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wdenk5b1d7132002-11-03 00:07:02 +00001/*
2 * (C) Copyright 2001, 2002
3 * Dave Ellis, SIXNET, dge@sixnetio.com.
4 * Based on code by:
5 * Wolfgang Denk, DENX Software Engineering, wd@denx.de.
6 * and other contributors to U-Boot. See file CREDITS for list
7 * of people who contributed to this project.
8 *
9 * This program is free software; you can redistribute it and/or
10 * modify it under the terms of the GNU General Public License as
11 * published by the Free Software Foundation; either version 2 of
12 * the License, or (at your option) any later version.
13 *
14 * This program is distributed in the hope that it will be useful,
15 * but WITHOUT ANY WARRANTY; without even the implied warranty of
16 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17 * GNU General Public License for more details.
18 *
19 * You should have received a copy of the GNU General Public License
20 * along with this program; if not, write to the Free Software
21 * Foundation, Inc., 59 Temple Place, Suite 330, Boston,
22 * MA 02111-1307 USA
23 */
24
25#include <common.h>
26#include <config.h>
27#include <mpc8xx.h>
28#include <net.h> /* for eth_init() */
29#include <rtc.h>
30#include "sixnet.h"
wdenk5840af22003-03-28 14:40:36 +000031#ifdef CONFIG_SHOW_BOOT_PROGRESS
32# include <status_led.h>
33#endif
wdenk5b1d7132002-11-03 00:07:02 +000034
wdenkabda5ca2003-05-31 18:35:21 +000035#if (CONFIG_COMMANDS & CFG_CMD_NAND)
36#include <linux/mtd/nand.h>
37extern struct nand_chip nand_dev_desc[CFG_MAX_NAND_DEVICE];
38#endif
39
wdenk5b1d7132002-11-03 00:07:02 +000040#define ORMASK(size) ((-size) & OR_AM_MSK)
41
42static long ram_size(ulong *, long);
43
44/* ------------------------------------------------------------------------- */
45
wdenk5840af22003-03-28 14:40:36 +000046#ifdef CONFIG_SHOW_BOOT_PROGRESS
47void show_boot_progress (int status)
48{
49#if defined(CONFIG_STATUS_LED)
50# if defined(STATUS_LED_BOOT)
51 if (status == 15) {
52 /* ready to transfer to kernel, make sure LED is proper state */
53 status_led_set(STATUS_LED_BOOT, CONFIG_BOOT_LED_STATE);
54 }
55# endif /* STATUS_LED_BOOT */
56#endif /* CONFIG_STATUS_LED */
57}
58#endif
59
60/* ------------------------------------------------------------------------- */
61
wdenk5b1d7132002-11-03 00:07:02 +000062/*
63 * Check Board Identity:
64 * returns 0 if recognized, -1 if unknown
65 */
66
67int checkboard (void)
68{
69 puts ("Board: SIXNET SXNI855T\n");
70 return 0;
71}
72
73/* ------------------------------------------------------------------------- */
74
75#if (CONFIG_COMMANDS & CFG_CMD_PCMCIA)
76#error "SXNI855T has no PCMCIA port"
77#endif /* CFG_CMD_PCMCIA */
78
79/* ------------------------------------------------------------------------- */
80
81#define _not_used_ 0xffffffff
82
83/* UPMB table for dual UART. */
84
85/* this table is for 50MHz operation, it should work at all lower speeds */
86const uint duart_table[] =
87{
88 /* single read. (offset 0 in upm RAM) */
89 0xfffffc04, 0x0ffffc04, 0x0ff3fc04, 0x0ff3fc04,
90 0x0ff3fc00, 0x0ff3fc04, 0xfffffc04, 0xfffffc05,
91
92 /* burst read. (offset 8 in upm RAM) */
93 _not_used_, _not_used_, _not_used_, _not_used_,
94 _not_used_, _not_used_, _not_used_, _not_used_,
95 _not_used_, _not_used_, _not_used_, _not_used_,
96 _not_used_, _not_used_, _not_used_, _not_used_,
97
98 /* single write. (offset 18 in upm RAM) */
99 0xfffffc04, 0x0ffffc04, 0x00fffc04, 0x00fffc04,
100 0x00fffc04, 0x00fffc00, 0xfffffc04, 0xfffffc05,
101
102 /* burst write. (offset 20 in upm RAM) */
103 _not_used_, _not_used_, _not_used_, _not_used_,
104 _not_used_, _not_used_, _not_used_, _not_used_,
105 _not_used_, _not_used_, _not_used_, _not_used_,
106 _not_used_, _not_used_, _not_used_, _not_used_,
107
108 /* refresh. (offset 30 in upm RAM) */
109 _not_used_, _not_used_, _not_used_, _not_used_,
110 _not_used_, _not_used_, _not_used_, _not_used_,
111 _not_used_, _not_used_, _not_used_, _not_used_,
112
113 /* exception. (offset 3c in upm RAM) */
114 _not_used_, _not_used_, _not_used_, _not_used_,
115};
116
117/* Load FPGA very early in boot sequence, since it must be
118 * loaded before the 16C2550 serial channels can be used as
119 * console channels.
120 *
121 * Note: Much of the configuration is not complete. The
122 * stack is in DPRAM since SDRAM has not been initialized,
123 * so the stack must be kept small. Global variables
124 * are still in FLASH, so they cannot be written.
125 * Only the FLASH, DPRAM, immap and FPGA can be addressed,
126 * the other chip selects may not have been initialized.
127 * The clocks have been initialized, so udelay() can be
128 * used.
129 */
130#define FPGA_DONE 0x0080 /* PA8, input, high when FPGA load complete */
131#define FPGA_PROGRAM_L 0x0040 /* PA9, output, low to reset, high to start */
132#define FPGA_INIT_L 0x0020 /* PA10, input, low indicates not ready */
133#define fpga (*(volatile unsigned char *)(CFG_FPGA_PROG)) /* FPGA port */
134
135int board_postclk_init (void)
136{
137
138 /* the data to load to the XCSxxXL FPGA */
139 static const unsigned char fpgadata[] = {
140# include "fpgadata.c"
141 };
142
143 volatile immap_t *immap = (immap_t *)CFG_IMMR;
144 volatile memctl8xx_t *memctl = &immap->im_memctl;
145#define porta (immap->im_ioport.iop_padat)
146 const unsigned char* pdata;
147
148 /* /INITFPGA and DONEFPGA signals are inputs */
149 immap->im_ioport.iop_padir &= ~(FPGA_INIT_L | FPGA_DONE);
150
151 /* Force output pin to begin at 0, /PROGRAM asserted (0) resets FPGA */
152 porta &= ~FPGA_PROGRAM_L;
153
154 /* Set FPGA as an output */
155 immap->im_ioport.iop_padir |= FPGA_PROGRAM_L;
156
157 /* delay a little to make sure FPGA sees it, really
158 * only need less than a microsecond.
159 */
160 udelay(10);
161
162 /* unassert /PROGRAM */
163 porta |= FPGA_PROGRAM_L;
164
165 /* delay while FPGA does last erase, indicated by
166 * /INITFPGA going high. This should happen within a
167 * few milliseconds.
168 */
169 /* ### FIXME - a timeout check would be good, maybe flash
170 * the status LED to indicate the error?
171 */
172 while ((porta & FPGA_INIT_L) == 0)
173 ; /* waiting */
174
175 /* write program data to FPGA at the programming address
176 * so extra /CS1 strobes at end of configuration don't actually
177 * write to any registers.
178 */
179 fpga = 0xff; /* first write is ignored */
180 fpga = 0xff; /* fill byte */
181 fpga = 0xff; /* fill byte */
182 fpga = 0x4f; /* preamble code */
183 fpga = 0x80; fpga = 0xaf; fpga = 0x9b; /* length (ignored) */
184 fpga = 0x4b; /* field check code */
185
186 pdata = fpgadata;
187 /* while no error write out each of the 28 byte frames */
188 while ((porta & (FPGA_INIT_L | FPGA_DONE)) == FPGA_INIT_L
189 && pdata < fpgadata + sizeof(fpgadata)) {
190
191 fpga = 0x4f; /* preamble code */
192
193 /* 21 bytes of data in a frame */
194 fpga = *(pdata++); fpga = *(pdata++);
195 fpga = *(pdata++); fpga = *(pdata++);
196 fpga = *(pdata++); fpga = *(pdata++);
197 fpga = *(pdata++); fpga = *(pdata++);
198 fpga = *(pdata++); fpga = *(pdata++);
199 fpga = *(pdata++); fpga = *(pdata++);
200 fpga = *(pdata++); fpga = *(pdata++);
201 fpga = *(pdata++); fpga = *(pdata++);
202 fpga = *(pdata++); fpga = *(pdata++);
203 fpga = *(pdata++); fpga = *(pdata++);
204 fpga = *(pdata++);
205
206 fpga = 0x4b; /* field check code */
207 fpga = 0xff; /* extended write cycle */
208 fpga = 0x4b; /* extended write cycle
209 * (actually 0x4b from bitgen.exe)
210 */
211 fpga = 0xff; /* extended write cycle */
212 fpga = 0xff; /* extended write cycle */
213 fpga = 0xff; /* extended write cycle */
214 }
215
216 fpga = 0xff; /* startup byte */
217 fpga = 0xff; /* startup byte */
218 fpga = 0xff; /* startup byte */
219 fpga = 0xff; /* startup byte */
220
221#if 0 /* ### FIXME */
222 /* If didn't load all the data or FPGA_DONE is low the load failed.
223 * Maybe someday stop here and flash the status LED? The console
224 * is not configured, so can't print an error message. Can't write
225 * global variables to set a flag (except gd?).
226 * For now it must work.
227 */
228#endif
229
230 /* Now that the FPGA is loaded, set up the Dual UART chip
231 * selects. Must be done here since it may be used as the console.
232 */
233 upmconfig(UPMB, (uint *)duart_table, sizeof(duart_table)/sizeof(uint));
234
235 memctl->memc_mbmr = DUART_MBMR;
236 memctl->memc_or5 = DUART_OR_VALUE;
237 memctl->memc_br5 = DUART_BR5_VALUE;
238 memctl->memc_or6 = DUART_OR_VALUE;
239 memctl->memc_br6 = DUART_BR6_VALUE;
240
241 return (0);
242}
243
244/* ------------------------------------------------------------------------- */
245
246/* base address for SRAM, assume 32-bit port, valid */
247#define NVRAM_BR_VALUE (CFG_SRAM_BASE | BR_PS_32 | BR_V)
248
249/* up to 64MB - will be adjusted for actual size */
250#define NVRAM_OR_PRELIM (ORMASK(CFG_SRAM_SIZE) \
251 | OR_CSNT_SAM | OR_ACS_DIV4 | OR_BI | OR_SCY_5_CLK | OR_EHTR)
252/*
253 * Miscellaneous platform dependent initializations after running in RAM.
254 */
255
256int misc_init_r (void)
257{
258 DECLARE_GLOBAL_DATA_PTR;
259
260 volatile immap_t *immap = (immap_t *)CFG_IMMR;
261 volatile memctl8xx_t *memctl = &immap->im_memctl;
wdenk5840af22003-03-28 14:40:36 +0000262 char* s;
263 char* e;
264 int reg;
wdenk5b1d7132002-11-03 00:07:02 +0000265 bd_t *bd = gd->bd;
266
267 memctl->memc_or2 = NVRAM_OR_PRELIM;
268 memctl->memc_br2 = NVRAM_BR_VALUE;
269
270 /* Is there any SRAM? Is it 16 or 32 bits wide? */
271
272 /* First look for 32-bit SRAM */
273 bd->bi_sramsize = ram_size((ulong*)CFG_SRAM_BASE, CFG_SRAM_SIZE);
274
275 if (bd->bi_sramsize == 0) {
276 /* no 32-bit SRAM, but there could be 16-bit SRAM since
277 * it would report size 0 when configured for 32-bit bus.
278 * Try again with a 16-bit bus.
279 */
280 memctl->memc_br2 |= BR_PS_16;
281 bd->bi_sramsize = ram_size((ulong*)CFG_SRAM_BASE, CFG_SRAM_SIZE);
282 }
283
284 if (bd->bi_sramsize == 0) {
285 memctl->memc_br2 = 0; /* disable select since nothing there */
286 }
287 else {
288 /* adjust or2 for actual size of SRAM */
289 memctl->memc_or2 |= ORMASK(bd->bi_sramsize);
290 bd->bi_sramstart = CFG_SRAM_BASE;
291 printf("SRAM: %lu KB\n", bd->bi_sramsize >> 10);
292 }
293
294
295 /* set standard MPC8xx clock so kernel will see the time
296 * even if it doesn't have a DS1306 clock driver.
297 * This helps with experimenting with standard kernels.
298 */
299 {
300 ulong tim;
301 struct rtc_time tmp;
302
303 rtc_get(&tmp); /* get time from DS1306 RTC */
304
305 /* convert to seconds since 1970 */
306 tim = mktime(tmp.tm_year, tmp.tm_mon, tmp.tm_mday,
307 tmp.tm_hour, tmp.tm_min, tmp.tm_sec);
308
309 immap->im_sitk.sitk_rtck = KAPWR_KEY;
310 immap->im_sit.sit_rtc = tim;
311 }
312
wdenk5840af22003-03-28 14:40:36 +0000313 /* set up ethernet address for SCC ethernet. If eth1addr
314 * is present it gets a unique address, otherwise it
315 * shares the FEC address.
wdenk5b1d7132002-11-03 00:07:02 +0000316 */
wdenk5840af22003-03-28 14:40:36 +0000317 s = getenv("eth1addr");
318 if (s == NULL)
319 s = getenv("ethaddr");
320 for (reg=0; reg<6; ++reg) {
321 bd->bi_enet1addr[reg] = s ? simple_strtoul(s, &e, 16) : 0;
322 if (s)
323 s = (*e) ? e+1 : e;
324 }
wdenk5b1d7132002-11-03 00:07:02 +0000325
wdenk5b1d7132002-11-03 00:07:02 +0000326 return (0);
327}
328
wdenkabda5ca2003-05-31 18:35:21 +0000329#if (CONFIG_COMMANDS & CFG_CMD_NAND)
330void nand_init(void)
331{
332 nand_probe(CFG_DFLASH_BASE); /* see if any NAND flash present */
333 if (nand_dev_desc[0].ChipID != NAND_ChipID_UNKNOWN) {
334 puts("NAND: ");
335 print_size(nand_dev_desc[0].totlen, "\n");
336 }
337}
338#endif
339
wdenk5b1d7132002-11-03 00:07:02 +0000340/* ------------------------------------------------------------------------- */
341
342/*
343 * Check memory range for valid RAM. A simple memory test determines
344 * the actually available RAM size between addresses `base' and
345 * `base + maxsize'.
346 *
347 * The memory size MUST be a power of 2 for this to work.
348 *
wdenk5840af22003-03-28 14:40:36 +0000349 * The only memory modified is 8 bytes at offset 0. This is important
wdenk5b1d7132002-11-03 00:07:02 +0000350 * since for the SRAM this location is reserved for autosizing, so if
351 * it is modified and the board is reset before ram_size() completes
352 * no damage is done. Normally even the memory at 0 is preserved. The
353 * higher SRAM addresses may contain battery backed RAM disk data which
354 * must never be corrupted.
355 */
356
357static long ram_size(ulong *base, long maxsize)
358{
359 volatile long *test_addr;
360 volatile long *base_addr = base;
wdenk5b1d7132002-11-03 00:07:02 +0000361 ulong ofs; /* byte offset from base_addr */
362 ulong save; /* to make test non-destructive */
wdenk5840af22003-03-28 14:40:36 +0000363 ulong save2; /* to make test non-destructive */
wdenk5b1d7132002-11-03 00:07:02 +0000364 long ramsize = -1; /* size not determined yet */
365
366 save = *base_addr; /* save value at 0 so can restore */
wdenk5840af22003-03-28 14:40:36 +0000367 save2 = *(base_addr+1); /* save value at 4 so can restore */
wdenk5b1d7132002-11-03 00:07:02 +0000368
369 /* is any SRAM present? */
370 *base_addr = 0x5555aaaa;
371
wdenk5840af22003-03-28 14:40:36 +0000372 /* It is important to drive the data bus with different data so
373 * it doesn't remember the value and look like RAM that isn't there.
wdenk5b1d7132002-11-03 00:07:02 +0000374 */
wdenk5840af22003-03-28 14:40:36 +0000375 *(base_addr + 1) = 0xaaaa5555; /* use write to modify data bus */
wdenk5b1d7132002-11-03 00:07:02 +0000376
377 if (*base_addr != 0x5555aaaa)
378 ramsize = 0; /* no RAM present, or defective */
379 else {
380 *base_addr = 0xaaaa5555;
wdenk5840af22003-03-28 14:40:36 +0000381 *(base_addr + 1) = 0x5555aaaa; /* use write to modify data bus */
wdenk5b1d7132002-11-03 00:07:02 +0000382 if (*base_addr != 0xaaaa5555)
383 ramsize = 0; /* no RAM present, or defective */
384 }
385
386 /* now size it if any is present */
387 for (ofs = 4; ofs < maxsize && ramsize < 0; ofs <<= 1) {
388 test_addr = (long*)((long)base_addr + ofs); /* location to test */
389
390 *base_addr = ~*test_addr;
391 if (*base_addr == *test_addr)
392 ramsize = ofs; /* wrapped back to 0, so this is the size */
393 }
394
395 *base_addr = save; /* restore value at 0 */
wdenk5840af22003-03-28 14:40:36 +0000396 *(base_addr+1) = save2; /* restore value at 4 */
wdenk5b1d7132002-11-03 00:07:02 +0000397 return (ramsize);
398}
399
400/* ------------------------------------------------------------------------- */
401/* sdram table based on the FADS manual */
402/* for chip MB811171622A-100 */
403
404/* this table is for 50MHz operation, it should work at all lower speeds */
405
406const uint sdram_table[] =
407{
408 /* single read. (offset 0 in upm RAM) */
409 0x1f07fc04, 0xeeaefc04, 0x11adfc04, 0xefbbbc00,
410 0x1ff77c47,
411
412 /* precharge and Mode Register Set initialization (offset 5).
413 * This is also entered at offset 6 to do Mode Register Set
414 * without the precharge.
415 */
416 0x1ff77c34, 0xefeabc34, 0x1fb57c35,
417
418 /* burst read. (offset 8 in upm RAM) */
419 0x1f07fc04, 0xeeaefc04, 0x10adfc04, 0xf0affc00,
420 0xf0affc00, 0xf1affc00, 0xefbbbc00, 0x1ff77c47,
421 _not_used_, _not_used_, _not_used_, _not_used_,
422 _not_used_, _not_used_, _not_used_, _not_used_,
423
424 /* single write. (offset 18 in upm RAM) */
425 /* FADS had 0x1f27fc04, ...
426 * but most other boards have 0x1f07fc04, which
427 * sets GPL0 from A11MPC to 0 1/4 clock earlier,
428 * like the single read.
429 * This seems better so I am going with the change.
430 */
431 0x1f07fc04, 0xeeaebc00, 0x01b93c04, 0x1ff77c47,
432 _not_used_, _not_used_, _not_used_, _not_used_,
433
434 /* burst write. (offset 20 in upm RAM) */
435 0x1f07fc04, 0xeeaebc00, 0x10ad7c00, 0xf0affc00,
436 0xf0affc00, 0xe1bbbc04, 0x1ff77c47, _not_used_,
437 _not_used_, _not_used_, _not_used_, _not_used_,
438 _not_used_, _not_used_, _not_used_, _not_used_,
439
440 /* refresh. (offset 30 in upm RAM) */
441 0x1ff5fc84, 0xfffffc04, 0xfffffc04, 0xfffffc04,
442 0xfffffc84, 0xfffffc07, _not_used_, _not_used_,
443 _not_used_, _not_used_, _not_used_, _not_used_,
444
445 /* exception. (offset 3c in upm RAM) */
446 0x7ffffc07, _not_used_, _not_used_, _not_used_ };
447
448/* ------------------------------------------------------------------------- */
449
450#define SDRAM_MAX_SIZE 0x10000000 /* max 256 MB SDRAM */
451
452/* precharge and set Mode Register */
453#define SDRAM_MCR_PRE (MCR_OP_RUN | MCR_UPM_A | /* select UPM */ \
454 MCR_MB_CS3 | /* chip select */ \
455 MCR_MLCF(1) | MCR_MAD(5)) /* 1 time at 0x05 */
456
457/* set Mode Register, no precharge */
458#define SDRAM_MCR_MRS (MCR_OP_RUN | MCR_UPM_A | /* select UPM */ \
459 MCR_MB_CS3 | /* chip select */ \
460 MCR_MLCF(1) | MCR_MAD(6)) /* 1 time at 0x06 */
461
462/* runs refresh loop twice so get 8 refresh cycles */
463#define SDRAM_MCR_REFR (MCR_OP_RUN | MCR_UPM_A | /* select UPM */ \
464 MCR_MB_CS3 | /* chip select */ \
465 MCR_MLCF(2) | MCR_MAD(0x30)) /* twice at 0x30 */
466
467/* MAMR values work in either mamr or mbmr */
wdenk5840af22003-03-28 14:40:36 +0000468#define SDRAM_MAMR_BASE /* refresh at 50MHz */ \
wdenk5b1d7132002-11-03 00:07:02 +0000469 ((195 << MAMR_PTA_SHIFT) | MAMR_PTAE \
wdenk5b1d7132002-11-03 00:07:02 +0000470 | MAMR_DSA_1_CYCL /* 1 cycle disable */ \
wdenk5b1d7132002-11-03 00:07:02 +0000471 | MAMR_RLFA_1X /* Read loop 1 time */ \
472 | MAMR_WLFA_1X /* Write loop 1 time */ \
473 | MAMR_TLFA_4X) /* Timer loop 4 times */
wdenk5840af22003-03-28 14:40:36 +0000474/* 8 column SDRAM */
475#define SDRAM_MAMR_8COL (SDRAM_MAMR_BASE \
476 | MAMR_AMA_TYPE_0 /* Address MUX 0 */ \
477 | MAMR_G0CLA_A11) /* GPL0 A11[MPC] */
wdenk5b1d7132002-11-03 00:07:02 +0000478
479/* 9 column SDRAM */
wdenk5840af22003-03-28 14:40:36 +0000480#define SDRAM_MAMR_9COL (SDRAM_MAMR_BASE \
481 | MAMR_AMA_TYPE_1 /* Address MUX 1 */ \
482 | MAMR_G0CLA_A10) /* GPL0 A10[MPC] */
wdenk5b1d7132002-11-03 00:07:02 +0000483
484/* base address 0, 32-bit port, SDRAM UPM, valid */
485#define SDRAM_BR_VALUE (BR_PS_32 | BR_MS_UPMA | BR_V)
486
487/* up to 256MB, SAM, G5LS - will be adjusted for actual size */
488#define SDRAM_OR_PRELIM (ORMASK(SDRAM_MAX_SIZE) | OR_CSNT_SAM | OR_G5LS)
489
490/* This is the Mode Select Register value for the SDRAM.
491 * Burst length: 4
492 * Burst Type: sequential
493 * CAS Latency: 2
494 * Write Burst Length: burst
495 */
496#define SDRAM_MODE 0x22 /* CAS latency 2, burst length 4 */
497
498/* ------------------------------------------------------------------------- */
499
500long int initdram(int board_type)
501{
502 volatile immap_t *immap = (immap_t *)CFG_IMMR;
503 volatile memctl8xx_t *memctl = &immap->im_memctl;
504 uint size_sdram = 0;
505 uint size_sdram9 = 0;
506 uint base = 0; /* SDRAM must start at 0 */
507 int i;
508
509 upmconfig(UPMA, (uint *)sdram_table, sizeof(sdram_table)/sizeof(uint));
510
511 /* Configure the refresh (mostly). This needs to be
512 * based upon processor clock speed and optimized to provide
513 * the highest level of performance.
514 *
515 * Preliminary prescaler for refresh.
516 * This value is selected for four cycles in 31.2 us,
517 * which gives 8192 cycles in 64 milliseconds.
518 * This may be too fast, but works for any memory.
519 * It is adjusted to 4096 cycles in 64 milliseconds if
520 * possible once we know what memory we have.
521 *
522 * We have to be careful changing UPM registers after we
523 * ask it to run these commands.
524 *
525 * PTA - periodic timer period for our design is
526 * 50 MHz x 31.2us
527 * --------------- = 195
528 * 1 x 8 x 1
529 *
530 * 50MHz clock
531 * 31.2us refresh interval
532 * SCCR[DFBRG] 0
533 * PTP divide by 8
534 * 1 chip select
535 */
536 memctl->memc_mptpr = MPTPR_PTP_DIV8; /* 0x0800 */
537 memctl->memc_mamr = SDRAM_MAMR_8COL & (~MAMR_PTAE); /* no refresh yet */
538
539 /* The SDRAM Mode Register value is shifted left 2 bits since
540 * A30 and A31 don't connect to the SDRAM for 32-bit wide memory.
541 */
542 memctl->memc_mar = SDRAM_MODE << 2; /* MRS code */
543 udelay(200); /* SDRAM needs 200uS before set it up */
544
545 /* Now run the precharge/nop/mrs commands. */
546 memctl->memc_mcr = SDRAM_MCR_PRE;
547 udelay(2);
548
549 /* Run 8 refresh cycles (2 sets of 4) */
550 memctl->memc_mcr = SDRAM_MCR_REFR; /* run refresh twice */
551 udelay(2);
552
553 /* some brands want Mode Register set after the refresh
554 * cycles. This shouldn't hurt anything for the brands
555 * that were happy with the first time we set it.
556 */
557 memctl->memc_mcr = SDRAM_MCR_MRS;
558 udelay(2);
559
560 memctl->memc_mamr = SDRAM_MAMR_8COL; /* enable refresh */
561 memctl->memc_or3 = SDRAM_OR_PRELIM;
562 memctl->memc_br3 = SDRAM_BR_VALUE + base;
563
564 /* Some brands need at least 10 DRAM accesses to stabilize.
565 * It wont hurt the brands that don't.
566 */
567 for (i=0; i<10; ++i) {
568 volatile ulong *addr = (volatile ulong *)base;
569 ulong val;
570
571 val = *(addr + i);
572 *(addr + i) = val;
573 }
574
575 /* Check SDRAM memory Size in 8 column mode.
576 * For a 9 column memory we will get half the actual size.
577 */
578 size_sdram = ram_size((ulong *)0, SDRAM_MAX_SIZE);
579
580 /* Check SDRAM memory Size in 9 column mode.
581 * For an 8 column memory we will see at most 4 megabytes.
582 */
583 memctl->memc_mamr = SDRAM_MAMR_9COL;
584 size_sdram9 = ram_size((ulong *)0, SDRAM_MAX_SIZE);
585
586 if (size_sdram < size_sdram9) /* leave configuration at 9 columns */
587 size_sdram = size_sdram9;
588 else /* go back to 8 columns */
589 memctl->memc_mamr = SDRAM_MAMR_8COL;
590
591 /* adjust or3 for actual size of SDRAM
592 */
593 memctl->memc_or3 |= ORMASK(size_sdram);
594
595 /* Adjust refresh rate depending on SDRAM type.
596 * For types > 128 MBit (32 Mbyte for 2 x16 devices) leave
597 * it at the current (fast) rate.
598 * For 16, 64 and 128 MBit half the rate will do.
599 */
600 if (size_sdram <= 32 * 1024 * 1024)
601 memctl->memc_mptpr = MPTPR_PTP_DIV16; /* 0x0400 */
602
603 return (size_sdram);
604}
605