src/tint/number.h - tint - Git at Google

 // Copyright 2021 The Tint Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #ifndef SRC_TINT_NUMBER_H_
 #define SRC_TINT_NUMBER_H_

 #include <stdint.h>
 #include <cmath>
 #include <functional>
 #include <limits>
 #include <optional>
 #include <ostream>

 #include "src/tint/traits.h"
 #include "src/tint/utils/compiler_macros.h"
 #include "src/tint/utils/result.h"

 // Forward declaration
 namespace tint {
 /// Number wraps a integer or floating point number, enforcing explicit casting.
 template <typename T>
 struct Number;
 }  // namespace tint

 namespace tint::detail {
 /// Base template for IsNumber
 template <typename T>
 struct IsNumber : std::false_type {};

 /// Specialization for IsNumber
 template <typename T>
 struct IsNumber<Number<T>> : std::true_type {};

 /// An empty structure used as a unique template type for Number when
 /// specializing for the f16 type.
 struct NumberKindF16 {};

 /// Helper for obtaining the underlying type for a Number.
 template <typename T>
 struct NumberUnwrapper {
     /// When T is not a Number, then type defined to be T.
     using type = T;
 };

 /// NumberUnwrapper specialization for Number<T>.
 template <typename T>
 struct NumberUnwrapper<Number<T>> {
     /// The Number's underlying type.
     using type = typename Number<T>::type;
 };

 }  // namespace tint::detail

 namespace tint {

 /// Evaluates to true iff T is a Number
 template <typename T>
 constexpr bool IsNumber = detail::IsNumber<T>::value;

 /// Resolves to the underlying type for a Number.
 template <typename T>
 using UnwrapNumber = typename detail::NumberUnwrapper<T>::type;

 /// Evaluates to true iff T or Number<T> is a floating-point type or is NumberKindF16.
 template <typename T, typename U = std::conditional_t<IsNumber<T>, UnwrapNumber<T>, T>>
 constexpr bool IsFloatingPoint =
     std::is_floating_point_v<U> || std::is_same_v<T, detail::NumberKindF16>;

 /// Evaluates to true iff T or Number<T> is an integral type.
 template <typename T>
 constexpr bool IsIntegral = std::is_integral_v<UnwrapNumber<T>>;

 /// Evaluates to true iff T or Number<T> is a signed integer type.
 template <typename T>
 constexpr bool IsSignedIntegral =
     std::is_integral_v<UnwrapNumber<T>> && std::is_signed_v<UnwrapNumber<T>>;

 /// Evaluates to true iff T or Number<T> is an unsigned integer type.
 template <typename T>
 constexpr bool IsUnsignedIntegral =
     std::is_integral_v<UnwrapNumber<T>> && std::is_unsigned_v<UnwrapNumber<T>>;

 /// Evaluates to true iff T is an integer type, floating-point type or is NumberKindF16.
 template <typename T>
 constexpr bool IsNumeric = IsIntegral<T> || IsFloatingPoint<T>;

 /// NumberBase is a CRTP base class for Number<T>
 template <typename NumberT>
 struct NumberBase {
     /// @returns value of type `Number<T>` with the highest value for that type.
     static NumberT Highest() { return NumberT(NumberT::kHighestValue); }
     /// @returns value of type `Number<T>` with the lowest value for that type.
     static NumberT Lowest() { return NumberT(NumberT::kLowestValue); }
     /// @returns value of type `Number<T>` with the smallest value for that type.
     static NumberT Smallest() { return NumberT(NumberT::kSmallestValue); }
     /// @returns value of type `Number<T>` that represents NaN for that type.
     static NumberT NaN() {
         return NumberT(std::numeric_limits<UnwrapNumber<NumberT>>::quiet_NaN());
     }
     /// @returns value of type `Number<T>` that represents infinity for that type.
     static NumberT Inf() { return NumberT(std::numeric_limits<UnwrapNumber<NumberT>>::infinity()); }
 };

 /// Number wraps a integer or floating point number, enforcing explicit casting.
 template <typename T>
 struct Number : NumberBase<Number<T>> {
     static_assert(IsNumeric<T>, "Number<T> constructed with non-numeric type");

     /// type is the underlying type of the Number
     using type = T;

     /// Highest finite representable value of this type.
     static constexpr type kHighestValue = std::numeric_limits<type>::max();

     /// Lowest finite representable value of this type.
     static constexpr type kLowestValue = std::numeric_limits<type>::lowest();

     /// Smallest positive normal value of this type.
     static constexpr type kSmallestValue =
         std::is_integral_v<type> ? 0 : std::numeric_limits<type>::min();

     /// Smallest positive subnormal value of this type, 0 for integral type.
     static constexpr type kSmallestSubnormalValue =
         std::is_integral_v<type> ? 0 : std::numeric_limits<type>::denorm_min();

     /// Constructor. The value is zero-initialized.
     Number() = default;

     /// Constructor.
     /// @param v the value to initialize this Number to
     template <typename U>
     explicit Number(U v) : value(static_cast<T>(v)) {}

     /// Constructor.
     /// @param v the value to initialize this Number to
     template <typename U>
     explicit Number(Number<U> v) : value(static_cast<T>(v.value)) {}

     /// Conversion operator
     /// @returns the value as T
     operator T() const { return value; }

     /// Negation operator
     /// @returns the negative value of the number
     Number operator-() const { return Number(-value); }

     /// Assignment operator
     /// @param v the new value
     /// @returns this Number so calls can be chained
     Number& operator=(T v) {
         value = v;
         return *this;
     }

     /// The number value
     type value = {};
 };

 /// Writes the number to the ostream.
 /// @param out the std::ostream to write to
 /// @param num the Number
 /// @return the std::ostream so calls can be chained
 template <typename T>
 inline std::ostream& operator<<(std::ostream& out, Number<T> num) {
     return out << num.value;
 }

 /// The partial specification of Number for f16 type, storing the f16 value as float,
 /// and enforcing proper explicit casting.
 template <>
 struct Number<detail::NumberKindF16> : NumberBase<Number<detail::NumberKindF16>> {
     /// C++ does not have a native float16 type, so we use a 32-bit float instead.
     using type = float;

     /// Highest finite representable value of this type.
     static constexpr type kHighestValue = 65504.0f;  // 2¹⁵ × (1 + 1023/1024)

     /// Lowest finite representable value of this type.
     static constexpr type kLowestValue = -65504.0f;

     /// Smallest positive normal value of this type.
     /// binary16 0_00001_0000000000, value is 2⁻¹⁴.
     static constexpr type kSmallestValue = 0x1p-14f;

     /// Smallest positive subnormal value of this type.
     /// binary16 0_00000_0000000001, value is 2⁻¹⁴ * 2⁻¹⁰ = 2⁻²⁴.
     static constexpr type kSmallestSubnormalValue = 0x1p-24f;

     /// Constructor. The value is zero-initialized.
     Number() = default;

     /// Constructor.
     /// @param v the value to initialize this Number to
     template <typename U>
     explicit Number(U v) : value(Quantize(static_cast<type>(v))) {}

     /// Constructor.
     /// @param v the value to initialize this Number to
     template <typename U>
     explicit Number(Number<U> v) : value(Quantize(static_cast<type>(v.value))) {}

     /// Conversion operator
     /// @returns the value as the internal representation type of F16
     operator float() const { return value; }

     /// Negation operator
     /// @returns the negative value of the number
     Number operator-() const { return Number<detail::NumberKindF16>(-value); }

     /// Assignment operator with parameter as native floating point type
     /// @param v the new value
     /// @returns this Number so calls can be chained
     Number& operator=(type v) {
         value = Quantize(v);
         return *this;
     }

     /// Get the binary16 bit pattern in type uint16_t of this value.
     /// @returns the binary16 bit pattern, in type uint16_t, of the stored quantized f16 value. If
     /// the value is NaN, the returned value will be 0x7e00u. If the value is positive infinity, the
     /// returned value will be 0x7c00u. If the input value is negative infinity, the returned value
     /// will be 0xfc00u.
     uint16_t BitsRepresentation() const;

     /// @param value the input float32 value
     /// @returns the float32 value quantized to the smaller float16 value, through truncation of the
     /// mantissa bits (no rounding). If the float32 value is too large (positive or negative) to be
     /// represented by a float16 value, then the returned value will be positive or negative
     /// infinity.
     static type Quantize(type value);

     /// The number value, stored as float
     type value = {};
 };

 /// `AInt` is a type alias to `Number<int64_t>`.
 using AInt = Number<int64_t>;
 /// `AFloat` is a type alias to `Number<double>`.
 using AFloat = Number<double>;

 /// `i32` is a type alias to `Number<int32_t>`.
 using i32 = Number<int32_t>;
 /// `u32` is a type alias to `Number<uint32_t>`.
 using u32 = Number<uint32_t>;
 /// `f32` is a type alias to `Number<float>`
 using f32 = Number<float>;
 /// `f16` is a type alias to `Number<detail::NumberKindF16>`, which should be IEEE 754 binary16.
 /// However since C++ don't have native binary16 type, the value is stored as float.
 using f16 = Number<detail::NumberKindF16>;

 /// @returns the friendly name of Number type T
 template <typename T, traits::EnableIf<IsNumber<T>>* = nullptr>
 const char* FriendlyName() {
     if constexpr (std::is_same_v<T, AInt>) {
         return "abstract-int";
     } else if constexpr (std::is_same_v<T, AFloat>) {
         return "abstract-float";
     } else if constexpr (std::is_same_v<T, i32>) {
         return "i32";
     } else if constexpr (std::is_same_v<T, u32>) {
         return "u32";
     } else if constexpr (std::is_same_v<T, f32>) {
         return "f32";
     } else if constexpr (std::is_same_v<T, f16>) {
         return "f16";
     } else {
         static_assert(!sizeof(T), "Unhandled type");
     }
 }

 /// @returns the friendly name of T when T is bool
 template <typename T, traits::EnableIf<std::is_same_v<T, bool>>* = nullptr>
 const char* FriendlyName() {
     return "bool";
 }

 /// Enumerator of failure reasons when converting from one number to another.
 enum class ConversionFailure {
     kExceedsPositiveLimit,  // The value was too big (+'ve) to fit in the target type
     kExceedsNegativeLimit,  // The value was too big (-'ve) to fit in the target type
 };

 /// Writes the conversion failure message to the ostream.
 /// @param out the std::ostream to write to
 /// @param failure the ConversionFailure
 /// @return the std::ostream so calls can be chained
 std::ostream& operator<<(std::ostream& out, ConversionFailure failure);

 /// Converts a number from one type to another, checking that the value fits in the target type.
 /// @returns the resulting value of the conversion, or a failure reason.
 template <typename TO, typename FROM>
 utils::Result<TO, ConversionFailure> CheckedConvert(Number<FROM> num) {
     // Use the highest-precision integer or floating-point type to perform the comparisons.
     using T = std::conditional_t<IsFloatingPoint<UnwrapNumber<TO>> || IsFloatingPoint<FROM>,
                                  AFloat::type, AInt::type>;
     const auto value = static_cast<T>(num.value);
     if (value > static_cast<T>(TO::kHighestValue)) {
         return ConversionFailure::kExceedsPositiveLimit;
     }
     if (value < static_cast<T>(TO::kLowestValue)) {
         return ConversionFailure::kExceedsNegativeLimit;
     }
     return TO(value);  // Success
 }

 /// Equality operator.
 /// @param a the LHS number
 /// @param b the RHS number
 /// @returns true if the numbers `a` and `b` are exactly equal. Also considers sign bit.
 template <typename A, typename B>
 bool operator==(Number<A> a, Number<B> b) {
     // Use the highest-precision integer or floating-point type to perform the comparisons.
     using T =
         std::conditional_t<IsFloatingPoint<A> || IsFloatingPoint<B>, AFloat::type, AInt::type>;
     auto va = static_cast<T>(a.value);
     auto vb = static_cast<T>(b.value);
     if constexpr (IsFloatingPoint<T>) {
         if (std::signbit(va) != std::signbit(vb)) {
             return false;
         }
     }
     return std::equal_to<T>()(va, vb);
 }

 /// Inequality operator.
 /// @param a the LHS number
 /// @param b the RHS number
 /// @returns true if the numbers `a` and `b` are exactly unequal. Also considers sign bit.
 template <typename A, typename B>
 bool operator!=(Number<A> a, Number<B> b) {
     return !(a == b);
 }

 /// Equality operator.
 /// @param a the LHS number
 /// @param b the RHS number
 /// @returns true if the numbers `a` and `b` are exactly equal.
 template <typename A, typename B>
 std::enable_if_t<IsNumeric<B>, bool> operator==(Number<A> a, B b) {
     return a == Number<B>(b);
 }

 /// Inequality operator.
 /// @param a the LHS number
 /// @param b the RHS number
 /// @returns true if the numbers `a` and `b` are exactly unequal.
 template <typename A, typename B>
 std::enable_if_t<IsNumeric<B>, bool> operator!=(Number<A> a, B b) {
     return !(a == b);
 }

 /// Equality operator.
 /// @param a the LHS number
 /// @param b the RHS number
 /// @returns true if the numbers `a` and `b` are exactly equal.
 template <typename A, typename B>
 std::enable_if_t<IsNumeric<A>, bool> operator==(A a, Number<B> b) {
     return Number<A>(a) == b;
 }

 /// Inequality operator.
 /// @param a the LHS number
 /// @param b the RHS number
 /// @returns true if the numbers `a` and `b` are exactly unequal.
 template <typename A, typename B>
 std::enable_if_t<IsNumeric<A>, bool> operator!=(A a, Number<B> b) {
     return !(a == b);
 }

 /// Define 'TINT_HAS_OVERFLOW_BUILTINS' if the compiler provide overflow checking builtins.
 /// If the compiler does not support these builtins, then these are emulated with algorithms
 /// described in:
 /// https://wiki.sei.cmu.edu/confluence/display/c/INT32-C.+Ensure+that+operations+on+signed+integers+do+not+result+in+overflow
 #if defined(__GNUC__) && __GNUC__ >= 5
 #define TINT_HAS_OVERFLOW_BUILTINS
 #elif defined(__clang__)
 #if __has_builtin(__builtin_add_overflow) && __has_builtin(__builtin_mul_overflow)
 #define TINT_HAS_OVERFLOW_BUILTINS
 #endif
 #endif

 /// @returns a + b, or an empty optional if the resulting value overflowed the AInt
 inline std::optional<AInt> CheckedAdd(AInt a, AInt b) {
     int64_t result;
 #ifdef TINT_HAS_OVERFLOW_BUILTINS
     if (__builtin_add_overflow(a.value, b.value, &result)) {
         return {};
     }
 #else   // TINT_HAS_OVERFLOW_BUILTINS
     if (a.value >= 0) {
         if (b.value > AInt::kHighestValue - a.value) {
             return {};
         }
     } else {
         if (b.value < AInt::kLowestValue - a.value) {
             return {};
         }
     }
     result = a.value + b.value;
 #endif  // TINT_HAS_OVERFLOW_BUILTINS
     return AInt(result);
 }

 /// @returns a + b, or an empty optional if the resulting value overflowed the AFloat
 inline std::optional<AFloat> CheckedAdd(AFloat a, AFloat b) {
     auto result = a.value + b.value;
     if (!std::isfinite(result)) {
         return {};
     }
     return AFloat{result};
 }

 /// @returns a - b, or an empty optional if the resulting value overflowed the AInt
 inline std::optional<AInt> CheckedSub(AInt a, AInt b) {
     int64_t result;
 #ifdef TINT_HAS_OVERFLOW_BUILTINS
     if (__builtin_sub_overflow(a.value, b.value, &result)) {
         return {};
     }
 #else   // TINT_HAS_OVERFLOW_BUILTINS
     if (b.value >= 0) {
         if (a.value < AInt::kLowestValue + b.value) {
             return {};
         }
     } else {
         if (a.value > AInt::kHighestValue + b.value) {
             return {};
         }
     }
     result = a.value - b.value;
 #endif  // TINT_HAS_OVERFLOW_BUILTINS
     return AInt(result);
 }

 /// @returns a + b, or an empty optional if the resulting value overflowed the AFloat
 inline std::optional<AFloat> CheckedSub(AFloat a, AFloat b) {
     auto result = a.value - b.value;
     if (!std::isfinite(result)) {
         return {};
     }
     return AFloat{result};
 }

 /// @returns a * b, or an empty optional if the resulting value overflowed the AInt
 inline std::optional<AInt> CheckedMul(AInt a, AInt b) {
     int64_t result;
 #ifdef TINT_HAS_OVERFLOW_BUILTINS
     if (__builtin_mul_overflow(a.value, b.value, &result)) {
         return {};
     }
 #else   // TINT_HAS_OVERFLOW_BUILTINS
     if (a > 0) {
         if (b > 0) {
             if (a > (AInt::kHighestValue / b)) {
                 return {};
             }
         } else {
             if (b < (AInt::kLowestValue / a)) {
                 return {};
             }
         }
     } else {
         if (b > 0) {
             if (a < (AInt::kLowestValue / b)) {
                 return {};
             }
         } else {
             if ((a != 0) && (b < (AInt::kHighestValue / a))) {
                 return {};
             }
         }
     }
     result = a.value * b.value;
 #endif  // TINT_HAS_OVERFLOW_BUILTINS
     return AInt(result);
 }

 /// @returns a * b, or an empty optional if the resulting value overflowed the AFloat
 inline std::optional<AFloat> CheckedMul(AFloat a, AFloat b) {
     auto result = a.value * b.value;
     if (!std::isfinite(result)) {
         return {};
     }
     return AFloat{result};
 }

 /// @returns a / b, or an empty optional if the resulting value overflowed the AInt
 inline std::optional<AInt> CheckedDiv(AInt a, AInt b) {
     if (b == 0) {
         return {};
     }

     if (b == -1 && a == AInt::Lowest()) {
         return {};
     }

     return AInt{a.value / b.value};
 }

 /// @returns a / b, or an empty optional if the resulting value overflowed the AFloat
 inline std::optional<AFloat> CheckedDiv(AFloat a, AFloat b) {
     auto result = a.value / b.value;
     if (!std::isfinite(result)) {
         return {};
     }
     return AFloat{result};
 }

 /// @returns a * b + c, or an empty optional if the value overflowed the AInt
 inline std::optional<AInt> CheckedMadd(AInt a, AInt b, AInt c) {
     // https://gcc.gnu.org/bugzilla/show_bug.cgi?id=80635
     TINT_BEGIN_DISABLE_WARNING(MAYBE_UNINITIALIZED);

     if (auto mul = CheckedMul(a, b)) {
         return CheckedAdd(mul.value(), c);
     }
     return {};

     TINT_END_DISABLE_WARNING(MAYBE_UNINITIALIZED);
 }

 }  // namespace tint

 namespace tint::number_suffixes {

 /// Literal suffix for abstract integer literals
 inline AInt operator""_a(unsigned long long int value) {  // NOLINT
     return AInt(static_cast<int64_t>(value));
 }

 /// Literal suffix for abstract float literals
 inline AFloat operator""_a(long double value) {  // NOLINT
     return AFloat(static_cast<double>(value));
 }

 /// Literal suffix for i32 literals
 inline i32 operator""_i(unsigned long long int value) {  // NOLINT
     return i32(static_cast<int32_t>(value));
 }

 /// Literal suffix for u32 literals
 inline u32 operator""_u(unsigned long long int value) {  // NOLINT
     return u32(static_cast<uint32_t>(value));
 }

 /// Literal suffix for f32 literals
 inline f32 operator""_f(long double value) {  // NOLINT
     return f32(static_cast<double>(value));
 }

 /// Literal suffix for f32 literals
 inline f32 operator""_f(unsigned long long int value) {  // NOLINT
     return f32(static_cast<double>(value));
 }

 /// Literal suffix for f16 literals
 inline f16 operator""_h(long double value) {  // NOLINT
     return f16(static_cast<double>(value));
 }

 /// Literal suffix for f16 literals
 inline f16 operator""_h(unsigned long long int value) {  // NOLINT
     return f16(static_cast<double>(value));
 }

 }  // namespace tint::number_suffixes

 namespace std {

 /// Custom std::hash specialization for tint::Number<T>
 template <typename T>
 class hash<tint::Number<T>> {
   public:
     /// @param n the Number
     /// @return the hash value
     inline std::size_t operator()(const tint::Number<T>& n) const {
         return std::hash<decltype(n.value)>()(n.value);
     }
 };

 }  // namespace std

 #endif  // SRC_TINT_NUMBER_H_
	// Copyright 2021 The Tint Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#ifndef SRC_TINT_NUMBER_H_
	#define SRC_TINT_NUMBER_H_

	#include <stdint.h>
	#include <cmath>
	#include <functional>
	#include <limits>
	#include <optional>
	#include <ostream>

	#include "src/tint/traits.h"
	#include "src/tint/utils/compiler_macros.h"
	#include "src/tint/utils/result.h"

	// Forward declaration
	namespace tint {
	/// Number wraps a integer or floating point number, enforcing explicit casting.
	template <typename T>
	struct Number;
	} // namespace tint

	namespace tint::detail {
	/// Base template for IsNumber
	template <typename T>
	struct IsNumber : std::false_type {};

	/// Specialization for IsNumber
	template <typename T>
	struct IsNumber<Number<T>> : std::true_type {};

	/// An empty structure used as a unique template type for Number when
	/// specializing for the f16 type.
	struct NumberKindF16 {};

	/// Helper for obtaining the underlying type for a Number.
	template <typename T>
	struct NumberUnwrapper {
	/// When T is not a Number, then type defined to be T.
	using type = T;
	};

	/// NumberUnwrapper specialization for Number<T>.
	template <typename T>
	struct NumberUnwrapper<Number<T>> {
	/// The Number's underlying type.
	using type = typename Number<T>::type;
	};

	} // namespace tint::detail

	namespace tint {

	/// Evaluates to true iff T is a Number
	template <typename T>
	constexpr bool IsNumber = detail::IsNumber<T>::value;

	/// Resolves to the underlying type for a Number.
	template <typename T>
	using UnwrapNumber = typename detail::NumberUnwrapper<T>::type;

	/// Evaluates to true iff T or Number<T> is a floating-point type or is NumberKindF16.
	template <typename T, typename U = std::conditional_t<IsNumber<T>, UnwrapNumber<T>, T>>
	constexpr bool IsFloatingPoint =
	std::is_floating_point_v<U> \|\| std::is_same_v<T, detail::NumberKindF16>;

	/// Evaluates to true iff T or Number<T> is an integral type.
	template <typename T>
	constexpr bool IsIntegral = std::is_integral_v<UnwrapNumber<T>>;

	/// Evaluates to true iff T or Number<T> is a signed integer type.
	template <typename T>
	constexpr bool IsSignedIntegral =
	std::is_integral_v<UnwrapNumber<T>> && std::is_signed_v<UnwrapNumber<T>>;

	/// Evaluates to true iff T or Number<T> is an unsigned integer type.
	template <typename T>
	constexpr bool IsUnsignedIntegral =
	std::is_integral_v<UnwrapNumber<T>> && std::is_unsigned_v<UnwrapNumber<T>>;

	/// Evaluates to true iff T is an integer type, floating-point type or is NumberKindF16.
	template <typename T>
	constexpr bool IsNumeric = IsIntegral<T> \|\| IsFloatingPoint<T>;

	/// NumberBase is a CRTP base class for Number<T>
	template <typename NumberT>
	struct NumberBase {
	/// @returns value of type `Number<T>` with the highest value for that type.
	static NumberT Highest() { return NumberT(NumberT::kHighestValue); }
	/// @returns value of type `Number<T>` with the lowest value for that type.
	static NumberT Lowest() { return NumberT(NumberT::kLowestValue); }
	/// @returns value of type `Number<T>` with the smallest value for that type.
	static NumberT Smallest() { return NumberT(NumberT::kSmallestValue); }
	/// @returns value of type `Number<T>` that represents NaN for that type.
	static NumberT NaN() {
	return NumberT(std::numeric_limits<UnwrapNumber<NumberT>>::quiet_NaN());
	}
	/// @returns value of type `Number<T>` that represents infinity for that type.
	static NumberT Inf() { return NumberT(std::numeric_limits<UnwrapNumber<NumberT>>::infinity()); }
	};

	/// Number wraps a integer or floating point number, enforcing explicit casting.
	template <typename T>
	struct Number : NumberBase<Number<T>> {
	static_assert(IsNumeric<T>, "Number<T> constructed with non-numeric type");

	/// type is the underlying type of the Number
	using type = T;

	/// Highest finite representable value of this type.
	static constexpr type kHighestValue = std::numeric_limits<type>::max();

	/// Lowest finite representable value of this type.
	static constexpr type kLowestValue = std::numeric_limits<type>::lowest();

	/// Smallest positive normal value of this type.
	static constexpr type kSmallestValue =
	std::is_integral_v<type> ? 0 : std::numeric_limits<type>::min();

	/// Smallest positive subnormal value of this type, 0 for integral type.
	static constexpr type kSmallestSubnormalValue =
	std::is_integral_v<type> ? 0 : std::numeric_limits<type>::denorm_min();

	/// Constructor. The value is zero-initialized.
	Number() = default;

	/// Constructor.
	/// @param v the value to initialize this Number to
	template <typename U>
	explicit Number(U v) : value(static_cast<T>(v)) {}

	/// Constructor.
	/// @param v the value to initialize this Number to
	template <typename U>
	explicit Number(Number<U> v) : value(static_cast<T>(v.value)) {}

	/// Conversion operator
	/// @returns the value as T
	operator T() const { return value; }

	/// Negation operator
	/// @returns the negative value of the number
	Number operator-() const { return Number(-value); }

	/// Assignment operator
	/// @param v the new value
	/// @returns this Number so calls can be chained
	Number& operator=(T v) {
	value = v;
	return *this;
	}

	/// The number value
	type value = {};
	};

	/// Writes the number to the ostream.
	/// @param out the std::ostream to write to
	/// @param num the Number
	/// @return the std::ostream so calls can be chained
	template <typename T>
	inline std::ostream& operator<<(std::ostream& out, Number<T> num) {
	return out << num.value;
	}

	/// The partial specification of Number for f16 type, storing the f16 value as float,
	/// and enforcing proper explicit casting.
	template <>
	struct Number<detail::NumberKindF16> : NumberBase<Number<detail::NumberKindF16>> {
	/// C++ does not have a native float16 type, so we use a 32-bit float instead.
	using type = float;

	/// Highest finite representable value of this type.
	static constexpr type kHighestValue = 65504.0f; // 2¹⁵ × (1 + 1023/1024)

	/// Lowest finite representable value of this type.
	static constexpr type kLowestValue = -65504.0f;

	/// Smallest positive normal value of this type.
	/// binary16 0_00001_0000000000, value is 2⁻¹⁴.
	static constexpr type kSmallestValue = 0x1p-14f;

	/// Smallest positive subnormal value of this type.
	/// binary16 0_00000_0000000001, value is 2⁻¹⁴ * 2⁻¹⁰ = 2⁻²⁴.
	static constexpr type kSmallestSubnormalValue = 0x1p-24f;

	/// Constructor. The value is zero-initialized.
	Number() = default;

	/// Constructor.
	/// @param v the value to initialize this Number to
	template <typename U>
	explicit Number(U v) : value(Quantize(static_cast<type>(v))) {}

	/// Constructor.
	/// @param v the value to initialize this Number to
	template <typename U>
	explicit Number(Number<U> v) : value(Quantize(static_cast<type>(v.value))) {}

	/// Conversion operator
	/// @returns the value as the internal representation type of F16
	operator float() const { return value; }

	/// Negation operator
	/// @returns the negative value of the number
	Number operator-() const { return Number<detail::NumberKindF16>(-value); }

	/// Assignment operator with parameter as native floating point type
	/// @param v the new value
	/// @returns this Number so calls can be chained
	Number& operator=(type v) {
	value = Quantize(v);
	return *this;
	}

	/// Get the binary16 bit pattern in type uint16_t of this value.
	/// @returns the binary16 bit pattern, in type uint16_t, of the stored quantized f16 value. If
	/// the value is NaN, the returned value will be 0x7e00u. If the value is positive infinity, the
	/// returned value will be 0x7c00u. If the input value is negative infinity, the returned value
	/// will be 0xfc00u.
	uint16_t BitsRepresentation() const;

	/// @param value the input float32 value
	/// @returns the float32 value quantized to the smaller float16 value, through truncation of the
	/// mantissa bits (no rounding). If the float32 value is too large (positive or negative) to be
	/// represented by a float16 value, then the returned value will be positive or negative
	/// infinity.
	static type Quantize(type value);

	/// The number value, stored as float
	type value = {};
	};

	/// `AInt` is a type alias to `Number<int64_t>`.
	using AInt = Number<int64_t>;
	/// `AFloat` is a type alias to `Number<double>`.
	using AFloat = Number<double>;

	/// `i32` is a type alias to `Number<int32_t>`.
	using i32 = Number<int32_t>;
	/// `u32` is a type alias to `Number<uint32_t>`.
	using u32 = Number<uint32_t>;
	/// `f32` is a type alias to `Number<float>`
	using f32 = Number<float>;
	/// `f16` is a type alias to `Number<detail::NumberKindF16>`, which should be IEEE 754 binary16.
	/// However since C++ don't have native binary16 type, the value is stored as float.
	using f16 = Number<detail::NumberKindF16>;

	/// @returns the friendly name of Number type T
	template <typename T, traits::EnableIf<IsNumber<T>>* = nullptr>
	const char* FriendlyName() {
	if constexpr (std::is_same_v<T, AInt>) {
	return "abstract-int";
	} else if constexpr (std::is_same_v<T, AFloat>) {
	return "abstract-float";
	} else if constexpr (std::is_same_v<T, i32>) {
	return "i32";
	} else if constexpr (std::is_same_v<T, u32>) {
	return "u32";
	} else if constexpr (std::is_same_v<T, f32>) {
	return "f32";
	} else if constexpr (std::is_same_v<T, f16>) {
	return "f16";
	} else {
	static_assert(!sizeof(T), "Unhandled type");
	}
	}

	/// @returns the friendly name of T when T is bool
	template <typename T, traits::EnableIf<std::is_same_v<T, bool>>* = nullptr>
	const char* FriendlyName() {
	return "bool";
	}

	/// Enumerator of failure reasons when converting from one number to another.
	enum class ConversionFailure {
	kExceedsPositiveLimit, // The value was too big (+'ve) to fit in the target type
	kExceedsNegativeLimit, // The value was too big (-'ve) to fit in the target type
	};

	/// Writes the conversion failure message to the ostream.
	/// @param out the std::ostream to write to
	/// @param failure the ConversionFailure
	/// @return the std::ostream so calls can be chained
	std::ostream& operator<<(std::ostream& out, ConversionFailure failure);

	/// Converts a number from one type to another, checking that the value fits in the target type.
	/// @returns the resulting value of the conversion, or a failure reason.
	template <typename TO, typename FROM>
	utils::Result<TO, ConversionFailure> CheckedConvert(Number<FROM> num) {
	// Use the highest-precision integer or floating-point type to perform the comparisons.
	using T = std::conditional_t<IsFloatingPoint<UnwrapNumber<TO>> \|\| IsFloatingPoint<FROM>,
	AFloat::type, AInt::type>;
	const auto value = static_cast<T>(num.value);
	if (value > static_cast<T>(TO::kHighestValue)) {
	return ConversionFailure::kExceedsPositiveLimit;
	}
	if (value < static_cast<T>(TO::kLowestValue)) {
	return ConversionFailure::kExceedsNegativeLimit;
	}
	return TO(value); // Success
	}

	/// Equality operator.
	/// @param a the LHS number
	/// @param b the RHS number
	/// @returns true if the numbers `a` and `b` are exactly equal. Also considers sign bit.
	template <typename A, typename B>
	bool operator==(Number<A> a, Number<B> b) {
	// Use the highest-precision integer or floating-point type to perform the comparisons.
	using T =
	std::conditional_t<IsFloatingPoint<A> \|\| IsFloatingPoint<B>, AFloat::type, AInt::type>;
	auto va = static_cast<T>(a.value);
	auto vb = static_cast<T>(b.value);
	if constexpr (IsFloatingPoint<T>) {
	if (std::signbit(va) != std::signbit(vb)) {
	return false;
	}
	}
	return std::equal_to<T>()(va, vb);
	}

	/// Inequality operator.
	/// @param a the LHS number
	/// @param b the RHS number
	/// @returns true if the numbers `a` and `b` are exactly unequal. Also considers sign bit.
	template <typename A, typename B>
	bool operator!=(Number<A> a, Number<B> b) {
	return !(a == b);
	}

	/// Equality operator.
	/// @param a the LHS number
	/// @param b the RHS number
	/// @returns true if the numbers `a` and `b` are exactly equal.
	template <typename A, typename B>
	std::enable_if_t<IsNumeric<B>, bool> operator==(Number<A> a, B b) {
	return a == Number<B>(b);
	}

	/// Inequality operator.
	/// @param a the LHS number
	/// @param b the RHS number
	/// @returns true if the numbers `a` and `b` are exactly unequal.
	template <typename A, typename B>
	std::enable_if_t<IsNumeric<B>, bool> operator!=(Number<A> a, B b) {
	return !(a == b);
	}

	/// Equality operator.
	/// @param a the LHS number
	/// @param b the RHS number
	/// @returns true if the numbers `a` and `b` are exactly equal.
	template <typename A, typename B>
	std::enable_if_t<IsNumeric<A>, bool> operator==(A a, Number<B> b) {
	return Number<A>(a) == b;
	}

	/// Inequality operator.
	/// @param a the LHS number
	/// @param b the RHS number
	/// @returns true if the numbers `a` and `b` are exactly unequal.
	template <typename A, typename B>
	std::enable_if_t<IsNumeric<A>, bool> operator!=(A a, Number<B> b) {
	return !(a == b);
	}

	/// Define 'TINT_HAS_OVERFLOW_BUILTINS' if the compiler provide overflow checking builtins.
	/// If the compiler does not support these builtins, then these are emulated with algorithms
	/// described in:
	/// https://wiki.sei.cmu.edu/confluence/display/c/INT32-C.+Ensure+that+operations+on+signed+integers+do+not+result+in+overflow
	#if defined(__GNUC__) && __GNUC__ >= 5
	#define TINT_HAS_OVERFLOW_BUILTINS
	#elif defined(__clang__)
	#if __has_builtin(__builtin_add_overflow) && __has_builtin(__builtin_mul_overflow)
	#define TINT_HAS_OVERFLOW_BUILTINS
	#endif
	#endif

	/// @returns a + b, or an empty optional if the resulting value overflowed the AInt
	inline std::optional<AInt> CheckedAdd(AInt a, AInt b) {
	int64_t result;
	#ifdef TINT_HAS_OVERFLOW_BUILTINS
	if (__builtin_add_overflow(a.value, b.value, &result)) {
	return {};
	}
	#else // TINT_HAS_OVERFLOW_BUILTINS
	if (a.value >= 0) {
	if (b.value > AInt::kHighestValue - a.value) {
	return {};
	}
	} else {
	if (b.value < AInt::kLowestValue - a.value) {
	return {};
	}
	}
	result = a.value + b.value;
	#endif // TINT_HAS_OVERFLOW_BUILTINS
	return AInt(result);
	}

	/// @returns a + b, or an empty optional if the resulting value overflowed the AFloat
	inline std::optional<AFloat> CheckedAdd(AFloat a, AFloat b) {
	auto result = a.value + b.value;
	if (!std::isfinite(result)) {
	return {};
	}
	return AFloat{result};
	}

	/// @returns a - b, or an empty optional if the resulting value overflowed the AInt
	inline std::optional<AInt> CheckedSub(AInt a, AInt b) {
	int64_t result;
	#ifdef TINT_HAS_OVERFLOW_BUILTINS
	if (__builtin_sub_overflow(a.value, b.value, &result)) {
	return {};
	}
	#else // TINT_HAS_OVERFLOW_BUILTINS
	if (b.value >= 0) {
	if (a.value < AInt::kLowestValue + b.value) {
	return {};
	}
	} else {
	if (a.value > AInt::kHighestValue + b.value) {
	return {};
	}
	}
	result = a.value - b.value;
	#endif // TINT_HAS_OVERFLOW_BUILTINS
	return AInt(result);
	}

	/// @returns a + b, or an empty optional if the resulting value overflowed the AFloat
	inline std::optional<AFloat> CheckedSub(AFloat a, AFloat b) {
	auto result = a.value - b.value;
	if (!std::isfinite(result)) {
	return {};
	}
	return AFloat{result};
	}

	/// @returns a * b, or an empty optional if the resulting value overflowed the AInt
	inline std::optional<AInt> CheckedMul(AInt a, AInt b) {
	int64_t result;
	#ifdef TINT_HAS_OVERFLOW_BUILTINS
	if (__builtin_mul_overflow(a.value, b.value, &result)) {
	return {};
	}
	#else // TINT_HAS_OVERFLOW_BUILTINS
	if (a > 0) {
	if (b > 0) {
	if (a > (AInt::kHighestValue / b)) {
	return {};
	}
	} else {
	if (b < (AInt::kLowestValue / a)) {
	return {};
	}
	}
	} else {
	if (b > 0) {
	if (a < (AInt::kLowestValue / b)) {
	return {};
	}
	} else {
	if ((a != 0) && (b < (AInt::kHighestValue / a))) {
	return {};
	}
	}
	}
	result = a.value * b.value;
	#endif // TINT_HAS_OVERFLOW_BUILTINS
	return AInt(result);
	}

	/// @returns a * b, or an empty optional if the resulting value overflowed the AFloat
	inline std::optional<AFloat> CheckedMul(AFloat a, AFloat b) {
	auto result = a.value * b.value;
	if (!std::isfinite(result)) {
	return {};
	}
	return AFloat{result};
	}

	/// @returns a / b, or an empty optional if the resulting value overflowed the AInt
	inline std::optional<AInt> CheckedDiv(AInt a, AInt b) {
	if (b == 0) {
	return {};
	}

	if (b == -1 && a == AInt::Lowest()) {
	return {};
	}

	return AInt{a.value / b.value};
	}

	/// @returns a / b, or an empty optional if the resulting value overflowed the AFloat
	inline std::optional<AFloat> CheckedDiv(AFloat a, AFloat b) {
	auto result = a.value / b.value;
	if (!std::isfinite(result)) {
	return {};
	}
	return AFloat{result};
	}

	/// @returns a * b + c, or an empty optional if the value overflowed the AInt
	inline std::optional<AInt> CheckedMadd(AInt a, AInt b, AInt c) {
	// https://gcc.gnu.org/bugzilla/show_bug.cgi?id=80635
	TINT_BEGIN_DISABLE_WARNING(MAYBE_UNINITIALIZED);

	if (auto mul = CheckedMul(a, b)) {
	return CheckedAdd(mul.value(), c);
	}
	return {};

	TINT_END_DISABLE_WARNING(MAYBE_UNINITIALIZED);
	}

	} // namespace tint

	namespace tint::number_suffixes {

	/// Literal suffix for abstract integer literals
	inline AInt operator""_a(unsigned long long int value) { // NOLINT
	return AInt(static_cast<int64_t>(value));
	}

	/// Literal suffix for abstract float literals
	inline AFloat operator""_a(long double value) { // NOLINT
	return AFloat(static_cast<double>(value));
	}

	/// Literal suffix for i32 literals
	inline i32 operator""_i(unsigned long long int value) { // NOLINT
	return i32(static_cast<int32_t>(value));
	}

	/// Literal suffix for u32 literals
	inline u32 operator""_u(unsigned long long int value) { // NOLINT
	return u32(static_cast<uint32_t>(value));
	}

	/// Literal suffix for f32 literals
	inline f32 operator""_f(long double value) { // NOLINT
	return f32(static_cast<double>(value));
	}

	/// Literal suffix for f32 literals
	inline f32 operator""_f(unsigned long long int value) { // NOLINT
	return f32(static_cast<double>(value));
	}

	/// Literal suffix for f16 literals
	inline f16 operator""_h(long double value) { // NOLINT
	return f16(static_cast<double>(value));
	}

	/// Literal suffix for f16 literals
	inline f16 operator""_h(unsigned long long int value) { // NOLINT
	return f16(static_cast<double>(value));
	}

	} // namespace tint::number_suffixes

	namespace std {

	/// Custom std::hash specialization for tint::Number<T>
	template <typename T>
	class hash<tint::Number<T>> {
	public:
	/// @param n the Number
	/// @return the hash value
	inline std::size_t operator()(const tint::Number<T>& n) const {
	return std::hash<decltype(n.value)>()(n.value);
	}
	};

	} // namespace std

	#endif // SRC_TINT_NUMBER_H_