------------------------------------------------------------------------------ -- -- -- GNAT RUN-TIME COMPONENTS -- -- -- -- A D A . W I D E _ T E X T _ I O . F I X E D _ I O -- -- -- -- B o d y -- -- -- -- Copyright (C) 2020, 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 -- -- . -- -- -- -- GNAT was originally developed by the GNAT team at New York University. -- -- Extensive contributions were provided by Ada Core Technologies Inc. -- -- -- ------------------------------------------------------------------------------ with Interfaces; with Ada.Wide_Text_IO.Fixed_Aux; with Ada.Wide_Text_IO.Float_Aux; with System.Img_Fixed_32; use System.Img_Fixed_32; with System.Img_Fixed_64; use System.Img_Fixed_64; with System.Img_Fixed_128; use System.Img_Fixed_128; with System.Val_Fixed_32; use System.Val_Fixed_32; with System.Val_Fixed_64; use System.Val_Fixed_64; with System.Val_Fixed_128; use System.Val_Fixed_128; with System.Val_LLF; use System.Val_LLF; with System.WCh_Con; use System.WCh_Con; with System.WCh_WtS; use System.WCh_WtS; package body Ada.Wide_Text_IO.Fixed_IO is -- Note: we still use the floating-point I/O routines for types whose small -- is not the ratio of two sufficiently small integers. This will result in -- inaccuracies for fixed point types that require more precision than is -- available in Long_Long_Float. subtype Int32 is Interfaces.Integer_32; use type Int32; subtype Int64 is Interfaces.Integer_64; use type Int64; subtype Int128 is Interfaces.Integer_128; use type Int128; package Aux32 is new Ada.Wide_Text_IO.Fixed_Aux (Int32, Scan_Fixed32, Set_Image_Fixed32); package Aux64 is new Ada.Wide_Text_IO.Fixed_Aux (Int64, Scan_Fixed64, Set_Image_Fixed64); package Aux128 is new Ada.Wide_Text_IO.Fixed_Aux (Int128, Scan_Fixed128, Set_Image_Fixed128); package Aux_Long_Long_Float is new Ada.Wide_Text_IO.Float_Aux (Long_Long_Float, Scan_Long_Long_Float); -- Throughout this generic body, we distinguish between the case where type -- Int32 is OK, where type Int64 is OK and where type Int128 is OK. These -- boolean constants are used to test for this, such that only code for the -- relevant case is included in the instance; that's why the computation of -- their value must be fully static (although it is not a static expression -- in the RM sense). OK_Get_32 : constant Boolean := Num'Base'Object_Size <= 32 and then ((Num'Small_Numerator = 1 and then Num'Small_Denominator <= 2**31) or else (Num'Small_Denominator = 1 and then Num'Small_Numerator <= 2**31) or else (Num'Small_Numerator <= 2**27 and then Num'Small_Denominator <= 2**27)); -- These conditions are derived from the prerequisites of System.Value_F OK_Put_32 : constant Boolean := Num'Base'Object_Size <= 32 and then ((Num'Small_Numerator = 1 and then Num'Small_Denominator <= 2**31) or else (Num'Small_Denominator = 1 and then Num'Small_Numerator <= 2**31) or else (Num'Small_Numerator < Num'Small_Denominator and then Num'Small_Denominator <= 2**27) or else (Num'Small_Denominator < Num'Small_Numerator and then Num'Small_Numerator <= 2**25)); -- These conditions are derived from the prerequisites of System.Image_F OK_Get_64 : constant Boolean := Num'Base'Object_Size <= 64 and then ((Num'Small_Numerator = 1 and then Num'Small_Denominator <= 2**63) or else (Num'Small_Denominator = 1 and then Num'Small_Numerator <= 2**63) or else (Num'Small_Numerator <= 2**59 and then Num'Small_Denominator <= 2**59)); -- These conditions are derived from the prerequisites of System.Value_F OK_Put_64 : constant Boolean := Num'Base'Object_Size <= 64 and then ((Num'Small_Numerator = 1 and then Num'Small_Denominator <= 2**63) or else (Num'Small_Denominator = 1 and then Num'Small_Numerator <= 2**63) or else (Num'Small_Numerator < Num'Small_Denominator and then Num'Small_Denominator <= 2**59) or else (Num'Small_Denominator < Num'Small_Numerator and then Num'Small_Numerator <= 2**53)); -- These conditions are derived from the prerequisites of System.Image_F OK_Get_128 : constant Boolean := Num'Base'Object_Size <= 128 and then ((Num'Small_Numerator = 1 and then Num'Small_Denominator <= 2**127) or else (Num'Small_Denominator = 1 and then Num'Small_Numerator <= 2**127) or else (Num'Small_Numerator <= 2**123 and then Num'Small_Denominator <= 2**123)); -- These conditions are derived from the prerequisites of System.Value_F OK_Put_128 : constant Boolean := Num'Base'Object_Size <= 128 and then ((Num'Small_Numerator = 1 and then Num'Small_Denominator <= 2**127) or else (Num'Small_Denominator = 1 and then Num'Small_Numerator <= 2**127) or else (Num'Small_Numerator < Num'Small_Denominator and then Num'Small_Denominator <= 2**123) or else (Num'Small_Denominator < Num'Small_Numerator and then Num'Small_Numerator <= 2**122)); -- These conditions are derived from the prerequisites of System.Image_F E : constant Natural := 127 - 64 * Boolean'Pos (OK_Put_64) - 32 * Boolean'Pos (OK_Put_32); -- T'Size - 1 for the selected Int{32,64,128} F0 : constant Natural := 0; F1 : constant Natural := F0 + 38 * Boolean'Pos (2.0**E * Num'Small * 10.0**(-F0) >= 1.0E+38); F2 : constant Natural := F1 + 19 * Boolean'Pos (2.0**E * Num'Small * 10.0**(-F1) >= 1.0E+19); F3 : constant Natural := F2 + 9 * Boolean'Pos (2.0**E * Num'Small * 10.0**(-F2) >= 1.0E+9); F4 : constant Natural := F3 + 5 * Boolean'Pos (2.0**E * Num'Small * 10.0**(-F3) >= 1.0E+5); F5 : constant Natural := F4 + 3 * Boolean'Pos (2.0**E * Num'Small * 10.0**(-F4) >= 1.0E+3); F6 : constant Natural := F5 + 2 * Boolean'Pos (2.0**E * Num'Small * 10.0**(-F5) >= 1.0E+2); F7 : constant Natural := F6 + 1 * Boolean'Pos (2.0**E * Num'Small * 10.0**(-F6) >= 1.0E+1); -- Binary search for the number of digits - 1 before the decimal point of -- the product 2.0**E * Num'Small. For0 : constant Natural := 2 + F7; -- Fore value for the fixed point type whose mantissa is Int{32,64,128} and -- whose small is Num'Small. --------- -- Get -- --------- procedure Get (File : File_Type; Item : out Num; Width : Field := 0) is pragma Unsuppress (Range_Check); begin if OK_Get_32 then Item := Num'Fixed_Value (Aux32.Get (File, Width, -Num'Small_Numerator, -Num'Small_Denominator)); elsif OK_Get_64 then Item := Num'Fixed_Value (Aux64.Get (File, Width, -Num'Small_Numerator, -Num'Small_Denominator)); elsif OK_Get_128 then Item := Num'Fixed_Value (Aux128.Get (File, Width, -Num'Small_Numerator, -Num'Small_Denominator)); else Aux_Long_Long_Float.Get (File, Long_Long_Float (Item), Width); end if; exception when Constraint_Error => raise Data_Error; end Get; procedure Get (Item : out Num; Width : Field := 0) is begin Get (Current_In, Item, Width); end Get; procedure Get (From : Wide_String; Item : out Num; Last : out Positive) is pragma Unsuppress (Range_Check); S : constant String := Wide_String_To_String (From, WCEM_Upper); -- String on which we do the actual conversion. Note that the method -- used for wide character encoding is irrelevant, since if there is -- a character outside the Standard.Character range then the call to -- Aux.Gets will raise Data_Error in any case. begin if OK_Get_32 then Item := Num'Fixed_Value (Aux32.Gets (S, Last, -Num'Small_Numerator, -Num'Small_Denominator)); elsif OK_Get_64 then Item := Num'Fixed_Value (Aux64.Gets (S, Last, -Num'Small_Numerator, -Num'Small_Denominator)); elsif OK_Get_128 then Item := Num'Fixed_Value (Aux128.Gets (S, Last, -Num'Small_Numerator, -Num'Small_Denominator)); else Aux_Long_Long_Float.Gets (S, Long_Long_Float (Item), Last); end if; exception when Constraint_Error => raise Data_Error; end Get; --------- -- Put -- --------- procedure Put (File : File_Type; Item : Num; Fore : Field := Default_Fore; Aft : Field := Default_Aft; Exp : Field := Default_Exp) is begin if OK_Put_32 then Aux32.Put (File, Int32'Integer_Value (Item), Fore, Aft, Exp, -Num'Small_Numerator, -Num'Small_Denominator, For0, Num'Aft); elsif OK_Put_64 then Aux64.Put (File, Int64'Integer_Value (Item), Fore, Aft, Exp, -Num'Small_Numerator, -Num'Small_Denominator, For0, Num'Aft); elsif OK_Put_128 then Aux128.Put (File, Int128'Integer_Value (Item), Fore, Aft, Exp, -Num'Small_Numerator, -Num'Small_Denominator, For0, Num'Aft); else Aux_Long_Long_Float.Put (File, Long_Long_Float (Item), Fore, Aft, Exp); end if; end Put; procedure Put (Item : Num; Fore : Field := Default_Fore; Aft : Field := Default_Aft; Exp : Field := Default_Exp) is begin Put (Current_Out, Item, Fore, Aft, Exp); end Put; procedure Put (To : out Wide_String; Item : Num; Aft : Field := Default_Aft; Exp : Field := Default_Exp) is S : String (To'First .. To'Last); begin if OK_Put_32 then Aux32.Puts (S, Int32'Integer_Value (Item), Aft, Exp, -Num'Small_Numerator, -Num'Small_Denominator, For0, Num'Aft); elsif OK_Put_64 then Aux64.Puts (S, Int64'Integer_Value (Item), Aft, Exp, -Num'Small_Numerator, -Num'Small_Denominator, For0, Num'Aft); elsif OK_Put_128 then Aux128.Puts (S, Int128'Integer_Value (Item), Aft, Exp, -Num'Small_Numerator, -Num'Small_Denominator, For0, Num'Aft); else Aux_Long_Long_Float.Puts (S, Long_Long_Float (Item), Aft, Exp); end if; for J in S'Range loop To (J) := Wide_Character'Val (Character'Pos (S (J))); end loop; end Put; end Ada.Wide_Text_IO.Fixed_IO;