->fde_r_symidx, dwarf_drt_data_reloc, address_size); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CHUNK_ALLOC, res); } /* Store the relocation information for the offset_into_exception_info field, if the offset is valid (0 is a valid offset). */ if (v0_augmentation && curfde->fde_offset_into_exception_tables >= 0) { res = dbg->de_relocate_by_name_symbol(dbg, DEBUG_FRAME, /* r_offset, where in cie this field starts */ cur_off + OFFSET_PLUS_EXTENSION_SIZE + offset_size + 2 * address_size + afl_length, curfde->fde_exception_table_symbol, dwarf_drt_segment_rel, DWARF_32BIT_SIZE); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_CHUNK_ALLOC, res); } } /* adjust for padding */ pad2 = (int) PADDING(fde_length, address_size); fde_length += pad2; /* write out fde */ GET_CHUNK(dbg, elfsectno, data, fde_length + OFFSET_PLUS_EXTENSION_SIZE, error); du = fde_length; { if (extension_size) { DISTINGUISHED_VALUE_ARRAY(v4); WRITE_UNALIGNED(dbg, (void *) data, (const void *) &v4[0], SIZEOFT32, extension_size); data += extension_size; } /* length */ WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; /* offset to cie */ du = cie_offs[curfde->fde_cie - 1]; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; du = curfde->fde_initloc; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), address_size); data += address_size; if (dbg->de_relocate_pair_by_symbol && curfde->fde_end_symbol != 0 && curfde->fde_addr_range == 0) { /* symbolic reloc, need reloc for length What if we really know the length? If so, should use the other part of 'if'. */ Dwarf_Unsigned val; res = dbg->de_relocate_pair_by_symbol(dbg, DEBUG_FRAME, cur_off + 2 * offset_size + address_size, /* r_offset */ curfde->fde_r_symidx, curfde->fde_end_symbol, dwarf_drt_first_of_length_pair, address_size); if (res != DW_DLV_OK) { { _dwarf_p_error(dbg, error, DW_DLE_ALLOC_FAIL); return DW_DLV_ERROR; } } /* arrange pre-calc so assem text can do .word end - begin + val (gets val from stream) */ val = curfde->fde_end_symbol_offset - curfde->fde_initloc; WRITE_UNALIGNED(dbg, data, (const void *) &val, sizeof(val), address_size); data += address_size; } else { du = curfde->fde_addr_range; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), address_size); data += address_size; } } if (v0_augmentation) { /* IRIX only. */ /* write the encoded augmented field length. */ Dwarf_Signed dsw = 0; memcpy((void *) data, (const void *) afl_buff, afl_length); data += afl_length; /* write the offset_into_exception_tables field. */ dsw = (Dwarf_Signed)curfde->fde_offset_into_exception_tables; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &dsw, sizeof(dsw), DWARF_32BIT_SIZE); data += DWARF_32BIT_SIZE; } curinst = curfde->fde_inst; if (curfde->fde_block) { unsigned long size = curfde->fde_inst_block_size; memcpy((void *) data, (const void *) curfde->fde_block, size); data += size; } else { while (curinst) { db = curinst->dfp_opcode; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); memcpy((void *) data, (const void *) curinst->dfp_args, curinst->dfp_nbytes); data += curinst->dfp_nbytes; curinst = curinst->dfp_next; } } /* padding */ for (i = 0; i < pad2; i++) { *data = DW_CFA_nop; data++; } cur_off += fde_length + offset_size; curfde = curfde->fde_next; } *nbufs = dbg->de_n_debug_sect; return DW_DLV_OK; } /* These functions remember all the markers we see along with the right offset in the .debug_info section so that we can dump them all back to the user with the section info. */ static int marker_init(Dwarf_P_Debug dbg, unsigned count) { dbg->de_marker_n_alloc = count; dbg->de_markers = NULL; if (count > 0) { dbg->de_markers = _dwarf_p_get_alloc(dbg, sizeof(struct Dwarf_P_Marker_s) * dbg->de_marker_n_alloc); if (dbg->de_markers == NULL) { dbg->de_marker_n_alloc = 0; return DW_DLV_ERROR; } } return DW_DLV_OK; } static int marker_add(Dwarf_P_Debug dbg, Dwarf_Unsigned offset, Dwarf_Unsigned marker) { if (dbg->de_marker_n_alloc >= (dbg->de_marker_n_used + 1)) { unsigned n = dbg->de_marker_n_used++; dbg->de_markers[n].ma_offset = offset; dbg->de_markers[n].ma_marker = marker; return DW_DLV_OK; } return DW_DLV_ERROR; } Dwarf_Signed dwarf_get_die_markers(Dwarf_P_Debug dbg, Dwarf_P_Marker * marker_list, /* pointer to a pointer */ Dwarf_Unsigned * marker_count, Dwarf_Error * error) { int res = 0; res = dwarf_get_die_markers_a(dbg,marker_list,marker_count, error); if (res == DW_DLV_ERROR) { return DW_DLV_BADADDR; } return 0; } int dwarf_get_die_markers_a(Dwarf_P_Debug dbg, Dwarf_P_Marker * marker_list, /* pointer to a pointer */ Dwarf_Unsigned * marker_count, Dwarf_Error * error) { if (marker_list == NULL || marker_count == NULL) { DWARF_P_DBG_ERROR(dbg, DW_DLE_IA, DW_DLV_ERROR); } if (dbg->de_marker_n_used != dbg->de_marker_n_alloc) { DWARF_P_DBG_ERROR(dbg, DW_DLE_MAF, DW_DLV_ERROR); } *marker_list = dbg->de_markers; *marker_count = dbg->de_marker_n_used; return DW_DLV_OK; } /* These functions provide the offsets of DW_FORM_string attributes in the section section_index. These information will enable a producer app that is generating assembly text output to easily emit those attributes in ascii form without having to decode the byte stream. */ static int string_attr_init (Dwarf_P_Debug dbg, Dwarf_Signed section_index, unsigned count) { Dwarf_P_Per_Sect_String_Attrs sect_sa = &dbg->de_sect_string_attr[section_index]; sect_sa->sect_sa_n_alloc = count; sect_sa->sect_sa_list = NULL; if (count > 0) { sect_sa->sect_sa_section_number = section_index; sect_sa->sect_sa_list = _dwarf_p_get_alloc(dbg, sizeof(struct Dwarf_P_String_Attr_s) * sect_sa->sect_sa_n_alloc); if (sect_sa->sect_sa_list == NULL) { sect_sa->sect_sa_n_alloc = 0; return DW_DLV_ERROR; } } return DW_DLV_OK; } static int string_attr_add (Dwarf_P_Debug dbg, Dwarf_Signed section_index, Dwarf_Unsigned offset, Dwarf_P_Attribute attr) { Dwarf_P_Per_Sect_String_Attrs sect_sa = &dbg->de_sect_string_attr[section_index]; if (sect_sa->sect_sa_n_alloc >= (sect_sa->sect_sa_n_used + 1)) { unsigned n = sect_sa->sect_sa_n_used++; sect_sa->sect_sa_list[n].sa_offset = offset; sect_sa->sect_sa_list[n].sa_nbytes = attr->ar_nbytes; return DW_DLV_OK; } return DW_DLV_ERROR; } int dwarf_get_string_attributes_count(Dwarf_P_Debug dbg, Dwarf_Unsigned * count_of_sa_sections, int *drd_buffer_version, UNUSEDARG Dwarf_Error *error) { int i = 0; unsigned int count = 0; for (i = 0; i < NUM_DEBUG_SECTIONS; ++i) { if (dbg->de_sect_string_attr[i].sect_sa_n_used > 0) { ++count; } } *count_of_sa_sections = (Dwarf_Unsigned) count; *drd_buffer_version = DWARF_DRD_BUFFER_VERSION; return DW_DLV_OK; } int dwarf_get_string_attributes_info(Dwarf_P_Debug dbg, Dwarf_Signed *elf_section_index, Dwarf_Unsigned *sect_sa_buffer_count, Dwarf_P_String_Attr *sect_sa_buffer, UNUSEDARG Dwarf_Error *error) { int i = 0; int next = dbg->de_sect_sa_next_to_return; for (i = next; i < NUM_DEBUG_SECTIONS; ++i) { Dwarf_P_Per_Sect_String_Attrs sect_sa = &dbg->de_sect_string_attr[i]; if (sect_sa->sect_sa_n_used > 0) { dbg->de_sect_sa_next_to_return = i + 1; *elf_section_index = sect_sa->sect_sa_section_number; *sect_sa_buffer_count = sect_sa->sect_sa_n_used; *sect_sa_buffer = sect_sa->sect_sa_list; return DW_DLV_OK; } } return DW_DLV_NO_ENTRY; } static int has_sibling_die_already(Dwarf_P_Die d) { Dwarf_P_Attribute a = 0; for(a = d->di_attrs; a ; a = a->ar_next) { if(a->ar_attribute == DW_AT_sibling) { return TRUE; } } return FALSE; } /* For DW_FORM_strp we need to set the symindex so we need to check that such applies. */ static int if_relocatable_string_form(Dwarf_P_Debug dbg, Dwarf_P_Attribute curattr, int *debug_str_reloc, Dwarf_Error *error) { if (curattr->ar_rel_type == R_MIPS_NONE) { *debug_str_reloc = 0; return DW_DLV_OK; } if (curattr->ar_attribute_form != DW_FORM_strp) { _dwarf_p_error(dbg, error,DW_DLE_DEBUGSTR_UNEXPECTED_REL); return DW_DLV_ERROR; } if (curattr->ar_rel_type != dbg->de_offset_reloc) { _dwarf_p_error(dbg, error,DW_DLE_DEBUGSTR_UNEXPECTED_REL); return DW_DLV_ERROR; } *debug_str_reloc = 1; return DW_DLV_OK; } /* Tries to see if given attribute and form combination of the attr exists in the given abbreviation. abbrevs and attrs are sorted in attrnum order. */ static int _dwarf_pro_match_attr(Dwarf_P_Attribute attr, Dwarf_P_Abbrev abbrev, int no_attr) { int i = 0; Dwarf_P_Attribute curatp = attr; for (i = 0; i < no_attr && curatp; i++,curatp = curatp->ar_next ) { if (curatp->ar_attribute != abbrev->abb_attrs[i] || curatp->ar_attribute_form != abbrev->abb_forms[i]) { return 0; } /* If either is implicit_const need special check for matching val. */ if (curatp->ar_attribute_form == DW_FORM_implicit_const) { if (abbrev->abb_forms[i] == DW_FORM_implicit_const) { if (curatp->ar_implicit_const != abbrev->abb_implicits[i]) { return 0; } } else { return 0; } } else { if (abbrev->abb_forms[i] == DW_FORM_implicit_const) { return 0; } } } return 1; } static int verify_ab_no_dups(struct Dwarf_Sort_Abbrev_s *sortab, int attrcount) { int k = 0; unsigned preva = 0; struct Dwarf_Sort_Abbrev_s *ab = sortab; if (attrcount < 2) { return DW_DLV_OK; } for(k = 0; k < attrcount; ++k,++ab) { if (k) { if (preva >= ab->dsa_attr) { return DW_DLV_ERROR; } } preva = ab->dsa_attr; } return DW_DLV_OK; } static int abcompare(const void *l_in, const void *r_in) { struct Dwarf_Sort_Abbrev_s *l = (struct Dwarf_Sort_Abbrev_s *)l_in; struct Dwarf_Sort_Abbrev_s *r = (struct Dwarf_Sort_Abbrev_s *)r_in; if (l->dsa_attr < r->dsa_attr) { return -1; } if (l->dsa_attr > r->dsa_attr) { return +1; } /* ASSERT: This never happens in correct dwarf. */ return 0; } /* Handles abbreviations. It takes a die, searches through current list of abbreviations for a matching one. If it finds one, it returns a pointer to the abbrev through the ab_out pointer, and if it does not, it returns a new abbrev through the ab_out pointer. The die->die_attrs are sorted by attribute and the curabbrev attrs are too. It is up to the user of this function to link it up to the abbreviation head. If it is a new abbrev abb_idx has 0. */ static int _dwarf_pro_getabbrev(Dwarf_P_Debug dbg, Dwarf_P_Die die, Dwarf_P_Abbrev head, Dwarf_P_Abbrev*ab_out,Dwarf_Error *error) { Dwarf_P_Abbrev curabbrev = 0; Dwarf_P_Attribute curattr = 0; int match = 0; Dwarf_Unsigned *forms = 0; Dwarf_Unsigned *attrs = 0; Dwarf_Signed *implicits = 0; int attrcount = die->di_n_attr; curabbrev = head; /* Loop thru the currently known abbreviations needed to see if we can share an existing abbrev. */ while (curabbrev) { if ((die->di_tag == curabbrev->abb_tag) && ((die->di_child != NULL && curabbrev->abb_children == DW_CHILDREN_yes) || (die->di_child == NULL && curabbrev->abb_children == DW_CHILDREN_no)) && (attrcount == curabbrev->abb_n_attr)) { /* There is a chance of a match, basic characterists match. Now Check the attrs and forms. */ curattr = die->di_attrs; match = _dwarf_pro_match_attr(curattr, curabbrev, (int) curabbrev->abb_n_attr); if (match == 1) { /* This tag/children/abbrev-list matches the incoming die needs exactly. Reuse this abbreviation. */ *ab_out = curabbrev; return DW_DLV_OK; } } curabbrev = curabbrev->abb_next; } /* no match, create new abbreviation */ if (attrcount) { forms = (Dwarf_Unsigned *) _dwarf_p_get_alloc(die->di_dbg, sizeof(Dwarf_Unsigned) * attrcount); if (forms == NULL) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ABBREV_ALLOC, DW_DLV_ERROR); } attrs = (Dwarf_Unsigned *) _dwarf_p_get_alloc(die->di_dbg, sizeof(Dwarf_Unsigned) * attrcount); if (attrs == NULL) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ABBREV_ALLOC, DW_DLV_ERROR); } implicits = (Dwarf_Signed *) _dwarf_p_get_alloc(die->di_dbg, sizeof(Dwarf_Signed) * attrcount); if (implicits == NULL) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ABBREV_ALLOC, DW_DLV_ERROR); } } curattr = die->di_attrs; if (forms && attrs && attrcount) { struct Dwarf_Sort_Abbrev_s *sortab = 0; struct Dwarf_Sort_Abbrev_s *ap = 0; int k = 0; int res = 0; sortab = (struct Dwarf_Sort_Abbrev_s *) malloc(sizeof(struct Dwarf_Sort_Abbrev_s)*attrcount); if(!sortab) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ABBREV_ALLOC, DW_DLV_ERROR); } /* ASSERT curattr->ar_next chain length == attrcount */ ap = sortab; for(; curattr; ++ap, curattr = curattr->ar_next) { ap->dsa_attr = curattr->ar_attribute; ap->dsa_form = curattr->ar_attribute_form; ap->dsa_implicitvalue = curattr->ar_implicit_const; ap->dsa_attrp = 0; } qsort(sortab,attrcount,sizeof(struct Dwarf_Sort_Abbrev_s), abcompare); ap = sortab; k = 0; res = verify_ab_no_dups(sortab,attrcount); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg,DW_DLE_DUP_ATTR_ON_DIE,DW_DLV_ERROR); } for( ; k < attrcount; ++k,++ap) { attrs[k] = ap->dsa_attr; forms[k] = ap->dsa_form; implicits[k] = ap->dsa_implicitvalue; } free(sortab); } curabbrev = (Dwarf_P_Abbrev) _dwarf_p_get_alloc(die->di_dbg, sizeof(struct Dwarf_P_Abbrev_s)); if (curabbrev == NULL) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ABBREV_ALLOC, DW_DLV_ERROR); } if (die->di_child == NULL) { curabbrev->abb_children = DW_CHILDREN_no; } else { curabbrev->abb_children = DW_CHILDREN_yes; } curabbrev->abb_tag = die->di_tag; curabbrev->abb_attrs = attrs; curabbrev->abb_forms = forms; curabbrev->abb_implicits = implicits; curabbrev->abb_n_attr = attrcount; curabbrev->abb_idx = 0; curabbrev->abb_next = NULL; *ab_out = curabbrev; return DW_DLV_OK; } /* Generate debug_info and debug_abbrev sections */ /* DWARF 2,3,4 */ static int generate_debuginfo_header_2(Dwarf_P_Debug dbg, unsigned *abbrev_offset_io, unsigned char **data_io, int *cu_header_size_out, Dwarf_Small **abbr_off_ptr_out, Dwarf_Half version, int extension_size, Dwarf_Ubyte address_size, Dwarf_Error * error) { unsigned abbrev_offset = 0; unsigned char * data = 0; int offset_size = dbg->de_dwarf_offset_size; int elfsectno_of_debug_info = dbg->de_elf_sects[DEBUG_INFO]; int cu_header_size = 0; Dwarf_Unsigned du = 0; Dwarf_Small *abbr_off_ptr = 0; /* write cu header. abbrev_offset used to generate relocation record below */ abbrev_offset = OFFSET_PLUS_EXTENSION_SIZE + DWARF_HALF_SIZE ; cu_header_size = abbrev_offset + offset_size + sizeof(Dwarf_Ubyte); GET_CHUNK_ERR(dbg, elfsectno_of_debug_info, data, cu_header_size, error); if (extension_size) { /* This for a dwarf-standard 64bit offset. */ DISTINGUISHED_VALUE_ARRAY(v4); WRITE_UNALIGNED(dbg, (void *) data, (const void *) &v4[0], SIZEOFT32, extension_size); data += extension_size; } abbr_off_ptr = data; du = 0; /* length of debug_info, not counting this field itself (unknown at this point). */ WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &version, sizeof(version), DWARF_HALF_SIZE); data += DWARF_HALF_SIZE; du = 0;/* offset into abbrev table, not yet known. */ WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &address_size, sizeof(address_size), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); /* We have filled the chunk we got with GET_CHUNK. At this point we no longer dare use "data" as a pointer any longer except to refer to that first small chunk for the cu header to update the section length. */ *abbrev_offset_io = abbrev_offset; *data_io = data; *cu_header_size_out = cu_header_size; *abbr_off_ptr_out = abbr_off_ptr; return DW_DLV_OK; } /* DWARF 5 */ static int generate_debuginfo_header_5(Dwarf_P_Debug dbg, unsigned *abbrev_offset_io, unsigned char **data_io, int *cu_header_size_out, Dwarf_Small **abbr_off_ptr_out, Dwarf_Half version, Dwarf_Ubyte unit_type, int extension_size, Dwarf_Ubyte address_size, Dwarf_Error *error) { int offset_size = dbg->de_dwarf_offset_size; unsigned abbrev_offset = 0; unsigned char * data = 0; int elfsectno_of_debug_info = dbg->de_elf_sects[DEBUG_INFO]; int cu_header_size = 0; Dwarf_Unsigned du = 0; Dwarf_Small *abbr_off_ptr = 0; /* write cu header. abbrev_offset used to generate relocation record below */ abbrev_offset = OFFSET_PLUS_EXTENSION_SIZE + DWARF_HALF_SIZE + /* version stamp */ sizeof(unit_type) + sizeof(Dwarf_Ubyte); cu_header_size = abbrev_offset + offset_size; GET_CHUNK_ERR(dbg, elfsectno_of_debug_info, data, cu_header_size, error); if (extension_size) { /* Impossible in DW5, really, is for IRIX64. But we allow it. */ DISTINGUISHED_VALUE_ARRAY(v4); WRITE_UNALIGNED(dbg, (void *) data, (const void *) &v4[0], SIZEOFT32, extension_size); data += extension_size; } abbr_off_ptr = data; du = 0; /* length of debug_info, not counting this field itself (unknown at this point). */ WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &version, sizeof(version), DWARF_HALF_SIZE); data += DWARF_HALF_SIZE; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &unit_type, sizeof(unit_type), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); WRITE_UNALIGNED(dbg, (void *) data, (const void *) &address_size, sizeof(address_size), sizeof(Dwarf_Ubyte)); data += sizeof(Dwarf_Ubyte); du = 0;/* offset into abbrev table, not yet known. */ WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), offset_size); data += offset_size; /* We have filled the chunk we got with GET_CHUNK. At this point we no longer dare use "data" as a pointer any longer except to refer to that first small chunk for the cu header to update the section length. */ *abbrev_offset_io = abbrev_offset; *data_io = data; *cu_header_size_out = cu_header_size; *abbr_off_ptr_out = abbr_off_ptr; return DW_DLV_OK; } /* Write out debug_abbrev section */ static int write_out_debug_abbrev(Dwarf_P_Debug dbg, Dwarf_P_Abbrev abbrev_head, Dwarf_Error * error) { Dwarf_P_Abbrev curabbrev = abbrev_head; unsigned char *data = 0; int res = 0; int abbrevsectno = dbg->de_elf_sects[DEBUG_ABBREV]; while (curabbrev) { int idx = 0; unsigned lebcount = 0; Dwarf_Ubyte db = 0; res = write_uval(curabbrev->abb_idx,dbg,abbrevsectno, &lebcount,error); if (res != DW_DLV_OK) { return res; } res = write_uval(curabbrev->abb_tag,dbg,abbrevsectno, &lebcount,error); if (res != DW_DLV_OK) { return res; } db = curabbrev->abb_children; res = write_ubyte(db,dbg,abbrevsectno,&lebcount,error); if (res != DW_DLV_OK) { return res; } /* add attributes and forms */ for (idx = 0; idx < curabbrev->abb_n_attr; idx++) { res =write_uval(curabbrev->abb_attrs[idx], dbg,abbrevsectno, &lebcount,error); if (res != DW_DLV_OK) { return res; } res =write_uval(curabbrev->abb_forms[idx], dbg,abbrevsectno, &lebcount,error); if (res != DW_DLV_OK) { return res; } if (curabbrev->abb_forms[idx] == DW_FORM_implicit_const){ res =write_sval(curabbrev->abb_implicits[idx], dbg,abbrevsectno, &lebcount,error); if (res != DW_DLV_OK) { return res; } } } /* Two zeros, for last entry, see dwarf2 sec 7.5.3 */ GET_CHUNK_ERR(dbg, abbrevsectno, data, 2, error); *data = 0; data++; *data = 0; curabbrev = curabbrev->abb_next; } /* one zero, for end of cu, see dwarf2 sec 7.5.3 */ GET_CHUNK_ERR(dbg, abbrevsectno, data, 1, error); *data = 0; return DW_DLV_OK; } static int sort_die_attrs(Dwarf_P_Debug dbg,Dwarf_P_Die die, Dwarf_Error *error) { struct Dwarf_Sort_Abbrev_s *sortab = 0; struct Dwarf_Sort_Abbrev_s *ap = 0; Dwarf_P_Attribute at = 0; Dwarf_P_Attribute sorted_attrlist = 0; Dwarf_P_Attribute sorted_tail = 0; int attrcount = die->di_n_attr; int res = 0; unsigned ct = 0; int k = 0; if (attrcount < 2) { return DW_DLV_OK; } sortab = (struct Dwarf_Sort_Abbrev_s *) malloc(sizeof(struct Dwarf_Sort_Abbrev_s)*attrcount); if(!sortab) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ABBREV_ALLOC, DW_DLV_ERROR); } /* ASSERT at->ar_next chain length == attrcount */ ap = sortab; at = die->di_attrs; for(; at; ++ap, at = at->ar_next) { ap->dsa_attr = at->ar_attribute; ap->dsa_form = at->ar_attribute_form; ap->dsa_attrp = at; ++ct; } qsort(sortab,attrcount,sizeof(struct Dwarf_Sort_Abbrev_s), abcompare); res = verify_ab_no_dups(sortab,attrcount); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_DUP_ATTR_ON_DIE, DW_DLV_ERROR); } ap = sortab; k = 0; for( ; k < attrcount; ++k,++ap) { Dwarf_P_Attribute localptr = ap->dsa_attrp; if (!sorted_attrlist) { sorted_attrlist = localptr; sorted_tail = sorted_attrlist; localptr->ar_next = 0; continue; } sorted_tail->ar_next = localptr; sorted_tail = localptr; localptr->ar_next = 0; } /* Now replace the list with the same pointers but in order sorted by attribute. */ die->di_attrs = sorted_attrlist; free(sortab); return DW_DLV_OK; } static int _dwarf_pro_generate_debuginfo(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error) { int elfsectno_of_debug_info = 0; unsigned char *data = 0; int cu_header_size = 0; Dwarf_P_Abbrev curabbrev = 0; Dwarf_P_Abbrev abbrev_head = 0; Dwarf_P_Abbrev abbrev_tail = 0; Dwarf_P_Die curdie = 0; Dwarf_P_Die first_child = 0; Dwarf_Unsigned dw = 0; Dwarf_Unsigned du = 0; Dwarf_Half dh = 0; Dwarf_Unsigned die_off = 0; /* Offset of die in debug_info. */ int n_abbrevs = 0; unsigned abbrev_offset = 0; int res = 0; unsigned marker_count = 0; unsigned string_attr_count = 0; unsigned string_attr_offset = 0; Dwarf_Small *abbr_off_ptr = 0; int offset_size = dbg->de_dwarf_offset_size; /* extension_size is oddly names. The standard calls for a 64bit offset to have a 4 byte 0xffff while original IRIX64 did not. So if dbg->de_64bit_extension set this is a standard DWARF 64bit offset and if de_64bit_extension not set this is non-standard IRIX64 64 bit offset. */ Dwarf_Half version = dbg->de_output_version; int extension_size = dbg->de_64bit_extension ? 4 : 0; /* For now just assume DW_UT_compile FIXME */ Dwarf_Ubyte unit_type = DW_UT_compile; Dwarf_Ubyte address_size = 0; elfsectno_of_debug_info = dbg->de_elf_sects[DEBUG_INFO]; address_size = dbg->de_pointer_size; if (version < 5) { res = generate_debuginfo_header_2(dbg, &abbrev_offset, &data, &cu_header_size, &abbr_off_ptr, version, extension_size, address_size, error); if (res != DW_DLV_OK) { return res; } } else if (version == 5) { res = generate_debuginfo_header_5(dbg, &abbrev_offset, &data, &cu_header_size, &abbr_off_ptr, version, unit_type, extension_size, address_size, error); if (res != DW_DLV_OK) { return res; } } else { DWARF_P_DBG_ERROR(dbg, DW_DLE_VERSION_STAMP_ERROR, DW_DLV_ERROR); } curdie = dbg->de_dies; /* Create AT_macro_info if appropriate */ if( version < 5) { if (dbg->de_first_macinfo != NULL) { res = _dwarf_pro_add_AT_macro_info(dbg, curdie, 0, error); if (res != DW_DLV_OK) { return res; } } } else { /* FIXME need to add code to emit DWARF5 macro data. */ #if 0 res = _dwarf_pro_add_AT_macro5_info(dbg, curdie, 0, error); #endif } /* Create AT_stmt_list attribute if necessary */ if (dwarf_need_debug_line_section(dbg) == TRUE) { res =_dwarf_pro_add_AT_stmt_list(dbg, curdie, error); if (res != DW_DLV_OK) { return res; } } die_off = cu_header_size; /* Relocation for abbrev offset in cu header store relocation record in linked list */ res = dbg->de_relocate_by_name_symbol(dbg, DEBUG_INFO, abbrev_offset /* r_offset */, dbg->de_sect_name_idx[DEBUG_ABBREV], dwarf_drt_data_reloc, offset_size); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_REL_ALLOC, DW_DLV_ERROR); } /* Pass 0: only top level dies, add at_sibling attribute to those dies with children, but if and only if there is no sibling attribute already. */ first_child = curdie->di_child; while (first_child && first_child->di_right) { if (first_child->di_child) { if (!has_sibling_die_already(first_child)) { dwarf_add_AT_reference(dbg, first_child, DW_AT_sibling, first_child->di_right, error); } } first_child = first_child->di_right; } /* Pass 1: create abbrev info, get die offsets, calc relocations */ abbrev_head = abbrev_tail = NULL; marker_count = 0; string_attr_count = 0; while (curdie != NULL) { int nbytes = 0; Dwarf_P_Attribute curattr = 0; char *space = 0; int cres = 0; char buff1[ENCODE_SPACE_NEEDED]; curdie->di_offset = die_off; if (curdie->di_marker != 0) { marker_count++; } cres =sort_die_attrs(dbg,curdie,error); if (cres != DW_DLV_OK) { /* DW_DLV_NO_ENTRY is impossible. */ return cres; } /* Find or create a final abbrev record for the debug_abbrev section we will write (below). */ cres = _dwarf_pro_getabbrev(dbg,curdie, abbrev_head,&curabbrev, error); if (cres != DW_DLV_OK) { return cres; } if (abbrev_head == NULL) { n_abbrevs = 1; curabbrev->abb_idx = n_abbrevs; abbrev_tail = abbrev_head = curabbrev; } else { /* Check if it is a new abbreviation, if yes, add to tail */ if (curabbrev->abb_idx == 0) { n_abbrevs++; curabbrev->abb_idx = n_abbrevs; abbrev_tail->abb_next = curabbrev; abbrev_tail = curabbrev; } } /* We know the abbrev number to use now. So create the bytes of the leb with the value and save those bytes in di_abbrev, we will emit in Pass 2 (below). */ cres = _dwarf_pro_encode_leb128_nm(curabbrev->abb_idx, &nbytes, buff1, sizeof(buff1)); if (cres != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ABBREV_ALLOC, DW_DLV_ERROR); } space = _dwarf_p_get_alloc(dbg, nbytes); if (space == NULL) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ABBREV_ALLOC, DW_DLV_ERROR); } memcpy(space, buff1, nbytes); curdie->di_abbrev = space; curdie->di_abbrev_nbytes = nbytes; die_off += nbytes; /* The abbrev and DIE attr lists match, so the die abbrevs are in the correct order, curdie->di_attrs. */ /* Now we attach the attributes list to the die. */ curattr = curdie->di_attrs; while (curattr) { if (curattr->ar_rel_type != R_MIPS_NONE) { int rres=0; switch (curattr->ar_attribute) { case DW_AT_stmt_list: curattr->ar_rel_symidx = dbg->de_sect_name_idx[DEBUG_LINE]; break; case DW_AT_MIPS_fde: curattr->ar_rel_symidx = dbg->de_sect_name_idx[DEBUG_FRAME]; break; case DW_AT_macro_info: curattr->ar_rel_symidx = dbg->de_sect_name_idx[DEBUG_MACINFO]; break; /* See also: pro_forms.c for same strings attribute list. */ case DW_AT_comp_dir: case DW_AT_const_value: case DW_AT_linkage_name: /* DWARF5 */ case DW_AT_MIPS_abstract_name: case DW_AT_MIPS_linkage_name: case DW_AT_name: case DW_AT_producer: { int is_debug_str = 0; int nres = if_relocatable_string_form(dbg,curattr, &is_debug_str,error); if (nres != DW_DLV_OK) { return res; } if (is_debug_str) { curattr->ar_rel_symidx = dbg->de_sect_name_idx[DEBUG_STR]; } } break; default: break; } rres = dbg->de_relocate_by_name_symbol(dbg, DEBUG_INFO, die_off + curattr->ar_rel_offset,/* r_offset */ curattr->ar_rel_symidx, dwarf_drt_data_reloc, curattr->ar_reloc_len); if (rres != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_REL_ALLOC, DW_DLV_ERROR); } } if (curattr->ar_attribute_form == DW_FORM_string) { string_attr_count++; } die_off += curattr->ar_nbytes; curattr = curattr->ar_next; } /* Depth first access to all the DIEs. */ if (curdie->di_child) { curdie = curdie->di_child; } else { while (curdie != NULL && curdie->di_right == NULL) { curdie = curdie->di_parent; /* See -nonrootsibling- below */ if (curdie != NULL) { die_off++; } } if (curdie != NULL) { curdie = curdie->di_right; } } } /* end while (curdie != NULL), the per-die loop */ res = marker_init(dbg, marker_count); if (res == DW_DLV_ERROR) { DWARF_P_DBG_ERROR(dbg, DW_DLE_REL_ALLOC, DW_DLV_ERROR); } res = string_attr_init(dbg, DEBUG_INFO, string_attr_count); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_REL_ALLOC, DW_DLV_ERROR); } /* Pass 2: Write out the die information Here 'data' is a temporary, one block for each GET_CHUNK. 'data' is overused. */ curdie = dbg->de_dies; while (curdie != NULL) { Dwarf_P_Attribute curattr; if (curdie->di_marker != 0) { res = marker_add(dbg, curdie->di_offset, curdie->di_marker); if (res == DW_DLV_ERROR) { DWARF_P_DBG_ERROR(dbg, DW_DLE_REL_ALLOC, DW_DLV_ERROR); } } /* Index to abbreviation table */ GET_CHUNK_ERR(dbg, elfsectno_of_debug_info, data, curdie->di_abbrev_nbytes, error); memcpy((void *) data, (const void *) curdie->di_abbrev, curdie->di_abbrev_nbytes); /* Attribute values - need to fill in all form attributes */ curattr = curdie->di_attrs; string_attr_offset = curdie->di_offset + curdie->di_abbrev_nbytes; while (curattr) { GET_CHUNK_ERR(dbg, elfsectno_of_debug_info, data, (unsigned long) curattr->ar_nbytes, error); switch (curattr->ar_attribute_form) { case DW_FORM_ref1: { Dwarf_Ubyte db = 0; if (curattr->ar_ref_die->di_offset > (unsigned) 0xff) { DWARF_P_DBG_ERROR(dbg, DW_DLE_OFFSET_UFLW, DW_DLV_ERROR); } db = curattr->ar_ref_die->di_offset; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &db, sizeof(db), sizeof(Dwarf_Ubyte)); break; } case DW_FORM_ref2: { if (curattr->ar_ref_die->di_offset > (unsigned) 0xffff) { DWARF_P_DBG_ERROR(dbg, DW_DLE_OFFSET_UFLW, DW_DLV_ERROR); } dh = curattr->ar_ref_die->di_offset; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &dh, sizeof(dh), DWARF_HALF_SIZE); break; } case DW_FORM_ref_addr: { /* curattr->ar_ref_die == NULL! DW_FORM_ref_addr doesn't take a CU-offset. This is different than other refs. This value will be set by the user of the producer library using a relocation. No need to set a value here. */ break; } case DW_FORM_ref4: { if (curattr->ar_ref_die->di_offset > (unsigned) 0xffffffff) { DWARF_P_DBG_ERROR(dbg, DW_DLE_OFFSET_UFLW, DW_DLV_ERROR); } dw = (Dwarf_Unsigned) curattr->ar_ref_die->di_offset; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &dw, sizeof(dw), DWARF_32BIT_SIZE); break; } case DW_FORM_ref8: du = curattr->ar_ref_die->di_offset; WRITE_UNALIGNED(dbg, (void *) data, (const void *) &du, sizeof(du), DWARF_64BIT_SIZE); break; case DW_FORM_ref_udata: { /* unsigned leb128 offset */ int nbytesx; char buff1[ENCODE_SPACE_NEEDED]; res = _dwarf_pro_encode_leb128_nm(curattr-> ar_ref_die-> di_offset, &nbytesx, buff1, sizeof(buff1)); if (res != DW_DLV_OK) { DWARF_P_DBG_ERROR(dbg, DW_DLE_ABBREV_ALLOC, DW_DLV_ERROR); } memcpy(data, buff1, nbytesx); break; } default: if(curattr->ar_nbytes) { memcpy((void *) data, (const void *) curattr->ar_data, curattr->ar_nbytes); } break; } if (curattr->ar_attribute_form == DW_FORM_string) { string_attr_add(dbg, DEBUG_INFO, string_attr_offset, curattr); } string_attr_offset += curattr->ar_nbytes; curattr = curattr->ar_next; } /* depth first search */ if (curdie->di_child) { curdie = curdie->di_child; } else { while (curdie != NULL && curdie->di_right == NULL) { /* -nonrootsibling- A null die should only be written for terminating siblings, not the root. Adding a terminating die for the root will cause, after object files are linked, warnings to be generated with newer versions of readelf. */ if (!curdie->di_parent) { /* The parent is not a DIE so ending a sibling chain makes no sense (wastes a byte). */ break; } GET_CHUNK_ERR(dbg, elfsectno_of_debug_info, data, 1, error); *data = '\0'; curdie = curdie->di_parent; } if (curdie != NULL) curdie = curdie->di_right; } } /* end while (curdir != NULL) */ /* Write out debug_info size, now that we know it This is back-patching the CU header we created above. */ du = die_off - OFFSET_PLUS_EXTENSION_SIZE; WRITE_UNALIGNED(dbg, (void *) abbr_off_ptr, (const void *) &du, sizeof(du), offset_size); data = 0; /* Emphasise not usable now */ res = write_out_debug_abbrev(dbg, abbrev_head, error); if (res != DW_DLV_OK) { return res; } *nbufs = dbg->de_n_debug_sect; return DW_DLV_OK; } static int _dwarf_pro_generate_debug_names(Dwarf_P_Debug dbg, UNUSEDARG Dwarf_Signed *nbufs, Dwarf_Error * error UNUSEDARG) { #if 0 int elfsectno_of_debug_names = dbg->de_elf_sects[DEBUG_NAMES]; FIXME: Needs implementation unsigned char *data = 0; GET_CHUNK(dbg, elfsectno_of_debug_names, data, dbg->de_debug_names->ds_nbytes, error); memcpy(data,dbg->de_debug_names->ds_data,dbg->de_debug_names->ds_nbytes); #endif *nbufs = dbg->de_n_debug_sect; return DW_DLV_OK; } static int _dwarf_pro_generate_debug_str(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error) { int elfsectno_of_debug_str = 0; unsigned char *data = 0; elfsectno_of_debug_str = dbg->de_elf_sects[DEBUG_STR]; GET_CHUNK(dbg, elfsectno_of_debug_str, data, dbg->de_debug_str->ds_nbytes, error); memcpy(data,dbg->de_debug_str->ds_data,dbg->de_debug_str->ds_nbytes); *nbufs = dbg->de_n_debug_sect; return DW_DLV_OK; } static int _dwarf_pro_generate_debug_line_str(Dwarf_P_Debug dbg, Dwarf_Signed *nbufs, Dwarf_Error * error) { int elfsectno_of_debug_line_str = 0; unsigned char *data = 0; elfsectno_of_debug_line_str = dbg->de_elf_sects[DEBUG_LINE_STR]; GET_CHUNK(dbg, elfsectno_of_debug_line_str, data, dbg->de_debug_line_str->ds_nbytes, error); memcpy(data,dbg->de_debug_line_str->ds_data, dbg->de_debug_line_str->ds_nbytes); *nbufs = dbg->de_n_debug_sect; return DW_DLV_OK; } /* Get a buffer of section data. section_idx is the elf-section number that this data applies to. length shows length of returned data This is the original format. Hard to check for error. */ /*ARGSUSED*/ /* pretend all args used */ Dwarf_Ptr dwarf_get_section_bytes(Dwarf_P_Debug dbg, UNUSEDARG Dwarf_Signed dwarf_section, Dwarf_Signed * section_idx, Dwarf_Unsigned * length, Dwarf_Error * error) { Dwarf_Ptr s_bytes = 0; int res = 0; res = dwarf_get_section_bytes_a(dbg, dwarf_section, section_idx, length, &s_bytes, error); if (res == DW_DLV_ERROR) { return (Dwarf_Ptr)DW_DLV_BADADDR; } if (res == DW_DLV_NO_ENTRY) { return NULL; } return s_bytes; } /* Get a buffer of section data. section_idx is the elf-section number that this data applies to. length shows length of returned data This is the September 2016 format. Preferred. */ int dwarf_get_section_bytes_a(Dwarf_P_Debug dbg, UNUSEDARG Dwarf_Signed dwarf_section, Dwarf_Signed * section_idx, Dwarf_Unsigned * length, Dwarf_Ptr * section_bytes, Dwarf_Error * error) { Dwarf_Ptr buf = 0; if (dbg->de_version_magic_number != PRO_VERSION_MAGIC) { DWARF_P_DBG_ERROR(dbg, DW_DLE_IA, DW_DLV_ERROR); } *section_bytes = 0; *length = 0; if (dbg->de_debug_sects == 0) { /* no more data !! */ return DW_DLV_NO_ENTRY; } if (dbg->de_debug_sects->ds_elf_sect_no == MAGIC_SECT_NO) { /* no data ever entered !! */ return DW_DLV_NO_ENTRY; } *section_idx = dbg->de_debug_sects->ds_elf_sect_no; *length = dbg->de_debug_sects->ds_nbytes; buf = (Dwarf_Ptr *) dbg->de_debug_sects->ds_data; /* Here is the iterator so the next call gets the next section. */ dbg->de_debug_sects = dbg->de_debug_sects->ds_next; /* We may want to call the section stuff more than once: see dwarf_reset_section_bytes() do not do: dbg->de_n_debug_sect--; */ *section_bytes = buf; return DW_DLV_OK; } /* No errors possible. */ void dwarf_reset_section_bytes(Dwarf_P_Debug dbg) { dbg->de_debug_sects = dbg->de_first_debug_sect; /* No need to reset; commented out decrement. dbg->de_n_debug_sect = ???; */ dbg->de_reloc_next_to_return = 0; dbg->de_sect_sa_next_to_return = 0; } /* Storage handler. Gets either a new chunk of memory, or a pointer in existing memory, from the linked list attached to dbg at de_debug_sects, depending on size of nbytes Assume dbg not null, checked in top level routine Returns a pointer to the allocated buffer space for the lib to fill in, predincrements next-to-use count so the space requested is already counted 'used' when this returns (ie, reserved). */ Dwarf_Small * _dwarf_pro_buffer(Dwarf_P_Debug dbg, int elfsectno, unsigned long nbytes) { Dwarf_P_Section_Data cursect = 0; cursect = dbg->de_current_active_section; /* By using MAGIC_SECT_NO we allow the following MAGIC_SECT_NO must not match any legit section number. test to have just two clauses (no NULL pointer test) See dwarf_producer_init(). */ if ((cursect->ds_elf_sect_no != elfsectno) || ((cursect->ds_nbytes + nbytes) > cursect->ds_orig_alloc) ) { /* Either the elf section has changed or there is not enough space in the current section. Create a new Dwarf_P_Section_Data_s for the chunk. and have space 'on the end' for the buffer itself so we just do one malloc (not two). */ unsigned long space = nbytes; if (nbytes < CHUNK_SIZE) space = CHUNK_SIZE; cursect = (Dwarf_P_Section_Data) _dwarf_p_get_alloc(dbg, sizeof(struct Dwarf_P_Section_Data_s) + space); if (cursect == NULL) { return (NULL); } /* _dwarf_p_get_alloc zeroes the space... */ cursect->ds_data = (char *) cursect + sizeof(struct Dwarf_P_Section_Data_s); cursect->ds_orig_alloc = space; cursect->ds_elf_sect_no = elfsectno; cursect->ds_nbytes = nbytes; /* reserve this number of bytes of space for caller to fill in */ /* Now link on the end of the list, and mark this one as the current one */ if (dbg->de_debug_sects->ds_elf_sect_no == MAGIC_SECT_NO) { /* The only entry is the special one for 'no entry' so delete that phony one while adding this initial real one. */ dbg->de_debug_sects = cursect; dbg->de_current_active_section = cursect; dbg->de_first_debug_sect = cursect; } else { dbg->de_current_active_section->ds_next = cursect; dbg->de_current_active_section = cursect; } dbg->de_n_debug_sect++; return ((Dwarf_Small *) cursect->ds_data); } /* There is enough space in the current buffer */ { Dwarf_Small *space_for_caller = (Dwarf_Small *) (cursect->ds_data + cursect->ds_nbytes); cursect->ds_nbytes += nbytes; return space_for_caller; } }