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| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Mon, 25 May 2020 18:13:55 +0900 |
| parents | 1830386684a0 |
| children |
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------------------------------------------------------------------------------ -- -- -- GNAT COMPILER COMPONENTS -- -- -- -- S E T _ T A R G -- -- -- -- B o d y -- -- -- -- Copyright (C) 2013-2019, 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. See the GNU General Public License -- -- for more details. You should have received a copy of the GNU General -- -- Public License distributed with GNAT; see file COPYING3. If not, go to -- -- http://www.gnu.org/licenses for a complete copy of the license. -- -- -- -- GNAT was originally developed by the GNAT team at New York University. -- -- Extensive contributions were provided by Ada Core Technologies Inc. -- -- -- ------------------------------------------------------------------------------ with Debug; use Debug; with Get_Targ; use Get_Targ; with Opt; use Opt; with Output; use Output; with System; use System; with System.OS_Lib; use System.OS_Lib; with Unchecked_Conversion; package body Set_Targ is -------------------------------------------------------- -- Data Used to Read/Write Target Dependent Info File -- -------------------------------------------------------- -- Table of string names written to file subtype Str is String; S_Bits_BE : constant Str := "Bits_BE"; S_Bits_Per_Unit : constant Str := "Bits_Per_Unit"; S_Bits_Per_Word : constant Str := "Bits_Per_Word"; S_Bytes_BE : constant Str := "Bytes_BE"; S_Char_Size : constant Str := "Char_Size"; S_Double_Float_Alignment : constant Str := "Double_Float_Alignment"; S_Double_Scalar_Alignment : constant Str := "Double_Scalar_Alignment"; S_Double_Size : constant Str := "Double_Size"; S_Float_Size : constant Str := "Float_Size"; S_Float_Words_BE : constant Str := "Float_Words_BE"; S_Int_Size : constant Str := "Int_Size"; S_Long_Double_Size : constant Str := "Long_Double_Size"; S_Long_Long_Size : constant Str := "Long_Long_Size"; S_Long_Size : constant Str := "Long_Size"; S_Maximum_Alignment : constant Str := "Maximum_Alignment"; S_Max_Unaligned_Field : constant Str := "Max_Unaligned_Field"; S_Pointer_Size : constant Str := "Pointer_Size"; S_Short_Enums : constant Str := "Short_Enums"; S_Short_Size : constant Str := "Short_Size"; S_Strict_Alignment : constant Str := "Strict_Alignment"; S_System_Allocator_Alignment : constant Str := "System_Allocator_Alignment"; S_Wchar_T_Size : constant Str := "Wchar_T_Size"; S_Words_BE : constant Str := "Words_BE"; -- Table of names type AStr is access all String; DTN : constant array (Nat range <>) of AStr := ( S_Bits_BE 'Unrestricted_Access, S_Bits_Per_Unit 'Unrestricted_Access, S_Bits_Per_Word 'Unrestricted_Access, S_Bytes_BE 'Unrestricted_Access, S_Char_Size 'Unrestricted_Access, S_Double_Float_Alignment 'Unrestricted_Access, S_Double_Scalar_Alignment 'Unrestricted_Access, S_Double_Size 'Unrestricted_Access, S_Float_Size 'Unrestricted_Access, S_Float_Words_BE 'Unrestricted_Access, S_Int_Size 'Unrestricted_Access, S_Long_Double_Size 'Unrestricted_Access, S_Long_Long_Size 'Unrestricted_Access, S_Long_Size 'Unrestricted_Access, S_Maximum_Alignment 'Unrestricted_Access, S_Max_Unaligned_Field 'Unrestricted_Access, S_Pointer_Size 'Unrestricted_Access, S_Short_Enums 'Unrestricted_Access, S_Short_Size 'Unrestricted_Access, S_Strict_Alignment 'Unrestricted_Access, S_System_Allocator_Alignment 'Unrestricted_Access, S_Wchar_T_Size 'Unrestricted_Access, S_Words_BE 'Unrestricted_Access); -- Table of corresponding value pointers DTV : constant array (Nat range <>) of System.Address := ( Bits_BE 'Address, Bits_Per_Unit 'Address, Bits_Per_Word 'Address, Bytes_BE 'Address, Char_Size 'Address, Double_Float_Alignment 'Address, Double_Scalar_Alignment 'Address, Double_Size 'Address, Float_Size 'Address, Float_Words_BE 'Address, Int_Size 'Address, Long_Double_Size 'Address, Long_Long_Size 'Address, Long_Size 'Address, Maximum_Alignment 'Address, Max_Unaligned_Field 'Address, Pointer_Size 'Address, Short_Enums 'Address, Short_Size 'Address, Strict_Alignment 'Address, System_Allocator_Alignment 'Address, Wchar_T_Size 'Address, Words_BE 'Address); DTR : array (Nat range DTV'Range) of Boolean := (others => False); -- Table of flags used to validate that all values are present in file ----------------------- -- Local Subprograms -- ----------------------- procedure Read_Target_Dependent_Values (File_Name : String); -- Read target dependent values from File_Name, and set the target -- dependent values (global variables) declared in this package. procedure Fail (E : String); pragma No_Return (Fail); -- Terminate program with fatal error message passed as parameter procedure Register_Float_Type (Name : C_String; Digs : Natural; Complex : Boolean; Count : Natural; Float_Rep : Float_Rep_Kind; Precision : Positive; Size : Positive; Alignment : Natural); pragma Convention (C, Register_Float_Type); -- Call back to allow the back end to register available types. This call -- back makes entries in the FPT_Mode_Table for any floating point types -- reported by the back end. Name is the name of the type as a normal -- format Null-terminated string. Digs is the number of digits, where 0 -- means it is not a fpt type (ignored during registration). Complex is -- non-zero if the type has real and imaginary parts (also ignored during -- registration). Count is the number of elements in a vector type (zero = -- not a vector, registration ignores vectors). Float_Rep shows the kind of -- floating-point type, and Precision, Size and Alignment are the precision -- size and alignment in bits. -- -- The only types that are actually registered have Digs non-zero, Complex -- zero (false), and Count zero (not a vector). The Long_Double_Index -- variable below is updated to indicate the index at which a "long double" -- type can be found if it gets registered at all. Long_Double_Index : Integer := -1; -- Once all the floating point types have been registered, the index in -- FPT_Mode_Table at which "long double" can be found, if anywhere. A -- negative value means that no "long double" has been registered. This -- is useful to know whether we have a "long double" available at all and -- get at it's characteristics without having to search the FPT_Mode_Table -- when we need to decide which C type should be used as the basis for -- Long_Long_Float in Ada. function FPT_Mode_Index_For (Name : String) return Natural; -- Return the index in FPT_Mode_Table that designates the entry -- corresponding to the C type named Name. Raise Program_Error if -- there is no such entry. function FPT_Mode_Index_For (T : S_Float_Types) return Natural; -- Return the index in FPT_Mode_Table that designates the entry for -- a back-end type suitable as a basis to construct the standard Ada -- floating point type identified by T. ---------------- -- C_Type_For -- ---------------- function C_Type_For (T : S_Float_Types) return String is -- ??? For now, we don't have a good way to tell the widest float -- type with hardware support. Basically, GCC knows the size of that -- type, but on x86-64 there often are two or three 128-bit types, -- one double extended that has 18 decimal digits, a 128-bit quad -- precision type with 33 digits and possibly a 128-bit decimal float -- type with 34 digits. As a workaround, we define Long_Long_Float as -- C's "long double" if that type exists and has at most 18 digits, -- or otherwise the same as Long_Float. Max_HW_Digs : constant := 18; -- Maximum hardware digits supported begin case T is when S_Float | S_Short_Float => return "float"; when S_Long_Float => return "double"; when S_Long_Long_Float => if Long_Double_Index >= 0 and then FPT_Mode_Table (Long_Double_Index).DIGS <= Max_HW_Digs then return "long double"; else return "double"; end if; end case; end C_Type_For; ---------- -- Fail -- ---------- procedure Fail (E : String) is E_Fatal : constant := 4; -- Code for fatal error begin Write_Str (E); Write_Eol; OS_Exit (E_Fatal); end Fail; ------------------------ -- FPT_Mode_Index_For -- ------------------------ function FPT_Mode_Index_For (Name : String) return Natural is begin for J in FPT_Mode_Table'First .. Num_FPT_Modes loop if FPT_Mode_Table (J).NAME.all = Name then return J; end if; end loop; raise Program_Error; end FPT_Mode_Index_For; function FPT_Mode_Index_For (T : S_Float_Types) return Natural is begin return FPT_Mode_Index_For (C_Type_For (T)); end FPT_Mode_Index_For; ------------------------- -- Register_Float_Type -- ------------------------- procedure Register_Float_Type (Name : C_String; Digs : Natural; Complex : Boolean; Count : Natural; Float_Rep : Float_Rep_Kind; Precision : Positive; Size : Positive; Alignment : Natural) is T : String (1 .. Name'Length); Last : Natural := 0; procedure Dump; -- Dump information given by the back end for the type to register ---------- -- Dump -- ---------- procedure Dump is begin Write_Str ("type " & T (1 .. Last) & " is "); if Count > 0 then Write_Str ("array (1 .. "); Write_Int (Int (Count)); if Complex then Write_Str (", 1 .. 2"); end if; Write_Str (") of "); elsif Complex then Write_Str ("array (1 .. 2) of "); end if; if Digs > 0 then Write_Str ("digits "); Write_Int (Int (Digs)); Write_Line (";"); Write_Str ("pragma Float_Representation ("); case Float_Rep is when AAMP => Write_Str ("AAMP"); when IEEE_Binary => Write_Str ("IEEE"); end case; Write_Line (", " & T (1 .. Last) & ");"); else Write_Str ("mod 2**"); Write_Int (Int (Precision / Positive'Max (1, Count))); Write_Line (";"); end if; if Precision = Size then Write_Str ("for " & T (1 .. Last) & "'Size use "); Write_Int (Int (Size)); Write_Line (";"); else Write_Str ("for " & T (1 .. Last) & "'Value_Size use "); Write_Int (Int (Precision)); Write_Line (";"); Write_Str ("for " & T (1 .. Last) & "'Object_Size use "); Write_Int (Int (Size)); Write_Line (";"); end if; Write_Str ("for " & T (1 .. Last) & "'Alignment use "); Write_Int (Int (Alignment / 8)); Write_Line (";"); Write_Eol; end Dump; -- Start of processing for Register_Float_Type begin -- Acquire name for J in T'Range loop T (J) := Name (Name'First + J - 1); if T (J) = ASCII.NUL then Last := J - 1; exit; end if; end loop; -- Dump info if debug flag set if Debug_Flag_Dot_B then Dump; end if; -- Acquire entry if non-vector non-complex fpt type (digits non-zero) if Digs > 0 and then not Complex and then Count = 0 then declare This_Name : constant String := T (1 .. Last); begin Num_FPT_Modes := Num_FPT_Modes + 1; FPT_Mode_Table (Num_FPT_Modes) := (NAME => new String'(This_Name), DIGS => Digs, FLOAT_REP => Float_Rep, PRECISION => Precision, SIZE => Size, ALIGNMENT => Alignment); if Long_Double_Index < 0 and then This_Name = "long double" then Long_Double_Index := Num_FPT_Modes; end if; end; end if; end Register_Float_Type; ----------------------------------- -- Write_Target_Dependent_Values -- ----------------------------------- -- We do this at the System.Os_Lib level, since we have to do the read at -- that level anyway, so it is easier and more consistent to follow the -- same path for the write. procedure Write_Target_Dependent_Values is Fdesc : File_Descriptor; OK : Boolean; Buffer : String (1 .. 80); Buflen : Natural; -- Buffer used to build line one of file type ANat is access all Natural; -- Pointer to Nat or Pos value (it is harmless to treat Pos values and -- Nat values as Natural via Unchecked_Conversion). function To_ANat is new Unchecked_Conversion (Address, ANat); procedure AddC (C : Character); -- Add one character to buffer procedure AddN (N : Natural); -- Add representation of integer N to Buffer, updating Buflen. N -- must be less than 1000, and output is 3 characters with leading -- spaces as needed. procedure Write_Line; -- Output contents of Buffer (1 .. Buflen) followed by a New_Line, -- and set Buflen back to zero, ready to write next line. ---------- -- AddC -- ---------- procedure AddC (C : Character) is begin Buflen := Buflen + 1; Buffer (Buflen) := C; end AddC; ---------- -- AddN -- ---------- procedure AddN (N : Natural) is begin if N > 999 then raise Program_Error; end if; if N > 99 then AddC (Character'Val (48 + N / 100)); else AddC (' '); end if; if N > 9 then AddC (Character'Val (48 + N / 10 mod 10)); else AddC (' '); end if; AddC (Character'Val (48 + N mod 10)); end AddN; ---------------- -- Write_Line -- ---------------- procedure Write_Line is begin AddC (ASCII.LF); if Buflen /= Write (Fdesc, Buffer'Address, Buflen) then Delete_File (Target_Dependent_Info_Write_Name.all, OK); Fail ("disk full writing file " & Target_Dependent_Info_Write_Name.all); end if; Buflen := 0; end Write_Line; -- Start of processing for Write_Target_Dependent_Values begin Fdesc := Create_File (Target_Dependent_Info_Write_Name.all, Text); if Fdesc = Invalid_FD then Fail ("cannot create file " & Target_Dependent_Info_Write_Name.all); end if; -- Loop through values for J in DTN'Range loop -- Output name Buflen := DTN (J)'Length; Buffer (1 .. Buflen) := DTN (J).all; -- Line up values while Buflen < 26 loop AddC (' '); end loop; AddC (' '); AddC (' '); -- Output value and write line AddN (To_ANat (DTV (J)).all); Write_Line; end loop; -- Blank line to separate sections Write_Line; -- Write lines for registered FPT types for J in 1 .. Num_FPT_Modes loop declare E : FPT_Mode_Entry renames FPT_Mode_Table (J); begin Buflen := E.NAME'Last; Buffer (1 .. Buflen) := E.NAME.all; -- Pad out to line up values while Buflen < 11 loop AddC (' '); end loop; AddC (' '); AddC (' '); AddN (E.DIGS); AddC (' '); AddC (' '); case E.FLOAT_REP is when AAMP => AddC ('A'); when IEEE_Binary => AddC ('I'); end case; AddC (' '); AddN (E.PRECISION); AddC (' '); AddN (E.ALIGNMENT); Write_Line; end; end loop; -- Close file Close (Fdesc, OK); if not OK then Fail ("disk full writing file " & Target_Dependent_Info_Write_Name.all); end if; end Write_Target_Dependent_Values; ---------------------------------- -- Read_Target_Dependent_Values -- ---------------------------------- procedure Read_Target_Dependent_Values (File_Name : String) is File_Desc : File_Descriptor; N : Natural; type ANat is access all Natural; -- Pointer to Nat or Pos value (it is harmless to treat Pos values -- as Nat via Unchecked_Conversion). function To_ANat is new Unchecked_Conversion (Address, ANat); VP : ANat; Buffer : String (1 .. 2000); Buflen : Natural; -- File information and length (2000 easily enough) Nam_Buf : String (1 .. 40); Nam_Len : Natural; procedure Check_Spaces; -- Checks that we have one or more spaces and skips them procedure FailN (S : String); pragma No_Return (FailN); -- Calls Fail adding " name in file xxx", where name is the currently -- gathered name in Nam_Buf, surrounded by quotes, and xxx is the -- name of the file. procedure Get_Name; -- Scan out name, leaving it in Nam_Buf with Nam_Len set. Calls -- Skip_Spaces to skip any following spaces. Note that the name is -- terminated by a sequence of at least two spaces. function Get_Nat return Natural; -- N on entry points to decimal integer, scan out decimal integer -- and return it, leaving N pointing to following space or LF. procedure Skip_Spaces; -- Skip past spaces ------------------ -- Check_Spaces -- ------------------ procedure Check_Spaces is begin if N > Buflen or else Buffer (N) /= ' ' then FailN ("missing space for"); end if; Skip_Spaces; return; end Check_Spaces; ----------- -- FailN -- ----------- procedure FailN (S : String) is begin Fail (S & " """ & Nam_Buf (1 .. Nam_Len) & """ in file " & File_Name); end FailN; -------------- -- Get_Name -- -------------- procedure Get_Name is begin Nam_Len := 0; -- Scan out name and put it in Nam_Buf loop if N > Buflen or else Buffer (N) = ASCII.LF then FailN ("incorrectly formatted line for"); end if; -- Name is terminated by two blanks exit when N < Buflen and then Buffer (N .. N + 1) = " "; Nam_Len := Nam_Len + 1; if Nam_Len > Nam_Buf'Last then Fail ("name too long"); end if; Nam_Buf (Nam_Len) := Buffer (N); N := N + 1; end loop; Check_Spaces; end Get_Name; ------------- -- Get_Nat -- ------------- function Get_Nat return Natural is Result : Natural := 0; begin loop if N > Buflen or else Buffer (N) not in '0' .. '9' or else Result > 999 then FailN ("bad value for"); end if; Result := Result * 10 + (Character'Pos (Buffer (N)) - 48); N := N + 1; exit when N <= Buflen and then (Buffer (N) = ASCII.LF or else Buffer (N) = ' '); end loop; return Result; end Get_Nat; ----------------- -- Skip_Spaces -- ----------------- procedure Skip_Spaces is begin while N <= Buflen and Buffer (N) = ' ' loop N := N + 1; end loop; end Skip_Spaces; -- Start of processing for Read_Target_Dependent_Values begin File_Desc := Open_Read (File_Name, Text); if File_Desc = Invalid_FD then Fail ("cannot read file " & File_Name); end if; Buflen := Read (File_Desc, Buffer'Address, Buffer'Length); Close (File_Desc); if Buflen = Buffer'Length then Fail ("file is too long: " & File_Name); end if; -- Scan through file for properly formatted entries in first section N := 1; while N <= Buflen and then Buffer (N) /= ASCII.LF loop Get_Name; -- Validate name and get corresponding value pointer VP := null; for J in DTN'Range loop if DTN (J).all = Nam_Buf (1 .. Nam_Len) then VP := To_ANat (DTV (J)); DTR (J) := True; exit; end if; end loop; if VP = null then FailN ("unrecognized name"); end if; -- Scan out value VP.all := Get_Nat; if N > Buflen or else Buffer (N) /= ASCII.LF then FailN ("misformatted line for"); end if; N := N + 1; -- skip LF end loop; -- Fall through this loop when all lines in first section read. -- Check that values have been supplied for all entries. for J in DTR'Range loop if not DTR (J) then Fail ("missing entry for " & DTN (J).all & " in file " & File_Name); end if; end loop; -- Now acquire FPT entries if N >= Buflen then Fail ("missing entries for FPT modes in file " & File_Name); end if; if Buffer (N) = ASCII.LF then N := N + 1; else Fail ("missing blank line in file " & File_Name); end if; Num_FPT_Modes := 0; while N <= Buflen loop Get_Name; Num_FPT_Modes := Num_FPT_Modes + 1; declare E : FPT_Mode_Entry renames FPT_Mode_Table (Num_FPT_Modes); begin E.NAME := new String'(Nam_Buf (1 .. Nam_Len)); if Long_Double_Index < 0 and then E.NAME.all = "long double" then Long_Double_Index := Num_FPT_Modes; end if; E.DIGS := Get_Nat; Check_Spaces; case Buffer (N) is when 'I' => E.FLOAT_REP := IEEE_Binary; when 'A' => E.FLOAT_REP := AAMP; when others => FailN ("bad float rep field for"); end case; N := N + 1; Check_Spaces; E.PRECISION := Get_Nat; Check_Spaces; E.ALIGNMENT := Get_Nat; if Buffer (N) /= ASCII.LF then FailN ("junk at end of line for"); end if; -- ??? We do not read E.SIZE, see Write_Target_Dependent_Values E.SIZE := (E.PRECISION + E.ALIGNMENT - 1) / E.ALIGNMENT * E.ALIGNMENT; N := N + 1; end; end loop; end Read_Target_Dependent_Values; -- Package Initialization, set target dependent values. This must be done -- early on, before we start accessing various compiler packages, since -- these values are used all over the place. begin -- First step: see if the -gnateT switch is present. As we have noted, -- this has to be done very early, so cannot depend on the normal circuit -- for reading switches and setting switches in Opt. The following code -- will set Opt.Target_Dependent_Info_Read_Name if the switch -gnateT=name -- is present in the options string. declare type Arg_Array is array (Nat) of Big_String_Ptr; type Arg_Array_Ptr is access Arg_Array; -- Types to access compiler arguments save_argc : Nat; pragma Import (C, save_argc); -- Saved value of argc (number of arguments), imported from misc.c save_argv : Arg_Array_Ptr; pragma Import (C, save_argv); -- Saved value of argv (argument pointers), imported from misc.c gnat_argc : Nat; gnat_argv : Arg_Array_Ptr; pragma Import (C, gnat_argc); pragma Import (C, gnat_argv); -- If save_argv is not set, default to gnat_argc/argv argc : Nat; argv : Arg_Array_Ptr; function Len_Arg (Arg : Big_String_Ptr) return Nat; -- Determine length of argument Arg (a nul terminated C string). ------------- -- Len_Arg -- ------------- function Len_Arg (Arg : Big_String_Ptr) return Nat is begin for J in 1 .. Nat'Last loop if Arg (Natural (J)) = ASCII.NUL then return J - 1; end if; end loop; raise Program_Error; end Len_Arg; begin if save_argv /= null then argv := save_argv; argc := save_argc; else -- Case of a non gcc compiler, e.g. gnat2why or gnat2scil argv := gnat_argv; argc := gnat_argc; end if; -- Loop through arguments looking for -gnateT, also look for -gnatd.b for Arg in 1 .. argc - 1 loop declare Argv_Ptr : constant Big_String_Ptr := argv (Arg); Argv_Len : constant Nat := Len_Arg (Argv_Ptr); begin if Argv_Len > 8 and then Argv_Ptr (1 .. 8) = "-gnateT=" then Opt.Target_Dependent_Info_Read_Name := new String'(Argv_Ptr (9 .. Natural (Argv_Len))); elsif Argv_Len >= 8 and then Argv_Ptr (1 .. 8) = "-gnatd.b" then Debug_Flag_Dot_B := True; end if; end; end loop; end; -- Case of reading the target dependent values from file -- This is bit more complex than might be expected, because it has to be -- done very early. All kinds of packages depend on these values, and we -- can't wait till the normal processing of reading command line switches -- etc to read the file. We do this at the System.OS_Lib level since it is -- too early to be using Osint directly. if Opt.Target_Dependent_Info_Read_Name /= null then Read_Target_Dependent_Values (Target_Dependent_Info_Read_Name.all); else -- If the back-end comes with a target config file, then use it -- to set the values declare Back_End_Config_File : constant String_Ptr := Get_Back_End_Config_File; begin if Back_End_Config_File /= null then pragma Gnat_Annotate (CodePeer, Intentional, "test always false", "some variant body will return non null"); Read_Target_Dependent_Values (Back_End_Config_File.all); -- Otherwise we get all values from the back end directly else Bits_BE := Get_Bits_BE; Bits_Per_Unit := Get_Bits_Per_Unit; Bits_Per_Word := Get_Bits_Per_Word; Bytes_BE := Get_Bytes_BE; Char_Size := Get_Char_Size; Double_Float_Alignment := Get_Double_Float_Alignment; Double_Scalar_Alignment := Get_Double_Scalar_Alignment; Float_Words_BE := Get_Float_Words_BE; Int_Size := Get_Int_Size; Long_Long_Size := Get_Long_Long_Size; Long_Size := Get_Long_Size; Maximum_Alignment := Get_Maximum_Alignment; Max_Unaligned_Field := Get_Max_Unaligned_Field; Pointer_Size := Get_Pointer_Size; Short_Enums := Get_Short_Enums; Short_Size := Get_Short_Size; Strict_Alignment := Get_Strict_Alignment; System_Allocator_Alignment := Get_System_Allocator_Alignment; Wchar_T_Size := Get_Wchar_T_Size; Words_BE := Get_Words_BE; -- Let the back-end register its floating point types and compute -- the sizes of our standard types from there: Num_FPT_Modes := 0; Register_Back_End_Types (Register_Float_Type'Access); declare T : FPT_Mode_Entry renames FPT_Mode_Table (FPT_Mode_Index_For (S_Float)); begin Float_Size := Pos (T.SIZE); end; declare T : FPT_Mode_Entry renames FPT_Mode_Table (FPT_Mode_Index_For (S_Long_Float)); begin Double_Size := Pos (T.SIZE); end; declare T : FPT_Mode_Entry renames FPT_Mode_Table (FPT_Mode_Index_For (S_Long_Long_Float)); begin Long_Double_Size := Pos (T.SIZE); end; end if; end; end if; end Set_Targ;