From: Eric Botcazou Date: Wed, 27 May 2020 20:42:27 +0000 (+0200) Subject: [Ada] Small cleanup throughout Exp_Ch4 X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=cbe3b8d49d07cf5eee62c3963b843f3ea931b03f;p=gcc.git [Ada] Small cleanup throughout Exp_Ch4 gcc/ada/ * exp_ch4.adb (Expand_Array_Comparison): Reformat. (Expand_Concatenate): Use standard size values directly and use Standard_Long_Long_Unsigned instead of RE_Long_Long_Unsigned. (Expand_Modular_Op): Use Standard_Long_Long_Integer in case the modulus is larger than Integer. (Expand_N_Op_Expon): Use standard size value directly. (Narrow_Large_Operation): Use Uint instead of Nat for sizes and use a local variable for the size of the type. (Get_Size_For_Range): Return Uint instead of Nat. (Is_OK_For_Range): Take Uint instead of Nat. --- diff --git a/gcc/ada/exp_ch4.adb b/gcc/ada/exp_ch4.adb index cd710754617..e3af266f551 100644 --- a/gcc/ada/exp_ch4.adb +++ b/gcc/ada/exp_ch4.adb @@ -1378,9 +1378,7 @@ package body Exp_Ch4 is -- except that we avoid this for targets for which are not addressable -- by bytes. - if not Is_Bit_Packed_Array (Typ1) - and then Byte_Addressable - then + if not Is_Bit_Packed_Array (Typ1) and then Byte_Addressable then -- The call we generate is: -- Compare_Array_xn[_Unaligned] @@ -3008,23 +3006,23 @@ package body Exp_Ch4 is -- For modular types, we use a 32-bit modular type for types whose size -- is in the range 1-31 bits. For 32-bit unsigned types, we use the - -- identity type, and for larger unsigned types we use 64-bits. + -- identity type, and for larger unsigned types we use a 64-bit type. elsif Is_Modular_Integer_Type (Ityp) then - if RM_Size (Ityp) < RM_Size (Standard_Unsigned) then + if RM_Size (Ityp) < Standard_Integer_Size then Artyp := Standard_Unsigned; - elsif RM_Size (Ityp) = RM_Size (Standard_Unsigned) then + elsif RM_Size (Ityp) = Standard_Integer_Size then Artyp := Ityp; else - Artyp := RTE (RE_Long_Long_Unsigned); + Artyp := Standard_Long_Long_Unsigned; end if; -- Similar treatment for signed types else - if RM_Size (Ityp) < RM_Size (Standard_Integer) then + if RM_Size (Ityp) < Standard_Integer_Size then Artyp := Standard_Integer; - elsif RM_Size (Ityp) = RM_Size (Standard_Integer) then + elsif RM_Size (Ityp) = Standard_Integer_Size then Artyp := Ityp; else Artyp := Standard_Long_Long_Integer; @@ -4167,7 +4165,7 @@ package body Exp_Ch4 is -- errors on large legal literals of the type. if Modulus (Etype (N)) > UI_From_Int (Int (Integer'Last)) then - Target_Type := Standard_Long_Integer; + Target_Type := Standard_Long_Long_Integer; else Target_Type := Standard_Integer; end if; @@ -8747,7 +8745,7 @@ package body Exp_Ch4 is -- We only handle cases where the right type is a integer and then Is_Integer_Type (Root_Type (Exptyp)) - and then Esize (Root_Type (Exptyp)) <= Esize (Standard_Integer) + and then Esize (Root_Type (Exptyp)) <= Standard_Integer_Size -- This transformation is not applicable for a modular type with a -- nonbinary modulus because we do not handle modular reduction in @@ -11394,7 +11392,7 @@ package body Exp_Ch4 is -- integer type large enough to hold the result. if Is_Fixed_Point_Type (Etype (Expr)) then - if Esize (Base_Type (Etype (Expr))) > Esize (Standard_Integer) then + if Esize (Base_Type (Etype (Expr))) > Standard_Integer_Size then Ityp := Standard_Long_Long_Integer; else Ityp := Standard_Integer; @@ -13910,8 +13908,9 @@ package body Exp_Ch4 is Compar : constant Boolean := Kind in N_Op_Compare or else In_Rng; R : constant Node_Id := Right_Opnd (N); Typ : constant Entity_Id := Etype (R); + Tsiz : constant Uint := RM_Size (Typ); - function Get_Size_For_Range (Lo, Hi : Uint) return Nat; + function Get_Size_For_Range (Lo, Hi : Uint) return Uint; -- Return the size of a small signed integer type covering Lo .. Hi. -- The important thing is to return a size lower than that of Typ. @@ -13919,16 +13918,16 @@ package body Exp_Ch4 is -- Get_Size_For_Range -- ------------------------ - function Get_Size_For_Range (Lo, Hi : Uint) return Nat is + function Get_Size_For_Range (Lo, Hi : Uint) return Uint is - function Is_OK_For_Range (Siz : Nat) return Boolean; + function Is_OK_For_Range (Siz : Uint) return Boolean; -- Return True if a signed integer with given size can cover Lo .. Hi -------------------------- -- Is_OK_For_Range -- -------------------------- - function Is_OK_For_Range (Siz : Nat) return Boolean is + function Is_OK_For_Range (Siz : Uint) return Boolean is B : constant Uint := Uint_2 ** (Siz - 1); begin @@ -13940,21 +13939,21 @@ package body Exp_Ch4 is begin -- This is (almost always) the size of Integer - if Is_OK_For_Range (32) then - return 32; + if Is_OK_For_Range (Uint_32) then + return Uint_32; -- If the size of Typ is 64 then check 63 - elsif RM_Size (Typ) = 64 and then Is_OK_For_Range (63) then - return 63; + elsif Tsiz = Uint_64 and then Is_OK_For_Range (Uint_63) then + return Uint_63; -- This is (almost always) the size of Long_Long_Integer - elsif Is_OK_For_Range (64) then - return 64; + elsif Is_OK_For_Range (Uint_64) then + return Uint_64; else - return 128; + return Uint_128; end if; end Get_Size_For_Range; @@ -13963,9 +13962,9 @@ package body Exp_Ch4 is L : Node_Id; Llo, Lhi : Uint; Rlo, Rhi : Uint; - Lsiz, Rsiz : Nat; + Lsiz, Rsiz : Uint; Nlo, Nhi : Uint; - Nsiz : Nat; + Nsiz : Uint; Ntyp : Entity_Id; Nop : Node_Id; OK : Boolean; @@ -14022,7 +14021,7 @@ package body Exp_Ch4 is if Binary then Lsiz := Get_Size_For_Range (Llo, Lhi); else - Lsiz := 0; + Lsiz := Uint_0; end if; Rsiz := Get_Size_For_Range (Rlo, Rhi); @@ -14032,7 +14031,7 @@ package body Exp_Ch4 is if Compar then -- The type must be able to accommodate the operands - Nsiz := Nat'Max (Lsiz, Rsiz); + Nsiz := UI_Max (Lsiz, Rsiz); else -- The type must be able to accommodate the operand(s) and result. @@ -14050,15 +14049,15 @@ package body Exp_Ch4 is -- here, we cannot be sure that the operation does not overflow. Nsiz := Get_Size_For_Range (Nlo, Nhi); - Nsiz := Nat'Max (Nsiz, Lsiz); - Nsiz := Nat'Max (Nsiz, Rsiz); + Nsiz := UI_Max (Nsiz, Lsiz); + Nsiz := UI_Max (Nsiz, Rsiz); end if; -- If the size is not lower than the size of the original type, then -- there is no point in changing the type, except in the case where -- we can remove a conversion to the original type from an operand. - if Nsiz >= RM_Size (Typ) + if Nsiz >= Tsiz and then not (Binary and then Nkind (L) = N_Type_Conversion and then Entity (Subtype_Mark (L)) = Typ) @@ -14072,10 +14071,10 @@ package body Exp_Ch4 is -- type instead of the first subtype because operations are done in -- the base type, so this avoids the need for useless conversions. - if Nsiz <= RM_Size (Standard_Integer) then + if Nsiz <= Standard_Integer_Size then Ntyp := Etype (Standard_Integer); - elsif Nsiz <= RM_Size (Standard_Long_Long_Integer) then + elsif Nsiz <= Standard_Long_Long_Integer_Size then Ntyp := Etype (Standard_Long_Long_Integer); else @@ -14112,7 +14111,7 @@ package body Exp_Ch4 is -- Analyze it with the narrower type and checks suppressed, but only -- when we are sure that the operation does not overflow, see above. - if Nsiz < RM_Size (Typ) then + if Nsiz < Tsiz then Analyze_And_Resolve (N, Ntyp, Suppress => Overflow_Check); else Analyze_And_Resolve (N, Ntyp);