// Code generated by "go test -run=Generate -write=all"; DO NOT EDIT. // Source: ../../cmd/compile/internal/types2/typeparam.go // 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 types 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 the type of a type parameter in a generic declaration. // // A TypeParam has a name; use the [TypeParam.Obj] method to access // its [TypeName] object. 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 // 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() } // Underlying returns the [underlying type] of the type parameter t, which is // the underlying type of its constraint. This type is always an interface. // // [underlying type]: https://go.dev/ref/spec#Underlying_types. 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) } // typeset is an iterator over the (type/underlying type) pairs of the // specific type terms of t's constraint. // If there are no specific terms, typeset calls yield with (nil, nil). // In any case, typeset is guaranteed to call yield at least once. func (t *TypeParam) typeset(yield func(t, u Type) bool) { t.iface().typeSet().typeset(yield) }