996 lines
26 KiB
Ada
996 lines
26 KiB
Ada
------------------------------------------------------------------------------
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-- --
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-- GNAT RUN-TIME COMPONENTS --
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-- --
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-- ADA.NUMERICS.GENERIC_ELEMENTARY_FUNCTIONS --
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-- --
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-- B o d y --
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-- --
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-- Copyright (C) 1992-2015, Free Software Foundation, Inc. --
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-- --
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-- GNAT is free software; you can redistribute it and/or modify it under --
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-- terms of the GNU General Public License as published by the Free Soft- --
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-- ware Foundation; either version 3, or (at your option) any later ver- --
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-- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
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-- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
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-- or FITNESS FOR A PARTICULAR PURPOSE. --
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-- --
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-- As a special exception under Section 7 of GPL version 3, you are granted --
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-- additional permissions described in the GCC Runtime Library Exception, --
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-- version 3.1, as published by the Free Software Foundation. --
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-- --
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-- You should have received a copy of the GNU General Public License and --
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-- a copy of the GCC Runtime Library Exception along with this program; --
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-- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see --
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-- <http://www.gnu.org/licenses/>. --
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-- --
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-- GNAT was originally developed by the GNAT team at New York University. --
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-- Extensive contributions were provided by Ada Core Technologies Inc. --
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-- --
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------------------------------------------------------------------------------
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-- This body is specifically for using an Ada interface to C math.h to get
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-- the computation engine. Many special cases are handled locally to avoid
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-- unnecessary calls or to meet Annex G strict mode requirements.
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-- Uses functions sqrt, exp, log, pow, sin, asin, cos, acos, tan, atan, sinh,
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-- cosh, tanh from C library via math.h
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with Ada.Numerics.Aux;
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package body Ada.Numerics.Generic_Elementary_Functions is
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use type Ada.Numerics.Aux.Double;
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Sqrt_Two : constant := 1.41421_35623_73095_04880_16887_24209_69807_85696;
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Log_Two : constant := 0.69314_71805_59945_30941_72321_21458_17656_80755;
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Half_Log_Two : constant := Log_Two / 2;
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subtype T is Float_Type'Base;
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subtype Double is Aux.Double;
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Two_Pi : constant T := 2.0 * Pi;
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Half_Pi : constant T := Pi / 2.0;
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Half_Log_Epsilon : constant T := T (1 - T'Model_Mantissa) * Half_Log_Two;
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Log_Inverse_Epsilon : constant T := T (T'Model_Mantissa - 1) * Log_Two;
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Sqrt_Epsilon : constant T := Sqrt_Two ** (1 - T'Model_Mantissa);
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-----------------------
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-- Local Subprograms --
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-----------------------
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function Exp_Strict (X : Float_Type'Base) return Float_Type'Base;
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-- Cody/Waite routine, supposedly more precise than the library version.
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-- Currently only needed for Sinh/Cosh on X86 with the largest FP type.
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function Local_Atan
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(Y : Float_Type'Base;
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X : Float_Type'Base := 1.0) return Float_Type'Base;
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-- Common code for arc tangent after cycle reduction
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----------
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-- "**" --
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----------
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function "**" (Left, Right : Float_Type'Base) return Float_Type'Base is
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A_Right : Float_Type'Base;
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Int_Part : Integer;
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Result : Float_Type'Base;
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R1 : Float_Type'Base;
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Rest : Float_Type'Base;
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begin
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if Left = 0.0
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and then Right = 0.0
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then
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raise Argument_Error;
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elsif Left < 0.0 then
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raise Argument_Error;
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elsif Right = 0.0 then
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return 1.0;
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elsif Left = 0.0 then
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if Right < 0.0 then
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raise Constraint_Error;
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else
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return 0.0;
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end if;
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elsif Left = 1.0 then
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return 1.0;
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elsif Right = 1.0 then
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return Left;
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else
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begin
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if Right = 2.0 then
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return Left * Left;
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elsif Right = 0.5 then
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return Sqrt (Left);
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else
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A_Right := abs (Right);
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-- If exponent is larger than one, compute integer exponen-
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-- tiation if possible, and evaluate fractional part with more
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-- precision. The relative error is now proportional to the
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-- fractional part of the exponent only.
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if A_Right > 1.0
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and then A_Right < Float_Type'Base (Integer'Last)
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then
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Int_Part := Integer (Float_Type'Base'Truncation (A_Right));
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Result := Left ** Int_Part;
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Rest := A_Right - Float_Type'Base (Int_Part);
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-- Compute with two leading bits of the mantissa using
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-- square roots. Bound to be better than logarithms, and
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-- easily extended to greater precision.
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if Rest >= 0.5 then
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R1 := Sqrt (Left);
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Result := Result * R1;
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Rest := Rest - 0.5;
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if Rest >= 0.25 then
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Result := Result * Sqrt (R1);
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Rest := Rest - 0.25;
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end if;
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elsif Rest >= 0.25 then
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Result := Result * Sqrt (Sqrt (Left));
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Rest := Rest - 0.25;
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end if;
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Result := Result *
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Float_Type'Base (Aux.Pow (Double (Left), Double (Rest)));
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if Right >= 0.0 then
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return Result;
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else
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return (1.0 / Result);
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end if;
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else
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return
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Float_Type'Base (Aux.Pow (Double (Left), Double (Right)));
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end if;
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end if;
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exception
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when others =>
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raise Constraint_Error;
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end;
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end if;
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end "**";
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------------
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-- Arccos --
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------------
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-- Natural cycle
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function Arccos (X : Float_Type'Base) return Float_Type'Base is
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Temp : Float_Type'Base;
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begin
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if abs X > 1.0 then
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raise Argument_Error;
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elsif abs X < Sqrt_Epsilon then
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return Pi / 2.0 - X;
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elsif X = 1.0 then
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return 0.0;
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elsif X = -1.0 then
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return Pi;
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end if;
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Temp := Float_Type'Base (Aux.Acos (Double (X)));
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if Temp < 0.0 then
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Temp := Pi + Temp;
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end if;
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return Temp;
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end Arccos;
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-- Arbitrary cycle
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function Arccos (X, Cycle : Float_Type'Base) return Float_Type'Base is
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Temp : Float_Type'Base;
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begin
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if Cycle <= 0.0 then
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raise Argument_Error;
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elsif abs X > 1.0 then
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raise Argument_Error;
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elsif abs X < Sqrt_Epsilon then
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return Cycle / 4.0;
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elsif X = 1.0 then
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return 0.0;
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elsif X = -1.0 then
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return Cycle / 2.0;
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end if;
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Temp := Arctan (Sqrt ((1.0 - X) * (1.0 + X)) / X, 1.0, Cycle);
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if Temp < 0.0 then
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Temp := Cycle / 2.0 + Temp;
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end if;
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return Temp;
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end Arccos;
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-------------
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-- Arccosh --
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-------------
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function Arccosh (X : Float_Type'Base) return Float_Type'Base is
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begin
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-- Return positive branch of Log (X - Sqrt (X * X - 1.0)), or the proper
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-- approximation for X close to 1 or >> 1.
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if X < 1.0 then
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raise Argument_Error;
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elsif X < 1.0 + Sqrt_Epsilon then
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return Sqrt (2.0 * (X - 1.0));
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elsif X > 1.0 / Sqrt_Epsilon then
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return Log (X) + Log_Two;
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else
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return Log (X + Sqrt ((X - 1.0) * (X + 1.0)));
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end if;
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end Arccosh;
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------------
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-- Arccot --
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------------
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-- Natural cycle
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function Arccot
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(X : Float_Type'Base;
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Y : Float_Type'Base := 1.0)
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return Float_Type'Base
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is
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begin
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-- Just reverse arguments
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return Arctan (Y, X);
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end Arccot;
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-- Arbitrary cycle
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function Arccot
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(X : Float_Type'Base;
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Y : Float_Type'Base := 1.0;
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Cycle : Float_Type'Base)
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return Float_Type'Base
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is
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begin
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-- Just reverse arguments
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return Arctan (Y, X, Cycle);
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end Arccot;
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-------------
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-- Arccoth --
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-------------
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function Arccoth (X : Float_Type'Base) return Float_Type'Base is
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begin
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if abs X > 2.0 then
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return Arctanh (1.0 / X);
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elsif abs X = 1.0 then
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raise Constraint_Error;
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elsif abs X < 1.0 then
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raise Argument_Error;
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else
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-- 1.0 < abs X <= 2.0. One of X + 1.0 and X - 1.0 is exact, the other
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-- has error 0 or Epsilon.
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return 0.5 * (Log (abs (X + 1.0)) - Log (abs (X - 1.0)));
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end if;
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end Arccoth;
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------------
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-- Arcsin --
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------------
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-- Natural cycle
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function Arcsin (X : Float_Type'Base) return Float_Type'Base is
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begin
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if abs X > 1.0 then
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raise Argument_Error;
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elsif abs X < Sqrt_Epsilon then
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return X;
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elsif X = 1.0 then
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return Pi / 2.0;
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elsif X = -1.0 then
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return -(Pi / 2.0);
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end if;
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return Float_Type'Base (Aux.Asin (Double (X)));
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end Arcsin;
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-- Arbitrary cycle
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function Arcsin (X, Cycle : Float_Type'Base) return Float_Type'Base is
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begin
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if Cycle <= 0.0 then
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raise Argument_Error;
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elsif abs X > 1.0 then
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raise Argument_Error;
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elsif X = 0.0 then
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return X;
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elsif X = 1.0 then
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return Cycle / 4.0;
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elsif X = -1.0 then
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return -(Cycle / 4.0);
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end if;
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return Arctan (X / Sqrt ((1.0 - X) * (1.0 + X)), 1.0, Cycle);
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end Arcsin;
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-------------
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-- Arcsinh --
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-------------
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function Arcsinh (X : Float_Type'Base) return Float_Type'Base is
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begin
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if abs X < Sqrt_Epsilon then
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return X;
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elsif X > 1.0 / Sqrt_Epsilon then
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return Log (X) + Log_Two;
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elsif X < -(1.0 / Sqrt_Epsilon) then
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return -(Log (-X) + Log_Two);
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elsif X < 0.0 then
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return -Log (abs X + Sqrt (X * X + 1.0));
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else
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return Log (X + Sqrt (X * X + 1.0));
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end if;
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end Arcsinh;
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------------
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-- Arctan --
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------------
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-- Natural cycle
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function Arctan
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(Y : Float_Type'Base;
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X : Float_Type'Base := 1.0)
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return Float_Type'Base
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is
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begin
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if X = 0.0 and then Y = 0.0 then
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raise Argument_Error;
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elsif Y = 0.0 then
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if X > 0.0 then
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return 0.0;
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else -- X < 0.0
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return Pi * Float_Type'Copy_Sign (1.0, Y);
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end if;
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elsif X = 0.0 then
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return Float_Type'Copy_Sign (Half_Pi, Y);
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else
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return Local_Atan (Y, X);
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end if;
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end Arctan;
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-- Arbitrary cycle
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function Arctan
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(Y : Float_Type'Base;
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X : Float_Type'Base := 1.0;
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Cycle : Float_Type'Base)
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return Float_Type'Base
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is
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begin
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if Cycle <= 0.0 then
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raise Argument_Error;
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elsif X = 0.0 and then Y = 0.0 then
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raise Argument_Error;
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elsif Y = 0.0 then
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if X > 0.0 then
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return 0.0;
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else -- X < 0.0
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return Cycle / 2.0 * Float_Type'Copy_Sign (1.0, Y);
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end if;
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elsif X = 0.0 then
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return Float_Type'Copy_Sign (Cycle / 4.0, Y);
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else
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return Local_Atan (Y, X) * Cycle / Two_Pi;
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end if;
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end Arctan;
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-------------
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-- Arctanh --
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-------------
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function Arctanh (X : Float_Type'Base) return Float_Type'Base is
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A, B, D, A_Plus_1, A_From_1 : Float_Type'Base;
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Mantissa : constant Integer := Float_Type'Base'Machine_Mantissa;
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begin
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-- The naive formula:
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-- Arctanh (X) := (1/2) * Log (1 + X) / (1 - X)
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-- is not well-behaved numerically when X < 0.5 and when X is close
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-- to one. The following is accurate but probably not optimal.
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if abs X = 1.0 then
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raise Constraint_Error;
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elsif abs X >= 1.0 - 2.0 ** (-Mantissa) then
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if abs X >= 1.0 then
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raise Argument_Error;
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else
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-- The one case that overflows if put through the method below:
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-- abs X = 1.0 - Epsilon. In this case (1/2) log (2/Epsilon) is
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-- accurate. This simplifies to:
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return Float_Type'Copy_Sign (
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Half_Log_Two * Float_Type'Base (Mantissa + 1), X);
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end if;
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-- elsif abs X <= 0.5 then
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-- why is above line commented out ???
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else
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-- Use several piecewise linear approximations. A is close to X,
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-- chosen so 1.0 + A, 1.0 - A, and X - A are exact. The two scalings
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-- remove the low-order bits of X.
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A := Float_Type'Base'Scaling (
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Float_Type'Base (Long_Long_Integer
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(Float_Type'Base'Scaling (X, Mantissa - 1))), 1 - Mantissa);
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B := X - A; -- This is exact; abs B <= 2**(-Mantissa).
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A_Plus_1 := 1.0 + A; -- This is exact.
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A_From_1 := 1.0 - A; -- Ditto.
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D := A_Plus_1 * A_From_1; -- 1 - A*A.
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-- use one term of the series expansion:
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-- f (x + e) = f(x) + e * f'(x) + ..
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-- The derivative of Arctanh at A is 1/(1-A*A). Next term is
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-- A*(B/D)**2 (if a quadratic approximation is ever needed).
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return 0.5 * (Log (A_Plus_1) - Log (A_From_1)) + B / D;
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end if;
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end Arctanh;
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---------
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-- Cos --
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---------
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-- Natural cycle
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function Cos (X : Float_Type'Base) return Float_Type'Base is
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begin
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if abs X < Sqrt_Epsilon then
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return 1.0;
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end if;
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return Float_Type'Base (Aux.Cos (Double (X)));
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end Cos;
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-- Arbitrary cycle
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function Cos (X, Cycle : Float_Type'Base) return Float_Type'Base is
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begin
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-- Just reuse the code for Sin. The potential small loss of speed is
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-- negligible with proper (front-end) inlining.
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return -Sin (abs X - Cycle * 0.25, Cycle);
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end Cos;
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----------
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-- Cosh --
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----------
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function Cosh (X : Float_Type'Base) return Float_Type'Base is
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Lnv : constant Float_Type'Base := 8#0.542714#;
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V2minus1 : constant Float_Type'Base := 0.13830_27787_96019_02638E-4;
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Y : constant Float_Type'Base := abs X;
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Z : Float_Type'Base;
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begin
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if Y < Sqrt_Epsilon then
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return 1.0;
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elsif Y > Log_Inverse_Epsilon then
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Z := Exp_Strict (Y - Lnv);
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return (Z + V2minus1 * Z);
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else
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Z := Exp_Strict (Y);
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return 0.5 * (Z + 1.0 / Z);
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end if;
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end Cosh;
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---------
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-- Cot --
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---------
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-- Natural cycle
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function Cot (X : Float_Type'Base) return Float_Type'Base is
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begin
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if X = 0.0 then
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raise Constraint_Error;
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elsif abs X < Sqrt_Epsilon then
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return 1.0 / X;
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end if;
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return 1.0 / Float_Type'Base (Aux.Tan (Double (X)));
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end Cot;
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-- Arbitrary cycle
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function Cot (X, Cycle : Float_Type'Base) return Float_Type'Base is
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T : Float_Type'Base;
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begin
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if Cycle <= 0.0 then
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raise Argument_Error;
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end if;
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T := Float_Type'Base'Remainder (X, Cycle);
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if T = 0.0 or else abs T = 0.5 * Cycle then
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|
raise Constraint_Error;
|
|
|
|
elsif abs T < Sqrt_Epsilon then
|
|
return 1.0 / T;
|
|
|
|
elsif abs T = 0.25 * Cycle then
|
|
return 0.0;
|
|
|
|
else
|
|
T := T / Cycle * Two_Pi;
|
|
return Cos (T) / Sin (T);
|
|
end if;
|
|
end Cot;
|
|
|
|
----------
|
|
-- Coth --
|
|
----------
|
|
|
|
function Coth (X : Float_Type'Base) return Float_Type'Base is
|
|
begin
|
|
if X = 0.0 then
|
|
raise Constraint_Error;
|
|
|
|
elsif X < Half_Log_Epsilon then
|
|
return -1.0;
|
|
|
|
elsif X > -Half_Log_Epsilon then
|
|
return 1.0;
|
|
|
|
elsif abs X < Sqrt_Epsilon then
|
|
return 1.0 / X;
|
|
end if;
|
|
|
|
return 1.0 / Float_Type'Base (Aux.Tanh (Double (X)));
|
|
end Coth;
|
|
|
|
---------
|
|
-- Exp --
|
|
---------
|
|
|
|
function Exp (X : Float_Type'Base) return Float_Type'Base is
|
|
Result : Float_Type'Base;
|
|
|
|
begin
|
|
if X = 0.0 then
|
|
return 1.0;
|
|
end if;
|
|
|
|
Result := Float_Type'Base (Aux.Exp (Double (X)));
|
|
|
|
-- Deal with case of Exp returning IEEE infinity. If Machine_Overflows
|
|
-- is False, then we can just leave it as an infinity (and indeed we
|
|
-- prefer to do so). But if Machine_Overflows is True, then we have
|
|
-- to raise a Constraint_Error exception as required by the RM.
|
|
|
|
if Float_Type'Machine_Overflows and then not Result'Valid then
|
|
raise Constraint_Error;
|
|
end if;
|
|
|
|
return Result;
|
|
end Exp;
|
|
|
|
----------------
|
|
-- Exp_Strict --
|
|
----------------
|
|
|
|
function Exp_Strict (X : Float_Type'Base) return Float_Type'Base is
|
|
G : Float_Type'Base;
|
|
Z : Float_Type'Base;
|
|
|
|
P0 : constant := 0.25000_00000_00000_00000;
|
|
P1 : constant := 0.75753_18015_94227_76666E-2;
|
|
P2 : constant := 0.31555_19276_56846_46356E-4;
|
|
|
|
Q0 : constant := 0.5;
|
|
Q1 : constant := 0.56817_30269_85512_21787E-1;
|
|
Q2 : constant := 0.63121_89437_43985_02557E-3;
|
|
Q3 : constant := 0.75104_02839_98700_46114E-6;
|
|
|
|
C1 : constant := 8#0.543#;
|
|
C2 : constant := -2.1219_44400_54690_58277E-4;
|
|
Le : constant := 1.4426_95040_88896_34074;
|
|
|
|
XN : Float_Type'Base;
|
|
P, Q, R : Float_Type'Base;
|
|
|
|
begin
|
|
if X = 0.0 then
|
|
return 1.0;
|
|
end if;
|
|
|
|
XN := Float_Type'Base'Rounding (X * Le);
|
|
G := (X - XN * C1) - XN * C2;
|
|
Z := G * G;
|
|
P := G * ((P2 * Z + P1) * Z + P0);
|
|
Q := ((Q3 * Z + Q2) * Z + Q1) * Z + Q0;
|
|
R := 0.5 + P / (Q - P);
|
|
|
|
R := Float_Type'Base'Scaling (R, Integer (XN) + 1);
|
|
|
|
-- Deal with case of Exp returning IEEE infinity. If Machine_Overflows
|
|
-- is False, then we can just leave it as an infinity (and indeed we
|
|
-- prefer to do so). But if Machine_Overflows is True, then we have to
|
|
-- raise a Constraint_Error exception as required by the RM.
|
|
|
|
if Float_Type'Machine_Overflows and then not R'Valid then
|
|
raise Constraint_Error;
|
|
else
|
|
return R;
|
|
end if;
|
|
|
|
end Exp_Strict;
|
|
|
|
----------------
|
|
-- Local_Atan --
|
|
----------------
|
|
|
|
function Local_Atan
|
|
(Y : Float_Type'Base;
|
|
X : Float_Type'Base := 1.0) return Float_Type'Base
|
|
is
|
|
Z : Float_Type'Base;
|
|
Raw_Atan : Float_Type'Base;
|
|
|
|
begin
|
|
Z := (if abs Y > abs X then abs (X / Y) else abs (Y / X));
|
|
|
|
Raw_Atan :=
|
|
(if Z < Sqrt_Epsilon then Z
|
|
elsif Z = 1.0 then Pi / 4.0
|
|
else Float_Type'Base (Aux.Atan (Double (Z))));
|
|
|
|
if abs Y > abs X then
|
|
Raw_Atan := Half_Pi - Raw_Atan;
|
|
end if;
|
|
|
|
if X > 0.0 then
|
|
return Float_Type'Copy_Sign (Raw_Atan, Y);
|
|
else
|
|
return Float_Type'Copy_Sign (Pi - Raw_Atan, Y);
|
|
end if;
|
|
end Local_Atan;
|
|
|
|
---------
|
|
-- Log --
|
|
---------
|
|
|
|
-- Natural base
|
|
|
|
function Log (X : Float_Type'Base) return Float_Type'Base is
|
|
begin
|
|
if X < 0.0 then
|
|
raise Argument_Error;
|
|
|
|
elsif X = 0.0 then
|
|
raise Constraint_Error;
|
|
|
|
elsif X = 1.0 then
|
|
return 0.0;
|
|
end if;
|
|
|
|
return Float_Type'Base (Aux.Log (Double (X)));
|
|
end Log;
|
|
|
|
-- Arbitrary base
|
|
|
|
function Log (X, Base : Float_Type'Base) return Float_Type'Base is
|
|
begin
|
|
if X < 0.0 then
|
|
raise Argument_Error;
|
|
|
|
elsif Base <= 0.0 or else Base = 1.0 then
|
|
raise Argument_Error;
|
|
|
|
elsif X = 0.0 then
|
|
raise Constraint_Error;
|
|
|
|
elsif X = 1.0 then
|
|
return 0.0;
|
|
end if;
|
|
|
|
return Float_Type'Base (Aux.Log (Double (X)) / Aux.Log (Double (Base)));
|
|
end Log;
|
|
|
|
---------
|
|
-- Sin --
|
|
---------
|
|
|
|
-- Natural cycle
|
|
|
|
function Sin (X : Float_Type'Base) return Float_Type'Base is
|
|
begin
|
|
if abs X < Sqrt_Epsilon then
|
|
return X;
|
|
end if;
|
|
|
|
return Float_Type'Base (Aux.Sin (Double (X)));
|
|
end Sin;
|
|
|
|
-- Arbitrary cycle
|
|
|
|
function Sin (X, Cycle : Float_Type'Base) return Float_Type'Base is
|
|
T : Float_Type'Base;
|
|
|
|
begin
|
|
if Cycle <= 0.0 then
|
|
raise Argument_Error;
|
|
|
|
-- If X is zero, return it as the result, preserving the argument sign.
|
|
-- Is this test really needed on any machine ???
|
|
|
|
elsif X = 0.0 then
|
|
return X;
|
|
end if;
|
|
|
|
T := Float_Type'Base'Remainder (X, Cycle);
|
|
|
|
-- The following two reductions reduce the argument to the interval
|
|
-- [-0.25 * Cycle, 0.25 * Cycle]. This reduction is exact and is needed
|
|
-- to prevent inaccuracy that may result if the sine function uses a
|
|
-- different (more accurate) value of Pi in its reduction than is used
|
|
-- in the multiplication with Two_Pi.
|
|
|
|
if abs T > 0.25 * Cycle then
|
|
T := 0.5 * Float_Type'Copy_Sign (Cycle, T) - T;
|
|
end if;
|
|
|
|
-- Could test for 12.0 * abs T = Cycle, and return an exact value in
|
|
-- those cases. It is not clear this is worth the extra test though.
|
|
|
|
return Float_Type'Base (Aux.Sin (Double (T / Cycle * Two_Pi)));
|
|
end Sin;
|
|
|
|
----------
|
|
-- Sinh --
|
|
----------
|
|
|
|
function Sinh (X : Float_Type'Base) return Float_Type'Base is
|
|
Lnv : constant Float_Type'Base := 8#0.542714#;
|
|
V2minus1 : constant Float_Type'Base := 0.13830_27787_96019_02638E-4;
|
|
Y : constant Float_Type'Base := abs X;
|
|
F : constant Float_Type'Base := Y * Y;
|
|
Z : Float_Type'Base;
|
|
|
|
Float_Digits_1_6 : constant Boolean := Float_Type'Digits < 7;
|
|
|
|
begin
|
|
if Y < Sqrt_Epsilon then
|
|
return X;
|
|
|
|
elsif Y > Log_Inverse_Epsilon then
|
|
Z := Exp_Strict (Y - Lnv);
|
|
Z := Z + V2minus1 * Z;
|
|
|
|
elsif Y < 1.0 then
|
|
|
|
if Float_Digits_1_6 then
|
|
|
|
-- Use expansion provided by Cody and Waite, p. 226. Note that
|
|
-- leading term of the polynomial in Q is exactly 1.0.
|
|
|
|
declare
|
|
P0 : constant := -0.71379_3159E+1;
|
|
P1 : constant := -0.19033_3399E+0;
|
|
Q0 : constant := -0.42827_7109E+2;
|
|
|
|
begin
|
|
Z := Y + Y * F * (P1 * F + P0) / (F + Q0);
|
|
end;
|
|
|
|
else
|
|
declare
|
|
P0 : constant := -0.35181_28343_01771_17881E+6;
|
|
P1 : constant := -0.11563_52119_68517_68270E+5;
|
|
P2 : constant := -0.16375_79820_26307_51372E+3;
|
|
P3 : constant := -0.78966_12741_73570_99479E+0;
|
|
Q0 : constant := -0.21108_77005_81062_71242E+7;
|
|
Q1 : constant := 0.36162_72310_94218_36460E+5;
|
|
Q2 : constant := -0.27773_52311_96507_01667E+3;
|
|
|
|
begin
|
|
Z := Y + Y * F * (((P3 * F + P2) * F + P1) * F + P0)
|
|
/ (((F + Q2) * F + Q1) * F + Q0);
|
|
end;
|
|
end if;
|
|
|
|
else
|
|
Z := Exp_Strict (Y);
|
|
Z := 0.5 * (Z - 1.0 / Z);
|
|
end if;
|
|
|
|
if X > 0.0 then
|
|
return Z;
|
|
else
|
|
return -Z;
|
|
end if;
|
|
end Sinh;
|
|
|
|
----------
|
|
-- Sqrt --
|
|
----------
|
|
|
|
function Sqrt (X : Float_Type'Base) return Float_Type'Base is
|
|
begin
|
|
if X < 0.0 then
|
|
raise Argument_Error;
|
|
|
|
-- Special case Sqrt (0.0) to preserve possible minus sign per IEEE
|
|
|
|
elsif X = 0.0 then
|
|
return X;
|
|
end if;
|
|
|
|
return Float_Type'Base (Aux.Sqrt (Double (X)));
|
|
end Sqrt;
|
|
|
|
---------
|
|
-- Tan --
|
|
---------
|
|
|
|
-- Natural cycle
|
|
|
|
function Tan (X : Float_Type'Base) return Float_Type'Base is
|
|
begin
|
|
if abs X < Sqrt_Epsilon then
|
|
return X;
|
|
end if;
|
|
|
|
-- Note: if X is exactly pi/2, then we should raise an exception, since
|
|
-- the result would overflow. But for all floating-point formats we deal
|
|
-- with, it is impossible for X to be exactly pi/2, and the result is
|
|
-- always in range.
|
|
|
|
return Float_Type'Base (Aux.Tan (Double (X)));
|
|
end Tan;
|
|
|
|
-- Arbitrary cycle
|
|
|
|
function Tan (X, Cycle : Float_Type'Base) return Float_Type'Base is
|
|
T : Float_Type'Base;
|
|
|
|
begin
|
|
if Cycle <= 0.0 then
|
|
raise Argument_Error;
|
|
|
|
elsif X = 0.0 then
|
|
return X;
|
|
end if;
|
|
|
|
T := Float_Type'Base'Remainder (X, Cycle);
|
|
|
|
if abs T = 0.25 * Cycle then
|
|
raise Constraint_Error;
|
|
|
|
elsif abs T = 0.5 * Cycle then
|
|
return 0.0;
|
|
|
|
else
|
|
T := T / Cycle * Two_Pi;
|
|
return Sin (T) / Cos (T);
|
|
end if;
|
|
|
|
end Tan;
|
|
|
|
----------
|
|
-- Tanh --
|
|
----------
|
|
|
|
function Tanh (X : Float_Type'Base) return Float_Type'Base is
|
|
P0 : constant Float_Type'Base := -0.16134_11902_39962_28053E+4;
|
|
P1 : constant Float_Type'Base := -0.99225_92967_22360_83313E+2;
|
|
P2 : constant Float_Type'Base := -0.96437_49277_72254_69787E+0;
|
|
|
|
Q0 : constant Float_Type'Base := 0.48402_35707_19886_88686E+4;
|
|
Q1 : constant Float_Type'Base := 0.22337_72071_89623_12926E+4;
|
|
Q2 : constant Float_Type'Base := 0.11274_47438_05349_49335E+3;
|
|
Q3 : constant Float_Type'Base := 0.10000_00000_00000_00000E+1;
|
|
|
|
Half_Ln3 : constant Float_Type'Base := 0.54930_61443_34054_84570;
|
|
|
|
P, Q, R : Float_Type'Base;
|
|
Y : constant Float_Type'Base := abs X;
|
|
G : constant Float_Type'Base := Y * Y;
|
|
|
|
Float_Type_Digits_15_Or_More : constant Boolean :=
|
|
Float_Type'Digits > 14;
|
|
|
|
begin
|
|
if X < Half_Log_Epsilon then
|
|
return -1.0;
|
|
|
|
elsif X > -Half_Log_Epsilon then
|
|
return 1.0;
|
|
|
|
elsif Y < Sqrt_Epsilon then
|
|
return X;
|
|
|
|
elsif Y < Half_Ln3
|
|
and then Float_Type_Digits_15_Or_More
|
|
then
|
|
P := (P2 * G + P1) * G + P0;
|
|
Q := ((Q3 * G + Q2) * G + Q1) * G + Q0;
|
|
R := G * (P / Q);
|
|
return X + X * R;
|
|
|
|
else
|
|
return Float_Type'Base (Aux.Tanh (Double (X)));
|
|
end if;
|
|
end Tanh;
|
|
|
|
end Ada.Numerics.Generic_Elementary_Functions;
|