/* * 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 2010 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* Get the sparc version of the relocation engine */ #define DO_RELOC_LIBLD_SPARC #include #include #include #include #include #include #include "msg.h" #include "_libld.h" #include "machsym.sparc.h" /* * Local Variable Definitions */ static Sword neggotoffset = 0; /* off. of GOT table from GOT symbol */ static Sword smlgotcnt = M_GOT_XNumber; /* no. of small GOT symbols */ static Sword mixgotcnt = 0; /* # syms with both large/small GOT */ /* * Search the GOT index list for a GOT entry with a matching reference and the * proper addend. */ static Gotndx * ld_find_got_ndx(Alist *alp, Gotref gref, Ofl_desc *ofl, Rel_desc *rdesc) { Aliste idx; Gotndx *gnp; assert(rdesc != 0); if ((gref == GOT_REF_TLSLD) && ofl->ofl_tlsldgotndx) return (ofl->ofl_tlsldgotndx); for (ALIST_TRAVERSE(alp, idx, gnp)) { if ((rdesc->rel_raddend == gnp->gn_addend) && (gref == gnp->gn_gotref)) return (gnp); } return (NULL); } static Xword ld_calc_got_offset(Rel_desc * rdesc, Ofl_desc * ofl) { Os_desc *osp = ofl->ofl_osgot; Sym_desc *sdp = rdesc->rel_sym; Xword gotndx; Gotref gref; Gotndx *gnp; if (rdesc->rel_flags & FLG_REL_DTLS) gref = GOT_REF_TLSGD; else if (rdesc->rel_flags & FLG_REL_MTLS) gref = GOT_REF_TLSLD; else if (rdesc->rel_flags & FLG_REL_STLS) gref = GOT_REF_TLSIE; else gref = GOT_REF_GENERIC; gnp = ld_find_got_ndx(sdp->sd_GOTndxs, gref, ofl, rdesc); assert(gnp); gotndx = (Xword)gnp->gn_gotndx; if ((rdesc->rel_flags & FLG_REL_DTLS) && (rdesc->rel_rtype == M_R_DTPOFF)) gotndx++; return ((Xword)((osp->os_shdr->sh_addr) + (gotndx * M_GOT_ENTSIZE) + (-neggotoffset * M_GOT_ENTSIZE))); } static Word ld_init_rel(Rel_desc *reld, void *reloc) { Rela *rela = (Rela *)reloc; /* LINTED */ reld->rel_rtype = (Word)ELF_R_TYPE(rela->r_info, M_MACH); reld->rel_roffset = rela->r_offset; reld->rel_raddend = rela->r_addend; reld->rel_typedata = (Word)ELF_R_TYPE_DATA(rela->r_info); reld->rel_flags |= FLG_REL_RELA; return ((Word)ELF_R_SYM(rela->r_info)); } static void ld_mach_eflags(Ehdr *ehdr, Ofl_desc *ofl) { Word eflags = ofl->ofl_dehdr->e_flags; Word memopt1, memopt2; static int firstpass; /* * If a *PLUS relocatable is included, the output object is type *PLUS. */ if ((ehdr->e_machine == EM_SPARC32PLUS) && (ehdr->e_flags & EF_SPARC_32PLUS)) ofl->ofl_dehdr->e_machine = EM_SPARC32PLUS; /* * On the first pass, we don't yet have a memory model to compare * against, therefore the initial file becomes our baseline. Subsequent * passes will do the comparison described below. */ if (firstpass == 0) { ofl->ofl_dehdr->e_flags |= ehdr->e_flags; firstpass++; return; } /* * Determine which memory model to mark the binary with. The options * are (most restrictive to least): * * EF_SPARCV9_TSO 0x0 Total Store Order * EF_SPARCV9_PSO 0x1 Partial Store Order * EF_SPARCV9_RMO 0x2 Relaxed Memory Order * * Mark the binary with the most restrictive option encountered from a * relocatable object included in the link. */ eflags |= (ehdr->e_flags & ~EF_SPARCV9_MM); memopt1 = eflags & EF_SPARCV9_MM; memopt2 = ehdr->e_flags & EF_SPARCV9_MM; eflags &= ~EF_SPARCV9_MM; if ((memopt1 == EF_SPARCV9_TSO) || (memopt2 == EF_SPARCV9_TSO)) /* EMPTY */ ; else if ((memopt1 == EF_SPARCV9_PSO) || (memopt2 == EF_SPARCV9_PSO)) eflags |= EF_SPARCV9_PSO; else eflags |= EF_SPARCV9_RMO; ofl->ofl_dehdr->e_flags = eflags; } static void ld_mach_make_dynamic(Ofl_desc *ofl, size_t *cnt) { if (!(ofl->ofl_flags & FLG_OF_RELOBJ)) { /* * Create this entry if we are going to create a PLT table. */ if (ofl->ofl_pltcnt) (*cnt)++; /* DT_PLTGOT */ } } static void ld_mach_update_odynamic(Ofl_desc *ofl, Dyn **dyn) { if (((ofl->ofl_flags & FLG_OF_RELOBJ) == 0) && ofl->ofl_pltcnt) { (*dyn)->d_tag = DT_PLTGOT; if (ofl->ofl_osplt) (*dyn)->d_un.d_ptr = ofl->ofl_osplt->os_shdr->sh_addr; else (*dyn)->d_un.d_ptr = 0; (*dyn)++; } } #if defined(_ELF64) static Xword ld_calc_plt_addr(Sym_desc *sdp, Ofl_desc *ofl) { Xword value, pltndx, farpltndx; pltndx = sdp->sd_aux->sa_PLTndx + M_PLT_XNumber - 1; if ((pltndx) < M64_PLT_NEARPLTS) { value = (Xword)(ofl->ofl_osplt->os_shdr->sh_addr) + (pltndx * M_PLT_ENTSIZE); return (value); } farpltndx = pltndx - M64_PLT_NEARPLTS; /* * pltoffset of a far plt is calculated by: * * + * + * */ value = /* size of near plt table */ (M64_PLT_NEARPLTS * M_PLT_ENTSIZE) + /* size of preceding far plt blocks */ ((farpltndx / M64_PLT_FBLKCNTS) * ((M64_PLT_FENTSIZE + sizeof (Addr)) * M64_PLT_FBLKCNTS)) + /* pltblockendx * fentsize */ ((farpltndx % M64_PLT_FBLKCNTS) * M64_PLT_FENTSIZE); value += (Xword)(ofl->ofl_osplt->os_shdr->sh_addr); return (value); } /* * Instructions required for Far PLT's */ static uchar_t farplt_instrs[24] = { 0x8a, 0x10, 0x00, 0x0f, /* mov %o7, %g5 */ 0x40, 0x00, 0x00, 0x02, /* call . + 0x8 */ 0x01, 0x00, 0x00, 0x00, /* nop */ 0xc2, 0x5b, 0xe0, 0x00, /* ldx [%o7 + 0], %g1 */ 0x83, 0xc3, 0xc0, 0x01, /* jmpl %o7 + %g1, %g1 */ 0x9e, 0x10, 0x00, 0x05 /* mov %g5, %o7 */ }; /* * Far PLT'S: * * Far PLT's are established in blocks of '160' at a time. These * PLT's consist of 6 instructions (24 bytes) and 1 pointer (8 bytes). * The instructions are collected together in blocks of 160 entries * followed by 160 pointers. The last group of entries and pointers * may contain less then 160 items. No padding is required. * * .PLT32768: * mov %o7, %g5 * call . + 8 * nop * ldx [%o7 + .PLTP32768 - (.PLT32768 + 4)], %g1 * jmpl %o7 + %g1, %g1 * mov %g5, %o7 * ................................ * .PLT32927: * mov %o7, %g5 * call . + 8 * nop * ldx [%o7 + .PLTP32927 - (.PLT32927 + 4)], %g1 * jmpl %o7 + %g1, %g1 * mov %g5, %o7 * .PLTP32768: * .xword .PLT0-(.PLT32768+4) * ................................ * .PLTP32927: * .xword .PLT0-(.PLT32927+4) * */ static void plt_far_entry(Ofl_desc *ofl, Xword pltndx, Xword *roffset, Sxword *raddend) { uint_t blockndx; /* # of far PLT blocks */ uint_t farblkcnt; /* Index to far PLT block */ Xword farpltndx; /* index of Far Plt */ Xword farpltblkndx; /* index of PLT in BLOCK */ uint32_t *pltent; /* ptr to plt instr. sequence */ uint64_t *pltentptr; /* ptr to plt addr ptr */ Sxword pltblockoff; /* offset to Far plt block */ Sxword pltoff; /* offset to PLT instr. sequence */ Sxword pltptroff; /* offset to PLT addr ptr */ uchar_t *pltbuf; /* ptr to PLT's in file */ farblkcnt = ((ofl->ofl_pltcnt - 1 + M_PLT_XNumber - M64_PLT_NEARPLTS) / M64_PLT_FBLKCNTS); /* * Determine the 'Far' PLT index. */ farpltndx = pltndx - 1 + M_PLT_XNumber - M64_PLT_NEARPLTS; farpltblkndx = farpltndx % M64_PLT_FBLKCNTS; /* * Determine what FPLT block this plt falls into. */ blockndx = (uint_t)(farpltndx / M64_PLT_FBLKCNTS); /* * Calculate the starting offset of the Far PLT block * that this PLT is a member of. */ pltblockoff = (M64_PLT_NEARPLTS * M_PLT_ENTSIZE) + (blockndx * M64_PLT_FBLOCKSZ); pltoff = pltblockoff + (farpltblkndx * M64_PLT_FENTSIZE); pltptroff = pltblockoff; if (farblkcnt > blockndx) { /* * If this is a full block - the 'pltptroffs' start * after 160 fplts. */ pltptroff += (M64_PLT_FBLKCNTS * M64_PLT_FENTSIZE) + (farpltblkndx * M64_PLT_PSIZE); } else { Xword lastblkpltndx; /* * If this is the last block - the the pltptr's start * after the last FPLT instruction sequence. */ lastblkpltndx = (ofl->ofl_pltcnt - 1 + M_PLT_XNumber - M64_PLT_NEARPLTS) % M64_PLT_FBLKCNTS; pltptroff += ((lastblkpltndx + 1) * M64_PLT_FENTSIZE) + (farpltblkndx * M64_PLT_PSIZE); } pltbuf = (uchar_t *)ofl->ofl_osplt->os_outdata->d_buf; /* * For far-plts, the Raddend and Roffset fields are defined * to be: * * roffset: address of .PLTP# * raddend: -(.PLT#+4) */ *roffset = pltptroff + (Xword)(ofl->ofl_osplt->os_shdr->sh_addr); *raddend = -(pltoff + 4 + (Xword)(ofl->ofl_osplt->os_shdr->sh_addr)); /* LINTED */ pltent = (uint32_t *)(pltbuf + pltoff); /* LINTED */ pltentptr = (uint64_t *)(pltbuf + pltptroff); (void) memcpy(pltent, farplt_instrs, sizeof (farplt_instrs)); /* * update * ldx [%o7 + 0], %g1 * to * ldx [%o7 + .PLTP# - (.PLT# + 4)], %g1 */ /* LINTED */ pltent[3] |= (uint32_t)(pltptroff - (pltoff + 4)); /* * Store: * .PLTP# * .xword .PLT0 - .PLT# + 4 */ *pltentptr = -(pltoff + 4); } /* * Build a single V9 P.L.T. entry - code is: * * For Target Addresses +/- 4GB of the entry * ----------------------------------------- * sethi (. - .PLT0), %g1 * ba,a %xcc, .PLT1 * nop * nop * nop * nop * nop * nop * * For Target Addresses +/- 2GB of the entry * ----------------------------------------- * * .PLT0 is the address of the first entry in the P.L.T. * This one is filled in by the run-time link editor. We just * have to leave space for it. */ static void plt_entry(Ofl_desc *ofl, Xword pltndx, Xword *roffset, Sxword *raddend) { uchar_t *pltent; /* PLT entry being created. */ Sxword pltoff; /* Offset of this entry from PLT top */ int bswap = (ofl->ofl_flags1 & FLG_OF1_ENCDIFF) != 0; /* * The second part of the V9 ABI (sec. 5.2.4) * applies to plt entries greater than 0x8000 (32,768). * This is handled in 'plt_far_entry()' */ if ((pltndx - 1 + M_PLT_XNumber) >= M64_PLT_NEARPLTS) { plt_far_entry(ofl, pltndx, roffset, raddend); return; } pltoff = M_PLT_RESERVSZ + (pltndx - 1) * M_PLT_ENTSIZE; pltent = (uchar_t *)ofl->ofl_osplt->os_outdata->d_buf + pltoff; *roffset = pltoff + (Xword)(ofl->ofl_osplt->os_shdr->sh_addr); *raddend = 0; /* * PLT[0]: sethi %hi(. - .L0), %g1 */ /* LINTED */ *(Word *)pltent = M_SETHIG1 | pltoff; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[1]: ba,a %xcc, .PLT1 (.PLT1 accessed as a * PC-relative index of longwords). */ pltent += M_PLT_INSSIZE; pltoff += M_PLT_INSSIZE; pltoff = -pltoff; /* LINTED */ *(Word *)pltent = M_BA_A_XCC | (((pltoff + M_PLT_ENTSIZE) >> 2) & S_MASK(19)); if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[2]: sethi 0, %g0 (NOP for delay slot of eventual CTI). */ pltent += M_PLT_INSSIZE; /* LINTED */ *(Word *)pltent = M_NOP; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[3]: sethi 0, %g0 (NOP for PLT padding). */ pltent += M_PLT_INSSIZE; /* LINTED */ *(Word *)pltent = M_NOP; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[4]: sethi 0, %g0 (NOP for PLT padding). */ pltent += M_PLT_INSSIZE; /* LINTED */ *(Word *)pltent = M_NOP; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[5]: sethi 0, %g0 (NOP for PLT padding). */ pltent += M_PLT_INSSIZE; /* LINTED */ *(Word *)pltent = M_NOP; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[6]: sethi 0, %g0 (NOP for PLT padding). */ pltent += M_PLT_INSSIZE; /* LINTED */ *(Word *)pltent = M_NOP; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[7]: sethi 0, %g0 (NOP for PLT padding). */ pltent += M_PLT_INSSIZE; /* LINTED */ *(Word *)pltent = M_NOP; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); } #else /* Elf 32 */ static Xword ld_calc_plt_addr(Sym_desc *sdp, Ofl_desc *ofl) { Xword value, pltndx; pltndx = sdp->sd_aux->sa_PLTndx + M_PLT_XNumber - 1; value = (Xword)(ofl->ofl_osplt->os_shdr->sh_addr) + (pltndx * M_PLT_ENTSIZE); return (value); } /* * Build a single P.L.T. entry - code is: * * sethi (. - .L0), %g1 * ba,a .L0 * sethi 0, %g0 (nop) * * .L0 is the address of the first entry in the P.L.T. * This one is filled in by the run-time link editor. We just * have to leave space for it. */ static void plt_entry(Ofl_desc * ofl, Xword pltndx, Xword *roffset, Sxword *raddend) { Byte *pltent; /* PLT entry being created. */ Sxword pltoff; /* Offset of this entry from PLT top */ int bswap = (ofl->ofl_flags1 & FLG_OF1_ENCDIFF) != 0; pltoff = M_PLT_RESERVSZ + (pltndx - 1) * M_PLT_ENTSIZE; pltent = (Byte *)ofl->ofl_osplt->os_outdata->d_buf + pltoff; *roffset = pltoff + (Xword)(ofl->ofl_osplt->os_shdr->sh_addr); *raddend = 0; /* * PLT[0]: sethi %hi(. - .L0), %g1 */ /* LINTED */ *(Word *)pltent = M_SETHIG1 | pltoff; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[1]: ba,a .L0 (.L0 accessed as a PC-relative index of longwords) */ pltent += M_PLT_INSSIZE; pltoff += M_PLT_INSSIZE; pltoff = -pltoff; /* LINTED */ *(Word *)pltent = M_BA_A | ((pltoff >> 2) & S_MASK(22)); if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[2]: sethi 0, %g0 (NOP for delay slot of eventual CTI). */ pltent += M_PLT_INSSIZE; /* LINTED */ *(Word *)pltent = M_SETHIG0; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); /* * PLT[3]: sethi 0, %g0 (NOP for PLT padding). */ pltent += M_PLT_INSSIZE; /* LINTED */ *(Word *)pltent = M_SETHIG0; if (bswap) /* LINTED */ *(Word *)pltent = ld_bswap_Word(*(Word *)pltent); } #endif /* _ELF64 */ static uintptr_t ld_perform_outreloc(Rel_desc *orsp, Ofl_desc *ofl) { Os_desc *relosp, *osp = NULL; Xword ndx, roffset, value; Sxword raddend; const Rel_entry *rep; Rela rea; char *relbits; Sym_desc *sdp, *psym = NULL; int sectmoved = 0; Word dtflags1 = ofl->ofl_dtflags_1; ofl_flag_t flags = ofl->ofl_flags; raddend = orsp->rel_raddend; sdp = orsp->rel_sym; /* * Special case, a regsiter symbol associated with symbol * index 0 is initialized (i.e. relocated) to a constant * in the r_addend field rather than to a symbol value. */ if ((orsp->rel_rtype == M_R_REGISTER) && !sdp) { relosp = ofl->ofl_osrel; relbits = (char *)relosp->os_outdata->d_buf; rea.r_info = ELF_R_INFO(0, ELF_R_TYPE_INFO(orsp->rel_typedata, orsp->rel_rtype)); rea.r_offset = orsp->rel_roffset; rea.r_addend = raddend; DBG_CALL(Dbg_reloc_out(ofl, ELF_DBG_LD, SHT_RELA, &rea, relosp->os_name, orsp->rel_sname)); assert(relosp->os_szoutrels <= relosp->os_shdr->sh_size); (void) memcpy((relbits + relosp->os_szoutrels), (char *)&rea, sizeof (Rela)); relosp->os_szoutrels += (Xword)sizeof (Rela); return (1); } /* * If the section this relocation is against has been discarded * (-zignore), then also discard (skip) the relocation itself. */ if (orsp->rel_isdesc && ((orsp->rel_flags & (FLG_REL_GOT | FLG_REL_BSS | FLG_REL_PLT | FLG_REL_NOINFO)) == 0) && (orsp->rel_isdesc->is_flags & FLG_IS_DISCARD)) { DBG_CALL(Dbg_reloc_discard(ofl->ofl_lml, M_MACH, orsp)); return (1); } /* * If this is a relocation against a move table, or expanded move * table, adjust the relocation entries. */ if (orsp->rel_move) ld_adj_movereloc(ofl, orsp); /* * If this is a relocation against a section then we need to adjust the * raddend field to compensate for the new position of the input section * within the new output section. */ if (ELF_ST_TYPE(sdp->sd_sym->st_info) == STT_SECTION) { if (ofl->ofl_parsyms && (sdp->sd_isc->is_flags & FLG_IS_RELUPD) && (psym = ld_am_I_partial(orsp, orsp->rel_raddend))) { /* * If the symbol is moved, adjust the value */ DBG_CALL(Dbg_move_outsctadj(ofl->ofl_lml, psym)); sectmoved = 1; if (ofl->ofl_flags & FLG_OF_RELOBJ) raddend = psym->sd_sym->st_value; else raddend = psym->sd_sym->st_value - psym->sd_isc->is_osdesc->os_shdr->sh_addr; /* LINTED */ raddend += (Off)_elf_getxoff(psym->sd_isc->is_indata); if (psym->sd_isc->is_shdr->sh_flags & SHF_ALLOC) raddend += psym->sd_isc->is_osdesc->os_shdr->sh_addr; } else { /* LINTED */ raddend += (Off)_elf_getxoff(sdp->sd_isc->is_indata); if (sdp->sd_isc->is_shdr->sh_flags & SHF_ALLOC) raddend += sdp->sd_isc->is_osdesc->os_shdr->sh_addr; } } value = sdp->sd_sym->st_value; if (orsp->rel_flags & FLG_REL_GOT) { osp = ofl->ofl_osgot; roffset = ld_calc_got_offset(orsp, ofl); } else if (orsp->rel_flags & FLG_REL_PLT) { osp = ofl->ofl_osplt; plt_entry(ofl, sdp->sd_aux->sa_PLTndx, &roffset, &raddend); } else if (orsp->rel_flags & FLG_REL_BSS) { /* * This must be a R_SPARC_COPY. For these set the roffset to * point to the new symbols location. */ osp = ofl->ofl_isbss->is_osdesc; roffset = (Xword)value; /* * The raddend doesn't mean anything in an R_SPARC_COPY * relocation. Null it out because it can confuse people. */ raddend = 0; } else if (orsp->rel_flags & FLG_REL_REG) { /* * The offsets of relocations against register symbols * identifiy the register directly - so the offset * does not need to be adjusted. */ roffset = orsp->rel_roffset; } else { osp = orsp->rel_osdesc; /* * Calculate virtual offset of reference point; equals offset * into section + vaddr of section for loadable sections, or * offset plus section displacement for nonloadable sections. */ roffset = orsp->rel_roffset + (Off)_elf_getxoff(orsp->rel_isdesc->is_indata); if (!(ofl->ofl_flags & FLG_OF_RELOBJ)) roffset += orsp->rel_isdesc->is_osdesc-> os_shdr->sh_addr; } if ((osp == 0) || ((relosp = osp->os_relosdesc) == 0)) relosp = ofl->ofl_osrel; /* * Verify that the output relocations offset meets the * alignment requirements of the relocation being processed. */ rep = &reloc_table[orsp->rel_rtype]; if (((flags & FLG_OF_RELOBJ) || !(dtflags1 & DF_1_NORELOC)) && !(rep->re_flags & FLG_RE_UNALIGN)) { if (((rep->re_fsize == 2) && (roffset & 0x1)) || ((rep->re_fsize == 4) && (roffset & 0x3)) || ((rep->re_fsize == 8) && (roffset & 0x7))) { Conv_inv_buf_t inv_buf; eprintf(ofl->ofl_lml, ERR_FATAL, MSG_INTL(MSG_REL_NONALIGN), conv_reloc_SPARC_type(orsp->rel_rtype, 0, &inv_buf), orsp->rel_isdesc->is_file->ifl_name, demangle(orsp->rel_sname), EC_XWORD(roffset)); return (S_ERROR); } } /* * Assign the symbols index for the output relocation. If the * relocation refers to a SECTION symbol then it's index is based upon * the output sections symbols index. Otherwise the index can be * derived from the symbols index itself. */ if (orsp->rel_rtype == R_SPARC_RELATIVE) ndx = STN_UNDEF; else if ((orsp->rel_flags & FLG_REL_SCNNDX) || (ELF_ST_TYPE(sdp->sd_sym->st_info) == STT_SECTION)) { if (sectmoved == 0) { /* * Check for a null input section. This can * occur if this relocation references a symbol * generated by sym_add_sym(). */ if (sdp->sd_isc && sdp->sd_isc->is_osdesc) ndx = sdp->sd_isc->is_osdesc->os_identndx; else ndx = sdp->sd_shndx; } else ndx = ofl->ofl_parexpnndx; } else ndx = sdp->sd_symndx; /* * Add the symbols 'value' to the addend field. */ if (orsp->rel_flags & FLG_REL_ADVAL) raddend += value; /* * The addend field for R_SPARC_TLS_DTPMOD32 and R_SPARC_TLS_DTPMOD64 * mean nothing. The addend is propagated in the corresponding * R_SPARC_TLS_DTPOFF* relocations. */ if (orsp->rel_rtype == M_R_DTPMOD) raddend = 0; relbits = (char *)relosp->os_outdata->d_buf; rea.r_info = ELF_R_INFO(ndx, ELF_R_TYPE_INFO(orsp->rel_typedata, orsp->rel_rtype)); rea.r_offset = roffset; rea.r_addend = raddend; DBG_CALL(Dbg_reloc_out(ofl, ELF_DBG_LD, SHT_RELA, &rea, relosp->os_name, orsp->rel_sname)); /* * Assert we haven't walked off the end of our relocation table. */ assert(relosp->os_szoutrels <= relosp->os_shdr->sh_size); (void) memcpy((relbits + relosp->os_szoutrels), (char *)&rea, sizeof (Rela)); relosp->os_szoutrels += (Xword)sizeof (Rela); /* * Determine if this relocation is against a non-writable, allocatable * section. If so we may need to provide a text relocation diagnostic. */ ld_reloc_remain_entry(orsp, osp, ofl); return (1); } /* * Sparc Instructions for TLS processing */ #if defined(_ELF64) #define TLS_GD_IE_LD 0xd0580000 /* ldx [%g0 + %g0], %o0 */ #else #define TLS_GD_IE_LD 0xd0000000 /* ld [%g0 + %g0], %o0 */ #endif #define TLS_GD_IE_ADD 0x9001c008 /* add %g7, %o0, %o0 */ #define TLS_GD_LE_XOR 0x80182000 /* xor %g0, 0, %g0 */ #define TLS_IE_LE_OR 0x80100000 /* or %g0, %o0, %o1 */ /* synthetic: mov %g0, %g0 */ #define TLS_LD_LE_CLRO0 0x90100000 /* clr %o0 */ #define FM3_REG_MSK_RD (0x1f << 25) /* Formate (3) rd register mask */ /* bits 25->29 */ #define FM3_REG_MSK_RS1 (0x1f << 14) /* Formate (3) rs1 register mask */ /* bits 14->18 */ #define FM3_REG_MSK_RS2 0x1f /* Formate (3) rs2 register mask */ /* bits 0->4 */ #define REG_G7 7 /* %g7 register */ static Fixupret tls_fixups(Ofl_desc *ofl, Rel_desc *arsp) { Sym_desc *sdp = arsp->rel_sym; Word rtype = arsp->rel_rtype; Word *offset, w; int bswap = OFL_SWAP_RELOC_DATA(ofl, arsp); offset = (Word *)((uintptr_t)arsp->rel_roffset + (uintptr_t)_elf_getxoff(arsp->rel_isdesc->is_indata) + (uintptr_t)arsp->rel_osdesc->os_outdata->d_buf); if (sdp->sd_ref == REF_DYN_NEED) { /* * IE reference model */ switch (rtype) { case R_SPARC_TLS_GD_HI22: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_TLS_IE_HI22, arsp)); arsp->rel_rtype = R_SPARC_TLS_IE_HI22; return (FIX_RELOC); case R_SPARC_TLS_GD_LO10: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_TLS_IE_LO10, arsp)); arsp->rel_rtype = R_SPARC_TLS_IE_LO10; return (FIX_RELOC); case R_SPARC_TLS_GD_ADD: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_NONE, arsp)); w = bswap ? ld_bswap_Word(*offset) : *offset; w = (TLS_GD_IE_LD | (w & (FM3_REG_MSK_RS1 | FM3_REG_MSK_RS2))); *offset = bswap ? ld_bswap_Word(w) : w; return (FIX_DONE); case R_SPARC_TLS_GD_CALL: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_NONE, arsp)); *offset = TLS_GD_IE_ADD; if (bswap) *offset = ld_bswap_Word(*offset); return (FIX_DONE); } return (FIX_RELOC); } /* * LE reference model */ switch (rtype) { case R_SPARC_TLS_IE_HI22: case R_SPARC_TLS_GD_HI22: case R_SPARC_TLS_LDO_HIX22: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_TLS_LE_HIX22, arsp)); arsp->rel_rtype = R_SPARC_TLS_LE_HIX22; return (FIX_RELOC); case R_SPARC_TLS_LDO_LOX10: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_TLS_LE_LOX10, arsp)); arsp->rel_rtype = R_SPARC_TLS_LE_LOX10; return (FIX_RELOC); case R_SPARC_TLS_IE_LO10: case R_SPARC_TLS_GD_LO10: /* * Current instruction is: * * or r1, %lo(x), r2 * or * add r1, %lo(x), r2 * * Need to udpate this to: * * xor r1, %lox(x), r2 */ DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_TLS_LE_LOX10, arsp)); w = bswap ? ld_bswap_Word(*offset) : *offset; w = TLS_GD_LE_XOR | (w & (FM3_REG_MSK_RS1 | FM3_REG_MSK_RD)); *offset = bswap ? ld_bswap_Word(w) : w; arsp->rel_rtype = R_SPARC_TLS_LE_LOX10; return (FIX_RELOC); case R_SPARC_TLS_IE_LD: case R_SPARC_TLS_IE_LDX: /* * Current instruction: * ld{x} [r1 + r2], r3 * * Need to update this to: * * mov r2, r3 (or %g0, r2, r3) */ DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_NONE, arsp)); w = bswap ? ld_bswap_Word(*offset) : *offset; w = (w & (FM3_REG_MSK_RS2 | FM3_REG_MSK_RD)) | TLS_IE_LE_OR; *offset = bswap ? ld_bswap_Word(w) : w; return (FIX_DONE); case R_SPARC_TLS_LDO_ADD: case R_SPARC_TLS_GD_ADD: /* * Current instruction is: * * add gptr_reg, r2, r3 * * Need to updated this to: * * add %g7, r2, r3 */ DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_NONE, arsp)); w = bswap ? ld_bswap_Word(*offset) : *offset; w = w & (~FM3_REG_MSK_RS1); w = w | (REG_G7 << 14); *offset = bswap ? ld_bswap_Word(w) : w; return (FIX_DONE); case R_SPARC_TLS_LDM_CALL: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_NONE, arsp)); *offset = TLS_LD_LE_CLRO0; if (bswap) *offset = ld_bswap_Word(*offset); return (FIX_DONE); case R_SPARC_TLS_LDM_HI22: case R_SPARC_TLS_LDM_LO10: case R_SPARC_TLS_LDM_ADD: case R_SPARC_TLS_IE_ADD: case R_SPARC_TLS_GD_CALL: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_NONE, arsp)); *offset = M_NOP; if (bswap) *offset = ld_bswap_Word(*offset); return (FIX_DONE); } return (FIX_RELOC); } #define GOTOP_ADDINST 0x80000000 /* add %g0, %g0, %g0 */ static Fixupret gotop_fixups(Ofl_desc *ofl, Rel_desc *arsp) { Word rtype = arsp->rel_rtype; Word *offset, w; const char *ifl_name; Conv_inv_buf_t inv_buf; int bswap; switch (rtype) { case R_SPARC_GOTDATA_OP_HIX22: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_GOTDATA_HIX22, arsp)); arsp->rel_rtype = R_SPARC_GOTDATA_HIX22; return (FIX_RELOC); case R_SPARC_GOTDATA_OP_LOX10: DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_GOTDATA_LOX10, arsp)); arsp->rel_rtype = R_SPARC_GOTDATA_LOX10; return (FIX_RELOC); case R_SPARC_GOTDATA_OP: /* * Current instruction: * ld{x} [r1 + r2], r3 * * Need to update this to: * * add r1, r2, r3 */ DBG_CALL(Dbg_reloc_transition(ofl->ofl_lml, M_MACH, R_SPARC_NONE, arsp)); offset = (Word *)(uintptr_t)(arsp->rel_roffset + _elf_getxoff(arsp->rel_isdesc->is_indata) + (uintptr_t)arsp->rel_osdesc->os_outdata->d_buf); bswap = OFL_SWAP_RELOC_DATA(ofl, arsp); w = bswap ? ld_bswap_Word(*offset) : *offset; w = (w & (FM3_REG_MSK_RS1 | FM3_REG_MSK_RS2 | FM3_REG_MSK_RD)) | GOTOP_ADDINST; *offset = bswap ? ld_bswap_Word(w) : w; return (FIX_DONE); } /* * We should not get here */ if (arsp->rel_isdesc->is_file) ifl_name = arsp->rel_isdesc->is_file->ifl_name; else ifl_name = MSG_INTL(MSG_STR_NULL); eprintf(ofl->ofl_lml, ERR_FATAL, MSG_INTL(MSG_REL_BADGOTFIX), conv_reloc_SPARC_type(arsp->rel_rtype, 0, &inv_buf), ifl_name, demangle(arsp->rel_sname)); assert(0); return (FIX_ERROR); } static uintptr_t ld_do_activerelocs(Ofl_desc *ofl) { Rel_desc *arsp; Rel_cache *rcp; Aliste idx; uintptr_t return_code = 1; ofl_flag_t flags = ofl->ofl_flags; if (ofl->ofl_actrels) DBG_CALL(Dbg_reloc_doact_title(ofl->ofl_lml)); /* * Process active relocations. */ for (APLIST_TRAVERSE(ofl->ofl_actrels, idx, rcp)) { /* LINTED */ for (arsp = (Rel_desc *)(rcp + 1); arsp < rcp->rc_free; arsp++) { uchar_t *addr; Xword value; Sym_desc *sdp; const char *ifl_name; Xword refaddr; /* * If the section this relocation is against has been * discarded (-zignore), then discard (skip) the * relocation itself. */ if ((arsp->rel_isdesc->is_flags & FLG_IS_DISCARD) && ((arsp->rel_flags & (FLG_REL_GOT | FLG_REL_BSS | FLG_REL_PLT | FLG_REL_NOINFO)) == 0)) { DBG_CALL(Dbg_reloc_discard(ofl->ofl_lml, M_MACH, arsp)); continue; } /* * Perform any required TLS fixups. */ if (arsp->rel_flags & FLG_REL_TLSFIX) { Fixupret ret; if ((ret = tls_fixups(ofl, arsp)) == FIX_ERROR) return (S_ERROR); if (ret == FIX_DONE) continue; } /* * Perform any required GOTOP fixups. */ if (arsp->rel_flags & FLG_REL_GOTFIX) { Fixupret ret; if ((ret = gotop_fixups(ofl, arsp)) == FIX_ERROR) return (S_ERROR); if (ret == FIX_DONE) continue; } /* * If this is a relocation against the move table, or * expanded move table, adjust the relocation entries. */ if (arsp->rel_move) ld_adj_movereloc(ofl, arsp); sdp = arsp->rel_sym; refaddr = arsp->rel_roffset + (Off)_elf_getxoff(arsp->rel_isdesc->is_indata); if ((arsp->rel_flags & FLG_REL_CLVAL) || (arsp->rel_flags & FLG_REL_GOTCL)) value = 0; else if (ELF_ST_TYPE(sdp->sd_sym->st_info) == STT_SECTION) { Sym_desc *sym; /* * The value for a symbol pointing to a SECTION * is based off of that sections position. */ if ((sdp->sd_isc->is_flags & FLG_IS_RELUPD) && (sym = ld_am_I_partial(arsp, arsp->rel_raddend))) { /* * The symbol was moved, so adjust * the value relative to the new * section. */ value = _elf_getxoff( sym->sd_isc->is_indata); if (sym->sd_isc->is_shdr->sh_flags & SHF_ALLOC) value += sym->sd_isc-> is_osdesc->os_shdr->sh_addr; /* * The original raddend covers the * displacement from the section start * to the desired address. The value * computed above gets us from the * section start to the start of the * symbol range. Adjust the old raddend * to remove the offset from section * start to symbol start, leaving the * displacement within the range of * the symbol. */ arsp->rel_raddend -= sym->sd_osym->st_value; } else { value = _elf_getxoff( sdp->sd_isc->is_indata); if (sdp->sd_isc->is_shdr->sh_flags & SHF_ALLOC) value += sdp->sd_isc-> is_osdesc->os_shdr->sh_addr; } if (sdp->sd_isc->is_shdr->sh_flags & SHF_TLS) value -= ofl->ofl_tlsphdr->p_vaddr; } else if (IS_SIZE(arsp->rel_rtype)) { /* * Size relocations require the symbols size. */ value = sdp->sd_sym->st_size; } else { /* * Else the value is the symbols value. */ value = sdp->sd_sym->st_value; } /* * Relocation against the GLOBAL_OFFSET_TABLE. */ if (arsp->rel_flags & FLG_REL_GOT) arsp->rel_osdesc = ofl->ofl_osgot; /* * If loadable and not producing a relocatable object * add the sections virtual address to the reference * address. */ if ((arsp->rel_flags & FLG_REL_LOAD) && ((flags & FLG_OF_RELOBJ) == 0)) refaddr += arsp->rel_isdesc->is_osdesc-> os_shdr->sh_addr; /* * If this entry has a PLT assigned to it, it's * value is actually the address of the PLT (and * not the address of the function). */ if (IS_PLT(arsp->rel_rtype)) { if (sdp->sd_aux && sdp->sd_aux->sa_PLTndx) value = ld_calc_plt_addr(sdp, ofl); } /* * Add relocations addend to value. Add extra * relocation addend if needed. */ value += arsp->rel_raddend; if (IS_EXTOFFSET(arsp->rel_rtype)) value += arsp->rel_typedata; /* * Determine whether the value needs further adjustment. * Filter through the attributes of the relocation to * determine what adjustment is required. Note, many * of the following cases are only applicable when a * .got is present. As a .got is not generated when a * relocatable object is being built, any adjustments * that require a .got need to be skipped. */ if ((arsp->rel_flags & FLG_REL_GOT) && ((flags & FLG_OF_RELOBJ) == 0)) { Xword R1addr; uintptr_t R2addr; Sword gotndx; Gotndx *gnp; Gotref gref; /* * Clear the GOT table entry, on SPARC we clear * the entry and the 'value' if needed is stored * in an output relocations addend. * * Calculate offset into GOT at which to apply * the relocation. */ if (arsp->rel_flags & FLG_REL_DTLS) gref = GOT_REF_TLSGD; else if (arsp->rel_flags & FLG_REL_MTLS) gref = GOT_REF_TLSLD; else if (arsp->rel_flags & FLG_REL_STLS) gref = GOT_REF_TLSIE; else gref = GOT_REF_GENERIC; gnp = ld_find_got_ndx(sdp->sd_GOTndxs, gref, ofl, arsp); assert(gnp); if (arsp->rel_rtype == M_R_DTPOFF) gotndx = gnp->gn_gotndx + 1; else gotndx = gnp->gn_gotndx; /* LINTED */ R1addr = (Xword)((-neggotoffset * M_GOT_ENTSIZE) + (gotndx * M_GOT_ENTSIZE)); /* * Add the GOTs data's offset. */ R2addr = R1addr + (uintptr_t) arsp->rel_osdesc->os_outdata->d_buf; DBG_CALL(Dbg_reloc_doact(ofl->ofl_lml, ELF_DBG_LD_ACT, M_MACH, SHT_RELA, arsp->rel_rtype, R1addr, value, arsp->rel_sname, arsp->rel_osdesc)); /* * And do it. */ if (ofl->ofl_flags1 & FLG_OF1_ENCDIFF) *(Xword *)R2addr = ld_bswap_Xword(value); else *(Xword *)R2addr = value; continue; } else if (IS_GOT_BASED(arsp->rel_rtype) && ((flags & FLG_OF_RELOBJ) == 0)) { value -= (ofl->ofl_osgot->os_shdr->sh_addr + (-neggotoffset * M_GOT_ENTSIZE)); } else if (IS_PC_RELATIVE(arsp->rel_rtype)) { value -= refaddr; } else if (IS_TLS_INS(arsp->rel_rtype) && IS_GOT_RELATIVE(arsp->rel_rtype) && ((flags & FLG_OF_RELOBJ) == 0)) { Gotndx *gnp; Gotref gref; if (arsp->rel_flags & FLG_REL_STLS) gref = GOT_REF_TLSIE; else if (arsp->rel_flags & FLG_REL_DTLS) gref = GOT_REF_TLSGD; else if (arsp->rel_flags & FLG_REL_MTLS) gref = GOT_REF_TLSLD; gnp = ld_find_got_ndx(sdp->sd_GOTndxs, gref, ofl, arsp); assert(gnp); value = gnp->gn_gotndx * M_GOT_ENTSIZE; } else if (IS_GOT_RELATIVE(arsp->rel_rtype) && ((flags & FLG_OF_RELOBJ) == 0)) { Gotndx *gnp; gnp = ld_find_got_ndx(sdp->sd_GOTndxs, GOT_REF_GENERIC, ofl, arsp); assert(gnp); value = gnp->gn_gotndx * M_GOT_ENTSIZE; } else if ((arsp->rel_flags & FLG_REL_STLS) && ((flags & FLG_OF_RELOBJ) == 0)) { Xword tlsstatsize; /* * This is the LE TLS * reference model. Static offset * is hard-coded, and negated so that * it can be added to the thread pointer (%g7) */ tlsstatsize = S_ROUND(ofl-> ofl_tlsphdr->p_memsz, M_TLSSTATALIGN); value = -(tlsstatsize - value); } if (arsp->rel_isdesc->is_file) ifl_name = arsp->rel_isdesc->is_file->ifl_name; else ifl_name = MSG_INTL(MSG_STR_NULL); /* * Make sure we have data to relocate. Compiler and * assembler developers have been known to generate * relocations against invalid sections (normally .bss), * so for their benefit give them sufficient information * to help analyze the problem. End users should never * see this. */ if (arsp->rel_isdesc->is_indata->d_buf == 0) { Conv_inv_buf_t inv_buf; eprintf(ofl->ofl_lml, ERR_FATAL, MSG_INTL(MSG_REL_EMPTYSEC), conv_reloc_SPARC_type(arsp->rel_rtype, 0, &inv_buf), ifl_name, demangle(arsp->rel_sname), EC_WORD(arsp->rel_isdesc->is_scnndx), arsp->rel_isdesc->is_name); return (S_ERROR); } /* * Get the address of the data item we need to modify. */ addr = (uchar_t *)((uintptr_t)arsp->rel_roffset + (uintptr_t)_elf_getxoff(arsp->rel_isdesc-> is_indata)); DBG_CALL(Dbg_reloc_doact(ofl->ofl_lml, ELF_DBG_LD_ACT, M_MACH, SHT_RELA, arsp->rel_rtype, EC_NATPTR(addr), value, arsp->rel_sname, arsp->rel_osdesc)); addr += (uintptr_t)arsp->rel_osdesc->os_outdata->d_buf; if ((((uintptr_t)addr - (uintptr_t)ofl->ofl_nehdr) > ofl->ofl_size) || (arsp->rel_roffset > arsp->rel_osdesc->os_shdr->sh_size)) { Conv_inv_buf_t inv_buf; int class; if (((uintptr_t)addr - (uintptr_t)ofl->ofl_nehdr) > ofl->ofl_size) class = ERR_FATAL; else class = ERR_WARNING; eprintf(ofl->ofl_lml, class, MSG_INTL(MSG_REL_INVALOFFSET), conv_reloc_SPARC_type(arsp->rel_rtype, 0, &inv_buf), ifl_name, EC_WORD(arsp->rel_isdesc->is_scnndx), arsp->rel_isdesc->is_name, demangle(arsp->rel_sname), EC_ADDR((uintptr_t)addr - (uintptr_t)ofl->ofl_nehdr)); if (class == ERR_FATAL) { return_code = S_ERROR; continue; } } /* * If '-z noreloc' is specified - skip the do_reloc * stage. */ if (OFL_DO_RELOC(ofl)) { if (do_reloc_ld((uchar_t)arsp->rel_rtype, addr, &value, arsp->rel_sname, ifl_name, OFL_SWAP_RELOC_DATA(ofl, arsp), ofl->ofl_lml) == 0) return_code = S_ERROR; } } } return (return_code); } static uintptr_t ld_add_outrel(Word flags, Rel_desc *rsp, Ofl_desc *ofl) { Rel_desc *orsp; Rel_cache *rcp; Sym_desc *sdp = rsp->rel_sym; static size_t nextsize = 0; Conv_inv_buf_t inv_buf; /* * Static executables *do not* want any relocations against them. * Since our engine still creates relocations against a WEAK UNDEFINED * symbol in a static executable, it's best to disable them here * instead of through out the relocation code. */ if (OFL_IS_STATIC_EXEC(ofl)) return (1); /* * Certain relocations do not make sense in a 64bit shared object, * if building a shared object do a sanity check on the output * relocations being created. */ if (ofl->ofl_flags & FLG_OF_SHAROBJ) { Word rtype = rsp->rel_rtype; /* * Because the R_SPARC_HIPLT22 & R_SPARC_LOPLT10 relocations * are not relative they make no sense to create in a shared * object - so emit the proper error message if that occurs. */ if ((rtype == R_SPARC_HIPLT22) || (rtype == R_SPARC_LOPLT10)) { eprintf(ofl->ofl_lml, ERR_FATAL, MSG_INTL(MSG_REL_UNRELREL), conv_reloc_SPARC_type(rsp->rel_rtype, 0, &inv_buf), rsp->rel_isdesc->is_file->ifl_name, demangle(rsp->rel_sname)); return (S_ERROR); } #if defined(_ELF64) /* * Each of the following relocations requires that the * object being built be loaded in either the upper 32 or * 44 bit range of memory. Since shared libraries traditionally * are loaded in the lower range of memory - this isn't going * to work. */ if ((rtype == R_SPARC_H44) || (rtype == R_SPARC_M44) || (rtype == R_SPARC_L44)) { eprintf(ofl->ofl_lml, ERR_FATAL, MSG_INTL(MSG_REL_SHOBJABS44), conv_reloc_SPARC_type(rsp->rel_rtype, 0, &inv_buf), rsp->rel_isdesc->is_file->ifl_name, demangle(rsp->rel_sname)); return (S_ERROR); } #endif } /* * Obtain the new available relocation cache entry. */ if ((rcp = ld_add_rel_cache(ofl, &ofl->ofl_outrels, &nextsize, REL_LOIDESCNO, REL_HOIDESCNO)) == (Rel_cache *)S_ERROR) return (S_ERROR); orsp = rcp->rc_free; /* * If we are adding a output relocation against a section * symbol (non-RELATIVE) then mark that section. These sections * will be added to the .dynsym symbol table. */ if (sdp && (rsp->rel_rtype != M_R_RELATIVE) && ((flags & FLG_REL_SCNNDX) || (ELF_ST_TYPE(sdp->sd_sym->st_info) == STT_SECTION))) { /* * If this is a COMMON symbol - no output section * exists yet - (it's created as part of sym_validate()). * So - we mark here that when it's created it should * be tagged with the FLG_OS_OUTREL flag. */ if ((sdp->sd_flags & FLG_SY_SPECSEC) && (sdp->sd_sym->st_shndx == SHN_COMMON)) { if (ELF_ST_TYPE(sdp->sd_sym->st_info) != STT_TLS) ofl->ofl_flags1 |= FLG_OF1_BSSOREL; else ofl->ofl_flags1 |= FLG_OF1_TLSOREL; } else { Os_desc *osp = sdp->sd_isc->is_osdesc; if (osp && ((osp->os_flags & FLG_OS_OUTREL) == 0)) { ofl->ofl_dynshdrcnt++; osp->os_flags |= FLG_OS_OUTREL; } } } *orsp = *rsp; orsp->rel_flags |= flags; rcp->rc_free++; ofl->ofl_outrelscnt++; if (flags & FLG_REL_GOT) ofl->ofl_relocgotsz += (Xword)sizeof (Rela); else if (flags & FLG_REL_PLT) ofl->ofl_relocpltsz += (Xword)sizeof (Rela); else if (flags & FLG_REL_BSS) ofl->ofl_relocbsssz += (Xword)sizeof (Rela); else if (flags & FLG_REL_NOINFO) ofl->ofl_relocrelsz += (Xword)sizeof (Rela); else orsp->rel_osdesc->os_szoutrels += (Xword)sizeof (Rela); if (orsp->rel_rtype == M_R_RELATIVE) ofl->ofl_relocrelcnt++; #if defined(_ELF64) /* * When building a 64-bit object any R_SPARC_WDISP30 relocation is given * a plt padding entry, unless we're building a relocatable object * (ld -r) or -b is in effect. */ if ((orsp->rel_rtype == R_SPARC_WDISP30) && ((ofl->ofl_flags & (FLG_OF_BFLAG | FLG_OF_RELOBJ)) == 0) && ((orsp->rel_sym->sd_flags & FLG_SY_PLTPAD) == 0)) { ofl->ofl_pltpad++; orsp->rel_sym->sd_flags |= FLG_SY_PLTPAD; } #endif /* * We don't perform sorting on PLT relocations because * they have already been assigned a PLT index and if we * were to sort them we would have to re-assign the plt indexes. */ if (!(flags & FLG_REL_PLT)) ofl->ofl_reloccnt++; /* * Insure a GLOBAL_OFFSET_TABLE is generated if required. */ if (IS_GOT_REQUIRED(orsp->rel_rtype)) ofl->ofl_flags |= FLG_OF_BLDGOT; /* * Identify and possibly warn of a displacement relocation. */ if (orsp->rel_flags & FLG_REL_DISP) { ofl->ofl_dtflags_1 |= DF_1_DISPRELPND; if (ofl->ofl_flags & FLG_OF_VERBOSE) ld_disp_errmsg(MSG_INTL(MSG_REL_DISPREL4), orsp, ofl); } DBG_CALL(Dbg_reloc_ors_entry(ofl->ofl_lml, ELF_DBG_LD, SHT_RELA, M_MACH, orsp)); return (1); } /* * Process relocation against a register symbol. Note, of -z muldefs is in * effect there may have been multiple register definitions, which would have * been processed as non-fatal, with the first definition winning. But, we * will also process multiple relocations for these multiple definitions. In * this case we must only preserve the relocation for the definition that was * kept. The sad part is that register relocations don't typically specify * the register symbol with which they are associated, so we might have to * search the input files global symbols to determine if this relocation is * appropriate. */ static uintptr_t ld_reloc_register(Rel_desc *rsp, Is_desc *isp, Ofl_desc *ofl) { if (ofl->ofl_flags & FLG_OF_MULDEFS) { Ifl_desc *ifl = isp->is_file; Sym_desc *sdp = rsp->rel_sym; if (sdp == 0) { Xword offset = rsp->rel_roffset; Word ndx; for (ndx = ifl->ifl_locscnt; ndx < ifl->ifl_symscnt; ndx++) { if (((sdp = ifl->ifl_oldndx[ndx]) != 0) && (sdp->sd_flags & FLG_SY_REGSYM) && (sdp->sd_sym->st_value == offset)) break; } } if (sdp && (sdp->sd_file != ifl)) return (1); } return (ld_add_outrel((rsp->rel_flags | FLG_REL_REG), rsp, ofl)); } /* * process relocation for a LOCAL symbol */ static uintptr_t ld_reloc_local(Rel_desc *rsp, Ofl_desc *ofl) { ofl_flag_t flags = ofl->ofl_flags; Sym_desc *sdp = rsp->rel_sym; Word shndx = sdp->sd_sym->st_shndx; /* * if ((shared object) and (not pc relative relocation) and * (not against ABS symbol)) * then * if (rtype != R_SPARC_32) * then * build relocation against section * else * build R_SPARC_RELATIVE * fi * fi */ if ((flags & FLG_OF_SHAROBJ) && (rsp->rel_flags & FLG_REL_LOAD) && !(IS_PC_RELATIVE(rsp->rel_rtype)) && !(IS_SIZE(rsp->rel_rtype)) && !(IS_GOT_BASED(rsp->rel_rtype)) && !(rsp->rel_isdesc != NULL && (rsp->rel_isdesc->is_shdr->sh_type == SHT_SUNW_dof)) && (((sdp->sd_flags & FLG_SY_SPECSEC) == 0) || (shndx != SHN_ABS) || (sdp->sd_aux && sdp->sd_aux->sa_symspec))) { Word ortype = rsp->rel_rtype; if ((rsp->rel_rtype != R_SPARC_32) && (rsp->rel_rtype != R_SPARC_PLT32) && (rsp->rel_rtype != R_SPARC_64)) return (ld_add_outrel((FLG_REL_SCNNDX | FLG_REL_ADVAL), rsp, ofl)); rsp->rel_rtype = R_SPARC_RELATIVE; if (ld_add_outrel(FLG_REL_ADVAL, rsp, ofl) == S_ERROR) return (S_ERROR); rsp->rel_rtype = ortype; return (1); } /* * If the relocation is against a 'non-allocatable' section * and we can not resolve it now - then give a warning * message. * * We can not resolve the symbol if either: * a) it's undefined * b) it's defined in a shared library and a * COPY relocation hasn't moved it to the executable * * Note: because we process all of the relocations against the * text segment before any others - we know whether * or not a copy relocation will be generated before * we get here (see reloc_init()->reloc_segments()). */ if (!(rsp->rel_flags & FLG_REL_LOAD) && ((shndx == SHN_UNDEF) || ((sdp->sd_ref == REF_DYN_NEED) && ((sdp->sd_flags & FLG_SY_MVTOCOMM) == 0)))) { Conv_inv_buf_t inv_buf; /* * If the relocation is against a SHT_SUNW_ANNOTATE * section - then silently ignore that the relocation * can not be resolved. */ if (rsp->rel_osdesc && (rsp->rel_osdesc->os_shdr->sh_type == SHT_SUNW_ANNOTATE)) return (0); (void) eprintf(ofl->ofl_lml, ERR_WARNING, MSG_INTL(MSG_REL_EXTERNSYM), conv_reloc_SPARC_type(rsp->rel_rtype, 0, &inv_buf), rsp->rel_isdesc->is_file->ifl_name, demangle(rsp->rel_sname), rsp->rel_osdesc->os_name); return (1); } /* * Perform relocation. */ return (ld_add_actrel(NULL, rsp, ofl)); } /* * Establish a relocation transition. Note, at this point of input relocation * processing, we have no idea of the relocation value that will be used in * the eventual relocation calculation. This value is only known after the * initial image has been constructed. Therefore, there is a small chance * that a value can exceed the capabilities of the transitioned relocation. * One example might be the offset from the GOT to a symbol. * * The only instance of this failure discovered so far has been via the use of * ABS symbols to represent an external memory location. This situation is * rare, since ABS symbols aren't typically generated by the compilers. * Therefore, our solution is to excluded ABS symbols from the transition * relocation possibilities. As an additional safeguard, if an inappropriate * value is passed to the final relocation engine, a verification ("V") * relocation should trigger a fatal error condition. */ static uintptr_t ld_reloc_GOTOP(Boolean local, Rel_desc *rsp, Ofl_desc *ofl) { Word rtype = rsp->rel_rtype; if (!local || (rsp->rel_sym->sd_sym->st_shndx == SHN_ABS)) { /* * When binding to a external symbol, no fixups are required * and the GOTDATA_OP relocation can be ignored. */ if (rtype == R_SPARC_GOTDATA_OP) return (1); return (ld_reloc_GOT_relative(local, rsp, ofl)); } /* * When binding to a local symbol the relocations can be transitioned: * * R_*_GOTDATA_OP_HIX22 -> R_*_GOTDATA_HIX22 * R_*_GOTDATA_OP_LOX10 -> R_*_GOTDATA_LOX10 * R_*_GOTDATA_OP -> instruction fixup */ return (ld_add_actrel(FLG_REL_GOTFIX, rsp, ofl)); } static uintptr_t ld_reloc_TLS(Boolean local, Rel_desc *rsp, Ofl_desc *ofl) { Word rtype = rsp->rel_rtype; Sym_desc *sdp = rsp->rel_sym; ofl_flag_t flags = ofl->ofl_flags; Gotndx *gnp; /* * If we're building an executable - use either the IE or LE access * model. If we're building a shared object process any IE model. */ if ((flags & FLG_OF_EXEC) || (IS_TLS_IE(rtype))) { /* * Set the DF_STATIC_TLS flag. */ ofl->ofl_dtflags |= DF_STATIC_TLS; if (!local || ((flags & FLG_OF_EXEC) == 0)) { /* * When processing static TLS - these relocations * can be ignored. */ if ((rtype == R_SPARC_TLS_IE_LD) || (rtype == R_SPARC_TLS_IE_LDX) || (rtype == R_SPARC_TLS_IE_ADD)) return (1); /* * Assign a GOT entry for IE static TLS references. */ if (((rtype == R_SPARC_TLS_GD_HI22) || (rtype == R_SPARC_TLS_GD_LO10) || (rtype == R_SPARC_TLS_IE_HI22) || (rtype == R_SPARC_TLS_IE_LO10)) && ((gnp = ld_find_got_ndx(sdp->sd_GOTndxs, GOT_REF_TLSIE, ofl, rsp)) == NULL)) { if (ld_assign_got_TLS(local, rsp, ofl, sdp, gnp, GOT_REF_TLSIE, FLG_REL_STLS, rtype, M_R_TPOFF, NULL) == S_ERROR) return (S_ERROR); } /* * IE access model. */ if (IS_TLS_IE(rtype)) return (ld_add_actrel(FLG_REL_STLS, rsp, ofl)); /* * Fixups are required for other executable models. */ return (ld_add_actrel((FLG_REL_TLSFIX | FLG_REL_STLS), rsp, ofl)); } /* * LE access model. */ if (IS_TLS_LE(rtype)) return (ld_add_actrel(FLG_REL_STLS, rsp, ofl)); /* * When processing static TLS - these relocations can be * ignored. */ if (rtype == R_SPARC_TLS_IE_ADD) return (1); return (ld_add_actrel((FLG_REL_TLSFIX | FLG_REL_STLS), rsp, ofl)); } /* * Building a shared object. * * For dynamic TLS references, ADD relocations are ignored. */ if ((rtype == R_SPARC_TLS_GD_ADD) || (rtype == R_SPARC_TLS_LDM_ADD) || (rtype == R_SPARC_TLS_LDO_ADD)) return (1); /* * Assign a GOT entry for a dynamic TLS reference. */ if (((rtype == R_SPARC_TLS_LDM_HI22) || (rtype == R_SPARC_TLS_LDM_LO10)) && ((gnp = ld_find_got_ndx(sdp->sd_GOTndxs, GOT_REF_TLSLD, ofl, rsp)) == NULL)) { if (ld_assign_got_TLS(local, rsp, ofl, sdp, gnp, GOT_REF_TLSLD, FLG_REL_MTLS, rtype, M_R_DTPMOD, 0) == S_ERROR) return (S_ERROR); } else if (((rtype == R_SPARC_TLS_GD_HI22) || (rtype == R_SPARC_TLS_GD_LO10)) && ((gnp = ld_find_got_ndx(sdp->sd_GOTndxs, GOT_REF_TLSGD, ofl, rsp)) == NULL)) { if (ld_assign_got_TLS(local, rsp, ofl, sdp, gnp, GOT_REF_TLSGD, FLG_REL_DTLS, rtype, M_R_DTPMOD, M_R_DTPOFF) == S_ERROR) return (S_ERROR); } /* * For GD/LD TLS reference - TLS_{GD,LD}_CALL, this will eventually * cause a call to __tls_get_addr(). Convert this relocation to that * symbol now, and prepare for the PLT magic. */ if ((rtype == R_SPARC_TLS_GD_CALL) || (rtype == R_SPARC_TLS_LDM_CALL)) { Sym_desc *tlsgetsym; if ((tlsgetsym = ld_sym_add_u(MSG_ORIG(MSG_SYM_TLSGETADDR_U), ofl, MSG_STR_TLSREL)) == (Sym_desc *)S_ERROR) return (S_ERROR); rsp->rel_sym = tlsgetsym; rsp->rel_sname = tlsgetsym->sd_name; rsp->rel_rtype = R_SPARC_WPLT30; if (ld_reloc_plt(rsp, ofl) == S_ERROR) return (S_ERROR); rsp->rel_sym = sdp; rsp->rel_sname = sdp->sd_name; rsp->rel_rtype = rtype; return (1); } if (IS_TLS_LD(rtype)) return (ld_add_actrel(FLG_REL_MTLS, rsp, ofl)); return (ld_add_actrel(FLG_REL_DTLS, rsp, ofl)); } /* * ld_allocate_got: if a GOT is to be made, after the section is built this * function is called to allocate all the GOT slots. The allocation is * deferred until after all GOTs have been counted and sorted according * to their size, for only then will we know how to allocate them on * a processor like SPARC which has different models for addressing the * GOT. SPARC has two: small and large, small uses a signed 13-bit offset * into the GOT, whereas large uses an unsigned 32-bit offset. */ static Sword small_index; /* starting index for small GOT entries */ static Sword mixed_index; /* starting index for mixed GOT entries */ static Sword large_index; /* starting index for large GOT entries */ static uintptr_t ld_assign_got(Ofl_desc *ofl, Sym_desc *sdp) { Aliste idx; Gotndx *gnp; for (ALIST_TRAVERSE(sdp->sd_GOTndxs, idx, gnp)) { uint_t gotents; Gotref gref = gnp->gn_gotref; if ((gref == GOT_REF_TLSGD) || (gref == GOT_REF_TLSLD)) gotents = 2; else gotents = 1; switch (gnp->gn_gotndx) { case M_GOT_SMALL: gnp->gn_gotndx = small_index; small_index += gotents; if (small_index == 0) small_index = M_GOT_XNumber; break; case M_GOT_MIXED: gnp->gn_gotndx = mixed_index; mixed_index += gotents; break; case M_GOT_LARGE: gnp->gn_gotndx = large_index; large_index += gotents; break; default: eprintf(ofl->ofl_lml, ERR_FATAL, MSG_INTL(MSG_REL_ASSIGNGOT), EC_XWORD(gnp->gn_gotndx), demangle(sdp->sd_name)); return (S_ERROR); } } return (1); } static uintptr_t ld_assign_got_ndx(Alist **alpp, Gotndx *pgnp, Gotref gref, Ofl_desc *ofl, Rel_desc *rsp, Sym_desc *sdp) { Xword raddend; Gotndx gn, *gnp; Aliste idx; uint_t gotents; /* Some TLS requires two relocations with two GOT entries */ if ((gref == GOT_REF_TLSGD) || (gref == GOT_REF_TLSLD)) gotents = 2; else gotents = 1; raddend = rsp->rel_raddend; if (pgnp && (pgnp->gn_addend == raddend) && (pgnp->gn_gotref == gref)) { /* * If an entry for this addend already exists, determine if it * has mixed mode GOT access (both PIC and pic). * * In order to be accessible by both large and small pic, * a mixed mode GOT must be located in the positive index * range above _GLOBAL_OFFSET_TABLE_, and in the range * reachable small pic. This is necessary because the large * PIC mode cannot use a negative offset. This implies that * there can be no more than (M_GOT_MAXSMALL/2 - M_GOT_XNumber) * such entries. */ switch (pgnp->gn_gotndx) { case M_GOT_SMALL: /* * This one was previously identified as a small * GOT. If this access is large, then convert * it to mixed. */ if (rsp->rel_rtype != R_SPARC_GOT13) { pgnp->gn_gotndx = M_GOT_MIXED; mixgotcnt += gotents; } break; case M_GOT_LARGE: /* * This one was previously identified as a large * GOT. If this access is small, convert it to mixed. */ if (rsp->rel_rtype == R_SPARC_GOT13) { smlgotcnt += gotents; mixgotcnt += gotents; pgnp->gn_gotndx = M_GOT_MIXED; sdp->sd_flags |= FLG_SY_SMGOT; } break; } return (1); } gn.gn_addend = raddend; gn.gn_gotref = gref; if (rsp->rel_rtype == R_SPARC_GOT13) { gn.gn_gotndx = M_GOT_SMALL; smlgotcnt += gotents; sdp->sd_flags |= FLG_SY_SMGOT; } else gn.gn_gotndx = M_GOT_LARGE; ofl->ofl_gotcnt += gotents; if (gref == GOT_REF_TLSLD) { if (ofl->ofl_tlsldgotndx == NULL) { if ((gnp = libld_malloc(sizeof (Gotndx))) == NULL) return (S_ERROR); (void) memcpy(gnp, &gn, sizeof (Gotndx)); ofl->ofl_tlsldgotndx = gnp; } return (1); } idx = 0; for (ALIST_TRAVERSE(*alpp, idx, gnp)) { if (gnp->gn_addend > raddend) break; } /* * GOT indexes are maintained on an Alist, where there is typically * only one index. The usage of this list is to scan the list to find * an index, and then apply that index immediately to a relocation. * Thus there are no external references to these GOT index structures * that can be compromised by the Alist being reallocated. */ if (alist_insert(alpp, &gn, sizeof (Gotndx), AL_CNT_SDP_GOT, idx) == NULL) return (S_ERROR); return (1); } static void ld_assign_plt_ndx(Sym_desc * sdp, Ofl_desc *ofl) { sdp->sd_aux->sa_PLTndx = 1 + ofl->ofl_pltcnt++; } static uintptr_t ld_allocate_got(Ofl_desc * ofl) { const Sword first_large_ndx = M_GOT_MAXSMALL / 2; Sym_desc *sdp; Addr addr; /* * Sanity check -- is this going to fit at all? There are two * limits to be concerned about: * 1) There is a limit on the number of small pic GOT indices, * given by M_GOT_MAXSMALL. * 2) If there are more than (M_GOT_MAXSMALL/2 - M_GOT_XNumber) * small GOT indices, there will be items at negative * offsets from _GLOBAL_OFFSET_TABLE_. Items that are * accessed via large (PIC) code cannot reach these * negative slots, so mixed mode items must be in the * non-negative range. This implies a limit of * (M_GOT_MAXSMALL/2 - M_GOT_XNumber) mixed mode indices. */ if (smlgotcnt > M_GOT_MAXSMALL) { eprintf(ofl->ofl_lml, ERR_FATAL, MSG_INTL(MSG_REL_SMALLGOT), EC_WORD(smlgotcnt), M_GOT_MAXSMALL); return (S_ERROR); } if (mixgotcnt > (first_large_ndx - M_GOT_XNumber)) { eprintf(ofl->ofl_lml, ERR_FATAL, MSG_INTL(MSG_REL_MIXEDGOT), EC_WORD(mixgotcnt), first_large_ndx - M_GOT_XNumber); return (S_ERROR); } /* * Set starting offset to be either 0, or a negative index into * the GOT based on the number of small symbols we've got. */ neggotoffset = ((smlgotcnt >= first_large_ndx) ? (first_large_ndx - smlgotcnt) : 0); /* * Initialize the got offsets used by assign_got() to * locate GOT items: * small - Starting index of items referenced only * by small offsets (-Kpic). * mixed - Starting index of items referenced * by both large (-KPIC) and small (-Kpic). * large - Indexes referenced only by large (-KPIC) * * Small items can have negative indexes (i.e. lie below * _GLOBAL_OFFSET_TABLE_). Mixed and large items must have * non-negative offsets. */ small_index = (neggotoffset == 0) ? M_GOT_XNumber : neggotoffset; large_index = neggotoffset + smlgotcnt; mixed_index = large_index - mixgotcnt; /* * Assign bias to GOT symbols. */ addr = -neggotoffset * M_GOT_ENTSIZE; if ((sdp = ld_sym_find(MSG_ORIG(MSG_SYM_GOFTBL), SYM_NOHASH, NULL, ofl)) != NULL) sdp->sd_sym->st_value = addr; if ((sdp = ld_sym_find(MSG_ORIG(MSG_SYM_GOFTBL_U), SYM_NOHASH, NULL, ofl)) != NULL) sdp->sd_sym->st_value = addr; if (ofl->ofl_tlsldgotndx) { ofl->ofl_tlsldgotndx->gn_gotndx = large_index; large_index += 2; } return (1); } /* * Initializes .got[0] with the _DYNAMIC symbol value. */ static uintptr_t ld_fillin_gotplt(Ofl_desc *ofl) { if (ofl->ofl_osgot) { Sym_desc *sdp; if ((sdp = ld_sym_find(MSG_ORIG(MSG_SYM_DYNAMIC_U), SYM_NOHASH, NULL, ofl)) != NULL) { uchar_t *genptr; genptr = ((uchar_t *)ofl->ofl_osgot->os_outdata->d_buf + (-neggotoffset * M_GOT_ENTSIZE) + (M_GOT_XDYNAMIC * M_GOT_ENTSIZE)); /* LINTED */ *((Xword *)genptr) = sdp->sd_sym->st_value; if (ofl->ofl_flags1 & FLG_OF1_ENCDIFF) /* LINTED */ *((Xword *)genptr) = /* LINTED */ ld_bswap_Xword(*((Xword *)genptr)); } } return (1); } /* * Template for generating "void (*)(void)" function */ static const uchar_t nullfunc_tmpl[] = { /* 0x00 */ 0x81, 0xc3, 0xe0, 0x08, /* retl */ /* 0x04 */ 0x01, 0x00, 0x00, 0x00 /* nop */ }; /* * Return the ld_targ definition for this target. */ const Target * ld_targ_init_sparc(void) { static const Target _ld_targ = { { /* Target_mach */ M_MACH, /* m_mach */ M_MACHPLUS, /* m_machplus */ M_FLAGSPLUS, /* m_flagsplus */ M_CLASS, /* m_class */ M_DATA, /* m_data */ M_SEGM_ALIGN, /* m_segm_align */ M_SEGM_ORIGIN, /* m_segm_origin */ M_SEGM_AORIGIN, /* m_segm_aorigin */ M_DATASEG_PERM, /* m_dataseg_perm */ M_STACK_PERM, /* m_stack_perm */ M_WORD_ALIGN, /* m_word_align */ /* m_def_interp */ #if defined(_ELF64) MSG_ORIG(MSG_PTH_RTLD_SPARCV9), #else MSG_ORIG(MSG_PTH_RTLD), #endif /* Relocation type codes */ M_R_ARRAYADDR, /* m_r_arrayaddr */ M_R_COPY, /* m_r_copy */ M_R_GLOB_DAT, /* m_r_glob_dat */ M_R_JMP_SLOT, /* m_r_jmp_slot */ M_R_NUM, /* m_r_num */ M_R_NONE, /* m_r_none */ M_R_RELATIVE, /* m_r_relative */ M_R_REGISTER, /* m_r_register */ /* Relocation related constants */ M_REL_DT_COUNT, /* m_rel_dt_count */ M_REL_DT_ENT, /* m_rel_dt_ent */ M_REL_DT_SIZE, /* m_rel_dt_size */ M_REL_DT_TYPE, /* m_rel_dt_type */ M_REL_SHT_TYPE, /* m_rel_sht_type */ /* GOT related constants */ M_GOT_ENTSIZE, /* m_got_entsize */ M_GOT_XNumber, /* m_got_xnumber */ /* PLT related constants */ M_PLT_ALIGN, /* m_plt_align */ M_PLT_ENTSIZE, /* m_plt_entsize */ M_PLT_RESERVSZ, /* m_plt_reservsz */ M_PLT_SHF_FLAGS, /* m_plt_shf_flags */ /* Section type of .eh_frame/.eh_frame_hdr sections */ SHT_PROGBITS, /* m_sht_unwind */ M_DT_REGISTER, /* m_dt_register */ }, { /* Target_machid */ M_ID_ARRAY, /* id_array */ M_ID_BSS, /* id_bss */ M_ID_CAP, /* id_cap */ M_ID_DATA, /* id_data */ M_ID_DYNAMIC, /* id_dynamic */ M_ID_DYNSORT, /* id_dynsort */ M_ID_DYNSTR, /* id_dynstr */ M_ID_DYNSYM, /* id_dynsym */ M_ID_DYNSYM_NDX, /* id_dynsym_ndx */ M_ID_GOT, /* id_got */ M_ID_GOTDATA, /* id_gotdata */ M_ID_HASH, /* id_hash */ M_ID_INTERP, /* id_interp */ M_ID_UNKNOWN, /* id_lbss (unused) */ M_ID_LDYNSYM, /* id_ldynsym */ M_ID_NOTE, /* id_note */ M_ID_NULL, /* id_null */ M_ID_PLT, /* id_plt */ M_ID_REL, /* id_rel */ M_ID_STRTAB, /* id_strtab */ M_ID_SYMINFO, /* id_syminfo */ M_ID_SYMTAB, /* id_symtab */ M_ID_SYMTAB_NDX, /* id_symtab_ndx */ M_ID_TEXT, /* id_text */ M_ID_TLS, /* id_tls */ M_ID_TLSBSS, /* id_tlsbss */ M_ID_UNKNOWN, /* id_unknown */ M_ID_UNWIND, /* id_unwind */ M_ID_UNWINDHDR, /* id_unwindhdr */ M_ID_USER, /* id_user */ M_ID_VERSION, /* id_version */ }, { /* Target_nullfunc */ nullfunc_tmpl, /* nf_template */ sizeof (nullfunc_tmpl), /* nf_size */ }, { /* Target_fillfunc */ /* * On sparc, special filling of executable sections * is undesirable, and the default 0 fill supplied * by libelf is preferred: * * - 0 fill is interpreted as UNIMP instructions, * which cause an illegal_instruction_trap. These * serve as a sentinel against poorly written * code. The sparc architecture manual discusses * this as providing a measure of runtime safety. * * - The one place where a hole should conceivably * be filled with NOP instructions is in the * .init/.fini sections. However, the sparc * assembler sizes the sections it generates * to a multiple of the section alignment, and as * such, takes the filling task out of our hands. * Furthermore, the sparc assembler uses 0-fill * for this, forcing the authors of sparc * assembler for .init/.fini sections to be aware * of this case and explicitly supply NOP fill. * Hence, there is no role for the link-editor. */ NULL /* ff_execfill */ }, { /* Target_machrel */ reloc_table, ld_init_rel, /* mr_init_rel */ ld_mach_eflags, /* mr_mach_eflags */ ld_mach_make_dynamic, /* mr_mach_make_dynamic */ ld_mach_update_odynamic, /* mr_mach_update_odynamic */ ld_calc_plt_addr, /* mr_calc_plt_addr */ ld_perform_outreloc, /* mr_perform_outreloc */ ld_do_activerelocs, /* mr_do_activerelocs */ ld_add_outrel, /* mr_add_outrel */ ld_reloc_register, /* mr_reloc_register */ ld_reloc_local, /* mr_reloc_local */ ld_reloc_GOTOP, /* mr_reloc_GOTOP */ ld_reloc_TLS, /* mr_reloc_TLS */ ld_assign_got, /* mr_assign_got */ ld_find_got_ndx, /* mr_find_got_ndx */ ld_calc_got_offset, /* mr_calc_got_offset */ ld_assign_got_ndx, /* mr_assign_got_ndx */ ld_assign_plt_ndx, /* mr_assign_plt_ndx */ ld_allocate_got, /* mr_allocate_got */ ld_fillin_gotplt, /* mr_fillin_gotplt */ }, { /* Target_machsym */ ld_reg_check_sparc, /* ms_reg_check */ ld_mach_sym_typecheck_sparc, /* ms_mach_sym_typecheck */ ld_is_regsym_sparc, /* ms_is_regsym */ ld_reg_find_sparc, /* ms_reg_find */ ld_reg_enter_sparc /* ms_reg_enter */ } }; return (&_ld_targ); }