base: link.File, ptr_width: PtrWidth, /// If this is not null, an object file is created by LLVM and linked with LLD afterwards. llvm_object: ?*LlvmObject = null, /// A list of all input files. /// Index of each input file also encodes the priority or precedence of one input file /// over another. files: std.MultiArrayList(File.Entry) = .{}, zig_object_index: ?File.Index = null, linker_defined_index: ?File.Index = null, objects: std.ArrayListUnmanaged(File.Index) = .{}, shared_objects: std.ArrayListUnmanaged(File.Index) = .{}, /// Stored in native-endian format, depending on target endianness needs to be bswapped on read/write. /// Same order as in the file. shdrs: std.ArrayListUnmanaged(elf.Elf64_Shdr) = .{}, /// Given index to a section, pulls index of containing phdr if any. phdr_to_shdr_table: std.AutoHashMapUnmanaged(u16, u16) = .{}, /// File offset into the shdr table. shdr_table_offset: ?u64 = null, /// Table of lists of atoms per output section. /// This table is not used to track incrementally generated atoms. output_sections: std.AutoArrayHashMapUnmanaged(u16, std.ArrayListUnmanaged(Atom.Index)) = .{}, /// Stored in native-endian format, depending on target endianness needs to be bswapped on read/write. /// Same order as in the file. phdrs: std.ArrayListUnmanaged(elf.Elf64_Phdr) = .{}, /// Tracked loadable segments during incremental linking. /// The index into the program headers of a PT_LOAD program header with Read and Execute flags phdr_zig_load_re_index: ?u16 = null, /// The index into the program headers of the global offset table. /// It needs PT_LOAD and Read flags. phdr_zig_got_index: ?u16 = null, /// The index into the program headers of a PT_LOAD program header with Read flag phdr_zig_load_ro_index: ?u16 = null, /// The index into the program headers of a PT_LOAD program header with Write flag phdr_zig_load_rw_index: ?u16 = null, /// The index into the program headers of a PT_LOAD program header with zerofill data. phdr_zig_load_zerofill_index: ?u16 = null, /// Special program headers /// PT_PHDR phdr_table_index: ?u16 = null, /// PT_LOAD for PHDR table /// We add this special load segment to ensure the EHDR and PHDR table are always /// loaded into memory. phdr_table_load_index: ?u16 = null, /// PT_INTERP phdr_interp_index: ?u16 = null, /// PT_DYNAMIC phdr_dynamic_index: ?u16 = null, /// PT_GNU_EH_FRAME phdr_gnu_eh_frame_index: ?u16 = null, /// PT_GNU_STACK phdr_gnu_stack_index: ?u16 = null, /// PT_TLS /// TODO I think ELF permits multiple TLS segments but for now, assume one per file. phdr_tls_index: ?u16 = null, entry_index: ?Symbol.Index = null, page_size: u32, default_sym_version: elf.Elf64_Versym, /// .shstrtab buffer shstrtab: std.ArrayListUnmanaged(u8) = .{}, /// .symtab buffer symtab: std.ArrayListUnmanaged(elf.Elf64_Sym) = .{}, /// .strtab buffer strtab: std.ArrayListUnmanaged(u8) = .{}, /// Dynamic symbol table. Only populated and emitted when linking dynamically. dynsym: DynsymSection = .{}, /// .dynstrtab buffer dynstrtab: std.ArrayListUnmanaged(u8) = .{}, /// Version symbol table. Only populated and emitted when linking dynamically. versym: std.ArrayListUnmanaged(elf.Elf64_Versym) = .{}, /// .verneed section verneed: VerneedSection = .{}, /// .got section got: GotSection = .{}, /// .rela.dyn section rela_dyn: std.ArrayListUnmanaged(elf.Elf64_Rela) = .{}, /// .dynamic section dynamic: DynamicSection = .{}, /// .hash section hash: HashSection = .{}, /// .gnu.hash section gnu_hash: GnuHashSection = .{}, /// .plt section plt: PltSection = .{}, /// .got.plt section got_plt: GotPltSection = .{}, /// .plt.got section plt_got: PltGotSection = .{}, /// .copyrel section copy_rel: CopyRelSection = .{}, /// .rela.plt section rela_plt: std.ArrayListUnmanaged(elf.Elf64_Rela) = .{}, /// .got.zig section zig_got: ZigGotSection = .{}, /// Tracked section headers with incremental updates to Zig object. /// .rela.* sections are only used when emitting a relocatable object file. zig_text_section_index: ?u16 = null, zig_text_rela_section_index: ?u16 = null, zig_data_rel_ro_section_index: ?u16 = null, zig_data_rel_ro_rela_section_index: ?u16 = null, zig_data_section_index: ?u16 = null, zig_data_rela_section_index: ?u16 = null, zig_bss_section_index: ?u16 = null, zig_got_section_index: ?u16 = null, debug_info_section_index: ?u16 = null, debug_abbrev_section_index: ?u16 = null, debug_str_section_index: ?u16 = null, debug_aranges_section_index: ?u16 = null, debug_line_section_index: ?u16 = null, copy_rel_section_index: ?u16 = null, dynamic_section_index: ?u16 = null, dynstrtab_section_index: ?u16 = null, dynsymtab_section_index: ?u16 = null, eh_frame_section_index: ?u16 = null, eh_frame_hdr_section_index: ?u16 = null, hash_section_index: ?u16 = null, gnu_hash_section_index: ?u16 = null, got_section_index: ?u16 = null, got_plt_section_index: ?u16 = null, interp_section_index: ?u16 = null, plt_section_index: ?u16 = null, plt_got_section_index: ?u16 = null, rela_dyn_section_index: ?u16 = null, rela_plt_section_index: ?u16 = null, versym_section_index: ?u16 = null, verneed_section_index: ?u16 = null, shstrtab_section_index: ?u16 = null, strtab_section_index: ?u16 = null, symtab_section_index: ?u16 = null, // Linker-defined symbols dynamic_index: ?Symbol.Index = null, ehdr_start_index: ?Symbol.Index = null, init_array_start_index: ?Symbol.Index = null, init_array_end_index: ?Symbol.Index = null, fini_array_start_index: ?Symbol.Index = null, fini_array_end_index: ?Symbol.Index = null, preinit_array_start_index: ?Symbol.Index = null, preinit_array_end_index: ?Symbol.Index = null, got_index: ?Symbol.Index = null, plt_index: ?Symbol.Index = null, end_index: ?Symbol.Index = null, gnu_eh_frame_hdr_index: ?Symbol.Index = null, dso_handle_index: ?Symbol.Index = null, rela_iplt_start_index: ?Symbol.Index = null, rela_iplt_end_index: ?Symbol.Index = null, start_stop_indexes: std.ArrayListUnmanaged(u32) = .{}, /// An array of symbols parsed across all input files. symbols: std.ArrayListUnmanaged(Symbol) = .{}, symbols_extra: std.ArrayListUnmanaged(u32) = .{}, symbols_free_list: std.ArrayListUnmanaged(Symbol.Index) = .{}, resolver: std.AutoArrayHashMapUnmanaged(u32, Symbol.Index) = .{}, has_text_reloc: bool = false, num_ifunc_dynrelocs: usize = 0, error_flags: link.File.ErrorFlags = link.File.ErrorFlags{}, misc_errors: std.ArrayListUnmanaged(link.File.ErrorMsg) = .{}, /// List of atoms that are owned directly by the linker. atoms: std.ArrayListUnmanaged(Atom) = .{}, /// Table of last atom index in a section and matching atom free list if any. last_atom_and_free_list_table: LastAtomAndFreeListTable = .{}, comdat_groups: std.ArrayListUnmanaged(ComdatGroup) = .{}, comdat_groups_owners: std.ArrayListUnmanaged(ComdatGroupOwner) = .{}, comdat_groups_table: std.AutoHashMapUnmanaged(u32, ComdatGroupOwner.Index) = .{}, /// Global string table used to provide quick access to global symbol resolvers /// such as `resolver` and `comdat_groups_table`. strings: StringTable = .{}, /// When allocating, the ideal_capacity is calculated by /// actual_capacity + (actual_capacity / ideal_factor) const ideal_factor = 3; /// In order for a slice of bytes to be considered eligible to keep metadata pointing at /// it as a possible place to put new symbols, it must have enough room for this many bytes /// (plus extra for reserved capacity). const minimum_atom_size = 64; pub const min_text_capacity = padToIdeal(minimum_atom_size); pub const PtrWidth = enum { p32, p64 }; pub fn openPath(allocator: Allocator, sub_path: []const u8, options: link.Options) !*Elf { assert(options.target.ofmt == .elf); const self = try createEmpty(allocator, options); errdefer self.base.destroy(); const is_obj = options.output_mode == .Obj; const is_obj_or_ar = is_obj or (options.output_mode == .Lib and options.link_mode == .Static); if (options.use_llvm) { const use_lld = build_options.have_llvm and self.base.options.use_lld; if (use_lld) return self; if (options.module != null) { self.base.intermediary_basename = try std.fmt.allocPrint(allocator, "{s}{s}", .{ sub_path, options.target.ofmt.fileExt(options.target.cpu.arch), }); } if (is_obj) { // TODO until we implement -r option, we don't want to open a file at this stage. return self; } } errdefer if (self.base.intermediary_basename) |path| allocator.free(path); self.base.file = try options.emit.?.directory.handle.createFile(sub_path, .{ .truncate = false, .read = true, .mode = link.determineMode(options), }); // Index 0 is always a null symbol. try self.symbols.append(allocator, .{}); // Index 0 is always a null symbol. try self.symbols_extra.append(allocator, 0); // Allocate atom index 0 to null atom try self.atoms.append(allocator, .{}); // Append null file at index 0 try self.files.append(allocator, .null); // Append null byte to string tables try self.shstrtab.append(allocator, 0); try self.strtab.append(allocator, 0); // There must always be a null shdr in index 0 _ = try self.addSection(.{ .name = "" }); // Append null symbol in output symtab try self.symtab.append(allocator, null_sym); if (!is_obj_or_ar) { try self.dynstrtab.append(allocator, 0); // Initialize PT_PHDR program header const p_align: u16 = switch (self.ptr_width) { .p32 => @alignOf(elf.Elf32_Phdr), .p64 => @alignOf(elf.Elf64_Phdr), }; const image_base = self.calcImageBase(); const ehsize: u64 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Ehdr), .p64 => @sizeOf(elf.Elf64_Ehdr), }; const phsize: u64 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Phdr), .p64 => @sizeOf(elf.Elf64_Phdr), }; const max_nphdrs = comptime getMaxNumberOfPhdrs(); const reserved: u64 = mem.alignForward(u64, padToIdeal(max_nphdrs * phsize), self.page_size); self.phdr_table_index = try self.addPhdr(.{ .type = elf.PT_PHDR, .flags = elf.PF_R, .@"align" = p_align, .addr = image_base + ehsize, .offset = ehsize, .filesz = reserved, .memsz = reserved, }); self.phdr_table_load_index = try self.addPhdr(.{ .type = elf.PT_LOAD, .flags = elf.PF_R, .@"align" = self.page_size, .addr = image_base, .offset = 0, .filesz = reserved + ehsize, .memsz = reserved + ehsize, }); } if (options.module != null and !options.use_llvm) { const index = @as(File.Index, @intCast(try self.files.addOne(allocator))); self.files.set(index, .{ .zig_object = .{ .index = index, .path = options.module.?.main_mod.root_src_path, } }); self.zig_object_index = index; try self.zigObjectPtr().?.init(self); try self.initMetadata(); } return self; } pub fn createEmpty(gpa: Allocator, options: link.Options) !*Elf { const ptr_width: PtrWidth = switch (options.target.ptrBitWidth()) { 0...32 => .p32, 33...64 => .p64, else => return error.UnsupportedELFArchitecture, }; const self = try gpa.create(Elf); errdefer gpa.destroy(self); const page_size: u32 = switch (options.target.cpu.arch) { .powerpc64le => 0x10000, .sparc64 => 0x2000, else => 0x1000, }; const is_dyn_lib = options.output_mode == .Lib and options.link_mode == .Dynamic; const default_sym_version: elf.Elf64_Versym = if (is_dyn_lib or options.rdynamic) elf.VER_NDX_GLOBAL else elf.VER_NDX_LOCAL; self.* = .{ .base = .{ .tag = .elf, .options = options, .allocator = gpa, .file = null, }, .ptr_width = ptr_width, .page_size = page_size, .default_sym_version = default_sym_version, }; if (options.use_llvm and options.module != null) { self.llvm_object = try LlvmObject.create(gpa, options); } return self; } pub fn deinit(self: *Elf) void { const gpa = self.base.allocator; if (self.llvm_object) |llvm_object| llvm_object.destroy(gpa); for (self.files.items(.tags), self.files.items(.data)) |tag, *data| switch (tag) { .null => {}, .zig_object => data.zig_object.deinit(gpa), .linker_defined => data.linker_defined.deinit(gpa), .object => data.object.deinit(gpa), .shared_object => data.shared_object.deinit(gpa), }; self.files.deinit(gpa); self.objects.deinit(gpa); self.shared_objects.deinit(gpa); self.shdrs.deinit(gpa); self.phdr_to_shdr_table.deinit(gpa); self.phdrs.deinit(gpa); for (self.output_sections.values()) |*list| { list.deinit(gpa); } self.output_sections.deinit(gpa); self.shstrtab.deinit(gpa); self.symtab.deinit(gpa); self.strtab.deinit(gpa); self.symbols.deinit(gpa); self.symbols_extra.deinit(gpa); self.symbols_free_list.deinit(gpa); self.resolver.deinit(gpa); self.start_stop_indexes.deinit(gpa); self.atoms.deinit(gpa); for (self.last_atom_and_free_list_table.values()) |*value| { value.free_list.deinit(gpa); } self.last_atom_and_free_list_table.deinit(gpa); self.misc_errors.deinit(gpa); self.comdat_groups.deinit(gpa); self.comdat_groups_owners.deinit(gpa); self.comdat_groups_table.deinit(gpa); self.strings.deinit(gpa); self.got.deinit(gpa); self.plt.deinit(gpa); self.plt_got.deinit(gpa); self.dynsym.deinit(gpa); self.dynstrtab.deinit(gpa); self.dynamic.deinit(gpa); self.hash.deinit(gpa); self.versym.deinit(gpa); self.verneed.deinit(gpa); self.copy_rel.deinit(gpa); self.rela_dyn.deinit(gpa); self.rela_plt.deinit(gpa); self.zig_got.deinit(gpa); } pub fn getDeclVAddr(self: *Elf, decl_index: Module.Decl.Index, reloc_info: link.File.RelocInfo) !u64 { assert(self.llvm_object == null); return self.zigObjectPtr().?.getDeclVAddr(self, decl_index, reloc_info); } pub fn lowerAnonDecl( self: *Elf, decl_val: InternPool.Index, explicit_alignment: InternPool.Alignment, src_loc: Module.SrcLoc, ) !codegen.Result { return self.zigObjectPtr().?.lowerAnonDecl(self, decl_val, explicit_alignment, src_loc); } pub fn getAnonDeclVAddr(self: *Elf, decl_val: InternPool.Index, reloc_info: link.File.RelocInfo) !u64 { assert(self.llvm_object == null); return self.zigObjectPtr().?.getAnonDeclVAddr(self, decl_val, reloc_info); } /// Returns end pos of collision, if any. fn detectAllocCollision(self: *Elf, start: u64, size: u64) ?u64 { const small_ptr = self.ptr_width == .p32; const ehdr_size: u64 = if (small_ptr) @sizeOf(elf.Elf32_Ehdr) else @sizeOf(elf.Elf64_Ehdr); if (start < ehdr_size) return ehdr_size; const end = start + padToIdeal(size); if (self.shdr_table_offset) |off| { const shdr_size: u64 = if (small_ptr) @sizeOf(elf.Elf32_Shdr) else @sizeOf(elf.Elf64_Shdr); const tight_size = self.shdrs.items.len * shdr_size; const increased_size = padToIdeal(tight_size); const test_end = off +| increased_size; if (end > off and start < test_end) { return test_end; } } for (self.shdrs.items) |shdr| { if (shdr.sh_type == elf.SHT_NOBITS) continue; const increased_size = padToIdeal(shdr.sh_size); const test_end = shdr.sh_offset +| increased_size; if (end > shdr.sh_offset and start < test_end) { return test_end; } } for (self.phdrs.items) |phdr| { if (phdr.p_type != elf.PT_LOAD) continue; const increased_size = padToIdeal(phdr.p_filesz); const test_end = phdr.p_offset +| increased_size; if (end > phdr.p_offset and start < test_end) { return test_end; } } return null; } fn allocatedSize(self: *Elf, start: u64) u64 { if (start == 0) return 0; var min_pos: u64 = std.math.maxInt(u64); if (self.shdr_table_offset) |off| { if (off > start and off < min_pos) min_pos = off; } for (self.shdrs.items) |section| { if (section.sh_offset <= start) continue; if (section.sh_offset < min_pos) min_pos = section.sh_offset; } for (self.phdrs.items) |phdr| { if (phdr.p_offset <= start) continue; if (phdr.p_offset < min_pos) min_pos = phdr.p_offset; } return min_pos - start; } fn allocatedVirtualSize(self: *Elf, start: u64) u64 { if (start == 0) return 0; var min_pos: u64 = std.math.maxInt(u64); for (self.phdrs.items) |phdr| { if (phdr.p_vaddr <= start) continue; if (phdr.p_vaddr < min_pos) min_pos = phdr.p_vaddr; } return min_pos - start; } fn findFreeSpace(self: *Elf, object_size: u64, min_alignment: u64) u64 { var start: u64 = 0; while (self.detectAllocCollision(start, object_size)) |item_end| { start = mem.alignForward(u64, item_end, min_alignment); } return start; } /// TODO move to ZigObject pub fn initMetadata(self: *Elf) !void { const gpa = self.base.allocator; const ptr_size = self.ptrWidthBytes(); const ptr_bit_width = self.base.options.target.ptrBitWidth(); const is_linux = self.base.options.target.os.tag == .linux; const zig_object = self.zigObjectPtr().?; const fillSection = struct { fn fillSection(elf_file: *Elf, shdr: *elf.Elf64_Shdr, size: u64, phndx: ?u16) void { if (elf_file.isRelocatable()) { const off = elf_file.findFreeSpace(size, shdr.sh_addralign); shdr.sh_offset = off; shdr.sh_size = size; } else { const phdr = elf_file.phdrs.items[phndx.?]; shdr.sh_addr = phdr.p_vaddr; shdr.sh_offset = phdr.p_offset; shdr.sh_size = phdr.p_memsz; } } }.fillSection; comptime assert(number_of_zig_segments == 5); if (!self.isRelocatable()) { if (self.phdr_zig_load_re_index == null) { const filesz = self.base.options.program_code_size_hint; const off = self.findFreeSpace(filesz, self.page_size); self.phdr_zig_load_re_index = try self.addPhdr(.{ .type = elf.PT_LOAD, .offset = off, .filesz = filesz, .addr = if (ptr_bit_width >= 32) 0x8000000 else 0x8000, .memsz = filesz, .@"align" = self.page_size, .flags = elf.PF_X | elf.PF_R | elf.PF_W, }); } if (self.phdr_zig_got_index == null) { // We really only need ptr alignment but since we are using PROGBITS, linux requires // page align. const alignment = if (is_linux) self.page_size else @as(u16, ptr_size); const filesz = @as(u64, ptr_size) * self.base.options.symbol_count_hint; const off = self.findFreeSpace(filesz, alignment); self.phdr_zig_got_index = try self.addPhdr(.{ .type = elf.PT_LOAD, .offset = off, .filesz = filesz, .addr = if (ptr_bit_width >= 32) 0x4000000 else 0x4000, .memsz = filesz, .@"align" = alignment, .flags = elf.PF_R | elf.PF_W, }); } if (self.phdr_zig_load_ro_index == null) { const alignment = if (is_linux) self.page_size else @as(u16, ptr_size); const filesz: u64 = 1024; const off = self.findFreeSpace(filesz, alignment); self.phdr_zig_load_ro_index = try self.addPhdr(.{ .type = elf.PT_LOAD, .offset = off, .filesz = filesz, .addr = if (ptr_bit_width >= 32) 0xc000000 else 0xa000, .memsz = filesz, .@"align" = alignment, .flags = elf.PF_R | elf.PF_W, }); } if (self.phdr_zig_load_rw_index == null) { const alignment = if (is_linux) self.page_size else @as(u16, ptr_size); const filesz: u64 = 1024; const off = self.findFreeSpace(filesz, alignment); self.phdr_zig_load_rw_index = try self.addPhdr(.{ .type = elf.PT_LOAD, .offset = off, .filesz = filesz, .addr = if (ptr_bit_width >= 32) 0x10000000 else 0xc000, .memsz = filesz, .@"align" = alignment, .flags = elf.PF_R | elf.PF_W, }); } if (self.phdr_zig_load_zerofill_index == null) { const alignment = if (is_linux) self.page_size else @as(u16, ptr_size); self.phdr_zig_load_zerofill_index = try self.addPhdr(.{ .type = elf.PT_LOAD, .addr = if (ptr_bit_width >= 32) 0x14000000 else 0xf000, .memsz = 1024, .@"align" = alignment, .flags = elf.PF_R | elf.PF_W, }); } } if (self.zig_text_section_index == null) { self.zig_text_section_index = try self.addSection(.{ .name = ".text.zig", .type = elf.SHT_PROGBITS, .flags = elf.SHF_ALLOC | elf.SHF_EXECINSTR, .addralign = 1, .offset = std.math.maxInt(u64), }); const shdr = &self.shdrs.items[self.zig_text_section_index.?]; fillSection(self, shdr, self.base.options.program_code_size_hint, self.phdr_zig_load_re_index); if (self.isRelocatable()) { try zig_object.addSectionSymbol(self.zig_text_section_index.?, self); self.zig_text_rela_section_index = try self.addRelaShdr( ".rela.text.zig", self.zig_text_section_index.?, ); } else { try self.phdr_to_shdr_table.putNoClobber( gpa, self.zig_text_section_index.?, self.phdr_zig_load_re_index.?, ); } try self.last_atom_and_free_list_table.putNoClobber(gpa, self.zig_text_section_index.?, .{}); } if (self.zig_got_section_index == null and !self.isRelocatable()) { self.zig_got_section_index = try self.addSection(.{ .name = ".got.zig", .type = elf.SHT_PROGBITS, .addralign = ptr_size, .flags = elf.SHF_ALLOC | elf.SHF_WRITE, .offset = std.math.maxInt(u64), }); const shdr = &self.shdrs.items[self.zig_got_section_index.?]; const phndx = self.phdr_zig_got_index.?; const phdr = self.phdrs.items[phndx]; shdr.sh_addr = phdr.p_vaddr; shdr.sh_offset = phdr.p_offset; shdr.sh_size = phdr.p_memsz; try self.phdr_to_shdr_table.putNoClobber( gpa, self.zig_got_section_index.?, self.phdr_zig_got_index.?, ); } if (self.zig_data_rel_ro_section_index == null) { self.zig_data_rel_ro_section_index = try self.addSection(.{ .name = ".data.rel.ro.zig", .type = elf.SHT_PROGBITS, .addralign = 1, .flags = elf.SHF_ALLOC | elf.SHF_WRITE, // TODO rename this section to .data.rel.ro .offset = std.math.maxInt(u64), }); const shdr = &self.shdrs.items[self.zig_data_rel_ro_section_index.?]; fillSection(self, shdr, 1024, self.phdr_zig_load_ro_index); if (self.isRelocatable()) { try zig_object.addSectionSymbol(self.zig_data_rel_ro_section_index.?, self); self.zig_data_rel_ro_rela_section_index = try self.addRelaShdr( ".rela.data.rel.ro.zig", self.zig_data_rel_ro_section_index.?, ); } else { try self.phdr_to_shdr_table.putNoClobber( gpa, self.zig_data_rel_ro_section_index.?, self.phdr_zig_load_ro_index.?, ); } try self.last_atom_and_free_list_table.putNoClobber(gpa, self.zig_data_rel_ro_section_index.?, .{}); } if (self.zig_data_section_index == null) { self.zig_data_section_index = try self.addSection(.{ .name = ".data.zig", .type = elf.SHT_PROGBITS, .addralign = ptr_size, .flags = elf.SHF_ALLOC | elf.SHF_WRITE, .offset = std.math.maxInt(u64), }); const shdr = &self.shdrs.items[self.zig_data_section_index.?]; fillSection(self, shdr, 1024, self.phdr_zig_load_rw_index); if (self.isRelocatable()) { try zig_object.addSectionSymbol(self.zig_data_section_index.?, self); self.zig_data_rela_section_index = try self.addRelaShdr( ".rela.data.zig", self.zig_data_section_index.?, ); } else { try self.phdr_to_shdr_table.putNoClobber( gpa, self.zig_data_section_index.?, self.phdr_zig_load_rw_index.?, ); } try self.last_atom_and_free_list_table.putNoClobber(gpa, self.zig_data_section_index.?, .{}); } if (self.zig_bss_section_index == null) { self.zig_bss_section_index = try self.addSection(.{ .name = ".bss.zig", .type = elf.SHT_NOBITS, .addralign = ptr_size, .flags = elf.SHF_ALLOC | elf.SHF_WRITE, .offset = 0, }); const shdr = &self.shdrs.items[self.zig_bss_section_index.?]; if (self.phdr_zig_load_zerofill_index) |phndx| { const phdr = self.phdrs.items[phndx]; shdr.sh_addr = phdr.p_vaddr; shdr.sh_size = phdr.p_memsz; try self.phdr_to_shdr_table.putNoClobber(gpa, self.zig_bss_section_index.?, phndx); } else { try zig_object.addSectionSymbol(self.zig_bss_section_index.?, self); shdr.sh_size = 1024; } try self.last_atom_and_free_list_table.putNoClobber(gpa, self.zig_bss_section_index.?, .{}); } if (zig_object.dwarf) |*dw| { if (self.debug_str_section_index == null) { assert(dw.strtab.buffer.items.len == 0); try dw.strtab.buffer.append(gpa, 0); self.debug_str_section_index = try self.addSection(.{ .name = ".debug_str", .flags = elf.SHF_MERGE | elf.SHF_STRINGS, .entsize = 1, .type = elf.SHT_PROGBITS, .addralign = 1, .offset = std.math.maxInt(u64), }); const shdr = &self.shdrs.items[self.debug_str_section_index.?]; const size = @as(u64, @intCast(dw.strtab.buffer.items.len)); const off = self.findFreeSpace(size, 1); shdr.sh_offset = off; shdr.sh_size = size; zig_object.debug_strtab_dirty = true; } if (self.debug_info_section_index == null) { self.debug_info_section_index = try self.addSection(.{ .name = ".debug_info", .type = elf.SHT_PROGBITS, .addralign = 1, .offset = std.math.maxInt(u64), }); const shdr = &self.shdrs.items[self.debug_info_section_index.?]; const size: u64 = 200; const off = self.findFreeSpace(size, 1); shdr.sh_offset = off; shdr.sh_size = size; zig_object.debug_info_header_dirty = true; } if (self.debug_abbrev_section_index == null) { self.debug_abbrev_section_index = try self.addSection(.{ .name = ".debug_abbrev", .type = elf.SHT_PROGBITS, .addralign = 1, .offset = std.math.maxInt(u64), }); const shdr = &self.shdrs.items[self.debug_abbrev_section_index.?]; const size: u64 = 128; const off = self.findFreeSpace(size, 1); shdr.sh_offset = off; shdr.sh_size = size; zig_object.debug_abbrev_section_dirty = true; } if (self.debug_aranges_section_index == null) { self.debug_aranges_section_index = try self.addSection(.{ .name = ".debug_aranges", .type = elf.SHT_PROGBITS, .addralign = 16, .offset = std.math.maxInt(u64), }); const shdr = &self.shdrs.items[self.debug_aranges_section_index.?]; const size: u64 = 160; const off = self.findFreeSpace(size, 16); shdr.sh_offset = off; shdr.sh_size = size; zig_object.debug_aranges_section_dirty = true; } if (self.debug_line_section_index == null) { self.debug_line_section_index = try self.addSection(.{ .name = ".debug_line", .type = elf.SHT_PROGBITS, .addralign = 1, .offset = std.math.maxInt(u64), }); const shdr = &self.shdrs.items[self.debug_line_section_index.?]; const size: u64 = 250; const off = self.findFreeSpace(size, 1); shdr.sh_offset = off; shdr.sh_size = size; zig_object.debug_line_header_dirty = true; } } } pub fn growAllocSection(self: *Elf, shdr_index: u16, needed_size: u64) !void { const shdr = &self.shdrs.items[shdr_index]; const maybe_phdr = if (self.phdr_to_shdr_table.get(shdr_index)) |phndx| &self.phdrs.items[phndx] else null; const is_zerofill = shdr.sh_type == elf.SHT_NOBITS; if (needed_size > self.allocatedSize(shdr.sh_offset) and !is_zerofill) { const existing_size = shdr.sh_size; shdr.sh_size = 0; // Must move the entire section. const alignment = if (maybe_phdr) |phdr| phdr.p_align else shdr.sh_addralign; const new_offset = self.findFreeSpace(needed_size, alignment); log.debug("new '{s}' file offset 0x{x} to 0x{x}", .{ self.getShString(shdr.sh_name), new_offset, new_offset + existing_size, }); const amt = try self.base.file.?.copyRangeAll(shdr.sh_offset, self.base.file.?, new_offset, existing_size); // TODO figure out what to about this error condition - how to communicate it up. if (amt != existing_size) return error.InputOutput; shdr.sh_offset = new_offset; if (maybe_phdr) |phdr| phdr.p_offset = new_offset; } shdr.sh_size = needed_size; if (!is_zerofill) { if (maybe_phdr) |phdr| phdr.p_filesz = needed_size; } if (maybe_phdr) |phdr| { const mem_capacity = self.allocatedVirtualSize(phdr.p_vaddr); if (needed_size > mem_capacity) { var err = try self.addErrorWithNotes(2); try err.addMsg(self, "fatal linker error: cannot expand load segment phdr({d}) in virtual memory", .{ self.phdr_to_shdr_table.get(shdr_index).?, }); try err.addNote(self, "TODO: emit relocations to memory locations in self-hosted backends", .{}); try err.addNote(self, "as a workaround, try increasing pre-allocated virtual memory of each segment", .{}); } phdr.p_memsz = needed_size; } self.markDirty(shdr_index); } pub fn growNonAllocSection( self: *Elf, shdr_index: u16, needed_size: u64, min_alignment: u32, requires_file_copy: bool, ) !void { const shdr = &self.shdrs.items[shdr_index]; if (needed_size > self.allocatedSize(shdr.sh_offset)) { const existing_size = shdr.sh_size; shdr.sh_size = 0; // Move all the symbols to a new file location. const new_offset = self.findFreeSpace(needed_size, min_alignment); log.debug("new '{s}' file offset 0x{x} to 0x{x}", .{ self.getShString(shdr.sh_name), new_offset, new_offset + existing_size, }); if (requires_file_copy) { const amt = try self.base.file.?.copyRangeAll( shdr.sh_offset, self.base.file.?, new_offset, existing_size, ); if (amt != existing_size) return error.InputOutput; } shdr.sh_offset = new_offset; } shdr.sh_size = needed_size; self.markDirty(shdr_index); } pub fn markDirty(self: *Elf, shdr_index: u16) void { const zig_object = self.zigObjectPtr().?; if (zig_object.dwarf) |_| { if (self.debug_info_section_index.? == shdr_index) { zig_object.debug_info_header_dirty = true; } else if (self.debug_line_section_index.? == shdr_index) { zig_object.debug_line_header_dirty = true; } else if (self.debug_abbrev_section_index.? == shdr_index) { zig_object.debug_abbrev_section_dirty = true; } else if (self.debug_str_section_index.? == shdr_index) { zig_object.debug_strtab_dirty = true; } else if (self.debug_aranges_section_index.? == shdr_index) { zig_object.debug_aranges_section_dirty = true; } } } pub fn flush(self: *Elf, comp: *Compilation, prog_node: *std.Progress.Node) link.File.FlushError!void { if (self.base.options.emit == null) { if (self.llvm_object) |llvm_object| { try llvm_object.flushModule(comp, prog_node); } return; } const use_lld = build_options.have_llvm and self.base.options.use_lld; if (use_lld) { return self.linkWithLLD(comp, prog_node); } try self.flushModule(comp, prog_node); } pub fn flushModule(self: *Elf, comp: *Compilation, prog_node: *std.Progress.Node) link.File.FlushError!void { const tracy = trace(@src()); defer tracy.end(); if (self.llvm_object) |llvm_object| { try llvm_object.flushModule(comp, prog_node); const use_lld = build_options.have_llvm and self.base.options.use_lld; if (use_lld) return; } const gpa = self.base.allocator; var sub_prog_node = prog_node.start("ELF Flush", 0); sub_prog_node.activate(); defer sub_prog_node.end(); var arena_allocator = std.heap.ArenaAllocator.init(self.base.allocator); defer arena_allocator.deinit(); const arena = arena_allocator.allocator(); const target = self.base.options.target; const directory = self.base.options.emit.?.directory; // Just an alias to make it shorter to type. const full_out_path = try directory.join(arena, &[_][]const u8{self.base.options.emit.?.sub_path}); const module_obj_path: ?[]const u8 = if (self.base.intermediary_basename) |path| blk: { if (fs.path.dirname(full_out_path)) |dirname| { break :blk try fs.path.join(arena, &.{ dirname, path }); } else { break :blk path; } } else null; const gc_sections = self.base.options.gc_sections orelse false; if (self.isRelocatable() and self.zig_object_index == null) { if (self.isStaticLib()) { var err = try self.addErrorWithNotes(0); try err.addMsg(self, "fatal linker error: emitting static libs unimplemented", .{}); return; } // TODO this will become -r route I guess. For now, just copy the object file. assert(self.base.file == null); // TODO uncomment once we implement -r const the_object_path = blk: { if (self.base.options.objects.len != 0) { break :blk self.base.options.objects[0].path; } if (comp.c_object_table.count() != 0) break :blk comp.c_object_table.keys()[0].status.success.object_path; if (module_obj_path) |p| break :blk p; // TODO I think this is unreachable. Audit this situation when solving the above TODO // regarding eliding redundant object -> object transformations. return error.NoObjectsToLink; }; // This can happen when using --enable-cache and using the stage1 backend. In this case // we can skip the file copy. if (!mem.eql(u8, the_object_path, full_out_path)) { try fs.cwd().copyFile(the_object_path, fs.cwd(), full_out_path, .{}); } return; } var csu = try CsuObjects.init(arena, self.base.options, comp); const compiler_rt_path: ?[]const u8 = blk: { if (comp.compiler_rt_lib) |x| break :blk x.full_object_path; if (comp.compiler_rt_obj) |x| break :blk x.full_object_path; break :blk null; }; // --verbose-link if (self.base.options.verbose_link) { var argv = std.ArrayList([]const u8).init(arena); try argv.append("zig"); try argv.append("ld"); try argv.append("-o"); try argv.append(full_out_path); if (self.base.options.entry) |entry| { try argv.append("--entry"); try argv.append(entry); } if (self.base.options.dynamic_linker) |path| { try argv.append("-dynamic-linker"); try argv.append(path); } if (self.base.options.soname) |name| { try argv.append("-soname"); try argv.append(name); } for (self.base.options.rpath_list) |rpath| { try argv.append("-rpath"); try argv.append(rpath); } if (self.base.options.each_lib_rpath) { for (self.base.options.lib_dirs) |lib_dir_path| { try argv.append("-rpath"); try argv.append(lib_dir_path); } for (self.base.options.objects) |obj| { if (Compilation.classifyFileExt(obj.path) == .shared_library) { const lib_dir_path = std.fs.path.dirname(obj.path) orelse continue; if (obj.loption) continue; try argv.append("-rpath"); try argv.append(lib_dir_path); } } } if (self.base.options.stack_size_override) |ss| { try argv.append("-z"); try argv.append(try std.fmt.allocPrint(arena, "stack-size={d}", .{ss})); } if (self.base.options.image_base_override) |image_base| { try argv.append(try std.fmt.allocPrint(arena, "--image-base={d}", .{image_base})); } if (gc_sections) { try argv.append("--gc-sections"); } if (self.base.options.print_gc_sections) { try argv.append("--print-gc-sections"); } if (self.base.options.eh_frame_hdr) { try argv.append("--eh-frame-hdr"); } if (self.base.options.rdynamic) { try argv.append("--export-dynamic"); } if (self.base.options.strip) { try argv.append("-s"); } if (self.base.options.z_notext) { try argv.append("-z"); try argv.append("notext"); } if (self.base.options.z_nocopyreloc) { try argv.append("-z"); try argv.append("nocopyreloc"); } if (self.base.options.z_now) { try argv.append("-z"); try argv.append("now"); } if (self.isStatic()) { try argv.append("-static"); } else if (self.isDynLib()) { try argv.append("-shared"); } if (self.base.options.pie and self.isExe()) { try argv.append("-pie"); } // csu prelude if (csu.crt0) |v| try argv.append(v); if (csu.crti) |v| try argv.append(v); if (csu.crtbegin) |v| try argv.append(v); for (self.base.options.lib_dirs) |lib_dir| { try argv.append("-L"); try argv.append(lib_dir); } if (self.base.options.link_libc) { if (self.base.options.libc_installation) |libc_installation| { try argv.append("-L"); try argv.append(libc_installation.crt_dir.?); } } var whole_archive = false; for (self.base.options.objects) |obj| { if (obj.must_link and !whole_archive) { try argv.append("-whole-archive"); whole_archive = true; } else if (!obj.must_link and whole_archive) { try argv.append("-no-whole-archive"); whole_archive = false; } if (obj.loption) { assert(obj.path[0] == ':'); try argv.append("-l"); } try argv.append(obj.path); } if (whole_archive) { try argv.append("-no-whole-archive"); whole_archive = false; } for (comp.c_object_table.keys()) |key| { try argv.append(key.status.success.object_path); } if (module_obj_path) |p| { try argv.append(p); } // TSAN if (self.base.options.tsan) { try argv.append(comp.tsan_static_lib.?.full_object_path); } // libc if (!self.base.options.skip_linker_dependencies and !self.base.options.link_libc) { if (comp.libc_static_lib) |lib| { try argv.append(lib.full_object_path); } } // stack-protector. // Related: https://github.com/ziglang/zig/issues/7265 if (comp.libssp_static_lib) |ssp| { try argv.append(ssp.full_object_path); } // Shared libraries. // Worst-case, we need an --as-needed argument for every lib, as well // as one before and one after. try argv.ensureUnusedCapacity(self.base.options.system_libs.keys().len * 2 + 2); argv.appendAssumeCapacity("--as-needed"); var as_needed = true; for (self.base.options.system_libs.values()) |lib_info| { const lib_as_needed = !lib_info.needed; switch ((@as(u2, @intFromBool(lib_as_needed)) << 1) | @intFromBool(as_needed)) { 0b00, 0b11 => {}, 0b01 => { argv.appendAssumeCapacity("--no-as-needed"); as_needed = false; }, 0b10 => { argv.appendAssumeCapacity("--as-needed"); as_needed = true; }, } argv.appendAssumeCapacity(lib_info.path.?); } if (!as_needed) { argv.appendAssumeCapacity("--as-needed"); as_needed = true; } // libc++ dep if (self.base.options.link_libcpp) { try argv.append(comp.libcxxabi_static_lib.?.full_object_path); try argv.append(comp.libcxx_static_lib.?.full_object_path); } // libunwind dep if (self.base.options.link_libunwind) { try argv.append(comp.libunwind_static_lib.?.full_object_path); } // libc dep if (self.base.options.link_libc) { if (self.base.options.libc_installation != null) { const needs_grouping = self.base.options.link_mode == .Static; if (needs_grouping) try argv.append("--start-group"); try argv.appendSlice(target_util.libcFullLinkFlags(target)); if (needs_grouping) try argv.append("--end-group"); } else if (target.isGnuLibC()) { for (glibc.libs) |lib| { const lib_path = try std.fmt.allocPrint(arena, "{s}{c}lib{s}.so.{d}", .{ comp.glibc_so_files.?.dir_path, fs.path.sep, lib.name, lib.sover, }); try argv.append(lib_path); } try argv.append(try comp.get_libc_crt_file(arena, "libc_nonshared.a")); } else if (target.isMusl()) { try argv.append(try comp.get_libc_crt_file(arena, switch (self.base.options.link_mode) { .Static => "libc.a", .Dynamic => "libc.so", })); } } // compiler-rt if (compiler_rt_path) |p| { try argv.append(p); } // crt postlude if (csu.crtend) |v| try argv.append(v); if (csu.crtn) |v| try argv.append(v); Compilation.dump_argv(argv.items); } if (self.zigObjectPtr()) |zig_object| try zig_object.flushModule(self); // Here we will parse input positional and library files (if referenced). // This will roughly match in any linker backend we support. var positionals = std.ArrayList(Compilation.LinkObject).init(arena); // csu prelude if (csu.crt0) |v| try positionals.append(.{ .path = v }); if (csu.crti) |v| try positionals.append(.{ .path = v }); if (csu.crtbegin) |v| try positionals.append(.{ .path = v }); try positionals.ensureUnusedCapacity(self.base.options.objects.len); positionals.appendSliceAssumeCapacity(self.base.options.objects); // This is a set of object files emitted by clang in a single `build-exe` invocation. // For instance, the implicit `a.o` as compiled by `zig build-exe a.c` will end up // in this set. for (comp.c_object_table.keys()) |key| { try positionals.append(.{ .path = key.status.success.object_path }); } if (module_obj_path) |path| try positionals.append(.{ .path = path }); // rpaths var rpath_table = std.StringArrayHashMap(void).init(self.base.allocator); defer rpath_table.deinit(); for (self.base.options.rpath_list) |rpath| { _ = try rpath_table.put(rpath, {}); } if (self.base.options.each_lib_rpath) { var test_path = std.ArrayList(u8).init(self.base.allocator); defer test_path.deinit(); for (self.base.options.lib_dirs) |lib_dir_path| { for (self.base.options.system_libs.keys()) |link_lib| { if (!(try self.accessLibPath(&test_path, null, lib_dir_path, link_lib, .Dynamic))) continue; _ = try rpath_table.put(lib_dir_path, {}); } } for (self.base.options.objects) |obj| { if (Compilation.classifyFileExt(obj.path) == .shared_library) { const lib_dir_path = std.fs.path.dirname(obj.path) orelse continue; if (obj.loption) continue; _ = try rpath_table.put(lib_dir_path, {}); } } } // TSAN if (self.base.options.tsan) { try positionals.append(.{ .path = comp.tsan_static_lib.?.full_object_path }); } // libc if (!self.base.options.skip_linker_dependencies and !self.base.options.link_libc) { if (comp.libc_static_lib) |lib| { try positionals.append(.{ .path = lib.full_object_path }); } } // stack-protector. // Related: https://github.com/ziglang/zig/issues/7265 if (comp.libssp_static_lib) |ssp| { try positionals.append(.{ .path = ssp.full_object_path }); } if (self.isStaticLib()) return self.flushStaticLib(comp, positionals.items); for (positionals.items) |obj| { var parse_ctx: ParseErrorCtx = .{ .detected_cpu_arch = undefined }; self.parsePositional(obj.path, obj.must_link, &parse_ctx) catch |err| try self.handleAndReportParseError(obj.path, err, &parse_ctx); } var system_libs = std.ArrayList(SystemLib).init(arena); try system_libs.ensureUnusedCapacity(self.base.options.system_libs.values().len); for (self.base.options.system_libs.values()) |lib_info| { system_libs.appendAssumeCapacity(.{ .needed = lib_info.needed, .path = lib_info.path.? }); } // libc++ dep if (self.base.options.link_libcpp) { try system_libs.ensureUnusedCapacity(2); system_libs.appendAssumeCapacity(.{ .path = comp.libcxxabi_static_lib.?.full_object_path }); system_libs.appendAssumeCapacity(.{ .path = comp.libcxx_static_lib.?.full_object_path }); } // libunwind dep if (self.base.options.link_libunwind) { try system_libs.append(.{ .path = comp.libunwind_static_lib.?.full_object_path }); } // libc dep self.error_flags.missing_libc = false; if (self.base.options.link_libc) { if (self.base.options.libc_installation) |lc| { const flags = target_util.libcFullLinkFlags(target); try system_libs.ensureUnusedCapacity(flags.len); var test_path = std.ArrayList(u8).init(arena); var checked_paths = std.ArrayList([]const u8).init(arena); for (flags) |flag| { checked_paths.clearRetainingCapacity(); const lib_name = flag["-l".len..]; success: { if (!self.isStatic()) { if (try self.accessLibPath(&test_path, &checked_paths, lc.crt_dir.?, lib_name, .Dynamic)) break :success; } if (try self.accessLibPath(&test_path, &checked_paths, lc.crt_dir.?, lib_name, .Static)) break :success; try self.reportMissingLibraryError( checked_paths.items, "missing system library: '{s}' was not found", .{lib_name}, ); continue; } const resolved_path = try arena.dupe(u8, test_path.items); system_libs.appendAssumeCapacity(.{ .path = resolved_path }); } } else if (target.isGnuLibC()) { try system_libs.ensureUnusedCapacity(glibc.libs.len + 1); for (glibc.libs) |lib| { const lib_path = try std.fmt.allocPrint(arena, "{s}{c}lib{s}.so.{d}", .{ comp.glibc_so_files.?.dir_path, fs.path.sep, lib.name, lib.sover, }); system_libs.appendAssumeCapacity(.{ .path = lib_path }); } system_libs.appendAssumeCapacity(.{ .path = try comp.get_libc_crt_file(arena, "libc_nonshared.a"), }); } else if (target.isMusl()) { const path = try comp.get_libc_crt_file(arena, switch (self.base.options.link_mode) { .Static => "libc.a", .Dynamic => "libc.so", }); try system_libs.append(.{ .path = path }); } else { self.error_flags.missing_libc = true; } } for (system_libs.items) |lib| { var parse_ctx: ParseErrorCtx = .{ .detected_cpu_arch = undefined }; self.parseLibrary(lib, false, &parse_ctx) catch |err| try self.handleAndReportParseError(lib.path, err, &parse_ctx); } // Finally, as the last input objects we add compiler_rt and CSU postlude (if any). positionals.clearRetainingCapacity(); // compiler-rt. Since compiler_rt exports symbols like `memset`, it needs // to be after the shared libraries, so they are picked up from the shared // libraries, not libcompiler_rt. if (compiler_rt_path) |path| try positionals.append(.{ .path = path }); // csu postlude if (csu.crtend) |v| try positionals.append(.{ .path = v }); if (csu.crtn) |v| try positionals.append(.{ .path = v }); for (positionals.items) |obj| { var parse_ctx: ParseErrorCtx = .{ .detected_cpu_arch = undefined }; self.parsePositional(obj.path, obj.must_link, &parse_ctx) catch |err| try self.handleAndReportParseError(obj.path, err, &parse_ctx); } // Dedup shared objects { var seen_dsos = std.StringHashMap(void).init(gpa); defer seen_dsos.deinit(); try seen_dsos.ensureTotalCapacity(@as(u32, @intCast(self.shared_objects.items.len))); var i: usize = 0; while (i < self.shared_objects.items.len) { const index = self.shared_objects.items[i]; const shared_object = self.file(index).?.shared_object; const soname = shared_object.soname(); const gop = seen_dsos.getOrPutAssumeCapacity(soname); if (gop.found_existing) { _ = self.shared_objects.orderedRemove(i); } else i += 1; } } // If we haven't already, create a linker-generated input file comprising of // linker-defined synthetic symbols only such as `_DYNAMIC`, etc. if (self.linker_defined_index == null and !self.isRelocatable()) { const index = @as(File.Index, @intCast(try self.files.addOne(gpa))); self.files.set(index, .{ .linker_defined = .{ .index = index } }); self.linker_defined_index = index; } // Now, we are ready to resolve the symbols across all input files. // We will first resolve the files in the ZigObject, next in the parsed // input Object files. // Any qualifing unresolved symbol will be upgraded to an absolute, weak // symbol for potential resolution at load-time. self.resolveSymbols(); self.markEhFrameAtomsDead(); if (self.isObject()) return self.flushObject(comp); try self.convertCommonSymbols(); self.markImportsExports(); // Look for entry address in objects if not set by the incremental compiler. if (self.entry_index == null) { const entry: ?[]const u8 = entry: { if (self.base.options.entry) |entry| break :entry entry; if (!self.isDynLib()) break :entry "_start"; break :entry null; }; self.entry_index = if (entry) |name| self.globalByName(name) else null; } if (gc_sections) { try gc.gcAtoms(self); if (self.base.options.print_gc_sections) { try gc.dumpPrunedAtoms(self); } } try self.addLinkerDefinedSymbols(); self.claimUnresolved(); // Scan and create missing synthetic entries such as GOT indirection. try self.scanRelocs(); // Generate and emit non-incremental sections. try self.initSections(); try self.initSpecialPhdrs(); try self.sortShdrs(); for (self.objects.items) |index| { try self.file(index).?.object.addAtomsToOutputSections(self); } try self.sortInitFini(); try self.setDynamicSection(rpath_table.keys()); self.sortDynamicSymtab(); try self.setHashSections(); try self.setVersionSymtab(); try self.updateSectionSizes(); try self.allocatePhdrTable(); try self.allocateAllocSections(); try self.sortPhdrs(); try self.allocateNonAllocSections(); self.allocateSpecialPhdrs(); self.allocateAtoms(); self.allocateLinkerDefinedSymbols(); // Dump the state for easy debugging. // State can be dumped via `--debug-log link_state`. if (build_options.enable_logging) { state_log.debug("{}", .{self.dumpState()}); } // Beyond this point, everything has been allocated a virtual address and we can resolve // the relocations, and commit objects to file. if (self.zigObjectPtr()) |zig_object| { for (zig_object.atoms.items) |atom_index| { const atom_ptr = self.atom(atom_index) orelse continue; if (!atom_ptr.flags.alive) continue; const out_shndx = atom_ptr.outputShndx() orelse continue; const shdr = &self.shdrs.items[out_shndx]; if (shdr.sh_type == elf.SHT_NOBITS) continue; const code = try zig_object.codeAlloc(self, atom_index); defer gpa.free(code); const file_offset = shdr.sh_offset + atom_ptr.value - shdr.sh_addr; atom_ptr.resolveRelocsAlloc(self, code) catch |err| switch (err) { // TODO error.RelaxFail, error.InvalidInstruction, error.CannotEncode => { log.err("relaxing intructions failed; TODO this should be a fatal linker error", .{}); }, else => |e| return e, }; try self.base.file.?.pwriteAll(code, file_offset); } } try self.writePhdrTable(); try self.writeShdrTable(); try self.writeAtoms(); try self.writeSyntheticSections(); if (self.entry_index == null and self.isExe()) { log.debug("flushing. no_entry_point_found = true", .{}); self.error_flags.no_entry_point_found = true; } else { log.debug("flushing. no_entry_point_found = false", .{}); self.error_flags.no_entry_point_found = false; try self.writeElfHeader(); } } pub fn flushStaticLib( self: *Elf, comp: *Compilation, positionals: []const Compilation.LinkObject, ) link.File.FlushError!void { _ = comp; if (positionals.len > 0) { var err = try self.addErrorWithNotes(1); try err.addMsg(self, "fatal linker error: too many input positionals", .{}); try err.addNote(self, "TODO implement linking objects into an static library", .{}); return; } const gpa = self.base.allocator; // First, we flush relocatable object file generated with our backends. if (self.zigObjectPtr()) |zig_object| { zig_object.resolveSymbols(self); zig_object.claimUnresolvedObject(self); try self.initSymtab(); try self.initShStrtab(); try self.sortShdrs(); zig_object.updateRelaSectionSizes(self); try self.updateSymtabSize(); self.updateShStrtabSize(); try self.allocateNonAllocSections(); try self.writeShdrTable(); try zig_object.writeRelaSections(self); try self.writeSymtab(); try self.writeShStrtab(); try self.writeElfHeader(); } // TODO parse positionals that we want to make part of the archive // TODO update ar symtab from parsed positionals var ar_symtab: Archive.ArSymtab = .{}; defer ar_symtab.deinit(gpa); if (self.zigObjectPtr()) |zig_object| { try zig_object.updateArSymtab(&ar_symtab, self); } ar_symtab.sort(); // Save object paths in filenames strtab. var ar_strtab: Archive.ArStrtab = .{}; defer ar_strtab.deinit(gpa); if (self.zigObjectPtr()) |zig_object| { try zig_object.updateArStrtab(gpa, &ar_strtab); zig_object.updateArSize(self); } // Update file offsets of contributing objects. const total_size: usize = blk: { var pos: usize = Archive.SARMAG; pos += @sizeOf(Archive.ar_hdr) + ar_symtab.size(.p64); if (ar_strtab.size() > 0) { pos = mem.alignForward(usize, pos, 2); pos += @sizeOf(Archive.ar_hdr) + ar_strtab.size(); } if (self.zigObjectPtr()) |zig_object| { pos = mem.alignForward(usize, pos, 2); zig_object.output_ar_state.file_off = pos; pos += @sizeOf(Archive.ar_hdr) + (math.cast(usize, zig_object.output_ar_state.size) orelse return error.Overflow); } break :blk pos; }; if (build_options.enable_logging) { state_log.debug("ar_symtab\n{}\n", .{ar_symtab.fmt(self)}); state_log.debug("ar_strtab\n{}\n", .{ar_strtab}); } var buffer = std.ArrayList(u8).init(gpa); defer buffer.deinit(); try buffer.ensureTotalCapacityPrecise(total_size); // Write magic try buffer.writer().writeAll(Archive.ARMAG); // Write symtab try ar_symtab.write(.p64, self, buffer.writer()); // Write strtab if (ar_strtab.size() > 0) { if (!mem.isAligned(buffer.items.len, 2)) try buffer.writer().writeByte(0); try ar_strtab.write(buffer.writer()); } // Write object files if (self.zigObjectPtr()) |zig_object| { if (!mem.isAligned(buffer.items.len, 2)) try buffer.writer().writeByte(0); try zig_object.writeAr(self, buffer.writer()); } assert(buffer.items.len == total_size); try self.base.file.?.setEndPos(total_size); try self.base.file.?.pwriteAll(buffer.items, 0); } pub fn flushObject(self: *Elf, comp: *Compilation) link.File.FlushError!void { _ = comp; if (self.objects.items.len > 0) { var err = try self.addErrorWithNotes(1); try err.addMsg(self, "fatal linker error: too many input positionals", .{}); try err.addNote(self, "TODO implement '-r' option", .{}); return; } self.claimUnresolvedObject(); try self.initSections(); try self.sortShdrs(); try self.updateSectionSizes(); try self.allocateNonAllocSections(); if (build_options.enable_logging) { state_log.debug("{}", .{self.dumpState()}); } try self.writeShdrTable(); try self.writeSyntheticSections(); try self.writeElfHeader(); } const ParseError = error{ UnknownFileType, InvalidCpuArch, OutOfMemory, Overflow, InputOutput, EndOfStream, FileSystem, NotSupported, InvalidCharacter, } || LdScript.Error || std.os.AccessError || std.os.SeekError || std.fs.File.OpenError || std.fs.File.ReadError; fn parsePositional(self: *Elf, path: []const u8, must_link: bool, ctx: *ParseErrorCtx) ParseError!void { const tracy = trace(@src()); defer tracy.end(); if (try Object.isObject(path)) { try self.parseObject(path, ctx); } else { try self.parseLibrary(.{ .path = path }, must_link, ctx); } } fn parseLibrary(self: *Elf, lib: SystemLib, must_link: bool, ctx: *ParseErrorCtx) ParseError!void { const tracy = trace(@src()); defer tracy.end(); if (try Archive.isArchive(lib.path)) { try self.parseArchive(lib.path, must_link, ctx); } else if (try SharedObject.isSharedObject(lib.path)) { try self.parseSharedObject(lib, ctx); } else { // TODO if the script has a top-level comment identifying it as GNU ld script, // then report parse errors. Otherwise return UnknownFileType. self.parseLdScript(lib, ctx) catch |err| switch (err) { else => return error.UnknownFileType, }; } } fn parseObject(self: *Elf, path: []const u8, ctx: *ParseErrorCtx) ParseError!void { const tracy = trace(@src()); defer tracy.end(); const gpa = self.base.allocator; const in_file = try std.fs.cwd().openFile(path, .{}); defer in_file.close(); const data = try in_file.readToEndAlloc(gpa, std.math.maxInt(u32)); const index = @as(File.Index, @intCast(try self.files.addOne(gpa))); self.files.set(index, .{ .object = .{ .path = try gpa.dupe(u8, path), .data = data, .index = index, } }); try self.objects.append(gpa, index); const object = self.file(index).?.object; try object.parse(self); ctx.detected_cpu_arch = object.header.?.e_machine.toTargetCpuArch().?; if (ctx.detected_cpu_arch != self.base.options.target.cpu.arch) return error.InvalidCpuArch; } fn parseArchive(self: *Elf, path: []const u8, must_link: bool, ctx: *ParseErrorCtx) ParseError!void { const tracy = trace(@src()); defer tracy.end(); const gpa = self.base.allocator; const in_file = try std.fs.cwd().openFile(path, .{}); defer in_file.close(); const data = try in_file.readToEndAlloc(gpa, std.math.maxInt(u32)); var archive = Archive{ .path = try gpa.dupe(u8, path), .data = data }; defer archive.deinit(gpa); try archive.parse(self); const objects = try archive.objects.toOwnedSlice(gpa); defer gpa.free(objects); for (objects) |extracted| { const index = @as(File.Index, @intCast(try self.files.addOne(gpa))); self.files.set(index, .{ .object = extracted }); const object = &self.files.items(.data)[index].object; object.index = index; object.alive = must_link; try object.parse(self); try self.objects.append(gpa, index); ctx.detected_cpu_arch = object.header.?.e_machine.toTargetCpuArch().?; if (ctx.detected_cpu_arch != self.base.options.target.cpu.arch) return error.InvalidCpuArch; } } fn parseSharedObject(self: *Elf, lib: SystemLib, ctx: *ParseErrorCtx) ParseError!void { const tracy = trace(@src()); defer tracy.end(); const gpa = self.base.allocator; const in_file = try std.fs.cwd().openFile(lib.path, .{}); defer in_file.close(); const data = try in_file.readToEndAlloc(gpa, std.math.maxInt(u32)); const index = @as(File.Index, @intCast(try self.files.addOne(gpa))); self.files.set(index, .{ .shared_object = .{ .path = try gpa.dupe(u8, lib.path), .data = data, .index = index, .needed = lib.needed, .alive = lib.needed, } }); try self.shared_objects.append(gpa, index); const shared_object = self.file(index).?.shared_object; try shared_object.parse(self); ctx.detected_cpu_arch = shared_object.header.?.e_machine.toTargetCpuArch().?; if (ctx.detected_cpu_arch != self.base.options.target.cpu.arch) return error.InvalidCpuArch; } fn parseLdScript(self: *Elf, lib: SystemLib, ctx: *ParseErrorCtx) ParseError!void { const tracy = trace(@src()); defer tracy.end(); const gpa = self.base.allocator; const in_file = try std.fs.cwd().openFile(lib.path, .{}); defer in_file.close(); const data = try in_file.readToEndAlloc(gpa, std.math.maxInt(u32)); defer gpa.free(data); var script = LdScript{}; defer script.deinit(gpa); try script.parse(data, self); if (script.cpu_arch) |cpu_arch| { ctx.detected_cpu_arch = cpu_arch; if (ctx.detected_cpu_arch != self.base.options.target.cpu.arch) return error.InvalidCpuArch; } const lib_dirs = self.base.options.lib_dirs; var arena_allocator = std.heap.ArenaAllocator.init(gpa); defer arena_allocator.deinit(); const arena = arena_allocator.allocator(); var test_path = std.ArrayList(u8).init(arena); var checked_paths = std.ArrayList([]const u8).init(arena); for (script.args.items) |scr_obj| { checked_paths.clearRetainingCapacity(); success: { if (mem.startsWith(u8, scr_obj.path, "-l")) { const lib_name = scr_obj.path["-l".len..]; // TODO I think technically we should re-use the mechanism used by the frontend here. // Maybe we should hoist search-strategy all the way here? for (lib_dirs) |lib_dir| { if (!self.isStatic()) { if (try self.accessLibPath(&test_path, &checked_paths, lib_dir, lib_name, .Dynamic)) break :success; } if (try self.accessLibPath(&test_path, &checked_paths, lib_dir, lib_name, .Static)) break :success; } } else { var buffer: [fs.MAX_PATH_BYTES]u8 = undefined; if (fs.realpath(scr_obj.path, &buffer)) |path| { test_path.clearRetainingCapacity(); try test_path.writer().writeAll(path); break :success; } else |_| {} try checked_paths.append(try gpa.dupe(u8, scr_obj.path)); for (lib_dirs) |lib_dir| { if (try self.accessLibPath(&test_path, &checked_paths, lib_dir, scr_obj.path, null)) break :success; } } try self.reportMissingLibraryError( checked_paths.items, "missing library dependency: GNU ld script '{s}' requires '{s}', but file not found", .{ lib.path, scr_obj.path, }, ); continue; } const full_path = test_path.items; var scr_ctx: ParseErrorCtx = .{ .detected_cpu_arch = undefined }; self.parseLibrary(.{ .needed = scr_obj.needed, .path = full_path, }, false, &scr_ctx) catch |err| try self.handleAndReportParseError(full_path, err, &scr_ctx); } } fn accessLibPath( self: *Elf, test_path: *std.ArrayList(u8), checked_paths: ?*std.ArrayList([]const u8), lib_dir_path: []const u8, lib_name: []const u8, link_mode: ?std.builtin.LinkMode, ) !bool { const sep = fs.path.sep_str; const target = self.base.options.target; test_path.clearRetainingCapacity(); const prefix = if (link_mode != null) "lib" else ""; const suffix = if (link_mode) |mode| switch (mode) { .Static => target.staticLibSuffix(), .Dynamic => target.dynamicLibSuffix(), } else ""; try test_path.writer().print("{s}" ++ sep ++ "{s}{s}{s}", .{ lib_dir_path, prefix, lib_name, suffix, }); if (checked_paths) |cpaths| { try cpaths.append(try self.base.allocator.dupe(u8, test_path.items)); } fs.cwd().access(test_path.items, .{}) catch |err| switch (err) { error.FileNotFound => return false, else => |e| return e, }; return true; } /// When resolving symbols, we approach the problem similarly to `mold`. /// 1. Resolve symbols across all objects (including those preemptively extracted archives). /// 2. Resolve symbols across all shared objects. /// 3. Mark live objects (see `Elf.markLive`) /// 4. Reset state of all resolved globals since we will redo this bit on the pruned set. /// 5. Remove references to dead objects/shared objects /// 6. Re-run symbol resolution on pruned objects and shared objects sets. fn resolveSymbols(self: *Elf) void { // Resolve symbols in the ZigObject. For now, we assume that it's always live. if (self.zigObjectPtr()) |zig_object| zig_object.asFile().resolveSymbols(self); // Resolve symbols on the set of all objects and shared objects (even if some are unneeded). for (self.objects.items) |index| self.file(index).?.resolveSymbols(self); for (self.shared_objects.items) |index| self.file(index).?.resolveSymbols(self); // Mark live objects. self.markLive(); // Reset state of all globals after marking live objects. if (self.zigObjectPtr()) |zig_object| zig_object.asFile().resetGlobals(self); for (self.objects.items) |index| self.file(index).?.resetGlobals(self); for (self.shared_objects.items) |index| self.file(index).?.resetGlobals(self); // Prune dead objects and shared objects. var i: usize = 0; while (i < self.objects.items.len) { const index = self.objects.items[i]; if (!self.file(index).?.isAlive()) { _ = self.objects.orderedRemove(i); } else i += 1; } i = 0; while (i < self.shared_objects.items.len) { const index = self.shared_objects.items[i]; if (!self.file(index).?.isAlive()) { _ = self.shared_objects.orderedRemove(i); } else i += 1; } // Dedup comdat groups. for (self.objects.items) |index| { const object = self.file(index).?.object; for (object.comdat_groups.items) |cg_index| { const cg = self.comdatGroup(cg_index); const cg_owner = self.comdatGroupOwner(cg.owner); const owner_file_index = if (self.file(cg_owner.file)) |file_ptr| file_ptr.object.index else std.math.maxInt(File.Index); cg_owner.file = @min(owner_file_index, index); } } for (self.objects.items) |index| { const object = self.file(index).?.object; for (object.comdat_groups.items) |cg_index| { const cg = self.comdatGroup(cg_index); const cg_owner = self.comdatGroupOwner(cg.owner); if (cg_owner.file != index) { for (object.comdatGroupMembers(cg.shndx)) |shndx| { const atom_index = object.atoms.items[shndx]; if (self.atom(atom_index)) |atom_ptr| { atom_ptr.flags.alive = false; atom_ptr.markFdesDead(self); } } } } } // Re-resolve the symbols. if (self.zigObjectPtr()) |zig_object| zig_object.resolveSymbols(self); for (self.objects.items) |index| self.file(index).?.resolveSymbols(self); for (self.shared_objects.items) |index| self.file(index).?.resolveSymbols(self); } /// Traverses all objects and shared objects marking any object referenced by /// a live object/shared object as alive itself. /// This routine will prune unneeded objects extracted from archives and /// unneeded shared objects. fn markLive(self: *Elf) void { if (self.zigObjectPtr()) |zig_object| zig_object.asFile().markLive(self); for (self.objects.items) |index| { const file_ptr = self.file(index).?; if (file_ptr.isAlive()) file_ptr.markLive(self); } for (self.shared_objects.items) |index| { const file_ptr = self.file(index).?; if (file_ptr.isAlive()) file_ptr.markLive(self); } } fn markEhFrameAtomsDead(self: *Elf) void { for (self.objects.items) |index| { const file_ptr = self.file(index).?; if (!file_ptr.isAlive()) continue; file_ptr.object.markEhFrameAtomsDead(self); } } fn convertCommonSymbols(self: *Elf) !void { for (self.objects.items) |index| { try self.file(index).?.object.convertCommonSymbols(self); } } fn markImportsExports(self: *Elf) void { const mark = struct { fn mark(elf_file: *Elf, file_index: File.Index) void { for (elf_file.file(file_index).?.globals()) |global_index| { const global = elf_file.symbol(global_index); if (global.version_index == elf.VER_NDX_LOCAL) continue; const file_ptr = global.file(elf_file) orelse continue; const vis = @as(elf.STV, @enumFromInt(global.elfSym(elf_file).st_other)); if (vis == .HIDDEN) continue; if (file_ptr == .shared_object and !global.isAbs(elf_file)) { global.flags.import = true; continue; } if (file_ptr.index() == file_index) { global.flags.@"export" = true; if (elf_file.isDynLib() and vis != .PROTECTED) { global.flags.import = true; } } } } }.mark; if (!self.isDynLib()) { for (self.shared_objects.items) |index| { for (self.file(index).?.globals()) |global_index| { const global = self.symbol(global_index); const file_ptr = global.file(self) orelse continue; const vis = @as(elf.STV, @enumFromInt(global.elfSym(self).st_other)); if (file_ptr != .shared_object and vis != .HIDDEN) global.flags.@"export" = true; } } } if (self.zig_object_index) |index| { mark(self, index); } for (self.objects.items) |index| { mark(self, index); } } fn claimUnresolved(self: *Elf) void { if (self.zigObjectPtr()) |zig_object| { zig_object.claimUnresolved(self); } for (self.objects.items) |index| { const object = self.file(index).?.object; object.claimUnresolved(self); } } fn claimUnresolvedObject(self: *Elf) void { if (self.zigObjectPtr()) |zig_object| { zig_object.claimUnresolvedObject(self); } } /// In scanRelocs we will go over all live atoms and scan their relocs. /// This will help us work out what synthetics to emit, GOT indirection, etc. /// This is also the point where we will report undefined symbols for any /// alloc sections. fn scanRelocs(self: *Elf) !void { const gpa = self.base.allocator; var undefs = std.AutoHashMap(Symbol.Index, std.ArrayList(Atom.Index)).init(gpa); defer { var it = undefs.iterator(); while (it.next()) |entry| { entry.value_ptr.deinit(); } undefs.deinit(); } if (self.zigObjectPtr()) |zig_object| { try zig_object.scanRelocs(self, &undefs); } for (self.objects.items) |index| { const object = self.file(index).?.object; try object.scanRelocs(self, &undefs); } try self.reportUndefined(&undefs); for (self.symbols.items, 0..) |*sym, i| { const index = @as(u32, @intCast(i)); if (!sym.isLocal(self) and !sym.flags.has_dynamic) { log.debug("'{s}' is non-local", .{sym.name(self)}); try self.dynsym.addSymbol(index, self); } if (sym.flags.needs_got) { log.debug("'{s}' needs GOT", .{sym.name(self)}); _ = try self.got.addGotSymbol(index, self); } if (sym.flags.needs_plt) { if (sym.flags.is_canonical) { log.debug("'{s}' needs CPLT", .{sym.name(self)}); sym.flags.@"export" = true; try self.plt.addSymbol(index, self); } else if (sym.flags.needs_got) { log.debug("'{s}' needs PLTGOT", .{sym.name(self)}); try self.plt_got.addSymbol(index, self); } else { log.debug("'{s}' needs PLT", .{sym.name(self)}); try self.plt.addSymbol(index, self); } } if (sym.flags.needs_copy_rel and !sym.flags.has_copy_rel) { log.debug("'{s}' needs COPYREL", .{sym.name(self)}); try self.copy_rel.addSymbol(index, self); } if (sym.flags.needs_tlsgd) { log.debug("'{s}' needs TLSGD", .{sym.name(self)}); try self.got.addTlsGdSymbol(index, self); } if (sym.flags.needs_gottp) { log.debug("'{s}' needs GOTTP", .{sym.name(self)}); try self.got.addGotTpSymbol(index, self); } if (sym.flags.needs_tlsdesc) { log.debug("'{s}' needs TLSDESC", .{sym.name(self)}); try self.dynsym.addSymbol(index, self); try self.got.addTlsDescSymbol(index, self); } } if (self.got.flags.needs_tlsld) { log.debug("program needs TLSLD", .{}); try self.got.addTlsLdSymbol(self); } } fn linkWithLLD(self: *Elf, comp: *Compilation, prog_node: *std.Progress.Node) !void { const tracy = trace(@src()); defer tracy.end(); var arena_allocator = std.heap.ArenaAllocator.init(self.base.allocator); defer arena_allocator.deinit(); const arena = arena_allocator.allocator(); const directory = self.base.options.emit.?.directory; // Just an alias to make it shorter to type. const full_out_path = try directory.join(arena, &[_][]const u8{self.base.options.emit.?.sub_path}); // If there is no Zig code to compile, then we should skip flushing the output file because it // will not be part of the linker line anyway. const module_obj_path: ?[]const u8 = if (self.base.options.module != null) blk: { try self.flushModule(comp, prog_node); if (fs.path.dirname(full_out_path)) |dirname| { break :blk try fs.path.join(arena, &.{ dirname, self.base.intermediary_basename.? }); } else { break :blk self.base.intermediary_basename.?; } } else null; var sub_prog_node = prog_node.start("LLD Link", 0); sub_prog_node.activate(); sub_prog_node.context.refresh(); defer sub_prog_node.end(); const is_obj = self.base.options.output_mode == .Obj; const is_lib = self.base.options.output_mode == .Lib; const is_dyn_lib = self.base.options.link_mode == .Dynamic and is_lib; const is_exe_or_dyn_lib = is_dyn_lib or self.base.options.output_mode == .Exe; const have_dynamic_linker = self.base.options.link_libc and self.base.options.link_mode == .Dynamic and is_exe_or_dyn_lib; const target = self.base.options.target; const gc_sections = self.base.options.gc_sections orelse !is_obj; const stack_size = self.base.options.stack_size_override orelse 16777216; const allow_shlib_undefined = self.base.options.allow_shlib_undefined orelse !self.base.options.is_native_os; const compiler_rt_path: ?[]const u8 = blk: { if (comp.compiler_rt_lib) |x| break :blk x.full_object_path; if (comp.compiler_rt_obj) |x| break :blk x.full_object_path; break :blk null; }; // Here we want to determine whether we can save time by not invoking LLD when the // output is unchanged. None of the linker options or the object files that are being // linked are in the hash that namespaces the directory we are outputting to. Therefore, // we must hash those now, and the resulting digest will form the "id" of the linking // job we are about to perform. // After a successful link, we store the id in the metadata of a symlink named "lld.id" in // the artifact directory. So, now, we check if this symlink exists, and if it matches // our digest. If so, we can skip linking. Otherwise, we proceed with invoking LLD. const id_symlink_basename = "lld.id"; var man: Cache.Manifest = undefined; defer if (!self.base.options.disable_lld_caching) man.deinit(); var digest: [Cache.hex_digest_len]u8 = undefined; if (!self.base.options.disable_lld_caching) { man = comp.cache_parent.obtain(); // We are about to obtain this lock, so here we give other processes a chance first. self.base.releaseLock(); comptime assert(Compilation.link_hash_implementation_version == 10); try man.addOptionalFile(self.base.options.linker_script); try man.addOptionalFile(self.base.options.version_script); for (self.base.options.objects) |obj| { _ = try man.addFile(obj.path, null); man.hash.add(obj.must_link); man.hash.add(obj.loption); } for (comp.c_object_table.keys()) |key| { _ = try man.addFile(key.status.success.object_path, null); } try man.addOptionalFile(module_obj_path); try man.addOptionalFile(compiler_rt_path); // We can skip hashing libc and libc++ components that we are in charge of building from Zig // installation sources because they are always a product of the compiler version + target information. man.hash.addOptionalBytes(self.base.options.entry); man.hash.addOptional(self.base.options.image_base_override); man.hash.add(gc_sections); man.hash.addOptional(self.base.options.sort_section); man.hash.add(self.base.options.eh_frame_hdr); man.hash.add(self.base.options.emit_relocs); man.hash.add(self.base.options.rdynamic); man.hash.addListOfBytes(self.base.options.lib_dirs); man.hash.addListOfBytes(self.base.options.rpath_list); man.hash.add(self.base.options.each_lib_rpath); if (self.base.options.output_mode == .Exe) { man.hash.add(stack_size); man.hash.add(self.base.options.build_id); } man.hash.addListOfBytes(self.base.options.symbol_wrap_set.keys()); man.hash.add(self.base.options.skip_linker_dependencies); man.hash.add(self.base.options.z_nodelete); man.hash.add(self.base.options.z_notext); man.hash.add(self.base.options.z_defs); man.hash.add(self.base.options.z_origin); man.hash.add(self.base.options.z_nocopyreloc); man.hash.add(self.base.options.z_now); man.hash.add(self.base.options.z_relro); man.hash.add(self.base.options.z_common_page_size orelse 0); man.hash.add(self.base.options.z_max_page_size orelse 0); man.hash.add(self.base.options.hash_style); // strip does not need to go into the linker hash because it is part of the hash namespace if (self.base.options.link_libc) { man.hash.add(self.base.options.libc_installation != null); if (self.base.options.libc_installation) |libc_installation| { man.hash.addBytes(libc_installation.crt_dir.?); } if (have_dynamic_linker) { man.hash.addOptionalBytes(self.base.options.dynamic_linker); } } man.hash.addOptionalBytes(self.base.options.soname); man.hash.addOptional(self.base.options.version); try link.hashAddSystemLibs(&man, self.base.options.system_libs); man.hash.addListOfBytes(self.base.options.force_undefined_symbols.keys()); man.hash.add(allow_shlib_undefined); man.hash.add(self.base.options.bind_global_refs_locally); man.hash.add(self.base.options.compress_debug_sections); man.hash.add(self.base.options.tsan); man.hash.addOptionalBytes(self.base.options.sysroot); man.hash.add(self.base.options.linker_optimization); // We don't actually care whether it's a cache hit or miss; we just need the digest and the lock. _ = try man.hit(); digest = man.final(); var prev_digest_buf: [digest.len]u8 = undefined; const prev_digest: []u8 = Cache.readSmallFile( directory.handle, id_symlink_basename, &prev_digest_buf, ) catch |err| blk: { log.debug("ELF LLD new_digest={s} error: {s}", .{ std.fmt.fmtSliceHexLower(&digest), @errorName(err) }); // Handle this as a cache miss. break :blk prev_digest_buf[0..0]; }; if (mem.eql(u8, prev_digest, &digest)) { log.debug("ELF LLD digest={s} match - skipping invocation", .{std.fmt.fmtSliceHexLower(&digest)}); // Hot diggity dog! The output binary is already there. self.base.lock = man.toOwnedLock(); return; } log.debug("ELF LLD prev_digest={s} new_digest={s}", .{ std.fmt.fmtSliceHexLower(prev_digest), std.fmt.fmtSliceHexLower(&digest) }); // We are about to change the output file to be different, so we invalidate the build hash now. directory.handle.deleteFile(id_symlink_basename) catch |err| switch (err) { error.FileNotFound => {}, else => |e| return e, }; } // Due to a deficiency in LLD, we need to special-case BPF to a simple file // copy when generating relocatables. Normally, we would expect `lld -r` to work. // However, because LLD wants to resolve BPF relocations which it shouldn't, it fails // before even generating the relocatable. if (self.base.options.output_mode == .Obj and (self.base.options.lto or target.isBpfFreestanding())) { // In this case we must do a simple file copy // here. TODO: think carefully about how we can avoid this redundant operation when doing // build-obj. See also the corresponding TODO in linkAsArchive. const the_object_path = blk: { if (self.base.options.objects.len != 0) break :blk self.base.options.objects[0].path; if (comp.c_object_table.count() != 0) break :blk comp.c_object_table.keys()[0].status.success.object_path; if (module_obj_path) |p| break :blk p; // TODO I think this is unreachable. Audit this situation when solving the above TODO // regarding eliding redundant object -> object transformations. return error.NoObjectsToLink; }; // This can happen when using --enable-cache and using the stage1 backend. In this case // we can skip the file copy. if (!mem.eql(u8, the_object_path, full_out_path)) { try fs.cwd().copyFile(the_object_path, fs.cwd(), full_out_path, .{}); } } else { // Create an LLD command line and invoke it. var argv = std.ArrayList([]const u8).init(self.base.allocator); defer argv.deinit(); // We will invoke ourselves as a child process to gain access to LLD. // This is necessary because LLD does not behave properly as a library - // it calls exit() and does not reset all global data between invocations. const linker_command = "ld.lld"; try argv.appendSlice(&[_][]const u8{ comp.self_exe_path.?, linker_command }); if (is_obj) { try argv.append("-r"); } try argv.append("--error-limit=0"); if (self.base.options.sysroot) |sysroot| { try argv.append(try std.fmt.allocPrint(arena, "--sysroot={s}", .{sysroot})); } if (self.base.options.lto) { switch (self.base.options.optimize_mode) { .Debug => {}, .ReleaseSmall => try argv.append("--lto-O2"), .ReleaseFast, .ReleaseSafe => try argv.append("--lto-O3"), } } try argv.append(try std.fmt.allocPrint(arena, "-O{d}", .{ self.base.options.linker_optimization, })); if (self.base.options.entry) |entry| { try argv.append("--entry"); try argv.append(entry); } for (self.base.options.force_undefined_symbols.keys()) |sym| { try argv.append("-u"); try argv.append(sym); } switch (self.base.options.hash_style) { .gnu => try argv.append("--hash-style=gnu"), .sysv => try argv.append("--hash-style=sysv"), .both => {}, // this is the default } if (self.base.options.output_mode == .Exe) { try argv.append("-z"); try argv.append(try std.fmt.allocPrint(arena, "stack-size={d}", .{stack_size})); switch (self.base.options.build_id) { .none => {}, .fast, .uuid, .sha1, .md5 => { try argv.append(try std.fmt.allocPrint(arena, "--build-id={s}", .{ @tagName(self.base.options.build_id), })); }, .hexstring => |hs| { try argv.append(try std.fmt.allocPrint(arena, "--build-id=0x{s}", .{ std.fmt.fmtSliceHexLower(hs.toSlice()), })); }, } } if (self.base.options.image_base_override) |image_base| { try argv.append(try std.fmt.allocPrint(arena, "--image-base={d}", .{image_base})); } if (self.base.options.linker_script) |linker_script| { try argv.append("-T"); try argv.append(linker_script); } if (self.base.options.sort_section) |how| { const arg = try std.fmt.allocPrint(arena, "--sort-section={s}", .{@tagName(how)}); try argv.append(arg); } if (gc_sections) { try argv.append("--gc-sections"); } if (self.base.options.print_gc_sections) { try argv.append("--print-gc-sections"); } if (self.base.options.print_icf_sections) { try argv.append("--print-icf-sections"); } if (self.base.options.print_map) { try argv.append("--print-map"); } if (self.base.options.eh_frame_hdr) { try argv.append("--eh-frame-hdr"); } if (self.base.options.emit_relocs) { try argv.append("--emit-relocs"); } if (self.base.options.rdynamic) { try argv.append("--export-dynamic"); } if (self.base.options.strip) { try argv.append("-s"); } if (self.base.options.z_nodelete) { try argv.append("-z"); try argv.append("nodelete"); } if (self.base.options.z_notext) { try argv.append("-z"); try argv.append("notext"); } if (self.base.options.z_defs) { try argv.append("-z"); try argv.append("defs"); } if (self.base.options.z_origin) { try argv.append("-z"); try argv.append("origin"); } if (self.base.options.z_nocopyreloc) { try argv.append("-z"); try argv.append("nocopyreloc"); } if (self.base.options.z_now) { // LLD defaults to -zlazy try argv.append("-znow"); } if (!self.base.options.z_relro) { // LLD defaults to -zrelro try argv.append("-znorelro"); } if (self.base.options.z_common_page_size) |size| { try argv.append("-z"); try argv.append(try std.fmt.allocPrint(arena, "common-page-size={d}", .{size})); } if (self.base.options.z_max_page_size) |size| { try argv.append("-z"); try argv.append(try std.fmt.allocPrint(arena, "max-page-size={d}", .{size})); } if (getLDMOption(target)) |ldm| { // Any target ELF will use the freebsd osabi if suffixed with "_fbsd". const arg = if (target.os.tag == .freebsd) try std.fmt.allocPrint(arena, "{s}_fbsd", .{ldm}) else ldm; try argv.append("-m"); try argv.append(arg); } if (self.base.options.link_mode == .Static) { if (target.cpu.arch.isArmOrThumb()) { try argv.append("-Bstatic"); } else { try argv.append("-static"); } } else if (is_dyn_lib) { try argv.append("-shared"); } if (self.base.options.pie and self.base.options.output_mode == .Exe) { try argv.append("-pie"); } if (is_dyn_lib and target.os.tag == .netbsd) { // Add options to produce shared objects with only 2 PT_LOAD segments. // NetBSD expects 2 PT_LOAD segments in a shared object, otherwise // ld.elf_so fails loading dynamic libraries with "not found" error. // See https://github.com/ziglang/zig/issues/9109 . try argv.append("--no-rosegment"); try argv.append("-znorelro"); } try argv.append("-o"); try argv.append(full_out_path); // csu prelude var csu = try CsuObjects.init(arena, self.base.options, comp); if (csu.crt0) |v| try argv.append(v); if (csu.crti) |v| try argv.append(v); if (csu.crtbegin) |v| try argv.append(v); // rpaths var rpath_table = std.StringHashMap(void).init(self.base.allocator); defer rpath_table.deinit(); for (self.base.options.rpath_list) |rpath| { if ((try rpath_table.fetchPut(rpath, {})) == null) { try argv.append("-rpath"); try argv.append(rpath); } } for (self.base.options.symbol_wrap_set.keys()) |symbol_name| { try argv.appendSlice(&.{ "-wrap", symbol_name }); } if (self.base.options.each_lib_rpath) { var test_path = std.ArrayList(u8).init(arena); for (self.base.options.lib_dirs) |lib_dir_path| { for (self.base.options.system_libs.keys()) |link_lib| { if (!(try self.accessLibPath(&test_path, null, lib_dir_path, link_lib, .Dynamic))) continue; if ((try rpath_table.fetchPut(lib_dir_path, {})) == null) { try argv.append("-rpath"); try argv.append(lib_dir_path); } } } for (self.base.options.objects) |obj| { if (Compilation.classifyFileExt(obj.path) == .shared_library) { const lib_dir_path = std.fs.path.dirname(obj.path) orelse continue; if (obj.loption) continue; if ((try rpath_table.fetchPut(lib_dir_path, {})) == null) { try argv.append("-rpath"); try argv.append(lib_dir_path); } } } } for (self.base.options.lib_dirs) |lib_dir| { try argv.append("-L"); try argv.append(lib_dir); } if (self.base.options.link_libc) { if (self.base.options.libc_installation) |libc_installation| { try argv.append("-L"); try argv.append(libc_installation.crt_dir.?); } if (have_dynamic_linker) { if (self.base.options.dynamic_linker) |dynamic_linker| { try argv.append("-dynamic-linker"); try argv.append(dynamic_linker); } } } if (is_dyn_lib) { if (self.base.options.soname) |soname| { try argv.append("-soname"); try argv.append(soname); } if (self.base.options.version_script) |version_script| { try argv.append("-version-script"); try argv.append(version_script); } } // Positional arguments to the linker such as object files. var whole_archive = false; for (self.base.options.objects) |obj| { if (obj.must_link and !whole_archive) { try argv.append("-whole-archive"); whole_archive = true; } else if (!obj.must_link and whole_archive) { try argv.append("-no-whole-archive"); whole_archive = false; } if (obj.loption) { assert(obj.path[0] == ':'); try argv.append("-l"); } try argv.append(obj.path); } if (whole_archive) { try argv.append("-no-whole-archive"); whole_archive = false; } for (comp.c_object_table.keys()) |key| { try argv.append(key.status.success.object_path); } if (module_obj_path) |p| { try argv.append(p); } // TSAN if (self.base.options.tsan) { try argv.append(comp.tsan_static_lib.?.full_object_path); } // libc if (is_exe_or_dyn_lib and !self.base.options.skip_linker_dependencies and !self.base.options.link_libc) { if (comp.libc_static_lib) |lib| { try argv.append(lib.full_object_path); } } // stack-protector. // Related: https://github.com/ziglang/zig/issues/7265 if (comp.libssp_static_lib) |ssp| { try argv.append(ssp.full_object_path); } // Shared libraries. if (is_exe_or_dyn_lib) { const system_libs = self.base.options.system_libs.keys(); const system_libs_values = self.base.options.system_libs.values(); // Worst-case, we need an --as-needed argument for every lib, as well // as one before and one after. try argv.ensureUnusedCapacity(system_libs.len * 2 + 2); argv.appendAssumeCapacity("--as-needed"); var as_needed = true; for (system_libs_values) |lib_info| { const lib_as_needed = !lib_info.needed; switch ((@as(u2, @intFromBool(lib_as_needed)) << 1) | @intFromBool(as_needed)) { 0b00, 0b11 => {}, 0b01 => { argv.appendAssumeCapacity("--no-as-needed"); as_needed = false; }, 0b10 => { argv.appendAssumeCapacity("--as-needed"); as_needed = true; }, } // By this time, we depend on these libs being dynamically linked // libraries and not static libraries (the check for that needs to be earlier), // but they could be full paths to .so files, in which case we // want to avoid prepending "-l". argv.appendAssumeCapacity(lib_info.path.?); } if (!as_needed) { argv.appendAssumeCapacity("--as-needed"); as_needed = true; } // libc++ dep if (self.base.options.link_libcpp) { try argv.append(comp.libcxxabi_static_lib.?.full_object_path); try argv.append(comp.libcxx_static_lib.?.full_object_path); } // libunwind dep if (self.base.options.link_libunwind) { try argv.append(comp.libunwind_static_lib.?.full_object_path); } // libc dep self.error_flags.missing_libc = false; if (self.base.options.link_libc) { if (self.base.options.libc_installation != null) { const needs_grouping = self.base.options.link_mode == .Static; if (needs_grouping) try argv.append("--start-group"); try argv.appendSlice(target_util.libcFullLinkFlags(target)); if (needs_grouping) try argv.append("--end-group"); } else if (target.isGnuLibC()) { for (glibc.libs) |lib| { const lib_path = try std.fmt.allocPrint(arena, "{s}{c}lib{s}.so.{d}", .{ comp.glibc_so_files.?.dir_path, fs.path.sep, lib.name, lib.sover, }); try argv.append(lib_path); } try argv.append(try comp.get_libc_crt_file(arena, "libc_nonshared.a")); } else if (target.isMusl()) { try argv.append(try comp.get_libc_crt_file(arena, switch (self.base.options.link_mode) { .Static => "libc.a", .Dynamic => "libc.so", })); } else { self.error_flags.missing_libc = true; return error.FlushFailure; } } } // compiler-rt. Since compiler_rt exports symbols like `memset`, it needs // to be after the shared libraries, so they are picked up from the shared // libraries, not libcompiler_rt. if (compiler_rt_path) |p| { try argv.append(p); } // crt postlude if (csu.crtend) |v| try argv.append(v); if (csu.crtn) |v| try argv.append(v); if (allow_shlib_undefined) { try argv.append("--allow-shlib-undefined"); } switch (self.base.options.compress_debug_sections) { .none => {}, .zlib => try argv.append("--compress-debug-sections=zlib"), .zstd => try argv.append("--compress-debug-sections=zstd"), } if (self.base.options.bind_global_refs_locally) { try argv.append("-Bsymbolic"); } if (self.base.options.verbose_link) { // Skip over our own name so that the LLD linker name is the first argv item. Compilation.dump_argv(argv.items[1..]); } if (std.process.can_spawn) { // If possible, we run LLD as a child process because it does not always // behave properly as a library, unfortunately. // https://github.com/ziglang/zig/issues/3825 var child = std.ChildProcess.init(argv.items, arena); if (comp.clang_passthrough_mode) { child.stdin_behavior = .Inherit; child.stdout_behavior = .Inherit; child.stderr_behavior = .Inherit; const term = child.spawnAndWait() catch |err| { log.err("unable to spawn {s}: {s}", .{ argv.items[0], @errorName(err) }); return error.UnableToSpawnSelf; }; switch (term) { .Exited => |code| { if (code != 0) { std.process.exit(code); } }, else => std.process.abort(), } } else { child.stdin_behavior = .Ignore; child.stdout_behavior = .Ignore; child.stderr_behavior = .Pipe; try child.spawn(); const stderr = try child.stderr.?.reader().readAllAlloc(arena, std.math.maxInt(usize)); const term = child.wait() catch |err| { log.err("unable to spawn {s}: {s}", .{ argv.items[0], @errorName(err) }); return error.UnableToSpawnSelf; }; switch (term) { .Exited => |code| { if (code != 0) { comp.lockAndParseLldStderr(linker_command, stderr); return error.LLDReportedFailure; } }, else => { log.err("{s} terminated with stderr:\n{s}", .{ argv.items[0], stderr }); return error.LLDCrashed; }, } if (stderr.len != 0) { log.warn("unexpected LLD stderr:\n{s}", .{stderr}); } } } else { const exit_code = try lldMain(arena, argv.items, false); if (exit_code != 0) { if (comp.clang_passthrough_mode) { std.process.exit(exit_code); } else { return error.LLDReportedFailure; } } } } if (!self.base.options.disable_lld_caching) { // Update the file with the digest. If it fails we can continue; it only // means that the next invocation will have an unnecessary cache miss. Cache.writeSmallFile(directory.handle, id_symlink_basename, &digest) catch |err| { log.warn("failed to save linking hash digest file: {s}", .{@errorName(err)}); }; // Again failure here only means an unnecessary cache miss. man.writeManifest() catch |err| { log.warn("failed to write cache manifest when linking: {s}", .{@errorName(err)}); }; // We hang on to this lock so that the output file path can be used without // other processes clobbering it. self.base.lock = man.toOwnedLock(); } } fn writeDwarfAddrAssumeCapacity(self: *Elf, buf: *std.ArrayList(u8), addr: u64) void { const target_endian = self.base.options.target.cpu.arch.endian(); switch (self.ptr_width) { .p32 => mem.writeInt(u32, buf.addManyAsArrayAssumeCapacity(4), @as(u32, @intCast(addr)), target_endian), .p64 => mem.writeInt(u64, buf.addManyAsArrayAssumeCapacity(8), addr, target_endian), } } fn writeShdrTable(self: *Elf) !void { const gpa = self.base.allocator; const target_endian = self.base.options.target.cpu.arch.endian(); const foreign_endian = target_endian != builtin.cpu.arch.endian(); const shsize: u64 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Shdr), .p64 => @sizeOf(elf.Elf64_Shdr), }; const shalign: u16 = switch (self.ptr_width) { .p32 => @alignOf(elf.Elf32_Shdr), .p64 => @alignOf(elf.Elf64_Shdr), }; const shoff = self.shdr_table_offset orelse 0; const needed_size = self.shdrs.items.len * shsize; if (needed_size > self.allocatedSize(shoff)) { self.shdr_table_offset = null; self.shdr_table_offset = self.findFreeSpace(needed_size, shalign); } log.debug("writing section headers from 0x{x} to 0x{x}", .{ self.shdr_table_offset.?, self.shdr_table_offset.? + needed_size, }); switch (self.ptr_width) { .p32 => { const buf = try gpa.alloc(elf.Elf32_Shdr, self.shdrs.items.len); defer gpa.free(buf); for (buf, 0..) |*shdr, i| { shdr.* = shdrTo32(self.shdrs.items[i]); if (foreign_endian) { mem.byteSwapAllFields(elf.Elf32_Shdr, shdr); } } try self.base.file.?.pwriteAll(mem.sliceAsBytes(buf), self.shdr_table_offset.?); }, .p64 => { const buf = try gpa.alloc(elf.Elf64_Shdr, self.shdrs.items.len); defer gpa.free(buf); for (buf, 0..) |*shdr, i| { shdr.* = self.shdrs.items[i]; if (foreign_endian) { mem.byteSwapAllFields(elf.Elf64_Shdr, shdr); } } try self.base.file.?.pwriteAll(mem.sliceAsBytes(buf), self.shdr_table_offset.?); }, } } fn writePhdrTable(self: *Elf) !void { const gpa = self.base.allocator; const target_endian = self.base.options.target.cpu.arch.endian(); const foreign_endian = target_endian != builtin.cpu.arch.endian(); const phdr_table = &self.phdrs.items[self.phdr_table_index.?]; log.debug("writing program headers from 0x{x} to 0x{x}", .{ phdr_table.p_offset, phdr_table.p_offset + phdr_table.p_filesz, }); switch (self.ptr_width) { .p32 => { const buf = try gpa.alloc(elf.Elf32_Phdr, self.phdrs.items.len); defer gpa.free(buf); for (buf, 0..) |*phdr, i| { phdr.* = phdrTo32(self.phdrs.items[i]); if (foreign_endian) { mem.byteSwapAllFields(elf.Elf32_Phdr, phdr); } } try self.base.file.?.pwriteAll(mem.sliceAsBytes(buf), phdr_table.p_offset); }, .p64 => { const buf = try gpa.alloc(elf.Elf64_Phdr, self.phdrs.items.len); defer gpa.free(buf); for (buf, 0..) |*phdr, i| { phdr.* = self.phdrs.items[i]; if (foreign_endian) { mem.byteSwapAllFields(elf.Elf64_Phdr, phdr); } } try self.base.file.?.pwriteAll(mem.sliceAsBytes(buf), phdr_table.p_offset); }, } } fn writeElfHeader(self: *Elf) !void { var hdr_buf: [@sizeOf(elf.Elf64_Ehdr)]u8 = undefined; var index: usize = 0; hdr_buf[0..4].* = elf.MAGIC.*; index += 4; hdr_buf[index] = switch (self.ptr_width) { .p32 => elf.ELFCLASS32, .p64 => elf.ELFCLASS64, }; index += 1; const endian = self.base.options.target.cpu.arch.endian(); hdr_buf[index] = switch (endian) { .little => elf.ELFDATA2LSB, .big => elf.ELFDATA2MSB, }; index += 1; hdr_buf[index] = 1; // ELF version index += 1; // OS ABI, often set to 0 regardless of target platform // ABI Version, possibly used by glibc but not by static executables // padding @memset(hdr_buf[index..][0..9], 0); index += 9; assert(index == 16); const elf_type: elf.ET = switch (self.base.options.output_mode) { .Exe => if (self.base.options.pie) .DYN else .EXEC, .Obj => .REL, .Lib => switch (self.base.options.link_mode) { .Static => @as(elf.ET, .REL), .Dynamic => .DYN, }, }; mem.writeInt(u16, hdr_buf[index..][0..2], @intFromEnum(elf_type), endian); index += 2; const machine = self.base.options.target.cpu.arch.toElfMachine(); mem.writeInt(u16, hdr_buf[index..][0..2], @intFromEnum(machine), endian); index += 2; // ELF Version, again mem.writeInt(u32, hdr_buf[index..][0..4], 1, endian); index += 4; const e_entry = if (self.entry_index) |entry_index| self.symbol(entry_index).value else 0; const phdr_table_offset = if (self.phdr_table_index) |phndx| self.phdrs.items[phndx].p_offset else 0; switch (self.ptr_width) { .p32 => { mem.writeInt(u32, hdr_buf[index..][0..4], @as(u32, @intCast(e_entry)), endian); index += 4; // e_phoff mem.writeInt(u32, hdr_buf[index..][0..4], @as(u32, @intCast(phdr_table_offset)), endian); index += 4; // e_shoff mem.writeInt(u32, hdr_buf[index..][0..4], @as(u32, @intCast(self.shdr_table_offset.?)), endian); index += 4; }, .p64 => { // e_entry mem.writeInt(u64, hdr_buf[index..][0..8], e_entry, endian); index += 8; // e_phoff mem.writeInt(u64, hdr_buf[index..][0..8], phdr_table_offset, endian); index += 8; // e_shoff mem.writeInt(u64, hdr_buf[index..][0..8], self.shdr_table_offset.?, endian); index += 8; }, } const e_flags = 0; mem.writeInt(u32, hdr_buf[index..][0..4], e_flags, endian); index += 4; const e_ehsize: u16 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Ehdr), .p64 => @sizeOf(elf.Elf64_Ehdr), }; mem.writeInt(u16, hdr_buf[index..][0..2], e_ehsize, endian); index += 2; const e_phentsize: u16 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Phdr), .p64 => @sizeOf(elf.Elf64_Phdr), }; mem.writeInt(u16, hdr_buf[index..][0..2], e_phentsize, endian); index += 2; const e_phnum = @as(u16, @intCast(self.phdrs.items.len)); mem.writeInt(u16, hdr_buf[index..][0..2], e_phnum, endian); index += 2; const e_shentsize: u16 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Shdr), .p64 => @sizeOf(elf.Elf64_Shdr), }; mem.writeInt(u16, hdr_buf[index..][0..2], e_shentsize, endian); index += 2; const e_shnum = @as(u16, @intCast(self.shdrs.items.len)); mem.writeInt(u16, hdr_buf[index..][0..2], e_shnum, endian); index += 2; mem.writeInt(u16, hdr_buf[index..][0..2], self.shstrtab_section_index.?, endian); index += 2; assert(index == e_ehsize); try self.base.file.?.pwriteAll(hdr_buf[0..index], 0); } pub fn freeDecl(self: *Elf, decl_index: Module.Decl.Index) void { if (self.llvm_object) |llvm_object| return llvm_object.freeDecl(decl_index); return self.zigObjectPtr().?.freeDecl(self, decl_index); } pub fn updateFunc(self: *Elf, mod: *Module, func_index: InternPool.Index, air: Air, liveness: Liveness) !void { if (build_options.skip_non_native and builtin.object_format != .elf) { @panic("Attempted to compile for object format that was disabled by build configuration"); } if (self.llvm_object) |llvm_object| return llvm_object.updateFunc(mod, func_index, air, liveness); return self.zigObjectPtr().?.updateFunc(self, mod, func_index, air, liveness); } pub fn updateDecl( self: *Elf, mod: *Module, decl_index: Module.Decl.Index, ) link.File.UpdateDeclError!void { if (build_options.skip_non_native and builtin.object_format != .elf) { @panic("Attempted to compile for object format that was disabled by build configuration"); } if (self.llvm_object) |llvm_object| return llvm_object.updateDecl(mod, decl_index); return self.zigObjectPtr().?.updateDecl(self, mod, decl_index); } pub fn lowerUnnamedConst(self: *Elf, typed_value: TypedValue, decl_index: Module.Decl.Index) !u32 { return self.zigObjectPtr().?.lowerUnnamedConst(self, typed_value, decl_index); } pub fn updateExports( self: *Elf, mod: *Module, exported: Module.Exported, exports: []const *Module.Export, ) link.File.UpdateExportsError!void { if (build_options.skip_non_native and builtin.object_format != .elf) { @panic("Attempted to compile for object format that was disabled by build configuration"); } if (self.llvm_object) |llvm_object| return llvm_object.updateExports(mod, exported, exports); if (self.base.options.emit == null) return; return self.zigObjectPtr().?.updateExports(self, mod, exported, exports); } pub fn updateDeclLineNumber(self: *Elf, mod: *Module, decl_index: Module.Decl.Index) !void { if (self.llvm_object) |_| return; return self.zigObjectPtr().?.updateDeclLineNumber(mod, decl_index); } pub fn deleteDeclExport( self: *Elf, decl_index: Module.Decl.Index, name: InternPool.NullTerminatedString, ) void { if (self.llvm_object) |_| return; return self.zigObjectPtr().?.deleteDeclExport(self, decl_index, name); } fn addLinkerDefinedSymbols(self: *Elf) !void { const linker_defined_index = self.linker_defined_index orelse return; const linker_defined = self.file(linker_defined_index).?.linker_defined; self.dynamic_index = try linker_defined.addGlobal("_DYNAMIC", self); self.ehdr_start_index = try linker_defined.addGlobal("__ehdr_start", self); self.init_array_start_index = try linker_defined.addGlobal("__init_array_start", self); self.init_array_end_index = try linker_defined.addGlobal("__init_array_end", self); self.fini_array_start_index = try linker_defined.addGlobal("__fini_array_start", self); self.fini_array_end_index = try linker_defined.addGlobal("__fini_array_end", self); self.preinit_array_start_index = try linker_defined.addGlobal("__preinit_array_start", self); self.preinit_array_end_index = try linker_defined.addGlobal("__preinit_array_end", self); self.got_index = try linker_defined.addGlobal("_GLOBAL_OFFSET_TABLE_", self); self.plt_index = try linker_defined.addGlobal("_PROCEDURE_LINKAGE_TABLE_", self); self.end_index = try linker_defined.addGlobal("_end", self); if (self.base.options.eh_frame_hdr) { self.gnu_eh_frame_hdr_index = try linker_defined.addGlobal("__GNU_EH_FRAME_HDR", self); } if (self.globalByName("__dso_handle")) |index| { if (self.symbol(index).file(self) == null) self.dso_handle_index = try linker_defined.addGlobal("__dso_handle", self); } self.rela_iplt_start_index = try linker_defined.addGlobal("__rela_iplt_start", self); self.rela_iplt_end_index = try linker_defined.addGlobal("__rela_iplt_end", self); for (self.objects.items) |index| { const object = self.file(index).?.object; for (object.atoms.items) |atom_index| { if (self.getStartStopBasename(atom_index)) |name| { const gpa = self.base.allocator; try self.start_stop_indexes.ensureUnusedCapacity(gpa, 2); const start = try std.fmt.allocPrintZ(gpa, "__start_{s}", .{name}); defer gpa.free(start); const stop = try std.fmt.allocPrintZ(gpa, "__stop_{s}", .{name}); defer gpa.free(stop); self.start_stop_indexes.appendAssumeCapacity(try linker_defined.addGlobal(start, self)); self.start_stop_indexes.appendAssumeCapacity(try linker_defined.addGlobal(stop, self)); } } } linker_defined.resolveSymbols(self); } fn allocateLinkerDefinedSymbols(self: *Elf) void { // _DYNAMIC if (self.dynamic_section_index) |shndx| { const shdr = &self.shdrs.items[shndx]; const symbol_ptr = self.symbol(self.dynamic_index.?); symbol_ptr.value = shdr.sh_addr; symbol_ptr.output_section_index = shndx; } // __ehdr_start { const symbol_ptr = self.symbol(self.ehdr_start_index.?); symbol_ptr.value = self.calcImageBase(); symbol_ptr.output_section_index = 1; } // __init_array_start, __init_array_end if (self.sectionByName(".init_array")) |shndx| { const start_sym = self.symbol(self.init_array_start_index.?); const end_sym = self.symbol(self.init_array_end_index.?); const shdr = &self.shdrs.items[shndx]; start_sym.output_section_index = shndx; start_sym.value = shdr.sh_addr; end_sym.output_section_index = shndx; end_sym.value = shdr.sh_addr + shdr.sh_size; } // __fini_array_start, __fini_array_end if (self.sectionByName(".fini_array")) |shndx| { const start_sym = self.symbol(self.fini_array_start_index.?); const end_sym = self.symbol(self.fini_array_end_index.?); const shdr = &self.shdrs.items[shndx]; start_sym.output_section_index = shndx; start_sym.value = shdr.sh_addr; end_sym.output_section_index = shndx; end_sym.value = shdr.sh_addr + shdr.sh_size; } // __preinit_array_start, __preinit_array_end if (self.sectionByName(".preinit_array")) |shndx| { const start_sym = self.symbol(self.preinit_array_start_index.?); const end_sym = self.symbol(self.preinit_array_end_index.?); const shdr = &self.shdrs.items[shndx]; start_sym.output_section_index = shndx; start_sym.value = shdr.sh_addr; end_sym.output_section_index = shndx; end_sym.value = shdr.sh_addr + shdr.sh_size; } // _GLOBAL_OFFSET_TABLE_ if (self.got_plt_section_index) |shndx| { const shdr = &self.shdrs.items[shndx]; const symbol_ptr = self.symbol(self.got_index.?); symbol_ptr.value = shdr.sh_addr; symbol_ptr.output_section_index = shndx; } // _PROCEDURE_LINKAGE_TABLE_ if (self.plt_section_index) |shndx| { const shdr = &self.shdrs.items[shndx]; const symbol_ptr = self.symbol(self.plt_index.?); symbol_ptr.value = shdr.sh_addr; symbol_ptr.output_section_index = shndx; } // __dso_handle if (self.dso_handle_index) |index| { const shdr = &self.shdrs.items[1]; const symbol_ptr = self.symbol(index); symbol_ptr.value = shdr.sh_addr; symbol_ptr.output_section_index = 0; } // __GNU_EH_FRAME_HDR if (self.eh_frame_hdr_section_index) |shndx| { const shdr = &self.shdrs.items[shndx]; const symbol_ptr = self.symbol(self.gnu_eh_frame_hdr_index.?); symbol_ptr.value = shdr.sh_addr; symbol_ptr.output_section_index = shndx; } // __rela_iplt_start, __rela_iplt_end if (self.rela_dyn_section_index) |shndx| blk: { if (self.base.options.link_mode != .Static or self.base.options.pie) break :blk; const shdr = &self.shdrs.items[shndx]; const end_addr = shdr.sh_addr + shdr.sh_size; const start_addr = end_addr - self.calcNumIRelativeRelocs() * @sizeOf(elf.Elf64_Rela); const start_sym = self.symbol(self.rela_iplt_start_index.?); const end_sym = self.symbol(self.rela_iplt_end_index.?); start_sym.value = start_addr; start_sym.output_section_index = shndx; end_sym.value = end_addr; end_sym.output_section_index = shndx; } // _end { const end_symbol = self.symbol(self.end_index.?); for (self.shdrs.items, 0..) |shdr, shndx| { if (shdr.sh_flags & elf.SHF_ALLOC != 0) { end_symbol.value = shdr.sh_addr + shdr.sh_size; end_symbol.output_section_index = @intCast(shndx); } } } // __start_*, __stop_* { var index: usize = 0; while (index < self.start_stop_indexes.items.len) : (index += 2) { const start = self.symbol(self.start_stop_indexes.items[index]); const name = start.name(self); const stop = self.symbol(self.start_stop_indexes.items[index + 1]); const shndx = self.sectionByName(name["__start_".len..]).?; const shdr = &self.shdrs.items[shndx]; start.value = shdr.sh_addr; start.output_section_index = shndx; stop.value = shdr.sh_addr + shdr.sh_size; stop.output_section_index = shndx; } } } fn initSections(self: *Elf) !void { const ptr_size = self.ptrWidthBytes(); for (self.objects.items) |index| { try self.file(index).?.object.initOutputSections(self); } const needs_eh_frame = for (self.objects.items) |index| { if (self.file(index).?.object.cies.items.len > 0) break true; } else false; if (needs_eh_frame) { self.eh_frame_section_index = try self.addSection(.{ .name = ".eh_frame", .type = elf.SHT_PROGBITS, .flags = elf.SHF_ALLOC, .addralign = ptr_size, .offset = std.math.maxInt(u64), }); if (self.base.options.eh_frame_hdr) { self.eh_frame_hdr_section_index = try self.addSection(.{ .name = ".eh_frame_hdr", .type = elf.SHT_PROGBITS, .flags = elf.SHF_ALLOC, .addralign = 4, .offset = std.math.maxInt(u64), }); } } if (self.got.entries.items.len > 0) { self.got_section_index = try self.addSection(.{ .name = ".got", .type = elf.SHT_PROGBITS, .flags = elf.SHF_ALLOC | elf.SHF_WRITE, .addralign = ptr_size, .offset = std.math.maxInt(u64), }); } const needs_rela_dyn = blk: { if (self.got.flags.needs_rela or self.got.flags.needs_tlsld or self.zig_got.flags.needs_rela or self.copy_rel.symbols.items.len > 0) break :blk true; if (self.zigObjectPtr()) |zig_object| { if (zig_object.num_dynrelocs > 0) break :blk true; } for (self.objects.items) |index| { if (self.file(index).?.object.num_dynrelocs > 0) break :blk true; } break :blk false; }; if (needs_rela_dyn) { self.rela_dyn_section_index = try self.addSection(.{ .name = ".rela.dyn", .type = elf.SHT_RELA, .flags = elf.SHF_ALLOC, .addralign = @alignOf(elf.Elf64_Rela), .entsize = @sizeOf(elf.Elf64_Rela), .offset = std.math.maxInt(u64), }); } if (self.plt.symbols.items.len > 0) { self.plt_section_index = try self.addSection(.{ .name = ".plt", .type = elf.SHT_PROGBITS, .flags = elf.SHF_ALLOC | elf.SHF_EXECINSTR, .addralign = 16, .offset = std.math.maxInt(u64), }); self.got_plt_section_index = try self.addSection(.{ .name = ".got.plt", .type = elf.SHT_PROGBITS, .flags = elf.SHF_ALLOC | elf.SHF_WRITE, .addralign = @alignOf(u64), .offset = std.math.maxInt(u64), }); self.rela_plt_section_index = try self.addSection(.{ .name = ".rela.plt", .type = elf.SHT_RELA, .flags = elf.SHF_ALLOC, .addralign = @alignOf(elf.Elf64_Rela), .entsize = @sizeOf(elf.Elf64_Rela), .offset = std.math.maxInt(u64), }); } if (self.plt_got.symbols.items.len > 0) { self.plt_got_section_index = try self.addSection(.{ .name = ".plt.got", .type = elf.SHT_PROGBITS, .flags = elf.SHF_ALLOC | elf.SHF_EXECINSTR, .addralign = 16, .offset = std.math.maxInt(u64), }); } if (self.copy_rel.symbols.items.len > 0) { self.copy_rel_section_index = try self.addSection(.{ .name = ".copyrel", .type = elf.SHT_NOBITS, .flags = elf.SHF_ALLOC | elf.SHF_WRITE, .offset = std.math.maxInt(u64), }); } const needs_interp = blk: { // On Ubuntu with musl-gcc, we get a weird combo of options looking like this: // -dynamic-linker= -static // In this case, if we do generate .interp section and segment, we will get // a segfault in the dynamic linker trying to load a binary that is static // and doesn't contain .dynamic section. if (self.isStatic() and !self.base.options.pie) break :blk false; break :blk self.base.options.dynamic_linker != null; }; if (needs_interp) { self.interp_section_index = try self.addSection(.{ .name = ".interp", .type = elf.SHT_PROGBITS, .flags = elf.SHF_ALLOC, .addralign = 1, .offset = std.math.maxInt(u64), }); } if (self.isDynLib() or self.shared_objects.items.len > 0 or self.base.options.pie) { self.dynstrtab_section_index = try self.addSection(.{ .name = ".dynstr", .flags = elf.SHF_ALLOC, .type = elf.SHT_STRTAB, .entsize = 1, .addralign = 1, .offset = std.math.maxInt(u64), }); self.dynamic_section_index = try self.addSection(.{ .name = ".dynamic", .flags = elf.SHF_ALLOC | elf.SHF_WRITE, .type = elf.SHT_DYNAMIC, .entsize = @sizeOf(elf.Elf64_Dyn), .addralign = @alignOf(elf.Elf64_Dyn), .offset = std.math.maxInt(u64), }); self.dynsymtab_section_index = try self.addSection(.{ .name = ".dynsym", .flags = elf.SHF_ALLOC, .type = elf.SHT_DYNSYM, .addralign = @alignOf(elf.Elf64_Sym), .entsize = @sizeOf(elf.Elf64_Sym), .info = 1, .offset = std.math.maxInt(u64), }); self.hash_section_index = try self.addSection(.{ .name = ".hash", .flags = elf.SHF_ALLOC, .type = elf.SHT_HASH, .addralign = 4, .entsize = 4, .offset = std.math.maxInt(u64), }); self.gnu_hash_section_index = try self.addSection(.{ .name = ".gnu.hash", .flags = elf.SHF_ALLOC, .type = elf.SHT_GNU_HASH, .addralign = 8, .offset = std.math.maxInt(u64), }); const needs_versions = for (self.dynsym.entries.items) |entry| { const sym = self.symbol(entry.symbol_index); if (sym.flags.import and sym.version_index & elf.VERSYM_VERSION > elf.VER_NDX_GLOBAL) break true; } else false; if (needs_versions) { self.versym_section_index = try self.addSection(.{ .name = ".gnu.version", .flags = elf.SHF_ALLOC, .type = elf.SHT_GNU_VERSYM, .addralign = @alignOf(elf.Elf64_Versym), .entsize = @sizeOf(elf.Elf64_Versym), .offset = std.math.maxInt(u64), }); self.verneed_section_index = try self.addSection(.{ .name = ".gnu.version_r", .flags = elf.SHF_ALLOC, .type = elf.SHT_GNU_VERNEED, .addralign = @alignOf(elf.Elf64_Verneed), .offset = std.math.maxInt(u64), }); } } try self.initSymtab(); try self.initShStrtab(); } fn initSymtab(self: *Elf) !void { const small_ptr = switch (self.ptr_width) { .p32 => true, .p64 => false, }; if (self.symtab_section_index == null) { self.symtab_section_index = try self.addSection(.{ .name = ".symtab", .type = elf.SHT_SYMTAB, .addralign = if (small_ptr) @alignOf(elf.Elf32_Sym) else @alignOf(elf.Elf64_Sym), .entsize = if (small_ptr) @sizeOf(elf.Elf32_Sym) else @sizeOf(elf.Elf64_Sym), .offset = std.math.maxInt(u64), }); } if (self.strtab_section_index == null) { self.strtab_section_index = try self.addSection(.{ .name = ".strtab", .type = elf.SHT_STRTAB, .entsize = 1, .addralign = 1, .offset = std.math.maxInt(u64), }); } } fn initShStrtab(self: *Elf) !void { if (self.shstrtab_section_index == null) { self.shstrtab_section_index = try self.addSection(.{ .name = ".shstrtab", .type = elf.SHT_STRTAB, .entsize = 1, .addralign = 1, .offset = std.math.maxInt(u64), }); } } fn initSpecialPhdrs(self: *Elf) !void { comptime assert(max_number_of_special_phdrs == 5); if (self.interp_section_index != null) { self.phdr_interp_index = try self.addPhdr(.{ .type = elf.PT_INTERP, .flags = elf.PF_R, .@"align" = 1, }); } if (self.dynamic_section_index != null) { self.phdr_dynamic_index = try self.addPhdr(.{ .type = elf.PT_DYNAMIC, .flags = elf.PF_R | elf.PF_W, }); } if (self.eh_frame_hdr_section_index != null) { self.phdr_gnu_eh_frame_index = try self.addPhdr(.{ .type = elf.PT_GNU_EH_FRAME, .flags = elf.PF_R, }); } self.phdr_gnu_stack_index = try self.addPhdr(.{ .type = elf.PT_GNU_STACK, .flags = elf.PF_W | elf.PF_R, .memsz = self.base.options.stack_size_override orelse 0, .@"align" = 1, }); const has_tls = for (self.shdrs.items) |shdr| { if (shdr.sh_flags & elf.SHF_TLS != 0) break true; } else false; if (has_tls) { self.phdr_tls_index = try self.addPhdr(.{ .type = elf.PT_TLS, .flags = elf.PF_R, .@"align" = 1, }); } } /// We need to sort constructors/destuctors in the following sections: /// * .init_array /// * .fini_array /// * .preinit_array /// * .ctors /// * .dtors /// The prority of inclusion is defined as part of the input section's name. For example, .init_array.10000. /// If no priority value has been specified, /// * for .init_array, .fini_array and .preinit_array, we automatically assign that section max value of maxInt(i32) /// and push it to the back of the queue, /// * for .ctors and .dtors, we automatically assign that section min value of -1 /// and push it to the front of the queue, /// crtbegin and ctrend are assigned minInt(i32) and maxInt(i32) respectively. /// Ties are broken by the file prority which corresponds to the inclusion of input sections in this output section /// we are about to sort. fn sortInitFini(self: *Elf) !void { const gpa = self.base.allocator; const Entry = struct { priority: i32, atom_index: Atom.Index, pub fn lessThan(ctx: *Elf, lhs: @This(), rhs: @This()) bool { if (lhs.priority == rhs.priority) { return ctx.atom(lhs.atom_index).?.priority(ctx) < ctx.atom(rhs.atom_index).?.priority(ctx); } return lhs.priority < rhs.priority; } }; for (self.shdrs.items, 0..) |*shdr, shndx| { if (shdr.sh_flags & elf.SHF_ALLOC == 0) continue; var is_init_fini = false; var is_ctor_dtor = false; switch (shdr.sh_type) { elf.SHT_PREINIT_ARRAY, elf.SHT_INIT_ARRAY, elf.SHT_FINI_ARRAY, => is_init_fini = true, else => { const name = self.getShString(shdr.sh_name); is_ctor_dtor = mem.indexOf(u8, name, ".ctors") != null or mem.indexOf(u8, name, ".dtors") != null; }, } if (!is_init_fini and !is_ctor_dtor) continue; const atom_list = self.output_sections.getPtr(@intCast(shndx)) orelse continue; var entries = std.ArrayList(Entry).init(gpa); try entries.ensureTotalCapacityPrecise(atom_list.items.len); defer entries.deinit(); for (atom_list.items) |atom_index| { const atom_ptr = self.atom(atom_index).?; const object = atom_ptr.file(self).?.object; const priority = blk: { if (is_ctor_dtor) { if (mem.indexOf(u8, object.path, "crtbegin") != null) break :blk std.math.minInt(i32); if (mem.indexOf(u8, object.path, "crtend") != null) break :blk std.math.maxInt(i32); } const default: i32 = if (is_ctor_dtor) -1 else std.math.maxInt(i32); const name = atom_ptr.name(self); var it = mem.splitBackwards(u8, name, "."); const priority = std.fmt.parseUnsigned(u16, it.first(), 10) catch default; break :blk priority; }; entries.appendAssumeCapacity(.{ .priority = priority, .atom_index = atom_index }); } mem.sort(Entry, entries.items, self, Entry.lessThan); atom_list.clearRetainingCapacity(); for (entries.items) |entry| { atom_list.appendAssumeCapacity(entry.atom_index); } } } fn setDynamicSection(self: *Elf, rpaths: []const []const u8) !void { if (self.dynamic_section_index == null) return; for (self.shared_objects.items) |index| { const shared_object = self.file(index).?.shared_object; if (!shared_object.alive) continue; try self.dynamic.addNeeded(shared_object, self); } if (self.base.options.soname) |soname| { try self.dynamic.setSoname(soname, self); } try self.dynamic.setRpath(rpaths, self); } fn sortDynamicSymtab(self: *Elf) void { if (self.gnu_hash_section_index == null) return; self.dynsym.sort(self); } fn setVersionSymtab(self: *Elf) !void { if (self.versym_section_index == null) return; try self.versym.resize(self.base.allocator, self.dynsym.count()); self.versym.items[0] = elf.VER_NDX_LOCAL; for (self.dynsym.entries.items, 1..) |entry, i| { const sym = self.symbol(entry.symbol_index); self.versym.items[i] = sym.version_index; } if (self.verneed_section_index) |shndx| { try self.verneed.generate(self); const shdr = &self.shdrs.items[shndx]; shdr.sh_info = @as(u32, @intCast(self.verneed.verneed.items.len)); } } fn setHashSections(self: *Elf) !void { if (self.hash_section_index != null) { try self.hash.generate(self); } if (self.gnu_hash_section_index != null) { try self.gnu_hash.calcSize(self); } } fn phdrRank(phdr: elf.Elf64_Phdr) u8 { switch (phdr.p_type) { elf.PT_NULL => return 0, elf.PT_PHDR => return 1, elf.PT_INTERP => return 2, elf.PT_LOAD => return 3, elf.PT_DYNAMIC, elf.PT_TLS => return 4, elf.PT_GNU_EH_FRAME => return 5, elf.PT_GNU_STACK => return 6, else => return 7, } } fn sortPhdrs(self: *Elf) error{OutOfMemory}!void { const Entry = struct { phndx: u16, pub fn lessThan(elf_file: *Elf, lhs: @This(), rhs: @This()) bool { const lhs_phdr = elf_file.phdrs.items[lhs.phndx]; const rhs_phdr = elf_file.phdrs.items[rhs.phndx]; const lhs_rank = phdrRank(lhs_phdr); const rhs_rank = phdrRank(rhs_phdr); if (lhs_rank == rhs_rank) return lhs_phdr.p_vaddr < rhs_phdr.p_vaddr; return lhs_rank < rhs_rank; } }; const gpa = self.base.allocator; var entries = try std.ArrayList(Entry).initCapacity(gpa, self.phdrs.items.len); defer entries.deinit(); for (0..self.phdrs.items.len) |phndx| { entries.appendAssumeCapacity(.{ .phndx = @as(u16, @intCast(phndx)) }); } mem.sort(Entry, entries.items, self, Entry.lessThan); const backlinks = try gpa.alloc(u16, entries.items.len); defer gpa.free(backlinks); for (entries.items, 0..) |entry, i| { backlinks[entry.phndx] = @as(u16, @intCast(i)); } var slice = try self.phdrs.toOwnedSlice(gpa); defer gpa.free(slice); try self.phdrs.ensureTotalCapacityPrecise(gpa, slice.len); for (entries.items) |sorted| { self.phdrs.appendAssumeCapacity(slice[sorted.phndx]); } for (&[_]*?u16{ &self.phdr_zig_load_re_index, &self.phdr_zig_got_index, &self.phdr_zig_load_ro_index, &self.phdr_zig_load_zerofill_index, &self.phdr_table_index, &self.phdr_table_load_index, &self.phdr_interp_index, &self.phdr_dynamic_index, &self.phdr_gnu_eh_frame_index, &self.phdr_tls_index, }) |maybe_index| { if (maybe_index.*) |*index| { index.* = backlinks[index.*]; } } { var it = self.phdr_to_shdr_table.iterator(); while (it.next()) |entry| { entry.value_ptr.* = backlinks[entry.value_ptr.*]; } } } fn shdrRank(self: *Elf, shndx: u16) u8 { const shdr = self.shdrs.items[shndx]; const name = self.getShString(shdr.sh_name); const flags = shdr.sh_flags; switch (shdr.sh_type) { elf.SHT_NULL => return 0, elf.SHT_DYNSYM => return 2, elf.SHT_HASH => return 3, elf.SHT_GNU_HASH => return 3, elf.SHT_GNU_VERSYM => return 4, elf.SHT_GNU_VERDEF => return 4, elf.SHT_GNU_VERNEED => return 4, elf.SHT_PREINIT_ARRAY, elf.SHT_INIT_ARRAY, elf.SHT_FINI_ARRAY, => return 0xf2, elf.SHT_DYNAMIC => return 0xf3, elf.SHT_RELA => return 0xf, elf.SHT_PROGBITS => if (flags & elf.SHF_ALLOC != 0) { if (flags & elf.SHF_EXECINSTR != 0) { return 0xf1; } else if (flags & elf.SHF_WRITE != 0) { return if (flags & elf.SHF_TLS != 0) 0xf4 else 0xf6; } else if (mem.eql(u8, name, ".interp")) { return 1; } else { return 0xf0; } } else { if (mem.startsWith(u8, name, ".debug")) { return 0xf8; } else { return 0xf9; } }, elf.SHT_NOBITS => return if (flags & elf.SHF_TLS != 0) 0xf5 else 0xf7, elf.SHT_SYMTAB => return 0xfa, elf.SHT_STRTAB => return if (mem.eql(u8, name, ".dynstr")) 0x4 else 0xfb, else => return 0xff, } } fn sortShdrs(self: *Elf) !void { const Entry = struct { shndx: u16, pub fn lessThan(elf_file: *Elf, lhs: @This(), rhs: @This()) bool { return elf_file.shdrRank(lhs.shndx) < elf_file.shdrRank(rhs.shndx); } }; const gpa = self.base.allocator; var entries = try std.ArrayList(Entry).initCapacity(gpa, self.shdrs.items.len); defer entries.deinit(); for (0..self.shdrs.items.len) |shndx| { entries.appendAssumeCapacity(.{ .shndx = @as(u16, @intCast(shndx)) }); } mem.sort(Entry, entries.items, self, Entry.lessThan); const backlinks = try gpa.alloc(u16, entries.items.len); defer gpa.free(backlinks); for (entries.items, 0..) |entry, i| { backlinks[entry.shndx] = @as(u16, @intCast(i)); } var slice = try self.shdrs.toOwnedSlice(gpa); defer gpa.free(slice); try self.shdrs.ensureTotalCapacityPrecise(gpa, slice.len); for (entries.items) |sorted| { self.shdrs.appendAssumeCapacity(slice[sorted.shndx]); } for (&[_]*?u16{ &self.eh_frame_section_index, &self.eh_frame_hdr_section_index, &self.got_section_index, &self.symtab_section_index, &self.strtab_section_index, &self.shstrtab_section_index, &self.interp_section_index, &self.dynamic_section_index, &self.dynsymtab_section_index, &self.dynstrtab_section_index, &self.hash_section_index, &self.gnu_hash_section_index, &self.plt_section_index, &self.got_plt_section_index, &self.plt_got_section_index, &self.rela_dyn_section_index, &self.rela_plt_section_index, &self.copy_rel_section_index, &self.versym_section_index, &self.verneed_section_index, &self.zig_text_section_index, &self.zig_text_rela_section_index, &self.zig_got_section_index, &self.zig_data_rel_ro_section_index, &self.zig_data_rel_ro_rela_section_index, &self.zig_data_section_index, &self.zig_data_rela_section_index, &self.zig_bss_section_index, &self.debug_str_section_index, &self.debug_info_section_index, &self.debug_abbrev_section_index, &self.debug_aranges_section_index, &self.debug_line_section_index, }) |maybe_index| { if (maybe_index.*) |*index| { index.* = backlinks[index.*]; } } if (self.symtab_section_index) |index| { const shdr = &self.shdrs.items[index]; shdr.sh_link = self.strtab_section_index.?; } if (self.dynamic_section_index) |index| { const shdr = &self.shdrs.items[index]; shdr.sh_link = self.dynstrtab_section_index.?; } if (self.dynsymtab_section_index) |index| { const shdr = &self.shdrs.items[index]; shdr.sh_link = self.dynstrtab_section_index.?; } if (self.hash_section_index) |index| { const shdr = &self.shdrs.items[index]; shdr.sh_link = self.dynsymtab_section_index.?; } if (self.gnu_hash_section_index) |index| { const shdr = &self.shdrs.items[index]; shdr.sh_link = self.dynsymtab_section_index.?; } if (self.versym_section_index) |index| { const shdr = &self.shdrs.items[index]; shdr.sh_link = self.dynsymtab_section_index.?; } if (self.verneed_section_index) |index| { const shdr = &self.shdrs.items[index]; shdr.sh_link = self.dynstrtab_section_index.?; } if (self.rela_dyn_section_index) |index| { const shdr = &self.shdrs.items[index]; shdr.sh_link = self.dynsymtab_section_index orelse 0; } if (self.rela_plt_section_index) |index| { const shdr = &self.shdrs.items[index]; shdr.sh_link = self.dynsymtab_section_index.?; shdr.sh_info = self.plt_section_index.?; } for (&[_]?u16{ self.zig_text_rela_section_index, self.zig_data_rel_ro_rela_section_index, self.zig_data_rela_section_index, }) |maybe_index| { const index = maybe_index orelse continue; const shdr = &self.shdrs.items[index]; shdr.sh_link = self.symtab_section_index.?; shdr.sh_info = backlinks[shdr.sh_info]; } { var last_atom_and_free_list_table = try self.last_atom_and_free_list_table.clone(gpa); defer last_atom_and_free_list_table.deinit(gpa); self.last_atom_and_free_list_table.clearRetainingCapacity(); var it = last_atom_and_free_list_table.iterator(); while (it.next()) |entry| { const shndx = entry.key_ptr.*; const meta = entry.value_ptr.*; self.last_atom_and_free_list_table.putAssumeCapacityNoClobber(backlinks[shndx], meta); } } { var phdr_to_shdr_table = try self.phdr_to_shdr_table.clone(gpa); defer phdr_to_shdr_table.deinit(gpa); self.phdr_to_shdr_table.clearRetainingCapacity(); var it = phdr_to_shdr_table.iterator(); while (it.next()) |entry| { const shndx = entry.key_ptr.*; const phndx = entry.value_ptr.*; self.phdr_to_shdr_table.putAssumeCapacityNoClobber(backlinks[shndx], phndx); } } if (self.zigObjectPtr()) |zig_object| { for (zig_object.atoms.items) |atom_index| { const atom_ptr = self.atom(atom_index) orelse continue; atom_ptr.output_section_index = backlinks[atom_ptr.output_section_index]; } for (zig_object.locals()) |local_index| { const local = self.symbol(local_index); local.output_section_index = backlinks[local.output_section_index]; } for (zig_object.globals()) |global_index| { const global = self.symbol(global_index); const atom_ptr = global.atom(self) orelse continue; if (!atom_ptr.flags.alive) continue; // TODO claim unresolved for objects if (global.file(self).?.index() != zig_object.index) continue; const out_shndx = global.outputShndx() orelse continue; global.output_section_index = backlinks[out_shndx]; } } } fn updateSectionSizes(self: *Elf) !void { for (self.output_sections.keys(), self.output_sections.values()) |shndx, atom_list| { if (atom_list.items.len == 0) continue; const shdr = &self.shdrs.items[shndx]; for (atom_list.items) |atom_index| { const atom_ptr = self.atom(atom_index) orelse continue; if (!atom_ptr.flags.alive) continue; const offset = atom_ptr.alignment.forward(shdr.sh_size); const padding = offset - shdr.sh_size; atom_ptr.value = offset; shdr.sh_size += padding + atom_ptr.size; shdr.sh_addralign = @max(shdr.sh_addralign, atom_ptr.alignment.toByteUnits(1)); } } if (self.zigObjectPtr()) |zig_object| { zig_object.updateRelaSectionSizes(self); } if (self.eh_frame_section_index) |index| { self.shdrs.items[index].sh_size = try eh_frame.calcEhFrameSize(self); } if (self.eh_frame_hdr_section_index) |index| { self.shdrs.items[index].sh_size = eh_frame.calcEhFrameHdrSize(self); } if (self.got_section_index) |index| { self.shdrs.items[index].sh_size = self.got.size(self); } if (self.plt_section_index) |index| { self.shdrs.items[index].sh_size = self.plt.size(); } if (self.got_plt_section_index) |index| { self.shdrs.items[index].sh_size = self.got_plt.size(self); } if (self.plt_got_section_index) |index| { self.shdrs.items[index].sh_size = self.plt_got.size(); } if (self.rela_dyn_section_index) |shndx| { var num = self.got.numRela(self) + self.copy_rel.numRela() + self.zig_got.numRela(); if (self.zigObjectPtr()) |zig_object| { num += zig_object.num_dynrelocs; } for (self.objects.items) |index| { num += self.file(index).?.object.num_dynrelocs; } self.shdrs.items[shndx].sh_size = num * @sizeOf(elf.Elf64_Rela); } if (self.rela_plt_section_index) |index| { self.shdrs.items[index].sh_size = self.plt.numRela() * @sizeOf(elf.Elf64_Rela); } if (self.copy_rel_section_index) |index| { try self.copy_rel.updateSectionSize(index, self); } if (self.interp_section_index) |index| { self.shdrs.items[index].sh_size = self.base.options.dynamic_linker.?.len + 1; } if (self.hash_section_index) |index| { self.shdrs.items[index].sh_size = self.hash.size(); } if (self.gnu_hash_section_index) |index| { self.shdrs.items[index].sh_size = self.gnu_hash.size(); } if (self.dynamic_section_index) |index| { self.shdrs.items[index].sh_size = self.dynamic.size(self); } if (self.dynsymtab_section_index) |index| { self.shdrs.items[index].sh_size = self.dynsym.size(); } if (self.dynstrtab_section_index) |index| { self.shdrs.items[index].sh_size = self.dynstrtab.items.len; } if (self.versym_section_index) |index| { self.shdrs.items[index].sh_size = self.versym.items.len * @sizeOf(elf.Elf64_Versym); } if (self.verneed_section_index) |index| { self.shdrs.items[index].sh_size = self.verneed.size(); } try self.updateSymtabSize(); self.updateShStrtabSize(); } fn updateShStrtabSize(self: *Elf) void { if (self.shstrtab_section_index) |index| { self.shdrs.items[index].sh_size = self.shstrtab.items.len; } } fn shdrToPhdrFlags(sh_flags: u64) u32 { const write = sh_flags & elf.SHF_WRITE != 0; const exec = sh_flags & elf.SHF_EXECINSTR != 0; var out_flags: u32 = elf.PF_R; if (write) out_flags |= elf.PF_W; if (exec) out_flags |= elf.PF_X; return out_flags; } /// Returns maximum number of program headers that may be emitted by the linker. /// (This is an upper bound so that we can reserve enough space for the header and progam header /// table without running out of space and being forced to move things around.) fn getMaxNumberOfPhdrs() u64 { // First, assume we compile Zig's source incrementally, this gives us: var num: u64 = number_of_zig_segments; // Next, the estimated maximum number of segments the linker can emit for input sections are: num += max_number_of_object_segments; // Next, any other non-loadable program headers, including TLS, DYNAMIC, GNU_STACK, GNU_EH_FRAME, INTERP: num += max_number_of_special_phdrs; // Finally, PHDR program header and corresponding read-only load segment: num += 2; return num; } /// Calculates how many segments (PT_LOAD progam headers) are required /// to cover the set of sections. /// We permit a maximum of 3**2 number of segments. fn calcNumberOfSegments(self: *Elf) usize { var covers: [9]bool = [_]bool{false} ** 9; for (self.shdrs.items, 0..) |shdr, shndx| { if (shdr.sh_type == elf.SHT_NULL) continue; if (shdr.sh_flags & elf.SHF_ALLOC == 0) continue; if (self.isZigSection(@intCast(shndx))) continue; const flags = shdrToPhdrFlags(shdr.sh_flags); covers[flags - 1] = true; } var count: usize = 0; for (covers) |cover| { if (cover) count += 1; } return count; } /// Allocates PHDR table in virtual memory and in file. fn allocatePhdrTable(self: *Elf) error{OutOfMemory}!void { const new_load_segments = self.calcNumberOfSegments(); const phdr_table = &self.phdrs.items[self.phdr_table_index.?]; const phdr_table_load = &self.phdrs.items[self.phdr_table_load_index.?]; const ehsize: u64 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Ehdr), .p64 => @sizeOf(elf.Elf64_Ehdr), }; const phsize: u64 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Phdr), .p64 => @sizeOf(elf.Elf64_Phdr), }; const needed_size = (self.phdrs.items.len + new_load_segments) * phsize; const available_space = self.allocatedSize(phdr_table.p_offset); if (needed_size > available_space) { // In this case, we have two options: // 1. increase the available padding for EHDR + PHDR table so that we don't overflow it // (revisit getMaxNumberOfPhdrs()) // 2. shift everything in file to free more space for EHDR + PHDR table // TODO verify `getMaxNumberOfPhdrs()` is accurate and convert this into no-op var err = try self.addErrorWithNotes(1); try err.addMsg(self, "fatal linker error: not enough space reserved for EHDR and PHDR table", .{}); try err.addNote(self, "required 0x{x}, available 0x{x}", .{ needed_size, available_space }); } phdr_table_load.p_filesz = needed_size + ehsize; phdr_table_load.p_memsz = needed_size + ehsize; phdr_table.p_filesz = needed_size; phdr_table.p_memsz = needed_size; } /// Allocates alloc sections and creates load segments for sections /// extracted from input object files. fn allocateAllocSections(self: *Elf) error{OutOfMemory}!void { // We use this struct to track maximum alignment of all TLS sections. // According to https://github.com/rui314/mold/commit/bd46edf3f0fe9e1a787ea453c4657d535622e61f in mold, // in-file offsets have to be aligned against the start of TLS program header. // If that's not ensured, then in a multi-threaded context, TLS variables across a shared object // boundary may not get correctly loaded at an aligned address. const Align = struct { tls_start_align: u64 = 1, first_tls_index: ?usize = null, fn isFirstTlsShdr(this: @This(), other: usize) bool { if (this.first_tls_index) |index| return index == other; return false; } fn @"align"(this: @This(), index: usize, sh_addralign: u64, addr: u64) u64 { const alignment = if (this.isFirstTlsShdr(index)) this.tls_start_align else sh_addralign; return mem.alignForward(u64, addr, alignment); } }; var alignment = Align{}; for (self.shdrs.items, 0..) |shdr, i| { if (shdr.sh_type == elf.SHT_NULL) continue; if (shdr.sh_flags & elf.SHF_TLS == 0) continue; if (alignment.first_tls_index == null) alignment.first_tls_index = i; alignment.tls_start_align = @max(alignment.tls_start_align, shdr.sh_addralign); } // Next, calculate segment covers by scanning all alloc sections. // If a section matches segment flags with the preceeding section, // we put it in the same segment. Otherwise, we create a new cover. // This algorithm is simple but suboptimal in terms of space re-use: // normally we would also take into account any gaps in allocated // virtual and file offsets. However, the simple one will do for one // as we are more interested in quick turnaround and compatibility // with `findFreeSpace` mechanics than anything else. const Cover = std.ArrayList(u16); const gpa = self.base.allocator; var covers: [max_number_of_object_segments]Cover = undefined; for (&covers) |*cover| { cover.* = Cover.init(gpa); } defer for (&covers) |*cover| { cover.deinit(); }; for (self.shdrs.items, 0..) |shdr, shndx| { if (shdr.sh_type == elf.SHT_NULL) continue; if (shdr.sh_flags & elf.SHF_ALLOC == 0) continue; if (self.isZigSection(@intCast(shndx))) continue; const flags = shdrToPhdrFlags(shdr.sh_flags); try covers[flags - 1].append(@intCast(shndx)); } // Now we can proceed with allocating the sections in virtual memory. // As the base address we take the end address of the PHDR table. // When allocating we first find the largest required alignment // of any section that is contained in a cover and use it to align // the start address of the segement (and first section). const phdr_table = &self.phdrs.items[self.phdr_table_load_index.?]; var addr = phdr_table.p_vaddr + phdr_table.p_memsz; for (covers) |cover| { if (cover.items.len == 0) continue; var @"align": u64 = self.page_size; for (cover.items) |shndx| { const shdr = self.shdrs.items[shndx]; if (shdr.sh_type == elf.SHT_NOBITS and shdr.sh_flags & elf.SHF_TLS != 0) continue; @"align" = @max(@"align", shdr.sh_addralign); } addr = mem.alignForward(u64, addr, @"align"); var memsz: u64 = 0; var filesz: u64 = 0; var i: usize = 0; while (i < cover.items.len) : (i += 1) { const shndx = cover.items[i]; const shdr = &self.shdrs.items[shndx]; if (shdr.sh_type == elf.SHT_NOBITS and shdr.sh_flags & elf.SHF_TLS != 0) { // .tbss is a little special as it's used only by the loader meaning it doesn't // need to be actually mmap'ed at runtime. We still need to correctly increment // the addresses of every TLS zerofill section tho. Thus, we hack it so that // we increment the start address like normal, however, after we are done, // the next ALLOC section will get its start address allocated within the same // range as the .tbss sections. We will get something like this: // // ... // .tbss 0x10 // .tcommon 0x20 // .data 0x10 // ... var tbss_addr = addr; while (i < cover.items.len and self.shdrs.items[cover.items[i]].sh_type == elf.SHT_NOBITS and self.shdrs.items[cover.items[i]].sh_flags & elf.SHF_TLS != 0) : (i += 1) { const tbss_shndx = cover.items[i]; const tbss_shdr = &self.shdrs.items[tbss_shndx]; tbss_addr = alignment.@"align"(tbss_shndx, tbss_shdr.sh_addralign, tbss_addr); tbss_shdr.sh_addr = tbss_addr; tbss_addr += tbss_shdr.sh_size; } i -= 1; continue; } const next = alignment.@"align"(shndx, shdr.sh_addralign, addr); const padding = next - addr; addr = next; shdr.sh_addr = addr; if (shdr.sh_type != elf.SHT_NOBITS) { filesz += padding + shdr.sh_size; } memsz += padding + shdr.sh_size; addr += shdr.sh_size; } const first = self.shdrs.items[cover.items[0]]; var off = self.findFreeSpace(filesz, @"align"); const phndx = try self.addPhdr(.{ .type = elf.PT_LOAD, .offset = off, .addr = first.sh_addr, .memsz = memsz, .filesz = filesz, .@"align" = @"align", .flags = shdrToPhdrFlags(first.sh_flags), }); for (cover.items) |shndx| { const shdr = &self.shdrs.items[shndx]; if (shdr.sh_type == elf.SHT_NOBITS) continue; off = alignment.@"align"(shndx, shdr.sh_addralign, off); shdr.sh_offset = off; off += shdr.sh_size; try self.phdr_to_shdr_table.putNoClobber(gpa, shndx, phndx); } addr = mem.alignForward(u64, addr, self.page_size); } } /// Allocates non-alloc sections (debug info, symtabs, etc.). fn allocateNonAllocSections(self: *Elf) !void { for (self.shdrs.items, 0..) |*shdr, shndx| { if (shdr.sh_type == elf.SHT_NULL) continue; if (shdr.sh_flags & elf.SHF_ALLOC != 0) continue; const needed_size = shdr.sh_size; if (needed_size > self.allocatedSize(shdr.sh_offset)) { shdr.sh_size = 0; const new_offset = self.findFreeSpace(needed_size, shdr.sh_addralign); if (self.isDebugSection(@intCast(shndx))) { log.debug("moving {s} from 0x{x} to 0x{x}", .{ self.getShString(shdr.sh_name), shdr.sh_offset, new_offset, }); const zig_object = self.zigObjectPtr().?; const existing_size = blk: { if (shndx == self.debug_info_section_index.?) break :blk zig_object.debug_info_section_zig_size; if (shndx == self.debug_abbrev_section_index.?) break :blk zig_object.debug_abbrev_section_zig_size; if (shndx == self.debug_str_section_index.?) break :blk zig_object.debug_str_section_zig_size; if (shndx == self.debug_aranges_section_index.?) break :blk zig_object.debug_aranges_section_zig_size; if (shndx == self.debug_line_section_index.?) break :blk zig_object.debug_line_section_zig_size; unreachable; }; const amt = try self.base.file.?.copyRangeAll( shdr.sh_offset, self.base.file.?, new_offset, existing_size, ); if (amt != existing_size) return error.InputOutput; } shdr.sh_offset = new_offset; shdr.sh_size = needed_size; } } } fn allocateSpecialPhdrs(self: *Elf) void { for (&[_]struct { ?u16, ?u16 }{ .{ self.phdr_interp_index, self.interp_section_index }, .{ self.phdr_dynamic_index, self.dynamic_section_index }, .{ self.phdr_gnu_eh_frame_index, self.eh_frame_hdr_section_index }, }) |pair| { if (pair[0]) |index| { const shdr = self.shdrs.items[pair[1].?]; const phdr = &self.phdrs.items[index]; phdr.p_align = shdr.sh_addralign; phdr.p_offset = shdr.sh_offset; phdr.p_vaddr = shdr.sh_addr; phdr.p_paddr = shdr.sh_addr; phdr.p_filesz = shdr.sh_size; phdr.p_memsz = shdr.sh_size; } } // Set the TLS segment boundaries. // We assume TLS sections are laid out contiguously and that there is // a single TLS segment. if (self.phdr_tls_index) |index| { const slice = self.shdrs.items; const phdr = &self.phdrs.items[index]; var shndx: u16 = 0; while (shndx < slice.len) { const shdr = slice[shndx]; if (shdr.sh_flags & elf.SHF_TLS == 0) { shndx += 1; continue; } phdr.p_offset = shdr.sh_offset; phdr.p_vaddr = shdr.sh_addr; phdr.p_paddr = shdr.sh_addr; phdr.p_align = shdr.sh_addralign; shndx += 1; phdr.p_align = @max(phdr.p_align, shdr.sh_addralign); if (shdr.sh_type != elf.SHT_NOBITS) { phdr.p_filesz = shdr.sh_offset + shdr.sh_size - phdr.p_offset; } phdr.p_memsz = shdr.sh_addr + shdr.sh_size - phdr.p_vaddr; while (shndx < slice.len) : (shndx += 1) { const next = slice[shndx]; if (next.sh_flags & elf.SHF_TLS == 0) break; phdr.p_align = @max(phdr.p_align, next.sh_addralign); if (next.sh_type != elf.SHT_NOBITS) { phdr.p_filesz = next.sh_offset + next.sh_size - phdr.p_offset; } phdr.p_memsz = next.sh_addr + next.sh_size - phdr.p_vaddr; } } } } fn allocateAtoms(self: *Elf) void { for (self.objects.items) |index| { self.file(index).?.object.allocateAtoms(self); } } fn writeAtoms(self: *Elf) !void { const gpa = self.base.allocator; var undefs = std.AutoHashMap(Symbol.Index, std.ArrayList(Atom.Index)).init(gpa); defer { var it = undefs.iterator(); while (it.next()) |entry| { entry.value_ptr.deinit(); } undefs.deinit(); } // TODO iterate over `output_sections` directly for (self.shdrs.items, 0..) |shdr, shndx| { if (shdr.sh_type == elf.SHT_NULL) continue; if (shdr.sh_type == elf.SHT_NOBITS) continue; const atom_list = self.output_sections.get(@intCast(shndx)) orelse continue; log.debug("writing atoms in '{s}' section", .{self.getShString(shdr.sh_name)}); // TODO really, really handle debug section separately const base_offset = if (self.isDebugSection(@intCast(shndx))) blk: { const zig_object = self.zigObjectPtr().?; if (shndx == self.debug_info_section_index.?) break :blk zig_object.debug_info_section_zig_size; if (shndx == self.debug_abbrev_section_index.?) break :blk zig_object.debug_abbrev_section_zig_size; if (shndx == self.debug_str_section_index.?) break :blk zig_object.debug_str_section_zig_size; if (shndx == self.debug_aranges_section_index.?) break :blk zig_object.debug_aranges_section_zig_size; if (shndx == self.debug_line_section_index.?) break :blk zig_object.debug_line_section_zig_size; unreachable; } else 0; const sh_offset = shdr.sh_offset + base_offset; const sh_size = math.cast(usize, shdr.sh_size - base_offset) orelse return error.Overflow; const buffer = try gpa.alloc(u8, sh_size); defer gpa.free(buffer); const padding_byte: u8 = if (shdr.sh_type == elf.SHT_PROGBITS and shdr.sh_flags & elf.SHF_EXECINSTR != 0) 0xcc // int3 else 0; @memset(buffer, padding_byte); for (atom_list.items) |atom_index| { const atom_ptr = self.atom(atom_index).?; assert(atom_ptr.flags.alive); const object = atom_ptr.file(self).?.object; const offset = math.cast(usize, atom_ptr.value - shdr.sh_addr - base_offset) orelse return error.Overflow; const size = math.cast(usize, atom_ptr.size) orelse return error.Overflow; log.debug("writing atom({d}) at 0x{x}", .{ atom_index, sh_offset + offset }); // TODO decompress directly into provided buffer const out_code = buffer[offset..][0..size]; const in_code = try object.codeDecompressAlloc(self, atom_index); defer gpa.free(in_code); @memcpy(out_code, in_code); if (shdr.sh_flags & elf.SHF_ALLOC == 0) { try atom_ptr.resolveRelocsNonAlloc(self, out_code, &undefs); } else { atom_ptr.resolveRelocsAlloc(self, out_code) catch |err| switch (err) { // TODO error.RelaxFail, error.InvalidInstruction, error.CannotEncode => { log.err("relaxing intructions failed; TODO this should be a fatal linker error", .{}); }, else => |e| return e, }; } } try self.base.file.?.pwriteAll(buffer, sh_offset); } try self.reportUndefined(&undefs); } fn updateSymtabSize(self: *Elf) !void { var sizes = SymtabSize{}; if (self.zigObjectPtr()) |zig_object| { zig_object.asFile().updateSymtabSize(self); sizes.add(zig_object.output_symtab_size); } for (self.objects.items) |index| { const file_ptr = self.file(index).?; file_ptr.updateSymtabSize(self); sizes.add(file_ptr.object.output_symtab_size); } for (self.shared_objects.items) |index| { const file_ptr = self.file(index).?; file_ptr.updateSymtabSize(self); sizes.add(file_ptr.shared_object.output_symtab_size); } if (self.zig_got_section_index) |_| { self.zig_got.updateSymtabSize(self); sizes.add(self.zig_got.output_symtab_size); } if (self.got_section_index) |_| { self.got.updateSymtabSize(self); sizes.add(self.got.output_symtab_size); } if (self.plt_section_index) |_| { self.plt.updateSymtabSize(self); sizes.add(self.plt.output_symtab_size); } if (self.plt_got_section_index) |_| { self.plt_got.updateSymtabSize(self); sizes.add(self.plt_got.output_symtab_size); } if (self.linker_defined_index) |index| { const file_ptr = self.file(index).?; file_ptr.updateSymtabSize(self); sizes.add(file_ptr.linker_defined.output_symtab_size); } const symtab_shdr = &self.shdrs.items[self.symtab_section_index.?]; symtab_shdr.sh_info = sizes.nlocals + 1; symtab_shdr.sh_link = self.strtab_section_index.?; const sym_size: u64 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Sym), .p64 => @sizeOf(elf.Elf64_Sym), }; const needed_size = (sizes.nlocals + sizes.nglobals + 1) * sym_size; symtab_shdr.sh_size = needed_size; const strtab = &self.shdrs.items[self.strtab_section_index.?]; strtab.sh_size = sizes.strsize + 1; } fn writeSyntheticSections(self: *Elf) !void { const gpa = self.base.allocator; if (self.zigObjectPtr()) |zig_object| { try zig_object.writeRelaSections(self); } if (self.interp_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; const sh_size = math.cast(usize, shdr.sh_size) orelse return error.Overflow; var buffer = try gpa.alloc(u8, sh_size); defer gpa.free(buffer); const dylinker = self.base.options.dynamic_linker.?; @memcpy(buffer[0..dylinker.len], dylinker); buffer[dylinker.len] = 0; try self.base.file.?.pwriteAll(buffer, shdr.sh_offset); } if (self.hash_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; try self.base.file.?.pwriteAll(self.hash.buffer.items, shdr.sh_offset); } if (self.gnu_hash_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; var buffer = try std.ArrayList(u8).initCapacity(gpa, self.gnu_hash.size()); defer buffer.deinit(); try self.gnu_hash.write(self, buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.versym_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; try self.base.file.?.pwriteAll(mem.sliceAsBytes(self.versym.items), shdr.sh_offset); } if (self.verneed_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; var buffer = try std.ArrayList(u8).initCapacity(gpa, self.verneed.size()); defer buffer.deinit(); try self.verneed.write(buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.dynamic_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; var buffer = try std.ArrayList(u8).initCapacity(gpa, self.dynamic.size(self)); defer buffer.deinit(); try self.dynamic.write(self, buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.dynsymtab_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; var buffer = try std.ArrayList(u8).initCapacity(gpa, self.dynsym.size()); defer buffer.deinit(); try self.dynsym.write(self, buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.dynstrtab_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; try self.base.file.?.pwriteAll(self.dynstrtab.items, shdr.sh_offset); } if (self.eh_frame_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; const sh_size = math.cast(usize, shdr.sh_size) orelse return error.Overflow; var buffer = try std.ArrayList(u8).initCapacity(gpa, sh_size); defer buffer.deinit(); try eh_frame.writeEhFrame(self, buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.eh_frame_hdr_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; const sh_size = math.cast(usize, shdr.sh_size) orelse return error.Overflow; var buffer = try std.ArrayList(u8).initCapacity(gpa, sh_size); defer buffer.deinit(); try eh_frame.writeEhFrameHdr(self, buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.got_section_index) |index| { const shdr = self.shdrs.items[index]; var buffer = try std.ArrayList(u8).initCapacity(gpa, self.got.size(self)); defer buffer.deinit(); try self.got.write(self, buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.rela_dyn_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; try self.got.addRela(self); try self.copy_rel.addRela(self); try self.zig_got.addRela(self); self.sortRelaDyn(); try self.base.file.?.pwriteAll(mem.sliceAsBytes(self.rela_dyn.items), shdr.sh_offset); } if (self.plt_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; var buffer = try std.ArrayList(u8).initCapacity(gpa, self.plt.size()); defer buffer.deinit(); try self.plt.write(self, buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.got_plt_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; var buffer = try std.ArrayList(u8).initCapacity(gpa, self.got_plt.size(self)); defer buffer.deinit(); try self.got_plt.write(self, buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.plt_got_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; var buffer = try std.ArrayList(u8).initCapacity(gpa, self.plt_got.size()); defer buffer.deinit(); try self.plt_got.write(self, buffer.writer()); try self.base.file.?.pwriteAll(buffer.items, shdr.sh_offset); } if (self.rela_plt_section_index) |shndx| { const shdr = self.shdrs.items[shndx]; try self.plt.addRela(self); try self.base.file.?.pwriteAll(mem.sliceAsBytes(self.rela_plt.items), shdr.sh_offset); } try self.writeSymtab(); try self.writeShStrtab(); } fn writeShStrtab(self: *Elf) !void { if (self.shstrtab_section_index) |index| { const shdr = self.shdrs.items[index]; try self.base.file.?.pwriteAll(self.shstrtab.items, shdr.sh_offset); } } fn writeSymtab(self: *Elf) !void { const gpa = self.base.allocator; const symtab_shdr = self.shdrs.items[self.symtab_section_index.?]; const strtab_shdr = self.shdrs.items[self.strtab_section_index.?]; const sym_size: u64 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Sym), .p64 => @sizeOf(elf.Elf64_Sym), }; const nsyms = math.cast(usize, @divExact(symtab_shdr.sh_size, sym_size)) orelse return error.Overflow; log.debug("writing {d} symbols at 0x{x}", .{ nsyms, symtab_shdr.sh_offset }); try self.symtab.resize(gpa, nsyms); const needed_strtab_size = math.cast(usize, strtab_shdr.sh_size - 1) orelse return error.Overflow; try self.strtab.ensureUnusedCapacity(gpa, needed_strtab_size); const Ctx = struct { ilocal: usize, iglobal: usize, fn incr(this: *@This(), ss: SymtabSize) void { this.ilocal += ss.nlocals; this.iglobal += ss.nglobals; } }; var ctx: Ctx = .{ .ilocal = 1, .iglobal = symtab_shdr.sh_info, }; if (self.zigObjectPtr()) |zig_object| { zig_object.asFile().writeSymtab(self, ctx); ctx.incr(zig_object.output_symtab_size); } for (self.objects.items) |index| { const file_ptr = self.file(index).?; file_ptr.writeSymtab(self, ctx); ctx.incr(file_ptr.object.output_symtab_size); } for (self.shared_objects.items) |index| { const file_ptr = self.file(index).?; file_ptr.writeSymtab(self, ctx); ctx.incr(file_ptr.shared_object.output_symtab_size); } if (self.zig_got_section_index) |_| { self.zig_got.writeSymtab(self, ctx); ctx.incr(self.zig_got.output_symtab_size); } if (self.got_section_index) |_| { self.got.writeSymtab(self, ctx); ctx.incr(self.got.output_symtab_size); } if (self.plt_section_index) |_| { self.plt.writeSymtab(self, ctx); ctx.incr(self.plt.output_symtab_size); } if (self.plt_got_section_index) |_| { self.plt_got.writeSymtab(self, ctx); ctx.incr(self.plt_got.output_symtab_size); } if (self.linker_defined_index) |index| { const file_ptr = self.file(index).?; file_ptr.writeSymtab(self, ctx); ctx.incr(file_ptr.linker_defined.output_symtab_size); } const foreign_endian = self.base.options.target.cpu.arch.endian() != builtin.cpu.arch.endian(); switch (self.ptr_width) { .p32 => { const buf = try gpa.alloc(elf.Elf32_Sym, self.symtab.items.len); defer gpa.free(buf); for (buf, self.symtab.items) |*out, sym| { out.* = .{ .st_name = sym.st_name, .st_info = sym.st_info, .st_other = sym.st_other, .st_shndx = sym.st_shndx, .st_value = @as(u32, @intCast(sym.st_value)), .st_size = @as(u32, @intCast(sym.st_size)), }; if (foreign_endian) mem.byteSwapAllFields(elf.Elf32_Sym, out); } try self.base.file.?.pwriteAll(mem.sliceAsBytes(buf), symtab_shdr.sh_offset); }, .p64 => { if (foreign_endian) { for (self.symtab.items) |*sym| mem.byteSwapAllFields(elf.Elf64_Sym, sym); } try self.base.file.?.pwriteAll(mem.sliceAsBytes(self.symtab.items), symtab_shdr.sh_offset); }, } try self.base.file.?.pwriteAll(self.strtab.items, strtab_shdr.sh_offset); } /// Always 4 or 8 depending on whether this is 32-bit ELF or 64-bit ELF. fn ptrWidthBytes(self: Elf) u8 { return switch (self.ptr_width) { .p32 => 4, .p64 => 8, }; } /// Does not necessarily match `ptrWidthBytes` for example can be 2 bytes /// in a 32-bit ELF file. pub fn archPtrWidthBytes(self: Elf) u8 { return @as(u8, @intCast(@divExact(self.base.options.target.ptrBitWidth(), 8))); } fn phdrTo32(phdr: elf.Elf64_Phdr) elf.Elf32_Phdr { return .{ .p_type = phdr.p_type, .p_flags = phdr.p_flags, .p_offset = @as(u32, @intCast(phdr.p_offset)), .p_vaddr = @as(u32, @intCast(phdr.p_vaddr)), .p_paddr = @as(u32, @intCast(phdr.p_paddr)), .p_filesz = @as(u32, @intCast(phdr.p_filesz)), .p_memsz = @as(u32, @intCast(phdr.p_memsz)), .p_align = @as(u32, @intCast(phdr.p_align)), }; } fn shdrTo32(shdr: elf.Elf64_Shdr) elf.Elf32_Shdr { return .{ .sh_name = shdr.sh_name, .sh_type = shdr.sh_type, .sh_flags = @as(u32, @intCast(shdr.sh_flags)), .sh_addr = @as(u32, @intCast(shdr.sh_addr)), .sh_offset = @as(u32, @intCast(shdr.sh_offset)), .sh_size = @as(u32, @intCast(shdr.sh_size)), .sh_link = shdr.sh_link, .sh_info = shdr.sh_info, .sh_addralign = @as(u32, @intCast(shdr.sh_addralign)), .sh_entsize = @as(u32, @intCast(shdr.sh_entsize)), }; } fn getLDMOption(target: std.Target) ?[]const u8 { switch (target.cpu.arch) { .x86 => return "elf_i386", .aarch64 => return "aarch64linux", .aarch64_be => return "aarch64_be_linux", .arm, .thumb => return "armelf_linux_eabi", .armeb, .thumbeb => return "armebelf_linux_eabi", .powerpc => return "elf32ppclinux", .powerpc64 => return "elf64ppc", .powerpc64le => return "elf64lppc", .sparc, .sparcel => return "elf32_sparc", .sparc64 => return "elf64_sparc", .mips => return "elf32btsmip", .mipsel => return "elf32ltsmip", .mips64 => { if (target.abi == .gnuabin32) { return "elf32btsmipn32"; } else { return "elf64btsmip"; } }, .mips64el => { if (target.abi == .gnuabin32) { return "elf32ltsmipn32"; } else { return "elf64ltsmip"; } }, .s390x => return "elf64_s390", .x86_64 => { if (target.abi == .gnux32) { return "elf32_x86_64"; } else { return "elf_x86_64"; } }, .riscv32 => return "elf32lriscv", .riscv64 => return "elf64lriscv", else => return null, } } pub fn padToIdeal(actual_size: anytype) @TypeOf(actual_size) { return actual_size +| (actual_size / ideal_factor); } // Provide a blueprint of csu (c-runtime startup) objects for supported // link modes. // // This is for cross-mode targets only. For host-mode targets the system // compiler can be probed to produce a robust blueprint. // // Targets requiring a libc for which zig does not bundle a libc are // host-mode targets. Unfortunately, host-mode probes are not yet // implemented. For now the data is hard-coded here. Such targets are // { freebsd, netbsd, openbsd, dragonfly }. const CsuObjects = struct { crt0: ?[]const u8 = null, crti: ?[]const u8 = null, crtbegin: ?[]const u8 = null, crtend: ?[]const u8 = null, crtn: ?[]const u8 = null, fn init(arena: mem.Allocator, link_options: link.Options, comp: *const Compilation) !CsuObjects { // crt objects are only required for libc. if (!link_options.link_libc) return CsuObjects{}; var result: CsuObjects = .{}; // Flatten crt cases. const mode: enum { dynamic_lib, dynamic_exe, dynamic_pie, static_exe, static_pie, } = switch (link_options.output_mode) { .Obj => return CsuObjects{}, .Lib => switch (link_options.link_mode) { .Dynamic => .dynamic_lib, .Static => return CsuObjects{}, }, .Exe => switch (link_options.link_mode) { .Dynamic => if (link_options.pie) .dynamic_pie else .dynamic_exe, .Static => if (link_options.pie) .static_pie else .static_exe, }, }; if (link_options.target.isAndroid()) { switch (mode) { // zig fmt: off .dynamic_lib => result.set( null, null, "crtbegin_so.o", "crtend_so.o", null ), .dynamic_exe, .dynamic_pie => result.set( null, null, "crtbegin_dynamic.o", "crtend_android.o", null ), .static_exe, .static_pie => result.set( null, null, "crtbegin_static.o", "crtend_android.o", null ), // zig fmt: on } } else { switch (link_options.target.os.tag) { .linux => { switch (mode) { // zig fmt: off .dynamic_lib => result.set( null, "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .dynamic_exe => result.set( "crt1.o", "crti.o", "crtbegin.o", "crtend.o", "crtn.o" ), .dynamic_pie => result.set( "Scrt1.o", "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .static_exe => result.set( "crt1.o", "crti.o", "crtbeginT.o", "crtend.o", "crtn.o" ), .static_pie => result.set( "rcrt1.o", "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), // zig fmt: on } if (link_options.libc_installation) |_| { // hosted-glibc provides crtbegin/end objects in platform/compiler-specific dirs // and they are not known at comptime. For now null-out crtbegin/end objects; // there is no feature loss, zig has never linked those objects in before. result.crtbegin = null; result.crtend = null; } else { // Bundled glibc only has Scrt1.o . if (result.crt0 != null and link_options.target.isGnuLibC()) result.crt0 = "Scrt1.o"; } }, .dragonfly => switch (mode) { // zig fmt: off .dynamic_lib => result.set( null, "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .dynamic_exe => result.set( "crt1.o", "crti.o", "crtbegin.o", "crtend.o", "crtn.o" ), .dynamic_pie => result.set( "Scrt1.o", "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .static_exe => result.set( "crt1.o", "crti.o", "crtbegin.o", "crtend.o", "crtn.o" ), .static_pie => result.set( "Scrt1.o", "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), // zig fmt: on }, .freebsd => switch (mode) { // zig fmt: off .dynamic_lib => result.set( null, "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .dynamic_exe => result.set( "crt1.o", "crti.o", "crtbegin.o", "crtend.o", "crtn.o" ), .dynamic_pie => result.set( "Scrt1.o", "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .static_exe => result.set( "crt1.o", "crti.o", "crtbeginT.o", "crtend.o", "crtn.o" ), .static_pie => result.set( "Scrt1.o", "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), // zig fmt: on }, .netbsd => switch (mode) { // zig fmt: off .dynamic_lib => result.set( null, "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .dynamic_exe => result.set( "crt0.o", "crti.o", "crtbegin.o", "crtend.o", "crtn.o" ), .dynamic_pie => result.set( "crt0.o", "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .static_exe => result.set( "crt0.o", "crti.o", "crtbeginT.o", "crtend.o", "crtn.o" ), .static_pie => result.set( "crt0.o", "crti.o", "crtbeginT.o", "crtendS.o", "crtn.o" ), // zig fmt: on }, .openbsd => switch (mode) { // zig fmt: off .dynamic_lib => result.set( null, null, "crtbeginS.o", "crtendS.o", null ), .dynamic_exe, .dynamic_pie => result.set( "crt0.o", null, "crtbegin.o", "crtend.o", null ), .static_exe, .static_pie => result.set( "rcrt0.o", null, "crtbegin.o", "crtend.o", null ), // zig fmt: on }, .haiku => switch (mode) { // zig fmt: off .dynamic_lib => result.set( null, "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .dynamic_exe => result.set( "start_dyn.o", "crti.o", "crtbegin.o", "crtend.o", "crtn.o" ), .dynamic_pie => result.set( "start_dyn.o", "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), .static_exe => result.set( "start_dyn.o", "crti.o", "crtbegin.o", "crtend.o", "crtn.o" ), .static_pie => result.set( "start_dyn.o", "crti.o", "crtbeginS.o", "crtendS.o", "crtn.o" ), // zig fmt: on }, .solaris, .illumos => switch (mode) { // zig fmt: off .dynamic_lib => result.set( null, "crti.o", null, null, "crtn.o" ), .dynamic_exe, .dynamic_pie => result.set( "crt1.o", "crti.o", null, null, "crtn.o" ), .static_exe, .static_pie => result.set( null, null, null, null, null ), // zig fmt: on }, else => {}, } } // Convert each object to a full pathname. if (link_options.libc_installation) |lci| { const crt_dir_path = lci.crt_dir orelse return error.LibCInstallationMissingCRTDir; switch (link_options.target.os.tag) { .dragonfly => { if (result.crt0) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ crt_dir_path, obj.* }); if (result.crti) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ crt_dir_path, obj.* }); if (result.crtn) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ crt_dir_path, obj.* }); var gccv: []const u8 = undefined; if (link_options.target.os.version_range.semver.isAtLeast(.{ .major = 5, .minor = 4, .patch = 0 }) orelse true) { gccv = "gcc80"; } else { gccv = "gcc54"; } if (result.crtbegin) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ crt_dir_path, gccv, obj.* }); if (result.crtend) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ crt_dir_path, gccv, obj.* }); }, .haiku => { const gcc_dir_path = lci.gcc_dir orelse return error.LibCInstallationMissingCRTDir; if (result.crt0) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ crt_dir_path, obj.* }); if (result.crti) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ crt_dir_path, obj.* }); if (result.crtn) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ crt_dir_path, obj.* }); if (result.crtbegin) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ gcc_dir_path, obj.* }); if (result.crtend) |*obj| obj.* = try fs.path.join(arena, &[_][]const u8{ gcc_dir_path, obj.* }); }, else => { inline for (std.meta.fields(@TypeOf(result))) |f| { if (@field(result, f.name)) |*obj| { obj.* = try fs.path.join(arena, &[_][]const u8{ crt_dir_path, obj.* }); } } }, } } else { inline for (std.meta.fields(@TypeOf(result))) |f| { if (@field(result, f.name)) |*obj| { if (comp.crt_files.get(obj.*)) |crtf| { obj.* = crtf.full_object_path; } else { @field(result, f.name) = null; } } } } return result; } fn set( self: *CsuObjects, crt0: ?[]const u8, crti: ?[]const u8, crtbegin: ?[]const u8, crtend: ?[]const u8, crtn: ?[]const u8, ) void { self.crt0 = crt0; self.crti = crti; self.crtbegin = crtbegin; self.crtend = crtend; self.crtn = crtn; } }; pub fn calcImageBase(self: Elf) u64 { if (self.isDynLib()) return 0; if (self.isExe() and self.base.options.pie) return 0; return self.base.options.image_base_override orelse switch (self.ptr_width) { .p32 => 0x1000, .p64 => 0x1000000, }; } pub fn isStatic(self: Elf) bool { return self.base.options.link_mode == .Static; } pub fn isObject(self: Elf) bool { return self.base.options.output_mode == .Obj; } pub fn isExe(self: Elf) bool { return self.base.options.output_mode == .Exe; } pub fn isStaticLib(self: Elf) bool { return self.base.options.output_mode == .Lib and self.isStatic(); } pub fn isRelocatable(self: Elf) bool { return self.isObject() or self.isStaticLib(); } pub fn isDynLib(self: Elf) bool { return self.base.options.output_mode == .Lib and !self.isStatic(); } pub fn isZigSection(self: Elf, shndx: u16) bool { inline for (&[_]?u16{ self.zig_text_section_index, self.zig_data_rel_ro_section_index, self.zig_data_section_index, self.zig_bss_section_index, self.zig_got_section_index, }) |maybe_index| { if (maybe_index) |index| { if (index == shndx) return true; } } return false; } pub fn isDebugSection(self: Elf, shndx: u16) bool { inline for (&[_]?u16{ self.debug_info_section_index, self.debug_abbrev_section_index, self.debug_str_section_index, self.debug_aranges_section_index, self.debug_line_section_index, }) |maybe_index| { if (maybe_index) |index| { if (index == shndx) return true; } } return false; } fn addPhdr(self: *Elf, opts: struct { type: u32 = 0, flags: u32 = 0, @"align": u64 = 0, offset: u64 = 0, addr: u64 = 0, filesz: u64 = 0, memsz: u64 = 0, }) error{OutOfMemory}!u16 { const index = @as(u16, @intCast(self.phdrs.items.len)); try self.phdrs.append(self.base.allocator, .{ .p_type = opts.type, .p_flags = opts.flags, .p_offset = opts.offset, .p_vaddr = opts.addr, .p_paddr = opts.addr, .p_filesz = opts.filesz, .p_memsz = opts.memsz, .p_align = opts.@"align", }); return index; } fn addRelaShdr(self: *Elf, name: [:0]const u8, shndx: u16) !u16 { const entsize: u64 = switch (self.ptr_width) { .p32 => @sizeOf(elf.Elf32_Rela), .p64 => @sizeOf(elf.Elf64_Rela), }; const addralign: u64 = switch (self.ptr_width) { .p32 => @alignOf(elf.Elf32_Rela), .p64 => @alignOf(elf.Elf64_Rela), }; return self.addSection(.{ .name = name, .type = elf.SHT_RELA, .flags = elf.SHF_INFO_LINK, .entsize = entsize, .info = shndx, .addralign = addralign, .offset = std.math.maxInt(u64), }); } pub const AddSectionOpts = struct { name: [:0]const u8, type: u32 = elf.SHT_NULL, flags: u64 = 0, link: u32 = 0, info: u32 = 0, addralign: u64 = 0, entsize: u64 = 0, offset: u64 = 0, }; pub fn addSection(self: *Elf, opts: AddSectionOpts) !u16 { const gpa = self.base.allocator; const index = @as(u16, @intCast(self.shdrs.items.len)); const shdr = try self.shdrs.addOne(gpa); shdr.* = .{ .sh_name = try self.insertShString(opts.name), .sh_type = opts.type, .sh_flags = opts.flags, .sh_addr = 0, .sh_offset = opts.offset, .sh_size = 0, .sh_link = opts.link, .sh_info = opts.info, .sh_addralign = opts.addralign, .sh_entsize = opts.entsize, }; return index; } pub fn sectionByName(self: *Elf, name: [:0]const u8) ?u16 { for (self.shdrs.items, 0..) |*shdr, i| { const this_name = self.getShString(shdr.sh_name); if (mem.eql(u8, this_name, name)) return @as(u16, @intCast(i)); } else return null; } const RelaDyn = struct { offset: u64, sym: u64 = 0, type: u32, addend: i64 = 0, }; pub fn addRelaDyn(self: *Elf, opts: RelaDyn) !void { try self.rela_dyn.ensureUnusedCapacity(self.base.alloctor, 1); self.addRelaDynAssumeCapacity(opts); } pub fn addRelaDynAssumeCapacity(self: *Elf, opts: RelaDyn) void { self.rela_dyn.appendAssumeCapacity(.{ .r_offset = opts.offset, .r_info = (opts.sym << 32) | opts.type, .r_addend = opts.addend, }); } fn sortRelaDyn(self: *Elf) void { const Sort = struct { fn rank(rel: elf.Elf64_Rela) u2 { return switch (rel.r_type()) { elf.R_X86_64_RELATIVE => 0, elf.R_X86_64_IRELATIVE => 2, else => 1, }; } pub fn lessThan(ctx: void, lhs: elf.Elf64_Rela, rhs: elf.Elf64_Rela) bool { _ = ctx; if (rank(lhs) == rank(rhs)) { if (lhs.r_sym() == rhs.r_sym()) return lhs.r_offset < rhs.r_offset; return lhs.r_sym() < rhs.r_sym(); } return rank(lhs) < rank(rhs); } }; mem.sort(elf.Elf64_Rela, self.rela_dyn.items, {}, Sort.lessThan); } fn calcNumIRelativeRelocs(self: *Elf) usize { var count: usize = self.num_ifunc_dynrelocs; for (self.got.entries.items) |entry| { if (entry.tag != .got) continue; const sym = self.symbol(entry.symbol_index); if (sym.isIFunc(self)) count += 1; } return count; } pub fn isCIdentifier(name: []const u8) bool { if (name.len == 0) return false; const first_c = name[0]; if (!std.ascii.isAlphabetic(first_c) and first_c != '_') return false; for (name[1..]) |c| { if (!std.ascii.isAlphanumeric(c) and c != '_') return false; } return true; } fn getStartStopBasename(self: *Elf, atom_index: Atom.Index) ?[]const u8 { const atom_ptr = self.atom(atom_index) orelse return null; const name = atom_ptr.name(self); if (atom_ptr.inputShdr(self).sh_flags & elf.SHF_ALLOC != 0 and name.len > 0) { if (isCIdentifier(name)) return name; } return null; } pub fn atom(self: *Elf, atom_index: Atom.Index) ?*Atom { if (atom_index == 0) return null; assert(atom_index < self.atoms.items.len); return &self.atoms.items[atom_index]; } pub fn addAtom(self: *Elf) !Atom.Index { const index = @as(Atom.Index, @intCast(self.atoms.items.len)); const atom_ptr = try self.atoms.addOne(self.base.allocator); atom_ptr.* = .{ .atom_index = index }; return index; } pub fn file(self: *Elf, index: File.Index) ?File { const tag = self.files.items(.tags)[index]; return switch (tag) { .null => null, .linker_defined => .{ .linker_defined = &self.files.items(.data)[index].linker_defined }, .zig_object => .{ .zig_object = &self.files.items(.data)[index].zig_object }, .object => .{ .object = &self.files.items(.data)[index].object }, .shared_object => .{ .shared_object = &self.files.items(.data)[index].shared_object }, }; } /// Returns pointer-to-symbol described at sym_index. pub fn symbol(self: *Elf, sym_index: Symbol.Index) *Symbol { return &self.symbols.items[sym_index]; } pub fn addSymbol(self: *Elf) !Symbol.Index { try self.symbols.ensureUnusedCapacity(self.base.allocator, 1); const index = blk: { if (self.symbols_free_list.popOrNull()) |index| { log.debug(" (reusing symbol index {d})", .{index}); break :blk index; } else { log.debug(" (allocating symbol index {d})", .{self.symbols.items.len}); const index = @as(Symbol.Index, @intCast(self.symbols.items.len)); _ = self.symbols.addOneAssumeCapacity(); break :blk index; } }; self.symbols.items[index] = .{}; return index; } pub fn addSymbolExtra(self: *Elf, extra: Symbol.Extra) !u32 { const fields = @typeInfo(Symbol.Extra).Struct.fields; try self.symbols_extra.ensureUnusedCapacity(self.base.allocator, fields.len); return self.addSymbolExtraAssumeCapacity(extra); } pub fn addSymbolExtraAssumeCapacity(self: *Elf, extra: Symbol.Extra) u32 { const index = @as(u32, @intCast(self.symbols_extra.items.len)); const fields = @typeInfo(Symbol.Extra).Struct.fields; inline for (fields) |field| { self.symbols_extra.appendAssumeCapacity(switch (field.type) { u32 => @field(extra, field.name), else => @compileError("bad field type"), }); } return index; } pub fn symbolExtra(self: *Elf, index: u32) ?Symbol.Extra { if (index == 0) return null; const fields = @typeInfo(Symbol.Extra).Struct.fields; var i: usize = index; var result: Symbol.Extra = undefined; inline for (fields) |field| { @field(result, field.name) = switch (field.type) { u32 => self.symbols_extra.items[i], else => @compileError("bad field type"), }; i += 1; } return result; } pub fn setSymbolExtra(self: *Elf, index: u32, extra: Symbol.Extra) void { assert(index > 0); const fields = @typeInfo(Symbol.Extra).Struct.fields; inline for (fields, 0..) |field, i| { self.symbols_extra.items[index + i] = switch (field.type) { u32 => @field(extra, field.name), else => @compileError("bad field type"), }; } } const GetOrPutGlobalResult = struct { found_existing: bool, index: Symbol.Index, }; pub fn getOrPutGlobal(self: *Elf, name: []const u8) !GetOrPutGlobalResult { const gpa = self.base.allocator; const name_off = try self.strings.insert(gpa, name); const gop = try self.resolver.getOrPut(gpa, name_off); if (!gop.found_existing) { const index = try self.addSymbol(); const global = self.symbol(index); global.name_offset = name_off; global.flags.global = true; gop.value_ptr.* = index; } return .{ .found_existing = gop.found_existing, .index = gop.value_ptr.*, }; } pub fn globalByName(self: *Elf, name: []const u8) ?Symbol.Index { const name_off = self.strings.getOffset(name) orelse return null; return self.resolver.get(name_off); } pub fn getGlobalSymbol(self: *Elf, name: []const u8, lib_name: ?[]const u8) !u32 { return self.zigObjectPtr().?.getGlobalSymbol(self, name, lib_name); } pub fn zigObjectPtr(self: *Elf) ?*ZigObject { const index = self.zig_object_index orelse return null; return self.file(index).?.zig_object; } const GetOrCreateComdatGroupOwnerResult = struct { found_existing: bool, index: ComdatGroupOwner.Index, }; pub fn getOrCreateComdatGroupOwner(self: *Elf, name: [:0]const u8) !GetOrCreateComdatGroupOwnerResult { const gpa = self.base.allocator; const off = try self.strings.insert(gpa, name); const gop = try self.comdat_groups_table.getOrPut(gpa, off); if (!gop.found_existing) { const index = @as(ComdatGroupOwner.Index, @intCast(self.comdat_groups_owners.items.len)); const owner = try self.comdat_groups_owners.addOne(gpa); owner.* = .{}; gop.value_ptr.* = index; } return .{ .found_existing = gop.found_existing, .index = gop.value_ptr.*, }; } pub fn addComdatGroup(self: *Elf) !ComdatGroup.Index { const index = @as(ComdatGroup.Index, @intCast(self.comdat_groups.items.len)); _ = try self.comdat_groups.addOne(self.base.allocator); return index; } pub fn comdatGroup(self: *Elf, index: ComdatGroup.Index) *ComdatGroup { assert(index < self.comdat_groups.items.len); return &self.comdat_groups.items[index]; } pub fn comdatGroupOwner(self: *Elf, index: ComdatGroupOwner.Index) *ComdatGroupOwner { assert(index < self.comdat_groups_owners.items.len); return &self.comdat_groups_owners.items[index]; } pub fn tpAddress(self: *Elf) u64 { const index = self.phdr_tls_index orelse return 0; const phdr = self.phdrs.items[index]; return mem.alignForward(u64, phdr.p_vaddr + phdr.p_memsz, phdr.p_align); } pub fn dtpAddress(self: *Elf) u64 { return self.tlsAddress(); } pub fn tlsAddress(self: *Elf) u64 { const index = self.phdr_tls_index orelse return 0; const phdr = self.phdrs.items[index]; return phdr.p_vaddr; } const ErrorWithNotes = struct { /// Allocated index in misc_errors array. index: usize, /// Next available note slot. note_slot: usize = 0, pub fn addMsg( err: ErrorWithNotes, elf_file: *Elf, comptime format: []const u8, args: anytype, ) error{OutOfMemory}!void { const gpa = elf_file.base.allocator; const err_msg = &elf_file.misc_errors.items[err.index]; err_msg.msg = try std.fmt.allocPrint(gpa, format, args); } pub fn addNote( err: *ErrorWithNotes, elf_file: *Elf, comptime format: []const u8, args: anytype, ) error{OutOfMemory}!void { const gpa = elf_file.base.allocator; const err_msg = &elf_file.misc_errors.items[err.index]; assert(err.note_slot < err_msg.notes.len); err_msg.notes[err.note_slot] = .{ .msg = try std.fmt.allocPrint(gpa, format, args) }; err.note_slot += 1; } }; pub fn addErrorWithNotes(self: *Elf, note_count: usize) error{OutOfMemory}!ErrorWithNotes { try self.misc_errors.ensureUnusedCapacity(self.base.allocator, 1); return self.addErrorWithNotesAssumeCapacity(note_count); } fn addErrorWithNotesAssumeCapacity(self: *Elf, note_count: usize) error{OutOfMemory}!ErrorWithNotes { const index = self.misc_errors.items.len; const err = self.misc_errors.addOneAssumeCapacity(); err.* = .{ .msg = undefined, .notes = try self.base.allocator.alloc(link.File.ErrorMsg, note_count) }; return .{ .index = index }; } pub fn getShString(self: Elf, off: u32) [:0]const u8 { assert(off < self.shstrtab.items.len); return mem.sliceTo(@as([*:0]const u8, @ptrCast(self.shstrtab.items.ptr + off)), 0); } pub fn insertShString(self: *Elf, name: [:0]const u8) error{OutOfMemory}!u32 { const off = @as(u32, @intCast(self.shstrtab.items.len)); try self.shstrtab.ensureUnusedCapacity(self.base.allocator, name.len + 1); self.shstrtab.writer(self.base.allocator).print("{s}\x00", .{name}) catch unreachable; return off; } pub fn getDynString(self: Elf, off: u32) [:0]const u8 { assert(off < self.dynstrtab.items.len); return mem.sliceTo(@as([*:0]const u8, @ptrCast(self.dynstrtab.items.ptr + off)), 0); } pub fn insertDynString(self: *Elf, name: []const u8) error{OutOfMemory}!u32 { const off = @as(u32, @intCast(self.dynstrtab.items.len)); try self.dynstrtab.ensureUnusedCapacity(self.base.allocator, name.len + 1); self.dynstrtab.writer(self.base.allocator).print("{s}\x00", .{name}) catch unreachable; return off; } fn reportUndefined(self: *Elf, undefs: anytype) !void { const gpa = self.base.allocator; const max_notes = 4; try self.misc_errors.ensureUnusedCapacity(gpa, undefs.count()); var it = undefs.iterator(); while (it.next()) |entry| { const undef_index = entry.key_ptr.*; const atoms = entry.value_ptr.*.items; const natoms = @min(atoms.len, max_notes); const nnotes = natoms + @intFromBool(atoms.len > max_notes); var err = try self.addErrorWithNotesAssumeCapacity(nnotes); try err.addMsg(self, "undefined symbol: {s}", .{self.symbol(undef_index).name(self)}); for (atoms[0..natoms]) |atom_index| { const atom_ptr = self.atom(atom_index).?; const file_ptr = self.file(atom_ptr.file_index).?; try err.addNote(self, "referenced by {s}:{s}", .{ file_ptr.fmtPath(), atom_ptr.name(self) }); } if (atoms.len > max_notes) { const remaining = atoms.len - max_notes; try err.addNote(self, "referenced {d} more times", .{remaining}); } } } fn reportMissingLibraryError( self: *Elf, checked_paths: []const []const u8, comptime format: []const u8, args: anytype, ) error{OutOfMemory}!void { var err = try self.addErrorWithNotes(checked_paths.len); try err.addMsg(self, format, args); for (checked_paths) |path| { try err.addNote(self, "tried {s}", .{path}); } } const ParseErrorCtx = struct { detected_cpu_arch: std.Target.Cpu.Arch, }; fn handleAndReportParseError( self: *Elf, path: []const u8, err: ParseError, ctx: *const ParseErrorCtx, ) error{OutOfMemory}!void { const cpu_arch = self.base.options.target.cpu.arch; switch (err) { error.UnknownFileType => try self.reportParseError(path, "unknown file type", .{}), error.InvalidCpuArch => try self.reportParseError( path, "invalid cpu architecture: expected '{s}', but found '{s}'", .{ @tagName(cpu_arch), @tagName(ctx.detected_cpu_arch) }, ), else => |e| try self.reportParseError( path, "unexpected error: parsing object failed with error {s}", .{@errorName(e)}, ), } } fn reportParseError( self: *Elf, path: []const u8, comptime format: []const u8, args: anytype, ) error{OutOfMemory}!void { var err = try self.addErrorWithNotes(1); try err.addMsg(self, format, args); try err.addNote(self, "while parsing {s}", .{path}); } const FormatShdrCtx = struct { elf_file: *Elf, shdr: elf.Elf64_Shdr, }; fn fmtShdr(self: *Elf, shdr: elf.Elf64_Shdr) std.fmt.Formatter(formatShdr) { return .{ .data = .{ .shdr = shdr, .elf_file = self, } }; } fn formatShdr( ctx: FormatShdrCtx, comptime unused_fmt_string: []const u8, options: std.fmt.FormatOptions, writer: anytype, ) !void { _ = options; _ = unused_fmt_string; const shdr = ctx.shdr; try writer.print("{s} : @{x} ({x}) : align({x}) : size({x})", .{ ctx.elf_file.getShString(shdr.sh_name), shdr.sh_offset, shdr.sh_addr, shdr.sh_addralign, shdr.sh_size, }); } const FormatPhdrCtx = struct { elf_file: *Elf, phdr: elf.Elf64_Phdr, }; fn fmtPhdr(self: *Elf, phdr: elf.Elf64_Phdr) std.fmt.Formatter(formatPhdr) { return .{ .data = .{ .phdr = phdr, .elf_file = self, } }; } fn formatPhdr( ctx: FormatPhdrCtx, comptime unused_fmt_string: []const u8, options: std.fmt.FormatOptions, writer: anytype, ) !void { _ = options; _ = unused_fmt_string; const phdr = ctx.phdr; const write = phdr.p_flags & elf.PF_W != 0; const read = phdr.p_flags & elf.PF_R != 0; const exec = phdr.p_flags & elf.PF_X != 0; var flags: [3]u8 = [_]u8{'_'} ** 3; if (exec) flags[0] = 'X'; if (write) flags[1] = 'W'; if (read) flags[2] = 'R'; const p_type = switch (phdr.p_type) { elf.PT_LOAD => "LOAD", elf.PT_TLS => "TLS", elf.PT_GNU_EH_FRAME => "GNU_EH_FRAME", elf.PT_GNU_STACK => "GNU_STACK", elf.PT_DYNAMIC => "DYNAMIC", elf.PT_INTERP => "INTERP", elf.PT_NULL => "NULL", elf.PT_PHDR => "PHDR", elf.PT_NOTE => "NOTE", else => "UNKNOWN", }; try writer.print("{s} : {s} : @{x} ({x}) : align({x}) : filesz({x}) : memsz({x})", .{ p_type, flags, phdr.p_offset, phdr.p_vaddr, phdr.p_align, phdr.p_filesz, phdr.p_memsz, }); } fn dumpState(self: *Elf) std.fmt.Formatter(fmtDumpState) { return .{ .data = self }; } fn fmtDumpState( self: *Elf, comptime unused_fmt_string: []const u8, options: std.fmt.FormatOptions, writer: anytype, ) !void { _ = unused_fmt_string; _ = options; if (self.zigObjectPtr()) |zig_object| { try writer.print("zig_object({d}) : {s}\n", .{ zig_object.index, zig_object.path }); try writer.print("{}{}\n", .{ zig_object.fmtAtoms(self), zig_object.fmtSymtab(self), }); } for (self.objects.items) |index| { const object = self.file(index).?.object; try writer.print("object({d}) : {}", .{ index, object.fmtPath() }); if (!object.alive) try writer.writeAll(" : [*]"); try writer.writeByte('\n'); try writer.print("{}{}{}{}{}\n", .{ object.fmtAtoms(self), object.fmtCies(self), object.fmtFdes(self), object.fmtSymtab(self), object.fmtComdatGroups(self), }); } for (self.shared_objects.items) |index| { const shared_object = self.file(index).?.shared_object; try writer.print("shared_object({d}) : ", .{index}); try writer.print("{s}", .{shared_object.path}); try writer.print(" : needed({})", .{shared_object.needed}); if (!shared_object.alive) try writer.writeAll(" : [*]"); try writer.writeByte('\n'); try writer.print("{}\n", .{shared_object.fmtSymtab(self)}); } if (self.linker_defined_index) |index| { const linker_defined = self.file(index).?.linker_defined; try writer.print("linker_defined({d}) : (linker defined)\n", .{index}); try writer.print("{}\n", .{linker_defined.fmtSymtab(self)}); } try writer.print("{}\n", .{self.got.fmt(self)}); try writer.print("{}\n", .{self.zig_got.fmt(self)}); try writer.writeAll("Output shdrs\n"); for (self.shdrs.items, 0..) |shdr, shndx| { try writer.print("shdr({d}) : phdr({?d}) : {}\n", .{ shndx, self.phdr_to_shdr_table.get(@intCast(shndx)), self.fmtShdr(shdr), }); } try writer.writeAll("\nOutput phdrs\n"); for (self.phdrs.items, 0..) |phdr, phndx| { try writer.print("phdr{d} : {}\n", .{ phndx, self.fmtPhdr(phdr) }); } } /// Binary search pub fn bsearch(comptime T: type, haystack: []align(1) const T, predicate: anytype) usize { if (!@hasDecl(@TypeOf(predicate), "predicate")) @compileError("Predicate is required to define fn predicate(@This(), T) bool"); var min: usize = 0; var max: usize = haystack.len; while (min < max) { const index = (min + max) / 2; const curr = haystack[index]; if (predicate.predicate(curr)) { min = index + 1; } else { max = index; } } return min; } /// Linear search pub fn lsearch(comptime T: type, haystack: []align(1) const T, predicate: anytype) usize { if (!@hasDecl(@TypeOf(predicate), "predicate")) @compileError("Predicate is required to define fn predicate(@This(), T) bool"); var i: usize = 0; while (i < haystack.len) : (i += 1) { if (predicate.predicate(haystack[i])) break; } return i; } /// The following three values are only observed at compile-time and used to emit a compile error /// to remind the programmer to update expected maximum numbers of different program header types /// so that we reserve enough space for the program header table up-front. /// Bump these numbers when adding or deleting a Zig specific pre-allocated segment, or adding /// more special-purpose program headers. const number_of_zig_segments = 5; const max_number_of_object_segments = 9; const max_number_of_special_phdrs = 5; const default_entry_addr = 0x8000000; pub const base_tag: link.File.Tag = .elf; const ComdatGroupOwner = struct { file: File.Index = 0, const Index = u32; }; pub const ComdatGroup = struct { owner: ComdatGroupOwner.Index, shndx: u16, pub const Index = u32; }; pub const SymtabSize = struct { nlocals: u32 = 0, nglobals: u32 = 0, strsize: u32 = 0, fn add(ss: *SymtabSize, other: SymtabSize) void { ss.nlocals += other.nlocals; ss.nglobals += other.nglobals; ss.strsize += other.strsize; } }; pub const null_sym = elf.Elf64_Sym{ .st_name = 0, .st_info = 0, .st_other = 0, .st_shndx = 0, .st_value = 0, .st_size = 0, }; pub const null_shdr = elf.Elf64_Shdr{ .sh_name = 0, .sh_type = 0, .sh_flags = 0, .sh_addr = 0, .sh_offset = 0, .sh_size = 0, .sh_link = 0, .sh_info = 0, .sh_addralign = 0, .sh_entsize = 0, }; pub const SystemLib = struct { needed: bool = false, path: []const u8, }; const LastAtomAndFreeList = struct { /// Index of the last allocated atom in this section. last_atom_index: Atom.Index = 0, /// A list of atoms that have surplus capacity. This list can have false /// positives, as functions grow and shrink over time, only sometimes being added /// or removed from the freelist. /// /// An atom has surplus capacity when its overcapacity value is greater than /// padToIdeal(minimum_atom_size). That is, when it has so /// much extra capacity, that we could fit a small new symbol in it, itself with /// ideal_capacity or more. /// /// Ideal capacity is defined by size + (size / ideal_factor) /// /// Overcapacity is measured by actual_capacity - ideal_capacity. Note that /// overcapacity can be negative. A simple way to have negative overcapacity is to /// allocate a fresh text block, which will have ideal capacity, and then grow it /// by 1 byte. It will then have -1 overcapacity. free_list: std.ArrayListUnmanaged(Atom.Index) = .{}, }; const LastAtomAndFreeListTable = std.AutoArrayHashMapUnmanaged(u16, LastAtomAndFreeList); pub const R_X86_64_ZIG_GOT32 = elf.R_X86_64_NUM + 1; pub const R_X86_64_ZIG_GOTPCREL = elf.R_X86_64_NUM + 2; const std = @import("std"); const build_options = @import("build_options"); const builtin = @import("builtin"); const assert = std.debug.assert; const elf = std.elf; const fs = std.fs; const log = std.log.scoped(.link); const state_log = std.log.scoped(.link_state); const math = std.math; const mem = std.mem; const codegen = @import("../codegen.zig"); const eh_frame = @import("Elf/eh_frame.zig"); const gc = @import("Elf/gc.zig"); const glibc = @import("../glibc.zig"); const link = @import("../link.zig"); const lldMain = @import("../main.zig").lldMain; const musl = @import("../musl.zig"); const target_util = @import("../target.zig"); const trace = @import("../tracy.zig").trace; const synthetic_sections = @import("Elf/synthetic_sections.zig"); const Air = @import("../Air.zig"); const Allocator = std.mem.Allocator; const Archive = @import("Elf/Archive.zig"); pub const Atom = @import("Elf/Atom.zig"); const Cache = std.Build.Cache; const Compilation = @import("../Compilation.zig"); const CopyRelSection = synthetic_sections.CopyRelSection; const DynamicSection = synthetic_sections.DynamicSection; const DynsymSection = synthetic_sections.DynsymSection; const Dwarf = @import("Dwarf.zig"); const Elf = @This(); const File = @import("Elf/file.zig").File; const GnuHashSection = synthetic_sections.GnuHashSection; const GotSection = synthetic_sections.GotSection; const GotPltSection = synthetic_sections.GotPltSection; const HashSection = synthetic_sections.HashSection; const LdScript = @import("Elf/LdScript.zig"); const LinkerDefined = @import("Elf/LinkerDefined.zig"); const Liveness = @import("../Liveness.zig"); const LlvmObject = @import("../codegen/llvm.zig").Object; const Module = @import("../Module.zig"); const Object = @import("Elf/Object.zig"); const InternPool = @import("../InternPool.zig"); const PltSection = synthetic_sections.PltSection; const PltGotSection = synthetic_sections.PltGotSection; const SharedObject = @import("Elf/SharedObject.zig"); const Symbol = @import("Elf/Symbol.zig"); const StringTable = @import("StringTable.zig"); const TypedValue = @import("../TypedValue.zig"); const VerneedSection = synthetic_sections.VerneedSection; const ZigGotSection = synthetic_sections.ZigGotSection; const ZigObject = @import("Elf/ZigObject.zig");