// 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 initialization and assignment checks. package types2 import "cmd/compile/internal/syntax" // assignment reports whether x can be assigned to a variable of type T, // if necessary by attempting to convert untyped values to the appropriate // type. context describes the context in which the assignment takes place. // Use T == nil to indicate assignment to an untyped blank identifier. // x.mode is set to invalid if the assignment failed. func (check *Checker) assignment(x *operand, T Type, context string) { check.singleValue(x) switch x.mode { case invalid: return // error reported before case constant_, variable, mapindex, value, nilvalue, commaok, commaerr: // ok default: // we may get here because of other problems (issue #39634, crash 12) check.errorf(x, "cannot assign %s to %s in %s", x, T, context) return } if isUntyped(x.typ) { target := T // spec: "If an untyped constant is assigned to a variable of interface // type or the blank identifier, the constant is first converted to type // bool, rune, int, float64, complex128 or string respectively, depending // on whether the value is a boolean, rune, integer, floating-point, // complex, or string constant." if x.isNil() { if T == nil { check.errorf(x, "use of untyped nil in %s", context) x.mode = invalid return } } else if T == nil || IsInterface(T) { target = Default(x.typ) } newType, val, code := check.implicitTypeAndValue(x, target) if code != 0 { msg := check.sprintf("cannot use %s as %s value in %s", x, target, context) switch code { case _TruncatedFloat: msg += " (truncated)" case _NumericOverflow: msg += " (overflows)" } check.error(x, msg) x.mode = invalid return } if val != nil { x.val = val check.updateExprVal(x.expr, val) } if newType != x.typ { x.typ = newType check.updateExprType(x.expr, newType, false) } } // x.typ is typed // A generic (non-instantiated) function value cannot be assigned to a variable. if sig := asSignature(x.typ); sig != nil && sig.TParams().Len() > 0 { check.errorf(x, "cannot use generic function %s without instantiation in %s", x, context) } // spec: "If a left-hand side is the blank identifier, any typed or // non-constant value except for the predeclared identifier nil may // be assigned to it." if T == nil { return } reason := "" if ok, _ := x.assignableTo(check, T, &reason); !ok { if check.conf.CompilerErrorMessages { check.errorf(x, "incompatible type: cannot use %s as %s value", x, T) } else { if reason != "" { check.errorf(x, "cannot use %s as %s value in %s: %s", x, T, context, reason) } else { check.errorf(x, "cannot use %s as %s value in %s", x, T, context) } } x.mode = invalid } } func (check *Checker) initConst(lhs *Const, x *operand) { if x.mode == invalid || x.typ == Typ[Invalid] || lhs.typ == Typ[Invalid] { if lhs.typ == nil { lhs.typ = Typ[Invalid] } return } // rhs must be a constant if x.mode != constant_ { check.errorf(x, "%s is not constant", x) if lhs.typ == nil { lhs.typ = Typ[Invalid] } return } assert(isConstType(x.typ)) // If the lhs doesn't have a type yet, use the type of x. if lhs.typ == nil { lhs.typ = x.typ } check.assignment(x, lhs.typ, "constant declaration") if x.mode == invalid { return } lhs.val = x.val } func (check *Checker) initVar(lhs *Var, x *operand, context string) Type { if x.mode == invalid || x.typ == Typ[Invalid] || lhs.typ == Typ[Invalid] { if lhs.typ == nil { lhs.typ = Typ[Invalid] } // Note: This was reverted in go/types (https://golang.org/cl/292751). // TODO(gri): decide what to do (also affects test/run.go exclusion list) lhs.used = true // avoid follow-on "declared but not used" errors return nil } // If the lhs doesn't have a type yet, use the type of x. if lhs.typ == nil { typ := x.typ if isUntyped(typ) { // convert untyped types to default types if typ == Typ[UntypedNil] { check.errorf(x, "use of untyped nil in %s", context) lhs.typ = Typ[Invalid] return nil } typ = Default(typ) } lhs.typ = typ } check.assignment(x, lhs.typ, context) if x.mode == invalid { return nil } return x.typ } func (check *Checker) assignVar(lhs syntax.Expr, x *operand) Type { if x.mode == invalid || x.typ == Typ[Invalid] { check.useLHS(lhs) return nil } // Determine if the lhs is a (possibly parenthesized) identifier. ident, _ := unparen(lhs).(*syntax.Name) // Don't evaluate lhs if it is the blank identifier. if ident != nil && ident.Value == "_" { check.recordDef(ident, nil) check.assignment(x, nil, "assignment to _ identifier") if x.mode == invalid { return nil } return x.typ } // If the lhs is an identifier denoting a variable v, this assignment // is not a 'use' of v. Remember current value of v.used and restore // after evaluating the lhs via check.expr. var v *Var var v_used bool if ident != nil { if obj := check.lookup(ident.Value); obj != nil { // It's ok to mark non-local variables, but ignore variables // from other packages to avoid potential race conditions with // dot-imported variables. if w, _ := obj.(*Var); w != nil && w.pkg == check.pkg { v = w v_used = v.used } } } var z operand check.expr(&z, lhs) if v != nil { v.used = v_used // restore v.used } if z.mode == invalid || z.typ == Typ[Invalid] { return nil } // spec: "Each left-hand side operand must be addressable, a map index // expression, or the blank identifier. Operands may be parenthesized." switch z.mode { case invalid: return nil case variable, mapindex: // ok case nilvalue: check.error(&z, "cannot assign to nil") // default would print "untyped nil" return nil default: if sel, ok := z.expr.(*syntax.SelectorExpr); ok { var op operand check.expr(&op, sel.X) if op.mode == mapindex { check.errorf(&z, "cannot assign to struct field %s in map", syntax.String(z.expr)) return nil } } check.errorf(&z, "cannot assign to %s", &z) return nil } check.assignment(x, z.typ, "assignment") if x.mode == invalid { return nil } return x.typ } // If returnPos is valid, initVars is called to type-check the assignment of // return expressions, and returnPos is the position of the return statement. func (check *Checker) initVars(lhs []*Var, orig_rhs []syntax.Expr, returnPos syntax.Pos) { rhs, commaOk := check.exprList(orig_rhs, len(lhs) == 2 && !returnPos.IsKnown()) if len(lhs) != len(rhs) { // invalidate lhs for _, obj := range lhs { if obj.typ == nil { obj.typ = Typ[Invalid] } } // don't report an error if we already reported one for _, x := range rhs { if x.mode == invalid { return } } if returnPos.IsKnown() { check.errorf(returnPos, "wrong number of return values (want %d, got %d)", len(lhs), len(rhs)) return } check.errorf(rhs[0], "cannot initialize %d variables with %d values", len(lhs), len(rhs)) return } context := "assignment" if returnPos.IsKnown() { context = "return statement" } if commaOk { var a [2]Type for i := range a { a[i] = check.initVar(lhs[i], rhs[i], context) } check.recordCommaOkTypes(orig_rhs[0], a) return } for i, lhs := range lhs { check.initVar(lhs, rhs[i], context) } } func (check *Checker) assignVars(lhs, orig_rhs []syntax.Expr) { rhs, commaOk := check.exprList(orig_rhs, len(lhs) == 2) if len(lhs) != len(rhs) { check.useLHS(lhs...) // don't report an error if we already reported one for _, x := range rhs { if x.mode == invalid { return } } check.errorf(rhs[0], "cannot assign %d values to %d variables", len(rhs), len(lhs)) return } if commaOk { var a [2]Type for i := range a { a[i] = check.assignVar(lhs[i], rhs[i]) } check.recordCommaOkTypes(orig_rhs[0], a) return } for i, lhs := range lhs { check.assignVar(lhs, rhs[i]) } } // unpack unpacks a *syntax.ListExpr into a list of syntax.Expr. // Helper introduced for the go/types -> types2 port. // TODO(gri) Should find a more efficient solution that doesn't // require introduction of a new slice for simple // expressions. func unpackExpr(x syntax.Expr) []syntax.Expr { if x, _ := x.(*syntax.ListExpr); x != nil { return x.ElemList } if x != nil { return []syntax.Expr{x} } return nil } func (check *Checker) shortVarDecl(pos syntax.Pos, lhs, rhs []syntax.Expr) { top := len(check.delayed) scope := check.scope // collect lhs variables seen := make(map[string]bool, len(lhs)) lhsVars := make([]*Var, len(lhs)) newVars := make([]*Var, 0, len(lhs)) hasErr := false for i, lhs := range lhs { ident, _ := lhs.(*syntax.Name) if ident == nil { check.useLHS(lhs) check.errorf(lhs, "non-name %s on left side of :=", lhs) hasErr = true continue } name := ident.Value if name != "_" { if seen[name] { check.errorf(lhs, "%s repeated on left side of :=", lhs) hasErr = true continue } seen[name] = true } // Use the correct obj if the ident is redeclared. The // variable's scope starts after the declaration; so we // must use Scope.Lookup here and call Scope.Insert // (via check.declare) later. if alt := scope.Lookup(name); alt != nil { check.recordUse(ident, alt) // redeclared object must be a variable if obj, _ := alt.(*Var); obj != nil { lhsVars[i] = obj } else { check.errorf(lhs, "cannot assign to %s", lhs) hasErr = true } continue } // declare new variable obj := NewVar(ident.Pos(), check.pkg, name, nil) lhsVars[i] = obj if name != "_" { newVars = append(newVars, obj) } check.recordDef(ident, obj) } // create dummy variables where the lhs is invalid for i, obj := range lhsVars { if obj == nil { lhsVars[i] = NewVar(lhs[i].Pos(), check.pkg, "_", nil) } } check.initVars(lhsVars, rhs, nopos) // process function literals in rhs expressions before scope changes check.processDelayed(top) if len(newVars) == 0 && !hasErr { check.softErrorf(pos, "no new variables on left side of :=") return } // declare new variables // spec: "The scope of a constant or variable identifier declared inside // a function begins at the end of the ConstSpec or VarSpec (ShortVarDecl // for short variable declarations) and ends at the end of the innermost // containing block." scopePos := syntax.EndPos(rhs[len(rhs)-1]) for _, obj := range newVars { check.declare(scope, nil, obj, scopePos) // id = nil: recordDef already called } }