/- Copyright (c) 2020 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura -/ module prelude public import Init.Core public import Init.Data.Int.Basic public import Init.Data.ToString.Basic public section structure FloatSpec where float : Type val : float lt : float → float → Prop le : float → float → Prop decLt : DecidableRel lt decLe : DecidableRel le -- Just show FloatSpec is inhabited. opaque floatSpec : FloatSpec := { float := Unit, val := (), lt := fun _ _ => True, le := fun _ _ => True, decLt := fun _ _ => inferInstanceAs (Decidable True), decLe := fun _ _ => inferInstanceAs (Decidable True) } /-- 64-bit floating-point numbers. `Float` corresponds to the IEEE 754 *binary64* format (`double` in C or `f64` in Rust). Floating-point numbers are a finite representation of a subset of the real numbers, extended with extra “sentinel” values that represent undefined and infinite results as well as separate positive and negative zeroes. Arithmetic on floating-point numbers approximates the corresponding operations on the real numbers by rounding the results to numbers that are representable, propagating error and infinite values. Floating-point numbers include [subnormal numbers](https://en.wikipedia.org/wiki/Subnormal_number). Their special values are: * `NaN`, which denotes a class of “not a number” values that result from operations such as dividing zero by zero, and * `Inf` and `-Inf`, which represent positive and infinities that result from dividing non-zero values by zero. -/ structure Float where val : floatSpec.float instance : Nonempty Float := ⟨{ val := floatSpec.val }⟩ /-- Adds two 64-bit floating-point numbers according to IEEE 754. Typically used via the `+` operator. This function does not reduce in the kernel. It is compiled to the C addition operator. -/ @[extern "lean_float_add"] opaque Float.add : Float → Float → Float /-- Subtracts 64-bit floating-point numbers according to IEEE 754. Typically used via the `-` operator. This function does not reduce in the kernel. It is compiled to the C subtraction operator. -/ @[extern "lean_float_sub"] opaque Float.sub : Float → Float → Float /-- Multiplies 64-bit floating-point numbers according to IEEE 754. Typically used via the `*` operator. This function does not reduce in the kernel. It is compiled to the C multiplication operator. -/ @[extern "lean_float_mul"] opaque Float.mul : Float → Float → Float /-- Divides 64-bit floating-point numbers according to IEEE 754. Typically used via the `/` operator. In Lean, division by zero typically yields zero. For `Float`, it instead yields either `Inf`, `-Inf`, or `NaN`. This function does not reduce in the kernel. It is compiled to the C division operator. -/ @[extern "lean_float_div"] opaque Float.div : Float → Float → Float /-- Negates 64-bit floating-point numbers according to IEEE 754. Typically used via the `-` prefix operator. This function does not reduce in the kernel. It is compiled to the C negation operator. -/ @[extern "lean_float_negate"] opaque Float.neg : Float → Float set_option bootstrap.genMatcherCode false /-- Strict inequality of floating-point numbers. Typically used via the `<` operator. -/ def Float.lt : Float → Float → Prop := fun a b => match a, b with | ⟨a⟩, ⟨b⟩ => floatSpec.lt a b /-- Non-strict inequality of floating-point numbers. Typically used via the `≤` operator. -/ def Float.le : Float → Float → Prop := fun a b => floatSpec.le a.val b.val /-- Bit-for-bit conversion from `UInt64`. Interprets a `UInt64` as a `Float`, ignoring the numeric value and treating the `UInt64`'s bit pattern as a `Float`. `Float`s and `UInt64`s have the same endianness on all supported platforms. IEEE 754 very precisely specifies the bit layout of floats. This function does not reduce in the kernel. -/ @[extern "lean_float_of_bits"] opaque Float.ofBits : UInt64 → Float /-- Bit-for-bit conversion to `UInt64`. Interprets a `Float` as a `UInt64`, ignoring the numeric value and treating the `Float`'s bit pattern as a `UInt64`. `Float`s and `UInt64`s have the same endianness on all supported platforms. IEEE 754 very precisely specifies the bit layout of floats. This function is distinct from `Float.toUInt64`, which attempts to preserve the numeric value rather than reinterpreting the bit pattern. -/ @[extern "lean_float_to_bits"] opaque Float.toBits : Float → UInt64 instance : Add Float := ⟨Float.add⟩ instance : Sub Float := ⟨Float.sub⟩ instance : Mul Float := ⟨Float.mul⟩ instance : Div Float := ⟨Float.div⟩ instance : Neg Float := ⟨Float.neg⟩ instance : LT Float := ⟨Float.lt⟩ instance : LE Float := ⟨Float.le⟩ /-- Checks whether two floating-point numbers are equal according to IEEE 754. Floating-point equality does not correspond with propositional equality. In particular, it is not reflexive since `NaN != NaN`, and it is not a congruence because `0.0 == -0.0`, but `1.0 / 0.0 != 1.0 / -0.0`. This function does not reduce in the kernel. It is compiled to the C equality operator. -/ @[extern "lean_float_beq"] opaque Float.beq (a b : Float) : Bool instance : BEq Float := ⟨Float.beq⟩ /-- Compares two floating point numbers for strict inequality. This function does not reduce in the kernel. It is compiled to the C inequality operator. -/ @[extern "lean_float_decLt"] opaque Float.decLt (a b : Float) : Decidable (a < b) := match a, b with | ⟨a⟩, ⟨b⟩ => floatSpec.decLt a b /-- Compares two floating point numbers for non-strict inequality. This function does not reduce in the kernel. It is compiled to the C inequality operator. -/ @[extern "lean_float_decLe"] opaque Float.decLe (a b : Float) : Decidable (a ≤ b) := match a, b with | ⟨a⟩, ⟨b⟩ => floatSpec.decLe a b attribute [instance] Float.decLt Float.decLe /-- Converts a floating-point number to a string. This function does not reduce in the kernel. -/ @[extern "lean_float_to_string"] opaque Float.toString : Float → String /-- Converts a floating-point number to an 8-bit unsigned integer. If the given `Float` is non-negative, truncates the value to a positive integer, rounding down and clamping to the range of `UInt8`. Returns `0` if the `Float` is negative or `NaN`, and returns the largest `UInt8` value (i.e. `UInt8.size - 1`) if the float is larger than it. This function does not reduce in the kernel. -/ @[extern "lean_float_to_uint8"] opaque Float.toUInt8 : Float → UInt8 /-- Converts a floating-point number to a 16-bit unsigned integer. If the given `Float` is non-negative, truncates the value to a positive integer, rounding down and clamping to the range of `UInt16`. Returns `0` if the `Float` is negative or `NaN`, and returns the largest `UInt16` value (i.e. `UInt16.size - 1`) if the float is larger than it. This function does not reduce in the kernel. -/ @[extern "lean_float_to_uint16"] opaque Float.toUInt16 : Float → UInt16 /-- Converts a floating-point number to a 32-bit unsigned integer. If the given `Float` is non-negative, truncates the value to a positive integer, rounding down and clamping to the range of `UInt32`. Returns `0` if the `Float` is negative or `NaN`, and returns the largest `UInt32` value (i.e. `UInt32.size - 1`) if the float is larger than it. This function does not reduce in the kernel. -/ @[extern "lean_float_to_uint32"] opaque Float.toUInt32 : Float → UInt32 /-- Converts a floating-point number to a 64-bit unsigned integer. If the given `Float` is non-negative, truncates the value to a positive integer, rounding down and clamping to the range of `UInt64`. Returns `0` if the `Float` is negative or `NaN`, and returns the largest `UInt64` value (i.e. `UInt64.size - 1`) if the float is larger than it. This function does not reduce in the kernel. -/ @[extern "lean_float_to_uint64"] opaque Float.toUInt64 : Float → UInt64 /-- Converts a floating-point number to a word-sized unsigned integer. If the given `Float` is non-negative, truncates the value to a positive integer, rounding down and clamping to the range of `USize`. Returns `0` if the `Float` is negative or `NaN`, and returns the largest `USize` value (i.e. `USize.size - 1`) if the float is larger than it. This function does not reduce in the kernel. -/ @[extern "lean_float_to_usize"] opaque Float.toUSize : Float → USize /-- Checks whether a floating point number is `NaN` (“not a number”) value. `NaN` values result from operations that might otherwise be errors, such as dividing zero by zero. This function does not reduce in the kernel. It is compiled to the C operator `isnan`. -/ @[extern "lean_float_isnan"] opaque Float.isNaN : Float → Bool /-- Checks whether a floating-point number is finite, that is, whether it is normal, subnormal, or zero, but not infinite or `NaN`. This function does not reduce in the kernel. It is compiled to the C operator `isfinite`. -/ @[extern "lean_float_isfinite"] opaque Float.isFinite : Float → Bool /-- Checks whether a floating-point number is a positive or negative infinite number, but not a finite number or `NaN`. This function does not reduce in the kernel. It is compiled to the C operator `isinf`. -/ @[extern "lean_float_isinf"] opaque Float.isInf : Float → Bool /-- Splits the given float `x` into a significand/exponent pair `(s, i)` such that `x = s * 2^i` where `s ∈ (-1;-0.5] ∪ [0.5; 1)`. Returns an undefined value if `x` is not finite. This function does not reduce in the kernel. It is implemented in compiled code by the C function `frexp`. -/ @[extern "lean_float_frexp"] opaque Float.frExp : Float → Float × Int instance : ToString Float where toString := Float.toString /-- Obtains the `Float` whose value is the same as the given `UInt8`. -/ @[extern "lean_uint8_to_float"] opaque UInt8.toFloat (n : UInt8) : Float /-- Obtains the `Float` whose value is the same as the given `UInt16`. -/ @[extern "lean_uint16_to_float"] opaque UInt16.toFloat (n : UInt16) : Float /-- Obtains the `Float` whose value is the same as the given `UInt32`. -/ @[extern "lean_uint32_to_float"] opaque UInt32.toFloat (n : UInt32) : Float /-- Obtains a `Float` whose value is near the given `UInt64`. It will be exactly the value of the given `UInt64` if such a `Float` exists. If no such `Float` exists, the returned value will either be the smallest `Float` that is larger than the given value, or the largest `Float` that is smaller than the given value. This function is opaque in the kernel, but is overridden at runtime with an efficient implementation. -/ @[extern "lean_uint64_to_float"] opaque UInt64.toFloat (n : UInt64) : Float /-- Obtains a `Float` whose value is near the given `USize`. It will be exactly the value of the given `USize` if such a `Float` exists. If no such `Float` exists, the returned value will either be the smallest `Float` that is larger than the given value, or the largest `Float` that is smaller than the given value. This function is opaque in the kernel, but is overridden at runtime with an efficient implementation. -/ @[extern "lean_usize_to_float"] opaque USize.toFloat (n : USize) : Float instance : Inhabited Float where default := UInt64.toFloat 0 protected def Float.repr (n : Float) (prec : Nat) : Std.Format := if n < UInt64.toFloat 0 then Repr.addAppParen (toString n) prec else toString n instance : Repr Float where reprPrec := Float.repr instance : ReprAtom Float := ⟨⟩ /-- Computes the sine of a floating-point number in radians. This function does not reduce in the kernel. It is implemented in compiled code by the C function `sin`. -/ @[extern "sin"] opaque Float.sin : Float → Float /-- Computes the cosine of a floating-point number in radians. This function does not reduce in the kernel. It is implemented in compiled code by the C function `cos`. -/ @[extern "cos"] opaque Float.cos : Float → Float /-- Computes the tangent of a floating-point number in radians. This function does not reduce in the kernel. It is implemented in compiled code by the C function `tan`. -/ @[extern "tan"] opaque Float.tan : Float → Float /-- Computes the arc sine (inverse sine) of a floating-point number in radians. This function does not reduce in the kernel. It is implemented in compiled code by the C function `asin`. -/ @[extern "asin"] opaque Float.asin : Float → Float /-- Computes the arc cosine (inverse cosine) of a floating-point number in radians. This function does not reduce in the kernel. It is implemented in compiled code by the C function `acos`. -/ @[extern "acos"] opaque Float.acos : Float → Float /-- Computes the arc tangent (inverse tangent) of a floating-point number in radians. This function does not reduce in the kernel. It is implemented in compiled code by the C function `atan`. -/ @[extern "atan"] opaque Float.atan : Float → Float /-- Computes the arc tangent (inverse tangent) of `y / x` in radians, in the range `-π`–`π`. The signs of the arguments determine the quadrant of the result. This function does not reduce in the kernel. It is implemented in compiled code by the C function `atan2`. -/ @[extern "atan2"] opaque Float.atan2 (y x : Float) : Float /-- Computes the hyperbolic sine of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `sinh`. -/ @[extern "sinh"] opaque Float.sinh : Float → Float /-- Computes the hyperbolic cosine of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `cosh`. -/ @[extern "cosh"] opaque Float.cosh : Float → Float /-- Computes the hyperbolic tangent of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `tanh`. -/ @[extern "tanh"] opaque Float.tanh : Float → Float /-- Computes the hyperbolic arc sine (inverse sine) of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `asinh`. -/ @[extern "asinh"] opaque Float.asinh : Float → Float /-- Computes the hyperbolic arc cosine (inverse cosine) of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `acosh`. -/ @[extern "acosh"] opaque Float.acosh : Float → Float /-- Computes the hyperbolic arc tangent (inverse tangent) of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `atanh`. -/ @[extern "atanh"] opaque Float.atanh : Float → Float /-- Computes the exponential `e^x` of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `exp`. -/ @[extern "exp"] opaque Float.exp (x : Float) : Float /-- Computes the base-2 exponential `2^x` of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `exp2`. -/ @[extern "exp2"] opaque Float.exp2 (x : Float) : Float /-- Computes the natural logarithm `ln x` of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `log`. -/ @[extern "log"] opaque Float.log (x : Float) : Float /-- Computes the base-2 logarithm of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `log2`. -/ @[extern "log2"] opaque Float.log2 : Float → Float /-- Computes the base-10 logarithm of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `log10`. -/ @[extern "log10"] opaque Float.log10 : Float → Float /-- Raises one floating-point number to the power of another. Typically used via the `^` operator. This function does not reduce in the kernel. It is implemented in compiled code by the C function `pow`. -/ @[extern "pow"] opaque Float.pow : Float → Float → Float /-- Computes the square root of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `sqrt`. -/ @[extern "sqrt"] opaque Float.sqrt : Float → Float /-- Computes the cube root of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `cbrt`. -/ @[extern "cbrt"] opaque Float.cbrt : Float → Float /-- Computes the ceiling of a floating-point number, which is the smallest integer that's no smaller than the given number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `ceil`. Examples: * `Float.ceil 1.5 = 2` * `Float.ceil (-1.5) = (-1)` -/ @[extern "ceil"] opaque Float.ceil : Float → Float /-- Computes the floor of a floating-point number, which is the largest integer that's no larger than the given number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `floor`. Examples: * `Float.floor 1.5 = 1` * `Float.floor (-1.5) = (-2)` -/ @[extern "floor"] opaque Float.floor : Float → Float /-- Rounds to the nearest integer, rounding away from zero at half-way points. This function does not reduce in the kernel. It is implemented in compiled code by the C function `round`. -/ @[extern "round"] opaque Float.round : Float → Float /-- Computes the absolute value of a floating-point number. This function does not reduce in the kernel. It is implemented in compiled code by the C function `fabs`. -/ @[extern "fabs"] opaque Float.abs : Float → Float instance : HomogeneousPow Float := ⟨Float.pow⟩ instance : Min Float := minOfLe instance : Max Float := maxOfLe /-- Efficiently computes `x * 2^i`. This function does not reduce in the kernel. -/ @[extern "lean_float_scaleb"] opaque Float.scaleB (x : Float) (i : @& Int) : Float