func NewCompiler(opts CompilerOptions) (Compiler, error) { compiler := &compiler{CompilerOptions: opts} if strings.ToLower(compiler.TargetTriple) == "pnacl" { compiler.TargetTriple = PNaClTriple compiler.pnacl = true } // Triples are several fields separated by '-' characters. // The first field is the architecture. The architecture's // canonical form may include a '-' character, which would // have been translated to '_' for inclusion in a triple. triple := compiler.TargetTriple arch := triple[:strings.IndexRune(triple, '-')] arch = parseArch(arch) var machine llvm.TargetMachine for target := llvm.FirstTarget(); target.C != nil; target = target.NextTarget() { if arch == target.Name() { machine = target.CreateTargetMachine(triple, "", "", llvm.CodeGenLevelDefault, llvm.RelocDefault, llvm.CodeModelDefault) compiler.machine = machine break } } if machine.C == nil { return nil, fmt.Errorf("Invalid target triple: %s", triple) } compiler.target = machine.TargetData() return compiler, nil }
func displayVersion() { fmt.Println("llgo version", llgo.LLGOVersion) fmt.Println() fmt.Println(" Available targets:") longestTargetName := 0 targetDescriptions := make(map[string]string) targetNames := make([]string, 0) for target := llvm.FirstTarget(); target.C != nil; target = target.NextTarget() { targetName := target.Name() targetNames = append(targetNames, targetName) targetDescriptions[targetName] = target.Description() if len(targetName) > longestTargetName { longestTargetName = len(targetName) } } sort.Strings(targetNames) for _, targetName := range targetNames { var paddingLen int = longestTargetName - len(targetName) fmt.Printf(" %s %*s %s\n", targetName, paddingLen+1, "-", targetDescriptions[targetName]) } fmt.Println() os.Exit(0) }
// llvmDataLayout returns the data layout string // representation for the specified LLVM triple. func llvmDataLayout(triple string) (string, error) { // Triples are several fields separated by '-' characters. // The first field is the architecture. The architecture's // canonical form may include a '-' character, which would // have been translated to '_' for inclusion in a triple. arch := parseArch(triple[:strings.IndexRune(triple, '-')]) switch arch { case "x86-64": return x86TargetData, nil } for target := llvm.FirstTarget(); target.C != nil; target = target.NextTarget() { if arch == target.Name() { machine := target.CreateTargetMachine( triple, "", "", llvm.CodeGenLevelDefault, llvm.RelocDefault, llvm.CodeModelDefault, ) target := machine.TargetData().String() machine.Dispose() return target, nil } } return "", fmt.Errorf("Invalid target triple: %s", triple) }
func (compiler *compiler) Compile(fset *token.FileSet, pkg *ast.Package, exprTypes map[ast.Expr]types.Type) (m *Module, err error) { // FIXME create a compilation state, rather than storing in 'compiler'. compiler.fileset = fset compiler.pkg = pkg compiler.initfuncs = make([]Value, 0) // Create a Builder, for building LLVM instructions. compiler.builder = llvm.GlobalContext().NewBuilder() defer compiler.builder.Dispose() // Create a TargetMachine from the OS & Arch. triple := fmt.Sprintf("%s-unknown-%s", getTripleArchName(compiler.targetArch), compiler.targetOs) var machine llvm.TargetMachine for target := llvm.FirstTarget(); target.C != nil && machine.C == nil; target = target.NextTarget() { if target.Name() == compiler.targetArch { machine = target.CreateTargetMachine(triple, "", "", llvm.CodeGenLevelDefault, llvm.RelocDefault, llvm.CodeModelDefault) defer machine.Dispose() } } if machine.C == nil { err = fmt.Errorf("Invalid target triple: %s", triple) return } // Create a Module, which contains the LLVM bitcode. Dispose it on panic, // otherwise we'll set a finalizer at the end. The caller may invoke // Dispose manually, which will render the finalizer a no-op. modulename := pkg.Name compiler.target = machine.TargetData() compiler.module = &Module{llvm.NewModule(modulename), modulename, false} compiler.module.SetTarget(triple) compiler.module.SetDataLayout(compiler.target.String()) defer func() { if e := recover(); e != nil { compiler.module.Dispose() panic(e) //err = e.(error) } }() compiler.types = NewTypeMap(compiler.module.Module, compiler.target, exprTypes) // Create a mapping from objects back to packages, so we can create the // appropriate symbol names. compiler.pkgmap = createPackageMap(pkg) // Compile each file in the package. for _, file := range pkg.Files { file.Scope.Outer = pkg.Scope compiler.filescope = file.Scope compiler.scope = file.Scope compiler.fixConstDecls(file) for _, decl := range file.Decls { compiler.VisitDecl(decl) } } // Define intrinsics for use by the runtime: malloc, free, memcpy, etc. compiler.defineRuntimeIntrinsics() // Create global constructors. // // XXX When imports are handled, we'll need to defer creating // llvm.global_ctors until we create an executable. This is // due to (a) imports having to be initialised before the // importer, and (b) LLVM having no specified order of // initialisation for ctors with the same priority. if len(compiler.initfuncs) > 0 { elttypes := []llvm.Type{ llvm.Int32Type(), llvm.PointerType( llvm.FunctionType(llvm.VoidType(), nil, false), 0)} ctortype := llvm.StructType(elttypes, false) ctors := make([]llvm.Value, len(compiler.initfuncs)) for i, fn := range compiler.initfuncs { struct_values := []llvm.Value{ llvm.ConstInt(llvm.Int32Type(), 1, false), fn.LLVMValue()} ctors[i] = llvm.ConstStruct(struct_values, false) } global_ctors_init := llvm.ConstArray(ctortype, ctors) global_ctors_var := llvm.AddGlobal( compiler.module.Module, global_ctors_init.Type(), "llvm.global_ctors") global_ctors_var.SetInitializer(global_ctors_init) global_ctors_var.SetLinkage(llvm.AppendingLinkage) } // Create debug metadata. compiler.createMetadata() return compiler.module, nil }
func (compiler *compiler) Compile(fset *token.FileSet, pkg *ast.Package, importpath string, exprTypes map[ast.Expr]types.Type) (m *Module, err error) { // FIXME create a compilation state, rather than storing in 'compiler'. compiler.fileset = fset compiler.pkg = pkg compiler.importpath = importpath compiler.initfuncs = nil compiler.varinitfuncs = nil // Create a Builder, for building LLVM instructions. compiler.builder = llvm.GlobalContext().NewBuilder() defer compiler.builder.Dispose() // Create a TargetMachine from the OS & Arch. triple := compiler.GetTargetTriple() var machine llvm.TargetMachine for target := llvm.FirstTarget(); target.C != nil && machine.C == nil; target = target.NextTarget() { if target.Name() == compiler.targetArch { machine = target.CreateTargetMachine(triple, "", "", llvm.CodeGenLevelDefault, llvm.RelocDefault, llvm.CodeModelDefault) defer machine.Dispose() } } if machine.C == nil { err = fmt.Errorf("Invalid target triple: %s", triple) return } // Create a Module, which contains the LLVM bitcode. Dispose it on panic, // otherwise we'll set a finalizer at the end. The caller may invoke // Dispose manually, which will render the finalizer a no-op. modulename := pkg.Name compiler.target = machine.TargetData() compiler.module = &Module{llvm.NewModule(modulename), modulename, false} compiler.module.SetTarget(triple) compiler.module.SetDataLayout(compiler.target.String()) defer func() { if e := recover(); e != nil { compiler.module.Dispose() panic(e) //err = e.(error) } }() // Create a mapping from objects back to packages, so we can create the // appropriate symbol names. compiler.pkgmap = createPackageMap(pkg, importpath) // Create a struct responsible for mapping static types to LLVM types, // and to runtime/dynamic type values. var resolver Resolver = compiler llvmtypemap := NewLLVMTypeMap(compiler.module.Module, compiler.target) compiler.FunctionCache = NewFunctionCache(compiler) compiler.types = NewTypeMap(llvmtypemap, importpath, exprTypes, compiler.FunctionCache, compiler.pkgmap, resolver) // Compile each file in the package. for _, file := range pkg.Files { file.Scope.Outer = pkg.Scope compiler.filescope = file.Scope compiler.scope = file.Scope compiler.fixConstDecls(file) for _, decl := range file.Decls { compiler.VisitDecl(decl) } } // Define intrinsics for use by the runtime: malloc, free, memcpy, etc. // These could be defined in LLVM IR, and may be moved there later. if pkg.Name == "runtime" { compiler.defineRuntimeIntrinsics() } // Export runtime type information. if pkg.Name == "runtime" { compiler.exportBuiltinRuntimeTypes() } // Create global constructors. // // XXX When imports are handled, we'll need to defer creating // llvm.global_ctors until we create an executable. This is // due to (a) imports having to be initialised before the // importer, and (b) LLVM having no specified order of // initialisation for ctors with the same priority. var initfuncs [][]Value if compiler.varinitfuncs != nil { initfuncs = append(initfuncs, compiler.varinitfuncs) } if compiler.initfuncs != nil { initfuncs = append(initfuncs, compiler.initfuncs) } if initfuncs != nil { elttypes := []llvm.Type{llvm.Int32Type(), llvm.PointerType(llvm.FunctionType(llvm.VoidType(), nil, false), 0)} ctortype := llvm.StructType(elttypes, false) var ctors []llvm.Value var priority uint64 for _, initfuncs := range initfuncs { for _, fn := range initfuncs { priorityval := llvm.ConstInt(llvm.Int32Type(), uint64(priority), false) struct_values := []llvm.Value{priorityval, fn.LLVMValue()} ctors = append(ctors, llvm.ConstStruct(struct_values, false)) priority++ } } global_ctors_init := llvm.ConstArray(ctortype, ctors) global_ctors_var := llvm.AddGlobal(compiler.module.Module, global_ctors_init.Type(), "llvm.global_ctors") global_ctors_var.SetInitializer(global_ctors_init) global_ctors_var.SetLinkage(llvm.AppendingLinkage) } // Create debug metadata. //compiler.createMetadata() return compiler.module, nil }