// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file // for details. All rights reserved. Use of this source code is governed by a // BSD-style license that can be found in the LICENSE file. // ignore_for_file: constant_identifier_names import 'int64.dart'; import 'intx.dart'; import 'utilities.dart' as u; /// An immutable 32-bit signed integer, in the range [-2^31, 2^31 - 1]. /// Arithmetic operations may overflow in order to maintain this range. class Int32 implements IntX { /// The maximum positive value attainable by an [Int32], namely /// 2147483647. static const Int32 MAX_VALUE = Int32._internal(0x7FFFFFFF); /// The minimum positive value attainable by an [Int32], namely /// -2147483648. static const Int32 MIN_VALUE = Int32._internal(-0x80000000); /// An [Int32] constant equal to 0. static const Int32 ZERO = Int32._internal(0); /// An [Int32] constant equal to 1. static const Int32 ONE = Int32._internal(1); /// An [Int32] constant equal to 2. static const Int32 TWO = Int32._internal(2); // Mask to 32-bits. static const int _MASK_U32 = 0xFFFFFFFF; /// Parses [source] in a given [radix] between 2 and 36. /// /// Returns an [Int32] with the numerical value of [source]. /// If the numerical value of [source] does not fit /// in a signed 32 bit integer, /// the numerical value is truncated to the lowest 32 bits /// of the value's binary representation, /// interpreted as a 32-bit two's complement integer. /// /// The [source] string must contain a sequence of base-[radix] /// digits (using letters from `a` to `z` as digits with values 10 through /// 25 for radixes above 10), possibly prefixed by a `-` sign. /// /// Throws a [FormatException] if the input is not a valid /// integer numeral in base [radix]. static Int32 parseRadix(String source, int radix) => _parseRadix(source, u.validateRadix(radix), true)!; /// Parses [source] in a given [radix] between 2 and 36. /// /// Returns an [Int32] with the numerical value of [source]. /// If the numerical value of [source] does not fit /// in a signed 32 bit integer, /// the numerical value is truncated to the lowest 32 bits /// of the value's binary representation, /// interpreted as a 32-bit two's complement integer. /// /// The [source] string must contain a sequence of base-[radix] /// digits (using letters from `a` to `z` as digits with values 10 through /// 25 for radixes above 10), possibly prefixed by a `-` sign. /// /// Throws a [FormatException] if the input is not a valid /// integer numeral in base [radix]. static Int32? tryParseRadix(String source, int radix) => _parseRadix(source, u.validateRadix(radix), false); // TODO(rice) - Make this faster by converting several digits at once. static Int32? _parseRadix(String s, int radix, bool throwOnError) { var index = 0; var negative = false; if (s.startsWith('-')) { negative = true; index = 1; } if (index == s.length) { if (!throwOnError) return null; throw FormatException('No digits', s, index); } var result = 0; for (; index < s.length; index++) { var c = s.codeUnitAt(index); var digit = u.decodeDigit(c); if (digit < radix) { /// Doesn't matter whether the result is unsigned /// or signed (as on the web), only the bits matter /// to the [Int32.new] constructor. result = (result * radix + digit) & _MASK_U32; } else { if (!throwOnError) return null; throw FormatException('Non radix code unit', s, index); } } if (negative) result = -result; return Int32(result); } /// Parses [source] as a decimal numeral. /// /// Returns an [Int32] with the numerical value of [source]. /// If the numerical value of [source] does not fit /// in a signed 32 bit integer, /// the numerical value is truncated to the lowest 32 bits /// of the value's binary representation, /// interpreted as a 32-bit two's complement integer. /// /// The [source] string must contain a sequence of digits (`0`-`9`), /// possibly prefixed by a `-` sign. /// /// Throws a [FormatException] if the input is not a valid /// decimal integer numeral. static Int32 parseInt(String source) => _parseRadix(source, 10, true)!; /// Parses [source] as a decimal numeral. /// /// Returns an [Int32] with the numerical value of [source]. /// If the numerical value of [source] does not fit /// in a signed 32 bit integer, /// the numerical value is truncated to the lowest 32 bits /// of the value's binary representation, /// interpreted as a 32-bit two's complement integer. /// /// The [source] string must contain a sequence of digits (`0`-`9`), /// possibly prefixed by a `-` sign. /// /// Throws a [FormatException] if the input is not a valid /// decimal integer numeral. static Int32? tryParseInt(String source) => _parseRadix(source, 10, false); /// Parses [source] as a hexadecimal numeral. /// /// Returns an [Int32] with the numerical value of [source]. /// If the numerical value of [source] does not fit /// in a signed 32 bit integer, /// the numerical value is truncated to the lowest 32 bits /// of the value's binary representation, /// interpreted as a 32-bit two's complement integer. /// /// The [source] string must contain a sequence of hexadecimal /// digits (`0`-`9`, `a`-`f` or `A`-`F`), possibly prefixed by a `-` sign. /// /// Returns `null` if the input is not a valid /// hexadecimal integer numeral. static Int32 parseHex(String source) => _parseRadix(source, 16, true)!; /// Parses [source] as a hexadecimal numeral. /// /// Returns an [Int32] with the numerical value of [source]. /// If the numerical value of [source] does not fit /// in a signed 32 bit integer, /// the numerical value is truncated to the lowest 32 bits /// of the value's binary representation, /// interpreted as a 32-bit two's complement integer. /// /// The [source] string must contain a sequence of hexadecimal /// digits (`0`-`9`, `a`-`f` or `A`-`F`), possibly prefixed by a `-` sign. /// /// Returns `null` if the input is not a valid /// hexadecimal integer numeral. static Int32? tryParseHex(String source) => _parseRadix(source, 16, false); // The internal value, kept in the range [MIN_VALUE, MAX_VALUE]. final int _i; const Int32._internal(int i) : _i = i; /// Constructs an [Int32] from an [int]. Only the low 32 bits of the input /// are used. Int32([int i = 0]) : _i = (i & 0x7fffffff) - (i & 0x80000000); // Returns the [int] representation of the specified value. Throws // [ArgumentError] for non-integer arguments. int _toInt(Object val) { if (val is Int32) { return val._i; } else if (val is int) { return val; } throw ArgumentError.value(val, 'other', 'Not an int, Int32 or Int64'); } // The +, -, * , &, |, and ^ operaters deal with types as follows: // // Int32 + int => Int32 // Int32 + Int32 => Int32 // Int32 + Int64 => Int64 // // The %, ~/ and remainder operators return an Int32 even with an Int64 // argument, since the result cannot be greater than the value on the // left-hand side: // // Int32 % int => Int32 // Int32 % Int32 => Int32 // Int32 % Int64 => Int32 @override IntX operator +(Object other) { if (other is Int64) { return toInt64() + other; } return Int32(_i + _toInt(other)); } @override IntX operator -(Object other) { if (other is Int64) { return toInt64() - other; } return Int32(_i - _toInt(other)); } @override Int32 operator -() => Int32(-_i); @override IntX operator *(Object other) { if (other is Int64) { return toInt64() * other; } // TODO(rice) - optimize return (toInt64() * other).toInt32(); } @override Int32 operator %(Object other) { if (other is Int64) { // Result will be Int32 return (toInt64() % other).toInt32(); } return Int32(_i % _toInt(other)); } @override Int32 operator ~/(Object other) { if (other is Int64) { return (toInt64() ~/ other).toInt32(); } return Int32(_i ~/ _toInt(other)); } @override Int32 remainder(Object other) { if (other is Int64) { var t = toInt64(); return (t - (t ~/ other) * other).toInt32(); } return this - (this ~/ other) * other as Int32; } @override Int32 operator &(Object other) { if (other is Int64) { return (toInt64() & other).toInt32(); } return Int32(_i & _toInt(other)); } @override Int32 operator |(Object other) { if (other is Int64) { return (toInt64() | other).toInt32(); } return Int32(_i | _toInt(other)); } @override Int32 operator ^(Object other) { if (other is Int64) { return (toInt64() ^ other).toInt32(); } return Int32(_i ^ _toInt(other)); } @override Int32 operator ~() => Int32(~_i); @override Int32 operator <<(int n) { if (n < 0) { throw ArgumentError(n); } if (n >= 32) { return ZERO; } return Int32(_i << n); } @override Int32 operator >>(int n) { if (n < 0) { throw ArgumentError(n); } if (n >= 32) { return isNegative ? const Int32._internal(-1) : ZERO; } int value; if (_i >= 0) { value = _i >> n; } else { value = (_i >> n) | (0xffffffff << (32 - n)); } return Int32(value); } @override Int32 shiftRightUnsigned(int n) { if (n < 0) { throw ArgumentError(n); } if (n >= 32) { return ZERO; } int value; if (_i >= 0) { value = _i >> n; } else { value = (_i >> n) & ((1 << (32 - n)) - 1); } return Int32(value); } /// Returns [:true:] if this [Int32] has the same numeric value as the /// given object. The argument may be an [int] or an [IntX]. @override bool operator ==(Object other) { if (other is Int32) { return _i == other._i; } else if (other is Int64) { return toInt64() == other; } else if (other is int) { return _i == other; } return false; } @override int compareTo(Object other) { if (other is Int64) { return toInt64().compareTo(other); } return _i.compareTo(_toInt(other)); } @override bool operator <(Object other) { if (other is Int64) { return toInt64() < other; } return _i < _toInt(other); } @override bool operator <=(Object other) { if (other is Int64) { return toInt64() <= other; } return _i <= _toInt(other); } @override bool operator >(Object other) { if (other is Int64) { return toInt64() > other; } return _i > _toInt(other); } @override bool operator >=(Object other) { if (other is Int64) { return toInt64() >= other; } return _i >= _toInt(other); } @override bool get isEven => (_i & 0x1) == 0; @override bool get isMaxValue => _i == 2147483647; @override bool get isMinValue => _i == -2147483648; @override bool get isNegative => _i < 0; @override bool get isOdd => (_i & 0x1) == 1; @override bool get isZero => _i == 0; @override int get bitLength => _i.bitLength; @override int get hashCode => _i; @override Int32 abs() => _i < 0 ? Int32(-_i) : this; @override Int32 clamp(Object lowerLimit, Object upperLimit) { if (this < lowerLimit) { if (lowerLimit is IntX) return lowerLimit.toInt32(); if (lowerLimit is int) return Int32(lowerLimit); throw ArgumentError(lowerLimit); } else if (this > upperLimit) { if (upperLimit is IntX) return upperLimit.toInt32(); if (upperLimit is int) return Int32(upperLimit); throw ArgumentError(upperLimit); } return this; } @override int numberOfLeadingZeros() => u.numberOfLeadingZeros(_i); @override int numberOfTrailingZeros() => u.numberOfTrailingZeros(_i); @override Int32 toSigned(int width) { if (width < 1 || width > 32) throw RangeError.range(width, 1, 32); return Int32(_i.toSigned(width)); } @override Int32 toUnsigned(int width) { if (width < 0 || width > 32) throw RangeError.range(width, 0, 32); return Int32(_i.toUnsigned(width)); } @override List toBytes() { var result = List.filled(4, 0); result[0] = _i & 0xff; result[1] = (_i >> 8) & 0xff; result[2] = (_i >> 16) & 0xff; result[3] = (_i >> 24) & 0xff; return result; } @override double toDouble() => _i.toDouble(); @override int toInt() => _i; @override Int32 toInt32() => this; @override Int64 toInt64() => Int64(_i); @override String toString() => _i.toString(); @override String toHexString() => _i.toRadixString(16); @override String toRadixString(int radix) => _i.toRadixString(radix); }