| blob | 0713e3a5a22cb4b4bf1baa1db4c5d57d01259e13 |
1 /* dilnetpc.c -- MTD map driver for SSV DIL/Net PC Boards "DNP" and "ADNP"
2 *
3 * This program is free software; you can redistribute it and/or modify
4 * it under the terms of the GNU General Public License as published by
5 * the Free Software Foundation; either version 2 of the License, or
6 * (at your option) any later version.
7 *
8 * This program is distributed in the hope that it will be useful,
9 * but WITHOUT ANY WARRANTY; without even the implied warranty of
10 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
11 * GNU General Public License for more details.
12 *
13 * You should have received a copy of the GNU General Public License
14 * along with this program; if not, write to the Free Software
15 * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA
16 *
17 * The DIL/Net PC is a tiny embedded PC board made by SSV Embedded Systems
18 * featuring the AMD Elan SC410 processor. There are two variants of this
19 * board: DNP/1486 and ADNP/1486. The DNP version has 2 megs of flash
20 * ROM (Intel 28F016S3) and 8 megs of DRAM, the ADNP version has 4 megs
21 * flash and 16 megs of RAM.
22 * For details, see http://www.ssv-embedded.de/ssv/pc104/p169.htm
23 * and http://www.ssv-embedded.de/ssv/pc104/p170.htm
24 */
26 #include <linux/module.h>
27 #include <linux/types.h>
28 #include <linux/kernel.h>
29 #include <linux/init.h>
30 #include <linux/string.h>
32 #include <linux/mtd/mtd.h>
33 #include <linux/mtd/map.h>
34 #include <linux/mtd/partitions.h>
35 #include <linux/mtd/concat.h>
37 #include <asm/io.h>
39 /*
40 ** The DIL/NetPC keeps its BIOS in two distinct flash blocks.
41 ** Destroying any of these blocks transforms the DNPC into
42 ** a paperweight (albeit not a very useful one, considering
43 ** it only weighs a few grams).
44 **
45 ** Therefore, the BIOS blocks must never be erased or written to
46 ** except by people who know exactly what they are doing (e.g.
47 ** to install a BIOS update). These partitions are marked read-only
48 ** by default, but can be made read/write by undefining
49 ** DNPC_BIOS_BLOCKS_WRITEPROTECTED:
50 */
51 #define DNPC_BIOS_BLOCKS_WRITEPROTECTED
53 /*
54 ** The ID string (in ROM) is checked to determine whether we
55 ** are running on a DNP/1486 or ADNP/1486
56 */
57 #define BIOSID_BASE 0x000fe100
62 /*
63 ** Address where the flash should appear in CPU space
64 */
65 #define FLASH_BASE 0x2000000
67 /*
68 ** Chip Setup and Control (CSC) indexed register space
69 */
70 #define CSC_INDEX 0x22
71 #define CSC_DATA 0x23
79 /* Z-bus/configuration register */
84 /*
85 ** PC Card indexed register space:
86 */
88 #define PCC_INDEX 0x3e0
89 #define PCC_DATA 0x3e1
100 /*
101 ** Access to SC4x0's Chip Setup and Control (CSC)
102 ** and PC Card (PCC) indexed registers:
103 */
105 {
108 }
111 {
114 }
117 {
120 }
123 {
126 }
129 /*
130 ************************************************************
131 ** Enable access to DIL/NetPC's flash by mapping it into
132 ** the SC4x0's MMS Window C.
133 ************************************************************
134 */
136 {
139 /*
140 ** enable setup of MMS windows C-F:
141 */
142 /* - enable PC Card indexed register space */
144 /* - set PC Card controller to operate in standard mode */
147 /*
148 ** Program base address and end address of window
149 ** where the flash ROM should appear in CPU address space
150 */
156 /* program offset of first flash location to appear in this window (0) */
160 /* set attributes for MMS window C: non-cacheable, write-enabled */
163 /* select physical device ROMCS0 (i.e. flash) for MMS Window C */
166 /* enable memory window 1 */
169 /* now disable PC Card indexed register space again */
171 }
174 /*
175 ************************************************************
176 ** Disable access to DIL/NetPC's flash by mapping it into
177 ** the SC4x0's MMS Window C.
178 ************************************************************
179 */
181 {
182 /* - enable PC Card indexed register space */
185 /* disable memory window 1 */
188 /* now disable PC Card indexed register space again */
190 }
194 /*
195 ************************************************************
196 ** Enable/Disable VPP to write to flash
197 ************************************************************
198 */
202 /*
203 ** This is what has to be done for the DNP board ..
204 */
206 {
210 {
213 }
214 else
215 {
218 else
220 }
222 }
224 /*
225 ** .. and this the ADNP version:
226 */
228 {
232 {
235 }
236 else
237 {
240 else
242 }
244 }
250 #define WINDOW_ADDR FLASH_BASE
258 };
260 /*
261 ** The layout of the flash is somewhat "strange":
262 **
263 ** 1. 960 KiB (15 blocks) : Space for ROM Bootloader and user data
264 ** 2. 64 KiB (1 block) : System BIOS
265 ** 3. 960 KiB (15 blocks) : User Data (DNP model) or
266 ** 3. 3008 KiB (47 blocks) : User Data (ADNP model)
267 ** 4. 64 KiB (1 block) : System BIOS Entry
268 */
271 {
272 {
276 },
277 {
281 #ifdef DNPC_BIOS_BLOCKS_WRITEPROTECTED
283 #endif
284 },
285 {
289 },
290 {
294 #ifdef DNPC_BIOS_BLOCKS_WRITEPROTECTED
296 #endif
297 },
298 };
300 #define NUM_PARTITIONS ARRAY_SIZE(partition_info)
306 /*
307 ** "Highlevel" partition info:
308 **
309 ** Using the MTD concat layer, we can re-arrange partitions to our
310 ** liking: we construct a virtual MTD device by concatenating the
311 ** partitions, specifying the sequence such that the boot block
312 ** is immediately followed by the filesystem block (i.e. the stupid
313 ** system BIOS block is mapped to a different place). When re-partitioning
314 ** this concatenated MTD device, we can set the boot block size to
315 ** an arbitrary (though erase block aligned) value i.e. not one that
316 ** is dictated by the flash's physical layout. We can thus set the
317 ** boot block to be e.g. 64 KB (which is fully sufficient if we want
318 ** to boot an etherboot image) or to -say- 1.5 MB if we want to boot
319 ** a large kernel image. In all cases, the remainder of the flash
320 ** is available as file system space.
321 */
324 {
325 {
329 },
330 {
334 },
335 {
339 #ifdef DNPC_BIOS_BLOCKS_WRITEPROTECTED
341 #endif
342 },
343 };
345 #define NUM_HIGHLVL_PARTITIONS ARRAY_SIZE(higlvl_partition_info)
349 {
354 {
359 }
362 }
366 {
369 /*
370 ** determine hardware (DNP/ADNP/invalid)
371 */
375 /*
376 ** Things are set up for ADNP by default
377 ** -> modify all that needs to be different for DNP
378 */
381 ** Adjust window size, select correct set_vpp function.
382 ** The partitioning scheme is identical on both DNP
383 ** and ADNP except for the size of the third partition.
384 */
390 /*
391 ** increment all string pointers so the leading 'A' gets skipped,
392 ** thus turning all occurrences of "ADNP ..." into "DNP ..."
393 */
401 }
413 }
423 /*
424 ** If flash probes fail, try to make flashes accessible
425 ** at least as ROM. Ajust erasesize in this case since
426 ** the default one (128M) will break our partitioning
427 */
435 }
439 /*
440 ** Supply pointers to lowlvl_parts[] array to add_mtd_partitions()
441 ** -> add_mtd_partitions() will _not_ register MTD devices for
442 ** the partitions, but will instead store pointers to the MTD
443 ** objects it creates into our lowlvl_parts[] array.
444 ** NOTE: we arrange the pointers such that the sequence of the
445 ** partitions gets re-arranged: partition #2 follows
446 ** partition #0.
447 */
455 /*
456 ** now create a virtual MTD device by concatenating the for partitions
457 ** (in the sequence given by the lowlvl_parts[] array.
458 */
462 ** now partition the new device the way we want it. This time,
463 ** we do not supply mtd pointers in higlvl_partition_info, so
464 ** add_mtd_partitions() will register the devices.
465 */
467 }
470 }
473 {
477 }
482 }
487 }
488 }