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>Values and Expressions</TITLE
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><TH
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COLSPAN="3"
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ALIGN="center"
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>The <SPAN
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CLASS="APPLICATION"
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>eCos</SPAN
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> Component Writer's Guide</TH
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></TR
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><TR
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><TD
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WIDTH="10%"
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ALIGN="left"
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VALIGN="bottom"
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><A
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HREF="language.tcl.html"
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ACCESSKEY="P"
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>Prev</A
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></TD
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><TD
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WIDTH="80%"
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ALIGN="center"
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VALIGN="bottom"
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>Chapter 3. The CDL Language</TD
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><TD
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WIDTH="10%"
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ALIGN="right"
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VALIGN="bottom"
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><A
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HREF="language.interface.html"
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>Next</A
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></TD
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></TR
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></TABLE
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><HR
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ALIGN="LEFT"
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WIDTH="100%"></DIV
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><DIV
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CLASS="SECT1"
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><H1
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CLASS="SECT1"
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><A
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NAME="LANGUAGE.VALUES">Values and Expressions</H1
89
><P
90
>It is fairly reasonable to expect that enabling or disabling a
91
configuration option such as
92
<TT
93
CLASS="VARNAME"
94
>CYGVAR_KERNEL_THREADS_DATA</TT
95
> in some way affects its
96
<SPAN
97
CLASS="emphasis"
98
><I
99
CLASS="EMPHASIS"
100
>value</I
101
></SPAN
102
>. This will have an effect on any
103
expressions that reference this option such as
104
<TT
105
CLASS="LITERAL"
106
>requires&nbsp;CYGVAR_KERNEL_THREADS_DATA</TT
107
>. It will
108
also affect the consequences of that option: how it affects the build
109
process and what happens to any constraints that
110
<TT
111
CLASS="VARNAME"
112
>CYGVAR_KERNEL_THREADS_DATA</TT
113
> may impose (as opposed
114
to constraints on this option imposed by others).</P
115
><P
116
>In a language like C the handling of variables is relatively
117
straightforward. If a variable <TT
118
CLASS="VARNAME"
119
>x</TT
120
> gets referenced in
121
an expression such as <TT
122
CLASS="LITERAL"
123
>if&nbsp;(x&nbsp;!=&nbsp;0)</TT
124
>,
125
and that variable is not defined anywhere, then the code will fail to
126
build, typically with an unresolved error at link-time. Also in C
127
a variable <TT
128
CLASS="VARNAME"
129
>x</TT
130
> does not live in any hierarchy, so its
131
value for the purposes of expression evaluation is not affected by
132
anything else. C variables also have a clear type such as
133
<TT
134
CLASS="LITERAL"
135
>int</TT
136
> or <TT
137
CLASS="LITERAL"
138
>long&nbsp;double</TT
139
>. </P
140
><P
141
>In <SPAN
142
CLASS="APPLICATION"
143
>CDL</SPAN
144
> things are not so straightforward.</P
145
><DIV
146
CLASS="SECT2"
147
><H2
148
CLASS="SECT2"
149
><A
150
NAME="LANGUAGE.VALUES.VALUE">Option Values</H2
151
><P
152
>There are four factors which go into an option's value:</P
153
><P
154
></P
155
><OL
156
TYPE="1"
157
><LI
158
><P
159
>An option may or may not be loaded.</P
160
></LI
161
><LI
162
><P
163
>If the option is loaded, it may or may not be active.</P
164
></LI
165
><LI
166
><P
167
>Even if the option is active, it may or may not be enabled.</P
168
></LI
169
><LI
170
><P
171
>If the option is loaded, active and enabled then it will have some
172
associated data which constitutes its value.</P
173
></LI
174
></OL
175
><DIV
176
CLASS="SECT3"
177
><H3
178
CLASS="SECT3"
179
><A
180
NAME="LANGUAGE.VALUES.VALUE.LOADED">Is the Option Loaded?</H3
181
><P
182
>At any one time a configuration will contain only a subset of all
183
possible packages. In fact it is impossible to combine certain
184
packages in a single configuration. For example architectural HAL
185
packages should contain a set of options defining endianness, the
186
sizes of basic data types and so on (many of which will of course be
187
constant for any given architecture). Any attempt to load two
188
architectural HAL packages into a configuration will fail because of
189
the resulting name clash. Since <SPAN
190
CLASS="APPLICATION"
191
>CDL</SPAN
192
> expressions can reference
193
options in other packages, and often need to do so, it is essential to
194
define the resulting behavior.</P
195
><P
196
>One complication is that the component framework does not know about
197
every single option in every single package. Obviously it cannot know
198
about packages from arbitrary third parties which have not been
199
installed. Even for packages which have been installed, the current
200
repository database does not hold details of every option, only of the
201
packages themselves. If a <SPAN
202
CLASS="APPLICATION"
203
>CDL</SPAN
204
> expression contains a reference to
205
some option <TT
206
CLASS="VARNAME"
207
>CYGSEM_KERNEL_SCHED_TIMESLICE</TT
208
> then the
209
component framework will only know about this option if the kernel
210
package is actually loaded into the current configuration. If the
211
package is not loaded then theoretically the framework might guess
212
that the option is somehow related to the kernel by examining the
213
option name but this would not be robust: the option could easily be
214
part of some other package that violates the naming convention.</P
215
><P
216
>Assume that the user is building a minimal configuration which does
217
not contain the kernel package, but does have other packages which
218
contain the following constraints:</P
219
><TABLE
220
BORDER="5"
221
BGCOLOR="#E0E0F0"
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WIDTH="70%"
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><TR
224
><TD
225
><PRE
226
CLASS="PROGRAMLISTING"
227
>    requires CYGPKG_KERNEL
228
    requires CYGPKG_KERNEL_THREADS_DATA
229
    requires !CYGSEM_KERNEL_SCHED_TIMESLICE</PRE
230
></TD
231
></TR
232
></TABLE
233
><P
234
>Clearly the first constraint is not satisfied because the kernel is
235
not loaded. The second constraint is also not satisfied. The third
236
constraint is trivially satisfied: if there is no kernel then the
237
kernel's timeslicing support cannot possibly be enabled. </P
238
><P
239
>Any options which are not in the current configuration are handled as
240
follows: </P
241
><P
242
></P
243
><OL
244
TYPE="1"
245
><LI
246
><P
247
>Any references to that option will evaluate to <TT
248
CLASS="LITERAL"
249
>0</TT
250
>,
251
so <TT
252
CLASS="LITERAL"
253
>requires&nbsp;!CYGSEM_KERNEL_SCHED_TIMESLICE</TT
254
> will
255
be satisfied but
256
<TT
257
CLASS="LITERAL"
258
>requires&nbsp;CYGSEM_KERNEL_THREADS_DATA</TT
259
> will not
260
be satisfied.</P
261
></LI
262
><LI
263
><P
264
>An option that is not loaded has no consequences on the build process.
265
It cannot directly result in any <TT
266
CLASS="LITERAL"
267
>#define's</TT
268
> in a
269
configuration header file, nor in any files being compiled. This is
270
only reasonable: if the option is not loaded then the component
271
framework has no way of knowing about any <SPAN
272
CLASS="PROPERTY"
273
>compile</SPAN
274
> or similar
275
properties. An option that is not loaded can have indirect
276
consequences by being referenced in <SPAN
277
CLASS="APPLICATION"
278
>CDL</SPAN
279
> expressions.</P
280
></LI
281
><LI
282
><P
283
>An option that is not loaded cannot impose any constraints on the rest
284
of the configuration. Again this is the only reasonable behavior: if
285
the option is not loaded then any associated <SPAN
286
CLASS="PROPERTY"
287
>requires</SPAN
288
> or
289
<SPAN
290
CLASS="PROPERTY"
291
>legal_values</SPAN
292
> properties will not be known.</P
293
></LI
294
></OL
295
></DIV
296
><DIV
297
CLASS="SECT3"
298
><H3
299
CLASS="SECT3"
300
><A
301
NAME="LANGUAGE.VALUES.VALUE.ACTIVE">Is the Option Active</H3
302
><P
303
>The next issue to consider is whether or not a particular option is
304
active. Configuration options are organized in a hierarchy of
305
components and sub-components. For example the C library package
306
contains a component <TT
307
CLASS="VARNAME"
308
>CYGPKG_LIBC_STDIO</TT
309
> containing
310
all the options related to standard I/O. If a user disables the
311
component as a whole then all the options below it become inactive: it
312
makes no sense to disable all stdio functionality and then manipulate
313
the buffer sizes.</P
314
><P
315
>Inactive is not quite the same as disabled, although the effects are
316
similar. The value of an inactive option is preserved. If the user
317
modifies a buffer size option, then disables the whole stdio
318
component, the buffer size value remains in case the stdio component
319
is re-enabled later on. Some tools such as the graphical configuration
320
tool will treat inactive options specially, for example such options
321
may be grayed out.</P
322
><P
323
>The active or inactive state of an option may affect other packages.
324
For example a package may use the <TT
325
CLASS="FUNCTION"
326
>sprintf</TT
327
>
328
function and require support for floating point conversions, a
329
constraint that is not satisfied if the relevant option is inactive.
330
It is necessary to define exactly what it means for an option to be
331
inactive:</P
332
><P
333
></P
334
><OL
335
TYPE="1"
336
><LI
337
><P
338
>An option is inactive if its parent is either inactive or disabled.
339
For example if <TT
340
CLASS="VARNAME"
341
>CYGPKG_LIBC_STDIO</TT
342
> is disabled then
343
all the options and sub-components become inactive; since
344
<TT
345
CLASS="VARNAME"
346
>CYGPKG_LIBC_STDIO_FLOATING_POINT</TT
347
> is now inactive,
348
<TT
349
CLASS="VARNAME"
350
>CYGSEM_LIBC_STDIO_PRINTF_FLOATING_POINT</TT
351
> is inactive
352
as well.</P
353
></LI
354
><LI
355
><P
356
>Options may also be inactive as a result of an <SPAN
357
CLASS="PROPERTY"
358
>active_if</SPAN
359
> property.
360
This is useful if a particular option is only relevant if two or more
361
disjoint sets of conditions need to be satisfied, since the
362
hierarchical structure can only cope with at most one such set.</P
363
></LI
364
><LI
365
><P
366
>If an option is inactive then any references to that option in <SPAN
367
CLASS="APPLICATION"
368
>CDL</SPAN
369
>
370
expressions will evaluate to <TT
371
CLASS="LITERAL"
372
>0</TT
373
>. Hence a constraint
374
of the form
375
<TT
376
CLASS="LITERAL"
377
>requires&nbsp;CYGSEM_LIBC_STDIO_PRINTF_FLOATING_POINT</TT
378
>
379
is not satisfied if the entire stdio component is disabled.</P
380
></LI
381
><LI
382
><P
383
>An option that is inactive has no consequences on the build process.
384
No <TT
385
CLASS="LITERAL"
386
>#define</TT
387
> will be generated. Any <SPAN
388
CLASS="PROPERTY"
389
>compile</SPAN
390
> or
391
similar properties will be ignored.</P
392
></LI
393
><LI
394
><P
395
>An option that is inactive cannot impose any constraints on the rest
396
of the configuration. For example
397
<TT
398
CLASS="VARNAME"
399
>CYGSEM_LIBC_STDIO_PRINTF_FLOATING_POINT</TT
400
> has a
401
dependency <TT
402
CLASS="LITERAL"
403
>requires&nbsp;CYGPKG_LIBM</TT
404
>, but if all of
405
the stdio functionality is disabled then this constraint is ignored
406
(although of course there may be other packages which have a
407
dependency on <TT
408
CLASS="VARNAME"
409
>CYGPKG_LIBM</TT
410
>.</P
411
></LI
412
></OL
413
></DIV
414
><DIV
415
CLASS="SECT3"
416
><H3
417
CLASS="SECT3"
418
><A
419
NAME="LANGUAGE.VALUES.VALUE.ENABLED">Is the Option Enabled? What is the Data?</H3
420
><P
421
>The majority of configuration options are boolean in nature, so the
422
user can either enable or disable some functionality. Some options are
423
different. For example <TT
424
CLASS="VARNAME"
425
>CYGNUM_LIBC_STDIO_BUFSIZE</TT
426
> is
427
a number, and <TT
428
CLASS="VARNAME"
429
>CYGDAT_LIBC_STDIO_DEFAULT_CONSOLE</TT
430
> is
431
a string corresponding to a device name. A few options like
432
<TT
433
CLASS="VARNAME"
434
>CYGDAT_UITRON_TASK_EXTERNS</TT
435
> can get very
436
complicated. <SPAN
437
CLASS="APPLICATION"
438
>CDL</SPAN
439
> has to cope with this variety, and define the exact
440
behavior of the system in terms of constraints and build-time
441
consequences. </P
442
><P
443
>In <SPAN
444
CLASS="APPLICATION"
445
>CDL</SPAN
446
> the value of an option consists of two parts. There is a
447
boolean part, controlling whether or not the option is enabled. There
448
is also a data part, providing additional information. For most
449
options one of these parts is fixed, as controlled by the option's
450
<SPAN
451
CLASS="PROPERTY"
452
>flavor</SPAN
453
> property:</P
454
><DIV
455
CLASS="INFORMALTABLE"
456
><A
457
NAME="AEN1413"><P
458
></P
459
><TABLE
460
BORDER="1"
461
CLASS="CALSTABLE"
462
><THEAD
463
><TR
464
><TH
465
ALIGN="LEFT"
466
VALIGN="TOP"
467
>Flavor</TH
468
><TH
469
ALIGN="LEFT"
470
VALIGN="TOP"
471
>Enabled</TH
472
><TH
473
ALIGN="LEFT"
474
VALIGN="TOP"
475
>Data</TH
476
></TR
477
></THEAD
478
><TBODY
479
><TR
480
><TD
481
ALIGN="LEFT"
482
VALIGN="TOP"
483
><TT
484
CLASS="LITERAL"
485
>none</TT
486
></TD
487
><TD
488
ALIGN="LEFT"
489
VALIGN="TOP"
490
>Always enabled</TD
491
><TD
492
ALIGN="LEFT"
493
VALIGN="TOP"
494
><TT
495
CLASS="LITERAL"
496
>1</TT
497
>, not modifiable</TD
498
></TR
499
><TR
500
><TD
501
ALIGN="LEFT"
502
VALIGN="TOP"
503
><TT
504
CLASS="LITERAL"
505
>bool</TT
506
></TD
507
><TD
508
ALIGN="LEFT"
509
VALIGN="TOP"
510
>User-modifiable</TD
511
><TD
512
ALIGN="LEFT"
513
VALIGN="TOP"
514
><TT
515
CLASS="LITERAL"
516
>1</TT
517
>, not modifiable</TD
518
></TR
519
><TR
520
><TD
521
ALIGN="LEFT"
522
VALIGN="TOP"
523
><TT
524
CLASS="LITERAL"
525
>data</TT
526
></TD
527
><TD
528
ALIGN="LEFT"
529
VALIGN="TOP"
530
>Always enabled</TD
531
><TD
532
ALIGN="LEFT"
533
VALIGN="TOP"
534
>User-modifiable</TD
535
></TR
536
><TR
537
><TD
538
ALIGN="LEFT"
539
VALIGN="TOP"
540
><TT
541
CLASS="LITERAL"
542
>booldata</TT
543
></TD
544
><TD
545
ALIGN="LEFT"
546
VALIGN="TOP"
547
>User-modifiable</TD
548
><TD
549
ALIGN="LEFT"
550
VALIGN="TOP"
551
>User-modifiable</TD
552
></TR
553
></TBODY
554
></TABLE
555
><P
556
></P
557
></DIV
558
><P
559
>The effects of the boolean and data parts are as follows:</P
560
><P
561
></P
562
><OL
563
TYPE="1"
564
><LI
565
><P
566
>If an option is disabled, in other words if the boolean part is false,
567
then any references to that option in <SPAN
568
CLASS="APPLICATION"
569
>CDL</SPAN
570
> expressions will evaluate
571
to <TT
572
CLASS="LITERAL"
573
>0</TT
574
>. This is the same behavior as for inactive
575
options. The data part is not relevant. The <TT
576
CLASS="LITERAL"
577
>none</TT
578
>
579
and <TT
580
CLASS="LITERAL"
581
>data</TT
582
> flavors specify that the option is always
583
enabled, in which case this rule is not applicable.</P
584
></LI
585
><LI
586
><P
587
>If an option is enabled then any references to that option in <SPAN
588
CLASS="APPLICATION"
589
>CDL</SPAN
590
>
591
expressions will evaluate to the option's data part. For two of the
592
flavors, <TT
593
CLASS="LITERAL"
594
>none</TT
595
> and <TT
596
CLASS="LITERAL"
597
>bool</TT
598
>, this
599
data part is fixed to the constant <TT
600
CLASS="LITERAL"
601
>1</TT
602
> which
603
generally has the expected result.</P
604
></LI
605
><LI
606
><P
607
>If a component or package is disabled then all sub-components and
608
options immediately below it in the hierarchy are inactive. By a
609
process of recursion this will affect all the nodes in the subtree.</P
610
></LI
611
><LI
612
><P
613
>If an option is disabled then it can impose no constraints on the rest
614
of the configuration, in particular <SPAN
615
CLASS="PROPERTY"
616
>requires</SPAN
617
> and <SPAN
618
CLASS="PROPERTY"
619
>legal_values</SPAN
620
>
621
properties will be ignored. If an option is enabled then its
622
constraints should be satisfied, or the component framework will
623
report various conflicts. Note that the <SPAN
624
CLASS="PROPERTY"
625
>legal_values</SPAN
626
> constraint only
627
applies to the data part of the option's value, so it is only useful
628
with the <TT
629
CLASS="LITERAL"
630
>data</TT
631
> and <TT
632
CLASS="LITERAL"
633
>booldata</TT
634
>
635
flavors. Options with the <TT
636
CLASS="LITERAL"
637
>none</TT
638
> and
639
<TT
640
CLASS="LITERAL"
641
>data</TT
642
> flavors are always enabled so their
643
constraints always have to be satisfied (assuming the option is
644
active). </P
645
></LI
646
><LI
647
><P
648
>If an option is disabled then it has no direct consequences at
649
build-time: no <TT
650
CLASS="LITERAL"
651
>#define</TT
652
> will be generated, no files
653
will get compiled, and so on. If an option is active and enabled then
654
all the consequences take effect. The option name and data part are
655
used to generate the <TT
656
CLASS="LITERAL"
657
>#define</TT
658
> in the appropriate
659
configuration header file, subject to various properties such as
660
<SPAN
661
CLASS="PROPERTY"
662
>no_define</SPAN
663
>, but the data part has no other effects on the build
664
system. </P
665
></LI
666
></OL
667
><P
668
>By default all options and components have the <TT
669
CLASS="LITERAL"
670
>bool</TT
671
>
672
flavor: most options are boolean in nature, so making this the default
673
allows for slightly more compact <SPAN
674
CLASS="APPLICATION"
675
>CDL</SPAN
676
> scripts. Packages have the
677
<TT
678
CLASS="LITERAL"
679
>booldata</TT
680
> flavor, where the data part always
681
corresponds to the version of the package that is loaded into the
682
configuration: changing this value corresponds to unloading the old
683
version and loading in a different one.</P
684
><DIV
685
CLASS="NOTE"
686
><BLOCKQUOTE
687
CLASS="NOTE"
688
><P
689
><B
690
><SPAN
691
CLASS="APPLICATION"
692
>CDL</SPAN
693
> Flavors: </B
694
>The concept of <SPAN
695
CLASS="APPLICATION"
696
>CDL</SPAN
697
> flavors tends to result in various discussions
698
about why it is unnecessarily complicated, and would it not have been
699
easier to do&nbsp;&#8230; However there are very good reasons why CDL
700
works the way it does.</P
701
><P
702
>The first common suggestion is that there is no need to have separate
703
flavors <TT
704
CLASS="LITERAL"
705
>bool</TT
706
>, <TT
707
CLASS="LITERAL"
708
>data</TT
709
>, and so on. A
710
boolean option could just be handled as a data option with legal
711
values <TT
712
CLASS="LITERAL"
713
>0</TT
714
> and <TT
715
CLASS="LITERAL"
716
>1</TT
717
>. The counter
718
arguments are as follows:</P
719
><P
720
></P
721
><OL
722
TYPE="1"
723
><LI
724
><P
725
>It would actually make <SPAN
726
CLASS="APPLICATION"
727
>CDL</SPAN
728
> scripts more verbose. By default all
729
options and components have the <TT
730
CLASS="LITERAL"
731
>bool</TT
732
> flavor, since
733
most options are boolean in nature. Without a <TT
734
CLASS="LITERAL"
735
>bool</TT
736
>
737
flavor it would be necessary to indicate explicitly what the legal
738
values are somehow, e.g. with a <SPAN
739
CLASS="PROPERTY"
740
>legal_values</SPAN
741
> property.</P
742
></LI
743
><LI
744
><P
745
>The boolean part of an option's value has a very different effect from
746
the data part. If an option is disabled then it has no consequences at
747
build time, and can impose no constraints. A <TT
748
CLASS="LITERAL"
749
>data</TT
750
>
751
option always has consequences and can impose constraints. To get the
752
desired effect it would be necessary to add <SPAN
753
CLASS="APPLICATION"
754
>CDL</SPAN
755
> data indicating that
756
a value of <TT
757
CLASS="LITERAL"
758
>0</TT
759
> should be treated specially. Arguably
760
this could be made built-in default behavior, although that would
761
complicate options where <TT
762
CLASS="LITERAL"
763
>0</TT
764
> is a perfectly legal
765
number, for example
766
<TT
767
CLASS="VARNAME"
768
>CYGNUM_LIBC_TIME_STD_DEFAULT_OFFSET</TT
769
>. </P
770
></LI
771
><LI
772
><P
773
>There would no replacement for a <TT
774
CLASS="LITERAL"
775
>booldata</TT
776
> option
777
for which <TT
778
CLASS="LITERAL"
779
>0</TT
780
> is a valid value. Again some additional
781
<SPAN
782
CLASS="APPLICATION"
783
>CDL</SPAN
784
> syntax would be needed to express such a concept.</P
785
></LI
786
></OL
787
><P
788
>Although initially it may seem confusing that an option's value has
789
both a boolean and a data part, it is an accurate reflection of how
790
configuration options actually work. The various alternatives would
791
all make it harder to write <SPAN
792
CLASS="APPLICATION"
793
>CDL</SPAN
794
> scripts.</P
795
><P
796
>The next common suggestion is that the data part of a value should be
797
typed in much the same way as C or C++ data types. For example it
798
should be possible to describe
799
<TT
800
CLASS="VARNAME"
801
>CYGNUM_LIBC_STDIO_BUFSIZE</TT
802
> as an integer value,
803
rather than imposing <SPAN
804
CLASS="PROPERTY"
805
>legal_values</SPAN
806
> constraints. Again there are very
807
good reasons why this approach was not taken:</P
808
><P
809
></P
810
><OL
811
TYPE="1"
812
><LI
813
><P
814
>The possible legal values for an integer are rarely correct for a
815
<SPAN
816
CLASS="APPLICATION"
817
>CDL</SPAN
818
> option. A constraint such as
819
<TT
820
CLASS="LITERAL"
821
>1&nbsp;to&nbsp;0x7fffffff</TT
822
> is a bit more accurate,
823
although if this option indicates a buffer size it is still not
824
particularly good&nbsp;&#8212; very few targets will have enough
825
memory for such a buffer. Forcing <SPAN
826
CLASS="APPLICATION"
827
>CDL</SPAN
828
> writers to list the
829
<SPAN
830
CLASS="PROPERTY"
831
>legal_values</SPAN
832
> constraints explicitly should make them think a bit
833
more about what values are actually sensible. For example
834
<TT
835
CLASS="VARNAME"
836
>CYGNUM_LIBC_TIME_DST_DEFAULT_OFFSET</TT
837
> has legal
838
values in the range <TT
839
CLASS="LITERAL"
840
>-90000&nbsp;to&nbsp;90000</TT
841
>,
842
which helps the user to set a sensible value.</P
843
></LI
844
><LI
845
><P
846
>Not all options correspond to simple data types such as integers.
847
<TT
848
CLASS="VARNAME"
849
>CYGDAT_LIBC_STDIO_DEFAULT_CONSOLE</TT
850
> is a C string,
851
and would have to be expressed using something like
852
<TT
853
CLASS="LITERAL"
854
>char&nbsp;[]</TT
855
>. This introduces plenty of
856
opportunities for confusion, especially since square brackets may get
857
processed by the <SPAN
858
CLASS="APPLICATION"
859
>Tcl</SPAN
860
> interpreter for command substitution.</P
861
></LI
862
><LI
863
><P
864
>Some configuration options can get very complicated indeed, for
865
example the default value of
866
<TT
867
CLASS="VARNAME"
868
>CYGDAT_UITRON_TASK_INITIALIZERS</TT
869
> is:</P
870
><TABLE
871
BORDER="5"
872
BGCOLOR="#E0E0F0"
873
WIDTH="70%"
874
><TR
875
><TD
876
><PRE
877
CLASS="PROGRAMLISTING"
878
>CYG_UIT_TASK( "t1", 1, task1, &amp;stack1, CYGNUM_UITRON_STACK_SIZE ), \
879
CYG_UIT_TASK( "t2", 2, task2, &amp;stack2, CYGNUM_UITRON_STACK_SIZE ), \
880
CYG_UIT_TASK( "t3", 3, task3, &amp;stack3, CYGNUM_UITRON_STACK_SIZE ), \
881
CYG_UIT_TASK( "t4", 4, task4, &amp;stack4, CYGNUM_UITRON_STACK_SIZE )</PRE
882
></TD
883
></TR
884
></TABLE
885
><P
886
>This would require <SPAN
887
CLASS="APPLICATION"
888
>CDL</SPAN
889
> knowing about C macros, structures, arrays,
890
static initializers, and so on. Adding such detailed knowledge about
891
the C language to the component framework is inappropriate.</P
892
></LI
893
><LI
894
><P
895
><SPAN
896
CLASS="APPLICATION"
897
>CDL</SPAN
898
> needs to be usable with languages other than C. At present this
899
includes C++, in future it may include languages such as Java. Each
900
language adds new data types and related complications, for example
901
C++ classes and inheritance. Making <SPAN
902
CLASS="APPLICATION"
903
>CDL</SPAN
904
> support a union of all data
905
types in all possible languages is not sensible.</P
906
></LI
907
></OL
908
><P
909
>The <SPAN
910
CLASS="APPLICATION"
911
>CDL</SPAN
912
> approach of treating all data as a sequence of characters,
913
possibly constrained by a <SPAN
914
CLASS="PROPERTY"
915
>legal_values</SPAN
916
> property or other means, has
917
the great advantage of simplicity. It also fits in with the <SPAN
918
CLASS="APPLICATION"
919
>Tcl</SPAN
920
>
921
language that underlies <SPAN
922
CLASS="APPLICATION"
923
>CDL</SPAN
924
>.</P
925
></BLOCKQUOTE
926
></DIV
927
></DIV
928
><DIV
929
CLASS="SECT3"
930
><H3
931
CLASS="SECT3"
932
><A
933
NAME="LANGUAGE.VALUES.VALUE.EXAMPLES">Some Examples</H3
934
><P
935
>The following excerpt from the C library's <SPAN
936
CLASS="APPLICATION"
937
>CDL</SPAN
938
> scripts can be used
939
to illustrate how values and flavors work in practice:</P
940
><TABLE
941
BORDER="5"
942
BGCOLOR="#E0E0F0"
943
WIDTH="70%"
944
><TR
945
><TD
946
><PRE
947
CLASS="PROGRAMLISTING"
948
>cdl_component CYGPKG_LIBC_RAND {
949
    flavor        none
950
    compile       stdlib/rand.cxx
951
 
952
    cdl_option CYGSEM_LIBC_PER_THREAD_RAND {
953
        requires      CYGVAR_KERNEL_THREADS_DATA
954
        default_value 0
955
    }
956
 
957
    cdl_option CYGNUM_LIBC_RAND_SEED {
958
        flavor        data
959
        legal_values  0 to 0x7fffffff
960
        default_value 1
961
    }
962
 
963
    cdl_option CYGNUM_LIBC_RAND_TRACE_LEVEL {
964
        flavor        data
965
        legal_values  0 to 1
966
        default_value 0
967
    }
968
}</PRE
969
></TD
970
></TR
971
></TABLE
972
><P
973
>If the application does not require any C library functionality then
974
it is possible to have a configuration where the C library is not
975
loaded. This can be achieved by starting with the minimal template, or
976
by starting with another template such as the default one and then
977
explicitly unloading the C library package. If this package is not
978
loaded then any references to the <TT
979
CLASS="VARNAME"
980
>CYGPKG_LIBC_RAND</TT
981
>
982
component or any of its options will have a value of
983
<TT
984
CLASS="LITERAL"
985
>0</TT
986
> for the purposes of expression evaluation. No
987
<TT
988
CLASS="LITERAL"
989
>#define's</TT
990
> will be generated for the component or
991
any of its options, and the file <TT
992
CLASS="FILENAME"
993
>stdlib/rand.cxx</TT
994
>
995
will not get compiled. There is nothing special about the C library
996
here, exactly the same would apply for say a device driver that does
997
not correspond to any of the devices on the target hardware.</P
998
><P
999
>Assuming the C library is loaded, the next thing to consider is
1000
whether or not the component and its options are active. The component
1001
is layered immediately below the C library package itself, so if the
1002
package is loaded then it is safe to assume that the package is also
1003
enabled. Therefore the parent of <TT
1004
CLASS="VARNAME"
1005
>CYGPKG_LIBC_RAND</TT
1006
>
1007
is active and enabled, and in the absence of any <SPAN
1008
CLASS="PROPERTY"
1009
>active_if</SPAN
1010
>
1011
properties <TT
1012
CLASS="VARNAME"
1013
>CYGPKG_LIBC_RAND</TT
1014
> will be active as well.</P
1015
><P
1016
>The component <TT
1017
CLASS="VARNAME"
1018
>CYGPKG_LIBC_RAND</TT
1019
> has the flavor
1020
<TT
1021
CLASS="LITERAL"
1022
>none</TT
1023
>. This means the component cannot be disabled.
1024
Therefore all the options in this component have an active and enabled
1025
parent, and in the absence of any <SPAN
1026
CLASS="PROPERTY"
1027
>active_if</SPAN
1028
> properties they are all
1029
active as well.</P
1030
><P
1031
>The component's flavor <TT
1032
CLASS="LITERAL"
1033
>none</TT
1034
> serves to group
1035
together all of the configuration options related to random number
1036
generation. This is particularly useful in the context of the
1037
graphical configuration tool, but it also helps when it comes to
1038
naming the options: all of the options begin with
1039
<TT
1040
CLASS="LITERAL"
1041
>CYGxxx_LIBC_RAND</TT
1042
>, giving a clear hint about both
1043
the package and the component within that package. The flavor means
1044
that the component is always enabled and has the value
1045
<TT
1046
CLASS="LITERAL"
1047
>1</TT
1048
> for the purposes of expression evaluation. There
1049
will always be a single <TT
1050
CLASS="LITERAL"
1051
>#define</TT
1052
> of the form:</P
1053
><TABLE
1054
BORDER="5"
1055
BGCOLOR="#E0E0F0"
1056
WIDTH="70%"
1057
><TR
1058
><TD
1059
><PRE
1060
CLASS="PROGRAMLISTING"
1061
>#define CYGPKG_LIBC_RAND 1</PRE
1062
></TD
1063
></TR
1064
></TABLE
1065
><P
1066
>In addition the file <TT
1067
CLASS="FILENAME"
1068
>stdlib/rand.cxx</TT
1069
> will always
1070
get built. If the component had the default <TT
1071
CLASS="LITERAL"
1072
>bool</TT
1073
>
1074
flavor then users would be able to disable the whole component,
1075
and one less file would need to be built. However random number
1076
generation is relatively simple, so the impact on eCos build times are
1077
small. Furthermore by default the code has no dependencies on other
1078
parts of the system, so compiling the code has no unexpected side
1079
effects. Even if it was possible to disable the component, the
1080
sensible default for most applications would still leave it enabled.
1081
The net result is that the flavor <TT
1082
CLASS="LITERAL"
1083
>none</TT
1084
> is probably
1085
the most sensible one for this component. For other components the
1086
default <TT
1087
CLASS="LITERAL"
1088
>bool</TT
1089
> flavor or one of the other flavors
1090
might be more appropriate.</P
1091
><P
1092
>Next consider option <TT
1093
CLASS="VARNAME"
1094
>CYGSEM_LIBC_PER_THREAD_RAND</TT
1095
>
1096
which can be used to get a per-thread random number seed, possibly
1097
useful if the application needs a consistent sequence of random
1098
numbers. In the absence of a <SPAN
1099
CLASS="PROPERTY"
1100
>flavor</SPAN
1101
> property this option will be
1102
boolean, and the <SPAN
1103
CLASS="PROPERTY"
1104
>default_value</SPAN
1105
> property means that it is disabled by
1106
default&nbsp;&#8212; reasonable since few applications need this
1107
particular functionality, and it does impose a constraint on the rest
1108
of the system. If the option is left disabled then no
1109
<TT
1110
CLASS="LITERAL"
1111
>#define</TT
1112
> will be generated, and if there were any
1113
<SPAN
1114
CLASS="PROPERTY"
1115
>compile</SPAN
1116
> or similar properties these would not take effect. If the
1117
option is enabled then a <TT
1118
CLASS="LITERAL"
1119
>#define</TT
1120
> will be generated,
1121
using the option's data part which is fixed at <TT
1122
CLASS="LITERAL"
1123
>1</TT
1124
>:</P
1125
><TABLE
1126
BORDER="5"
1127
BGCOLOR="#E0E0F0"
1128
WIDTH="70%"
1129
><TR
1130
><TD
1131
><PRE
1132
CLASS="PROGRAMLISTING"
1133
>#define CYGSEM_LIBC_PER_THREAD_RAND 1</PRE
1134
></TD
1135
></TR
1136
></TABLE
1137
><P
1138
>The <TT
1139
CLASS="VARNAME"
1140
>CYGSEM_LIBC_PER_THREAD_RAND</TT
1141
> option has a
1142
<SPAN
1143
CLASS="PROPERTY"
1144
>requires</SPAN
1145
> constraint on
1146
<TT
1147
CLASS="VARNAME"
1148
>CYGVAR_KERNEL_THREADS_DATA</TT
1149
>. If the C library option
1150
is enabled then the constraint should be satisfied, or else the
1151
configuration contains a conflict. If the configuration does not
1152
include the kernel package then
1153
<TT
1154
CLASS="VARNAME"
1155
>CYGVAR_KERNEL_THREADS_DATA</TT
1156
> will evaluate to
1157
<TT
1158
CLASS="LITERAL"
1159
>0</TT
1160
> and the constraint is not satisfied. Similarly if
1161
the option is inactive or disabled the constraint will not be
1162
satisfied.</P
1163
><P
1164
><TT
1165
CLASS="VARNAME"
1166
>CYGNUM_LIBC_RAND_SEED</TT
1167
> and
1168
<TT
1169
CLASS="VARNAME"
1170
>CYGNUM_LIBC_RAND_TRACE_LEVEL</TT
1171
> both have the
1172
<TT
1173
CLASS="LITERAL"
1174
>data</TT
1175
> flavor, so they are always enabled and the
1176
component framework will generate appropriate
1177
<TT
1178
CLASS="LITERAL"
1179
>#define's</TT
1180
>:</P
1181
><TABLE
1182
BORDER="5"
1183
BGCOLOR="#E0E0F0"
1184
WIDTH="70%"
1185
><TR
1186
><TD
1187
><PRE
1188
CLASS="PROGRAMLISTING"
1189
>#define CYGNUM_LIBC_RAND_SEED 1
1190
#define CYGNUM_LIBC_RAND_SEED_1
1191
#define CYGNUM_LIBC_RAND_TRACE_LEVEL 0
1192
#define CYGNUM_LIBC_RAND_TRACE_LEVEL_0</PRE
1193
></TD
1194
></TR
1195
></TABLE
1196
><P
1197
>Neither option has a <SPAN
1198
CLASS="PROPERTY"
1199
>compile</SPAN
1200
> or similar property, but any such
1201
properties would take effect. Any references to these options in <SPAN
1202
CLASS="APPLICATION"
1203
>CDL</SPAN
1204
>
1205
expressions would evaluate to the data part, so a hypothetical
1206
constraint of the form
1207
<TT
1208
CLASS="LITERAL"
1209
>{&nbsp;requires&nbsp;CYGNUM_LIBC_RAND_SEED&nbsp;&gt;&nbsp;42&nbsp;}</TT
1210
>
1211
would not be satisfied with the default values. Both options use a
1212
simple constant for the <SPAN
1213
CLASS="PROPERTY"
1214
>default_value</SPAN
1215
> expression. It would be
1216
possible to use a more complicated expression, for example the default
1217
for <TT
1218
CLASS="VARNAME"
1219
>CYGNUM_LIBC_RAND_TRACE_LEVEL</TT
1220
> could be
1221
determined from some global debugging option or from a debugging
1222
option that applies to the C library as a whole. Both options also
1223
have a <SPAN
1224
CLASS="PROPERTY"
1225
>legal_values</SPAN
1226
> constraint, which must be satisfied since the
1227
options are active and enabled. </P
1228
><DIV
1229
CLASS="NOTE"
1230
><BLOCKQUOTE
1231
CLASS="NOTE"
1232
><P
1233
><B
1234
>Note: </B
1235
>The value <TT
1236
CLASS="LITERAL"
1237
>0</TT
1238
> is legal for both
1239
<TT
1240
CLASS="VARNAME"
1241
>CYGNUM_LIBC_RAND_SEED</TT
1242
> and
1243
<TT
1244
CLASS="VARNAME"
1245
>CYGNUM_LIBC_RAND_TRACE_LEVEL</TT
1246
>, so in a <SPAN
1247
CLASS="APPLICATION"
1248
>CDL</SPAN
1249
>
1250
expression there is no easy way of distinguishing between the options
1251
being absent or having that particular value. This will be addressed
1252
by future enhancements to the expression syntax.</P
1253
></BLOCKQUOTE
1254
></DIV
1255
></DIV
1256
></DIV
1257
><DIV
1258
CLASS="SECT2"
1259
><H2
1260
CLASS="SECT2"
1261
><A
1262
NAME="LANGUAGE.EXPRESSION">Ordinary Expressions</H2
1263
><P
1264
>Expressions in <SPAN
1265
CLASS="APPLICATION"
1266
>CDL</SPAN
1267
> follow a conventional syntax, for example:</P
1268
><TABLE
1269
BORDER="5"
1270
BGCOLOR="#E0E0F0"
1271
WIDTH="70%"
1272
><TR
1273
><TD
1274
><PRE
1275
CLASS="PROGRAMLISTING"
1276
>    default_value CYGGLO_CODESIZE &gt; CYGGLO_SPEED
1277
    default_value { (CYG_HAL_STARTUP == "RAM" &#38;&#38;
1278
                     !CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS &#38;&#38;
1279
                     !CYGINT_HAL_USE_ROM_MONITOR_UNSUPPORTED &#38;&#38;
1280
                     !CYGSEM_HAL_POWERPC_COPY_VECTORS) ? 1 : 0 }
1281
    default_value { "\"/dev/ser0\"" }</PRE
1282
></TD
1283
></TR
1284
></TABLE
1285
><P
1286
>However there is a complication in that the various arguments to a
1287
<SPAN
1288
CLASS="PROPERTY"
1289
>default_value</SPAN
1290
> property will first get processed by a <SPAN
1291
CLASS="APPLICATION"
1292
>Tcl</SPAN
1293
>
1294
interpreter, so special characters like quotes and square brackets may
1295
get processed. Such problems can be avoided by enclosing non-trivial
1296
expressions in braces, as in the second example above. The way
1297
expression parsing actually works is as follows:</P
1298
><P
1299
></P
1300
><OL
1301
TYPE="1"
1302
><LI
1303
><P
1304
>The <SPAN
1305
CLASS="APPLICATION"
1306
>Tcl</SPAN
1307
> interpreter splits the line or lines into a command and its
1308
arguments. In the first <SPAN
1309
CLASS="PROPERTY"
1310
>default_value</SPAN
1311
> expression above the command
1312
is <TT
1313
CLASS="LITERAL"
1314
>default_value</TT
1315
> and there are three arguments,
1316
<TT
1317
CLASS="LITERAL"
1318
>CYGGLO_CODESIZE</TT
1319
>, <TT
1320
CLASS="LITERAL"
1321
>&gt;</TT
1322
> and
1323
<TT
1324
CLASS="LITERAL"
1325
>CYGGLO_SPEED</TT
1326
>. In the second and third examples
1327
there is just one argument, courtesy of the braces.</P
1328
></LI
1329
><LI
1330
><P
1331
>Next option processing takes place, so any initial arguments that
1332
begin with a hyphen will be interpreted as options. This can cause
1333
problems if the expression involves a negative number, so the
1334
special argument <TT
1335
CLASS="LITERAL"
1336
>--</TT
1337
> can be used to prevent option
1338
processing on the subsequent arguments.</P
1339
></LI
1340
><LI
1341
><P
1342
>All of the arguments are now concatenated, with a single space in
1343
between each one. Hence the following two expressions are equivalent,
1344
even though they will have been processed differently up to this point.</P
1345
><TABLE
1346
BORDER="5"
1347
BGCOLOR="#E0E0F0"
1348
WIDTH="70%"
1349
><TR
1350
><TD
1351
><PRE
1352
CLASS="PROGRAMLISTING"
1353
>    default_value CYGGLO_CODESIZE &gt; CYGGLO_SPEED
1354
    default_value {CYGGLO_CODESIZE &gt; CYGGLO_SPEED}</PRE
1355
></TD
1356
></TR
1357
></TABLE
1358
></LI
1359
><LI
1360
><P
1361
>The expression parsing code now has a single string to process.</P
1362
></LI
1363
></OL
1364
><P
1365
><SPAN
1366
CLASS="APPLICATION"
1367
>CDL</SPAN
1368
> expressions consist of four types of element: references to
1369
configuration options, constant strings, integers, and floating point
1370
numbers. These are combined using a conventional set of operators: the
1371
unary operators <TT
1372
CLASS="LITERAL"
1373
>-</TT
1374
>, <TT
1375
CLASS="LITERAL"
1376
>~</TT
1377
> and
1378
<TT
1379
CLASS="LITERAL"
1380
>!</TT
1381
>; the arithmetic operators <TT
1382
CLASS="LITERAL"
1383
>+</TT
1384
>,
1385
<TT
1386
CLASS="LITERAL"
1387
>-</TT
1388
>, <TT
1389
CLASS="LITERAL"
1390
>*</TT
1391
>, <TT
1392
CLASS="LITERAL"
1393
>/</TT
1394
> and
1395
<TT
1396
CLASS="LITERAL"
1397
>%</TT
1398
>; the shift operators <TT
1399
CLASS="LITERAL"
1400
>&lt;&lt;</TT
1401
>
1402
and <TT
1403
CLASS="LITERAL"
1404
>&gt;&gt;</TT
1405
>; the comparison operators
1406
<TT
1407
CLASS="LITERAL"
1408
>==</TT
1409
>, <TT
1410
CLASS="LITERAL"
1411
>!=</TT
1412
>, <TT
1413
CLASS="LITERAL"
1414
>&lt;</TT
1415
>,
1416
<TT
1417
CLASS="LITERAL"
1418
>&lt;=</TT
1419
>, <TT
1420
CLASS="LITERAL"
1421
>&gt;</TT
1422
> and
1423
<TT
1424
CLASS="LITERAL"
1425
>&gt;=</TT
1426
>; the bitwise operators
1427
<TT
1428
CLASS="LITERAL"
1429
>&amp;</TT
1430
>, <TT
1431
CLASS="LITERAL"
1432
>^</TT
1433
> and
1434
<TT
1435
CLASS="LITERAL"
1436
>|</TT
1437
>; the logical operators <TT
1438
CLASS="LITERAL"
1439
>&#38;&#38;</TT
1440
> and
1441
<TT
1442
CLASS="LITERAL"
1443
>||</TT
1444
>; the string concatenation operator
1445
<TT
1446
CLASS="LITERAL"
1447
>.</TT
1448
>; and the ternary conditional operator
1449
<TT
1450
CLASS="LITERAL"
1451
>A&nbsp;?&nbsp;B&nbsp;:&nbsp;C</TT
1452
>. There is also support for
1453
some less widely available operators for logical equivalence and
1454
implication, and for a set of function-style operations. Bracketed
1455
sub-expressions are supported, and the operators have the usual
1456
precedence:</P
1457
><DIV
1458
CLASS="INFORMALTABLE"
1459
><A
1460
NAME="AEN1653"><P
1461
></P
1462
><TABLE
1463
BORDER="1"
1464
CLASS="CALSTABLE"
1465
><THEAD
1466
><TR
1467
><TH
1468
WIDTH="33%"
1469
ALIGN="CENTER"
1470
VALIGN="TOP"
1471
>Priority</TH
1472
><TH
1473
WIDTH="33%"
1474
ALIGN="CENTER"
1475
VALIGN="TOP"
1476
>Operators</TH
1477
><TH
1478
WIDTH="33%"
1479
ALIGN="CENTER"
1480
VALIGN="TOP"
1481
>Category</TH
1482
></TR
1483
></THEAD
1484
><TBODY
1485
><TR
1486
><TD
1487
WIDTH="33%"
1488
ALIGN="CENTER"
1489
VALIGN="TOP"
1490
>16</TD
1491
><TD
1492
WIDTH="33%"
1493
ALIGN="CENTER"
1494
VALIGN="TOP"
1495
>references, constants</TD
1496
><TD
1497
WIDTH="33%"
1498
ALIGN="CENTER"
1499
VALIGN="TOP"
1500
>basic elements</TD
1501
></TR
1502
><TR
1503
><TD
1504
WIDTH="33%"
1505
ALIGN="CENTER"
1506
VALIGN="TOP"
1507
>15</TD
1508
><TD
1509
WIDTH="33%"
1510
ALIGN="CENTER"
1511
VALIGN="TOP"
1512
><TT
1513
CLASS="LITERAL"
1514
>f(a, b, c)</TT
1515
></TD
1516
><TD
1517
WIDTH="33%"
1518
ALIGN="CENTER"
1519
VALIGN="TOP"
1520
>function calls</TD
1521
></TR
1522
><TR
1523
><TD
1524
WIDTH="33%"
1525
ALIGN="CENTER"
1526
VALIGN="TOP"
1527
>14</TD
1528
><TD
1529
WIDTH="33%"
1530
ALIGN="CENTER"
1531
VALIGN="TOP"
1532
><TT
1533
CLASS="LITERAL"
1534
>~</TT
1535
></TD
1536
><TD
1537
WIDTH="33%"
1538
ALIGN="CENTER"
1539
VALIGN="TOP"
1540
>bitwise not</TD
1541
></TR
1542
><TR
1543
><TD
1544
WIDTH="33%"
1545
ALIGN="CENTER"
1546
VALIGN="TOP"
1547
>14</TD
1548
><TD
1549
WIDTH="33%"
1550
ALIGN="CENTER"
1551
VALIGN="TOP"
1552
><TT
1553
CLASS="LITERAL"
1554
>!</TT
1555
></TD
1556
><TD
1557
WIDTH="33%"
1558
ALIGN="CENTER"
1559
VALIGN="TOP"
1560
>logical not</TD
1561
></TR
1562
><TR
1563
><TD
1564
WIDTH="33%"
1565
ALIGN="CENTER"
1566
VALIGN="TOP"
1567
>14</TD
1568
><TD
1569
WIDTH="33%"
1570
ALIGN="CENTER"
1571
VALIGN="TOP"
1572
><TT
1573
CLASS="LITERAL"
1574
>-</TT
1575
></TD
1576
><TD
1577
WIDTH="33%"
1578
ALIGN="CENTER"
1579
VALIGN="TOP"
1580
>arithmetic negation</TD
1581
></TR
1582
><TR
1583
><TD
1584
WIDTH="33%"
1585
ALIGN="CENTER"
1586
VALIGN="TOP"
1587
>13</TD
1588
><TD
1589
WIDTH="33%"
1590
ALIGN="CENTER"
1591
VALIGN="TOP"
1592
><TT
1593
CLASS="LITERAL"
1594
>* / %</TT
1595
></TD
1596
><TD
1597
WIDTH="33%"
1598
ALIGN="CENTER"
1599
VALIGN="TOP"
1600
>multiplicative arithmetic</TD
1601
></TR
1602
><TR
1603
><TD
1604
WIDTH="33%"
1605
ALIGN="CENTER"
1606
VALIGN="TOP"
1607
>12</TD
1608
><TD
1609
WIDTH="33%"
1610
ALIGN="CENTER"
1611
VALIGN="TOP"
1612
><TT
1613
CLASS="LITERAL"
1614
>+ - .</TT
1615
></TD
1616
><TD
1617
WIDTH="33%"
1618
ALIGN="CENTER"
1619
VALIGN="TOP"
1620
>additive arithmetic and string concatenation</TD
1621
></TR
1622
><TR
1623
><TD
1624
WIDTH="33%"
1625
ALIGN="CENTER"
1626
VALIGN="TOP"
1627
>11</TD
1628
><TD
1629
WIDTH="33%"
1630
ALIGN="CENTER"
1631
VALIGN="TOP"
1632
><TT
1633
CLASS="LITERAL"
1634
>&lt;&lt; &gt;&gt;</TT
1635
></TD
1636
><TD
1637
WIDTH="33%"
1638
ALIGN="CENTER"
1639
VALIGN="TOP"
1640
>bitwise shifts</TD
1641
></TR
1642
><TR
1643
><TD
1644
WIDTH="33%"
1645
ALIGN="CENTER"
1646
VALIGN="TOP"
1647
>10</TD
1648
><TD
1649
WIDTH="33%"
1650
ALIGN="CENTER"
1651
VALIGN="TOP"
1652
><TT
1653
CLASS="LITERAL"
1654
>&lt;= &lt; &gt; &gt;=</TT
1655
></TD
1656
><TD
1657
WIDTH="33%"
1658
ALIGN="CENTER"
1659
VALIGN="TOP"
1660
>inequality</TD
1661
></TR
1662
><TR
1663
><TD
1664
WIDTH="33%"
1665
ALIGN="CENTER"
1666
VALIGN="TOP"
1667
>9</TD
1668
><TD
1669
WIDTH="33%"
1670
ALIGN="CENTER"
1671
VALIGN="TOP"
1672
><TT
1673
CLASS="LITERAL"
1674
>== !=</TT
1675
></TD
1676
><TD
1677
WIDTH="33%"
1678
ALIGN="CENTER"
1679
VALIGN="TOP"
1680
>comparison</TD
1681
></TR
1682
><TR
1683
><TD
1684
WIDTH="33%"
1685
ALIGN="CENTER"
1686
VALIGN="TOP"
1687
>8</TD
1688
><TD
1689
WIDTH="33%"
1690
ALIGN="CENTER"
1691
VALIGN="TOP"
1692
><TT
1693
CLASS="LITERAL"
1694
>&#38;</TT
1695
></TD
1696
><TD
1697
WIDTH="33%"
1698
ALIGN="CENTER"
1699
VALIGN="TOP"
1700
>bitwise and</TD
1701
></TR
1702
><TR
1703
><TD
1704
WIDTH="33%"
1705
ALIGN="CENTER"
1706
VALIGN="TOP"
1707
>7</TD
1708
><TD
1709
WIDTH="33%"
1710
ALIGN="CENTER"
1711
VALIGN="TOP"
1712
><TT
1713
CLASS="LITERAL"
1714
>^</TT
1715
></TD
1716
><TD
1717
WIDTH="33%"
1718
ALIGN="CENTER"
1719
VALIGN="TOP"
1720
>bitwise xor</TD
1721
></TR
1722
><TR
1723
><TD
1724
WIDTH="33%"
1725
ALIGN="CENTER"
1726
VALIGN="TOP"
1727
>6</TD
1728
><TD
1729
WIDTH="33%"
1730
ALIGN="CENTER"
1731
VALIGN="TOP"
1732
><TT
1733
CLASS="LITERAL"
1734
>|</TT
1735
></TD
1736
><TD
1737
WIDTH="33%"
1738
ALIGN="CENTER"
1739
VALIGN="TOP"
1740
>bitwise or</TD
1741
></TR
1742
><TR
1743
><TD
1744
WIDTH="33%"
1745
ALIGN="CENTER"
1746
VALIGN="TOP"
1747
>5</TD
1748
><TD
1749
WIDTH="33%"
1750
ALIGN="CENTER"
1751
VALIGN="TOP"
1752
><TT
1753
CLASS="LITERAL"
1754
>&#38;&#38;</TT
1755
></TD
1756
><TD
1757
WIDTH="33%"
1758
ALIGN="CENTER"
1759
VALIGN="TOP"
1760
>logical and</TD
1761
></TR
1762
><TR
1763
><TD
1764
WIDTH="33%"
1765
ALIGN="CENTER"
1766
VALIGN="TOP"
1767
>4</TD
1768
><TD
1769
WIDTH="33%"
1770
ALIGN="CENTER"
1771
VALIGN="TOP"
1772
><TT
1773
CLASS="LITERAL"
1774
>||</TT
1775
></TD
1776
><TD
1777
WIDTH="33%"
1778
ALIGN="CENTER"
1779
VALIGN="TOP"
1780
>logical or</TD
1781
></TR
1782
><TR
1783
><TD
1784
WIDTH="33%"
1785
ALIGN="CENTER"
1786
VALIGN="TOP"
1787
>3</TD
1788
><TD
1789
WIDTH="33%"
1790
ALIGN="CENTER"
1791
VALIGN="TOP"
1792
><TT
1793
CLASS="LITERAL"
1794
>xor, eqv</TT
1795
></TD
1796
><TD
1797
WIDTH="33%"
1798
ALIGN="CENTER"
1799
VALIGN="TOP"
1800
>logical equivalance</TD
1801
></TR
1802
><TR
1803
><TD
1804
WIDTH="33%"
1805
ALIGN="CENTER"
1806
VALIGN="TOP"
1807
>2</TD
1808
><TD
1809
WIDTH="33%"
1810
ALIGN="CENTER"
1811
VALIGN="TOP"
1812
><TT
1813
CLASS="LITERAL"
1814
>implies</TT
1815
></TD
1816
><TD
1817
WIDTH="33%"
1818
ALIGN="CENTER"
1819
VALIGN="TOP"
1820
>logical implication</TD
1821
></TR
1822
><TR
1823
><TD
1824
WIDTH="33%"
1825
ALIGN="CENTER"
1826
VALIGN="TOP"
1827
>1</TD
1828
><TD
1829
WIDTH="33%"
1830
ALIGN="CENTER"
1831
VALIGN="TOP"
1832
><TT
1833
CLASS="LITERAL"
1834
>? :</TT
1835
></TD
1836
><TD
1837
WIDTH="33%"
1838
ALIGN="CENTER"
1839
VALIGN="TOP"
1840
>conditional</TD
1841
></TR
1842
></TBODY
1843
></TABLE
1844
><P
1845
></P
1846
></DIV
1847
><P
1848
>Function calls have the usual format of a name, an opening bracket,
1849
one or more arguments separated by commas, and a closing bracket. For
1850
example:</P
1851
><TABLE
1852
BORDER="5"
1853
BGCOLOR="#E0E0F0"
1854
WIDTH="70%"
1855
><TR
1856
><TD
1857
><PRE
1858
CLASS="PROGRAMLISTING"
1859
>    requires { !is_substr(CYGBLD_GLOBAL_CFLAGS, " -fno-rtti") }</PRE
1860
></TD
1861
></TR
1862
></TABLE
1863
><P
1864
>Functions will differ in the number of arguments and may impose
1865
restrictions on some or all of their arguments. For example it may be
1866
necessary for the first argument to be a reference to a configuration
1867
option. The available functions are described in <A
1868
HREF="language.values.html#LANGUAGE.FUNCTIONS"
1869
>the Section called <I
1870
>Functions</I
1871
></A
1872
>. </P
1873
><P
1874
>The logical <TT
1875
CLASS="LITERAL"
1876
>xor</TT
1877
> operator evaluates to true if
1878
either the left hand side or the right hand side but not both evaluate
1879
to true The logical <TT
1880
CLASS="LITERAL"
1881
>eqv</TT
1882
> operator evaluates to true
1883
if both the left and right hand sides evaluate to true, or if both
1884
evaluate to false. The <TT
1885
CLASS="LITERAL"
1886
>implies</TT
1887
> operator evaluates
1888
to true either if the left hand side is false or if the right hand
1889
side is true, in other words <TT
1890
CLASS="LITERAL"
1891
>A&nbsp;implies&nbsp;B</TT
1892
>
1893
has the same meaning as <TT
1894
CLASS="LITERAL"
1895
>!A&nbsp;||&nbsp;B</TT
1896
>. An
1897
example use would be:</P
1898
><TABLE
1899
BORDER="5"
1900
BGCOLOR="#E0E0F0"
1901
WIDTH="70%"
1902
><TR
1903
><TD
1904
><PRE
1905
CLASS="PROGRAMLISTING"
1906
>    requires { is_active(CYGNUM_LIBC_MAIN_DEFAULT_STACK_SIZE) implies
1907
                   (CYGNUM_LIBC_MAIN_DEFAULT_STACK_SIZE &#62;= (16 * 1024)) }</PRE
1908
></TD
1909
></TR
1910
></TABLE
1911
><P
1912
>This constraint would be satisfied if either the support for a main
1913
stack size is disabled, or if that stack is at least 16K. However if
1914
such a stack were in use but was too small, a conflict would be raised.</P
1915
><P
1916
>A valid <SPAN
1917
CLASS="APPLICATION"
1918
>CDL</SPAN
1919
> identifier in an expression, for example
1920
<TT
1921
CLASS="VARNAME"
1922
>CYGGLO_SPEED</TT
1923
>, will be interpreted as a reference to
1924
a configuration option by that name. The option does not have to be
1925
loaded into the current configuration. When the component framework
1926
evaluates the expression it will substitute in a suitable value that
1927
depends on whether or not the option is loaded, active, and enabled.
1928
The exact rules are described in <A
1929
HREF="language.values.html#LANGUAGE.VALUES.VALUE"
1930
>the Section called <I
1931
>Option Values</I
1932
></A
1933
>.</P
1934
><P
1935
>A constant string is any sequence of characters enclosed in quotes.
1936
Care has to be taken that these quotes are not stripped off by the
1937
<SPAN
1938
CLASS="APPLICATION"
1939
>Tcl</SPAN
1940
> interpreter before the <SPAN
1941
CLASS="APPLICATION"
1942
>CDL</SPAN
1943
> expression parser sees them.
1944
Consider the following:</P
1945
><TABLE
1946
BORDER="5"
1947
BGCOLOR="#E0E0F0"
1948
WIDTH="70%"
1949
><TR
1950
><TD
1951
><PRE
1952
CLASS="PROGRAMLISTING"
1953
>    default_value "RAM"</PRE
1954
></TD
1955
></TR
1956
></TABLE
1957
><P
1958
>The quote marks will be stripped before the <SPAN
1959
CLASS="APPLICATION"
1960
>CDL</SPAN
1961
> expression parser
1962
sees the data, so the expression will be interpreted as a reference to
1963
a configuration option <TT
1964
CLASS="VARNAME"
1965
>RAM</TT
1966
>. There is unlikely to be
1967
such an option, so the actual default value will be
1968
<TT
1969
CLASS="LITERAL"
1970
>0</TT
1971
>. Careful use of braces or other <SPAN
1972
CLASS="APPLICATION"
1973
>Tcl</SPAN
1974
> quoting
1975
mechanisms can be used to avoid such problems.</P
1976
><P
1977
>
1978
String constants consist of the data inside the quotes. If the data
1979
itself needs to contain quote characters then appropriate quoting is
1980
again necessary, for example:</P
1981
><TABLE
1982
BORDER="5"
1983
BGCOLOR="#E0E0F0"
1984
WIDTH="70%"
1985
><TR
1986
><TD
1987
><PRE
1988
CLASS="PROGRAMLISTING"
1989
>    default_value { "\"/dev/ser0\"" }</PRE
1990
></TD
1991
></TR
1992
></TABLE
1993
><P
1994
>An integer constant consists of a sequence of digits, optionally
1995
preceeded with the unary <TT
1996
CLASS="LITERAL"
1997
>+</TT
1998
> or <TT
1999
CLASS="LITERAL"
2000
>-</TT
2001
>
2002
operators. As usual the sequence <TT
2003
CLASS="LITERAL"
2004
>0x</TT
2005
> or
2006
<TT
2007
CLASS="LITERAL"
2008
>0X</TT
2009
> can be used for hexadecimal data, and a leading
2010
<TT
2011
CLASS="LITERAL"
2012
>0</TT
2013
> indicates octal data. Internally the component
2014
framework uses 64-bit arithmetic for integer data. If a constant is
2015
too large then double precision arithmetic will be used instead.
2016
Traditional syntax is also used for double precision numbers, for
2017
example <TT
2018
CLASS="LITERAL"
2019
>3.141592</TT
2020
> or <TT
2021
CLASS="LITERAL"
2022
>-3E6</TT
2023
>. </P
2024
><P
2025
>Of course this is not completely accurate: <SPAN
2026
CLASS="APPLICATION"
2027
>CDL</SPAN
2028
> is not a typed
2029
language, all data is treated as if it were a string. For example the
2030
following two lines are equivalent:</P
2031
><TABLE
2032
BORDER="5"
2033
BGCOLOR="#E0E0F0"
2034
WIDTH="70%"
2035
><TR
2036
><TD
2037
><PRE
2038
CLASS="PROGRAMLISTING"
2039
>    requires CYGNUM_UITRON_SEMAS &#62; 10
2040
    requires { CYGNUM_UITRON_SEMAS &#62; "10" }</PRE
2041
></TD
2042
></TR
2043
></TABLE
2044
><P
2045
>When an expression gets evaluated the operators will attempt
2046
appropriate conversions. The <TT
2047
CLASS="LITERAL"
2048
>&gt;</TT
2049
> comparison
2050
operator can be used on either integer or double precision numbers, so
2051
it will begin by attempting a string to integer conversion of both
2052
operands. If that fails it will attempt string to double conversions.
2053
If that fails as well then the component framework will report a
2054
conflict, an evaluation exception. If the conversions from string to
2055
integer are successful then the result will be either the string
2056
<TT
2057
CLASS="LITERAL"
2058
>0</TT
2059
> or the string <TT
2060
CLASS="LITERAL"
2061
>1</TT
2062
>, both of which
2063
can be converted to integers or doubles as required.</P
2064
><P
2065
>It is worth noting that the expression
2066
<TT
2067
CLASS="LITERAL"
2068
>CYGNUM_UITRON_SEMAS&nbsp;&gt;10</TT
2069
> is not ambiguous.
2070
<SPAN
2071
CLASS="APPLICATION"
2072
>CDL</SPAN
2073
> identifiers can never begin with a digit, so it is not possible
2074
for <TT
2075
CLASS="LITERAL"
2076
>10</TT
2077
> to be misinterpreted as a reference to an
2078
identifier instead of as a string.</P
2079
><P
2080
>Of course the implementation is slightly different again. The <SPAN
2081
CLASS="APPLICATION"
2082
>CDL</SPAN
2083
>
2084
language definition is such that all data is treated as if it were a
2085
string, with conversions to integer, double or boolean as and when
2086
required. The implementation is allowed to avoid conversions until
2087
they are necessary. For example, given
2088
<TT
2089
CLASS="LITERAL"
2090
>CYGNUM_UITRON_SEMAS&nbsp;&gt;&nbsp;10</TT
2091
> the
2092
expression parsing code will perform an immediate conversion from
2093
string to integer, storing the integer representation, and there is no
2094
need for a conversion by the comparison operator when the expression
2095
gets evaluated. Given
2096
<TT
2097
CLASS="LITERAL"
2098
>{&nbsp;CYGNUM_UITRON_SEMAS&nbsp;&gt;&nbsp;"10"&nbsp;}</TT
2099
>
2100
the parsing code will store the string representation and a conversion
2101
happens the first time the expression is evaluated. All of this is an
2102
implementation detail, and does not affect the semantics of the
2103
language. </P
2104
><P
2105
>Different operators have different requirements, for example the
2106
bitwise or operator only makes sense if both operands have an integer
2107
representation. For operators which can work with either integer or
2108
double precision numbers, integer arithmetic will be preferred.</P
2109
><P
2110
>The following operators only accept integer operands:
2111
unary <TT
2112
CLASS="LITERAL"
2113
>~</TT
2114
> (bitwise not), the shift operators
2115
<TT
2116
CLASS="LITERAL"
2117
>&lt;&lt;</TT
2118
> and <TT
2119
CLASS="LITERAL"
2120
>&gt;&gt;</TT
2121
>, and the
2122
bitwise operators <TT
2123
CLASS="LITERAL"
2124
>&#38;</TT
2125
>, <TT
2126
CLASS="LITERAL"
2127
>|</TT
2128
> and
2129
<TT
2130
CLASS="LITERAL"
2131
>^</TT
2132
>.</P
2133
><P
2134
>The following operators will attempt integer arithmetic first, then
2135
double precision arithmetic: unary <TT
2136
CLASS="LITERAL"
2137
>-</TT
2138
>,
2139
the arithmetic operators <TT
2140
CLASS="LITERAL"
2141
>+</TT
2142
>, <TT
2143
CLASS="LITERAL"
2144
>-</TT
2145
>,
2146
<TT
2147
CLASS="LITERAL"
2148
>*</TT
2149
>, <TT
2150
CLASS="LITERAL"
2151
>/</TT
2152
>, and <TT
2153
CLASS="LITERAL"
2154
>%</TT
2155
>;
2156
and the comparision operators <TT
2157
CLASS="LITERAL"
2158
>&lt;</TT
2159
>,
2160
<TT
2161
CLASS="LITERAL"
2162
>&lt;=</TT
2163
>, <TT
2164
CLASS="LITERAL"
2165
>&gt;</TT
2166
> and
2167
<TT
2168
CLASS="LITERAL"
2169
>&gt;=</TT
2170
>. </P
2171
><P
2172
>The equality <TT
2173
CLASS="LITERAL"
2174
>==</TT
2175
> and inequality
2176
<TT
2177
CLASS="LITERAL"
2178
>!=</TT
2179
> operators will first attempt integer conversion
2180
and comparison. If that fails then double precision will be attempted
2181
(although arguably using these operators on double precision data is
2182
not sensible). As a last resort string comparison will be used.</P
2183
><P
2184
>The operators <TT
2185
CLASS="LITERAL"
2186
>!</TT
2187
>, <TT
2188
CLASS="LITERAL"
2189
>&#38;&#38;</TT
2190
> and
2191
<TT
2192
CLASS="LITERAL"
2193
>||</TT
2194
> all work with boolean data. Any string that can
2195
be converted to the integer <TT
2196
CLASS="LITERAL"
2197
>0</TT
2198
> or the double
2199
<TT
2200
CLASS="LITERAL"
2201
>0.0</TT
2202
> is treated as false, as is the empty string or
2203
the constant string <TT
2204
CLASS="LITERAL"
2205
>false</TT
2206
>. Anything else is
2207
interpreted as true. The result is either <TT
2208
CLASS="LITERAL"
2209
>0</TT
2210
> or
2211
<TT
2212
CLASS="LITERAL"
2213
>1</TT
2214
>.</P
2215
><P
2216
>The conditional operator <TT
2217
CLASS="LITERAL"
2218
>?&nbsp;:</TT
2219
> will interpret
2220
its first operand as a boolean. It does not perform any processing on
2221
the second or third operands.</P
2222
><P
2223
>In practice it is rarely necessary to worry about any of these
2224
details. In nearly every case <SPAN
2225
CLASS="APPLICATION"
2226
>CDL</SPAN
2227
> expressions just work as expected,
2228
and there is no need to understand the full details.</P
2229
><DIV
2230
CLASS="NOTE"
2231
><BLOCKQUOTE
2232
CLASS="NOTE"
2233
><P
2234
><B
2235
>Note: </B
2236
>The current expression syntax does not meet all the needs of component
2237
writers. Some future enhancements will definitely be made, others are
2238
more controversial. The list includes the following:</P
2239
><P
2240
></P
2241
><OL
2242
TYPE="1"
2243
><LI
2244
><P
2245
>An option's value is determined by several different factors: whether
2246
or not it is loaded, whether or not it is active, whether or not it is
2247
enabled, and the data part. Currently there is no way of querying
2248
these individually. This is very significant in the context of options
2249
with the <TT
2250
CLASS="LITERAL"
2251
>bool</TT
2252
> or <TT
2253
CLASS="LITERAL"
2254
>booldata</TT
2255
>
2256
flavors, because there is no way of distinguishing between the option
2257
being absent/inactive/disabled or it being enabled with a data field
2258
of <TT
2259
CLASS="LITERAL"
2260
>0</TT
2261
>. There should be unary operators that allow
2262
any of the factors to be checked.</P
2263
></LI
2264
><LI
2265
><P
2266
>Only the <TT
2267
CLASS="LITERAL"
2268
>==</TT
2269
> and <TT
2270
CLASS="LITERAL"
2271
>!=</TT
2272
> operators can
2273
be used for string data. More string-related facilities are needed.</P
2274
></LI
2275
><LI
2276
><P
2277
>An implies operator would be useful for many goal expression, where
2278
<TT
2279
CLASS="LITERAL"
2280
>A&nbsp;implies&nbsp;B</TT
2281
> is equivalent to
2282
<TT
2283
CLASS="LITERAL"
2284
>!A&nbsp;||B</TT
2285
>.</P
2286
></LI
2287
><LI
2288
><P
2289
>Similarly there is inadequate support for lists. On occasion it would
2290
be useful to write expressions involving say the list of implementors
2291
of a given CDL interface, for example a sensible default value could
2292
be the first implementor. Associated with this is a need for an
2293
indirection operator.</P
2294
></LI
2295
><LI
2296
><P
2297
>Arguably extending the basic <SPAN
2298
CLASS="APPLICATION"
2299
>CDL</SPAN
2300
> expression syntax with lots of new
2301
operators is unnecessary, instead expressions should just support
2302
<SPAN
2303
CLASS="APPLICATION"
2304
>Tcl</SPAN
2305
> command substitution and then component writers could escape
2306
into <SPAN
2307
CLASS="APPLICATION"
2308
>Tcl</SPAN
2309
> scripts for complicated operations. This has some major
2310
disadvantages. First, the inference engine would no longer have any
2311
sensible way of interpreting an expression to resolve a conflict.
2312
Second, the component framework's value propagation code keeps track
2313
of which options get referenced in which expressions and avoids
2314
unnecessary re-evaluation of expressions; if expressions can involve
2315
arbitrary <SPAN
2316
CLASS="APPLICATION"
2317
>Tcl</SPAN
2318
> code then there is no simple way to eliminate
2319
unnecessary recalculations, with a potentially major impact on
2320
performance.</P
2321
></LI
2322
></OL
2323
></BLOCKQUOTE
2324
></DIV
2325
><DIV
2326
CLASS="NOTE"
2327
><BLOCKQUOTE
2328
CLASS="NOTE"
2329
><P
2330
><B
2331
>Note: </B
2332
>The current implementation of the component framework uses 64 bit
2333
arithmetic on all host platforms. Although this is adequate for
2334
current target architectures, it may cause problems in future. At some
2335
stage it is likely that an arbitrary precision integer arithmetic
2336
package will be used instead.</P
2337
></BLOCKQUOTE
2338
></DIV
2339
></DIV
2340
><DIV
2341
CLASS="SECT2"
2342
><H2
2343
CLASS="SECT2"
2344
><A
2345
NAME="LANGUAGE.FUNCTIONS">Functions</H2
2346
><P
2347
>CDL expressions can contain calls to a set of built-in functions
2348
using the usual syntax, for example;</P
2349
><TABLE
2350
BORDER="5"
2351
BGCOLOR="#E0E0F0"
2352
WIDTH="70%"
2353
><TR
2354
><TD
2355
><PRE
2356
CLASS="PROGRAMLISTING"
2357
>    requires { !is_substr(CYGBLD_GLOBAL_CFLAGS, "-fno-rtti") }</PRE
2358
></TD
2359
></TR
2360
></TABLE
2361
><P
2362
>The available function calls are as follows:</P
2363
><P
2364
></P
2365
><DIV
2366
CLASS="VARIABLELIST"
2367
><DL
2368
><DT
2369
><TT
2370
CLASS="LITERAL"
2371
>get_data(option)</TT
2372
></DT
2373
><DD
2374
><P
2375
>This function can be used to obtain just the data part of a loaded
2376
configuration option, ignoring other factors such as whether or not
2377
the option is active and enabled. It takes a single argument which
2378
should be the name of a configuration option. If the specified option
2379
is not loaded in the current configuration then the function returns
2380
0, otherwise it returns the data part. Typically this function will
2381
only be used in conjunction with <TT
2382
CLASS="FUNCTION"
2383
>is_active</TT
2384
> and
2385
<TT
2386
CLASS="FUNCTION"
2387
>is_enabled</TT
2388
> for fine-grained control over the
2389
various factors that make up an option's value.</P
2390
></DD
2391
><DT
2392
><TT
2393
CLASS="LITERAL"
2394
>is_active(option)</TT
2395
></DT
2396
><DD
2397
><P
2398
>This function can be used to determine whether or not a particular
2399
configuration option is active. It takes a single argument which
2400
should be the name of an option, and returns a boolean. If the
2401
specified option is not loaded then the function will return false.
2402
Otherwise it will consider the state of the option's parents and
2403
evaluate any <SPAN
2404
CLASS="PROPERTY"
2405
>active_if</SPAN
2406
> properties, and return the option's current
2407
active state. A typical use might be:</P
2408
><TABLE
2409
BORDER="5"
2410
BGCOLOR="#E0E0F0"
2411
WIDTH="70%"
2412
><TR
2413
><TD
2414
><PRE
2415
CLASS="PROGRAMLISTING"
2416
>    requires { is_active(CYGNUM_LIBC_MAIN_DEFAULT_STACK_SIZE) implies
2417
                   (CYGNUM_LIBC_MAIN_DEFAULT_STACK_SIZE &#62;= (16 * 1024)) }</PRE
2418
></TD
2419
></TR
2420
></TABLE
2421
><P
2422
>In other words either the specified configuration option must be
2423
inactive, for example because the current application does not use
2424
any related C library or POSIX functionality, or the stack size must
2425
be at least 16K.</P
2426
><P
2427
>The configuration system's inference engine can attempt to satisfy
2428
constraints involving <TT
2429
CLASS="FUNCTION"
2430
>is_active</TT
2431
> in various
2432
different ways, for example by enabling or disabling parent
2433
components, or by examining <SPAN
2434
CLASS="PROPERTY"
2435
>active_if</SPAN
2436
> properties and manipulating
2437
terms in the associated expressions.</P
2438
></DD
2439
><DT
2440
><TT
2441
CLASS="LITERAL"
2442
>is_enabled(option)</TT
2443
></DT
2444
><DD
2445
><P
2446
>This function can be used to determine whether or not a particular
2447
configuration option is enabled. It takes a single argument which
2448
should be the name of an option, and returns a boolean. If the
2449
specified option is not loaded then the function will return false.
2450
Otherwise it will return the current boolean part of the option's
2451
value. The option's active or inactive state is ignored. Typically
2452
this function will be used in conjunction with
2453
<TT
2454
CLASS="FUNCTION"
2455
>is_active</TT
2456
> and possibly
2457
<TT
2458
CLASS="FUNCTION"
2459
>get_data</TT
2460
> to provide fine-grained control over the
2461
various factors that make up an option's value.</P
2462
></DD
2463
><DT
2464
><TT
2465
CLASS="LITERAL"
2466
>is_loaded(option)</TT
2467
></DT
2468
><DD
2469
><P
2470
>This function can be used to determine whether or not a particular
2471
configuration option is loaded. It takes a single argument which
2472
should be the name of an option, and returns a boolean. If the
2473
argument is a package then the <TT
2474
CLASS="FUNCTION"
2475
>is_loaded</TT
2476
> function
2477
provides little or no extra information, for example the following two
2478
constraints are usually equivalent:</P
2479
><TABLE
2480
BORDER="5"
2481
BGCOLOR="#E0E0F0"
2482
WIDTH="70%"
2483
><TR
2484
><TD
2485
><PRE
2486
CLASS="PROGRAMLISTING"
2487
>    requires { CYGPKG_KERNEL }
2488
    requires { is_loaded(CYGPKG_KERNEL) }</PRE
2489
></TD
2490
></TR
2491
></TABLE
2492
><P
2493
>However if the specified package is loaded but re-parented below a
2494
disabled component, or inactive as a result of an <SPAN
2495
CLASS="PROPERTY"
2496
>active_if</SPAN
2497
>
2498
property, then the first constraint would not be satisfied but the
2499
second constraint would. In other words the
2500
<TT
2501
CLASS="FUNCTION"
2502
>is_loaded</TT
2503
> makes it possible to consider in
2504
isolation one of the factors that are considered when CDL expressions
2505
are evaluated.</P
2506
><P
2507
>The configuration system's inference engine will not automatically
2508
load or unload packages to satisfy <TT
2509
CLASS="FUNCTION"
2510
>is_loaded</TT
2511
>
2512
constraints. </P
2513
></DD
2514
><DT
2515
><TT
2516
CLASS="LITERAL"
2517
>is_substr(haystack,&nbsp;needle)</TT
2518
></DT
2519
><DD
2520
><P
2521
>This can be used to check whether or not a particular string is
2522
present in another string. It is used mainly for manipulating compiler
2523
flags. The function takes two arguments, both of which can be
2524
arbitrary expressions, and returns a boolean.</P
2525
><P
2526
><TT
2527
CLASS="FUNCTION"
2528
>is_substr</TT
2529
> has some understanding of word
2530
boundaries. If the second argument starts with a space character then
2531
that will match either a real space or the start of the string.
2532
Similarly if the second argument ends with a space character then that
2533
will match a real space or the end of the string. For example, all of
2534
the following conditions are satisfied:</P
2535
><TABLE
2536
BORDER="5"
2537
BGCOLOR="#E0E0F0"
2538
WIDTH="70%"
2539
><TR
2540
><TD
2541
><PRE
2542
CLASS="PROGRAMLISTING"
2543
>    is_substr("abracadabra", "abra")
2544
    is_substr("abracadabra", " abra")
2545
    is_substr("hocus pocus", " pocus")
2546
    is_substr("abracadabra", "abra ")</PRE
2547
></TD
2548
></TR
2549
></TABLE
2550
><P
2551
>The first is an exact match. The second is a match because the leading
2552
space matches the start of the string. The third is an exact match,
2553
with the leading space matching an actual space. The fourth is a match
2554
because the trailing space matches the end of the string. However, the
2555
following condition is not satisfied.</P
2556
><TABLE
2557
BORDER="5"
2558
BGCOLOR="#E0E0F0"
2559
WIDTH="70%"
2560
><TR
2561
><TD
2562
><PRE
2563
CLASS="PROGRAMLISTING"
2564
>    is_substr("abracadabra", " abra ")</PRE
2565
></TD
2566
></TR
2567
></TABLE
2568
><P
2569
>This fails to match at the start of the string because the trailing
2570
space is not matched by either a real space or the end of the string.
2571
Similarly it fails to match at the end of the string.</P
2572
><P
2573
>If a constraint involving <TT
2574
CLASS="FUNCTION"
2575
>is_substr</TT
2576
> is not
2577
satisfied and the first argument is a reference to a configuration
2578
option, the inference engine will attempt to modify that option's
2579
value. This can be achieved either by appending the second argument to
2580
the current value, or by removing all occurrences of that argument
2581
from the current value.</P
2582
><TABLE
2583
BORDER="5"
2584
BGCOLOR="#E0E0F0"
2585
WIDTH="70%"
2586
><TR
2587
><TD
2588
><PRE
2589
CLASS="PROGRAMLISTING"
2590
>    requires { !is_substr(CYGBLD_GLOBAL_CFLAGS, " -fno-rtti ") }
2591
    requires { is_substr(CYGBLD_GLOBAL_CFLAGS, " -frtti ") }</PRE
2592
></TD
2593
></TR
2594
></TABLE
2595
><P
2596
>When data is removed the leading and trailing spaces will be left. For
2597
example, given an initial value of
2598
&#60;<TT
2599
CLASS="VARNAME"
2600
>CYGBLD_GLOBAL_CFLAGS</TT
2601
> of
2602
<TT
2603
CLASS="LITERAL"
2604
>-g&nbsp;-fno-rtti&nbsp;-O2</TT
2605
> the result will be
2606
<TT
2607
CLASS="LITERAL"
2608
>-g&nbsp;&nbsp;-O2</TT
2609
> rather than <TT
2610
CLASS="LITERAL"
2611
>-g-O2</TT
2612
>.</P
2613
><P
2614
>If exact matches are needed, the function
2615
<TT
2616
CLASS="FUNCTION"
2617
>is_xsubstr</TT
2618
> can be used instead.</P
2619
></DD
2620
><DT
2621
><TT
2622
CLASS="LITERAL"
2623
>is_xsubstr(haystack,&nbsp;needle)</TT
2624
></DT
2625
><DD
2626
><P
2627
>This function checks whether or not the pattern string is an exact
2628
substring of the string being searched. It is similar to
2629
<TT
2630
CLASS="FUNCTION"
2631
>is_substr</TT
2632
> but uses exact matching only. In other
2633
words, leading or trailing spaces have to match exactly and will not
2634
match the beginning or end of the string being searched. The function
2635
takes two arguments, both of which can be arbitrary expressions, and
2636
returns a boolean. The difference between
2637
<TT
2638
CLASS="FUNCTION"
2639
>is_substr</TT
2640
> and <TT
2641
CLASS="FUNCTION"
2642
>is_xsubstr</TT
2643
> is
2644
illustrated by the following examples:</P
2645
><TABLE
2646
BORDER="5"
2647
BGCOLOR="#E0E0F0"
2648
WIDTH="70%"
2649
><TR
2650
><TD
2651
><PRE
2652
CLASS="PROGRAMLISTING"
2653
>    cdl_option MAGIC {
2654
        flavor data
2655
        default_value { "abracadabra" }
2656
    }
2657
    &#8230;
2658
    requires { is_substr(MAGIC,  " abra") }
2659
    requires { is_xsubstr(MAGIC, " abra") }</PRE
2660
></TD
2661
></TR
2662
></TABLE
2663
><P
2664
>The first goal will be satisfied because the leading space in the
2665
pattern matches the beginning of the string. The second goal will not
2666
be satisfied initialy because there is no exact match, so the
2667
inference engine is likely to update the value of
2668
<TT
2669
CLASS="VARNAME"
2670
>MAGIC</TT
2671
> to <TT
2672
CLASS="LITERAL"
2673
>abracadabra abra</TT
2674
> which
2675
does give an exact match.</P
2676
></DD
2677
><DT
2678
><TT
2679
CLASS="LITERAL"
2680
>version_cmp(A,&nbsp;B)</TT
2681
></DT
2682
><DD
2683
><P
2684
>This function is used primarily to check that a sufficiently recent
2685
<A
2686
HREF="package.versions.html"
2687
>version</A
2688
> of some other package
2689
is being used. It takes two arguments, both of which can be arbitrary
2690
expressions. In practice usually one of the arguments will be a
2691
reference to a package and the other will be a constant version
2692
string. The return value is -1 if the first argument is a more recent
2693
version then the second, 0 if the two arguments correspond to
2694
identical versions, and 1 if the first argument is an older version.
2695
For example the following constraint can be used to indicate that the
2696
current package depends on kernel functionality that only became
2697
available in version 1.3:</P
2698
><TABLE
2699
BORDER="5"
2700
BGCOLOR="#E0E0F0"
2701
WIDTH="70%"
2702
><TR
2703
><TD
2704
><PRE
2705
CLASS="PROGRAMLISTING"
2706
>    requires { version_cmp(CYGPKG_KERNEL, "v1.3") &#60;= 0 }</PRE
2707
></TD
2708
></TR
2709
></TABLE
2710
></DD
2711
></DL
2712
></DIV
2713
><DIV
2714
CLASS="NOTE"
2715
><BLOCKQUOTE
2716
CLASS="NOTE"
2717
><P
2718
><B
2719
>Note: </B
2720
>At this time it is not possible to define new functions inside a CDL
2721
script. Instead functions can only be added at the C++ level, usually
2722
by extending libcdl itself. This is partly because there is more to
2723
CDL functions than simple evaluation: associated with most functions
2724
is support for the inference engine, so that if a constraint involving
2725
a function is not currently satisfied the system may be able to find a
2726
solution automatically.</P
2727
></BLOCKQUOTE
2728
></DIV
2729
></DIV
2730
><DIV
2731
CLASS="SECT2"
2732
><H2
2733
CLASS="SECT2"
2734
><A
2735
NAME="LANGUAGE.GOAL-EXPRESSION">Goal Expressions</H2
2736
><P
2737
>The arguments to certain properties, notably <SPAN
2738
CLASS="PROPERTY"
2739
>requires</SPAN
2740
> and
2741
<SPAN
2742
CLASS="PROPERTY"
2743
>active_if</SPAN
2744
>, constitute a goal expression. As with an ordinary
2745
expression, all of the arguments get combined and then the expression
2746
parser takes over. The same care has to be taken with constant strings
2747
and anything else that may get processed by the Tcl interpreter, so
2748
often a goal expression is enclosed entirely in braces and the
2749
expression parsing code sees just a single argument.</P
2750
><P
2751
>A goal expression is basically just a sequence of ordinary
2752
expressions, for example:</P
2753
><TABLE
2754
BORDER="5"
2755
BGCOLOR="#E0E0F0"
2756
WIDTH="70%"
2757
><TR
2758
><TD
2759
><PRE
2760
CLASS="PROGRAMLISTING"
2761
>    requires { CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS
2762
               !CYGDBG_HAL_DEBUG_GDB_BREAK_SUPPORT
2763
               !CYGDBG_HAL_DEBUG_GDB_CTRLC_SUPPORT }</PRE
2764
></TD
2765
></TR
2766
></TABLE
2767
><P
2768
>This consists of three separate expressions, all of which should
2769
evaluate to a non-zero result. The same expression could be written
2770
as: </P
2771
><TABLE
2772
BORDER="5"
2773
BGCOLOR="#E0E0F0"
2774
WIDTH="70%"
2775
><TR
2776
><TD
2777
><PRE
2778
CLASS="PROGRAMLISTING"
2779
>    requires { CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS  &#38;&#38;
2780
               !CYGDBG_HAL_DEBUG_GDB_BREAK_SUPPORT &#38;&#38;
2781
               !CYGDBG_HAL_DEBUG_GDB_CTRLC_SUPPORT }</PRE
2782
></TD
2783
></TR
2784
></TABLE
2785
><P
2786
>Alternatively the following would have much the same effect:</P
2787
><TABLE
2788
BORDER="5"
2789
BGCOLOR="#E0E0F0"
2790
WIDTH="70%"
2791
><TR
2792
><TD
2793
><PRE
2794
CLASS="PROGRAMLISTING"
2795
>    requires CYGDBG_HAL_DEBUG_GDB_INCLUDE_STUBS
2796
    requires !CYGDBG_HAL_DEBUG_GDB_BREAK_SUPPORT
2797
    requires !CYGDBG_HAL_DEBUG_GDB_CTRLC_SUPPORT</PRE
2798
></TD
2799
></TR
2800
></TABLE
2801
><P
2802
>Selecting between these alternatives is largely a stylistic choice.
2803
The first is slightly more concise than the others. The second is more
2804
likely to appeal to mathematical purists. The third is more amenable
2805
to cutting and pasting.</P
2806
><P
2807
>The result of evaluating a goal expression is a boolean. If any part
2808
of the goal expression evaluates to the integer <TT
2809
CLASS="LITERAL"
2810
>0</TT
2811
>
2812
or an equivalent string then the result is false, otherwise it is
2813
true. </P
2814
><P
2815
>The term &#8220;goal&nbsp;expression&#8221; relates to the component
2816
framework's inference engine: it is a description of a goal that
2817
should be satisfied for a conflict-free configuration. If a <SPAN
2818
CLASS="PROPERTY"
2819
>requires</SPAN
2820
>
2821
constraint is not satisfied then the inference engine will examine the
2822
goal expression: if there is some way of changing the configuration
2823
that does not introduce new conflicts and that will cause the goal
2824
expression to evaluate to true, the conflict can be resolved.</P
2825
><P
2826
>The inference engine works with one conflict and hence one goal
2827
expression at a time. This means that there can be slightly different
2828
behavior if a constraint is specified using a single <SPAN
2829
CLASS="PROPERTY"
2830
>requires</SPAN
2831
>
2832
property or several different ones. Given the above example, suppose
2833
that none of the three conditions are satisfied. If a single goal
2834
expression is used then the inference engine might be able to satisfy
2835
only two of the three parts, but since the conflict as a whole cannot
2836
be resolved no part of the solution will be applied. Instead the user
2837
will have to resolve the entire conflict. If three separate goal
2838
expressions are used then the inference engine might well find
2839
solutions to two of them, leaving less work for the user. On the other
2840
hand, if a single goal expression is used then the inference engine
2841
has a bit more information to work with, and it might well find a
2842
solution to the entire conflict where it would be unable to find
2843
separate solutions for the three parts. Things can get very
2844
complicated, and in general component writers should not worry about
2845
the subtleties of the inference engine and how to manipulate its
2846
behavior. </P
2847
><P
2848
>It is possible to write ambiguous goal expressions, for example:</P
2849
><TABLE
2850
BORDER="5"
2851
BGCOLOR="#E0E0F0"
2852
WIDTH="70%"
2853
><TR
2854
><TD
2855
><PRE
2856
CLASS="PROGRAMLISTING"
2857
>    requires CYGNUM_LIBC_RAND_SEED -CYGNUM_LIBC_RAND_TRACE_LEVEL &gt; 5</PRE
2858
></TD
2859
></TR
2860
></TABLE
2861
><P
2862
>This could be parsed in two ways:</P
2863
><TABLE
2864
BORDER="5"
2865
BGCOLOR="#E0E0F0"
2866
WIDTH="70%"
2867
><TR
2868
><TD
2869
><PRE
2870
CLASS="PROGRAMLISTING"
2871
>    requires ((CYGNUM_LIBC_RAND_SEED - CYGNUM_LIBC_RAND_TRACE_LEVEL) &gt; 5)
2872
    requires CYGNUM_LIBC_RAND_SEED &amp;&amp; ((-CYGNUM_LIBC_RAND_TRACE_LEVEL) &gt; 5)</PRE
2873
></TD
2874
></TR
2875
></TABLE
2876
><P
2877
>The goal expression parsing code will always use the largest ordinary
2878
expression for each goal, so the first interpretation will be used.
2879
In such cases it is a good idea to use brackets and avoid possible
2880
confusion. </P
2881
></DIV
2882
><DIV
2883
CLASS="SECT2"
2884
><H2
2885
CLASS="SECT2"
2886
><A
2887
NAME="LANGUAGE.LIST-EXPRESSION">List Expressions</H2
2888
><P
2889
>The arguments to the <SPAN
2890
CLASS="PROPERTY"
2891
>legal_values</SPAN
2892
> property constitute a goal
2893
expression. As with an ordinary and goal expressions, all of the
2894
arguments get combined and then the expression parser takes over. The
2895
same care has to be taken with constant strings and anything else that
2896
may get processed by the Tcl interpreter, so often a list expression
2897
is enclosed entirely in braces and the expression parsing code sees
2898
just a single argument.</P
2899
><P
2900
>Most list expressions take one of two forms:</P
2901
><TABLE
2902
BORDER="5"
2903
BGCOLOR="#E0E0F0"
2904
WIDTH="70%"
2905
><TR
2906
><TD
2907
><PRE
2908
CLASS="PROGRAMLISTING"
2909
>    legal_values &lt;expr1&gt; &lt;expr2&gt; &lt;expr3&gt; ...
2910
    legal_values &lt;expr1&gt; to &lt;expr2&gt;</PRE
2911
></TD
2912
></TR
2913
></TABLE
2914
><P
2915
><TT
2916
CLASS="LITERAL"
2917
>expr1</TT
2918
>, <TT
2919
CLASS="LITERAL"
2920
>expr2</TT
2921
> and so on are
2922
ordinary expressions. Often these will be constants or references to
2923
calculated options in the architectural HAL package, but it is
2924
possible to use arbitrary expressions when necessary. The first syntax
2925
indicates a list of possible values, which need not be numerical. The
2926
second syntax indicates a numerical range: both sides of the
2927
<TT
2928
CLASS="LITERAL"
2929
>to</TT
2930
> must evaluate to a numerical value; if either
2931
side involves a floating point number then any floating point number
2932
in that range is legal; otherwise only integer values are legal;
2933
ranges are inclusive, so <TT
2934
CLASS="LITERAL"
2935
>4</TT
2936
> is a valid value given a
2937
list expression <TT
2938
CLASS="LITERAL"
2939
>1&nbsp;to&nbsp;</TT
2940
>; if one or both
2941
sides of the <TT
2942
CLASS="LITERAL"
2943
>to</TT
2944
> does not evaluate to a numerical
2945
value then this will result in a run-time conflict. The following
2946
examples illustrate these possibilities:</P
2947
><TABLE
2948
BORDER="5"
2949
BGCOLOR="#E0E0F0"
2950
WIDTH="70%"
2951
><TR
2952
><TD
2953
><PRE
2954
CLASS="PROGRAMLISTING"
2955
>    legal_values { "red" "green" "blue" }
2956
    legal_values 1 2 4 8 16
2957
    legal_values 1 to CYGARC_MAXINT
2958
    legal_values 1.0 to 2.0</PRE
2959
></TD
2960
></TR
2961
></TABLE
2962
><P
2963
>It is possible to combine the two syntaxes, for example:</P
2964
><TABLE
2965
BORDER="5"
2966
BGCOLOR="#E0E0F0"
2967
WIDTH="70%"
2968
><TR
2969
><TD
2970
><PRE
2971
CLASS="PROGRAMLISTING"
2972
>    legal_values 1 2 4 to CYGARC_MAXINT -1024 -20.0 to -10</PRE
2973
></TD
2974
></TR
2975
></TABLE
2976
><P
2977
>This indicates three legal values <TT
2978
CLASS="LITERAL"
2979
>1</TT
2980
>,
2981
<TT
2982
CLASS="LITERAL"
2983
>2</TT
2984
> and <TT
2985
CLASS="LITERAL"
2986
>-1024</TT
2987
>, one
2988
integer range <TT
2989
CLASS="LITERAL"
2990
>4&nbsp;to&nbsp;CYGARC_MAXINT</TT
2991
>, and one
2992
floating point range <TT
2993
CLASS="LITERAL"
2994
>-20.0&nbsp;to&nbsp;-10.0</TT
2995
>. In
2996
practice such list expressions are rarely useful.</P
2997
><P
2998
>The identifier <TT
2999
CLASS="VARNAME"
3000
>to</TT
3001
> is not reserved, so it is
3002
possible to have a configuration option with that name (although it
3003
violates every naming convention). Using that option in a list
3004
expression may however give unexpected results.</P
3005
><P
3006
>The graphical configuration tool uses the <SPAN
3007
CLASS="PROPERTY"
3008
>legal_values</SPAN
3009
> list
3010
expression to determine how best to let users manipulate the option's
3011
value. Different widgets will be appropriate for different lists, so
3012
<TT
3013
CLASS="LITERAL"
3014
>{&nbsp;"red"&nbsp;"green"&nbsp;"blue"&nbsp;}</TT
3015
> might
3016
involve a pull-down option menu, and
3017
<TT
3018
CLASS="LITERAL"
3019
>1&nbsp;to&nbsp;16</TT
3020
> could involve a spinner. The
3021
exact way in which <SPAN
3022
CLASS="PROPERTY"
3023
>legal_values</SPAN
3024
> lists get mapped on to GUI widgets
3025
is not defined and is subject to change at any time.</P
3026
><P
3027
>As with goal expressions, list expressions can be ambiguous. Consider
3028
the following hypothetical example:</P
3029
><TABLE
3030
BORDER="5"
3031
BGCOLOR="#E0E0F0"
3032
WIDTH="70%"
3033
><TR
3034
><TD
3035
><PRE
3036
CLASS="PROGRAMLISTING"
3037
>    legal_values CYGNUM_LIBC_RAND_SEED -CYGNUM_LIBC_RAND_TRACE_LEVEL</PRE
3038
></TD
3039
></TR
3040
></TABLE
3041
><P
3042
>This could be parsed in two ways:</P
3043
><TABLE
3044
BORDER="5"
3045
BGCOLOR="#E0E0F0"
3046
WIDTH="70%"
3047
><TR
3048
><TD
3049
><PRE
3050
CLASS="PROGRAMLISTING"
3051
>    legal_values (CYGNUM_LIBC_RAND_SEED - CYGNUM_LIBC_RAND_TRACE_LEVEL)
3052
    legal_values (CYGNUM_LIBC_RAND_SEED) (-CYGNUM_LIBC_RAND_TRACE_LEVEL)</PRE
3053
></TD
3054
></TR
3055
></TABLE
3056
><P
3057
>Both are legal. The list expression parsing code will always use the
3058
largest ordinary expression for each element, so the first
3059
interpretation will be used. In cases like this it is a good idea to
3060
use brackets and avoid possible confusion.</P
3061
></DIV
3062
></DIV
3063
><DIV
3064
CLASS="NAVFOOTER"
3065
><HR
3066
ALIGN="LEFT"
3067
WIDTH="100%"><TABLE
3068
SUMMARY="Footer navigation table"
3069
WIDTH="100%"
3070
BORDER="0"
3071
CELLPADDING="0"
3072
CELLSPACING="0"
3073
><TR
3074
><TD
3075
WIDTH="33%"
3076
ALIGN="left"
3077
VALIGN="top"
3078
><A
3079
HREF="language.tcl.html"
3080
ACCESSKEY="P"
3081
>Prev</A
3082
></TD
3083
><TD
3084
WIDTH="34%"
3085
ALIGN="center"
3086
VALIGN="top"
3087
><A
3088
HREF="cdl-guide.html"
3089
ACCESSKEY="H"
3090
>Home</A
3091
></TD
3092
><TD
3093
WIDTH="33%"
3094
ALIGN="right"
3095
VALIGN="top"
3096
><A
3097
HREF="language.interface.html"
3098
ACCESSKEY="N"
3099
>Next</A
3100
></TD
3101
></TR
3102
><TR
3103
><TD
3104
WIDTH="33%"
3105
ALIGN="left"
3106
VALIGN="top"
3107
>An Introduction to Tcl</TD
3108
><TD
3109
WIDTH="34%"
3110
ALIGN="center"
3111
VALIGN="top"
3112
><A
3113
HREF="language.html"
3114
ACCESSKEY="U"
3115
>Up</A
3116
></TD
3117
><TD
3118
WIDTH="33%"
3119
ALIGN="right"
3120
VALIGN="top"
3121
>Interfaces</TD
3122
></TR
3123
></TABLE
3124
></DIV
3125
></BODY
3126
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3127
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