1
 /*
2
  * A driver for the PCMCIA Smartcard Reader "Omnikey CardMan Mobile 4000"
3
  *
4
  * cm4000_cs.c [email protected]
5
  *
6
  * Tue Oct 23 11:32:43 GMT 2001 herp - cleaned up header files
7
  * Sun Jan 20 10:11:15 MET 2002 herp - added modversion header files
8
  * Thu Nov 14 16:34:11 GMT 2002 mh   - added PPS functionality
9
  * Tue Nov 19 16:36:27 GMT 2002 mh   - added SUSPEND/RESUME functionailty
10
  * Wed Jul 28 12:55:01 CEST 2004 mh  - kernel 2.6 adjustments
11
  *
12
  * current version: 2.4.0gm4
13
  *
14
  * (C) 2000,2001,2002,2003,2004 Omnikey AG
15
  *
16
  * (C) 2005-2006 Harald Welte <[email protected]>
17
  * 	- Adhere to Kernel CodingStyle
18
  * 	- Port to 2.6.13 "new" style PCMCIA
19
  * 	- Check for copy_{from,to}_user return values
20
  * 	- Use nonseekable_open()
21
  * 	- add class interface for udev device creation
22
  *
23
  * All rights reserved. Licensed under dual BSD/GPL license.
24
  */
25

26
#include <linux/kernel.h>
27
#include <linux/module.h>
28
#include <linux/slab.h>
29
#include <linux/init.h>
30
#include <linux/fs.h>
31
#include <linux/delay.h>
32
#include <linux/bitrev.h>
33
#include <linux/mutex.h>
34
#include <linux/uaccess.h>
35
#include <linux/io.h>
36

37
#include <pcmcia/cistpl.h>
38
#include <pcmcia/cisreg.h>
39
#include <pcmcia/ciscode.h>
40
#include <pcmcia/ds.h>
41

42
#include <linux/cm4000_cs.h>
43

44
/* #define ATR_CSUM */
45

46
#define reader_to_dev(x)	(&x->p_dev->dev)
47

48
/* n (debug level) is ignored */
49
/* additional debug output may be enabled by re-compiling with
50
 * CM4000_DEBUG set */
51
/* #define CM4000_DEBUG */
52
#define DEBUGP(n, rdr, x, args...) do { 		\
53
		dev_dbg(reader_to_dev(rdr), "%s:" x, 	\
54
			   __func__ , ## args);		\
55
	} while (0)
56

57
static DEFINE_MUTEX(cmm_mutex);
58

59
#define	T_1SEC		(HZ)
60
#define	T_10MSEC	msecs_to_jiffies(10)
61
#define	T_20MSEC	msecs_to_jiffies(20)
62
#define	T_40MSEC	msecs_to_jiffies(40)
63
#define	T_50MSEC	msecs_to_jiffies(50)
64
#define	T_100MSEC	msecs_to_jiffies(100)
65
#define	T_500MSEC	msecs_to_jiffies(500)
66

67
static void cm4000_release(struct pcmcia_device *link);
68

69
static int major;		/* major number we get from the kernel */
70

71
/* note: the first state has to have number 0 always */
72

73
#define	M_FETCH_ATR	0
74
#define	M_TIMEOUT_WAIT	1
75
#define	M_READ_ATR_LEN	2
76
#define	M_READ_ATR	3
77
#define	M_ATR_PRESENT	4
78
#define	M_BAD_CARD	5
79
#define M_CARDOFF	6
80

81
#define	LOCK_IO			0
82
#define	LOCK_MONITOR		1
83

84
#define IS_AUTOPPS_ACT		 6
85
#define	IS_PROCBYTE_PRESENT	 7
86
#define	IS_INVREV		 8
87
#define IS_ANY_T0		 9
88
#define	IS_ANY_T1		10
89
#define	IS_ATR_PRESENT		11
90
#define	IS_ATR_VALID		12
91
#define	IS_CMM_ABSENT		13
92
#define	IS_BAD_LENGTH		14
93
#define	IS_BAD_CSUM		15
94
#define	IS_BAD_CARD		16
95

96
#define REG_FLAGS0(x)		(x + 0)
97
#define REG_FLAGS1(x)		(x + 1)
98
#define REG_NUM_BYTES(x)	(x + 2)
99
#define REG_BUF_ADDR(x)		(x + 3)
100
#define REG_BUF_DATA(x)		(x + 4)
101
#define REG_NUM_SEND(x)		(x + 5)
102
#define REG_BAUDRATE(x)		(x + 6)
103
#define REG_STOPBITS(x)		(x + 7)
104

105
struct cm4000_dev {
106
	struct pcmcia_device *p_dev;
107

108
	unsigned char atr[MAX_ATR];
109
	unsigned char rbuf[512];
110
	unsigned char sbuf[512];
111

112
	wait_queue_head_t devq;		/* when removing cardman must not be
113
					   zeroed! */
114

115
	wait_queue_head_t ioq;		/* if IO is locked, wait on this Q */
116
	wait_queue_head_t atrq;		/* wait for ATR valid */
117
	wait_queue_head_t readq;	/* used by write to wake blk.read */
118

119
	/* warning: do not move this fields.
120
	 * initialising to zero depends on it - see ZERO_DEV below.  */
121
	unsigned char atr_csum;
122
	unsigned char atr_len_retry;
123
	unsigned short atr_len;
124
	unsigned short rlen;	/* bytes avail. after write */
125
	unsigned short rpos;	/* latest read pos. write zeroes */
126
	unsigned char procbyte;	/* T=0 procedure byte */
127
	unsigned char mstate;	/* state of card monitor */
128
	unsigned char cwarn;	/* slow down warning */
129
	unsigned char flags0;	/* cardman IO-flags 0 */
130
	unsigned char flags1;	/* cardman IO-flags 1 */
131
	unsigned int mdelay;	/* variable monitor speeds, in jiffies */
132

133
	unsigned int baudv;	/* baud value for speed */
134
	unsigned char ta1;
135
	unsigned char proto;	/* T=0, T=1, ... */
136
	unsigned long flags;	/* lock+flags (MONITOR,IO,ATR) * for concurrent
137
				   access */
138

139
	unsigned char pts[4];
140

141
	struct timer_list timer;	/* used to keep monitor running */
142
	int monitor_running;
143
};
144

145
#define	ZERO_DEV(dev)  						\
146
	memset(&dev->atr_csum,0,				\
147
		sizeof(struct cm4000_dev) - 			\
148
		offsetof(struct cm4000_dev, atr_csum))
149

150
static struct pcmcia_device *dev_table[CM4000_MAX_DEV];
151
static struct class *cmm_class;
152

153
/* This table doesn't use spaces after the comma between fields and thus
154
 * violates CodingStyle.  However, I don't really think wrapping it around will
155
 * make it any clearer to read -HW */
156
static unsigned char fi_di_table[10][14] = {
157
/*FI     00   01   02   03   04   05   06   07   08   09   10   11   12   13 */
158
/*DI */
159
/* 0 */ {0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11},
160
/* 1 */ {0x01,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x91,0x11,0x11,0x11,0x11},
161
/* 2 */ {0x02,0x12,0x22,0x32,0x11,0x11,0x11,0x11,0x11,0x92,0xA2,0xB2,0x11,0x11},
162
/* 3 */ {0x03,0x13,0x23,0x33,0x43,0x53,0x63,0x11,0x11,0x93,0xA3,0xB3,0xC3,0xD3},
163
/* 4 */ {0x04,0x14,0x24,0x34,0x44,0x54,0x64,0x11,0x11,0x94,0xA4,0xB4,0xC4,0xD4},
164
/* 5 */ {0x00,0x15,0x25,0x35,0x45,0x55,0x65,0x11,0x11,0x95,0xA5,0xB5,0xC5,0xD5},
165
/* 6 */ {0x06,0x16,0x26,0x36,0x46,0x56,0x66,0x11,0x11,0x96,0xA6,0xB6,0xC6,0xD6},
166
/* 7 */ {0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11,0x11},
167
/* 8 */ {0x08,0x11,0x28,0x38,0x48,0x58,0x68,0x11,0x11,0x98,0xA8,0xB8,0xC8,0xD8},
168
/* 9 */ {0x09,0x19,0x29,0x39,0x49,0x59,0x69,0x11,0x11,0x99,0xA9,0xB9,0xC9,0xD9}
169
};
170

171
#ifndef CM4000_DEBUG
172
#define	xoutb	outb
173
#define	xinb	inb
174
#else
175
static inline void xoutb(unsigned char val, unsigned short port)
176
{
177
	pr_debug("outb(val=%.2x,port=%.4x)\n", val, port);
178
	outb(val, port);
179
}
180
static inline unsigned char xinb(unsigned short port)
181
{
182
	unsigned char val;
183

184
	val = inb(port);
185
	pr_debug("%.2x=inb(%.4x)\n", val, port);
186

187
	return val;
188
}
189
#endif
190

191
static inline unsigned char invert_revert(unsigned char ch)
192
{
193
	return bitrev8(~ch);
194
}
195

196
static void str_invert_revert(unsigned char *b, int len)
197
{
198
	int i;
199

200
	for (i = 0; i < len; i++)
201
		b[i] = invert_revert(b[i]);
202
}
203

204
#define	ATRLENCK(dev,pos) \
205
	if (pos>=dev->atr_len || pos>=MAX_ATR) \
206
		goto return_0;
207

208
static unsigned int calc_baudv(unsigned char fidi)
209
{
210
	unsigned int wcrcf, wbrcf, fi_rfu, di_rfu;
211

212
	fi_rfu = 372;
213
	di_rfu = 1;
214

215
	/* FI */
216
	switch ((fidi >> 4) & 0x0F) {
217
	case 0x00:
218
		wcrcf = 372;
219
		break;
220
	case 0x01:
221
		wcrcf = 372;
222
		break;
223
	case 0x02:
224
		wcrcf = 558;
225
		break;
226
	case 0x03:
227
		wcrcf = 744;
228
		break;
229
	case 0x04:
230
		wcrcf = 1116;
231
		break;
232
	case 0x05:
233
		wcrcf = 1488;
234
		break;
235
	case 0x06:
236
		wcrcf = 1860;
237
		break;
238
	case 0x07:
239
		wcrcf = fi_rfu;
240
		break;
241
	case 0x08:
242
		wcrcf = fi_rfu;
243
		break;
244
	case 0x09:
245
		wcrcf = 512;
246
		break;
247
	case 0x0A:
248
		wcrcf = 768;
249
		break;
250
	case 0x0B:
251
		wcrcf = 1024;
252
		break;
253
	case 0x0C:
254
		wcrcf = 1536;
255
		break;
256
	case 0x0D:
257
		wcrcf = 2048;
258
		break;
259
	default:
260
		wcrcf = fi_rfu;
261
		break;
262
	}
263

264
	/* DI */
265
	switch (fidi & 0x0F) {
266
	case 0x00:
267
		wbrcf = di_rfu;
268
		break;
269
	case 0x01:
270
		wbrcf = 1;
271
		break;
272
	case 0x02:
273
		wbrcf = 2;
274
		break;
275
	case 0x03:
276
		wbrcf = 4;
277
		break;
278
	case 0x04:
279
		wbrcf = 8;
280
		break;
281
	case 0x05:
282
		wbrcf = 16;
283
		break;
284
	case 0x06:
285
		wbrcf = 32;
286
		break;
287
	case 0x07:
288
		wbrcf = di_rfu;
289
		break;
290
	case 0x08:
291
		wbrcf = 12;
292
		break;
293
	case 0x09:
294
		wbrcf = 20;
295
		break;
296
	default:
297
		wbrcf = di_rfu;
298
		break;
299
	}
300

301
	return (wcrcf / wbrcf);
302
}
303

304
static unsigned short io_read_num_rec_bytes(unsigned int iobase,
305
					    unsigned short *s)
306
{
307
	unsigned short tmp;
308

309
	tmp = *s = 0;
310
	do {
311
		*s = tmp;
312
		tmp = inb(REG_NUM_BYTES(iobase)) |
313
				(inb(REG_FLAGS0(iobase)) & 4 ? 0x100 : 0);
314
	} while (tmp != *s);
315

316
	return *s;
317
}
318

319
static int parse_atr(struct cm4000_dev *dev)
320
{
321
	unsigned char any_t1, any_t0;
322
	unsigned char ch, ifno;
323
	int ix, done;
324

325
	DEBUGP(3, dev, "-> parse_atr: dev->atr_len = %i\n", dev->atr_len);
326

327
	if (dev->atr_len < 3) {
328
		DEBUGP(5, dev, "parse_atr: atr_len < 3\n");
329
		return 0;
330
	}
331

332
	if (dev->atr[0] == 0x3f)
333
		set_bit(IS_INVREV, &dev->flags);
334
	else
335
		clear_bit(IS_INVREV, &dev->flags);
336
	ix = 1;
337
	ifno = 1;
338
	ch = dev->atr[1];
339
	dev->proto = 0;		/* XXX PROTO */
340
	any_t1 = any_t0 = done = 0;
341
	dev->ta1 = 0x11;	/* defaults to 9600 baud */
342
	do {
343
		if (ifno == 1 && (ch & 0x10)) {
344
			/* read first interface byte and TA1 is present */
345
			dev->ta1 = dev->atr[2];
346
			DEBUGP(5, dev, "Card says FiDi is 0x%.2x\n", dev->ta1);
347
			ifno++;
348
		} else if ((ifno == 2) && (ch & 0x10)) { /* TA(2) */
349
			dev->ta1 = 0x11;
350
			ifno++;
351
		}
352

353
		DEBUGP(5, dev, "Yi=%.2x\n", ch & 0xf0);
354
		ix += ((ch & 0x10) >> 4)	/* no of int.face chars */
355
		    +((ch & 0x20) >> 5)
356
		    + ((ch & 0x40) >> 6)
357
		    + ((ch & 0x80) >> 7);
358
		/* ATRLENCK(dev,ix); */
359
		if (ch & 0x80) {	/* TDi */
360
			ch = dev->atr[ix];
361
			if ((ch & 0x0f)) {
362
				any_t1 = 1;
363
				DEBUGP(5, dev, "card is capable of T=1\n");
364
			} else {
365
				any_t0 = 1;
366
				DEBUGP(5, dev, "card is capable of T=0\n");
367
			}
368
		} else
369
			done = 1;
370
	} while (!done);
371

372
	DEBUGP(5, dev, "ix=%d noHist=%d any_t1=%d\n",
373
	      ix, dev->atr[1] & 15, any_t1);
374
	if (ix + 1 + (dev->atr[1] & 0x0f) + any_t1 != dev->atr_len) {
375
		DEBUGP(5, dev, "length error\n");
376
		return 0;
377
	}
378
	if (any_t0)
379
		set_bit(IS_ANY_T0, &dev->flags);
380

381
	if (any_t1) {		/* compute csum */
382
		dev->atr_csum = 0;
383
#ifdef ATR_CSUM
384
		for (i = 1; i < dev->atr_len; i++)
385
			dev->atr_csum ^= dev->atr[i];
386
		if (dev->atr_csum) {
387
			set_bit(IS_BAD_CSUM, &dev->flags);
388
			DEBUGP(5, dev, "bad checksum\n");
389
			goto return_0;
390
		}
391
#endif
392
		if (any_t0 == 0)
393
			dev->proto = 1;	/* XXX PROTO */
394
		set_bit(IS_ANY_T1, &dev->flags);
395
	}
396

397
	return 1;
398
}
399

400
struct card_fixup {
401
	char atr[12];
402
	u_int8_t atr_len;
403
	u_int8_t stopbits;
404
};
405

406
static struct card_fixup card_fixups[] = {
407
	{	/* ACOS */
408
		.atr = { 0x3b, 0xb3, 0x11, 0x00, 0x00, 0x41, 0x01 },
409
		.atr_len = 7,
410
		.stopbits = 0x03,
411
	},
412
	{	/* Motorola */
413
		.atr = {0x3b, 0x76, 0x13, 0x00, 0x00, 0x80, 0x62, 0x07,
414
			0x41, 0x81, 0x81 },
415
		.atr_len = 11,
416
		.stopbits = 0x04,
417
	},
418
};
419

420
static void set_cardparameter(struct cm4000_dev *dev)
421
{
422
	int i;
423
	unsigned int iobase = dev->p_dev->resource[0]->start;
424
	u_int8_t stopbits = 0x02; /* ISO default */
425

426
	DEBUGP(3, dev, "-> set_cardparameter\n");
427

428
	dev->flags1 = dev->flags1 | (((dev->baudv - 1) & 0x0100) >> 8);
429
	xoutb(dev->flags1, REG_FLAGS1(iobase));
430
	DEBUGP(5, dev, "flags1 = 0x%02x\n", dev->flags1);
431

432
	/* set baudrate */
433
	xoutb((unsigned char)((dev->baudv - 1) & 0xFF), REG_BAUDRATE(iobase));
434

435
	DEBUGP(5, dev, "baudv = %i -> write 0x%02x\n", dev->baudv,
436
	      ((dev->baudv - 1) & 0xFF));
437

438
	/* set stopbits */
439
	for (i = 0; i < ARRAY_SIZE(card_fixups); i++) {
440
		if (!memcmp(dev->atr, card_fixups[i].atr,
441
			    card_fixups[i].atr_len))
442
			stopbits = card_fixups[i].stopbits;
443
	}
444
	xoutb(stopbits, REG_STOPBITS(iobase));
445

446
	DEBUGP(3, dev, "<- set_cardparameter\n");
447
}
448

449
static int set_protocol(struct cm4000_dev *dev, struct ptsreq *ptsreq)
450
{
451

452
	unsigned long tmp, i;
453
	unsigned short num_bytes_read;
454
	unsigned char pts_reply[4];
455
	ssize_t rc;
456
	unsigned int iobase = dev->p_dev->resource[0]->start;
457

458
	rc = 0;
459

460
	DEBUGP(3, dev, "-> set_protocol\n");
461
	DEBUGP(5, dev, "ptsreq->Protocol = 0x%.8x, ptsreq->Flags=0x%.8x, "
462
		 "ptsreq->pts1=0x%.2x, ptsreq->pts2=0x%.2x, "
463
		 "ptsreq->pts3=0x%.2x\n", (unsigned int)ptsreq->protocol,
464
		 (unsigned int)ptsreq->flags, ptsreq->pts1, ptsreq->pts2,
465
		 ptsreq->pts3);
466

467
	/* Fill PTS structure */
468
	dev->pts[0] = 0xff;
469
	dev->pts[1] = 0x00;
470
	tmp = ptsreq->protocol;
471
	while ((tmp = (tmp >> 1)) > 0)
472
		dev->pts[1]++;
473
	dev->proto = dev->pts[1];	/* Set new protocol */
474
	dev->pts[1] = (0x01 << 4) | (dev->pts[1]);
475

476
	/* Correct Fi/Di according to CM4000 Fi/Di table */
477
	DEBUGP(5, dev, "Ta(1) from ATR is 0x%.2x\n", dev->ta1);
478
	/* set Fi/Di according to ATR TA(1) */
479
	dev->pts[2] = fi_di_table[dev->ta1 & 0x0F][(dev->ta1 >> 4) & 0x0F];
480

481
	/* Calculate PCK character */
482
	dev->pts[3] = dev->pts[0] ^ dev->pts[1] ^ dev->pts[2];
483

484
	DEBUGP(5, dev, "pts0=%.2x, pts1=%.2x, pts2=%.2x, pts3=%.2x\n",
485
	       dev->pts[0], dev->pts[1], dev->pts[2], dev->pts[3]);
486

487
	/* check card convention */
488
	if (test_bit(IS_INVREV, &dev->flags))
489
		str_invert_revert(dev->pts, 4);
490

491
	/* reset SM */
492
	xoutb(0x80, REG_FLAGS0(iobase));
493

494
	/* Enable access to the message buffer */
495
	DEBUGP(5, dev, "Enable access to the messages buffer\n");
496
	dev->flags1 = 0x20	/* T_Active */
497
	    | (test_bit(IS_INVREV, &dev->flags) ? 0x02 : 0x00) /* inv parity */
498
	    | ((dev->baudv >> 8) & 0x01);	/* MSB-baud */
499
	xoutb(dev->flags1, REG_FLAGS1(iobase));
500

501
	DEBUGP(5, dev, "Enable message buffer -> flags1 = 0x%.2x\n",
502
	       dev->flags1);
503

504
	/* write challenge to the buffer */
505
	DEBUGP(5, dev, "Write challenge to buffer: ");
506
	for (i = 0; i < 4; i++) {
507
		xoutb(i, REG_BUF_ADDR(iobase));
508
		xoutb(dev->pts[i], REG_BUF_DATA(iobase));	/* buf data */
509
#ifdef CM4000_DEBUG
510
		pr_debug("0x%.2x ", dev->pts[i]);
511
	}
512
	pr_debug("\n");
513
#else
514
	}
515
#endif
516

517
	/* set number of bytes to write */
518
	DEBUGP(5, dev, "Set number of bytes to write\n");
519
	xoutb(0x04, REG_NUM_SEND(iobase));
520

521
	/* Trigger CARDMAN CONTROLLER */
522
	xoutb(0x50, REG_FLAGS0(iobase));
523

524
	/* Monitor progress */
525
	/* wait for xmit done */
526
	DEBUGP(5, dev, "Waiting for NumRecBytes getting valid\n");
527

528
	for (i = 0; i < 100; i++) {
529
		if (inb(REG_FLAGS0(iobase)) & 0x08) {
530
			DEBUGP(5, dev, "NumRecBytes is valid\n");
531
			break;
532
		}
533
		mdelay(10);
534
	}
535
	if (i == 100) {
536
		DEBUGP(5, dev, "Timeout waiting for NumRecBytes getting "
537
		       "valid\n");
538
		rc = -EIO;
539
		goto exit_setprotocol;
540
	}
541

542
	DEBUGP(5, dev, "Reading NumRecBytes\n");
543
	for (i = 0; i < 100; i++) {
544
		io_read_num_rec_bytes(iobase, &num_bytes_read);
545
		if (num_bytes_read >= 4) {
546
			DEBUGP(2, dev, "NumRecBytes = %i\n", num_bytes_read);
547
			break;
548
		}
549
		mdelay(10);
550
	}
551

552
	/* check whether it is a short PTS reply? */
553
	if (num_bytes_read == 3)
554
		i = 0;
555

556
	if (i == 100) {
557
		DEBUGP(5, dev, "Timeout reading num_bytes_read\n");
558
		rc = -EIO;
559
		goto exit_setprotocol;
560
	}
561

562
	DEBUGP(5, dev, "Reset the CARDMAN CONTROLLER\n");
563
	xoutb(0x80, REG_FLAGS0(iobase));
564

565
	/* Read PPS reply */
566
	DEBUGP(5, dev, "Read PPS reply\n");
567
	for (i = 0; i < num_bytes_read; i++) {
568
		xoutb(i, REG_BUF_ADDR(iobase));
569
		pts_reply[i] = inb(REG_BUF_DATA(iobase));
570
	}
571

572
#ifdef CM4000_DEBUG
573
	DEBUGP(2, dev, "PTSreply: ");
574
	for (i = 0; i < num_bytes_read; i++) {
575
		pr_debug("0x%.2x ", pts_reply[i]);
576
	}
577
	pr_debug("\n");
578
#endif	/* CM4000_DEBUG */
579

580
	DEBUGP(5, dev, "Clear Tactive in Flags1\n");
581
	xoutb(0x20, REG_FLAGS1(iobase));
582

583
	/* Compare ptsreq and ptsreply */
584
	if ((dev->pts[0] == pts_reply[0]) &&
585
	    (dev->pts[1] == pts_reply[1]) &&
586
	    (dev->pts[2] == pts_reply[2]) && (dev->pts[3] == pts_reply[3])) {
587
		/* setcardparameter according to PPS */
588
		dev->baudv = calc_baudv(dev->pts[2]);
589
		set_cardparameter(dev);
590
	} else if ((dev->pts[0] == pts_reply[0]) &&
591
		   ((dev->pts[1] & 0xef) == pts_reply[1]) &&
592
		   ((pts_reply[0] ^ pts_reply[1]) == pts_reply[2])) {
593
		/* short PTS reply, set card parameter to default values */
594
		dev->baudv = calc_baudv(0x11);
595
		set_cardparameter(dev);
596
	} else
597
		rc = -EIO;
598

599
exit_setprotocol:
600
	DEBUGP(3, dev, "<- set_protocol\n");
601
	return rc;
602
}
603

604
static int io_detect_cm4000(unsigned int iobase, struct cm4000_dev *dev)
605
{
606

607
	/* note: statemachine is assumed to be reset */
608
	if (inb(REG_FLAGS0(iobase)) & 8) {
609
		clear_bit(IS_ATR_VALID, &dev->flags);
610
		set_bit(IS_CMM_ABSENT, &dev->flags);
611
		return 0;	/* detect CMM = 1 -> failure */
612
	}
613
	/* xoutb(0x40, REG_FLAGS1(iobase)); detectCMM */
614
	xoutb(dev->flags1 | 0x40, REG_FLAGS1(iobase));
615
	if ((inb(REG_FLAGS0(iobase)) & 8) == 0) {
616
		clear_bit(IS_ATR_VALID, &dev->flags);
617
		set_bit(IS_CMM_ABSENT, &dev->flags);
618
		return 0;	/* detect CMM=0 -> failure */
619
	}
620
	/* clear detectCMM again by restoring original flags1 */
621
	xoutb(dev->flags1, REG_FLAGS1(iobase));
622
	return 1;
623
}
624

625
static void terminate_monitor(struct cm4000_dev *dev)
626
{
627

628
	/* tell the monitor to stop and wait until
629
	 * it terminates.
630
	 */
631
	DEBUGP(3, dev, "-> terminate_monitor\n");
632
	wait_event_interruptible(dev->devq,
633
				 test_and_set_bit(LOCK_MONITOR,
634
						  (void *)&dev->flags));
635

636
	/* now, LOCK_MONITOR has been set.
637
	 * allow a last cycle in the monitor.
638
	 * the monitor will indicate that it has
639
	 * finished by clearing this bit.
640
	 */
641
	DEBUGP(5, dev, "Now allow last cycle of monitor!\n");
642
	while (test_bit(LOCK_MONITOR, (void *)&dev->flags))
643
		msleep(25);
644

645
	DEBUGP(5, dev, "Delete timer\n");
646
	del_timer_sync(&dev->timer);
647
#ifdef CM4000_DEBUG
648
	dev->monitor_running = 0;
649
#endif
650

651
	DEBUGP(3, dev, "<- terminate_monitor\n");
652
}
653

654
/*
655
 * monitor the card every 50msec. as a side-effect, retrieve the
656
 * atr once a card is inserted. another side-effect of retrieving the
657
 * atr is that the card will be powered on, so there is no need to
658
 * power on the card explictely from the application: the driver
659
 * is already doing that for you.
660
 */
661

662
static void monitor_card(unsigned long p)
663
{
664
	struct cm4000_dev *dev = (struct cm4000_dev *) p;
665
	unsigned int iobase = dev->p_dev->resource[0]->start;
666
	unsigned short s;
667
	struct ptsreq ptsreq;
668
	int i, atrc;
669

670
	DEBUGP(7, dev, "->  monitor_card\n");
671

672
	/* if someone has set the lock for us: we're done! */
673
	if (test_and_set_bit(LOCK_MONITOR, &dev->flags)) {
674
		DEBUGP(4, dev, "About to stop monitor\n");
675
		/* no */
676
		dev->rlen =
677
		    dev->rpos =
678
		    dev->atr_csum = dev->atr_len_retry = dev->cwarn = 0;
679
		dev->mstate = M_FETCH_ATR;
680
		clear_bit(LOCK_MONITOR, &dev->flags);
681
		/* close et al. are sleeping on devq, so wake it */
682
		wake_up_interruptible(&dev->devq);
683
		DEBUGP(2, dev, "<- monitor_card (we are done now)\n");
684
		return;
685
	}
686

687
	/* try to lock io: if it is already locked, just add another timer */
688
	if (test_and_set_bit(LOCK_IO, (void *)&dev->flags)) {
689
		DEBUGP(4, dev, "Couldn't get IO lock\n");
690
		goto return_with_timer;
691
	}
692

693
	/* is a card/a reader inserted at all ? */
694
	dev->flags0 = xinb(REG_FLAGS0(iobase));
695
	DEBUGP(7, dev, "dev->flags0 = 0x%2x\n", dev->flags0);
696
	DEBUGP(7, dev, "smartcard present: %s\n",
697
	       dev->flags0 & 1 ? "yes" : "no");
698
	DEBUGP(7, dev, "cardman present: %s\n",
699
	       dev->flags0 == 0xff ? "no" : "yes");
700

701
	if ((dev->flags0 & 1) == 0	/* no smartcard inserted */
702
	    || dev->flags0 == 0xff) {	/* no cardman inserted */
703
		/* no */
704
		dev->rlen =
705
		    dev->rpos =
706
		    dev->atr_csum = dev->atr_len_retry = dev->cwarn = 0;
707
		dev->mstate = M_FETCH_ATR;
708

709
		dev->flags &= 0x000000ff; /* only keep IO and MONITOR locks */
710

711
		if (dev->flags0 == 0xff) {
712
			DEBUGP(4, dev, "set IS_CMM_ABSENT bit\n");
713
			set_bit(IS_CMM_ABSENT, &dev->flags);
714
		} else if (test_bit(IS_CMM_ABSENT, &dev->flags)) {
715
			DEBUGP(4, dev, "clear IS_CMM_ABSENT bit "
716
			       "(card is removed)\n");
717
			clear_bit(IS_CMM_ABSENT, &dev->flags);
718
		}
719

720
		goto release_io;
721
	} else if ((dev->flags0 & 1) && test_bit(IS_CMM_ABSENT, &dev->flags)) {
722
		/* cardman and card present but cardman was absent before
723
		 * (after suspend with inserted card) */
724
		DEBUGP(4, dev, "clear IS_CMM_ABSENT bit (card is inserted)\n");
725
		clear_bit(IS_CMM_ABSENT, &dev->flags);
726
	}
727

728
	if (test_bit(IS_ATR_VALID, &dev->flags) == 1) {
729
		DEBUGP(7, dev, "believe ATR is already valid (do nothing)\n");
730
		goto release_io;
731
	}
732

733
	switch (dev->mstate) {
734
		unsigned char flags0;
735
	case M_CARDOFF:
736
		DEBUGP(4, dev, "M_CARDOFF\n");
737
		flags0 = inb(REG_FLAGS0(iobase));
738
		if (flags0 & 0x02) {
739
			/* wait until Flags0 indicate power is off */
740
			dev->mdelay = T_10MSEC;
741
		} else {
742
			/* Flags0 indicate power off and no card inserted now;
743
			 * Reset CARDMAN CONTROLLER */
744
			xoutb(0x80, REG_FLAGS0(iobase));
745

746
			/* prepare for fetching ATR again: after card off ATR
747
			 * is read again automatically */
748
			dev->rlen =
749
			    dev->rpos =
750
			    dev->atr_csum =
751
			    dev->atr_len_retry = dev->cwarn = 0;
752
			dev->mstate = M_FETCH_ATR;
753

754
			/* minimal gap between CARDOFF and read ATR is 50msec */
755
			dev->mdelay = T_50MSEC;
756
		}
757
		break;
758
	case M_FETCH_ATR:
759
		DEBUGP(4, dev, "M_FETCH_ATR\n");
760
		xoutb(0x80, REG_FLAGS0(iobase));
761
		DEBUGP(4, dev, "Reset BAUDV to 9600\n");
762
		dev->baudv = 0x173;	/* 9600 */
763
		xoutb(0x02, REG_STOPBITS(iobase));	/* stopbits=2 */
764
		xoutb(0x73, REG_BAUDRATE(iobase));	/* baud value */
765
		xoutb(0x21, REG_FLAGS1(iobase));	/* T_Active=1, baud
766
							   value */
767
		/* warm start vs. power on: */
768
		xoutb(dev->flags0 & 2 ? 0x46 : 0x44, REG_FLAGS0(iobase));
769
		dev->mdelay = T_40MSEC;
770
		dev->mstate = M_TIMEOUT_WAIT;
771
		break;
772
	case M_TIMEOUT_WAIT:
773
		DEBUGP(4, dev, "M_TIMEOUT_WAIT\n");
774
		/* numRecBytes */
775
		io_read_num_rec_bytes(iobase, &dev->atr_len);
776
		dev->mdelay = T_10MSEC;
777
		dev->mstate = M_READ_ATR_LEN;
778
		break;
779
	case M_READ_ATR_LEN:
780
		DEBUGP(4, dev, "M_READ_ATR_LEN\n");
781
		/* infinite loop possible, since there is no timeout */
782

783
#define	MAX_ATR_LEN_RETRY	100
784

785
		if (dev->atr_len == io_read_num_rec_bytes(iobase, &s)) {
786
			if (dev->atr_len_retry++ >= MAX_ATR_LEN_RETRY) {					/* + XX msec */
787
				dev->mdelay = T_10MSEC;
788
				dev->mstate = M_READ_ATR;
789
			}
790
		} else {
791
			dev->atr_len = s;
792
			dev->atr_len_retry = 0;	/* set new timeout */
793
		}
794

795
		DEBUGP(4, dev, "Current ATR_LEN = %i\n", dev->atr_len);
796
		break;
797
	case M_READ_ATR:
798
		DEBUGP(4, dev, "M_READ_ATR\n");
799
		xoutb(0x80, REG_FLAGS0(iobase));	/* reset SM */
800
		for (i = 0; i < dev->atr_len; i++) {
801
			xoutb(i, REG_BUF_ADDR(iobase));
802
			dev->atr[i] = inb(REG_BUF_DATA(iobase));
803
		}
804
		/* Deactivate T_Active flags */
805
		DEBUGP(4, dev, "Deactivate T_Active flags\n");
806
		dev->flags1 = 0x01;
807
		xoutb(dev->flags1, REG_FLAGS1(iobase));
808

809
		/* atr is present (which doesn't mean it's valid) */
810
		set_bit(IS_ATR_PRESENT, &dev->flags);
811
		if (dev->atr[0] == 0x03)
812
			str_invert_revert(dev->atr, dev->atr_len);
813
		atrc = parse_atr(dev);
814
		if (atrc == 0) {	/* atr invalid */
815
			dev->mdelay = 0;
816
			dev->mstate = M_BAD_CARD;
817
		} else {
818
			dev->mdelay = T_50MSEC;
819
			dev->mstate = M_ATR_PRESENT;
820
			set_bit(IS_ATR_VALID, &dev->flags);
821
		}
822

823
		if (test_bit(IS_ATR_VALID, &dev->flags) == 1) {
824
			DEBUGP(4, dev, "monitor_card: ATR valid\n");
825
 			/* if ta1 == 0x11, no PPS necessary (default values) */
826
			/* do not do PPS with multi protocol cards */
827
			if ((test_bit(IS_AUTOPPS_ACT, &dev->flags) == 0) &&
828
			    (dev->ta1 != 0x11) &&
829
			    !(test_bit(IS_ANY_T0, &dev->flags) &&
830
			    test_bit(IS_ANY_T1, &dev->flags))) {
831
				DEBUGP(4, dev, "Perform AUTOPPS\n");
832
				set_bit(IS_AUTOPPS_ACT, &dev->flags);
833
				ptsreq.protocol = (0x01 << dev->proto);
834
				ptsreq.flags = 0x01;
835
				ptsreq.pts1 = 0x00;
836
				ptsreq.pts2 = 0x00;
837
				ptsreq.pts3 = 0x00;
838
				if (set_protocol(dev, &ptsreq) == 0) {
839
					DEBUGP(4, dev, "AUTOPPS ret SUCC\n");
840
					clear_bit(IS_AUTOPPS_ACT, &dev->flags);
841
					wake_up_interruptible(&dev->atrq);
842
				} else {
843
					DEBUGP(4, dev, "AUTOPPS failed: "
844
					       "repower using defaults\n");
845
					/* prepare for repowering  */
846
					clear_bit(IS_ATR_PRESENT, &dev->flags);
847
					clear_bit(IS_ATR_VALID, &dev->flags);
848
					dev->rlen =
849
					    dev->rpos =
850
					    dev->atr_csum =
851
					    dev->atr_len_retry = dev->cwarn = 0;
852
					dev->mstate = M_FETCH_ATR;
853

854
					dev->mdelay = T_50MSEC;
855
				}
856
			} else {
857
				/* for cards which use slightly different
858
				 * params (extra guard time) */
859
				set_cardparameter(dev);
860
				if (test_bit(IS_AUTOPPS_ACT, &dev->flags) == 1)
861
					DEBUGP(4, dev, "AUTOPPS already active "
862
					       "2nd try:use default values\n");
863
				if (dev->ta1 == 0x11)
864
					DEBUGP(4, dev, "No AUTOPPS necessary "
865
					       "TA(1)==0x11\n");
866
				if (test_bit(IS_ANY_T0, &dev->flags)
867
				    && test_bit(IS_ANY_T1, &dev->flags))
868
					DEBUGP(4, dev, "Do NOT perform AUTOPPS "
869
					       "with multiprotocol cards\n");
870
				clear_bit(IS_AUTOPPS_ACT, &dev->flags);
871
				wake_up_interruptible(&dev->atrq);
872
			}
873
		} else {
874
			DEBUGP(4, dev, "ATR invalid\n");
875
			wake_up_interruptible(&dev->atrq);
876
		}
877
		break;
878
	case M_BAD_CARD:
879
		DEBUGP(4, dev, "M_BAD_CARD\n");
880
		/* slow down warning, but prompt immediately after insertion */
881
		if (dev->cwarn == 0 || dev->cwarn == 10) {
882
			set_bit(IS_BAD_CARD, &dev->flags);
883
			dev_warn(&dev->p_dev->dev, MODULE_NAME ": ");
884
			if (test_bit(IS_BAD_CSUM, &dev->flags)) {
885
				DEBUGP(4, dev, "ATR checksum (0x%.2x, should "
886
				       "be zero) failed\n", dev->atr_csum);
887
			}
888
#ifdef CM4000_DEBUG
889
			else if (test_bit(IS_BAD_LENGTH, &dev->flags)) {
890
				DEBUGP(4, dev, "ATR length error\n");
891
			} else {
892
				DEBUGP(4, dev, "card damaged or wrong way "
893
					"inserted\n");
894
			}
895
#endif
896
			dev->cwarn = 0;
897
			wake_up_interruptible(&dev->atrq);	/* wake open */
898
		}
899
		dev->cwarn++;
900
		dev->mdelay = T_100MSEC;
901
		dev->mstate = M_FETCH_ATR;
902
		break;
903
	default:
904
		DEBUGP(7, dev, "Unknown action\n");
905
		break;		/* nothing */
906
	}
907

908
release_io:
909
	DEBUGP(7, dev, "release_io\n");
910
	clear_bit(LOCK_IO, &dev->flags);
911
	wake_up_interruptible(&dev->ioq);	/* whoever needs IO */
912

913
return_with_timer:
914
	DEBUGP(7, dev, "<- monitor_card (returns with timer)\n");
915
	mod_timer(&dev->timer, jiffies + dev->mdelay);
916
	clear_bit(LOCK_MONITOR, &dev->flags);
917
}
918

919
/* Interface to userland (file_operations) */
920

921
static ssize_t cmm_read(struct file *filp, __user char *buf, size_t count,
922
			loff_t *ppos)
923
{
924
	struct cm4000_dev *dev = filp->private_data;
925
	unsigned int iobase = dev->p_dev->resource[0]->start;
926
	ssize_t rc;
927
	int i, j, k;
928

929
	DEBUGP(2, dev, "-> cmm_read(%s,%d)\n", current->comm, current->pid);
930

931
	if (count == 0)		/* according to manpage */
932
		return 0;
933

934
	if (!pcmcia_dev_present(dev->p_dev) || /* device removed */
935
	    test_bit(IS_CMM_ABSENT, &dev->flags))
936
		return -ENODEV;
937

938
	if (test_bit(IS_BAD_CSUM, &dev->flags))
939
		return -EIO;
940

941
	/* also see the note about this in cmm_write */
942
	if (wait_event_interruptible
943
	    (dev->atrq,
944
	     ((filp->f_flags & O_NONBLOCK)
945
	      || (test_bit(IS_ATR_PRESENT, (void *)&dev->flags) != 0)))) {
946
		if (filp->f_flags & O_NONBLOCK)
947
			return -EAGAIN;
948
		return -ERESTARTSYS;
949
	}
950

951
	if (test_bit(IS_ATR_VALID, &dev->flags) == 0)
952
		return -EIO;
953

954
	/* this one implements blocking IO */
955
	if (wait_event_interruptible
956
	    (dev->readq,
957
	     ((filp->f_flags & O_NONBLOCK) || (dev->rpos < dev->rlen)))) {
958
		if (filp->f_flags & O_NONBLOCK)
959
			return -EAGAIN;
960
		return -ERESTARTSYS;
961
	}
962

963
	/* lock io */
964
	if (wait_event_interruptible
965
	    (dev->ioq,
966
	     ((filp->f_flags & O_NONBLOCK)
967
	      || (test_and_set_bit(LOCK_IO, (void *)&dev->flags) == 0)))) {
968
		if (filp->f_flags & O_NONBLOCK)
969
			return -EAGAIN;
970
		return -ERESTARTSYS;
971
	}
972

973
	rc = 0;
974
	dev->flags0 = inb(REG_FLAGS0(iobase));
975
	if ((dev->flags0 & 1) == 0	/* no smartcard inserted */
976
	    || dev->flags0 == 0xff) {	/* no cardman inserted */
977
		clear_bit(IS_ATR_VALID, &dev->flags);
978
		if (dev->flags0 & 1) {
979
			set_bit(IS_CMM_ABSENT, &dev->flags);
980
			rc = -ENODEV;
981
		} else {
982
			rc = -EIO;
983
		}
984
		goto release_io;
985
	}
986

987
	DEBUGP(4, dev, "begin read answer\n");
988
	j = min(count, (size_t)(dev->rlen - dev->rpos));
989
	k = dev->rpos;
990
	if (k + j > 255)
991
		j = 256 - k;
992
	DEBUGP(4, dev, "read1 j=%d\n", j);
993
	for (i = 0; i < j; i++) {
994
		xoutb(k++, REG_BUF_ADDR(iobase));
995
		dev->rbuf[i] = xinb(REG_BUF_DATA(iobase));
996
	}
997
	j = min(count, (size_t)(dev->rlen - dev->rpos));
998
	if (k + j > 255) {
999
		DEBUGP(4, dev, "read2 j=%d\n", j);
1000
		dev->flags1 |= 0x10;	/* MSB buf addr set */
1001
		xoutb(dev->flags1, REG_FLAGS1(iobase));
1002
		for (; i < j; i++) {
1003
			xoutb(k++, REG_BUF_ADDR(iobase));
1004
			dev->rbuf[i] = xinb(REG_BUF_DATA(iobase));
1005
		}
1006
	}
1007

1008
	if (dev->proto == 0 && count > dev->rlen - dev->rpos && i) {
1009
		DEBUGP(4, dev, "T=0 and count > buffer\n");
1010
		dev->rbuf[i] = dev->rbuf[i - 1];
1011
		dev->rbuf[i - 1] = dev->procbyte;
1012
		j++;
1013
	}
1014
	count = j;
1015

1016
	dev->rpos = dev->rlen + 1;
1017

1018
	/* Clear T1Active */
1019
	DEBUGP(4, dev, "Clear T1Active\n");
1020
	dev->flags1 &= 0xdf;
1021
	xoutb(dev->flags1, REG_FLAGS1(iobase));
1022

1023
	xoutb(0, REG_FLAGS1(iobase));	/* clear detectCMM */
1024
	/* last check before exit */
1025
	if (!io_detect_cm4000(iobase, dev)) {
1026
		rc = -ENODEV;
1027
		goto release_io;
1028
	}
1029

1030
	if (test_bit(IS_INVREV, &dev->flags) && count > 0)
1031
		str_invert_revert(dev->rbuf, count);
1032

1033
	if (copy_to_user(buf, dev->rbuf, count))
1034
		rc = -EFAULT;
1035

1036
release_io:
1037
	clear_bit(LOCK_IO, &dev->flags);
1038
	wake_up_interruptible(&dev->ioq);
1039

1040
	DEBUGP(2, dev, "<- cmm_read returns: rc = %Zi\n",
1041
	       (rc < 0 ? rc : count));
1042
	return rc < 0 ? rc : count;
1043
}
1044

1045
static ssize_t cmm_write(struct file *filp, const char __user *buf,
1046
			 size_t count, loff_t *ppos)
1047
{
1048
	struct cm4000_dev *dev = filp->private_data;
1049
	unsigned int iobase = dev->p_dev->resource[0]->start;
1050
	unsigned short s;
1051
	unsigned char tmp;
1052
	unsigned char infolen;
1053
	unsigned char sendT0;
1054
	unsigned short nsend;
1055
	unsigned short nr;
1056
	ssize_t rc;
1057
	int i;
1058

1059
	DEBUGP(2, dev, "-> cmm_write(%s,%d)\n", current->comm, current->pid);
1060

1061
	if (count == 0)		/* according to manpage */
1062
		return 0;
1063

1064
	if (dev->proto == 0 && count < 4) {
1065
		/* T0 must have at least 4 bytes */
1066
		DEBUGP(4, dev, "T0 short write\n");
1067
		return -EIO;
1068
	}
1069

1070
	nr = count & 0x1ff;	/* max bytes to write */
1071

1072
	sendT0 = dev->proto ? 0 : nr > 5 ? 0x08 : 0;
1073

1074
	if (!pcmcia_dev_present(dev->p_dev) || /* device removed */
1075
	    test_bit(IS_CMM_ABSENT, &dev->flags))
1076
		return -ENODEV;
1077

1078
	if (test_bit(IS_BAD_CSUM, &dev->flags)) {
1079
		DEBUGP(4, dev, "bad csum\n");
1080
		return -EIO;
1081
	}
1082

1083
	/*
1084
	 * wait for atr to become valid.
1085
	 * note: it is important to lock this code. if we dont, the monitor
1086
	 * could be run between test_bit and the call to sleep on the
1087
	 * atr-queue.  if *then* the monitor detects atr valid, it will wake up
1088
	 * any process on the atr-queue, *but* since we have been interrupted,
1089
	 * we do not yet sleep on this queue. this would result in a missed
1090
	 * wake_up and the calling process would sleep forever (until
1091
	 * interrupted).  also, do *not* restore_flags before sleep_on, because
1092
	 * this could result in the same situation!
1093
	 */
1094
	if (wait_event_interruptible
1095
	    (dev->atrq,
1096
	     ((filp->f_flags & O_NONBLOCK)
1097
	      || (test_bit(IS_ATR_PRESENT, (void *)&dev->flags) != 0)))) {
1098
		if (filp->f_flags & O_NONBLOCK)
1099
			return -EAGAIN;
1100
		return -ERESTARTSYS;
1101
	}
1102

1103
	if (test_bit(IS_ATR_VALID, &dev->flags) == 0) {	/* invalid atr */
1104
		DEBUGP(4, dev, "invalid ATR\n");
1105
		return -EIO;
1106
	}
1107

1108
	/* lock io */
1109
	if (wait_event_interruptible
1110
	    (dev->ioq,
1111
	     ((filp->f_flags & O_NONBLOCK)
1112
	      || (test_and_set_bit(LOCK_IO, (void *)&dev->flags) == 0)))) {
1113
		if (filp->f_flags & O_NONBLOCK)
1114
			return -EAGAIN;
1115
		return -ERESTARTSYS;
1116
	}
1117

1118
	if (copy_from_user(dev->sbuf, buf, ((count > 512) ? 512 : count)))
1119
		return -EFAULT;
1120

1121
	rc = 0;
1122
	dev->flags0 = inb(REG_FLAGS0(iobase));
1123
	if ((dev->flags0 & 1) == 0	/* no smartcard inserted */
1124
	    || dev->flags0 == 0xff) {	/* no cardman inserted */
1125
		clear_bit(IS_ATR_VALID, &dev->flags);
1126
		if (dev->flags0 & 1) {
1127
			set_bit(IS_CMM_ABSENT, &dev->flags);
1128
			rc = -ENODEV;
1129
		} else {
1130
			DEBUGP(4, dev, "IO error\n");
1131
			rc = -EIO;
1132
		}
1133
		goto release_io;
1134
	}
1135

1136
	xoutb(0x80, REG_FLAGS0(iobase));	/* reset SM  */
1137

1138
	if (!io_detect_cm4000(iobase, dev)) {
1139
		rc = -ENODEV;
1140
		goto release_io;
1141
	}
1142

1143
	/* reflect T=0 send/read mode in flags1 */
1144
	dev->flags1 |= (sendT0);
1145

1146
	set_cardparameter(dev);
1147

1148
	/* dummy read, reset flag procedure received */
1149
	tmp = inb(REG_FLAGS1(iobase));
1150

1151
	dev->flags1 = 0x20	/* T_Active */
1152
	    | (sendT0)
1153
	    | (test_bit(IS_INVREV, &dev->flags) ? 2 : 0)/* inverse parity  */
1154
	    | (((dev->baudv - 1) & 0x0100) >> 8);	/* MSB-Baud */
1155
	DEBUGP(1, dev, "set dev->flags1 = 0x%.2x\n", dev->flags1);
1156
	xoutb(dev->flags1, REG_FLAGS1(iobase));
1157

1158
	/* xmit data */
1159
	DEBUGP(4, dev, "Xmit data\n");
1160
	for (i = 0; i < nr; i++) {
1161
		if (i >= 256) {
1162
			dev->flags1 = 0x20	/* T_Active */
1163
			    | (sendT0)	/* SendT0 */
1164
				/* inverse parity: */
1165
			    | (test_bit(IS_INVREV, &dev->flags) ? 2 : 0)
1166
			    | (((dev->baudv - 1) & 0x0100) >> 8) /* MSB-Baud */
1167
			    | 0x10;	/* set address high */
1168
			DEBUGP(4, dev, "dev->flags = 0x%.2x - set address "
1169
			       "high\n", dev->flags1);
1170
			xoutb(dev->flags1, REG_FLAGS1(iobase));
1171
		}
1172
		if (test_bit(IS_INVREV, &dev->flags)) {
1173
			DEBUGP(4, dev, "Apply inverse convention for 0x%.2x "
1174
				"-> 0x%.2x\n", (unsigned char)dev->sbuf[i],
1175
			      invert_revert(dev->sbuf[i]));
1176
			xoutb(i, REG_BUF_ADDR(iobase));
1177
			xoutb(invert_revert(dev->sbuf[i]),
1178
			      REG_BUF_DATA(iobase));
1179
		} else {
1180
			xoutb(i, REG_BUF_ADDR(iobase));
1181
			xoutb(dev->sbuf[i], REG_BUF_DATA(iobase));
1182
		}
1183
	}
1184
	DEBUGP(4, dev, "Xmit done\n");
1185

1186
	if (dev->proto == 0) {
1187
		/* T=0 proto: 0 byte reply  */
1188
		if (nr == 4) {
1189
			DEBUGP(4, dev, "T=0 assumes 0 byte reply\n");
1190
			xoutb(i, REG_BUF_ADDR(iobase));
1191
			if (test_bit(IS_INVREV, &dev->flags))
1192
				xoutb(0xff, REG_BUF_DATA(iobase));
1193
			else
1194
				xoutb(0x00, REG_BUF_DATA(iobase));
1195
		}
1196

1197
		/* numSendBytes */
1198
		if (sendT0)
1199
			nsend = nr;
1200
		else {
1201
			if (nr == 4)
1202
				nsend = 5;
1203
			else {
1204
				nsend = 5 + (unsigned char)dev->sbuf[4];
1205
				if (dev->sbuf[4] == 0)
1206
					nsend += 0x100;
1207
			}
1208
		}
1209
	} else
1210
		nsend = nr;
1211

1212
	/* T0: output procedure byte */
1213
	if (test_bit(IS_INVREV, &dev->flags)) {
1214
		DEBUGP(4, dev, "T=0 set Procedure byte (inverse-reverse) "
1215
		       "0x%.2x\n", invert_revert(dev->sbuf[1]));
1216
		xoutb(invert_revert(dev->sbuf[1]), REG_NUM_BYTES(iobase));
1217
	} else {
1218
		DEBUGP(4, dev, "T=0 set Procedure byte 0x%.2x\n", dev->sbuf[1]);
1219
		xoutb(dev->sbuf[1], REG_NUM_BYTES(iobase));
1220
	}
1221

1222
	DEBUGP(1, dev, "set NumSendBytes = 0x%.2x\n",
1223
	       (unsigned char)(nsend & 0xff));
1224
	xoutb((unsigned char)(nsend & 0xff), REG_NUM_SEND(iobase));
1225

1226
	DEBUGP(1, dev, "Trigger CARDMAN CONTROLLER (0x%.2x)\n",
1227
	       0x40	/* SM_Active */
1228
	      | (dev->flags0 & 2 ? 0 : 4)	/* power on if needed */
1229
	      |(dev->proto ? 0x10 : 0x08)	/* T=1/T=0 */
1230
	      |(nsend & 0x100) >> 8 /* MSB numSendBytes */ );
1231
	xoutb(0x40		/* SM_Active */
1232
	      | (dev->flags0 & 2 ? 0 : 4)	/* power on if needed */
1233
	      |(dev->proto ? 0x10 : 0x08)	/* T=1/T=0 */
1234
	      |(nsend & 0x100) >> 8,	/* MSB numSendBytes */
1235
	      REG_FLAGS0(iobase));
1236

1237
	/* wait for xmit done */
1238
	if (dev->proto == 1) {
1239
		DEBUGP(4, dev, "Wait for xmit done\n");
1240
		for (i = 0; i < 1000; i++) {
1241
			if (inb(REG_FLAGS0(iobase)) & 0x08)
1242
				break;
1243
			msleep_interruptible(10);
1244
		}
1245
		if (i == 1000) {
1246
			DEBUGP(4, dev, "timeout waiting for xmit done\n");
1247
			rc = -EIO;
1248
			goto release_io;
1249
		}
1250
	}
1251

1252
	/* T=1: wait for infoLen */
1253

1254
	infolen = 0;
1255
	if (dev->proto) {
1256
		/* wait until infoLen is valid */
1257
		for (i = 0; i < 6000; i++) {	/* max waiting time of 1 min */
1258
			io_read_num_rec_bytes(iobase, &s);
1259
			if (s >= 3) {
1260
				infolen = inb(REG_FLAGS1(iobase));
1261
				DEBUGP(4, dev, "infolen=%d\n", infolen);
1262
				break;
1263
			}
1264
			msleep_interruptible(10);
1265
		}
1266
		if (i == 6000) {
1267
			DEBUGP(4, dev, "timeout waiting for infoLen\n");
1268
			rc = -EIO;
1269
			goto release_io;
1270
		}
1271
	} else
1272
		clear_bit(IS_PROCBYTE_PRESENT, &dev->flags);
1273

1274
	/* numRecBytes | bit9 of numRecytes */
1275
	io_read_num_rec_bytes(iobase, &dev->rlen);
1276
	for (i = 0; i < 600; i++) {	/* max waiting time of 2 sec */
1277
		if (dev->proto) {
1278
			if (dev->rlen >= infolen + 4)
1279
				break;
1280
		}
1281
		msleep_interruptible(10);
1282
		/* numRecBytes | bit9 of numRecytes */
1283
		io_read_num_rec_bytes(iobase, &s);
1284
		if (s > dev->rlen) {
1285
			DEBUGP(1, dev, "NumRecBytes inc (reset timeout)\n");
1286
			i = 0;	/* reset timeout */
1287
			dev->rlen = s;
1288
		}
1289
		/* T=0: we are done when numRecBytes doesn't
1290
		 *      increment any more and NoProcedureByte
1291
		 *      is set and numRecBytes == bytes sent + 6
1292
		 *      (header bytes + data + 1 for sw2)
1293
		 *      except when the card replies an error
1294
		 *      which means, no data will be sent back.
1295
		 */
1296
		else if (dev->proto == 0) {
1297
			if ((inb(REG_BUF_ADDR(iobase)) & 0x80)) {
1298
				/* no procedure byte received since last read */
1299
				DEBUGP(1, dev, "NoProcedure byte set\n");
1300
				/* i=0; */
1301
			} else {
1302
				/* procedure byte received since last read */
1303
				DEBUGP(1, dev, "NoProcedure byte unset "
1304
					"(reset timeout)\n");
1305
				dev->procbyte = inb(REG_FLAGS1(iobase));
1306
				DEBUGP(1, dev, "Read procedure byte 0x%.2x\n",
1307
				      dev->procbyte);
1308
				i = 0;	/* resettimeout */
1309
			}
1310
			if (inb(REG_FLAGS0(iobase)) & 0x08) {
1311
				DEBUGP(1, dev, "T0Done flag (read reply)\n");
1312
				break;
1313
			}
1314
		}
1315
		if (dev->proto)
1316
			infolen = inb(REG_FLAGS1(iobase));
1317
	}
1318
	if (i == 600) {
1319
		DEBUGP(1, dev, "timeout waiting for numRecBytes\n");
1320
		rc = -EIO;
1321
		goto release_io;
1322
	} else {
1323
		if (dev->proto == 0) {
1324
			DEBUGP(1, dev, "Wait for T0Done bit to be  set\n");
1325
			for (i = 0; i < 1000; i++) {
1326
				if (inb(REG_FLAGS0(iobase)) & 0x08)
1327
					break;
1328
				msleep_interruptible(10);
1329
			}
1330
			if (i == 1000) {
1331
				DEBUGP(1, dev, "timeout waiting for T0Done\n");
1332
				rc = -EIO;
1333
				goto release_io;
1334
			}
1335

1336
			dev->procbyte = inb(REG_FLAGS1(iobase));
1337
			DEBUGP(4, dev, "Read procedure byte 0x%.2x\n",
1338
			      dev->procbyte);
1339

1340
			io_read_num_rec_bytes(iobase, &dev->rlen);
1341
			DEBUGP(4, dev, "Read NumRecBytes = %i\n", dev->rlen);
1342

1343
		}
1344
	}
1345
	/* T=1: read offset=zero, T=0: read offset=after challenge */
1346
	dev->rpos = dev->proto ? 0 : nr == 4 ? 5 : nr > dev->rlen ? 5 : nr;
1347
	DEBUGP(4, dev, "dev->rlen = %i,  dev->rpos = %i, nr = %i\n",
1348
	      dev->rlen, dev->rpos, nr);
1349

1350
release_io:
1351
	DEBUGP(4, dev, "Reset SM\n");
1352
	xoutb(0x80, REG_FLAGS0(iobase));	/* reset SM */
1353

1354
	if (rc < 0) {
1355
		DEBUGP(4, dev, "Write failed but clear T_Active\n");
1356
		dev->flags1 &= 0xdf;
1357
		xoutb(dev->flags1, REG_FLAGS1(iobase));
1358
	}
1359

1360
	clear_bit(LOCK_IO, &dev->flags);
1361
	wake_up_interruptible(&dev->ioq);
1362
	wake_up_interruptible(&dev->readq);	/* tell read we have data */
1363

1364
	/* ITSEC E2: clear write buffer */
1365
	memset((char *)dev->sbuf, 0, 512);
1366

1367
	/* return error or actually written bytes */
1368
	DEBUGP(2, dev, "<- cmm_write\n");
1369
	return rc < 0 ? rc : nr;
1370
}
1371

1372
static void start_monitor(struct cm4000_dev *dev)
1373
{
1374
	DEBUGP(3, dev, "-> start_monitor\n");
1375
	if (!dev->monitor_running) {
1376
		DEBUGP(5, dev, "create, init and add timer\n");
1377
		setup_timer(&dev->timer, monitor_card, (unsigned long)dev);
1378
		dev->monitor_running = 1;
1379
		mod_timer(&dev->timer, jiffies);
1380
	} else
1381
		DEBUGP(5, dev, "monitor already running\n");
1382
	DEBUGP(3, dev, "<- start_monitor\n");
1383
}
1384

1385
static void stop_monitor(struct cm4000_dev *dev)
1386
{
1387
	DEBUGP(3, dev, "-> stop_monitor\n");
1388
	if (dev->monitor_running) {
1389
		DEBUGP(5, dev, "stopping monitor\n");
1390
		terminate_monitor(dev);
1391
		/* reset monitor SM */
1392
		clear_bit(IS_ATR_VALID, &dev->flags);
1393
		clear_bit(IS_ATR_PRESENT, &dev->flags);
1394
	} else
1395
		DEBUGP(5, dev, "monitor already stopped\n");
1396
	DEBUGP(3, dev, "<- stop_monitor\n");
1397
}
1398

1399
static long cmm_ioctl(struct file *filp, unsigned int cmd, unsigned long arg)
1400
{
1401
	struct cm4000_dev *dev = filp->private_data;
1402
	unsigned int iobase = dev->p_dev->resource[0]->start;
1403
	struct inode *inode = filp->f_path.dentry->d_inode;
1404
	struct pcmcia_device *link;
1405
	int size;
1406
	int rc;
1407
	void __user *argp = (void __user *)arg;
1408
#ifdef CM4000_DEBUG
1409
	char *ioctl_names[CM_IOC_MAXNR + 1] = {
1410
		[_IOC_NR(CM_IOCGSTATUS)] "CM_IOCGSTATUS",
1411
		[_IOC_NR(CM_IOCGATR)] "CM_IOCGATR",
1412
		[_IOC_NR(CM_IOCARDOFF)] "CM_IOCARDOFF",
1413
		[_IOC_NR(CM_IOCSPTS)] "CM_IOCSPTS",
1414
		[_IOC_NR(CM_IOSDBGLVL)] "CM4000_DBGLVL",
1415
	};
1416
	DEBUGP(3, dev, "cmm_ioctl(device=%d.%d) %s\n", imajor(inode),
1417
	       iminor(inode), ioctl_names[_IOC_NR(cmd)]);
1418
#endif
1419

1420
	mutex_lock(&cmm_mutex);
1421
	rc = -ENODEV;
1422
	link = dev_table[iminor(inode)];
1423
	if (!pcmcia_dev_present(link)) {
1424
		DEBUGP(4, dev, "DEV_OK false\n");
1425
		goto out;
1426
	}
1427

1428
	if (test_bit(IS_CMM_ABSENT, &dev->flags)) {
1429
		DEBUGP(4, dev, "CMM_ABSENT flag set\n");
1430
		goto out;
1431
	}
1432
	rc = -EINVAL;
1433

1434
	if (_IOC_TYPE(cmd) != CM_IOC_MAGIC) {
1435
		DEBUGP(4, dev, "ioctype mismatch\n");
1436
		goto out;
1437
	}
1438
	if (_IOC_NR(cmd) > CM_IOC_MAXNR) {
1439
		DEBUGP(4, dev, "iocnr mismatch\n");
1440
		goto out;
1441
	}
1442
	size = _IOC_SIZE(cmd);
1443
	rc = -EFAULT;
1444
	DEBUGP(4, dev, "iocdir=%.4x iocr=%.4x iocw=%.4x iocsize=%d cmd=%.4x\n",
1445
	      _IOC_DIR(cmd), _IOC_READ, _IOC_WRITE, size, cmd);
1446

1447
	if (_IOC_DIR(cmd) & _IOC_READ) {
1448
		if (!access_ok(VERIFY_WRITE, argp, size))
1449
			goto out;
1450
	}
1451
	if (_IOC_DIR(cmd) & _IOC_WRITE) {
1452
		if (!access_ok(VERIFY_READ, argp, size))
1453
			goto out;
1454
	}
1455
	rc = 0;
1456

1457
	switch (cmd) {
1458
	case CM_IOCGSTATUS:
1459
		DEBUGP(4, dev, " ... in CM_IOCGSTATUS\n");
1460
		{
1461
			int status;
1462

1463
			/* clear other bits, but leave inserted & powered as
1464
			 * they are */
1465
			status = dev->flags0 & 3;
1466
			if (test_bit(IS_ATR_PRESENT, &dev->flags))
1467
				status |= CM_ATR_PRESENT;
1468
			if (test_bit(IS_ATR_VALID, &dev->flags))
1469
				status |= CM_ATR_VALID;
1470
			if (test_bit(IS_CMM_ABSENT, &dev->flags))
1471
				status |= CM_NO_READER;
1472
			if (test_bit(IS_BAD_CARD, &dev->flags))
1473
				status |= CM_BAD_CARD;
1474
			if (copy_to_user(argp, &status, sizeof(int)))
1475
				rc = -EFAULT;
1476
		}
1477
		break;
1478
	case CM_IOCGATR:
1479
		DEBUGP(4, dev, "... in CM_IOCGATR\n");
1480
		{
1481
			struct atreq __user *atreq = argp;
1482
			int tmp;
1483
			/* allow nonblocking io and being interrupted */
1484
			if (wait_event_interruptible
1485
			    (dev->atrq,
1486
			     ((filp->f_flags & O_NONBLOCK)
1487
			      || (test_bit(IS_ATR_PRESENT, (void *)&dev->flags)
1488
				  != 0)))) {
1489
				if (filp->f_flags & O_NONBLOCK)
1490
					rc = -EAGAIN;
1491
				else
1492
					rc = -ERESTARTSYS;
1493
				break;
1494
			}
1495

1496
			rc = -EFAULT;
1497
			if (test_bit(IS_ATR_VALID, &dev->flags) == 0) {
1498
				tmp = -1;
1499
				if (copy_to_user(&(atreq->atr_len), &tmp,
1500
						 sizeof(int)))
1501
					break;
1502
			} else {
1503
				if (copy_to_user(atreq->atr, dev->atr,
1504
						 dev->atr_len))
1505
					break;
1506

1507
				tmp = dev->atr_len;
1508
				if (copy_to_user(&(atreq->atr_len), &tmp, sizeof(int)))
1509
					break;
1510
			}
1511
			rc = 0;
1512
			break;
1513
		}
1514
	case CM_IOCARDOFF:
1515

1516
#ifdef CM4000_DEBUG
1517
		DEBUGP(4, dev, "... in CM_IOCARDOFF\n");
1518
		if (dev->flags0 & 0x01) {
1519
			DEBUGP(4, dev, "    Card inserted\n");
1520
		} else {
1521
			DEBUGP(2, dev, "    No card inserted\n");
1522
		}
1523
		if (dev->flags0 & 0x02) {
1524
			DEBUGP(4, dev, "    Card powered\n");
1525
		} else {
1526
			DEBUGP(2, dev, "    Card not powered\n");
1527
		}
1528
#endif
1529

1530
		/* is a card inserted and powered? */
1531
		if ((dev->flags0 & 0x01) && (dev->flags0 & 0x02)) {
1532

1533
			/* get IO lock */
1534
			if (wait_event_interruptible
1535
			    (dev->ioq,
1536
			     ((filp->f_flags & O_NONBLOCK)
1537
			      || (test_and_set_bit(LOCK_IO, (void *)&dev->flags)
1538
				  == 0)))) {
1539
				if (filp->f_flags & O_NONBLOCK)
1540
					rc = -EAGAIN;
1541
				else
1542
					rc = -ERESTARTSYS;
1543
				break;
1544
			}
1545
			/* Set Flags0 = 0x42 */
1546
			DEBUGP(4, dev, "Set Flags0=0x42 \n");
1547
			xoutb(0x42, REG_FLAGS0(iobase));
1548
			clear_bit(IS_ATR_PRESENT, &dev->flags);
1549
			clear_bit(IS_ATR_VALID, &dev->flags);
1550
			dev->mstate = M_CARDOFF;
1551
			clear_bit(LOCK_IO, &dev->flags);
1552
			if (wait_event_interruptible
1553
			    (dev->atrq,
1554
			     ((filp->f_flags & O_NONBLOCK)
1555
			      || (test_bit(IS_ATR_VALID, (void *)&dev->flags) !=
1556
				  0)))) {
1557
				if (filp->f_flags & O_NONBLOCK)
1558
					rc = -EAGAIN;
1559
				else
1560
					rc = -ERESTARTSYS;
1561
				break;
1562
			}
1563
		}
1564
		/* release lock */
1565
		clear_bit(LOCK_IO, &dev->flags);
1566
		wake_up_interruptible(&dev->ioq);
1567

1568
		rc = 0;
1569
		break;
1570
	case CM_IOCSPTS:
1571
		{
1572
			struct ptsreq krnptsreq;
1573

1574
			if (copy_from_user(&krnptsreq, argp,
1575
					   sizeof(struct ptsreq))) {
1576
				rc = -EFAULT;
1577
				break;
1578
			}
1579

1580
			rc = 0;
1581
			DEBUGP(4, dev, "... in CM_IOCSPTS\n");
1582
			/* wait for ATR to get valid */
1583
			if (wait_event_interruptible
1584
			    (dev->atrq,
1585
			     ((filp->f_flags & O_NONBLOCK)
1586
			      || (test_bit(IS_ATR_PRESENT, (void *)&dev->flags)
1587
				  != 0)))) {
1588
				if (filp->f_flags & O_NONBLOCK)
1589
					rc = -EAGAIN;
1590
				else
1591
					rc = -ERESTARTSYS;
1592
				break;
1593
			}
1594
			/* get IO lock */
1595
			if (wait_event_interruptible
1596
			    (dev->ioq,
1597
			     ((filp->f_flags & O_NONBLOCK)
1598
			      || (test_and_set_bit(LOCK_IO, (void *)&dev->flags)
1599
				  == 0)))) {
1600
				if (filp->f_flags & O_NONBLOCK)
1601
					rc = -EAGAIN;
1602
				else
1603
					rc = -ERESTARTSYS;
1604
				break;
1605
			}
1606

1607
			if ((rc = set_protocol(dev, &krnptsreq)) != 0) {
1608
				/* auto power_on again */
1609
				dev->mstate = M_FETCH_ATR;
1610
				clear_bit(IS_ATR_VALID, &dev->flags);
1611
			}
1612
			/* release lock */
1613
			clear_bit(LOCK_IO, &dev->flags);
1614
			wake_up_interruptible(&dev->ioq);
1615

1616
		}
1617
		break;
1618
#ifdef CM4000_DEBUG
1619
	case CM_IOSDBGLVL:
1620
		rc = -ENOTTY;
1621
		break;
1622
#endif
1623
	default:
1624
		DEBUGP(4, dev, "... in default (unknown IOCTL code)\n");
1625
		rc = -ENOTTY;
1626
	}
1627
out:
1628
	mutex_unlock(&cmm_mutex);
1629
	return rc;
1630
}
1631

1632
static int cmm_open(struct inode *inode, struct file *filp)
1633
{
1634
	struct cm4000_dev *dev;
1635
	struct pcmcia_device *link;
1636
	int minor = iminor(inode);
1637
	int ret;
1638

1639
	if (minor >= CM4000_MAX_DEV)
1640
		return -ENODEV;
1641

1642
	mutex_lock(&cmm_mutex);
1643
	link = dev_table[minor];
1644
	if (link == NULL || !pcmcia_dev_present(link)) {
1645
		ret = -ENODEV;
1646
		goto out;
1647
	}
1648

1649
	if (link->open) {
1650
		ret = -EBUSY;
1651
		goto out;
1652
	}
1653

1654
	dev = link->priv;
1655
	filp->private_data = dev;
1656

1657
	DEBUGP(2, dev, "-> cmm_open(device=%d.%d process=%s,%d)\n",
1658
	      imajor(inode), minor, current->comm, current->pid);
1659

1660
	/* init device variables, they may be "polluted" after close
1661
	 * or, the device may never have been closed (i.e. open failed)
1662
	 */
1663

1664
	ZERO_DEV(dev);
1665

1666
	/* opening will always block since the
1667
	 * monitor will be started by open, which
1668
	 * means we have to wait for ATR becoming
1669
	 * valid = block until valid (or card
1670
	 * inserted)
1671
	 */
1672
	if (filp->f_flags & O_NONBLOCK) {
1673
		ret = -EAGAIN;
1674
		goto out;
1675
	}
1676

1677
	dev->mdelay = T_50MSEC;
1678

1679
	/* start monitoring the cardstatus */
1680
	start_monitor(dev);
1681

1682
	link->open = 1;		/* only one open per device */
1683

1684
	DEBUGP(2, dev, "<- cmm_open\n");
1685
	ret = nonseekable_open(inode, filp);
1686
out:
1687
	mutex_unlock(&cmm_mutex);
1688
	return ret;
1689
}
1690

1691
static int cmm_close(struct inode *inode, struct file *filp)
1692
{
1693
	struct cm4000_dev *dev;
1694
	struct pcmcia_device *link;
1695
	int minor = iminor(inode);
1696

1697
	if (minor >= CM4000_MAX_DEV)
1698
		return -ENODEV;
1699

1700
	link = dev_table[minor];
1701
	if (link == NULL)
1702
		return -ENODEV;
1703

1704
	dev = link->priv;
1705

1706
	DEBUGP(2, dev, "-> cmm_close(maj/min=%d.%d)\n",
1707
	       imajor(inode), minor);
1708

1709
	stop_monitor(dev);
1710

1711
	ZERO_DEV(dev);
1712

1713
	link->open = 0;		/* only one open per device */
1714
	wake_up(&dev->devq);	/* socket removed? */
1715

1716
	DEBUGP(2, dev, "cmm_close\n");
1717
	return 0;
1718
}
1719

1720
static void cmm_cm4000_release(struct pcmcia_device * link)
1721
{
1722
	struct cm4000_dev *dev = link->priv;
1723

1724
	/* dont terminate the monitor, rather rely on
1725
	 * close doing that for us.
1726
	 */
1727
	DEBUGP(3, dev, "-> cmm_cm4000_release\n");
1728
	while (link->open) {
1729
		printk(KERN_INFO MODULE_NAME ": delaying release until "
1730
		       "process has terminated\n");
1731
		/* note: don't interrupt us:
1732
		 * close the applications which own
1733
		 * the devices _first_ !
1734
		 */
1735
		wait_event(dev->devq, (link->open == 0));
1736
	}
1737
	/* dev->devq=NULL;	this cannot be zeroed earlier */
1738
	DEBUGP(3, dev, "<- cmm_cm4000_release\n");
1739
	return;
1740
}
1741

1742
/*==== Interface to PCMCIA Layer =======================================*/
1743

1744
static int cm4000_config_check(struct pcmcia_device *p_dev, void *priv_data)
1745
{
1746
	return pcmcia_request_io(p_dev);
1747
}
1748

1749
static int cm4000_config(struct pcmcia_device * link, int devno)
1750
{
1751
	struct cm4000_dev *dev;
1752

1753
	link->config_flags |= CONF_AUTO_SET_IO;
1754

1755
	/* read the config-tuples */
1756
	if (pcmcia_loop_config(link, cm4000_config_check, NULL))
1757
		goto cs_release;
1758

1759
	if (pcmcia_enable_device(link))
1760
		goto cs_release;
1761

1762
	dev = link->priv;
1763

1764
	return 0;
1765

1766
cs_release:
1767
	cm4000_release(link);
1768
	return -ENODEV;
1769
}
1770

1771
static int cm4000_suspend(struct pcmcia_device *link)
1772
{
1773
	struct cm4000_dev *dev;
1774

1775
	dev = link->priv;
1776
	stop_monitor(dev);
1777

1778
	return 0;
1779
}
1780

1781
static int cm4000_resume(struct pcmcia_device *link)
1782
{
1783
	struct cm4000_dev *dev;
1784

1785
	dev = link->priv;
1786
	if (link->open)
1787
		start_monitor(dev);
1788

1789
	return 0;
1790
}
1791

1792
static void cm4000_release(struct pcmcia_device *link)
1793
{
1794
	cmm_cm4000_release(link);	/* delay release until device closed */
1795
	pcmcia_disable_device(link);
1796
}
1797

1798
static int cm4000_probe(struct pcmcia_device *link)
1799
{
1800
	struct cm4000_dev *dev;
1801
	int i, ret;
1802

1803
	for (i = 0; i < CM4000_MAX_DEV; i++)
1804
		if (dev_table[i] == NULL)
1805
			break;
1806

1807
	if (i == CM4000_MAX_DEV) {
1808
		printk(KERN_NOTICE MODULE_NAME ": all devices in use\n");
1809
		return -ENODEV;
1810
	}
1811

1812
	/* create a new cm4000_cs device */
1813
	dev = kzalloc(sizeof(struct cm4000_dev), GFP_KERNEL);
1814
	if (dev == NULL)
1815
		return -ENOMEM;
1816

1817
	dev->p_dev = link;
1818
	link->priv = dev;
1819
	dev_table[i] = link;
1820

1821
	init_waitqueue_head(&dev->devq);
1822
	init_waitqueue_head(&dev->ioq);
1823
	init_waitqueue_head(&dev->atrq);
1824
	init_waitqueue_head(&dev->readq);
1825

1826
	ret = cm4000_config(link, i);
1827
	if (ret) {
1828
		dev_table[i] = NULL;
1829
		kfree(dev);
1830
		return ret;
1831
	}
1832

1833
	device_create(cmm_class, NULL, MKDEV(major, i), NULL, "cmm%d", i);
1834

1835
	return 0;
1836
}
1837

1838
static void cm4000_detach(struct pcmcia_device *link)
1839
{
1840
	struct cm4000_dev *dev = link->priv;
1841
	int devno;
1842

1843
	/* find device */
1844
	for (devno = 0; devno < CM4000_MAX_DEV; devno++)
1845
		if (dev_table[devno] == link)
1846
			break;
1847
	if (devno == CM4000_MAX_DEV)
1848
		return;
1849

1850
	stop_monitor(dev);
1851

1852
	cm4000_release(link);
1853

1854
	dev_table[devno] = NULL;
1855
	kfree(dev);
1856

1857
	device_destroy(cmm_class, MKDEV(major, devno));
1858

1859
	return;
1860
}
1861

1862
static const struct file_operations cm4000_fops = {
1863
	.owner	= THIS_MODULE,
1864
	.read	= cmm_read,
1865
	.write	= cmm_write,
1866
	.unlocked_ioctl	= cmm_ioctl,
1867
	.open	= cmm_open,
1868
	.release= cmm_close,
1869
	.llseek = no_llseek,
1870
};
1871

1872
static const struct pcmcia_device_id cm4000_ids[] = {
1873
	PCMCIA_DEVICE_MANF_CARD(0x0223, 0x0002),
1874
	PCMCIA_DEVICE_PROD_ID12("CardMan", "4000", 0x2FB368CA, 0xA2BD8C39),
1875
	PCMCIA_DEVICE_NULL,
1876
};
1877
MODULE_DEVICE_TABLE(pcmcia, cm4000_ids);
1878

1879
static struct pcmcia_driver cm4000_driver = {
1880
	.owner	  = THIS_MODULE,
1881
	.name	  = "cm4000_cs",
1882
	.probe    = cm4000_probe,
1883
	.remove   = cm4000_detach,
1884
	.suspend  = cm4000_suspend,
1885
	.resume   = cm4000_resume,
1886
	.id_table = cm4000_ids,
1887
};
1888

1889
static int __init cmm_init(void)
1890
{
1891
	int rc;
1892

1893
	cmm_class = class_create(THIS_MODULE, "cardman_4000");
1894
	if (IS_ERR(cmm_class))
1895
		return PTR_ERR(cmm_class);
1896

1897
	major = register_chrdev(0, DEVICE_NAME, &cm4000_fops);
1898
	if (major < 0) {
1899
		printk(KERN_WARNING MODULE_NAME
1900
			": could not get major number\n");
1901
		class_destroy(cmm_class);
1902
		return major;
1903
	}
1904

1905
	rc = pcmcia_register_driver(&cm4000_driver);
1906
	if (rc < 0) {
1907
		unregister_chrdev(major, DEVICE_NAME);
1908
		class_destroy(cmm_class);
1909
		return rc;
1910
	}
1911

1912
	return 0;
1913
}
1914

1915
static void __exit cmm_exit(void)
1916
{
1917
	pcmcia_unregister_driver(&cm4000_driver);
1918
	unregister_chrdev(major, DEVICE_NAME);
1919
	class_destroy(cmm_class);
1920
};
1921

1922
module_init(cmm_init);
1923
module_exit(cmm_exit);
1924
MODULE_LICENSE("Dual BSD/GPL");
1925

1926