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>eCos Reference Manual</TH
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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="hal-porting-structure.html"
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ACCESSKEY="P"
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>Prev</A
60
></TD
61
><TD
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WIDTH="80%"
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ALIGN="center"
64
VALIGN="bottom"
65
>Chapter 11. Porting Guide</TD
66
><TD
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WIDTH="10%"
68
ALIGN="right"
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VALIGN="bottom"
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><A
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HREF="hal-porting-coding-conventions.html"
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>Next</A
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><HR
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ALIGN="LEFT"
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WIDTH="100%"></DIV
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><DIV
81
CLASS="SECTION"
82
><H1
83
CLASS="SECTION"
84
><A
85
NAME="HAL-CALLING-IF">Virtual Vectors (eCos/ROM Monitor Calling Interface)</H1
86
><P
87
>Some eCos platforms have supported full debugging capabilities via
88
CygMon since day one. Platforms of the architectures PowerPC, ARM, and
89
SH do not provide those features unless a GDB stub is included in the
90
application.</P
91
><P
92
>This is going to change. All platforms will (eventually) support
93
all the debugging features by relying on a ROM/RAM calling interface
94
(also referred to as virtual vector table) provided by the ROM
95
monitor. This calling interface is based on the tables used by libbsp
96
and is thus backwards compatible with the existing CygMon supported
97
platforms.</P
98
><DIV
99
CLASS="SECTION"
100
><H2
101
CLASS="SECTION"
102
><A
103
NAME="HAL-PORTING-VIRTUAL-VECTORS">Virtual Vectors</H2
104
><P
105
>What are virtual vectors, what do they do, and why are they
106
needed?</P
107
><P
108
>"Virtual vectors" is the name of a table located at a static
109
location in the target address space. This table contains 64 vectors
110
that point to <SPAN
111
CLASS="emphasis"
112
><I
113
CLASS="EMPHASIS"
114
>service</I
115
></SPAN
116
> functions or data.</P
117
><P
118
>The fact that the vectors are always placed at the same location in
119
the address space means that both ROM and RAM startup configurations
120
can access these and thus the services pointed to.</P
121
><P
122
>The primary goal is to allow services to be provided by ROM
123
configurations (ROM monitors such as RedBoot in particular) with
124
<SPAN
125
CLASS="emphasis"
126
><I
127
CLASS="EMPHASIS"
128
>clients</I
129
></SPAN
130
> in RAM configurations being able to use these
131
services.</P
132
><P
133
>Without the table of pointers this would be impossible since the
134
ROM and RAM applications would be linked separately - in effect having
135
separate name spaces - preventing direct references from one to the
136
other.</P
137
><P
138
>This decoupling of service from client is needed by RedBoot,
139
allowing among other things debugging of applications which do not
140
contain debugging client code (stubs).</P
141
><DIV
142
CLASS="SECTION"
143
><H3
144
CLASS="SECTION"
145
><A
146
NAME="AEN8971">Initialization (or Mechanism vs. Policy)</H3
147
><P
148
>Virtual vectors are a <SPAN
149
CLASS="emphasis"
150
><I
151
CLASS="EMPHASIS"
152
>mechanism</I
153
></SPAN
154
> for decoupling services
155
from clients in the address space.</P
156
><P
157
>The mechanism allows services to be implemented by a ROM
158
monitor, a RAM application, to be switched out at run-time, to be
159
disabled by installing pointers to dummy functions, etc.</P
160
><P
161
>The appropriate use of the mechanism is specified loosely by a
162
<SPAN
163
CLASS="emphasis"
164
><I
165
CLASS="EMPHASIS"
166
>policy</I
167
></SPAN
168
>. The general policy dictates that the vectors are
169
initialized in whole by ROM monitors (built for ROM or RAM), or by
170
stand-alone applications.</P
171
><P
172
>For configurations relying on a ROM monitor environment, the policy
173
is to allow initialization on a service by service basis. The default
174
is to initialize all services, except COMMS services since these are
175
presumed to already be carrying a communication session to the
176
debugger / console which was used for launching the application.  This
177
means that the bulk of the code gets tested in normal builds, and not
178
just once in a blue moon when building new stubs or a ROM
179
configuration.</P
180
><P
181
>The configuration options are written to comply with this policy by
182
default, but can be overridden by the user if desired. Defaults
183
are:</P
184
><P
185
></P
186
><UL
187
><LI
188
><P
189
>For application development: the ROM monitor provides
190
debugging and diagnostic IO services, the RAM application relies
191
on these by default.</P
192
></LI
193
><LI
194
><P
195
>For production systems: the application contains all the
196
necessary services.</P
197
></LI
198
></UL
199
></DIV
200
><DIV
201
CLASS="SECTION"
202
><H3
203
CLASS="SECTION"
204
><A
205
NAME="AEN8985">Pros and Cons of Virtual Vectors</H3
206
><P
207
>There are pros and cons associated with the use of virtual
208
vectors. We do believe that the pros generally outweigh the cons by a
209
great margin, but there may be situations where the opposite is
210
true.</P
211
><P
212
>The use of the services are implemented by way of macros, meaning
213
that it is possible to circumvent the virtual vectors if
214
desired. There is (as yet) no implementation for doing this, but it is
215
possible.</P
216
><P
217
>Here is a list of pros and cons:</P
218
><P
219
></P
220
><DIV
221
CLASS="VARIABLELIST"
222
><DL
223
><DT
224
>Pro: Allows debugging without including stubs</DT
225
><DD
226
><P
227
>This is the primary reason for using virtual vectors. It
228
          allows the ROM monitor to provide most of the debugging
229
          infrastructure, requiring only the application to provide
230
          hooks for asynchronous debugger interrupts and for accessing
231
          kernel thread information.</P
232
></DD
233
><DT
234
>Pro: Allows debugging to be initiated from arbitrary
235
       channel</DT
236
><DD
237
><P
238
> While this is only true where the application does not
239
           actively override the debugging channel setup, it is a very
240
           nice feature during development. In particular it makes it
241
           possible to launch (and/or debug) applications via Ethernet
242
           even though the application configuration does not contain
243
           networking support.</P
244
></DD
245
><DT
246
>Pro: Image smaller due to services being provided by ROM
247
       monitor</DT
248
><DD
249
><P
250
>All service functions except HAL IO are included in the
251
           default configuration. But if these are all disabled the
252
           image for download will be a little smaller. Probably
253
           doesn't matter much for regular development, but it is a
254
           worthwhile saving for the 20000 daily tests run in the Red
255
           Hat eCos test farm.</P
256
></DD
257
><DT
258
>Con: The vectors add a layer of indirection, increasing application
259
       size and reducing performance.</DT
260
><DD
261
><P
262
>The size increase is a fraction of what is required to
263
           implement the services. So for RAM configurations there is
264
           a net saving, while for ROM configurations there is a small
265
           overhead.</P
266
><P
267
>The performance loss means little for most of the
268
           services (of which the most commonly used is diagnostic IO
269
           which happens via polled routines
270
           anyway).</P
271
></DD
272
><DT
273
>Con: The layer of indirection is another point of
274
       failure.</DT
275
><DD
276
><P
277
> The concern primarily being that of vectors being
278
           trashed by rogue writes from bad code, causing a complete
279
           loss of the service and possibly a crash.  But this does
280
           not differ much from a rogue write to anywhere else in the
281
           address space which could cause the same amount of
282
           mayhem. But it is arguably an additional point of failure
283
           for the service in question.</P
284
></DD
285
><DT
286
>Con: All the indirection stuff makes it harder to bring a HAL
287
       up</DT
288
><DD
289
><P
290
> This is a valid concern. However, seeing as most of the
291
           code in question is shared between all HALs and should
292
           remain unchanged over time, the risk of it being broken
293
           when a new HAL is being worked on should be
294
           minimal.</P
295
><P
296
> When starting a new port, be sure to implement the HAL
297
           IO drivers according to the scheme used in other drivers,
298
           and there should be no problem.</P
299
><P
300
> However, it is still possible to circumvent the vectors
301
           if they are suspect of causing problems: simply change the
302
           HAL_DIAG_INIT and HAL_DIAG_WRITE_CHAR macros to use the raw
303
           IO functions.</P
304
></DD
305
></DL
306
></DIV
307
></DIV
308
><DIV
309
CLASS="SECTION"
310
><H3
311
CLASS="SECTION"
312
><A
313
NAME="AEN9018">Available services</H3
314
><P
315
>The <TT
316
CLASS="FILENAME"
317
>hal_if.h</TT
318
> file in the common HAL defines the
319
complete list of available services. A few worth mentioning in
320
particular:</P
321
><P
322
></P
323
><UL
324
><LI
325
><P
326
>COMMS services. All HAL IO happens via the communication
327
        channels.</P
328
></LI
329
><LI
330
><P
331
>uS delay. Fine granularity (busy wait) delay function.</P
332
></LI
333
><LI
334
><P
335
>Reset. Allows a software initiated reset of the board.</P
336
></LI
337
></UL
338
></DIV
339
></DIV
340
><DIV
341
CLASS="SECTION"
342
><H2
343
CLASS="SECTION"
344
><A
345
NAME="AEN9029">The COMMS channels</H2
346
><P
347
>As all HAL IO happens via the COMMS channels these deserve to be
348
described in a little more detail. In particular the controls of where
349
diagnostic output is routed and how it is treated to allow for display
350
in debuggers.</P
351
><DIV
352
CLASS="SECTION"
353
><H3
354
CLASS="SECTION"
355
><A
356
NAME="AEN9032">Console and Debugging Channels</H3
357
><P
358
>There are two COMMS channels - one for console IO and one for
359
debugging IO. They can be individually configured to use any of the
360
actual IO ports (serial or Ethernet) available on the platform.</P
361
><P
362
>The console channel is used for any IO initiated by calling the
363
<TT
364
CLASS="FUNCTION"
365
>diag_*()</TT
366
> functions. Note that these should only be used during
367
development for debugging, assertion and possibly tracing
368
messages. All proper IO should happen via proper devices. This means
369
it should be possible to remove the HAL device drivers from production
370
configurations where assertions are disabled.</P
371
><P
372
>The debugging channel is used for communication between the
373
debugger and the stub which remotely controls the target for the
374
debugger (the stub runs on the target). This usually happens via some
375
protocol, encoding commands and replies in some suitable form.</P
376
><P
377
>Having two separate channels allows, e.g., for simple logging
378
without conflicts with the debugger or interactive IO which some
379
debuggers do not allow.</P
380
></DIV
381
><DIV
382
CLASS="SECTION"
383
><H3
384
CLASS="SECTION"
385
><A
386
NAME="AEN9039">Mangling</H3
387
><P
388
>As debuggers usually have a protocol using specialized commands
389
when communicating with the stub on the target, sending out text as
390
raw ASCII from the target on the same channel will either result in
391
protocol errors (with loss of control over the target) or the text may
392
just be ignored as junk by the debugger.</P
393
><P
394
>To get around this, some debuggers have a special command for text
395
output. Mangling is the process of encoding diagnostic ASCII text
396
output in the form specified by the debugger protocol.</P
397
><P
398
>When it is necessary to use mangling, i.e. when writing console
399
output to the same port used for debugging, a mangler function is
400
installed on the console channel which mangles the text and passes it
401
on to the debugger channel.</P
402
></DIV
403
><DIV
404
CLASS="SECTION"
405
><H3
406
CLASS="SECTION"
407
><A
408
NAME="AEN9044">Controlling the Console Channel</H3
409
><P
410
>Console output configuration is either inherited from the ROM
411
monitor launching the application, or it is specified by the
412
application. This is controlled by the new option
413
<TT
414
CLASS="LITERAL"
415
>CYGSEM_HAL_VIRTUAL_VECTOR_INHERIT_CONSOLE</TT
416
> which
417
defaults to enabled when the configuration is set to use a ROM
418
monitor.</P
419
><P
420
>If the user wants to specify the console configuration in the
421
application image, there are two new options that are used for
422
this.</P
423
><P
424
>Defaults are to direct diagnostic output via a mangler to the
425
debugging channel (<TT
426
CLASS="LITERAL"
427
>CYGDBG_HAL_DIAG_TO_DEBUG_CHAN</TT
428
>
429
enabled). The mangler type is controlled by the option
430
<TT
431
CLASS="LITERAL"
432
>CYGSEM_HAL_DIAG_MANGLER</TT
433
>. At present there are only
434
two mangler types:</P
435
><P
436
></P
437
><DIV
438
CLASS="VARIABLELIST"
439
><DL
440
><DT
441
><SPAN
442
CLASS="ACRONYM"
443
>GDB</SPAN
444
></DT
445
><DD
446
><P
447
> This causes a mangler appropriate for debugging with GDB to be
448
       installed on the console channel.</P
449
></DD
450
><DT
451
>None</DT
452
><DD
453
><P
454
> This causes a NULL mangler to be installed on the console
455
        channel.  It will redirect the IO to/from the debug channel
456
        without mangling of the data. This option differs from setting
457
        the console channel to the same IO port as the debugging
458
        channel in that it will keep redirecting data to the debugging
459
        channel even if that is changed to some other port.</P
460
></DD
461
></DL
462
></DIV
463
><P
464
>Finally, by disabling <TT
465
CLASS="LITERAL"
466
>CYGDBG_HAL_DIAG_TO_DEBUG_CHAN</TT
467
>, the diagnostic
468
output is directed in raw form to the specified console IO port.</P
469
><P
470
>In summary this results in the following common configuration
471
scenarios for RAM startup configurations:</P
472
><P
473
></P
474
><UL
475
><LI
476
><P
477
> For regular debugging with diagnostic output appearing in the
478
     debugger, mangling is enabled and stubs disabled.</P
479
><P
480
>Diagnostic output appears via the debugging channel as
481
     initiated by the ROM monitor, allowing for correct behavior
482
     whether the application was launched via serial or Ethernet, from
483
     the RedBoot command line or from a debugger.</P
484
></LI
485
><LI
486
><P
487
> For debugging with raw diagnostic output, mangling is
488
     disabled.</P
489
><P
490
> Debugging session continues as initiated by the ROM monitor,
491
     whether the application was launched via serial or
492
     Ethernet. Diagnostic output is directed at the IO port configured
493
     in the application configuration.</P
494
><DIV
495
CLASS="NOTE"
496
><BLOCKQUOTE
497
CLASS="NOTE"
498
><P
499
><B
500
>Note:: </B
501
> There is one caveat to be aware of. If the
502
       application uses proper devices (be it serial or Ethernet) on
503
       the same ports as those used by the ROM monitor, the
504
       connections initiated by the ROM monitor will be
505
       terminated.</P
506
></BLOCKQUOTE
507
></DIV
508
></LI
509
></UL
510
><P
511
>And for ROM startup configurations:</P
512
><P
513
></P
514
><UL
515
><LI
516
><P
517
> Production configuration with raw output and no debugging
518
     features (configured for RAM or ROM), mangling is disabled, no
519
     stubs are included.</P
520
><P
521
>Diagnostic output appears (in unmangled form) on the specified
522
     IO port.</P
523
></LI
524
><LI
525
><P
526
> RedBoot configuration, includes debugging features and necessary
527
     mangling.</P
528
><P
529
>Diagnostic and debugging output port is auto-selected by the
530
     first connection to any of the supported IO ports. Can change
531
     from interactive mode to debugging mode when a debugger is
532
     detected - when this happens a mangler will be installed as
533
     required.</P
534
></LI
535
><LI
536
><P
537
> GDB stubs configuration (obsoleted by RedBoot configuration),
538
     includes debugging features, mangling is hardwired to GDB
539
     protocol.</P
540
><P
541
>Diagnostic and debugging output is hardwired to configured IO
542
     ports, mangling is hardwired.</P
543
></LI
544
></UL
545
></DIV
546
><DIV
547
CLASS="SECTION"
548
><H3
549
CLASS="SECTION"
550
><A
551
NAME="AEN9086">Footnote: Design Reasoning for Control of Console Channel</H3
552
><P
553
>The current code for controlling the console channel is a
554
replacement for an older implementation which had some shortcomings
555
which addressed by the new implementation.</P
556
><P
557
>This is what the old implementation did: on initialization it would
558
check if the CDL configured console channel differed from the active
559
debug channel - and if so, set the console channel, thereby disabling
560
mangling.</P
561
><P
562
>The idea was that whatever channel was configured to be used for
563
console (i.e., diagnostic output) in the application was what should
564
be used. Also, it meant that if debug and console channels were
565
normally the same, a changed console channel would imply a request for
566
unmangled output.</P
567
><P
568
>But this prevented at least two things:</P
569
><P
570
></P
571
><UL
572
><LI
573
><P
574
> It was impossible to inherit the existing connection by which
575
     the application was launched (either by RedBoot commands via
576
     telnet, or by via a debugger).</P
577
><P
578
>This was mostly a problem on targets supporting Ethernet
579
     access since the diagnostic output would not be returned via the
580
     Ethernet connection, but on the configured serial port.</P
581
><P
582
>The problem also occurred on any targets with multiple serial
583
     ports where the ROM monitor was configured to use a different
584
     port than the CDL defaults.</P
585
></LI
586
><LI
587
><P
588
> Proper control of when to mangle or just write out raw ASCII
589
        text.</P
590
><P
591
>Sometimes it's desirable to disable mangling, even if the
592
     channel specified is the same as that used for debugging. This
593
     usually happens if GDB is used to download the application, but
594
     direct interaction with the application on the same channel is
595
     desired (GDB protocol only allows output from the target, no
596
     input).</P
597
></LI
598
></UL
599
></DIV
600
></DIV
601
><DIV
602
CLASS="SECTION"
603
><H2
604
CLASS="SECTION"
605
><A
606
NAME="AEN9100">The calling Interface API</H2
607
><P
608
>The calling interface API is defined by hal_if.h and hal_if.c in
609
hal/common.</P
610
><P
611
>The API provides a set of services. Different platforms, or
612
different versions of the ROM monitor for a single platform, may
613
implement fewer or extra service. The table has room for growth, and
614
any entries which are not supported map to a NOP-service (when called
615
it returns 0 (<TT
616
CLASS="LITERAL"
617
>false</TT
618
>)).</P
619
><P
620
>A client of a service should either be selected by configuration,
621
or have suitable fall back alternatives in case the feature is not
622
implemented by the ROM monitor.</P
623
><DIV
624
CLASS="NOTE"
625
><BLOCKQUOTE
626
CLASS="NOTE"
627
><P
628
><B
629
>Note:: </B
630
>Checking for unimplemented service when this may be a data
631
field/pointer instead of a function: suggest reserving the last entry
632
in the table as the NOP-service pointer. Then clients can compare a
633
service entry with this pointer to determine whether it's initialized
634
or not.</P
635
></BLOCKQUOTE
636
></DIV
637
><P
638
>The header file <TT
639
CLASS="FILENAME"
640
>cyg/hal/hal_if.h</TT
641
> defines
642
 the table layout and accessor macros (allowing primitive type
643
 checking and alternative implementations should it become necessary).</P
644
><P
645
>The source file <TT
646
CLASS="FILENAME"
647
>hal_if.c</TT
648
> defines the table
649
 initialization function. All HALs should call this during platform
650
 initialization - the table will get initialized according to
651
 configuration.  Also defined here are wrapper functions which map
652
 between the calling interface API and the API of the used eCos
653
 functions.</P
654
><DIV
655
CLASS="SECTION"
656
><H3
657
CLASS="SECTION"
658
><A
659
NAME="AEN9113">Implemented Services</H3
660
><P
661
>This is a brief description of the services, some of which are
662
described in further detail below.</P
663
><P
664
></P
665
><DIV
666
CLASS="VARIABLELIST"
667
><DL
668
><DT
669
><TT
670
CLASS="LITERAL"
671
>VERSION</TT
672
></DT
673
><DD
674
><P
675
>Version of table. Serves as a way to check for how many
676
        features are available in the table. This is the index of the
677
        last service in the table.</P
678
></DD
679
><DT
680
><TT
681
CLASS="LITERAL"
682
>KILL_VECTOR</TT
683
></DT
684
><DD
685
><P
686
>[Presently unused by the stub code, but initialized] This
687
        vector defines a function to execute when the system receives
688
        a kill signal from the debugger. It is initialized with the
689
        reset function (see below), but the application (or eCos) can
690
        override it if necessary.</P
691
></DD
692
><DT
693
><TT
694
CLASS="LITERAL"
695
>CONSOLE_PROCS</TT
696
></DT
697
><DD
698
><P
699
>The communication procedure table used for console IO
700
        (see <A
701
HREF="hal-calling-if.html#HAL-PORTING-IO-CHANNELS"
702
>the Section called <I
703
>IO channels</I
704
></A
705
>.</P
706
></DD
707
><DT
708
><TT
709
CLASS="LITERAL"
710
>DEBUG_PROCS</TT
711
></DT
712
><DD
713
><P
714
>The communication procedure table used for debugger IO
715
        (see <A
716
HREF="hal-calling-if.html#HAL-PORTING-IO-CHANNELS"
717
>the Section called <I
718
>IO channels</I
719
></A
720
>).</P
721
></DD
722
><DT
723
><TT
724
CLASS="LITERAL"
725
>FLUSH_DCACHE</TT
726
></DT
727
><DD
728
><P
729
>Flushes the data cache for the specified
730
        region. Some implementations may flush the entire data cache.</P
731
></DD
732
><DT
733
><TT
734
CLASS="LITERAL"
735
>FLUSH_ICACHE</TT
736
></DT
737
><DD
738
><P
739
>Flushes (invalidates) the instruction cache
740
        for the specified region. Some implementations may flush the
741
        entire instruction cache.</P
742
></DD
743
><DT
744
><TT
745
CLASS="LITERAL"
746
>SET_DEBUG_COMM</TT
747
></DT
748
><DD
749
><P
750
>Change debugging communication channel.</P
751
></DD
752
><DT
753
><TT
754
CLASS="LITERAL"
755
>SET_CONSOLE_COMM</TT
756
></DT
757
><DD
758
><P
759
>Change console communication channel.</P
760
></DD
761
><DT
762
><TT
763
CLASS="LITERAL"
764
>DBG_SYSCALL</TT
765
></DT
766
><DD
767
><P
768
>Vector used to communication between debugger functions in
769
        ROM and in RAM. RAM eCos configurations may install a function
770
        pointer here which the ROM monitor uses to get thread
771
        information from the kernel running in RAM.</P
772
></DD
773
><DT
774
><TT
775
CLASS="LITERAL"
776
>RESET</TT
777
></DT
778
><DD
779
><P
780
>Resets the board on call. If it is not possible to reset
781
        the board from software, it will jump to the ROM entry point
782
        which will perform a "software" reset of the board.</P
783
></DD
784
><DT
785
><TT
786
CLASS="LITERAL"
787
>CONSOLE_INTERRUPT_FLAG</TT
788
></DT
789
><DD
790
><P
791
>Set if a debugger interrupt request was detected while
792
        processing console IO. Allows the actual breakpoint action to
793
        be handled after return to RAM, ensuring proper backtraces
794
        etc.</P
795
></DD
796
><DT
797
><TT
798
CLASS="LITERAL"
799
>DELAY_US</TT
800
></DT
801
><DD
802
><P
803
>Will delay the specified number of microseconds. The
804
        precision is platform dependent to some extend - a small value
805
        (&#60;100us) is likely to cause bigger delays than requested.</P
806
></DD
807
><DT
808
><TT
809
CLASS="LITERAL"
810
>FLASH_CFG_OP</TT
811
></DT
812
><DD
813
><P
814
>For accessing configuration settings kept in flash memory.</P
815
></DD
816
><DT
817
><TT
818
CLASS="LITERAL"
819
>INSTALL_BPT_FN</TT
820
></DT
821
><DD
822
><P
823
>Installs a breakpoint at the specified address. This is
824
        used by the asynchronous breakpoint support
825
        (see ).</P
826
></DD
827
></DL
828
></DIV
829
></DIV
830
><DIV
831
CLASS="SECTION"
832
><H3
833
CLASS="SECTION"
834
><A
835
NAME="AEN9189">Compatibility</H3
836
><P
837
>When a platform is changed to support the calling interface,
838
applications will use it if so configured. That means that if an
839
application is run on a platform with an older ROM monitor, the
840
service is almost guaranteed to fail.</P
841
><P
842
>For this reason, applications should only use Console Comm for HAL
843
diagnostics output if explicitly configured to do so
844
(<TT
845
CLASS="LITERAL"
846
>CYGSEM_HAL_VIRTUAL_VECTOR_DIAG</TT
847
>).</P
848
><P
849
>As for asynchronous GDB interrupts, the service will always be
850
used. This is likely to cause a crash under older ROM monitors, but
851
this crash may be caught by the debugger. The old workaround still
852
applies: if you need asynchronous breakpoints or thread debugging
853
under older ROM monitors, you may have to include the debugging
854
support when configuring eCos.</P
855
></DIV
856
><DIV
857
CLASS="SECTION"
858
><H3
859
CLASS="SECTION"
860
><A
861
NAME="AEN9195">Implementation details</H3
862
><P
863
>During the startup of a ROM monitor, the calling table will be
864
initialized. This also happens if eCos is configured <SPAN
865
CLASS="emphasis"
866
><I
867
CLASS="EMPHASIS"
868
>not</I
869
></SPAN
870
> to rely on
871
a ROM monitor.</P
872
><DIV
873
CLASS="NOTE"
874
><BLOCKQUOTE
875
CLASS="NOTE"
876
><P
877
><B
878
>Note:: </B
879
> There is reserved space (256 bytes) for the vector
880
table whether it gets used or not. This may be something that we want
881
to change if we ever have to shave off every last byte for a given
882
target.</P
883
></BLOCKQUOTE
884
></DIV
885
><P
886
>If thread debugging features are enabled, the function for accessing
887
the thread information gets registered in the table during startup of
888
a RAM startup configuration.</P
889
><P
890
>Further implementation details are described where the service itself
891
is described.</P
892
></DIV
893
><DIV
894
CLASS="SECTION"
895
><H3
896
CLASS="SECTION"
897
><A
898
NAME="AEN9204">New Platform Ports</H3
899
><P
900
>The <TT
901
CLASS="FUNCTION"
902
>hal_platform_init()</TT
903
> function must call
904
<TT
905
CLASS="FUNCTION"
906
>hal_if_init()</TT
907
>.</P
908
><P
909
>The HAL serial driver must, when called via
910
<TT
911
CLASS="FUNCTION"
912
>cyg_hal_plf_comms_init()</TT
913
> must initialize the
914
communication channels.</P
915
><P
916
>The <TT
917
CLASS="FUNCTION"
918
>reset()</TT
919
> function defined in
920
<TT
921
CLASS="FILENAME"
922
>hal_if.c</TT
923
> will attempt to do a hardware reset, but
924
if this fails it will fall back to simply jumping to the reset
925
entry-point. On most platforms the startup initialization will go a
926
long way to reset the target to a sane state (there will be
927
exceptions, of course). For this reason, make sure to define
928
<TT
929
CLASS="LITERAL"
930
>HAL_STUB_PLATFORM_RESET_ENTRY</TT
931
> in plf_stub.h.</P
932
><P
933
>All debugging features must be in place in order for the debugging
934
services to be functional. See general platform porting notes.</P
935
></DIV
936
><DIV
937
CLASS="SECTION"
938
><H3
939
CLASS="SECTION"
940
><A
941
NAME="AEN9216">New architecture ports</H3
942
><P
943
>There are no specific requirements for a new architecture port in
944
order to support the calling interface, but the basic debugging
945
features must be in place. See general architecture porting notes.</P
946
></DIV
947
></DIV
948
><DIV
949
CLASS="SECTION"
950
><H2
951
CLASS="SECTION"
952
><A
953
NAME="HAL-PORTING-IO-CHANNELS">IO channels</H2
954
><P
955
>The calling interface provides procedure tables for all IO channels on
956
the platform. These are used for console (diagnostic) and debugger IO,
957
allowing a ROM monitor to provided all the needed IO routines. At
958
the same time, this makes it easy to switch console/debugger channels
959
at run-time (the old implementation had hardwired drivers for console
960
and debugger IO, preventing these to change at run-time).</P
961
><P
962
>The hal_if provides wrappers which interface these services to the
963
eCos infrastructure diagnostics routines. This is done in a way which
964
ensures proper string mangling of the diagnostics output when required
965
(e.g. O-packetization when using a GDB compatible ROM monitor).</P
966
><DIV
967
CLASS="SECTION"
968
><H3
969
CLASS="SECTION"
970
><A
971
NAME="AEN9223">Available Procedures</H3
972
><P
973
>This is a brief description of the procedures</P
974
><P
975
></P
976
><DIV
977
CLASS="VARIABLELIST"
978
><DL
979
><DT
980
><TT
981
CLASS="LITERAL"
982
>CH_DATA</TT
983
></DT
984
><DD
985
><P
986
>Pointer to the controller IO base (or a pointer to a per-device
987
    structure if more data than the IO base is required). All the
988
    procedures below are called with this data item as the first
989
    argument.</P
990
></DD
991
><DT
992
><TT
993
CLASS="LITERAL"
994
>WRITE</TT
995
></DT
996
><DD
997
><P
998
>Writes the buffer to the device.</P
999
></DD
1000
><DT
1001
><TT
1002
CLASS="LITERAL"
1003
>READ</TT
1004
></DT
1005
><DD
1006
><P
1007
>Fills a buffer from the device.</P
1008
></DD
1009
><DT
1010
><TT
1011
CLASS="LITERAL"
1012
>PUTC</TT
1013
></DT
1014
><DD
1015
><P
1016
>Write a character to the device.</P
1017
></DD
1018
><DT
1019
><TT
1020
CLASS="LITERAL"
1021
>GETC</TT
1022
></DT
1023
><DD
1024
><P
1025
>Read a character from the device.</P
1026
></DD
1027
><DT
1028
><TT
1029
CLASS="LITERAL"
1030
>CONTROL</TT
1031
></DT
1032
><DD
1033
><P
1034
>Device feature control. Second argument specifies function:</P
1035
><P
1036
></P
1037
><DIV
1038
CLASS="VARIABLELIST"
1039
><DL
1040
><DT
1041
><TT
1042
CLASS="LITERAL"
1043
>SETBAUD</TT
1044
></DT
1045
><DD
1046
><P
1047
>Changes baud rate.</P
1048
></DD
1049
><DT
1050
><TT
1051
CLASS="LITERAL"
1052
>GETBAUD</TT
1053
></DT
1054
><DD
1055
><P
1056
>Returns the current baud rate.</P
1057
></DD
1058
><DT
1059
><TT
1060
CLASS="LITERAL"
1061
>INSTALL_DBG_ISR</TT
1062
></DT
1063
><DD
1064
><P
1065
>[Unused]</P
1066
></DD
1067
><DT
1068
><TT
1069
CLASS="LITERAL"
1070
>REMOVE_DBG_ISR</TT
1071
></DT
1072
><DD
1073
><P
1074
>[Unused]</P
1075
></DD
1076
><DT
1077
><TT
1078
CLASS="LITERAL"
1079
>IRQ_DISABLE</TT
1080
></DT
1081
><DD
1082
><P
1083
>Disable debugging receive interrupts on the device.</P
1084
></DD
1085
><DT
1086
><TT
1087
CLASS="LITERAL"
1088
>IRQ_ENABLE</TT
1089
></DT
1090
><DD
1091
><P
1092
>Enable debugging receive interrupts on the device.</P
1093
></DD
1094
><DT
1095
><TT
1096
CLASS="LITERAL"
1097
>DBG_ISR_VECTOR</TT
1098
></DT
1099
><DD
1100
><P
1101
>Returns the ISR vector used by the device for debugging
1102
        receive interrupts.</P
1103
></DD
1104
><DT
1105
><TT
1106
CLASS="LITERAL"
1107
>SET_TIMEOUT</TT
1108
></DT
1109
><DD
1110
><P
1111
>Set GETC timeout in milliseconds.</P
1112
></DD
1113
><DT
1114
><TT
1115
CLASS="LITERAL"
1116
>FLUSH_OUTPUT</TT
1117
></DT
1118
><DD
1119
><P
1120
>Forces driver to flush data in its buffers. Note
1121
            that this may not affect hardware buffers
1122
        (e.g. FIFOs).</P
1123
></DD
1124
></DL
1125
></DIV
1126
></DD
1127
><DT
1128
><TT
1129
CLASS="LITERAL"
1130
>DBG_ISR</TT
1131
></DT
1132
><DD
1133
><P
1134
>ISR used to handle receive interrupts from the
1135
        device (see ).</P
1136
></DD
1137
><DT
1138
><TT
1139
CLASS="LITERAL"
1140
>GETC_TIMEOUT</TT
1141
></DT
1142
><DD
1143
><P
1144
>Read a character from the device with timeout.</P
1145
></DD
1146
></DL
1147
></DIV
1148
></DIV
1149
><DIV
1150
CLASS="SECTION"
1151
><H3
1152
CLASS="SECTION"
1153
><A
1154
NAME="AEN9313">Usage</H3
1155
><P
1156
>The standard eCos diagnostics IO functions use the channel
1157
procedure table when <TT
1158
CLASS="LITERAL"
1159
>CYGSEM_HAL_VIRTUAL_VECTOR_DIAG</TT
1160
> is enabled. That
1161
means that when you use diag_printf (or the libc printf function) the
1162
stream goes through the selected console procedure table. If you use
1163
the virtual vector function SET_CONSOLE_COMM you can change the device
1164
which the diagnostics output goes to at run-time.</P
1165
><P
1166
>You can also use the table functions directly if desired
1167
(regardless of the <TT
1168
CLASS="LITERAL"
1169
>CYGSEM_HAL_VIRTUAL_VECTOR_DIAG</TT
1170
> setting - assuming
1171
the ROM monitor provides the services). Here is a small example which
1172
changes the console to use channel 2, fetches the comm procs pointer
1173
and calls the write function from that table, then restores the
1174
console to the original channel:</P
1175
><TABLE
1176
BORDER="5"
1177
BGCOLOR="#E0E0F0"
1178
WIDTH="70%"
1179
><TR
1180
><TD
1181
><PRE
1182
CLASS="PROGRAMLISTING"
1183
>#define T "Hello World!\n"
1184
 
1185
int
1186
main(void)
1187
{
1188
    hal_virtual_comm_table_t* comm;
1189
    int cur = CYGACC_CALL_IF_SET_CONSOLE_COMM(CYGNUM_CALL_IF_SET_COMM_ID_QUERY_CURRENT);
1190
 
1191
    CYGACC_CALL_IF_SET_CONSOLE_COMM(2);
1192
 
1193
    comm = CYGACC_CALL_IF_CONSOLE_PROCS();
1194
    CYGACC_COMM_IF_WRITE(*comm, T, strlen(T));
1195
 
1196
    CYGACC_CALL_IF_SET_CONSOLE_COMM(cur);
1197
}</PRE
1198
></TD
1199
></TR
1200
></TABLE
1201
><P
1202
>Beware that if doing something like the above, you should only do
1203
it to a channel which does not have GDB at the other end: GDB ignores
1204
raw data, so you would not see the output.</P
1205
></DIV
1206
><DIV
1207
CLASS="SECTION"
1208
><H3
1209
CLASS="SECTION"
1210
><A
1211
NAME="AEN9321">Compatibility</H3
1212
><P
1213
>The use of this service is controlled by the option
1214
<TT
1215
CLASS="LITERAL"
1216
>CYGSEM_HAL_VIRTUAL_VECTOR_DIAG</TT
1217
> which is disabled per default on most
1218
older platforms (thus preserving backwards compatibility with older
1219
stubs). On newer ports, this option should always be set.</P
1220
></DIV
1221
><DIV
1222
CLASS="SECTION"
1223
><H3
1224
CLASS="SECTION"
1225
><A
1226
NAME="AEN9325">Implementation Details</H3
1227
><P
1228
>There is an array of procedure tables (raw comm channels) for each
1229
IO device of the platform which get initialized by the ROM monitor, or
1230
optionally by a RAM startup configuration (allowing the RAM
1231
configuration to take full control of the target).  In addition to
1232
this, there's a special table which is used to hold mangler
1233
procedures.</P
1234
><P
1235
>The vector table defines which of these channels are selected for
1236
console and debugging IO respectively: console entry can be empty,
1237
point to mangler channel, or point to a raw channel. The debugger
1238
entry should always point to a raw channel.</P
1239
><P
1240
>During normal console output (i.e., diagnostic output) the console
1241
table will be used to handle IO if defined. If not defined, the debug
1242
table will be used.</P
1243
><P
1244
>This means that debuggers (such as GDB) which require text streams
1245
to be mangled (O-packetized in the case of GDB), can rely on the ROM
1246
monitor install mangling IO routines in the special mangler table and
1247
select this for console output. The mangler will pass the mangled data
1248
on to the selected debugging channel.</P
1249
><P
1250
>If the eCos configuration specifies a different console channel
1251
from that used by the debugger, the console entry will point to the
1252
selected raw channel, thus overriding any mangler provided by the ROM
1253
monitor.</P
1254
><P
1255
>See hal_if_diag_* routines in hal_if.c for more details of the stream
1256
path of diagnostic output. See <TT
1257
CLASS="FUNCTION"
1258
>cyg_hal_gdb_diag_*()</TT
1259
> routines in
1260
<TT
1261
CLASS="FILENAME"
1262
>hal_stub.c</TT
1263
> for the mangler used for GDB communication.</P
1264
></DIV
1265
><DIV
1266
CLASS="SECTION"
1267
><H3
1268
CLASS="SECTION"
1269
><A
1270
NAME="AEN9335">New Platform Ports</H3
1271
><P
1272
>Define CDL options <TT
1273
CLASS="LITERAL"
1274
>CYGNUM_HAL_VIRTUAL_VECTOR_COMM_CHANNELS</TT
1275
>,
1276
<TT
1277
CLASS="LITERAL"
1278
>CYGNUM_HAL_VIRTUAL_VECTOR_DEBUG_CHANNEL</TT
1279
>, and
1280
<TT
1281
CLASS="LITERAL"
1282
>CYGNUM_HAL_VIRTUAL_VECTOR_CONSOLE_CHANNEL</TT
1283
>.</P
1284
><P
1285
>If <TT
1286
CLASS="LITERAL"
1287
>CYGSEM_HAL_VIRTUAL_VECTOR_DIAG</TT
1288
> is set, make sure the infra diag
1289
code uses the hal_if diag functions:</P
1290
><TABLE
1291
BORDER="5"
1292
BGCOLOR="#E0E0F0"
1293
WIDTH="70%"
1294
><TR
1295
><TD
1296
><PRE
1297
CLASS="PROGRAMLISTING"
1298
> #define HAL_DIAG_INIT() hal_if_diag_init()
1299
 #define HAL_DIAG_WRITE_CHAR(_c_) hal_if_diag_write_char(_c_)
1300
 #define HAL_DIAG_READ_CHAR(_c_) hal_if_diag_read_char(&#38;_c_)</PRE
1301
></TD
1302
></TR
1303
></TABLE
1304
><P
1305
>In addition to the above functions, the platform HAL must also
1306
provide a function cyg_hal_plf_comms_init which initializes the
1307
drivers and the channel procedure tables.</P
1308
><P
1309
>Most of the other functionality in the table is more or less
1310
possible to copy unchanged from existing ports. Some care is necessary
1311
though to ensure the proper handling of interrupt vectors and timeouts
1312
for various devices handled by the same driver. See PowerPC/Cogent
1313
platform HAL for an example implementation.</P
1314
><DIV
1315
CLASS="NOTE"
1316
><BLOCKQUOTE
1317
CLASS="NOTE"
1318
><P
1319
><B
1320
>Note:: </B
1321
> When vector table console code is <SPAN
1322
CLASS="emphasis"
1323
><I
1324
CLASS="EMPHASIS"
1325
>not</I
1326
></SPAN
1327
> used,
1328
the platform HAL must map the HAL_DIAG_INIT, HAL_DIAG_WRITE_CHAR and
1329
HAL_DIAG_READ_CHAR macros directly to the low-level IO functions,
1330
hardwired to use a compile-time configured channel.</P
1331
></BLOCKQUOTE
1332
></DIV
1333
><DIV
1334
CLASS="NOTE"
1335
><BLOCKQUOTE
1336
CLASS="NOTE"
1337
><P
1338
><B
1339
>Note:: </B
1340
> On old ports the hardwired <TT
1341
CLASS="LITERAL"
1342
>HAL_DIAG_INIT</TT
1343
>,
1344
<TT
1345
CLASS="LITERAL"
1346
>HAL_DIAG_WRITE_CHAR</TT
1347
> and
1348
<TT
1349
CLASS="LITERAL"
1350
>HAL_DIAG_READ_CHAR</TT
1351
> implementations will also
1352
contain code to O-packetize the output for GDB. This should
1353
<SPAN
1354
CLASS="emphasis"
1355
><I
1356
CLASS="EMPHASIS"
1357
>not</I
1358
></SPAN
1359
> be adopted for new ports! On new ports the
1360
ROM monitor is guaranteed to provide the necessary mangling via the
1361
vector table. The hardwired configuration should be reserved for ROM
1362
startups where achieving minimal image size is crucial.</P
1363
></BLOCKQUOTE
1364
></DIV
1365
></DIV
1366
></DIV
1367
></DIV
1368
><DIV
1369
CLASS="NAVFOOTER"
1370
><HR
1371
ALIGN="LEFT"
1372
WIDTH="100%"><TABLE
1373
SUMMARY="Footer navigation table"
1374
WIDTH="100%"
1375
BORDER="0"
1376
CELLPADDING="0"
1377
CELLSPACING="0"
1378
><TR
1379
><TD
1380
WIDTH="33%"
1381
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