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\input texinfo        @c                    -*- Texinfo -*-
2
@setfilename porting.info
3
@settitle Embed with GNU
4
 
5
@c
6
@c This file documents the process of porting the GNU tools to an
7
@c embedded environment.
8
@c
9
 
10
@finalout
11
@setchapternewpage off
12
@iftex
13
@raggedbottom
14
@global@parindent=0pt
15
@end iftex
16
 
17
@titlepage
18
@title Embed With GNU
19
@subtitle Porting The GNU Tools To Embedded Systems
20
@sp 4
21
@subtitle Spring 1995
22
@subtitle Very *Rough* Draft
23
@author Rob Savoye - Cygnus Support
24
@page
25
 
26
@vskip 0pt plus 1filll
27
Copyright @copyright{} 1993, 1994, 1995 Cygnus Support
28
 
29
Permission is granted to make and distribute verbatim copies of
30
this manual provided the copyright notice and this permission notice
31
are preserved on all copies.
32
 
33
Permission is granted to copy and distribute modified versions of this
34
manual under the conditions for verbatim copying, provided also that
35
the entire resulting derived work is distributed under the terms of a
36
permission notice identical to this one.
37
 
38
Permission is granted to copy and distribute translations of this manual
39
into another language, under the above conditions for modified versions.
40
@end titlepage
41
 
42
@ifinfo
43
@format
44
START-INFO-DIR-ENTRY
45
* Embed with GNU: (porting-).         Embed with GNU
46
END-INFO-DIR-ENTRY
47
@end format
48
Copyright (c) 1993, 1994, 1995 Cygnus Support
49
 
50
Permission is granted to make and distribute verbatim copies of
51
this manual provided the copyright notice and this permission notice
52
are preserved on all copies.
53
 
54
Permission is granted to copy and distribute modified versions of this
55
manual under the conditions for verbatim copying, provided also that
56
the entire resulting derived work is distributed under the terms of a
57
permission notice identical to this one.
58
 
59
Permission is granted to copy and distribute translations of this manual
60
into another language, under the above conditions for modified versions.
61
 
62
@node Top
63
@top Embed with GNU
64
 
65
@end ifinfo
66
@strong{Rough Draft}
67
 
68
The goal of this document is to gather all the information needed to
69
port the GNU tools to a new embedded target in one place. This will
70
duplicate some info found in the other manual for the GNU tools, but
71
this should be all you'll need.
72
 
73
@menu
74
* Libgloss::            Libgloss, a library of board support packages.
75
* GCC::                 Porting GCC/G++ to a new embedded target.
76
* Libraries::           Making Newlib run on an new embedded target.
77
* GDB::                 Making GDB understand a new back end.
78
* Binutils::            Using the GNU binary utilities.
79
* Code Listings::       Listings of the commented source code from the
80
                        text.
81
@end menu
82
 
83
@node Libgloss, GCC, Top, Top
84
@chapter Libgloss
85
Libgloss is a library for all the details that usually get glossed over.
86
This library refers to things like startup code, and usually I/O support
87
for @code{gcc} and @code{C library}. The C library used through out
88
this manual is @code{newlib}. Newlib is a ANSI conforming C library
89
developed by Cygnus Support. Libgloss could easily be made to
90
support other C libraries, and it can be used standalone as well. The
91
standalone configuration is typically used when bringing up new
92
hardware, or on small systems.
93
 
94
For a long time, these details were part of newlib. This approach worked
95
well when a complete tool chain only had to support one system. A tool
96
chain refers to the series of compiler passes required to produce a
97
binary file that will run on an embedded system. For C, the passes are
98
cpp, gcc, gas, ld. Cpp is the preprocessor, which process all the header
99
files and macros. Gcc is the compiler, which produces assembler from the
100
processed C files. Gas assembles the code into object files, and then ld
101
combines the object files and binds the code to addresses and produces
102
the final executable image.
103
 
104
Most of the time a tool chain does only have to support one target
105
execution environment. An example of this would be a tool chain for the
106
AMD 29k processor family. All of the execution environments for this
107
processor are have the same interface, the same memory map, and the same
108
I/O code. In this case all of the support code is in newlib/sys/FIXME.
109
Libgloss's creation was forced initially be the @code{cpu32} processor
110
family. There are many different execution environments for this line,
111
and they vary wildly. newlib itself has only has a few dependencies that
112
it needs for each target. These are explained later in this doc. The
113
hardware dependent part of newlib was reorganized into a separate
114
directory structure within newlib called the stub dirs. It was initially
115
called this because most of the routines newlib needs for a target were
116
simple stubs that do nothing, but return a value to the application. They
117
only exist so the linker can produce a final executable image. This work
118
was done during the early part of 1993.
119
 
120
After a while it became apparent that this approach of isolating the
121
hardware and systems files together made sense. Around this same time
122
the stub dirs were made to run standalone, mostly so it could also be
123
used to support GDB's remote debugging needs. At this time it was
124
decided to move the stub dirs out of newlib and into it's own separate
125
library so it could be used standalone, and be included in various other
126
GNU tools without having to bring in all of newlib, which is large. The
127
new library is called Libgloss, for Gnu Low-level OS support.
128
 
129
@menu
130
* Supported targets::           What targets libgloss currently
131
                                supports.
132
* Building libgloss::           How to configure and built libgloss
133
                                for a target.
134
@end menu
135
 
136
@node Supported targets, Building libgloss, Libgloss, Libgloss
137
@subsection Supported Targets
138
Currently libgloss is being used for the following targets:
139
 
140
@menu
141
* Sparclite::                   Fujitsu's sparclite.
142
* CPU32::                       Various m68k based targets.
143
* Mips::                        Mips code based targets.
144
* PA-RISC::                     Precision Risc Organization..
145
@end menu
146
 
147
@node Sparclite, CPU32, , Supported targets
148
@subsection Sparclite Targets Supported
149
@c FIXME: put links to the docs in etc/targetdoc
150
This is for the Fujitsu Sparclite family of processors. Currently this
151
covers the ex930, ex931, ex932, ex933, and the ex934. In addition to the
152
I/O code a startup file, this has a GDB debug-stub that gets linked into
153
your application. This is an exception handler style debug stub. For
154
more info, see the section on Porting GDB. @ref{GDB,,Porting GDB}.
155
 
156
The Fujitsu eval boards use a host based terminal program to load and
157
execute programs on the target. This program, @code{pciuh} is relatively
158
new (in 1994) and it replaced the previous ROM monitor which had the
159
shell in the ROM. GDB uses the the GDB remote protocol, the relevant
160
source files from the gdb sources are remote-sparcl.c. The debug stub is
161
part of libgloss and is called sparcl-stub.c.
162
 
163
@node CPU32, Mips, Sparclite, Supported targets
164
@subsection Motorola CPU32 Targets supported
165
This refers to Motorola's m68k based CPU32 processor family. The crt0.S
166
startup file should be usable with any target environment, and it's
167
mostly just the I/O code and linker scripts that vary. Currently there
168
is support for the Motorola MVME line of 6U VME boards and IDP
169
line of eval boards. All of the
170
Motorola VME boards run @code{Bug}, a ROM based debug monitor.
171
This monitor has the feature of using user level traps to do I/O, so
172
this code should be portable to other MVME boards with little if any
173
change. The startup file also can remain unchanged. About the only thing
174
that varies is the address for where the text section begins. This can
175
be accomplished either in the linker script, or on the command line
176
using the @samp{-Ttext [address]}.
177
 
178
@c FIXME: Intermetrics or ISI wrote rom68k ?
179
There is also support for the @code{rom68k} monitor as shipped on
180
Motorola's IDP eval board line. This code should be portable across the
181
range of CPU's the board supports. There is also GDB support for this
182
target environment in the GDB source tree. The relevant files are
183
gdb/monitor.c, monitor.h, and rom58k-rom.c. The usage of these files is
184
discussed in the GDB section.
185
 
186
@node Mips, PA-RISC, CPU32, Supported targets
187
@subsection Mips core Targets Supported
188
The Crt0 startup file should run on any mips target that doesn't require
189
additional hardware initialization. The I/O code so far only supports a
190
custom LSI33k based RAID disk controller board. It should easy to
191
change to support the IDT line of eval boards. Currently the two
192
debugging protocols supported by GDB for mips targets is IDT's mips
193
debug protocol, and a customized hybrid of the standard GDB remote
194
protocol and GDB's standard ROM monitor support. Included here is the
195
debug stub for the hybrid monitor. This supports the LSI33k processor,
196
and only has support for the GDB protocol commands @code{g}, @code{G},
197
@code{m}, @code{M}, which basically only supports the register and
198
memory reading and writing commands. This is part of libgloss and is
199
called lsi33k-stub.c.
200
 
201
The crt0.S should also work on the IDT line of eval boards, but has only
202
been run on the LSI33k for now. There is no I/O support for the IDT eval
203
board at this time. The current I/O code is for a customized version of
204
LSI's @code{pmon} ROM monitor. This uses entry points into the monitor,
205
and should easily port to other versions of the pmon monitor. Pmon is
206
distributed in source by LSI.
207
 
208
@node PA-RISC, , Mips, Supported targets
209
@subsection PA-RISC Targets Supported
210
This supports the various boards manufactured by the HP-PRO consortium.
211
This is a group of companies all making variations on the PA-RISC
212
processor. Currently supported are ports to the WinBond @samp{Cougar}
213
board based around their w89k version of the PA. Also supported is the
214
Oki op50n processor.
215
 
216
There is also included, but never built an unfinished port to the HP 743
217
board. This board is the main CPU board for the HP700 line of industrial
218
computers. This target isn't exactly an embedded system, in fact it's
219
really only designed to load and run HP-UX. Still, the crt0.S and I/O
220
code are fully working. It is included mostly because their is a barely
221
functioning exception handler GDB debug stub, and I hope somebody could
222
use it. The other PRO targets all use GDB's ability to talk to ROM
223
monitors directly, so it doesn't need a debug stub. There is also a
224
utility that will produce a bootable file by HP's ROM monitor. This is
225
all included in the hopes somebody else will finish it. :-)
226
 
227
Both the WinBond board and the Oki board download srecords. The WinBond
228
board also has support for loading the SOM files as produced by the
229
native compiler on HP-UX. WinBond supplies a set of DOS programs that
230
will allow the loading of files via a bidirectional parallel port. This
231
has never been tested with the output of GNU SOM, as this manual is
232
mostly for Unix based systems.
233
 
234
@node Building libgloss, , Supported targets, Libgloss
235
@subsection Configuring and building libgloss.
236
 
237
Libgloss uses an autoconf based script to configure. Autoconf scripts
238
are portable shell scripts that are generated from a configure.in file.
239
Configure input scripts are based themselves on m4. Most configure
240
scripts run a series of tests to determine features the various
241
supported features of the target. For features that can't be determined
242
by a feature test, a makefile fragment is merged in. The configure
243
process leaves creates a Makefile in the build directory. For libgloss,
244
there are only a few configure options of importance. These are --target
245
and --srcdir.
246
 
247
Typically libgloss is built in a separate tree just for objects. In this
248
manner, it's possible to have a single source tree, and multiple object
249
trees. If you only need to configure for a single target environment,
250
then you can configure in the source tree. The argument for --target is
251
a config string. It's usually safest to use the full canonical opposed
252
to the target alias. So, to configure for a CPU32 (m68k) with a separate
253
source tree, use:
254
 
255
@smallexample
256
../src/libgloss/configure --verbose --target m68k-coff
257
@end smallexample
258
 
259
The configure script is in the source tree. When configure is invoked
260
it will determine it's own source tree, so the --srcdir is would be
261
redundant here.
262
 
263
Once libgloss is configured, @code{make} is sufficient to build it. The
264
default values for @code{Makefiles} are typically correct for all
265
supported systems. The test cases in the testsuite will also built
266
automatically as opposed to a @code{make check}, where test binaries
267
aren't built till test time. This is mostly cause the libgloss
268
testsuites are the last thing built when building the entire GNU source
269
tree, so it's a good test of all the other compilation passes.
270
 
271
The default values for the Makefiles are set in the Makefile fragment
272
merged in during configuration. This fragment typically has rules like
273
 
274
@smallexample
275
CC_FOR_TARGET = `if [ -f $$@{OBJROOT@}/gcc/xgcc ] ; \
276
        then echo $@{OBJROOT@}/gcc/xgcc -B$@{OBJROOT@}/gcc/ ; \
277
        else t='$@{program_transform_name@}'; echo gcc | sed -e '' $$t ; fi`
278
@end smallexample
279
 
280
Basically this is a runtime test to determine whether there are freshly
281
built executables for the other main passes of the GNU tools. If there
282
isn't an executable built in the same object tree, then
283
@emph{transformed}the generic tool name (like gcc) is transformed to the
284
name typically used in GNU cross compilers. The  names are
285
typically based on the target's canonical name, so if you've configured
286
for @code{m68k-coff} the transformed name is @code{m68k-coff-gcc} in
287
this case. If you install with aliases or rename the tools, this won't
288
work, and it will always look for tools in the path. You can force the a
289
different name to work by reconfiguring with the
290
@code{--program-transform-name} option to configure. This option takes a
291
sed script like this @code{-e s,^,m68k-coff-,} which produces tools
292
using the standard names (at least here at Cygnus).
293
 
294
The search for the other GNU development tools is exactly the same idea.
295
This technique gets messier when build options like @code{-msoft-float}
296
support are used. The Makefile fragments set the @code{MUTILIB}
297
variable, and if it is set, the search path is modified. If the linking
298
is done with an installed cross compiler, then none of this needs to be
299
used. This is done so libgloss will build automatically with a fresh,
300
and uninstalled object tree. It also makes it easier to debug the other
301
tools using libgloss's test suites.
302
 
303
@node GCC, Libraries, Libgloss, Top
304
@chapter Porting GCC
305
 
306
Porting GCC requires two things, neither of which has anything to do
307
with GCC. If GCC already supports a processor type, then all the work in
308
porting GCC is really a linker issue. All GCC has to do is produce
309
assembler output in the proper syntax. Most of the work is done by the
310
linker, which is described elsewhere.
311
 
312
Mostly all GCC does is format the command line for the linker pass. The
313
command line for GCC is set in the various config subdirectories of gcc.
314
The options of interest to us are @code{CPP_SPEC} and
315
@code{STARTFILE_SPEC}. CPP_SPEC sets the builtin defines for your
316
environment. If you support multiple environments with the same
317
processor, then OS specific defines will need to be elsewhere.
318
@c FIXME: Check these names
319
 
320
@code{STARTFILE_SPEC}
321
 
322
Once you have linker support, GCC will be able to produce a fully linked
323
executable image. The only @emph{part} of GCC that the linker wants is a
324
crt0.o, and a memory map. If you plan on running any programs that do
325
I/O of any kind, you'll need to write support for the C library, which
326
is described elsewhere.
327
 
328
@menu
329
* Overview::            An overview as to the compilation passes.
330
* Options::             Useful GCC options for embedded systems.
331
@end menu
332
 
333
@node Overview, Options, , GCC
334
@subsection Compilation passes
335
 
336
GCC by itself only compiles the C or C++ code into assembler. Typically
337
GCC invokes all the passes required for you. These passes are cpp, cc1,
338
gas, ld. @code{cpp} is the C preprocessor. This will merge in the
339
include files, expand all macros definitions, and process all the
340
@code{#ifdef} sections. To see the output of ccp, invoke gcc with the
341
@code{-E} option, and the preprocessed file will be printed on the
342
stdout. cc1 is the actual compiler pass that produces the assembler for
343
the processed file. GCC is actually only a driver program for all the
344
compiler passes. It will format command line options for the other passes.
345
The usual command line GCC uses for the final link phase will have LD
346
link in the startup code and additional libraries by default.
347
 
348
GNU AS started it's life to only function as a compiler pass, but
349
these days it can also be used as a source level assembler. When used as
350
a source level assembler, it has a companion assembler preprocessor
351
called @code{gasp}. This has a syntax similar to most other assembler
352
macros packages. GAS emits a relocatable object file from the assembler
353
source. The object file contains the executable part of the application,
354
and debug symbols.
355
 
356
LD is responsible for resolving the addresses and symbols to something
357
that will be fully self-contained. Some RTOS's use relocatable object
358
file formats like @code{a.out}, but more commonly the final image will
359
only use absolute addresses for symbols. This enables code to be burned
360
into PROMS as well. Although LD can produce an executable image, there
361
is usually a hidden object file called @code{crt0.o} that is required as
362
startup code.  With this startup code and a memory map, the executable
363
image will actually run on the target environment. @ref{Crt0,,Startup
364
Files}.
365
 
366
The startup code usually defines a special symbol like @code{_start}
367
that is the default base address for the application, and the first
368
symbol in the executable image. If you plan to use any routines from the
369
standard C library, you'll also need to implement the functions that
370
this library is dependent on. @ref{Libraries,,Porting Newlib}.
371
 
372
@node Options, , Overview, GCC
373
@c FIXME: Need stuff here about -fpic, -Ttext, etc...
374
 
375
Options for the various development tools are covered in more detail
376
elsewhere. Still, the amount of options can be an overwhelming amount of
377
stuff, so the options most suited to embedded systems are summarized
378
here. If you use GCC as the main driver for all the passes, most of the
379
linker options can be passed directly to the compiler. There are also
380
GCC options that control how the GCC driver formats the command line
381
arguments for the linker.
382
 
383
@menu
384
* GCC Options::         Options for the compiler.
385
* GAS Options::         Options for the assembler.
386
* LD Options::          Options for the linker.
387
@end menu
388
 
389
@node GCC Options, GAS Options, , Options
390
Most of the GCC options that we're interested control how the GCC driver
391
formats the options for the linker pass.
392
 
393
@c FIXME: this section is still under work.
394
@table @code
395
@item -nostartfiles
396
@item -nostdlib
397
@item -Xlinker
398
Pass the next option directly to the linker.
399
 
400
@item -v
401
@item -fpic
402
@end table
403
 
404
@node GAS Options, LD Options, GCC Options, Options
405
@c FIXME: Needs stuff here
406
 
407
@node LD Options, , GAS Options, Options
408
@c FIXME: Needs stuff here
409
 
410
 
411
@node Libraries, GDB, GCC, Top
412
@chapter Porting newlib
413
 
414
@menu
415
* Crt0::                Crt0.S.
416
* Linker Scripts::      Linker scripts for memory management.
417
* What to do now::      Tricks for manipulating formats.
418
* Libc::                Making libc work.
419
@end menu
420
 
421
@node Crt0, Linker Scripts, , Libraries
422
@section Crt0, the main startup file
423
 
424
To make a program that has been compiled with GCC to run, you
425
need to write some startup code. The initial piece of startup code is
426
called a crt0. (C RunTime 0) This is usually written in assembler, and
427
it's object gets linked in first, and bootstraps the rest of the
428
application when executed. This file needs to do the following things.
429
 
430
@enumerate
431
@item
432
Initialize anything that needs it. This init section varies. If you are
433
developing an application that gets download to a ROM monitor, then
434
there is usually no need for any special initialization. The ROM monitor
435
handles it for you.
436
 
437
If you plan to burn your code in a ROM, then the crt0 typically has to
438
do all the hardware initialization that is required to run an
439
application. This can include things like initializing serial ports or
440
run a memory check. It all depends on the hardware.
441
 
442
@item
443
Zero the BSS section. This is for uninitialized data. All the addresses in
444
this section need to be initialized to zero so that programs that forget
445
to check new variables default value will get unpredictable results.
446
 
447
@item
448
Call main()
449
This is what basically starts things running. If your ROM monitor
450
supports it, then first setup argc and argv for command line arguments
451
and an environment pointer. Then branch to main(). For G++ the the main
452
routine gets a branch to __main inserted by the code generator at the
453
very top.  __main() is used by G++ to initialize it's internal tables.
454
__main() then returns back to your original main() and your code gets
455
executed.
456
 
457
@item
458
Call exit()
459
After main() has returned, you need to cleanup things and return control
460
of the hardware from the application. On some hardware, there is nothing
461
to return to, especially if your program is in ROM.  Sometimes the best
462
thing to do in this case is do a hardware reset, or branch back to the
463
start address all over again.
464
 
465
When there is a ROM monitor present, usually a user trap can be called
466
and then the ROM takes over. Pick a safe vector with no side
467
effects. Some ROMs have a builtin trap handler just for this case.
468
@end enumerate
469
portable between all the m68k based boards we have here.
470
@ref{crt0.S,,Example Crt0.S}.
471
 
472
 
473
@smallexample
474
/* ANSI concatenation macros.  */
475
 
476
#define CONCAT1(a, b) CONCAT2(a, b)
477
#define CONCAT2(a, b) a ## b
478
@end smallexample
479
These we'll use later.
480
 
481
@smallexample
482
/* These are predefined by new versions of GNU cpp.  */
483
 
484
#ifndef __USER_LABEL_PREFIX__
485
#define __USER_LABEL_PREFIX__ _
486
#endif
487
 
488
/* Use the right prefix for global labels.  */
489
#define SYM(x) CONCAT1 (__USER_LABEL_PREFIX__, x)
490
 
491
@end smallexample
492
 
493
These macros are to make this code portable between both @emph{COFF} and
494
@emph{a.out}. @emph{COFF} always has an @var{_ (underline)} prepended on
495
the front of all global symbol names. @emph{a.out} has none.
496
 
497
@smallexample
498
#ifndef __REGISTER_PREFIX__
499
#define __REGISTER_PREFIX__
500
#endif
501
 
502
/* Use the right prefix for registers.  */
503
#define REG(x) CONCAT1 (__REGISTER_PREFIX__, x)
504
 
505
#define d0 REG (d0)
506
#define d1 REG (d1)
507
#define d2 REG (d2)
508
#define d3 REG (d3)
509
#define d4 REG (d4)
510
#define d5 REG (d5)
511
#define d6 REG (d6)
512
#define d7 REG (d7)
513
#define a0 REG (a0)
514
#define a1 REG (a1)
515
#define a2 REG (a2)
516
#define a3 REG (a3)
517
#define a4 REG (a4)
518
#define a5 REG (a5)
519
#define a6 REG (a6)
520
#define fp REG (fp)
521
#define sp REG (sp)
522
@end smallexample
523
 
524
This is for portability between assemblers. Some register names have a
525
@var{%} or @var{$} prepended to the register name.
526
 
527
@smallexample
528
/*
529
 * Set up some room for a stack. We just grab a chunk of memory.
530
 */
531
        .set    stack_size, 0x2000
532
        .comm   SYM (stack), stack_size
533
@end smallexample
534
 
535
Set up space for the stack. This can also be done in the linker script,
536
but it typically gets done here.
537
 
538
@smallexample
539
/*
540
 * Define an empty environment.
541
 */
542
        .data
543
        .align 2
544
SYM (environ):
545
        .long 0
546
@end smallexample
547
 
548
Set up an empty space for the environment. This is bogus on any most ROM
549
monitor, but we setup a valid address for it, and pass it to main. At
550
least that way if an application checks for it, it won't crash.
551
 
552
@smallexample
553
        .align  2
554
        .text
555
        .global SYM (stack)
556
 
557
        .global SYM (main)
558
        .global SYM (exit)
559
/*
560
 * This really should be __bss_start, not SYM (__bss_start).
561
 */
562
        .global __bss_start
563
@end smallexample
564
 
565
Setup a few global symbols that get used elsewhere. @var{__bss_start}
566
needs to be unchanged, as it's setup by the linker script.
567
 
568
@smallexample
569
/*
570
 * start -- set things up so the application will run.
571
 */
572
SYM (start):
573
        link    a6, #-8
574
        moveal  #SYM (stack) + stack_size, sp
575
 
576
/*
577
 * zerobss -- zero out the bss section
578
 */
579
        moveal  #__bss_start, a0
580
        moveal  #SYM (end), a1
581
1:
582
        movel   #0, (a0)
583
        leal    4(a0), a0
584
        cmpal   a0, a1
585
        bne     1b
586
@end smallexample
587
 
588
The global symbol @code{start} is used by the linker as the default
589
address to use for the @code{.text} section. then it zeros the
590
@code{.bss} section so the uninitialized data will all be cleared. Some
591
programs have wild side effects from having the .bss section let
592
uncleared. Particularly it causes problems with some implementations of
593
@code{malloc}.
594
 
595
@smallexample
596
/*
597
 * Call the main routine from the application to get it going.
598
 * main (argc, argv, environ)
599
 * We pass argv as a pointer to NULL.
600
 */
601
        pea     0
602
        pea     SYM (environ)
603
        pea     sp@@(4)
604
        pea     0
605
        jsr     SYM (main)
606
        movel   d0, sp@@-
607
@end smallexample
608
 
609
Setup the environment pointer and jump to @code{main()}. When
610
@code{main()} returns, it drops down to the @code{exit} routine below.
611
 
612
@smallexample
613
/*
614
 * _exit -- Exit from the application. Normally we cause a user trap
615
 *          to return to the ROM monitor for another run.
616
 */
617
SYM (exit):
618
        trap    #0
619
@end smallexample
620
 
621
Implementing @code{exit} here is easy. Both the @code{rom68k} and @code{bug}
622
can handle a user caused exception of @code{zero} with no side effects.
623
Although the @code{bug} monitor has a user caused trap that will return
624
control to the ROM monitor, this solution has been more portable.
625
 
626
@node Linker Scripts, What to do now, Crt0, Libraries
627
@section Linker scripts for memory management
628
 
629
The linker script sets up the memory map of an application. It also
630
sets up default values for variables used elsewhere by sbrk() and the
631
crt0. These default variables are typically called @code{_bss_start} and
632
@code{_end}.
633
 
634
For G++, the constructor and destructor tables must also be setup here.
635
The actual section names vary depending on the object file format. For
636
@code{a.out} and @code{coff}, the three main sections are @code{.text},
637
@code{.data}, and @code{.bss}.
638
 
639
Now that you have an image, you can test to make sure it got the
640
memory map right. You can do this by having the linker create a memory
641
map (by using the @code{-Map} option), or afterwards by using @code{nm} to
642
check a few critical addresses like @code{start}, @code{bss_end}, and
643
@code{_etext}.
644
 
645
Here's a breakdown of a linker script for a m68k based target board.
646
See the file @code{libgloss/m68k/idp.ld}, or go to the appendixes in
647
the end of the manual. @ref{idp.ld,,Example Linker Script}.
648
 
649
@smallexample
650
STARTUP(crt0.o)
651
OUTPUT_ARCH(m68k)
652
INPUT(idp.o)
653
SEARCH_DIR(.)
654
__DYNAMIC  =  0;
655
@end smallexample
656
 
657
The @code{STARTUP} command loads the file specified so that it's
658
first. In this case it also doubles to load the file as well, because
659
the m68k-coff configuration defaults to not linking in the crt0.o by
660
default. It assumes that the developer probably has their own crt0.o.
661
This behavior is controlled in the config file for each architecture.
662
It's a macro called @code{STARTFILE_SPEC}, and if it's set to
663
@code{null}, then when @code{gcc} formats it's command line, it doesn't
664
add @code{crto.o}. Any file name can be specified here, but the default
665
is always @code{crt0.o}.
666
 
667
Course if you only use @code{ld} to link, then the control of whether or
668
not to link in @code{crt0.o} is done on the command line. If you have
669
multiple crto files, then you can leave this out all together, and link
670
in the @code{crt0.o} in the makefile, or by having different linker
671
scripts. Sometimes this is done for initializing floating point
672
optionally, or to add device support.
673
 
674
The @code{OUTPUT_ARCH} sets architecture the output file is for.
675
 
676
@code{INPUT} loads in the file specified. In this case, it's a relocated
677
library that contains the definitions for the low-level functions need
678
by libc.a.  This could have also been specified on the command line, but
679
as it's always needed, it might as well be here as a default.
680
@code{SEARCH_DIR} specifies the path to look for files, and
681
@code{_DYNAMIC} means in this case there are no shared libraries.
682
 
683
@c FIXME: Check the linker manual to make sure this is accurate.
684
@smallexample
685
/*
686
 * Setup the memory map of the MC68ec0x0 Board (IDP)
687
 * stack grows up towards high memory. This works for
688
 * both the rom68k and the mon68k monitors.
689
 */
690
MEMORY
691
@{
692
  ram     : ORIGIN = 0x10000, LENGTH = 2M
693
@}
694
@end smallexample
695
 
696
This specifies a name for a section that can be referred to later in the
697
script. In this case, it's only a pointer to the beginning of free RAM
698
space, with an upper limit at 2M. If the output file exceeds the upper
699
limit, it will produce an error message.
700
 
701
@smallexample
702
/*
703
 * stick everything in ram (of course)
704
 */
705
SECTIONS
706
@{
707
  .text :
708
  @{
709
    CREATE_OBJECT_SYMBOLS
710
    *(.text)
711
     etext  =  .;
712
     __CTOR_LIST__ = .;
713
     LONG((__CTOR_END__ - __CTOR_LIST__) / 4 - 2)
714
    *(.ctors)
715
     LONG(0)
716
     __CTOR_END__ = .;
717
     __DTOR_LIST__ = .;
718
     LONG((__DTOR_END__ - __DTOR_LIST__) / 4 - 2)
719
    *(.dtors)
720
     LONG(0)
721
     __DTOR_END__ = .;
722
    *(.lit)
723
    *(.shdata)
724
  @}  > ram
725
  .shbss SIZEOF(.text) + ADDR(.text) :  @{
726
    *(.shbss)
727
  @}
728
@end smallexample
729
 
730
Set up the @code{.text} section. In a @code{COFF} file, .text is where
731
all the actual instructions are. This also sets up the @emph{CONTRUCTOR}
732
and the @emph{DESTRUCTOR} tables for @code{G++}. Notice that the section
733
description redirects itself to the @emph{ram} variable setup earlier.
734
 
735
@smallexample
736
  .talias :      @{ @}  > ram
737
  .data  : @{
738
    *(.data)
739
    CONSTRUCTORS
740
    _edata  =  .;
741
  @} > ram
742
@end smallexample
743
 
744
Setup the @code{.data} section. In a @code{coff} file, this is where all
745
he initialized data goes. @code{CONSTRUCTORS} is a special command used
746
by @code{ld}.
747
 
748
@smallexample
749
  .bss SIZEOF(.data) + ADDR(.data) :
750
  @{
751
   __bss_start = ALIGN(0x8);
752
   *(.bss)
753
   *(COMMON)
754
      end = ALIGN(0x8);
755
      _end = ALIGN(0x8);
756
      __end = ALIGN(0x8);
757
  @}
758
  .mstack  : @{ @}  > ram
759
  .rstack  : @{ @}  > ram
760
  .stab  . (NOLOAD) :
761
  @{
762
    [ .stab ]
763
  @}
764
  .stabstr  . (NOLOAD) :
765
  @{
766
    [ .stabstr ]
767
  @}
768
@}
769
@end smallexample
770
 
771
Setup the @code{.bss} section. In a @code{COFF} file, this is where
772
unitialized data goes. The symbols @code{_bss_start} and @code{_end}
773
are setup here for use by the @code{crt0.o} when it zero's the
774
@code{.bss} section.
775
 
776
 
777
@node What to do now, Libc, Linker Scripts, Libraries
778
@section What to do when you have a binary image
779
 
780
A few ROM monitors load binary images, typically @code{a.out}, but most all
781
will load an @code{srecord}. An srecord is an ASCII representation of a binary
782
image. At it's simplest, an srecord is an address, followed by a byte
783
count, followed by the bytes, and a 2's compliment checksum. A whole
784
srecord file has an optional @emph{start} record, and a required @emph{end}
785
record. To make an srecord from a binary image, the GNU @code{objcopy} program
786
is used. This will read the image and make an srecord from it. To do
787
this, invoke objcopy like this: @code{objcopy -O srec infile outfile}. Most
788
PROM burners also read srecords or a similar format. Use @code{objdump -i} to
789
get a list of support object files types for your architecture.
790
 
791
@node Libc, , What to do now, Libraries
792
@section Libraries
793
 
794
This describes @code{newlib}, a freely available libc replacement. Most
795
applications use calls in the standard C library. When initially linking
796
in libc.a, several I/O functions are undefined. If you don't plan on
797
doing any I/O, then you're OK, otherwise they need to be created. These
798
routines are read, write, open, close. sbrk, and kill. Open & close
799
don't need to be fully supported unless you have a filesystems, so
800
typically they are stubbed out. Kill is also a stub, since you can't do
801
process control on an embedded system.
802
 
803
Sbrk() is only needed by applications that do dynamic memory
804
allocation. It's uses the symbol @code{_end} that is setup in the linker
805
script. It also requires a compile time option to set the upper size
806
limit on the heap space. This leaves us with read and write, which are
807
required for serial I/O. Usually these two routines are written in C,
808
and call a lower level function for the actual I/O operation. These two
809
lowest level I/O primitives are inbyte() and outbyte(), and are also
810
used by GDB back ends if you've written an exception handler. Some
811
systems also implement a havebyte() for input as well.
812
 
813
Other commonly included functions are routines for manipulating
814
LED's on the target (if they exist) or low level debug help. Typically a
815
putnum() for printing words and bytes as a hex number is helpful, as
816
well as a low-level print() to output simple strings.
817
 
818
As libg++ uses the I/O routines in libc.a, if read and write work,
819
then libg++ will also work with no additional changes.
820
 
821
@menu
822
* I/O Support::         Functions that make serial I/O work.
823
* Memory Support::      Memory support.
824
* Misc Support::        Other needed functions.
825
* Debugging::            Useful Debugging Functions
826
@end menu
827
 
828
@node I/O Support, Memory Support, , Libc
829
@subsection Making I/O work
830
 
831
@node Memory Support, Misc Support, I/O Support, Libc
832
@subsection Routines for dynamic memory allocation
833
To support using any of the memory functions, you need to implement
834
sbrk(). @code{malloc()}, @code{calloc()}, and @code{realloc()} all call
835
@code{sbrk()} at there lowest level. @code{caddr_t} is defined elsewhere
836
as @code{char *}. @code{RAMSIZE} is presently a compile time option. All
837
this does is move a pointer to heap memory and check for the upper
838
limit. @ref{glue.c,,Example libc support code}. @code{sbrk()} returns a
839
pointer to the previous value before more memory was allocated.
840
 
841
@smallexample
842
/* _end is set in the linker command file *
843
extern caddr_t _end;/
844
 
845
/* just in case, most boards have at least some memory */
846
#ifndef RAMSIZE
847
#  define RAMSIZE             (caddr_t)0x100000
848
#endif
849
 
850
/*
851
 * sbrk -- changes heap size size. Get nbytes more
852
 *         RAM. We just increment a pointer in what's
853
 *         left of memory on the board.
854
 */
855
caddr_t
856
sbrk(nbytes)
857
     int nbytes;
858
@{
859
  static caddr_t heap_ptr = NULL;
860
  caddr_t        base;
861
 
862
  if (heap_ptr == NULL) @{
863
    heap_ptr = (caddr_t)&_end;
864
  @}
865
 
866
  if ((RAMSIZE - heap_ptr) >= 0) @{
867
    base = heap_ptr;
868
    heap_ptr += nbytes;
869
    return (base);
870
  @} else @{
871
    errno = ENOMEM;
872
    return ((caddr_t)-1);
873
  @}
874
@}
875
@end smallexample
876
 
877
@node Misc Support, Debugging, Memory Support, Libc
878
@subsection Misc support routines
879
 
880
These are called by @code{newlib} but don't apply to the embedded
881
environment. @code{isatty()} is self explanatory. @code{kill()} doesn't
882
apply either in an environment withno process control, so it justs
883
exits, which is a similar enough behavior. @code{getpid()} can safely
884
return any value greater than 1. The value doesn't effect anything in
885
@code{newlib} because once again there is no process control.
886
 
887
@smallexample
888
/*
889
 * isatty -- returns 1 if connected to a terminal device,
890
 *           returns 0 if not. Since we're hooked up to a
891
 *           serial port, we'll say yes and return a 1.
892
 */
893
int
894
isatty(fd)
895
     int fd;
896
@{
897
  return (1);
898
@}
899
 
900
/*
901
 * getpid -- only one process, so just return 1.
902
 */
903
#define __MYPID 1
904
int
905
getpid()
906
@{
907
  return __MYPID;
908
@}
909
 
910
/*
911
 * kill -- go out via exit...
912
 */
913
int
914
kill(pid, sig)
915
     int pid;
916
     int sig;
917
@{
918
  if(pid == __MYPID)
919
    _exit(sig);
920
  return 0;
921
@}
922
@end smallexample
923
 
924
@node Debugging, , Misc Support, Libc
925
@subsection Useful debugging functions
926
 
927
There are always a few useful functions for debugging your project in
928
progress. I typically implement a simple @code{print()} routine that
929
runs standalone in liblgoss, with no @code{newlib} support. The I/O
930
function @code{outbyte()} can also be used for low level debugging. Many
931
times print will work when there are problems that cause @code{printf()} to
932
cause an exception. @code{putnum()} is just to print out values in hex
933
so they are easier to read.
934
 
935
@smallexample
936
/*
937
 * print -- do a raw print of a string
938
 */
939
int
940
print(ptr)
941
char *ptr;
942
@{
943
  while (*ptr) @{
944
    outbyte (*ptr++);
945
  @}
946
@}
947
 
948
/*
949
 * putnum -- print a 32 bit number in hex
950
 */
951
int
952
putnum (num)
953
unsigned int num;
954
@{
955
  char  buffer[9];
956
  int   count;
957
  char  *bufptr = buffer;
958
  int   digit;
959
 
960
  for (count = 7 ; count >= 0 ; count--) @{
961
    digit = (num >> (count * 4)) & 0xf;
962
 
963
    if (digit <= 9)
964
      *bufptr++ = (char) ('0' + digit);
965
    else
966
      *bufptr++ = (char) ('a' - 10 + digit);
967
  @}
968
 
969
  *bufptr = (char) 0;
970
  print (buffer);
971
  return;
972
@}
973
@end smallexample
974
 
975
If there are LEDs on the board, they can also be put to use for
976
debugging when the serial I/O code is being written. I usually implement
977
a @code{zylons()} function, which strobes the LEDS (if there is more
978
than one) in sequence, creating a rotating effect. This is convenient
979
between I/O to see if the target is still alive. Another useful LED
980
function is @code{led_putnum()}, which takes a digit and displays it as
981
a bit pattern or number. These usually have to be written in assembler
982
for each target board. Here are a number of C based routines that may be
983
useful.
984
 
985
@code{led_putnum()} puts a number on a single digit segmented
986
LED display. This LED is set by setting a bit mask to an address, where
987
1 turns the segment off, and 0 turns it on. There is also a little
988
decimal point on the LED display, so it gets the leftmost bit. The other
989
bits specify the segment location. The bits look like:
990
 
991
@smallexample
992
        [d.p | g | f | e | d | c | b | a ] is the byte.
993
@end smallexample
994
 
995
The locations are set up as:
996
 
997
@smallexample
998
             a
999
           -----
1000
        f |     | b
1001
          |  g  |
1002
           -----
1003
          |     |
1004
        e |     | c
1005
           -----
1006
             d
1007
@end smallexample
1008
 
1009
This takes a number that's already been converted to a string, and
1010
prints it.
1011
 
1012
@smallexample
1013
#define LED_ADDR        0xd00003
1014
 
1015
void
1016
led_putnum ( num )
1017
char num;
1018
@{
1019
    static unsigned char *leds = (unsigned char *)LED_ADDR;
1020
    static unsigned char num_bits [18] = @{
1021
      0xff,                                             /* clear all */
1022
      0xc0, 0xf9, 0xa4, 0xb0, 0x99, 0x92, 0x82, 0xf8, 0x80, 0x98, /* numbers 0-9 */
1023
      0x98, 0x20, 0x3, 0x27, 0x21, 0x4, 0xe             /* letters a-f */
1024
    @};
1025
 
1026
    if (num >= '0' && num <= '9')
1027
      num = (num - '0') + 1;
1028
 
1029
    if (num >= 'a' && num <= 'f')
1030
      num = (num - 'a') + 12;
1031
 
1032
    if (num == ' ')
1033
      num = 0;
1034
 
1035
    *leds = num_bits[num];
1036
@}
1037
 
1038
/*
1039
 * zylons -- draw a rotating pattern. NOTE: this function never returns.
1040
 */
1041
void
1042
zylons()
1043
@{
1044
  unsigned char *leds   = (unsigned char *)LED_ADDR;
1045
  unsigned char curled = 0xfe;
1046
 
1047
  while (1)
1048
    @{
1049
      *leds = curled;
1050
      curled = (curled >> 1) | (curled << 7);
1051
      delay ( 200 );
1052
    @}
1053
@}
1054
@end smallexample
1055
 
1056
 
1057
@node GDB, Binutils, Libraries, Top
1058
@chapter Writing a new GDB backend
1059
 
1060
Typically, either the low-level I/O routines are used for debugging, or
1061
LEDs, if present. It is much easier to use GDb for debugging an
1062
application. There are several different techniques used to have GDB work
1063
remotely. Commonly more than one kind of GDB interface is used to cober
1064
a wide variety of development needs.
1065
 
1066
The most common style of GDB backend is an exception handler for
1067
breakpoints. This is also called a @emph{gdb stub}, and is requires the
1068
two additional lines of init code in your @code{main()} routine. The GDB
1069
stubs all use the GDB @emph{remote protocol}. When the application gets a
1070
breakpoint exception, it communicates to GDB on the host.
1071
 
1072
Another common style of interfacing GDB to a target is by using an
1073
existing ROM monitor. These break down into two main kinds, a similar
1074
protocol to the GDB remote protocol, and an interface that uses the ROM
1075
monitor directly. This kind has GDB simulating a human operator, and all
1076
GDB does is work as a command formatter and parser.
1077
 
1078
@menu
1079
* GNU remote protocol::         The standard remote protocol.
1080
* Exception handler::           A linked in exception handler.
1081
* ROM monitors::                Using a ROM monitor as a backend.
1082
* Other remote protocols::      Adding support for new protocols.
1083
@end menu
1084
 
1085
@node GNU remote protocol, Exception handler, ,GDB
1086
@section The standard remote protocol
1087
 
1088
The standard remote protocol is a simple, packet based scheme. A debug
1089
packet whose contents are @emph{<data>} is encapsulated for transmission
1090
in the form:
1091
 
1092
@smallexample
1093
        $ <data> # CSUM1 CSUM2
1094
@end smallexample
1095
 
1096
@emph{<data>} must be ASCII alphanumeric and cannot include characters
1097
@code{$} or @code{#}.  If @emph{<data>} starts with two characters
1098
followed by @code{:}, then the existing stubs interpret this as a
1099
sequence number. For example, the command @code{g} is used to read the
1100
values of the registers. So, a packet to do this would look like
1101
 
1102
@smallexample
1103
        $g#67
1104
@end smallexample
1105
 
1106
@emph{CSUM1} and @emph{CSUM2} are an ascii representation in hex of an
1107
8-bit checksum of @emph{<data>}, the most significant nibble is sent first.
1108
the hex digits 0-9,a-f are used.
1109
 
1110
A simple protocol is used when communicating with the target. This is
1111
mainly to give a degree of error handling over the serial cable. For
1112
each packet transmitted successfully, the target responds with a
1113
@code{+} (@code{ACK}). If there was a transmission error, then the target
1114
responds with a @code{-} (@code{NAK}). An error is determined when the
1115
checksum doesn't match the calculated checksum for that data record.
1116
Upon reciept of the @code{ACK}, @code{GDB} can then transmit the next
1117
packet.
1118
 
1119
Here is a list of the main functions that need to be supported. Each data
1120
packet is a command with a set number of bytes in the command packet.
1121
Most commands either return data, or respond with a @code{NAK}. Commands
1122
that don't return data respond with an @code{ACK}. All data values are
1123
ascii hex digits. Every byte needs two hex digits to represent t. This
1124
means that a byte with the value @samp{7} becomes @samp{07}. On a 32 bit
1125
machine this works out to 8 characters per word. All of the bytes in a
1126
word are stored in the target byte order. When writing the host side of
1127
the GDB protocol, be careful of byte order, and make sure that the code
1128
will run on both big and little endian hosts and produce the same answers.
1129
 
1130
These functions are the minimum required to make a GDB backend work. All
1131
other commands are optional, and not supported by all GDB backends.
1132
 
1133
@table @samp
1134
@item  read registers  @code{g}
1135
 
1136
returns @code{XXXXXXXX...}
1137
 
1138
Registers are in the internal order for GDB, and the bytes in a register
1139
are in the same order the machine uses. All values are in sequence
1140
starting with register 0. All registers are listed in the same packet. A
1141
sample packet would look like @code{$g#}.
1142
 
1143
@item   write registers @code{GXXXXXXXX...}
1144
@code{XXXXXXXX} is the value to set the register to.  Registers are in
1145
the internal order for GDB, and the bytes in a register are in the same
1146
order the machine uses. All values are in sequence starting with
1147
register 0. All registers values are listed in the same packet. A sample
1148
packet would look like @code{$G000000001111111122222222...#}
1149
 
1150
returns @code{ACK} or @code{NAK}
1151
 
1152
@item   read memory     @code{mAAAAAAAA,LLLL}
1153
@code{AAAAAAAA} is address, @code{LLLL} is length. A sample packet would
1154
look like @code{$m00005556,0024#}. This would request 24 bytes starting
1155
at address @emph{00005556}
1156
 
1157
returns @code{XXXXXXXX...}
1158
@code{XXXXXXXX} is the memory contents. Fewer bytes than requested will
1159
be returned if only part of the data can be read. This can be determined
1160
by counting the values till the end of packet @code{#} is seen and
1161
comparing that with the total count of bytes that was requested.
1162
 
1163
@item   write memory    @code{MAAAAAAAA,LLLL:XXXXXXXX}
1164
@code{AAAAAAAA} is the starting address, @code{LLLL} is the number of
1165
bytes to be written, and @code{XXXXXXXX} is value to be written. A
1166
sample packet would look like
1167
@code{$M00005556,0024:101010101111111100000000...#}
1168
 
1169
returns @code{ACK} or @code{NAK} for an error. @code{NAK} is also
1170
returned when only part of the data is written.
1171
 
1172
@item   continue        @code{cAAAAAAAAA}
1173
@code{AAAAAAAA} is address to resume execution at. If @code{AAAAAAAA} is
1174
omitted, resume at the curent address of the @code{pc} register.
1175
 
1176
returns the same replay as @code{last signal}. There is no immediate
1177
replay to @code{cont} until the next breakpoint is reached, and the
1178
program stops executing.
1179
 
1180
@item   step            sAA..AA
1181
@code{AA..AA} is address to resume
1182
If @code{AA..AA} is omitted, resume at same address.
1183
 
1184
returns the same replay as @code{last signal}. There is no immediate
1185
replay to @code{step} until the next breakpoint is reached, and the
1186
program stops executing.
1187
 
1188
@item   last signal     @code{?}
1189
 
1190
This returns one of the following:
1191
 
1192
@itemize @bullet
1193
@item @code{SAA}
1194
Where @code{AA} is the number of the last signal.
1195
Exceptions on the target are converted to the most similar Unix style
1196
signal number, like @code{SIGSEGV}. A sample response of this type would
1197
look like @code{$S05#}.
1198
 
1199
@item TAAnn:XXXXXXXX;nn:XXXXXXXX;nn:XXXXXXXX;
1200
@code{AA} is the signal number.
1201
@code{nn} is the register number.
1202
@code{XXXXXXXX} is the register value.
1203
 
1204
@item WAA
1205
The process exited, and @code{AA} is the exit status.  This is only
1206
applicable for certains sorts of targets.
1207
 
1208
@end itemize
1209
 
1210
These are used in some GDB backends, but not all.
1211
 
1212
@item write reg         @code{Pnn=XXXXXXXX}
1213
Write register @code{nn} with value @code{XXXXXXXX}.
1214
 
1215
returns @code{ACK} or @code{NAK}
1216
 
1217
@item   kill request    k
1218
 
1219
@item   toggle debug    d
1220
toggle debug flag (see 386 & 68k stubs)
1221
 
1222
@item   reset           r
1223
reset -- see sparc stub.
1224
 
1225
@item   reserved        @code{other}
1226
On other requests, the stub should ignore the request and send an empty
1227
response @code{$#<checksum>}.  This way we can extend the protocol and GDB
1228
can tell whether the stub it is talking to uses the old or the new.
1229
 
1230
@item   search          @code{tAA:PP,MM}
1231
Search backwards starting at address @code{AA} for a match with pattern
1232
PP and mask @code{MM}. @code{PP} and @code{MM} are 4 bytes.
1233
 
1234
@item   general query   @code{qXXXX}
1235
Request info about XXXX.
1236
 
1237
@item   general set     @code{QXXXX=yyyy}
1238
Set value of @code{XXXX} to @code{yyyy}.
1239
 
1240
@item   query sect offs @code{qOffsets}
1241
Get section offsets.  Reply is @code{Text=xxx;Data=yyy;Bss=zzz}
1242
 
1243
@item   console output  Otext
1244
Send text to stdout. The text gets display from the target side of the
1245
serial connection.
1246
 
1247
@end table
1248
 
1249
Responses can be run-length encoded to save space.  A @code{*}means that
1250
the next character is an ASCII encoding giving a repeat count which
1251
stands for that many repetitions of the character preceding the @code{*}.
1252
The encoding is n+29, yielding a printable character where n >=3
1253
(which is where run length encoding starts to win). You can't use a
1254
value of where n >126 because it's only a two byte value. An example
1255
would be a @code{0*03} means the same thing as @code{0000}.
1256
 
1257
@node Exception handler, ROM monitors, GNU remote protocol, GDB
1258
@section A linked in exception handler
1259
 
1260
A @emph{GDB stub} consists of two parts, support for the exception
1261
handler, and the exception handler itself. The exception handler needs
1262
to communicate to GDB on the host whenever there is a breakpoint
1263
exception. When GDB starts a program running on the target, it's polling
1264
the serial port during execution looking for any debug packets. So when
1265
a breakpoint occurs, the exception handler needs to save state, and send
1266
a GDB remote protocol packet to GDB on the host. GDB takes any output
1267
that isn't a debug command packet and displays it in the command window.
1268
 
1269
Support for the exception handler varies between processors, but the
1270
minimum supported functions are those needed by GDB. These are functions
1271
to support the reading and writing of registers, the reading and writing
1272
of memory, start execution at an address, single step, and last signal.
1273
Sometimes other functions for adjusting the baud rate, or resetting the
1274
hardware are implemented.
1275
 
1276
Once GDB gets the command packet from the breakpoint, it will read a few
1277
registers and memory locations an then wait for the user. When the user
1278
types @code{run} or @code{continue} a @code{continue} command is issued
1279
to the backend, and control returns from the breakpoint routine to the
1280
application.
1281
 
1282
@node ROM monitors, Other remote protocols, Exception handler, GDB
1283
@section Using a ROM monitor as a backend
1284
GDB also can mimic a human user and use a ROM monitors normal debug
1285
commands as a backend. This consists mostly of sending and parsing
1286
@code{ASCII} strings. All the ROM monitor interfaces share a common set
1287
of routines in @code{gdb/monitor.c}. This supports adding new ROM
1288
monitor interfaces by filling in a structure with the common commands
1289
GDB needs. GDb already supports several command ROM monitors, including
1290
Motorola's @code{Bug} monitor for their VME boards, and the Rom68k
1291
monitor by Integrated Systems, Inc. for various m68k based boards. GDB
1292
also supports the custom ROM monitors on the WinBond and Oki PA based
1293
targets. There is builtin support for loading files to ROM monitors
1294
specifically. GDB can convert a binary into an srecord and then load it
1295
as an ascii file, or using @code{xmodem}.
1296
 
1297
@c FIXME: do I need trademark somethings here ? Is Integrated the right
1298
@c company?
1299
 
1300
@node Other remote protocols, ,ROM monitors, GDB
1301
@section Adding support for new protocols
1302
@c FIXME: write something here
1303
 
1304
@node Binutils, Code Listings, GDB, Top
1305
 
1306
@node Code Listings, idp.ld, Binutils, Top
1307
@appendix Code Listings
1308
 
1309
@menu
1310
* idp.ld::              A m68k linker script.
1311
* crt0.S::              Crt0.S for an m68k.
1312
* glue.c::              C based support for for Stdio functions.
1313
* mvme.S::              Rom monitor based I/O support in assembler.
1314
* io.c::                C based for memory mapped I/O.
1315
* leds.c::              C based LED routines.
1316
@end menu
1317
 
1318
@node idp.ld, crt0.S, Code Listings, Code Listings
1319
@section Linker script for the IDP board
1320
 
1321
This is the linker script script that is used on the Motorola IDP board.
1322
 
1323
@example
1324
STARTUP(crt0.o)
1325
OUTPUT_ARCH(m68k)
1326
INPUT(idp.o)
1327
SEARCH_DIR(.)
1328
__DYNAMIC  =  0;
1329
/*
1330
 * Setup the memory map of the MC68ec0x0 Board (IDP)
1331
 * stack grows up towards high memory. This works for
1332
 * both the rom68k and the mon68k monitors.
1333
 */
1334
MEMORY
1335
@{
1336
  ram     : ORIGIN = 0x10000, LENGTH = 2M
1337
@}
1338
/*
1339
 * stick everything in ram (of course)
1340
 */
1341
SECTIONS
1342
@{
1343
  .text :
1344
  @{
1345
    CREATE_OBJECT_SYMBOLS
1346
    *(.text)
1347
     etext  =  .;
1348
     __CTOR_LIST__ = .;
1349
     LONG((__CTOR_END__ - __CTOR_LIST__) / 4 - 2)
1350
    *(.ctors)
1351
     LONG(0)
1352
     __CTOR_END__ = .;
1353
     __DTOR_LIST__ = .;
1354
     LONG((__DTOR_END__ - __DTOR_LIST__) / 4 - 2)
1355
    *(.dtors)
1356
     LONG(0)
1357
     __DTOR_END__ = .;
1358
    *(.lit)
1359
    *(.shdata)
1360
  @}  > ram
1361
  .shbss SIZEOF(.text) + ADDR(.text) :  @{
1362
    *(.shbss)
1363
  @}
1364
  .talias :      @{ @}  > ram
1365
  .data  : @{
1366
    *(.data)
1367
    CONSTRUCTORS
1368
    _edata  =  .;
1369
  @} > ram
1370
 
1371
  .bss SIZEOF(.data) + ADDR(.data) :
1372
  @{
1373
   __bss_start = ALIGN(0x8);
1374
   *(.bss)
1375
   *(COMMON)
1376
      end = ALIGN(0x8);
1377
      _end = ALIGN(0x8);
1378
      __end = ALIGN(0x8);
1379
  @}
1380
  .mstack  : @{ @}  > ram
1381
  .rstack  : @{ @}  > ram
1382
  .stab  . (NOLOAD) :
1383
  @{
1384
    [ .stab ]
1385
  @}
1386
  .stabstr  . (NOLOAD) :
1387
  @{
1388
    [ .stabstr ]
1389
  @}
1390
@}
1391
@end example
1392
 
1393
@node crt0.S, glue.c, idp.ld, Code Listings
1394
@section crt0.S - The startup file
1395
 
1396
@example
1397
/*
1398
 * crt0.S -- startup file for m68k-coff
1399
 *
1400
 */
1401
 
1402
        .title "crt0.S for m68k-coff"
1403
 
1404
/* These are predefined by new versions of GNU cpp.  */
1405
 
1406
#ifndef __USER_LABEL_PREFIX__
1407
#define __USER_LABEL_PREFIX__ _
1408
#endif
1409
 
1410
#ifndef __REGISTER_PREFIX__
1411
#define __REGISTER_PREFIX__
1412
#endif
1413
 
1414
/* ANSI concatenation macros.  */
1415
 
1416
#define CONCAT1(a, b) CONCAT2(a, b)
1417
#define CONCAT2(a, b) a ## b
1418
 
1419
/* Use the right prefix for global labels.  */
1420
 
1421
#define SYM(x) CONCAT1 (__USER_LABEL_PREFIX__, x)
1422
 
1423
/* Use the right prefix for registers.  */
1424
 
1425
#define REG(x) CONCAT1 (__REGISTER_PREFIX__, x)
1426
 
1427
#define d0 REG (d0)
1428
#define d1 REG (d1)
1429
#define d2 REG (d2)
1430
#define d3 REG (d3)
1431
#define d4 REG (d4)
1432
#define d5 REG (d5)
1433
#define d6 REG (d6)
1434
#define d7 REG (d7)
1435
#define a0 REG (a0)
1436
#define a1 REG (a1)
1437
#define a2 REG (a2)
1438
#define a3 REG (a3)
1439
#define a4 REG (a4)
1440
#define a5 REG (a5)
1441
#define a6 REG (a6)
1442
#define fp REG (fp)
1443
#define sp REG (sp)
1444
 
1445
/*
1446
 * Set up some room for a stack. We just grab a chunk of memory.
1447
 */
1448
        .set    stack_size, 0x2000
1449
        .comm   SYM (stack), stack_size
1450
 
1451
/*
1452
 * Define an empty environment.
1453
 */
1454
        .data
1455
        .align 2
1456
SYM (environ):
1457
        .long 0
1458
 
1459
        .align  2
1460
        .text
1461
        .global SYM (stack)
1462
 
1463
        .global SYM (main)
1464
        .global SYM (exit)
1465
/*
1466
 * This really should be __bss_start, not SYM (__bss_start).
1467
 */
1468
        .global __bss_start
1469
 
1470
/*
1471
 * start -- set things up so the application will run.
1472
 */
1473
SYM (start):
1474
        link    a6, #-8
1475
        moveal  #SYM (stack) + stack_size, sp
1476
 
1477
/*
1478
 * zerobss -- zero out the bss section
1479
 */
1480
        moveal  #__bss_start, a0
1481
        moveal  #SYM (end), a1
1482
1:
1483
        movel   #0, (a0)
1484
        leal    4(a0), a0
1485
        cmpal   a0, a1
1486
        bne     1b
1487
 
1488
/*
1489
 * Call the main routine from the application to get it going.
1490
 * main (argc, argv, environ)
1491
 * We pass argv as a pointer to NULL.
1492
 */
1493
        pea     0
1494
        pea     SYM (environ)
1495
        pea     sp@@(4)
1496
        pea     0
1497
        jsr     SYM (main)
1498
        movel   d0, sp@@-
1499
 
1500
/*
1501
 * _exit -- Exit from the application. Normally we cause a user trap
1502
 *          to return to the ROM monitor for another run.
1503
 */
1504
SYM (exit):
1505
        trap    #0
1506
@end example
1507
 
1508
@node glue.c, mvme.S, crt0.S, Code Listings
1509
@section C based "glue" code.
1510
 
1511
@example
1512
 
1513
/*
1514
 * glue.c -- all the code to make GCC and the libraries run on
1515
 *           a bare target board. These should work with any
1516
 *           target if inbyte() and outbyte() exist.
1517
 */
1518
 
1519
#include <sys/types.h>
1520
#include <sys/stat.h>
1521
#include <errno.h>
1522
#ifndef NULL
1523
#define NULL 0
1524
#endif
1525
 
1526
/* FIXME: this is a hack till libc builds */
1527
__main()
1528
@{
1529
  return;
1530
@}
1531
 
1532
#undef errno
1533
int errno;
1534
 
1535
extern caddr_t _end;                /* _end is set in the linker command file */
1536
extern int outbyte();
1537
extern unsigned char inbyte();
1538
extern int havebyte();
1539
 
1540
/* just in case, most boards have at least some memory */
1541
#ifndef RAMSIZE
1542
#  define RAMSIZE             (caddr_t)0x100000
1543
#endif
1544
 
1545
/*
1546
 * read  -- read bytes from the serial port. Ignore fd, since
1547
 *          we only have stdin.
1548
 */
1549
int
1550
read(fd, buf, nbytes)
1551
     int fd;
1552
     char *buf;
1553
     int nbytes;
1554
@{
1555
  int i = 0;
1556
 
1557
  for (i = 0; i < nbytes; i++) @{
1558
    *(buf + i) = inbyte();
1559
    if ((*(buf + i) == '\n') || (*(buf + i) == '\r')) @{
1560
      (*(buf + i)) = 0;
1561
      break;
1562
    @}
1563
  @}
1564
  return (i);
1565
@}
1566
 
1567
/*
1568
 * write -- write bytes to the serial port. Ignore fd, since
1569
 *          stdout and stderr are the same. Since we have no filesystem,
1570
 *          open will only return an error.
1571
 */
1572
int
1573
write(fd, buf, nbytes)
1574
     int fd;
1575
     char *buf;
1576
     int nbytes;
1577
@{
1578
  int i;
1579
 
1580
  for (i = 0; i < nbytes; i++) @{
1581
    if (*(buf + i) == '\n') @{
1582
      outbyte ('\r');
1583
    @}
1584
    outbyte (*(buf + i));
1585
  @}
1586
  return (nbytes);
1587
@}
1588
 
1589
/*
1590
 * open -- open a file descriptor. We don't have a filesystem, so
1591
 *         we return an error.
1592
 */
1593
int
1594
open(buf, flags, mode)
1595
     char *buf;
1596
     int flags;
1597
     int mode;
1598
@{
1599
  errno = EIO;
1600
  return (-1);
1601
@}
1602
 
1603
/*
1604
 * close -- close a file descriptor. We don't need
1605
 *          to do anything, but pretend we did.
1606
 */
1607
int
1608
close(fd)
1609
     int fd;
1610
@{
1611
  return (0);
1612
@}
1613
 
1614
/*
1615
 * sbrk -- changes heap size size. Get nbytes more
1616
 *         RAM. We just increment a pointer in what's
1617
 *         left of memory on the board.
1618
 */
1619
caddr_t
1620
sbrk(nbytes)
1621
     int nbytes;
1622
@{
1623
  static caddr_t heap_ptr = NULL;
1624
  caddr_t        base;
1625
 
1626
  if (heap_ptr == NULL) @{
1627
    heap_ptr = (caddr_t)&_end;
1628
  @}
1629
 
1630
  if ((RAMSIZE - heap_ptr) >= 0) @{
1631
    base = heap_ptr;
1632
    heap_ptr += nbytes;
1633
    return (base);
1634
  @} else @{
1635
    errno = ENOMEM;
1636
    return ((caddr_t)-1);
1637
  @}
1638
@}
1639
 
1640
/*
1641
 * isatty -- returns 1 if connected to a terminal device,
1642
 *           returns 0 if not. Since we're hooked up to a
1643
 *           serial port, we'll say yes and return a 1.
1644
 */
1645
int
1646
isatty(fd)
1647
     int fd;
1648
@{
1649
  return (1);
1650
@}
1651
 
1652
/*
1653
 * lseek -- move read/write pointer. Since a serial port
1654
 *          is non-seekable, we return an error.
1655
 */
1656
off_t
1657
lseek(fd,  offset, whence)
1658
     int fd;
1659
     off_t offset;
1660
     int whence;
1661
@{
1662
  errno = ESPIPE;
1663
  return ((off_t)-1);
1664
@}
1665
 
1666
/*
1667
 * fstat -- get status of a file. Since we have no file
1668
 *          system, we just return an error.
1669
 */
1670
int
1671
fstat(fd, buf)
1672
     int fd;
1673
     struct stat *buf;
1674
@{
1675
  errno = EIO;
1676
  return (-1);
1677
@}
1678
 
1679
/*
1680
 * getpid -- only one process, so just return 1.
1681
 */
1682
#define __MYPID 1
1683
int
1684
getpid()
1685
@{
1686
  return __MYPID;
1687
@}
1688
 
1689
/*
1690
 * kill -- go out via exit...
1691
 */
1692
int
1693
kill(pid, sig)
1694
     int pid;
1695
     int sig;
1696
@{
1697
  if(pid == __MYPID)
1698
    _exit(sig);
1699
  return 0;
1700
@}
1701
 
1702
/*
1703
 * print -- do a raw print of a string
1704
 */
1705
int
1706
print(ptr)
1707
char *ptr;
1708
@{
1709
  while (*ptr) @{
1710
    outbyte (*ptr++);
1711
  @}
1712
@}
1713
 
1714
/*
1715
 * putnum -- print a 32 bit number in hex
1716
 */
1717
int
1718
putnum (num)
1719
unsigned int num;
1720
@{
1721
  char  buffer[9];
1722
  int   count;
1723
  char  *bufptr = buffer;
1724
  int   digit;
1725
 
1726
  for (count = 7 ; count >= 0 ; count--) @{
1727
    digit = (num >> (count * 4)) & 0xf;
1728
 
1729
    if (digit <= 9)
1730
      *bufptr++ = (char) ('0' + digit);
1731
    else
1732
      *bufptr++ = (char) ('a' - 10 + digit);
1733
  @}
1734
 
1735
  *bufptr = (char) 0;
1736
  print (buffer);
1737
  return;
1738
@}
1739
@end example
1740
 
1741
@node mvme.S, io.c, glue.c, Code Listings
1742
@section I/O assembler code sample
1743
 
1744
@example
1745
/*
1746
 * mvme.S -- board support for m68k
1747
 */
1748
 
1749
        .title "mvme.S for m68k-coff"
1750
 
1751
/* These are predefined by new versions of GNU cpp.  */
1752
 
1753
#ifndef __USER_LABEL_PREFIX__
1754
#define __USER_LABEL_PREFIX__ _
1755
#endif
1756
 
1757
#ifndef __REGISTER_PREFIX__
1758
#define __REGISTER_PREFIX__
1759
#endif
1760
 
1761
/* ANSI concatenation macros.  */
1762
 
1763
#define CONCAT1(a, b) CONCAT2(a, b)
1764
#define CONCAT2(a, b) a ## b
1765
 
1766
/* Use the right prefix for global labels.  */
1767
 
1768
#define SYM(x) CONCAT1 (__USER_LABEL_PREFIX__, x)
1769
 
1770
/* Use the right prefix for registers.  */
1771
 
1772
#define REG(x) CONCAT1 (__REGISTER_PREFIX__, x)
1773
 
1774
#define d0 REG (d0)
1775
#define d1 REG (d1)
1776
#define d2 REG (d2)
1777
#define d3 REG (d3)
1778
#define d4 REG (d4)
1779
#define d5 REG (d5)
1780
#define d6 REG (d6)
1781
#define d7 REG (d7)
1782
#define a0 REG (a0)
1783
#define a1 REG (a1)
1784
#define a2 REG (a2)
1785
#define a3 REG (a3)
1786
#define a4 REG (a4)
1787
#define a5 REG (a5)
1788
#define a6 REG (a6)
1789
#define fp REG (fp)
1790
#define sp REG (sp)
1791
#define vbr REG (vbr)
1792
 
1793
        .align  2
1794
        .text
1795
        .global SYM (_exit)
1796
        .global SYM (outln)
1797
        .global SYM (outbyte)
1798
        .global SYM (putDebugChar)
1799
        .global SYM (inbyte)
1800
        .global SYM (getDebugChar)
1801
        .global SYM (havebyte)
1802
        .global SYM (exceptionHandler)
1803
 
1804
        .set    vbr_size, 0x400
1805
        .comm   SYM (vbr_table), vbr_size
1806
 
1807
/*
1808
 * inbyte -- get a byte from the serial port
1809
 *      d0 - contains the byte read in
1810
 */
1811
        .align  2
1812
SYM (getDebugChar):             /* symbol name used by m68k-stub */
1813
SYM (inbyte):
1814
        link    a6, #-8
1815
        trap    #15
1816
        .word   inchr
1817
        moveb   sp@@, d0
1818
        extbl   d0
1819
        unlk    a6
1820
        rts
1821
 
1822
/*
1823
 * outbyte -- sends a byte out the serial port
1824
 *      d0 - contains the byte to be sent
1825
 */
1826
        .align  2
1827
SYM (putDebugChar):             /* symbol name used by m68k-stub */
1828
SYM (outbyte):
1829
        link    fp, #-4
1830
        moveb   fp@@(11), sp@@
1831
        trap    #15
1832
        .word   outchr
1833
        unlk    fp
1834
        rts
1835
 
1836
/*
1837
 * outln -- sends a string of bytes out the serial port with a CR/LF
1838
 *      a0 - contains the address of the string's first byte
1839
 *      a1 - contains the address of the string's last byte
1840
 */
1841
        .align  2
1842
SYM (outln):
1843
        link    a6, #-8
1844
        moveml  a0/a1, sp@@
1845
        trap    #15
1846
        .word   outln
1847
        unlk    a6
1848
        rts
1849
 
1850
/*
1851
 * outstr -- sends a string of bytes out the serial port without a CR/LF
1852
 *      a0 - contains the address of the string's first byte
1853
 *      a1 - contains the address of the string's last byte
1854
 */
1855
        .align  2
1856
SYM (outstr):
1857
        link    a6, #-8
1858
        moveml  a0/a1, sp@@
1859
        trap    #15
1860
        .word   outstr
1861
        unlk    a6
1862
        rts
1863
 
1864
/*
1865
 * havebyte -- checks to see if there is a byte in the serial port,
1866
 *           returns 1 if there is a byte, 0 otherwise.
1867
 */
1868
SYM (havebyte):
1869
        trap    #15
1870
        .word   instat
1871
        beqs    empty
1872
        movel   #1, d0
1873
        rts
1874
empty:
1875
        movel   #0, d0
1876
        rts
1877
 
1878
/*
1879
 * These constants are for the MVME-135 board's boot monitor. They
1880
 * are used with a TRAP #15 call to access the monitor's I/O routines.
1881
 * they must be in the word following the trap call.
1882
 */
1883
        .set inchr, 0x0
1884
        .set instat, 0x1
1885
        .set inln, 0x2
1886
        .set readstr, 0x3
1887
        .set readln, 0x4
1888
        .set chkbrk, 0x5
1889
 
1890
        .set outchr, 0x20
1891
        .set outstr, 0x21
1892
        .set outln, 0x22
1893
        .set write, 0x23
1894
        .set writeln, 0x24
1895
        .set writdln, 0x25
1896
        .set pcrlf, 0x26
1897
        .set eraseln, 0x27
1898
        .set writd, 0x28
1899
        .set sndbrk, 0x29
1900
 
1901
        .set tm_ini, 0x40
1902
        .set dt_ini, 0x42
1903
        .set tm_disp, 0x43
1904
        .set tm_rd, 0x44
1905
 
1906
        .set redir, 0x60
1907
        .set redir_i, 0x61
1908
        .set redir_o, 0x62
1909
        .set return, 0x63
1910
        .set bindec, 0x64
1911
 
1912
        .set changev, 0x67
1913
        .set strcmp, 0x68
1914
        .set mulu32, 0x69
1915
        .set divu32, 0x6A
1916
        .set chk_sum, 0x6B
1917
 
1918
@end example
1919
 
1920
@node io.c, leds.c, mvme.S, Code Listings
1921
@section I/O code sample
1922
 
1923
@example
1924
#include "w89k.h"
1925
 
1926
/*
1927
 * outbyte -- shove a byte out the serial port. We wait till the byte
1928
 */
1929
int
1930
outbyte(byte)
1931
     unsigned char byte;
1932
@{
1933
  while ((inp(RS232REG) & TRANSMIT) == 0x0) @{  @} ;
1934
  return (outp(RS232PORT, byte));
1935
@}
1936
 
1937
/*
1938
 * inbyte -- get a byte from the serial port
1939
 */
1940
unsigned char
1941
inbyte()
1942
@{
1943
  while ((inp(RS232REG) & RECEIVE) == 0x0) @{ @};
1944
  return (inp(RS232PORT));
1945
@}
1946
@end example
1947
 
1948
@node leds.c, ,io.c, Code Listings
1949
@section Led control sample
1950
 
1951
@example
1952
/*
1953
 * leds.h -- control the led's on a Motorola mc68ec0x0 board.
1954
 */
1955
 
1956
#ifndef __LEDS_H__
1957
#define __LEDS_H__
1958
 
1959
#define LED_ADDR        0xd00003
1960
#define LED_0           ~0x1
1961
#define LED_1           ~0x2
1962
#define LED_2           ~0x4
1963
#define LED_3           ~0x8
1964
#define LED_4           ~0x10
1965
#define LED_5           ~0x20
1966
#define LED_6           ~0x40
1967
#define LED_7           ~0x80
1968
#define LEDS_OFF        0xff
1969
#define LEDS_ON         0x0
1970
 
1971
#define FUDGE(x) ((x >= 0xa && x <= 0xf) ? (x + 'a') & 0x7f : (x + '0') & 0x7f)
1972
 
1973
extern void led_putnum( char );
1974
 
1975
#endif          /* __LEDS_H__ */
1976
 
1977
/*
1978
 * leds.c -- control the led's on a Motorola mc68ec0x0 (IDP)board.
1979
 */
1980
#include "leds.h"
1981
 
1982
void zylons();
1983
void led_putnum();
1984
 
1985
/*
1986
 * led_putnum -- print a hex number on the LED. the value of num must be a char with
1987
 *              the ascii value. ie... number 0 is '0', a is 'a', ' ' (null) clears
1988
 *              the led display.
1989
 *              Setting the bit to 0 turns it on, 1 turns it off.
1990
 *              the LED's are controlled by setting the right bit mask in the base
1991
 *              address.
1992
 *              The bits are:
1993
 *                      [d.p | g | f | e | d | c | b | a ] is the byte.
1994
 *
1995
 *              The locations are:
1996
 *
1997
 *                       a
1998
 *                     -----
1999
 *                  f |     | b
2000
 *                    |  g  |
2001
 *                     -----
2002
 *                    |     |
2003
 *                  e |     | c
2004
 *                     -----
2005
 *                       d                . d.p (decimal point)
2006
 */
2007
void
2008
led_putnum ( num )
2009
char num;
2010
@{
2011
    static unsigned char *leds = (unsigned char *)LED_ADDR;
2012
    static unsigned char num_bits [18] = @{
2013
      0xff,                                             /* clear all */
2014
      0xc0, 0xf9, 0xa4, 0xb0, 0x99, 0x92, 0x82, 0xf8, 0x80, 0x98, /* numbers 0-9 */
2015
      0x98, 0x20, 0x3, 0x27, 0x21, 0x4, 0xe             /* letters a-f */
2016
    @};
2017
 
2018
    if (num >= '0' && num <= '9')
2019
      num = (num - '0') + 1;
2020
 
2021
    if (num >= 'a' && num <= 'f')
2022
      num = (num - 'a') + 12;
2023
 
2024
    if (num == ' ')
2025
      num = 0;
2026
 
2027
    *leds = num_bits[num];
2028
@}
2029
 
2030
/*
2031
 * zylons -- draw a rotating pattern. NOTE: this function never returns.
2032
 */
2033
void
2034
zylons()
2035
@{
2036
  unsigned char *leds   = (unsigned char *)LED_ADDR;
2037
  unsigned char curled = 0xfe;
2038
 
2039
  while (1)
2040
    @{
2041
      *leds = curled;
2042
      curled = (curled >> 1) | (curled << 7);
2043
      delay ( 200 );
2044
    @}
2045
@}
2046
@end example
2047
 
2048
@page
2049
@contents
2050
@c second page break makes sure right-left page alignment works right
2051
@c with a one-page toc, even though we don't have setchapternewpage odd.
2052
@page
2053
@bye

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