usr/gri/pretty/symboltable.go - go - Git at Google

 // Copyright 2009 The Go Authors.  All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package SymbolTable

 import (
 	"container/vector";
 	"unicode";
 	"utf8";
 )


 type Type struct;


 // ----------------------------------------------------------------------------
 // Support

 func assert(pred bool) {
 	if !pred {
 		panic("assertion failed");
 	}
 }


 // ----------------------------------------------------------------------------
 // Objects

 // Object represents a language object, such as a constant, variable, type, etc.

 const /* kind */ (
 	BADOBJ = iota;  // error handling
 	NONE;  // kind unknown
 	CONST; TYPE; VAR; FIELD; FUNC; BUILTIN; PACKAGE; LABEL;
 	END;  // end of scope (import/export only)
 )


 func KindStr(kind int) string {
 	switch kind {
 	case BADOBJ: return "BADOBJ";
 	case NONE: return "NONE";
 	case CONST: return "CONST";
 	case TYPE: return "TYPE";
 	case VAR: return "VAR";
 	case FIELD: return "FIELD";
 	case FUNC: return "FUNC";
 	case BUILTIN: return "BUILTIN";
 	case PACKAGE: return "PACKAGE";
 	case LABEL: return "LABEL";
 	case END: return "END";
 	}
 	return "<unknown Object kind>";
 }


 type Object struct {
 	Id int;  // unique id

 	Pos int;  // source position (< 0 if unknown position)
 	Kind int;  // object kind
 	Ident string;
 	Typ *Type;  // nil for packages
 	Pnolev int;  // >= 0: package no., <= 0: function nesting level, 0: global level
 }


 func (obj *Object) IsExported() bool {
 	switch obj.Kind {
 	case NONE /* FUNC for now */, CONST, TYPE, VAR, FUNC:
 		ch, size := utf8.DecodeRuneInString(obj.Ident);
 		return unicode.IsUpper(ch);
 	}
 	return false;
 }


 func (obj* Object) String() string {
 	if obj != nil {
 		return
 			"Object(" +
 			KindStr(obj.Kind) + ", " +
 			obj.Ident +
 			")";
 	}
 	return "nil";
 }


 var Universe_void_typ *Type  // initialized by Universe to Universe.void_typ
 var objectId int;

 func NewObject(pos, kind int, ident string) *Object {
 	obj := new(Object);
 	obj.Id = objectId;
 	objectId++;

 	obj.Pos = pos;
 	obj.Kind = kind;
 	obj.Ident = ident;
 	obj.Typ = Universe_void_typ;  // TODO would it be better to use nil instead?
 	obj.Pnolev = 0;

 	return obj;
 }


 // ----------------------------------------------------------------------------
 // Scopes

 type Scope struct {
 	Parent *Scope;
 	entries map[string] *Object;
 }


 func NewScope(parent *Scope) *Scope {
 	scope := new(Scope);
 	scope.Parent = parent;
 	scope.entries = make(map[string] *Object, 8);
 	return scope;
 }


 func (scope *Scope) LookupLocal(ident string) *Object {
 	obj, found := scope.entries[ident];
 	if found {
 		return obj;
 	}
 	return nil;
 }


 func (scope *Scope) Lookup(ident string) *Object {
 	for scope != nil {
 		obj := scope.LookupLocal(ident);
 		if obj != nil {
 			return obj;
 		}
 		scope = scope.Parent;
 	}
 	return nil;
 }


 func (scope *Scope) add(obj *Object) {
 	scope.entries[obj.Ident] = obj;
 }


 func (scope *Scope) Insert(obj *Object) {
 	if scope.LookupLocal(obj.Ident) != nil {
 		panic("obj already inserted");
 	}
 	scope.add(obj);
 }


 func (scope *Scope) InsertImport(obj *Object) *Object {
 	 p := scope.LookupLocal(obj.Ident);
 	 if p == nil {
 		scope.add(obj);
 		p = obj;
 	 }
 	 return p;
 }


 func (scope *Scope) Print() {
 	print("scope {");
 	for key := range scope.entries {
 		print("\n  ", key);
 	}
 	print("\n}\n");
 }


 // ----------------------------------------------------------------------------
 // Types

 const /* form */ (
 	// internal types
 	// We should never see one of these.
 	UNDEF = iota;

 	// VOID types are used when we don't have a type. Never exported.
 	// (exported type forms must be > 0)
 	VOID;

 	// BADTYPE types are compatible with any type and don't cause further errors.
 	// They are introduced only as a result of an error in the source code. A
 	// correct program cannot have BAD types.
 	BADTYPE;

 	// FORWARD types are forward-declared (incomplete) types. They can only
 	// be used as element types of pointer types and must be resolved before
 	// their internals are accessible.
 	FORWARD;

 	// TUPLE types represent multi-valued result types of functions and
 	// methods.
 	TUPLE;

 	// The type of nil.
 	NIL;

 	// A type name
 	TYPENAME;

 	// basic types
 	BOOL; UINT; INT; FLOAT; STRING; INTEGER;

 	// composite types
 	ALIAS; ARRAY; STRUCT; INTERFACE; MAP; CHANNEL; FUNCTION; METHOD; POINTER;

 	// open-ended parameter type
 	ELLIPSIS
 )


 func FormStr(form int) string {
 	switch form {
 	case VOID: return "VOID";
 	case BADTYPE: return "BADTYPE";
 	case FORWARD: return "FORWARD";
 	case TUPLE: return "TUPLE";
 	case NIL: return "NIL";
 	case TYPENAME: return "TYPENAME";
 	case BOOL: return "BOOL";
 	case UINT: return "UINT";
 	case INT: return "INT";
 	case FLOAT: return "FLOAT";
 	case STRING: return "STRING";
 	case ALIAS: return "ALIAS";
 	case ARRAY: return "ARRAY";
 	case STRUCT: return "STRUCT";
 	case INTERFACE: return "INTERFACE";
 	case MAP: return "MAP";
 	case CHANNEL: return "CHANNEL";
 	case FUNCTION: return "FUNCTION";
 	case METHOD: return "METHOD";
 	case POINTER: return "POINTER";
 	case ELLIPSIS: return "ELLIPSIS";
 	}
 	return "<unknown Type form>";
 }


 const /* channel mode */ (
 	FULL = iota;
 	SEND;
 	RECV;
 )


 type Type struct {
 	Id int;  // unique id

 	Ref int;  // for exporting only: >= 0 means already exported
 	Form int;  // type form
 	Size int;  // size in bytes
 	Obj *Object;  // primary type object or nil
 	Scope *Scope;  // locals, fields & methods

 	// syntactic components
 	Pos int;  // source position (< 0 if unknown position)
 	Len int;  // array length
 	Mode int;  // channel mode
 	Key *Type;  // receiver type or map key
 	Elt *Type;  // type name type, array, map, channel or pointer element type, function result type
 	List *vector.Vector; End int;  // struct fields, interface methods, function parameters
 }


 var typeId int;

 func NewType(pos, form int) *Type {
 	typ := new(Type);
 	typ.Id = typeId;
 	typeId++;

 	typ.Ref = -1;  // not yet exported
 	typ.Pos = pos;
 	typ.Form = form;

 	return typ;
 }


 func (typ* Type) String() string {
 	if typ != nil {
 		return
 			"Type(" +
 			FormStr(typ.Form) +
 			")";
 	}
 	return "nil";
 }


 // ----------------------------------------------------------------------------
 // Universe scope

 var (
 	Universe *Scope;
 	PredeclaredTypes vector.Vector;

 	// internal types
 	Void_typ,
 	Bad_typ,
 	Nil_typ,

 	// basic types
 	Bool_typ,
 	Uint8_typ,
 	Uint16_typ,
 	Uint32_typ,
 	Uint64_typ,
 	Int8_typ,
 	Int16_typ,
 	Int32_typ,
 	Int64_typ,
 	Float32_typ,
 	Float64_typ,
 	Float80_typ,
 	String_typ,
 	Integer_typ,

 	// convenience types
 	Byte_typ,
 	Uint_typ,
 	Int_typ,
 	Float_typ,
 	Uintptr_typ *Type;

 	True_obj,
 	False_obj,
 	Iota_obj,
 	Nil_obj *Object;
 )


 func declObj(kind int, ident string, typ *Type) *Object {
 	obj := NewObject(-1 /* no source pos */, kind, ident);
 	obj.Typ = typ;
 	if kind == TYPE && typ.Obj == nil {
 		typ.Obj = obj;  // set primary type object
 	}
 	Universe.Insert(obj);
 	return obj
 }


 func declType(form int, ident string, size int) *Type {
   typ := NewType(-1 /* no source pos */, form);
   typ.Size = size;
   return declObj(TYPE, ident, typ).Typ;
 }


 func register(typ *Type) *Type {
 	typ.Ref = PredeclaredTypes.Len();
 	PredeclaredTypes.Push(typ);
 	return typ;
 }


 func init() {
 	Universe = NewScope(nil);  // universe has no parent
 	PredeclaredTypes.Init(32);

 	// Interal types
 	Void_typ = NewType(-1 /* no source pos */, VOID);
 	Universe_void_typ = Void_typ;
 	Bad_typ = NewType(-1 /* no source pos */, BADTYPE);
 	Nil_typ = NewType(-1 /* no source pos */, NIL);

 	// Basic types
 	Bool_typ = register(declType(BOOL, "bool", 1));
 	Uint8_typ = register(declType(UINT, "uint8", 1));
 	Uint16_typ = register(declType(UINT, "uint16", 2));
 	Uint32_typ = register(declType(UINT, "uint32", 4));
 	Uint64_typ = register(declType(UINT, "uint64", 8));
 	Int8_typ = register(declType(INT, "int8", 1));
 	Int16_typ = register(declType(INT, "int16", 2));
 	Int32_typ = register(declType(INT, "int32", 4));
 	Int64_typ = register(declType(INT, "int64", 8));
 	Float32_typ = register(declType(FLOAT, "float32", 4));
 	Float64_typ = register(declType(FLOAT, "float64", 8));
 	Float80_typ = register(declType(FLOAT, "float80", 10));
 	String_typ = register(declType(STRING, "string", 8));
 	Integer_typ = register(declType(INTEGER, "integer", 8));

 	// All but 'byte' should be platform-dependent, eventually.
 	Byte_typ = register(declType(UINT, "byte", 1));
 	Uint_typ = register(declType(UINT, "uint", 4));
 	Int_typ = register(declType(INT, "int", 4));
 	Float_typ = register(declType(FLOAT, "float", 4));
 	Uintptr_typ = register(declType(UINT, "uintptr", 8));

 	// Predeclared constants
 	True_obj = declObj(CONST, "true", Bool_typ);
 	False_obj = declObj(CONST, "false", Bool_typ);
 	Iota_obj = declObj(CONST, "iota", Int_typ);
 	Nil_obj = declObj(CONST, "nil", Nil_typ);

 	// Builtin functions
 	declObj(BUILTIN, "len", Void_typ);
 	declObj(BUILTIN, "new", Void_typ);
 	declObj(BUILTIN, "panic", Void_typ);
 	declObj(BUILTIN, "print", Void_typ);

 	// scope.Print();
 }
	// Copyright 2009 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package SymbolTable

	import (
	"container/vector";
	"unicode";
	"utf8";
	)


	type Type struct;


	// ----------------------------------------------------------------------------
	// Support

	func assert(pred bool) {
	if !pred {
	panic("assertion failed");
	}
	}


	// ----------------------------------------------------------------------------
	// Objects

	// Object represents a language object, such as a constant, variable, type, etc.

	const /* kind */ (
	BADOBJ = iota; // error handling
	NONE; // kind unknown
	CONST; TYPE; VAR; FIELD; FUNC; BUILTIN; PACKAGE; LABEL;
	END; // end of scope (import/export only)
	)


	func KindStr(kind int) string {
	switch kind {
	case BADOBJ: return "BADOBJ";
	case NONE: return "NONE";
	case CONST: return "CONST";
	case TYPE: return "TYPE";
	case VAR: return "VAR";
	case FIELD: return "FIELD";
	case FUNC: return "FUNC";
	case BUILTIN: return "BUILTIN";
	case PACKAGE: return "PACKAGE";
	case LABEL: return "LABEL";
	case END: return "END";
	}
	return "<unknown Object kind>";
	}


	type Object struct {
	Id int; // unique id

	Pos int; // source position (< 0 if unknown position)
	Kind int; // object kind
	Ident string;
	Typ *Type; // nil for packages
	Pnolev int; // >= 0: package no., <= 0: function nesting level, 0: global level
	}


	func (obj *Object) IsExported() bool {
	switch obj.Kind {
	case NONE /* FUNC for now */, CONST, TYPE, VAR, FUNC:
	ch, size := utf8.DecodeRuneInString(obj.Ident);
	return unicode.IsUpper(ch);
	}
	return false;
	}


	func (obj* Object) String() string {
	if obj != nil {
	return
	"Object(" +
	KindStr(obj.Kind) + ", " +
	obj.Ident +
	")";
	}
	return "nil";
	}


	var Universe_void_typ *Type // initialized by Universe to Universe.void_typ
	var objectId int;

	func NewObject(pos, kind int, ident string) *Object {
	obj := new(Object);
	obj.Id = objectId;
	objectId++;

	obj.Pos = pos;
	obj.Kind = kind;
	obj.Ident = ident;
	obj.Typ = Universe_void_typ; // TODO would it be better to use nil instead?
	obj.Pnolev = 0;

	return obj;
	}


	// ----------------------------------------------------------------------------
	// Scopes

	type Scope struct {
	Parent *Scope;
	entries map[string] *Object;
	}


	func NewScope(parent Scope) Scope {
	scope := new(Scope);
	scope.Parent = parent;
	scope.entries = make(map[string] *Object, 8);
	return scope;
	}


	func (scope Scope) LookupLocal(ident string) Object {
	obj, found := scope.entries[ident];
	if found {
	return obj;
	}
	return nil;
	}


	func (scope Scope) Lookup(ident string) Object {
	for scope != nil {
	obj := scope.LookupLocal(ident);
	if obj != nil {
	return obj;
	}
	scope = scope.Parent;
	}
	return nil;
	}


	func (scope Scope) add(obj Object) {
	scope.entries[obj.Ident] = obj;
	}


	func (scope Scope) Insert(obj Object) {
	if scope.LookupLocal(obj.Ident) != nil {
	panic("obj already inserted");
	}
	scope.add(obj);
	}


	func (scope Scope) InsertImport(obj Object) *Object {
	p := scope.LookupLocal(obj.Ident);
	if p == nil {
	scope.add(obj);
	p = obj;
	}
	return p;
	}


	func (scope *Scope) Print() {
	print("scope {");
	for key := range scope.entries {
	print("\n ", key);
	}
	print("\n}\n");
	}


	// ----------------------------------------------------------------------------
	// Types

	const /* form */ (
	// internal types
	// We should never see one of these.
	UNDEF = iota;

	// VOID types are used when we don't have a type. Never exported.
	// (exported type forms must be > 0)
	VOID;

	// BADTYPE types are compatible with any type and don't cause further errors.
	// They are introduced only as a result of an error in the source code. A
	// correct program cannot have BAD types.
	BADTYPE;

	// FORWARD types are forward-declared (incomplete) types. They can only
	// be used as element types of pointer types and must be resolved before
	// their internals are accessible.
	FORWARD;

	// TUPLE types represent multi-valued result types of functions and
	// methods.
	TUPLE;

	// The type of nil.
	NIL;

	// A type name
	TYPENAME;

	// basic types
	BOOL; UINT; INT; FLOAT; STRING; INTEGER;

	// composite types
	ALIAS; ARRAY; STRUCT; INTERFACE; MAP; CHANNEL; FUNCTION; METHOD; POINTER;

	// open-ended parameter type
	ELLIPSIS
	)


	func FormStr(form int) string {
	switch form {
	case VOID: return "VOID";
	case BADTYPE: return "BADTYPE";
	case FORWARD: return "FORWARD";
	case TUPLE: return "TUPLE";
	case NIL: return "NIL";
	case TYPENAME: return "TYPENAME";
	case BOOL: return "BOOL";
	case UINT: return "UINT";
	case INT: return "INT";
	case FLOAT: return "FLOAT";
	case STRING: return "STRING";
	case ALIAS: return "ALIAS";
	case ARRAY: return "ARRAY";
	case STRUCT: return "STRUCT";
	case INTERFACE: return "INTERFACE";
	case MAP: return "MAP";
	case CHANNEL: return "CHANNEL";
	case FUNCTION: return "FUNCTION";
	case METHOD: return "METHOD";
	case POINTER: return "POINTER";
	case ELLIPSIS: return "ELLIPSIS";
	}
	return "<unknown Type form>";
	}


	const /* channel mode */ (
	FULL = iota;
	SEND;
	RECV;
	)


	type Type struct {
	Id int; // unique id

	Ref int; // for exporting only: >= 0 means already exported
	Form int; // type form
	Size int; // size in bytes
	Obj *Object; // primary type object or nil
	Scope *Scope; // locals, fields & methods

	// syntactic components
	Pos int; // source position (< 0 if unknown position)
	Len int; // array length
	Mode int; // channel mode
	Key *Type; // receiver type or map key
	Elt *Type; // type name type, array, map, channel or pointer element type, function result type
	List *vector.Vector; End int; // struct fields, interface methods, function parameters
	}


	var typeId int;

	func NewType(pos, form int) *Type {
	typ := new(Type);
	typ.Id = typeId;
	typeId++;

	typ.Ref = -1; // not yet exported
	typ.Pos = pos;
	typ.Form = form;

	return typ;
	}


	func (typ* Type) String() string {
	if typ != nil {
	return
	"Type(" +
	FormStr(typ.Form) +
	")";
	}
	return "nil";
	}


	// ----------------------------------------------------------------------------
	// Universe scope

	var (
	Universe *Scope;
	PredeclaredTypes vector.Vector;

	// internal types
	Void_typ,
	Bad_typ,
	Nil_typ,

	// basic types
	Bool_typ,
	Uint8_typ,
	Uint16_typ,
	Uint32_typ,
	Uint64_typ,
	Int8_typ,
	Int16_typ,
	Int32_typ,
	Int64_typ,
	Float32_typ,
	Float64_typ,
	Float80_typ,
	String_typ,
	Integer_typ,

	// convenience types
	Byte_typ,
	Uint_typ,
	Int_typ,
	Float_typ,
	Uintptr_typ *Type;

	True_obj,
	False_obj,
	Iota_obj,
	Nil_obj *Object;
	)


	func declObj(kind int, ident string, typ Type) Object {
	obj := NewObject(-1 /* no source pos */, kind, ident);
	obj.Typ = typ;
	if kind == TYPE && typ.Obj == nil {
	typ.Obj = obj; // set primary type object
	}
	Universe.Insert(obj);
	return obj
	}


	func declType(form int, ident string, size int) *Type {
	typ := NewType(-1 /* no source pos */, form);
	typ.Size = size;
	return declObj(TYPE, ident, typ).Typ;
	}


	func register(typ Type) Type {
	typ.Ref = PredeclaredTypes.Len();
	PredeclaredTypes.Push(typ);
	return typ;
	}


	func init() {
	Universe = NewScope(nil); // universe has no parent
	PredeclaredTypes.Init(32);

	// Interal types
	Void_typ = NewType(-1 /* no source pos */, VOID);
	Universe_void_typ = Void_typ;
	Bad_typ = NewType(-1 /* no source pos */, BADTYPE);
	Nil_typ = NewType(-1 /* no source pos */, NIL);

	// Basic types
	Bool_typ = register(declType(BOOL, "bool", 1));
	Uint8_typ = register(declType(UINT, "uint8", 1));
	Uint16_typ = register(declType(UINT, "uint16", 2));
	Uint32_typ = register(declType(UINT, "uint32", 4));
	Uint64_typ = register(declType(UINT, "uint64", 8));
	Int8_typ = register(declType(INT, "int8", 1));
	Int16_typ = register(declType(INT, "int16", 2));
	Int32_typ = register(declType(INT, "int32", 4));
	Int64_typ = register(declType(INT, "int64", 8));
	Float32_typ = register(declType(FLOAT, "float32", 4));
	Float64_typ = register(declType(FLOAT, "float64", 8));
	Float80_typ = register(declType(FLOAT, "float80", 10));
	String_typ = register(declType(STRING, "string", 8));
	Integer_typ = register(declType(INTEGER, "integer", 8));

	// All but 'byte' should be platform-dependent, eventually.
	Byte_typ = register(declType(UINT, "byte", 1));
	Uint_typ = register(declType(UINT, "uint", 4));
	Int_typ = register(declType(INT, "int", 4));
	Float_typ = register(declType(FLOAT, "float", 4));
	Uintptr_typ = register(declType(UINT, "uintptr", 8));

	// Predeclared constants
	True_obj = declObj(CONST, "true", Bool_typ);
	False_obj = declObj(CONST, "false", Bool_typ);
	Iota_obj = declObj(CONST, "iota", Int_typ);
	Nil_obj = declObj(CONST, "nil", Nil_typ);

	// Builtin functions
	declObj(BUILTIN, "len", Void_typ);
	declObj(BUILTIN, "new", Void_typ);
	declObj(BUILTIN, "panic", Void_typ);
	declObj(BUILTIN, "print", Void_typ);

	// scope.Print();
	}