* toplev.h (floor_log2): If GCC_VERSION >= 3004, declare as static
[official-gcc.git] / gcc / ada / targparm.ads
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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT RUN-TIME COMPONENTS --
4 -- --
5 -- T A R G P A R M --
6 -- --
7 -- S p e c --
8 -- --
9 -- Copyright (C) 1999-2009, 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. --
17 -- --
18 -- As a special exception under Section 7 of GPL version 3, you are granted --
19 -- additional permissions described in the GCC Runtime Library Exception, --
20 -- version 3.1, as published by the Free Software Foundation. --
21 -- --
22 -- You should have received a copy of the GNU General Public License and --
23 -- a copy of the GCC Runtime Library Exception along with this program; --
24 -- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see --
25 -- <http://www.gnu.org/licenses/>. --
26 -- --
27 -- GNAT was originally developed by the GNAT team at New York University. --
28 -- Extensive contributions were provided by Ada Core Technologies Inc. --
29 -- --
30 ------------------------------------------------------------------------------
32 -- This package obtains parameters from the target runtime version of System,
33 -- to indicate parameters relevant to the target environment.
35 -- Is it right for this to be modified GPL???
37 -- Conceptually, these parameters could be obtained using rtsfind, but
38 -- we do not do this for four reasons:
40 -- 1. Compiling System for every compilation wastes time
42 -- 2. This compilation impedes debugging by adding extra compile steps
44 -- 3. There are recursion problems coming from compiling System itself
45 -- or any of its children.
47 -- 4. The binder also needs the parameters, and we do not want to have
48 -- to drag a lot of front end stuff into the binder.
50 -- For all these reasons, we read in the source of System, and then scan
51 -- it at the text level to extract the parameter values.
53 -- Note however, that later on, when the ali file is written, we make sure
54 -- that the System file is at least parsed, so that the checksum is properly
55 -- computed and set in the ali file. This partially negates points 1 and 2
56 -- above although just parsing is quick and does not impact debugging much.
58 -- The parameters acquired by this routine from system.ads fall into four
59 -- categories:
61 -- 1. Configuration pragmas, that must appear at the start of the file.
62 -- Any such pragmas automatically apply to any unit compiled in the
63 -- presence of this system file. Only a limited set of such pragmas
64 -- may appear as documented in the corresponding section below,
66 -- 2. Target parameters. These are boolean constants that are defined
67 -- in the private part of the package giving fixed information
68 -- about the target architecture, and the capabilities of the
69 -- code generator and run-time library.
71 -- 3. Identification information. This is an optional string constant
72 -- that gives the name of the run-time library configuration. This
73 -- line may be omitted for a version of system.ads to be used with
74 -- the full Ada 95 run time.
76 -- 4. Other characteristics of package System. At the current time the
77 -- only item in this category is whether type Address is private.
79 with Rident; use Rident;
80 with Namet; use Namet;
81 with Types; use Types;
83 package Targparm is
85 ---------------------------
86 -- Configuration Pragmas --
87 ---------------------------
89 -- The following switches get set if the corresponding configuration
90 -- pragma is scanned from the source of system.ads. No other pragmas
91 -- are permitted to appear at the start of the system.ads source file.
93 -- If a pragma Discard_Names appears, then Opt.Global_Discard_Names is
94 -- set to True to indicate that all units must be compiled in this mode.
96 -- If a pragma Locking_Policy appears, then Opt.Locking_Policy is set
97 -- to the first character of the policy name, and Opt.Locking_Policy_Sloc
98 -- is set to System_Location.
100 -- If a pragma Normalize_Scalars appears, then Opt.Normalize_Scalars
101 -- is set True, as well as Opt.Init_Or_Norm_Scalars.
103 -- If a pragma Queuing_Policy appears, then Opt.Queuing_Policy is set
104 -- to the first character of the policy name, and Opt.Queuing_Policy_Sloc
105 -- is set to System_Location.
107 -- If a pragma Task_Dispatching_Policy appears, then the flag
108 -- Opt.Task_Dispatching_Policy is set to the first character of the
109 -- policy name, and Opt.Task_Dispatching_Policy_Sloc is set to
110 -- System_Location.
112 -- If a pragma Polling (On) appears, then the flag Opt.Polling_Required
113 -- is set to True.
115 -- If a pragma Detect_Blocking appears, then the flag Opt.Detect_Blocking
116 -- is set to True.
118 -- if a pragma Suppress_Exception_Locations appears, then the flag
119 -- Opt.Exception_Locations_Suppressed is set to True.
121 -- If a pragma Profile with a valid profile argument appears, then
122 -- the appropriate restrictions and policy flags are set.
124 -- The only other pragma allowed is a pragma Restrictions that specifies
125 -- a restriction that will be imposed on all units in the partition. Note
126 -- that in this context, only one restriction can be specified in a single
127 -- pragma, and the pragma must appear on its own on a single source line.
129 -- If package System contains exactly the line "type Address is private;"
130 -- then the flag Opt.Address_Is_Private is set True, otherwise this flag
131 -- is set False.
133 Restrictions_On_Target : Restrictions_Info := No_Restrictions;
134 -- Records restrictions specified by system.ads. Only the Set and Value
135 -- members are modified. The Violated and Count fields are never modified.
136 -- Note that entries can be set either by a pragma Restrictions or by
137 -- a pragma Profile.
139 -------------------
140 -- Run Time Name --
141 -------------------
143 -- This parameter should be regarded as read only by all clients of
144 -- of package. The only way they get modified is by calling the
145 -- Get_Target_Parameters routine which reads the values from a provided
146 -- text buffer containing the source of the system package.
148 -- The corresponding string constant is placed immediately at the start
149 -- of the private part of system.ads if is present, e.g. in the form:
151 -- Run_Time_Name : constant String := "Zero Footprint Run Time";
153 -- the corresponding messages will look something like
155 -- xxx not supported (Zero Footprint Run Time)
157 Run_Time_Name_On_Target : Name_Id := No_Name;
158 -- Set to appropriate names table entry Id value if a Run_Time_Name
159 -- string constant is defined in system.ads. This name is used only
160 -- for the configurable run-time case, and is used to parametrize
161 -- messages that complain about non-supported run-time features.
162 -- The name should contain only letters A-Z, digits 1-9, spaces,
163 -- and underscores.
165 --------------------------
166 -- Executable Extension --
167 --------------------------
169 Executable_Extension_On_Target : Name_Id := No_Name;
170 -- Executable extension on the target. This name is useful for setting
171 -- the executable extension in a dynamic way, e.g. depending on the
172 -- run time used, rather than using a configure-time macro as done by
173 -- Get_Target_Executable_Suffix. If not set (No_Name), instead use
174 -- System.OS_Lib.Get_Target_Executable_Suffix.
176 -----------------------
177 -- Target Parameters --
178 -----------------------
180 -- The following parameters correspond to the variables defined in the
181 -- private part of System (without the terminating _On_Target). Note
182 -- that it is required that all parameters defined here be specified
183 -- in the target specific version of system.ads. Thus, to add a new
184 -- parameter, add it to all system*.ads files. (There is a defaulting
185 -- mechanism, but we don't normally take advantage of it, as explained
186 -- below.)
188 -- The default values here are used if no value is found in system.ads.
189 -- This should normally happen if the special version of system.ads used
190 -- by the compiler itself is in use or if the value is only relevant to
191 -- a particular target (e.g. OpenVMS, AAMP). The default values are
192 -- suitable for use in normal environments. This approach allows the
193 -- possibility of new versions of the compiler (possibly with new system
194 -- parameters added) being used to compile older versions of the compiler
195 -- sources, as well as avoiding duplicating values in all system-*.ads
196 -- files for flags that are used on a few platforms only.
198 -- All these parameters should be regarded as read only by all clients
199 -- of the package. The only way they get modified is by calling the
200 -- Get_Target_Parameters routine which reads the values from a provided
201 -- text buffer containing the source of the system package.
203 ----------------------------
204 -- Special Target Control --
205 ----------------------------
207 -- The great majority of GNAT ports are based on GCC. The switches in
208 -- This section indicate the use of some non-standard target back end
209 -- or other special targetting requirements.
211 AAMP_On_Target : Boolean := False;
212 -- Set to True if target is AAMP
214 OpenVMS_On_Target : Boolean := False;
215 -- Set to True if target is OpenVMS
217 RTX_RTSS_Kernel_Module_On_Target : Boolean := False;
218 -- Set to True if target is RTSS module for RTX
220 type Virtual_Machine_Kind is (No_VM, JVM_Target, CLI_Target);
221 VM_Target : Virtual_Machine_Kind := No_VM;
222 -- Kind of virtual machine targetted
223 -- No_VM: no virtual machine, default case of a standard processor
224 -- JVM_Target: Java Virtual Machine
225 -- CLI_Target: CLI/.NET Virtual Machine
227 -------------------------------
228 -- Backend Arithmetic Checks --
229 -------------------------------
231 -- Divide and overflow checks are either done in the front end or
232 -- back end. The front end will generate checks when required unless
233 -- the corresponding parameter here is set to indicate that the back
234 -- end will generate the required checks (or that the checks are
235 -- automatically performed by the hardware in an appropriate form).
237 Backend_Divide_Checks_On_Target : Boolean := False;
238 -- Set True if the back end generates divide checks, or if the hardware
239 -- checks automatically. Set False if the front end must generate the
240 -- required tests using explicit expanded code.
242 Backend_Overflow_Checks_On_Target : Boolean := False;
243 -- Set True if the back end generates arithmetic overflow checks, or if
244 -- the hardware checks automatically. Set False if the front end must
245 -- generate the required tests using explicit expanded code.
247 -----------------------------------
248 -- Control of Exception Handling --
249 -----------------------------------
251 -- GNAT implements three methods of implementing exceptions:
253 -- Front-End Longjmp/Setjmp Exceptions
255 -- This approach uses longjmp/setjmp to handle exceptions. It
256 -- uses less storage, and can often propagate exceptions faster,
257 -- at the expense of (sometimes considerable) overhead in setting
258 -- up an exception handler. This approach is available on all
259 -- targets, and is the default where it is the only approach.
261 -- The generation of the setjmp and longjmp calls is handled by
262 -- the front end of the compiler (this includes gigi in the case
263 -- of the standard GCC back end). It does not use any back end
264 -- support (such as the GCC3 exception handling mechanism). When
265 -- this approach is used, the compiler generates special exception
266 -- handlers for handling cleanups when an exception is raised.
268 -- Front-End Zero Cost Exceptions
270 -- This approach uses separate exception tables. These use extra
271 -- storage, and exception propagation can be quite slow, but there
272 -- is no overhead in setting up an exception handler (it is to this
273 -- latter operation that the phrase zero-cost refers). This approach
274 -- is only available on some targets, and is the default where it is
275 -- available.
277 -- The generation of the exception tables is handled by the front
278 -- end of the compiler. It does not use any back end support (such
279 -- as the GCC3 exception handling mechanism). When this approach
280 -- is used, the compiler generates special exception handlers for
281 -- handling cleanups when an exception is raised.
283 -- Back-End Zero Cost Exceptions
285 -- With this approach, the back end handles the generation and
286 -- handling of exceptions. For example, the GCC3 exception handling
287 -- mechanisms are used in this mode. The front end simply generates
288 -- code for explicit exception handlers, and AT END cleanup handlers
289 -- are simply passed unchanged to the backend for generating cleanups
290 -- both in the exceptional and non-exceptional cases.
292 -- As the name implies, this approach generally uses a zero-cost
293 -- mechanism with tables, but the tables are generated by the back
294 -- end. However, since the back-end is entirely responsible for the
295 -- handling of exceptions, another mechanism might be used. In the
296 -- case of GCC3 for instance, it might be the case that the compiler
297 -- is configured for setjmp/longjmp handling, then everything will
298 -- work correctly. However, it is definitely preferred that the
299 -- back end provide zero cost exception handling.
301 -- Controlling the selection of methods
303 -- On most implementations, back-end zero-cost exceptions are used.
304 -- Otherwise, Front-End Longjmp/Setjmp approach is used.
305 -- Note that there is a requirement that all Ada units in a partition
306 -- be compiled with the same exception model.
308 -- Control of Available Methods and Defaults
310 -- The following switches specify whether ZCX is available, and
311 -- whether it is enabled by default.
313 ZCX_By_Default_On_Target : Boolean := False;
314 -- Indicates if zero cost exceptions are active by default. If this
315 -- variable is False, then the only possible exception method is the
316 -- front-end setjmp/longjmp approach, and this is the default. If
317 -- this variable is True, then GCC ZCX is used.
319 GCC_ZCX_Support_On_Target : Boolean := False;
320 -- Indicates that the target supports GCC Exceptions
322 ------------------------------------
323 -- Run-Time Library Configuration --
324 ------------------------------------
326 -- In configurable run-time mode, the system run-time may not support
327 -- the full Ada language. The effect of setting this switch is to let
328 -- the compiler know that it is not surprising (i.e. the system is not
329 -- misconfigured) if run-time library units or entities within units are
330 -- not present in the run-time.
332 Configurable_Run_Time_On_Target : Boolean := False;
333 -- Indicates that the system.ads file is for a configurable run-time
335 -- This has some specific effects as follows
337 -- The binder generates the gnat_argc/argv/envp variables in the
338 -- binder file instead of being imported from the run-time library.
339 -- If Command_Line_Args_On_Target is set to False, then the
340 -- generation of these variables is suppressed completely.
342 -- The binder generates the gnat_exit_status variable in the binder
343 -- file instead of being imported from the run-time library. If
344 -- Exit_Status_Supported_On_Target is set to False, then the
345 -- generation of this variable is suppressed entirely.
347 -- The routine __gnat_break_start is defined within the binder file
348 -- instead of being imported from the run-time library.
350 -- The variable __gnat_exit_status is generated within the binder file
351 -- instead of being imported from the run-time library.
353 Suppress_Standard_Library_On_Target : Boolean := False;
354 -- If this flag is True, then the standard library is not included by
355 -- default in the executable (see unit System.Standard_Library in file
356 -- s-stalib.ads for details of what this includes). This is for example
357 -- set True for the zero foot print case, where these files should not
358 -- be included by default.
360 -- This flag has some other related effects:
362 -- The generation of global variables in the bind file is suppressed,
363 -- with the exception of the priority of the environment task, which
364 -- is needed by the Ravenscar run-time.
366 -- The calls to __gnat_initialize and __gnat_finalize are omitted
368 -- All finalization and initialization (controlled types) is omitted
370 -- The routine __gnat_handler_installed is not imported
372 Preallocated_Stacks_On_Target : Boolean := False;
373 -- If this flag is True, then the expander preallocates all task stacks
374 -- at compile time. If the flag is False, then task stacks are not pre-
375 -- allocated, and task stack allocation is the responsibility of the
376 -- run-time (which typically delegates the task to the underlying
377 -- operating system environment).
379 ---------------------
380 -- Duration Format --
381 ---------------------
383 -- By default, type Duration is a 64-bit fixed-point type with a delta
384 -- and small of 10**(-9) (i.e. it is a count in nanoseconds. This flag
385 -- allows that standard format to be modified.
387 Duration_32_Bits_On_Target : Boolean := False;
388 -- If True, then Duration is represented in 32 bits and the delta and
389 -- small values are set to 20.0*(10**(-3)) (i.e. it is a count in units
390 -- of 20 milliseconds.
392 ------------------------------------
393 -- Back-End Code Generation Flags --
394 ------------------------------------
396 -- These flags indicate possible limitations in what the code generator
397 -- can handle. They will all be True for a full run-time, but one or more
398 -- of these may be false for a configurable run-time, and if a feature is
399 -- used at the source level, and the corresponding flag is false, then an
400 -- error message will be issued saying the feature is not supported.
402 Support_64_Bit_Divides_On_Target : Boolean := True;
403 -- If True, the back end supports 64-bit divide operations. If False, then
404 -- the source program may not contain 64-bit divide operations. This is
405 -- specifically useful in the zero foot-print case, where the issue is
406 -- whether there is a hardware divide instruction for 64-bits so that
407 -- no run-time support is required. It should always be set True if the
408 -- necessary run-time support is present.
410 Support_Aggregates_On_Target : Boolean := True;
411 -- In the general case, the use of aggregates may generate calls
412 -- to run-time routines in the C library, including memset, memcpy,
413 -- memmove, and bcopy. This flag is set to True if these routines
414 -- are available. If any of these routines is not available, then
415 -- this flag is False, and the use of aggregates is not permitted.
417 Support_Composite_Assign_On_Target : Boolean := True;
418 -- The assignment of composite objects other than small records and
419 -- arrays whose size is 64-bits or less and is set by an explicit
420 -- size clause may generate calls to memcpy, memmove, and bcopy.
421 -- If versions of all these routines are available, then this flag
422 -- is set to True. If any of these routines is not available, then
423 -- the flag is set False, and composite assignments are not allowed.
425 Support_Composite_Compare_On_Target : Boolean := True;
426 -- If this flag is True, then the back end supports bit-wise comparison
427 -- of composite objects for equality, either generating inline code or
428 -- calling appropriate (and available) run-time routines. If this flag
429 -- is False, then the back end does not provide this support, and the
430 -- front end uses component by component comparison for composites.
432 Support_Long_Shifts_On_Target : Boolean := True;
433 -- If True, the back end supports 64-bit shift operations. If False, then
434 -- the source program may not contain explicit 64-bit shifts. In addition,
435 -- the code generated for packed arrays will avoid the use of long shifts.
437 --------------------
438 -- Indirect Calls --
439 --------------------
441 Always_Compatible_Rep_On_Target : Boolean := True;
442 -- If True, the Can_Use_Internal_Rep flag (see Einfo) is set to False in
443 -- all cases. This corresponds to the traditional code generation
444 -- strategy. False allows the front end to choose a policy that partly or
445 -- entirely eliminates dynamically generated trampolines.
447 -------------------------------
448 -- Control of Stack Checking --
449 -------------------------------
451 -- GNAT provides three methods of implementing exceptions:
453 -- GCC Probing Mechanism
455 -- This approach uses the standard GCC mechanism for
456 -- stack checking. The method assumes that accessing
457 -- storage immediately beyond the end of the stack
458 -- will result in a trap that is converted to a storage
459 -- error by the runtime system. This mechanism has
460 -- minimal overhead, but requires complex hardware,
461 -- operating system and run-time support. Probing is
462 -- the default method where it is available. The stack
463 -- size for the environment task depends on the operating
464 -- system and cannot be set in a system-independent way.
466 -- GCC Stack-limit Mechanism
468 -- This approach uses the GCC stack limits mechanism.
469 -- It relies on comparing the stack pointer with the
470 -- values of a global symbol. If the check fails, a
471 -- trap is explicitly generated. The advantage is
472 -- that the mechanism requires no memory protection,
473 -- but operating system and run-time support are
474 -- needed to manage the per-task values of the symbol.
475 -- This is the default method after probing where it
476 -- is available.
478 -- GNAT Stack-limit Checking
480 -- This method relies on comparing the stack pointer
481 -- with per-task stack limits. If the check fails, an
482 -- exception is explicitly raised. The advantage is
483 -- that the method requires no extra system dependent
484 -- runtime support and can be used on systems without
485 -- memory protection as well, but at the cost of more
486 -- overhead for doing the check. This is the fallback
487 -- method if the above two are not supported.
489 Stack_Check_Probes_On_Target : Boolean := False;
490 -- Indicates if the GCC probing mechanism is used
492 Stack_Check_Limits_On_Target : Boolean := False;
493 -- Indicates if the GCC stack-limit mechanism is used
495 -- Both flags cannot be simultaneously set to True. If neither
496 -- is, the target independent fallback method is used.
498 Stack_Check_Default_On_Target : Boolean := False;
499 -- Indicates if stack checking is on by default
501 ----------------------------
502 -- Command Line Arguments --
503 ----------------------------
505 -- For most ports of GNAT, command line arguments are supported. The
506 -- following flag is set to False for targets that do not support
507 -- command line arguments (VxWorks and AAMP). Note that support of
508 -- command line arguments is not required on such targets (RM A.15(13)).
510 Command_Line_Args_On_Target : Boolean := True;
511 -- Set False if no command line arguments on target. Note that if this
512 -- is False in with Configurable_Run_Time_On_Target set to True, then
513 -- this causes suppression of generation of the argv/argc variables
514 -- used to record command line arguments.
516 -- Similarly, most ports support the use of an exit status, but AAMP
517 -- is an exception (as allowed by RM A.15(18-20))
519 Exit_Status_Supported_On_Target : Boolean := True;
520 -- Set False if returning of an exit status is not supported on target.
521 -- Note that if this False in with Configurable_Run_Time_On_Target
522 -- set to True, then this causes suppression of the gnat_exit_status
523 -- variable used to record the exit status.
525 -----------------------
526 -- Main Program Name --
527 -----------------------
529 -- When the binder generates the main program to be used to create the
530 -- executable, the main program name is main by default (to match the
531 -- usual Unix practice). If this parameter is set to True, then the
532 -- name is instead by default taken from the actual Ada main program
533 -- name (just the name of the child if the main program is a child unit).
534 -- In either case, this value can be overridden using -M name.
536 Use_Ada_Main_Program_Name_On_Target : Boolean := False;
537 -- Set True to use the Ada main program name as the main name
539 ----------------------------------------------
540 -- Boolean-Valued Floating-Point Attributes --
541 ----------------------------------------------
543 -- The constants below give the values for representation oriented
544 -- floating-point attributes that are the same for all float types
545 -- on the target. These are all boolean values.
547 -- A value is only True if the target reliably supports the corresponding
548 -- feature. Reliably here means that support is guaranteed for all
549 -- possible settings of the relevant compiler switches (like -mieee),
550 -- since we cannot control the user setting of those switches.
552 -- The attributes cannot dependent on the current setting of compiler
553 -- switches, since the values must be static and consistent throughout
554 -- the partition. We probably should add such consistency checks in future,
555 -- but for now we don't do this.
557 -- Note: the compiler itself does not use floating-point, so the
558 -- settings of the defaults here are not really relevant.
560 -- Note: in some cases, proper support of some of these floating point
561 -- features may require a specific switch (e.g. -mieee on the Alpha)
562 -- to be used to obtain full RM compliant support.
564 Denorm_On_Target : Boolean := False;
565 -- Set to False on targets that do not reliably support denormals
567 Machine_Rounds_On_Target : Boolean := True;
568 -- Set to False for targets where S'Machine_Rounds is False
570 Machine_Overflows_On_Target : Boolean := False;
571 -- Set to True for targets where S'Machine_Overflows is True
573 Signed_Zeros_On_Target : Boolean := True;
574 -- Set to False on targets that do not reliably support signed zeros
576 -------------------------------------------
577 -- Boolean-Valued Fixed-Point Attributes --
578 -------------------------------------------
580 Fractional_Fixed_Ops_On_Target : Boolean := False;
581 -- Set to True for targets that support fixed-by-fixed multiplication
582 -- and division for fixed-point types with a small value equal to
583 -- 2 ** (-(T'Object_Size - 1)) and whose values have an absolute
584 -- value less than 1.0.
586 -----------------
587 -- Data Layout --
588 -----------------
590 -- Normally when using the GCC backend, Gigi and GCC perform much of the
591 -- data layout using the standard layout capabilities of GCC. If the
592 -- parameter Backend_Layout is set to False, then the front end must
593 -- perform all data layout. For further details see the package Layout.
595 Frontend_Layout_On_Target : Boolean := False;
596 -- Set True if front end does layout
598 -----------------
599 -- Subprograms --
600 -----------------
602 -- These subprograms are used to initialize the target parameter values
603 -- from the system.ads file. Note that this is only done once, so if more
604 -- than one call is made to either routine, the second and subsequent
605 -- calls are ignored.
607 procedure Get_Target_Parameters
608 (System_Text : Source_Buffer_Ptr;
609 Source_First : Source_Ptr;
610 Source_Last : Source_Ptr);
611 -- Called at the start of execution to obtain target parameters from
612 -- the source of package System. The parameters provide the source
613 -- text to be scanned (in System_Text (Source_First .. Source_Last)).
615 procedure Get_Target_Parameters;
616 -- This version reads in system.ads using Osint. The idea is that the
617 -- caller uses the first version if they have to read system.ads anyway
618 -- (e.g. the compiler) and uses this simpler interface if system.ads is
619 -- not otherwise needed.
621 end Targparm;