import (
"go/ast"
"go/token"
+ . "internal/types/errors"
)
// ----------------------------------------------------------------------------
// An Interface represents an interface type.
type Interface struct {
check *Checker // for error reporting; nil once type set is computed
- obj *TypeName // type name object defining this interface; or nil (for better error messages)
methods []*Func // ordered list of explicitly declared methods
embeddeds []Type // ordered list of explicitly embedded elements
embedPos *[]token.Pos // positions of embedded elements; or nil (for error messages) - use pointer to save space
+ implicit bool // interface is wrapper for type set literal (non-interface T, ~T, or A|B)
complete bool // indicates that obj, methods, and embeddeds are set and type set can be computed
tset *_TypeSet // type set described by this interface, computed lazily
}
// typeSet returns the type set for interface t.
-func (t *Interface) typeSet() *_TypeSet { return computeInterfaceTypeSet(t.check, token.NoPos, t) }
+func (t *Interface) typeSet() *_TypeSet { return computeInterfaceTypeSet(t.check, nopos, t) }
// emptyInterface represents the empty (completed) interface
var emptyInterface = Interface{complete: true, tset: &topTypeSet}
}
// set method receivers if necessary
- typ := new(Interface)
+ typ := (*Checker)(nil).newInterface()
for _, m := range methods {
if sig := m.typ.(*Signature); sig.recv == nil {
sig.recv = NewVar(m.pos, m.pkg, "", typ)
return typ
}
+// check may be nil
+func (check *Checker) newInterface() *Interface {
+ typ := &Interface{check: check}
+ if check != nil {
+ check.needsCleanup(typ)
+ }
+ return typ
+}
+
+// MarkImplicit marks the interface t as implicit, meaning this interface
+// corresponds to a constraint literal such as ~T or A|B without explicit
+// interface embedding. MarkImplicit should be called before any concurrent use
+// of implicit interfaces.
+func (t *Interface) MarkImplicit() {
+ t.implicit = true
+}
+
// NumExplicitMethods returns the number of explicitly declared methods of interface t.
func (t *Interface) NumExplicitMethods() int { return len(t.methods) }
// ExplicitMethod returns the i'th explicitly declared method of interface t for 0 <= i < t.NumExplicitMethods().
-// The methods are ordered by their unique Id.
+// The methods are ordered by their unique [Id].
func (t *Interface) ExplicitMethod(i int) *Func { return t.methods[i] }
// NumEmbeddeds returns the number of embedded types in interface t.
func (t *Interface) NumEmbeddeds() int { return len(t.embeddeds) }
-// Embedded returns the i'th embedded defined (*Named) type of interface t for 0 <= i < t.NumEmbeddeds().
+// Embedded returns the i'th embedded defined (*[Named]) type of interface t for 0 <= i < t.NumEmbeddeds().
// The result is nil if the i'th embedded type is not a defined type.
//
-// Deprecated: Use EmbeddedType which is not restricted to defined (*Named) types.
-func (t *Interface) Embedded(i int) *Named { tname, _ := t.embeddeds[i].(*Named); return tname }
+// Deprecated: Use [Interface.EmbeddedType] which is not restricted to defined (*[Named]) types.
+func (t *Interface) Embedded(i int) *Named { return asNamed(t.embeddeds[i]) }
// EmbeddedType returns the i'th embedded type of interface t for 0 <= i < t.NumEmbeddeds().
func (t *Interface) EmbeddedType(i int) Type { return t.embeddeds[i] }
func (t *Interface) Empty() bool { return t.typeSet().IsAll() }
// IsComparable reports whether each type in interface t's type set is comparable.
-func (t *Interface) IsComparable() bool { return t.typeSet().IsComparable() }
+func (t *Interface) IsComparable() bool { return t.typeSet().IsComparable(nil) }
+
+// IsMethodSet reports whether the interface t is fully described by its method
+// set.
+func (t *Interface) IsMethodSet() bool { return t.typeSet().IsMethodSet() }
-// IsConstraint reports whether interface t is not just a method set.
-func (t *Interface) IsConstraint() bool { return t.typeSet().IsConstraint() }
+// IsImplicit reports whether the interface t is a wrapper for a type set literal.
+func (t *Interface) IsImplicit() bool { return t.implicit }
// Complete computes the interface's type set. It must be called by users of
-// NewInterfaceType and NewInterface after the interface's embedded types are
+// [NewInterfaceType] and [NewInterface] after the interface's embedded types are
// fully defined and before using the interface type in any way other than to
// form other types. The interface must not contain duplicate methods or a
// panic occurs. Complete returns the receiver.
// ----------------------------------------------------------------------------
// Implementation
-func (check *Checker) interfaceType(ityp *Interface, iface *ast.InterfaceType, def *Named) {
- var tlist []ast.Expr
- var tname *ast.Ident // "type" name of first entry in a type list declaration
+func (t *Interface) cleanup() {
+ t.typeSet() // any interface that escapes type checking must be safe for concurrent use
+ t.check = nil
+ t.embedPos = nil
+}
+func (check *Checker) interfaceType(ityp *Interface, iface *ast.InterfaceType, def *TypeName) {
addEmbedded := func(pos token.Pos, typ Type) {
ityp.embeddeds = append(ityp.embeddeds, typ)
if ityp.embedPos == nil {
for _, f := range iface.Methods.List {
if len(f.Names) == 0 {
- // We have an embedded type; possibly a union of types.
- addEmbedded(f.Type.Pos(), parseUnion(check, flattenUnion(nil, f.Type)))
+ addEmbedded(f.Type.Pos(), parseUnion(check, f.Type))
continue
}
+ // f.Name != nil
- // We have a method with name f.Names[0], or a type
- // of a type list (name.Name == "type").
- // (The parser ensures that there's only one method
- // and we don't care if a constructed AST has more.)
+ // We have a method with name f.Names[0].
name := f.Names[0]
if name.Name == "_" {
- check.errorf(name, _BlankIfaceMethod, "invalid method name _")
+ check.error(name, BlankIfaceMethod, "methods must have a unique non-blank name")
continue // ignore
}
- // TODO(rfindley) Remove type list handling once the parser doesn't accept type lists anymore.
- if name.Name == "type" {
- // Report an error for the first type list per interface
- // if we don't allow type lists, but continue.
- if !allowTypeLists && tlist == nil {
- check.softErrorf(name, _Todo, "use generalized embedding syntax instead of a type list")
- }
- // For now, collect all type list entries as if it
- // were a single union, where each union element is
- // of the form ~T.
- // TODO(rfindley) remove once we disallow type lists
- op := new(ast.UnaryExpr)
- op.Op = token.TILDE
- op.X = f.Type
- tlist = append(tlist, op)
- // Report an error if we have multiple type lists in an
- // interface, but only if they are permitted in the first place.
- if allowTypeLists && tname != nil && tname != name {
- check.errorf(name, _Todo, "cannot have multiple type lists in an interface")
- }
- tname = name
- continue
- }
-
typ := check.typ(f.Type)
sig, _ := typ.(*Signature)
if sig == nil {
- if typ != Typ[Invalid] {
- check.invalidAST(f.Type, "%s is not a method signature", typ)
+ if isValid(typ) {
+ check.errorf(f.Type, InvalidSyntaxTree, "%s is not a method signature", typ)
}
continue // ignore
}
- // Always type-check method type parameters but complain if they are not enabled.
- // (This extra check is needed here because interface method signatures don't have
- // a receiver specification.)
+ // The go/parser doesn't accept method type parameters but an ast.FuncType may have them.
if sig.tparams != nil {
var at positioner = f.Type
if ftyp, _ := f.Type.(*ast.FuncType); ftyp != nil && ftyp.TypeParams != nil {
at = ftyp.TypeParams
}
- check.errorf(at, _Todo, "methods cannot have type parameters")
+ check.error(at, InvalidSyntaxTree, "methods cannot have type parameters")
}
// use named receiver type if available (for better error messages)
var recvTyp Type = ityp
if def != nil {
- recvTyp = def
+ if named := asNamed(def.typ); named != nil {
+ recvTyp = named
+ }
}
sig.recv = NewVar(name.Pos(), check.pkg, "", recvTyp)
ityp.methods = append(ityp.methods, m)
}
- // type constraints
- if tlist != nil {
- // TODO(rfindley): this differs from types2 due to the use of Pos() below,
- // which should actually be on the ~. Confirm that this position is correct.
- addEmbedded(tlist[0].Pos(), parseUnion(check, tlist))
- }
-
// All methods and embedded elements for this interface are collected;
// i.e., this interface may be used in a type set computation.
ityp.complete = true
sortMethods(ityp.methods)
// (don't sort embeddeds: they must correspond to *embedPos entries)
- // Compute type set with a non-nil *Checker as soon as possible
- // to report any errors. Subsequent uses of type sets will use
- // this computed type set and won't need to pass in a *Checker.
- //
- // Pin the checker to the interface type in the interim, in case the type set
- // must be used before delayed funcs are processed (see issue #48234).
- // TODO(rfindley): clean up use of *Checker with computeInterfaceTypeSet
- ityp.check = check
+ // Compute type set as soon as possible to report any errors.
+ // Subsequent uses of type sets will use this computed type
+ // set and won't need to pass in a *Checker.
check.later(func() {
computeInterfaceTypeSet(check, iface.Pos(), ityp)
- ityp.check = nil
- })
-}
-
-func flattenUnion(list []ast.Expr, x ast.Expr) []ast.Expr {
- if o, _ := x.(*ast.BinaryExpr); o != nil && o.Op == token.OR {
- list = flattenUnion(list, o.X)
- x = o.Y
- }
- return append(list, x)
+ }).describef(iface, "compute type set for %s", ityp)
}