// index checks an index expression for validity. // If max >= 0, it is the upper bound for index. // If index is valid and the result i >= 0, then i is the constant value of index. func (check *Checker) index(index ast.Expr, max int64) (i int64, valid bool) { var x operand check.expr(&x, index) if x.mode == invalid { return } // an untyped constant must be representable as Int check.convertUntyped(&x, Typ[Int]) if x.mode == invalid { return } // the index must be of integer type if !isInteger(x.typ) { check.invalidArg(x.pos(), "index %s must be integer", &x) return } // a constant index i must be in bounds if x.mode == constant { if exact.Sign(x.val) < 0 { check.invalidArg(x.pos(), "index %s must not be negative", &x) return } i, valid = exact.Int64Val(x.val) if !valid || max >= 0 && i >= max { check.errorf(x.pos(), "index %s is out of bounds", &x) return i, false } // 0 <= i [ && i < max ] return i, true } return -1, true }
func (check *Checker) shift(x, y *operand, op token.Token) { untypedx := isUntyped(x.typ) // The lhs must be of integer type or be representable // as an integer; otherwise the shift has no chance. if !x.isInteger() { check.invalidOp(x.pos(), "shifted operand %s must be integer", x) x.mode = invalid return } // spec: "The right operand in a shift expression must have unsigned // integer type or be an untyped constant that can be converted to // unsigned integer type." switch { case isInteger(y.typ) && isUnsigned(y.typ): // nothing to do case isUntyped(y.typ): check.convertUntyped(y, Typ[UntypedInt]) if y.mode == invalid { x.mode = invalid return } default: check.invalidOp(y.pos(), "shift count %s must be unsigned integer", y) x.mode = invalid return } if x.mode == constant { if y.mode == constant { // rhs must be an integer value if !y.isInteger() { check.invalidOp(y.pos(), "shift count %s must be unsigned integer", y) x.mode = invalid return } // rhs must be within reasonable bounds const stupidShift = 1023 - 1 + 52 // so we can express smallestFloat64 s, ok := exact.Uint64Val(y.val) if !ok || s > stupidShift { check.invalidOp(y.pos(), "stupid shift count %s", y) x.mode = invalid return } // The lhs is representable as an integer but may not be an integer // (e.g., 2.0, an untyped float) - this can only happen for untyped // non-integer numeric constants. Correct the type so that the shift // result is of integer type. if !isInteger(x.typ) { x.typ = Typ[UntypedInt] } x.val = exact.Shift(x.val, op, uint(s)) return } // non-constant shift with constant lhs if untypedx { // spec: "If the left operand of a non-constant shift // expression is an untyped constant, the type of the // constant is what it would be if the shift expression // were replaced by its left operand alone.". // // Delay operand checking until we know the final type: // The lhs expression must be in the untyped map, mark // the entry as lhs shift operand. info, found := check.untyped[x.expr] assert(found) info.isLhs = true check.untyped[x.expr] = info // keep x's type x.mode = value return } } // constant rhs must be >= 0 if y.mode == constant && exact.Sign(y.val) < 0 { check.invalidOp(y.pos(), "shift count %s must not be negative", y) } // non-constant shift - lhs must be an integer if !isInteger(x.typ) { check.invalidOp(x.pos(), "shifted operand %s must be integer", x) x.mode = invalid return } x.mode = value }
// The binary expression e may be nil. It's passed in for better error messages only. func (check *Checker) binary(x *operand, e *ast.BinaryExpr, lhs, rhs ast.Expr, op token.Token) { var y operand check.expr(x, lhs) check.expr(&y, rhs) if x.mode == invalid { return } if y.mode == invalid { x.mode = invalid x.expr = y.expr return } if isShift(op) { check.shift(x, &y, op) return } check.convertUntyped(x, y.typ) if x.mode == invalid { return } check.convertUntyped(&y, x.typ) if y.mode == invalid { x.mode = invalid return } if isComparison(op) { check.comparison(x, &y, op) return } if !Identical(x.typ, y.typ) { // only report an error if we have valid types // (otherwise we had an error reported elsewhere already) if x.typ != Typ[Invalid] && y.typ != Typ[Invalid] { check.invalidOp(x.pos(), "mismatched types %s and %s", x.typ, y.typ) } x.mode = invalid return } if !check.op(binaryOpPredicates, x, op) { x.mode = invalid return } if (op == token.QUO || op == token.REM) && (x.mode == constant || isInteger(x.typ)) && y.mode == constant && exact.Sign(y.val) == 0 { check.invalidOp(y.pos(), "division by zero") x.mode = invalid return } if x.mode == constant && y.mode == constant { typ := x.typ.Underlying().(*Basic) // force integer division of integer operands if op == token.QUO && isInteger(typ) { op = token.QUO_ASSIGN } x.val = exact.BinaryOp(x.val, op, y.val) // Typed constants must be representable in // their type after each constant operation. if isTyped(typ) { if e != nil { x.expr = e // for better error message } check.representable(x, typ) } return } x.mode = value // x.typ is unchanged }
// representableConst reports whether x can be represented as // value of the given basic type kind and for the configuration // provided (only needed for int/uint sizes). // // If rounded != nil, *rounded is set to the rounded value of x for // representable floating-point values; it is left alone otherwise. // It is ok to provide the addressof the first argument for rounded. func representableConst(x exact.Value, conf *Config, as BasicKind, rounded *exact.Value) bool { switch x.Kind() { case exact.Unknown: return true case exact.Bool: return as == Bool || as == UntypedBool case exact.Int: if x, ok := exact.Int64Val(x); ok { switch as { case Int: var s = uint(conf.sizeof(Typ[as])) * 8 return int64(-1)<<(s-1) <= x && x <= int64(1)<<(s-1)-1 case Int8: const s = 8 return -1<<(s-1) <= x && x <= 1<<(s-1)-1 case Int16: const s = 16 return -1<<(s-1) <= x && x <= 1<<(s-1)-1 case Int32: const s = 32 return -1<<(s-1) <= x && x <= 1<<(s-1)-1 case Int64: return true case Uint, Uintptr: if s := uint(conf.sizeof(Typ[as])) * 8; s < 64 { return 0 <= x && x <= int64(1)<<s-1 } return 0 <= x case Uint8: const s = 8 return 0 <= x && x <= 1<<s-1 case Uint16: const s = 16 return 0 <= x && x <= 1<<s-1 case Uint32: const s = 32 return 0 <= x && x <= 1<<s-1 case Uint64: return 0 <= x case Float32, Float64, Complex64, Complex128, UntypedInt, UntypedFloat, UntypedComplex: return true } } n := exact.BitLen(x) switch as { case Uint, Uintptr: var s = uint(conf.sizeof(Typ[as])) * 8 return exact.Sign(x) >= 0 && n <= int(s) case Uint64: return exact.Sign(x) >= 0 && n <= 64 case Float32, Complex64: if rounded == nil { return fitsFloat32(x) } r := roundFloat32(x) if r != nil { *rounded = r return true } case Float64, Complex128: if rounded == nil { return fitsFloat64(x) } r := roundFloat64(x) if r != nil { *rounded = r return true } case UntypedInt, UntypedFloat, UntypedComplex: return true } case exact.Float: switch as { case Float32, Complex64: if rounded == nil { return fitsFloat32(x) } r := roundFloat32(x) if r != nil { *rounded = r return true } case Float64, Complex128: if rounded == nil { return fitsFloat64(x) } r := roundFloat64(x) if r != nil { *rounded = r return true } case UntypedFloat, UntypedComplex: return true } case exact.Complex: switch as { case Complex64: if rounded == nil { return fitsFloat32(exact.Real(x)) && fitsFloat32(exact.Imag(x)) } re := roundFloat32(exact.Real(x)) im := roundFloat32(exact.Imag(x)) if re != nil && im != nil { *rounded = exact.BinaryOp(re, token.ADD, exact.MakeImag(im)) return true } case Complex128: if rounded == nil { return fitsFloat64(exact.Real(x)) && fitsFloat64(exact.Imag(x)) } re := roundFloat64(exact.Real(x)) im := roundFloat64(exact.Imag(x)) if re != nil && im != nil { *rounded = exact.BinaryOp(re, token.ADD, exact.MakeImag(im)) return true } case UntypedComplex: return true } case exact.String: return as == String || as == UntypedString default: unreachable() } return false }