// 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 type-checking of identifiers and type expressions. package types2 import ( "cmd/compile/internal/syntax" "fmt" "go/constant" "strings" ) // ident type-checks identifier e and initializes x with the value or type of e. // If an error occurred, x.mode is set to invalid. // For the meaning of def, see Checker.definedType, below. // If wantType is set, the identifier e is expected to denote a type. // func (check *Checker) ident(x *operand, e *syntax.Name, def *Named, wantType bool) { x.mode = invalid x.expr = e // Note that we cannot use check.lookup here because the returned scope // may be different from obj.Parent(). See also Scope.LookupParent doc. scope, obj := check.scope.LookupParent(e.Value, check.pos) switch obj { case nil: if e.Value == "_" { // Blank identifiers are never declared, but the current identifier may // be a placeholder for a receiver type parameter. In this case we can // resolve its type and object from Checker.recvTParamMap. if tpar := check.recvTParamMap[e]; tpar != nil { x.mode = typexpr x.typ = tpar } else { check.error(e, "cannot use _ as value or type") } } else { if check.conf.CompilerErrorMessages { check.errorf(e, "undefined: %s", e.Value) } else { check.errorf(e, "undeclared name: %s", e.Value) } } return case universeAny, universeComparable: if !check.allowVersion(check.pkg, 1, 18) { check.errorf(e, "undeclared name: %s (requires version go1.18 or later)", e.Value) return // avoid follow-on errors } } check.recordUse(e, obj) // Type-check the object. // Only call Checker.objDecl if the object doesn't have a type yet // (in which case we must actually determine it) or the object is a // TypeName and we also want a type (in which case we might detect // a cycle which needs to be reported). Otherwise we can skip the // call and avoid a possible cycle error in favor of the more // informative "not a type/value" error that this function's caller // will issue (see issue #25790). typ := obj.Type() if _, gotType := obj.(*TypeName); typ == nil || gotType && wantType { check.objDecl(obj, def) typ = obj.Type() // type must have been assigned by Checker.objDecl } assert(typ != nil) // The object may have been dot-imported. // If so, mark the respective package as used. // (This code is only needed for dot-imports. Without them, // we only have to mark variables, see *Var case below). if pkgName := check.dotImportMap[dotImportKey{scope, obj.Name()}]; pkgName != nil { pkgName.used = true } switch obj := obj.(type) { case *PkgName: check.errorf(e, "use of package %s not in selector", obj.name) return case *Const: check.addDeclDep(obj) if typ == Typ[Invalid] { return } if obj == universeIota { if check.iota == nil { check.error(e, "cannot use iota outside constant declaration") return } x.val = check.iota } else { x.val = obj.val } assert(x.val != nil) x.mode = constant_ case *TypeName: if check.isBrokenAlias(obj) { check.errorf(e, "invalid use of type alias %s in recursive type (see issue #50729)", obj.name) return } x.mode = typexpr case *Var: // It's ok to mark non-local variables, but ignore variables // from other packages to avoid potential race conditions with // dot-imported variables. if obj.pkg == check.pkg { obj.used = true } check.addDeclDep(obj) if typ == Typ[Invalid] { return } x.mode = variable case *Func: check.addDeclDep(obj) x.mode = value case *Builtin: x.id = obj.id x.mode = builtin case *Nil: x.mode = nilvalue default: unreachable() } x.typ = typ } // typ type-checks the type expression e and returns its type, or Typ[Invalid]. // The type must not be an (uninstantiated) generic type. func (check *Checker) typ(e syntax.Expr) Type { return check.definedType(e, nil) } // varType type-checks the type expression e and returns its type, or Typ[Invalid]. // The type must not be an (uninstantiated) generic type and it must not be a // constraint interface. func (check *Checker) varType(e syntax.Expr) Type { typ := check.definedType(e, nil) check.validVarType(e, typ) return typ } // validVarType reports an error if typ is a constraint interface. // The expression e is used for error reporting, if any. func (check *Checker) validVarType(e syntax.Expr, typ Type) { // If we have a type parameter there's nothing to do. if isTypeParam(typ) { return } // We don't want to call under() or complete interfaces while we are in // the middle of type-checking parameter declarations that might belong // to interface methods. Delay this check to the end of type-checking. check.later(func() { if t, _ := under(typ).(*Interface); t != nil { pos := syntax.StartPos(e) tset := computeInterfaceTypeSet(check, pos, t) // TODO(gri) is this the correct position? if !tset.IsMethodSet() { if tset.comparable { check.softErrorf(pos, "interface is (or embeds) comparable") } else { check.softErrorf(pos, "interface contains type constraints") } } } }) } // definedType is like typ but also accepts a type name def. // If def != nil, e is the type specification for the defined type def, declared // in a type declaration, and def.underlying will be set to the type of e before // any components of e are type-checked. // func (check *Checker) definedType(e syntax.Expr, def *Named) Type { typ := check.typInternal(e, def) assert(isTyped(typ)) if isGeneric(typ) { check.errorf(e, "cannot use generic type %s without instantiation", typ) typ = Typ[Invalid] } check.recordTypeAndValue(e, typexpr, typ, nil) return typ } // genericType is like typ but the type must be an (uninstantiated) generic type. func (check *Checker) genericType(e syntax.Expr, reportErr bool) Type { typ := check.typInternal(e, nil) assert(isTyped(typ)) if typ != Typ[Invalid] && !isGeneric(typ) { if reportErr { check.errorf(e, "%s is not a generic type", typ) } typ = Typ[Invalid] } // TODO(gri) what is the correct call below? check.recordTypeAndValue(e, typexpr, typ, nil) return typ } // goTypeName returns the Go type name for typ and // removes any occurrences of "types2." from that name. func goTypeName(typ Type) string { return strings.Replace(fmt.Sprintf("%T", typ), "types2.", "", -1) // strings.ReplaceAll is not available in Go 1.4 } // typInternal drives type checking of types. // Must only be called by definedType or genericType. // func (check *Checker) typInternal(e0 syntax.Expr, def *Named) (T Type) { if check.conf.Trace { check.trace(e0.Pos(), "-- type %s", e0) check.indent++ defer func() { check.indent-- var under Type if T != nil { // Calling under() here may lead to endless instantiations. // Test case: type T[P any] *T[P] under = safeUnderlying(T) } if T == under { check.trace(e0.Pos(), "=> %s // %s", T, goTypeName(T)) } else { check.trace(e0.Pos(), "=> %s (under = %s) // %s", T, under, goTypeName(T)) } }() } switch e := e0.(type) { case *syntax.BadExpr: // ignore - error reported before case *syntax.Name: var x operand check.ident(&x, e, def, true) switch x.mode { case typexpr: typ := x.typ def.setUnderlying(typ) return typ case invalid: // ignore - error reported before case novalue: check.errorf(&x, "%s used as type", &x) default: check.errorf(&x, "%s is not a type", &x) } case *syntax.SelectorExpr: var x operand check.selector(&x, e, def) switch x.mode { case typexpr: typ := x.typ def.setUnderlying(typ) return typ case invalid: // ignore - error reported before case novalue: check.errorf(&x, "%s used as type", &x) default: check.errorf(&x, "%s is not a type", &x) } case *syntax.IndexExpr: if !check.allowVersion(check.pkg, 1, 18) { check.versionErrorf(e.Pos(), "go1.18", "type instantiation") } return check.instantiatedType(e.X, unpackExpr(e.Index), def) case *syntax.ParenExpr: // Generic types must be instantiated before they can be used in any form. // Consequently, generic types cannot be parenthesized. return check.definedType(e.X, def) case *syntax.ArrayType: typ := new(Array) def.setUnderlying(typ) if e.Len != nil { typ.len = check.arrayLength(e.Len) } else { // [...]array check.error(e, "invalid use of [...] array (outside a composite literal)") typ.len = -1 } typ.elem = check.varType(e.Elem) if typ.len >= 0 { return typ } // report error if we encountered [...] case *syntax.SliceType: typ := new(Slice) def.setUnderlying(typ) typ.elem = check.varType(e.Elem) return typ case *syntax.DotsType: // dots are handled explicitly where they are legal // (array composite literals and parameter lists) check.error(e, "invalid use of '...'") check.use(e.Elem) case *syntax.StructType: typ := new(Struct) def.setUnderlying(typ) check.structType(typ, e) return typ case *syntax.Operation: if e.Op == syntax.Mul && e.Y == nil { typ := new(Pointer) typ.base = Typ[Invalid] // avoid nil base in invalid recursive type declaration def.setUnderlying(typ) typ.base = check.varType(e.X) // If typ.base is invalid, it's unlikely that *base is particularly // useful - even a valid dereferenciation will lead to an invalid // type again, and in some cases we get unexpected follow-on errors // (e.g., see #49005). Return an invalid type instead. if typ.base == Typ[Invalid] { return Typ[Invalid] } return typ } check.errorf(e0, "%s is not a type", e0) check.use(e0) case *syntax.FuncType: typ := new(Signature) def.setUnderlying(typ) check.funcType(typ, nil, nil, e) return typ case *syntax.InterfaceType: typ := check.newInterface() def.setUnderlying(typ) if def != nil { typ.obj = def.obj } check.interfaceType(typ, e, def) return typ case *syntax.MapType: typ := new(Map) def.setUnderlying(typ) typ.key = check.varType(e.Key) typ.elem = check.varType(e.Value) // spec: "The comparison operators == and != must be fully defined // for operands of the key type; thus the key type must not be a // function, map, or slice." // // Delay this check because it requires fully setup types; // it is safe to continue in any case (was issue 6667). check.later(func() { if !Comparable(typ.key) { var why string if isTypeParam(typ.key) { why = " (missing comparable constraint)" } check.errorf(e.Key, "invalid map key type %s%s", typ.key, why) } }) return typ case *syntax.ChanType: typ := new(Chan) def.setUnderlying(typ) dir := SendRecv switch e.Dir { case 0: // nothing to do case syntax.SendOnly: dir = SendOnly case syntax.RecvOnly: dir = RecvOnly default: check.errorf(e, invalidAST+"unknown channel direction %d", e.Dir) // ok to continue } typ.dir = dir typ.elem = check.varType(e.Elem) return typ default: check.errorf(e0, "%s is not a type", e0) check.use(e0) } typ := Typ[Invalid] def.setUnderlying(typ) return typ } func (check *Checker) instantiatedType(x syntax.Expr, xlist []syntax.Expr, def *Named) (res Type) { if check.conf.Trace { check.trace(x.Pos(), "-- instantiating %s with %s", x, xlist) check.indent++ defer func() { check.indent-- // Don't format the underlying here. It will always be nil. check.trace(x.Pos(), "=> %s", res) }() } gtyp := check.genericType(x, true) if gtyp == Typ[Invalid] { return gtyp // error already reported } orig, _ := gtyp.(*Named) if orig == nil { panic(fmt.Sprintf("%v: cannot instantiate %v", x.Pos(), gtyp)) } // evaluate arguments targs := check.typeList(xlist) if targs == nil { def.setUnderlying(Typ[Invalid]) // avoid errors later due to lazy instantiation return Typ[Invalid] } // enableTypeTypeInference controls whether to infer missing type arguments // using constraint type inference. See issue #51527. const enableTypeTypeInference = false // create the instance ctxt := check.bestContext(nil) h := ctxt.instanceHash(orig, targs) // targs may be incomplete, and require inference. In any case we should de-duplicate. inst, _ := ctxt.lookup(h, orig, targs).(*Named) // If inst is non-nil, we can't just return here. Inst may have been // constructed via recursive substitution, in which case we wouldn't do the // validation below. Ensure that the validation (and resulting errors) runs // for each instantiated type in the source. if inst == nil { // x may be a selector for an imported type; use its start pos rather than x.Pos(). tname := NewTypeName(syntax.StartPos(x), orig.obj.pkg, orig.obj.name, nil) inst = check.newNamed(tname, orig, nil, nil, nil) // underlying, methods and tparams are set when named is resolved inst.targs = newTypeList(targs) inst = ctxt.update(h, orig, targs, inst).(*Named) } def.setUnderlying(inst) inst.resolver = func(ctxt *Context, n *Named) (*TypeParamList, Type, *methodList) { tparams := n.orig.TypeParams().list() targs := n.targs.list() if enableTypeTypeInference && len(targs) < len(tparams) { // If inference fails, len(inferred) will be 0, and inst.underlying will // be set to Typ[Invalid] in expandNamed. inferred := check.infer(x.Pos(), tparams, targs, nil, nil) if len(inferred) > len(targs) { n.targs = newTypeList(inferred) } } return expandNamed(ctxt, n, x.Pos()) } // orig.tparams may not be set up, so we need to do expansion later. check.later(func() { // This is an instance from the source, not from recursive substitution, // and so it must be resolved during type-checking so that we can report // errors. inst.resolve(ctxt) // Since check is non-nil, we can still mutate inst. Unpinning the resolver // frees some memory. inst.resolver = nil check.recordInstance(x, inst.TypeArgs().list(), inst) if check.validateTArgLen(x.Pos(), inst.tparams.Len(), inst.targs.Len()) { if i, err := check.verify(x.Pos(), inst.tparams.list(), inst.targs.list()); err != nil { // best position for error reporting pos := x.Pos() if i < len(xlist) { pos = syntax.StartPos(xlist[i]) } check.softErrorf(pos, "%s", err) } else { check.mono.recordInstance(check.pkg, x.Pos(), inst.tparams.list(), inst.targs.list(), xlist) } } check.validType(inst) }) return inst } // arrayLength type-checks the array length expression e // and returns the constant length >= 0, or a value < 0 // to indicate an error (and thus an unknown length). func (check *Checker) arrayLength(e syntax.Expr) int64 { // If e is an identifier, the array declaration might be an // attempt at a parameterized type declaration with missing // constraint. Provide an error message that mentions array // length. if name, _ := e.(*syntax.Name); name != nil { obj := check.lookup(name.Value) if obj == nil { check.errorf(name, "undeclared name %s for array length", name.Value) return -1 } if _, ok := obj.(*Const); !ok { check.errorf(name, "invalid array length %s", name.Value) return -1 } } var x operand check.expr(&x, e) if x.mode != constant_ { if x.mode != invalid { check.errorf(&x, "array length %s must be constant", &x) } return -1 } if isUntyped(x.typ) || isInteger(x.typ) { if val := constant.ToInt(x.val); val.Kind() == constant.Int { if representableConst(val, check, Typ[Int], nil) { if n, ok := constant.Int64Val(val); ok && n >= 0 { return n } check.errorf(&x, "invalid array length %s", &x) return -1 } } } check.errorf(&x, "array length %s must be integer", &x) return -1 } // typeList provides the list of types corresponding to the incoming expression list. // If an error occurred, the result is nil, but all list elements were type-checked. func (check *Checker) typeList(list []syntax.Expr) []Type { res := make([]Type, len(list)) // res != nil even if len(list) == 0 for i, x := range list { t := check.varType(x) if t == Typ[Invalid] { res = nil } if res != nil { res[i] = t } } return res }