const std = @import("std"); const Allocator = std.mem.Allocator; const Compilation = @import("Compilation.zig"); const Module = @import("Module.zig"); const fs = std.fs; const trace = @import("tracy.zig").trace; const Package = @import("Package.zig"); const Type = @import("type.zig").Type; const build_options = @import("build_options"); const LibCInstallation = @import("libc_installation.zig").LibCInstallation; pub const producer_string = if (std.builtin.is_test) "zig test" else "zig " ++ build_options.version; pub const Options = struct { /// Where the output will go. directory: Compilation.Directory, /// Path to the output file, relative to `directory`. sub_path: []const u8, target: std.Target, output_mode: std.builtin.OutputMode, link_mode: std.builtin.LinkMode, object_format: std.builtin.ObjectFormat, optimize_mode: std.builtin.Mode, root_name: []const u8, /// Not every Compilation compiles .zig code! For example you could do `zig build-exe foo.o`. module: ?*Module, dynamic_linker: ?[]const u8 = null, /// Used for calculating how much space to reserve for symbols in case the binary file /// does not already have a symbol table. symbol_count_hint: u64 = 32, /// Used for calculating how much space to reserve for executable program code in case /// the binary file does not already have such a section. program_code_size_hint: u64 = 256 * 1024, entry_addr: ?u64 = null, stack_size_override: ?u64 = null, /// Set to `true` to omit debug info. strip: bool = false, /// If this is true then this link code is responsible for outputting an object /// file and then using LLD to link it together with the link options and other objects. /// Otherwise (depending on `use_llvm`) this link code directly outputs and updates the final binary. use_lld: bool = false, /// If this is true then this link code is responsible for making an LLVM IR Module, /// outputting it to an object file, and then linking that together with link options and /// other objects. /// Otherwise (depending on `use_lld`) this link code directly outputs and updates the final binary. use_llvm: bool = false, link_libc: bool = false, link_libcpp: bool = false, function_sections: bool = false, eh_frame_hdr: bool = false, rdynamic: bool = false, z_nodelete: bool = false, z_defs: bool = false, bind_global_refs_locally: bool, is_native_os: bool, pic: bool, valgrind: bool, stack_check: bool, single_threaded: bool, debug_link: bool = false, gc_sections: ?bool = null, allow_shlib_undefined: ?bool = null, linker_script: ?[]const u8 = null, version_script: ?[]const u8 = null, override_soname: ?[]const u8 = null, /// Extra args passed directly to LLD. Ignored when not linking with LLD. extra_lld_args: []const []const u8 = &[0][]const u8, objects: []const []const u8 = &[0][]const u8{}, framework_dirs: []const []const u8 = &[0][]const u8{}, frameworks: []const []const u8 = &[0][]const u8{}, system_libs: []const []const u8 = &[0][]const u8{}, lib_dirs: []const []const u8 = &[0][]const u8{}, rpath_list: []const []const u8 = &[0][]const u8{}, version: ?std.builtin.Version, libc_installation: ?*const LibCInstallation, pub fn effectiveOutputMode(options: Options) std.builtin.OutputMode { return if (options.use_lld) .Obj else options.output_mode; } }; pub const File = struct { tag: Tag, options: Options, file: ?fs.File, allocator: *Allocator, /// When linking with LLD, this linker code will output an object file only at /// this location, and then this path can be placed on the LLD linker line. intermediary_basename: ?[]const u8 = null, pub const LinkBlock = union { elf: Elf.TextBlock, coff: Coff.TextBlock, macho: MachO.TextBlock, c: void, wasm: void, }; pub const LinkFn = union { elf: Elf.SrcFn, coff: Coff.SrcFn, macho: MachO.SrcFn, c: void, wasm: ?Wasm.FnData, }; /// For DWARF .debug_info. pub const DbgInfoTypeRelocsTable = std.HashMapUnmanaged(Type, DbgInfoTypeReloc, Type.hash, Type.eql, std.hash_map.DefaultMaxLoadPercentage); /// For DWARF .debug_info. pub const DbgInfoTypeReloc = struct { /// Offset from `TextBlock.dbg_info_off` (the buffer that is local to a Decl). /// This is where the .debug_info tag for the type is. off: u32, /// Offset from `TextBlock.dbg_info_off` (the buffer that is local to a Decl). /// List of DW.AT_type / DW.FORM_ref4 that points to the type. relocs: std.ArrayListUnmanaged(u32), }; /// Attempts incremental linking, if the file already exists. If /// incremental linking fails, falls back to truncating the file and /// rewriting it. A malicious file is detected as incremental link failure /// and does not cause Illegal Behavior. This operation is not atomic. pub fn openPath(allocator: *Allocator, options: Options) !*File { const use_lld = build_options.have_llvm and options.use_lld; // comptime known false when !have_llvm const sub_path = if (use_lld) blk: { if (options.module == null) { // No point in opening a file, we would not write anything to it. Initialize with empty. return switch (options.object_format) { .coff, .pe => &(try Coff.createEmpty(allocator, options)).base, .elf => &(try Elf.createEmpty(allocator, options)).base, .macho => &(try MachO.createEmpty(allocator, options)).base, .wasm => &(try Wasm.createEmpty(allocator, options)).base, .c => unreachable, // Reported error earlier. .hex => return error.HexObjectFormatUnimplemented, .raw => return error.RawObjectFormatUnimplemented, }; } // Open a temporary object file, not the final output file because we want to link with LLD. break :blk try std.fmt.allocPrint(allocator, "{}{}", .{ options.sub_path, options.target.oFileExt() }); } else options.sub_path; errdefer if (use_lld) allocator.free(sub_path); const file: *File = switch (options.object_format) { .coff, .pe => &(try Coff.openPath(allocator, sub_path, options)).base, .elf => &(try Elf.openPath(allocator, sub_path, options)).base, .macho => &(try MachO.openPath(allocator, sub_path, options)).base, .wasm => &(try Wasm.openPath(allocator, sub_path, options)).base, .c => &(try C.openPath(allocator, sub_path, options)).base, .hex => return error.HexObjectFormatUnimplemented, .raw => return error.RawObjectFormatUnimplemented, }; if (use_lld) { file.intermediary_basename = sub_path; } return file; } pub fn cast(base: *File, comptime T: type) ?*T { if (base.tag != T.base_tag) return null; return @fieldParentPtr(T, "base", base); } pub fn makeWritable(base: *File) !void { switch (base.tag) { .coff, .elf, .macho => { if (base.file != null) return; base.file = try base.options.directory.handle.createFile(base.options.sub_path, .{ .truncate = false, .read = true, .mode = determineMode(base.options), }); }, .c, .wasm => {}, } } pub fn makeExecutable(base: *File) !void { switch (base.tag) { .coff, .elf, .macho => if (base.file) |f| { if (base.intermediary_basename != null) { // The file we have open is not the final file that we want to // make executable, so we don't have to close it. return; } f.close(); base.file = null; }, .c, .wasm => {}, } } /// May be called before or after updateDeclExports but must be called /// after allocateDeclIndexes for any given Decl. pub fn updateDecl(base: *File, module: *Module, decl: *Module.Decl) !void { switch (base.tag) { .coff => return @fieldParentPtr(Coff, "base", base).updateDecl(module, decl), .elf => return @fieldParentPtr(Elf, "base", base).updateDecl(module, decl), .macho => return @fieldParentPtr(MachO, "base", base).updateDecl(module, decl), .c => return @fieldParentPtr(C, "base", base).updateDecl(module, decl), .wasm => return @fieldParentPtr(Wasm, "base", base).updateDecl(module, decl), } } pub fn updateDeclLineNumber(base: *File, module: *Module, decl: *Module.Decl) !void { switch (base.tag) { .coff => return @fieldParentPtr(Coff, "base", base).updateDeclLineNumber(module, decl), .elf => return @fieldParentPtr(Elf, "base", base).updateDeclLineNumber(module, decl), .macho => return @fieldParentPtr(MachO, "base", base).updateDeclLineNumber(module, decl), .c, .wasm => {}, } } /// Must be called before any call to updateDecl or updateDeclExports for /// any given Decl. pub fn allocateDeclIndexes(base: *File, decl: *Module.Decl) !void { switch (base.tag) { .coff => return @fieldParentPtr(Coff, "base", base).allocateDeclIndexes(decl), .elf => return @fieldParentPtr(Elf, "base", base).allocateDeclIndexes(decl), .macho => return @fieldParentPtr(MachO, "base", base).allocateDeclIndexes(decl), .c, .wasm => {}, } } pub fn destroy(base: *File) void { if (base.file) |f| f.close(); if (base.intermediary_basename) |sub_path| base.allocator.free(sub_path); switch (base.tag) { .coff => { const parent = @fieldParentPtr(Coff, "base", base); parent.deinit(); base.allocator.destroy(parent); }, .elf => { const parent = @fieldParentPtr(Elf, "base", base); parent.deinit(); base.allocator.destroy(parent); }, .macho => { const parent = @fieldParentPtr(MachO, "base", base); parent.deinit(); base.allocator.destroy(parent); }, .c => { const parent = @fieldParentPtr(C, "base", base); parent.deinit(); base.allocator.destroy(parent); }, .wasm => { const parent = @fieldParentPtr(Wasm, "base", base); parent.deinit(); base.allocator.destroy(parent); }, } } pub fn flush(base: *File, comp: *Compilation) !void { const tracy = trace(@src()); defer tracy.end(); try switch (base.tag) { .coff => @fieldParentPtr(Coff, "base", base).flush(comp), .elf => @fieldParentPtr(Elf, "base", base).flush(comp), .macho => @fieldParentPtr(MachO, "base", base).flush(comp), .c => @fieldParentPtr(C, "base", base).flush(comp), .wasm => @fieldParentPtr(Wasm, "base", base).flush(comp), }; } pub fn freeDecl(base: *File, decl: *Module.Decl) void { switch (base.tag) { .coff => @fieldParentPtr(Coff, "base", base).freeDecl(decl), .elf => @fieldParentPtr(Elf, "base", base).freeDecl(decl), .macho => @fieldParentPtr(MachO, "base", base).freeDecl(decl), .c => unreachable, .wasm => @fieldParentPtr(Wasm, "base", base).freeDecl(decl), } } pub fn errorFlags(base: *File) ErrorFlags { return switch (base.tag) { .coff => @fieldParentPtr(Coff, "base", base).error_flags, .elf => @fieldParentPtr(Elf, "base", base).error_flags, .macho => @fieldParentPtr(MachO, "base", base).error_flags, .c => return .{ .no_entry_point_found = false }, .wasm => return ErrorFlags{}, }; } /// May be called before or after updateDecl, but must be called after /// allocateDeclIndexes for any given Decl. pub fn updateDeclExports( base: *File, module: *Module, decl: *const Module.Decl, exports: []const *Module.Export, ) !void { switch (base.tag) { .coff => return @fieldParentPtr(Coff, "base", base).updateDeclExports(module, decl, exports), .elf => return @fieldParentPtr(Elf, "base", base).updateDeclExports(module, decl, exports), .macho => return @fieldParentPtr(MachO, "base", base).updateDeclExports(module, decl, exports), .c => return {}, .wasm => return @fieldParentPtr(Wasm, "base", base).updateDeclExports(module, decl, exports), } } pub fn getDeclVAddr(base: *File, decl: *const Module.Decl) u64 { switch (base.tag) { .coff => return @fieldParentPtr(Coff, "base", base).getDeclVAddr(decl), .elf => return @fieldParentPtr(Elf, "base", base).getDeclVAddr(decl), .macho => return @fieldParentPtr(MachO, "base", base).getDeclVAddr(decl), .c => unreachable, .wasm => unreachable, } } pub const Tag = enum { coff, elf, macho, c, wasm, }; pub const ErrorFlags = struct { no_entry_point_found: bool = false, }; pub const C = @import("link/C.zig"); pub const Coff = @import("link/Coff.zig"); pub const Elf = @import("link/Elf.zig"); pub const MachO = @import("link/MachO.zig"); pub const Wasm = @import("link/Wasm.zig"); }; pub fn determineMode(options: Options) fs.File.Mode { // On common systems with a 0o022 umask, 0o777 will still result in a file created // with 0o755 permissions, but it works appropriately if the system is configured // more leniently. As another data point, C's fopen seems to open files with the // 666 mode. const executable_mode = if (std.Target.current.os.tag == .windows) 0 else 0o777; switch (options.effectiveOutputMode()) { .Lib => return switch (options.link_mode) { .Dynamic => executable_mode, .Static => fs.File.default_mode, }, .Exe => return executable_mode, .Obj => return fs.File.default_mode, } }