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2
Installation of RedBoot on a Target Board using RedBoot's Flash Commands
3
------------------------------------------------------------------------
4
 
5
These are generic instructions applicable to RedBoot for many platforms.
6
Details of what you type have been changed to refer specifically to the
7
nanoEngine hardware, but you should also read the further instructions for
8
Bright Star Engineering's nanoEngine and SA1110 boards - known as target
9
"nano" in eCos configuration terms - which follow.
10
 
11
Here's how to install RedBoot, using the redboot images you should find in
12
        loaders/PLATFORM/
13
in your installation directory (sizes and dates are just examples):
14
        431497 Aug  9 15:28 redboot-ram.elf
15
        184802 Aug  9 15:28 redboot-ram.srec
16
        433104 Aug  9 15:29 redboot-rom.elf      (not used in this recipe)
17
        194732 Aug  9 15:29 redboot-rom.srec
18
 
19
Copy the two '.srec' files to /tftpboot or where-ever they have to be for
20
your TFTP server.
21
 
22
Briefly, we use whatever boot flash image you have in place already (CygMon
23
or an eCos stub ROM) along with GDB, to execute a RAM based version of
24
RedBoot.  That is used, in its command-line mode, to fetch a ROM-based boot
25
image of RedBoot and write it into the flash memory.  "Fetching" the image
26
means TFTP from a server; the image must be in S-Record format.  We then
27
reset the target, thus running the newly-installed boot image of RedBoot.
28
That in turn is used, in its command-line mode, to fetch a RAM-based boot
29
image of RedBoot and write it into a different area of the flash memory, in
30
order to make it easier to do the first part (running a RAM-based RedBoot
31
in order to update the boot block) again in future.
32
 
33
NB: the instructions below refer to a system with 8Mb of flash, at address
34
0x50000000 in memory.  That address is common to SA11x0 CPUs.
35
 
36
Other boards might have a different start address, such as 0x41000000 and
37
different flash blocksizes.  RedBoot's startup banner will tell you the
38
details, if all is functioning correctly.  If the address is different, you
39
must use different addresses for saving the images into the Flash Image
40
System (fis).  The command "fis list" will tell you the addresses to use
41
for the "RedBoot" and "RedBoot[backup]" images, immediately after the "fis
42
init" command.
43
 
44
 
45
Alternatively you can make a plain binary from the redboot-rom.elf and
46
"blow" that into the boot flash using the means of your choice, as with
47
previous systems.
48
 
49
 
50
1. Load a RedBoot, built for RAM startup, into RAM using existing GDB
51
   stubs.  Note: do not run it yet!
52
 
53
   % arm-elf-gdb -nw loaders/nano/redboot-ram.elf
54
 
55
   GNU gdb 4.18-ecos-99r1-991015
56
   Copyright 1998 Free Software Foundation, Inc.
57
   GDB is free software, covered by the GNU General Public License, and you are
58
   welcome to change it and/or distribute copies of it under certain conditions.
59
   Type "show copying" to see the conditions.  This version of GDB is supported
60
   for customers of Cygnus Solutions.  Type "show warranty" for details.
61
   This GDB was configured as "--host=i686-pc-linux-gnu
62
   --target=arm-elf"...(no debugging symbols found)...
63
   (gdb) set remotebaud 38400
64
   (gdb) tar rem /dev/ttyS0
65
   Remote debugging using /dev/ttyS0
66
   0x41000838 in ?? ()
67
   (gdb) load
68
   Loading section .rom_vectors, size 0x44 lma 0x20000
69
   Loading section .text, size 0xf06c lma 0x20044
70
   Loading section .rodata, size 0x19a8 lma 0x2f0b0
71
   Loading section .data, size 0x474 lma 0x30a58
72
   Start address 0x20044 , load size 69324
73
   Transfer rate: 25208 bits/sec.
74
   (gdb) detach
75
   Ending remote debugging.
76
   (gdb) q
77
 
78
2. Execute RedBoot from RAM, and initialize the flash filing system.
79
       Notes: the key here is the "-o" option which keeps minicom from
80
       sending junk.
81
       The magic phrase "$c#63" is important: you must type it in exactly
82
       thus.  It is the packet which a "continue" command in GDB would send
83
       to the target.  If you get no response, try "+$c#63" instead.
84
       The IP and server info comes from BOOTP, which is how this RedBoot
85
       will start up if the flash does not contain good config info.
86
 
87
   % minicom -o ttyS0
88
 
89
   $c#63
90
   RedBoot(tm) debug environment - built 07:45:57, Aug  7 2000
91
   Copyright (C) 2000, Red Hat, Inc.
92
 
93
   RAM: 0x00000000-0x01000000
94
   FLASH: 0x50000000 - 0x50400000, 32 blocks of 0x00020000 bytes ea.
95
   IP: 192.168.1.25, Default server: 192.168.1.101
96
   RedBoot> fi init
97
   About to initialize [format] FLASH image system - are you sure (y/n)? y
98
   *** Initialize FLASH Image System
99
       Warning: device contents not erased, some blocks may not be usable
100
   ... Erase from 0x503c0000-0x50400000: .
101
   ... Program from 0x00fb0000-0x00fb0400 at 0x503c0000: .
102
 
103
 
104
3. Program RedBoot image into FLASH:
105
       This expects the file redboot-post.srec (see below) to exist in the
106
       TFTP server space on the server that answered the BOOTP request.
107
       It loads into the free flash memory following the boot firmware, at
108
       address 0x50040000.
109
 
110
   RedBoot> lo -v /tftpboot/redboot-post.srec -b 0x00100000
111
   Address offset = bf100000
112
   Entry point: 0x50040044, address range: 0x50040000-0x50051384
113
   RedBoot> fi cr RedBoot[post] -f 0x50040000 -b 0x00100000 -l 0x20000
114
   An image named 'RedBoot[post]' exists - are you sure (y/n)? y
115
   ... Erase from 0x50040000-0x50060000: .
116
   ... Program from 0x00100000-0x00120000 at 0x50040000: .
117
   ... Erase from 0x503c0000-0x50400000: .
118
   ... Program from 0x00fb0000-0x00ff0000 at 0x503c0000: .
119
   RedBoot>
120
 
121
****reset the board here, leaving your terminal program connected****
122
 
123
   RedBoot(tm) debug environment - built 07:47:35, Aug  7 2000
124
   Copyright (C) 2000, Red Hat, Inc.
125
 
126
   RAM: 0x00000000-0x01000000
127
   FLASH: 0x50000000 - 0x50400000, 32 blocks of 0x00020000 bytes ea.
128
   IP: 192.168.1.25, Default server: 192.168.1.101
129
   RedBoot>
130
 
131
 
132
4. Install RAM based RedBoot for backup/update:
133
       Similar considerations apply: redboot-ram.srec must be an S-record
134
       version of RedBoot built for RAM startup.
135
 
136
   RedBoot> lo -v /tftpboot/redboot-ram.srec
137
   Entry point: 0x00020044, address range: 0x00020000-0x00030ecc
138
   RedBoot> fi cr RedBoot[backup] -f 0x50060000 -b 0x20000 -r 0x20000 -l 0x20000
139
   An image named 'RedBoot[backup]' exists - are you sure (y/n)? y
140
   ... Erase from 0x50060000-0x50080000: .
141
   ... Program from 0x00020000-0x00040000 at 0x50060000: .
142
   ... Erase from 0x503c0000-0x50400000: .
143
   ... Program from 0x00fb0000-0x00ff0000 at 0x503c0000: .
144
   RedBoot>
145
 
146
        You have now updated your board completely.  Phew!
147
 
148
 
149
 
150
5. To update RedBoot with a new version of RedBoot, it is necessary to run
151
   a RAM-based version of RedBoot which itself re-writes the ROM-based one,
152
   because you can't re-write the code that is executing at the time.
153
 
154
   RedBoot> fi lo RedBoot[backup]
155
   RedBoot> g
156
   +
157
   RedBoot(tm) debug environment - built 07:45:57, Aug  7 2000
158
   Copyright (C) 2000, Red Hat, Inc.
159
 
160
   RAM: 0x00000000-0x01000000
161
   FLASH: 0x50000000 - 0x50400000, 32 blocks of 0x00020000 bytes ea.
162
   IP: 192.168.1.25, Default server: 192.168.1.101
163
   RedBoot>
164
 
165
     .. continue with step 3, using whatever your new boot image is called
166
        in the TFTP-place, in .srec format.
167
 
168
 
169
You probably also want to set up then environment with your own IP
170
addresses and so on.  Recall that this IP address is the one you use for
171
GDB to talk to the board, not the IP address which the eCos application
172
will take on (by BOOTP/DHCP or whatever means according to configury as
173
usual).
174
 
175
   RedBoot> fconfig
176
   Network debug at boot time: false
177
   Use BOOTP for network configuration: false
178
   Local IP address: 192.168.1.25
179
   Default server IP address: 192.168.1.101
180
   GDB connection port: 1000
181
   Run script at boot: false
182
   RedBoot>
183
 
184
 
185
RedBoot for the nanoEngine/commEngine "nano" Target
186
---------------------------------------------------
187
 
188
Unlike other targets, the nanoEngine comes equipped with boot firmware
189
which you cannot modify.  See chapter 5 "nanoEngine Firmware" of the
190
nanoEngine Hardware Reference Manual (we refer to "July 17, 2000 Rev 0.6")
191
from Bright Star Engineering.
192
 
193
Because of this, eCos and so Redboot supports only these two startup types:
194
RAM and POST, rather than the more usual ROM, RAM and optionally POST.
195
 
196
Briefly, the POST-startup RedBoot image lives in flash following the BSE
197
firmware.  The BSE firmware is configured, using its standard "bootcmd"
198
parameter, to jump into the RedBoot image at startup.
199
 
200
You can perform the initial load of the POST-startup RedBoot image into
201
flash using the BSE firmware's "load" command.  This will load, using TFTP,
202
a binary file and program it into flash in one neat operation.  Because no
203
memory management is used in the BSE firmware, flash is mapped from address
204
zero upwards, so the address for the RedBoot POST image is 0x40000.  You
205
must use the binary version of RedBoot for this, "redboot-post.bin"
206
 
207
This assumes you have set up the other BSE firmware config parameters such
208
that it can communicate over your network, to your TFTP server.
209
 
210
        >
211
        >load /tftpboot/redboot-post.bin 40000
212
        loading ... erasing blk at 00040000
213
        erasing blk at 00050000
214
        94168 bytes loaded cksum 00008579
215
         done
216
        >
217
        > set bootcmd "go 40000"
218
        > get
219
        myip = 10.16.19.198
220
        netmask = 255.255.255.0
221
        eth = 0
222
        gateway = 10.16.19.66
223
        serverip = 10.16.19.66
224
        bootcmd = go 40000
225
        >
226
 
227
NB: the BSE firmware runs its serial IO at 9600 Baud; RedBoot runs instead
228
at 38400 Baud.  You must select the right baud rate in your terminal
229
program to be able to set up the BSE firmware.
230
 
231
After a reset, the BSE firmware will print
232
        Boot: BSE 2000 Sep 12 2000 14:00:30
233
        autoboot: "go 40000" [hit ESC to abort]
234
and then RedBoot starts, switching to 38400 Baud.
235
 
236
Once you have installed a bootable RedBoot in the system in this manner, we
237
advice re-installing using the generic method described first in this note
238
in order that the Flash Image System contains an appropriate description of
239
the flash entries.
240
 
241
 
242
Rebuilding RedBoot from Source
243
------------------------------
244
 
245
To rebuild RedBoot from source, first locate the configuration export files
246
for your platform in the eCos source repository.  The RAM and POST startup
247
configuration exports can usually be found in a directory named "misc" in
248
the platform HAL in the eCos source repository, named either:
249
   2164 Nov 29 14:59 misc/redboot_RAM.cfg
250
   2221 Nov 29 14:59 misc/redboot_POST.cfg
251
or
252
   1432 Feb  1 13:27 misc/redboot_RAM.ecm
253
   1487 Feb  1 14:38 misc/redboot_POST.ecm
254
Having located these files, copy them say to /tmp, say, for less typing.
255
 
256
To make redboot for RAM startup:
257
  mkdir redboot.RAM
258
  cd redboot.RAM
259
  ecosconfig new nano redboot
260
  ecosconfig import /tmp/redboot_RAM.ecm
261
  ecosconfig tree
262
  make
263
 
264
To build the POST version, in a different build/config directory, just use
265
the config export redboot_POST.ecm (or .cfg) instead.
266
 
267
The resulting files will be, in each of the POST and RAM startup build
268
places:
269
   70456     ..../install/bin/redboot.bin
270
  433104     ..../install/bin/redboot.elf
271
   91407     ..../install/bin/redboot.img
272
  194732     ..../install/bin/redboot.srec
273
 
274
The .elf and .srec files have the obvious relationship to those supplied in
275
the "loaders/nano" directory in the install.
276
 
277
 
278
Cohabiting with POST in Flash
279
-----------------------------
280
 
281
The configuration export named redboot_POST.ecm configures redboot to build
282
for execution at address 0x50040000 (or during bootup, 0x00040000).  This
283
is to allow power-on self-test (POST) code or immutable firmware to live in
284
the lower addresses of the flash and to run before RedBoot gets control.
285
The assumption is that RedBoot will be entered at its base address in
286
physical memory, ie. 0x00040000.  Alternatively, for testing, you can call
287
it in an already running system by "go 0x50040040" at another RedBoot
288
prompt, or a branch to that address; the address is where the reset vector
289
points, and is reported by RedBoot's tftp load command and listed by the
290
fis list command, amongst other places.
291
 
292
Using the POST configuration enables a normal config option which causes
293
linking and initialization against memory layout files called "...post..."
294
rather than "...rom..." or "...ram..." in the include/pkgconf directory,
295
specifically:
296
   665 Feb  9 17:57 include/pkgconf/mlt_arm_sa11x0_nano_post.h
297
   839 Feb  9 17:57 include/pkgconf/mlt_arm_sa11x0_nano_post.ldi
298
   585 Feb  9 17:57 include/pkgconf/mlt_arm_sa11x0_nano_post.mlt
299
It is these you should edit if you wish to move that execution address from
300
0x50040000 in the POST configuration.  Startup type naturally remains ROM
301
in this configuration.
302
 
303
Because the nanoEngine contains immutable boot firmware at the start of
304
flash, RedBoot for this target is configured to reserve that area in the
305
Flash Image System, and to create by default an entry for the POST startup
306
RedBoot.
307
 
308
  RedBoot> fis list
309
  Name              FLASH addr  Mem addr    Length      Entry point
310
  (reserved)        0x50000000  0x50000000  0x00040000  0x00000000
311
  RedBoot[post]     0x50040000  0x00100000  0x00020000  0x50040040
312
  RedBoot[backup]   0x50060000  0x00020000  0x00020000  0x00020040
313
  RedBoot config    0x503E0000  0x503E0000  0x00010000  0x00000000
314
  FIS directory     0x503F0000  0x503F0000  0x00010000  0x00000000
315
  RedBoot>
316
 
317
The entry "(reserved)" ensures that the FIS cannot attempt to overwrite the
318
BSE firmware, thus ensuring that the board remains bootable and recoverable
319
even after installing a broken RedBoot image.
320
 
321
 
322
Special Redboot Commands
323
------------------------
324
 
325
The nanoEngine/commEngine has one or two Intel i82559 Ethernet controllers
326
installed, but these have no associated serial EEPROM in which to record
327
their Ethernet Station Address (ESA, or MAC address).  The BSE firmware
328
records an ESA for the device it uses, but this information is not
329
available to RedBoot; we cannot share it.
330
 
331
To keep the ESAs for the two ethernet interfaces, two new items of RedBoot
332
configuration data are introduced.  You can list them with the RedBoot
333
command "fconfig -l" thus:
334
 
335
  RedBoot> fconfig -l
336
  Run script at boot: false
337
  Use BOOTP for network configuration: false
338
  Local IP address: 10.16.19.91
339
  Default server IP address: 10.16.19.66
340
  Network hardware address [MAC] for eth0: 0x00:0xB5:0xE0:0xB5:0xE0:0x99
341
  Network hardware address [MAC] for eth1: 0x00:0xB5:0xE0:0xB5:0xE0:0x9A
342
  GDB connection port: 9000
343
  Network debug at boot time: false
344
  RedBoot>
345
 
346
You should set them before running RedBoot or eCos applications with the
347
board connected to a network.  The fconfig command can be used as for any
348
configuration data item; the entire ESA is entered in one line.
349
 
350
 
351
Memory Maps
352
-----------
353
 
354
The first level page table is located at physical address
355
0xc0004000.  No second level tables are used.
356
 
357
NOTE
358
The virtual memory maps in this section use a C and B column to
359
indicate whether or not the region is cached (C) or buffered (B).
360
 
361
Physical Address Range     Description
362
-----------------------    ----------------------------------
363
0x00000000 - 0x003fffff    4Mb FLASH (nCS0)
364
0x18000000 - 0x18ffffff    Internal PCI bus - 2 x i82559 ethernet
365
0x40000000 - 0x4fffffff    External IO or PCI bus
366
0x80000000 - 0xbfffffff    SA-1110 Internal Registers
367
0xc0000000 - 0xc7ffffff    DRAM Bank 0 - 32Mb SDRAM
368
0xc8000000 - 0xcfffffff    DRAM Bank 1 - empty
369
0xe0000000 - 0xe7ffffff    Cache Clean
370
 
371
Virtual Address Range    C B  Description
372
-----------------------  - -  ----------------------------------
373
0x00000000 - 0x001fffff  Y Y  DRAM - 8Mb to 32Mb
374
0x18000000 - 0x180fffff  N N  Internal PCI bus - 2 x i82559 ethernet
375
0x40000000 - 0x4fffffff  N N  External IO or PCI bus
376
0x50000000 - 0x51ffffff  Y Y  Up to 32Mb FLASH (nCS0)
377
0x80000000 - 0xbfffffff  N N  SA-1110 Internal Registers
378
0xc0000000 - 0xc0ffffff  N Y  DRAM Bank 0: 8 or 16Mb
379
0xc8000000 - 0xc8ffffff  N Y  DRAM Bank 1: 8 or 16Mb or absent
380
0xe0000000 - 0xe7ffffff  Y Y  Cache Clean
381
 
382
The FLASH based RedBoot POST-startup image occupies virtual addresses
383
0x50040000 - 0x5005ffff.
384
 
385
The ethernet devices use a "PCI window" to communicate with the CPU.  This
386
is 1Mb of SDRAM which is shared with the ethernet devices that are on the
387
PCI bus.  It is neither cached nor buffered, to ensure that CPU and PCI
388
accesses see correct data in the correct order.  By default it is
389
configured to be megabyte number 30, at addresses 0x01e00000-0x01efffff.
390
This can be modified - and indeed must be, if less than 32Mb of SDRAM is
391
installed - via the memory layout tool, or by moving the section
392
"__pci_window" referred to by symbols CYGMEM_SECTION_pci_window* in the
393
linker script.
394
 
395
Though the nanoEngine ships with 32Mb of SDRAM all attached to DRAM bank 0,
396
the code can cope with any of these combinations also; "2 x " in this
397
context means one device in each DRAM Bank.
398
 
399
  1 x 8Mb = 8Mb     2 x 8Mb = 16Mb
400
  1 x 16Mb = 16Mb   2 x 16Mb = 32Mb
401
 
402
All are programmed the same in the memory controller.
403
 
404
Startup code detects which is fitted and programs the memory map
405
accordingly.  If the device(s) is 8Mb, then there are gaps in the
406
physical memory map, because a high order address bit is not
407
connected.  The gaps are the higher 2Mb out of every 4Mb.
408
 
409
The SA11x0 OS timer is used as a polled timer to provide timeout
410
support within RedBoot.
411
 
412
 
413
Nano Platform Port
414
------------------
415
 
416
The nano is in the set of SA11X0-based platforms.  It uses the
417
arm architectural HAL, the sa11x0 variant HAL, plus the nano
418
platform hal.  These are components
419
        CYGPKG_HAL_ARM                  hal/arm/arch/
420
        CYGPKG_HAL_ARM_SA11X0           hal/arm/sa11x0/var
421
        CYGPKG_HAL_ARM_SA11X0_NANO      hal/arm/sa11x0/nano
422
respectively.
423
 
424
The target name is "nano" which includes all these, plus the
425
ethernet driver packages, flash driver, and so on.
426
 
427
 
428
Ethernet Driver
429
---------------
430
 
431
The ethernet driver is in two parts:
432
 
433
A generic ether driver for Intel i8255x series devices, specifically the
434
i82559, is devs/eth/intel/i82559.  Its package name is
435
CYGPKG_DEVS_ETH_INTEL_I82559.
436
 
437
The platform-specific ether driver is devs/eth/arm/nano.  Its package is
438
CYGPKG_DEVS_ETH_ARM_NANO.  This tells the generic driver the address in IO
439
memory of the chip, for example, and other configuration details.
440
 
441
This driver picks up the ESA from RedBoot's configuration data - unless
442
configured to use a static ESA in the usual manner.
443
 

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