naiveproxy/base/numerics/checked_math.h

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2018-01-28 19:30:36 +03:00
// Copyright 2017 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef BASE_NUMERICS_CHECKED_MATH_H_
#define BASE_NUMERICS_CHECKED_MATH_H_
#include <stddef.h>
#include <limits>
#include <type_traits>
#include "base/numerics/checked_math_impl.h"
namespace base {
namespace internal {
template <typename T>
class CheckedNumeric {
static_assert(std::is_arithmetic<T>::value,
"CheckedNumeric<T>: T must be a numeric type.");
public:
using type = T;
constexpr CheckedNumeric() {}
// Copy constructor.
template <typename Src>
constexpr CheckedNumeric(const CheckedNumeric<Src>& rhs)
: state_(rhs.state_.value(), rhs.IsValid()) {}
template <typename Src>
friend class CheckedNumeric;
// This is not an explicit constructor because we implicitly upgrade regular
// numerics to CheckedNumerics to make them easier to use.
template <typename Src>
constexpr CheckedNumeric(Src value) // NOLINT(runtime/explicit)
: state_(value) {
static_assert(std::is_arithmetic<Src>::value, "Argument must be numeric.");
}
// This is not an explicit constructor because we want a seamless conversion
// from StrictNumeric types.
template <typename Src>
constexpr CheckedNumeric(
StrictNumeric<Src> value) // NOLINT(runtime/explicit)
: state_(static_cast<Src>(value)) {}
// IsValid() - The public API to test if a CheckedNumeric is currently valid.
// A range checked destination type can be supplied using the Dst template
// parameter.
template <typename Dst = T>
constexpr bool IsValid() const {
return state_.is_valid() &&
IsValueInRangeForNumericType<Dst>(state_.value());
}
// AssignIfValid(Dst) - Assigns the underlying value if it is currently valid
// and is within the range supported by the destination type. Returns true if
// successful and false otherwise.
template <typename Dst>
#if defined(__clang__) || defined(__GNUC__)
__attribute__((warn_unused_result))
#elif defined(_MSC_VER)
_Check_return_
#endif
constexpr bool
AssignIfValid(Dst* result) const {
return BASE_NUMERICS_LIKELY(IsValid<Dst>())
? ((*result = static_cast<Dst>(state_.value())), true)
: false;
}
// ValueOrDie() - The primary accessor for the underlying value. If the
// current state is not valid it will CHECK and crash.
// A range checked destination type can be supplied using the Dst template
// parameter, which will trigger a CHECK if the value is not in bounds for
// the destination.
// The CHECK behavior can be overridden by supplying a handler as a
// template parameter, for test code, etc. However, the handler cannot access
// the underlying value, and it is not available through other means.
template <typename Dst = T, class CheckHandler = CheckOnFailure>
constexpr StrictNumeric<Dst> ValueOrDie() const {
return BASE_NUMERICS_LIKELY(IsValid<Dst>())
? static_cast<Dst>(state_.value())
: CheckHandler::template HandleFailure<Dst>();
}
// ValueOrDefault(T default_value) - A convenience method that returns the
// current value if the state is valid, and the supplied default_value for
// any other state.
// A range checked destination type can be supplied using the Dst template
// parameter. WARNING: This function may fail to compile or CHECK at runtime
// if the supplied default_value is not within range of the destination type.
template <typename Dst = T, typename Src>
constexpr StrictNumeric<Dst> ValueOrDefault(const Src default_value) const {
return BASE_NUMERICS_LIKELY(IsValid<Dst>())
? static_cast<Dst>(state_.value())
: checked_cast<Dst>(default_value);
}
// Returns a checked numeric of the specified type, cast from the current
// CheckedNumeric. If the current state is invalid or the destination cannot
// represent the result then the returned CheckedNumeric will be invalid.
template <typename Dst>
constexpr CheckedNumeric<typename UnderlyingType<Dst>::type> Cast() const {
return *this;
}
// This friend method is available solely for providing more detailed logging
// in the the tests. Do not implement it in production code, because the
// underlying values may change at any time.
template <typename U>
friend U GetNumericValueForTest(const CheckedNumeric<U>& src);
// Prototypes for the supported arithmetic operator overloads.
template <typename Src>
constexpr CheckedNumeric& operator+=(const Src rhs);
template <typename Src>
constexpr CheckedNumeric& operator-=(const Src rhs);
template <typename Src>
constexpr CheckedNumeric& operator*=(const Src rhs);
template <typename Src>
constexpr CheckedNumeric& operator/=(const Src rhs);
template <typename Src>
constexpr CheckedNumeric& operator%=(const Src rhs);
template <typename Src>
constexpr CheckedNumeric& operator<<=(const Src rhs);
template <typename Src>
constexpr CheckedNumeric& operator>>=(const Src rhs);
template <typename Src>
constexpr CheckedNumeric& operator&=(const Src rhs);
template <typename Src>
constexpr CheckedNumeric& operator|=(const Src rhs);
template <typename Src>
constexpr CheckedNumeric& operator^=(const Src rhs);
constexpr CheckedNumeric operator-() const {
// The negation of two's complement int min is int min, so we simply
// check for that in the constexpr case.
// We use an optimized code path for a known run-time variable.
return MustTreatAsConstexpr(state_.value()) || !std::is_signed<T>::value ||
std::is_floating_point<T>::value
? CheckedNumeric<T>(
NegateWrapper(state_.value()),
IsValid() && (!std::is_signed<T>::value ||
std::is_floating_point<T>::value ||
NegateWrapper(state_.value()) !=
std::numeric_limits<T>::lowest()))
: FastRuntimeNegate();
}
constexpr CheckedNumeric operator~() const {
return CheckedNumeric<decltype(InvertWrapper(T()))>(
InvertWrapper(state_.value()), IsValid());
}
constexpr CheckedNumeric Abs() const {
return !IsValueNegative(state_.value()) ? *this : -*this;
}
template <typename U>
constexpr CheckedNumeric<typename MathWrapper<CheckedMaxOp, T, U>::type> Max(
const U rhs) const {
using R = typename UnderlyingType<U>::type;
using result_type = typename MathWrapper<CheckedMaxOp, T, U>::type;
// TODO(jschuh): This can be converted to the MathOp version and remain
// constexpr once we have C++14 support.
return CheckedNumeric<result_type>(
static_cast<result_type>(
IsGreater<T, R>::Test(state_.value(), Wrapper<U>::value(rhs))
? state_.value()
: Wrapper<U>::value(rhs)),
state_.is_valid() && Wrapper<U>::is_valid(rhs));
}
template <typename U>
constexpr CheckedNumeric<typename MathWrapper<CheckedMinOp, T, U>::type> Min(
const U rhs) const {
using R = typename UnderlyingType<U>::type;
using result_type = typename MathWrapper<CheckedMinOp, T, U>::type;
// TODO(jschuh): This can be converted to the MathOp version and remain
// constexpr once we have C++14 support.
return CheckedNumeric<result_type>(
static_cast<result_type>(
IsLess<T, R>::Test(state_.value(), Wrapper<U>::value(rhs))
? state_.value()
: Wrapper<U>::value(rhs)),
state_.is_valid() && Wrapper<U>::is_valid(rhs));
}
// This function is available only for integral types. It returns an unsigned
// integer of the same width as the source type, containing the absolute value
// of the source, and properly handling signed min.
constexpr CheckedNumeric<typename UnsignedOrFloatForSize<T>::type>
UnsignedAbs() const {
return CheckedNumeric<typename UnsignedOrFloatForSize<T>::type>(
SafeUnsignedAbs(state_.value()), state_.is_valid());
}
constexpr CheckedNumeric& operator++() {
*this += 1;
return *this;
}
constexpr CheckedNumeric operator++(int) {
CheckedNumeric value = *this;
*this += 1;
return value;
}
constexpr CheckedNumeric& operator--() {
*this -= 1;
return *this;
}
constexpr CheckedNumeric operator--(int) {
CheckedNumeric value = *this;
*this -= 1;
return value;
}
// These perform the actual math operations on the CheckedNumerics.
// Binary arithmetic operations.
template <template <typename, typename, typename> class M,
typename L,
typename R>
static constexpr CheckedNumeric MathOp(const L lhs, const R rhs) {
using Math = typename MathWrapper<M, L, R>::math;
T result = 0;
bool is_valid =
Wrapper<L>::is_valid(lhs) && Wrapper<R>::is_valid(rhs) &&
Math::Do(Wrapper<L>::value(lhs), Wrapper<R>::value(rhs), &result);
return CheckedNumeric<T>(result, is_valid);
}
// Assignment arithmetic operations.
template <template <typename, typename, typename> class M, typename R>
constexpr CheckedNumeric& MathOp(const R rhs) {
using Math = typename MathWrapper<M, T, R>::math;
T result = 0; // Using T as the destination saves a range check.
bool is_valid = state_.is_valid() && Wrapper<R>::is_valid(rhs) &&
Math::Do(state_.value(), Wrapper<R>::value(rhs), &result);
*this = CheckedNumeric<T>(result, is_valid);
return *this;
}
private:
CheckedNumericState<T> state_;
CheckedNumeric FastRuntimeNegate() const {
T result;
bool success = CheckedSubOp<T, T>::Do(T(0), state_.value(), &result);
return CheckedNumeric<T>(result, IsValid() && success);
}
template <typename Src>
constexpr CheckedNumeric(Src value, bool is_valid)
: state_(value, is_valid) {}
// These wrappers allow us to handle state the same way for both
// CheckedNumeric and POD arithmetic types.
template <typename Src>
struct Wrapper {
static constexpr bool is_valid(Src) { return true; }
static constexpr Src value(Src value) { return value; }
};
template <typename Src>
struct Wrapper<CheckedNumeric<Src>> {
static constexpr bool is_valid(const CheckedNumeric<Src> v) {
return v.IsValid();
}
static constexpr Src value(const CheckedNumeric<Src> v) {
return v.state_.value();
}
};
template <typename Src>
struct Wrapper<StrictNumeric<Src>> {
static constexpr bool is_valid(const StrictNumeric<Src>) { return true; }
static constexpr Src value(const StrictNumeric<Src> v) {
return static_cast<Src>(v);
}
};
};
// Convenience functions to avoid the ugly template disambiguator syntax.
template <typename Dst, typename Src>
constexpr bool IsValidForType(const CheckedNumeric<Src> value) {
return value.template IsValid<Dst>();
}
template <typename Dst, typename Src>
constexpr StrictNumeric<Dst> ValueOrDieForType(
const CheckedNumeric<Src> value) {
return value.template ValueOrDie<Dst>();
}
template <typename Dst, typename Src, typename Default>
constexpr StrictNumeric<Dst> ValueOrDefaultForType(
const CheckedNumeric<Src> value,
const Default default_value) {
return value.template ValueOrDefault<Dst>(default_value);
}
// Convience wrapper to return a new CheckedNumeric from the provided arithmetic
// or CheckedNumericType.
template <typename T>
constexpr CheckedNumeric<typename UnderlyingType<T>::type> MakeCheckedNum(
const T value) {
return value;
}
// These implement the variadic wrapper for the math operations.
template <template <typename, typename, typename> class M,
typename L,
typename R>
constexpr CheckedNumeric<typename MathWrapper<M, L, R>::type> CheckMathOp(
const L lhs,
const R rhs) {
using Math = typename MathWrapper<M, L, R>::math;
return CheckedNumeric<typename Math::result_type>::template MathOp<M>(lhs,
rhs);
}
// General purpose wrapper template for arithmetic operations.
template <template <typename, typename, typename> class M,
typename L,
typename R,
typename... Args>
constexpr CheckedNumeric<typename ResultType<M, L, R, Args...>::type>
CheckMathOp(const L lhs, const R rhs, const Args... args) {
return CheckMathOp<M>(CheckMathOp<M>(lhs, rhs), args...);
}
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, Add, +, +=)
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, Sub, -, -=)
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, Mul, *, *=)
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, Div, /, /=)
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, Mod, %, %=)
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, Lsh, <<, <<=)
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, Rsh, >>, >>=)
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, And, &, &=)
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, Or, |, |=)
BASE_NUMERIC_ARITHMETIC_OPERATORS(Checked, Check, Xor, ^, ^=)
BASE_NUMERIC_ARITHMETIC_VARIADIC(Checked, Check, Max)
BASE_NUMERIC_ARITHMETIC_VARIADIC(Checked, Check, Min)
// These are some extra StrictNumeric operators to support simple pointer
// arithmetic with our result types. Since wrapping on a pointer is always
// bad, we trigger the CHECK condition here.
template <typename L, typename R>
L* operator+(L* lhs, const StrictNumeric<R> rhs) {
uintptr_t result = CheckAdd(reinterpret_cast<uintptr_t>(lhs),
CheckMul(sizeof(L), static_cast<R>(rhs)))
.template ValueOrDie<uintptr_t>();
return reinterpret_cast<L*>(result);
}
template <typename L, typename R>
L* operator-(L* lhs, const StrictNumeric<R> rhs) {
uintptr_t result = CheckSub(reinterpret_cast<uintptr_t>(lhs),
CheckMul(sizeof(L), static_cast<R>(rhs)))
.template ValueOrDie<uintptr_t>();
return reinterpret_cast<L*>(result);
}
} // namespace internal
using internal::CheckedNumeric;
using internal::IsValidForType;
using internal::ValueOrDieForType;
using internal::ValueOrDefaultForType;
using internal::MakeCheckedNum;
using internal::CheckMax;
using internal::CheckMin;
using internal::CheckAdd;
using internal::CheckSub;
using internal::CheckMul;
using internal::CheckDiv;
using internal::CheckMod;
using internal::CheckLsh;
using internal::CheckRsh;
using internal::CheckAnd;
using internal::CheckOr;
using internal::CheckXor;
} // namespace base
#endif // BASE_NUMERICS_CHECKED_MATH_H_