Imported GNU Classpath 0.90
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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- T Y P E S --
6 -- --
7 -- S p e c --
8 -- --
9 -- Copyright (C) 1992-2006, 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 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, 51 Franklin Street, Fifth Floor, --
20 -- Boston, MA 02110-1301, USA. --
21 -- --
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. --
28 -- --
29 -- GNAT was originally developed by the GNAT team at New York University. --
30 -- Extensive contributions were provided by Ada Core Technologies Inc. --
31 -- --
32 ------------------------------------------------------------------------------
34 -- This package contains host independent type definitions which are used
35 -- in more than one unit in the compiler. They are gathered here for easy
36 -- reference, though in some cases the full description is found in the
37 -- relevant module which implements the definition. The main reason that
38 -- they are not in their "natural" specs is that this would cause a lot of
39 -- inter-spec dependencies, and in particular some awkward circular
40 -- dependencies would have to be dealt with.
42 -- WARNING: There is a C version of this package. Any changes to this
43 -- source file must be properly reflected in the C header file types.h
45 -- Note: the declarations in this package reflect an expectation that the
46 -- host machine has an efficient integer base type with a range at least
47 -- 32 bits 2s-complement. If there are any machines for which this is not
48 -- a correct assumption, a significant number of changes will be required!
50 with Unchecked_Deallocation;
52 package Types is
53 pragma Preelaborate;
55 -------------------------------
56 -- General Use Integer Types --
57 -------------------------------
59 type Int is range -2 ** 31 .. +2 ** 31 - 1;
60 -- Signed 32-bit integer
62 type Dint is range -2 ** 63 .. +2 ** 63 - 1;
63 -- Double length (64-bit) integer
65 subtype Nat is Int range 0 .. Int'Last;
66 -- Non-negative Int values
68 subtype Pos is Int range 1 .. Int'Last;
69 -- Positive Int values
71 type Word is mod 2 ** 32;
72 -- Unsigned 32-bit integer
74 type Short is range -32768 .. +32767;
75 for Short'Size use 16;
76 -- 16-bit signed integer
78 type Byte is mod 2 ** 8;
79 for Byte'Size use 8;
80 -- 8-bit unsigned integer
82 type size_t is mod 2 ** Standard'Address_Size;
83 -- Memory size value, for use in calls to C routines
85 --------------------------------------
86 -- 8-Bit Character and String Types --
87 --------------------------------------
89 -- We use Standard.Character and Standard.String freely, since we are
90 -- compiling ourselves, and we properly implement the required 8-bit
91 -- character code as required in Ada 95. This section defines a few
92 -- general use constants and subtypes.
94 EOF : constant Character := ASCII.SUB;
95 -- The character SUB (16#1A#) is used in DOS and other systems derived
96 -- from DOS (OS/2, NT etc) to signal the end of a text file. Internally
97 -- all source files are ended by an EOF character, even on Unix systems.
98 -- An EOF character acts as the end of file only as the last character
99 -- of a source buffer, in any other position, it is treated as a blank
100 -- if it appears between tokens, and as an illegal character otherwise.
101 -- This makes life easier dealing with files that originated from DOS,
102 -- including concatenated files with interspersed EOF characters.
104 subtype Graphic_Character is Character range ' ' .. '~';
105 -- Graphic characters, as defined in ARM
107 subtype Line_Terminator is Character range ASCII.LF .. ASCII.CR;
108 -- Line terminator characters (LF, VT, FF, CR)
109 -- This definition is dubious now that we have two more wide character
110 -- sequences that constitute a line terminator. Every reference to
111 -- this subtype needs checking to make sure the wide character case
112 -- is handled appropriately.
114 subtype Upper_Half_Character is
115 Character range Character'Val (16#80#) .. Character'Val (16#FF#);
116 -- Characters with the upper bit set
118 type Character_Ptr is access all Character;
119 type String_Ptr is access all String;
120 -- Standard character and string pointers
122 procedure Free is new Unchecked_Deallocation (String, String_Ptr);
123 -- Procedure for freeing dynamically allocated String values
125 subtype Word_Hex_String is String (1 .. 8);
126 -- Type used to represent Word value as 8 hex digits, with lower case
127 -- letters for the alphabetic cases.
129 function Get_Hex_String (W : Word) return Word_Hex_String;
130 -- Convert word value to 8-character hex string
132 -----------------------------------------
133 -- Types Used for Text Buffer Handling --
134 -----------------------------------------
136 -- We can't use type String for text buffers, since we must use the
137 -- standard 32-bit integer as an index value, since we count on all
138 -- index values being the same size.
140 type Text_Ptr is new Int;
141 -- Type used for subscripts in text buffer
143 type Text_Buffer is array (Text_Ptr range <>) of Character;
144 -- Text buffer used to hold source file or library information file
146 type Text_Buffer_Ptr is access all Text_Buffer;
147 -- Text buffers for input files are allocated dynamically and this type
148 -- is used to reference these text buffers.
150 procedure Free is new Unchecked_Deallocation (Text_Buffer, Text_Buffer_Ptr);
151 -- Procedure for freeing dynamically allocated text buffers
153 ------------------------------------------
154 -- Types Used for Source Input Handling --
155 ------------------------------------------
157 type Logical_Line_Number is range 0 .. Int'Last;
158 for Logical_Line_Number'Size use 32;
159 -- Line number type, used for storing logical line numbers (i.e. line
160 -- numbers that include effects of any Source_Reference pragmas in the
161 -- source file). The value zero indicates a line containing a source
162 -- reference pragma.
164 No_Line_Number : constant Logical_Line_Number := 0;
165 -- Special value used to indicate no line number
167 type Physical_Line_Number is range 1 .. Int'Last;
168 for Physical_Line_Number'Size use 32;
169 -- Line number type, used for storing physical line numbers (i.e.
170 -- line numbers in the physical file being compiled, unaffected by
171 -- the presence of source reference pragmas.
173 type Column_Number is range 0 .. 32767;
174 for Column_Number'Size use 16;
175 -- Column number (assume that 2**15 - 1 is large enough). The range for
176 -- this type is used to compute Hostparm.Max_Line_Length. See also the
177 -- processing for -gnatyM in Stylesw).
179 No_Column_Number : constant Column_Number := 0;
180 -- Special value used to indicate no column number
182 subtype Source_Buffer is Text_Buffer;
183 -- Type used to store text of a source file . The buffer for the main
184 -- source (the source specified on the command line) has a lower bound
185 -- starting at zero. Subsequent subsidiary sources have lower bounds
186 -- which are one greater than the previous upper bound.
188 subtype Big_Source_Buffer is Text_Buffer (0 .. Text_Ptr'Last);
189 -- This is a virtual type used as the designated type of the access
190 -- type Source_Buffer_Ptr, see Osint.Read_Source_File for details.
192 type Source_Buffer_Ptr is access all Big_Source_Buffer;
193 -- Pointer to source buffer. We use virtual origin addressing for
194 -- source buffers, with thin pointers. The pointer points to a virtual
195 -- instance of type Big_Source_Buffer, where the actual type is in fact
196 -- of type Source_Buffer. The address is adjusted so that the virtual
197 -- origin addressing works correctly. See Osint.Read_Source_Buffer for
198 -- further details.
200 subtype Source_Ptr is Text_Ptr;
201 -- Type used to represent a source location, which is a subscript of a
202 -- character in the source buffer. As noted above, diffferent source
203 -- buffers have different ranges, so it is possible to tell from a
204 -- Source_Ptr value which source it refers to. Note that negative numbers
205 -- are allowed to accommodate the following special values.
207 No_Location : constant Source_Ptr := -1;
208 -- Value used to indicate no source position set in a node. A test for
209 -- a Source_Ptr value being >= No_Location is the apporoved way to test
210 -- for a standard value that does not include No_Location or any of the
211 -- following special definitions.
213 Standard_Location : constant Source_Ptr := -2;
214 -- Used for all nodes in the representation of package Standard other
215 -- than nodes representing the contents of Standard.ASCII. Note that
216 -- testing for <= Standard_Location tests for both Standard_Location
217 -- and for Standard_ASCII_Location.
219 Standard_ASCII_Location : constant Source_Ptr := -3;
220 -- Used for all nodes in the presentation of package Standard.ASCII
222 System_Location : constant Source_Ptr := -4;
223 -- Used to identify locations of pragmas scanned by Targparm, where we
224 -- know the location is in System, but we don't know exactly what line.
226 First_Source_Ptr : constant Source_Ptr := 0;
227 -- Starting source pointer index value for first source program
229 -------------------------------------
230 -- Range Definitions for Tree Data --
231 -------------------------------------
233 -- The tree has fields that can hold any of the following types:
235 -- Pointers to other tree nodes (type Node_Id)
236 -- List pointers (type List_Id)
237 -- Element list pointers (type Elist_Id)
238 -- Names (type Name_Id)
239 -- Strings (type String_Id)
240 -- Universal integers (type Uint)
241 -- Universal reals (type Ureal)
243 -- In most contexts, the strongly typed interface determines which of
244 -- these types is present. However, there are some situations (involving
245 -- untyped traversals of the tree), where it is convenient to be easily
246 -- able to distinguish these values. The underlying representation in all
247 -- cases is an integer type Union_Id, and we ensure that the range of
248 -- the various possible values for each of the above types is disjoint
249 -- so that this distinction is possible.
251 type Union_Id is new Int;
252 -- The type in the tree for a union of possible ID values
254 -- Note: it is also helpful for debugging purposes to make these ranges
255 -- distinct. If a bug leads to misidentification of a value, then it will
256 -- typically result in an out of range value and a Constraint_Error.
258 List_Low_Bound : constant := -100_000_000;
259 -- The List_Id values are subscripts into an array of list headers which
260 -- has List_Low_Bound as its lower bound. This value is chosen so that all
261 -- List_Id values are negative, and the value zero is in the range of both
262 -- List_Id and Node_Id values (see further description below).
264 List_High_Bound : constant := 0;
265 -- Maximum List_Id subscript value. This allows up to 100 million list
266 -- Id values, which is in practice infinite, and there is no need to
267 -- check the range. The range overlaps the node range by one element
268 -- (with value zero), which is used both for the Empty node, and for
269 -- indicating no list. The fact that the same value is used is convenient
270 -- because it means that the default value of Empty applies to both nodes
271 -- and lists, and also is more efficient to test for.
273 Node_Low_Bound : constant := 0;
274 -- The tree Id values start at zero, because we use zero for Empty (to
275 -- allow a zero test for Empty). Actual tree node subscripts start at 0
276 -- since Empty is a legitimate node value.
278 Node_High_Bound : constant := 099_999_999;
279 -- Maximum number of nodes that can be allocated is 100 million, which
280 -- is in practice infinite, and there is no need to check the range.
282 Elist_Low_Bound : constant := 100_000_000;
283 -- The Elist_Id values are subscripts into an array of elist headers which
284 -- has Elist_Low_Bound as its lower bound.
286 Elist_High_Bound : constant := 199_999_999;
287 -- Maximum Elist_Id subscript value. This allows up to 100 million Elists,
288 -- which is in practice infinite and there is no need to check the range.
290 Elmt_Low_Bound : constant := 200_000_000;
291 -- Low bound of element Id values. The use of these values is internal to
292 -- the Elists package, but the definition of the range is included here
293 -- since it must be disjoint from other Id values. The Elmt_Id values are
294 -- subscripts into an array of list elements which has this as lower bound.
296 Elmt_High_Bound : constant := 299_999_999;
297 -- Upper bound of Elmt_Id values. This allows up to 100 million element
298 -- list members, which is in practice infinite (no range check needed).
300 Names_Low_Bound : constant := 300_000_000;
301 -- Low bound for name Id values
303 Names_High_Bound : constant := 399_999_999;
304 -- Maximum number of names that can be allocated is 100 million, which is
305 -- in practice infinite and there is no need to check the range.
307 Strings_Low_Bound : constant := 400_000_000;
308 -- Low bound for string Id values
310 Strings_High_Bound : constant := 499_999_999;
311 -- Maximum number of strings that can be allocated is 100 million, which
312 -- is in practice infinite and there is no need to check the range.
314 Ureal_Low_Bound : constant := 500_000_000;
315 -- Low bound for Ureal values
317 Ureal_High_Bound : constant := 599_999_999;
318 -- Maximum number of Ureal values stored is 100_000_000 which is in
319 -- practice infinite so that no check is required.
321 Uint_Low_Bound : constant := 600_000_000;
322 -- Low bound for Uint values
324 Uint_Table_Start : constant := 2_000_000_000;
325 -- Location where table entries for universal integers start (see
326 -- Uintp spec for details of the representation of Uint values).
328 Uint_High_Bound : constant := 2_099_999_999;
329 -- The range of Uint values is very large, since a substantial part
330 -- of this range is used to store direct values, see Uintp for details.
332 -- The following subtype definitions are used to provide convenient names
333 -- for membership tests on Int values to see what data type range they
334 -- lie in. Such tests appear only in the lowest level packages.
336 subtype List_Range is Union_Id
337 range List_Low_Bound .. List_High_Bound;
339 subtype Node_Range is Union_Id
340 range Node_Low_Bound .. Node_High_Bound;
342 subtype Elist_Range is Union_Id
343 range Elist_Low_Bound .. Elist_High_Bound;
345 subtype Elmt_Range is Union_Id
346 range Elmt_Low_Bound .. Elmt_High_Bound;
348 subtype Names_Range is Union_Id
349 range Names_Low_Bound .. Names_High_Bound;
351 subtype Strings_Range is Union_Id
352 range Strings_Low_Bound .. Strings_High_Bound;
354 subtype Uint_Range is Union_Id
355 range Uint_Low_Bound .. Uint_High_Bound;
357 subtype Ureal_Range is Union_Id
358 range Ureal_Low_Bound .. Ureal_High_Bound;
360 -----------------------------
361 -- Types for Namet Package --
362 -----------------------------
364 -- Name_Id values are used to identify entries in the names table. Except
365 -- for the special values No_Name, and Error_Name, they are subscript
366 -- values for the Names table defined in package Namet.
368 -- Note that with only a few exceptions, which are clearly documented, the
369 -- type Name_Id should be regarded as a private type. In particular it is
370 -- never appropriate to perform arithmetic operations using this type.
372 type Name_Id is range Names_Low_Bound .. Names_High_Bound;
373 for Name_Id'Size use 32;
374 -- Type used to identify entries in the names table
376 No_Name : constant Name_Id := Names_Low_Bound;
377 -- The special Name_Id value No_Name is used in the parser to indicate
378 -- a situation where no name is present (e.g. on a loop or block).
380 Error_Name : constant Name_Id := Names_Low_Bound + 1;
381 -- The special Name_Id value Error_Name is used in the parser to
382 -- indicate that some kind of error was encountered in scanning out
383 -- the relevant name, so it does not have a representable label.
385 subtype Error_Name_Or_No_Name is Name_Id range No_Name .. Error_Name;
386 -- Used to test for either error name or no name
388 First_Name_Id : constant Name_Id := Names_Low_Bound + 2;
389 -- Subscript of first entry in names table
391 ----------------------------
392 -- Types for Atree Package --
393 ----------------------------
395 -- Node_Id values are used to identify nodes in the tree. They are
396 -- subscripts into the Node table declared in package Tree. Note that
397 -- the special values Empty and Error are subscripts into this table,
398 -- See package Atree for further details.
400 type Node_Id is range Node_Low_Bound .. Node_High_Bound;
401 -- Type used to identify nodes in the tree
403 subtype Entity_Id is Node_Id;
404 -- A synonym for node types, used in the entity package to refer to
405 -- nodes that are entities (i.e. nodes with an Nkind of N_Defining_xxx)
406 -- All such nodes are extended nodes and these are the only extended
407 -- nodes, so that in practice entity and extended nodes are synonymous.
409 subtype Node_Or_Entity_Id is Node_Id;
410 -- A synonym for node types, used in cases where a given value may be used
411 -- to represent either a node or an entity. We like to minimize such uses
412 -- for obvious reasons of logical type consistency, but where such uses
413 -- occur, they should be documented by use of this type.
415 Empty : constant Node_Id := Node_Low_Bound;
416 -- Used to indicate null node. A node is actually allocated with this
417 -- Id value, so that Nkind (Empty) = N_Empty. Note that Node_Low_Bound
418 -- is zero, so Empty = No_List = zero.
420 Empty_List_Or_Node : constant := 0;
421 -- This constant is used in situations (e.g. initializing empty fields)
422 -- where the value set will be used to represent either an empty node
423 -- or a non-existent list, depending on the context.
425 Error : constant Node_Id := Node_Low_Bound + 1;
426 -- Used to indicate that there was an error in the source program. A node
427 -- is actually allocated at this address, so that Nkind (Error) = N_Error.
429 Empty_Or_Error : constant Node_Id := Error;
430 -- Since Empty and Error are the first two Node_Id values, the test for
431 -- N <= Empty_Or_Error tests to see if N is Empty or Error. This definition
432 -- provides convenient self-documentation for such tests.
434 First_Node_Id : constant Node_Id := Node_Low_Bound;
435 -- Subscript of first allocated node. Note that Empty and Error are both
436 -- allocated nodes, whose Nkind fields can be accessed without error.
438 ------------------------------
439 -- Types for Nlists Package --
440 ------------------------------
442 -- List_Id values are used to identify node lists in the tree. They are
443 -- subscripts into the Lists table declared in package Tree. Note that
444 -- the special value Error_List is a subscript in this table, but the
445 -- value No_List is *not* a valid subscript, and any attempt to apply
446 -- list operations to No_List will cause a (detected) error.
448 type List_Id is range List_Low_Bound .. List_High_Bound;
449 -- Type used to identify a node list
451 No_List : constant List_Id := List_High_Bound;
452 -- Used to indicate absence of a list. Note that the value is zero, which
453 -- is the same as Empty, which is helpful in intializing nodes where a
454 -- value of zero can represent either an empty node or an empty list.
456 Error_List : constant List_Id := List_Low_Bound;
457 -- Used to indicate that there was an error in the source program in a
458 -- context which would normally require a list. This node appears to be
459 -- an empty list to the list operations (a null list is actually allocated
460 -- which has this Id value).
462 First_List_Id : constant List_Id := Error_List;
463 -- Subscript of first allocated list header
465 ------------------------------
466 -- Types for Elists Package --
467 ------------------------------
469 -- Element list Id values are used to identify element lists stored in
470 -- the tree (see package Tree for further details). They are formed by
471 -- adding a bias (Element_List_Bias) to subscript values in the same
472 -- array that is used for node list headers.
474 type Elist_Id is range Elist_Low_Bound .. Elist_High_Bound;
475 -- Type used to identify an element list (Elist header table subscript)
477 No_Elist : constant Elist_Id := Elist_Low_Bound;
478 -- Used to indicate absense of an element list. Note that this is not
479 -- an actual Elist header, so element list operations on this value
480 -- are not valid.
482 First_Elist_Id : constant Elist_Id := No_Elist + 1;
483 -- Subscript of first allocated Elist header
485 -- Element Id values are used to identify individual elements of an
486 -- element list (see package Elists for further details).
488 type Elmt_Id is range Elmt_Low_Bound .. Elmt_High_Bound;
489 -- Type used to identify an element list
491 No_Elmt : constant Elmt_Id := Elmt_Low_Bound;
492 -- Used to represent empty element
494 First_Elmt_Id : constant Elmt_Id := No_Elmt + 1;
495 -- Subscript of first allocated Elmt table entry
497 -------------------------------
498 -- Types for Stringt Package --
499 -------------------------------
501 -- String_Id values are used to identify entries in the strings table.
502 -- They are subscripts into the strings table defined in package Strings.
504 -- Note that with only a few exceptions, which are clearly documented, the
505 -- type String_Id should be regarded as a private type. In particular it is
506 -- never appropriate to perform arithmetic operations using this type.
508 type String_Id is range Strings_Low_Bound .. Strings_High_Bound;
509 -- Type used to identify entries in the strings table
511 No_String : constant String_Id := Strings_Low_Bound;
512 -- Used to indicate missing string Id. Note that the value zero is used
513 -- to indicate a missing data value for all the Int types in this section.
515 First_String_Id : constant String_Id := No_String + 1;
516 -- First subscript allocated in string table
518 -------------------------
519 -- Character Code Type --
520 -------------------------
522 -- The type Char is used for character data internally in the compiler,
523 -- but character codes in the source are represented by the Char_Code
524 -- type. Each character literal in the source is interpreted as being one
525 -- of the 16#8000_0000 possible Wide_Wide_Character codes, and a unique
526 -- Integer Value is assigned, corresponding to the UTF_32 value, which
527 -- also correspondds to the POS value in the Wide_Wide_Character type,
528 -- and also corresponds to the POS value in the Wide_Character and
529 -- Character types for values that are in appropriate range. String
530 -- literals are similarly interpreted as a sequence of such codes.
532 type Char_Code_Base is mod 2 ** 32;
533 for Char_Code_Base'Size use 32;
535 subtype Char_Code is Char_Code_Base range 0 .. 16#7FFF_FFFF#;
536 for Char_Code'Value_Size use 32;
537 for Char_Code'Object_Size use 32;
539 function Get_Char_Code (C : Character) return Char_Code;
540 pragma Inline (Get_Char_Code);
541 -- Function to obtain internal character code from source character. For
542 -- the moment, the internal character code is simply the Pos value of the
543 -- input source character, but we provide this interface for possible
544 -- later support of alternative character sets.
546 function In_Character_Range (C : Char_Code) return Boolean;
547 pragma Inline (In_Character_Range);
548 -- Determines if the given character code is in range of type Character,
549 -- and if so, returns True. If not, returns False.
551 function In_Wide_Character_Range (C : Char_Code) return Boolean;
552 pragma Inline (In_Wide_Character_Range);
553 -- Determines if the given character code is in range of the type
554 -- Wide_Character, and if so, returns True. If not, returns False.
556 function Get_Character (C : Char_Code) return Character;
557 pragma Inline (Get_Character);
558 -- For a character C that is in Character range (see above function), this
559 -- function returns the corresponding Character value. It is an error to
560 -- call Get_Character if C is not in C haracter range
562 function Get_Wide_Character (C : Char_Code) return Wide_Character;
563 -- For a character C that is in Wide_Character range (see above function),
564 -- this function returns the corresponding Wide_Character value. It is an
565 -- error to call Get_Wide_Character if C is not in Wide_Character range.
567 ---------------------------------------
568 -- Types used for Library Management --
569 ---------------------------------------
571 type Unit_Number_Type is new Int;
572 -- Unit number. The main source is unit 0, and subsidiary sources have
573 -- non-zero numbers starting with 1. Unit numbers are used to index the
574 -- file table in Lib.
576 Main_Unit : constant Unit_Number_Type := 0;
577 -- Unit number value for main unit
579 No_Unit : constant Unit_Number_Type := -1;
580 -- Special value used to signal no unit
582 type Source_File_Index is new Int range -1 .. Int'Last;
583 -- Type used to index the source file table (see package Sinput)
585 Internal_Source_File : constant Source_File_Index :=
586 Source_File_Index'First;
587 -- Value used to indicate the buffer for the source-code-like strings
588 -- internally created withing the compiler (see package Sinput)
590 No_Source_File : constant Source_File_Index := 0;
591 -- Value used to indicate no source file present
593 subtype File_Name_Type is Name_Id;
594 -- File names are stored in the names table and this synonym is used to
595 -- indicate that a Name_Id value is being used to hold a simple file
596 -- name (which does not include any directory information).
598 No_File : constant File_Name_Type := File_Name_Type (No_Name);
599 -- Constant used to indicate no file found
601 subtype Unit_Name_Type is Name_Id;
602 -- Unit names are stored in the names table and this synonym is used to
603 -- indicate that a Name_Id value is being used to hold a unit name.
605 -----------------------------------
606 -- Representation of Time Stamps --
607 -----------------------------------
609 -- All compiled units are marked with a time stamp which is derived from
610 -- the source file (we assume that the host system has the concept of a
611 -- file time stamp which is modified when a file is modified). These
612 -- time stamps are used to ensure consistency of the set of units that
613 -- constitutes a library. Time stamps are 12 character strings with
614 -- with the following format:
616 -- YYYYMMDDHHMMSS
618 -- YYYY year
619 -- MM month (2 digits 01-12)
620 -- DD day (2 digits 01-31)
621 -- HH hour (2 digits 00-23)
622 -- MM minutes (2 digits 00-59)
623 -- SS seconds (2 digits 00-59)
625 -- In the case of Unix systems (and other systems which keep the time in
626 -- GMT), the time stamp is the GMT time of the file, not the local time.
627 -- This solves problems in using libraries across networks with clients
628 -- spread across multiple time-zones.
630 Time_Stamp_Length : constant := 14;
631 -- Length of time stamp value
633 subtype Time_Stamp_Index is Natural range 1 .. Time_Stamp_Length;
634 type Time_Stamp_Type is new String (Time_Stamp_Index);
635 -- Type used to represent time stamp
637 Empty_Time_Stamp : constant Time_Stamp_Type := (others => ' ');
638 -- Type used to represent an empty or missing time stamp. Looks less
639 -- than any real time stamp if two time stamps are compared. Note that
640 -- although this is not a private type, clients should not rely on the
641 -- exact way in which this string is represented, and instead should
642 -- use the subprograms below.
644 Dummy_Time_Stamp : constant Time_Stamp_Type := (others => '0');
645 -- This is used for dummy time stamp values used in the D lines for
646 -- non-existant files, and is intended to be an impossible value.
648 function "=" (Left, Right : Time_Stamp_Type) return Boolean;
649 function "<=" (Left, Right : Time_Stamp_Type) return Boolean;
650 function ">=" (Left, Right : Time_Stamp_Type) return Boolean;
651 function "<" (Left, Right : Time_Stamp_Type) return Boolean;
652 function ">" (Left, Right : Time_Stamp_Type) return Boolean;
653 -- Comparison functions on time stamps. Note that two time stamps
654 -- are defined as being equal if they have the same day/month/year
655 -- and the hour/minutes/seconds values are within 2 seconds of one
656 -- another. This deals with rounding effects in library file time
657 -- stamps caused by copying operations during installation. We have
658 -- particularly noticed that WinNT seems susceptible to such changes.
659 -- Note: the Empty_Time_Stamp value looks equal to itself, and less
660 -- than any non-empty time stamp value.
662 procedure Split_Time_Stamp
663 (TS : Time_Stamp_Type;
664 Year : out Nat;
665 Month : out Nat;
666 Day : out Nat;
667 Hour : out Nat;
668 Minutes : out Nat;
669 Seconds : out Nat);
670 -- Given a time stamp, decompose it into its components
672 procedure Make_Time_Stamp
673 (Year : Nat;
674 Month : Nat;
675 Day : Nat;
676 Hour : Nat;
677 Minutes : Nat;
678 Seconds : Nat;
679 TS : out Time_Stamp_Type);
680 -- Given the components of a time stamp, initialize the value
682 -----------------------------------------------
683 -- Types used for Pragma Suppress Management --
684 -----------------------------------------------
686 type Check_Id is (
687 Access_Check,
688 Accessibility_Check,
689 Discriminant_Check,
690 Division_Check,
691 Elaboration_Check,
692 Index_Check,
693 Length_Check,
694 Overflow_Check,
695 Range_Check,
696 Storage_Check,
697 Tag_Check,
698 All_Checks);
700 -- The following array contains an entry for each recognized check name
701 -- for pragma Suppress. It is used to represent current settings of scope
702 -- based suppress actions from pragma Suppress or command line settings.
704 -- Note: when Suppress_Array (All_Checks) is True, then generally all other
705 -- specific check entries are set True, except for the Elaboration_Check
706 -- entry which is set only if an explicit Suppress for this check is given.
707 -- The reason for this non-uniformity is that we do not want All_Checks to
708 -- suppress elaboration checking when using the static elaboration model.
709 -- We recognize only an explicit suppress of Elaboration_Check as a signal
710 -- that the static elaboration checking should skip a compile time check.
712 type Suppress_Array is array (Check_Id) of Boolean;
713 pragma Pack (Suppress_Array);
715 -- To add a new check type to GNAT, the following steps are required:
717 -- 1. Add an entry to Snames spec and body for the new name
718 -- 2. Add an entry to the definition of Check_Id above
719 -- 3. Add a new function to Checks to handle the new check test
720 -- 4. Add a new Do_xxx_Check flag to Sinfo (if required)
721 -- 5. Add appropriate checks for the new test
723 -----------------------------------
724 -- Global Exception Declarations --
725 -----------------------------------
727 -- This section contains declarations of exceptions that are used
728 -- throughout the compiler or in other GNAT tools.
730 Unrecoverable_Error : exception;
731 -- This exception is raised to immediately terminate the compilation
732 -- of the current source program. Used in situations where things are
733 -- bad enough that it doesn't seem worth continuing (e.g. max errors
734 -- reached, or a required file is not found). Also raised when the
735 -- compiler finds itself in trouble after an error (see Comperr).
737 Terminate_Program : exception;
738 -- This exception is raised to immediately terminate the tool being
739 -- executed. Each tool where this exception may be raised must have
740 -- a single exception handler that contains only a null statement and
741 -- that is the last statement of the program. If needed, procedure
742 -- Set_Exit_Status is called with the appropriate exit status before
743 -- raising Terminate_Program.
745 ---------------------------------
746 -- Parameter Mechanism Control --
747 ---------------------------------
749 -- Function and parameter entities have a field that records the
750 -- passing mechanism. See specification of Sem_Mech for full details.
751 -- The following subtype is used to represent values of this type:
753 subtype Mechanism_Type is Int range -10 .. Int'Last;
754 -- Type used to represent a mechanism value. This is a subtype rather
755 -- than a type to avoid some annoying processing problems with certain
756 -- routines in Einfo (processing them to create the corresponding C).
758 ------------------------------
759 -- Run-Time Exception Codes --
760 ------------------------------
762 -- When the code generator generates a run-time exception, it provides
763 -- a reason code which is one of the following. This reason code is used
764 -- to select the appropriate run-time routine to be called, determining
765 -- both the exception to be raised, and the message text to be added.
767 -- The prefix CE/PE/SE indicates the exception to be raised
768 -- CE = Constraint_Error
769 -- PE = Program_Error
770 -- SE = Storage_Error
772 -- The remaining part of the name indicates the message text to be added,
773 -- where all letters are lower case, and underscores are converted to
774 -- spaces (for example CE_Invalid_Data adds the text "invalid data").
776 -- To add a new code, you need to do the following:
778 -- 1. Modify the type and subtype declarations below appropriately,
779 -- keeping things in alphabetical order.
781 -- 2. Modify the corresponding definitions in types.h, including
782 -- the definition of last_reason_code.
784 -- 3. Add a new routine in Ada.Exceptions with the appropriate call
785 -- and static string constant. Note that there is more than one
786 -- version of a-except.adb which must be modified.
788 type RT_Exception_Code is
789 (CE_Access_Check_Failed, -- 00
790 CE_Access_Parameter_Is_Null, -- 01
791 CE_Discriminant_Check_Failed, -- 02
792 CE_Divide_By_Zero, -- 03
793 CE_Explicit_Raise, -- 04
794 CE_Index_Check_Failed, -- 05
795 CE_Invalid_Data, -- 06
796 CE_Length_Check_Failed, -- 07
797 CE_Null_Exception_Id, -- 08
798 CE_Null_Not_Allowed, -- 09
799 CE_Overflow_Check_Failed, -- 10
800 CE_Partition_Check_Failed, -- 11
801 CE_Range_Check_Failed, -- 12
802 CE_Tag_Check_Failed, -- 13
804 PE_Access_Before_Elaboration, -- 14
805 PE_Accessibility_Check_Failed, -- 15
806 PE_All_Guards_Closed, -- 16
807 PE_Duplicated_Entry_Address, -- 17
808 PE_Explicit_Raise, -- 18
809 PE_Finalize_Raised_Exception, -- 19
810 PE_Implicit_Return, -- 20
811 PE_Misaligned_Address_Value, -- 21
812 PE_Missing_Return, -- 22
813 PE_Overlaid_Controlled_Object, -- 23
814 PE_Potentially_Blocking_Operation, -- 24
815 PE_Stubbed_Subprogram_Called, -- 25
816 PE_Unchecked_Union_Restriction, -- 26
817 PE_Illegal_RACW_E_4_18, -- 27
819 SE_Empty_Storage_Pool, -- 28
820 SE_Explicit_Raise, -- 29
821 SE_Infinite_Recursion, -- 30
822 SE_Object_Too_Large, -- 31
823 SE_Restriction_Violation); -- 32
825 subtype RT_CE_Exceptions is RT_Exception_Code range
826 CE_Access_Check_Failed ..
827 CE_Tag_Check_Failed;
829 subtype RT_PE_Exceptions is RT_Exception_Code range
830 PE_Access_Before_Elaboration ..
831 PE_Illegal_RACW_E_4_18;
833 subtype RT_SE_Exceptions is RT_Exception_Code range
834 SE_Empty_Storage_Pool ..
835 SE_Restriction_Violation;
837 end Types;