xref: /titanic_41/usr/src/cmd/sgs/libld/common/update.c (revision 4558d122136f151d62acbbc02ddb42df89a5ef66)

/*
 * CDDL HEADER START
 *
 * The contents of this file are subject to the terms of the
 * Common Development and Distribution License (the "License").
 * You may not use this file except in compliance with the License.
 *
 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
 * or http://www.opensolaris.org/os/licensing.
 * See the License for the specific language governing permissions
 * and limitations under the License.
 *
 * When distributing Covered Code, include this CDDL HEADER in each
 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
 * If applicable, add the following below this CDDL HEADER, with the
 * fields enclosed by brackets "[]" replaced with your own identifying
 * information: Portions Copyright [yyyy] [name of copyright owner]
 *
 * CDDL HEADER END
 */

/*
 *	Copyright (c) 1988 AT&T
 *	  All Rights Reserved
 *
 * Copyright (c) 1989, 2010, Oracle and/or its affiliates. All rights reserved.
 */

/*
 * Update the new output file image, perform virtual address, offset and
 * displacement calculations on the program headers and sections headers,
 * and generate any new output section information.
 */

#define	ELF_TARGET_AMD64

#include	<stdio.h>
#include	<string.h>
#include	<unistd.h>
#include	<debug.h>
#include	"msg.h"
#include	"_libld.h"

/*
 * Comparison routine used by qsort() for sorting of the global symbol list
 * based off of the hashbuckets the symbol will eventually be deposited in.
 */
static int
sym_hash_compare(Sym_s_list * s1, Sym_s_list * s2)
{
	return (s1->sl_hval - s2->sl_hval);
}

/*
 * Comparison routine used by qsort() for sorting of dyn[sym|tls]sort section
 * indices based on the address of the symbols they reference. The
 * use of the global dynsort_compare_syms variable is needed because
 * we need to examine the symbols the indices reference. It is safe, because
 * the linker is single threaded.
 */
Sym *dynsort_compare_syms;

static int
dynsort_compare(const void *idx1, const void *idx2)
{
	Sym *s1 = dynsort_compare_syms + *((const Word *) idx1);
	Sym *s2 = dynsort_compare_syms + *((const Word *) idx2);

	/*
	 * Note: the logical computation for this is
	 *	(st_value1 - st_value2)
	 * However, that is only correct if the address type is smaller
	 * than a pointer. Writing it this way makes it immune to the
	 * class (32 or 64-bit) of the linker.
	 */
	return ((s1->st_value < s2->st_value) ? -1 :
	    (s1->st_value > s2->st_value));
}

/*
 * Scan the sorted symbols, and issue warnings if there are any duplicate
 * values in the list. We only do this if -zverbose is set, or we are
 * running with LD_DEBUG defined
 *
 * entry:
 *	ofl - Output file descriptor
 *	ldynsym - Pointer to start of .SUNW_ldynsym section that the
 *		sort section indexes reference.
 *	symsort - Pointer to start of .SUNW_dynsymsort or .SUNW_dyntlssort
 *		section.
 *	n - # of indices in symsort array
 *	secname - Name of the symsort section.
 *
 * exit:
 *	If the symsort section contains indexes to more than one
 *	symbol with the same address value, a warning is issued.
 */
static void
dynsort_dupwarn(Ofl_desc *ofl, Sym *ldynsym, const char *str,
    Word *symsort, Word n, const char *secname)
{
	int zverbose = (ofl->ofl_flags & FLG_OF_VERBOSE) != 0;
	Word ndx, cmp_ndx;
	Addr addr, cmp_addr;

	/* Nothing to do if -zverbose or LD_DEBUG are not active */
	if (!(zverbose || DBG_ENABLED))
		return;

	cmp_ndx = 0;
	cmp_addr = ldynsym[symsort[cmp_ndx]].st_value;
	for (ndx = 1; ndx < n; ndx++) {
		addr = ldynsym[symsort[ndx]].st_value;
		if (cmp_addr == addr) {
			if (zverbose)
				eprintf(ofl->ofl_lml, ERR_WARNING,
				    MSG_INTL(MSG_SYM_DUPSORTADDR), secname,
				    str + ldynsym[symsort[cmp_ndx]].st_name,
				    str + ldynsym[symsort[ndx]].st_name,
				    EC_ADDR(addr));
			DBG_CALL(Dbg_syms_dup_sort_addr(ofl->ofl_lml, secname,
			    str + ldynsym[symsort[cmp_ndx]].st_name,
			    str + ldynsym[symsort[ndx]].st_name,
			    EC_ADDR(addr)));
		} else {	/* Not a dup. Move reference up */
			cmp_ndx = ndx;
			cmp_addr = addr;
		}
	}
}

/*
 * Build and update any output symbol tables.  Here we work on all the symbol
 * tables at once to reduce the duplication of symbol and string manipulation.
 * Symbols and their associated strings are copied from the read-only input
 * file images to the output image and their values and index's updated in the
 * output image.
 */
static Addr
update_osym(Ofl_desc *ofl)
{
	/*
	 * There are several places in this function where we wish
	 * to insert a symbol index to the combined .SUNW_ldynsym/.dynsym
	 * symbol table into one of the two sort sections (.SUNW_dynsymsort
	 * or .SUNW_dyntlssort), if that symbol has the right attributes.
	 * This macro is used to generate the necessary code from a single
	 * specification.
	 *
	 * entry:
	 *	_sdp, _sym, _type - As per DYNSORT_COUNT. See _libld.h
	 *	_sym_ndx - Index that _sym will have in the combined
	 *		.SUNW_ldynsym/.dynsym symbol table.
	 */
#define	ADD_TO_DYNSORT(_sdp, _sym, _type, _sym_ndx) \
	{ \
		Word *_dynsort_arr, *_dynsort_ndx; \
		\
		if (dynsymsort_symtype[_type]) { \
			_dynsort_arr = dynsymsort; \
			_dynsort_ndx = &dynsymsort_ndx; \
		} else if (_type == STT_TLS) { \
			_dynsort_arr = dyntlssort; \
			_dynsort_ndx = &dyntlssort_ndx; \
		} else { \
			_dynsort_arr = NULL; \
		} \
		if ((_dynsort_arr != NULL) && DYNSORT_TEST_ATTR(_sdp, _sym)) \
		    _dynsort_arr[(*_dynsort_ndx)++] = _sym_ndx; \
	}

	Sym_desc	*sdp;
	Sym_avlnode	*sav;
	Sg_desc		*sgp, *tsgp = NULL, *dsgp = NULL, *esgp = NULL;
	Os_desc		*osp, *iosp = NULL, *fosp = NULL;
	Is_desc		*isc;
	Ifl_desc	*ifl;
	Word		bssndx, etext_ndx, edata_ndx = 0, end_ndx, start_ndx;
	Word		end_abs = 0, etext_abs = 0, edata_abs;
	Word		tlsbssndx = 0, parexpnndx;
#if	defined(_ELF64)
	Word		lbssndx = 0;
	Addr		lbssaddr = 0;
#endif
	Addr		bssaddr, etext = 0, edata = 0, end = 0, start = 0;
	Addr		tlsbssaddr = 0;
	Addr 		parexpnbase, parexpnaddr;
	int		start_set = 0;
	Sym		_sym = {0}, *sym, *symtab = NULL;
	Sym		*dynsym = NULL, *ldynsym = NULL;
	Word		symtab_ndx = 0;		/* index into .symtab */
	Word		symtab_gbl_bndx;	/* .symtab ndx 1st global */
	Word		ldynsym_ndx = 0;	/* index into .SUNW_ldynsym */
	Word		dynsym_ndx = 0;		/* index into .dynsym */
	Word		scopesym_ndx = 0;	/* index into scoped symbols */
	Word		scopesym_bndx = 0;	/* .symtab ndx 1st scoped sym */
	Word		ldynscopesym_ndx = 0;	/* index to ldynsym scoped */
						/*	symbols */
	Word		*dynsymsort = NULL;	/* SUNW_dynsymsort index */
						/*	vector */
	Word		*dyntlssort = NULL;	/* SUNW_dyntlssort index */
						/*	vector */
	Word		dynsymsort_ndx;		/* index dynsymsort array */
	Word		dyntlssort_ndx;		/* index dyntlssort array */
	Word		*symndx;		/* symbol index (for */
						/*	relocation use) */
	Word		*symshndx = NULL;	/* .symtab_shndx table */
	Word		*dynshndx = NULL;	/* .dynsym_shndx table */
	Word		*ldynshndx = NULL;	/* .SUNW_ldynsym_shndx table */
	Word		ldynsym_cnt = NULL;	/* number of items in */
						/*	.SUNW_ldynsym */
	Str_tbl		*shstrtab;
	Str_tbl		*strtab;
	Str_tbl		*dynstr;
	Word		*hashtab;	/* hash table pointer */
	Word		*hashbkt;	/* hash table bucket pointer */
	Word		*hashchain;	/* hash table chain pointer */
	Wk_desc		*wkp;
	Alist		*weak = NULL;
	ofl_flag_t	flags = ofl->ofl_flags;
	Versym		*versym;
	Gottable	*gottable;	/* used for display got debugging */
					/*	information */
	Syminfo		*syminfo;
	Sym_s_list	*sorted_syms;	/* table to hold sorted symbols */
	Word		ssndx;		/* global index into sorted_syms */
	Word		scndx;		/* scoped index into sorted_syms */
	size_t		stoff;		/* string offset */
	Aliste		idx1;

	/*
	 * Initialize pointers to the symbol table entries and the symbol
	 * table strings.  Skip the first symbol entry and the first string
	 * table byte.  Note that if we are not generating any output symbol
	 * tables we must still generate and update internal copies so
	 * that the relocation phase has the correct information.
	 */
	if (!(flags & FLG_OF_STRIP) || (flags & FLG_OF_RELOBJ) ||
	    ((flags & FLG_OF_STATIC) && ofl->ofl_osversym)) {
		symtab = (Sym *)ofl->ofl_ossymtab->os_outdata->d_buf;
		symtab[symtab_ndx++] = _sym;
		if (ofl->ofl_ossymshndx)
			symshndx =
			    (Word *)ofl->ofl_ossymshndx->os_outdata->d_buf;
	}
	if (OFL_ALLOW_DYNSYM(ofl)) {
		dynsym = (Sym *)ofl->ofl_osdynsym->os_outdata->d_buf;
		dynsym[dynsym_ndx++] = _sym;
		/*
		 * If we are also constructing a .SUNW_ldynsym section
		 * to contain local function symbols, then set it up too.
		 */
		if (ofl->ofl_osldynsym) {
			ldynsym = (Sym *)ofl->ofl_osldynsym->os_outdata->d_buf;
			ldynsym[ldynsym_ndx++] = _sym;
			ldynsym_cnt = 1 + ofl->ofl_dynlocscnt +
			    ofl->ofl_dynscopecnt;

			/*
			 * If there is a SUNW_ldynsym, then there may also
			 * be a .SUNW_dynsymsort and/or .SUNW_dyntlssort
			 * sections, used to collect indices of function
			 * and data symbols sorted by address order.
			 */
			if (ofl->ofl_osdynsymsort) {	/* .SUNW_dynsymsort */
				dynsymsort = (Word *)
				    ofl->ofl_osdynsymsort->os_outdata->d_buf;
				dynsymsort_ndx = 0;
			}
			if (ofl->ofl_osdyntlssort) {	/* .SUNW_dyntlssort */
				dyntlssort = (Word *)
				    ofl->ofl_osdyntlssort->os_outdata->d_buf;
				dyntlssort_ndx = 0;
			}
		}

		/*
		 * Initialize the hash table.
		 */
		hashtab = (Word *)(ofl->ofl_oshash->os_outdata->d_buf);
		hashbkt = &hashtab[2];
		hashchain = &hashtab[2 + ofl->ofl_hashbkts];
		hashtab[0] = ofl->ofl_hashbkts;
		hashtab[1] = DYNSYM_ALL_CNT(ofl);
		if (ofl->ofl_osdynshndx)
			dynshndx =
			    (Word *)ofl->ofl_osdynshndx->os_outdata->d_buf;
		if (ofl->ofl_osldynshndx)
			ldynshndx =
			    (Word *)ofl->ofl_osldynshndx->os_outdata->d_buf;
	}

	/*
	 * symndx is the symbol index to be used for relocation processing.  It
	 * points to the relevant symtab's (.dynsym or .symtab) symbol ndx.
	 */
	if (dynsym)
		symndx = &dynsym_ndx;
	else
		symndx = &symtab_ndx;

	/*
	 * If we have version definitions initialize the version symbol index
	 * table.  There is one entry for each symbol which contains the symbols
	 * version index.
	 */
	if (!(flags & FLG_OF_NOVERSEC) &&
	    (flags & (FLG_OF_VERNEED | FLG_OF_VERDEF))) {
		versym = (Versym *)ofl->ofl_osversym->os_outdata->d_buf;
		versym[0] = NULL;
	} else
		versym = NULL;

	/*
	 * If syminfo section exists be prepared to fill it in.
	 */
	if (ofl->ofl_ossyminfo) {
		syminfo = ofl->ofl_ossyminfo->os_outdata->d_buf;
		syminfo[0].si_flags = SYMINFO_CURRENT;
	} else
		syminfo = NULL;

	/*
	 * Setup our string tables.
	 */
	shstrtab = ofl->ofl_shdrsttab;
	strtab = ofl->ofl_strtab;
	dynstr = ofl->ofl_dynstrtab;

	DBG_CALL(Dbg_syms_sec_title(ofl->ofl_lml));

	/*
	 * Put output file name to the first .symtab and .SUNW_ldynsym symbol.
	 */
	if (symtab) {
		(void) st_setstring(strtab, ofl->ofl_name, &stoff);
		sym = &symtab[symtab_ndx++];
		/* LINTED */
		sym->st_name = stoff;
		sym->st_value = 0;
		sym->st_size = 0;
		sym->st_info = ELF_ST_INFO(STB_LOCAL, STT_FILE);
		sym->st_other = 0;
		sym->st_shndx = SHN_ABS;

		if (versym && !dynsym)
			versym[1] = 0;
	}
	if (ldynsym) {
		(void) st_setstring(dynstr, ofl->ofl_name, &stoff);
		sym = &ldynsym[ldynsym_ndx];
		/* LINTED */
		sym->st_name = stoff;
		sym->st_value = 0;
		sym->st_size = 0;
		sym->st_info = ELF_ST_INFO(STB_LOCAL, STT_FILE);
		sym->st_other = 0;
		sym->st_shndx = SHN_ABS;

		/* Scoped symbols get filled in global loop below */
		ldynscopesym_ndx = ldynsym_ndx + 1;
		ldynsym_ndx += ofl->ofl_dynscopecnt;
	}

	/*
	 * If we are to display GOT summary information, then allocate
	 * the buffer to 'cache' the GOT symbols into now.
	 */
	if (DBG_ENABLED) {
		if ((ofl->ofl_gottable = gottable =
		    libld_calloc(ofl->ofl_gotcnt, sizeof (Gottable))) == NULL)
			return ((Addr)S_ERROR);
	}

	/*
	 * Traverse the program headers.  Determine the last executable segment
	 * and the last data segment so that we can update etext and edata. If
	 * we have empty segments (reservations) record them for setting _end.
	 */
	for (APLIST_TRAVERSE(ofl->ofl_segs, idx1, sgp)) {
		Phdr	*phd = &(sgp->sg_phdr);
		Os_desc	*osp;
		Aliste	idx2;

		if (phd->p_type == PT_LOAD) {
			if (sgp->sg_osdescs != NULL) {
				Word	_flags = phd->p_flags & (PF_W | PF_R);

				if (_flags == PF_R)
					tsgp = sgp;
				else if (_flags == (PF_W | PF_R))
					dsgp = sgp;
			} else if (sgp->sg_flags & FLG_SG_EMPTY)
				esgp = sgp;
		}

		/*
		 * Generate a section symbol for each output section.
		 */
		for (APLIST_TRAVERSE(sgp->sg_osdescs, idx2, osp)) {
			Word	sectndx;

			sym = &_sym;
			sym->st_value = osp->os_shdr->sh_addr;
			sym->st_info = ELF_ST_INFO(STB_LOCAL, STT_SECTION);
			/* LINTED */
			sectndx = elf_ndxscn(osp->os_scn);

			if (symtab) {
				if (sectndx >= SHN_LORESERVE) {
					symshndx[symtab_ndx] = sectndx;
					sym->st_shndx = SHN_XINDEX;
				} else {
					/* LINTED */
					sym->st_shndx = (Half)sectndx;
				}
				symtab[symtab_ndx++] = *sym;
			}

			if (dynsym && (osp->os_flags & FLG_OS_OUTREL))
				dynsym[dynsym_ndx++] = *sym;

			if ((dynsym == NULL) ||
			    (osp->os_flags & FLG_OS_OUTREL)) {
				if (versym)
					versym[*symndx - 1] = 0;
				osp->os_identndx = *symndx - 1;
				DBG_CALL(Dbg_syms_sec_entry(ofl->ofl_lml,
				    osp->os_identndx, sgp, osp));
			}

			/*
			 * Generate the .shstrtab for this section.
			 */
			(void) st_setstring(shstrtab, osp->os_name, &stoff);
			osp->os_shdr->sh_name = (Word)stoff;

			/*
			 * Find the section index for our special symbols.
			 */
			if (sgp == tsgp) {
				/* LINTED */
				etext_ndx = elf_ndxscn(osp->os_scn);
			} else if (dsgp == sgp) {
				if (osp->os_shdr->sh_type != SHT_NOBITS) {
					/* LINTED */
					edata_ndx = elf_ndxscn(osp->os_scn);
				}
			}

			if (start_set == 0) {
				start = sgp->sg_phdr.p_vaddr;
				/* LINTED */
				start_ndx = elf_ndxscn(osp->os_scn);
				start_set++;
			}

			/*
			 * While we're here, determine whether a .init or .fini
			 * section exist.
			 */
			if ((iosp == NULL) && (strcmp(osp->os_name,
			    MSG_ORIG(MSG_SCN_INIT)) == 0))
				iosp = osp;
			if ((fosp == NULL) && (strcmp(osp->os_name,
			    MSG_ORIG(MSG_SCN_FINI)) == 0))
				fosp = osp;
		}
	}

	/*
	 * Add local register symbols to the .dynsym.  These are required as
	 * DT_REGISTER .dynamic entries must have a symbol to reference.
	 */
	if (ofl->ofl_regsyms && dynsym) {
		int	ndx;

		for (ndx = 0; ndx < ofl->ofl_regsymsno; ndx++) {
			Sym_desc	*rsdp;

			if ((rsdp = ofl->ofl_regsyms[ndx]) == NULL)
				continue;

			if (!SYM_IS_HIDDEN(rsdp) &&
			    (ELF_ST_BIND(rsdp->sd_sym->st_info) != STB_LOCAL))
				continue;

			dynsym[dynsym_ndx] = *(rsdp->sd_sym);
			rsdp->sd_symndx = *symndx;

			if (dynsym[dynsym_ndx].st_name) {
				(void) st_setstring(dynstr, rsdp->sd_name,
				    &stoff);
				dynsym[dynsym_ndx].st_name = stoff;
			}
			dynsym_ndx++;
		}
	}

	/*
	 * Having traversed all the output segments, warn the user if the
	 * traditional text or data segments don't exist.  Otherwise from these
	 * segments establish the values for `etext', `edata', `end', `END',
	 * and `START'.
	 */
	if (!(flags & FLG_OF_RELOBJ)) {
		Sg_desc	*sgp;

		if (tsgp)
			etext = tsgp->sg_phdr.p_vaddr + tsgp->sg_phdr.p_filesz;
		else {
			etext = (Addr)0;
			etext_ndx = SHN_ABS;
			etext_abs = 1;
			if (flags & FLG_OF_VERBOSE)
				eprintf(ofl->ofl_lml, ERR_WARNING,
				    MSG_INTL(MSG_UPD_NOREADSEG));
		}
		if (dsgp) {
			edata = dsgp->sg_phdr.p_vaddr + dsgp->sg_phdr.p_filesz;
		} else {
			edata = (Addr)0;
			edata_ndx = SHN_ABS;
			edata_abs = 1;
			if (flags & FLG_OF_VERBOSE)
				eprintf(ofl->ofl_lml, ERR_WARNING,
				    MSG_INTL(MSG_UPD_NORDWRSEG));
		}

		if (dsgp == NULL) {
			if (tsgp)
				sgp = tsgp;
			else
				sgp = 0;
		} else if (tsgp == NULL)
			sgp = dsgp;
		else if (dsgp->sg_phdr.p_vaddr > tsgp->sg_phdr.p_vaddr)
			sgp = dsgp;
		else if (dsgp->sg_phdr.p_vaddr < tsgp->sg_phdr.p_vaddr)
			sgp = tsgp;
		else {
			/*
			 * One of the segments must be of zero size.
			 */
			if (tsgp->sg_phdr.p_memsz)
				sgp = tsgp;
			else
				sgp = dsgp;
		}

		if (esgp && (esgp->sg_phdr.p_vaddr > sgp->sg_phdr.p_vaddr))
			sgp = esgp;

		if (sgp) {
			end = sgp->sg_phdr.p_vaddr + sgp->sg_phdr.p_memsz;

			/*
			 * If the last loadable segment is a read-only segment,
			 * then the application which uses the symbol _end to
			 * find the beginning of writable heap area may cause
			 * segmentation violation. We adjust the value of the
			 * _end to skip to the next page boundary.
			 *
			 * 6401812 System interface which returs beginning
			 *	   heap would be nice.
			 * When the above RFE is implemented, the changes below
			 * could be changed in a better way.
			 */
			if ((sgp->sg_phdr.p_flags & PF_W) == 0)
				end = (Addr)S_ROUND(end, sysconf(_SC_PAGESIZE));

			/*
			 * If we're dealing with a memory reservation there are
			 * no sections to establish an index for _end, so assign
			 * it as an absolute.
			 */
			if (sgp->sg_osdescs != NULL) {
				/*
				 * Determine the last section for this segment.
				 */
				Os_desc	*osp = sgp->sg_osdescs->apl_data
				    [sgp->sg_osdescs->apl_nitems - 1];

				/* LINTED */
				end_ndx = elf_ndxscn(osp->os_scn);
			} else {
				end_ndx = SHN_ABS;
				end_abs = 1;
			}
		} else {
			end = (Addr) 0;
			end_ndx = SHN_ABS;
			end_abs = 1;
			eprintf(ofl->ofl_lml, ERR_WARNING,
			    MSG_INTL(MSG_UPD_NOSEG));
		}
	}

	/*
	 * Initialize the scoped symbol table entry point.  This is for all
	 * the global symbols that have been scoped to locals and will be
	 * filled in during global symbol processing so that we don't have
	 * to traverse the globals symbol hash array more than once.
	 */
	if (symtab) {
		scopesym_bndx = symtab_ndx;
		scopesym_ndx = scopesym_bndx;
		symtab_ndx += ofl->ofl_scopecnt;
	}

	/*
	 * If expanding partially expanded symbols under '-z nopartial',
	 * prepare to do that.
	 */
	if (ofl->ofl_isparexpn) {
		osp = ofl->ofl_isparexpn->is_osdesc;
		parexpnbase = parexpnaddr = (Addr)(osp->os_shdr->sh_addr +
		    ofl->ofl_isparexpn->is_indata->d_off);
		/* LINTED */
		parexpnndx = elf_ndxscn(osp->os_scn);
		ofl->ofl_parexpnndx = osp->os_identndx;
	}

	/*
	 * If we are generating a .symtab collect all the local symbols,
	 * assigning a new virtual address or displacement (value).
	 */
	for (APLIST_TRAVERSE(ofl->ofl_objs, idx1, ifl)) {
		Xword		lndx, local = ifl->ifl_locscnt;
		Cap_desc	*cdp = ifl->ifl_caps;

		for (lndx = 1; lndx < local; lndx++) {
			Gotndx		*gnp;
			uchar_t		type;
			Word		*_symshndx;
			int		enter_in_symtab, enter_in_ldynsym;
			int		update_done;

			sdp = ifl->ifl_oldndx[lndx];
			sym = sdp->sd_sym;

			/*
			 * Assign a got offset if necessary.
			 */
			if ((ld_targ.t_mr.mr_assign_got != NULL) &&
			    (*ld_targ.t_mr.mr_assign_got)(ofl, sdp) == S_ERROR)
				return ((Addr)S_ERROR);

			if (DBG_ENABLED) {
				Aliste	idx2;

				for (ALIST_TRAVERSE(sdp->sd_GOTndxs,
				    idx2, gnp)) {
					gottable->gt_sym = sdp;
					gottable->gt_gndx.gn_gotndx =
					    gnp->gn_gotndx;
					gottable->gt_gndx.gn_addend =
					    gnp->gn_addend;
					gottable++;
				}
			}

			if ((type = ELF_ST_TYPE(sym->st_info)) == STT_SECTION)
				continue;

			/*
			 * Ignore any symbols that have been marked as invalid
			 * during input processing.  Providing these aren't used
			 * for relocation they'll just be dropped from the
			 * output image.
			 */
			if (sdp->sd_flags & FLG_SY_INVALID)
				continue;

			/*
			 * If the section that this symbol was associated
			 * with has been discarded - then we discard
			 * the local symbol along with it.
			 */
			if (sdp->sd_flags & FLG_SY_ISDISC)
				continue;

			/*
			 * If this symbol is from a different file
			 * than the input descriptor we are processing,
			 * treat it as if it has FLG_SY_ISDISC set.
			 * This happens when sloppy_comdat_reloc()
			 * replaces a symbol to a discarded comdat section
			 * with an equivalent symbol from a different
			 * file. We only want to enter such a symbol
			 * once --- as part of the file that actually
			 * supplies it.
			 */
			if (ifl != sdp->sd_file)
				continue;

			/*
			 * Generate an output symbol to represent this input
			 * symbol.  Even if the symbol table is to be stripped
			 * we still need to update any local symbols that are
			 * used during relocation.
			 */
			enter_in_symtab = symtab &&
			    (!(ofl->ofl_flags & FLG_OF_REDLSYM) ||
			    sdp->sd_move);
			enter_in_ldynsym = ldynsym && sdp->sd_name &&
			    ldynsym_symtype[type] &&
			    !(ofl->ofl_flags & FLG_OF_REDLSYM);
			_symshndx = NULL;

			if (enter_in_symtab) {
				if (!dynsym)
					sdp->sd_symndx = *symndx;
				symtab[symtab_ndx] = *sym;

				/*
				 * Provided this isn't an unnamed register
				 * symbol, update its name.
				 */
				if (((sdp->sd_flags & FLG_SY_REGSYM) == 0) ||
				    symtab[symtab_ndx].st_name) {
					(void) st_setstring(strtab,
					    sdp->sd_name, &stoff);
					symtab[symtab_ndx].st_name = stoff;
				}
				sdp->sd_flags &= ~FLG_SY_CLEAN;
				if (symshndx)
					_symshndx = &symshndx[symtab_ndx];
				sdp->sd_sym = sym = &symtab[symtab_ndx++];

				if ((sdp->sd_flags & FLG_SY_SPECSEC) &&
				    (sym->st_shndx == SHN_ABS) &&
				    !enter_in_ldynsym)
					continue;
			} else if (enter_in_ldynsym) {
				/*
				 * Not using symtab, but we do have ldynsym
				 * available.
				 */
				ldynsym[ldynsym_ndx] = *sym;
				(void) st_setstring(dynstr, sdp->sd_name,
				    &stoff);
				ldynsym[ldynsym_ndx].st_name = stoff;

				sdp->sd_flags &= ~FLG_SY_CLEAN;
				if (ldynshndx)
					_symshndx = &ldynshndx[ldynsym_ndx];
				sdp->sd_sym = sym = &ldynsym[ldynsym_ndx];
				/* Add it to sort section if it qualifies */
				ADD_TO_DYNSORT(sdp, sym, type, ldynsym_ndx);
				ldynsym_ndx++;
			} else {	/* Not using symtab or ldynsym */
				/*
				 * If this symbol requires modifying to provide
				 * for a relocation or move table update, make
				 * a copy of it.
				 */
				if (!(sdp->sd_flags & FLG_SY_UPREQD) &&
				    !(sdp->sd_move))
					continue;
				if ((sdp->sd_flags & FLG_SY_SPECSEC) &&
				    (sym->st_shndx == SHN_ABS))
					continue;

				if (ld_sym_copy(sdp) == S_ERROR)
					return ((Addr)S_ERROR);
				sym = sdp->sd_sym;
			}

			/*
			 * Update the symbols contents if necessary.
			 */
			update_done = 0;
			if (type == STT_FILE) {
				sdp->sd_shndx = sym->st_shndx = SHN_ABS;
				sdp->sd_flags |= FLG_SY_SPECSEC;
				update_done = 1;
			}

			/*
			 * If we are expanding the locally bound partially
			 * initialized symbols, then update the address here.
			 */
			if (ofl->ofl_isparexpn &&
			    (sdp->sd_flags & FLG_SY_PAREXPN) && !update_done) {
				sym->st_shndx = parexpnndx;
				sdp->sd_isc = ofl->ofl_isparexpn;
				sym->st_value = parexpnaddr;
				parexpnaddr += sym->st_size;
				if ((flags & FLG_OF_RELOBJ) == 0)
					sym->st_value -= parexpnbase;
			}

			/*
			 * If this isn't an UNDEF symbol (ie. an input section
			 * is associated), update the symbols value and index.
			 */
			if (((isc = sdp->sd_isc) != NULL) && !update_done) {
				Word	sectndx;

				osp = isc->is_osdesc;
				/* LINTED */
				sym->st_value +=
				    (Off)_elf_getxoff(isc->is_indata);
				if ((flags & FLG_OF_RELOBJ) == 0) {
					sym->st_value += osp->os_shdr->sh_addr;
					/*
					 * TLS symbols are relative to
					 * the TLS segment.
					 */
					if ((type == STT_TLS) &&
					    (ofl->ofl_tlsphdr)) {
						sym->st_value -=
						    ofl->ofl_tlsphdr->p_vaddr;
					}
				}
				/* LINTED */
				if ((sdp->sd_shndx = sectndx =
				    elf_ndxscn(osp->os_scn)) >= SHN_LORESERVE) {
					if (_symshndx) {
						*_symshndx = sectndx;
					}
					sym->st_shndx = SHN_XINDEX;
				} else {
					/* LINTED */
					sym->st_shndx = sectndx;
				}
			}

			/*
			 * If entering the symbol in both the symtab and the
			 * ldynsym, then the one in symtab needs to be
			 * copied to ldynsym. If it is only in the ldynsym,
			 * then the code above already set it up and we have
			 * nothing more to do here.
			 */
			if (enter_in_symtab && enter_in_ldynsym) {
				ldynsym[ldynsym_ndx] = *sym;
				(void) st_setstring(dynstr, sdp->sd_name,
				    &stoff);
				ldynsym[ldynsym_ndx].st_name = stoff;

				if (_symshndx && ldynshndx)
					ldynshndx[ldynsym_ndx] = *_symshndx;

				/* Add it to sort section if it qualifies */
				ADD_TO_DYNSORT(sdp, sym, type, ldynsym_ndx);

				ldynsym_ndx++;
			}
		}

		/*
		 * If this input file has undergone object to symbol
		 * capabilities conversion, supply any new capabilities symbols.
		 * These symbols are copies of the original global symbols, and
		 * follow the existing local symbols that are supplied from this
		 * input file (which are identified with a preceding STT_FILE).
		 */
		if (symtab && cdp && cdp->ca_syms) {
			Aliste		idx2;
			Cap_sym		*csp;

			for (APLIST_TRAVERSE(cdp->ca_syms, idx2, csp)) {
				Is_desc	*isp;

				sdp = csp->cs_sdp;
				sym = sdp->sd_sym;

				if ((isp = sdp->sd_isc) != NULL) {
					Os_desc	*osp = isp->is_osdesc;

					/*
					 * Update the symbols value.
					 */
					/* LINTED */
					sym->st_value +=
					    (Off)_elf_getxoff(isp->is_indata);
					if ((flags & FLG_OF_RELOBJ) == 0)
						sym->st_value +=
						    osp->os_shdr->sh_addr;

					/*
					 * Update the symbols section index.
					 */
					sdp->sd_shndx = sym->st_shndx =
					    elf_ndxscn(osp->os_scn);
				}

				symtab[symtab_ndx] = *sym;
				(void) st_setstring(strtab, sdp->sd_name,
				    &stoff);
				symtab[symtab_ndx].st_name = stoff;
				sdp->sd_symndx = symtab_ndx++;
			}
		}
	}

	symtab_gbl_bndx = symtab_ndx;	/* .symtab index of 1st global entry */

	/*
	 * Two special symbols are `_init' and `_fini'.  If these are supplied
	 * by crti.o then they are used to represent the total concatenation of
	 * the `.init' and `.fini' sections.
	 *
	 * Determine whether any .init or .fini sections exist.  If these
	 * sections exist and a dynamic object is being built, but no `_init'
	 * or `_fini' symbols are found, then the user is probably building
	 * this object directly from ld(1) rather than using a compiler driver
	 * that provides the symbols via crt's.
	 *
	 * If the .init or .fini section exist, and their associated symbols,
	 * determine the size of the sections and updated the symbols value
	 * accordingly.
	 */
	if (((sdp = ld_sym_find(MSG_ORIG(MSG_SYM_INIT_U), SYM_NOHASH, 0,
	    ofl)) != NULL) && (sdp->sd_ref == REF_REL_NEED) && sdp->sd_isc &&
	    (sdp->sd_isc->is_osdesc == iosp)) {
		if (ld_sym_copy(sdp) == S_ERROR)
			return ((Addr)S_ERROR);
		sdp->sd_sym->st_size = sdp->sd_isc->is_osdesc->os_shdr->sh_size;

	} else if (iosp && !(flags & FLG_OF_RELOBJ)) {
		eprintf(ofl->ofl_lml, ERR_WARNING, MSG_INTL(MSG_SYM_NOCRT),
		    MSG_ORIG(MSG_SYM_INIT_U), MSG_ORIG(MSG_SCN_INIT));
	}

	if (((sdp = ld_sym_find(MSG_ORIG(MSG_SYM_FINI_U), SYM_NOHASH, 0,
	    ofl)) != NULL) && (sdp->sd_ref == REF_REL_NEED) && sdp->sd_isc &&
	    (sdp->sd_isc->is_osdesc == fosp)) {
		if (ld_sym_copy(sdp) == S_ERROR)
			return ((Addr)S_ERROR);
		sdp->sd_sym->st_size = sdp->sd_isc->is_osdesc->os_shdr->sh_size;

	} else if (fosp && !(flags & FLG_OF_RELOBJ)) {
		eprintf(ofl->ofl_lml, ERR_WARNING, MSG_INTL(MSG_SYM_NOCRT),
		    MSG_ORIG(MSG_SYM_FINI_U), MSG_ORIG(MSG_SCN_FINI));
	}

	/*
	 * Assign .bss information for use with updating COMMON symbols.
	 */
	if (ofl->ofl_isbss) {
		isc = ofl->ofl_isbss;
		osp = isc->is_osdesc;

		bssaddr = osp->os_shdr->sh_addr +
		    (Off)_elf_getxoff(isc->is_indata);
		/* LINTED */
		bssndx = elf_ndxscn(osp->os_scn);
	}

#if	defined(_ELF64)
	/*
	 * For amd64 target, assign .lbss information for use
	 * with updating LCOMMON symbols.
	 */
	if ((ld_targ.t_m.m_mach == EM_AMD64) && ofl->ofl_islbss) {
		osp = ofl->ofl_islbss->is_osdesc;

		lbssaddr = osp->os_shdr->sh_addr +
		    (Off)_elf_getxoff(ofl->ofl_islbss->is_indata);
		/* LINTED */
		lbssndx = elf_ndxscn(osp->os_scn);
	}
#endif
	/*
	 * Assign .tlsbss information for use with updating COMMON symbols.
	 */
	if (ofl->ofl_istlsbss) {
		osp = ofl->ofl_istlsbss->is_osdesc;
		tlsbssaddr = osp->os_shdr->sh_addr +
		    (Off)_elf_getxoff(ofl->ofl_istlsbss->is_indata);
		/* LINTED */
		tlsbssndx = elf_ndxscn(osp->os_scn);
	}

	if ((sorted_syms = libld_calloc(ofl->ofl_globcnt +
	    ofl->ofl_elimcnt + ofl->ofl_scopecnt,
	    sizeof (*sorted_syms))) == NULL)
		return ((Addr)S_ERROR);

	scndx = 0;
	ssndx = ofl->ofl_scopecnt + ofl->ofl_elimcnt;

	DBG_CALL(Dbg_syms_up_title(ofl->ofl_lml));

	/*
	 * Traverse the internal symbol table updating global symbol information
	 * and allocating common.
	 */
	for (sav = avl_first(&ofl->ofl_symavl); sav;
	    sav = AVL_NEXT(&ofl->ofl_symavl, sav)) {
		Sym	*symptr;
		int	local;
		int	restore;

		sdp = sav->sav_sdp;

		/*
		 * Ignore any symbols that have been marked as invalid during
		 * input processing.  Providing these aren't used for
		 * relocation, they will be dropped from the output image.
		 */
		if (sdp->sd_flags & FLG_SY_INVALID) {
			DBG_CALL(Dbg_syms_old(ofl, sdp));
			DBG_CALL(Dbg_syms_ignore(ofl, sdp));
			continue;
		}

		/*
		 * Only needed symbols are copied to the output symbol table.
		 */
		if (sdp->sd_ref == REF_DYN_SEEN)
			continue;

		if (SYM_IS_HIDDEN(sdp) && (flags & FLG_OF_PROCRED))
			local = 1;
		else
			local = 0;

		if (local || (ofl->ofl_hashbkts == 0)) {
			sorted_syms[scndx++].sl_sdp = sdp;
		} else {
			sorted_syms[ssndx].sl_hval = sdp->sd_aux->sa_hash %
			    ofl->ofl_hashbkts;
			sorted_syms[ssndx].sl_sdp = sdp;
			ssndx++;
		}

		/*
		 * Note - expand the COMMON symbols here because an address
		 * must be assigned to them in the same order that space was
		 * calculated in sym_validate().  If this ordering isn't
		 * followed differing alignment requirements can throw us all
		 * out of whack.
		 *
		 * The expanded .bss global symbol is handled here as well.
		 *
		 * The actual adding entries into the symbol table still occurs
		 * below in hashbucket order.
		 */
		symptr = sdp->sd_sym;
		restore = 0;
		if ((sdp->sd_flags & FLG_SY_PAREXPN) ||
		    ((sdp->sd_flags & FLG_SY_SPECSEC) &&
		    (sdp->sd_shndx = symptr->st_shndx) == SHN_COMMON)) {

			/*
			 * An expanded symbol goes to a special .data section
			 * prepared for that purpose (ofl->ofl_isparexpn).
			 * Assign COMMON allocations to .bss.
			 * Otherwise leave it as is.
			 */
			if (sdp->sd_flags & FLG_SY_PAREXPN) {
				restore = 1;
				sdp->sd_shndx = parexpnndx;
				sdp->sd_flags &= ~FLG_SY_SPECSEC;
				symptr->st_value = (Xword) S_ROUND(
				    parexpnaddr, symptr->st_value);
				parexpnaddr = symptr->st_value +
				    symptr->st_size;
				sdp->sd_isc = ofl->ofl_isparexpn;
				sdp->sd_flags |= FLG_SY_COMMEXP;

			} else if (ELF_ST_TYPE(symptr->st_info) != STT_TLS &&
			    (local || !(flags & FLG_OF_RELOBJ))) {
				restore = 1;
				sdp->sd_shndx = bssndx;
				sdp->sd_flags &= ~FLG_SY_SPECSEC;
				symptr->st_value = (Xword)S_ROUND(bssaddr,
				    symptr->st_value);
				bssaddr = symptr->st_value + symptr->st_size;
				sdp->sd_isc = ofl->ofl_isbss;
				sdp->sd_flags |= FLG_SY_COMMEXP;

			} else if (ELF_ST_TYPE(symptr->st_info) == STT_TLS &&
			    (local || !(flags & FLG_OF_RELOBJ))) {
				restore = 1;
				sdp->sd_shndx = tlsbssndx;
				sdp->sd_flags &= ~FLG_SY_SPECSEC;
				symptr->st_value = (Xword)S_ROUND(tlsbssaddr,
				    symptr->st_value);
				tlsbssaddr = symptr->st_value + symptr->st_size;
				sdp->sd_isc = ofl->ofl_istlsbss;
				sdp->sd_flags |= FLG_SY_COMMEXP;
				/*
				 * TLS symbols are relative to the TLS segment.
				 */
				symptr->st_value -= ofl->ofl_tlsphdr->p_vaddr;
			}
#if	defined(_ELF64)
		} else if ((ld_targ.t_m.m_mach == EM_AMD64) &&
		    (sdp->sd_flags & FLG_SY_SPECSEC) &&
		    ((sdp->sd_shndx = symptr->st_shndx) ==
		    SHN_X86_64_LCOMMON) &&
		    ((local || !(flags & FLG_OF_RELOBJ)))) {
			restore = 1;
			sdp->sd_shndx = lbssndx;
			sdp->sd_flags &= ~FLG_SY_SPECSEC;
			symptr->st_value = (Xword)S_ROUND(lbssaddr,
			    symptr->st_value);
			lbssaddr = symptr->st_value + symptr->st_size;
			sdp->sd_isc = ofl->ofl_islbss;
			sdp->sd_flags |= FLG_SY_COMMEXP;
#endif
		}

		if (restore != 0) {
			uchar_t		type, bind;

			/*
			 * Make sure this COMMON symbol is returned to the same
			 * binding as was defined in the original relocatable
			 * object reference.
			 */
			type = ELF_ST_TYPE(symptr->st_info);
			if (sdp->sd_flags & FLG_SY_GLOBREF)
				bind = STB_GLOBAL;
			else
				bind = STB_WEAK;

			symptr->st_info = ELF_ST_INFO(bind, type);
		}
	}

	/*
	 * If this is a dynamic object then add any local capabilities symbols.
	 */
	if (dynsym && ofl->ofl_capfamilies) {
		Cap_avlnode	*cav;

		for (cav = avl_first(ofl->ofl_capfamilies); cav;
		    cav = AVL_NEXT(ofl->ofl_capfamilies, cav)) {
			Cap_sym		*csp;
			Aliste		idx;

			for (APLIST_TRAVERSE(cav->cn_members, idx, csp)) {
				sdp = csp->cs_sdp;

				DBG_CALL(Dbg_syms_created(ofl->ofl_lml,
				    sdp->sd_name));
				DBG_CALL(Dbg_syms_entered(ofl, sdp->sd_sym,
				    sdp));

				dynsym[dynsym_ndx] = *sdp->sd_sym;

				(void) st_setstring(dynstr, sdp->sd_name,
				    &stoff);
				dynsym[dynsym_ndx].st_name = stoff;

				sdp->sd_sym = &dynsym[dynsym_ndx];
				sdp->sd_symndx = dynsym_ndx;

				/*
				 * Indicate that this is a capabilities symbol.
				 * Note, that this identification only provides
				 * information regarding the symbol that is
				 * visible from elfdump(1) -y.  The association
				 * of a symbol to its capabilities is derived
				 * from a .SUNW_capinfo entry.
				 */
				if (syminfo) {
					syminfo[dynsym_ndx].si_flags |=
					    SYMINFO_FLG_CAP;
				}

				dynsym_ndx++;
			}
		}
	}

	if (ofl->ofl_hashbkts) {
		qsort(sorted_syms + ofl->ofl_scopecnt + ofl->ofl_elimcnt,
		    ofl->ofl_globcnt, sizeof (Sym_s_list),
		    (int (*)(const void *, const void *))sym_hash_compare);
	}

	for (ssndx = 0; ssndx < (ofl->ofl_elimcnt + ofl->ofl_scopecnt +
	    ofl->ofl_globcnt); ssndx++) {
		const char	*name;
		Sym		*sym;
		Sym_aux		*sap;
		Half		spec;
		int		local = 0, dynlocal = 0, enter_in_symtab;
		Gotndx		*gnp;
		Word		sectndx;

		sdp = sorted_syms[ssndx].sl_sdp;
		sectndx = 0;

		if (symtab)
			enter_in_symtab = 1;
		else
			enter_in_symtab = 0;

		/*
		 * Assign a got offset if necessary.
		 */
		if ((ld_targ.t_mr.mr_assign_got != NULL) &&
		    (*ld_targ.t_mr.mr_assign_got)(ofl, sdp) == S_ERROR)
			return ((Addr)S_ERROR);

		if (DBG_ENABLED) {
			Aliste	idx2;

			for (ALIST_TRAVERSE(sdp->sd_GOTndxs, idx2, gnp)) {
				gottable->gt_sym = sdp;
				gottable->gt_gndx.gn_gotndx = gnp->gn_gotndx;
				gottable->gt_gndx.gn_addend = gnp->gn_addend;
				gottable++;
			}

			if (sdp->sd_aux && sdp->sd_aux->sa_PLTGOTndx) {
				gottable->gt_sym = sdp;
				gottable->gt_gndx.gn_gotndx =
				    sdp->sd_aux->sa_PLTGOTndx;
				gottable++;
			}
		}

		/*
		 * If this symbol has been marked as being reduced to local
		 * scope then it will have to be placed in the scoped portion
		 * of the .symtab.  Retain the appropriate index for use in
		 * version symbol indexing and relocation.
		 */
		if (SYM_IS_HIDDEN(sdp) && (flags & FLG_OF_PROCRED)) {
			local = 1;
			if (!(sdp->sd_flags & FLG_SY_ELIM) && !dynsym)
				sdp->sd_symndx = scopesym_ndx;
			else
				sdp->sd_symndx = 0;

			if (sdp->sd_flags & FLG_SY_ELIM) {
				enter_in_symtab = 0;
			} else if (ldynsym && sdp->sd_sym->st_name &&
			    ldynsym_symtype[
			    ELF_ST_TYPE(sdp->sd_sym->st_info)]) {
				dynlocal = 1;
			}
		} else {
			sdp->sd_symndx = *symndx;
		}

		/*
		 * Copy basic symbol and string information.
		 */
		name = sdp->sd_name;
		sap = sdp->sd_aux;

		/*
		 * If we require to record version symbol indexes, update the
		 * associated version symbol information for all defined
		 * symbols.  If a version definition is required any zero value
		 * symbol indexes would have been flagged as undefined symbol
		 * errors, however if we're just scoping these need to fall into
		 * the base of global symbols.
		 */
		if (sdp->sd_symndx && versym) {
			Half	vndx = 0;

			if (sdp->sd_flags & FLG_SY_MVTOCOMM) {
				vndx = VER_NDX_GLOBAL;
			} else if (sdp->sd_ref == REF_REL_NEED) {
				vndx = sap->sa_overndx;

				if ((vndx == 0) &&
				    (sdp->sd_sym->st_shndx != SHN_UNDEF)) {
					if (SYM_IS_HIDDEN(sdp))
						vndx = VER_NDX_LOCAL;
					else
						vndx = VER_NDX_GLOBAL;
				}
			} else if ((sdp->sd_ref == REF_DYN_NEED) &&
			    (sap->sa_dverndx > 0) &&
			    (sap->sa_dverndx <= sdp->sd_file->ifl_vercnt) &&
			    (sdp->sd_file->ifl_verndx != NULL)) {
				/* Use index of verneed record */
				vndx = sdp->sd_file->ifl_verndx
				    [sap->sa_dverndx].vi_overndx;
			}
			versym[sdp->sd_symndx] = vndx;
		}

		/*
		 * If we are creating the .syminfo section then set per symbol
		 * flags here.
		 */
		if (sdp->sd_symndx && syminfo &&
		    !(sdp->sd_flags & FLG_SY_NOTAVAIL)) {
			int	ndx = sdp->sd_symndx;
			APlist	**alpp = &(ofl->ofl_symdtent);

			if (sdp->sd_flags & FLG_SY_MVTOCOMM)
				/*
				 * Identify a copy relocation symbol.
				 */
				syminfo[ndx].si_flags |= SYMINFO_FLG_COPY;

			if (sdp->sd_ref == REF_DYN_NEED) {
				/*
				 * A reference is bound to a needed dependency.
				 * Save the syminfo entry, so that when the
				 * .dynamic section has been updated, a
				 * DT_NEEDED entry can be associated
				 * (see update_osyminfo()).
				 */
				if (aplist_append(alpp, sdp,
				    AL_CNT_OFL_SYMINFOSYMS) == NULL)
					return (0);

				/*
				 * Flag that the symbol has a direct association
				 * with the external reference (this is an old
				 * tagging, that has no real effect by itself).
				 */
				syminfo[ndx].si_flags |= SYMINFO_FLG_DIRECT;

				/*
				 * Flag any lazy or deferred reference.
				 */
				if (sdp->sd_flags & FLG_SY_LAZYLD)
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_LAZYLOAD;
				if (sdp->sd_flags & FLG_SY_DEFERRED)
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_DEFERRED;

				/*
				 * Enable direct symbol bindings if:
				 *
				 *  -	Symbol was identified with the DIRECT
				 *	keyword in a mapfile.
				 *
				 *  -	Symbol reference has been bound to a
				 * 	dependency which was specified as
				 *	requiring direct bindings with -zdirect.
				 *
				 *  -	All symbol references are required to
				 *	use direct bindings via -Bdirect.
				 */
				if (sdp->sd_flags & FLG_SY_DIR)
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_DIRECTBIND;

			} else if ((sdp->sd_flags & FLG_SY_EXTERN) &&
			    (sdp->sd_sym->st_shndx == SHN_UNDEF)) {
				/*
				 * If this symbol has been explicitly defined
				 * as external, and remains unresolved, mark
				 * it as external.
				 */
				syminfo[ndx].si_boundto = SYMINFO_BT_EXTERN;

			} else if ((sdp->sd_flags & FLG_SY_PARENT) &&
			    (sdp->sd_sym->st_shndx == SHN_UNDEF)) {
				/*
				 * If this symbol has been explicitly defined
				 * to be a reference to a parent object,
				 * indicate whether a direct binding should be
				 * established.
				 */
				syminfo[ndx].si_flags |= SYMINFO_FLG_DIRECT;
				syminfo[ndx].si_boundto = SYMINFO_BT_PARENT;
				if (sdp->sd_flags & FLG_SY_DIR)
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_DIRECTBIND;

			} else if (sdp->sd_flags & FLG_SY_STDFLTR) {
				/*
				 * A filter definition.  Although this symbol
				 * can only be a stub, it might be necessary to
				 * prevent external direct bindings.
				 */
				syminfo[ndx].si_flags |= SYMINFO_FLG_FILTER;
				if (sdp->sd_flags & FLG_SY_NDIR)
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_NOEXTDIRECT;

			} else if (sdp->sd_flags & FLG_SY_AUXFLTR) {
				/*
				 * An auxiliary filter definition.  By nature,
				 * this definition is direct, in that should the
				 * filtee lookup fail, we'll fall back to this
				 * object.  It may still be necessary to
				 * prevent external direct bindings.
				 */
				syminfo[ndx].si_flags |= SYMINFO_FLG_AUXILIARY;
				if (sdp->sd_flags & FLG_SY_NDIR)
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_NOEXTDIRECT;

			} else if ((sdp->sd_ref == REF_REL_NEED) &&
			    (sdp->sd_sym->st_shndx != SHN_UNDEF)) {
				/*
				 * This definition exists within the object
				 * being created.  Provide a default boundto
				 * definition, which may be overridden later.
				 */
				syminfo[ndx].si_boundto = SYMINFO_BT_NONE;

				/*
				 * Indicate whether it is necessary to prevent
				 * external direct bindings.
				 */
				if (sdp->sd_flags & FLG_SY_NDIR) {
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_NOEXTDIRECT;
				}

				/*
				 * Indicate that this symbol is acting as an
				 * individual interposer.
				 */
				if (sdp->sd_flags & FLG_SY_INTPOSE) {
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_INTERPOSE;
				}

				/*
				 * Indicate that this symbol is deferred, and
				 * hence should not be bound to during BIND_NOW
				 * relocations.
				 */
				if (sdp->sd_flags & FLG_SY_DEFERRED) {
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_DEFERRED;
				}

				/*
				 * If external bindings are allowed, indicate
				 * the binding, and a direct binding if
				 * necessary.
				 */
				if ((sdp->sd_flags & FLG_SY_NDIR) == 0) {
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_DIRECT;

					if (sdp->sd_flags & FLG_SY_DIR)
						syminfo[ndx].si_flags |=
						    SYMINFO_FLG_DIRECTBIND;

					/*
					 * Provide a default boundto definition,
					 * which may be overridden later.
					 */
					syminfo[ndx].si_boundto =
					    SYMINFO_BT_SELF;
				}

				/*
				 * Indicate that this is a capabilities symbol.
				 * Note, that this identification only provides
				 * information regarding the symbol that is
				 * visible from elfdump(1) -y.  The association
				 * of a symbol to its capabilities is derived
				 * from a .SUNW_capinfo entry.
				 */
				if ((sdp->sd_flags & FLG_SY_CAP) &&
				    ofl->ofl_oscapinfo) {
					syminfo[ndx].si_flags |=
					    SYMINFO_FLG_CAP;
				}
			}
		}

		/*
		 * Note that the `sym' value is reset to be one of the new
		 * symbol table entries.  This symbol will be updated further
		 * depending on the type of the symbol.  Process the .symtab
		 * first, followed by the .dynsym, thus the `sym' value will
		 * remain as the .dynsym value when the .dynsym is present.
		 * This ensures that any versioning symbols st_name value will
		 * be appropriate for the string table used by version
		 * entries.
		 */
		if (enter_in_symtab) {
			Word	_symndx;

			if (local)
				_symndx = scopesym_ndx;
			else
				_symndx = symtab_ndx;

			symtab[_symndx] = *sdp->sd_sym;
			sdp->sd_sym = sym = &symtab[_symndx];
			(void) st_setstring(strtab, name, &stoff);
			sym->st_name = stoff;
		}
		if (dynlocal) {
			ldynsym[ldynscopesym_ndx] = *sdp->sd_sym;
			sdp->sd_sym = sym = &ldynsym[ldynscopesym_ndx];
			(void) st_setstring(dynstr, name, &stoff);
			ldynsym[ldynscopesym_ndx].st_name = stoff;
			/* Add it to sort section if it qualifies */
			ADD_TO_DYNSORT(sdp, sym, ELF_ST_TYPE(sym->st_info),
			    ldynscopesym_ndx);
		}

		if (dynsym && !local) {
			dynsym[dynsym_ndx] = *sdp->sd_sym;

			/*
			 * Provided this isn't an unnamed register symbol,
			 * update the symbols name and hash value.
			 */
			if (((sdp->sd_flags & FLG_SY_REGSYM) == 0) ||
			    dynsym[dynsym_ndx].st_name) {
				(void) st_setstring(dynstr, name, &stoff);
				dynsym[dynsym_ndx].st_name = stoff;

				if (stoff) {
					Word	hashval, _hashndx;

					hashval =
					    sap->sa_hash % ofl->ofl_hashbkts;

					/* LINTED */
					if (_hashndx = hashbkt[hashval]) {
						while (hashchain[_hashndx]) {
							_hashndx =
							    hashchain[_hashndx];
						}
						hashchain[_hashndx] =
						    sdp->sd_symndx;
					} else {
						hashbkt[hashval] =
						    sdp->sd_symndx;
					}
				}
			}
			sdp->sd_sym = sym = &dynsym[dynsym_ndx];

			/*
			 * Add it to sort section if it qualifies.
			 * The indexes in that section are relative to the
			 * the adjacent SUNW_ldynsym/dymsym pair, so we
			 * add the number of items in SUNW_ldynsym to the
			 * dynsym index.
			 */
			ADD_TO_DYNSORT(sdp, sym, ELF_ST_TYPE(sym->st_info),
			    ldynsym_cnt + dynsym_ndx);
		}

		if (!enter_in_symtab && (!dynsym || (local && !dynlocal))) {
			if (!(sdp->sd_flags & FLG_SY_UPREQD))
				continue;
			sym = sdp->sd_sym;
		} else
			sdp->sd_flags &= ~FLG_SY_CLEAN;

		/*
		 * If we have a weak data symbol for which we need the real
		 * symbol also, save this processing until later.
		 *
		 * The exception to this is if the weak/strong have PLT's
		 * assigned to them.  In that case we don't do the post-weak
		 * processing because the PLT's must be maintained so that we
		 * can do 'interpositioning' on both of the symbols.
		 */
		if ((sap->sa_linkndx) &&
		    (ELF_ST_BIND(sym->st_info) == STB_WEAK) &&
		    (!sap->sa_PLTndx)) {
			Sym_desc	*_sdp;

			_sdp = sdp->sd_file->ifl_oldndx[sap->sa_linkndx];

			if (_sdp->sd_ref != REF_DYN_SEEN) {
				Wk_desc	wk;

				if (enter_in_symtab) {
					if (local) {
						wk.wk_symtab =
						    &symtab[scopesym_ndx];
						scopesym_ndx++;
					} else {
						wk.wk_symtab =
						    &symtab[symtab_ndx];
						symtab_ndx++;
					}
				} else {
					wk.wk_symtab = NULL;
				}
				if (dynsym) {
					if (!local) {
						wk.wk_dynsym =
						    &dynsym[dynsym_ndx];
						dynsym_ndx++;
					} else if (dynlocal) {
						wk.wk_dynsym =
						    &ldynsym[ldynscopesym_ndx];
						ldynscopesym_ndx++;
					}
				} else {
					wk.wk_dynsym = NULL;
				}
				wk.wk_weak = sdp;
				wk.wk_alias = _sdp;

				if (alist_append(&weak, &wk,
				    sizeof (Wk_desc), AL_CNT_WEAK) == NULL)
					return ((Addr)S_ERROR);

				continue;
			}
		}

		DBG_CALL(Dbg_syms_old(ofl, sdp));

		spec = NULL;
		/*
		 * assign new symbol value.
		 */
		sectndx = sdp->sd_shndx;
		if (sectndx == SHN_UNDEF) {
			if (((sdp->sd_flags & FLG_SY_REGSYM) == 0) &&
			    (sym->st_value != 0)) {
				eprintf(ofl->ofl_lml, ERR_WARNING,
				    MSG_INTL(MSG_SYM_NOTNULL),
				    demangle(name), sdp->sd_file->ifl_name);
			}

			/*
			 * Undefined weak global, if we are generating a static
			 * executable, output as an absolute zero.  Otherwise
			 * leave it as is, ld.so.1 will skip symbols of this
			 * type (this technique allows applications and
			 * libraries to test for the existence of a symbol as an
			 * indication of the presence or absence of certain
			 * functionality).
			 */
			if (OFL_IS_STATIC_EXEC(ofl) &&
			    (ELF_ST_BIND(sym->st_info) == STB_WEAK)) {
				sdp->sd_flags |= FLG_SY_SPECSEC;
				sdp->sd_shndx = sectndx = SHN_ABS;
			}
		} else if ((sdp->sd_flags & FLG_SY_SPECSEC) &&
		    (sectndx == SHN_COMMON)) {
			/* COMMONs have already been processed */
			/* EMPTY */
			;
		} else {
			if ((sdp->sd_flags & FLG_SY_SPECSEC) &&
			    (sectndx == SHN_ABS))
				spec = sdp->sd_aux->sa_symspec;

			/* LINTED */
			if (sdp->sd_flags & FLG_SY_COMMEXP) {
				/*
				 * This is (or was) a COMMON symbol which was
				 * processed above - no processing
				 * required here.
				 */
				;
			} else if (sdp->sd_ref == REF_DYN_NEED) {
				uchar_t	type, bind;

				sectndx = SHN_UNDEF;
				sym->st_value = 0;
				sym->st_size = 0;

				/*
				 * Make sure this undefined symbol is returned
				 * to the same binding as was defined in the
				 * original relocatable object reference.
				 */
				type = ELF_ST_TYPE(sym-> st_info);
				if (sdp->sd_flags & FLG_SY_GLOBREF)
					bind = STB_GLOBAL;
				else
					bind = STB_WEAK;

				sym->st_info = ELF_ST_INFO(bind, type);

			} else if (((sdp->sd_flags & FLG_SY_SPECSEC) == 0) &&
			    (sdp->sd_ref == REF_REL_NEED)) {
				osp = sdp->sd_isc->is_osdesc;
				/* LINTED */
				sectndx = elf_ndxscn(osp->os_scn);

				/*
				 * In an executable, the new symbol value is the
				 * old value (offset into defining section) plus
				 * virtual address of defining section.  In a
				 * relocatable, the new value is the old value
				 * plus the displacement of the section within
				 * the file.
				 */
				/* LINTED */
				sym->st_value +=
				    (Off)_elf_getxoff(sdp->sd_isc->is_indata);

				if (!(flags & FLG_OF_RELOBJ)) {
					sym->st_value += osp->os_shdr->sh_addr;
					/*
					 * TLS symbols are relative to
					 * the TLS segment.
					 */
					if ((ELF_ST_TYPE(sym->st_info) ==
					    STT_TLS) && (ofl->ofl_tlsphdr))
						sym->st_value -=
						    ofl->ofl_tlsphdr->p_vaddr;
				}
			}
		}

		if (spec) {
			switch (spec) {
			case SDAUX_ID_ETEXT:
				sym->st_value = etext;
				sectndx = etext_ndx;
				if (etext_abs)
					sdp->sd_flags |= FLG_SY_SPECSEC;
				else
					sdp->sd_flags &= ~FLG_SY_SPECSEC;
				break;
			case SDAUX_ID_EDATA:
				sym->st_value = edata;
				sectndx = edata_ndx;
				if (edata_abs)
					sdp->sd_flags |= FLG_SY_SPECSEC;
				else
					sdp->sd_flags &= ~FLG_SY_SPECSEC;
				break;
			case SDAUX_ID_END:
				sym->st_value = end;
				sectndx = end_ndx;
				if (end_abs)
					sdp->sd_flags |= FLG_SY_SPECSEC;
				else
					sdp->sd_flags &= ~FLG_SY_SPECSEC;
				break;
			case SDAUX_ID_START:
				sym->st_value = start;
				sectndx = start_ndx;
				sdp->sd_flags &= ~FLG_SY_SPECSEC;
				break;
			case SDAUX_ID_DYN:
				if (flags & FLG_OF_DYNAMIC) {
					sym->st_value = ofl->
					    ofl_osdynamic->os_shdr->sh_addr;
					/* LINTED */
					sectndx = elf_ndxscn(
					    ofl->ofl_osdynamic->os_scn);
					sdp->sd_flags &= ~FLG_SY_SPECSEC;
				}
				break;
			case SDAUX_ID_PLT:
				if (ofl->ofl_osplt) {
					sym->st_value = ofl->
					    ofl_osplt->os_shdr->sh_addr;
					/* LINTED */
					sectndx = elf_ndxscn(
					    ofl->ofl_osplt->os_scn);
					sdp->sd_flags &= ~FLG_SY_SPECSEC;
				}
				break;
			case SDAUX_ID_GOT:
				/*
				 * Symbol bias for negative growing tables is
				 * stored in symbol's value during
				 * allocate_got().
				 */
				sym->st_value += ofl->
				    ofl_osgot->os_shdr->sh_addr;
				/* LINTED */
				sectndx = elf_ndxscn(ofl->
				    ofl_osgot->os_scn);
				sdp->sd_flags &= ~FLG_SY_SPECSEC;
				break;
			default:
				/* NOTHING */
				;
			}
		}

		/*
		 * If a plt index has been assigned to an undefined function,
		 * update the symbols value to the appropriate .plt address.
		 */
		if ((flags & FLG_OF_DYNAMIC) && (flags & FLG_OF_EXEC) &&
		    (sdp->sd_file) &&
		    (sdp->sd_file->ifl_ehdr->e_type == ET_DYN) &&
		    (ELF_ST_TYPE(sym->st_info) == STT_FUNC) &&
		    !(flags & FLG_OF_BFLAG)) {
			if (sap->sa_PLTndx)
				sym->st_value =
				    (*ld_targ.t_mr.mr_calc_plt_addr)(sdp, ofl);
		}

		/*
		 * Finish updating the symbols.
		 */

		/*
		 * Sym Update: if scoped local - set local binding
		 */
		if (local)
			sym->st_info = ELF_ST_INFO(STB_LOCAL,
			    ELF_ST_TYPE(sym->st_info));

		/*
		 * Sym Updated: If both the .symtab and .dynsym
		 * are present then we've actually updated the information in
		 * the .dynsym, therefore copy this same information to the
		 * .symtab entry.
		 */
		sdp->sd_shndx = sectndx;
		if (enter_in_symtab && dynsym && (!local || dynlocal)) {
			Word _symndx = dynlocal ? scopesym_ndx : symtab_ndx;

			symtab[_symndx].st_value = sym->st_value;
			symtab[_symndx].st_size = sym->st_size;
			symtab[_symndx].st_info = sym->st_info;
			symtab[_symndx].st_other = sym->st_other;
		}

		if (enter_in_symtab) {
			Word	_symndx;

			if (local)
				_symndx = scopesym_ndx++;
			else
				_symndx = symtab_ndx++;
			if (((sdp->sd_flags & FLG_SY_SPECSEC) == 0) &&
			    (sectndx >= SHN_LORESERVE)) {
				assert(symshndx != NULL);
				symshndx[_symndx] = sectndx;
				symtab[_symndx].st_shndx = SHN_XINDEX;
			} else {
				/* LINTED */
				symtab[_symndx].st_shndx = (Half)sectndx;
			}
		}

		if (dynsym && (!local || dynlocal)) {
			/*
			 * dynsym and ldynsym are distinct tables, so
			 * we use indirection to access the right one
			 * and the related extended section index array.
			 */
			Word	_symndx;
			Sym	*_dynsym;
			Word	*_dynshndx;

			if (!local) {
				_symndx = dynsym_ndx++;
				_dynsym = dynsym;
				_dynshndx = dynshndx;
			} else {
				_symndx = ldynscopesym_ndx++;
				_dynsym = ldynsym;
				_dynshndx = ldynshndx;
			}
			if (((sdp->sd_flags & FLG_SY_SPECSEC) == 0) &&
			    (sectndx >= SHN_LORESERVE)) {
				assert(_dynshndx != NULL);
				_dynshndx[_symndx] = sectndx;
				_dynsym[_symndx].st_shndx = SHN_XINDEX;
			} else {
				/* LINTED */
				_dynsym[_symndx].st_shndx = (Half)sectndx;
			}
		}

		DBG_CALL(Dbg_syms_new(ofl, sym, sdp));
	}

	/*
	 * Now that all the symbols have been processed update any weak symbols
	 * information (ie. copy all information except `st_name').  As both
	 * symbols will be represented in the output, return the weak symbol to
	 * its correct type.
	 */
	for (ALIST_TRAVERSE(weak, idx1, wkp)) {
		Sym_desc	*sdp, *_sdp;
		Sym		*sym, *_sym, *__sym;
		uchar_t		bind;

		sdp = wkp->wk_weak;
		_sdp = wkp->wk_alias;
		_sym = __sym = _sdp->sd_sym;

		sdp->sd_flags |= FLG_SY_WEAKDEF;

		/*
		 * If the symbol definition has been scoped then assign it to
		 * be local, otherwise if it's from a shared object then we need
		 * to maintain the binding of the original reference.
		 */
		if (SYM_IS_HIDDEN(sdp)) {
			if (flags & FLG_OF_PROCRED)
				bind = STB_LOCAL;
			else
				bind = STB_WEAK;
		} else if ((sdp->sd_ref == REF_DYN_NEED) &&
		    (sdp->sd_flags & FLG_SY_GLOBREF))
			bind = STB_GLOBAL;
		else
			bind = STB_WEAK;

		DBG_CALL(Dbg_syms_old(ofl, sdp));
		if ((sym = wkp->wk_symtab) != NULL) {
			sym->st_value = _sym->st_value;
			sym->st_size = _sym->st_size;
			sym->st_other = _sym->st_other;
			sym->st_shndx = _sym->st_shndx;
			sym->st_info = ELF_ST_INFO(bind,
			    ELF_ST_TYPE(sym->st_info));
			__sym = sym;
		}
		if ((sym = wkp->wk_dynsym) != NULL) {
			sym->st_value = _sym->st_value;
			sym->st_size = _sym->st_size;
			sym->st_other = _sym->st_other;
			sym->st_shndx = _sym->st_shndx;
			sym->st_info = ELF_ST_INFO(bind,
			    ELF_ST_TYPE(sym->st_info));
			__sym = sym;
		}
		DBG_CALL(Dbg_syms_new(ofl, __sym, sdp));
	}

	/*
	 * Now display GOT debugging information if required.
	 */
	DBG_CALL(Dbg_got_display(ofl, 0, 0,
	    ld_targ.t_m.m_got_xnumber, ld_targ.t_m.m_got_entsize));

	/*
	 * Update the section headers information. sh_info is
	 * supposed to contain the offset at which the first
	 * global symbol resides in the symbol table, while
	 * sh_link contains the section index of the associated
	 * string table.
	 */
	if (symtab) {
		Shdr	*shdr = ofl->ofl_ossymtab->os_shdr;

		shdr->sh_info = symtab_gbl_bndx;
		/* LINTED */
		shdr->sh_link = (Word)elf_ndxscn(ofl->ofl_osstrtab->os_scn);
		if (symshndx)
			ofl->ofl_ossymshndx->os_shdr->sh_link =
			    (Word)elf_ndxscn(ofl->ofl_ossymtab->os_scn);

		/*
		 * Ensure that the expected number of symbols
		 * were entered into the right spots:
		 *	- Scoped symbols in the right range
		 *	- Globals start at the right spot
		 *		(correct number of locals entered)
		 *	- The table is exactly filled
		 *		(correct number of globals entered)
		 */
		assert((scopesym_bndx + ofl->ofl_scopecnt) == scopesym_ndx);
		assert(shdr->sh_info == SYMTAB_LOC_CNT(ofl));
		assert((shdr->sh_info + ofl->ofl_globcnt) == symtab_ndx);
	}
	if (dynsym) {
		Shdr	*shdr = ofl->ofl_osdynsym->os_shdr;

		shdr->sh_info = DYNSYM_LOC_CNT(ofl);
		/* LINTED */
		shdr->sh_link = (Word)elf_ndxscn(ofl->ofl_osdynstr->os_scn);

		ofl->ofl_oshash->os_shdr->sh_link =
		    /* LINTED */
		    (Word)elf_ndxscn(ofl->ofl_osdynsym->os_scn);
		if (dynshndx) {
			shdr = ofl->ofl_osdynshndx->os_shdr;
			shdr->sh_link =
			    (Word)elf_ndxscn(ofl->ofl_osdynsym->os_scn);
		}
	}
	if (ldynsym) {
		Shdr	*shdr = ofl->ofl_osldynsym->os_shdr;

		/* ldynsym has no globals, so give index one past the end */
		shdr->sh_info = ldynsym_ndx;

		/*
		 * The ldynsym and dynsym must be adjacent. The
		 * idea is that rtld should be able to start with
		 * the ldynsym and march straight through the end
		 * of dynsym, seeing them as a single symbol table,
		 * despite the fact that they are in distinct sections.
		 * Ensure that this happened correctly.
		 *
		 * Note that I use ldynsym_ndx here instead of the
		 * computation I used to set the section size
		 * (found in ldynsym_cnt). The two will agree, unless
		 * we somehow miscounted symbols or failed to insert them
		 * all. Using ldynsym_ndx here catches that error in
		 * addition to checking for adjacency.
		 */
		assert(dynsym == (ldynsym + ldynsym_ndx));


		/* LINTED */
		shdr->sh_link = (Word)elf_ndxscn(ofl->ofl_osdynstr->os_scn);

		if (ldynshndx) {
			shdr = ofl->ofl_osldynshndx->os_shdr;
			shdr->sh_link =
			    (Word)elf_ndxscn(ofl->ofl_osldynsym->os_scn);
		}

		/*
		 * The presence of .SUNW_ldynsym means that there may be
		 * associated sort sections, one for regular symbols
		 * and the other for TLS. Each sort section needs the
		 * following done:
		 *	- Section header link references .SUNW_ldynsym
		 *	- Should have received the expected # of items
		 *	- Sorted by increasing address
		 */
		if (ofl->ofl_osdynsymsort) {	/* .SUNW_dynsymsort */
			ofl->ofl_osdynsymsort->os_shdr->sh_link =
			    (Word)elf_ndxscn(ofl->ofl_osldynsym->os_scn);
			assert(ofl->ofl_dynsymsortcnt == dynsymsort_ndx);

			if (dynsymsort_ndx > 1) {
				dynsort_compare_syms = ldynsym;
				qsort(dynsymsort, dynsymsort_ndx,
				    sizeof (*dynsymsort), dynsort_compare);
				dynsort_dupwarn(ofl, ldynsym,
				    st_getstrbuf(dynstr),
				    dynsymsort, dynsymsort_ndx,
				    MSG_ORIG(MSG_SCN_DYNSYMSORT));
			}
		}
		if (ofl->ofl_osdyntlssort) {	/* .SUNW_dyntlssort */
			ofl->ofl_osdyntlssort->os_shdr->sh_link =
			    (Word)elf_ndxscn(ofl->ofl_osldynsym->os_scn);
			assert(ofl->ofl_dyntlssortcnt == dyntlssort_ndx);

			if (dyntlssort_ndx > 1) {
				dynsort_compare_syms = ldynsym;
				qsort(dyntlssort, dyntlssort_ndx,
				    sizeof (*dyntlssort), dynsort_compare);
				dynsort_dupwarn(ofl, ldynsym,
				    st_getstrbuf(dynstr),
				    dyntlssort, dyntlssort_ndx,
				    MSG_ORIG(MSG_SCN_DYNTLSSORT));
			}
		}
	}

	/*
	 * Used by ld.so.1 only.
	 */
	return (etext);

#undef ADD_TO_DYNSORT
}

/*
 * Build the dynamic section.
 *
 * This routine must be maintained in parallel with make_dynamic()
 * in sections.c
 */
static int
update_odynamic(Ofl_desc *ofl)
{
	Aliste		idx;
	Ifl_desc	*ifl;
	Sym_desc	*sdp;
	Shdr		*shdr;
	Dyn		*_dyn = (Dyn *)ofl->ofl_osdynamic->os_outdata->d_buf;
	Dyn		*dyn;
	Os_desc		*symosp, *strosp;
	Str_tbl		*strtbl;
	size_t		stoff;
	ofl_flag_t	flags = ofl->ofl_flags;
	int		not_relobj = !(flags & FLG_OF_RELOBJ);
	Word		cnt;

	/*
	 * Relocatable objects can be built with -r and -dy to trigger the
	 * creation of a .dynamic section.  This model is used to create kernel
	 * device drivers.  The .dynamic section provides a subset of userland
	 * .dynamic entries, typically entries such as DT_NEEDED and DT_RUNPATH.
	 *
	 * Within a dynamic object, any .dynamic string references are to the
	 * .dynstr table.  Within a relocatable object, these strings can reside
	 * within the .strtab.
	 */
	if (OFL_IS_STATIC_OBJ(ofl)) {
		symosp = ofl->ofl_ossymtab;
		strosp = ofl->ofl_osstrtab;
		strtbl = ofl->ofl_strtab;
	} else {
		symosp = ofl->ofl_osdynsym;
		strosp = ofl->ofl_osdynstr;
		strtbl = ofl->ofl_dynstrtab;
	}

	/* LINTED */
	ofl->ofl_osdynamic->os_shdr->sh_link = (Word)elf_ndxscn(strosp->os_scn);

	dyn = _dyn;

	for (APLIST_TRAVERSE(ofl->ofl_sos, idx, ifl)) {
		if ((ifl->ifl_flags &
		    (FLG_IF_IGNORE | FLG_IF_DEPREQD)) == FLG_IF_IGNORE)
			continue;

		/*
		 * Create and set up the DT_POSFLAG_1 entry here if required.
		 */
		if ((ifl->ifl_flags & MSK_IF_POSFLAG1) &&
		    (ifl->ifl_flags & FLG_IF_NEEDED) && not_relobj) {
			dyn->d_tag = DT_POSFLAG_1;
			if (ifl->ifl_flags & FLG_IF_LAZYLD)
				dyn->d_un.d_val = DF_P1_LAZYLOAD;
			if (ifl->ifl_flags & FLG_IF_GRPPRM)
				dyn->d_un.d_val |= DF_P1_GROUPPERM;
			if (ifl->ifl_flags & FLG_IF_DEFERRED)
				dyn->d_un.d_val |= DF_P1_DEFERRED;
			dyn++;
		}

		if (ifl->ifl_flags & (FLG_IF_NEEDED | FLG_IF_NEEDSTR))
			dyn->d_tag = DT_NEEDED;
		else
			continue;

		(void) st_setstring(strtbl, ifl->ifl_soname, &stoff);
		dyn->d_un.d_val = stoff;
		/* LINTED */
		ifl->ifl_neededndx = (Half)(((uintptr_t)dyn - (uintptr_t)_dyn) /
		    sizeof (Dyn));
		dyn++;
	}

	if (not_relobj) {
		if (ofl->ofl_dtsfltrs != NULL) {
			Dfltr_desc	*dftp;

			for (ALIST_TRAVERSE(ofl->ofl_dtsfltrs, idx, dftp)) {
				if (dftp->dft_flag == FLG_SY_AUXFLTR)
					dyn->d_tag = DT_SUNW_AUXILIARY;
				else
					dyn->d_tag = DT_SUNW_FILTER;

				(void) st_setstring(strtbl, dftp->dft_str,
				    &stoff);
				dyn->d_un.d_val = stoff;
				dftp->dft_ndx = (Half)(((uintptr_t)dyn -
				    (uintptr_t)_dyn) / sizeof (Dyn));
				dyn++;
			}
		}
		if (((sdp = ld_sym_find(MSG_ORIG(MSG_SYM_INIT_U),
		    SYM_NOHASH, 0, ofl)) != NULL) &&
		    (sdp->sd_ref == REF_REL_NEED) &&
		    (sdp->sd_sym->st_shndx != SHN_UNDEF)) {
			dyn->d_tag = DT_INIT;
			dyn->d_un.d_ptr = sdp->sd_sym->st_value;
			dyn++;
		}
		if (((sdp = ld_sym_find(MSG_ORIG(MSG_SYM_FINI_U),
		    SYM_NOHASH, 0, ofl)) != NULL) &&
		    (sdp->sd_ref == REF_REL_NEED) &&
		    (sdp->sd_sym->st_shndx != SHN_UNDEF)) {
			dyn->d_tag = DT_FINI;
			dyn->d_un.d_ptr = sdp->sd_sym->st_value;
			dyn++;
		}
		if (ofl->ofl_soname) {
			dyn->d_tag = DT_SONAME;
			(void) st_setstring(strtbl, ofl->ofl_soname, &stoff);
			dyn->d_un.d_val = stoff;
			dyn++;
		}
		if (ofl->ofl_filtees) {
			if (flags & FLG_OF_AUX) {
				dyn->d_tag = DT_AUXILIARY;
			} else {
				dyn->d_tag = DT_FILTER;
			}
			(void) st_setstring(strtbl, ofl->ofl_filtees, &stoff);
			dyn->d_un.d_val = stoff;
			dyn++;
		}
	}

	if (ofl->ofl_rpath) {
		(void) st_setstring(strtbl, ofl->ofl_rpath, &stoff);
		dyn->d_tag = DT_RUNPATH;
		dyn->d_un.d_val = stoff;
		dyn++;
		dyn->d_tag = DT_RPATH;
		dyn->d_un.d_val = stoff;
		dyn++;
	}

	if (not_relobj) {
		Aliste	idx;

		if (ofl->ofl_config) {
			dyn->d_tag = DT_CONFIG;
			(void) st_setstring(strtbl, ofl->ofl_config, &stoff);
			dyn->d_un.d_val = stoff;
			dyn++;
		}
		if (ofl->ofl_depaudit) {
			dyn->d_tag = DT_DEPAUDIT;
			(void) st_setstring(strtbl, ofl->ofl_depaudit, &stoff);
			dyn->d_un.d_val = stoff;
			dyn++;
		}
		if (ofl->ofl_audit) {
			dyn->d_tag = DT_AUDIT;
			(void) st_setstring(strtbl, ofl->ofl_audit, &stoff);
			dyn->d_un.d_val = stoff;
			dyn++;
		}

		dyn->d_tag = DT_HASH;
		dyn->d_un.d_ptr = ofl->ofl_oshash->os_shdr->sh_addr;
		dyn++;

		shdr = strosp->os_shdr;
		dyn->d_tag = DT_STRTAB;
		dyn->d_un.d_ptr = shdr->sh_addr;
		dyn++;

		dyn->d_tag = DT_STRSZ;
		dyn->d_un.d_ptr = shdr->sh_size;
		dyn++;

		/*
		 * Note, the shdr is set and used in the ofl->ofl_osldynsym case
		 * that follows.
		 */
		shdr = symosp->os_shdr;
		dyn->d_tag = DT_SYMTAB;
		dyn->d_un.d_ptr = shdr->sh_addr;
		dyn++;

		dyn->d_tag = DT_SYMENT;
		dyn->d_un.d_ptr = shdr->sh_entsize;
		dyn++;

		if (ofl->ofl_osldynsym) {
			Shdr	*lshdr = ofl->ofl_osldynsym->os_shdr;

			/*
			 * We have arranged for the .SUNW_ldynsym data to be
			 * immediately in front of the .dynsym data.
			 * This means that you could start at the top
			 * of .SUNW_ldynsym and see the data for both tables
			 * without a break. This is the view we want to
			 * provide for DT_SUNW_SYMTAB, which is why we
			 * add the lengths together.
			 */
			dyn->d_tag = DT_SUNW_SYMTAB;
			dyn->d_un.d_ptr = lshdr->sh_addr;
			dyn++;

			dyn->d_tag = DT_SUNW_SYMSZ;
			dyn->d_un.d_val = lshdr->sh_size + shdr->sh_size;
			dyn++;
		}

		if (ofl->ofl_osdynsymsort || ofl->ofl_osdyntlssort) {
			dyn->d_tag = DT_SUNW_SORTENT;
			dyn->d_un.d_val = sizeof (Word);
			dyn++;
		}

		if (ofl->ofl_osdynsymsort) {
			shdr = ofl->ofl_osdynsymsort->os_shdr;

			dyn->d_tag = DT_SUNW_SYMSORT;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;

			dyn->d_tag = DT_SUNW_SYMSORTSZ;
			dyn->d_un.d_val = shdr->sh_size;
			dyn++;
		}

		if (ofl->ofl_osdyntlssort) {
			shdr = ofl->ofl_osdyntlssort->os_shdr;

			dyn->d_tag = DT_SUNW_TLSSORT;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;

			dyn->d_tag = DT_SUNW_TLSSORTSZ;
			dyn->d_un.d_val = shdr->sh_size;
			dyn++;
		}

		/*
		 * Reserve the DT_CHECKSUM entry.  Its value will be filled in
		 * after the complete image is built.
		 */
		dyn->d_tag = DT_CHECKSUM;
		ofl->ofl_checksum = &dyn->d_un.d_val;
		dyn++;

		/*
		 * Versioning sections: DT_VERDEF and DT_VERNEED.
		 *
		 * The Solaris ld does not produce DT_VERSYM, but the GNU ld
		 * does, in order to support their style of versioning, which
		 * differs from ours:
		 *
		 *	- The top bit of the 16-bit Versym index is
		 *		not part of the version, but is interpreted
		 *		as a "hidden bit".
		 *
		 *	- External (SHN_UNDEF) symbols can have non-zero
		 *		Versym values, which specify versions in
		 *		referenced objects, via the Verneed section.
		 *
		 *	- The vna_other field of the Vernaux structures
		 *		found in the Verneed section are not zero as
		 *		with Solaris, but instead contain the version
		 *		index to be used by Versym indices to reference
		 *		the given external version.
		 *
		 * The Solaris ld, rtld, and elfdump programs all interpret the
		 * presence of DT_VERSYM as meaning that GNU versioning rules
		 * apply to the given file. If DT_VERSYM is not present,
		 * then Solaris versioning rules apply. If we should ever need
		 * to change our ld so that it does issue DT_VERSYM, then
		 * this rule for detecting GNU versioning will no longer work.
		 * In that case, we will have to invent a way to explicitly
		 * specify the style of versioning in use, perhaps via a
		 * new dynamic entry named something like DT_SUNW_VERSIONSTYLE,
		 * where the d_un.d_val value specifies which style is to be
		 * used.
		 */
		if ((flags & (FLG_OF_VERDEF | FLG_OF_NOVERSEC)) ==
		    FLG_OF_VERDEF) {
			shdr = ofl->ofl_osverdef->os_shdr;

			dyn->d_tag = DT_VERDEF;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;
			dyn->d_tag = DT_VERDEFNUM;
			dyn->d_un.d_ptr = shdr->sh_info;
			dyn++;
		}
		if ((flags & (FLG_OF_VERNEED | FLG_OF_NOVERSEC)) ==
		    FLG_OF_VERNEED) {
			shdr = ofl->ofl_osverneed->os_shdr;

			dyn->d_tag = DT_VERNEED;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;
			dyn->d_tag = DT_VERNEEDNUM;
			dyn->d_un.d_ptr = shdr->sh_info;
			dyn++;
		}

		if ((flags & FLG_OF_COMREL) && ofl->ofl_relocrelcnt) {
			dyn->d_tag = ld_targ.t_m.m_rel_dt_count;
			dyn->d_un.d_val = ofl->ofl_relocrelcnt;
			dyn++;
		}
		if (flags & FLG_OF_TEXTREL) {
			/*
			 * Only the presence of this entry is used in this
			 * implementation, not the value stored.
			 */
			dyn->d_tag = DT_TEXTREL;
			dyn->d_un.d_val = 0;
			dyn++;
		}

		if (ofl->ofl_osfiniarray) {
			shdr = ofl->ofl_osfiniarray->os_shdr;

			dyn->d_tag = DT_FINI_ARRAY;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;

			dyn->d_tag = DT_FINI_ARRAYSZ;
			dyn->d_un.d_val = shdr->sh_size;
			dyn++;
		}

		if (ofl->ofl_osinitarray) {
			shdr = ofl->ofl_osinitarray->os_shdr;

			dyn->d_tag = DT_INIT_ARRAY;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;

			dyn->d_tag = DT_INIT_ARRAYSZ;
			dyn->d_un.d_val = shdr->sh_size;
			dyn++;
		}

		if (ofl->ofl_ospreinitarray) {
			shdr = ofl->ofl_ospreinitarray->os_shdr;

			dyn->d_tag = DT_PREINIT_ARRAY;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;

			dyn->d_tag = DT_PREINIT_ARRAYSZ;
			dyn->d_un.d_val = shdr->sh_size;
			dyn++;
		}

		if (ofl->ofl_pltcnt) {
			shdr = ofl->ofl_osplt->os_relosdesc->os_shdr;

			dyn->d_tag = DT_PLTRELSZ;
			dyn->d_un.d_ptr = shdr->sh_size;
			dyn++;
			dyn->d_tag = DT_PLTREL;
			dyn->d_un.d_ptr = ld_targ.t_m.m_rel_dt_type;
			dyn++;
			dyn->d_tag = DT_JMPREL;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;
		}
		if (ofl->ofl_pltpad) {
			shdr = ofl->ofl_osplt->os_shdr;

			dyn->d_tag = DT_PLTPAD;
			if (ofl->ofl_pltcnt) {
				dyn->d_un.d_ptr = shdr->sh_addr +
				    ld_targ.t_m.m_plt_reservsz +
				    ofl->ofl_pltcnt * ld_targ.t_m.m_plt_entsize;
			} else
				dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;
			dyn->d_tag = DT_PLTPADSZ;
			dyn->d_un.d_val = ofl->ofl_pltpad *
			    ld_targ.t_m.m_plt_entsize;
			dyn++;
		}
		if (ofl->ofl_relocsz) {
			shdr = ofl->ofl_osrelhead->os_shdr;

			dyn->d_tag = ld_targ.t_m.m_rel_dt_type;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;
			dyn->d_tag = ld_targ.t_m.m_rel_dt_size;
			dyn->d_un.d_ptr = ofl->ofl_relocsz;
			dyn++;
			dyn->d_tag = ld_targ.t_m.m_rel_dt_ent;
			if (shdr->sh_type == SHT_REL)
				dyn->d_un.d_ptr = sizeof (Rel);
			else
				dyn->d_un.d_ptr = sizeof (Rela);
			dyn++;
		}
		if (ofl->ofl_ossyminfo) {
			shdr = ofl->ofl_ossyminfo->os_shdr;

			dyn->d_tag = DT_SYMINFO;
			dyn->d_un.d_ptr = shdr->sh_addr;
			dyn++;
			dyn->d_tag = DT_SYMINSZ;
			dyn->d_un.d_val = shdr->sh_size;
			dyn++;
			dyn->d_tag = DT_SYMINENT;
			dyn->d_un.d_val = sizeof (Syminfo);
			dyn++;
		}
		if (ofl->ofl_osmove) {
			shdr = ofl->ofl_osmove->os_shdr;

			dyn->d_tag = DT_MOVETAB;
			dyn->d_un.d_val = shdr->sh_addr;
			dyn++;
			dyn->d_tag = DT_MOVESZ;
			dyn->d_un.d_val = shdr->sh_size;
			dyn++;
			dyn->d_tag = DT_MOVEENT;
			dyn->d_un.d_val = shdr->sh_entsize;
			dyn++;
		}
		if (ofl->ofl_regsymcnt) {
			int	ndx;

			for (ndx = 0; ndx < ofl->ofl_regsymsno; ndx++) {
				if ((sdp = ofl->ofl_regsyms[ndx]) == NULL)
					continue;

				dyn->d_tag = ld_targ.t_m.m_dt_register;
				dyn->d_un.d_val = sdp->sd_symndx;
				dyn++;
			}
		}

		for (APLIST_TRAVERSE(ofl->ofl_rtldinfo, idx, sdp)) {
			dyn->d_tag = DT_SUNW_RTLDINF;
			dyn->d_un.d_ptr = sdp->sd_sym->st_value;
			dyn++;
		}

		if (ofl->ofl_osdynamic->os_sgdesc &&
		    (ofl->ofl_osdynamic->os_sgdesc->sg_phdr.p_flags & PF_W)) {
			if (ofl->ofl_osinterp) {
				dyn->d_tag = DT_DEBUG;
				dyn->d_un.d_ptr = 0;
				dyn++;
			}

			dyn->d_tag = DT_FEATURE_1;
			if (ofl->ofl_osmove)
				dyn->d_un.d_val = 0;
			else
				dyn->d_un.d_val = DTF_1_PARINIT;
			dyn++;
		}

		if (ofl->ofl_oscap) {
			dyn->d_tag = DT_SUNW_CAP;
			dyn->d_un.d_val = ofl->ofl_oscap->os_shdr->sh_addr;
			dyn++;
		}
		if (ofl->ofl_oscapinfo) {
			dyn->d_tag = DT_SUNW_CAPINFO;
			dyn->d_un.d_val = ofl->ofl_oscapinfo->os_shdr->sh_addr;
			dyn++;
		}
		if (ofl->ofl_oscapchain) {
			shdr = ofl->ofl_oscapchain->os_shdr;

			dyn->d_tag = DT_SUNW_CAPCHAIN;
			dyn->d_un.d_val = shdr->sh_addr;
			dyn++;
			dyn->d_tag = DT_SUNW_CAPCHAINSZ;
			dyn->d_un.d_val = shdr->sh_size;
			dyn++;
			dyn->d_tag = DT_SUNW_CAPCHAINENT;
			dyn->d_un.d_val = shdr->sh_entsize;
			dyn++;
		}
		if (flags & FLG_OF_SYMBOLIC) {
			dyn->d_tag = DT_SYMBOLIC;
			dyn->d_un.d_val = 0;
			dyn++;
		}
	}

	dyn->d_tag = DT_FLAGS;
	dyn->d_un.d_val = ofl->ofl_dtflags;
	dyn++;

	/*
	 * If -Bdirect was specified, but some NODIRECT symbols were specified
	 * via a mapfile, or -znodirect was used on the command line, then
	 * clear the DF_1_DIRECT flag.  The resultant object will use per-symbol
	 * direct bindings rather than be enabled for global direct bindings.
	 *
	 * If any no-direct bindings exist within this object, set the
	 * DF_1_NODIRECT flag.  ld(1) recognizes this flag when processing
	 * dependencies, and performs extra work to ensure that no direct
	 * bindings are established to the no-direct symbols that exist
	 * within these dependencies.
	 */
	if (ofl->ofl_flags1 & FLG_OF1_NGLBDIR)
		ofl->ofl_dtflags_1 &= ~DF_1_DIRECT;
	if (ofl->ofl_flags1 & FLG_OF1_NDIRECT)
		ofl->ofl_dtflags_1 |= DF_1_NODIRECT;

	dyn->d_tag = DT_FLAGS_1;
	dyn->d_un.d_val = ofl->ofl_dtflags_1;
	dyn++;

	dyn->d_tag = DT_SUNW_STRPAD;
	dyn->d_un.d_val = DYNSTR_EXTRA_PAD;
	dyn++;

	dyn->d_tag = DT_SUNW_LDMACH;
	dyn->d_un.d_val = ld_sunw_ldmach();
	dyn++;

	(*ld_targ.t_mr.mr_mach_update_odynamic)(ofl, &dyn);

	for (cnt = 1 + DYNAMIC_EXTRA_ELTS; cnt--; dyn++) {
		dyn->d_tag = DT_NULL;
		dyn->d_un.d_val = 0;
	}

	/*
	 * Ensure that we wrote the right number of entries. If not, we either
	 * miscounted in make_dynamic(), or we did something wrong in this
	 * function.
	 */
	assert((ofl->ofl_osdynamic->os_shdr->sh_size /
	    ofl->ofl_osdynamic->os_shdr->sh_entsize) ==
	    ((uintptr_t)dyn - (uintptr_t)_dyn) / sizeof (*dyn));

	return (1);
}

/*
 * Build the version definition section
 */
static int
update_overdef(Ofl_desc *ofl)
{
	Aliste		idx1;
	Ver_desc	*vdp, *_vdp;
	Verdef		*vdf, *_vdf;
	int		num = 0;
	Os_desc		*strosp;
	Str_tbl		*strtbl;

	/*
	 * Determine which string table to use.
	 */
	if (OFL_IS_STATIC_OBJ(ofl)) {
		strtbl = ofl->ofl_strtab;
		strosp = ofl->ofl_osstrtab;
	} else {
		strtbl = ofl->ofl_dynstrtab;
		strosp = ofl->ofl_osdynstr;
	}

	/*
	 * Traverse the version descriptors and update the version structures
	 * to point to the dynstr name in preparation for building the version
	 * section structure.
	 */
	for (APLIST_TRAVERSE(ofl->ofl_verdesc, idx1, vdp)) {
		Sym_desc	*sdp;

		if (vdp->vd_flags & VER_FLG_BASE) {
			const char	*name = vdp->vd_name;
			size_t		stoff;

			/*
			 * Create a new string table entry to represent the base
			 * version name (there is no corresponding symbol for
			 * this).
			 */
			(void) st_setstring(strtbl, name, &stoff);
			/* LINTED */
			vdp->vd_name = (const char *)stoff;
		} else {
			sdp = ld_sym_find(vdp->vd_name, vdp->vd_hash, 0, ofl);
			/* LINTED */
			vdp->vd_name = (const char *)
			    (uintptr_t)sdp->sd_sym->st_name;
		}
	}

	_vdf = vdf = (Verdef *)ofl->ofl_osverdef->os_outdata->d_buf;

	/*
	 * Traverse the version descriptors and update the version section to
	 * reflect each version and its associated dependencies.
	 */
	for (APLIST_TRAVERSE(ofl->ofl_verdesc, idx1, vdp)) {
		Aliste		idx2;
		Half		cnt = 1;
		Verdaux		*vdap, *_vdap;

		_vdap = vdap = (Verdaux *)(vdf + 1);

		vdf->vd_version = VER_DEF_CURRENT;
		vdf->vd_flags	= vdp->vd_flags & MSK_VER_USER;
		vdf->vd_ndx	= vdp->vd_ndx;
		vdf->vd_hash	= vdp->vd_hash;

		/* LINTED */
		vdap->vda_name = (uintptr_t)vdp->vd_name;
		vdap++;
		/* LINTED */
		_vdap->vda_next = (Word)((uintptr_t)vdap - (uintptr_t)_vdap);

		/*
		 * Traverse this versions dependency list generating the
		 * appropriate version dependency entries.
		 */
		for (APLIST_TRAVERSE(vdp->vd_deps, idx2, _vdp)) {
			/* LINTED */
			vdap->vda_name = (uintptr_t)_vdp->vd_name;
			_vdap = vdap;
			vdap++, cnt++;
			/* LINTED */
			_vdap->vda_next = (Word)((uintptr_t)vdap -
			    (uintptr_t)_vdap);
		}
		_vdap->vda_next = 0;

		/*
		 * Record the versions auxiliary array offset and the associated
		 * dependency count.
		 */
		/* LINTED */
		vdf->vd_aux = (Word)((uintptr_t)(vdf + 1) - (uintptr_t)vdf);
		vdf->vd_cnt = cnt;

		/*
		 * Record the next versions offset and update the version
		 * pointer.  Remember the previous version offset as the very
		 * last structures next pointer should be null.
		 */
		_vdf = vdf;
		vdf = (Verdef *)vdap, num++;
		/* LINTED */
		_vdf->vd_next = (Word)((uintptr_t)vdf - (uintptr_t)_vdf);
	}
	_vdf->vd_next = 0;

	/*
	 * Record the string table association with the version definition
	 * section, and the symbol table associated with the version symbol
	 * table (the actual contents of the version symbol table are filled
	 * in during symbol update).
	 */
	/* LINTED */
	ofl->ofl_osverdef->os_shdr->sh_link = (Word)elf_ndxscn(strosp->os_scn);

	/*
	 * The version definition sections `info' field is used to indicate the
	 * number of entries in this section.
	 */
	ofl->ofl_osverdef->os_shdr->sh_info = num;

	return (1);
}

/*
 * Finish the version symbol index section
 */
static void
update_oversym(Ofl_desc *ofl)
{
	Os_desc		*osp;

	/*
	 * Record the symbol table associated with the version symbol table.
	 * The contents of the version symbol table are filled in during
	 * symbol update.
	 */
	if (OFL_IS_STATIC_OBJ(ofl))
		osp = ofl->ofl_ossymtab;
	else
		osp = ofl->ofl_osdynsym;

	/* LINTED */
	ofl->ofl_osversym->os_shdr->sh_link = (Word)elf_ndxscn(osp->os_scn);
}

/*
 * Build the version needed section
 */
static int
update_overneed(Ofl_desc *ofl)
{
	Aliste		idx1;
	Ifl_desc	*ifl;
	Verneed		*vnd, *_vnd;
	Os_desc		*strosp;
	Str_tbl		*strtbl;
	Word		num = 0;

	_vnd = vnd = (Verneed *)ofl->ofl_osverneed->os_outdata->d_buf;

	/*
	 * Determine which string table is appropriate.
	 */
	if (OFL_IS_STATIC_OBJ(ofl)) {
		strosp = ofl->ofl_osstrtab;
		strtbl = ofl->ofl_strtab;
	} else {
		strosp = ofl->ofl_osdynstr;
		strtbl = ofl->ofl_dynstrtab;
	}

	/*
	 * Traverse the shared object list looking for dependencies that have
	 * versions defined within them.
	 */
	for (APLIST_TRAVERSE(ofl->ofl_sos, idx1, ifl)) {
		Half		_cnt;
		Word		cnt = 0;
		Vernaux		*_vnap, *vnap;
		size_t		stoff;

		if (!(ifl->ifl_flags & FLG_IF_VERNEED))
			continue;

		vnd->vn_version = VER_NEED_CURRENT;

		(void) st_setstring(strtbl, ifl->ifl_soname, &stoff);
		vnd->vn_file = stoff;

		_vnap = vnap = (Vernaux *)(vnd + 1);

		/*
		 * Traverse the version index list recording
		 * each version as a needed dependency.
		 */
		for (_cnt = 0; _cnt <= ifl->ifl_vercnt; _cnt++) {
			Ver_index	*vip = &ifl->ifl_verndx[_cnt];

			if (vip->vi_flags & FLG_VER_REFER) {
				(void) st_setstring(strtbl, vip->vi_name,
				    &stoff);
				vnap->vna_name = stoff;

				if (vip->vi_desc) {
					vnap->vna_hash = vip->vi_desc->vd_hash;
					vnap->vna_flags =
					    vip->vi_desc->vd_flags;
				} else {
					vnap->vna_hash = 0;
					vnap->vna_flags = 0;
				}
				vnap->vna_other = vip->vi_overndx;

				/*
				 * If version A inherits version B, then
				 * B is implicit in A. It suffices for ld.so.1
				 * to verify A at runtime and skip B. The
				 * version normalization process sets the INFO
				 * flag for the versions we want ld.so.1 to
				 * skip.
				 */
				if (vip->vi_flags & VER_FLG_INFO)
					vnap->vna_flags |= VER_FLG_INFO;

				_vnap = vnap;
				vnap++, cnt++;
				_vnap->vna_next =
				    /* LINTED */
				    (Word)((uintptr_t)vnap - (uintptr_t)_vnap);
			}
		}

		_vnap->vna_next = 0;

		/*
		 * Record the versions auxiliary array offset and
		 * the associated dependency count.
		 */
		/* LINTED */
		vnd->vn_aux = (Word)((uintptr_t)(vnd + 1) - (uintptr_t)vnd);
		/* LINTED */
		vnd->vn_cnt = (Half)cnt;

		/*
		 * Record the next versions offset and update the version
		 * pointer.  Remember the previous version offset as the very
		 * last structures next pointer should be null.
		 */
		_vnd = vnd;
		vnd = (Verneed *)vnap, num++;
		/* LINTED */
		_vnd->vn_next = (Word)((uintptr_t)vnd - (uintptr_t)_vnd);
	}
	_vnd->vn_next = 0;

	/*
	 * Use sh_link to record the associated string table section, and
	 * sh_info to indicate the number of entries contained in the section.
	 */
	/* LINTED */
	ofl->ofl_osverneed->os_shdr->sh_link = (Word)elf_ndxscn(strosp->os_scn);
	ofl->ofl_osverneed->os_shdr->sh_info = num;

	return (1);
}

/*
 * Update syminfo section.
 */
static uintptr_t
update_osyminfo(Ofl_desc *ofl)
{
	Os_desc		*symosp, *infosp = ofl->ofl_ossyminfo;
	Syminfo		*sip = infosp->os_outdata->d_buf;
	Shdr		*shdr = infosp->os_shdr;
	char		*strtab;
	Aliste		idx;
	Sym_desc	*sdp;
	Sfltr_desc	*sftp;

	if (ofl->ofl_flags & FLG_OF_RELOBJ) {
		symosp = ofl->ofl_ossymtab;
		strtab = ofl->ofl_osstrtab->os_outdata->d_buf;
	} else {
		symosp = ofl->ofl_osdynsym;
		strtab = ofl->ofl_osdynstr->os_outdata->d_buf;
	}

	/* LINTED */
	infosp->os_shdr->sh_link = (Word)elf_ndxscn(symosp->os_scn);
	if (ofl->ofl_osdynamic)
		infosp->os_shdr->sh_info =
		    /* LINTED */
		    (Word)elf_ndxscn(ofl->ofl_osdynamic->os_scn);

	/*
	 * Update any references with the index into the dynamic table.
	 */
	for (APLIST_TRAVERSE(ofl->ofl_symdtent, idx, sdp))
		sip[sdp->sd_symndx].si_boundto = sdp->sd_file->ifl_neededndx;

	/*
	 * Update any filtee references with the index into the dynamic table.
	 */
	for (ALIST_TRAVERSE(ofl->ofl_symfltrs, idx, sftp)) {
		Dfltr_desc	*dftp;

		dftp = alist_item(ofl->ofl_dtsfltrs, sftp->sft_idx);
		sip[sftp->sft_sdp->sd_symndx].si_boundto = dftp->dft_ndx;
	}

	/*
	 * Display debugging information about section.
	 */
	DBG_CALL(Dbg_syminfo_title(ofl->ofl_lml));
	if (DBG_ENABLED) {
		Word	_cnt, cnt = shdr->sh_size / shdr->sh_entsize;
		Sym	*symtab = symosp->os_outdata->d_buf;
		Dyn	*dyn;

		if (ofl->ofl_osdynamic)
			dyn = ofl->ofl_osdynamic->os_outdata->d_buf;
		else
			dyn = NULL;

		for (_cnt = 1; _cnt < cnt; _cnt++) {
			if (sip[_cnt].si_flags || sip[_cnt].si_boundto)
				/* LINTED */
				DBG_CALL(Dbg_syminfo_entry(ofl->ofl_lml, _cnt,
				    &sip[_cnt], &symtab[_cnt], strtab, dyn));
		}
	}
	return (1);
}

/*
 * Build the output elf header.
 */
static uintptr_t
update_oehdr(Ofl_desc * ofl)
{
	Ehdr	*ehdr = ofl->ofl_nehdr;

	/*
	 * If an entry point symbol has already been established (refer
	 * sym_validate()) simply update the elf header entry point with the
	 * symbols value.  If no entry point is defined it will have been filled
	 * with the start address of the first section within the text segment
	 * (refer update_outfile()).
	 */
	if (ofl->ofl_entry)
		ehdr->e_entry =
		    ((Sym_desc *)(ofl->ofl_entry))->sd_sym->st_value;

	ehdr->e_ident[EI_DATA] = ld_targ.t_m.m_data;
	ehdr->e_version = ofl->ofl_dehdr->e_version;

	/*
	 * When generating a relocatable object under -z symbolcap, set the
	 * e_machine to be generic, and remove any e_flags.  Input relocatable
	 * objects may identify alternative e_machine (m.machplus) and e_flags
	 * values.  However, the functions within the created output object
	 * are selected at runtime using the capabilities mechanism, which
	 * supersedes the e-machine and e_flags information.  Therefore,
	 * e_machine and e_flag values are not propagated to the output object,
	 * as these values might prevent the kernel from loading the object
	 * before the runtime linker gets control.
	 */
	if (ofl->ofl_flags & FLG_OF_OTOSCAP) {
		ehdr->e_machine = ld_targ.t_m.m_mach;
		ehdr->e_flags = 0;
	} else {
		/*
		 * Note. it may be necessary to update the e_flags field in the
		 * machine dependent section.
		 */
		ehdr->e_machine = ofl->ofl_dehdr->e_machine;
		ehdr->e_flags = ofl->ofl_dehdr->e_flags;

		if (ehdr->e_machine != ld_targ.t_m.m_mach) {
			if (ehdr->e_machine != ld_targ.t_m.m_machplus)
				return (S_ERROR);
			if ((ehdr->e_flags & ld_targ.t_m.m_flagsplus) == 0)
				return (S_ERROR);
		}
	}

	if (ofl->ofl_flags & FLG_OF_SHAROBJ)
		ehdr->e_type = ET_DYN;
	else if (ofl->ofl_flags & FLG_OF_RELOBJ)
		ehdr->e_type = ET_REL;
	else
		ehdr->e_type = ET_EXEC;

	return (1);
}

/*
 * Perform move table expansion.
 */
static void
expand_move(Ofl_desc *ofl, Sym_desc *sdp, Move *mvp)
{
	Os_desc		*osp;
	uchar_t		*taddr, *taddr0;
	Sxword		offset;
	Half		cnt;
	uint_t		stride;

	osp = ofl->ofl_isparexpn->is_osdesc;
	offset = sdp->sd_sym->st_value - osp->os_shdr->sh_addr;

	taddr0 = taddr = osp->os_outdata->d_buf;
	taddr += offset;
	taddr = taddr + mvp->m_poffset;

	for (cnt = 0; cnt < mvp->m_repeat; cnt++) {
		/* LINTED */
		DBG_CALL(Dbg_move_expand(ofl->ofl_lml, mvp,
		    (Addr)(taddr - taddr0)));
		stride = (uint_t)mvp->m_stride + 1;

		/*
		 * Update the target address based upon the move entry size.
		 * This size was validated in ld_process_move().
		 */
		/* LINTED */
		switch (ELF_M_SIZE(mvp->m_info)) {
		case 1:
			/* LINTED */
			*taddr = (uchar_t)mvp->m_value;
			taddr += stride;
			break;
		case 2:
			/* LINTED */
			*((Half *)taddr) = (Half)mvp->m_value;
			taddr += 2 * stride;
			break;
		case 4:
			/* LINTED */
			*((Word *)taddr) = (Word)mvp->m_value;
			taddr += 4 * stride;
			break;
		case 8:
			/* LINTED */
			*((u_longlong_t *)taddr) = mvp->m_value;
			taddr += 8 * stride;
			break;
		}
	}
}

/*
 * Update Move sections.
 */
static void
update_move(Ofl_desc *ofl)
{
	Word		ndx = 0;
	ofl_flag_t	flags = ofl->ofl_flags;
	Move		*omvp;
	Aliste		idx1;
	Sym_desc	*sdp;

	/*
	 * Determine the index of the symbol table that will be referenced by
	 * the Move section.
	 */
	if (OFL_ALLOW_DYNSYM(ofl))
		/* LINTED */
		ndx = (Word) elf_ndxscn(ofl->ofl_osdynsym->os_scn);
	else if (!(flags & FLG_OF_STRIP) || (flags & FLG_OF_RELOBJ))
		/* LINTED */
		ndx = (Word) elf_ndxscn(ofl->ofl_ossymtab->os_scn);

	/*
	 * Update sh_link of the Move section, and point to the new Move data.
	 */
	if (ofl->ofl_osmove) {
		ofl->ofl_osmove->os_shdr->sh_link = ndx;
		omvp = (Move *)ofl->ofl_osmove->os_outdata->d_buf;
	}

	/*
	 * Update symbol entry index
	 */
	for (APLIST_TRAVERSE(ofl->ofl_parsyms, idx1, sdp)) {
		Aliste		idx2;
		Mv_desc		*mdp;

		/*
		 * Expand move table
		 */
		if (sdp->sd_flags & FLG_SY_PAREXPN) {
			const char	*str;

			if (flags & FLG_OF_STATIC)
				str = MSG_INTL(MSG_PSYM_EXPREASON1);
			else if (ofl->ofl_flags1 & FLG_OF1_NOPARTI)
				str = MSG_INTL(MSG_PSYM_EXPREASON2);
			else
				str = MSG_INTL(MSG_PSYM_EXPREASON3);

			DBG_CALL(Dbg_move_parexpn(ofl->ofl_lml,
			    sdp->sd_name, str));

			for (ALIST_TRAVERSE(sdp->sd_move, idx2, mdp)) {
				DBG_CALL(Dbg_move_entry1(ofl->ofl_lml, 0,
				    mdp->md_move, sdp));
				expand_move(ofl, sdp, mdp->md_move);
			}
			continue;
		}

		/*
		 * Process move table
		 */
		DBG_CALL(Dbg_move_outmove(ofl->ofl_lml, sdp->sd_name));

		for (ALIST_TRAVERSE(sdp->sd_move, idx2, mdp)) {
			Move	*imvp;
			int	idx = 1;
			Sym	*sym;

			imvp = mdp->md_move;
			sym = sdp->sd_sym;

			DBG_CALL(Dbg_move_entry1(ofl->ofl_lml, 1, imvp, sdp));

			*omvp = *imvp;
			if ((flags & FLG_OF_RELOBJ) == 0) {
				if (ELF_ST_BIND(sym->st_info) == STB_LOCAL) {
					Os_desc	*osp = sdp->sd_isc->is_osdesc;
					Word	ndx = osp->os_identndx;

					omvp->m_info =
					    /* LINTED */
					    ELF_M_INFO(ndx, imvp->m_info);

					if (ELF_ST_TYPE(sym->st_info) !=
					    STT_SECTION) {
						omvp->m_poffset =
						    sym->st_value -
						    osp->os_shdr->sh_addr +
						    imvp->m_poffset;
					}
				} else {
					omvp->m_info =
					    /* LINTED */
					    ELF_M_INFO(sdp->sd_symndx,
					    imvp->m_info);
				}
			} else {
				Boolean 	isredloc = FALSE;

				if ((ELF_ST_BIND(sym->st_info) == STB_LOCAL) &&
				    (ofl->ofl_flags & FLG_OF_REDLSYM))
					isredloc = TRUE;

				if (isredloc && !(sdp->sd_move)) {
					Os_desc	*osp = sdp->sd_isc->is_osdesc;
					Word	ndx = osp->os_identndx;

					omvp->m_info =
					    /* LINTED */
					    ELF_M_INFO(ndx, imvp->m_info);

					omvp->m_poffset += sym->st_value;
				} else {
					if (isredloc)
						DBG_CALL(Dbg_syms_reduce(ofl,
						    DBG_SYM_REDUCE_RETAIN,
						    sdp, idx,
						    ofl->ofl_osmove->os_name));

					omvp->m_info =
					    /* LINTED */
					    ELF_M_INFO(sdp->sd_symndx,
					    imvp->m_info);
				}
			}

			DBG_CALL(Dbg_move_entry1(ofl->ofl_lml, 0, omvp, sdp));
			omvp++;
			idx++;
		}
	}
}

/*
 * Scan through the SHT_GROUP output sections.  Update their sh_link/sh_info
 * fields as well as the section contents.
 */
static uintptr_t
update_ogroup(Ofl_desc *ofl)
{
	Aliste		idx;
	Os_desc		*osp;
	uintptr_t	error = 0;

	for (APLIST_TRAVERSE(ofl->ofl_osgroups, idx, osp)) {
		Is_desc		*isp;
		Ifl_desc	*ifl;
		Shdr		*shdr = osp->os_shdr;
		Sym_desc	*sdp;
		Xword		i, grpcnt;
		Word		*gdata;

		/*
		 * Since input GROUP sections always create unique
		 * output GROUP sections - we know there is only one
		 * item on the list.
		 */
		isp = ld_os_first_isdesc(osp);

		ifl = isp->is_file;
		sdp = ifl->ifl_oldndx[isp->is_shdr->sh_info];
		shdr->sh_link = (Word)elf_ndxscn(ofl->ofl_ossymtab->os_scn);
		shdr->sh_info = sdp->sd_symndx;

		/*
		 * Scan through the group data section and update
		 * all of the links to new values.
		 */
		grpcnt = shdr->sh_size / shdr->sh_entsize;
		gdata = (Word *)osp->os_outdata->d_buf;

		for (i = 1; i < grpcnt; i++) {
			Os_desc	*_osp;
			Is_desc	*_isp = ifl->ifl_isdesc[gdata[i]];

			/*
			 * If the referenced section didn't make it to the
			 * output file - just zero out the entry.
			 */
			if ((_osp = _isp->is_osdesc) == NULL)
				gdata[i] = 0;
			else
				gdata[i] = (Word)elf_ndxscn(_osp->os_scn);
		}
	}
	return (error);
}

static void
update_ostrtab(Os_desc *osp, Str_tbl *stp, uint_t extra)
{
	Elf_Data	*data;

	if (osp == NULL)
		return;

	data = osp->os_outdata;
	assert(data->d_size == (st_getstrtab_sz(stp) + extra));
	(void) st_setstrbuf(stp, data->d_buf, data->d_size - extra);
	/* If leaving an extra hole at the end, zero it */
	if (extra > 0)
		(void) memset((char *)data->d_buf + data->d_size - extra,
		    0x0, extra);
}

/*
 * Update capabilities information.
 *
 * If string table capabilities exist, then the associated string must be
 * translated into an offset into the string table.
 */
static void
update_oscap(Ofl_desc *ofl)
{
	Os_desc		*strosp, *cosp;
	Cap		*cap;
	Str_tbl		*strtbl;
	Capstr		*capstr;
	size_t		stoff;
	Aliste		idx1;

	/*
	 * Determine which symbol table or string table is appropriate.
	 */
	if (OFL_IS_STATIC_OBJ(ofl)) {
		strosp = ofl->ofl_osstrtab;
		strtbl = ofl->ofl_strtab;
	} else {
		strosp = ofl->ofl_osdynstr;
		strtbl = ofl->ofl_dynstrtab;
	}

	/*
	 * If symbol capabilities exist, set the sh_link field of the .SUNW_cap
	 * section to the .SUNW_capinfo section.
	 */
	if (ofl->ofl_oscapinfo) {
		cosp = ofl->ofl_oscap;
		cosp->os_shdr->sh_link =
		    (Word)elf_ndxscn(ofl->ofl_oscapinfo->os_scn);
	}

	/*
	 * If there are capability strings to process, set the sh_info
	 * field of the .SUNW_cap section to the associated string table, and
	 * proceed to process any CA_SUNW_PLAT entries.
	 */
	if ((ofl->ofl_flags & FLG_OF_CAPSTRS) == 0)
		return;

	cosp = ofl->ofl_oscap;
	cosp->os_shdr->sh_info = (Word)elf_ndxscn(strosp->os_scn);

	cap = ofl->ofl_oscap->os_outdata->d_buf;

	/*
	 * Determine whether an object capability identifier, or object
	 * machine/platform capabilities exists.
	 */
	capstr = &ofl->ofl_ocapset.oc_id;
	if (capstr->cs_str) {
		(void) st_setstring(strtbl, capstr->cs_str, &stoff);
		cap[capstr->cs_ndx].c_un.c_ptr = stoff;
	}
	for (ALIST_TRAVERSE(ofl->ofl_ocapset.oc_plat.cl_val, idx1, capstr)) {
		(void) st_setstring(strtbl, capstr->cs_str, &stoff);
		cap[capstr->cs_ndx].c_un.c_ptr = stoff;
	}
	for (ALIST_TRAVERSE(ofl->ofl_ocapset.oc_mach.cl_val, idx1, capstr)) {
		(void) st_setstring(strtbl, capstr->cs_str, &stoff);
		cap[capstr->cs_ndx].c_un.c_ptr = stoff;
	}

	/*
	 * Determine any symbol capability identifiers, or machine/platform
	 * capabilities.
	 */
	if (ofl->ofl_capgroups) {
		Cap_group	*cgp;

		for (APLIST_TRAVERSE(ofl->ofl_capgroups, idx1, cgp)) {
			Objcapset	*ocapset = &cgp->cg_set;
			Aliste		idx2;

			capstr = &ocapset->oc_id;
			if (capstr->cs_str) {
				(void) st_setstring(strtbl, capstr->cs_str,
				    &stoff);
				cap[capstr->cs_ndx].c_un.c_ptr = stoff;
			}
			for (ALIST_TRAVERSE(ocapset->oc_plat.cl_val, idx2,
			    capstr)) {
				(void) st_setstring(strtbl, capstr->cs_str,
				    &stoff);
				cap[capstr->cs_ndx].c_un.c_ptr = stoff;
			}
			for (ALIST_TRAVERSE(ocapset->oc_mach.cl_val, idx2,
			    capstr)) {
				(void) st_setstring(strtbl, capstr->cs_str,
				    &stoff);
				cap[capstr->cs_ndx].c_un.c_ptr = stoff;
			}
		}
	}
}

/*
 * Update the .SUNW_capinfo, and possibly the .SUNW_capchain sections.
 */
static void
update_oscapinfo(Ofl_desc *ofl)
{
	Os_desc		*symosp, *ciosp, *ccosp = NULL;
	Capinfo		*ocapinfo;
	Capchain	*ocapchain;
	Cap_avlnode	*cav;
	Word		chainndx = 0;

	/*
	 * Determine which symbol table is appropriate.
	 */
	if (OFL_IS_STATIC_OBJ(ofl))
		symosp = ofl->ofl_ossymtab;
	else
		symosp = ofl->ofl_osdynsym;

	/*
	 * Update the .SUNW_capinfo sh_link to point to the appropriate symbol
	 * table section.  If we're creating a dynamic object, the
	 * .SUNW_capinfo sh_info is updated to point to the .SUNW_capchain
	 * section.
	 */
	ciosp = ofl->ofl_oscapinfo;
	ciosp->os_shdr->sh_link = (Word)elf_ndxscn(symosp->os_scn);

	if (OFL_IS_STATIC_OBJ(ofl) == 0) {
		ccosp = ofl->ofl_oscapchain;
		ciosp->os_shdr->sh_info = (Word)elf_ndxscn(ccosp->os_scn);
	}

	/*
	 * Establish the data for each section.  The first element of each
	 * section defines the section's version number.
	 */
	ocapinfo = ciosp->os_outdata->d_buf;
	ocapinfo[0] = CAPINFO_CURRENT;
	if (ccosp) {
		ocapchain = ccosp->os_outdata->d_buf;
		ocapchain[chainndx++] = CAPCHAIN_CURRENT;
	}

	/*
	 * Traverse all capabilities families.  Each member has a .SUNW_capinfo
	 * assignment.  The .SUNW_capinfo entry differs for relocatable objects
	 * and dynamic objects.
	 *
	 * Relocatable objects:
	 *			ELF_C_GROUP		ELF_C_SYM
	 *
	 * Family lead:		CAPINFO_SUNW_GLOB	lead symbol index
	 * Family lead alias:	CAPINFO_SUNW_GLOB	lead symbol index
	 * Family member:	.SUNW_cap index		lead symbol index
	 *
	 * Dynamic objects:
	 *			ELF_C_GROUP		ELF_C_SYM
	 *
	 * Family lead:		CAPINFO_SUNW_GLOB	.SUNW_capchain index
	 * Family lead alias:	CAPINFO_SUNW_GLOB	.SUNW_capchain index
	 * Family member:	.SUNW_cap index		lead symbol index
	 *
	 * The ELF_C_GROUP field identifies a capabilities symbol.  Lead
	 * capability symbols, and lead capability aliases are identified by
	 * a CAPINFO_SUNW_GLOB group identifier.  For family members, the
	 * ELF_C_GROUP provides an index to the associate capabilities group
	 * (i.e, an index into the SUNW_cap section that defines a group).
	 *
	 * For relocatable objects, the ELF_C_SYM field identifies the lead
	 * capability symbol.  For the lead symbol itself, the .SUNW_capinfo
	 * index is the same as the ELF_C_SYM value.  For lead alias symbols,
	 * the .SUNW_capinfo index differs from the ELF_C_SYM value.  This
	 * differentiation of CAPINFO_SUNW_GLOB symbols allows ld(1) to
	 * identify, and propagate lead alias symbols.  For example, the lead
	 * capability symbol memcpy() would have the ELF_C_SYM for memcpy(),
	 * and the lead alias _memcpy() would also have the ELF_C_SYM for
	 * memcpy().
	 *
	 * For dynamic objects, both a lead capability symbol, and alias symbol
	 * would have a ELF_C_SYM value that represents the same capability
	 * chain index.  The capability chain allows ld.so.1 to traverse a
	 * family chain for a given lead symbol, and select the most appropriate
	 * family member.  The .SUNW_capchain array contains a series of symbol
	 * indexes for each family member:
	 *
	 *    chaincap[n]  chaincap[n + 1]  chaincap[n + 2]  chaincap[n + x]
	 *	foo() ndx    foo%x() ndx	foo%y() ndx	0
	 *
	 * For family members, the ELF_C_SYM value associates the capability
	 * members with their family lead symbol.  This association, although
	 * unused within a dynamic object, allows ld(1) to identify, and
	 * propagate family members when processing relocatable objects.
	 */
	for (cav = avl_first(ofl->ofl_capfamilies); cav;
	    cav = AVL_NEXT(ofl->ofl_capfamilies, cav)) {
		Cap_sym		*csp;
		Aliste		idx;
		Sym_desc	*asdp, *lsdp = cav->cn_symavlnode.sav_sdp;

		if (ccosp) {
			/*
			 * For a dynamic object, identify this lead symbol, and
			 * point it to the head of a capability chain.  Set the
			 * head of the capability chain to the same lead symbol.
			 */
			ocapinfo[lsdp->sd_symndx] =
			    ELF_C_INFO(chainndx, CAPINFO_SUNW_GLOB);
			ocapchain[chainndx] = lsdp->sd_symndx;
		} else {
			/*
			 * For a relocatable object, identify this lead symbol,
			 * and set the lead symbol index to itself.
			 */
			ocapinfo[lsdp->sd_symndx] =
			    ELF_C_INFO(lsdp->sd_symndx, CAPINFO_SUNW_GLOB);
		}

		/*
		 * Gather any lead symbol aliases.
		 */
		for (APLIST_TRAVERSE(cav->cn_aliases, idx, asdp)) {
			if (ccosp) {
				/*
				 * For a dynamic object, identify this lead
				 * alias symbol, and point it to the same
				 * capability chain index as the lead symbol.
				 */
				ocapinfo[asdp->sd_symndx] =
				    ELF_C_INFO(chainndx, CAPINFO_SUNW_GLOB);
			} else {
				/*
				 * For a relocatable object, identify this lead
				 * alias symbol, and set the lead symbol index
				 * to the lead symbol.
				 */
				ocapinfo[asdp->sd_symndx] =
				    ELF_C_INFO(lsdp->sd_symndx,
				    CAPINFO_SUNW_GLOB);
			}
		}

		chainndx++;

		/*
		 * Gather the family members.
		 */
		for (APLIST_TRAVERSE(cav->cn_members, idx, csp)) {
			Sym_desc	*msdp = csp->cs_sdp;

			/*
			 * Identify the members capability group, and the lead
			 * symbol of the family this symbol is a member of.
			 */
			ocapinfo[msdp->sd_symndx] =
			    ELF_C_INFO(lsdp->sd_symndx, csp->cs_group->cg_ndx);
			if (ccosp) {
				/*
				 * For a dynamic object, set the next capability
				 * chain to point to this family member.
				 */
				ocapchain[chainndx++] = msdp->sd_symndx;
			}
		}

		/*
		 * Any chain of family members is terminated with a 0 element.
		 */
		if (ccosp)
			ocapchain[chainndx++] = 0;
	}
}

/*
 * Translate the shdr->sh_{link, info} from its input section value to that
 * of the corresponding shdr->sh_{link, info} output section value.
 */
static Word
translate_link(Ofl_desc *ofl, Os_desc *osp, Word link, const char *msg)
{
	Is_desc		*isp;
	Ifl_desc	*ifl;

	/*
	 * Don't translate the special section numbers.
	 */
	if (link >= SHN_LORESERVE)
		return (link);

	/*
	 * Does this output section translate back to an input file.  If not
	 * then there is no translation to do.  In this case we will assume that
	 * if sh_link has a value, it's the right value.
	 */
	isp = ld_os_first_isdesc(osp);
	if ((ifl = isp->is_file) == NULL)
		return (link);

	/*
	 * Sanity check to make sure that the sh_{link, info} value
	 * is within range for the input file.
	 */
	if (link >= ifl->ifl_shnum) {
		eprintf(ofl->ofl_lml, ERR_WARNING, msg, ifl->ifl_name,
		    EC_WORD(isp->is_scnndx), isp->is_name, EC_XWORD(link));
		return (link);
	}

	/*
	 * Follow the link to the input section.
	 */
	if ((isp = ifl->ifl_isdesc[link]) == NULL)
		return (0);
	if ((osp = isp->is_osdesc) == NULL)
		return (0);

	/* LINTED */
	return ((Word)elf_ndxscn(osp->os_scn));
}

/*
 * Having created all of the necessary sections, segments, and associated
 * headers, fill in the program headers and update any other data in the
 * output image.  Some general rules:
 *
 *  -	If an interpreter is required always generate a PT_PHDR entry as
 *	well.  It is this entry that triggers the kernel into passing the
 *	interpreter an aux vector instead of just a file descriptor.
 *
 *  -	When generating an image that will be interpreted (ie. a dynamic
 *	executable, a shared object, or a static executable that has been
 *	provided with an interpreter - weird, but possible), make the initial
 *	loadable segment include both the ehdr and phdr[].  Both of these
 *	tables are used by the interpreter therefore it seems more intuitive
 *	to explicitly defined them as part of the mapped image rather than
 *	relying on page rounding by the interpreter to allow their access.
 *
 *  -	When generating a static image that does not require an interpreter
 *	have the first loadable segment indicate the address of the first
 *	.section as the start address (things like /kernel/unix and ufsboot
 *	expect this behavior).
 */
uintptr_t
ld_update_outfile(Ofl_desc *ofl)
{
	Addr		size, etext, vaddr;
	Sg_desc		*sgp;
	Sg_desc		*dtracesgp = NULL, *capsgp = NULL, *intpsgp = NULL;
	Os_desc		*osp;
	int		phdrndx = 0, segndx = -1, secndx, intppndx, intpsndx;
	int		dtracepndx, dtracesndx, cappndx, capsndx;
	Ehdr		*ehdr = ofl->ofl_nehdr;
	Shdr		*hshdr;
	Phdr		*_phdr = NULL;
	Word		phdrsz = (ehdr->e_phnum * ehdr->e_phentsize), shscnndx;
	ofl_flag_t	flags = ofl->ofl_flags;
	Word		ehdrsz = ehdr->e_ehsize;
	Boolean		nobits;
	Off		offset;
	Aliste		idx1;

	/*
	 * Initialize the starting address for the first segment.  Executables
	 * have different starting addresses depending upon the target ABI,
	 * where as shared objects have a starting address of 0.  If this is
	 * a 64-bit executable that is being constructed to run in a restricted
	 * address space, use an alternative origin that will provide more free
	 * address space for the the eventual process.
	 */
	if (ofl->ofl_flags & FLG_OF_EXEC) {
#if	defined(_ELF64)
		if (ofl->ofl_ocapset.oc_sf_1.cm_val & SF1_SUNW_ADDR32)
			vaddr = ld_targ.t_m.m_segm_aorigin;
		else
#endif
			vaddr = ld_targ.t_m.m_segm_origin;
	} else
		vaddr = 0;

	/*
	 * Loop through the segment descriptors and pick out what we need.
	 */
	DBG_CALL(Dbg_seg_title(ofl->ofl_lml));
	for (APLIST_TRAVERSE(ofl->ofl_segs, idx1, sgp)) {
		Phdr		*phdr = &(sgp->sg_phdr);
		Xword 		p_align;
		Aliste		idx2;
		Sym_desc	*sdp;

		segndx++;

		/*
		 * If an interpreter is required generate a PT_INTERP and
		 * PT_PHDR program header entry.  The PT_PHDR entry describes
		 * the program header table itself.  This information will be
		 * passed via the aux vector to the interpreter (ld.so.1).
		 * The program header array is actually part of the first
		 * loadable segment (and the PT_PHDR entry is the first entry),
		 * therefore its virtual address isn't known until the first
		 * loadable segment is processed.
		 */
		if (phdr->p_type == PT_PHDR) {
			if (ofl->ofl_osinterp) {
				phdr->p_offset = ehdr->e_phoff;
				phdr->p_filesz = phdr->p_memsz = phdrsz;

				DBG_CALL(Dbg_seg_entry(ofl, segndx, sgp));
				ofl->ofl_phdr[phdrndx++] = *phdr;
			}
			continue;
		}
		if (phdr->p_type == PT_INTERP) {
			if (ofl->ofl_osinterp) {
				intpsgp = sgp;
				intpsndx = segndx;
				intppndx = phdrndx++;
			}
			continue;
		}

		/*
		 * If we are creating a PT_SUNWDTRACE segment, remember where
		 * the program header is.  The header values are assigned after
		 * update_osym() has completed and the symbol table addresses
		 * have been updated.
		 */
		if (phdr->p_type == PT_SUNWDTRACE) {
			if (ofl->ofl_dtracesym &&
			    ((flags & FLG_OF_RELOBJ) == 0)) {
				dtracesgp = sgp;
				dtracesndx = segndx;
				dtracepndx = phdrndx++;
			}
			continue;
		}

		/*
		 * If a hardware/software capabilities section is required,
		 * generate the PT_SUNWCAP header.  Note, as this comes before
		 * the first loadable segment, we don't yet know its real
		 * virtual address.  This is updated later.
		 */
		if (phdr->p_type == PT_SUNWCAP) {
			if (ofl->ofl_oscap && (ofl->ofl_flags & FLG_OF_PTCAP) &&
			    ((flags & FLG_OF_RELOBJ) == 0)) {
				capsgp = sgp;
				capsndx = segndx;
				cappndx = phdrndx++;
			}
			continue;
		}

		/*
		 * As the dynamic program header occurs after the loadable
		 * headers in the segment descriptor table, all the address
		 * information for the .dynamic output section will have been
		 * figured out by now.
		 */
		if (phdr->p_type == PT_DYNAMIC) {
			if (OFL_ALLOW_DYNSYM(ofl)) {
				Shdr	*shdr = ofl->ofl_osdynamic->os_shdr;

				phdr->p_vaddr = shdr->sh_addr;
				phdr->p_offset = shdr->sh_offset;
				phdr->p_filesz = shdr->sh_size;
				phdr->p_flags = ld_targ.t_m.m_dataseg_perm;

				DBG_CALL(Dbg_seg_entry(ofl, segndx, sgp));
				ofl->ofl_phdr[phdrndx++] = *phdr;
			}
			continue;
		}

		/*
		 * As the unwind (.eh_frame_hdr) program header occurs after
		 * the loadable headers in the segment descriptor table, all
		 * the address information for the .eh_frame output section
		 * will have been figured out by now.
		 */
		if (phdr->p_type == PT_SUNW_UNWIND) {
			Shdr	    *shdr;

			if (ofl->ofl_unwindhdr == NULL)
				continue;

			shdr = ofl->ofl_unwindhdr->os_shdr;

			phdr->p_flags = PF_R;
			phdr->p_vaddr = shdr->sh_addr;
			phdr->p_memsz = shdr->sh_size;
			phdr->p_filesz = shdr->sh_size;
			phdr->p_offset = shdr->sh_offset;
			phdr->p_align = shdr->sh_addralign;
			phdr->p_paddr = 0;
			ofl->ofl_phdr[phdrndx++] = *phdr;
			continue;
		}

		/*
		 * The sunwstack program is used to convey non-default
		 * flags for the process stack. Only emit it if it would
		 * change the default.
		 */
		if (phdr->p_type == PT_SUNWSTACK) {
			if (((flags & FLG_OF_RELOBJ) == 0) &&
			    ((sgp->sg_flags & FLG_SG_DISABLED) == 0))
				ofl->ofl_phdr[phdrndx++] = *phdr;
			continue;
		}

		/*
		 * As the TLS program header occurs after the loadable
		 * headers in the segment descriptor table, all the address
		 * information for the .tls output section will have been
		 * figured out by now.
		 */
		if (phdr->p_type == PT_TLS) {
			Os_desc		*tlsosp;
			Shdr		*lastfileshdr = NULL;
			Shdr		*firstshdr = NULL, *lastshdr;
			Aliste		idx;

			if (ofl->ofl_ostlsseg == NULL)
				continue;

			/*
			 * Scan the output sections that have contributed TLS.
			 * Remember the first and last so as to determine the
			 * TLS memory size requirement.  Remember the last
			 * progbits section to determine the TLS data
			 * contribution, which determines the TLS program
			 * header filesz.
			 */
			for (APLIST_TRAVERSE(ofl->ofl_ostlsseg, idx, tlsosp)) {
				Shdr	*tlsshdr = tlsosp->os_shdr;

				if (firstshdr == NULL)
					firstshdr = tlsshdr;
				if (tlsshdr->sh_type != SHT_NOBITS)
					lastfileshdr = tlsshdr;
				lastshdr = tlsshdr;
			}

			phdr->p_flags = PF_R | PF_W;
			phdr->p_vaddr = firstshdr->sh_addr;
			phdr->p_offset = firstshdr->sh_offset;
			phdr->p_align = firstshdr->sh_addralign;

			/*
			 * Determine the initialized TLS data size.  This
			 * address range is from the start of the TLS segment
			 * to the end of the last piece of initialized data.
			 */
			if (lastfileshdr)
				phdr->p_filesz = lastfileshdr->sh_offset +
				    lastfileshdr->sh_size - phdr->p_offset;
			else
				phdr->p_filesz = 0;

			/*
			 * Determine the total TLS memory size.  This includes
			 * all TLS data and TLS uninitialized data.  This
			 * address range is from the start of the TLS segment
			 * to the memory address of the last piece of
			 * uninitialized data.
			 */
			phdr->p_memsz = lastshdr->sh_addr +
			    lastshdr->sh_size - phdr->p_vaddr;

			DBG_CALL(Dbg_seg_entry(ofl, segndx, sgp));
			ofl->ofl_phdr[phdrndx] = *phdr;
			ofl->ofl_tlsphdr = &ofl->ofl_phdr[phdrndx++];
			continue;
		}

		/*
		 * If this is an empty segment declaration, it will occur after
		 * all other loadable segments.  As empty segments can be
		 * defined with fixed addresses, make sure that no loadable
		 * segments overlap.  This might occur as the object evolves
		 * and the loadable segments grow, thus encroaching upon an
		 * existing segment reservation.
		 *
		 * Segments are only created for dynamic objects, thus this
		 * checking can be skipped when building a relocatable object.
		 */
		if (!(flags & FLG_OF_RELOBJ) &&
		    (sgp->sg_flags & FLG_SG_EMPTY)) {
			int	i;
			Addr	v_e;

			vaddr = phdr->p_vaddr;
			phdr->p_memsz = sgp->sg_length;
			DBG_CALL(Dbg_seg_entry(ofl, segndx, sgp));
			ofl->ofl_phdr[phdrndx++] = *phdr;

			if (phdr->p_type != PT_LOAD)
				continue;

			v_e = vaddr + phdr->p_memsz;

			/*
			 * Check overlaps
			 */
			for (i = 0; i < phdrndx - 1; i++) {
				Addr 	p_s = (ofl->ofl_phdr[i]).p_vaddr;
				Addr 	p_e;

				if ((ofl->ofl_phdr[i]).p_type != PT_LOAD)
					continue;

				p_e = p_s + (ofl->ofl_phdr[i]).p_memsz;
				if (((p_s <= vaddr) && (p_e > vaddr)) ||
				    ((vaddr <= p_s) && (v_e > p_s)))
					eprintf(ofl->ofl_lml, ERR_WARNING,
					    MSG_INTL(MSG_UPD_SEGOVERLAP),
					    ofl->ofl_name, EC_ADDR(p_e),
					    sgp->sg_name, EC_ADDR(vaddr));
			}
			continue;
		}

		/*
		 * Having processed any of the special program headers any
		 * remaining headers will be built to express individual
		 * segments.  Segments are only built if they have output
		 * section descriptors associated with them (ie. some form of
		 * input section has been matched to this segment).
		 */
		if (sgp->sg_osdescs == NULL)
			continue;

		/*
		 * Determine the segments offset and size from the section
		 * information provided from elf_update().
		 * Allow for multiple NOBITS sections.
		 */
		osp = sgp->sg_osdescs->apl_data[0];
		hshdr = osp->os_shdr;

		phdr->p_filesz = 0;
		phdr->p_memsz = 0;
		phdr->p_offset = offset = hshdr->sh_offset;

		nobits = ((hshdr->sh_type == SHT_NOBITS) &&
		    ((sgp->sg_flags & FLG_SG_PHREQ) == 0));

		for (APLIST_TRAVERSE(sgp->sg_osdescs, idx2, osp)) {
			Shdr	*shdr = osp->os_shdr;

			p_align = 0;
			if (shdr->sh_addralign > p_align)
				p_align = shdr->sh_addralign;

			offset = (Off)S_ROUND(offset, shdr->sh_addralign);
			offset += shdr->sh_size;

			if (shdr->sh_type != SHT_NOBITS) {
				if (nobits) {
					eprintf(ofl->ofl_lml, ERR_FATAL,
					    MSG_INTL(MSG_UPD_NOBITS));
					return (S_ERROR);
				}
				phdr->p_filesz = offset - phdr->p_offset;
			} else if ((sgp->sg_flags & FLG_SG_PHREQ) == 0)
				nobits = TRUE;
		}
		phdr->p_memsz = offset - hshdr->sh_offset;

		/*
		 * If this is the first loadable segment of a dynamic object,
		 * or an interpreter has been specified (a static object built
		 * with an interpreter will still be given a PT_HDR entry), then
		 * compensate for the elf header and program header array.  Both
		 * of these are actually part of the loadable segment as they
		 * may be inspected by the interpreter.  Adjust the segments
		 * size and offset accordingly.
		 */
		if ((_phdr == NULL) && (phdr->p_type == PT_LOAD) &&
		    ((ofl->ofl_osinterp) || (flags & FLG_OF_DYNAMIC)) &&
		    (!(ofl->ofl_dtflags_1 & DF_1_NOHDR))) {
			size = (Addr)S_ROUND((phdrsz + ehdrsz),
			    hshdr->sh_addralign);
			phdr->p_offset -= size;
			phdr->p_filesz += size;
			phdr->p_memsz += size;
		}

		/*
		 * If segment size symbols are required (specified via a
		 * mapfile) update their value.
		 */
		for (APLIST_TRAVERSE(sgp->sg_sizesym, idx2, sdp))
			sdp->sd_sym->st_value = phdr->p_memsz;

		/*
		 * If no file content has been assigned to this segment (it
		 * only contains no-bits sections), then reset the offset for
		 * consistency.
		 */
		if (phdr->p_filesz == 0)
			phdr->p_offset = 0;

		/*
		 * If a virtual address has been specified for this segment
		 * from a mapfile use it and make sure the previous segment
		 * does not run into this segment.
		 */
		if (phdr->p_type == PT_LOAD) {
			if ((sgp->sg_flags & FLG_SG_P_VADDR)) {
				if (_phdr && (vaddr > phdr->p_vaddr) &&
				    (phdr->p_type == PT_LOAD))
					eprintf(ofl->ofl_lml, ERR_WARNING,
					    MSG_INTL(MSG_UPD_SEGOVERLAP),
					    ofl->ofl_name, EC_ADDR(vaddr),
					    sgp->sg_name,
					    EC_ADDR(phdr->p_vaddr));
				vaddr = phdr->p_vaddr;
				phdr->p_align = 0;
			} else {
				vaddr = phdr->p_vaddr =
				    (Addr)S_ROUND(vaddr, phdr->p_align);
			}
		}

		/*
		 * Adjust the address offset and p_align if needed.
		 */
		if (((sgp->sg_flags & FLG_SG_P_VADDR) == 0) &&
		    ((ofl->ofl_dtflags_1 & DF_1_NOHDR) == 0)) {
			if (phdr->p_align != 0)
				vaddr += phdr->p_offset % phdr->p_align;
			else
				vaddr += phdr->p_offset;
			phdr->p_vaddr = vaddr;
		}

		/*
		 * If an interpreter is required set the virtual address of the
		 * PT_PHDR program header now that we know the virtual address
		 * of the loadable segment that contains it.  Update the
		 * PT_SUNWCAP header similarly.
		 */
		if ((_phdr == NULL) && (phdr->p_type == PT_LOAD)) {
			_phdr = phdr;

			if ((ofl->ofl_dtflags_1 & DF_1_NOHDR) == 0) {
				if (ofl->ofl_osinterp)
					ofl->ofl_phdr[0].p_vaddr =
					    vaddr + ehdrsz;

				/*
				 * Finally, if we're creating a dynamic object
				 * (or a static object in which an interpreter
				 * is specified) update the vaddr to reflect
				 * the address of the first section within this
				 * segment.
				 */
				if ((ofl->ofl_osinterp) ||
				    (flags & FLG_OF_DYNAMIC))
					vaddr += size;
			} else {
				/*
				 * If the DF_1_NOHDR flag was set, and an
				 * interpreter is being generated, the PT_PHDR
				 * will not be part of any loadable segment.
				 */
				if (ofl->ofl_osinterp) {
					ofl->ofl_phdr[0].p_vaddr = 0;
					ofl->ofl_phdr[0].p_memsz = 0;
					ofl->ofl_phdr[0].p_flags = 0;
				}
			}
		}

		/*
		 * Ensure the ELF entry point defaults to zero.  Typically, this
		 * value is overridden in update_oehdr() to one of the standard
		 * entry points.  Historically, this default was set to the
		 * address of first executable section, but this has since been
		 * found to be more confusing than it is helpful.
		 */
		ehdr->e_entry = 0;

		DBG_CALL(Dbg_seg_entry(ofl, segndx, sgp));

		/*
		 * Traverse the output section descriptors for this segment so
		 * that we can update the section headers addresses.  We've
		 * calculated the virtual address of the initial section within
		 * this segment, so each successive section can be calculated
		 * based on their offsets from each other.
		 */
		secndx = 0;
		hshdr = 0;
		for (APLIST_TRAVERSE(sgp->sg_osdescs, idx2, osp)) {
			Shdr	*shdr = osp->os_shdr;

			if (shdr->sh_link)
				shdr->sh_link = translate_link(ofl, osp,
				    shdr->sh_link, MSG_INTL(MSG_FIL_INVSHLINK));

			if (shdr->sh_info && (shdr->sh_flags & SHF_INFO_LINK))
				shdr->sh_info = translate_link(ofl, osp,
				    shdr->sh_info, MSG_INTL(MSG_FIL_INVSHINFO));

			if (!(flags & FLG_OF_RELOBJ) &&
			    (phdr->p_type == PT_LOAD)) {
				if (hshdr)
					vaddr += (shdr->sh_offset -
					    hshdr->sh_offset);

				shdr->sh_addr = vaddr;
				hshdr = shdr;
			}

			DBG_CALL(Dbg_seg_os(ofl, osp, secndx));
			secndx++;
		}

		/*
		 * Establish the virtual address of the end of the last section
		 * in this segment so that the next segments offset can be
		 * calculated from this.
		 */
		if (hshdr)
			vaddr += hshdr->sh_size;

		/*
		 * Output sections for this segment complete.  Adjust the
		 * virtual offset for the last sections size, and make sure we
		 * haven't exceeded any maximum segment length specification.
		 */
		if ((sgp->sg_length != 0) && (sgp->sg_length < phdr->p_memsz)) {
			eprintf(ofl->ofl_lml, ERR_FATAL,
			    MSG_INTL(MSG_UPD_LARGSIZE), ofl->ofl_name,
			    sgp->sg_name, EC_XWORD(phdr->p_memsz),
			    EC_XWORD(sgp->sg_length));
			return (S_ERROR);
		}

		if (phdr->p_type == PT_NOTE) {
			phdr->p_vaddr = 0;
			phdr->p_paddr = 0;
			phdr->p_align = 0;
			phdr->p_memsz = 0;
		}

		if ((phdr->p_type != PT_NULL) && !(flags & FLG_OF_RELOBJ))
			ofl->ofl_phdr[phdrndx++] = *phdr;
	}

	/*
	 * Update any new output sections.  When building the initial output
	 * image, a number of sections were created but left uninitialized (eg.
	 * .dynsym, .dynstr, .symtab, .symtab, etc.).  Here we update these
	 * sections with the appropriate data.  Other sections may still be
	 * modified via reloc_process().
	 *
	 * Copy the interpreter name into the .interp section.
	 */
	if (ofl->ofl_interp)
		(void) strcpy((char *)ofl->ofl_osinterp->os_outdata->d_buf,
		    ofl->ofl_interp);

	/*
	 * Update the .shstrtab, .strtab and .dynstr sections.
	 */
	update_ostrtab(ofl->ofl_osshstrtab, ofl->ofl_shdrsttab, 0);
	update_ostrtab(ofl->ofl_osstrtab, ofl->ofl_strtab, 0);
	update_ostrtab(ofl->ofl_osdynstr, ofl->ofl_dynstrtab, DYNSTR_EXTRA_PAD);

	/*
	 * Build any output symbol tables, the symbols information is copied
	 * and updated into the new output image.
	 */
	if ((etext = update_osym(ofl)) == (Addr)S_ERROR)
		return (S_ERROR);

	/*
	 * If we have an PT_INTERP phdr, update it now from the associated
	 * section information.
	 */
	if (intpsgp) {
		Phdr	*phdr = &(intpsgp->sg_phdr);
		Shdr	*shdr = ofl->ofl_osinterp->os_shdr;

		phdr->p_vaddr = shdr->sh_addr;
		phdr->p_offset = shdr->sh_offset;
		phdr->p_memsz = phdr->p_filesz = shdr->sh_size;
		phdr->p_flags = PF_R;

		DBG_CALL(Dbg_seg_entry(ofl, intpsndx, intpsgp));
		ofl->ofl_phdr[intppndx] = *phdr;
	}

	/*
	 * If we have a PT_SUNWDTRACE phdr, update it now with the address of
	 * the symbol.  It's only now been updated via update_sym().
	 */
	if (dtracesgp) {
		Phdr		*aphdr, *phdr = &(dtracesgp->sg_phdr);
		Sym_desc	*sdp = ofl->ofl_dtracesym;

		phdr->p_vaddr = sdp->sd_sym->st_value;
		phdr->p_memsz = sdp->sd_sym->st_size;

		/*
		 * Take permissions from the segment that the symbol is
		 * associated with.
		 */
		aphdr = &sdp->sd_isc->is_osdesc->os_sgdesc->sg_phdr;
		assert(aphdr);
		phdr->p_flags = aphdr->p_flags;

		DBG_CALL(Dbg_seg_entry(ofl, dtracesndx, dtracesgp));
		ofl->ofl_phdr[dtracepndx] = *phdr;
	}

	/*
	 * If we have a PT_SUNWCAP phdr, update it now from the associated
	 * section information.
	 */
	if (capsgp) {
		Phdr	*phdr = &(capsgp->sg_phdr);
		Shdr	*shdr = ofl->ofl_oscap->os_shdr;

		phdr->p_vaddr = shdr->sh_addr;
		phdr->p_offset = shdr->sh_offset;
		phdr->p_memsz = phdr->p_filesz = shdr->sh_size;
		phdr->p_flags = PF_R;

		DBG_CALL(Dbg_seg_entry(ofl, capsndx, capsgp));
		ofl->ofl_phdr[cappndx] = *phdr;
	}

	/*
	 * Update the GROUP sections.
	 */
	if (update_ogroup(ofl) == S_ERROR)
		return (S_ERROR);

	/*
	 * Update Move Table.
	 */
	if (ofl->ofl_osmove || ofl->ofl_isparexpn)
		update_move(ofl);

	/*
	 * Build any output headers, version information, dynamic structure and
	 * syminfo structure.
	 */
	if (update_oehdr(ofl) == S_ERROR)
		return (S_ERROR);
	if (!(flags & FLG_OF_NOVERSEC)) {
		if ((flags & FLG_OF_VERDEF) &&
		    (update_overdef(ofl) == S_ERROR))
			return (S_ERROR);
		if ((flags & FLG_OF_VERNEED) &&
		    (update_overneed(ofl) == S_ERROR))
			return (S_ERROR);
		if (flags & (FLG_OF_VERNEED | FLG_OF_VERDEF))
			update_oversym(ofl);
	}
	if (flags & FLG_OF_DYNAMIC) {
		if (update_odynamic(ofl) == S_ERROR)
			return (S_ERROR);
	}
	if (ofl->ofl_ossyminfo) {
		if (update_osyminfo(ofl) == S_ERROR)
			return (S_ERROR);
	}

	/*
	 * Update capabilities information if required.
	 */
	if (ofl->ofl_oscap)
		update_oscap(ofl);
	if (ofl->ofl_oscapinfo)
		update_oscapinfo(ofl);

	/*
	 * Sanity test: the first and last data byte of a string table
	 * must be NULL.
	 */
	assert((ofl->ofl_osshstrtab == NULL) ||
	    (*((char *)ofl->ofl_osshstrtab->os_outdata->d_buf) == '\0'));
	assert((ofl->ofl_osshstrtab == NULL) ||
	    (*(((char *)ofl->ofl_osshstrtab->os_outdata->d_buf) +
	    ofl->ofl_osshstrtab->os_outdata->d_size - 1) == '\0'));

	assert((ofl->ofl_osstrtab == NULL) ||
	    (*((char *)ofl->ofl_osstrtab->os_outdata->d_buf) == '\0'));
	assert((ofl->ofl_osstrtab == NULL) ||
	    (*(((char *)ofl->ofl_osstrtab->os_outdata->d_buf) +
	    ofl->ofl_osstrtab->os_outdata->d_size - 1) == '\0'));

	assert((ofl->ofl_osdynstr == NULL) ||
	    (*((char *)ofl->ofl_osdynstr->os_outdata->d_buf) == '\0'));
	assert((ofl->ofl_osdynstr == NULL) ||
	    (*(((char *)ofl->ofl_osdynstr->os_outdata->d_buf) +
	    ofl->ofl_osdynstr->os_outdata->d_size - DYNSTR_EXTRA_PAD - 1) ==
	    '\0'));

	/*
	 * Emit Strtab diagnostics.
	 */
	DBG_CALL(Dbg_sec_strtab(ofl->ofl_lml, ofl->ofl_osshstrtab,
	    ofl->ofl_shdrsttab));
	DBG_CALL(Dbg_sec_strtab(ofl->ofl_lml, ofl->ofl_osstrtab,
	    ofl->ofl_strtab));
	DBG_CALL(Dbg_sec_strtab(ofl->ofl_lml, ofl->ofl_osdynstr,
	    ofl->ofl_dynstrtab));

	/*
	 * Initialize the section headers string table index within the elf
	 * header.
	 */
	/* LINTED */
	if ((shscnndx = elf_ndxscn(ofl->ofl_osshstrtab->os_scn)) <
	    SHN_LORESERVE) {
		ofl->ofl_nehdr->e_shstrndx =
		    /* LINTED */
		    (Half)shscnndx;
	} else {
		/*
		 * If the STRTAB section index doesn't fit into
		 * e_shstrndx, then we store it in 'shdr[0].st_link'.
		 */
		Elf_Scn	*scn;
		Shdr	*shdr0;

		if ((scn = elf_getscn(ofl->ofl_elf, 0)) == NULL) {
			eprintf(ofl->ofl_lml, ERR_ELF,
			    MSG_INTL(MSG_ELF_GETSCN), ofl->ofl_name);
			return (S_ERROR);
		}
		if ((shdr0 = elf_getshdr(scn)) == NULL) {
			eprintf(ofl->ofl_lml, ERR_ELF,
			    MSG_INTL(MSG_ELF_GETSHDR), ofl->ofl_name);
			return (S_ERROR);
		}
		ofl->ofl_nehdr->e_shstrndx = SHN_XINDEX;
		shdr0->sh_link = shscnndx;
	}

	return ((uintptr_t)etext);
}