Subversion Repositories freemyipod

Rev

Go to most recent revision | Details | Last modification | View Log | RSS feed

Rev Author Line No. Line
2 theseven 1 
//
2 
//
3 
//    Copyright 2010 TheSeven
4 
//
5 
//
427 farthen 6 
//    This file is part of emCORE.
2 theseven 7 
//
427 farthen 8 
//    emCORE is free software: you can redistribute it and/or
2 theseven 9 
//    modify it under the terms of the GNU General Public License as
10 
//    published by the Free Software Foundation, either version 2 of the
11 
//    License, or (at your option) any later version.
12 
//
427 farthen 13 
//    emCORE is distributed in the hope that it will be useful,
2 theseven 14 
//    but WITHOUT ANY WARRANTY; without even the implied warranty of
15 
//    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
16 
//    See the GNU General Public License for more details.
17 
//
18 
//    You should have received a copy of the GNU General Public License along
427 farthen 19 
//    with emCORE.  If not, see <http://www.gnu.org/licenses/>.
2 theseven 20 
//
21 
//
22 
 
23 
 
24 
#include "global.h"
54 theseven 25 
#include "panic.h"
26 
#include "thread.h"
2 theseven 27 
#include "util.h"
28 
#include "timer.h"
29 
#include "nand.h"
54 theseven 30 
#include "pmu.h"
31 
#include "mmu.h"
85 theseven 32 
#include "s5l8701.h"
2 theseven 33 
 
34 
#define NAND_CMD_READ       0x00
35 
#define NAND_CMD_PROGCNFRM  0x10
36 
#define NAND_CMD_READ2      0x30
37 
#define NAND_CMD_BLOCKERASE 0x60
38 
#define NAND_CMD_GET_STATUS 0x70
39 
#define NAND_CMD_PROGRAM    0x80
40 
#define NAND_CMD_ERASECNFRM 0xD0
41 
#define NAND_CMD_RESET      0xFF
42 
 
43 
#define NAND_STATUS_READY   0x40
44 
 
45 
static const struct nand_device_info_type nand_deviceinfotable[] =
46 
{
47 
    {0x1580F1EC, 1024, 968, 0x40, 6, 2, 1, 2, 1},
48 
    {0x1580DAEC, 2048, 1936, 0x40, 6, 2, 1, 2, 1},
49 
    {0x15C1DAEC, 2048, 1936, 0x40, 6, 2, 1, 2, 1},
50 
    {0x1510DCEC, 4096, 3872, 0x40, 6, 2, 1, 2, 1},
51 
    {0x95C1DCEC, 4096, 3872, 0x40, 6, 2, 1, 2, 1},
52 
    {0x2514DCEC, 2048, 1936, 0x80, 7, 2, 1, 2, 1},
53 
    {0x2514D3EC, 4096, 3872, 0x80, 7, 2, 1, 2, 1},
54 
    {0x2555D3EC, 4096, 3872, 0x80, 7, 2, 1, 2, 1},
55 
    {0x2555D5EC, 8192, 7744, 0x80, 7, 2, 1, 2, 1},
56 
    {0x2585D3AD, 4096, 3872, 0x80, 7, 3, 2, 3, 2},
57 
    {0x9580DCAD, 4096, 3872, 0x40, 6, 3, 2, 3, 2},
58 
    {0xA514D3AD, 4096, 3872, 0x80, 7, 3, 2, 3, 2},
59 
    {0xA550D3AD, 4096, 3872, 0x80, 7, 3, 2, 3, 2},
60 
    {0xA560D5AD, 4096, 3872, 0x80, 7, 3, 2, 3, 2},
61 
    {0xA555D5AD, 8192, 7744, 0x80, 7, 3, 2, 3, 2},
62 
    {0xA585D598, 8320, 7744, 0x80, 7, 3, 1, 2, 1},
63 
    {0xA584D398, 4160, 3872, 0x80, 7, 3, 1, 2, 1},
64 
    {0x95D1D32C, 8192, 7744, 0x40, 6, 2, 1, 2, 1},
65 
    {0x1580DC2C, 4096, 3872, 0x40, 6, 2, 1, 2, 1},
66 
    {0x15C1D32C, 8192, 7744, 0x40, 6, 2, 1, 2, 1},
67 
    {0x9590DC2C, 4096, 3872, 0x40, 6, 2, 1, 2, 1},
68 
    {0xA594D32C, 4096, 3872, 0x80, 7, 2, 1, 2, 1},
69 
    {0x2584DC2C, 2048, 1936, 0x80, 7, 2, 1, 2, 1},
70 
    {0xA5D5D52C, 8192, 7744, 0x80, 7, 3, 2, 2, 1},
71 
    {0x95D1D389, 8192, 7744, 0x40, 6, 2, 1, 2, 1},
72 
    {0x1580DC89, 4096, 3872, 0x40, 6, 2, 1, 2, 1},
73 
    {0x15C1D389, 8192, 7744, 0x40, 6, 2, 1, 2, 1},
74 
    {0x9590DC89, 4096, 3872, 0x40, 6, 2, 1, 2, 1},
75 
    {0xA594D389, 4096, 3872, 0x80, 7, 2, 1, 2, 1},
76 
    {0x2584DC89, 2048, 1936, 0x80, 7, 2, 1, 2, 1},
77 
    {0xA5D5D589, 8192, 7744, 0x80, 7, 2, 1, 2, 1},
78 
    {0xA514D320, 4096, 3872, 0x80, 7, 2, 1, 2, 1},
79 
    {0xA555D520, 8192, 3872, 0x80, 7, 2, 1, 2, 1}
80 
};
81 
 
66 theseven 82 
static uint8_t nand_tunk1[4];
83 
static uint8_t nand_twp[4];
84 
static uint8_t nand_tunk2[4];
85 
static uint8_t nand_tunk3[4];
86 
static int nand_type[4];
87 
static int nand_powered = 0;
88 
static int nand_interleaved = 0;
89 
static int nand_cached = 0;
90 
static long nand_last_activity_value = -1;
429 theseven 91 
static struct scheduler_thread nand_thread_handle;
92 
static uint32_t nand_stack[0x80] STACK_ATTR;
2 theseven 93 
 
54 theseven 94 
static struct mutex nand_mtx;
95 
static struct wakeup nand_wakeup;
96 
static struct mutex ecc_mtx;
97 
static struct wakeup ecc_wakeup;
2 theseven 98 
 
54 theseven 99 
static uint8_t nand_ctrl[0x200] CACHEALIGN_ATTR;
100 
static uint8_t nand_spare[0x40] CACHEALIGN_ATTR;
101 
static uint8_t nand_ecc[0x30] CACHEALIGN_ATTR;
2 theseven 102 
 
54 theseven 103 
 
66 theseven 104 
static uint32_t nand_unlock(uint32_t rc)
54 theseven 105 
{
106 
    nand_last_activity_value = USEC_TIMER;
107 
    mutex_unlock(&nand_mtx);
108 
    return rc;
109 
}
110 
 
66 theseven 111 
static uint32_t ecc_unlock(uint32_t rc)
54 theseven 112 
{
113 
    mutex_unlock(&ecc_mtx);
114 
    return rc;
115 
}
116 
 
66 theseven 117 
static uint32_t nand_timeout(long timeout)
54 theseven 118 
{
119 
    if (TIME_AFTER(USEC_TIMER, timeout)) return 1;
120 
    else
121 
    {
122 
        yield();
123 
        return 0;
124 
    }
125 
}
126 
 
66 theseven 127 
static uint32_t nand_wait_rbbdone(void)
2 theseven 128 
{
54 theseven 129 
    uint32_t timeout = USEC_TIMER + 20000;
130 
    while (!(FMCSTAT & FMCSTAT_RBBDONE))
131 
        if (nand_timeout(timeout)) return 1;
2 theseven 132 
    FMCSTAT = FMCSTAT_RBBDONE;
133 
    return 0;
134 
}
135 
 
66 theseven 136 
static uint32_t nand_wait_cmddone(void)
2 theseven 137 
{
54 theseven 138 
    uint32_t timeout = USEC_TIMER + 20000;
139 
    while (!(FMCSTAT & FMCSTAT_CMDDONE))
140 
        if (nand_timeout(timeout)) return 1;
2 theseven 141 
    FMCSTAT = FMCSTAT_CMDDONE;
142 
    return 0;
143 
}
144 
 
66 theseven 145 
static uint32_t nand_wait_addrdone(void)
2 theseven 146 
{
54 theseven 147 
    uint32_t timeout = USEC_TIMER + 20000;
148 
    while (!(FMCSTAT & FMCSTAT_ADDRDONE))
149 
        if (nand_timeout(timeout)) return 1;
2 theseven 150 
    FMCSTAT = FMCSTAT_ADDRDONE;
151 
    return 0;
152 
}
153 
 
66 theseven 154 
static uint32_t nand_wait_chip_ready(uint32_t bank)
2 theseven 155 
{
54 theseven 156 
    uint32_t timeout = USEC_TIMER + 20000;
157 
    while (!(FMCSTAT & (FMCSTAT_BANK0READY << bank)))
158 
        if (nand_timeout(timeout)) return 1;
2 theseven 159 
    FMCSTAT = (FMCSTAT_BANK0READY << bank);
160 
    return 0;
161 
}
162 
 
66 theseven 163 
static void nand_set_fmctrl0(uint32_t bank, uint32_t flags)
2 theseven 164 
{
165 
    FMCTRL0 = (nand_tunk1[bank] << 16) | (nand_twp[bank] << 12)
166 
            | (1 << 11) | 1 | (1 << (bank + 1)) | flags;
167 
}
168 
 
66 theseven 169 
static uint32_t nand_send_cmd(uint32_t cmd)
2 theseven 170 
{
171 
    FMCMD = cmd;
172 
    return nand_wait_rbbdone();
173 
}
174 
 
66 theseven 175 
static uint32_t nand_send_address(uint32_t page, uint32_t offset)
2 theseven 176 
{
177 
    FMANUM = 4;
178 
    FMADDR0 = (page << 16) | offset;
179 
    FMADDR1 = (page >> 16) & 0xFF;
180 
    FMCTRL1 = FMCTRL1_DOTRANSADDR;
181 
    return nand_wait_cmddone();
182 
}
183 
 
184 
uint32_t nand_reset(uint32_t bank)
185 
{
186 
    nand_set_fmctrl0(bank, 0);
187 
    if (nand_send_cmd(NAND_CMD_RESET)) return 1;
188 
    if (nand_wait_chip_ready(bank)) return 1;
189 
    FMCTRL1 = FMCTRL1_CLEARRFIFO | FMCTRL1_CLEARWFIFO;
190 
    sleep(1000);
191 
    return 0;
192 
}
193 
 
66 theseven 194 
static uint32_t nand_wait_status_ready(uint32_t bank)
2 theseven 195 
{
54 theseven 196 
    uint32_t timeout = USEC_TIMER + 20000;
2 theseven 197 
    nand_set_fmctrl0(bank, 0);
198 
    if ((FMCSTAT & (FMCSTAT_BANK0READY << bank)))
199 
        FMCSTAT = (FMCSTAT_BANK0READY << bank);
200 
    FMCTRL1 = FMCTRL1_CLEARRFIFO;
201 
    if (nand_send_cmd(NAND_CMD_GET_STATUS)) return 1;
202 
    while (1)
203 
    {
54 theseven 204 
        if (nand_timeout(timeout)) return 1;
2 theseven 205 
        FMDNUM = 0;
206 
        FMCTRL1 = FMCTRL1_DOREADDATA;
207 
        if (nand_wait_addrdone()) return 1;
208 
        if ((FMFIFO & NAND_STATUS_READY)) break;
209 
        FMCTRL1 = FMCTRL1_CLEARRFIFO;
210 
    }
211 
    FMCTRL1 = FMCTRL1_CLEARRFIFO;
212 
    return nand_send_cmd(NAND_CMD_READ);
213 
}
214 
 
66 theseven 215 
static void nand_transfer_data_start(uint32_t bank, uint32_t direction,
216 
                                     void* buffer, uint32_t size)
2 theseven 217 
{
218 
    nand_set_fmctrl0(bank, FMCTRL0_ENABLEDMA);
219 
    FMDNUM = size - 1;
220 
    FMCTRL1 = FMCTRL1_DOREADDATA << direction;
221 
    DMACON3 = (2 << DMACON_DEVICE_SHIFT)
222 
            | (direction << DMACON_DIRECTION_SHIFT)
223 
            | (2 << DMACON_DATA_SIZE_SHIFT)
224 
            | (3 << DMACON_BURST_LEN_SHIFT);
225 
    while ((DMAALLST & DMAALLST_CHAN3_MASK))
226 
        DMACOM3 = DMACOM_CLEARBOTHDONE;
265 theseven 227 
    DMABASE3 = buffer;
2 theseven 228 
    DMATCNT3 = (size >> 4) - 1;
636 theseven 229 
    if (direction) clean_dcache();
230 
    else invalidate_dcache();
2 theseven 231 
    DMACOM3 = 4;
54 theseven 232 
}
233 
 
66 theseven 234 
static uint32_t nand_transfer_data_collect(uint32_t direction)
54 theseven 235 
{
236 
    uint32_t timeout = USEC_TIMER + 20000;
251 theseven 237 
    while (DMAALLST & DMAALLST_DMABUSY3)
54 theseven 238 
        if (nand_timeout(timeout)) return 1;
2 theseven 239 
    if (nand_wait_addrdone()) return 1;
240 
    if (!direction) FMCTRL1 = FMCTRL1_CLEARRFIFO | FMCTRL1_CLEARWFIFO;
241 
    else FMCTRL1 = FMCTRL1_CLEARRFIFO;
242 
    return 0;
243 
}
244 
 
66 theseven 245 
static uint32_t nand_transfer_data(uint32_t bank, uint32_t direction,
246 
                                   void* buffer, uint32_t size)
2 theseven 247 
{
54 theseven 248 
    nand_transfer_data_start(bank, direction, buffer, size);
249 
    uint32_t rc = nand_transfer_data_collect(direction);
250 
    return rc;
251 
}
252 
 
66 theseven 253 
static void ecc_start(uint32_t size, void* databuffer, void* sparebuffer,
254 
                      uint32_t type)
54 theseven 255 
{
256 
    mutex_lock(&ecc_mtx, TIMEOUT_BLOCK);
2 theseven 257 
    ECC_INT_CLR = 1;
85 theseven 258 
    SRCPND = (1 << IRQ_ECC);
2 theseven 259 
    ECC_UNK1 = size;
265 theseven 260 
    ECC_DATA_PTR = databuffer;
261 
    ECC_SPARE_PTR = sparebuffer;
636 theseven 262 
    invalidate_dcache();
54 theseven 263 
    ECC_CTRL = type;
264 
}
265 
 
66 theseven 266 
static uint32_t ecc_collect(void)
54 theseven 267 
{
268 
    uint32_t timeout = USEC_TIMER + 20000;
85 theseven 269 
    while (!(SRCPND & (1 << IRQ_ECC)))
54 theseven 270 
        if (nand_timeout(timeout)) return ecc_unlock(1);
2 theseven 271 
    ECC_INT_CLR = 1;
85 theseven 272 
    SRCPND = (1 << IRQ_ECC);
54 theseven 273 
    return ecc_unlock(ECC_RESULT);
2 theseven 274 
}
275 
 
66 theseven 276 
static uint32_t ecc_decode(uint32_t size, void* databuffer, void* sparebuffer)
54 theseven 277 
{
278 
    ecc_start(size, databuffer, sparebuffer, ECCCTRL_STARTDECODING);
279 
    uint32_t rc = ecc_collect();
280 
    return rc;
281 
}
282 
 
66 theseven 283 
static uint32_t ecc_encode(uint32_t size, void* databuffer, void* sparebuffer)
2 theseven 284 
{
54 theseven 285 
    ecc_start(size, databuffer, sparebuffer, ECCCTRL_STARTENCODING);
286 
    ecc_collect();
2 theseven 287 
    return 0;
288 
}
289 
 
66 theseven 290 
static uint32_t nand_check_empty(uint8_t* buffer)
2 theseven 291 
{
292 
    uint32_t i, count;
293 
    count = 0;
294 
    for (i = 0; i < 0x40; i++) if (buffer[i] != 0xFF) count++;
295 
    if (count < 2) return 1;
296 
    return 0;
297 
}
298 
 
66 theseven 299 
static uint32_t nand_get_chip_type(uint32_t bank)
2 theseven 300 
{
54 theseven 301 
    mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
2 theseven 302 
    uint32_t result;
61 theseven 303 
    if (nand_reset(bank)) return nand_unlock(0xFFFFFFFE);
304 
    if (nand_send_cmd(0x90)) return nand_unlock(0xFFFFFFFD);
2 theseven 305 
    FMANUM = 0;
306 
    FMADDR0 = 0;
307 
    FMCTRL1 = FMCTRL1_DOTRANSADDR;
61 theseven 308 
    if (nand_wait_cmddone()) return nand_unlock(0xFFFFFFFC);
2 theseven 309 
    FMDNUM = 4;
310 
    FMCTRL1 = FMCTRL1_DOREADDATA;
61 theseven 311 
    if (nand_wait_addrdone()) return nand_unlock(0xFFFFFFFB);
2 theseven 312 
    result = FMFIFO;
313 
    FMCTRL1 = FMCTRL1_CLEARRFIFO;
54 theseven 314 
    return nand_unlock(result);
2 theseven 315 
}
316 
 
54 theseven 317 
void nand_set_active(void)
2 theseven 318 
{
54 theseven 319 
    nand_last_activity_value = USEC_TIMER;
320 
}
321 
 
322 
long nand_last_activity(void)
323 
{
324 
    return nand_last_activity_value;
325 
}
326 
 
327 
void nand_power_up(void)
328 
{
329 
    uint32_t i;
330 
    mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
331 
    nand_last_activity_value = USEC_TIMER;
88 theseven 332 
    PWRCON(1) &= ~0x40;
333 
    PWRCON(0) &= ~0x100000;
54 theseven 334 
    PCON2 = 0x33333333;
335 
    PDAT2 = 0;
336 
    PCON3 = 0x11113333;
337 
    PDAT3 = 0;
338 
    PCON4 = 0x33333333;
339 
    PDAT4 = 0;
340 
    PCON5 = (PCON5 & ~0xF) | 3;
341 
    PUNK5 = 1;
342 
    pmu_ldo_set_voltage(4, 0x15);
343 
    pmu_ldo_power_on(4);
344 
    sleep(50000);
345 
    nand_last_activity_value = USEC_TIMER;
346 
    for (i = 0; i < 4; i++)
61 theseven 347 
        if (nand_type[i] >= 0)
348 
            if (nand_reset(i))
249 theseven 349 
				panicf(PANIC_KILLTHREAD, "nand_power_up: nand_reset(bank=%d) failed.", (unsigned int)i);
54 theseven 350 
    nand_powered = 1;
351 
    nand_last_activity_value = USEC_TIMER;
352 
    mutex_unlock(&nand_mtx);
353 
}
354 
 
355 
void nand_power_down(void)
356 
{
357 
    if (!nand_powered) return;
358 
    mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
359 
    pmu_ldo_power_off(4);
360 
    PCON2 = 0x11111111;
361 
    PDAT2 = 0;
362 
    PCON3 = 0x11111111;
363 
    PDAT3 = 0;
364 
    PCON4 = 0x11111111;
365 
    PDAT4 = 0;
366 
    PCON5 = (PCON5 & ~0xF) | 1;
367 
    PUNK5 = 1;
88 theseven 368 
    PWRCON(1) |= 0x40;
369 
    PWRCON(0) |= 0x100000;
54 theseven 370 
    nand_powered = 0;
371 
    mutex_unlock(&nand_mtx);
372 
}
373 
 
374 
uint32_t nand_read_page(uint32_t bank, uint32_t page, void* databuffer,
375 
                        void* sparebuffer, uint32_t doecc,
376 
                        uint32_t checkempty)
377 
{
224 theseven 378 
#ifdef NAND_TRACE
379 
    DEBUGF("NAND: Read bank %d, page %d", bank, page);
380 
#endif
68 theseven 381 
    uint8_t* data = (uint8_t*)databuffer;
54 theseven 382 
    uint8_t* spare = nand_spare;
68 theseven 383 
    if (sparebuffer) spare = (uint8_t*)sparebuffer;
69 theseven 384 
	if ((uint32_t)databuffer & (CACHEALIGN_SIZE - 1))
249 theseven 385 
		panicf(PANIC_KILLTHREAD,
68 theseven 386 
	           "nand_read_page: Misaligned data buffer at %08X (bank %lu, page %lu)",
387 
			   (unsigned int)databuffer, bank, page);
69 theseven 388 
	if ((uint32_t)sparebuffer & (CACHEALIGN_SIZE - 1))
249 theseven 389 
		panicf(PANIC_KILLTHREAD,
68 theseven 390 
	           "nand_read_page: Misaligned spare buffer at %08X (bank %lu, page %lu)",
391 
			   (unsigned int)sparebuffer, bank, page);
54 theseven 392 
    mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
393 
    nand_last_activity_value = USEC_TIMER;
394 
    if (!nand_powered) nand_power_up();
2 theseven 395 
    uint32_t rc, eccresult;
396 
    nand_set_fmctrl0(bank, FMCTRL0_ENABLEDMA);
54 theseven 397 
    if (nand_send_cmd(NAND_CMD_READ)) return nand_unlock(1);
68 theseven 398 
    if (nand_send_address(page, data ? 0 : 0x800))
54 theseven 399 
        return nand_unlock(1);
400 
    if (nand_send_cmd(NAND_CMD_READ2)) return nand_unlock(1);
401 
    if (nand_wait_status_ready(bank)) return nand_unlock(1);
68 theseven 402 
    if (data)
54 theseven 403 
        if (nand_transfer_data(bank, 0, data, 0x800))
404 
            return nand_unlock(1);
2 theseven 405 
    rc = 0;
406 
    if (!doecc)
407 
    {
408 
        if (sparebuffer)
409 
        {
54 theseven 410 
            if (nand_transfer_data(bank, 0, spare, 0x40))
411 
                return nand_unlock(1);
2 theseven 412 
            if (checkempty)
54 theseven 413 
                rc = nand_check_empty((uint8_t*)sparebuffer) << 1;
2 theseven 414 
        }
54 theseven 415 
        return nand_unlock(rc);
2 theseven 416 
    }
54 theseven 417 
    if (nand_transfer_data(bank, 0, spare, 0x40)) return nand_unlock(1);
418 
    if (databuffer)
2 theseven 419 
    {
54 theseven 420 
        memcpy(nand_ecc, &spare[0xC], 0x28);
2 theseven 421 
        rc |= (ecc_decode(3, data, nand_ecc) & 0xF) << 4;
422 
    }
423 
    memset(nand_ctrl, 0xFF, 0x200);
424 
    memcpy(nand_ctrl, spare, 0xC);
54 theseven 425 
    memcpy(nand_ecc, &spare[0x34], 0xC);
2 theseven 426 
    eccresult = ecc_decode(0, nand_ctrl, nand_ecc);
427 
    rc |= (eccresult & 0xF) << 8;
54 theseven 428 
    if (sparebuffer)
2 theseven 429 
    {
54 theseven 430 
        if (eccresult & 1) memset(sparebuffer, 0xFF, 0xC);
431 
        else memcpy(sparebuffer, nand_ctrl, 0xC);
2 theseven 432 
    }
433 
    if (checkempty) rc |= nand_check_empty(spare) << 1;
224 theseven 434 
#ifdef NAND_DEBUG
435 
    if ((rc & 2) == 0)
436 
    {
437 
        if ((rc & 0x10) != 0)
438 
            DEBUGF("NAND: ECC failed to correct bank %d page %d user data!", bank, page);
439 
        if ((rc & 0xE0) != 0)
440 
            DEBUGF("NAND: ECC corrected %d errors in bank %d page %d user data!", rc >> 5, bank, page);
441 
        if ((rc & 0x100) != 0)
442 
            DEBUGF("NAND: ECC failed to correct bank %d page %d control data!", bank, page);
443 
        if ((rc & 0xE00) != 0)
444 
            DEBUGF("NAND: ECC corrected %d errors in bank %d page %d control data!", (rc >> 9) & 7, bank, page);
445 
    }
446 
#ifdef NAND_TRACE
447 
    else DEBUGF("NAND: Bank %d page %d: Erased page!", bank, page);
448 
#endif
449 
#endif
54 theseven 450 
 
224 theseven 451 
#ifdef NAND_TRACE
452 
    DEBUGF("NAND: Read success, RC=%X", rc);
453 
#endif
54 theseven 454 
    return nand_unlock(rc);
2 theseven 455 
}
456 
 
66 theseven 457 
static uint32_t nand_write_page_int(uint32_t bank, uint32_t page,
458 
                                    void* databuffer, void* sparebuffer,
459 
                                    uint32_t doecc, uint32_t wait)
2 theseven 460 
{
224 theseven 461 
#ifdef NAND_TRACE
462 
    DEBUGF("NAND: Write bank %d, page %d", bank, page);
463 
#endif
68 theseven 464 
    uint8_t* data = (uint8_t*)databuffer;
2 theseven 465 
    uint8_t* spare = nand_spare;
68 theseven 466 
    if (sparebuffer) spare = (uint8_t*)sparebuffer;
467 
	if ((uint32_t)databuffer & 0xf)
249 theseven 468 
		panicf(PANIC_KILLTHREAD,
68 theseven 469 
	           "nand_write_page: Misaligned data buffer at %08X (bank %lu, page %lu)",
470 
			   (unsigned int)databuffer, bank, page);
471 
	if ((uint32_t)sparebuffer & 0xf)
249 theseven 472 
		panicf(PANIC_KILLTHREAD,
68 theseven 473 
	           "nand_write_page: Misaligned spare buffer at %08X (bank %lu, page %lu)",
474 
			   (unsigned int)sparebuffer, bank, page);
54 theseven 475 
    mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
476 
    nand_last_activity_value = USEC_TIMER;
477 
    if (!nand_powered) nand_power_up();
68 theseven 478 
    if (!sparebuffer) memset(spare, 0xFF, 0x40);
54 theseven 479 
    nand_set_fmctrl0(bank, FMCTRL0_ENABLEDMA);
480 
    if (nand_send_cmd(NAND_CMD_PROGRAM)) return nand_unlock(1);
68 theseven 481 
    if (nand_send_address(page, data ? 0 : 0x800))
54 theseven 482 
        return nand_unlock(1);
68 theseven 483 
    if (data) nand_transfer_data_start(bank, 1, data, 0x800);
2 theseven 484 
    if (doecc)
485 
    {
54 theseven 486 
        if (ecc_encode(3, data, nand_ecc)) return nand_unlock(1);
2 theseven 487 
        memcpy(&spare[0xC], nand_ecc, 0x28);
488 
        memset(nand_ctrl, 0xFF, 0x200);
489 
        memcpy(nand_ctrl, spare, 0xC);
54 theseven 490 
        if (ecc_encode(0, nand_ctrl, nand_ecc)) return nand_unlock(1);
2 theseven 491 
        memcpy(&spare[0x34], nand_ecc, 0xC);
492 
    }
68 theseven 493 
    if (data)
54 theseven 494 
        if (nand_transfer_data_collect(1))
495 
            return nand_unlock(1);
2 theseven 496 
    if (sparebuffer || doecc)
54 theseven 497 
        if (nand_transfer_data(bank, 1, spare, 0x40))
498 
            return nand_unlock(1);
499 
    if (nand_send_cmd(NAND_CMD_PROGCNFRM)) return nand_unlock(1);
500 
    if (wait) if (nand_wait_status_ready(bank)) return nand_unlock(1);
501 
    return nand_unlock(0);
2 theseven 502 
}
503 
 
504 
uint32_t nand_block_erase(uint32_t bank, uint32_t page)
505 
{
224 theseven 506 
#ifdef NAND_TRACE
507 
    DEBUGF("NAND: Block erase starting at bank %d, page %d", bank, page);
508 
#endif
54 theseven 509 
    mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
510 
    nand_last_activity_value = USEC_TIMER;
511 
    if (!nand_powered) nand_power_up();
2 theseven 512 
    nand_set_fmctrl0(bank, 0);
54 theseven 513 
    if (nand_send_cmd(NAND_CMD_BLOCKERASE)) return nand_unlock(1);
2 theseven 514 
    FMANUM = 2;
515 
    FMADDR0 = page;
516 
    FMCTRL1 = FMCTRL1_DOTRANSADDR;
54 theseven 517 
    if (nand_wait_cmddone()) return nand_unlock(1);
518 
    if (nand_send_cmd(NAND_CMD_ERASECNFRM)) return nand_unlock(1);
519 
    if (nand_wait_status_ready(bank)) return nand_unlock(1);
520 
    return nand_unlock(0);
521 
}
522 
 
523 
uint32_t nand_read_page_fast(uint32_t page, void* databuffer,
524 
                             void* sparebuffer, uint32_t doecc,
525 
                             uint32_t checkempty)
526 
{
224 theseven 527 
#ifdef NAND_TRACE
528 
    DEBUGF("NAND: Read all banks, page %d", page);
529 
#endif
54 theseven 530 
    uint32_t i, rc = 0;
531 
    if (((uint32_t)databuffer & 0xf) || ((uint32_t)sparebuffer & 0xf)
532 
     || !databuffer || !sparebuffer || !doecc)
533 
    {
534 
        for (i = 0; i < 4; i++)
535 
        {
61 theseven 536 
            if (nand_type[i] < 0) continue;
54 theseven 537 
            void* databuf = (void*)0;
538 
            void* sparebuf = (void*)0;
539 
            if (databuffer) databuf = (void*)((uint32_t)databuffer + 0x800 * i);
540 
            if (sparebuffer) sparebuf = (void*)((uint32_t)sparebuffer + 0x40 * i);
541 
            uint32_t ret = nand_read_page(i, page, databuf, sparebuf, doecc, checkempty);
542 
            if (ret & 1) rc |= 1 << (i << 2);
543 
            if (ret & 2) rc |= 2 << (i << 2);
544 
            if (ret & 0x10) rc |= 4 << (i << 2);
545 
            if (ret & 0x100) rc |= 8 << (i << 2);
546 
        }
547 
        return rc;
548 
    }
549 
    mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
550 
    nand_last_activity_value = USEC_TIMER;
551 
    if (!nand_powered) nand_power_up();
552 
    uint8_t status[4];
61 theseven 553 
    for (i = 0; i < 4; i++) status[i] = (nand_type[i] < 0);
54 theseven 554 
    for (i = 0; i < 4; i++)
555 
    {
556 
        if (!status[i])
557 
        {
558 
            nand_set_fmctrl0(i, FMCTRL0_ENABLEDMA);
559 
            if (nand_send_cmd(NAND_CMD_READ))
560 
                status[i] = 1;
561 
        }
562 
        if (!status[i])
563 
            if (nand_send_address(page, 0))
564 
                status[i] = 1;
565 
        if (!status[i])
566 
            if (nand_send_cmd(NAND_CMD_READ2))
567 
                status[i] = 1;
568 
    }
569 
    if (!status[0])
570 
        if (nand_wait_status_ready(0))
571 
            status[0] = 1;
572 
    if (!status[0])
573 
        if (nand_transfer_data(0, 0, databuffer, 0x800))
574 
            status[0] = 1;
575 
    if (!status[0])
576 
        if (nand_transfer_data(0, 0, sparebuffer, 0x40))
577 
            status[0] = 1;
578 
    for (i = 1; i < 4; i++)
579 
    {
580 
        if (!status[i])
581 
            if (nand_wait_status_ready(i))
582 
                status[i] = 1;
583 
        if (!status[i])
584 
            nand_transfer_data_start(i, 0, (void*)((uint32_t)databuffer
585 
                                                 + 0x800 * i), 0x800);
586 
        if (!status[i - 1])
587 
        {
588 
            memcpy(nand_ecc, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1) + 0xC), 0x28);
589 
            ecc_start(3, (void*)((uint32_t)databuffer
590 
                               + 0x800 * (i - 1)), nand_ecc, ECCCTRL_STARTDECODING);
591 
        }
592 
        if (!status[i])
593 
            if (nand_transfer_data_collect(0))
594 
                status[i] = 1;
595 
        if (!status[i])
596 
            nand_transfer_data_start(i, 0, (void*)((uint32_t)sparebuffer
597 
                                                 + 0x40 * i), 0x40);
598 
        if (!status[i - 1])
599 
            if (ecc_collect() & 1)
600 
                status[i - 1] = 4;
601 
        if (!status[i - 1])
602 
        {
603 
            memset(nand_ctrl, 0xFF, 0x200);
604 
            memcpy(nand_ctrl, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), 0xC);
605 
            memcpy(nand_ecc, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1) + 0x34), 0xC);
606 
            ecc_start(0, nand_ctrl, nand_ecc, ECCCTRL_STARTDECODING);
607 
        }
608 
        if (!status[i])
609 
            if (nand_transfer_data_collect(0))
610 
                status[i] = 1;
611 
        if (!status[i - 1])
612 
        {
613 
            if (ecc_collect() & 1)
614 
            {
615 
                status[i - 1] |= 8;
616 
                memset((void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), 0xFF, 0xC);
617 
            }
618 
            else memcpy((void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), nand_ctrl, 0xC);
619 
            if (checkempty)
620 
                status[i - 1] |= nand_check_empty((void*)((uint32_t)sparebuffer
621 
                                                        + 0x40 * (i - 1))) << 1;
622 
        }
623 
    }
624 
    if (!status[i - 1])
625 
    {
626 
        memcpy(nand_ecc,(void*)((uint32_t)sparebuffer + 0x40 * (i - 1) + 0xC), 0x28);
627 
        if (ecc_decode(3, (void*)((uint32_t)databuffer
628 
                                + 0x800 * (i - 1)), nand_ecc) & 1)
629 
            status[i - 1] = 4;
630 
    }
631 
    if (!status[i - 1])
632 
    {
633 
        memset(nand_ctrl, 0xFF, 0x200);
634 
        memcpy(nand_ctrl, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), 0xC);
635 
        memcpy(nand_ecc, (void*)((uint32_t)sparebuffer + 0x40 * (i - 1) + 0x34), 0xC);
636 
        if (ecc_decode(0, nand_ctrl, nand_ecc) & 1)
637 
        {
638 
            status[i - 1] |= 8;
639 
            memset((void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), 0xFF, 0xC);
640 
        }
641 
        else memcpy((void*)((uint32_t)sparebuffer + 0x40 * (i - 1)), nand_ctrl, 0xC);
642 
        if (checkempty)
643 
            status[i - 1] |= nand_check_empty((void*)((uint32_t)sparebuffer
644 
                                                    + 0x40 * (i - 1))) << 1;
645 
    }
646 
    for (i = 0; i < 4; i++)
61 theseven 647 
        if (nand_type[i] < 0)
54 theseven 648 
            rc |= status[i] << (i << 2);
649 
    return nand_unlock(rc);
650 
}
651 
 
652 
uint32_t nand_write_page(uint32_t bank, uint32_t page, void* databuffer,
653 
                         void* sparebuffer, uint32_t doecc)
654 
{
655 
    return nand_write_page_int(bank, page, databuffer, sparebuffer, doecc, 1);
656 
}
657 
 
658 
uint32_t nand_write_page_start(uint32_t bank, uint32_t page, void* databuffer,
659 
                               void* sparebuffer, uint32_t doecc)
660 
{
224 theseven 661 
#ifdef NAND_TRACE
662 
    DEBUGF("NAND: Write all banks, page %d", page);
663 
#endif
54 theseven 664 
    if (((uint32_t)databuffer & 0xf) || ((uint32_t)sparebuffer & 0xf)
665 
     || !databuffer || !sparebuffer || !doecc || !nand_interleaved)
666 
        return nand_write_page_int(bank, page, databuffer, sparebuffer, doecc, !nand_interleaved);
667 
 
668 
    mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
669 
    nand_last_activity_value = USEC_TIMER;
670 
    if (!nand_powered) nand_power_up();
671 
    nand_set_fmctrl0(bank, FMCTRL0_ENABLEDMA);
672 
    if (nand_send_cmd(NAND_CMD_PROGRAM))
673 
        return nand_unlock(1);
674 
    if (nand_send_address(page, 0))
675 
        return nand_unlock(1);
676 
    nand_transfer_data_start(bank, 1, databuffer, 0x800);
677 
    if (ecc_encode(3, databuffer, nand_ecc))
678 
        return nand_unlock(1);
679 
    memcpy((void*)((uint32_t)sparebuffer + 0xC), nand_ecc, 0x28);
680 
    memset(nand_ctrl, 0xFF, 0x200);
681 
    memcpy(nand_ctrl, sparebuffer, 0xC);
682 
    if (ecc_encode(0, nand_ctrl, nand_ecc))
683 
        return nand_unlock(1);
684 
    memcpy((void*)((uint32_t)sparebuffer + 0x34), nand_ecc, 0xC);
685 
    if (nand_transfer_data_collect(0))
686 
        return nand_unlock(1);
687 
    if (nand_transfer_data(bank, 1, sparebuffer, 0x40))
688 
        return nand_unlock(1);
689 
    return nand_unlock(nand_send_cmd(NAND_CMD_PROGCNFRM));
690 
}
691 
 
692 
uint32_t nand_write_page_collect(uint32_t bank)
693 
{
2 theseven 694 
    return nand_wait_status_ready(bank);
695 
}
696 
 
66 theseven 697 
static uint32_t nand_block_erase_fast(uint32_t page)
2 theseven 698 
{
699 
    uint32_t i, rc = 0;
54 theseven 700 
    mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
701 
    nand_last_activity_value = USEC_TIMER;
702 
    if (!nand_powered) nand_power_up();
2 theseven 703 
    for (i = 0; i < 4; i++)
704 
    {
61 theseven 705 
        if (nand_type[i] < 0) continue;
2 theseven 706 
        nand_set_fmctrl0(i, 0);
707 
        if (nand_send_cmd(NAND_CMD_BLOCKERASE))
708 
        {
709 
            rc |= 1 << i;
710 
            continue;
711 
        }
712 
        FMANUM = 2;
713 
        FMADDR0 = page;
714 
        FMCTRL1 = FMCTRL1_DOTRANSADDR;
715 
        if (nand_wait_cmddone())
716 
        {
717 
            rc |= 1 << i;
718 
            continue;
719 
        }
720 
        if (nand_send_cmd(NAND_CMD_ERASECNFRM)) rc |= 1 << i;
721 
    }
722 
    for (i = 0; i < 4; i++)
723 
    {
61 theseven 724 
        if (nand_type[i] < 0) continue;
2 theseven 725 
        if (rc & (1 << i)) continue;
726 
        if (nand_wait_status_ready(i)) rc |= 1 << i;
727 
    }
54 theseven 728 
    return nand_unlock(rc);
2 theseven 729 
}
730 
 
731 
const struct nand_device_info_type* nand_get_device_type(uint32_t bank)
732 
{
61 theseven 733 
    if (nand_type[bank] < 0)
2 theseven 734 
        return (struct nand_device_info_type*)0;
735 
    return &nand_deviceinfotable[nand_type[bank]];
736 
}
737 
 
835 theseven 738 
static void nand_thread(void* arg0, void* arg1, void* arg2, void* arg3)
2 theseven 739 
{
54 theseven 740 
    while (1)
741 
    {
300 theseven 742 
        mutex_lock(&nand_mtx, TIMEOUT_BLOCK);
54 theseven 743 
        if (TIME_AFTER(USEC_TIMER, nand_last_activity_value + 200000) && nand_powered)
744 
            nand_power_down();
300 theseven 745 
        mutex_unlock(&nand_mtx);
54 theseven 746 
        sleep(100000);
747 
    }
748 
}
749 
 
61 theseven 750 
int nand_device_init(void)
54 theseven 751 
{
752 
    mutex_init(&nand_mtx);
753 
    wakeup_init(&nand_wakeup);
754 
    mutex_init(&ecc_mtx);
755 
    wakeup_init(&ecc_wakeup);
756 
 
2 theseven 757 
    uint32_t type;
758 
    uint32_t i, j;
54 theseven 759 
 
760 
    /* Assume there are 0 banks, to prevent
761 
       nand_power_up from talking with them yet. */
61 theseven 762 
    for (i = 0; i < 4; i++) nand_type[i] = -1;
54 theseven 763 
    nand_power_up();
764 
 
765 
    /* Now that the flash is powered on, detect how
766 
       many banks we really have and initialize them. */
2 theseven 767 
    for (i = 0; i < 4; i++)
768 
    {
769 
        nand_tunk1[i] = 7;
770 
        nand_twp[i] = 7;
771 
        nand_tunk2[i] = 7;
772 
        nand_tunk3[i] = 7;
773 
        type = nand_get_chip_type(i);
61 theseven 774 
        if (type >= 0xFFFFFFF0)
775 
        {
776 
            nand_type[i] = (int)type;
777 
            continue;
778 
        }
2 theseven 779 
        for (j = 0; ; j++)
780 
        {
58 theseven 781 
            if (j == ARRAYLEN(nand_deviceinfotable)) break;
2 theseven 782 
            else if (nand_deviceinfotable[j].id == type)
783 
            {
784 
                nand_type[i] = j;
785 
                break;
786 
            }
787 
        }
788 
        nand_tunk1[i] = nand_deviceinfotable[nand_type[i]].tunk1;
789 
        nand_twp[i] = nand_deviceinfotable[nand_type[i]].twp;
790 
        nand_tunk2[i] = nand_deviceinfotable[nand_type[i]].tunk2;
791 
        nand_tunk3[i] = nand_deviceinfotable[nand_type[i]].tunk3;
792 
    }
61 theseven 793 
    if (nand_type[0] < 0) return nand_type[0];
54 theseven 794 
    nand_interleaved = ((nand_type[0] >> 22) & 1);
795 
    nand_cached = ((nand_type[0] >> 23) & 1);
796 
 
797 
    nand_last_activity_value = USEC_TIMER;
429 theseven 798 
    thread_create(&nand_thread_handle, "NAND idle monitor", nand_thread, nand_stack,
835 theseven 799 
                  sizeof(nand_stack), OS_THREAD, 1, true, NULL, NULL, NULL, NULL);
54 theseven 800 
 
2 theseven 801 
    return 0;
802 
}