#include "Rts.h" #if defined(darwin_HOST_OS) || defined(ios_HOST_OS) /* for roundUpToPage */ #include "sm/OSMem.h" #include "RtsUtils.h" #include "GetEnv.h" #include "LinkerInternals.h" #include "linker/MachO.h" #include "linker/CacheFlush.h" #include "linker/SymbolExtras.h" #include #include #include #include #include #include #include #if defined(HAVE_SYS_MMAN_H) && RTS_LINKER_USE_MMAP # include #endif #if defined(x86_64_HOST_ARCH) # include #endif #if defined(aarch64_HOST_ARCH) # include #endif /* Support for MachO linking on Darwin/MacOS X by Wolfgang Thaller (wolfgang.thaller@gmx.net) I hereby formally apologize for the hackish nature of this code. Things that need to be done: *) implement ocVerifyImage_MachO *) add still more sanity checks. */ #if defined(aarch64_HOST_ARCH) /* aarch64 linker by moritz angermann */ /* often times we need to extend some value of certain number of bits * int an int64_t for e.g. relative offsets. */ int64_t signExtend(uint64_t val, uint8_t bits); /* Helper functions to check some instruction properties */ bool isVectorPp(uint32_t *p); bool isLoadStore(uint32_t *p); /* aarch64 relocations may contain an addend already in the position * where we want to write the address offset to. Thus decoding as well * as encoding is needed. */ bool fitsBits(size_t bits, int64_t value); int64_t decodeAddend(ObjectCode * oc, Section * section, MachORelocationInfo * ri); void encodeAddend(ObjectCode * oc, Section * section, MachORelocationInfo * ri, int64_t addend); /* finding and making stubs. We don't need to care about the symbol they * represent. As long as two stubs point to the same address, they are identical */ bool findStub(Section * section, void ** addr); bool makeStub(Section * section, void ** addr); void freeStubs(Section * section); /* Global Offset Table logic */ bool isGotLoad(MachORelocationInfo * ri); bool needGotSlot(MachONList * symbol); bool makeGot(ObjectCode * oc); void freeGot(ObjectCode * oc); #endif /* aarch64_HOST_ARCH */ /* * Initialize some common data in the object code so we don't have to * continuously look up the addresses. */ void ocInit_MachO(ObjectCode * oc) { ocDeinit_MachO(oc); oc->info = (struct ObjectCodeFormatInfo*)stgCallocBytes( 1, sizeof *oc->info, "ocInit_MachO(ObjectCodeFormatInfo)"); oc->info->header = (MachOHeader *) oc->image; oc->info->symCmd = NULL; oc->info->segCmd = NULL; oc->info->dsymCmd = NULL; MachOLoadCommand *lc = (MachOLoadCommand*)(oc->image + sizeof(MachOHeader)); for(size_t i = 0; i < oc->info->header->ncmds; i++) { if (lc->cmd == LC_SEGMENT || lc->cmd == LC_SEGMENT_64) { oc->info->segCmd = (MachOSegmentCommand*) lc; } else if (lc->cmd == LC_SYMTAB) { oc->info->symCmd = (MachOSymtabCommand*) lc; } else if (lc->cmd == LC_DYSYMTAB) { oc->info->dsymCmd = (MachODsymtabCommand*) lc; } lc = (MachOLoadCommand *) ( ((char*)lc) + lc->cmdsize ); } if (NULL == oc->info->segCmd) { barf("ocGetNames_MachO: no segment load command"); } oc->info->macho_sections = (MachOSection*) (oc->info->segCmd+1); oc->n_sections = oc->info->segCmd->nsects; oc->info->nlist = oc->info->symCmd == NULL ? NULL : (MachONList *)(oc->image + oc->info->symCmd->symoff); oc->info->names = oc->info->symCmd == NULL ? NULL : (oc->image + oc->info->symCmd->stroff); /* If we have symbols, allocate and fill the macho_symbols * This will make relocation easier. */ oc->info->n_macho_symbols = 0; oc->info->macho_symbols = NULL; if(NULL != oc->info->nlist) { oc->info->n_macho_symbols = oc->info->symCmd->nsyms; oc->info->macho_symbols = (MachOSymbol*)stgCallocBytes( oc->info->symCmd->nsyms, sizeof(MachOSymbol), "ocInit_MachO(MachOSymbol)"); for(uint32_t i = 0; i < oc->info->symCmd->nsyms; i++) { oc->info->macho_symbols[i].name = oc->info->names + oc->info->nlist[i].n_un.n_strx; oc->info->macho_symbols[i].nlist = &oc->info->nlist[i]; /* We don't have an address for this symbol yet; this * will be populated during ocGetNames_MachO. Hence init * with NULL */ oc->info->macho_symbols[i].addr = NULL; oc->info->macho_symbols[i].got_addr = NULL; } } } void ocDeinit_MachO(ObjectCode * oc) { if (oc->info != NULL) { if(oc->info->n_macho_symbols > 0) { stgFree(oc->info->macho_symbols); } #if defined(aarch64_HOST_ARCH) freeGot(oc); for(int i = 0; i < oc->n_sections; i++) { freeStubs(&oc->sections[i]); } #endif stgFree(oc->info); oc->info = NULL; } } static int resolveImports( ObjectCode* oc, MachOSection *sect, // ptr to lazy or non-lazy symbol pointer section unsigned long *indirectSyms); #if NEED_SYMBOL_EXTRAS #if defined(x86_64_HOST_ARCH) || defined(aarch64_HOST_ARCH) int ocAllocateExtras_MachO(ObjectCode* oc) { IF_DEBUG(linker, debugBelch("ocAllocateExtras_MachO: start\n")); if (NULL != oc->info->symCmd) { IF_DEBUG(linker, debugBelch("ocAllocateExtras_MachO: allocate %d symbols\n", oc->info->symCmd->nsyms)); IF_DEBUG(linker, debugBelch("ocAllocateExtras_MachO: done\n")); return ocAllocateExtras(oc, oc->info->symCmd->nsyms, 0, 0); } IF_DEBUG(linker, debugBelch("ocAllocateExtras_MachO: allocated no symbols\n")); IF_DEBUG(linker, debugBelch("ocAllocateExtras_MachO: done\n")); return ocAllocateExtras(oc, 0, 0, 0); } #else #error Unknown MachO architecture #endif /* HOST_ARCH */ #endif /* NEED_SYMBOL_EXTRAS */ int ocVerifyImage_MachO(ObjectCode * oc) { char *image = (char*) oc->image; MachOHeader *header = (MachOHeader*) image; IF_DEBUG(linker, debugBelch("ocVerifyImage_MachO: start\n")); if(header->magic != MH_MAGIC_64) { errorBelch("Could not load image %s: bad magic!\n" " Expected %08x (64bit), got %08x%s\n", oc->fileName, MH_MAGIC_64, header->magic, header->magic == MH_MAGIC ? " (32bit)." : "."); return 0; } // FIXME: do some more verifying here IF_DEBUG(linker, debugBelch("ocVerifyImage_MachO: done\n")); return 1; } static int resolveImports( ObjectCode* oc, MachOSection *sect, // ptr to lazy or non-lazy symbol pointer section unsigned long *indirectSyms) { size_t itemSize = 4; IF_DEBUG(linker, debugBelch("resolveImports: start\n")); for(unsigned i = 0; i * itemSize < sect->size; i++) { // according to otool, reserved1 contains the first index into the // indirect symbol table unsigned long indirectSymbolIndex = indirectSyms[sect->reserved1+i]; MachOSymbol *symbol = &oc->info->macho_symbols[indirectSymbolIndex]; SymbolAddr* addr = NULL; IF_DEBUG(linker, debugBelch("resolveImports: resolving %s\n", symbol->name)); if ((symbol->nlist->n_type & N_TYPE) == N_UNDF && (symbol->nlist->n_type & N_EXT) && (symbol->nlist->n_value != 0)) { addr = (SymbolAddr*) (symbol->nlist->n_value); IF_DEBUG(linker, debugBelch("resolveImports: undefined external %s has value %p\n", symbol->name, addr)); } else { addr = lookupSymbol_(symbol->name); IF_DEBUG(linker, debugBelch("resolveImports: looking up %s, %p\n", symbol->name, addr)); } if (addr == NULL) { errorBelch("\nlookupSymbol failed in resolveImports\n" "%s: unknown symbol `%s'", oc->fileName, symbol->name); return 0; } ASSERT(addr); checkProddableBlock(oc, ((void**)(oc->image + sect->offset)) + i, sizeof(void *)); ((void**)(oc->image + sect->offset))[i] = addr; } IF_DEBUG(linker, debugBelch("resolveImports: done\n")); return 1; } #if defined(aarch64_HOST_ARCH) /* aarch64 linker by moritz angermann */ int64_t signExtend(uint64_t val, uint8_t bits) { return (int64_t)(val << (64-bits)) >> (64-bits); } bool isVectorOp(uint32_t *p) { return (*p & 0x04800000) == 0x04800000; } bool isLoadStore(uint32_t *p) { return (*p & 0x3B000000) == 0x39000000; } int64_t decodeAddend(ObjectCode * oc, Section * section, MachORelocationInfo * ri) { /* the instruction. It is 32bit wide */ uint32_t * p = (uint32_t*)((uint8_t*)section->start + ri->r_address); checkProddableBlock(oc, (void*)p, 1 << ri->r_length); switch(ri->r_type) { case ARM64_RELOC_UNSIGNED: case ARM64_RELOC_SUBTRACTOR: { switch (ri->r_length) { case 0: return signExtend(*(uint8_t*)p, 8 * (1 << ri->r_length)); case 1: return signExtend(*(uint16_t*)p, 8 * (1 << ri->r_length)); case 2: return signExtend(*(uint32_t*)p, 8 * (1 << ri->r_length)); case 3: return signExtend(*(uint64_t*)p, 8 * (1 << ri->r_length)); default: barf("Unsupported r_length (%d) for SUBTRACTOR relocation", ri->r_length); } } case ARM64_RELOC_BRANCH26: /* take the lower 26 bits and shift them by 2. The last two are * implicitly 0 (as the instructions must be aligned!) and sign * extend to 64 bits. */ return signExtend( (*p & 0x03FFFFFF) << 2, 28 ); case ARM64_RELOC_PAGE21: case ARM64_RELOC_GOT_LOAD_PAGE21: /* take the instruction bits masked with 0x6 (0110), and push them * down. into the last two bits, and mask in the * * the 21 bits are encoded as follows in the instruction * * -**- ---* **** **** **** **** ***-- ---- * ^^ * ''-- these are the low two bits. */ return signExtend( (*p & 0x60000000) >> 29 | ((*p & 0x01FFFFE0) >> 3) << 12, 33); case ARM64_RELOC_PAGEOFF12: case ARM64_RELOC_GOT_LOAD_PAGEOFF12: { /* the 12 bits for the page offset are encoded from bit 11 onwards * * ---- ---- --** **** **** **-- ---- ---- */ int64_t a = (*p & 0x003FFC00) >> 10; int shift = 0; if (isLoadStore(p)) { shift = (*p >> 30) & 0x3; if(0 == shift && isVectorOp(p)) { shift = 4; } } return a << shift; } } barf("unsupported relocation type: %d\n", ri->r_type); } inline bool fitsBits(size_t bits, int64_t value) { if(bits == 64) return true; if(bits > 64) barf("fits_bits with %d bits and an 64bit integer!", bits); return 0 == (value >> bits) // All bits off: 0 || -1 == (value >> bits); // All bits on: -1 } void encodeAddend(ObjectCode * oc, Section * section, MachORelocationInfo * ri, int64_t addend) { uint32_t * p = (uint32_t*)((uint8_t*)section->start + ri->r_address); checkProddableBlock(oc, (void*)p, 1 << ri->r_length); switch (ri->r_type) { case ARM64_RELOC_UNSIGNED: case ARM64_RELOC_SUBTRACTOR: { if(!fitsBits(8 << ri->r_length, addend)) barf("Relocation out of range for UNSIGNED/SUBTRACTOR"); switch (ri->r_length) { case 0: *(uint8_t*)p = (uint8_t)addend; break; case 1: *(uint16_t*)p = (uint16_t)addend; break; case 2: *(uint32_t*)p = (uint32_t)addend; break; case 3: *(uint64_t*)p = (uint64_t)addend; break; default: barf("Unsupported r_length (%d) for SUBTRACTOR relocation", ri->r_length); } return; } case ARM64_RELOC_BRANCH26: { /* We can only store 26 bits in the instruction, due to alignment we * do not need the last two bits of the value. If the value >> 2 * still exceeds 26bits, we won't be able to reach it. */ if(!fitsBits(26, addend >> 2)) barf("Relocation target for BRACH26 out of range."); *p = (*p & 0xFC000000) | ((uint32_t)(addend >> 2) & 0x03FFFFFF); return; } case ARM64_RELOC_PAGE21: case ARM64_RELOC_GOT_LOAD_PAGE21: { /* We store 21bits, in bits 6 to 24, and bits 30 and 31. * The encoded value describes a multiple of 4k pages, and together * with the PAGEOFF12 relocation allows to address a relative range * of +-4GB. */ if(!fitsBits(21, addend >> 12)) barf("Relocation target for PAGE21 out of range."); *p = (*p & 0x9F00001F) | (uint32_t)((addend << 17) & 0x60000000) | (uint32_t)((addend >> 9) & 0x00FFFFE0); return; } case ARM64_RELOC_PAGEOFF12: case ARM64_RELOC_GOT_LOAD_PAGEOFF12: { /* Store an offset into a page (4k). Depending on the instruction * the bits are stored at slightly different positions. */ if(!fitsBits(12, addend)) barf("Relocation target for PAGEOFF12 out or range."); int shift = 0; if(isLoadStore(p)) { shift = (*p >> 30) & 0x3; if(0 == shift && isVectorOp(p)) { shift = 4; } } *p = (*p & 0xFFC003FF) | ((uint32_t)(addend >> shift << 10) & 0x003FFC00); return; } } barf("unsupported relocation type: %d\n", ri->r_type); } bool isGotLoad(struct relocation_info * ri) { return ri->r_type == ARM64_RELOC_GOT_LOAD_PAGE21 || ri->r_type == ARM64_RELOC_GOT_LOAD_PAGEOFF12; } /* This is very similar to makeSymbolExtra * However, as we load sections into different * pages, that may be further apart than * branching allows, we'll use some extra * space at the end of each section allocated * for stubs. */ bool findStub(Section * section, void ** addr) { for(Stub * s = section->info->stubs; s != NULL; s = s->next) { if(s->target == *addr) { *addr = s->addr; return EXIT_SUCCESS; } } return EXIT_FAILURE; } bool makeStub(Section * section, void ** addr) { Stub * s = stgCallocBytes(1, sizeof(Stub), "makeStub(Stub)"); s->target = *addr; s->addr = (uint8_t*)section->info->stub_offset + ((8+8)*section->info->nstubs) + 8; s->next = NULL; /* target address */ *(uint64_t*)((uint8_t*)s->addr - 8) = (uint64_t)s->target; /* ldr x16, - (8 bytes) */ *(uint32_t*)(s->addr) = (uint32_t)0x58ffffd0; /* br x16 */ *(uint32_t*)((uint8_t*)s->addr + 4) = (uint32_t)0xd61f0200; if(section->info->nstubs == 0) { /* no stubs yet, let's just create this one */ section->info->stubs = s; } else { Stub * tail = section->info->stubs; while(tail->next != NULL) tail = tail->next; tail->next = s; } section->info->nstubs += 1; *addr = s->addr; return EXIT_SUCCESS; } void freeStubs(Section * section) { if(section->info->nstubs == 0) return; Stub * last = section->info->stubs; while(last->next != NULL) { Stub * t = last; last = last->next; stgFree(t); } section->info->stubs = NULL; section->info->nstubs = 0; } /* * Check if we need a global offset table slot for a * given symbol */ bool needGotSlot(MachONList * symbol) { return (symbol->n_type & N_EXT) /* is an external symbol */ && (N_UNDF == (symbol->n_type & N_TYPE) /* and is undefined */ || NO_SECT != symbol->n_sect); /* or is defined in a * different section */ } bool makeGot(ObjectCode * oc) { size_t got_slots = 0; for(size_t i=0; i < oc->info->n_macho_symbols; i++) if(needGotSlot(oc->info->macho_symbols[i].nlist)) got_slots += 1; if(got_slots > 0) { oc->info->got_size = got_slots * sizeof(void*); oc->info->got_start = mmap(NULL, oc->info->got_size, PROT_READ | PROT_WRITE, MAP_ANON | MAP_PRIVATE, -1, 0); if( oc->info->got_start == MAP_FAILED ) { barf("MAP_FAILED. errno=%d", errno ); return EXIT_FAILURE; } /* update got_addr */ size_t slot = 0; for(size_t i=0; i < oc->info->n_macho_symbols; i++) if(needGotSlot(oc->info->macho_symbols[i].nlist)) oc->info->macho_symbols[i].got_addr = ((uint8_t*)oc->info->got_start) + (slot++ * sizeof(void *)); } return EXIT_SUCCESS; } void freeGot(ObjectCode * oc) { munmap(oc->info->got_start, oc->info->got_size); oc->info->got_start = NULL; oc->info->got_size = 0; } static int relocateSectionAarch64(ObjectCode * oc, Section * section) { if(section->size == 0) return 1; /* at this point, we have: * * - loaded the sections (potentially into non-contiguous memory), * (in ocGetNames_MachO) * - registered exported symbols * (in ocGetNames_MachO) * - and fixed the nlist[i].n_value for common storage symbols (N_UNDF, * N_EXT and n_value != 0) so that they point into the common storage. * (in ocGetNames_MachO) * - All oc->symbols however should now point at the right place. */ /* we need to care about the explicit addend */ int64_t explicit_addend = 0; size_t nreloc = section->info->macho_section->nreloc; for(size_t i = 0; i < nreloc; i++) { MachORelocationInfo * ri = §ion->info->relocation_info[i]; switch (ri->r_type) { case ARM64_RELOC_UNSIGNED: { MachOSymbol* symbol = &oc->info->macho_symbols[ri->r_symbolnum]; int64_t addend = decodeAddend(oc, section, ri); uint64_t value = 0; if(symbol->nlist->n_type & N_EXT) { /* external symbols should be able to be * looked up via the lookupSymbol_ function. * Either through the global symbol hashmap * or asking the system, if not found * in the symbol hashmap */ value = (uint64_t)lookupSymbol_((char*)symbol->name); if(!value) barf("Could not lookup symbol: %s!", symbol->name); } else { value = (uint64_t)symbol->addr; // address of the symbol. } encodeAddend(oc, section, ri, value + addend); break; } case ARM64_RELOC_SUBTRACTOR: { MachOSymbol* symbol = &oc->info->macho_symbols[ri->r_symbolnum]; // subtractor and unsigned are called in tandem: // first pc <- pc - symbol address (SUBTRACTOR) // second pc <- pc + symbol address (UNSIGNED) // to achieve pc <- pc + target - base. // // the current implementation uses absolute addresses, // which is simpler than trying to do this section // relative, but could more easily lead to overflow. // if(!(i+1 < nreloc) || !(section->info->relocation_info[i+1].r_type == ARM64_RELOC_UNSIGNED)) barf("SUBTRACTOR relocation *must* be followed by UNSIGNED relocation."); int64_t addend = decodeAddend(oc, section, ri); int64_t value = (uint64_t)symbol->addr; encodeAddend(oc, section, ri, addend - value); break; } case ARM64_RELOC_BRANCH26: { MachOSymbol* symbol = &oc->info->macho_symbols[ri->r_symbolnum]; // pre-existing addend int64_t addend = decodeAddend(oc, section, ri); // address of the branch (b/bl) instruction. uint64_t pc = (uint64_t)section->start + ri->r_address; uint64_t value = 0; if(symbol->nlist->n_type & N_EXT) { value = (uint64_t)lookupSymbol_((char*)symbol->name); if(!value) barf("Could not lookup symbol: %s!", symbol->name); } else { value = (uint64_t)symbol->addr; // address of the symbol. } if((value - pc + addend) >> (2 + 26)) { /* we need a stub */ /* check if we already have that stub */ if(findStub(section, (void**)&value)) { /* did not find it. Crete a new stub. */ if(makeStub(section, (void**)&value)) { barf("could not find or make stub"); } } } encodeAddend(oc, section, ri, value - pc + addend); break; } case ARM64_RELOC_PAGE21: case ARM64_RELOC_GOT_LOAD_PAGE21: { MachOSymbol* symbol = &oc->info->macho_symbols[ri->r_symbolnum]; int64_t addend = decodeAddend(oc, section, ri); if(!(explicit_addend == 0 || addend == 0)) barf("explicit_addend and addend can't be set at the same time."); uint64_t pc = (uint64_t)section->start + ri->r_address; uint64_t value = (uint64_t)(isGotLoad(ri) ? symbol->got_addr : symbol->addr); encodeAddend(oc, section, ri, ((value + addend + explicit_addend) & (-4096)) - (pc & (-4096))); // reset, just in case. explicit_addend = 0; break; } case ARM64_RELOC_PAGEOFF12: case ARM64_RELOC_GOT_LOAD_PAGEOFF12: { MachOSymbol* symbol = &oc->info->macho_symbols[ri->r_symbolnum]; int64_t addend = decodeAddend(oc, section, ri); if(!(explicit_addend == 0 || addend == 0)) barf("explicit_addend and addend can't be set at the same time."); uint64_t value = (uint64_t)(isGotLoad(ri) ? symbol->got_addr : symbol->addr); encodeAddend(oc, section, ri, 0xFFF & (value + addend + explicit_addend)); // reset, just in case. explicit_addend = 0; break; } case ARM64_RELOC_ADDEND: { explicit_addend = signExtend(ri->r_symbolnum, 24); if(!(i+1 < nreloc) || !(section->info->relocation_info[i+1].r_type == ARM64_RELOC_PAGE21 || section->info->relocation_info[i+1].r_type == ARM64_RELOC_PAGEOFF12)) barf("ADDEND relocation *must* be followed by PAGE or PAGEOFF relocation"); break; } default: { barf("Relocation of type: %d not (yet) supported!\n", ri->r_type); } } } return 1; } #endif /* aarch64_HOST_ARCH */ #if defined(x86_64_HOST_ARCH) static int relocateSection(ObjectCode* oc, int curSection) { Section * sect = &oc->sections[curSection]; MachOSection * msect = sect->info->macho_section; // for access convenience MachORelocationInfo * relocs = sect->info->relocation_info; MachOSymbol * symbols = oc->info->macho_symbols; IF_DEBUG(linker, debugBelch("relocateSection %d (%s, %s): start\n", curSection, msect->segname, msect->sectname)); if(!strcmp(msect->sectname,"__la_symbol_ptr")) return 1; else if(!strcmp(msect->sectname,"__nl_symbol_ptr")) return 1; else if(!strcmp(msect->sectname,"__la_sym_ptr2")) return 1; else if(!strcmp(msect->sectname,"__la_sym_ptr3")) return 1; IF_DEBUG(linker, debugBelch("relocateSection: number of relocations: %d\n", msect->nreloc)); for(uint32_t i = 0; i < msect->nreloc; i++) { MachORelocationInfo *reloc = &relocs[i]; char *thingPtr = (char *) sect->start + reloc->r_address; uint64_t thing; /* We shouldn't need to initialise this, but gcc on OS X 64 bit complains that it may be used uninitialized if we don't */ uint64_t value = 0; uint64_t baseValue; int type = reloc->r_type; int relocLenBytes; int nextInstrAdj = 0; IF_DEBUG(linker, debugBelch("relocateSection: relocation %d\n", i)); IF_DEBUG(linker, debugBelch(" : type = %d\n", reloc->r_type)); IF_DEBUG(linker, debugBelch(" : address = %d\n", reloc->r_address)); IF_DEBUG(linker, debugBelch(" : symbolnum = %u\n", reloc->r_symbolnum)); IF_DEBUG(linker, debugBelch(" : pcrel = %d\n", reloc->r_pcrel)); IF_DEBUG(linker, debugBelch(" : length = %d\n", reloc->r_length)); IF_DEBUG(linker, debugBelch(" : extern = %d\n", reloc->r_extern)); IF_DEBUG(linker, debugBelch(" : type = %d\n", reloc->r_type)); switch(reloc->r_length) { case 0: thing = *(uint8_t*)thingPtr; relocLenBytes = 1; break; case 1: thing = *(uint16_t*)thingPtr; relocLenBytes = 2; break; case 2: thing = *(uint32_t*)thingPtr; relocLenBytes = 4; break; case 3: thing = *(uint64_t*)thingPtr; relocLenBytes = 8; break; default: barf("Unknown size."); } checkProddableBlock(oc,thingPtr,relocLenBytes); /* * With SIGNED_N the relocation is not at the end of the * instruction and baseValue needs to be adjusted accordingly. */ switch (type) { case X86_64_RELOC_SIGNED_1: nextInstrAdj = 1; break; case X86_64_RELOC_SIGNED_2: nextInstrAdj = 2; break; case X86_64_RELOC_SIGNED_4: nextInstrAdj = 4; break; } baseValue = (uint64_t)thingPtr + relocLenBytes + nextInstrAdj; IF_DEBUG(linker, debugBelch("relocateSection: length = %d, thing = %" PRId64 ", baseValue = %p\n", reloc->r_length, thing, (char *)baseValue)); if (type == X86_64_RELOC_GOT || type == X86_64_RELOC_GOT_LOAD) { MachOSymbol *symbol = &symbols[reloc->r_symbolnum]; SymbolName* nm = symbol->name; SymbolAddr* addr = NULL; IF_DEBUG(linker, debugBelch("relocateSection: making jump island for %s, extern = %d, X86_64_RELOC_GOT\n", nm, reloc->r_extern)); if (reloc->r_extern == 0) { errorBelch("\nrelocateSection: global offset table relocation for symbol with r_extern == 0\n"); } if (symbol->nlist->n_type & N_EXT) { // The external bit is set, meaning the symbol is exported, // and therefore can be looked up in this object module's // symtab, or it is undefined, meaning dlsym must be used // to resolve it. addr = lookupSymbol_(nm); IF_DEBUG(linker, debugBelch("relocateSection: looked up %s, " "external X86_64_RELOC_GOT or X86_64_RELOC_GOT_LOAD\n" " : addr = %p\n", nm, addr)); if (addr == NULL) { errorBelch("\nlookupSymbol failed in relocateSection (RELOC_GOT)\n" "%s: unknown symbol `%s'", oc->fileName, nm); return 0; } } else { IF_DEBUG(linker, debugBelch("relocateSection: %s is not an exported symbol\n", nm)); // The symbol is not exported, or defined in another // module, so it must be in the current object module, // at the location given by the section index and // symbol address (symbol->n_value) if ((symbol->nlist->n_type & N_TYPE) == N_SECT) { if (symbol->addr == NULL) { errorBelch("relocateSection: address of internal symbol %s was not resolved\n", nm); return 0; } addr = symbol->addr; IF_DEBUG(linker, debugBelch("relocateSection: calculated relocation of " "non-external X86_64_RELOC_GOT or X86_64_RELOC_GOT_LOAD\n")); IF_DEBUG(linker, debugBelch(" : addr = %p\n", addr)); } else { errorBelch("\nrelocateSection: %s is not exported," " and should be defined in a section, but isn't!\n", nm); return 0; } } // creates a jump island for every relocation entry for a symbol // TODO (AP): use got_addr to store the loc. of a jump island to reuse later value = (uint64_t) &makeSymbolExtra(oc, reloc->r_symbolnum, (unsigned long)addr)->addr; type = X86_64_RELOC_SIGNED; } else if (reloc->r_extern) { MachOSymbol *symbol = &symbols[reloc->r_symbolnum]; SymbolName* nm = symbol->name; SymbolAddr* addr = NULL; IF_DEBUG(linker, debugBelch("relocateSection: looking up external symbol %s\n", nm)); IF_DEBUG(linker, debugBelch(" : type = %d\n", symbol->nlist->n_type)); IF_DEBUG(linker, debugBelch(" : sect = %d\n", symbol->nlist->n_sect)); IF_DEBUG(linker, debugBelch(" : desc = %d\n", symbol->nlist->n_desc)); IF_DEBUG(linker, debugBelch(" : value = %p\n", (void *)symbol->nlist->n_value)); if ((symbol->nlist->n_type & N_TYPE) == N_SECT) { ASSERT(symbol->addr != NULL); value = (uint64_t) symbol->addr; IF_DEBUG(linker, debugBelch("relocateSection, defined external symbol %s, relocated address %p\n", nm, (void *)value)); } else { addr = lookupSymbol_(nm); if (addr == NULL) { errorBelch("\nlookupSymbol failed in relocateSection (relocate external)\n" "%s: unknown symbol `%s'", oc->fileName, nm); return 0; } value = (uint64_t) addr; IF_DEBUG(linker, debugBelch("relocateSection: external symbol %s, address %p\n", nm, (void *)value)); } } else { /* Since the relocation is internal, r_symbolnum contains a section * number relative to which the relocation is. Depending on whether * the relocation is unsigned or signed, the given displacement is * relative to the image or the section respectively. * * For instance, in a signed case: * thing = (1) * + * (1) needs to be updated due to different section placement in memory. */ CHECKM(reloc->r_symbolnum > 0, "relocateSection: unsupported r_symbolnum = %" PRIu32 " < 1 for internal relocation", reloc->r_symbolnum); int targetSecNum = reloc->r_symbolnum - 1; // sec numbers start with 1 Section * targetSec = &oc->sections[targetSecNum]; MachOSection * targetMacho = targetSec->info->macho_section; IF_DEBUG(linker, debugBelch("relocateSection: internal relocation relative to section %d (%s, %s)\n", targetSecNum, targetMacho->segname, targetMacho->sectname)); switch (type) { case X86_64_RELOC_UNSIGNED: { CHECKM(thing >= targetMacho->addr, "relocateSection: unsigned displacement %" PRIx64 "before target section start address %" PRIx64 "\n", thing, (uint64_t) targetMacho->addr); uint64_t thingRelativeOffset = thing - targetMacho->addr; IF_DEBUG(linker, debugBelch(" " "unsigned displacement %" PRIx64 " with section relative offset %" PRIx64 "\n", thing, thingRelativeOffset)); thing = (uint64_t) targetSec->start + thingRelativeOffset; IF_DEBUG(linker, debugBelch(" " "relocated address is %p\n", (void *) thing)); /* Compared to external relocation we don't need to adjust value * any further since thing already has absolute address. */ value = 0; break; } case X86_64_RELOC_SIGNED: case X86_64_RELOC_SIGNED_1: case X86_64_RELOC_SIGNED_2: case X86_64_RELOC_SIGNED_4: { uint32_t baseValueOffset = reloc->r_address + relocLenBytes + nextInstrAdj; uint64_t imThingLoc = msect->addr + baseValueOffset + (int64_t) thing; CHECKM(imThingLoc >= targetMacho->addr, "relocateSection: target location %p in image before target section start address %p\n", (void *) imThingLoc, (void *) targetMacho->addr); int64_t thingRelativeOffset = imThingLoc - targetMacho->addr; IF_DEBUG(linker, debugBelch(" " "original displacement %" PRId64 " to %p with section relative offset %" PRIu64 "\n", thing, (void *) imThingLoc, thingRelativeOffset)); thing = (int64_t) ((uint64_t) targetSec->start + thingRelativeOffset) - ((uint64_t) sect->start + baseValueOffset); value = baseValue; // so that it further cancels out with baseValue IF_DEBUG(linker, debugBelch(" " "relocated displacement %" PRId64 " to %p\n", (int64_t) thing, (void *) (baseValue + thing))); break; } default: barf("relocateSection: unexpected internal relocation type %d\n", type); return 0; } } IF_DEBUG(linker, debugBelch("relocateSection: value = %p\n", (void *) value)); if (type == X86_64_RELOC_BRANCH) { if((int32_t)(value - baseValue) != (int64_t)(value - baseValue)) { ASSERT(reloc->r_extern); value = (uint64_t) &makeSymbolExtra(oc, reloc->r_symbolnum, value) -> jumpIsland; } ASSERT((int32_t)(value - baseValue) == (int64_t)(value - baseValue)); type = X86_64_RELOC_SIGNED; } switch(type) { case X86_64_RELOC_UNSIGNED: ASSERT(!reloc->r_pcrel); thing += value; break; case X86_64_RELOC_SIGNED: case X86_64_RELOC_SIGNED_1: case X86_64_RELOC_SIGNED_2: case X86_64_RELOC_SIGNED_4: ASSERT(reloc->r_pcrel); thing += value - baseValue; break; case X86_64_RELOC_SUBTRACTOR: ASSERT(!reloc->r_pcrel); thing -= value; break; default: barf("unknown relocation"); } IF_DEBUG(linker, debugBelch("relocateSection: thing = %p\n", (void *) thing)); /* Thing points to memory within one of the relocated sections. We can * probe the first byte to sanity check internal relocations. */ if (0 == reloc->r_extern) { if (reloc->r_pcrel) { checkProddableBlock(oc, (void *)((char *)thing + baseValue), 1); } else { checkProddableBlock(oc, (void *)thing, 1); } } switch(reloc->r_length) { case 0: *(uint8_t*)thingPtr = thing; break; case 1: *(uint16_t*)thingPtr = thing; break; case 2: *(uint32_t*)thingPtr = thing; break; case 3: *(uint64_t*)thingPtr = thing; break; } } IF_DEBUG(linker, debugBelch("relocateSection: done\n")); return 1; } #endif /* x86_64_HOST_ARCH */ SectionKind getSectionKind_MachO(MachOSection *section) { SectionKind kind; /* todo: Use section flags instead */ if (0==strcmp(section->sectname,"__text")) { kind = SECTIONKIND_CODE_OR_RODATA; } else if (0==strcmp(section->sectname,"__const") || 0==strcmp(section->sectname,"__data") || 0==strcmp(section->sectname,"__bss") || 0==strcmp(section->sectname,"__common") || 0==strcmp(section->sectname,"__mod_init_func")) { kind = SECTIONKIND_RWDATA; } else { kind = SECTIONKIND_OTHER; } return kind; } /* Calculate the # of active segments and their sizes based on section * sizes and alignments. This is done in 2 passes over sections: * 1. Calculate how many sections is going to be in each segment and * the total segment size. * 2. Fill in segment's sections_idx arrays. * * gbZerofillSegment is there because of this comment in mach-o/loader.h: * The gigabyte zero fill sections, those with the section type * S_GB_ZEROFILL, can only be in a segment with sections of this * type. These segments are then placed after all other segments. */ int ocBuildSegments_MachO(ObjectCode *oc) { int n_rxSections = 0; size_t size_rxSegment = 0; Segment *rxSegment = NULL; int n_rwSections = 0; size_t size_rwSegment = 0; Segment *rwSegment = NULL; int n_gbZerofills = 0; size_t size_gbZerofillSegment = 0; Segment *gbZerofillSegment = NULL; int n_activeSegments = 0; int curSegment = 0; size_t size_compound; Segment *segments = NULL; void *mem = NULL, *curMem = NULL; for (int i = 0; i < oc->n_sections; i++) { MachOSection *macho = &oc->info->macho_sections[i]; if (0 == macho->size) { IF_DEBUG(linker, debugBelch("ocBuildSegments_MachO: found a zero length section, skipping\n")); continue; } size_t alignment = 1 << macho->align; if (S_GB_ZEROFILL == (macho->flags & SECTION_TYPE)) { size_gbZerofillSegment = roundUpToAlign(size_gbZerofillSegment, alignment); size_gbZerofillSegment += macho->size; n_gbZerofills++; } else if (getSectionKind_MachO(macho) == SECTIONKIND_CODE_OR_RODATA) { size_rxSegment = roundUpToAlign(size_rxSegment, alignment); size_rxSegment += macho->size; n_rxSections++; } else { size_rwSegment = roundUpToAlign(size_rwSegment, alignment); size_rwSegment += macho->size; n_rwSections++; } } size_compound = roundUpToPage(size_rxSegment) + roundUpToPage(size_rwSegment) + roundUpToPage(size_gbZerofillSegment); if (n_rxSections > 0) { n_activeSegments++; } if (n_rwSections > 0) { n_activeSegments++; } if (n_gbZerofills > 0) { n_activeSegments++; } // N.B. it's possible that there is nothing mappable in an object. In this // case we avoid the mmap call and segment allocation/building since it will // fail either here or further down the road, e.g. on size > 0 assert in // addProddableBlock. See #16701. if (0 == size_compound) { IF_DEBUG(linker, debugBelch("ocBuildSegments_MachO: all segments are empty, skipping\n")); return 1; } mem = mmapForLinker(size_compound, MAP_ANON, -1, 0); if (NULL == mem) return 0; IF_DEBUG(linker, debugBelch("ocBuildSegments: allocating %d segments\n", n_activeSegments)); segments = (Segment*)stgCallocBytes(n_activeSegments, sizeof(Segment), "ocBuildSegments_MachO(segments)"); curMem = mem; /* Allocate space for RX segment */ if (n_rxSections > 0) { rxSegment = &segments[curSegment]; initSegment(rxSegment, curMem, roundUpToPage(size_rxSegment), SEGMENT_PROT_RX, n_rxSections); IF_DEBUG(linker, debugBelch("ocBuildSegments_MachO: init segment %d (RX) at %p size %zu\n", curSegment, rxSegment->start, rxSegment->size)); curMem = (char *)curMem + rxSegment->size; curSegment++; } /* Allocate space for RW segment */ if (n_rwSections > 0) { rwSegment = &segments[curSegment]; initSegment(rwSegment, curMem, roundUpToPage(size_rwSegment), SEGMENT_PROT_RWO, n_rwSections); IF_DEBUG(linker, debugBelch("ocBuildSegments_MachO: init segment %d (RWO) at %p size %zu\n", curSegment, rwSegment->start, rwSegment->size)); curMem = (char *)curMem + rwSegment->size; curSegment++; } /* Allocate space for GB_ZEROFILL segment */ if (n_gbZerofills > 0) { gbZerofillSegment = &segments[curSegment]; initSegment(gbZerofillSegment, curMem, roundUpToPage(size_gbZerofillSegment), SEGMENT_PROT_RWO, n_gbZerofills); IF_DEBUG(linker, debugBelch("ocBuildSegments_MachO: init segment %d (GB_ZEROFILL) at %p size %zu\n", curSegment, gbZerofillSegment->start, gbZerofillSegment->size)); curMem = (char *)curMem + gbZerofillSegment->size; curSegment++; } /* Second pass over sections to fill in sections_idx arrays */ for (int i = 0, rx = 0, rw = 0, gb = 0; i < oc->n_sections; i++) { MachOSection *macho = &oc->info->macho_sections[i]; // Skip zero size sections here as well since there was no place // allocated for them in Segment's sections_idx array if (0 == macho->size) { continue; } if (S_GB_ZEROFILL == (macho->flags & SECTION_TYPE)) { gbZerofillSegment->sections_idx[gb++] = i; } else if (getSectionKind_MachO(macho) == SECTIONKIND_CODE_OR_RODATA) { rxSegment->sections_idx[rx++] = i; } else { rwSegment->sections_idx[rw++] = i; } } oc->segments = segments; oc->n_segments = n_activeSegments; return 1; } int ocGetNames_MachO(ObjectCode* oc) { unsigned curSymbol = 0; unsigned long commonSize = 0; SymbolAddr* commonStorage = NULL; unsigned long commonCounter; IF_DEBUG(linker,debugBelch("ocGetNames_MachO: start\n")); Section *secArray; secArray = (Section*)stgCallocBytes( oc->info->segCmd->nsects, sizeof(Section), "ocGetNames_MachO(sections)"); oc->sections = secArray; IF_DEBUG(linker, debugBelch("ocGetNames_MachO: will load %d sections\n", oc->n_sections)); CHECKM(ocBuildSegments_MachO(oc), "ocGetNames_MachO: failed to build segments\n"); for (int seg_n = 0; seg_n < oc->n_segments; seg_n++) { Segment *segment = &oc->segments[seg_n]; void *curMem = segment->start; IF_DEBUG(linker, debugBelch("ocGetNames_MachO: loading segment %d " "(address = %p, size = %zu) " "with %d sections\n", seg_n, segment->start, segment->size, segment->n_sections)); for (int sec_n = 0; sec_n < segment->n_sections; sec_n++) { int sec_idx = segment->sections_idx[sec_n]; MachOSection *section = &oc->info->macho_sections[sec_idx]; size_t alignment = 1 << section->align; SectionKind kind = getSectionKind_MachO(section); void *secMem = (void *)roundUpToAlign((size_t)curMem, alignment); IF_DEBUG(linker, debugBelch("ocGetNames_MachO: loading section %d in segment %d " "(#%d, %s %s)\n" " skipped %zu bytes due to alignment of %zu\n", sec_n, seg_n, sec_idx, section->segname, section->sectname, (char *)secMem - (char *)curMem, alignment)); switch (section->flags & SECTION_TYPE) { case S_ZEROFILL: case S_GB_ZEROFILL: IF_DEBUG(linker, debugBelch("ocGetNames_MachO: memset to 0 a ZEROFILL section\n")); memset(secMem, 0, section->size); break; default: IF_DEBUG(linker, debugBelch("ocGetNames_MachO: copying from %p to %p" " a block of %" PRIu64 " bytes\n", (void *) (oc->image + section->offset), secMem, section->size)); memcpy(secMem, oc->image + section->offset, section->size); } /* SECTION_NOMEM since memory is already allocated in segments */ addSection(&secArray[sec_idx], kind, SECTION_NOMEM, secMem, section->size, 0, 0, 0); addProddableBlock(oc, secMem, section->size); curMem = (char*) secMem + section->size; secArray[sec_idx].info->nstubs = 0; secArray[sec_idx].info->stub_offset = NULL; secArray[sec_idx].info->stub_size = 0; secArray[sec_idx].info->stubs = NULL; secArray[sec_idx].info->macho_section = section; secArray[sec_idx].info->relocation_info = (MachORelocationInfo*)(oc->image + section->reloff); } } /* now, as all sections have been loaded, we can resolve the absolute * address of symbols defined in those sections. */ for(size_t i=0; i < oc->info->n_macho_symbols; i++) { MachOSymbol * s = &oc->info->macho_symbols[i]; if( N_SECT == (s->nlist->n_type & N_TYPE) ) { if( NO_SECT == s->nlist->n_sect ) barf("Symbol with N_SECT type, but no section."); /* section is given, and n_sect is >0 */ uint8_t n = s->nlist->n_sect - 1; if(0 == oc->info->macho_sections[n].size) { continue; } /* addr <- address in memory where the relocated section resides | (a) * - section's address in the image | (b) * + symbol's address in the image | (c) * (c) - (b) gives symbol's offset relative to section start * (a) - (b) + (c) gives symbol's address for the relocated section * * (c) and (b) are not _real_ addresses and not equal * to file offsets in the image. * Rather they are (virtual) aligned addresses within * a single segment of MH_OBJECT object file. */ s->addr = (uint8_t*)oc->sections[n].start - oc->info->macho_sections[n].addr + s->nlist->n_value; if(NULL == s->addr) barf("Failed to compute address for symbol %s", s->name); } } // count external symbols defined here oc->n_symbols = 0; if (oc->info->symCmd) { for (size_t i = 0; i < oc->info->n_macho_symbols; i++) { if (oc->info->nlist[i].n_type & N_STAB) { ; } else if(oc->info->nlist[i].n_type & N_EXT) { if((oc->info->nlist[i].n_type & N_TYPE) == N_UNDF && (oc->info->nlist[i].n_value != 0)) { commonSize += oc->info->nlist[i].n_value; oc->n_symbols++; } else if((oc->info->nlist[i].n_type & N_TYPE) == N_SECT) oc->n_symbols++; } } } /* allocate space for the exported symbols * in the object code. This is used to track * which symbols will have to be removed when * this object code is unloaded */ IF_DEBUG(linker, debugBelch("ocGetNames_MachO: %d external symbols\n", oc->n_symbols)); oc->symbols = stgMallocBytes(oc->n_symbols * sizeof(Symbol_t), "ocGetNames_MachO(oc->symbols)"); if (oc->info->symCmd) { for (size_t i = 0; i < oc->info->n_macho_symbols; i++) { SymbolName* nm = oc->info->macho_symbols[i].name; if (oc->info->nlist[i].n_type & N_STAB) { IF_DEBUG(linker, debugBelch("ocGetNames_MachO: Skip STAB: %s\n", nm)); } else if ((oc->info->nlist[i].n_type & N_TYPE) == N_SECT) { if (oc->info->nlist[i].n_type & N_EXT) { if ( (oc->info->nlist[i].n_desc & N_WEAK_DEF) && lookupSymbol_(nm)) { // weak definition, and we already have a definition IF_DEBUG(linker, debugBelch(" weak: %s\n", nm)); } else { IF_DEBUG(linker, debugBelch("ocGetNames_MachO: inserting %s\n", nm)); SymbolAddr* addr = oc->info->macho_symbols[i].addr; ghciInsertSymbolTable( oc->fileName , symhash , nm , addr , HS_BOOL_FALSE , oc); oc->symbols[curSymbol].name = nm; oc->symbols[curSymbol].addr = addr; curSymbol++; } } else { IF_DEBUG(linker, debugBelch("ocGetNames_MachO: \t...not external, skipping %s\n", nm)); } } else { IF_DEBUG(linker, debugBelch("ocGetNames_MachO: \t...not defined in this section, skipping %s\n", nm)); } } } /* setup the common storage */ commonStorage = stgCallocBytes(1,commonSize,"ocGetNames_MachO(common symbols)"); commonCounter = (unsigned long)commonStorage; if (oc->info->symCmd) { for (size_t i = 0; i < oc->info->n_macho_symbols; i++) { SymbolName* nm = oc->info->macho_symbols[i].name; MachONList *nlist = &oc->info->nlist[i]; if((nlist->n_type & N_TYPE) == N_UNDF && (nlist->n_type & N_EXT) && (nlist->n_value != 0)) { unsigned long sz = nlist->n_value; nlist->n_value = commonCounter; /* also set the final address to the macho_symbol */ oc->info->macho_symbols[i].addr = (void*)commonCounter; IF_DEBUG(linker, debugBelch("ocGetNames_MachO: inserting common symbol: %s\n", nm)); ghciInsertSymbolTable(oc->fileName, symhash, nm, (void*)commonCounter, HS_BOOL_FALSE, oc); oc->symbols[curSymbol].name = nm; oc->symbols[curSymbol].addr = oc->info->macho_symbols[i].addr; curSymbol++; commonCounter += sz; } } } #if defined(aarch64_HOST_ARCH) /* Setup the global offset table * This is for symbols that are external, and not defined here. * So that we can load their address indirectly. * * We will get GOT request for any symbol that is * - EXT and UNDF * - EXT and not in the same section. * * As sections are not necessarily contiguous and can live * anywhere in the addressable space. This obviously makes * sense. However it took me a while to figure this out. */ makeGot(oc); /* at this point, macho_symbols, should know the addresses for * all symbols defined by this object code. * - those that are defined in sections. * - those that are undefined, but have a value (common storage). */ #endif IF_DEBUG(linker, debugBelch("ocGetNames_MachO: done\n")); return 1; } static bool ocMprotect_MachO( ObjectCode *oc ) { for(int i=0; i < oc->n_segments; i++) { Segment *segment = &oc->segments[i]; if(segment->size == 0) continue; if(segment->prot == SEGMENT_PROT_RX) { mmapForLinkerMarkExecutable(segment->start, segment->size); } } return true; } int ocResolve_MachO(ObjectCode* oc) { IF_DEBUG(linker, debugBelch("ocResolve_MachO: start\n")); if(NULL != oc->info->dsymCmd) { unsigned long *indirectSyms = (unsigned long*) (oc->image + oc->info->dsymCmd->indirectsymoff); IF_DEBUG(linker, debugBelch("ocResolve_MachO: resolving dsymLC\n")); for (int i = 0; i < oc->n_sections; i++) { const char * sectionName = oc->info->macho_sections[i].sectname; if( !strcmp(sectionName,"__la_symbol_ptr") || !strcmp(sectionName,"__la_sym_ptr2") || !strcmp(sectionName,"__la_sym_ptr3")) { if(!resolveImports(oc,&oc->info->macho_sections[i], indirectSyms)) return 0; } else if(!strcmp(sectionName,"__nl_symbol_ptr") || !strcmp(sectionName,"__pointers")) { if(!resolveImports(oc,&oc->info->macho_sections[i], indirectSyms)) return 0; } else if(!strcmp(sectionName,"__jump_table")) { if(!resolveImports(oc,&oc->info->macho_sections[i], indirectSyms)) return 0; } else { IF_DEBUG(linker, debugBelch("ocResolve_MachO: unknown section\n")); } } } #if defined(aarch64_HOST_ARCH) /* fill the GOT table */ for(size_t i = 0; i < oc->info->n_macho_symbols; i++) { MachOSymbol * symbol = &oc->info->macho_symbols[i]; if(needGotSlot(symbol->nlist)) { if(N_UNDF == (symbol->nlist->n_type & N_TYPE)) { /* an undefined symbol. So we need to ensure we * have the address. */ if(NULL == symbol->addr) { symbol->addr = lookupSymbol_((char*)symbol->name); if(NULL == symbol->addr) barf("Failed to lookup symbol: %s", symbol->name); } else { // we already have the address. } } /* else it was defined in the same object, * just a different section. We should have * the address as well already */ if(NULL == symbol->addr) { barf("Something went wrong!"); } if(NULL == symbol->got_addr) { barf("Not good either!"); } *(uint64_t*)symbol->got_addr = (uint64_t)symbol->addr; } } #endif for(int i = 0; i < oc->n_sections; i++) { IF_DEBUG(linker, debugBelch("ocResolve_MachO: relocating section %d\n", i)); #if defined(aarch64_HOST_ARCH) if (!relocateSectionAarch64(oc, &oc->sections[i])) return 0; #else if (!relocateSection(oc, i)) return 0; #endif } if(!ocMprotect_MachO ( oc )) return 0; return 1; } int ocRunInit_MachO ( ObjectCode *oc ) { if (NULL == oc->info->segCmd) { barf("ocRunInit_MachO: no segment load command"); } int argc, envc; char **argv, **envv; getProgArgv(&argc, &argv); getProgEnvv(&envc, &envv); for (int i = 0; i < oc->n_sections; i++) { IF_DEBUG(linker, debugBelch("ocRunInit_MachO: checking section %d\n", i)); // ToDo: replace this with a proper check for the S_MOD_INIT_FUNC_POINTERS // flag. We should do this elsewhere in the Mach-O linker code // too. Note that the system linker will *refuse* to honor // sections which don't have this flag, so this could cause // weird behavior divergence (albeit reproducible). if (0 == strcmp(oc->info->macho_sections[i].sectname, "__mod_init_func")) { IF_DEBUG(linker, debugBelch("ocRunInit_MachO: running mod init functions\n")); void *init_startC = oc->sections[i].start; init_t *init = (init_t*)init_startC; init_t *init_end = (init_t*)((uint8_t*)init_startC + oc->sections[i].info->macho_section->size); for (int pn = 0; init < init_end; init++, pn++) { IF_DEBUG(linker, debugBelch("ocRunInit_MachO: function pointer %d at %p to %p\n", pn, (void *) init, (void *) *init)); (*init)(argc, argv, envv); } } } freeProgEnvv(envc, envv); return 1; } /* * Figure out by how much to shift the entire Mach-O file in memory * when loading so that its single segment ends up 16-byte-aligned */ int machoGetMisalignment( FILE * f ) { MachOHeader header; int misalignment; { size_t n = fread(&header, sizeof(header), 1, f); if (n != 1) { barf("machoGetMisalignment: can't read the Mach-O header"); } } fseek(f, -sizeof(header), SEEK_CUR); if(header.magic != MH_MAGIC_64) { barf("Bad magic. Expected: %08x, got: %08x.", MH_MAGIC_64, header.magic); } misalignment = (header.sizeofcmds + sizeof(header)) & 0xF; IF_DEBUG(linker, debugBelch("mach-o misalignment %d\n", misalignment)); return misalignment ? (16 - misalignment) : 0; } #endif /* darwin_HOST_OS || ios_HOST_OS */