1 ------------------------------------------------------------------------------
3 -- GNAT COMPILER COMPONENTS --
9 -- Copyright (C) 1999-2004 Free Software Foundation, Inc. --
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 2, 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 COPYING. If not, write --
19 -- to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, --
20 -- MA 02111-1307, USA. --
22 -- As a special exception, if other files instantiate generics from this --
23 -- unit, or you link this unit with other files to produce an executable, --
24 -- this unit does not by itself cause the resulting executable to be --
25 -- covered by the GNU General Public License. This exception does not --
26 -- however invalidate any other reasons why the executable file might be --
27 -- covered by the GNU Public License. --
29 -- GNAT was originally developed by the GNAT team at New York University. --
30 -- Extensive contributions were provided by Ada Core Technologies Inc. --
32 ------------------------------------------------------------------------------
34 -- This package contains the routines to handle back annotation of the
35 -- tree to fill in representation information, and also the routine used
36 -- by -gnatR to print this information. This unit is used both in the
37 -- compiler and in ASIS (it is used in ASIS as part of the implementation
38 -- of the data decomposition annex.
40 with Types
; use Types
;
41 with Uintp
; use Uintp
;
45 --------------------------------
46 -- Representation Information --
47 --------------------------------
49 -- The representation information of interest here is size and
50 -- component information for arrays and records. For primitive
51 -- types, the front end computes the Esize and RM_Size fields of
52 -- the corresponding entities as constant non-negative integers,
53 -- and the Uint values are stored directly in these fields.
55 -- For composite types, there are three cases:
57 -- 1. In some cases the front end knows the values statically,
58 -- for example in the ase where representation clauses or
59 -- pragmas specify the values.
61 -- 2. If Backend_Layout is True, then the backend is responsible
62 -- for layout of all types and objects not laid out by the
63 -- front end. This includes all dynamic values, and also
64 -- static values (e.g. record sizes) when not set by the
67 -- 3. If Backend_Layout is False, then the front end lays out
68 -- all data, according to target dependent size and alignment
69 -- information, creating dynamic inlinable functions where
70 -- needed in the case of sizes not known till runtime.
72 -----------------------------
73 -- Back-Annotation by Gigi --
74 -----------------------------
76 -- The following interface is used by gigi if Backend_Layout is True
78 -- As part of the processing in gigi, the types are laid out and
79 -- appropriate values computed for the sizes and component positions
80 -- and sizes of records and arrays.
82 -- The back-annotation circuit in gigi is responsible for updating the
83 -- relevant fields in the tree to reflect these computations, as follows:
85 -- For E_Array_Type entities, the Component_Size field
87 -- For all record and array types and subtypes, the Esize field,
88 -- which contains the Size (more accurately the Object_SIze) value
89 -- for the type or subtype.
91 -- For E_Component and E_Distriminant entities, the Esize (size
92 -- of component) and Component_Bit_Offset fields. Note that gigi
93 -- does not (yet ???) back annotate Normalized_Position/First_Bit.
95 -- There are three cases to consider:
97 -- 1. The value is constant. In this case, the back annotation works
98 -- by simply storing the non-negative universal integer value in
99 -- the appropriate field corresponding to this constant size.
101 -- 2. The value depends on variables other than discriminants of the
102 -- current record. In this case, the value is not known, even if
103 -- the complete data of the record is available, and gigi marks
104 -- this situation by storing the special value No_Uint.
106 -- 3. The value depends on the discriminant values for the current
107 -- record. In this case, gigi back annotates the field with a
108 -- representation of the expression for computing the value in
109 -- terms of the discriminants. A negative Uint value is used to
110 -- represent the value of such an expression, as explained in
111 -- the following section.
113 -- GCC expressions are represented with a Uint value that is negative.
114 -- See the body of this package for details on the representation used.
116 -- One other case in which gigi back annotates GCC expressions is in
117 -- the Present_Expr field of an N_Variant node. This expression which
118 -- will always depend on discriminants, and hence always be represented
119 -- as a negative Uint value, provides an expression which, when evaluated
120 -- with a given set of discriminant values, indicates whether the variant
121 -- is present for that set of values (result is True, i.e. non-zero) or
122 -- not present (result is False, i.e. zero).
124 subtype Node_Ref
is Uint
;
125 -- Subtype used for negative Uint values used to represent nodes
127 subtype Node_Ref_Or_Val
is Uint
;
128 -- Subtype used for values that can either be a Node_Ref (negative)
129 -- or a value (non-negative)
131 type TCode
is range 0 .. 27;
132 -- Type used on Ada side to represent DEFTREECODE values defined in
133 -- tree.def. Only a subset of these tree codes can actually appear.
134 -- The names are the names from tree.def in Ada casing.
136 -- name code description operands
138 Cond_Expr
: constant TCode
:= 1; -- conditional 3
139 Plus_Expr
: constant TCode
:= 2; -- addition 2
140 Minus_Expr
: constant TCode
:= 3; -- subtraction 2
141 Mult_Expr
: constant TCode
:= 4; -- multiplication 2
142 Trunc_Div_Expr
: constant TCode
:= 5; -- truncating division 2
143 Ceil_Div_Expr
: constant TCode
:= 6; -- division rounding up 2
144 Floor_Div_Expr
: constant TCode
:= 7; -- division rounding down 2
145 Trunc_Mod_Expr
: constant TCode
:= 8; -- mod for trunc_div 2
146 Ceil_Mod_Expr
: constant TCode
:= 9; -- mod for ceil_div 2
147 Floor_Mod_Expr
: constant TCode
:= 10; -- mod for floor_div 2
148 Exact_Div_Expr
: constant TCode
:= 11; -- exact div 2
149 Negate_Expr
: constant TCode
:= 12; -- negation 1
150 Min_Expr
: constant TCode
:= 13; -- minimum 2
151 Max_Expr
: constant TCode
:= 14; -- maximum 2
152 Abs_Expr
: constant TCode
:= 15; -- absolute value 1
153 Truth_Andif_Expr
: constant TCode
:= 16; -- Boolean and then 2
154 Truth_Orif_Expr
: constant TCode
:= 17; -- Boolean or else 2
155 Truth_And_Expr
: constant TCode
:= 18; -- Boolean and 2
156 Truth_Or_Expr
: constant TCode
:= 19; -- Boolean or 2
157 Truth_Xor_Expr
: constant TCode
:= 20; -- Boolean xor 2
158 Truth_Not_Expr
: constant TCode
:= 21; -- Boolean not 1
159 Lt_Expr
: constant TCode
:= 22; -- comparision < 2
160 Le_Expr
: constant TCode
:= 23; -- comparision <= 2
161 Gt_Expr
: constant TCode
:= 24; -- comparision > 2
162 Ge_Expr
: constant TCode
:= 25; -- comparision >= 2
163 Eq_Expr
: constant TCode
:= 26; -- comparision = 2
164 Ne_Expr
: constant TCode
:= 27; -- comparision /= 2
166 -- The following entry is used to represent a discriminant value in
167 -- the tree. It has a special tree code that does not correspond
168 -- directly to a gcc node. The single operand is the number of the
169 -- discriminant in the record (1 = first discriminant).
171 Discrim_Val
: constant TCode
:= 0; -- discriminant value 1
173 ------------------------
174 -- The gigi Interface --
175 ------------------------
177 -- The following declarations are for use by gigi for back annotation
181 Op1
: Node_Ref_Or_Val
;
182 Op2
: Node_Ref_Or_Val
:= No_Uint
;
183 Op3
: Node_Ref_Or_Val
:= No_Uint
) return Node_Ref
;
184 -- Creates a node with using the tree code defined by Expr and from
185 -- 1-3 operands as required (unused operands set as shown to No_Uint)
186 -- Note that this call can be used to create a discriminant reference
187 -- by using (Expr => Discrim_Val, Op1 => discriminant_number).
189 function Create_Discrim_Ref
(Discr
: Entity_Id
) return Node_Ref
;
190 -- Creates a refrerence to the discriminant whose entity is Discr
192 --------------------------------------------------------
193 -- Front-End Interface for Dynamic Size/Offset Values --
194 --------------------------------------------------------
196 -- If Backend_Layout is False, then the front-end deals with all
197 -- dynamic size and offset fields. There are two cases:
199 -- 1. The value can be computed at the time of type freezing, and
200 -- is stored in a run-time constant. In this case, the field
201 -- contains a reference to this entity. In the case of sizes
202 -- the value stored is the size in storage units, since dynamic
203 -- sizes are always a multiple of storage units.
205 -- 2. The size/offset depends on the value of discriminants at
206 -- run-time. In this case, the front end builds a function to
207 -- compute the value. This function has a single parameter
208 -- which is the discriminated record object in question. Any
209 -- references to discriminant values are simply references to
210 -- the appropriate discriminant in this single argument, and
211 -- to compute the required size/offset value at run time, the
212 -- code generator simply constructs a call to the function
213 -- with the appropriate argument. The size/offset field in
214 -- this case contains a reference to the function entity.
215 -- Note that as for case 1, if such a function is used to
216 -- return a size, then the size in storage units is returned,
217 -- not the size in bits.
219 -- The interface here allows these created entities to be referenced
220 -- using negative Unit values, so that they can be stored in the
221 -- appropriate size and offset fields in the tree.
223 -- In the case of components, if the location of the component is static,
224 -- then all four fields (Component_Bit_Offset, Normalized_Position, Esize,
225 -- and Normalized_First_Bit) are set to appropraite values. In the case of
226 -- a non-static component location, Component_Bit_Offset is not used and
227 -- is left set to Unknown. Normalized_Position and Normalized_First_Bit
228 -- are set appropriately.
230 subtype SO_Ref
is Uint
;
231 -- Type used to represent a Uint value that represents a static or
232 -- dynamic size/offset value (non-negative if static, negative if
233 -- the size value is dynamic).
235 subtype Dynamic_SO_Ref
is Uint
;
236 -- Type used to represent a negative Uint value used to store
237 -- a dynamic size/offset value.
239 function Is_Dynamic_SO_Ref
(U
: SO_Ref
) return Boolean;
240 pragma Inline
(Is_Dynamic_SO_Ref
);
241 -- Given a SO_Ref (Uint) value, returns True iff the SO_Ref value
242 -- represents a dynamic Size/Offset value (i.e. it is negative).
244 function Is_Static_SO_Ref
(U
: SO_Ref
) return Boolean;
245 pragma Inline
(Is_Static_SO_Ref
);
246 -- Given a SO_Ref (Uint) value, returns True iff the SO_Ref value
247 -- represents a static Size/Offset value (i.e. it is non-negative).
249 function Create_Dynamic_SO_Ref
(E
: Entity_Id
) return Dynamic_SO_Ref
;
250 -- Given the Entity_Id for a constant (case 1), the Node_Id for an
251 -- expression (case 2), or the Entity_Id for a function (case 3),
252 -- this function returns a (negative) Uint value that can be used
253 -- to retrieve the entity or expression for later use.
255 function Get_Dynamic_SO_Entity
(U
: Dynamic_SO_Ref
) return Entity_Id
;
256 -- Retrieve the Node_Id or Entity_Id stored by a previous call to
257 -- Create_Dynamic_SO_Ref. The approach is that the front end makes
258 -- the necessary Create_Dynamic_SO_Ref calls to associate the node
259 -- and entity id values and the back end makes Get_Dynamic_SO_Ref
260 -- calls to retrive them.
266 type Discrim_List
is array (Pos
range <>) of Uint
;
267 -- Type used to represent list of discriminant values
270 (Val
: Node_Ref_Or_Val
;
271 D
: Discrim_List
) return Uint
;
272 -- Given the contents of a First_Bit_Position or Esize field containing
273 -- a node reference (i.e. a negative Uint value) and D, the list of
274 -- discriminant values, returns the interpreted value of this field.
275 -- For convenience, Rep_Value will take a non-negative Uint value
276 -- as an argument value, and return it unmodified. A No_Uint value is
277 -- also returned unmodified.
280 -- Initializes internal tables from current tree file using the relevant
281 -- Table.Tree_Read routines.
283 ------------------------
284 -- Compiler Interface --
285 ------------------------
287 procedure List_Rep_Info
;
288 -- Procedure to list representation information
290 procedure Tree_Write
;
291 -- Writes out internal tables to current tree file using the relevant
292 -- Table.Tree_Write routines.
294 --------------------------
295 -- Debugging Procedures --
296 --------------------------
298 procedure List_GCC_Expression
(U
: Node_Ref_Or_Val
);
299 -- Prints out given expression in symbolic form. Constants are listed
300 -- in decimal numeric form, Discriminants are listed with a # followed
301 -- by the discriminant number, and operators are output in appropriate
302 -- symbolic form No_Uint displays as two question marks. The output is
303 -- on a single line but has no line return after it. This procedure is
304 -- useful only if operating in backend layout mode.
306 procedure lgx
(U
: Node_Ref_Or_Val
);
307 -- In backend layout mode, this is like List_GCC_Expression, but
308 -- includes a line return at the end. If operating in front end
309 -- layout mode, then the name of the entity for the size (either
310 -- a function of a variable) is listed followed by a line return.