// Copyright 2021 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 typechecking of index/slice expressions. package types import ( "go/ast" "go/constant" "go/token" . "internal/types/errors" ) // If e is a valid function instantiation, indexExpr returns true. // In that case x represents the uninstantiated function value and // it is the caller's responsibility to instantiate the function. func (check *Checker) indexExpr(x *operand, e *indexedExpr) (isFuncInst bool) { check.exprOrType(x, e.x, true) // x may be generic switch x.mode { case invalid: check.use(e.indices...) return false case typexpr: // type instantiation x.mode = invalid // TODO(gri) here we re-evaluate e.X - try to avoid this x.typ = check.varType(e.orig) if isValid(x.typ) { x.mode = typexpr } return false case value: if sig, _ := under(x.typ).(*Signature); sig != nil && sig.TypeParams().Len() > 0 { // function instantiation return true } } // x should not be generic at this point, but be safe and check check.nonGeneric(nil, x) if x.mode == invalid { return false } // ordinary index expression valid := false length := int64(-1) // valid if >= 0 switch typ := under(x.typ).(type) { case *Basic: if isString(typ) { valid = true if x.mode == constant_ { length = int64(len(constant.StringVal(x.val))) } // an indexed string always yields a byte value // (not a constant) even if the string and the // index are constant x.mode = value x.typ = universeByte // use 'byte' name } case *Array: valid = true length = typ.len if x.mode != variable { x.mode = value } x.typ = typ.elem case *Pointer: if typ, _ := under(typ.base).(*Array); typ != nil { valid = true length = typ.len x.mode = variable x.typ = typ.elem } case *Slice: valid = true x.mode = variable x.typ = typ.elem case *Map: index := check.singleIndex(e) if index == nil { x.mode = invalid return false } var key operand check.expr(nil, &key, index) check.assignment(&key, typ.key, "map index") // ok to continue even if indexing failed - map element type is known x.mode = mapindex x.typ = typ.elem x.expr = e.orig return false case *Interface: if !isTypeParam(x.typ) { break } // TODO(gri) report detailed failure cause for better error messages var key, elem Type // key != nil: we must have all maps mode := variable // non-maps result mode // TODO(gri) factor out closure and use it for non-typeparam cases as well if underIs(x.typ, func(u Type) bool { l := int64(-1) // valid if >= 0 var k, e Type // k is only set for maps switch t := u.(type) { case *Basic: if isString(t) { e = universeByte mode = value } case *Array: l = t.len e = t.elem if x.mode != variable { mode = value } case *Pointer: if t, _ := under(t.base).(*Array); t != nil { l = t.len e = t.elem } case *Slice: e = t.elem case *Map: k = t.key e = t.elem } if e == nil { return false } if elem == nil { // first type length = l key, elem = k, e return true } // all map keys must be identical (incl. all nil) // (that is, we cannot mix maps with other types) if !Identical(key, k) { return false } // all element types must be identical if !Identical(elem, e) { return false } // track the minimal length for arrays, if any if l >= 0 && l < length { length = l } return true }) { // For maps, the index expression must be assignable to the map key type. if key != nil { index := check.singleIndex(e) if index == nil { x.mode = invalid return false } var k operand check.expr(nil, &k, index) check.assignment(&k, key, "map index") // ok to continue even if indexing failed - map element type is known x.mode = mapindex x.typ = elem x.expr = e.orig return false } // no maps valid = true x.mode = mode x.typ = elem } } if !valid { // types2 uses the position of '[' for the error check.errorf(x, NonIndexableOperand, invalidOp+"cannot index %s", x) check.use(e.indices...) x.mode = invalid return false } index := check.singleIndex(e) if index == nil { x.mode = invalid return false } // In pathological (invalid) cases (e.g.: type T1 [][[]T1{}[0][0]]T0) // the element type may be accessed before it's set. Make sure we have // a valid type. if x.typ == nil { x.typ = Typ[Invalid] } check.index(index, length) return false } func (check *Checker) sliceExpr(x *operand, e *ast.SliceExpr) { check.expr(nil, x, e.X) if x.mode == invalid { check.use(e.Low, e.High, e.Max) return } valid := false length := int64(-1) // valid if >= 0 switch u := coreString(x.typ).(type) { case nil: check.errorf(x, NonSliceableOperand, invalidOp+"cannot slice %s: %s has no core type", x, x.typ) x.mode = invalid return case *Basic: if isString(u) { if e.Slice3 { at := e.Max if at == nil { at = e // e.Index[2] should be present but be careful } check.error(at, InvalidSliceExpr, invalidOp+"3-index slice of string") x.mode = invalid return } valid = true if x.mode == constant_ { length = int64(len(constant.StringVal(x.val))) } // spec: "For untyped string operands the result // is a non-constant value of type string." if isUntyped(x.typ) { x.typ = Typ[String] } } case *Array: valid = true length = u.len if x.mode != variable { check.errorf(x, NonSliceableOperand, invalidOp+"cannot slice %s (value not addressable)", x) x.mode = invalid return } x.typ = &Slice{elem: u.elem} case *Pointer: if u, _ := under(u.base).(*Array); u != nil { valid = true length = u.len x.typ = &Slice{elem: u.elem} } case *Slice: valid = true // x.typ doesn't change } if !valid { check.errorf(x, NonSliceableOperand, invalidOp+"cannot slice %s", x) x.mode = invalid return } x.mode = value // spec: "Only the first index may be omitted; it defaults to 0." if e.Slice3 && (e.High == nil || e.Max == nil) { check.error(inNode(e, e.Rbrack), InvalidSyntaxTree, "2nd and 3rd index required in 3-index slice") x.mode = invalid return } // check indices var ind [3]int64 for i, expr := range []ast.Expr{e.Low, e.High, e.Max} { x := int64(-1) switch { case expr != nil: // The "capacity" is only known statically for strings, arrays, // and pointers to arrays, and it is the same as the length for // those types. max := int64(-1) if length >= 0 { max = length + 1 } if _, v := check.index(expr, max); v >= 0 { x = v } case i == 0: // default is 0 for the first index x = 0 case length >= 0: // default is length (== capacity) otherwise x = length } ind[i] = x } // constant indices must be in range // (check.index already checks that existing indices >= 0) L: for i, x := range ind[:len(ind)-1] { if x > 0 { for j, y := range ind[i+1:] { if y >= 0 && y < x { // The value y corresponds to the expression e.Index[i+1+j]. // Because y >= 0, it must have been set from the expression // when checking indices and thus e.Index[i+1+j] is not nil. at := []ast.Expr{e.Low, e.High, e.Max}[i+1+j] check.errorf(at, SwappedSliceIndices, "invalid slice indices: %d < %d", y, x) break L // only report one error, ok to continue } } } } } // singleIndex returns the (single) index from the index expression e. // If the index is missing, or if there are multiple indices, an error // is reported and the result is nil. func (check *Checker) singleIndex(expr *indexedExpr) ast.Expr { if len(expr.indices) == 0 { check.errorf(expr.orig, InvalidSyntaxTree, "index expression %v with 0 indices", expr) return nil } if len(expr.indices) > 1 { // TODO(rFindley) should this get a distinct error code? check.error(expr.indices[1], InvalidIndex, invalidOp+"more than one index") } return expr.indices[0] } // index checks an index expression for validity. // If max >= 0, it is the upper bound for index. // If the result typ is != Typ[Invalid], index is valid and typ is its (possibly named) integer type. // If the result val >= 0, index is valid and val is its constant int value. func (check *Checker) index(index ast.Expr, max int64) (typ Type, val int64) { typ = Typ[Invalid] val = -1 var x operand check.expr(nil, &x, index) if !check.isValidIndex(&x, InvalidIndex, "index", false) { return } if x.mode != constant_ { return x.typ, -1 } if x.val.Kind() == constant.Unknown { return } v, ok := constant.Int64Val(x.val) assert(ok) if max >= 0 && v >= max { check.errorf(&x, InvalidIndex, invalidArg+"index %s out of bounds [0:%d]", x.val.String(), max) return } // 0 <= v [ && v < max ] return x.typ, v } func (check *Checker) isValidIndex(x *operand, code Code, what string, allowNegative bool) bool { if x.mode == invalid { return false } // spec: "a constant index that is untyped is given type int" check.convertUntyped(x, Typ[Int]) if x.mode == invalid { return false } // spec: "the index x must be of integer type or an untyped constant" if !allInteger(x.typ) { check.errorf(x, code, invalidArg+"%s %s must be integer", what, x) return false } if x.mode == constant_ { // spec: "a constant index must be non-negative ..." if !allowNegative && constant.Sign(x.val) < 0 { check.errorf(x, code, invalidArg+"%s %s must not be negative", what, x) return false } // spec: "... and representable by a value of type int" if !representableConst(x.val, check, Typ[Int], &x.val) { check.errorf(x, code, invalidArg+"%s %s overflows int", what, x) return false } } return true } // indexedExpr wraps an ast.IndexExpr or ast.IndexListExpr. // // Orig holds the original ast.Expr from which this indexedExpr was derived. // // Note: indexedExpr (intentionally) does not wrap ast.Expr, as that leads to // accidental misuse such as encountered in golang/go#63933. // // TODO(rfindley): remove this helper, in favor of just having a helper // function that returns indices. type indexedExpr struct { orig ast.Expr // the wrapped expr, which may be distinct from the IndexListExpr below. x ast.Expr // expression lbrack token.Pos // position of "[" indices []ast.Expr // index expressions rbrack token.Pos // position of "]" } func (x *indexedExpr) Pos() token.Pos { return x.orig.Pos() } func unpackIndexedExpr(n ast.Node) *indexedExpr { switch e := n.(type) { case *ast.IndexExpr: return &indexedExpr{ orig: e, x: e.X, lbrack: e.Lbrack, indices: []ast.Expr{e.Index}, rbrack: e.Rbrack, } case *ast.IndexListExpr: return &indexedExpr{ orig: e, x: e.X, lbrack: e.Lbrack, indices: e.Indices, rbrack: e.Rbrack, } } return nil }