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|
------------------------------------------------------------------------------
-- --
-- GNAT COMPILER COMPONENTS --
-- --
-- G N A T . A L T I V E C . C O N V E R S I O N S --
-- --
-- B o d y --
-- --
-- Copyright (C) 2005-2008, 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 2, 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 COPYING. If not, write --
-- to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, --
-- MA 02111-1307, USA. --
-- --
-- As a special exception, if other files instantiate generics from this --
-- unit, or you link this unit with other files to produce an executable, --
-- this unit does not by itself cause the resulting executable to be --
-- covered by the GNU General Public License. This exception does not --
-- however invalidate any other reasons why the executable file might be --
-- covered by the GNU Public License. --
-- --
-- GNAT was originally developed by the GNAT team at New York University. --
-- Extensive contributions were provided by Ada Core Technologies Inc. --
-- --
------------------------------------------------------------------------------
with Ada.Unchecked_Conversion;
with System; use System;
package body GNAT.Altivec.Conversions is
-- All the vector/view conversions operate similarly: bare unchecked
-- conversion on big endian targets, and elements permutation on little
-- endian targets. We call "Mirroring" the elements permutation process.
-- We would like to provide a generic version of the conversion routines
-- and just have a set of "renaming as body" declarations to satisfy the
-- public interface. This unfortunately prevents inlining, which we must
-- preserve at least for the hard binding.
-- We instead provide a generic version of facilities needed by all the
-- conversion routines and use them repeatedly.
generic
type Vitem_Type is private;
type Varray_Index_Type is range <>;
type Varray_Type is array (Varray_Index_Type) of Vitem_Type;
type Vector_Type is private;
type View_Type is private;
package Generic_Conversions is
subtype Varray is Varray_Type;
-- This provides an easy common way to refer to the type parameter
-- in contexts where a specific instance of this package is "use"d.
procedure Mirror (A : Varray_Type; Into : out Varray_Type);
pragma Inline (Mirror);
-- Mirror the elements of A into INTO, not touching the per-element
-- internal ordering.
-- A procedure with an out parameter is a bit heavier to use than a
-- function but reduces the amount of temporary creations around the
-- call. Instances are typically not front-end inlined. They can still
-- be back-end inlined on request with the proper command-line option.
-- Below are Unchecked Conversion routines for various purposes,
-- relying on internal knowledge about the bits layout in the different
-- types (all 128 value bits blocks).
-- View<->Vector straight bitwise conversions on BE targets
function UNC_To_Vector is
new Ada.Unchecked_Conversion (View_Type, Vector_Type);
function UNC_To_View is
new Ada.Unchecked_Conversion (Vector_Type, View_Type);
-- Varray->Vector/View for returning mirrored results on LE targets
function UNC_To_Vector is
new Ada.Unchecked_Conversion (Varray_Type, Vector_Type);
function UNC_To_View is
new Ada.Unchecked_Conversion (Varray_Type, View_Type);
-- Vector/View->Varray for to-be-permuted source on LE targets
function UNC_To_Varray is
new Ada.Unchecked_Conversion (Vector_Type, Varray_Type);
function UNC_To_Varray is
new Ada.Unchecked_Conversion (View_Type, Varray_Type);
end Generic_Conversions;
package body Generic_Conversions is
procedure Mirror (A : Varray_Type; Into : out Varray_Type) is
begin
for J in A'Range loop
Into (J) := A (A'Last - J + A'First);
end loop;
end Mirror;
end Generic_Conversions;
-- Now we declare the instances and implement the interface function
-- bodies simply calling the instantiated routines.
---------------------
-- Char components --
---------------------
package SC_Conversions is new Generic_Conversions
(signed_char, Vchar_Range, Varray_signed_char, VSC, VSC_View);
function To_Vector (S : VSC_View) return VSC is
use SC_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VSC) return VSC_View is
use SC_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
--
package UC_Conversions is new Generic_Conversions
(unsigned_char, Vchar_Range, Varray_unsigned_char, VUC, VUC_View);
function To_Vector (S : VUC_View) return VUC is
use UC_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VUC) return VUC_View is
use UC_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
--
package BC_Conversions is new Generic_Conversions
(bool_char, Vchar_Range, Varray_bool_char, VBC, VBC_View);
function To_Vector (S : VBC_View) return VBC is
use BC_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VBC) return VBC_View is
use BC_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
----------------------
-- Short components --
----------------------
package SS_Conversions is new Generic_Conversions
(signed_short, Vshort_Range, Varray_signed_short, VSS, VSS_View);
function To_Vector (S : VSS_View) return VSS is
use SS_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VSS) return VSS_View is
use SS_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
--
package US_Conversions is new Generic_Conversions
(unsigned_short, Vshort_Range, Varray_unsigned_short, VUS, VUS_View);
function To_Vector (S : VUS_View) return VUS is
use US_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VUS) return VUS_View is
use US_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
--
package BS_Conversions is new Generic_Conversions
(bool_short, Vshort_Range, Varray_bool_short, VBS, VBS_View);
function To_Vector (S : VBS_View) return VBS is
use BS_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VBS) return VBS_View is
use BS_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
--------------------
-- Int components --
--------------------
package SI_Conversions is new Generic_Conversions
(signed_int, Vint_Range, Varray_signed_int, VSI, VSI_View);
function To_Vector (S : VSI_View) return VSI is
use SI_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VSI) return VSI_View is
use SI_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
--
package UI_Conversions is new Generic_Conversions
(unsigned_int, Vint_Range, Varray_unsigned_int, VUI, VUI_View);
function To_Vector (S : VUI_View) return VUI is
use UI_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VUI) return VUI_View is
use UI_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
--
package BI_Conversions is new Generic_Conversions
(bool_int, Vint_Range, Varray_bool_int, VBI, VBI_View);
function To_Vector (S : VBI_View) return VBI is
use BI_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VBI) return VBI_View is
use BI_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
----------------------
-- Float components --
----------------------
package F_Conversions is new Generic_Conversions
(C_float, Vfloat_Range, Varray_float, VF, VF_View);
function To_Vector (S : VF_View) return VF is
use F_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VF) return VF_View is
use F_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
----------------------
-- Pixel components --
----------------------
package P_Conversions is new Generic_Conversions
(pixel, Vpixel_Range, Varray_pixel, VP, VP_View);
function To_Vector (S : VP_View) return VP is
use P_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_Vector (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_Vector (M);
end;
end if;
end To_Vector;
function To_View (S : VP) return VP_View is
use P_Conversions;
begin
if Default_Bit_Order = High_Order_First then
return UNC_To_View (S);
else
declare
M : Varray;
begin
Mirror (UNC_To_Varray (S), Into => M);
return UNC_To_View (M);
end;
end if;
end To_View;
end GNAT.Altivec.Conversions;
|