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 ------------------------------------------------------------------------------
 --                                                                          --
 --                         GNAT RUN-TIME COMPONENTS                         --
 --                                                                          --
 --                     A D A . N U M E R I C S . A U X                      --
 --                                                                          --
 --                                 B o d y                                  --
 --                        (Machine Version for x86)                         --
 --                                                                          --
 --          Copyright (C) 1998-2009, Free Software Foundation, Inc.         --
 --                                                                          --
 -- GNAT is free software;  you can  redistribute it  and/or modify it under --
 -- terms of the  GNU General Public License as published  by the Free Soft- --
 -- ware  Foundation;  either version 3,  or (at your option) any later ver- --
 -- sion.  GNAT is distributed in the hope that it will be useful, but WITH- --
 -- OUT ANY WARRANTY;  without even the  implied warranty of MERCHANTABILITY --
 -- or FITNESS FOR A PARTICULAR PURPOSE.                                     --
 --                                                                          --
 -- As a special exception under Section 7 of GPL version 3, you are granted --
 -- additional permissions described in the GCC Runtime Library Exception,   --
 -- version 3.1, as published by the Free Software Foundation.               --
 --                                                                          --
 -- You should have received a copy of the GNU General Public License and    --
 -- a copy of the GCC Runtime Library Exception along with this program;     --
 -- see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see    --
 -- <http://www.gnu.org/licenses/>.                                          --
 --                                                                          --
 -- GNAT was originally developed  by the GNAT team at  New York University. --
 -- Extensive contributions were provided by Ada Core Technologies Inc.      --
 --                                                                          --
 ------------------------------------------------------------------------------

 --  File a-numaux.adb <- 86numaux.adb

 --  This version of Numerics.Aux is for the IEEE Double Extended floating
 --  point format on x86.

 with System.Machine_Code; use System.Machine_Code;

 package body Ada.Numerics.Aux is

    NL : constant String := ASCII.LF & ASCII.HT;

    -----------------------
    -- Local subprograms --
    -----------------------

    function Is_Nan (X : Double) return Boolean;
    --  Return True iff X is a IEEE NaN value

    function Logarithmic_Pow (X, Y : Double) return Double;
    --  Implementation of X**Y using Exp and Log functions (binary base)
    --  to calculate the exponentiation. This is used by Pow for values
    --  for values of Y in the open interval (-0.25, 0.25)

    procedure Reduce (X : in out Double; Q : out Natural);
    --  Implements reduction of X by Pi/2. Q is the quadrant of the final
    --  result in the range 0 .. 3. The absolute value of X is at most Pi.

    pragma Inline (Is_Nan);
    pragma Inline (Reduce);

    --------------------------------
    -- Basic Elementary Functions --
    --------------------------------

    --  This section implements a few elementary functions that are used to
    --  build the more complex ones. This ordering enables better inlining.

    ----------
    -- Atan --
    ----------

    function Atan (X : Double) return Double is
       Result  : Double;

    begin
       Asm (Template =>
            "fld1" & NL
          & "fpatan",
          Outputs  => Double'Asm_Output ("=t", Result),
          Inputs   => Double'Asm_Input  ("0", X));

       --  The result value is NaN iff input was invalid

       if not (Result = Result) then
          raise Argument_Error;
       end if;

       return Result;
    end Atan;

    ---------
    -- Exp --
    ---------

    function Exp (X : Double) return Double is
       Result : Double;
    begin
       Asm (Template =>
          "fldl2e               " & NL
        & "fmulp   %%st, %%st(1)" & NL -- X * log2 (E)
        & "fld     %%st(0)      " & NL
        & "frndint              " & NL -- Integer (X * Log2 (E))
        & "fsubr   %%st, %%st(1)" & NL -- Fraction (X * Log2 (E))
        & "fxch                 " & NL
        & "f2xm1                " & NL -- 2**(...) - 1
        & "fld1                 " & NL
        & "faddp   %%st, %%st(1)" & NL -- 2**(Fraction (X * Log2 (E)))
        & "fscale               " & NL -- E ** X
        & "fstp    %%st(1)      ",
          Outputs  => Double'Asm_Output ("=t", Result),
          Inputs   => Double'Asm_Input  ("0", X));
       return Result;
    end Exp;

    ------------
    -- Is_Nan --
    ------------

    function Is_Nan (X : Double) return Boolean is
    begin
       --  The IEEE NaN values are the only ones that do not equal themselves

       return not (X = X);
    end Is_Nan;

    ---------
    -- Log --
    ---------

    function Log (X : Double) return Double is
       Result : Double;

    begin
       Asm (Template =>
          "fldln2               " & NL
        & "fxch                 " & NL
        & "fyl2x                " & NL,
          Outputs  => Double'Asm_Output ("=t", Result),
          Inputs   => Double'Asm_Input  ("0", X));
       return Result;
    end Log;

    ------------
    -- Reduce --
    ------------

    procedure Reduce (X : in out Double; Q : out Natural) is
       Half_Pi     : constant := Pi / 2.0;
       Two_Over_Pi : constant := 2.0 / Pi;

       HM : constant := Integer'Min (Double'Machine_Mantissa / 2, Natural'Size);
       M  : constant Double := 0.5 + 2.0**(1 - HM); -- Splitting constant
       P1 : constant Double := Double'Leading_Part (Half_Pi, HM);
       P2 : constant Double := Double'Leading_Part (Half_Pi - P1, HM);
       P3 : constant Double := Double'Leading_Part (Half_Pi - P1 - P2, HM);
       P4 : constant Double := Double'Leading_Part (Half_Pi - P1 - P2 - P3, HM);
       P5 : constant Double := Double'Leading_Part (Half_Pi - P1 - P2 - P3
                                                                  - P4, HM);
       P6 : constant Double := Double'Model (Half_Pi - P1 - P2 - P3 - P4 - P5);
       K  : Double := X * Two_Over_Pi;
    begin
       --  For X < 2.0**32, all products below are computed exactly.
       --  Due to cancellation effects all subtractions are exact as well.
       --  As no double extended floating-point number has more than 75
       --  zeros after the binary point, the result will be the correctly
       --  rounded result of X - K * (Pi / 2.0).

       while abs K >= 2.0**HM loop
          K := K * M - (K * M - K);
          X := (((((X - K * P1) - K * P2) - K * P3)
                      - K * P4) - K * P5) - K * P6;
          K := X * Two_Over_Pi;
       end loop;

       if K /= K then

          --  K is not a number, because X was not finite

          raise Constraint_Error;
       end if;

       K := Double'Rounding (K);
       Q := Integer (K) mod 4;
       X := (((((X - K * P1) - K * P2) - K * P3)
                   - K * P4) - K * P5) - K * P6;
    end Reduce;

    ----------
    -- Sqrt --
    ----------

    function Sqrt (X : Double) return Double is
       Result  : Double;

    begin
       if X < 0.0 then
          raise Argument_Error;
       end if;

       Asm (Template => "fsqrt",
            Outputs  => Double'Asm_Output ("=t", Result),
            Inputs   => Double'Asm_Input  ("0", X));

       return Result;
    end Sqrt;

    --------------------------------
    -- Other Elementary Functions --
    --------------------------------

    --  These are built using the previously implemented basic functions

    ----------
    -- Acos --
    ----------

    function Acos (X : Double) return Double is
       Result  : Double;

    begin
       Result := 2.0 * Atan (Sqrt ((1.0 - X) / (1.0 + X)));

       --  The result value is NaN iff input was invalid

       if Is_Nan (Result) then
          raise Argument_Error;
       end if;

       return Result;
    end Acos;

    ----------
    -- Asin --
    ----------

    function Asin (X : Double) return Double is
       Result  : Double;

    begin
       Result := Atan (X / Sqrt ((1.0 - X) * (1.0 + X)));

       --  The result value is NaN iff input was invalid

       if Is_Nan (Result) then
          raise Argument_Error;
       end if;

       return Result;
    end Asin;

    ---------
    -- Cos --
    ---------

    function Cos (X : Double) return Double is
       Reduced_X : Double := abs X;
       Result    : Double;
       Quadrant  : Natural range 0 .. 3;

    begin
       if Reduced_X > Pi / 4.0 then
          Reduce (Reduced_X, Quadrant);

          case Quadrant is
             when 0 =>
                Asm (Template  => "fcos",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", Reduced_X));
             when 1 =>
                Asm (Template  => "fsin",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", -Reduced_X));
             when 2 =>
                Asm (Template  => "fcos ; fchs",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", Reduced_X));
             when 3 =>
                Asm (Template  => "fsin",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", Reduced_X));
          end case;

       else
          Asm (Template  => "fcos",
               Outputs  => Double'Asm_Output ("=t", Result),
               Inputs   => Double'Asm_Input  ("0", Reduced_X));
       end if;

       return Result;
    end Cos;

    ---------------------
    -- Logarithmic_Pow --
    ---------------------

    function Logarithmic_Pow (X, Y : Double) return Double is
       Result  : Double;
    begin
       Asm (Template => ""             --  X                  : Y
        & "fyl2x                " & NL --  Y * Log2 (X)
        & "fld     %%st(0)      " & NL --  Y * Log2 (X)       : Y * Log2 (X)
        & "frndint              " & NL --  Int (...)          : Y * Log2 (X)
        & "fsubr   %%st, %%st(1)" & NL --  Int (...)          : Fract (...)
        & "fxch                 " & NL --  Fract (...)        : Int (...)
        & "f2xm1                " & NL --  2**Fract (...) - 1 : Int (...)
        & "fld1                 " & NL --  1 : 2**Fract (...) - 1 : Int (...)
        & "faddp   %%st, %%st(1)" & NL --  2**Fract (...)     : Int (...)
        & "fscale               ",     --  2**(Fract (...) + Int (...))
          Outputs  => Double'Asm_Output ("=t", Result),
          Inputs   =>
            (Double'Asm_Input  ("0", X),
             Double'Asm_Input  ("u", Y)));
       return Result;
    end Logarithmic_Pow;

    ---------
    -- Pow --
    ---------

    function Pow (X, Y : Double) return Double is
       type Mantissa_Type is mod 2**Double'Machine_Mantissa;
       --  Modular type that can hold all bits of the mantissa of Double

       --  For negative exponents, do divide at the end of the processing

       Negative_Y : constant Boolean := Y < 0.0;
       Abs_Y      : constant Double := abs Y;

       --  During this function the following invariant is kept:
       --  X ** (abs Y) = Base**(Exp_High + Exp_Mid + Exp_Low) * Factor

       Base : Double := X;

       Exp_High : Double := Double'Floor (Abs_Y);
       Exp_Mid  : Double;
       Exp_Low  : Double;
       Exp_Int  : Mantissa_Type;

       Factor : Double := 1.0;

    begin
       --  Select algorithm for calculating Pow (integer cases fall through)

       if Exp_High >= 2.0**Double'Machine_Mantissa then

          --  In case of Y that is IEEE infinity, just raise constraint error

          if Exp_High > Double'Safe_Last then
             raise Constraint_Error;
          end if;

          --  Large values of Y are even integers and will stay integer
          --  after division by two.

          loop
             --  Exp_Mid and Exp_Low are zero, so
             --    X**(abs Y) = Base ** Exp_High = (Base**2) ** (Exp_High / 2)

             Exp_High := Exp_High / 2.0;
             Base := Base * Base;
             exit when Exp_High < 2.0**Double'Machine_Mantissa;
          end loop;

       elsif Exp_High /= Abs_Y then
          Exp_Low := Abs_Y - Exp_High;
          Factor := 1.0;

          if Exp_Low /= 0.0 then

             --  Exp_Low now is in interval (0.0, 1.0)
             --  Exp_Mid := Double'Floor (Exp_Low * 4.0) / 4.0;

             Exp_Mid := 0.0;
             Exp_Low := Exp_Low - Exp_Mid;

             if Exp_Low >= 0.5 then
                Factor := Sqrt (X);
                Exp_Low := Exp_Low - 0.5;  -- exact

                if Exp_Low >= 0.25 then
                   Factor := Factor * Sqrt (Factor);
                   Exp_Low := Exp_Low - 0.25; --  exact
                end if;

             elsif Exp_Low >= 0.25 then
                Factor := Sqrt (Sqrt (X));
                Exp_Low := Exp_Low - 0.25; --  exact
             end if;

             --  Exp_Low now is in interval (0.0, 0.25)

             --  This means it is safe to call Logarithmic_Pow
             --  for the remaining part.

             Factor := Factor * Logarithmic_Pow (X, Exp_Low);
          end if;

       elsif X = 0.0 then
          return 0.0;
       end if;

       --  Exp_High is non-zero integer smaller than 2**Double'Machine_Mantissa

       Exp_Int := Mantissa_Type (Exp_High);

       --  Standard way for processing integer powers > 0

       while Exp_Int > 1 loop
          if (Exp_Int and 1) = 1 then

             --  Base**Y = Base**(Exp_Int - 1) * Exp_Int for Exp_Int > 0

             Factor := Factor * Base;
          end if;

          --  Exp_Int is even and Exp_Int > 0, so
          --    Base**Y = (Base**2)**(Exp_Int / 2)

          Base := Base * Base;
          Exp_Int := Exp_Int / 2;
       end loop;

       --  Exp_Int = 1 or Exp_Int = 0

       if Exp_Int = 1 then
          Factor := Base * Factor;
       end if;

       if Negative_Y then
          Factor := 1.0 / Factor;
       end if;

       return Factor;
    end Pow;

    ---------
    -- Sin --
    ---------

    function Sin (X : Double) return Double is
       Reduced_X : Double := X;
       Result    : Double;
       Quadrant  : Natural range 0 .. 3;

    begin
       if abs X > Pi / 4.0 then
          Reduce (Reduced_X, Quadrant);

          case Quadrant is
             when 0 =>
                Asm (Template  => "fsin",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", Reduced_X));
             when 1 =>
                Asm (Template  => "fcos",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", Reduced_X));
             when 2 =>
                Asm (Template  => "fsin",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", -Reduced_X));
             when 3 =>
                Asm (Template  => "fcos ; fchs",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", Reduced_X));
          end case;

       else
          Asm (Template  => "fsin",
             Outputs  => Double'Asm_Output ("=t", Result),
             Inputs   => Double'Asm_Input  ("0", Reduced_X));
       end if;

       return Result;
    end Sin;

    ---------
    -- Tan --
    ---------

    function Tan (X : Double) return Double is
       Reduced_X : Double := X;
       Result    : Double;
       Quadrant  : Natural range 0 .. 3;

    begin
       if abs X > Pi / 4.0 then
          Reduce (Reduced_X, Quadrant);

          if Quadrant mod 2 = 0 then
             Asm (Template  => "fptan" & NL
                             & "ffree   %%st(0)"  & NL
                             & "fincstp",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", Reduced_X));
          else
             Asm (Template  => "fsincos" & NL
                             & "fdivp   %%st, %%st(1)" & NL
                             & "fchs",
                   Outputs  => Double'Asm_Output ("=t", Result),
                   Inputs   => Double'Asm_Input  ("0", Reduced_X));
          end if;

       else
          Asm (Template  =>
                "fptan                 " & NL
              & "ffree   %%st(0)      " & NL
              & "fincstp              ",
                Outputs  => Double'Asm_Output ("=t", Result),
                Inputs   => Double'Asm_Input  ("0", Reduced_X));
       end if;

       return Result;
    end Tan;

    ----------
    -- Sinh --
    ----------

    function Sinh (X : Double) return Double is
    begin
       --  Mathematically Sinh (x) is defined to be (Exp (X) - Exp (-X)) / 2.0

       if abs X < 25.0 then
          return (Exp (X) - Exp (-X)) / 2.0;
       else
          return Exp (X) / 2.0;
       end if;
    end Sinh;

    ----------
    -- Cosh --
    ----------

    function Cosh (X : Double) return Double is
    begin
       --  Mathematically Cosh (X) is defined to be (Exp (X) + Exp (-X)) / 2.0

       if abs X < 22.0 then
          return (Exp (X) + Exp (-X)) / 2.0;
       else
          return Exp (X) / 2.0;
       end if;
    end Cosh;

    ----------
    -- Tanh --
    ----------

    function Tanh (X : Double) return Double is
    begin
       --  Return the Hyperbolic Tangent of x

       --                                    x    -x
       --                                   e  - e        Sinh (X)
       --       Tanh (X) is defined to be -----------   = --------
       --                                    x    -x      Cosh (X)
       --                                   e  + e

       if abs X > 23.0 then
          return Double'Copy_Sign (1.0, X);
       end if;

       return 1.0 / (1.0 + Exp (-(2.0 * X))) - 1.0 / (1.0 + Exp (2.0 * X));
    end Tanh;

 end Ada.Numerics.Aux;
	------------------------------------------------------------------------------
	-- --
	-- GNAT RUN-TIME COMPONENTS --
	-- --
	-- A D A . N U M E R I C S . A U X --
	-- --
	-- B o d y --
	-- (Machine Version for x86) --
	-- --
	-- Copyright (C) 1998-2009, Free Software Foundation, Inc. --
	-- --
	-- GNAT is free software; you can redistribute it and/or modify it under --
	-- terms of the GNU General Public License as published by the Free Soft- --
	-- ware Foundation; either version 3, or (at your option) any later ver- --
	-- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
	-- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
	-- or FITNESS FOR A PARTICULAR PURPOSE. --
	-- --
	-- As a special exception under Section 7 of GPL version 3, you are granted --
	-- additional permissions described in the GCC Runtime Library Exception, --
	-- version 3.1, as published by the Free Software Foundation. --
	-- --
	-- You should have received a copy of the GNU General Public License and --
	-- a copy of the GCC Runtime Library Exception along with this program; --
	-- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see --
	-- <http://www.gnu.org/licenses/>. --
	-- --
	-- GNAT was originally developed by the GNAT team at New York University. --
	-- Extensive contributions were provided by Ada Core Technologies Inc. --
	-- --
	------------------------------------------------------------------------------

	-- File a-numaux.adb <- 86numaux.adb

	-- This version of Numerics.Aux is for the IEEE Double Extended floating
	-- point format on x86.

	with System.Machine_Code; use System.Machine_Code;

	package body Ada.Numerics.Aux is

	NL : constant String := ASCII.LF & ASCII.HT;

	-----------------------
	-- Local subprograms --
	-----------------------

	function Is_Nan (X : Double) return Boolean;
	-- Return True iff X is a IEEE NaN value

	function Logarithmic_Pow (X, Y : Double) return Double;
	-- Implementation of X**Y using Exp and Log functions (binary base)
	-- to calculate the exponentiation. This is used by Pow for values
	-- for values of Y in the open interval (-0.25, 0.25)

	procedure Reduce (X : in out Double; Q : out Natural);
	-- Implements reduction of X by Pi/2. Q is the quadrant of the final
	-- result in the range 0 .. 3. The absolute value of X is at most Pi.

	pragma Inline (Is_Nan);
	pragma Inline (Reduce);

	--------------------------------
	-- Basic Elementary Functions --
	--------------------------------

	-- This section implements a few elementary functions that are used to
	-- build the more complex ones. This ordering enables better inlining.

	----------
	-- Atan --
	----------

	function Atan (X : Double) return Double is
	Result : Double;

	begin
	Asm (Template =>
	"fld1" & NL
	& "fpatan",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", X));

	-- The result value is NaN iff input was invalid

	if not (Result = Result) then
	raise Argument_Error;
	end if;

	return Result;
	end Atan;

	---------
	-- Exp --
	---------

	function Exp (X : Double) return Double is
	Result : Double;
	begin
	Asm (Template =>
	"fldl2e " & NL
	& "fmulp %%st, %%st(1)" & NL -- X * log2 (E)
	& "fld %%st(0) " & NL
	& "frndint " & NL -- Integer (X * Log2 (E))
	& "fsubr %%st, %%st(1)" & NL -- Fraction (X * Log2 (E))
	& "fxch " & NL
	& "f2xm1 " & NL -- 2**(...) - 1
	& "fld1 " & NL
	& "faddp %%st, %%st(1)" & NL -- 2*(Fraction (X Log2 (E)))
	& "fscale " & NL -- E ** X
	& "fstp %%st(1) ",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", X));
	return Result;
	end Exp;

	------------
	-- Is_Nan --
	------------

	function Is_Nan (X : Double) return Boolean is
	begin
	-- The IEEE NaN values are the only ones that do not equal themselves

	return not (X = X);
	end Is_Nan;

	---------
	-- Log --
	---------

	function Log (X : Double) return Double is
	Result : Double;

	begin
	Asm (Template =>
	"fldln2 " & NL
	& "fxch " & NL
	& "fyl2x " & NL,
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", X));
	return Result;
	end Log;

	------------
	-- Reduce --
	------------

	procedure Reduce (X : in out Double; Q : out Natural) is
	Half_Pi : constant := Pi / 2.0;
	Two_Over_Pi : constant := 2.0 / Pi;

	HM : constant := Integer'Min (Double'Machine_Mantissa / 2, Natural'Size);
	M : constant Double := 0.5 + 2.0**(1 - HM); -- Splitting constant
	P1 : constant Double := Double'Leading_Part (Half_Pi, HM);
	P2 : constant Double := Double'Leading_Part (Half_Pi - P1, HM);
	P3 : constant Double := Double'Leading_Part (Half_Pi - P1 - P2, HM);
	P4 : constant Double := Double'Leading_Part (Half_Pi - P1 - P2 - P3, HM);
	P5 : constant Double := Double'Leading_Part (Half_Pi - P1 - P2 - P3
	- P4, HM);
	P6 : constant Double := Double'Model (Half_Pi - P1 - P2 - P3 - P4 - P5);
	K : Double := X * Two_Over_Pi;
	begin
	-- For X < 2.0**32, all products below are computed exactly.
	-- Due to cancellation effects all subtractions are exact as well.
	-- As no double extended floating-point number has more than 75
	-- zeros after the binary point, the result will be the correctly
	-- rounded result of X - K * (Pi / 2.0).

	while abs K >= 2.0**HM loop
	K := K * M - (K * M - K);
	X := (((((X - K * P1) - K * P2) - K * P3)
	- K * P4) - K * P5) - K * P6;
	K := X * Two_Over_Pi;
	end loop;

	if K /= K then

	-- K is not a number, because X was not finite

	raise Constraint_Error;
	end if;

	K := Double'Rounding (K);
	Q := Integer (K) mod 4;
	X := (((((X - K * P1) - K * P2) - K * P3)
	- K * P4) - K * P5) - K * P6;
	end Reduce;

	----------
	-- Sqrt --
	----------

	function Sqrt (X : Double) return Double is
	Result : Double;

	begin
	if X < 0.0 then
	raise Argument_Error;
	end if;

	Asm (Template => "fsqrt",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", X));

	return Result;
	end Sqrt;

	--------------------------------
	-- Other Elementary Functions --
	--------------------------------

	-- These are built using the previously implemented basic functions

	----------
	-- Acos --
	----------

	function Acos (X : Double) return Double is
	Result : Double;

	begin
	Result := 2.0 * Atan (Sqrt ((1.0 - X) / (1.0 + X)));

	-- The result value is NaN iff input was invalid

	if Is_Nan (Result) then
	raise Argument_Error;
	end if;

	return Result;
	end Acos;

	----------
	-- Asin --
	----------

	function Asin (X : Double) return Double is
	Result : Double;

	begin
	Result := Atan (X / Sqrt ((1.0 - X) * (1.0 + X)));

	-- The result value is NaN iff input was invalid

	if Is_Nan (Result) then
	raise Argument_Error;
	end if;

	return Result;
	end Asin;

	---------
	-- Cos --
	---------

	function Cos (X : Double) return Double is
	Reduced_X : Double := abs X;
	Result : Double;
	Quadrant : Natural range 0 .. 3;

	begin
	if Reduced_X > Pi / 4.0 then
	Reduce (Reduced_X, Quadrant);

	case Quadrant is
	when 0 =>
	Asm (Template => "fcos",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	when 1 =>
	Asm (Template => "fsin",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", -Reduced_X));
	when 2 =>
	Asm (Template => "fcos ; fchs",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	when 3 =>
	Asm (Template => "fsin",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	end case;

	else
	Asm (Template => "fcos",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	end if;

	return Result;
	end Cos;

	---------------------
	-- Logarithmic_Pow --
	---------------------

	function Logarithmic_Pow (X, Y : Double) return Double is
	Result : Double;
	begin
	Asm (Template => "" -- X : Y
	& "fyl2x " & NL -- Y * Log2 (X)
	& "fld %%st(0) " & NL -- Y * Log2 (X) : Y * Log2 (X)
	& "frndint " & NL -- Int (...) : Y * Log2 (X)
	& "fsubr %%st, %%st(1)" & NL -- Int (...) : Fract (...)
	& "fxch " & NL -- Fract (...) : Int (...)
	& "f2xm1 " & NL -- 2**Fract (...) - 1 : Int (...)
	& "fld1 " & NL -- 1 : 2**Fract (...) - 1 : Int (...)
	& "faddp %%st, %%st(1)" & NL -- 2**Fract (...) : Int (...)
	& "fscale ", -- 2**(Fract (...) + Int (...))
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs =>
	(Double'Asm_Input ("0", X),
	Double'Asm_Input ("u", Y)));
	return Result;
	end Logarithmic_Pow;

	---------
	-- Pow --
	---------

	function Pow (X, Y : Double) return Double is
	type Mantissa_Type is mod 2**Double'Machine_Mantissa;
	-- Modular type that can hold all bits of the mantissa of Double

	-- For negative exponents, do divide at the end of the processing

	Negative_Y : constant Boolean := Y < 0.0;
	Abs_Y : constant Double := abs Y;

	-- During this function the following invariant is kept:
	-- X (abs Y) = Base(Exp_High + Exp_Mid + Exp_Low) * Factor

	Base : Double := X;

	Exp_High : Double := Double'Floor (Abs_Y);
	Exp_Mid : Double;
	Exp_Low : Double;
	Exp_Int : Mantissa_Type;

	Factor : Double := 1.0;

	begin
	-- Select algorithm for calculating Pow (integer cases fall through)

	if Exp_High >= 2.0**Double'Machine_Mantissa then

	-- In case of Y that is IEEE infinity, just raise constraint error

	if Exp_High > Double'Safe_Last then
	raise Constraint_Error;
	end if;

	-- Large values of Y are even integers and will stay integer
	-- after division by two.

	loop
	-- Exp_Mid and Exp_Low are zero, so
	-- X(abs Y) = Base Exp_High = (Base2) (Exp_High / 2)

	Exp_High := Exp_High / 2.0;
	Base := Base * Base;
	exit when Exp_High < 2.0**Double'Machine_Mantissa;
	end loop;

	elsif Exp_High /= Abs_Y then
	Exp_Low := Abs_Y - Exp_High;
	Factor := 1.0;

	if Exp_Low /= 0.0 then

	-- Exp_Low now is in interval (0.0, 1.0)
	-- Exp_Mid := Double'Floor (Exp_Low * 4.0) / 4.0;

	Exp_Mid := 0.0;
	Exp_Low := Exp_Low - Exp_Mid;

	if Exp_Low >= 0.5 then
	Factor := Sqrt (X);
	Exp_Low := Exp_Low - 0.5; -- exact

	if Exp_Low >= 0.25 then
	Factor := Factor * Sqrt (Factor);
	Exp_Low := Exp_Low - 0.25; -- exact
	end if;

	elsif Exp_Low >= 0.25 then
	Factor := Sqrt (Sqrt (X));
	Exp_Low := Exp_Low - 0.25; -- exact
	end if;

	-- Exp_Low now is in interval (0.0, 0.25)

	-- This means it is safe to call Logarithmic_Pow
	-- for the remaining part.

	Factor := Factor * Logarithmic_Pow (X, Exp_Low);
	end if;

	elsif X = 0.0 then
	return 0.0;
	end if;

	-- Exp_High is non-zero integer smaller than 2**Double'Machine_Mantissa

	Exp_Int := Mantissa_Type (Exp_High);

	-- Standard way for processing integer powers > 0

	while Exp_Int > 1 loop
	if (Exp_Int and 1) = 1 then

	-- BaseY = Base(Exp_Int - 1) * Exp_Int for Exp_Int > 0

	Factor := Factor * Base;
	end if;

	-- Exp_Int is even and Exp_Int > 0, so
	-- BaseY = (Base2)**(Exp_Int / 2)

	Base := Base * Base;
	Exp_Int := Exp_Int / 2;
	end loop;

	-- Exp_Int = 1 or Exp_Int = 0

	if Exp_Int = 1 then
	Factor := Base * Factor;
	end if;

	if Negative_Y then
	Factor := 1.0 / Factor;
	end if;

	return Factor;
	end Pow;

	---------
	-- Sin --
	---------

	function Sin (X : Double) return Double is
	Reduced_X : Double := X;
	Result : Double;
	Quadrant : Natural range 0 .. 3;

	begin
	if abs X > Pi / 4.0 then
	Reduce (Reduced_X, Quadrant);

	case Quadrant is
	when 0 =>
	Asm (Template => "fsin",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	when 1 =>
	Asm (Template => "fcos",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	when 2 =>
	Asm (Template => "fsin",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", -Reduced_X));
	when 3 =>
	Asm (Template => "fcos ; fchs",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	end case;

	else
	Asm (Template => "fsin",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	end if;

	return Result;
	end Sin;

	---------
	-- Tan --
	---------

	function Tan (X : Double) return Double is
	Reduced_X : Double := X;
	Result : Double;
	Quadrant : Natural range 0 .. 3;

	begin
	if abs X > Pi / 4.0 then
	Reduce (Reduced_X, Quadrant);

	if Quadrant mod 2 = 0 then
	Asm (Template => "fptan" & NL
	& "ffree %%st(0)" & NL
	& "fincstp",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	else
	Asm (Template => "fsincos" & NL
	& "fdivp %%st, %%st(1)" & NL
	& "fchs",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	end if;

	else
	Asm (Template =>
	"fptan " & NL
	& "ffree %%st(0) " & NL
	& "fincstp ",
	Outputs => Double'Asm_Output ("=t", Result),
	Inputs => Double'Asm_Input ("0", Reduced_X));
	end if;

	return Result;
	end Tan;

	----------
	-- Sinh --
	----------

	function Sinh (X : Double) return Double is
	begin
	-- Mathematically Sinh (x) is defined to be (Exp (X) - Exp (-X)) / 2.0

	if abs X < 25.0 then
	return (Exp (X) - Exp (-X)) / 2.0;
	else
	return Exp (X) / 2.0;
	end if;
	end Sinh;

	----------
	-- Cosh --
	----------

	function Cosh (X : Double) return Double is
	begin
	-- Mathematically Cosh (X) is defined to be (Exp (X) + Exp (-X)) / 2.0

	if abs X < 22.0 then
	return (Exp (X) + Exp (-X)) / 2.0;
	else
	return Exp (X) / 2.0;
	end if;
	end Cosh;

	----------
	-- Tanh --
	----------

	function Tanh (X : Double) return Double is
	begin
	-- Return the Hyperbolic Tangent of x

	-- x -x
	-- e - e Sinh (X)
	-- Tanh (X) is defined to be ----------- = --------
	-- x -x Cosh (X)
	-- e + e

	if abs X > 23.0 then
	return Double'Copy_Sign (1.0, X);
	end if;

	return 1.0 / (1.0 + Exp (-(2.0 * X))) - 1.0 / (1.0 + Exp (2.0 * X));
	end Tanh;

	end Ada.Numerics.Aux;