src/go/types/methodset.go - go - Git at Google

 // Copyright 2013 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.

 // This file implements method sets.

 package types

 import (
 	"fmt"
 	"sort"
 	"strings"
 )

 // A MethodSet is an ordered set of concrete or abstract (interface) methods;
 // a method is a MethodVal selection, and they are ordered by ascending m.Obj().Id().
 // The zero value for a MethodSet is a ready-to-use empty method set.
 type MethodSet struct {
 	list []*Selection
 }

 func (s *MethodSet) String() string {
 	if s.Len() == 0 {
 		return "MethodSet {}"
 	}

 	var buf strings.Builder
 	fmt.Fprintln(&buf, "MethodSet {")
 	for _, f := range s.list {
 		fmt.Fprintf(&buf, "\t%s\n", f)
 	}
 	fmt.Fprintln(&buf, "}")
 	return buf.String()
 }

 // Len returns the number of methods in s.
 func (s *MethodSet) Len() int { return len(s.list) }

 // At returns the i'th method in s for 0 <= i < s.Len().
 func (s *MethodSet) At(i int) *Selection { return s.list[i] }

 // Lookup returns the method with matching package and name, or nil if not found.
 func (s *MethodSet) Lookup(pkg *Package, name string) *Selection {
 	if s.Len() == 0 {
 		return nil
 	}

 	key := Id(pkg, name)
 	i := sort.Search(len(s.list), func(i int) bool {
 		m := s.list[i]
 		return m.obj.Id() >= key
 	})
 	if i < len(s.list) {
 		m := s.list[i]
 		if m.obj.Id() == key {
 			return m
 		}
 	}
 	return nil
 }

 // Shared empty method set.
 var emptyMethodSet MethodSet

 // NewMethodSet returns the method set for the given type T.
 // It always returns a non-nil method set, even if it is empty.
 func NewMethodSet(T Type) *MethodSet {
 	// WARNING: The code in this function is extremely subtle - do not modify casually!
 	//          This function and lookupFieldOrMethod should be kept in sync.

 	// method set up to the current depth, allocated lazily
 	var base methodSet

 	typ, isPtr := deref(T)

 	// *typ where typ is an interface has no methods.
 	if isPtr && IsInterface(typ) {
 		return &emptyMethodSet
 	}

 	// Start with typ as single entry at shallowest depth.
 	current := []embeddedType{{typ, nil, isPtr, false}}

 	// Named types that we have seen already, allocated lazily.
 	// Used to avoid endless searches in case of recursive types.
 	// Since only Named types can be used for recursive types, we
 	// only need to track those.
 	// (If we ever allow type aliases to construct recursive types,
 	// we must use type identity rather than pointer equality for
 	// the map key comparison, as we do in consolidateMultiples.)
 	var seen map[*Named]bool

 	// collect methods at current depth
 	for len(current) > 0 {
 		var next []embeddedType // embedded types found at current depth

 		// field and method sets at current depth, allocated lazily
 		var fset fieldSet
 		var mset methodSet

 		for _, e := range current {
 			typ := e.typ

 			// If we have a named type, we may have associated methods.
 			// Look for those first.
 			if named, _ := typ.(*Named); named != nil {
 				if seen[named] {
 					// We have seen this type before, at a more shallow depth
 					// (note that multiples of this type at the current depth
 					// were consolidated before). The type at that depth shadows
 					// this same type at the current depth, so we can ignore
 					// this one.
 					continue
 				}
 				if seen == nil {
 					seen = make(map[*Named]bool)
 				}
 				seen[named] = true

 				mset = mset.add(named.methods, e.index, e.indirect, e.multiples)

 				// continue with underlying type
 				typ = named.underlying
 			}

 			switch t := typ.(type) {
 			case *Struct:
 				for i, f := range t.fields {
 					fset = fset.add(f, e.multiples)

 					// Embedded fields are always of the form T or *T where
 					// T is a type name. If typ appeared multiple times at
 					// this depth, f.Type appears multiple times at the next
 					// depth.
 					if f.embedded {
 						typ, isPtr := deref(f.typ)
 						// TODO(gri) optimization: ignore types that can't
 						// have fields or methods (only Named, Struct, and
 						// Interface types need to be considered).
 						next = append(next, embeddedType{typ, concat(e.index, i), e.indirect || isPtr, e.multiples})
 					}
 				}

 			case *Interface:
 				mset = mset.add(t.allMethods, e.index, true, e.multiples)
 			}
 		}

 		// Add methods and collisions at this depth to base if no entries with matching
 		// names exist already.
 		for k, m := range mset {
 			if _, found := base[k]; !found {
 				// Fields collide with methods of the same name at this depth.
 				if _, found := fset[k]; found {
 					m = nil // collision
 				}
 				if base == nil {
 					base = make(methodSet)
 				}
 				base[k] = m
 			}
 		}

 		// Multiple fields with matching names collide at this depth and shadow all
 		// entries further down; add them as collisions to base if no entries with
 		// matching names exist already.
 		for k, f := range fset {
 			if f == nil {
 				if _, found := base[k]; !found {
 					if base == nil {
 						base = make(methodSet)
 					}
 					base[k] = nil // collision
 				}
 			}
 		}

 		current = consolidateMultiples(next)
 	}

 	if len(base) == 0 {
 		return &emptyMethodSet
 	}

 	// collect methods
 	var list []*Selection
 	for _, m := range base {
 		if m != nil {
 			m.recv = T
 			list = append(list, m)
 		}
 	}
 	// sort by unique name
 	sort.Slice(list, func(i, j int) bool {
 		return list[i].obj.Id() < list[j].obj.Id()
 	})
 	return &MethodSet{list}
 }

 // A fieldSet is a set of fields and name collisions.
 // A collision indicates that multiple fields with the
 // same unique id appeared.
 type fieldSet map[string]*Var // a nil entry indicates a name collision

 // Add adds field f to the field set s.
 // If multiples is set, f appears multiple times
 // and is treated as a collision.
 func (s fieldSet) add(f *Var, multiples bool) fieldSet {
 	if s == nil {
 		s = make(fieldSet)
 	}
 	key := f.Id()
 	// if f is not in the set, add it
 	if !multiples {
 		if _, found := s[key]; !found {
 			s[key] = f
 			return s
 		}
 	}
 	s[key] = nil // collision
 	return s
 }

 // A methodSet is a set of methods and name collisions.
 // A collision indicates that multiple methods with the
 // same unique id appeared.
 type methodSet map[string]*Selection // a nil entry indicates a name collision

 // Add adds all functions in list to the method set s.
 // If multiples is set, every function in list appears multiple times
 // and is treated as a collision.
 func (s methodSet) add(list []*Func, index []int, indirect bool, multiples bool) methodSet {
 	if len(list) == 0 {
 		return s
 	}
 	if s == nil {
 		s = make(methodSet)
 	}
 	for i, f := range list {
 		key := f.Id()
 		// if f is not in the set, add it
 		if !multiples {
 			// TODO(gri) A found method may not be added because it's not in the method set
 			// (!indirect && ptrRecv(f)). A 2nd method on the same level may be in the method
 			// set and may not collide with the first one, thus leading to a false positive.
 			// Is that possible? Investigate.
 			if _, found := s[key]; !found && (indirect || !ptrRecv(f)) {
 				s[key] = &Selection{MethodVal, nil, f, concat(index, i), indirect}
 				continue
 			}
 		}
 		s[key] = nil // collision
 	}
 	return s
 }

 // ptrRecv reports whether the receiver is of the form *T.
 // The receiver must exist.
 func ptrRecv(f *Func) bool {
 	_, isPtr := deref(f.typ.(*Signature).recv.typ)
 	return isPtr
 }
	// Copyright 2013 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.

	// This file implements method sets.

	package types

	import (
	"fmt"
	"sort"
	"strings"
	)

	// A MethodSet is an ordered set of concrete or abstract (interface) methods;
	// a method is a MethodVal selection, and they are ordered by ascending m.Obj().Id().
	// The zero value for a MethodSet is a ready-to-use empty method set.
	type MethodSet struct {
	list []*Selection
	}

	func (s *MethodSet) String() string {
	if s.Len() == 0 {
	return "MethodSet {}"
	}

	var buf strings.Builder
	fmt.Fprintln(&buf, "MethodSet {")
	for _, f := range s.list {
	fmt.Fprintf(&buf, "\t%s\n", f)
	}
	fmt.Fprintln(&buf, "}")
	return buf.String()
	}

	// Len returns the number of methods in s.
	func (s *MethodSet) Len() int { return len(s.list) }

	// At returns the i'th method in s for 0 <= i < s.Len().
	func (s MethodSet) At(i int) Selection { return s.list[i] }

	// Lookup returns the method with matching package and name, or nil if not found.
	func (s MethodSet) Lookup(pkg Package, name string) *Selection {
	if s.Len() == 0 {
	return nil
	}

	key := Id(pkg, name)
	i := sort.Search(len(s.list), func(i int) bool {
	m := s.list[i]
	return m.obj.Id() >= key
	})
	if i < len(s.list) {
	m := s.list[i]
	if m.obj.Id() == key {
	return m
	}
	}
	return nil
	}

	// Shared empty method set.
	var emptyMethodSet MethodSet

	// NewMethodSet returns the method set for the given type T.
	// It always returns a non-nil method set, even if it is empty.
	func NewMethodSet(T Type) *MethodSet {
	// WARNING: The code in this function is extremely subtle - do not modify casually!
	// This function and lookupFieldOrMethod should be kept in sync.

	// method set up to the current depth, allocated lazily
	var base methodSet

	typ, isPtr := deref(T)

	// *typ where typ is an interface has no methods.
	if isPtr && IsInterface(typ) {
	return &emptyMethodSet
	}

	// Start with typ as single entry at shallowest depth.
	current := []embeddedType{{typ, nil, isPtr, false}}

	// Named types that we have seen already, allocated lazily.
	// Used to avoid endless searches in case of recursive types.
	// Since only Named types can be used for recursive types, we
	// only need to track those.
	// (If we ever allow type aliases to construct recursive types,
	// we must use type identity rather than pointer equality for
	// the map key comparison, as we do in consolidateMultiples.)
	var seen map[*Named]bool

	// collect methods at current depth
	for len(current) > 0 {
	var next []embeddedType // embedded types found at current depth

	// field and method sets at current depth, allocated lazily
	var fset fieldSet
	var mset methodSet

	for _, e := range current {
	typ := e.typ

	// If we have a named type, we may have associated methods.
	// Look for those first.
	if named, _ := typ.(*Named); named != nil {
	if seen[named] {
	// We have seen this type before, at a more shallow depth
	// (note that multiples of this type at the current depth
	// were consolidated before). The type at that depth shadows
	// this same type at the current depth, so we can ignore
	// this one.
	continue
	}
	if seen == nil {
	seen = make(map[*Named]bool)
	}
	seen[named] = true

	mset = mset.add(named.methods, e.index, e.indirect, e.multiples)

	// continue with underlying type
	typ = named.underlying
	}

	switch t := typ.(type) {
	case *Struct:
	for i, f := range t.fields {
	fset = fset.add(f, e.multiples)

	// Embedded fields are always of the form T or *T where
	// T is a type name. If typ appeared multiple times at
	// this depth, f.Type appears multiple times at the next
	// depth.
	if f.embedded {
	typ, isPtr := deref(f.typ)
	// TODO(gri) optimization: ignore types that can't
	// have fields or methods (only Named, Struct, and
	// Interface types need to be considered).
	next = append(next, embeddedType{typ, concat(e.index, i), e.indirect \|\| isPtr, e.multiples})
	}
	}

	case *Interface:
	mset = mset.add(t.allMethods, e.index, true, e.multiples)
	}
	}

	// Add methods and collisions at this depth to base if no entries with matching
	// names exist already.
	for k, m := range mset {
	if _, found := base[k]; !found {
	// Fields collide with methods of the same name at this depth.
	if _, found := fset[k]; found {
	m = nil // collision
	}
	if base == nil {
	base = make(methodSet)
	}
	base[k] = m
	}
	}

	// Multiple fields with matching names collide at this depth and shadow all
	// entries further down; add them as collisions to base if no entries with
	// matching names exist already.
	for k, f := range fset {
	if f == nil {
	if _, found := base[k]; !found {
	if base == nil {
	base = make(methodSet)
	}
	base[k] = nil // collision
	}
	}
	}

	current = consolidateMultiples(next)
	}

	if len(base) == 0 {
	return &emptyMethodSet
	}

	// collect methods
	var list []*Selection
	for _, m := range base {
	if m != nil {
	m.recv = T
	list = append(list, m)
	}
	}
	// sort by unique name
	sort.Slice(list, func(i, j int) bool {
	return list[i].obj.Id() < list[j].obj.Id()
	})
	return &MethodSet{list}
	}

	// A fieldSet is a set of fields and name collisions.
	// A collision indicates that multiple fields with the
	// same unique id appeared.
	type fieldSet map[string]*Var // a nil entry indicates a name collision

	// Add adds field f to the field set s.
	// If multiples is set, f appears multiple times
	// and is treated as a collision.
	func (s fieldSet) add(f *Var, multiples bool) fieldSet {
	if s == nil {
	s = make(fieldSet)
	}
	key := f.Id()
	// if f is not in the set, add it
	if !multiples {
	if _, found := s[key]; !found {
	s[key] = f
	return s
	}
	}
	s[key] = nil // collision
	return s
	}

	// A methodSet is a set of methods and name collisions.
	// A collision indicates that multiple methods with the
	// same unique id appeared.
	type methodSet map[string]*Selection // a nil entry indicates a name collision

	// Add adds all functions in list to the method set s.
	// If multiples is set, every function in list appears multiple times
	// and is treated as a collision.
	func (s methodSet) add(list []*Func, index []int, indirect bool, multiples bool) methodSet {
	if len(list) == 0 {
	return s
	}
	if s == nil {
	s = make(methodSet)
	}
	for i, f := range list {
	key := f.Id()
	// if f is not in the set, add it
	if !multiples {
	// TODO(gri) A found method may not be added because it's not in the method set
	// (!indirect && ptrRecv(f)). A 2nd method on the same level may be in the method
	// set and may not collide with the first one, thus leading to a false positive.
	// Is that possible? Investigate.
	if _, found := s[key]; !found && (indirect \|\| !ptrRecv(f)) {
	s[key] = &Selection{MethodVal, nil, f, concat(index, i), indirect}
	continue
	}
	}
	s[key] = nil // collision
	}
	return s
	}

	// ptrRecv reports whether the receiver is of the form *T.
	// The receiver must exist.
	func ptrRecv(f *Func) bool {
	_, isPtr := deref(f.typ.(*Signature).recv.typ)
	return isPtr
	}