// SPARC is a RISC ISA developed by Sun Microsystems. // // The byte order of the processor is big-endian. Anything larger than a // byte is stored in the "reverse" order compared to little-endian // processors such as x86-64. // // All instructions are 4 bytes long and aligned to 4 bytes boundaries. // // A notable feature of SPARC is that, unlike other RISC ISAs, it doesn't // need range extension thunks. It is because the SPARC's CALL instruction // contains a whopping 30 bits immediate. The processor scales it by 4 to // extend it to 32 bits (this is doable because all instructions are // aligned to 4 bytes boundaries, so the least significant two bits are // always zero). That means CALL's reach is PC ± 2 GiB, elinating the // need of range extension thunks. It comes with the cost that the CALL // instruction alone takes 1/4th of the instruction encoding space, // though. // // SPARC has 32 general purpose registers. CALL instruction saves a return // address to %o7, which is an alias for %r15. Thread pointer is stored to // %g7 which is %r7. // // SPARC does not have PC-relative load/store instructions. To access data // in the position-independent manner, we usually first set the address of // .got to, for example, %l7, with the following piece of code // // sethi %hi(. - _GLOBAL_OFFSET_TABLE_), %l7 // add %l7, %lo(. - _GLOBAL_OFFSET_TABLE_), %l7 // call __sparc_get_pc_thunk.l7 // nop // // where __sparc_get_pc_thunk.l7 is defined as // // retl // add %o7, %l7, %l7 // // . SETHI and the following ADD materialize a 32 bits offset to .got. // CALL instruction sets a return address to $o7, and the subsequent ADD // adds it to the GOT offset to materialize the absolute address of .got. // // Note that we have a NOP after CALL and an ADD after RETL because of // SPARC's delay branch slots. That is, the SPARC processor always // executes one instruction after a branch even if the branch is taken. // This may seem like an odd behavior, and indeed it is considered as such // (that's a premature optimization for the early pipelined SPARC // processors), but that's been a part of the ISA's spec so that's what it // is. // // Note also that the .got address obtained this way is not shared between // functions, so functions can use an arbitrary register to hold the .got // address. That also means each function needs to execute the above piece // of code to become position-independent. // // This scheme is very similar to i386. That may not be a coincidence // because the i386 ELF psABI is created by Sun Microsystems too. // // https://docs.oracle.com/cd/E36784_01/html/E36857/chapter6-62988.html // https://docs.oracle.com/cd/E19120-01/open.solaris/819-0690/chapter8-40/index.html #include "mold.h" namespace mold::elf { using E = SPARC64; // SPARC's PLT section is writable despite containing executable code. // We don't need to write the PLT header entry because the dynamic loader // will do that for us. // // We also don't need a .got.plt section to store the result of lazy PLT // symbol resolution because the dynamic symbol resolver directly mutates // instructions in PLT so that they jump to the right places next time. // That's why each PLT entry contains lots of NOPs; they are a placeholder // for the runtime to add more instructions. // // Self-modifying code is nowadays considered really bad from the security // point of view, though. template <> void write_plt_header(Context &ctx, u8 *buf) { memset(buf, 0, E::plt_hdr_size); } template <> void write_plt_entry(Context &ctx, u8 *buf, Symbol &sym) { static ub32 insn[] = { 0x0300'0000, // sethi (. - .PLT0), %g1 0x3068'0000, // ba,a %xcc, .PLT1 0x0100'0000, // nop 0x0100'0000, // nop 0x0100'0000, // nop 0x0100'0000, // nop 0x0100'0000, // nop 0x0100'0000, // nop }; u64 plt0 = ctx.plt->shdr.sh_addr; u64 plt1 = ctx.plt->shdr.sh_addr + E::plt_size; u64 entry = sym.get_plt_addr(ctx); memcpy(buf, insn, sizeof(insn)); *(ub32 *)buf |= bits(entry - plt0, 21, 0); *(ub32 *)(buf + 4) |= bits(plt1 - entry - 4, 20, 2); } template <> void write_pltgot_entry(Context &ctx, u8 *buf, Symbol &sym) { static ub32 entry[] = { 0x8a10'000f, // mov %o7, %g5 0x4000'0002, // call . + 8 0xc25b'e014, // ldx [ %o7 + 20 ], %g1 0xc25b'c001, // ldx [ %o7 + %g1 ], %g1 0x81c0'4000, // jmp %g1 0x9e10'0005, // mov %g5, %o7 0x0000'0000, // .quad $plt_entry - $got_entry 0x0000'0000, }; memcpy(buf, entry, sizeof(entry)); *(ub64 *)(buf + 24) = sym.get_got_addr(ctx) - sym.get_plt_addr(ctx) - 4; } template <> void EhFrameSection::apply_reloc(Context &ctx, const ElfRel &rel, u64 offset, u64 val) { u8 *loc = ctx.buf + this->shdr.sh_offset + offset; switch (rel.r_type) { case R_NONE: break; case R_SPARC_64: case R_SPARC_UA64: *(ub64 *)loc = val; break; case R_SPARC_DISP32: *(ub32 *)loc = val - this->shdr.sh_addr - offset; break; default: Fatal(ctx) << "unsupported relocation in .eh_frame: " << rel; } } template <> void InputSection::apply_reloc_alloc(Context &ctx, u8 *base) { std::span> rels = get_rels(ctx); ElfRel *dynrel = nullptr; if (ctx.reldyn) dynrel = (ElfRel *)(ctx.buf + ctx.reldyn->shdr.sh_offset + file.reldyn_offset + this->reldyn_offset); for (i64 i = 0; i < rels.size(); i++) { const ElfRel &rel = rels[i]; if (rel.r_type == R_NONE) continue; Symbol &sym = *file.symbols[rel.r_sym]; u8 *loc = base + rel.r_offset; #define S sym.get_addr(ctx) #define A rel.r_addend #define P (get_addr() + rel.r_offset) #define G (sym.get_got_idx(ctx) * sizeof(Word)) #define GOT ctx.got->shdr.sh_addr switch (rel.r_type) { case R_SPARC_64: apply_abs_dyn_rel(ctx, sym, rel, loc, S, A, P, dynrel); break; case R_SPARC_5: *(ub32 *)loc |= bits(S + A, 4, 0); break; case R_SPARC_6: *(ub32 *)loc |= bits(S + A, 5, 0); break; case R_SPARC_7: *(ub32 *)loc |= bits(S + A, 6, 0); break; case R_SPARC_8: *(u8 *)loc = S + A; break; case R_SPARC_10: case R_SPARC_LO10: case R_SPARC_LOPLT10: *(ub32 *)loc |= bits(S + A, 9, 0); break; case R_SPARC_11: *(ub32 *)loc |= bits(S + A, 10, 0); break; case R_SPARC_13: *(ub32 *)loc |= bits(S + A, 12, 0); break; case R_SPARC_16: case R_SPARC_UA16: *(ub16 *)loc = S + A; break; case R_SPARC_22: *(ub32 *)loc |= bits(S + A, 21, 0); break; case R_SPARC_32: case R_SPARC_UA32: case R_SPARC_PLT32: *(ub32 *)loc = S + A; break; case R_SPARC_PLT64: case R_SPARC_UA64: case R_SPARC_REGISTER: *(ub64 *)loc = S + A; break; case R_SPARC_DISP8: *(u8 *)loc = S + A - P; break; case R_SPARC_DISP16: *(ub16 *)loc = S + A - P; break; case R_SPARC_DISP32: case R_SPARC_PCPLT32: *(ub32 *)loc = S + A - P; break; case R_SPARC_DISP64: *(ub64 *)loc = S + A - P; break; case R_SPARC_WDISP16: { i64 val = S + A - P; *(ub16 *)loc |= (bit(val, 16) << 21) | bits(val, 15, 2); break; } case R_SPARC_WDISP19: *(ub32 *)loc |= bits(S + A - P, 20, 2); break; case R_SPARC_WDISP22: *(ub32 *)loc |= bits(S + A - P, 23, 2); break; case R_SPARC_WDISP30: case R_SPARC_WPLT30: *(ub32 *)loc |= bits(S + A - P, 31, 2); break; case R_SPARC_HI22: case R_SPARC_HIPLT22: case R_SPARC_LM22: *(ub32 *)loc |= bits(S + A, 31, 10); break; case R_SPARC_GOT10: *(ub32 *)loc |= bits(G, 9, 0); break; case R_SPARC_GOT13: *(ub32 *)loc |= bits(G, 12, 0); break; case R_SPARC_GOT22: *(ub32 *)loc |= bits(G, 31, 10); break; case R_SPARC_GOTDATA_HIX22: { i64 val = S + A - GOT; *(ub32 *)loc |= bits(val < 0 ? ~val : val, 31, 10); break; } case R_SPARC_GOTDATA_LOX10: { i64 val = S + A - GOT; *(ub32 *)loc |= bits(val, 9, 0) | (val < 0 ? 0b1'1100'0000'0000 : 0); break; } case R_SPARC_GOTDATA_OP_HIX22: // We always have to relax a GOT load to a load immediate if a // symbol is local, because R_SPARC_GOTDATA_OP cannot represent // an addend for a local symbol. if (sym.is_imported) { *(ub32 *)loc |= bits(G < 0 ? ~G : G, 31, 10); } else if (sym.is_absolute()) { i64 val = S + A; *(ub32 *)loc |= bits(val < 0 ? ~val : val, 31, 10); } else { i64 val = S + A - GOT; *(ub32 *)loc |= bits(val < 0 ? ~val : val, 31, 10); } break; case R_SPARC_GOTDATA_OP_LOX10: { if (sym.is_imported) { *(ub32 *)loc |= bits(G, 9, 0) | (G < 0 ? 0b1'1100'0000'0000 : 0); } else if (sym.is_absolute()) { i64 val = S + A; *(ub32 *)loc |= bits(val, 9, 0) | (val < 0 ? 0b1'1100'0000'0000 : 0); } else { i64 val = S + A - GOT; *(ub32 *)loc |= bits(val, 9, 0) | (val < 0 ? 0b1'1100'0000'0000 : 0); } break; } case R_SPARC_GOTDATA_OP: if (sym.is_imported) break; if (sym.is_absolute()) { // ldx [ %g2 + %g1 ], %g1 → nop *(ub32 *)loc = 0x0100'0000; } else { // ldx [ %g2 + %g1 ], %g1 → add %g2, %g1, %g1 *(ub32 *)loc &= 0b00'11111'000000'11111'1'11111111'11111; *(ub32 *)loc |= 0b10'00000'000000'00000'0'00000000'00000; } break; case R_SPARC_PC10: case R_SPARC_PCPLT10: *(ub32 *)loc |= bits(S + A - P, 9, 0); break; case R_SPARC_PC22: case R_SPARC_PCPLT22: case R_SPARC_PC_LM22: *(ub32 *)loc |= bits(S + A - P, 31, 10); break; case R_SPARC_OLO10: *(ub32 *)loc |= bits(bits(S + A, 9, 0) + rel.r_type_data, 12, 0); break; case R_SPARC_HH22: *(ub32 *)loc |= bits(S + A, 63, 42); break; case R_SPARC_HM10: *(ub32 *)loc |= bits(S + A, 41, 32); break; case R_SPARC_PC_HH22: *(ub32 *)loc |= bits(S + A - P, 63, 42); break; case R_SPARC_PC_HM10: *(ub32 *)loc |= bits(S + A - P, 41, 32); break; case R_SPARC_HIX22: *(ub32 *)loc |= bits(~(S + A), 31, 10); break; case R_SPARC_LOX10: *(ub32 *)loc |= bits(S + A, 9, 0) | 0b1'1100'0000'0000; break; case R_SPARC_H44: *(ub32 *)loc |= bits(S + A, 43, 22); break; case R_SPARC_M44: *(ub32 *)loc |= bits(S + A, 21, 12); break; case R_SPARC_L44: *(ub32 *)loc |= bits(S + A, 11, 0); break; case R_SPARC_TLS_GD_HI22: *(ub32 *)loc |= bits(sym.get_tlsgd_addr(ctx) + A - GOT, 31, 10); break; case R_SPARC_TLS_GD_LO10: *(ub32 *)loc |= bits(sym.get_tlsgd_addr(ctx) + A - GOT, 9, 0); break; case R_SPARC_TLS_GD_CALL: case R_SPARC_TLS_LDM_CALL: if (ctx.arg.is_static) *(ub32 *)loc |= bits(ctx.sparc_tls_get_addr->shdr.sh_addr + A - P, 31, 2); else *(ub32 *)loc |= bits(ctx.tls_get_addr->get_addr(ctx) + A - P, 31, 2); break; case R_SPARC_TLS_LDM_HI22: *(ub32 *)loc |= bits(ctx.got->get_tlsld_addr(ctx) + A - GOT, 31, 10); break; case R_SPARC_TLS_LDM_LO10: *(ub32 *)loc |= bits(ctx.got->get_tlsld_addr(ctx) + A - GOT, 9, 0); break; case R_SPARC_TLS_LDO_HIX22: *(ub32 *)loc |= bits(S + A - ctx.tls_begin, 31, 10); break; case R_SPARC_TLS_LDO_LOX10: *(ub32 *)loc |= bits(S + A - ctx.tls_begin, 9, 0); break; case R_SPARC_TLS_IE_HI22: *(ub32 *)loc |= bits(sym.get_gottp_addr(ctx) + A - GOT, 31, 10); break; case R_SPARC_TLS_IE_LO10: *(ub32 *)loc |= bits(sym.get_gottp_addr(ctx) + A - GOT, 9, 0); break; case R_SPARC_TLS_LE_HIX22: *(ub32 *)loc |= bits(~(S + A - ctx.tp_addr), 31, 10); break; case R_SPARC_TLS_LE_LOX10: *(ub32 *)loc |= bits(S + A - ctx.tp_addr, 9, 0) | 0b1'1100'0000'0000; break; case R_SPARC_SIZE32: *(ub32 *)loc = sym.esym().st_size + A; break; case R_SPARC_TLS_GD_ADD: case R_SPARC_TLS_LDM_ADD: case R_SPARC_TLS_LDO_ADD: case R_SPARC_TLS_IE_LD: case R_SPARC_TLS_IE_LDX: case R_SPARC_TLS_IE_ADD: break; default: unreachable(); } #undef S #undef A #undef P #undef G #undef GOT } } template <> void InputSection::apply_reloc_nonalloc(Context &ctx, u8 *base) { std::span> rels = get_rels(ctx); for (i64 i = 0; i < rels.size(); i++) { const ElfRel &rel = rels[i]; if (rel.r_type == R_NONE) continue; Symbol &sym = *file.symbols[rel.r_sym]; u8 *loc = base + rel.r_offset; if (!sym.file) { record_undef_error(ctx, rel); continue; } SectionFragment *frag; i64 frag_addend; std::tie(frag, frag_addend) = get_fragment(ctx, rel); #define S (frag ? frag->get_addr(ctx) : sym.get_addr(ctx)) #define A (frag ? frag_addend : (i64)rel.r_addend) switch (rel.r_type) { case R_SPARC_64: case R_SPARC_UA64: if (std::optional val = get_tombstone(sym, frag)) *(ub64 *)loc = *val; else *(ub64 *)loc = S + A; break; case R_SPARC_32: case R_SPARC_UA32: *(ub32 *)loc = S + A; break; case R_SPARC_TLS_DTPOFF32: *(ub32 *)loc = S + A - ctx.tls_begin; break; case R_SPARC_TLS_DTPOFF64: *(ub64 *)loc = S + A - ctx.tls_begin; break; default: Fatal(ctx) << *this << ": apply_reloc_nonalloc: " << rel; } #undef S #undef A } } template <> void InputSection::scan_relocations(Context &ctx) { assert(shdr().sh_flags & SHF_ALLOC); this->reldyn_offset = file.num_dynrel * sizeof(ElfRel); std::span> rels = get_rels(ctx); // Scan relocations for (i64 i = 0; i < rels.size(); i++) { const ElfRel &rel = rels[i]; if (rel.r_type == R_NONE) continue; Symbol &sym = *file.symbols[rel.r_sym]; if (!sym.file) { record_undef_error(ctx, rel); continue; } if (sym.is_ifunc()) sym.flags |= (NEEDS_GOT | NEEDS_PLT); switch (rel.r_type) { case R_SPARC_64: scan_abs_dyn_rel(ctx, sym, rel); break; case R_SPARC_8: case R_SPARC_5: case R_SPARC_6: case R_SPARC_7: case R_SPARC_10: case R_SPARC_11: case R_SPARC_13: case R_SPARC_16: case R_SPARC_22: case R_SPARC_32: case R_SPARC_REGISTER: case R_SPARC_UA16: case R_SPARC_UA32: case R_SPARC_UA64: case R_SPARC_PC_HM10: case R_SPARC_OLO10: case R_SPARC_LOX10: case R_SPARC_HM10: case R_SPARC_M44: case R_SPARC_HIX22: case R_SPARC_LO10: case R_SPARC_L44: case R_SPARC_LM22: case R_SPARC_HI22: case R_SPARC_H44: case R_SPARC_HH22: scan_abs_rel(ctx, sym, rel); break; case R_SPARC_PLT32: case R_SPARC_WPLT30: case R_SPARC_WDISP30: case R_SPARC_HIPLT22: case R_SPARC_LOPLT10: case R_SPARC_PCPLT32: case R_SPARC_PCPLT22: case R_SPARC_PCPLT10: case R_SPARC_PLT64: if (sym.is_imported) sym.flags |= NEEDS_PLT; break; case R_SPARC_GOT13: case R_SPARC_GOT10: case R_SPARC_GOT22: case R_SPARC_GOTDATA_HIX22: sym.flags |= NEEDS_GOT; break; case R_SPARC_GOTDATA_OP_HIX22: if (sym.is_imported) sym.flags |= NEEDS_GOT; break; case R_SPARC_DISP16: case R_SPARC_DISP32: case R_SPARC_DISP64: case R_SPARC_DISP8: case R_SPARC_PC10: case R_SPARC_PC22: case R_SPARC_PC_LM22: case R_SPARC_WDISP16: case R_SPARC_WDISP19: case R_SPARC_WDISP22: case R_SPARC_PC_HH22: scan_pcrel_rel(ctx, sym, rel); break; case R_SPARC_TLS_GD_HI22: sym.flags |= NEEDS_TLSGD; break; case R_SPARC_TLS_LDM_HI22: ctx.needs_tlsld = true; break; case R_SPARC_TLS_IE_HI22: sym.flags |= NEEDS_GOTTP; break; case R_SPARC_TLS_GD_CALL: case R_SPARC_TLS_LDM_CALL: if (!ctx.arg.is_static && ctx.tls_get_addr->is_imported) ctx.tls_get_addr->flags |= NEEDS_PLT; break; case R_SPARC_GOTDATA_OP_LOX10: case R_SPARC_GOTDATA_OP: case R_SPARC_GOTDATA_LOX10: case R_SPARC_TLS_GD_LO10: case R_SPARC_TLS_GD_ADD: case R_SPARC_TLS_LDM_LO10: case R_SPARC_TLS_LDM_ADD: case R_SPARC_TLS_LDO_HIX22: case R_SPARC_TLS_LDO_LOX10: case R_SPARC_TLS_LDO_ADD: case R_SPARC_TLS_IE_ADD: case R_SPARC_TLS_IE_LD: case R_SPARC_TLS_IE_LDX: case R_SPARC_TLS_IE_LO10: case R_SPARC_TLS_LE_HIX22: case R_SPARC_TLS_LE_LOX10: case R_SPARC_SIZE32: break; default: Fatal(ctx) << *this << ": scan_relocations: " << rel; } } } // __tls_get_addr is not defined by libc.a, so we can't use that function // in statically-linked executables. This section provides a replacement. void SparcTlsGetAddrSection::copy_buf(Context &ctx) { ub32 *buf = (ub32 *)(ctx.buf + this->shdr.sh_offset); static const ub32 insn[] = { 0x0300'0000, // sethi %hi(TP_SIZE), %g1 0x8210'6000, // or %g1, %lo(TP_SIZE), %g1 0x8221'c001, // sub %g7, %g1, %g1 0xd05a'2008, // ldx [ %o0 + 8 ], %o0 0x81c3'e008, // retl 0x9000'4008, // add %g1, %o0, %o0 }; assert(this->shdr.sh_size == sizeof(insn)); memcpy(buf, insn, sizeof(insn)); buf[0] |= bits(ctx.tp_addr - ctx.tls_begin, 31, 10); buf[1] |= bits(ctx.tp_addr - ctx.tls_begin, 9, 0); } } // namespace mold::elf