src/cmd/compile/internal/types2/assignments.go - go - Git at Google

 // 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"
 	"fmt"
 	. "internal/types/errors"
 	"strings"
 )

 // 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.
 // If the assignment check fails, x.mode is set to invalid.
 func (check *Checker) assignment(x *operand, T Type, context string) {
 	check.singleValue(x)

 	switch x.mode {
 	case invalid:
 		return // error reported before
 	case nilvalue:
 		assert(isTypes2)
 		// ok
 	case constant_, variable, mapindex, value, commaok, commaerr:
 		// ok
 	default:
 		// we may get here because of other problems (go.dev/issue/39634, crash 12)
 		// TODO(gri) do we need a new "generic" error code here?
 		check.errorf(x, IncompatibleAssign, "cannot assign %s to %s in %s", x, T, context)
 		x.mode = invalid
 		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 isTypes2 {
 			if x.isNil() {
 				if T == nil {
 					check.errorf(x, UntypedNilUse, "use of untyped nil in %s", context)
 					x.mode = invalid
 					return
 				}
 			} else if T == nil || isNonTypeParamInterface(T) {
 				target = Default(x.typ)
 			}
 		} else { // go/types
 			if T == nil || isNonTypeParamInterface(T) {
 				if T == nil && x.typ == Typ[UntypedNil] {
 					check.errorf(x, UntypedNilUse, "use of untyped nil in %s", context)
 					x.mode = invalid
 					return
 				}
 				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)"
 			default:
 				code = IncompatibleAssign
 			}
 			check.error(x, code, 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, _ := under(x.typ).(*Signature); sig != nil && sig.TypeParams().Len() > 0 {
 		check.errorf(x, WrongTypeArgCount, "cannot use generic function %s without instantiation in %s", x, context)
 		x.mode = invalid
 		return
 	}

 	// 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
 	}

 	cause := ""
 	if ok, code := x.assignableTo(check, T, &cause); !ok {
 		if cause != "" {
 			check.errorf(x, code, "cannot use %s as %s value in %s: %s", x, T, context, cause)
 		} else {
 			check.errorf(x, code, "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 || !isValid(x.typ) || !isValid(lhs.typ) {
 		if lhs.typ == nil {
 			lhs.typ = Typ[Invalid]
 		}
 		return
 	}

 	// rhs must be a constant
 	if x.mode != constant_ {
 		check.errorf(x, InvalidConstInit, "%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
 }

 // initVar checks the initialization lhs = x in a variable declaration.
 // If lhs doesn't have a type yet, it is given the type of x,
 // or Typ[Invalid] in case of an error.
 // If the initialization check fails, x.mode is set to invalid.
 func (check *Checker) initVar(lhs *Var, x *operand, context string) {
 	if x.mode == invalid || !isValid(x.typ) || !isValid(lhs.typ) {
 		if lhs.typ == nil {
 			lhs.typ = Typ[Invalid]
 		}
 		x.mode = invalid
 		return
 	}

 	// If 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, UntypedNilUse, "use of untyped nil in %s", context)
 				lhs.typ = Typ[Invalid]
 				x.mode = invalid
 				return
 			}
 			typ = Default(typ)
 		}
 		lhs.typ = typ
 	}

 	check.assignment(x, lhs.typ, context)
 }

 // lhsVar checks a lhs variable in an assignment and returns its type.
 // lhsVar takes care of not counting a lhs identifier as a "use" of
 // that identifier. The result is nil if it is the blank identifier,
 // and Typ[Invalid] if it is an invalid lhs expression.
 func (check *Checker) lhsVar(lhs syntax.Expr) Type {
 	// Determine if the lhs is a (possibly parenthesized) identifier.
 	ident, _ := syntax.Unparen(lhs).(*syntax.Name)

 	// Don't evaluate lhs if it is the blank identifier.
 	if ident != nil && ident.Value == "_" {
 		check.recordDef(ident, nil)
 		return nil
 	}

 	// If the lhs is an identifier denoting a variable v, this reference
 	// 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 x operand
 	check.expr(nil, &x, lhs)

 	if v != nil {
 		v.used = v_used // restore v.used
 	}

 	if x.mode == invalid || !isValid(x.typ) {
 		return Typ[Invalid]
 	}

 	// spec: "Each left-hand side operand must be addressable, a map index
 	// expression, or the blank identifier. Operands may be parenthesized."
 	switch x.mode {
 	case invalid:
 		return Typ[Invalid]
 	case variable, mapindex:
 		// ok
 	default:
 		if sel, ok := x.expr.(*syntax.SelectorExpr); ok {
 			var op operand
 			check.expr(nil, &op, sel.X)
 			if op.mode == mapindex {
 				check.errorf(&x, UnaddressableFieldAssign, "cannot assign to struct field %s in map", ExprString(x.expr))
 				return Typ[Invalid]
 			}
 		}
 		check.errorf(&x, UnassignableOperand, "cannot assign to %s (neither addressable nor a map index expression)", x.expr)
 		return Typ[Invalid]
 	}

 	return x.typ
 }

 // assignVar checks the assignment lhs = rhs (if x == nil), or lhs = x (if x != nil).
 // If x != nil, it must be the evaluation of rhs (and rhs will be ignored).
 // If the assignment check fails and x != nil, x.mode is set to invalid.
 func (check *Checker) assignVar(lhs, rhs syntax.Expr, x *operand, context string) {
 	T := check.lhsVar(lhs) // nil if lhs is _
 	if !isValid(T) {
 		if x != nil {
 			x.mode = invalid
 		} else {
 			check.use(rhs)
 		}
 		return
 	}

 	if x == nil {
 		var target *target
 		// avoid calling ExprString if not needed
 		if T != nil {
 			if _, ok := under(T).(*Signature); ok {
 				target = newTarget(T, ExprString(lhs))
 			}
 		}
 		x = new(operand)
 		check.expr(target, x, rhs)
 	}

 	if T == nil && context == "assignment" {
 		context = "assignment to _ identifier"
 	}
 	check.assignment(x, T, context)
 }

 // operandTypes returns the list of types for the given operands.
 func operandTypes(list []*operand) (res []Type) {
 	for _, x := range list {
 		res = append(res, x.typ)
 	}
 	return res
 }

 // varTypes returns the list of types for the given variables.
 func varTypes(list []*Var) (res []Type) {
 	for _, x := range list {
 		res = append(res, x.typ)
 	}
 	return res
 }

 // typesSummary returns a string of the form "(t1, t2, ...)" where the
 // ti's are user-friendly string representations for the given types.
 // If variadic is set and the last type is a slice, its string is of
 // the form "...E" where E is the slice's element type.
 func (check *Checker) typesSummary(list []Type, variadic bool) string {
 	var res []string
 	for i, t := range list {
 		var s string
 		switch {
 		case t == nil:
 			fallthrough // should not happen but be cautious
 		case !isValid(t):
 			s = "unknown type"
 		case isUntyped(t):
 			if isNumeric(t) {
 				// Do not imply a specific type requirement:
 				// "have number, want float64" is better than
 				// "have untyped int, want float64" or
 				// "have int, want float64".
 				s = "number"
 			} else {
 				// If we don't have a number, omit the "untyped" qualifier
 				// for compactness.
 				s = strings.Replace(t.(*Basic).name, "untyped ", "", -1)
 			}
 		case variadic && i == len(list)-1:
 			s = check.sprintf("...%s", t.(*Slice).elem)
 		}
 		if s == "" {
 			s = check.sprintf("%s", t)
 		}
 		res = append(res, s)
 	}
 	return "(" + strings.Join(res, ", ") + ")"
 }

 func measure(x int, unit string) string {
 	if x != 1 {
 		unit += "s"
 	}
 	return fmt.Sprintf("%d %s", x, unit)
 }

 func (check *Checker) assignError(rhs []syntax.Expr, l, r int) {
 	vars := measure(l, "variable")
 	vals := measure(r, "value")
 	rhs0 := rhs[0]

 	if len(rhs) == 1 {
 		if call, _ := syntax.Unparen(rhs0).(*syntax.CallExpr); call != nil {
 			check.errorf(rhs0, WrongAssignCount, "assignment mismatch: %s but %s returns %s", vars, call.Fun, vals)
 			return
 		}
 	}
 	check.errorf(rhs0, WrongAssignCount, "assignment mismatch: %s but %s", vars, vals)
 }

 func (check *Checker) returnError(at poser, lhs []*Var, rhs []*operand) {
 	l, r := len(lhs), len(rhs)
 	qualifier := "not enough"
 	if r > l {
 		at = rhs[l] // report at first extra value
 		qualifier = "too many"
 	} else if r > 0 {
 		at = rhs[r-1] // report at last value
 	}
 	err := check.newError(WrongResultCount)
 	err.addf(at, "%s return values", qualifier)
 	err.addf(nopos, "have %s", check.typesSummary(operandTypes(rhs), false))
 	err.addf(nopos, "want %s", check.typesSummary(varTypes(lhs), false))
 	err.report()
 }

 // initVars type-checks assignments of initialization expressions orig_rhs
 // to variables lhs.
 // If returnStmt is non-nil, initVars type-checks the implicit assignment
 // of result expressions orig_rhs to function result parameters lhs.
 func (check *Checker) initVars(lhs []*Var, orig_rhs []syntax.Expr, returnStmt syntax.Stmt) {
 	context := "assignment"
 	if returnStmt != nil {
 		context = "return statement"
 	}

 	l, r := len(lhs), len(orig_rhs)

 	// If l == 1 and the rhs is a single call, for a better
 	// error message don't handle it as n:n mapping below.
 	isCall := false
 	if r == 1 {
 		_, isCall = syntax.Unparen(orig_rhs[0]).(*syntax.CallExpr)
 	}

 	// If we have a n:n mapping from lhs variable to rhs expression,
 	// each value can be assigned to its corresponding variable.
 	if l == r && !isCall {
 		var x operand
 		for i, lhs := range lhs {
 			desc := lhs.name
 			if returnStmt != nil && desc == "" {
 				desc = "result variable"
 			}
 			check.expr(newTarget(lhs.typ, desc), &x, orig_rhs[i])
 			check.initVar(lhs, &x, context)
 		}
 		return
 	}

 	// If we don't have an n:n mapping, the rhs must be a single expression
 	// resulting in 2 or more values; otherwise we have an assignment mismatch.
 	if r != 1 {
 		// Only report a mismatch error if there are no other errors on the rhs.
 		if check.use(orig_rhs...) {
 			if returnStmt != nil {
 				rhs := check.exprList(orig_rhs)
 				check.returnError(returnStmt, lhs, rhs)
 			} else {
 				check.assignError(orig_rhs, l, r)
 			}
 		}
 		// ensure that LHS variables have a type
 		for _, v := range lhs {
 			if v.typ == nil {
 				v.typ = Typ[Invalid]
 			}
 		}
 		return
 	}

 	rhs, commaOk := check.multiExpr(orig_rhs[0], l == 2 && returnStmt == nil)
 	r = len(rhs)
 	if l == r {
 		for i, lhs := range lhs {
 			check.initVar(lhs, rhs[i], context)
 		}
 		// Only record comma-ok expression if both initializations succeeded
 		// (go.dev/issue/59371).
 		if commaOk && rhs[0].mode != invalid && rhs[1].mode != invalid {
 			check.recordCommaOkTypes(orig_rhs[0], rhs)
 		}
 		return
 	}

 	// In all other cases we have an assignment mismatch.
 	// Only report a mismatch error if there are no other errors on the rhs.
 	if rhs[0].mode != invalid {
 		if returnStmt != nil {
 			check.returnError(returnStmt, lhs, rhs)
 		} else {
 			check.assignError(orig_rhs, l, r)
 		}
 	}
 	// ensure that LHS variables have a type
 	for _, v := range lhs {
 		if v.typ == nil {
 			v.typ = Typ[Invalid]
 		}
 	}
 	// orig_rhs[0] was already evaluated
 }

 // assignVars type-checks assignments of expressions orig_rhs to variables lhs.
 func (check *Checker) assignVars(lhs, orig_rhs []syntax.Expr) {
 	l, r := len(lhs), len(orig_rhs)

 	// If l == 1 and the rhs is a single call, for a better
 	// error message don't handle it as n:n mapping below.
 	isCall := false
 	if r == 1 {
 		_, isCall = syntax.Unparen(orig_rhs[0]).(*syntax.CallExpr)
 	}

 	// If we have a n:n mapping from lhs variable to rhs expression,
 	// each value can be assigned to its corresponding variable.
 	if l == r && !isCall {
 		for i, lhs := range lhs {
 			check.assignVar(lhs, orig_rhs[i], nil, "assignment")
 		}
 		return
 	}

 	// If we don't have an n:n mapping, the rhs must be a single expression
 	// resulting in 2 or more values; otherwise we have an assignment mismatch.
 	if r != 1 {
 		// Only report a mismatch error if there are no other errors on the lhs or rhs.
 		okLHS := check.useLHS(lhs...)
 		okRHS := check.use(orig_rhs...)
 		if okLHS && okRHS {
 			check.assignError(orig_rhs, l, r)
 		}
 		return
 	}

 	rhs, commaOk := check.multiExpr(orig_rhs[0], l == 2)
 	r = len(rhs)
 	if l == r {
 		for i, lhs := range lhs {
 			check.assignVar(lhs, nil, rhs[i], "assignment")
 		}
 		// Only record comma-ok expression if both assignments succeeded
 		// (go.dev/issue/59371).
 		if commaOk && rhs[0].mode != invalid && rhs[1].mode != invalid {
 			check.recordCommaOkTypes(orig_rhs[0], rhs)
 		}
 		return
 	}

 	// In all other cases we have an assignment mismatch.
 	// Only report a mismatch error if there are no other errors on the rhs.
 	if rhs[0].mode != invalid {
 		check.assignError(orig_rhs, l, r)
 	}
 	check.useLHS(lhs...)
 	// orig_rhs[0] was already evaluated
 }

 func (check *Checker) shortVarDecl(pos poser, 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)
 			// TODO(gri) This is redundant with a go/parser error. Consider omitting in go/types?
 			check.errorf(lhs, BadDecl, "non-name %s on left side of :=", lhs)
 			hasErr = true
 			continue
 		}

 		name := ident.Value
 		if name != "_" {
 			if seen[name] {
 				check.errorf(lhs, RepeatedDecl, "%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, UnassignableOperand, "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, nil)

 	// process function literals in rhs expressions before scope changes
 	check.processDelayed(top)

 	if len(newVars) == 0 && !hasErr {
 		check.softErrorf(pos, NoNewVar, "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 := endPos(rhs[len(rhs)-1])
 	for _, obj := range newVars {
 		check.declare(scope, nil, obj, scopePos) // id = nil: recordDef already called
 	}
 }
	// 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"
	"fmt"
	. "internal/types/errors"
	"strings"
	)

	// 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.
	// If the assignment check fails, x.mode is set to invalid.
	func (check Checker) assignment(x operand, T Type, context string) {
	check.singleValue(x)

	switch x.mode {
	case invalid:
	return // error reported before
	case nilvalue:
	assert(isTypes2)
	// ok
	case constant_, variable, mapindex, value, commaok, commaerr:
	// ok
	default:
	// we may get here because of other problems (go.dev/issue/39634, crash 12)
	// TODO(gri) do we need a new "generic" error code here?
	check.errorf(x, IncompatibleAssign, "cannot assign %s to %s in %s", x, T, context)
	x.mode = invalid
	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 isTypes2 {
	if x.isNil() {
	if T == nil {
	check.errorf(x, UntypedNilUse, "use of untyped nil in %s", context)
	x.mode = invalid
	return
	}
	} else if T == nil \|\| isNonTypeParamInterface(T) {
	target = Default(x.typ)
	}
	} else { // go/types
	if T == nil \|\| isNonTypeParamInterface(T) {
	if T == nil && x.typ == Typ[UntypedNil] {
	check.errorf(x, UntypedNilUse, "use of untyped nil in %s", context)
	x.mode = invalid
	return
	}
	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)"
	default:
	code = IncompatibleAssign
	}
	check.error(x, code, 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, _ := under(x.typ).(*Signature); sig != nil && sig.TypeParams().Len() > 0 {
	check.errorf(x, WrongTypeArgCount, "cannot use generic function %s without instantiation in %s", x, context)
	x.mode = invalid
	return
	}

	// 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
	}

	cause := ""
	if ok, code := x.assignableTo(check, T, &cause); !ok {
	if cause != "" {
	check.errorf(x, code, "cannot use %s as %s value in %s: %s", x, T, context, cause)
	} else {
	check.errorf(x, code, "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 \|\| !isValid(x.typ) \|\| !isValid(lhs.typ) {
	if lhs.typ == nil {
	lhs.typ = Typ[Invalid]
	}
	return
	}

	// rhs must be a constant
	if x.mode != constant_ {
	check.errorf(x, InvalidConstInit, "%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
	}

	// initVar checks the initialization lhs = x in a variable declaration.
	// If lhs doesn't have a type yet, it is given the type of x,
	// or Typ[Invalid] in case of an error.
	// If the initialization check fails, x.mode is set to invalid.
	func (check Checker) initVar(lhs Var, x *operand, context string) {
	if x.mode == invalid \|\| !isValid(x.typ) \|\| !isValid(lhs.typ) {
	if lhs.typ == nil {
	lhs.typ = Typ[Invalid]
	}
	x.mode = invalid
	return
	}

	// If 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, UntypedNilUse, "use of untyped nil in %s", context)
	lhs.typ = Typ[Invalid]
	x.mode = invalid
	return
	}
	typ = Default(typ)
	}
	lhs.typ = typ
	}

	check.assignment(x, lhs.typ, context)
	}

	// lhsVar checks a lhs variable in an assignment and returns its type.
	// lhsVar takes care of not counting a lhs identifier as a "use" of
	// that identifier. The result is nil if it is the blank identifier,
	// and Typ[Invalid] if it is an invalid lhs expression.
	func (check *Checker) lhsVar(lhs syntax.Expr) Type {
	// Determine if the lhs is a (possibly parenthesized) identifier.
	ident, _ := syntax.Unparen(lhs).(*syntax.Name)

	// Don't evaluate lhs if it is the blank identifier.
	if ident != nil && ident.Value == "_" {
	check.recordDef(ident, nil)
	return nil
	}

	// If the lhs is an identifier denoting a variable v, this reference
	// 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 x operand
	check.expr(nil, &x, lhs)

	if v != nil {
	v.used = v_used // restore v.used
	}

	if x.mode == invalid \|\| !isValid(x.typ) {
	return Typ[Invalid]
	}

	// spec: "Each left-hand side operand must be addressable, a map index
	// expression, or the blank identifier. Operands may be parenthesized."
	switch x.mode {
	case invalid:
	return Typ[Invalid]
	case variable, mapindex:
	// ok
	default:
	if sel, ok := x.expr.(*syntax.SelectorExpr); ok {
	var op operand
	check.expr(nil, &op, sel.X)
	if op.mode == mapindex {
	check.errorf(&x, UnaddressableFieldAssign, "cannot assign to struct field %s in map", ExprString(x.expr))
	return Typ[Invalid]
	}
	}
	check.errorf(&x, UnassignableOperand, "cannot assign to %s (neither addressable nor a map index expression)", x.expr)
	return Typ[Invalid]
	}

	return x.typ
	}

	// assignVar checks the assignment lhs = rhs (if x == nil), or lhs = x (if x != nil).
	// If x != nil, it must be the evaluation of rhs (and rhs will be ignored).
	// If the assignment check fails and x != nil, x.mode is set to invalid.
	func (check Checker) assignVar(lhs, rhs syntax.Expr, x operand, context string) {
	T := check.lhsVar(lhs) // nil if lhs is _
	if !isValid(T) {
	if x != nil {
	x.mode = invalid
	} else {
	check.use(rhs)
	}
	return
	}

	if x == nil {
	var target *target
	// avoid calling ExprString if not needed
	if T != nil {
	if _, ok := under(T).(*Signature); ok {
	target = newTarget(T, ExprString(lhs))
	}
	}
	x = new(operand)
	check.expr(target, x, rhs)
	}

	if T == nil && context == "assignment" {
	context = "assignment to _ identifier"
	}
	check.assignment(x, T, context)
	}

	// operandTypes returns the list of types for the given operands.
	func operandTypes(list []*operand) (res []Type) {
	for _, x := range list {
	res = append(res, x.typ)
	}
	return res
	}

	// varTypes returns the list of types for the given variables.
	func varTypes(list []*Var) (res []Type) {
	for _, x := range list {
	res = append(res, x.typ)
	}
	return res
	}

	// typesSummary returns a string of the form "(t1, t2, ...)" where the
	// ti's are user-friendly string representations for the given types.
	// If variadic is set and the last type is a slice, its string is of
	// the form "...E" where E is the slice's element type.
	func (check *Checker) typesSummary(list []Type, variadic bool) string {
	var res []string
	for i, t := range list {
	var s string
	switch {
	case t == nil:
	fallthrough // should not happen but be cautious
	case !isValid(t):
	s = "unknown type"
	case isUntyped(t):
	if isNumeric(t) {
	// Do not imply a specific type requirement:
	// "have number, want float64" is better than
	// "have untyped int, want float64" or
	// "have int, want float64".
	s = "number"
	} else {
	// If we don't have a number, omit the "untyped" qualifier
	// for compactness.
	s = strings.Replace(t.(*Basic).name, "untyped ", "", -1)
	}
	case variadic && i == len(list)-1:
	s = check.sprintf("...%s", t.(*Slice).elem)
	}
	if s == "" {
	s = check.sprintf("%s", t)
	}
	res = append(res, s)
	}
	return "(" + strings.Join(res, ", ") + ")"
	}

	func measure(x int, unit string) string {
	if x != 1 {
	unit += "s"
	}
	return fmt.Sprintf("%d %s", x, unit)
	}

	func (check *Checker) assignError(rhs []syntax.Expr, l, r int) {
	vars := measure(l, "variable")
	vals := measure(r, "value")
	rhs0 := rhs[0]

	if len(rhs) == 1 {
	if call, _ := syntax.Unparen(rhs0).(*syntax.CallExpr); call != nil {
	check.errorf(rhs0, WrongAssignCount, "assignment mismatch: %s but %s returns %s", vars, call.Fun, vals)
	return
	}
	}
	check.errorf(rhs0, WrongAssignCount, "assignment mismatch: %s but %s", vars, vals)
	}

	func (check Checker) returnError(at poser, lhs []Var, rhs []*operand) {
	l, r := len(lhs), len(rhs)
	qualifier := "not enough"
	if r > l {
	at = rhs[l] // report at first extra value
	qualifier = "too many"
	} else if r > 0 {
	at = rhs[r-1] // report at last value
	}
	err := check.newError(WrongResultCount)
	err.addf(at, "%s return values", qualifier)
	err.addf(nopos, "have %s", check.typesSummary(operandTypes(rhs), false))
	err.addf(nopos, "want %s", check.typesSummary(varTypes(lhs), false))
	err.report()
	}

	// initVars type-checks assignments of initialization expressions orig_rhs
	// to variables lhs.
	// If returnStmt is non-nil, initVars type-checks the implicit assignment
	// of result expressions orig_rhs to function result parameters lhs.
	func (check Checker) initVars(lhs []Var, orig_rhs []syntax.Expr, returnStmt syntax.Stmt) {
	context := "assignment"
	if returnStmt != nil {
	context = "return statement"
	}

	l, r := len(lhs), len(orig_rhs)

	// If l == 1 and the rhs is a single call, for a better
	// error message don't handle it as n:n mapping below.
	isCall := false
	if r == 1 {
	_, isCall = syntax.Unparen(orig_rhs[0]).(*syntax.CallExpr)
	}

	// If we have a n:n mapping from lhs variable to rhs expression,
	// each value can be assigned to its corresponding variable.
	if l == r && !isCall {
	var x operand
	for i, lhs := range lhs {
	desc := lhs.name
	if returnStmt != nil && desc == "" {
	desc = "result variable"
	}
	check.expr(newTarget(lhs.typ, desc), &x, orig_rhs[i])
	check.initVar(lhs, &x, context)
	}
	return
	}

	// If we don't have an n:n mapping, the rhs must be a single expression
	// resulting in 2 or more values; otherwise we have an assignment mismatch.
	if r != 1 {
	// Only report a mismatch error if there are no other errors on the rhs.
	if check.use(orig_rhs...) {
	if returnStmt != nil {
	rhs := check.exprList(orig_rhs)
	check.returnError(returnStmt, lhs, rhs)
	} else {
	check.assignError(orig_rhs, l, r)
	}
	}
	// ensure that LHS variables have a type
	for _, v := range lhs {
	if v.typ == nil {
	v.typ = Typ[Invalid]
	}
	}
	return
	}

	rhs, commaOk := check.multiExpr(orig_rhs[0], l == 2 && returnStmt == nil)
	r = len(rhs)
	if l == r {
	for i, lhs := range lhs {
	check.initVar(lhs, rhs[i], context)
	}
	// Only record comma-ok expression if both initializations succeeded
	// (go.dev/issue/59371).
	if commaOk && rhs[0].mode != invalid && rhs[1].mode != invalid {
	check.recordCommaOkTypes(orig_rhs[0], rhs)
	}
	return
	}

	// In all other cases we have an assignment mismatch.
	// Only report a mismatch error if there are no other errors on the rhs.
	if rhs[0].mode != invalid {
	if returnStmt != nil {
	check.returnError(returnStmt, lhs, rhs)
	} else {
	check.assignError(orig_rhs, l, r)
	}
	}
	// ensure that LHS variables have a type
	for _, v := range lhs {
	if v.typ == nil {
	v.typ = Typ[Invalid]
	}
	}
	// orig_rhs[0] was already evaluated
	}

	// assignVars type-checks assignments of expressions orig_rhs to variables lhs.
	func (check *Checker) assignVars(lhs, orig_rhs []syntax.Expr) {
	l, r := len(lhs), len(orig_rhs)

	// If l == 1 and the rhs is a single call, for a better
	// error message don't handle it as n:n mapping below.
	isCall := false
	if r == 1 {
	_, isCall = syntax.Unparen(orig_rhs[0]).(*syntax.CallExpr)
	}

	// If we have a n:n mapping from lhs variable to rhs expression,
	// each value can be assigned to its corresponding variable.
	if l == r && !isCall {
	for i, lhs := range lhs {
	check.assignVar(lhs, orig_rhs[i], nil, "assignment")
	}
	return
	}

	// If we don't have an n:n mapping, the rhs must be a single expression
	// resulting in 2 or more values; otherwise we have an assignment mismatch.
	if r != 1 {
	// Only report a mismatch error if there are no other errors on the lhs or rhs.
	okLHS := check.useLHS(lhs...)
	okRHS := check.use(orig_rhs...)
	if okLHS && okRHS {
	check.assignError(orig_rhs, l, r)
	}
	return
	}

	rhs, commaOk := check.multiExpr(orig_rhs[0], l == 2)
	r = len(rhs)
	if l == r {
	for i, lhs := range lhs {
	check.assignVar(lhs, nil, rhs[i], "assignment")
	}
	// Only record comma-ok expression if both assignments succeeded
	// (go.dev/issue/59371).
	if commaOk && rhs[0].mode != invalid && rhs[1].mode != invalid {
	check.recordCommaOkTypes(orig_rhs[0], rhs)
	}
	return
	}

	// In all other cases we have an assignment mismatch.
	// Only report a mismatch error if there are no other errors on the rhs.
	if rhs[0].mode != invalid {
	check.assignError(orig_rhs, l, r)
	}
	check.useLHS(lhs...)
	// orig_rhs[0] was already evaluated
	}

	func (check *Checker) shortVarDecl(pos poser, 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)
	// TODO(gri) This is redundant with a go/parser error. Consider omitting in go/types?
	check.errorf(lhs, BadDecl, "non-name %s on left side of :=", lhs)
	hasErr = true
	continue
	}

	name := ident.Value
	if name != "_" {
	if seen[name] {
	check.errorf(lhs, RepeatedDecl, "%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, UnassignableOperand, "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, nil)

	// process function literals in rhs expressions before scope changes
	check.processDelayed(top)

	if len(newVars) == 0 && !hasErr {
	check.softErrorf(pos, NoNewVar, "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 := endPos(rhs[len(rhs)-1])
	for _, obj := range newVars {
	check.declare(scope, nil, obj, scopePos) // id = nil: recordDef already called
	}
	}