OpenCores
URL https://opencores.org/ocsvn/openrisc/openrisc/trunk

Subversion Repositories openrisc

[/] [openrisc/] [trunk/] [gnu-dev/] [or1k-gcc/] [gcc/] [ada/] [exp_pakd.ads] - Blame information for rev 707

Go to most recent revision | Details | Compare with Previous | View Log

Line No. Rev Author Line
1 706 jeremybenn
------------------------------------------------------------------------------
2
--                                                                          --
3
--                         GNAT COMPILER COMPONENTS                         --
4
--                                                                          --
5
--                             E X P _ P A K D                              --
6
--                                                                          --
7
--                                 S p e c                                  --
8
--                                                                          --
9
--          Copyright (C) 1992-2010, Free Software Foundation, Inc.         --
10
--                                                                          --
11
-- GNAT is free software;  you can  redistribute it  and/or modify it under --
12
-- terms of the  GNU General Public License as published  by the Free Soft- --
13
-- ware  Foundation;  either version 3,  or (at your option) any later ver- --
14
-- sion.  GNAT is distributed in the hope that it will be useful, but WITH- --
15
-- OUT ANY WARRANTY;  without even the  implied warranty of MERCHANTABILITY --
16
-- or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License --
17
-- for  more details.  You should have  received  a copy of the GNU General --
18
-- Public License  distributed with GNAT; see file COPYING3.  If not, go to --
19
-- http://www.gnu.org/licenses for a complete copy of the license.          --
20
--                                                                          --
21
-- GNAT was originally developed  by the GNAT team at  New York University. --
22
-- Extensive contributions were provided by Ada Core Technologies Inc.      --
23
--                                                                          --
24
------------------------------------------------------------------------------
25
 
26
--  Expand routines for manipulation of packed arrays
27
 
28
with Types; use Types;
29
 
30
package Exp_Pakd is
31
 
32
   -------------------------------------
33
   -- Implementation of Packed Arrays --
34
   -------------------------------------
35
 
36
   --  When a packed array (sub)type is frozen, we create a corresponding
37
   --  type that will be used to hold the bits of the packed value, and
38
   --  store the entity for this type in the Packed_Array_Type field of the
39
   --  E_Array_Type or E_Array_Subtype entity for the packed array.
40
 
41
   --  This packed array type has the name xxxPn, where xxx is the name
42
   --  of the packed type, and n is the component size. The expanded
43
   --  declaration declares a type that is one of the following:
44
 
45
   --    For an unconstrained array with component size 1,2,4 or any other
46
   --    odd component size. These are the cases in which we do not need
47
   --    to align the underlying array.
48
 
49
   --      type xxxPn is new Packed_Bytes1;
50
 
51
   --    For an unconstrained array with component size that is divisible
52
   --    by 2, but not divisible by 4 (other than 2 itself). These are the
53
   --    cases in which we can generate better code if the underlying array
54
   --    is 2-byte aligned (see System.Pack_14 in file s-pack14 for example).
55
 
56
   --      type xxxPn is new Packed_Bytes2;
57
 
58
   --    For an unconstrained array with component size that is divisible
59
   --    by 4, other than powers of 2 (which either come under the 1,2,4
60
   --    exception above, or are not packed at all). These are cases where
61
   --    we can generate better code if the underlying array is 4-byte
62
   --    aligned (see System.Pack_20 in file s-pack20 for example).
63
 
64
   --      type xxxPn is new Packed_Bytes4;
65
 
66
   --    For a constrained array with a static index type where the number
67
   --    of bits does not exceed the size of Unsigned:
68
 
69
   --      type xxxPn is new Unsigned range 0 .. 2 ** nbits - 1;
70
 
71
   --    For a constrained array with a static index type where the number
72
   --    of bits is greater than the size of Unsigned, but does not exceed
73
   --    the size of Long_Long_Unsigned:
74
 
75
   --       type xxxPn is new Long_Long_Unsigned range 0 .. 2 ** nbits - 1;
76
 
77
   --    For all other constrained arrays, we use one of
78
 
79
   --       type xxxPn is new Packed_Bytes1 (0 .. m);
80
   --       type xxxPn is new Packed_Bytes2 (0 .. m);
81
   --       type xxxPn is new Packed_Bytes4 (0 .. m);
82
 
83
   --    where m is calculated (from the length of the original packed array)
84
   --    to hold the required number of bits, and the choice of the particular
85
   --    Packed_Bytes{1,2,4} type is made on the basis of alignment needs as
86
   --    described above for the unconstrained case.
87
 
88
   --  When a variable of packed array type is allocated, gigi will allocate
89
   --  the amount of space indicated by the corresponding packed array type.
90
   --  However, we do NOT attempt to rewrite the types of any references or
91
   --  to retype the variable itself, since this would cause all kinds of
92
   --  semantic problems in the front end (remember that expansion proceeds
93
   --  at the same time as analysis).
94
 
95
   --  For an indexed reference to a packed array, we simply convert the
96
   --  reference to the appropriate equivalent reference to the object
97
   --  of the packed array type (using unchecked conversion).
98
 
99
   --  In some cases (for internally generated types, and for the subtypes
100
   --  for record fields that depend on a discriminant), the corresponding
101
   --  packed type cannot be easily generated in advance. In these cases,
102
   --  we generate the required subtype on the fly at the reference point.
103
 
104
   --  For the modular case, any unused bits are initialized to zero, and
105
   --  all operations maintain these bits as zero (where necessary all
106
   --  unchecked conversions from corresponding array values require
107
   --  these bits to be clear, which is done automatically by gigi).
108
 
109
   --  For the array cases, there can be unused bits in the last byte, and
110
   --  these are neither initialized, nor treated specially in operations
111
   --  (i.e. it is allowable for these bits to be clobbered, e.g. by not).
112
 
113
   ---------------------------
114
   -- Endian Considerations --
115
   ---------------------------
116
 
117
   --  The standard does not specify the way in which bits are numbered in
118
   --  a packed array. There are two reasonable rules for deciding this:
119
 
120
   --    Store the first bit at right end (low order) word. This means
121
   --    that the scaled subscript can be used directly as a left shift
122
   --    count (if we put bit 0 at the left end, then we need an extra
123
   --    subtract to compute the shift count).
124
 
125
   --    Layout the bits so that if the packed boolean array is overlaid on
126
   --    a record, using unchecked conversion, then bit 0 of the array is
127
   --    the same as the bit numbered bit 0 in a record representation
128
   --    clause applying to the record. For example:
129
 
130
   --       type Rec is record
131
   --          C : Bits4;
132
   --          D : Bits7;
133
   --          E : Bits5;
134
   --       end record;
135
 
136
   --       for Rec use record
137
   --          C at 0 range  0  .. 3;
138
   --          D at 0 range  4 .. 10;
139
   --          E at 0 range 11 .. 15;
140
   --       end record;
141
 
142
   --       type P16 is array (0 .. 15) of Boolean;
143
   --       pragma Pack (P16);
144
 
145
   --    Now if we use unchecked conversion to convert a value of the record
146
   --    type to the packed array type, according to this second criterion,
147
   --    we would expect field D to occupy bits 4..10 of the Boolean array.
148
 
149
   --  Although not required, this correspondence seems a highly desirable
150
   --  property, and is one that GNAT decides to guarantee. For a little
151
   --  endian machine, we can also meet the first requirement, but for a
152
   --  big endian machine, it will be necessary to store the first bit of
153
   --  a Boolean array in the left end (most significant) bit of the word.
154
   --  This may cost an extra instruction on some machines, but we consider
155
   --  that a worthwhile price to pay for the consistency.
156
 
157
   --  One more important point arises in the case where we have a constrained
158
   --  subtype of an unconstrained array. Take the case of 20 bits. For the
159
   --  unconstrained representation, we would use an array of bytes:
160
 
161
   --     Little-endian case
162
   --       8-7-6-5-4-3-2-1  16-15-14-13-12-11-10-9  x-x-x-x-20-19-18-17
163
 
164
   --     Big-endian case
165
   --       1-2-3-4-5-6-7-8  9-10-11-12-13-14-15-16  17-18-19-20-x-x-x-x
166
 
167
   --   For the constrained case, we use a 20-bit modular value, but in
168
   --   general this value may well be stored in 32 bits. Let's look at
169
   --   what it looks like:
170
 
171
   --     Little-endian case
172
 
173
   --       x-x-x-x-x-x-x-x-x-x-x-x-20-19-18-17-...-10-9-8-7-6-5-4-3-2-1
174
 
175
   --         which stored in memory looks like
176
 
177
   --       8-7-...-2-1  16-15-...-10-9  x-x-x-x-20-19-18-17  x-x-x-x-x-x-x
178
 
179
   --   An important rule is that the constrained and unconstrained cases
180
   --   must have the same bit representation in memory, since we will often
181
   --   convert from one to the other (e.g. when calling a procedure whose
182
   --   formal is unconstrained). As we see, that criterion is met for the
183
   --   little-endian case above. Now let's look at the big-endian case:
184
 
185
   --     Big-endian case
186
 
187
   --       x-x-x-x-x-x-x-x-x-x-x-x-1-2-3-4-5-6-7-8-9-10-...-17-18-19-20
188
 
189
   --         which stored in memory looks like
190
 
191
   --       x-x-x-x-x-x-x-x  x-x-x-x-1-2-3-4  5-6-...11-12  13-14-...-19-20
192
 
193
   --   That won't do, the representation value in memory is NOT the same in
194
   --   the constrained and unconstrained case. The solution is to store the
195
   --   modular value left-justified:
196
 
197
   --       1-2-3-4-5-6-7-8-9-10-...-17-18-19-20-x-x-x-x-x-x-x-x-x-x-x
198
 
199
   --         which stored in memory looks like
200
 
201
   --       1-2-...-7-8  9-10-...15-16  17-18-19-20-x-x-x-x  x-x-x-x-x-x-x-x
202
 
203
   --   and now, we do indeed have the same representation for the memory
204
   --   version in the constrained and unconstrained cases.
205
 
206
   -----------------
207
   -- Subprograms --
208
   -----------------
209
 
210
   procedure Create_Packed_Array_Type (Typ  : Entity_Id);
211
   --  Typ is a array type or subtype to which pragma Pack applies. If the
212
   --  Packed_Array_Type field of Typ is already set, then the call has no
213
   --  effect, otherwise a suitable type or subtype is created and stored
214
   --  in the Packed_Array_Type field of Typ. This created type is an Itype
215
   --  so that Gigi will simply elaborate and freeze the type on first use
216
   --  (which is typically the definition of the corresponding array type).
217
   --
218
   --  Note: although this routine is included in the expander package for
219
   --  packed types, it is actually called unconditionally from Freeze,
220
   --  whether or not expansion (and code generation) is enabled. We do this
221
   --  since we want gigi to be able to properly compute type characteristics
222
   --  (for the Data Decomposition Annex of ASIS, and possible other future
223
   --  uses) even if code generation is not active. Strictly this means that
224
   --  this procedure is not part of the expander, but it seems appropriate
225
   --  to keep it together with the other expansion routines that have to do
226
   --  with packed array types.
227
 
228
   procedure Expand_Packed_Boolean_Operator (N : Node_Id);
229
   --  N is an N_Op_And, N_Op_Or or N_Op_Xor node whose operand type is a
230
   --  packed boolean array. This routine expands the appropriate operations
231
   --  to carry out the logical operation on the packed arrays. It handles
232
   --  both the modular and array representation cases.
233
 
234
   procedure Expand_Packed_Element_Reference (N : Node_Id);
235
   --  N is an N_Indexed_Component node whose prefix is a packed array. In
236
   --  the bit packed case, this routine can only be used for the expression
237
   --  evaluation case, not the assignment case, since the result is not a
238
   --  variable. See Expand_Bit_Packed_Element_Set for how the assignment case
239
   --  is handled in the bit packed case. For the enumeration case, the result
240
   --  of this call is always a variable, so the call can be used for both the
241
   --  expression evaluation and assignment cases.
242
 
243
   procedure Expand_Bit_Packed_Element_Set (N : Node_Id);
244
   --  N is an N_Assignment_Statement node whose name is an indexed
245
   --  component of a bit-packed array. This procedure rewrites the entire
246
   --  assignment statement with appropriate code to set the referenced
247
   --  bits of the packed array type object. Note that this procedure is
248
   --  used only for the bit-packed case, not for the enumeration case.
249
 
250
   procedure Expand_Packed_Eq (N : Node_Id);
251
   --  N is an N_Op_Eq node where the operands are packed arrays whose
252
   --  representation is an array-of-bytes type (the case where a modular
253
   --  type is used for the representation does not require any special
254
   --  handling, because in the modular case, unused bits are zeroes.
255
 
256
   procedure Expand_Packed_Not (N : Node_Id);
257
   --  N is an N_Op_Not node where the operand is packed array of Boolean
258
   --  in standard representation (i.e. component size is one bit). This
259
   --  procedure expands the corresponding not operation. Note that the
260
   --  non-standard representation case is handled by using a loop through
261
   --  elements generated by the normal non-packed circuitry.
262
 
263
   function Involves_Packed_Array_Reference (N : Node_Id) return Boolean;
264
   --  N is the node for a name. This function returns true if the name
265
   --  involves a packed array reference. A node involves a packed array
266
   --  reference if it is itself an indexed component referring to a bit-
267
   --  packed array, or it is a selected component whose prefix involves
268
   --  a packed array reference.
269
 
270
   procedure Expand_Packed_Address_Reference (N : Node_Id);
271
   --  The node N is an attribute reference for the 'Address reference, where
272
   --  the prefix involves a packed array reference. This routine expands the
273
   --  necessary code for performing the address reference in this case.
274
 
275
   procedure Expand_Packed_Bit_Reference (N : Node_Id);
276
   --  The node N is an attribute reference for the 'Bit reference, where the
277
   --  prefix involves a packed array reference. This routine expands the
278
   --  necessary code for performing the bit reference in this case.
279
 
280
end Exp_Pakd;

powered by: WebSVN 2.1.0

© copyright 1999-2024 OpenCores.org, equivalent to Oliscience, all rights reserved. OpenCores®, registered trademark.