From: Arnaud Charlet Date: Wed, 8 Dec 2004 11:26:32 +0000 (+0100) Subject: * eval_fat.adb: Revert previous change. X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=e913f03badb889da71c50a230b357aac6561ea01;p=gcc.git * eval_fat.adb: Revert previous change. From-SVN: r91880 --- diff --git a/gcc/ada/eval_fat.adb b/gcc/ada/eval_fat.adb index 9221e919cdc..00a131dd623 100644 --- a/gcc/ada/eval_fat.adb +++ b/gcc/ada/eval_fat.adb @@ -38,14 +38,14 @@ package body Eval_Fat is -- case of anyone ever having to adjust this code for another value, -- and for documentation purposes. - -- Another assumption is that the range of the floating-point type - -- is symmetric around zero. - type Radix_Power_Table is array (Int range 1 .. 4) of Int; Radix_Powers : constant Radix_Power_Table := (Radix ** 1, Radix ** 2, Radix ** 3, Radix ** 4); + function Float_Radix return T renames Ureal_2; + -- Radix expressed in real form + ----------------------- -- Local Subprograms -- ----------------------- @@ -74,6 +74,12 @@ package body Eval_Fat is -- even, a floor operation or a ceiling operation depending on the setting -- of Mode (see corresponding descriptions in Urealp). + function Eps_Model (RT : R) return T; + -- Return the smallest model number of R. + + function Eps_Denorm (RT : R) return T; + -- Return the smallest denormal of type R. + function Machine_Emin (RT : R) return Int; -- Return value of the Machine_Emin attribute @@ -85,8 +91,10 @@ package body Eval_Fat is begin if Towards = X then return X; + elsif Towards > X then return Succ (RT, X); + else return Pred (RT, X); end if; @@ -98,11 +106,14 @@ package body Eval_Fat is function Ceiling (RT : R; X : T) return T is XT : constant T := Truncation (RT, X); + begin if UR_Is_Negative (X) then return XT; + elsif X = XT then return X; + else return XT + Ureal_1; end if; @@ -371,10 +382,10 @@ package body Eval_Fat is Calculate_Fraction_And_Exponent : begin Uintp_Mark := Mark; - -- Determine correct rounding based on the remainder which is in - -- N and the divisor D. The rounding is performed on the absolute - -- value of X, so Ceiling and Floor need to check for the sign of - -- X explicitly. + -- Determine correct rounding based on the remainder + -- which is in N and the divisor D. The rounding is + -- performed on the absolute value of X, so Ceiling + -- and Floor need to check for the sign of X explicitly. case Mode is when Round_Even => @@ -429,6 +440,25 @@ package body Eval_Fat is end Calculate_Fraction_And_Exponent; end Decompose_Int; + ---------------- + -- Eps_Denorm -- + ---------------- + + function Eps_Denorm (RT : R) return T is + begin + return Float_Radix ** UI_From_Int + (Machine_Emin (RT) - Machine_Mantissa (RT)); + end Eps_Denorm; + + --------------- + -- Eps_Model -- + --------------- + + function Eps_Model (RT : R) return T is + begin + return Float_Radix ** UI_From_Int (Machine_Emin (RT)); + end Eps_Model; + -------------- -- Exponent -- -------------- @@ -705,8 +735,37 @@ package body Eval_Fat is ---------- function Pred (RT : R; X : T) return T is + Result_F : UI; + Result_X : UI; + begin - return -Succ (RT, -X); + if abs X < Eps_Model (RT) then + if Denorm_On_Target then + return X - Eps_Denorm (RT); + + elsif X > Ureal_0 then + + -- Target does not support denorms, so predecessor is 0.0 + + return Ureal_0; + + else + -- Target does not support denorms, and X is 0.0 + -- or at least bigger than -Eps_Model (RT) + + return -Eps_Model (RT); + end if; + + else + Decompose_Int (RT, X, Result_F, Result_X, Ceiling); + return UR_From_Components + (Num => Result_F - 1, + Den => Machine_Mantissa (RT) - Result_X, + Rbase => Radix, + Negative => False); + -- Result_F may be false, but this is OK as UR_From_Components + -- handles that situation. + end if; end Pred; --------------- @@ -833,38 +892,35 @@ package body Eval_Fat is ---------- function Succ (RT : R; X : T) return T is - Emin : constant UI := UI_From_Int (Machine_Emin (RT)); - Mantissa : constant UI := UI_From_Int (Machine_Mantissa (RT)); - Exp : UI := UI_Max (Emin, Exponent (RT, X)); - Frac : T; - New_Frac : T; + Result_F : UI; + Result_X : UI; begin - if UR_Is_Zero (X) then - Exp := Emin; - end if; + if abs X < Eps_Model (RT) then + if Denorm_On_Target then + return X + Eps_Denorm (RT); - -- Set exponent such that the radix point will be directly - -- following the mantissa after scaling + elsif X < Ureal_0 then + -- Target does not support denorms, so successor is 0.0 + return Ureal_0; - if Denorm_On_Target or Exp /= Emin then - Exp := Exp - Mantissa; - else - Exp := Exp - 1; - end if; - - Frac := Scaling (RT, X, -Exp); - New_Frac := Ceiling (RT, Frac); - - if New_Frac = Frac then - if New_Frac = Scaling (RT, -Ureal_1, Mantissa - 1) then - New_Frac := New_Frac + Scaling (RT, Ureal_1, Uint_Minus_1); else - New_Frac := New_Frac + Ureal_1; + -- Target does not support denorms, and X is 0.0 + -- or at least smaller than Eps_Model (RT) + + return Eps_Model (RT); end if; - end if; - return Scaling (RT, New_Frac, Exp); + else + Decompose_Int (RT, X, Result_F, Result_X, Floor); + return UR_From_Components + (Num => Result_F + 1, + Den => Machine_Mantissa (RT) - Result_X, + Rbase => Radix, + Negative => False); + -- Result_F may be false, but this is OK as UR_From_Components + -- handles that situation. + end if; end Succ; ---------------- @@ -873,6 +929,7 @@ package body Eval_Fat is function Truncation (RT : R; X : T) return T is pragma Warnings (Off, RT); + begin return UR_From_Uint (UR_Trunc (X)); end Truncation;