[kernel/2.6.38] refresh patches
[openwrt.git] / target / linux / mpc83xx / patches-2.6.36 / 013-drivers_ata_pata_rbppc_cf.patch
1 --- /dev/null
2 +++ b/drivers/ata/pata_rbppc_cf.c
3 @@ -0,0 +1,701 @@
4 +/*
5 + * Copyright (C) 2008-2009 Noah Fontes <nfontes@transtruct.org>
6 + * Copyright (C) Mikrotik 2007
7 + *
8 + * This program is free software; you can redistribute it and/or modify it
9 + * under the terms of the GNU General Public License as published by the
10 + * Free Software Foundation; either version 2 of the License, or (at your
11 + * option) any later version.
12 + */
13 +
14 +#include <linux/kernel.h>
15 +#include <linux/module.h>
16 +#include <linux/init.h>
17 +#include <scsi/scsi_host.h>
18 +#include <linux/libata.h>
19 +#include <linux/of_platform.h>
20 +#include <linux/ata_platform.h>
21 +
22 +#define DEBUG_UPM 0
23 +
24 +#define DRV_NAME "pata_rbppc_cf"
25 +#define DRV_VERSION "0.0.2"
26 +
27 +#define DEV2SEL_OFFSET 0x00100000
28 +
29 +#define IMMR_LBCFG_OFFSET 0x00005000
30 +#define IMMR_LBCFG_SIZE 0x00001000
31 +
32 +#define LOCAL_BUS_MCMR 0x00000078
33 +#define MxMR_OP_MASK 0x30000000
34 +#define MxMR_OP_NORMAL 0x00000000
35 +#define MxMR_OP_WRITE 0x10000000
36 +#define MxMR_OP_READ 0x20000000
37 +#define MxMR_OP_RUN 0x30000000
38 +#define MxMR_LUPWAIT_LOW 0x08000000
39 +#define MxMR_LUPWAIT_HIGH 0x00000000
40 +#define MxMR_LUPWAIT_ENABLE 0x00040000
41 +#define MxMR_RLF_MASK 0x0003c000
42 +#define MxMR_RLF_SHIFT 14
43 +#define MxMR_WLF_MASK 0x00003c00
44 +#define MxMR_WLF_SHIFT 10
45 +#define MxMR_MAD_MASK 0x0000003f
46 +#define LOCAL_BUS_MDR 0x00000088
47 +#define LOCAL_BUS_LCRR 0x000000D4
48 +#define LCRR_CLKDIV_MASK 0x0000000f
49 +
50 +#define LOOP_SIZE 4
51 +
52 +#define UPM_READ_SINGLE_OFFSET 0x00
53 +#define UPM_WRITE_SINGLE_OFFSET 0x18
54 +#define UPM_DATA_SIZE 0x40
55 +
56 +#define LBT_CPUIN_MIN 0
57 +#define LBT_CPUOUT_MIN 1
58 +#define LBT_CPUOUT_MAX 2
59 +#define LBT_EXTDEL_MIN 3
60 +#define LBT_EXTDEL_MAX 4
61 +#define LBT_SIZE 5
62 +
63 +/* UPM machine configuration bits */
64 +#define N_BASE 0x00f00000
65 +#define N_CS 0xf0000000
66 +#define N_CS_H1 0xc0000000
67 +#define N_CS_H2 0x30000000
68 +#define N_WE 0x0f000000
69 +#define N_WE_H1 0x0c000000
70 +#define N_WE_H2 0x03000000
71 +#define N_OE 0x00030000
72 +#define N_OE_H1 0x00020000
73 +#define N_OE_H2 0x00010000
74 +#define WAEN 0x00001000
75 +#define REDO_2 0x00000100
76 +#define REDO_3 0x00000200
77 +#define REDO_4 0x00000300
78 +#define LOOP 0x00000080
79 +#define NA 0x00000008
80 +#define UTA 0x00000004
81 +#define LAST 0x00000001
82 +
83 +#define REDO_VAL(mult) (REDO_2 * ((mult) - 1))
84 +#define REDO_MAX_MULT 4
85 +
86 +#define READ_BASE (N_BASE | N_WE)
87 +#define WRITE_BASE (N_BASE | N_OE)
88 +#define EMPTY (N_BASE | N_CS | N_OE | N_WE | LAST)
89 +
90 +#define EOF_UPM_SETTINGS 0
91 +#define ANOTHER_TIMING 1
92 +
93 +#define OA_CPUIN_MIN 0x01
94 +#define OA_CPUOUT_MAX 0x02
95 +#define OD_CPUOUT_MIN 0x04
96 +#define OA_CPUOUT_DELTA 0x06
97 +#define OA_EXTDEL_MAX 0x08
98 +#define OD_EXTDEL_MIN 0x10
99 +#define OA_EXTDEL_DELTA 0x18
100 +#define O_MIN_CYCLE_TIME 0x20
101 +#define O_MINUS_PREV 0x40
102 +#define O_HALF_CYCLE 0x80
103 +
104 +extern void __iomem *localbus_map(unsigned long addr, unsigned int len);
105 +extern void localbus_unmap(void __iomem *addr);
106 +
107 +struct rbppc_cf_info {
108 + unsigned lbcfg_addr;
109 + unsigned clk_time_ps;
110 + int cur_mode;
111 + u32 lb_timings[LBT_SIZE];
112 +};
113 +static struct rbppc_cf_info *rbinfo = NULL;
114 +
115 +struct upm_setting {
116 + unsigned value;
117 + unsigned ns[7];
118 + unsigned clk_minus;
119 + unsigned group_size;
120 + unsigned options;
121 +};
122 +
123 +static const struct upm_setting cfUpmReadSingle[] = {
124 + { READ_BASE | N_OE,
125 + /* t1 - ADDR setup time */
126 + { 70, 50, 30, 30, 25, 15, 10 }, 0, 0, (OA_CPUOUT_DELTA |
127 + OA_EXTDEL_MAX) },
128 + { READ_BASE | N_OE_H1,
129 + { 0, 0, 0, 0, 0, 0, 0 }, 0, 0, O_HALF_CYCLE },
130 + { READ_BASE,
131 + /* t2 - OE0 time */
132 + { 290, 290, 290, 80, 70, 65, 55 }, 0, 2, (OA_CPUOUT_MAX |
133 + OA_CPUIN_MIN) },
134 + { READ_BASE | WAEN,
135 + { 1, 1, 1, 1, 1, 0, 0 }, 0, 0, 0 },
136 + { READ_BASE | UTA,
137 + { 1, 1, 1, 1, 1, 1, 1 }, 0, 0, 0 },
138 + { READ_BASE | N_OE,
139 + /* t9 - ADDR hold time */
140 + { 20, 15, 10, 10, 10, 10, 10 }, 0, 0, (OA_CPUOUT_DELTA |
141 + OD_EXTDEL_MIN) },
142 + { READ_BASE | N_OE | N_CS_H2,
143 + { 0, 0, 0, 0, 0, 0, 0 }, 0, 0, O_HALF_CYCLE },
144 + { READ_BASE | N_OE | N_CS,
145 + /* t6Z -IORD data tristate */
146 + { 30, 30, 30, 30, 30, 20, 20 }, 1, 1, O_MINUS_PREV },
147 + { ANOTHER_TIMING,
148 + /* t2i -IORD recovery time */
149 + { 0, 0, 0, 70, 25, 25, 20 }, 2, 0, 0 },
150 + { ANOTHER_TIMING,
151 + /* CS 0 -> 1 MAX */
152 + { 0, 0, 0, 0, 0, 0, 0 }, 1, 0, (OA_CPUOUT_DELTA |
153 + OA_EXTDEL_MAX) },
154 + { READ_BASE | N_OE | N_CS | LAST,
155 + { 1, 1, 1, 1, 1, 1, 1 }, 0, 0, 0 },
156 + { EOF_UPM_SETTINGS,
157 + /* min total cycle time - includes turnaround and ALE cycle */
158 + { 600, 383, 240, 180, 120, 100, 80 }, 2, 0, O_MIN_CYCLE_TIME },
159 +};
160 +
161 +static const struct upm_setting cfUpmWriteSingle[] = {
162 + { WRITE_BASE | N_WE,
163 + /* t1 - ADDR setup time */
164 + { 70, 50, 30, 30, 25, 15, 10 }, 0, 0, (OA_CPUOUT_DELTA |
165 + OA_EXTDEL_MAX) },
166 + { WRITE_BASE | N_WE_H1,
167 + { 0, 0, 0, 0, 0, 0, 0 }, 0, 0, O_HALF_CYCLE },
168 + { WRITE_BASE,
169 + /* t2 - WE0 time */
170 + { 290, 290, 290, 80, 70, 65, 55 }, 0, 1, OA_CPUOUT_DELTA },
171 + { WRITE_BASE | WAEN,
172 + { 1, 1, 1, 1, 1, 0, 0 }, 0, 0, 0 },
173 + { WRITE_BASE | N_WE,
174 + /* t9 - ADDR hold time */
175 + { 20, 15, 10, 10, 10, 10, 10 }, 0, 0, (OA_CPUOUT_DELTA |
176 + OD_EXTDEL_MIN) },
177 + { WRITE_BASE | N_WE | N_CS_H2,
178 + { 0, 0, 0, 0, 0, 0, 0 }, 0, 0, O_HALF_CYCLE },
179 + { WRITE_BASE | N_WE | N_CS,
180 + /* t4 - DATA hold time */
181 + { 30, 20, 15, 10, 10, 10, 10 }, 0, 1, O_MINUS_PREV },
182 + { ANOTHER_TIMING,
183 + /* t2i -IOWR recovery time */
184 + { 0, 0, 0, 70, 25, 25, 20 }, 1, 0, 0 },
185 + { ANOTHER_TIMING,
186 + /* CS 0 -> 1 MAX */
187 + { 0, 0, 0, 0, 0, 0, 0 }, 0, 0, (OA_CPUOUT_DELTA |
188 + OA_EXTDEL_MAX) },
189 + { WRITE_BASE | N_WE | N_CS | UTA | LAST,
190 + { 1, 1, 1, 1, 1, 1, 1 }, 0, 0, 0 },
191 + /* min total cycle time - includes ALE cycle */
192 + { EOF_UPM_SETTINGS,
193 + { 600, 383, 240, 180, 120, 100, 80 }, 1, 0, O_MIN_CYCLE_TIME },
194 +};
195 +
196 +static u8 rbppc_cf_check_status(struct ata_port *ap) {
197 + u8 val = ioread8(ap->ioaddr.status_addr);
198 + if (val == 0xF9)
199 + val = 0x7F;
200 + return val;
201 +}
202 +
203 +static u8 rbppc_cf_check_altstatus(struct ata_port *ap) {
204 + u8 val = ioread8(ap->ioaddr.altstatus_addr);
205 + if (val == 0xF9)
206 + val = 0x7F;
207 + return val;
208 +}
209 +
210 +static void rbppc_cf_dummy_noret(struct ata_port *ap) { }
211 +static int rbppc_cf_dummy_ret0(struct ata_port *ap) { return 0; }
212 +
213 +static int ps2clk(int ps, unsigned clk_time_ps) {
214 + int psMaxOver;
215 + if (ps <= 0) return 0;
216 +
217 + /* round down if <= 2% over clk border, but no more than 1/4 clk cycle */
218 + psMaxOver = ps * 2 / 100;
219 + if (4 * psMaxOver > clk_time_ps) {
220 + psMaxOver = clk_time_ps / 4;
221 + }
222 + return (ps + clk_time_ps - 1 - psMaxOver) / clk_time_ps;
223 +}
224 +
225 +static int upm_gen_ps_table(const struct upm_setting *upm,
226 + int mode, struct rbppc_cf_info *info,
227 + int *psFinal) {
228 + int uidx;
229 + int lastUpmValIdx = 0;
230 + int group_start_idx = -1;
231 + int group_left_num = -1;
232 + int clk_time_ps = info->clk_time_ps;
233 +
234 + for (uidx = 0; upm[uidx].value != EOF_UPM_SETTINGS; ++uidx) {
235 + const struct upm_setting *us = upm + uidx;
236 + unsigned opt = us->options;
237 + int ps = us->ns[mode] * 1000 - us->clk_minus * clk_time_ps;
238 +
239 + if (opt & OA_CPUIN_MIN) ps += info->lb_timings[LBT_CPUIN_MIN];
240 + if (opt & OD_CPUOUT_MIN) ps -= info->lb_timings[LBT_CPUOUT_MIN];
241 + if (opt & OA_CPUOUT_MAX) ps += info->lb_timings[LBT_CPUOUT_MAX];
242 + if (opt & OD_EXTDEL_MIN) ps -= info->lb_timings[LBT_EXTDEL_MIN];
243 + if (opt & OA_EXTDEL_MAX) ps += info->lb_timings[LBT_EXTDEL_MAX];
244 +
245 + if (us->value == ANOTHER_TIMING) {
246 + /* use longest timing from alternatives */
247 + if (psFinal[lastUpmValIdx] < ps) {
248 + psFinal[lastUpmValIdx] = ps;
249 + }
250 + ps = 0;
251 + }
252 + else {
253 + if (us->group_size) {
254 + group_start_idx = uidx;
255 + group_left_num = us->group_size;
256 + }
257 + else if (group_left_num > 0) {
258 + /* group time is divided on all group members */
259 + int clk = ps2clk(ps, clk_time_ps);
260 + psFinal[group_start_idx] -= clk * clk_time_ps;
261 + --group_left_num;
262 + }
263 + if ((opt & O_MINUS_PREV) && lastUpmValIdx > 0) {
264 + int clk = ps2clk(psFinal[lastUpmValIdx],
265 + clk_time_ps);
266 + ps -= clk * clk_time_ps;
267 + }
268 + lastUpmValIdx = uidx;
269 + }
270 + psFinal[uidx] = ps;
271 + }
272 + return uidx;
273 +}
274 +
275 +static int free_half(int ps, int clk, int clk_time_ps) {
276 + if (clk < 2) return 0;
277 + return (clk * clk_time_ps - ps) * 2 >= clk_time_ps;
278 +}
279 +
280 +static void upm_gen_clk_table(const struct upm_setting *upm,
281 + int mode, int clk_time_ps,
282 + int max_uidx, const int *psFinal, int *clkFinal) {
283 + int clk_cycle_time;
284 + int clk_total;
285 + int uidx;
286 +
287 + /* convert picoseconds to clocks */
288 + clk_total = 0;
289 + for (uidx = 0; uidx < max_uidx; ++uidx) {
290 + int clk = ps2clk(psFinal[uidx], clk_time_ps);
291 + clkFinal[uidx] = clk;
292 + clk_total += clk;
293 + }
294 +
295 + /* check possibility of half cycle usage */
296 + for (uidx = 1; uidx < max_uidx - 1; ++uidx) {
297 + if ((upm[uidx].options & O_HALF_CYCLE) &&
298 + free_half(psFinal[uidx - 1], clkFinal[uidx - 1],
299 + clk_time_ps) &&
300 + free_half(psFinal[uidx + 1], clkFinal[uidx + 1],
301 + clk_time_ps)) {
302 + ++clkFinal[uidx];
303 + --clkFinal[uidx - 1];
304 + --clkFinal[uidx + 1];
305 + }
306 + }
307 +
308 + if ((upm[max_uidx].options & O_MIN_CYCLE_TIME) == 0) return;
309 +
310 + /* check cycle time, adjust timings if needed */
311 + clk_cycle_time = (ps2clk(upm[max_uidx].ns[mode] * 1000, clk_time_ps) -
312 + upm[max_uidx].clk_minus);
313 + uidx = 0;
314 + while (clk_total < clk_cycle_time) {
315 + /* extend all timings in round-robin to match cycle time */
316 + if (clkFinal[uidx]) {
317 +#if DEBUG_UPM
318 + printk(KERN_INFO "extending %u by 1 clk\n", uidx);
319 +#endif
320 + ++clkFinal[uidx];
321 + ++clk_total;
322 + }
323 + ++uidx;
324 + if (uidx == max_uidx) uidx = 0;
325 + }
326 +}
327 +
328 +static void add_data_val(unsigned val, int *clkLeft, int maxClk,
329 + unsigned *data, int *dataIdx) {
330 + if (*clkLeft == 0) return;
331 +
332 + if (maxClk == 0 && *clkLeft >= LOOP_SIZE * 2) {
333 + int times;
334 + int times1;
335 + int times2;
336 +
337 + times = *clkLeft / LOOP_SIZE;
338 + if (times > REDO_MAX_MULT * 2) times = REDO_MAX_MULT * 2;
339 + times1 = times / 2;
340 + times2 = times - times1;
341 +
342 + val |= LOOP;
343 + data[*dataIdx] = val | REDO_VAL(times1);
344 + ++(*dataIdx);
345 + data[*dataIdx] = val | REDO_VAL(times2);
346 + ++(*dataIdx);
347 +
348 + *clkLeft -= times * LOOP_SIZE;
349 + return;
350 + }
351 +
352 + if (maxClk < 1 || maxClk > REDO_MAX_MULT) maxClk = REDO_MAX_MULT;
353 + if (*clkLeft < maxClk) maxClk = *clkLeft;
354 +
355 + *clkLeft -= maxClk;
356 + val |= REDO_VAL(maxClk);
357 +
358 + data[*dataIdx] = val;
359 + ++(*dataIdx);
360 +}
361 +
362 +static int upm_gen_final_data(const struct upm_setting *upm,
363 + int max_uidx, int *clkFinal, unsigned *data) {
364 + int dataIdx;
365 + int uidx;
366 +
367 + dataIdx = 0;
368 + for (uidx = 0; uidx < max_uidx; ++uidx) {
369 + int clk = clkFinal[uidx];
370 + while (clk > 0) {
371 + add_data_val(upm[uidx].value, &clk, 0,
372 + data, &dataIdx);
373 + }
374 + }
375 + return dataIdx;
376 +}
377 +
378 +static int conv_upm_table(const struct upm_setting *upm,
379 + int mode, struct rbppc_cf_info *info,
380 + unsigned *data) {
381 +#if DEBUG_UPM
382 + int uidx;
383 +#endif
384 + int psFinal[32];
385 + int clkFinal[32];
386 + int max_uidx;
387 + int data_len;
388 +
389 + max_uidx = upm_gen_ps_table(upm, mode, info, psFinal);
390 +
391 + upm_gen_clk_table(upm, mode, info->clk_time_ps, max_uidx,
392 + psFinal, clkFinal);
393 +
394 +#if DEBUG_UPM
395 + /* dump out debug info */
396 + for (uidx = 0; uidx < max_uidx; ++uidx) {
397 + if (clkFinal[uidx]) {
398 + printk(KERN_INFO "idx %d val %08x clk %d ps %d\n",
399 + uidx, upm[uidx].value,
400 + clkFinal[uidx], psFinal[uidx]);
401 + }
402 + }
403 +#endif
404 +
405 + data_len = upm_gen_final_data(upm, max_uidx, clkFinal, data);
406 +
407 +#if DEBUG_UPM
408 + for (uidx = 0; uidx < data_len; ++uidx) {
409 + printk(KERN_INFO "cf UPM x result: idx %d val %08x\n",
410 + uidx, data[uidx]);
411 + }
412 +#endif
413 + return 0;
414 +}
415 +
416 +static int gen_upm_data(int mode, struct rbppc_cf_info *info, unsigned *data) {
417 + int i;
418 +
419 + for (i = 0; i < UPM_DATA_SIZE; ++i) {
420 + data[i] = EMPTY;
421 + }
422 +
423 + if (conv_upm_table(cfUpmReadSingle, mode, info, data + UPM_READ_SINGLE_OFFSET)) {
424 + return -1;
425 + }
426 + if (conv_upm_table(cfUpmWriteSingle, mode, info, data + UPM_WRITE_SINGLE_OFFSET)) {
427 + return -1;
428 + }
429 + return 0;
430 +}
431 +
432 +static void rbppc_cf_program_upm(void *upmMemAddr, volatile void *lbcfg_mxmr, volatile void *lbcfg_mdr, const unsigned *upmData, unsigned offset, unsigned len) {
433 + unsigned i;
434 + unsigned mxmr;
435 +
436 + mxmr = in_be32(lbcfg_mxmr);
437 + mxmr &= ~(MxMR_OP_MASK | MxMR_MAD_MASK);
438 + mxmr |= (MxMR_OP_WRITE | offset);
439 + out_be32(lbcfg_mxmr, mxmr);
440 + in_be32(lbcfg_mxmr); /* flush MxMR write */
441 +
442 + for (i = 0; i < len; ++i) {
443 + int to;
444 + unsigned data = upmData[i + offset];
445 + out_be32(lbcfg_mdr, data);
446 + in_be32(lbcfg_mdr); /* flush MDR write */
447 +
448 + iowrite8(1, upmMemAddr); /* dummy write to any CF addr */
449 +
450 + /* wait for dummy write to complete */
451 + for (to = 10000; to >= 0; --to) {
452 + mxmr = in_be32(lbcfg_mxmr);
453 + if (((mxmr ^ (i + 1)) & MxMR_MAD_MASK) == 0) {
454 + break;
455 + }
456 + if (to == 0) {
457 + printk(KERN_ERR "rbppc_cf_program_upm: UPMx program error at 0x%x: Timeout\n", i);
458 + }
459 + }
460 + }
461 + mxmr &= ~(MxMR_OP_MASK | MxMR_RLF_MASK | MxMR_WLF_MASK);
462 + mxmr |= (MxMR_OP_NORMAL | (LOOP_SIZE << MxMR_RLF_SHIFT) | (LOOP_SIZE << MxMR_WLF_SHIFT));
463 + out_be32(lbcfg_mxmr, mxmr);
464 +}
465 +
466 +static int rbppc_cf_update_piomode(struct ata_port *ap, int mode) {
467 + struct rbppc_cf_info *info = (struct rbppc_cf_info *)ap->host->private_data;
468 + void *lbcfgBase;
469 + unsigned upmData[UPM_DATA_SIZE];
470 +
471 + if (gen_upm_data(mode, info, upmData)) {
472 + return -1;
473 + }
474 +
475 + lbcfgBase = ioremap_nocache(info->lbcfg_addr, IMMR_LBCFG_SIZE);
476 +
477 + rbppc_cf_program_upm(ap->ioaddr.cmd_addr, ((char *)lbcfgBase) + LOCAL_BUS_MCMR, ((char *)lbcfgBase) + LOCAL_BUS_MDR, upmData, 0, UPM_DATA_SIZE);
478 + iounmap(lbcfgBase);
479 + return 0;
480 +}
481 +
482 +static void rbppc_cf_set_piomode(struct ata_port *ap, struct ata_device *adev)
483 +{
484 + struct rbppc_cf_info *info = (struct rbppc_cf_info *)ap->host->private_data;
485 + int mode = adev->pio_mode - XFER_PIO_0;
486 +
487 + DPRINTK("rbppc_cf_set_piomode: PIO %d\n", mode);
488 + if (mode < 0) mode = 0;
489 + if (mode > 6) mode = 6;
490 +
491 + if (info->cur_mode < 0 || info->cur_mode > mode) {
492 + if (rbppc_cf_update_piomode(ap, mode) == 0) {
493 + printk(KERN_INFO "rbppc_cf_set_piomode: PIO mode changed to %d\n", mode);
494 + info->cur_mode = mode;
495 + }
496 + }
497 +}
498 +
499 +static struct scsi_host_template rbppc_cf_sht = {
500 + ATA_BASE_SHT(DRV_NAME),
501 +};
502 +
503 +static struct ata_port_operations rbppc_cf_port_ops = {
504 + .inherits = &ata_bmdma_port_ops,
505 +
506 + .sff_check_status = rbppc_cf_check_status,
507 + .sff_check_altstatus = rbppc_cf_check_altstatus,
508 +
509 + .set_piomode = rbppc_cf_set_piomode,
510 +
511 + .port_start = rbppc_cf_dummy_ret0,
512 +
513 + .sff_irq_clear = rbppc_cf_dummy_noret,
514 +};
515 +
516 +static int rbppc_cf_init_info(struct of_device *pdev, struct rbppc_cf_info *info) {
517 + struct device_node *np;
518 + struct resource res;
519 + const u32 *u32ptr;
520 + void *lbcfgBase;
521 + void *lbcfg_lcrr;
522 + unsigned lbc_clk_khz;
523 + unsigned lbc_extra_divider = 1;
524 + unsigned ccb_freq_hz;
525 + unsigned lb_div;
526 +
527 + u32ptr = of_get_property(pdev->node, "lbc_extra_divider", NULL);
528 + if (u32ptr && *u32ptr) {
529 + lbc_extra_divider = *u32ptr;
530 +#if DEBUG_UPM
531 + printk(KERN_INFO "rbppc_cf_init_info: LBC extra divider %u\n",
532 + lbc_extra_divider);
533 +#endif
534 + }
535 +
536 + np = of_find_node_by_type(NULL, "serial");
537 + if (!np) {
538 + printk(KERN_ERR "rbppc_cf_init_info: No serial node found\n");
539 + return -1;
540 + }
541 + u32ptr = of_get_property(np, "clock-frequency", NULL);
542 + if (u32ptr == 0 || *u32ptr == 0) {
543 + printk(KERN_ERR "rbppc_cf_init_info: Serial does not have clock-frequency\n");
544 + of_node_put(np);
545 + return -1;
546 + }
547 + ccb_freq_hz = *u32ptr;
548 + of_node_put(np);
549 +
550 + np = of_find_node_by_type(NULL, "soc");
551 + if (!np) {
552 + printk(KERN_ERR "rbppc_cf_init_info: No soc node found\n");
553 + return -1;
554 + }
555 + if (of_address_to_resource(np, 0, &res)) {
556 + printk(KERN_ERR "rbppc_cf_init_info: soc does not have resource\n");
557 + of_node_put(np);
558 + return -1;
559 + }
560 + info->lbcfg_addr = res.start + IMMR_LBCFG_OFFSET;
561 + of_node_put(np);
562 +
563 + lbcfgBase = ioremap_nocache(info->lbcfg_addr, IMMR_LBCFG_SIZE);
564 + lbcfg_lcrr = ((char*)lbcfgBase) + LOCAL_BUS_LCRR;
565 + lb_div = (in_be32(lbcfg_lcrr) & LCRR_CLKDIV_MASK) * lbc_extra_divider;
566 + iounmap(lbcfgBase);
567 +
568 + lbc_clk_khz = ccb_freq_hz / (1000 * lb_div);
569 + info->clk_time_ps = 1000000000 / lbc_clk_khz;
570 + printk(KERN_INFO "rbppc_cf_init_info: Using Local-Bus clock %u kHz %u ps\n",
571 + lbc_clk_khz, info->clk_time_ps);
572 +
573 + u32ptr = of_get_property(pdev->node, "lb-timings", NULL);
574 + if (u32ptr) {
575 + memcpy(info->lb_timings, u32ptr, LBT_SIZE * sizeof(*u32ptr));
576 +#if DEBUG_UPM
577 + printk(KERN_INFO "rbppc_cf_init_info: Got LB timings <%u %u %u %u %u>\n",
578 + u32ptr[0], u32ptr[1], u32ptr[2], u32ptr[3], u32ptr[4]);
579 +#endif
580 + }
581 + info->cur_mode = -1;
582 + return 0;
583 +}
584 +
585 +static int rbppc_cf_probe(struct of_device *pdev,
586 + const struct of_device_id *match)
587 +{
588 + struct ata_host *host;
589 + struct ata_port *ap;
590 + struct rbppc_cf_info *info = NULL;
591 + struct resource res;
592 + void *baddr;
593 + const u32 *u32ptr;
594 + int irq_level = 0;
595 + int err = -ENOMEM;
596 +
597 + printk(KERN_INFO "rbppc_cf_probe: MikroTik RouterBOARD 600 series Compact Flash PATA driver, version " DRV_VERSION "\n");
598 +
599 + if (rbinfo == NULL) {
600 + info = kmalloc(sizeof(*info), GFP_KERNEL);
601 + if (info == NULL) {
602 + printk(KERN_ERR "rbppc_cf_probe: Out of memory\n");
603 + goto err_info;
604 + }
605 + memset(info, 0, sizeof(*info));
606 +
607 + if (rbppc_cf_init_info(pdev, info)) {
608 + goto err_info;
609 + }
610 + rbinfo = info;
611 + }
612 +
613 + u32ptr = of_get_property(pdev->node, "interrupt-at-level", NULL);
614 + if (u32ptr) {
615 + irq_level = *u32ptr;
616 + printk(KERN_INFO "rbppc_cf_probe: IRQ level %u\n", irq_level);
617 + }
618 +
619 + if (of_address_to_resource(pdev->node, 0, &res)) {
620 + printk(KERN_ERR "rbppc_cf_probe: No reg property found\n");
621 + goto err_info;
622 + }
623 +
624 + host = ata_host_alloc(&pdev->dev, 1);
625 + if (!host)
626 + goto err_info;
627 +
628 + baddr = localbus_map(res.start, res.end - res.start + 1);
629 + host->iomap = baddr;
630 + host->private_data = rbinfo;
631 +
632 + ap = host->ports[0];
633 + ap->ops = &rbppc_cf_port_ops;
634 + ap->pio_mask = 0x7F; /* PIO modes 0-6 */
635 + ap->flags = ATA_FLAG_NO_LEGACY;
636 + ap->mwdma_mask = 0;
637 +
638 + ap->ioaddr.cmd_addr = baddr;
639 + ata_sff_std_ports(&ap->ioaddr);
640 + ap->ioaddr.ctl_addr = ap->ioaddr.cmd_addr + 14;
641 + ap->ioaddr.altstatus_addr = ap->ioaddr.ctl_addr;
642 + ap->ioaddr.bmdma_addr = 0;
643 +
644 + err = ata_host_activate(
645 + host,
646 + irq_of_parse_and_map(pdev->node, 0), ata_sff_interrupt,
647 + irq_level ? IRQF_TRIGGER_HIGH : IRQF_TRIGGER_LOW,
648 + &rbppc_cf_sht);
649 + if (!err) return 0;
650 +
651 + localbus_unmap(baddr);
652 +err_info:
653 + if (info) {
654 + kfree(info);
655 + rbinfo = NULL;
656 + }
657 + return err;
658 +}
659 +
660 +static int rbppc_cf_remove(struct of_device *pdev)
661 +{
662 + struct device *dev = &pdev->dev;
663 + struct ata_host *host = dev_get_drvdata(dev);
664 +
665 + if (host == NULL) return -1;
666 +
667 + ata_host_detach(host);
668 + return 0;
669 +}
670 +
671 +static struct of_device_id rbppc_cf_ids[] = {
672 + { .name = "cf", },
673 + { },
674 +};
675 +
676 +static struct of_platform_driver rbppc_cf_driver = {
677 + .name = "cf",
678 + .probe = rbppc_cf_probe,
679 + .remove = rbppc_cf_remove,
680 + .match_table = rbppc_cf_ids,
681 + .driver = {
682 + .name = "rbppc-cf",
683 + .owner = THIS_MODULE,
684 + },
685 +};
686 +
687 +static int __init rbppc_init(void)
688 +{
689 + return of_register_platform_driver(&rbppc_cf_driver);
690 +}
691 +
692 +static void __exit rbppc_exit(void)
693 +{
694 + of_unregister_platform_driver(&rbppc_cf_driver);
695 +}
696 +
697 +MODULE_AUTHOR("Mikrotikls SIA");
698 +MODULE_AUTHOR("Noah Fontes");
699 +MODULE_DESCRIPTION("MikroTik RouterBOARD 600 series Compact Flash PATA driver");
700 +MODULE_LICENSE("GPL");
701 +MODULE_VERSION(DRV_VERSION);
702 +
703 +module_init(rbppc_init);
704 +module_exit(rbppc_exit);
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