mirror of
https://github.com/mozilla/gecko-dev.git
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810 lines
23 KiB
C++
810 lines
23 KiB
C++
/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this file,
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* You can obtain one at http://mozilla.org/MPL/2.0/. */
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/* Provides checked integers, detecting integer overflow and divide-by-0. */
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#ifndef mozilla_CheckedInt_h_
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#define mozilla_CheckedInt_h_
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/*
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* Build options. Comment out these #defines to disable the corresponding
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* optional feature. Disabling features may be useful for code using
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* CheckedInt outside of Mozilla (e.g. WebKit)
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*/
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// Enable usage of MOZ_STATIC_ASSERT to check for unsupported types.
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// If disabled, static asserts are replaced by regular assert().
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#define MOZ_CHECKEDINT_ENABLE_MOZ_ASSERTS
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/*
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* End of build options
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*/
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#ifdef MOZ_CHECKEDINT_ENABLE_MOZ_ASSERTS
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# include "mozilla/Assertions.h"
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#else
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# ifndef MOZ_STATIC_ASSERT
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# include <cassert>
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# define MOZ_STATIC_ASSERT(cond, reason) assert((cond) && reason)
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# define MOZ_ASSERT(cond, reason) assert((cond) && reason)
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# endif
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#endif
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#include "mozilla/StandardInteger.h"
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#include <climits>
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#include <cstddef>
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namespace mozilla {
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namespace detail {
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/*
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* Step 1: manually record supported types
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*
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* What's nontrivial here is that there are different families of integer
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* types: basic integer types and stdint types. It is merrily undefined which
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* types from one family may be just typedefs for a type from another family.
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*
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* For example, on GCC 4.6, aside from the basic integer types, the only other
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* type that isn't just a typedef for some of them, is int8_t.
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*/
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struct UnsupportedType {};
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template<typename IntegerType>
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struct IsSupportedPass2
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{
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static const bool value = false;
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};
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template<typename IntegerType>
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struct IsSupported
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{
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static const bool value = IsSupportedPass2<IntegerType>::value;
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};
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template<>
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struct IsSupported<int8_t>
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{ static const bool value = true; };
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template<>
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struct IsSupported<uint8_t>
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{ static const bool value = true; };
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template<>
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struct IsSupported<int16_t>
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{ static const bool value = true; };
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template<>
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struct IsSupported<uint16_t>
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{ static const bool value = true; };
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template<>
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struct IsSupported<int32_t>
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{ static const bool value = true; };
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template<>
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struct IsSupported<uint32_t>
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{ static const bool value = true; };
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template<>
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struct IsSupported<int64_t>
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{ static const bool value = true; };
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template<>
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struct IsSupported<uint64_t>
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{ static const bool value = true; };
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template<>
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struct IsSupportedPass2<char>
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{ static const bool value = true; };
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template<>
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struct IsSupportedPass2<unsigned char>
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{ static const bool value = true; };
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template<>
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struct IsSupportedPass2<short>
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{ static const bool value = true; };
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template<>
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struct IsSupportedPass2<unsigned short>
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{ static const bool value = true; };
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template<>
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struct IsSupportedPass2<int>
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{ static const bool value = true; };
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template<>
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struct IsSupportedPass2<unsigned int>
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{ static const bool value = true; };
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template<>
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struct IsSupportedPass2<long>
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{ static const bool value = true; };
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template<>
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struct IsSupportedPass2<unsigned long>
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{ static const bool value = true; };
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/*
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* Step 2: some integer-traits kind of stuff.
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*/
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template<size_t Size, bool Signedness>
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struct StdintTypeForSizeAndSignedness
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{};
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template<>
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struct StdintTypeForSizeAndSignedness<1, true>
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{ typedef int8_t Type; };
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template<>
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struct StdintTypeForSizeAndSignedness<1, false>
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{ typedef uint8_t Type; };
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template<>
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struct StdintTypeForSizeAndSignedness<2, true>
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{ typedef int16_t Type; };
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template<>
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struct StdintTypeForSizeAndSignedness<2, false>
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{ typedef uint16_t Type; };
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template<>
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struct StdintTypeForSizeAndSignedness<4, true>
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{ typedef int32_t Type; };
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template<>
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struct StdintTypeForSizeAndSignedness<4, false>
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{ typedef uint32_t Type; };
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template<>
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struct StdintTypeForSizeAndSignedness<8, true>
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{ typedef int64_t Type; };
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template<>
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struct StdintTypeForSizeAndSignedness<8, false>
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{ typedef uint64_t Type; };
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template<typename IntegerType>
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struct UnsignedType
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{
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typedef typename StdintTypeForSizeAndSignedness<sizeof(IntegerType),
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false>::Type Type;
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};
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template<typename IntegerType>
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struct IsSigned
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{
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static const bool value = IntegerType(-1) <= IntegerType(0);
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};
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template<typename IntegerType, size_t Size = sizeof(IntegerType)>
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struct TwiceBiggerType
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{
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typedef typename StdintTypeForSizeAndSignedness<
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sizeof(IntegerType) * 2,
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IsSigned<IntegerType>::value
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>::Type Type;
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};
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template<typename IntegerType>
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struct TwiceBiggerType<IntegerType, 8>
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{
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typedef UnsupportedType Type;
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};
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template<typename IntegerType>
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struct PositionOfSignBit
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{
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static const size_t value = CHAR_BIT * sizeof(IntegerType) - 1;
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};
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template<typename IntegerType>
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struct MinValue
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{
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private:
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typedef typename UnsignedType<IntegerType>::Type UnsignedIntegerType;
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static const size_t PosOfSignBit = PositionOfSignBit<IntegerType>::value;
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public:
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// Bitwise ops may return a larger type, that's why we cast explicitly.
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// In C++, left bit shifts on signed values is undefined by the standard
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// unless the shifted value is representable.
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// Notice that signed-to-unsigned conversions are always well-defined in
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// the standard as the value congruent to 2**n, as expected. By contrast,
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// unsigned-to-signed is only well-defined if the value is representable.
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static const IntegerType value =
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IsSigned<IntegerType>::value
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? IntegerType(UnsignedIntegerType(1) << PosOfSignBit)
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: IntegerType(0);
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};
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template<typename IntegerType>
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struct MaxValue
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{
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// Tricksy, but covered by the unit test.
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// Relies heavily on the type of MinValue<IntegerType>::value
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// being IntegerType.
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static const IntegerType value = ~MinValue<IntegerType>::value;
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};
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/*
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* Step 3: Implement the actual validity checks.
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*
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* Ideas taken from IntegerLib, code different.
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*/
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template<typename T>
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inline bool
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HasSignBit(T x)
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{
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// In C++, right bit shifts on negative values is undefined by the standard.
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// Notice that signed-to-unsigned conversions are always well-defined in the
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// standard, as the value congruent modulo 2**n as expected. By contrast,
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// unsigned-to-signed is only well-defined if the value is representable.
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return bool(typename UnsignedType<T>::Type(x)
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>> PositionOfSignBit<T>::value);
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}
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// Bitwise ops may return a larger type, so it's good to use this inline
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// helper guaranteeing that the result is really of type T.
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template<typename T>
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inline T
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BinaryComplement(T x)
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{
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return ~x;
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}
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template<typename T,
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typename U,
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bool IsTSigned = IsSigned<T>::value,
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bool IsUSigned = IsSigned<U>::value>
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struct DoesRangeContainRange
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{
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};
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template<typename T, typename U, bool Signedness>
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struct DoesRangeContainRange<T, U, Signedness, Signedness>
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{
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static const bool value = sizeof(T) >= sizeof(U);
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};
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template<typename T, typename U>
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struct DoesRangeContainRange<T, U, true, false>
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{
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static const bool value = sizeof(T) > sizeof(U);
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};
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template<typename T, typename U>
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struct DoesRangeContainRange<T, U, false, true>
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{
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static const bool value = false;
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};
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template<typename T,
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typename U,
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bool IsTSigned = IsSigned<T>::value,
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bool IsUSigned = IsSigned<U>::value,
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bool DoesTRangeContainURange = DoesRangeContainRange<T, U>::value>
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struct IsInRangeImpl {};
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template<typename T, typename U, bool IsTSigned, bool IsUSigned>
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struct IsInRangeImpl<T, U, IsTSigned, IsUSigned, true>
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{
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static bool run(U)
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{
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return true;
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}
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};
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template<typename T, typename U>
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struct IsInRangeImpl<T, U, true, true, false>
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{
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static bool run(U x)
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{
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return x <= MaxValue<T>::value && x >= MinValue<T>::value;
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}
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};
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template<typename T, typename U>
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struct IsInRangeImpl<T, U, false, false, false>
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{
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static bool run(U x)
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{
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return x <= MaxValue<T>::value;
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}
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};
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template<typename T, typename U>
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struct IsInRangeImpl<T, U, true, false, false>
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{
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static bool run(U x)
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{
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return sizeof(T) > sizeof(U) || x <= U(MaxValue<T>::value);
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}
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};
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template<typename T, typename U>
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struct IsInRangeImpl<T, U, false, true, false>
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{
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static bool run(U x)
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{
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return sizeof(T) >= sizeof(U)
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? x >= 0
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: x >= 0 && x <= U(MaxValue<T>::value);
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}
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};
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template<typename T, typename U>
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inline bool
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IsInRange(U x)
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{
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return IsInRangeImpl<T, U>::run(x);
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}
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template<typename T>
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inline bool
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IsAddValid(T x, T y)
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{
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// Addition is valid if the sign of x+y is equal to either that of x or that
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// of y. Since the value of x+y is undefined if we have a signed type, we
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// compute it using the unsigned type of the same size.
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// Beware! These bitwise operations can return a larger integer type,
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// if T was a small type like int8_t, so we explicitly cast to T.
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typename UnsignedType<T>::Type ux = x;
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typename UnsignedType<T>::Type uy = y;
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typename UnsignedType<T>::Type result = ux + uy;
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return IsSigned<T>::value
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? HasSignBit(BinaryComplement(T((result ^ x) & (result ^ y))))
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: BinaryComplement(x) >= y;
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}
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template<typename T>
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inline bool
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IsSubValid(T x, T y)
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{
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// Subtraction is valid if either x and y have same sign, or x-y and x have
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// same sign. Since the value of x-y is undefined if we have a signed type,
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// we compute it using the unsigned type of the same size.
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typename UnsignedType<T>::Type ux = x;
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typename UnsignedType<T>::Type uy = y;
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typename UnsignedType<T>::Type result = ux - uy;
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return IsSigned<T>::value
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? HasSignBit(BinaryComplement(T((result ^ x) & (x ^ y))))
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: x >= y;
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}
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template<typename T,
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bool IsSigned = IsSigned<T>::value,
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bool TwiceBiggerTypeIsSupported =
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IsSupported<typename TwiceBiggerType<T>::Type>::value>
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struct IsMulValidImpl {};
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template<typename T, bool IsSigned>
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struct IsMulValidImpl<T, IsSigned, true>
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{
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static bool run(T x, T y)
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{
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typedef typename TwiceBiggerType<T>::Type TwiceBiggerType;
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TwiceBiggerType product = TwiceBiggerType(x) * TwiceBiggerType(y);
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return IsInRange<T>(product);
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}
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};
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template<typename T>
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struct IsMulValidImpl<T, true, false>
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{
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static bool run(T x, T y)
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{
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const T max = MaxValue<T>::value;
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const T min = MinValue<T>::value;
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if (x == 0 || y == 0)
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return true;
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if (x > 0) {
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return y > 0
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? x <= max / y
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: y >= min / x;
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}
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// If we reach this point, we know that x < 0.
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return y > 0
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? x >= min / y
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: y >= max / x;
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}
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};
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template<typename T>
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struct IsMulValidImpl<T, false, false>
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{
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static bool run(T x, T y)
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{
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return y == 0 || x <= MaxValue<T>::value / y;
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}
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};
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template<typename T>
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inline bool
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IsMulValid(T x, T y)
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{
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return IsMulValidImpl<T>::run(x, y);
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}
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template<typename T>
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inline bool
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IsDivValid(T x, T y)
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{
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// Keep in mind that in the signed case, min/-1 is invalid because abs(min)>max.
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return y != 0 &&
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!(IsSigned<T>::value && x == MinValue<T>::value && y == T(-1));
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}
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// This is just to shut up msvc warnings about negating unsigned ints.
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template<typename T, bool IsSigned = IsSigned<T>::value>
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struct OppositeIfSignedImpl
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{
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static T run(T x) { return -x; }
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};
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template<typename T>
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struct OppositeIfSignedImpl<T, false>
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{
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static T run(T x) { return x; }
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};
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template<typename T>
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inline T
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OppositeIfSigned(T x)
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{
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return OppositeIfSignedImpl<T>::run(x);
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}
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} // namespace detail
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/*
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* Step 4: Now define the CheckedInt class.
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*/
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/**
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* @class CheckedInt
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* @brief Integer wrapper class checking for integer overflow and other errors
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* @param T the integer type to wrap. Can be any type among the following:
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* - any basic integer type such as |int|
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* - any stdint type such as |int8_t|
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*
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* This class implements guarded integer arithmetic. Do a computation, check
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* that isValid() returns true, you then have a guarantee that no problem, such
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* as integer overflow, happened during this computation, and you can call
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* value() to get the plain integer value.
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*
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* The arithmetic operators in this class are guaranteed not to raise a signal
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* (e.g. in case of a division by zero).
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*
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* For example, suppose that you want to implement a function that computes
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* (x+y)/z, that doesn't crash if z==0, and that reports on error (divide by
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* zero or integer overflow). You could code it as follows:
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@code
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bool computeXPlusYOverZ(int x, int y, int z, int *result)
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{
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CheckedInt<int> checkedResult = (CheckedInt<int>(x) + y) / z;
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if (checkedResult.isValid()) {
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*result = checkedResult.value();
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return true;
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} else {
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return false;
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}
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}
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@endcode
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*
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* Implicit conversion from plain integers to checked integers is allowed. The
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* plain integer is checked to be in range before being casted to the
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* destination type. This means that the following lines all compile, and the
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* resulting CheckedInts are correctly detected as valid or invalid:
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* @code
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// 1 is of type int, is found to be in range for uint8_t, x is valid
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CheckedInt<uint8_t> x(1);
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// -1 is of type int, is found not to be in range for uint8_t, x is invalid
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CheckedInt<uint8_t> x(-1);
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// -1 is of type int, is found to be in range for int8_t, x is valid
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CheckedInt<int8_t> x(-1);
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// 1000 is of type int16_t, is found not to be in range for int8_t,
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// x is invalid
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CheckedInt<int8_t> x(int16_t(1000));
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// 3123456789 is of type uint32_t, is found not to be in range for int32_t,
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// x is invalid
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CheckedInt<int32_t> x(uint32_t(3123456789));
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* @endcode
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* Implicit conversion from
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* checked integers to plain integers is not allowed. As shown in the
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* above example, to get the value of a checked integer as a normal integer,
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* call value().
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*
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* Arithmetic operations between checked and plain integers is allowed; the
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* result type is the type of the checked integer.
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*
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* Checked integers of different types cannot be used in the same arithmetic
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* expression.
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*
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* There are convenience typedefs for all stdint types, of the following form
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* (these are just 2 examples):
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@code
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typedef CheckedInt<int32_t> CheckedInt32;
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typedef CheckedInt<uint16_t> CheckedUint16;
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@endcode
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*/
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template<typename T>
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class CheckedInt
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{
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protected:
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T mValue;
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bool mIsValid;
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template<typename U>
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CheckedInt(U value, bool isValid) : mValue(value), mIsValid(isValid)
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{
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MOZ_STATIC_ASSERT(detail::IsSupported<T>::value,
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"This type is not supported by CheckedInt");
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}
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public:
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/**
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* Constructs a checked integer with given @a value. The checked integer is
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* initialized as valid or invalid depending on whether the @a value
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* is in range.
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*
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* This constructor is not explicit. Instead, the type of its argument is a
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* separate template parameter, ensuring that no conversion is performed
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* before this constructor is actually called. As explained in the above
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* documentation for class CheckedInt, this constructor checks that its
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* argument is valid.
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*/
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template<typename U>
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CheckedInt(U value)
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: mValue(T(value)),
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mIsValid(detail::IsInRange<T>(value))
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{
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MOZ_STATIC_ASSERT(detail::IsSupported<T>::value,
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"This type is not supported by CheckedInt");
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}
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/** Constructs a valid checked integer with initial value 0 */
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CheckedInt() : mValue(0), mIsValid(true)
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{
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MOZ_STATIC_ASSERT(detail::IsSupported<T>::value,
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"This type is not supported by CheckedInt");
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}
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/** @returns the actual value */
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T value() const
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{
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MOZ_ASSERT(mIsValid, "Invalid checked integer (division by zero or integer overflow)");
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return mValue;
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}
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/**
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* @returns true if the checked integer is valid, i.e. is not the result
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* of an invalid operation or of an operation involving an invalid checked
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* integer
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*/
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bool isValid() const
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{
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return mIsValid;
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}
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template<typename U>
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friend CheckedInt<U> operator +(const CheckedInt<U>& lhs,
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const CheckedInt<U>& rhs);
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template<typename U>
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CheckedInt& operator +=(U rhs);
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template<typename U>
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friend CheckedInt<U> operator -(const CheckedInt<U>& lhs,
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const CheckedInt<U> &rhs);
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template<typename U>
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CheckedInt& operator -=(U rhs);
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template<typename U>
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friend CheckedInt<U> operator *(const CheckedInt<U>& lhs,
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const CheckedInt<U> &rhs);
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template<typename U>
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CheckedInt& operator *=(U rhs);
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template<typename U>
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friend CheckedInt<U> operator /(const CheckedInt<U>& lhs,
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const CheckedInt<U> &rhs);
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template<typename U>
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CheckedInt& operator /=(U rhs);
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CheckedInt operator -() const
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{
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// Circumvent msvc warning about - applied to unsigned int.
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// if we're unsigned, the only valid case anyway is 0
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// in which case - is a no-op.
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T result = detail::OppositeIfSigned(mValue);
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/* Help the compiler perform RVO (return value optimization). */
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return CheckedInt(result,
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mIsValid && detail::IsSubValid(T(0),
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mValue));
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}
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/**
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* @returns true if the left and right hand sides are valid
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* and have the same value.
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*
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* Note that these semantics are the reason why we don't offer
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* a operator!=. Indeed, we'd want to have a!=b be equivalent to !(a==b)
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* but that would mean that whenever a or b is invalid, a!=b
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* is always true, which would be very confusing.
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*
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* For similar reasons, operators <, >, <=, >= would be very tricky to
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* specify, so we just avoid offering them.
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*
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* Notice that these == semantics are made more reasonable by these facts:
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* 1. a==b implies equality at the raw data level
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* (the converse is false, as a==b is never true among invalids)
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* 2. This is similar to the behavior of IEEE floats, where a==b
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* means that a and b have the same value *and* neither is NaN.
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*/
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bool operator ==(const CheckedInt& other) const
|
|
{
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return mIsValid && other.mIsValid && mValue == other.mValue;
|
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}
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|
|
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/** prefix ++ */
|
|
CheckedInt& operator++()
|
|
{
|
|
*this += 1;
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|
return *this;
|
|
}
|
|
|
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/** postfix ++ */
|
|
CheckedInt operator++(int)
|
|
{
|
|
CheckedInt tmp = *this;
|
|
*this += 1;
|
|
return tmp;
|
|
}
|
|
|
|
/** prefix -- */
|
|
CheckedInt& operator--()
|
|
{
|
|
*this -= 1;
|
|
return *this;
|
|
}
|
|
|
|
/** postfix -- */
|
|
CheckedInt operator--(int)
|
|
{
|
|
CheckedInt tmp = *this;
|
|
*this -= 1;
|
|
return tmp;
|
|
}
|
|
|
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private:
|
|
/**
|
|
* The !=, <, <=, >, >= operators are disabled:
|
|
* see the comment on operator==.
|
|
*/
|
|
template<typename U>
|
|
bool operator !=(U other) const MOZ_DELETE;
|
|
template<typename U>
|
|
bool operator <(U other) const MOZ_DELETE;
|
|
template<typename U>
|
|
bool operator <=(U other) const MOZ_DELETE;
|
|
template<typename U>
|
|
bool operator >(U other) const MOZ_DELETE;
|
|
template<typename U>
|
|
bool operator >=(U other) const MOZ_DELETE;
|
|
};
|
|
|
|
#define MOZ_CHECKEDINT_BASIC_BINARY_OPERATOR(NAME, OP) \
|
|
template<typename T> \
|
|
inline CheckedInt<T> operator OP(const CheckedInt<T> &lhs, \
|
|
const CheckedInt<T> &rhs) \
|
|
{ \
|
|
if (!detail::Is##NAME##Valid(lhs.mValue, rhs.mValue)) \
|
|
return CheckedInt<T>(0, false); \
|
|
\
|
|
return CheckedInt<T>(lhs.mValue OP rhs.mValue, \
|
|
lhs.mIsValid && rhs.mIsValid); \
|
|
}
|
|
|
|
MOZ_CHECKEDINT_BASIC_BINARY_OPERATOR(Add, +)
|
|
MOZ_CHECKEDINT_BASIC_BINARY_OPERATOR(Sub, -)
|
|
MOZ_CHECKEDINT_BASIC_BINARY_OPERATOR(Mul, *)
|
|
MOZ_CHECKEDINT_BASIC_BINARY_OPERATOR(Div, /)
|
|
|
|
#undef MOZ_CHECKEDINT_BASIC_BINARY_OPERATOR
|
|
|
|
// Implement castToCheckedInt<T>(x), making sure that
|
|
// - it allows x to be either a CheckedInt<T> or any integer type
|
|
// that can be casted to T
|
|
// - if x is already a CheckedInt<T>, we just return a reference to it,
|
|
// instead of copying it (optimization)
|
|
|
|
namespace detail {
|
|
|
|
template<typename T, typename U>
|
|
struct CastToCheckedIntImpl
|
|
{
|
|
typedef CheckedInt<T> ReturnType;
|
|
static CheckedInt<T> run(U u) { return u; }
|
|
};
|
|
|
|
template<typename T>
|
|
struct CastToCheckedIntImpl<T, CheckedInt<T> >
|
|
{
|
|
typedef const CheckedInt<T>& ReturnType;
|
|
static const CheckedInt<T>& run(const CheckedInt<T>& u) { return u; }
|
|
};
|
|
|
|
} // namespace detail
|
|
|
|
template<typename T, typename U>
|
|
inline typename detail::CastToCheckedIntImpl<T, U>::ReturnType
|
|
castToCheckedInt(U u)
|
|
{
|
|
return detail::CastToCheckedIntImpl<T, U>::run(u);
|
|
}
|
|
|
|
#define MOZ_CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(OP, COMPOUND_OP) \
|
|
template<typename T> \
|
|
template<typename U> \
|
|
CheckedInt<T>& CheckedInt<T>::operator COMPOUND_OP(U rhs) \
|
|
{ \
|
|
*this = *this OP castToCheckedInt<T>(rhs); \
|
|
return *this; \
|
|
} \
|
|
template<typename T, typename U> \
|
|
inline CheckedInt<T> operator OP(const CheckedInt<T> &lhs, U rhs) \
|
|
{ \
|
|
return lhs OP castToCheckedInt<T>(rhs); \
|
|
} \
|
|
template<typename T, typename U> \
|
|
inline CheckedInt<T> operator OP(U lhs, const CheckedInt<T> &rhs) \
|
|
{ \
|
|
return castToCheckedInt<T>(lhs) OP rhs; \
|
|
}
|
|
|
|
MOZ_CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(+, +=)
|
|
MOZ_CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(*, *=)
|
|
MOZ_CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(-, -=)
|
|
MOZ_CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(/, /=)
|
|
|
|
#undef MOZ_CHECKEDINT_CONVENIENCE_BINARY_OPERATORS
|
|
|
|
template<typename T, typename U>
|
|
inline bool
|
|
operator ==(const CheckedInt<T> &lhs, U rhs)
|
|
{
|
|
return lhs == castToCheckedInt<T>(rhs);
|
|
}
|
|
|
|
template<typename T, typename U>
|
|
inline bool
|
|
operator ==(U lhs, const CheckedInt<T> &rhs)
|
|
{
|
|
return castToCheckedInt<T>(lhs) == rhs;
|
|
}
|
|
|
|
// Convenience typedefs.
|
|
typedef CheckedInt<int8_t> CheckedInt8;
|
|
typedef CheckedInt<uint8_t> CheckedUint8;
|
|
typedef CheckedInt<int16_t> CheckedInt16;
|
|
typedef CheckedInt<uint16_t> CheckedUint16;
|
|
typedef CheckedInt<int32_t> CheckedInt32;
|
|
typedef CheckedInt<uint32_t> CheckedUint32;
|
|
typedef CheckedInt<int64_t> CheckedInt64;
|
|
typedef CheckedInt<uint64_t> CheckedUint64;
|
|
|
|
} // namespace mozilla
|
|
|
|
#endif /* mozilla_CheckedInt_h_ */
|