src/cmd/compile/internal/types2/typeparam.go - go - Git at Google

 // Copyright 2011 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 types2

 import "sync/atomic"

 // Note: This is a uint32 rather than a uint64 because the
 // respective 64 bit atomic instructions are not available
 // on all platforms.
 var lastID atomic.Uint32

 // nextID returns a value increasing monotonically by 1 with
 // each call, starting with 1. It may be called concurrently.
 func nextID() uint64 { return uint64(lastID.Add(1)) }

 // A TypeParam represents a type parameter type.
 type TypeParam struct {
 	check *Checker  // for lazy type bound completion
 	id    uint64    // unique id, for debugging only
 	obj   *TypeName // corresponding type name
 	index int       // type parameter index in source order, starting at 0
 	bound Type      // any type, but underlying is eventually *Interface for correct programs (see TypeParam.iface)
 }

 // NewTypeParam returns a new TypeParam. Type parameters may be set on a Named
 // or Signature type by calling SetTypeParams. Setting a type parameter on more
 // than one type will result in a panic.
 //
 // The constraint argument can be nil, and set later via SetConstraint. If the
 // constraint is non-nil, it must be fully defined.
 func NewTypeParam(obj *TypeName, constraint Type) *TypeParam {
 	return (*Checker)(nil).newTypeParam(obj, constraint)
 }

 // check may be nil
 func (check *Checker) newTypeParam(obj *TypeName, constraint Type) *TypeParam {
 	// Always increment lastID, even if it is not used.
 	id := nextID()
 	if check != nil {
 		check.nextID++
 		id = check.nextID
 	}
 	typ := &TypeParam{check: check, id: id, obj: obj, index: -1, bound: constraint}
 	if obj.typ == nil {
 		obj.typ = typ
 	}
 	// iface may mutate typ.bound, so we must ensure that iface() is called
 	// at least once before the resulting TypeParam escapes.
 	if check != nil {
 		check.needsCleanup(typ)
 	} else if constraint != nil {
 		typ.iface()
 	}
 	return typ
 }

 // Obj returns the type name for the type parameter t.
 func (t *TypeParam) Obj() *TypeName { return t.obj }

 // Index returns the index of the type param within its param list, or -1 if
 // the type parameter has not yet been bound to a type.
 func (t *TypeParam) Index() int {
 	return t.index
 }

 // Constraint returns the type constraint specified for t.
 func (t *TypeParam) Constraint() Type {
 	return t.bound
 }

 // SetConstraint sets the type constraint for t.
 //
 // It must be called by users of NewTypeParam after the bound's underlying is
 // fully defined, and before using the type parameter in any way other than to
 // form other types. Once SetConstraint returns the receiver, t is safe for
 // concurrent use.
 func (t *TypeParam) SetConstraint(bound Type) {
 	if bound == nil {
 		panic("nil constraint")
 	}
 	t.bound = bound
 	// iface may mutate t.bound (if bound is not an interface), so ensure that
 	// this is done before returning.
 	t.iface()
 }

 func (t *TypeParam) Underlying() Type {
 	return t.iface()
 }

 func (t *TypeParam) String() string { return TypeString(t, nil) }

 // ----------------------------------------------------------------------------
 // Implementation

 func (t *TypeParam) cleanup() {
 	t.iface()
 	t.check = nil
 }

 // iface returns the constraint interface of t.
 func (t *TypeParam) iface() *Interface {
 	bound := t.bound

 	// determine constraint interface
 	var ityp *Interface
 	switch u := under(bound).(type) {
 	case *Basic:
 		if !isValid(u) {
 			// error is reported elsewhere
 			return &emptyInterface
 		}
 	case *Interface:
 		if isTypeParam(bound) {
 			// error is reported in Checker.collectTypeParams
 			return &emptyInterface
 		}
 		ityp = u
 	}

 	// If we don't have an interface, wrap constraint into an implicit interface.
 	if ityp == nil {
 		ityp = NewInterfaceType(nil, []Type{bound})
 		ityp.implicit = true
 		t.bound = ityp // update t.bound for next time (optimization)
 	}

 	// compute type set if necessary
 	if ityp.tset == nil {
 		// pos is used for tracing output; start with the type parameter position.
 		pos := t.obj.pos
 		// use the (original or possibly instantiated) type bound position if we have one
 		if n := asNamed(bound); n != nil {
 			pos = n.obj.pos
 		}
 		computeInterfaceTypeSet(t.check, pos, ityp)
 	}

 	return ityp
 }

 // is calls f with the specific type terms of t's constraint and reports whether
 // all calls to f returned true. If there are no specific terms, is
 // returns the result of f(nil).
 func (t *TypeParam) is(f func(*term) bool) bool {
 	return t.iface().typeSet().is(f)
 }

 // underIs calls f with the underlying types of the specific type terms
 // of t's constraint and reports whether all calls to f returned true.
 // If there are no specific terms, underIs returns the result of f(nil).
 func (t *TypeParam) underIs(f func(Type) bool) bool {
 	return t.iface().typeSet().underIs(f)
 }
	// Copyright 2011 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 types2

	import "sync/atomic"

	// Note: This is a uint32 rather than a uint64 because the
	// respective 64 bit atomic instructions are not available
	// on all platforms.
	var lastID atomic.Uint32

	// nextID returns a value increasing monotonically by 1 with
	// each call, starting with 1. It may be called concurrently.
	func nextID() uint64 { return uint64(lastID.Add(1)) }

	// A TypeParam represents a type parameter type.
	type TypeParam struct {
	check *Checker // for lazy type bound completion
	id uint64 // unique id, for debugging only
	obj *TypeName // corresponding type name
	index int // type parameter index in source order, starting at 0
	bound Type // any type, but underlying is eventually *Interface for correct programs (see TypeParam.iface)
	}

	// NewTypeParam returns a new TypeParam. Type parameters may be set on a Named
	// or Signature type by calling SetTypeParams. Setting a type parameter on more
	// than one type will result in a panic.
	//
	// The constraint argument can be nil, and set later via SetConstraint. If the
	// constraint is non-nil, it must be fully defined.
	func NewTypeParam(obj TypeName, constraint Type) TypeParam {
	return (*Checker)(nil).newTypeParam(obj, constraint)
	}

	// check may be nil
	func (check Checker) newTypeParam(obj TypeName, constraint Type) *TypeParam {
	// Always increment lastID, even if it is not used.
	id := nextID()
	if check != nil {
	check.nextID++
	id = check.nextID
	}
	typ := &TypeParam{check: check, id: id, obj: obj, index: -1, bound: constraint}
	if obj.typ == nil {
	obj.typ = typ
	}
	// iface may mutate typ.bound, so we must ensure that iface() is called
	// at least once before the resulting TypeParam escapes.
	if check != nil {
	check.needsCleanup(typ)
	} else if constraint != nil {
	typ.iface()
	}
	return typ
	}

	// Obj returns the type name for the type parameter t.
	func (t TypeParam) Obj() TypeName { return t.obj }

	// Index returns the index of the type param within its param list, or -1 if
	// the type parameter has not yet been bound to a type.
	func (t *TypeParam) Index() int {
	return t.index
	}

	// Constraint returns the type constraint specified for t.
	func (t *TypeParam) Constraint() Type {
	return t.bound
	}

	// SetConstraint sets the type constraint for t.
	//
	// It must be called by users of NewTypeParam after the bound's underlying is
	// fully defined, and before using the type parameter in any way other than to
	// form other types. Once SetConstraint returns the receiver, t is safe for
	// concurrent use.
	func (t *TypeParam) SetConstraint(bound Type) {
	if bound == nil {
	panic("nil constraint")
	}
	t.bound = bound
	// iface may mutate t.bound (if bound is not an interface), so ensure that
	// this is done before returning.
	t.iface()
	}

	func (t *TypeParam) Underlying() Type {
	return t.iface()
	}

	func (t *TypeParam) String() string { return TypeString(t, nil) }

	// ----------------------------------------------------------------------------
	// Implementation

	func (t *TypeParam) cleanup() {
	t.iface()
	t.check = nil
	}

	// iface returns the constraint interface of t.
	func (t TypeParam) iface() Interface {
	bound := t.bound

	// determine constraint interface
	var ityp *Interface
	switch u := under(bound).(type) {
	case *Basic:
	if !isValid(u) {
	// error is reported elsewhere
	return &emptyInterface
	}
	case *Interface:
	if isTypeParam(bound) {
	// error is reported in Checker.collectTypeParams
	return &emptyInterface
	}
	ityp = u
	}

	// If we don't have an interface, wrap constraint into an implicit interface.
	if ityp == nil {
	ityp = NewInterfaceType(nil, []Type{bound})
	ityp.implicit = true
	t.bound = ityp // update t.bound for next time (optimization)
	}

	// compute type set if necessary
	if ityp.tset == nil {
	// pos is used for tracing output; start with the type parameter position.
	pos := t.obj.pos
	// use the (original or possibly instantiated) type bound position if we have one
	if n := asNamed(bound); n != nil {
	pos = n.obj.pos
	}
	computeInterfaceTypeSet(t.check, pos, ityp)
	}

	return ityp
	}

	// is calls f with the specific type terms of t's constraint and reports whether
	// all calls to f returned true. If there are no specific terms, is
	// returns the result of f(nil).
	func (t TypeParam) is(f func(term) bool) bool {
	return t.iface().typeSet().is(f)
	}

	// underIs calls f with the underlying types of the specific type terms
	// of t's constraint and reports whether all calls to f returned true.
	// If there are no specific terms, underIs returns the result of f(nil).
	func (t *TypeParam) underIs(f func(Type) bool) bool {
	return t.iface().typeSet().underIs(f)
	}