llvm-gcc-4.2/gcc/ada/g-altive.ads - llvm-archive - Git at Google

 ------------------------------------------------------------------------------
 --                                                                          --
 --                         GNAT COMPILER COMPONENTS                         --
 --                                                                          --
 --                         G N A T . A L T I V E C                          --
 --                                                                          --
 --                                 S p e c                                  --
 --                                                                          --
 --          Copyright (C) 2004-2006, 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.      --
 --                                                                          --
 ------------------------------------------------------------------------------

 -------------------------
 -- General description --
 -------------------------

 --  This is the root of a package hierarchy offering an Ada binding to the
 --  PowerPC AltiVec extensions. These extensions basically consist in a set of
 --  128bit vector types together with a set of subprograms operating on such
 --  vectors. On a real Altivec capable target, vector objects map to hardware
 --  vector registers and the subprograms map to a set of specific hardware
 --  instructions.

 --  Relevant documents are:

 --  o AltiVec Technology, Programming Interface Manual (1999-06)
 --    to which we will refer as [PIM], describes the data types, the
 --    functional interface and the ABI conventions.

 --  o AltiVec Technology, Programming Environments Manual (2002-02)
 --    to which we will refer as [PEM], describes the hardware architecture
 --    and instruction set.

 --  These documents, as well as a number of others of general interest on the
 --  AltiVec technology, are available from the Motorola/AltiVec Web site at

 --  http://www.motorola.com/altivec

 --  We offer two versions of this binding: one for real AltiVec capable
 --  targets, and one for other targets. In the latter case, everything is
 --  emulated in software. We will refer to the two bindings as:

 --  o The Hard binding for AltiVec capable targets (with the appropriate
 --    hardware support and corresponding instruction set)

 --  o The Soft binding for other targets (with the low level primitives
 --    emulated in software).

 --  The two versions of the binding are expected to be equivalent from the
 --  functional standpoint. The same client application code should observe no
 --  difference in operation results, even if the Soft version is used on a
 --  non-powerpc target. The Hard binding is naturally expected to run faster
 --  than the Soft version on the same target.

 --  We also offer interfaces not strictly part of the base AltiVec API, such
 --  as vector conversions to/from array representations, which are of interest
 --  for client applications (e.g. for vector initialization purposes) and may
 --  also be used as implementation facilities.

 -----------------------------------------
 -- General package architecture survey --
 -----------------------------------------

 --  The various vector representations are all "containers" of elementary
 --  values, the possible types of which are declared in this root package to
 --  be generally accessible.

 --  From the user standpoint, the two versions of the binding are available
 --  through a consistent hierarchy of units providing identical services:

 --                             GNAT.Altivec
 --                           (component types)
 --                                   |
 --          o----------------o----------------o-------------o
 --          |                |                |             |
 --    Vector_Types   Vector_Operations   Vector_Views   Conversions

 --  The user can manipulate vectors through two families of types: Vector
 --  types and View types.

 --  Vector types are defined in the GNAT.Altivec.Vector_Types package

 --  On these types, the user can apply the Altivec operations defined in
 --  GNAT.Altivec.Vector_Operations. Their layout is opaque and may vary across
 --  configurations, for it is typically target-endianness dependant.

 --  Vector_Types and Vector_Operations implement the core binding to the
 --  AltiVec API, as described in [PIM-2.1 data types] and [PIM-4 AltiVec
 --  operations and predicates].

 --  View types are defined in the GNAT.Altivec.Vector_Views package

 --  These types do not represent Altivec vectors per se, in the sense that the
 --  Altivec_Operations are not available for them. They are intended to allow
 --  Vector initializations as well as access to the Vector component values.

 --  The GNAT.Altivec.Conversions package is provided to convert a View to the
 --  corresponding Vector and vice-versa.

 --  The two versions of the binding rely on a low level internal interface,
 --  and switching from one version to the other amounts to select one low
 --  level implementation instead of the other.

 --  The bindings are provided as a set of sources together with a project file
 --  (altivec.gpr). The hard/soft binding selection is controlled by a project
 --  variable on targets where switching makes sense. See the example usage
 --  section below.

 ---------------------------
 -- Underlying principles --
 ---------------------------

 --  The general organization sketched above has been devised from a number
 --  of driving ideas:

 --  o From the clients standpoint, the two versions of the binding should be
 --    as easily exchangable as possible,

 --  o From the maintenance standpoint, we want to avoid as much code
 --    duplication as possible.

 --  o From both standpoints above, we want to maintain a clear interface
 --    separation between the base bindings to the Motorola API and the
 --    additional facilities.

 --  The identification of the low level interface is directly inspired by the
 --  the base API organization, basically consisting of a rich set of functions
 --  around a core of low level primitives mapping to AltiVec instructions.

 --  See for instance "vec_add" in [PIM-4.4 Generic and Specific AltiVec
 --  operations]: no less than six result/arguments combinations of byte vector
 --  types map to "vaddubm".

 --  The "hard" version of the low level primitives map to real AltiVec
 --  instructions via the corresponding GCC builtins. The "soft" version is
 --  a software emulation of those.

 -------------------
 -- Example usage --
 -------------------

 --  Here is a sample program declaring and initializing two vectors, 'add'ing
 --  them and displaying the result components:

 --  with GNAT.Altivec.Vector_Types;      use GNAT.Altivec.Vector_Types;
 --  with GNAT.Altivec.Vector_Operations; use GNAT.Altivec.Vector_Operations;
 --  with GNAT.Altivec.Vector_Views;      use GNAT.Altivec.Vector_Views;
 --  with GNAT.Altivec.Conversions;       use GNAT.Altivec.Conversions;

 --  use GNAT.Altivec;

 --  procedure Sample is
 --     Va : Vector_Unsigned_Int := To_Vector ((Values => (1, 2, 3, 4)));
 --     Vb : Vector_Unsigned_Int := To_Vector ((Values => (1, 2, 3, 4)));

 --     Vs : Vector_Unsigned_Int;
 --     Vs_View : VUI_View;
 --  begin
 --     Vs := Vec_Add (Va, Vb);
 --     Vs_View := To_View (Vs);

 --     for I in Vs_View.Values'Range loop
 --        Put_Line (Unsigned_Int'Image (Vs_View.Values (I)));
 --     end loop;
 --  end;

 --  This currently requires the GNAT project management facilities to compile,
 --  to automatically retrieve the set of necessary sources and switches
 --  depending on your configuration. For the example above, customizing the
 --  switches to include -g also, this would be something like:

 --  sample.gpr
 --
 --  with "altivec.gpr";
 --
 --  project Sample is

 --    for Source_Dirs use (".");
 --    for Main use ("sample");

 --    package Compiler is
 --       for Default_Switches ("Ada") use
 --           Altivec.Compiler'Default_Switches ("Ada") & "-g";
 --    end Compiler;

 --  end Sample;

 --  $ gnatmake -Psample
 --  [...]
 --  $ ./sample
 --  2
 --  4
 --  6
 --  8

 ------------------------------------------------------------------------------

 with System;

 package GNAT.Altivec is

    --  Definitions of constants and vector/array component types common to all
    --  the versions of the binding.

    --  All the vector types are 128bits

    VECTOR_BIT : constant := 128;

    -------------------------------------------
    -- [PIM-2.3.1 Alignment of vector types] --
    -------------------------------------------

    --  "A defined data item of any vector data type in memory is always
    --  aligned on a 16-byte boundary. A pointer to any vector data type always
    --  points to a 16-byte boundary. The compiler is responsible for aligning
    --  vector data types on 16-byte boundaries."

    VECTOR_ALIGNMENT : constant := Natural'Min (16, Standard'Maximum_Alignment);
    --  This value is used to set the alignment of vector datatypes in both the
    --  hard and the soft binding implementations.
    --
    --  We want this value to never be greater than 16, because none of the
    --  binding implementations requires larger alignments and such a value
    --  would cause useless space to be allocated/wasted for vector objects.
    --  Furthermore, the alignment of 16 matches the hard binding leading to
    --  a more faithful emulation.
    --
    --  It needs to be exactly 16 for the hard binding, and the initializing
    --  expression is just right for this purpose since Maximum_Alignment is
    --  expected to be 16 for the real Altivec ABI.
    --
    --  The soft binding doesn't rely on strict 16byte alignment, and we want
    --  the value to be no greater than Standard'Maximum_Alignment in this case
    --  to ensure it is supported on every possible target.

    -------------------------------------------------------
    -- [PIM-2.1] Data Types - Interpretation of contents --
    -------------------------------------------------------

    ---------------------
    -- char components --
    ---------------------

    CHAR_BIT    : constant := 8;
    SCHAR_MIN   : constant := -2 ** (CHAR_BIT - 1);
    SCHAR_MAX   : constant := 2 ** (CHAR_BIT - 1) - 1;
    UCHAR_MAX   : constant := 2 ** CHAR_BIT - 1;

    type unsigned_char is mod UCHAR_MAX + 1;
    for unsigned_char'Size use CHAR_BIT;

    type signed_char is range SCHAR_MIN .. SCHAR_MAX;
    for signed_char'Size use CHAR_BIT;

    subtype bool_char is unsigned_char;
    --  ??? There is a difference here between what the Altivec Technology
    --  Programming Interface Manual says and what GCC says. In the manual,
    --  vector_bool_char is a vector_unsigned_char, while in altivec.h it
    --  is a vector_signed_char.

    bool_char_True  : constant bool_char := bool_char'Last;
    bool_char_False : constant bool_char := 0;

    ----------------------
    -- short components --
    ----------------------

    SHORT_BIT   : constant := 16;
    SSHORT_MIN  : constant := -2 ** (SHORT_BIT - 1);
    SSHORT_MAX  : constant := 2 ** (SHORT_BIT - 1) - 1;
    USHORT_MAX  : constant := 2 ** SHORT_BIT - 1;

    type unsigned_short is mod USHORT_MAX + 1;
    for unsigned_short'Size use SHORT_BIT;

    subtype unsigned_short_int is unsigned_short;

    type signed_short is range SSHORT_MIN .. SSHORT_MAX;
    for signed_short'Size use SHORT_BIT;

    subtype signed_short_int is signed_short;

    subtype bool_short is unsigned_short;
    --  ??? See bool_char

    bool_short_True  : constant bool_short := bool_short'Last;
    bool_short_False : constant bool_short := 0;

    subtype bool_short_int is bool_short;

    --------------------
    -- int components --
    --------------------

    INT_BIT     : constant := 32;
    SINT_MIN    : constant := -2 ** (INT_BIT - 1);
    SINT_MAX    : constant := 2 ** (INT_BIT - 1) - 1;
    UINT_MAX    : constant := 2 ** INT_BIT - 1;

    type unsigned_int is mod UINT_MAX + 1;
    for unsigned_int'Size use INT_BIT;

    type signed_int is range SINT_MIN .. SINT_MAX;
    for signed_int'Size use INT_BIT;

    subtype bool_int is unsigned_int;
    --  ??? See bool_char

    bool_int_True  : constant bool_int := bool_int'Last;
    bool_int_False : constant bool_int := 0;

    ----------------------
    -- float components --
    ----------------------

    FLOAT_BIT   : constant := 32;
    FLOAT_DIGIT : constant := 6;
    FLOAT_MIN   : constant := -16#0.FFFF_FF#E+32;
    FLOAT_MAX   : constant := 16#0.FFFF_FF#E+32;

    type C_float is digits FLOAT_DIGIT range FLOAT_MIN .. FLOAT_MAX;
    for C_float'Size use FLOAT_BIT;

    ----------------------
    -- pixel components --
    ----------------------

    subtype pixel is unsigned_short;

    -----------------------------------------------------------
    -- Subtypes for variants found in the GCC implementation --
    -----------------------------------------------------------

    subtype c_int is signed_int;
    subtype c_short is c_int;

    LONG_BIT  : constant := 32;
    --  Some of the GCC builtins are built with "long" arguments and
    --  expect SImode to come in.

    SLONG_MIN : constant := -2 ** (LONG_BIT - 1);
    SLONG_MAX : constant :=  2 ** (LONG_BIT - 1) - 1;
    ULONG_MAX : constant :=  2 ** LONG_BIT - 1;

    type signed_long   is range SLONG_MIN .. SLONG_MAX;
    type unsigned_long is mod ULONG_MAX + 1;

    subtype c_long is signed_long;

    subtype c_ptr is System.Address;

    ---------------------------------------------------------
    -- Access types, for the sake of some argument passing --
    ---------------------------------------------------------

    type signed_char_ptr    is access all signed_char;
    type unsigned_char_ptr  is access all unsigned_char;

    type short_ptr          is access all c_short;
    type signed_short_ptr   is access all signed_short;
    type unsigned_short_ptr is access all unsigned_short;

    type int_ptr            is access all c_int;
    type signed_int_ptr     is access all signed_int;
    type unsigned_int_ptr   is access all unsigned_int;

    type long_ptr           is access all c_long;
    type signed_long_ptr    is access all signed_long;
    type unsigned_long_ptr  is access all unsigned_long;

    type float_ptr          is access all Float;

    --

    type const_signed_char_ptr    is access constant signed_char;
    type const_unsigned_char_ptr  is access constant unsigned_char;

    type const_short_ptr          is access constant c_short;
    type const_signed_short_ptr   is access constant signed_short;
    type const_unsigned_short_ptr is access constant unsigned_short;

    type const_int_ptr            is access constant c_int;
    type const_signed_int_ptr     is access constant signed_int;
    type const_unsigned_int_ptr   is access constant unsigned_int;

    type const_long_ptr           is access constant c_long;
    type const_signed_long_ptr    is access constant signed_long;
    type const_unsigned_long_ptr  is access constant unsigned_long;

    type const_float_ptr          is access constant Float;

    --  Access to const volatile arguments need specialized types

    type volatile_float is new Float;
    pragma Volatile (volatile_float);

    type volatile_signed_char is new signed_char;
    pragma Volatile (volatile_signed_char);

    type volatile_unsigned_char is new unsigned_char;
    pragma Volatile (volatile_unsigned_char);

    type volatile_signed_short is new signed_short;
    pragma Volatile (volatile_signed_short);

    type volatile_unsigned_short is new unsigned_short;
    pragma Volatile (volatile_unsigned_short);

    type volatile_signed_int is new signed_int;
    pragma Volatile (volatile_signed_int);

    type volatile_unsigned_int is new unsigned_int;
    pragma Volatile (volatile_unsigned_int);

    type volatile_signed_long is new signed_long;
    pragma Volatile (volatile_signed_long);

    type volatile_unsigned_long is new unsigned_long;
    pragma Volatile (volatile_unsigned_long);

    type constv_char_ptr           is access constant volatile_signed_char;
    type constv_signed_char_ptr    is access constant volatile_signed_char;
    type constv_unsigned_char_ptr  is access constant volatile_unsigned_char;

    type constv_short_ptr          is access constant volatile_signed_short;
    type constv_signed_short_ptr   is access constant volatile_signed_short;
    type constv_unsigned_short_ptr is access constant volatile_unsigned_short;

    type constv_int_ptr            is access constant volatile_signed_int;
    type constv_signed_int_ptr     is access constant volatile_signed_int;
    type constv_unsigned_int_ptr   is access constant volatile_unsigned_int;

    type constv_long_ptr           is access constant volatile_signed_long;
    type constv_signed_long_ptr    is access constant volatile_signed_long;
    type constv_unsigned_long_ptr  is access constant volatile_unsigned_long;

    type constv_float_ptr  is access constant volatile_float;

 private

    -----------------------
    -- Various constants --
    -----------------------

    CR6_EQ     : constant := 0;
    CR6_EQ_REV : constant := 1;
    CR6_LT     : constant := 2;
    CR6_LT_REV : constant := 3;

 end GNAT.Altivec;
	------------------------------------------------------------------------------
	-- --
	-- GNAT COMPILER COMPONENTS --
	-- --
	-- G N A T . A L T I V E C --
	-- --
	-- S p e c --
	-- --
	-- Copyright (C) 2004-2006, 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. --
	-- --
	------------------------------------------------------------------------------

	-------------------------
	-- General description --
	-------------------------

	-- This is the root of a package hierarchy offering an Ada binding to the
	-- PowerPC AltiVec extensions. These extensions basically consist in a set of
	-- 128bit vector types together with a set of subprograms operating on such
	-- vectors. On a real Altivec capable target, vector objects map to hardware
	-- vector registers and the subprograms map to a set of specific hardware
	-- instructions.

	-- Relevant documents are:

	-- o AltiVec Technology, Programming Interface Manual (1999-06)
	-- to which we will refer as [PIM], describes the data types, the
	-- functional interface and the ABI conventions.

	-- o AltiVec Technology, Programming Environments Manual (2002-02)
	-- to which we will refer as [PEM], describes the hardware architecture
	-- and instruction set.

	-- These documents, as well as a number of others of general interest on the
	-- AltiVec technology, are available from the Motorola/AltiVec Web site at

	-- http://www.motorola.com/altivec

	-- We offer two versions of this binding: one for real AltiVec capable
	-- targets, and one for other targets. In the latter case, everything is
	-- emulated in software. We will refer to the two bindings as:

	-- o The Hard binding for AltiVec capable targets (with the appropriate
	-- hardware support and corresponding instruction set)

	-- o The Soft binding for other targets (with the low level primitives
	-- emulated in software).

	-- The two versions of the binding are expected to be equivalent from the
	-- functional standpoint. The same client application code should observe no
	-- difference in operation results, even if the Soft version is used on a
	-- non-powerpc target. The Hard binding is naturally expected to run faster
	-- than the Soft version on the same target.

	-- We also offer interfaces not strictly part of the base AltiVec API, such
	-- as vector conversions to/from array representations, which are of interest
	-- for client applications (e.g. for vector initialization purposes) and may
	-- also be used as implementation facilities.

	-----------------------------------------
	-- General package architecture survey --
	-----------------------------------------

	-- The various vector representations are all "containers" of elementary
	-- values, the possible types of which are declared in this root package to
	-- be generally accessible.

	-- From the user standpoint, the two versions of the binding are available
	-- through a consistent hierarchy of units providing identical services:

	-- GNAT.Altivec
	-- (component types)
	-- \|
	-- o----------------o----------------o-------------o
	-- \| \| \| \|
	-- Vector_Types Vector_Operations Vector_Views Conversions

	-- The user can manipulate vectors through two families of types: Vector
	-- types and View types.

	-- Vector types are defined in the GNAT.Altivec.Vector_Types package

	-- On these types, the user can apply the Altivec operations defined in
	-- GNAT.Altivec.Vector_Operations. Their layout is opaque and may vary across
	-- configurations, for it is typically target-endianness dependant.

	-- Vector_Types and Vector_Operations implement the core binding to the
	-- AltiVec API, as described in [PIM-2.1 data types] and [PIM-4 AltiVec
	-- operations and predicates].

	-- View types are defined in the GNAT.Altivec.Vector_Views package

	-- These types do not represent Altivec vectors per se, in the sense that the
	-- Altivec_Operations are not available for them. They are intended to allow
	-- Vector initializations as well as access to the Vector component values.

	-- The GNAT.Altivec.Conversions package is provided to convert a View to the
	-- corresponding Vector and vice-versa.

	-- The two versions of the binding rely on a low level internal interface,
	-- and switching from one version to the other amounts to select one low
	-- level implementation instead of the other.

	-- The bindings are provided as a set of sources together with a project file
	-- (altivec.gpr). The hard/soft binding selection is controlled by a project
	-- variable on targets where switching makes sense. See the example usage
	-- section below.

	---------------------------
	-- Underlying principles --
	---------------------------

	-- The general organization sketched above has been devised from a number
	-- of driving ideas:

	-- o From the clients standpoint, the two versions of the binding should be
	-- as easily exchangable as possible,

	-- o From the maintenance standpoint, we want to avoid as much code
	-- duplication as possible.

	-- o From both standpoints above, we want to maintain a clear interface
	-- separation between the base bindings to the Motorola API and the
	-- additional facilities.

	-- The identification of the low level interface is directly inspired by the
	-- the base API organization, basically consisting of a rich set of functions
	-- around a core of low level primitives mapping to AltiVec instructions.

	-- See for instance "vec_add" in [PIM-4.4 Generic and Specific AltiVec
	-- operations]: no less than six result/arguments combinations of byte vector
	-- types map to "vaddubm".

	-- The "hard" version of the low level primitives map to real AltiVec
	-- instructions via the corresponding GCC builtins. The "soft" version is
	-- a software emulation of those.

	-------------------
	-- Example usage --
	-------------------

	-- Here is a sample program declaring and initializing two vectors, 'add'ing
	-- them and displaying the result components:

	-- with GNAT.Altivec.Vector_Types; use GNAT.Altivec.Vector_Types;
	-- with GNAT.Altivec.Vector_Operations; use GNAT.Altivec.Vector_Operations;
	-- with GNAT.Altivec.Vector_Views; use GNAT.Altivec.Vector_Views;
	-- with GNAT.Altivec.Conversions; use GNAT.Altivec.Conversions;

	-- use GNAT.Altivec;

	-- procedure Sample is
	-- Va : Vector_Unsigned_Int := To_Vector ((Values => (1, 2, 3, 4)));
	-- Vb : Vector_Unsigned_Int := To_Vector ((Values => (1, 2, 3, 4)));

	-- Vs : Vector_Unsigned_Int;
	-- Vs_View : VUI_View;
	-- begin
	-- Vs := Vec_Add (Va, Vb);
	-- Vs_View := To_View (Vs);

	-- for I in Vs_View.Values'Range loop
	-- Put_Line (Unsigned_Int'Image (Vs_View.Values (I)));
	-- end loop;
	-- end;

	-- This currently requires the GNAT project management facilities to compile,
	-- to automatically retrieve the set of necessary sources and switches
	-- depending on your configuration. For the example above, customizing the
	-- switches to include -g also, this would be something like:

	-- sample.gpr
	--
	-- with "altivec.gpr";
	--
	-- project Sample is

	-- for Source_Dirs use (".");
	-- for Main use ("sample");

	-- package Compiler is
	-- for Default_Switches ("Ada") use
	-- Altivec.Compiler'Default_Switches ("Ada") & "-g";
	-- end Compiler;

	-- end Sample;

	-- $ gnatmake -Psample
	-- [...]
	-- $ ./sample
	-- 2
	-- 4
	-- 6
	-- 8

	------------------------------------------------------------------------------

	with System;

	package GNAT.Altivec is

	-- Definitions of constants and vector/array component types common to all
	-- the versions of the binding.

	-- All the vector types are 128bits

	VECTOR_BIT : constant := 128;

	-------------------------------------------
	-- [PIM-2.3.1 Alignment of vector types] --
	-------------------------------------------

	-- "A defined data item of any vector data type in memory is always
	-- aligned on a 16-byte boundary. A pointer to any vector data type always
	-- points to a 16-byte boundary. The compiler is responsible for aligning
	-- vector data types on 16-byte boundaries."

	VECTOR_ALIGNMENT : constant := Natural'Min (16, Standard'Maximum_Alignment);
	-- This value is used to set the alignment of vector datatypes in both the
	-- hard and the soft binding implementations.
	--
	-- We want this value to never be greater than 16, because none of the
	-- binding implementations requires larger alignments and such a value
	-- would cause useless space to be allocated/wasted for vector objects.
	-- Furthermore, the alignment of 16 matches the hard binding leading to
	-- a more faithful emulation.
	--
	-- It needs to be exactly 16 for the hard binding, and the initializing
	-- expression is just right for this purpose since Maximum_Alignment is
	-- expected to be 16 for the real Altivec ABI.
	--
	-- The soft binding doesn't rely on strict 16byte alignment, and we want
	-- the value to be no greater than Standard'Maximum_Alignment in this case
	-- to ensure it is supported on every possible target.

	-------------------------------------------------------
	-- [PIM-2.1] Data Types - Interpretation of contents --
	-------------------------------------------------------

	---------------------
	-- char components --
	---------------------

	CHAR_BIT : constant := 8;
	SCHAR_MIN : constant := -2 ** (CHAR_BIT - 1);
	SCHAR_MAX : constant := 2 ** (CHAR_BIT - 1) - 1;
	UCHAR_MAX : constant := 2 ** CHAR_BIT - 1;

	type unsigned_char is mod UCHAR_MAX + 1;
	for unsigned_char'Size use CHAR_BIT;

	type signed_char is range SCHAR_MIN .. SCHAR_MAX;
	for signed_char'Size use CHAR_BIT;

	subtype bool_char is unsigned_char;
	-- ??? There is a difference here between what the Altivec Technology
	-- Programming Interface Manual says and what GCC says. In the manual,
	-- vector_bool_char is a vector_unsigned_char, while in altivec.h it
	-- is a vector_signed_char.

	bool_char_True : constant bool_char := bool_char'Last;
	bool_char_False : constant bool_char := 0;

	----------------------
	-- short components --
	----------------------

	SHORT_BIT : constant := 16;
	SSHORT_MIN : constant := -2 ** (SHORT_BIT - 1);
	SSHORT_MAX : constant := 2 ** (SHORT_BIT - 1) - 1;
	USHORT_MAX : constant := 2 ** SHORT_BIT - 1;

	type unsigned_short is mod USHORT_MAX + 1;
	for unsigned_short'Size use SHORT_BIT;

	subtype unsigned_short_int is unsigned_short;

	type signed_short is range SSHORT_MIN .. SSHORT_MAX;
	for signed_short'Size use SHORT_BIT;

	subtype signed_short_int is signed_short;

	subtype bool_short is unsigned_short;
	-- ??? See bool_char

	bool_short_True : constant bool_short := bool_short'Last;
	bool_short_False : constant bool_short := 0;

	subtype bool_short_int is bool_short;

	--------------------
	-- int components --
	--------------------

	INT_BIT : constant := 32;
	SINT_MIN : constant := -2 ** (INT_BIT - 1);
	SINT_MAX : constant := 2 ** (INT_BIT - 1) - 1;
	UINT_MAX : constant := 2 ** INT_BIT - 1;

	type unsigned_int is mod UINT_MAX + 1;
	for unsigned_int'Size use INT_BIT;

	type signed_int is range SINT_MIN .. SINT_MAX;
	for signed_int'Size use INT_BIT;

	subtype bool_int is unsigned_int;
	-- ??? See bool_char

	bool_int_True : constant bool_int := bool_int'Last;
	bool_int_False : constant bool_int := 0;

	----------------------
	-- float components --
	----------------------

	FLOAT_BIT : constant := 32;
	FLOAT_DIGIT : constant := 6;
	FLOAT_MIN : constant := -16#0.FFFF_FF#E+32;
	FLOAT_MAX : constant := 16#0.FFFF_FF#E+32;

	type C_float is digits FLOAT_DIGIT range FLOAT_MIN .. FLOAT_MAX;
	for C_float'Size use FLOAT_BIT;

	----------------------
	-- pixel components --
	----------------------

	subtype pixel is unsigned_short;

	-----------------------------------------------------------
	-- Subtypes for variants found in the GCC implementation --
	-----------------------------------------------------------

	subtype c_int is signed_int;
	subtype c_short is c_int;

	LONG_BIT : constant := 32;
	-- Some of the GCC builtins are built with "long" arguments and
	-- expect SImode to come in.

	SLONG_MIN : constant := -2 ** (LONG_BIT - 1);
	SLONG_MAX : constant := 2 ** (LONG_BIT - 1) - 1;
	ULONG_MAX : constant := 2 ** LONG_BIT - 1;

	type signed_long is range SLONG_MIN .. SLONG_MAX;
	type unsigned_long is mod ULONG_MAX + 1;

	subtype c_long is signed_long;

	subtype c_ptr is System.Address;

	---------------------------------------------------------
	-- Access types, for the sake of some argument passing --
	---------------------------------------------------------

	type signed_char_ptr is access all signed_char;
	type unsigned_char_ptr is access all unsigned_char;

	type short_ptr is access all c_short;
	type signed_short_ptr is access all signed_short;
	type unsigned_short_ptr is access all unsigned_short;

	type int_ptr is access all c_int;
	type signed_int_ptr is access all signed_int;
	type unsigned_int_ptr is access all unsigned_int;

	type long_ptr is access all c_long;
	type signed_long_ptr is access all signed_long;
	type unsigned_long_ptr is access all unsigned_long;

	type float_ptr is access all Float;

	--

	type const_signed_char_ptr is access constant signed_char;
	type const_unsigned_char_ptr is access constant unsigned_char;

	type const_short_ptr is access constant c_short;
	type const_signed_short_ptr is access constant signed_short;
	type const_unsigned_short_ptr is access constant unsigned_short;

	type const_int_ptr is access constant c_int;
	type const_signed_int_ptr is access constant signed_int;
	type const_unsigned_int_ptr is access constant unsigned_int;

	type const_long_ptr is access constant c_long;
	type const_signed_long_ptr is access constant signed_long;
	type const_unsigned_long_ptr is access constant unsigned_long;

	type const_float_ptr is access constant Float;

	-- Access to const volatile arguments need specialized types

	type volatile_float is new Float;
	pragma Volatile (volatile_float);

	type volatile_signed_char is new signed_char;
	pragma Volatile (volatile_signed_char);

	type volatile_unsigned_char is new unsigned_char;
	pragma Volatile (volatile_unsigned_char);

	type volatile_signed_short is new signed_short;
	pragma Volatile (volatile_signed_short);

	type volatile_unsigned_short is new unsigned_short;
	pragma Volatile (volatile_unsigned_short);

	type volatile_signed_int is new signed_int;
	pragma Volatile (volatile_signed_int);

	type volatile_unsigned_int is new unsigned_int;
	pragma Volatile (volatile_unsigned_int);

	type volatile_signed_long is new signed_long;
	pragma Volatile (volatile_signed_long);

	type volatile_unsigned_long is new unsigned_long;
	pragma Volatile (volatile_unsigned_long);

	type constv_char_ptr is access constant volatile_signed_char;
	type constv_signed_char_ptr is access constant volatile_signed_char;
	type constv_unsigned_char_ptr is access constant volatile_unsigned_char;

	type constv_short_ptr is access constant volatile_signed_short;
	type constv_signed_short_ptr is access constant volatile_signed_short;
	type constv_unsigned_short_ptr is access constant volatile_unsigned_short;

	type constv_int_ptr is access constant volatile_signed_int;
	type constv_signed_int_ptr is access constant volatile_signed_int;
	type constv_unsigned_int_ptr is access constant volatile_unsigned_int;

	type constv_long_ptr is access constant volatile_signed_long;
	type constv_signed_long_ptr is access constant volatile_signed_long;
	type constv_unsigned_long_ptr is access constant volatile_unsigned_long;

	type constv_float_ptr is access constant volatile_float;

	private

	-----------------------
	-- Various constants --
	-----------------------

	CR6_EQ : constant := 0;
	CR6_EQ_REV : constant := 1;
	CR6_LT : constant := 2;
	CR6_LT_REV : constant := 3;

	end GNAT.Altivec;