1
/*
2
 * Kernel Debugger Architecture Independent Main Code
3
 *
4
 * This file is subject to the terms and conditions of the GNU General Public
5
 * License.  See the file "COPYING" in the main directory of this archive
6
 * for more details.
7
 *
8
 * Copyright (C) 1999-2004 Silicon Graphics, Inc.  All Rights Reserved.
9
 * Copyright (C) 2000 Stephane Eranian <[email protected]>
10
 * Xscale (R) modifications copyright (C) 2003 Intel Corporation.
11
 * Copyright (c) 2009 Wind River Systems, Inc.  All Rights Reserved.
12
 */
13

14
#include <linux/ctype.h>
15
#include <linux/string.h>
16
#include <linux/kernel.h>
17
#include <linux/reboot.h>
18
#include <linux/sched.h>
19
#include <linux/sysrq.h>
20
#include <linux/smp.h>
21
#include <linux/utsname.h>
22
#include <linux/vmalloc.h>
23
#include <linux/module.h>
24
#include <linux/mm.h>
25
#include <linux/init.h>
26
#include <linux/kallsyms.h>
27
#include <linux/kgdb.h>
28
#include <linux/kdb.h>
29
#include <linux/notifier.h>
30
#include <linux/interrupt.h>
31
#include <linux/delay.h>
32
#include <linux/nmi.h>
33
#include <linux/time.h>
34
#include <linux/ptrace.h>
35
#include <linux/sysctl.h>
36
#include <linux/cpu.h>
37
#include <linux/kdebug.h>
38
#include <linux/proc_fs.h>
39
#include <linux/uaccess.h>
40
#include <linux/slab.h>
41
#include "kdb_private.h"
42

43
#define GREP_LEN 256
44
char kdb_grep_string[GREP_LEN];
45
int kdb_grepping_flag;
46
EXPORT_SYMBOL(kdb_grepping_flag);
47
int kdb_grep_leading;
48
int kdb_grep_trailing;
49

50
/*
51
 * Kernel debugger state flags
52
 */
53
int kdb_flags;
54
atomic_t kdb_event;
55

56
/*
57
 * kdb_lock protects updates to kdb_initial_cpu.  Used to
58
 * single thread processors through the kernel debugger.
59
 */
60
int kdb_initial_cpu = -1;	/* cpu number that owns kdb */
61
int kdb_nextline = 1;
62
int kdb_state;			/* General KDB state */
63

64
struct task_struct *kdb_current_task;
65
EXPORT_SYMBOL(kdb_current_task);
66
struct pt_regs *kdb_current_regs;
67

68
const char *kdb_diemsg;
69
static int kdb_go_count;
70
#ifdef CONFIG_KDB_CONTINUE_CATASTROPHIC
71
static unsigned int kdb_continue_catastrophic =
72
	CONFIG_KDB_CONTINUE_CATASTROPHIC;
73
#else
74
static unsigned int kdb_continue_catastrophic;
75
#endif
76

77
/* kdb_commands describes the available commands. */
78
static kdbtab_t *kdb_commands;
79
#define KDB_BASE_CMD_MAX 50
80
static int kdb_max_commands = KDB_BASE_CMD_MAX;
81
static kdbtab_t kdb_base_commands[KDB_BASE_CMD_MAX];
82
#define for_each_kdbcmd(cmd, num)					\
83
	for ((cmd) = kdb_base_commands, (num) = 0;			\
84
	     num < kdb_max_commands;					\
85
	     num++, num == KDB_BASE_CMD_MAX ? cmd = kdb_commands : cmd++)
86

87
typedef struct _kdbmsg {
88
	int	km_diag;	/* kdb diagnostic */
89
	char	*km_msg;	/* Corresponding message text */
90
} kdbmsg_t;
91

92
#define KDBMSG(msgnum, text) \
93
	{ KDB_##msgnum, text }
94

95
static kdbmsg_t kdbmsgs[] = {
96
	KDBMSG(NOTFOUND, "Command Not Found"),
97
	KDBMSG(ARGCOUNT, "Improper argument count, see usage."),
98
	KDBMSG(BADWIDTH, "Illegal value for BYTESPERWORD use 1, 2, 4 or 8, "
99
	       "8 is only allowed on 64 bit systems"),
100
	KDBMSG(BADRADIX, "Illegal value for RADIX use 8, 10 or 16"),
101
	KDBMSG(NOTENV, "Cannot find environment variable"),
102
	KDBMSG(NOENVVALUE, "Environment variable should have value"),
103
	KDBMSG(NOTIMP, "Command not implemented"),
104
	KDBMSG(ENVFULL, "Environment full"),
105
	KDBMSG(ENVBUFFULL, "Environment buffer full"),
106
	KDBMSG(TOOMANYBPT, "Too many breakpoints defined"),
107
#ifdef CONFIG_CPU_XSCALE
108
	KDBMSG(TOOMANYDBREGS, "More breakpoints than ibcr registers defined"),
109
#else
110
	KDBMSG(TOOMANYDBREGS, "More breakpoints than db registers defined"),
111
#endif
112
	KDBMSG(DUPBPT, "Duplicate breakpoint address"),
113
	KDBMSG(BPTNOTFOUND, "Breakpoint not found"),
114
	KDBMSG(BADMODE, "Invalid IDMODE"),
115
	KDBMSG(BADINT, "Illegal numeric value"),
116
	KDBMSG(INVADDRFMT, "Invalid symbolic address format"),
117
	KDBMSG(BADREG, "Invalid register name"),
118
	KDBMSG(BADCPUNUM, "Invalid cpu number"),
119
	KDBMSG(BADLENGTH, "Invalid length field"),
120
	KDBMSG(NOBP, "No Breakpoint exists"),
121
	KDBMSG(BADADDR, "Invalid address"),
122
};
123
#undef KDBMSG
124

125
static const int __nkdb_err = sizeof(kdbmsgs) / sizeof(kdbmsg_t);
126

127

128
/*
129
 * Initial environment.   This is all kept static and local to
130
 * this file.   We don't want to rely on the memory allocation
131
 * mechanisms in the kernel, so we use a very limited allocate-only
132
 * heap for new and altered environment variables.  The entire
133
 * environment is limited to a fixed number of entries (add more
134
 * to __env[] if required) and a fixed amount of heap (add more to
135
 * KDB_ENVBUFSIZE if required).
136
 */
137

138
static char *__env[] = {
139
#if defined(CONFIG_SMP)
140
 "PROMPT=[%d]kdb> ",
141
 "MOREPROMPT=[%d]more> ",
142
#else
143
 "PROMPT=kdb> ",
144
 "MOREPROMPT=more> ",
145
#endif
146
 "RADIX=16",
147
 "MDCOUNT=8",			/* lines of md output */
148
 "BTARGS=9",			/* 9 possible args in bt */
149
 KDB_PLATFORM_ENV,
150
 "DTABCOUNT=30",
151
 "NOSECT=1",
152
 (char *)0,
153
 (char *)0,
154
 (char *)0,
155
 (char *)0,
156
 (char *)0,
157
 (char *)0,
158
 (char *)0,
159
 (char *)0,
160
 (char *)0,
161
 (char *)0,
162
 (char *)0,
163
 (char *)0,
164
 (char *)0,
165
 (char *)0,
166
 (char *)0,
167
 (char *)0,
168
 (char *)0,
169
 (char *)0,
170
 (char *)0,
171
 (char *)0,
172
 (char *)0,
173
 (char *)0,
174
 (char *)0,
175
};
176

177
static const int __nenv = (sizeof(__env) / sizeof(char *));
178

179
struct task_struct *kdb_curr_task(int cpu)
180
{
181
	struct task_struct *p = curr_task(cpu);
182
#ifdef	_TIF_MCA_INIT
183
	if ((task_thread_info(p)->flags & _TIF_MCA_INIT) && KDB_TSK(cpu))
184
		p = krp->p;
185
#endif
186
	return p;
187
}
188

189
/*
190
 * kdbgetenv - This function will return the character string value of
191
 *	an environment variable.
192
 * Parameters:
193
 *	match	A character string representing an environment variable.
194
 * Returns:
195
 *	NULL	No environment variable matches 'match'
196
 *	char*	Pointer to string value of environment variable.
197
 */
198
char *kdbgetenv(const char *match)
199
{
200
	char **ep = __env;
201
	int matchlen = strlen(match);
202
	int i;
203

204
	for (i = 0; i < __nenv; i++) {
205
		char *e = *ep++;
206

207
		if (!e)
208
			continue;
209

210
		if ((strncmp(match, e, matchlen) == 0)
211
		 && ((e[matchlen] == '\0')
212
		   || (e[matchlen] == '='))) {
213
			char *cp = strchr(e, '=');
214
			return cp ? ++cp : "";
215
		}
216
	}
217
	return NULL;
218
}
219

220
/*
221
 * kdballocenv - This function is used to allocate bytes for
222
 *	environment entries.
223
 * Parameters:
224
 *	match	A character string representing a numeric value
225
 * Outputs:
226
 *	*value  the unsigned long representation of the env variable 'match'
227
 * Returns:
228
 *	Zero on success, a kdb diagnostic on failure.
229
 * Remarks:
230
 *	We use a static environment buffer (envbuffer) to hold the values
231
 *	of dynamically generated environment variables (see kdb_set).  Buffer
232
 *	space once allocated is never free'd, so over time, the amount of space
233
 *	(currently 512 bytes) will be exhausted if env variables are changed
234
 *	frequently.
235
 */
236
static char *kdballocenv(size_t bytes)
237
{
238
#define	KDB_ENVBUFSIZE	512
239
	static char envbuffer[KDB_ENVBUFSIZE];
240
	static int envbufsize;
241
	char *ep = NULL;
242

243
	if ((KDB_ENVBUFSIZE - envbufsize) >= bytes) {
244
		ep = &envbuffer[envbufsize];
245
		envbufsize += bytes;
246
	}
247
	return ep;
248
}
249

250
/*
251
 * kdbgetulenv - This function will return the value of an unsigned
252
 *	long-valued environment variable.
253
 * Parameters:
254
 *	match	A character string representing a numeric value
255
 * Outputs:
256
 *	*value  the unsigned long represntation of the env variable 'match'
257
 * Returns:
258
 *	Zero on success, a kdb diagnostic on failure.
259
 */
260
static int kdbgetulenv(const char *match, unsigned long *value)
261
{
262
	char *ep;
263

264
	ep = kdbgetenv(match);
265
	if (!ep)
266
		return KDB_NOTENV;
267
	if (strlen(ep) == 0)
268
		return KDB_NOENVVALUE;
269

270
	*value = simple_strtoul(ep, NULL, 0);
271

272
	return 0;
273
}
274

275
/*
276
 * kdbgetintenv - This function will return the value of an
277
 *	integer-valued environment variable.
278
 * Parameters:
279
 *	match	A character string representing an integer-valued env variable
280
 * Outputs:
281
 *	*value  the integer representation of the environment variable 'match'
282
 * Returns:
283
 *	Zero on success, a kdb diagnostic on failure.
284
 */
285
int kdbgetintenv(const char *match, int *value)
286
{
287
	unsigned long val;
288
	int diag;
289

290
	diag = kdbgetulenv(match, &val);
291
	if (!diag)
292
		*value = (int) val;
293
	return diag;
294
}
295

296
/*
297
 * kdbgetularg - This function will convert a numeric string into an
298
 *	unsigned long value.
299
 * Parameters:
300
 *	arg	A character string representing a numeric value
301
 * Outputs:
302
 *	*value  the unsigned long represntation of arg.
303
 * Returns:
304
 *	Zero on success, a kdb diagnostic on failure.
305
 */
306
int kdbgetularg(const char *arg, unsigned long *value)
307
{
308
	char *endp;
309
	unsigned long val;
310

311
	val = simple_strtoul(arg, &endp, 0);
312

313
	if (endp == arg) {
314
		/*
315
		 * Also try base 16, for us folks too lazy to type the
316
		 * leading 0x...
317
		 */
318
		val = simple_strtoul(arg, &endp, 16);
319
		if (endp == arg)
320
			return KDB_BADINT;
321
	}
322

323
	*value = val;
324

325
	return 0;
326
}
327

328
int kdbgetu64arg(const char *arg, u64 *value)
329
{
330
	char *endp;
331
	u64 val;
332

333
	val = simple_strtoull(arg, &endp, 0);
334

335
	if (endp == arg) {
336

337
		val = simple_strtoull(arg, &endp, 16);
338
		if (endp == arg)
339
			return KDB_BADINT;
340
	}
341

342
	*value = val;
343

344
	return 0;
345
}
346

347
/*
348
 * kdb_set - This function implements the 'set' command.  Alter an
349
 *	existing environment variable or create a new one.
350
 */
351
int kdb_set(int argc, const char **argv)
352
{
353
	int i;
354
	char *ep;
355
	size_t varlen, vallen;
356

357
	/*
358
	 * we can be invoked two ways:
359
	 *   set var=value    argv[1]="var", argv[2]="value"
360
	 *   set var = value  argv[1]="var", argv[2]="=", argv[3]="value"
361
	 * - if the latter, shift 'em down.
362
	 */
363
	if (argc == 3) {
364
		argv[2] = argv[3];
365
		argc--;
366
	}
367

368
	if (argc != 2)
369
		return KDB_ARGCOUNT;
370

371
	/*
372
	 * Check for internal variables
373
	 */
374
	if (strcmp(argv[1], "KDBDEBUG") == 0) {
375
		unsigned int debugflags;
376
		char *cp;
377

378
		debugflags = simple_strtoul(argv[2], &cp, 0);
379
		if (cp == argv[2] || debugflags & ~KDB_DEBUG_FLAG_MASK) {
380
			kdb_printf("kdb: illegal debug flags '%s'\n",
381
				    argv[2]);
382
			return 0;
383
		}
384
		kdb_flags = (kdb_flags &
385
			     ~(KDB_DEBUG_FLAG_MASK << KDB_DEBUG_FLAG_SHIFT))
386
			| (debugflags << KDB_DEBUG_FLAG_SHIFT);
387

388
		return 0;
389
	}
390

391
	/*
392
	 * Tokenizer squashed the '=' sign.  argv[1] is variable
393
	 * name, argv[2] = value.
394
	 */
395
	varlen = strlen(argv[1]);
396
	vallen = strlen(argv[2]);
397
	ep = kdballocenv(varlen + vallen + 2);
398
	if (ep == (char *)0)
399
		return KDB_ENVBUFFULL;
400

401
	sprintf(ep, "%s=%s", argv[1], argv[2]);
402

403
	ep[varlen+vallen+1] = '\0';
404

405
	for (i = 0; i < __nenv; i++) {
406
		if (__env[i]
407
		 && ((strncmp(__env[i], argv[1], varlen) == 0)
408
		   && ((__env[i][varlen] == '\0')
409
		    || (__env[i][varlen] == '=')))) {
410
			__env[i] = ep;
411
			return 0;
412
		}
413
	}
414

415
	/*
416
	 * Wasn't existing variable.  Fit into slot.
417
	 */
418
	for (i = 0; i < __nenv-1; i++) {
419
		if (__env[i] == (char *)0) {
420
			__env[i] = ep;
421
			return 0;
422
		}
423
	}
424

425
	return KDB_ENVFULL;
426
}
427

428
static int kdb_check_regs(void)
429
{
430
	if (!kdb_current_regs) {
431
		kdb_printf("No current kdb registers."
432
			   "  You may need to select another task\n");
433
		return KDB_BADREG;
434
	}
435
	return 0;
436
}
437

438
/*
439
 * kdbgetaddrarg - This function is responsible for parsing an
440
 *	address-expression and returning the value of the expression,
441
 *	symbol name, and offset to the caller.
442
 *
443
 *	The argument may consist of a numeric value (decimal or
444
 *	hexidecimal), a symbol name, a register name (preceded by the
445
 *	percent sign), an environment variable with a numeric value
446
 *	(preceded by a dollar sign) or a simple arithmetic expression
447
 *	consisting of a symbol name, +/-, and a numeric constant value
448
 *	(offset).
449
 * Parameters:
450
 *	argc	- count of arguments in argv
451
 *	argv	- argument vector
452
 *	*nextarg - index to next unparsed argument in argv[]
453
 *	regs	- Register state at time of KDB entry
454
 * Outputs:
455
 *	*value	- receives the value of the address-expression
456
 *	*offset - receives the offset specified, if any
457
 *	*name   - receives the symbol name, if any
458
 *	*nextarg - index to next unparsed argument in argv[]
459
 * Returns:
460
 *	zero is returned on success, a kdb diagnostic code is
461
 *      returned on error.
462
 */
463
int kdbgetaddrarg(int argc, const char **argv, int *nextarg,
464
		  unsigned long *value,  long *offset,
465
		  char **name)
466
{
467
	unsigned long addr;
468
	unsigned long off = 0;
469
	int positive;
470
	int diag;
471
	int found = 0;
472
	char *symname;
473
	char symbol = '\0';
474
	char *cp;
475
	kdb_symtab_t symtab;
476

477
	/*
478
	 * Process arguments which follow the following syntax:
479
	 *
480
	 *  symbol | numeric-address [+/- numeric-offset]
481
	 *  %register
482
	 *  $environment-variable
483
	 */
484

485
	if (*nextarg > argc)
486
		return KDB_ARGCOUNT;
487

488
	symname = (char *)argv[*nextarg];
489

490
	/*
491
	 * If there is no whitespace between the symbol
492
	 * or address and the '+' or '-' symbols, we
493
	 * remember the character and replace it with a
494
	 * null so the symbol/value can be properly parsed
495
	 */
496
	cp = strpbrk(symname, "+-");
497
	if (cp != NULL) {
498
		symbol = *cp;
499
		*cp++ = '\0';
500
	}
501

502
	if (symname[0] == '$') {
503
		diag = kdbgetulenv(&symname[1], &addr);
504
		if (diag)
505
			return diag;
506
	} else if (symname[0] == '%') {
507
		diag = kdb_check_regs();
508
		if (diag)
509
			return diag;
510
		/* Implement register values with % at a later time as it is
511
		 * arch optional.
512
		 */
513
		return KDB_NOTIMP;
514
	} else {
515
		found = kdbgetsymval(symname, &symtab);
516
		if (found) {
517
			addr = symtab.sym_start;
518
		} else {
519
			diag = kdbgetularg(argv[*nextarg], &addr);
520
			if (diag)
521
				return diag;
522
		}
523
	}
524

525
	if (!found)
526
		found = kdbnearsym(addr, &symtab);
527

528
	(*nextarg)++;
529

530
	if (name)
531
		*name = symname;
532
	if (value)
533
		*value = addr;
534
	if (offset && name && *name)
535
		*offset = addr - symtab.sym_start;
536

537
	if ((*nextarg > argc)
538
	 && (symbol == '\0'))
539
		return 0;
540

541
	/*
542
	 * check for +/- and offset
543
	 */
544

545
	if (symbol == '\0') {
546
		if ((argv[*nextarg][0] != '+')
547
		 && (argv[*nextarg][0] != '-')) {
548
			/*
549
			 * Not our argument.  Return.
550
			 */
551
			return 0;
552
		} else {
553
			positive = (argv[*nextarg][0] == '+');
554
			(*nextarg)++;
555
		}
556
	} else
557
		positive = (symbol == '+');
558

559
	/*
560
	 * Now there must be an offset!
561
	 */
562
	if ((*nextarg > argc)
563
	 && (symbol == '\0')) {
564
		return KDB_INVADDRFMT;
565
	}
566

567
	if (!symbol) {
568
		cp = (char *)argv[*nextarg];
569
		(*nextarg)++;
570
	}
571

572
	diag = kdbgetularg(cp, &off);
573
	if (diag)
574
		return diag;
575

576
	if (!positive)
577
		off = -off;
578

579
	if (offset)
580
		*offset += off;
581

582
	if (value)
583
		*value += off;
584

585
	return 0;
586
}
587

588
static void kdb_cmderror(int diag)
589
{
590
	int i;
591

592
	if (diag >= 0) {
593
		kdb_printf("no error detected (diagnostic is %d)\n", diag);
594
		return;
595
	}
596

597
	for (i = 0; i < __nkdb_err; i++) {
598
		if (kdbmsgs[i].km_diag == diag) {
599
			kdb_printf("diag: %d: %s\n", diag, kdbmsgs[i].km_msg);
600
			return;
601
		}
602
	}
603

604
	kdb_printf("Unknown diag %d\n", -diag);
605
}
606

607
/*
608
 * kdb_defcmd, kdb_defcmd2 - This function implements the 'defcmd'
609
 *	command which defines one command as a set of other commands,
610
 *	terminated by endefcmd.  kdb_defcmd processes the initial
611
 *	'defcmd' command, kdb_defcmd2 is invoked from kdb_parse for
612
 *	the following commands until 'endefcmd'.
613
 * Inputs:
614
 *	argc	argument count
615
 *	argv	argument vector
616
 * Returns:
617
 *	zero for success, a kdb diagnostic if error
618
 */
619
struct defcmd_set {
620
	int count;
621
	int usable;
622
	char *name;
623
	char *usage;
624
	char *help;
625
	char **command;
626
};
627
static struct defcmd_set *defcmd_set;
628
static int defcmd_set_count;
629
static int defcmd_in_progress;
630

631
/* Forward references */
632
static int kdb_exec_defcmd(int argc, const char **argv);
633

634
static int kdb_defcmd2(const char *cmdstr, const char *argv0)
635
{
636
	struct defcmd_set *s = defcmd_set + defcmd_set_count - 1;
637
	char **save_command = s->command;
638
	if (strcmp(argv0, "endefcmd") == 0) {
639
		defcmd_in_progress = 0;
640
		if (!s->count)
641
			s->usable = 0;
642
		if (s->usable)
643
			kdb_register(s->name, kdb_exec_defcmd,
644
				     s->usage, s->help, 0);
645
		return 0;
646
	}
647
	if (!s->usable)
648
		return KDB_NOTIMP;
649
	s->command = kzalloc((s->count + 1) * sizeof(*(s->command)), GFP_KDB);
650
	if (!s->command) {
651
		kdb_printf("Could not allocate new kdb_defcmd table for %s\n",
652
			   cmdstr);
653
		s->usable = 0;
654
		return KDB_NOTIMP;
655
	}
656
	memcpy(s->command, save_command, s->count * sizeof(*(s->command)));
657
	s->command[s->count++] = kdb_strdup(cmdstr, GFP_KDB);
658
	kfree(save_command);
659
	return 0;
660
}
661

662
static int kdb_defcmd(int argc, const char **argv)
663
{
664
	struct defcmd_set *save_defcmd_set = defcmd_set, *s;
665
	if (defcmd_in_progress) {
666
		kdb_printf("kdb: nested defcmd detected, assuming missing "
667
			   "endefcmd\n");
668
		kdb_defcmd2("endefcmd", "endefcmd");
669
	}
670
	if (argc == 0) {
671
		int i;
672
		for (s = defcmd_set; s < defcmd_set + defcmd_set_count; ++s) {
673
			kdb_printf("defcmd %s \"%s\" \"%s\"\n", s->name,
674
				   s->usage, s->help);
675
			for (i = 0; i < s->count; ++i)
676
				kdb_printf("%s", s->command[i]);
677
			kdb_printf("endefcmd\n");
678
		}
679
		return 0;
680
	}
681
	if (argc != 3)
682
		return KDB_ARGCOUNT;
683
	defcmd_set = kmalloc((defcmd_set_count + 1) * sizeof(*defcmd_set),
684
			     GFP_KDB);
685
	if (!defcmd_set) {
686
		kdb_printf("Could not allocate new defcmd_set entry for %s\n",
687
			   argv[1]);
688
		defcmd_set = save_defcmd_set;
689
		return KDB_NOTIMP;
690
	}
691
	memcpy(defcmd_set, save_defcmd_set,
692
	       defcmd_set_count * sizeof(*defcmd_set));
693
	kfree(save_defcmd_set);
694
	s = defcmd_set + defcmd_set_count;
695
	memset(s, 0, sizeof(*s));
696
	s->usable = 1;
697
	s->name = kdb_strdup(argv[1], GFP_KDB);
698
	s->usage = kdb_strdup(argv[2], GFP_KDB);
699
	s->help = kdb_strdup(argv[3], GFP_KDB);
700
	if (s->usage[0] == '"') {
701
		strcpy(s->usage, s->usage+1);
702
		s->usage[strlen(s->usage)-1] = '\0';
703
	}
704
	if (s->help[0] == '"') {
705
		strcpy(s->help, s->help+1);
706
		s->help[strlen(s->help)-1] = '\0';
707
	}
708
	++defcmd_set_count;
709
	defcmd_in_progress = 1;
710
	return 0;
711
}
712

713
/*
714
 * kdb_exec_defcmd - Execute the set of commands associated with this
715
 *	defcmd name.
716
 * Inputs:
717
 *	argc	argument count
718
 *	argv	argument vector
719
 * Returns:
720
 *	zero for success, a kdb diagnostic if error
721
 */
722
static int kdb_exec_defcmd(int argc, const char **argv)
723
{
724
	int i, ret;
725
	struct defcmd_set *s;
726
	if (argc != 0)
727
		return KDB_ARGCOUNT;
728
	for (s = defcmd_set, i = 0; i < defcmd_set_count; ++i, ++s) {
729
		if (strcmp(s->name, argv[0]) == 0)
730
			break;
731
	}
732
	if (i == defcmd_set_count) {
733
		kdb_printf("kdb_exec_defcmd: could not find commands for %s\n",
734
			   argv[0]);
735
		return KDB_NOTIMP;
736
	}
737
	for (i = 0; i < s->count; ++i) {
738
		/* Recursive use of kdb_parse, do not use argv after
739
		 * this point */
740
		argv = NULL;
741
		kdb_printf("[%s]kdb> %s\n", s->name, s->command[i]);
742
		ret = kdb_parse(s->command[i]);
743
		if (ret)
744
			return ret;
745
	}
746
	return 0;
747
}
748

749
/* Command history */
750
#define KDB_CMD_HISTORY_COUNT	32
751
#define CMD_BUFLEN		200	/* kdb_printf: max printline
752
					 * size == 256 */
753
static unsigned int cmd_head, cmd_tail;
754
static unsigned int cmdptr;
755
static char cmd_hist[KDB_CMD_HISTORY_COUNT][CMD_BUFLEN];
756
static char cmd_cur[CMD_BUFLEN];
757

758
/*
759
 * The "str" argument may point to something like  | grep xyz
760
 */
761
static void parse_grep(const char *str)
762
{
763
	int	len;
764
	char	*cp = (char *)str, *cp2;
765

766
	/* sanity check: we should have been called with the \ first */
767
	if (*cp != '|')
768
		return;
769
	cp++;
770
	while (isspace(*cp))
771
		cp++;
772
	if (strncmp(cp, "grep ", 5)) {
773
		kdb_printf("invalid 'pipe', see grephelp\n");
774
		return;
775
	}
776
	cp += 5;
777
	while (isspace(*cp))
778
		cp++;
779
	cp2 = strchr(cp, '\n');
780
	if (cp2)
781
		*cp2 = '\0'; /* remove the trailing newline */
782
	len = strlen(cp);
783
	if (len == 0) {
784
		kdb_printf("invalid 'pipe', see grephelp\n");
785
		return;
786
	}
787
	/* now cp points to a nonzero length search string */
788
	if (*cp == '"') {
789
		/* allow it be "x y z" by removing the "'s - there must
790
		   be two of them */
791
		cp++;
792
		cp2 = strchr(cp, '"');
793
		if (!cp2) {
794
			kdb_printf("invalid quoted string, see grephelp\n");
795
			return;
796
		}
797
		*cp2 = '\0'; /* end the string where the 2nd " was */
798
	}
799
	kdb_grep_leading = 0;
800
	if (*cp == '^') {
801
		kdb_grep_leading = 1;
802
		cp++;
803
	}
804
	len = strlen(cp);
805
	kdb_grep_trailing = 0;
806
	if (*(cp+len-1) == '$') {
807
		kdb_grep_trailing = 1;
808
		*(cp+len-1) = '\0';
809
	}
810
	len = strlen(cp);
811
	if (!len)
812
		return;
813
	if (len >= GREP_LEN) {
814
		kdb_printf("search string too long\n");
815
		return;
816
	}
817
	strcpy(kdb_grep_string, cp);
818
	kdb_grepping_flag++;
819
	return;
820
}
821

822
/*
823
 * kdb_parse - Parse the command line, search the command table for a
824
 *	matching command and invoke the command function.  This
825
 *	function may be called recursively, if it is, the second call
826
 *	will overwrite argv and cbuf.  It is the caller's
827
 *	responsibility to save their argv if they recursively call
828
 *	kdb_parse().
829
 * Parameters:
830
 *      cmdstr	The input command line to be parsed.
831
 *	regs	The registers at the time kdb was entered.
832
 * Returns:
833
 *	Zero for success, a kdb diagnostic if failure.
834
 * Remarks:
835
 *	Limited to 20 tokens.
836
 *
837
 *	Real rudimentary tokenization. Basically only whitespace
838
 *	is considered a token delimeter (but special consideration
839
 *	is taken of the '=' sign as used by the 'set' command).
840
 *
841
 *	The algorithm used to tokenize the input string relies on
842
 *	there being at least one whitespace (or otherwise useless)
843
 *	character between tokens as the character immediately following
844
 *	the token is altered in-place to a null-byte to terminate the
845
 *	token string.
846
 */
847

848
#define MAXARGC	20
849

850
int kdb_parse(const char *cmdstr)
851
{
852
	static char *argv[MAXARGC];
853
	static int argc;
854
	static char cbuf[CMD_BUFLEN+2];
855
	char *cp;
856
	char *cpp, quoted;
857
	kdbtab_t *tp;
858
	int i, escaped, ignore_errors = 0, check_grep;
859

860
	/*
861
	 * First tokenize the command string.
862
	 */
863
	cp = (char *)cmdstr;
864
	kdb_grepping_flag = check_grep = 0;
865

866
	if (KDB_FLAG(CMD_INTERRUPT)) {
867
		/* Previous command was interrupted, newline must not
868
		 * repeat the command */
869
		KDB_FLAG_CLEAR(CMD_INTERRUPT);
870
		KDB_STATE_SET(PAGER);
871
		argc = 0;	/* no repeat */
872
	}
873

874
	if (*cp != '\n' && *cp != '\0') {
875
		argc = 0;
876
		cpp = cbuf;
877
		while (*cp) {
878
			/* skip whitespace */
879
			while (isspace(*cp))
880
				cp++;
881
			if ((*cp == '\0') || (*cp == '\n') ||
882
			    (*cp == '#' && !defcmd_in_progress))
883
				break;
884
			/* special case: check for | grep pattern */
885
			if (*cp == '|') {
886
				check_grep++;
887
				break;
888
			}
889
			if (cpp >= cbuf + CMD_BUFLEN) {
890
				kdb_printf("kdb_parse: command buffer "
891
					   "overflow, command ignored\n%s\n",
892
					   cmdstr);
893
				return KDB_NOTFOUND;
894
			}
895
			if (argc >= MAXARGC - 1) {
896
				kdb_printf("kdb_parse: too many arguments, "
897
					   "command ignored\n%s\n", cmdstr);
898
				return KDB_NOTFOUND;
899
			}
900
			argv[argc++] = cpp;
901
			escaped = 0;
902
			quoted = '\0';
903
			/* Copy to next unquoted and unescaped
904
			 * whitespace or '=' */
905
			while (*cp && *cp != '\n' &&
906
			       (escaped || quoted || !isspace(*cp))) {
907
				if (cpp >= cbuf + CMD_BUFLEN)
908
					break;
909
				if (escaped) {
910
					escaped = 0;
911
					*cpp++ = *cp++;
912
					continue;
913
				}
914
				if (*cp == '\\') {
915
					escaped = 1;
916
					++cp;
917
					continue;
918
				}
919
				if (*cp == quoted)
920
					quoted = '\0';
921
				else if (*cp == '\'' || *cp == '"')
922
					quoted = *cp;
923
				*cpp = *cp++;
924
				if (*cpp == '=' && !quoted)
925
					break;
926
				++cpp;
927
			}
928
			*cpp++ = '\0';	/* Squash a ws or '=' character */
929
		}
930
	}
931
	if (!argc)
932
		return 0;
933
	if (check_grep)
934
		parse_grep(cp);
935
	if (defcmd_in_progress) {
936
		int result = kdb_defcmd2(cmdstr, argv[0]);
937
		if (!defcmd_in_progress) {
938
			argc = 0;	/* avoid repeat on endefcmd */
939
			*(argv[0]) = '\0';
940
		}
941
		return result;
942
	}
943
	if (argv[0][0] == '-' && argv[0][1] &&
944
	    (argv[0][1] < '0' || argv[0][1] > '9')) {
945
		ignore_errors = 1;
946
		++argv[0];
947
	}
948

949
	for_each_kdbcmd(tp, i) {
950
		if (tp->cmd_name) {
951
			/*
952
			 * If this command is allowed to be abbreviated,
953
			 * check to see if this is it.
954
			 */
955

956
			if (tp->cmd_minlen
957
			 && (strlen(argv[0]) <= tp->cmd_minlen)) {
958
				if (strncmp(argv[0],
959
					    tp->cmd_name,
960
					    tp->cmd_minlen) == 0) {
961
					break;
962
				}
963
			}
964

965
			if (strcmp(argv[0], tp->cmd_name) == 0)
966
				break;
967
		}
968
	}
969

970
	/*
971
	 * If we don't find a command by this name, see if the first
972
	 * few characters of this match any of the known commands.
973
	 * e.g., md1c20 should match md.
974
	 */
975
	if (i == kdb_max_commands) {
976
		for_each_kdbcmd(tp, i) {
977
			if (tp->cmd_name) {
978
				if (strncmp(argv[0],
979
					    tp->cmd_name,
980
					    strlen(tp->cmd_name)) == 0) {
981
					break;
982
				}
983
			}
984
		}
985
	}
986

987
	if (i < kdb_max_commands) {
988
		int result;
989
		KDB_STATE_SET(CMD);
990
		result = (*tp->cmd_func)(argc-1, (const char **)argv);
991
		if (result && ignore_errors && result > KDB_CMD_GO)
992
			result = 0;
993
		KDB_STATE_CLEAR(CMD);
994
		switch (tp->cmd_repeat) {
995
		case KDB_REPEAT_NONE:
996
			argc = 0;
997
			if (argv[0])
998
				*(argv[0]) = '\0';
999
			break;
1000
		case KDB_REPEAT_NO_ARGS:
1001
			argc = 1;
1002
			if (argv[1])
1003
				*(argv[1]) = '\0';
1004
			break;
1005
		case KDB_REPEAT_WITH_ARGS:
1006
			break;
1007
		}
1008
		return result;
1009
	}
1010

1011
	/*
1012
	 * If the input with which we were presented does not
1013
	 * map to an existing command, attempt to parse it as an
1014
	 * address argument and display the result.   Useful for
1015
	 * obtaining the address of a variable, or the nearest symbol
1016
	 * to an address contained in a register.
1017
	 */
1018
	{
1019
		unsigned long value;
1020
		char *name = NULL;
1021
		long offset;
1022
		int nextarg = 0;
1023

1024
		if (kdbgetaddrarg(0, (const char **)argv, &nextarg,
1025
				  &value, &offset, &name)) {
1026
			return KDB_NOTFOUND;
1027
		}
1028

1029
		kdb_printf("%s = ", argv[0]);
1030
		kdb_symbol_print(value, NULL, KDB_SP_DEFAULT);
1031
		kdb_printf("\n");
1032
		return 0;
1033
	}
1034
}
1035

1036

1037
static int handle_ctrl_cmd(char *cmd)
1038
{
1039
#define CTRL_P	16
1040
#define CTRL_N	14
1041

1042
	/* initial situation */
1043
	if (cmd_head == cmd_tail)
1044
		return 0;
1045
	switch (*cmd) {
1046
	case CTRL_P:
1047
		if (cmdptr != cmd_tail)
1048
			cmdptr = (cmdptr-1) % KDB_CMD_HISTORY_COUNT;
1049
		strncpy(cmd_cur, cmd_hist[cmdptr], CMD_BUFLEN);
1050
		return 1;
1051
	case CTRL_N:
1052
		if (cmdptr != cmd_head)
1053
			cmdptr = (cmdptr+1) % KDB_CMD_HISTORY_COUNT;
1054
		strncpy(cmd_cur, cmd_hist[cmdptr], CMD_BUFLEN);
1055
		return 1;
1056
	}
1057
	return 0;
1058
}
1059

1060
/*
1061
 * kdb_reboot - This function implements the 'reboot' command.  Reboot
1062
 *	the system immediately, or loop for ever on failure.
1063
 */
1064
static int kdb_reboot(int argc, const char **argv)
1065
{
1066
	emergency_restart();
1067
	kdb_printf("Hmm, kdb_reboot did not reboot, spinning here\n");
1068
	while (1)
1069
		cpu_relax();
1070
	/* NOTREACHED */
1071
	return 0;
1072
}
1073

1074
static void kdb_dumpregs(struct pt_regs *regs)
1075
{
1076
	int old_lvl = console_loglevel;
1077
	console_loglevel = 15;
1078
	kdb_trap_printk++;
1079
	show_regs(regs);
1080
	kdb_trap_printk--;
1081
	kdb_printf("\n");
1082
	console_loglevel = old_lvl;
1083
}
1084

1085
void kdb_set_current_task(struct task_struct *p)
1086
{
1087
	kdb_current_task = p;
1088

1089
	if (kdb_task_has_cpu(p)) {
1090
		kdb_current_regs = KDB_TSKREGS(kdb_process_cpu(p));
1091
		return;
1092
	}
1093
	kdb_current_regs = NULL;
1094
}
1095

1096
/*
1097
 * kdb_local - The main code for kdb.  This routine is invoked on a
1098
 *	specific processor, it is not global.  The main kdb() routine
1099
 *	ensures that only one processor at a time is in this routine.
1100
 *	This code is called with the real reason code on the first
1101
 *	entry to a kdb session, thereafter it is called with reason
1102
 *	SWITCH, even if the user goes back to the original cpu.
1103
 * Inputs:
1104
 *	reason		The reason KDB was invoked
1105
 *	error		The hardware-defined error code
1106
 *	regs		The exception frame at time of fault/breakpoint.
1107
 *	db_result	Result code from the break or debug point.
1108
 * Returns:
1109
 *	0	KDB was invoked for an event which it wasn't responsible
1110
 *	1	KDB handled the event for which it was invoked.
1111
 *	KDB_CMD_GO	User typed 'go'.
1112
 *	KDB_CMD_CPU	User switched to another cpu.
1113
 *	KDB_CMD_SS	Single step.
1114
 *	KDB_CMD_SSB	Single step until branch.
1115
 */
1116
static int kdb_local(kdb_reason_t reason, int error, struct pt_regs *regs,
1117
		     kdb_dbtrap_t db_result)
1118
{
1119
	char *cmdbuf;
1120
	int diag;
1121
	struct task_struct *kdb_current =
1122
		kdb_curr_task(raw_smp_processor_id());
1123

1124
	KDB_DEBUG_STATE("kdb_local 1", reason);
1125
	kdb_go_count = 0;
1126
	if (reason == KDB_REASON_DEBUG) {
1127
		/* special case below */
1128
	} else {
1129
		kdb_printf("\nEntering kdb (current=0x%p, pid %d) ",
1130
			   kdb_current, kdb_current ? kdb_current->pid : 0);
1131
#if defined(CONFIG_SMP)
1132
		kdb_printf("on processor %d ", raw_smp_processor_id());
1133
#endif
1134
	}
1135

1136
	switch (reason) {
1137
	case KDB_REASON_DEBUG:
1138
	{
1139
		/*
1140
		 * If re-entering kdb after a single step
1141
		 * command, don't print the message.
1142
		 */
1143
		switch (db_result) {
1144
		case KDB_DB_BPT:
1145
			kdb_printf("\nEntering kdb (0x%p, pid %d) ",
1146
				   kdb_current, kdb_current->pid);
1147
#if defined(CONFIG_SMP)
1148
			kdb_printf("on processor %d ", raw_smp_processor_id());
1149
#endif
1150
			kdb_printf("due to Debug @ " kdb_machreg_fmt "\n",
1151
				   instruction_pointer(regs));
1152
			break;
1153
		case KDB_DB_SSB:
1154
			/*
1155
			 * In the midst of ssb command. Just return.
1156
			 */
1157
			KDB_DEBUG_STATE("kdb_local 3", reason);
1158
			return KDB_CMD_SSB;	/* Continue with SSB command */
1159

1160
			break;
1161
		case KDB_DB_SS:
1162
			break;
1163
		case KDB_DB_SSBPT:
1164
			KDB_DEBUG_STATE("kdb_local 4", reason);
1165
			return 1;	/* kdba_db_trap did the work */
1166
		default:
1167
			kdb_printf("kdb: Bad result from kdba_db_trap: %d\n",
1168
				   db_result);
1169
			break;
1170
		}
1171

1172
	}
1173
		break;
1174
	case KDB_REASON_ENTER:
1175
		if (KDB_STATE(KEYBOARD))
1176
			kdb_printf("due to Keyboard Entry\n");
1177
		else
1178
			kdb_printf("due to KDB_ENTER()\n");
1179
		break;
1180
	case KDB_REASON_KEYBOARD:
1181
		KDB_STATE_SET(KEYBOARD);
1182
		kdb_printf("due to Keyboard Entry\n");
1183
		break;
1184
	case KDB_REASON_ENTER_SLAVE:
1185
		/* drop through, slaves only get released via cpu switch */
1186
	case KDB_REASON_SWITCH:
1187
		kdb_printf("due to cpu switch\n");
1188
		break;
1189
	case KDB_REASON_OOPS:
1190
		kdb_printf("Oops: %s\n", kdb_diemsg);
1191
		kdb_printf("due to oops @ " kdb_machreg_fmt "\n",
1192
			   instruction_pointer(regs));
1193
		kdb_dumpregs(regs);
1194
		break;
1195
	case KDB_REASON_NMI:
1196
		kdb_printf("due to NonMaskable Interrupt @ "
1197
			   kdb_machreg_fmt "\n",
1198
			   instruction_pointer(regs));
1199
		kdb_dumpregs(regs);
1200
		break;
1201
	case KDB_REASON_SSTEP:
1202
	case KDB_REASON_BREAK:
1203
		kdb_printf("due to %s @ " kdb_machreg_fmt "\n",
1204
			   reason == KDB_REASON_BREAK ?
1205
			   "Breakpoint" : "SS trap", instruction_pointer(regs));
1206
		/*
1207
		 * Determine if this breakpoint is one that we
1208
		 * are interested in.
1209
		 */
1210
		if (db_result != KDB_DB_BPT) {
1211
			kdb_printf("kdb: error return from kdba_bp_trap: %d\n",
1212
				   db_result);
1213
			KDB_DEBUG_STATE("kdb_local 6", reason);
1214
			return 0;	/* Not for us, dismiss it */
1215
		}
1216
		break;
1217
	case KDB_REASON_RECURSE:
1218
		kdb_printf("due to Recursion @ " kdb_machreg_fmt "\n",
1219
			   instruction_pointer(regs));
1220
		break;
1221
	default:
1222
		kdb_printf("kdb: unexpected reason code: %d\n", reason);
1223
		KDB_DEBUG_STATE("kdb_local 8", reason);
1224
		return 0;	/* Not for us, dismiss it */
1225
	}
1226

1227
	while (1) {
1228
		/*
1229
		 * Initialize pager context.
1230
		 */
1231
		kdb_nextline = 1;
1232
		KDB_STATE_CLEAR(SUPPRESS);
1233

1234
		cmdbuf = cmd_cur;
1235
		*cmdbuf = '\0';
1236
		*(cmd_hist[cmd_head]) = '\0';
1237

1238
		if (KDB_FLAG(ONLY_DO_DUMP)) {
1239
			/* kdb is off but a catastrophic error requires a dump.
1240
			 * Take the dump and reboot.
1241
			 * Turn on logging so the kdb output appears in the log
1242
			 * buffer in the dump.
1243
			 */
1244
			const char *setargs[] = { "set", "LOGGING", "1" };
1245
			kdb_set(2, setargs);
1246
			kdb_reboot(0, NULL);
1247
			/*NOTREACHED*/
1248
		}
1249

1250
do_full_getstr:
1251
#if defined(CONFIG_SMP)
1252
		snprintf(kdb_prompt_str, CMD_BUFLEN, kdbgetenv("PROMPT"),
1253
			 raw_smp_processor_id());
1254
#else
1255
		snprintf(kdb_prompt_str, CMD_BUFLEN, kdbgetenv("PROMPT"));
1256
#endif
1257
		if (defcmd_in_progress)
1258
			strncat(kdb_prompt_str, "[defcmd]", CMD_BUFLEN);
1259

1260
		/*
1261
		 * Fetch command from keyboard
1262
		 */
1263
		cmdbuf = kdb_getstr(cmdbuf, CMD_BUFLEN, kdb_prompt_str);
1264
		if (*cmdbuf != '\n') {
1265
			if (*cmdbuf < 32) {
1266
				if (cmdptr == cmd_head) {
1267
					strncpy(cmd_hist[cmd_head], cmd_cur,
1268
						CMD_BUFLEN);
1269
					*(cmd_hist[cmd_head] +
1270
					  strlen(cmd_hist[cmd_head])-1) = '\0';
1271
				}
1272
				if (!handle_ctrl_cmd(cmdbuf))
1273
					*(cmd_cur+strlen(cmd_cur)-1) = '\0';
1274
				cmdbuf = cmd_cur;
1275
				goto do_full_getstr;
1276
			} else {
1277
				strncpy(cmd_hist[cmd_head], cmd_cur,
1278
					CMD_BUFLEN);
1279
			}
1280

1281
			cmd_head = (cmd_head+1) % KDB_CMD_HISTORY_COUNT;
1282
			if (cmd_head == cmd_tail)
1283
				cmd_tail = (cmd_tail+1) % KDB_CMD_HISTORY_COUNT;
1284
		}
1285

1286
		cmdptr = cmd_head;
1287
		diag = kdb_parse(cmdbuf);
1288
		if (diag == KDB_NOTFOUND) {
1289
			kdb_printf("Unknown kdb command: '%s'\n", cmdbuf);
1290
			diag = 0;
1291
		}
1292
		if (diag == KDB_CMD_GO
1293
		 || diag == KDB_CMD_CPU
1294
		 || diag == KDB_CMD_SS
1295
		 || diag == KDB_CMD_SSB
1296
		 || diag == KDB_CMD_KGDB)
1297
			break;
1298

1299
		if (diag)
1300
			kdb_cmderror(diag);
1301
	}
1302
	KDB_DEBUG_STATE("kdb_local 9", diag);
1303
	return diag;
1304
}
1305

1306

1307
/*
1308
 * kdb_print_state - Print the state data for the current processor
1309
 *	for debugging.
1310
 * Inputs:
1311
 *	text		Identifies the debug point
1312
 *	value		Any integer value to be printed, e.g. reason code.
1313
 */
1314
void kdb_print_state(const char *text, int value)
1315
{
1316
	kdb_printf("state: %s cpu %d value %d initial %d state %x\n",
1317
		   text, raw_smp_processor_id(), value, kdb_initial_cpu,
1318
		   kdb_state);
1319
}
1320

1321
/*
1322
 * kdb_main_loop - After initial setup and assignment of the
1323
 *	controlling cpu, all cpus are in this loop.  One cpu is in
1324
 *	control and will issue the kdb prompt, the others will spin
1325
 *	until 'go' or cpu switch.
1326
 *
1327
 *	To get a consistent view of the kernel stacks for all
1328
 *	processes, this routine is invoked from the main kdb code via
1329
 *	an architecture specific routine.  kdba_main_loop is
1330
 *	responsible for making the kernel stacks consistent for all
1331
 *	processes, there should be no difference between a blocked
1332
 *	process and a running process as far as kdb is concerned.
1333
 * Inputs:
1334
 *	reason		The reason KDB was invoked
1335
 *	error		The hardware-defined error code
1336
 *	reason2		kdb's current reason code.
1337
 *			Initially error but can change
1338
 *			according to kdb state.
1339
 *	db_result	Result code from break or debug point.
1340
 *	regs		The exception frame at time of fault/breakpoint.
1341
 *			should always be valid.
1342
 * Returns:
1343
 *	0	KDB was invoked for an event which it wasn't responsible
1344
 *	1	KDB handled the event for which it was invoked.
1345
 */
1346
int kdb_main_loop(kdb_reason_t reason, kdb_reason_t reason2, int error,
1347
	      kdb_dbtrap_t db_result, struct pt_regs *regs)
1348
{
1349
	int result = 1;
1350
	/* Stay in kdb() until 'go', 'ss[b]' or an error */
1351
	while (1) {
1352
		/*
1353
		 * All processors except the one that is in control
1354
		 * will spin here.
1355
		 */
1356
		KDB_DEBUG_STATE("kdb_main_loop 1", reason);
1357
		while (KDB_STATE(HOLD_CPU)) {
1358
			/* state KDB is turned off by kdb_cpu to see if the
1359
			 * other cpus are still live, each cpu in this loop
1360
			 * turns it back on.
1361
			 */
1362
			if (!KDB_STATE(KDB))
1363
				KDB_STATE_SET(KDB);
1364
		}
1365

1366
		KDB_STATE_CLEAR(SUPPRESS);
1367
		KDB_DEBUG_STATE("kdb_main_loop 2", reason);
1368
		if (KDB_STATE(LEAVING))
1369
			break;	/* Another cpu said 'go' */
1370
		/* Still using kdb, this processor is in control */
1371
		result = kdb_local(reason2, error, regs, db_result);
1372
		KDB_DEBUG_STATE("kdb_main_loop 3", result);
1373

1374
		if (result == KDB_CMD_CPU)
1375
			break;
1376

1377
		if (result == KDB_CMD_SS) {
1378
			KDB_STATE_SET(DOING_SS);
1379
			break;
1380
		}
1381

1382
		if (result == KDB_CMD_SSB) {
1383
			KDB_STATE_SET(DOING_SS);
1384
			KDB_STATE_SET(DOING_SSB);
1385
			break;
1386
		}
1387

1388
		if (result == KDB_CMD_KGDB) {
1389
			if (!(KDB_STATE(DOING_KGDB) || KDB_STATE(DOING_KGDB2)))
1390
				kdb_printf("Entering please attach debugger "
1391
					   "or use $D#44+ or $3#33\n");
1392
			break;
1393
		}
1394
		if (result && result != 1 && result != KDB_CMD_GO)
1395
			kdb_printf("\nUnexpected kdb_local return code %d\n",
1396
				   result);
1397
		KDB_DEBUG_STATE("kdb_main_loop 4", reason);
1398
		break;
1399
	}
1400
	if (KDB_STATE(DOING_SS))
1401
		KDB_STATE_CLEAR(SSBPT);
1402

1403
	return result;
1404
}
1405

1406
/*
1407
 * kdb_mdr - This function implements the guts of the 'mdr', memory
1408
 * read command.
1409
 *	mdr  <addr arg>,<byte count>
1410
 * Inputs:
1411
 *	addr	Start address
1412
 *	count	Number of bytes
1413
 * Returns:
1414
 *	Always 0.  Any errors are detected and printed by kdb_getarea.
1415
 */
1416
static int kdb_mdr(unsigned long addr, unsigned int count)
1417
{
1418
	unsigned char c;
1419
	while (count--) {
1420
		if (kdb_getarea(c, addr))
1421
			return 0;
1422
		kdb_printf("%02x", c);
1423
		addr++;
1424
	}
1425
	kdb_printf("\n");
1426
	return 0;
1427
}
1428

1429
/*
1430
 * kdb_md - This function implements the 'md', 'md1', 'md2', 'md4',
1431
 *	'md8' 'mdr' and 'mds' commands.
1432
 *
1433
 *	md|mds  [<addr arg> [<line count> [<radix>]]]
1434
 *	mdWcN	[<addr arg> [<line count> [<radix>]]]
1435
 *		where W = is the width (1, 2, 4 or 8) and N is the count.
1436
 *		for eg., md1c20 reads 20 bytes, 1 at a time.
1437
 *	mdr  <addr arg>,<byte count>
1438
 */
1439
static void kdb_md_line(const char *fmtstr, unsigned long addr,
1440
			int symbolic, int nosect, int bytesperword,
1441
			int num, int repeat, int phys)
1442
{
1443
	/* print just one line of data */
1444
	kdb_symtab_t symtab;
1445
	char cbuf[32];
1446
	char *c = cbuf;
1447
	int i;
1448
	unsigned long word;
1449

1450
	memset(cbuf, '\0', sizeof(cbuf));
1451
	if (phys)
1452
		kdb_printf("phys " kdb_machreg_fmt0 " ", addr);
1453
	else
1454
		kdb_printf(kdb_machreg_fmt0 " ", addr);
1455

1456
	for (i = 0; i < num && repeat--; i++) {
1457
		if (phys) {
1458
			if (kdb_getphysword(&word, addr, bytesperword))
1459
				break;
1460
		} else if (kdb_getword(&word, addr, bytesperword))
1461
			break;
1462
		kdb_printf(fmtstr, word);
1463
		if (symbolic)
1464
			kdbnearsym(word, &symtab);
1465
		else
1466
			memset(&symtab, 0, sizeof(symtab));
1467
		if (symtab.sym_name) {
1468
			kdb_symbol_print(word, &symtab, 0);
1469
			if (!nosect) {
1470
				kdb_printf("\n");
1471
				kdb_printf("                       %s %s "
1472
					   kdb_machreg_fmt " "
1473
					   kdb_machreg_fmt " "
1474
					   kdb_machreg_fmt, symtab.mod_name,
1475
					   symtab.sec_name, symtab.sec_start,
1476
					   symtab.sym_start, symtab.sym_end);
1477
			}
1478
			addr += bytesperword;
1479
		} else {
1480
			union {
1481
				u64 word;
1482
				unsigned char c[8];
1483
			} wc;
1484
			unsigned char *cp;
1485
#ifdef	__BIG_ENDIAN
1486
			cp = wc.c + 8 - bytesperword;
1487
#else
1488
			cp = wc.c;
1489
#endif
1490
			wc.word = word;
1491
#define printable_char(c) \
1492
	({unsigned char __c = c; isascii(__c) && isprint(__c) ? __c : '.'; })
1493
			switch (bytesperword) {
1494
			case 8:
1495
				*c++ = printable_char(*cp++);
1496
				*c++ = printable_char(*cp++);
1497
				*c++ = printable_char(*cp++);
1498
				*c++ = printable_char(*cp++);
1499
				addr += 4;
1500
			case 4:
1501
				*c++ = printable_char(*cp++);
1502
				*c++ = printable_char(*cp++);
1503
				addr += 2;
1504
			case 2:
1505
				*c++ = printable_char(*cp++);
1506
				addr++;
1507
			case 1:
1508
				*c++ = printable_char(*cp++);
1509
				addr++;
1510
				break;
1511
			}
1512
#undef printable_char
1513
		}
1514
	}
1515
	kdb_printf("%*s %s\n", (int)((num-i)*(2*bytesperword + 1)+1),
1516
		   " ", cbuf);
1517
}
1518

1519
static int kdb_md(int argc, const char **argv)
1520
{
1521
	static unsigned long last_addr;
1522
	static int last_radix, last_bytesperword, last_repeat;
1523
	int radix = 16, mdcount = 8, bytesperword = KDB_WORD_SIZE, repeat;
1524
	int nosect = 0;
1525
	char fmtchar, fmtstr[64];
1526
	unsigned long addr;
1527
	unsigned long word;
1528
	long offset = 0;
1529
	int symbolic = 0;
1530
	int valid = 0;
1531
	int phys = 0;
1532

1533
	kdbgetintenv("MDCOUNT", &mdcount);
1534
	kdbgetintenv("RADIX", &radix);
1535
	kdbgetintenv("BYTESPERWORD", &bytesperword);
1536

1537
	/* Assume 'md <addr>' and start with environment values */
1538
	repeat = mdcount * 16 / bytesperword;
1539

1540
	if (strcmp(argv[0], "mdr") == 0) {
1541
		if (argc != 2)
1542
			return KDB_ARGCOUNT;
1543
		valid = 1;
1544
	} else if (isdigit(argv[0][2])) {
1545
		bytesperword = (int)(argv[0][2] - '0');
1546
		if (bytesperword == 0) {
1547
			bytesperword = last_bytesperword;
1548
			if (bytesperword == 0)
1549
				bytesperword = 4;
1550
		}
1551
		last_bytesperword = bytesperword;
1552
		repeat = mdcount * 16 / bytesperword;
1553
		if (!argv[0][3])
1554
			valid = 1;
1555
		else if (argv[0][3] == 'c' && argv[0][4]) {
1556
			char *p;
1557
			repeat = simple_strtoul(argv[0] + 4, &p, 10);
1558
			mdcount = ((repeat * bytesperword) + 15) / 16;
1559
			valid = !*p;
1560
		}
1561
		last_repeat = repeat;
1562
	} else if (strcmp(argv[0], "md") == 0)
1563
		valid = 1;
1564
	else if (strcmp(argv[0], "mds") == 0)
1565
		valid = 1;
1566
	else if (strcmp(argv[0], "mdp") == 0) {
1567
		phys = valid = 1;
1568
	}
1569
	if (!valid)
1570
		return KDB_NOTFOUND;
1571

1572
	if (argc == 0) {
1573
		if (last_addr == 0)
1574
			return KDB_ARGCOUNT;
1575
		addr = last_addr;
1576
		radix = last_radix;
1577
		bytesperword = last_bytesperword;
1578
		repeat = last_repeat;
1579
		mdcount = ((repeat * bytesperword) + 15) / 16;
1580
	}
1581

1582
	if (argc) {
1583
		unsigned long val;
1584
		int diag, nextarg = 1;
1585
		diag = kdbgetaddrarg(argc, argv, &nextarg, &addr,
1586
				     &offset, NULL);
1587
		if (diag)
1588
			return diag;
1589
		if (argc > nextarg+2)
1590
			return KDB_ARGCOUNT;
1591

1592
		if (argc >= nextarg) {
1593
			diag = kdbgetularg(argv[nextarg], &val);
1594
			if (!diag) {
1595
				mdcount = (int) val;
1596
				repeat = mdcount * 16 / bytesperword;
1597
			}
1598
		}
1599
		if (argc >= nextarg+1) {
1600
			diag = kdbgetularg(argv[nextarg+1], &val);
1601
			if (!diag)
1602
				radix = (int) val;
1603
		}
1604
	}
1605

1606
	if (strcmp(argv[0], "mdr") == 0)
1607
		return kdb_mdr(addr, mdcount);
1608

1609
	switch (radix) {
1610
	case 10:
1611
		fmtchar = 'd';
1612
		break;
1613
	case 16:
1614
		fmtchar = 'x';
1615
		break;
1616
	case 8:
1617
		fmtchar = 'o';
1618
		break;
1619
	default:
1620
		return KDB_BADRADIX;
1621
	}
1622

1623
	last_radix = radix;
1624

1625
	if (bytesperword > KDB_WORD_SIZE)
1626
		return KDB_BADWIDTH;
1627

1628
	switch (bytesperword) {
1629
	case 8:
1630
		sprintf(fmtstr, "%%16.16l%c ", fmtchar);
1631
		break;
1632
	case 4:
1633
		sprintf(fmtstr, "%%8.8l%c ", fmtchar);
1634
		break;
1635
	case 2:
1636
		sprintf(fmtstr, "%%4.4l%c ", fmtchar);
1637
		break;
1638
	case 1:
1639
		sprintf(fmtstr, "%%2.2l%c ", fmtchar);
1640
		break;
1641
	default:
1642
		return KDB_BADWIDTH;
1643
	}
1644

1645
	last_repeat = repeat;
1646
	last_bytesperword = bytesperword;
1647

1648
	if (strcmp(argv[0], "mds") == 0) {
1649
		symbolic = 1;
1650
		/* Do not save these changes as last_*, they are temporary mds
1651
		 * overrides.
1652
		 */
1653
		bytesperword = KDB_WORD_SIZE;
1654
		repeat = mdcount;
1655
		kdbgetintenv("NOSECT", &nosect);
1656
	}
1657

1658
	/* Round address down modulo BYTESPERWORD */
1659

1660
	addr &= ~(bytesperword-1);
1661

1662
	while (repeat > 0) {
1663
		unsigned long a;
1664
		int n, z, num = (symbolic ? 1 : (16 / bytesperword));
1665

1666
		if (KDB_FLAG(CMD_INTERRUPT))
1667
			return 0;
1668
		for (a = addr, z = 0; z < repeat; a += bytesperword, ++z) {
1669
			if (phys) {
1670
				if (kdb_getphysword(&word, a, bytesperword)
1671
						|| word)
1672
					break;
1673
			} else if (kdb_getword(&word, a, bytesperword) || word)
1674
				break;
1675
		}
1676
		n = min(num, repeat);
1677
		kdb_md_line(fmtstr, addr, symbolic, nosect, bytesperword,
1678
			    num, repeat, phys);
1679
		addr += bytesperword * n;
1680
		repeat -= n;
1681
		z = (z + num - 1) / num;
1682
		if (z > 2) {
1683
			int s = num * (z-2);
1684
			kdb_printf(kdb_machreg_fmt0 "-" kdb_machreg_fmt0
1685
				   " zero suppressed\n",
1686
				addr, addr + bytesperword * s - 1);
1687
			addr += bytesperword * s;
1688
			repeat -= s;
1689
		}
1690
	}
1691
	last_addr = addr;
1692

1693
	return 0;
1694
}
1695

1696
/*
1697
 * kdb_mm - This function implements the 'mm' command.
1698
 *	mm address-expression new-value
1699
 * Remarks:
1700
 *	mm works on machine words, mmW works on bytes.
1701
 */
1702
static int kdb_mm(int argc, const char **argv)
1703
{
1704
	int diag;
1705
	unsigned long addr;
1706
	long offset = 0;
1707
	unsigned long contents;
1708
	int nextarg;
1709
	int width;
1710

1711
	if (argv[0][2] && !isdigit(argv[0][2]))
1712
		return KDB_NOTFOUND;
1713

1714
	if (argc < 2)
1715
		return KDB_ARGCOUNT;
1716

1717
	nextarg = 1;
1718
	diag = kdbgetaddrarg(argc, argv, &nextarg, &addr, &offset, NULL);
1719
	if (diag)
1720
		return diag;
1721

1722
	if (nextarg > argc)
1723
		return KDB_ARGCOUNT;
1724
	diag = kdbgetaddrarg(argc, argv, &nextarg, &contents, NULL, NULL);
1725
	if (diag)
1726
		return diag;
1727

1728
	if (nextarg != argc + 1)
1729
		return KDB_ARGCOUNT;
1730

1731
	width = argv[0][2] ? (argv[0][2] - '0') : (KDB_WORD_SIZE);
1732
	diag = kdb_putword(addr, contents, width);
1733
	if (diag)
1734
		return diag;
1735

1736
	kdb_printf(kdb_machreg_fmt " = " kdb_machreg_fmt "\n", addr, contents);
1737

1738
	return 0;
1739
}
1740

1741
/*
1742
 * kdb_go - This function implements the 'go' command.
1743
 *	go [address-expression]
1744
 */
1745
static int kdb_go(int argc, const char **argv)
1746
{
1747
	unsigned long addr;
1748
	int diag;
1749
	int nextarg;
1750
	long offset;
1751

1752
	if (raw_smp_processor_id() != kdb_initial_cpu) {
1753
		kdb_printf("go must execute on the entry cpu, "
1754
			   "please use \"cpu %d\" and then execute go\n",
1755
			   kdb_initial_cpu);
1756
		return KDB_BADCPUNUM;
1757
	}
1758
	if (argc == 1) {
1759
		nextarg = 1;
1760
		diag = kdbgetaddrarg(argc, argv, &nextarg,
1761
				     &addr, &offset, NULL);
1762
		if (diag)
1763
			return diag;
1764
	} else if (argc) {
1765
		return KDB_ARGCOUNT;
1766
	}
1767

1768
	diag = KDB_CMD_GO;
1769
	if (KDB_FLAG(CATASTROPHIC)) {
1770
		kdb_printf("Catastrophic error detected\n");
1771
		kdb_printf("kdb_continue_catastrophic=%d, ",
1772
			kdb_continue_catastrophic);
1773
		if (kdb_continue_catastrophic == 0 && kdb_go_count++ == 0) {
1774
			kdb_printf("type go a second time if you really want "
1775
				   "to continue\n");
1776
			return 0;
1777
		}
1778
		if (kdb_continue_catastrophic == 2) {
1779
			kdb_printf("forcing reboot\n");
1780
			kdb_reboot(0, NULL);
1781
		}
1782
		kdb_printf("attempting to continue\n");
1783
	}
1784
	return diag;
1785
}
1786

1787
/*
1788
 * kdb_rd - This function implements the 'rd' command.
1789
 */
1790
static int kdb_rd(int argc, const char **argv)
1791
{
1792
	int len = kdb_check_regs();
1793
#if DBG_MAX_REG_NUM > 0
1794
	int i;
1795
	char *rname;
1796
	int rsize;
1797
	u64 reg64;
1798
	u32 reg32;
1799
	u16 reg16;
1800
	u8 reg8;
1801

1802
	if (len)
1803
		return len;
1804

1805
	for (i = 0; i < DBG_MAX_REG_NUM; i++) {
1806
		rsize = dbg_reg_def[i].size * 2;
1807
		if (rsize > 16)
1808
			rsize = 2;
1809
		if (len + strlen(dbg_reg_def[i].name) + 4 + rsize > 80) {
1810
			len = 0;
1811
			kdb_printf("\n");
1812
		}
1813
		if (len)
1814
			len += kdb_printf("  ");
1815
		switch(dbg_reg_def[i].size * 8) {
1816
		case 8:
1817
			rname = dbg_get_reg(i, &reg8, kdb_current_regs);
1818
			if (!rname)
1819
				break;
1820
			len += kdb_printf("%s: %02x", rname, reg8);
1821
			break;
1822
		case 16:
1823
			rname = dbg_get_reg(i, &reg16, kdb_current_regs);
1824
			if (!rname)
1825
				break;
1826
			len += kdb_printf("%s: %04x", rname, reg16);
1827
			break;
1828
		case 32:
1829
			rname = dbg_get_reg(i, &reg32, kdb_current_regs);
1830
			if (!rname)
1831
				break;
1832
			len += kdb_printf("%s: %08x", rname, reg32);
1833
			break;
1834
		case 64:
1835
			rname = dbg_get_reg(i, &reg64, kdb_current_regs);
1836
			if (!rname)
1837
				break;
1838
			len += kdb_printf("%s: %016llx", rname, reg64);
1839
			break;
1840
		default:
1841
			len += kdb_printf("%s: ??", dbg_reg_def[i].name);
1842
		}
1843
	}
1844
	kdb_printf("\n");
1845
#else
1846
	if (len)
1847
		return len;
1848

1849
	kdb_dumpregs(kdb_current_regs);
1850
#endif
1851
	return 0;
1852
}
1853

1854
/*
1855
 * kdb_rm - This function implements the 'rm' (register modify)  command.
1856
 *	rm register-name new-contents
1857
 * Remarks:
1858
 *	Allows register modification with the same restrictions as gdb
1859
 */
1860
static int kdb_rm(int argc, const char **argv)
1861
{
1862
#if DBG_MAX_REG_NUM > 0
1863
	int diag;
1864
	const char *rname;
1865
	int i;
1866
	u64 reg64;
1867
	u32 reg32;
1868
	u16 reg16;
1869
	u8 reg8;
1870

1871
	if (argc != 2)
1872
		return KDB_ARGCOUNT;
1873
	/*
1874
	 * Allow presence or absence of leading '%' symbol.
1875
	 */
1876
	rname = argv[1];
1877
	if (*rname == '%')
1878
		rname++;
1879

1880
	diag = kdbgetu64arg(argv[2], &reg64);
1881
	if (diag)
1882
		return diag;
1883

1884
	diag = kdb_check_regs();
1885
	if (diag)
1886
		return diag;
1887

1888
	diag = KDB_BADREG;
1889
	for (i = 0; i < DBG_MAX_REG_NUM; i++) {
1890
		if (strcmp(rname, dbg_reg_def[i].name) == 0) {
1891
			diag = 0;
1892
			break;
1893
		}
1894
	}
1895
	if (!diag) {
1896
		switch(dbg_reg_def[i].size * 8) {
1897
		case 8:
1898
			reg8 = reg64;
1899
			dbg_set_reg(i, &reg8, kdb_current_regs);
1900
			break;
1901
		case 16:
1902
			reg16 = reg64;
1903
			dbg_set_reg(i, &reg16, kdb_current_regs);
1904
			break;
1905
		case 32:
1906
			reg32 = reg64;
1907
			dbg_set_reg(i, &reg32, kdb_current_regs);
1908
			break;
1909
		case 64:
1910
			dbg_set_reg(i, &reg64, kdb_current_regs);
1911
			break;
1912
		}
1913
	}
1914
	return diag;
1915
#else
1916
	kdb_printf("ERROR: Register set currently not implemented\n");
1917
    return 0;
1918
#endif
1919
}
1920

1921
#if defined(CONFIG_MAGIC_SYSRQ)
1922
/*
1923
 * kdb_sr - This function implements the 'sr' (SYSRQ key) command
1924
 *	which interfaces to the soi-disant MAGIC SYSRQ functionality.
1925
 *		sr <magic-sysrq-code>
1926
 */
1927
static int kdb_sr(int argc, const char **argv)
1928
{
1929
	if (argc != 1)
1930
		return KDB_ARGCOUNT;
1931
	kdb_trap_printk++;
1932
	__handle_sysrq(*argv[1], false);
1933
	kdb_trap_printk--;
1934

1935
	return 0;
1936
}
1937
#endif	/* CONFIG_MAGIC_SYSRQ */
1938

1939
/*
1940
 * kdb_ef - This function implements the 'regs' (display exception
1941
 *	frame) command.  This command takes an address and expects to
1942
 *	find an exception frame at that address, formats and prints
1943
 *	it.
1944
 *		regs address-expression
1945
 * Remarks:
1946
 *	Not done yet.
1947
 */
1948
static int kdb_ef(int argc, const char **argv)
1949
{
1950
	int diag;
1951
	unsigned long addr;
1952
	long offset;
1953
	int nextarg;
1954

1955
	if (argc != 1)
1956
		return KDB_ARGCOUNT;
1957

1958
	nextarg = 1;
1959
	diag = kdbgetaddrarg(argc, argv, &nextarg, &addr, &offset, NULL);
1960
	if (diag)
1961
		return diag;
1962
	show_regs((struct pt_regs *)addr);
1963
	return 0;
1964
}
1965

1966
#if defined(CONFIG_MODULES)
1967
/*
1968
 * kdb_lsmod - This function implements the 'lsmod' command.  Lists
1969
 *	currently loaded kernel modules.
1970
 *	Mostly taken from userland lsmod.
1971
 */
1972
static int kdb_lsmod(int argc, const char **argv)
1973
{
1974
	struct module *mod;
1975

1976
	if (argc != 0)
1977
		return KDB_ARGCOUNT;
1978

1979
	kdb_printf("Module                  Size  modstruct     Used by\n");
1980
	list_for_each_entry(mod, kdb_modules, list) {
1981

1982
		kdb_printf("%-20s%8u  0x%p ", mod->name,
1983
			   mod->core_size, (void *)mod);
1984
#ifdef CONFIG_MODULE_UNLOAD
1985
		kdb_printf("%4d ", module_refcount(mod));
1986
#endif
1987
		if (mod->state == MODULE_STATE_GOING)
1988
			kdb_printf(" (Unloading)");
1989
		else if (mod->state == MODULE_STATE_COMING)
1990
			kdb_printf(" (Loading)");
1991
		else
1992
			kdb_printf(" (Live)");
1993
		kdb_printf(" 0x%p", mod->module_core);
1994

1995
#ifdef CONFIG_MODULE_UNLOAD
1996
		{
1997
			struct module_use *use;
1998
			kdb_printf(" [ ");
1999
			list_for_each_entry(use, &mod->source_list,
2000
					    source_list)
2001
				kdb_printf("%s ", use->target->name);
2002
			kdb_printf("]\n");
2003
		}
2004
#endif
2005
	}
2006

2007
	return 0;
2008
}
2009

2010
#endif	/* CONFIG_MODULES */
2011

2012
/*
2013
 * kdb_env - This function implements the 'env' command.  Display the
2014
 *	current environment variables.
2015
 */
2016

2017
static int kdb_env(int argc, const char **argv)
2018
{
2019
	int i;
2020

2021
	for (i = 0; i < __nenv; i++) {
2022
		if (__env[i])
2023
			kdb_printf("%s\n", __env[i]);
2024
	}
2025

2026
	if (KDB_DEBUG(MASK))
2027
		kdb_printf("KDBFLAGS=0x%x\n", kdb_flags);
2028

2029
	return 0;
2030
}
2031

2032
#ifdef CONFIG_PRINTK
2033
/*
2034
 * kdb_dmesg - This function implements the 'dmesg' command to display
2035
 *	the contents of the syslog buffer.
2036
 *		dmesg [lines] [adjust]
2037
 */
2038
static int kdb_dmesg(int argc, const char **argv)
2039
{
2040
	char *syslog_data[4], *start, *end, c = '\0', *p;
2041
	int diag, logging, logsize, lines = 0, adjust = 0, n;
2042

2043
	if (argc > 2)
2044
		return KDB_ARGCOUNT;
2045
	if (argc) {
2046
		char *cp;
2047
		lines = simple_strtol(argv[1], &cp, 0);
2048
		if (*cp)
2049
			lines = 0;
2050
		if (argc > 1) {
2051
			adjust = simple_strtoul(argv[2], &cp, 0);
2052
			if (*cp || adjust < 0)
2053
				adjust = 0;
2054
		}
2055
	}
2056

2057
	/* disable LOGGING if set */
2058
	diag = kdbgetintenv("LOGGING", &logging);
2059
	if (!diag && logging) {
2060
		const char *setargs[] = { "set", "LOGGING", "0" };
2061
		kdb_set(2, setargs);
2062
	}
2063

2064
	/* syslog_data[0,1] physical start, end+1.  syslog_data[2,3]
2065
	 * logical start, end+1. */
2066
	kdb_syslog_data(syslog_data);
2067
	if (syslog_data[2] == syslog_data[3])
2068
		return 0;
2069
	logsize = syslog_data[1] - syslog_data[0];
2070
	start = syslog_data[2];
2071
	end = syslog_data[3];
2072
#define KDB_WRAP(p) (((p - syslog_data[0]) % logsize) + syslog_data[0])
2073
	for (n = 0, p = start; p < end; ++p) {
2074
		c = *KDB_WRAP(p);
2075
		if (c == '\n')
2076
			++n;
2077
	}
2078
	if (c != '\n')
2079
		++n;
2080
	if (lines < 0) {
2081
		if (adjust >= n)
2082
			kdb_printf("buffer only contains %d lines, nothing "
2083
				   "printed\n", n);
2084
		else if (adjust - lines >= n)
2085
			kdb_printf("buffer only contains %d lines, last %d "
2086
				   "lines printed\n", n, n - adjust);
2087
		if (adjust) {
2088
			for (; start < end && adjust; ++start) {
2089
				if (*KDB_WRAP(start) == '\n')
2090
					--adjust;
2091
			}
2092
			if (start < end)
2093
				++start;
2094
		}
2095
		for (p = start; p < end && lines; ++p) {
2096
			if (*KDB_WRAP(p) == '\n')
2097
				++lines;
2098
		}
2099
		end = p;
2100
	} else if (lines > 0) {
2101
		int skip = n - (adjust + lines);
2102
		if (adjust >= n) {
2103
			kdb_printf("buffer only contains %d lines, "
2104
				   "nothing printed\n", n);
2105
			skip = n;
2106
		} else if (skip < 0) {
2107
			lines += skip;
2108
			skip = 0;
2109
			kdb_printf("buffer only contains %d lines, first "
2110
				   "%d lines printed\n", n, lines);
2111
		}
2112
		for (; start < end && skip; ++start) {
2113
			if (*KDB_WRAP(start) == '\n')
2114
				--skip;
2115
		}
2116
		for (p = start; p < end && lines; ++p) {
2117
			if (*KDB_WRAP(p) == '\n')
2118
				--lines;
2119
		}
2120
		end = p;
2121
	}
2122
	/* Do a line at a time (max 200 chars) to reduce protocol overhead */
2123
	c = '\n';
2124
	while (start != end) {
2125
		char buf[201];
2126
		p = buf;
2127
		if (KDB_FLAG(CMD_INTERRUPT))
2128
			return 0;
2129
		while (start < end && (c = *KDB_WRAP(start)) &&
2130
		       (p - buf) < sizeof(buf)-1) {
2131
			++start;
2132
			*p++ = c;
2133
			if (c == '\n')
2134
				break;
2135
		}
2136
		*p = '\0';
2137
		kdb_printf("%s", buf);
2138
	}
2139
	if (c != '\n')
2140
		kdb_printf("\n");
2141

2142
	return 0;
2143
}
2144
#endif /* CONFIG_PRINTK */
2145
/*
2146
 * kdb_cpu - This function implements the 'cpu' command.
2147
 *	cpu	[<cpunum>]
2148
 * Returns:
2149
 *	KDB_CMD_CPU for success, a kdb diagnostic if error
2150
 */
2151
static void kdb_cpu_status(void)
2152
{
2153
	int i, start_cpu, first_print = 1;
2154
	char state, prev_state = '?';
2155

2156
	kdb_printf("Currently on cpu %d\n", raw_smp_processor_id());
2157
	kdb_printf("Available cpus: ");
2158
	for (start_cpu = -1, i = 0; i < NR_CPUS; i++) {
2159
		if (!cpu_online(i)) {
2160
			state = 'F';	/* cpu is offline */
2161
		} else {
2162
			state = ' ';	/* cpu is responding to kdb */
2163
			if (kdb_task_state_char(KDB_TSK(i)) == 'I')
2164
				state = 'I';	/* idle task */
2165
		}
2166
		if (state != prev_state) {
2167
			if (prev_state != '?') {
2168
				if (!first_print)
2169
					kdb_printf(", ");
2170
				first_print = 0;
2171
				kdb_printf("%d", start_cpu);
2172
				if (start_cpu < i-1)
2173
					kdb_printf("-%d", i-1);
2174
				if (prev_state != ' ')
2175
					kdb_printf("(%c)", prev_state);
2176
			}
2177
			prev_state = state;
2178
			start_cpu = i;
2179
		}
2180
	}
2181
	/* print the trailing cpus, ignoring them if they are all offline */
2182
	if (prev_state != 'F') {
2183
		if (!first_print)
2184
			kdb_printf(", ");
2185
		kdb_printf("%d", start_cpu);
2186
		if (start_cpu < i-1)
2187
			kdb_printf("-%d", i-1);
2188
		if (prev_state != ' ')
2189
			kdb_printf("(%c)", prev_state);
2190
	}
2191
	kdb_printf("\n");
2192
}
2193

2194
static int kdb_cpu(int argc, const char **argv)
2195
{
2196
	unsigned long cpunum;
2197
	int diag;
2198

2199
	if (argc == 0) {
2200
		kdb_cpu_status();
2201
		return 0;
2202
	}
2203

2204
	if (argc != 1)
2205
		return KDB_ARGCOUNT;
2206

2207
	diag = kdbgetularg(argv[1], &cpunum);
2208
	if (diag)
2209
		return diag;
2210

2211
	/*
2212
	 * Validate cpunum
2213
	 */
2214
	if ((cpunum > NR_CPUS) || !cpu_online(cpunum))
2215
		return KDB_BADCPUNUM;
2216

2217
	dbg_switch_cpu = cpunum;
2218

2219
	/*
2220
	 * Switch to other cpu
2221
	 */
2222
	return KDB_CMD_CPU;
2223
}
2224

2225
/* The user may not realize that ps/bta with no parameters does not print idle
2226
 * or sleeping system daemon processes, so tell them how many were suppressed.
2227
 */
2228
void kdb_ps_suppressed(void)
2229
{
2230
	int idle = 0, daemon = 0;
2231
	unsigned long mask_I = kdb_task_state_string("I"),
2232
		      mask_M = kdb_task_state_string("M");
2233
	unsigned long cpu;
2234
	const struct task_struct *p, *g;
2235
	for_each_online_cpu(cpu) {
2236
		p = kdb_curr_task(cpu);
2237
		if (kdb_task_state(p, mask_I))
2238
			++idle;
2239
	}
2240
	kdb_do_each_thread(g, p) {
2241
		if (kdb_task_state(p, mask_M))
2242
			++daemon;
2243
	} kdb_while_each_thread(g, p);
2244
	if (idle || daemon) {
2245
		if (idle)
2246
			kdb_printf("%d idle process%s (state I)%s\n",
2247
				   idle, idle == 1 ? "" : "es",
2248
				   daemon ? " and " : "");
2249
		if (daemon)
2250
			kdb_printf("%d sleeping system daemon (state M) "
2251
				   "process%s", daemon,
2252
				   daemon == 1 ? "" : "es");
2253
		kdb_printf(" suppressed,\nuse 'ps A' to see all.\n");
2254
	}
2255
}
2256

2257
/*
2258
 * kdb_ps - This function implements the 'ps' command which shows a
2259
 *	list of the active processes.
2260
 *		ps [DRSTCZEUIMA]   All processes, optionally filtered by state
2261
 */
2262
void kdb_ps1(const struct task_struct *p)
2263
{
2264
	int cpu;
2265
	unsigned long tmp;
2266

2267
	if (!p || probe_kernel_read(&tmp, (char *)p, sizeof(unsigned long)))
2268
		return;
2269

2270
	cpu = kdb_process_cpu(p);
2271
	kdb_printf("0x%p %8d %8d  %d %4d   %c  0x%p %c%s\n",
2272
		   (void *)p, p->pid, p->parent->pid,
2273
		   kdb_task_has_cpu(p), kdb_process_cpu(p),
2274
		   kdb_task_state_char(p),
2275
		   (void *)(&p->thread),
2276
		   p == kdb_curr_task(raw_smp_processor_id()) ? '*' : ' ',
2277
		   p->comm);
2278
	if (kdb_task_has_cpu(p)) {
2279
		if (!KDB_TSK(cpu)) {
2280
			kdb_printf("  Error: no saved data for this cpu\n");
2281
		} else {
2282
			if (KDB_TSK(cpu) != p)
2283
				kdb_printf("  Error: does not match running "
2284
				   "process table (0x%p)\n", KDB_TSK(cpu));
2285
		}
2286
	}
2287
}
2288

2289
static int kdb_ps(int argc, const char **argv)
2290
{
2291
	struct task_struct *g, *p;
2292
	unsigned long mask, cpu;
2293

2294
	if (argc == 0)
2295
		kdb_ps_suppressed();
2296
	kdb_printf("%-*s      Pid   Parent [*] cpu State %-*s Command\n",
2297
		(int)(2*sizeof(void *))+2, "Task Addr",
2298
		(int)(2*sizeof(void *))+2, "Thread");
2299
	mask = kdb_task_state_string(argc ? argv[1] : NULL);
2300
	/* Run the active tasks first */
2301
	for_each_online_cpu(cpu) {
2302
		if (KDB_FLAG(CMD_INTERRUPT))
2303
			return 0;
2304
		p = kdb_curr_task(cpu);
2305
		if (kdb_task_state(p, mask))
2306
			kdb_ps1(p);
2307
	}
2308
	kdb_printf("\n");
2309
	/* Now the real tasks */
2310
	kdb_do_each_thread(g, p) {
2311
		if (KDB_FLAG(CMD_INTERRUPT))
2312
			return 0;
2313
		if (kdb_task_state(p, mask))
2314
			kdb_ps1(p);
2315
	} kdb_while_each_thread(g, p);
2316

2317
	return 0;
2318
}
2319

2320
/*
2321
 * kdb_pid - This function implements the 'pid' command which switches
2322
 *	the currently active process.
2323
 *		pid [<pid> | R]
2324
 */
2325
static int kdb_pid(int argc, const char **argv)
2326
{
2327
	struct task_struct *p;
2328
	unsigned long val;
2329
	int diag;
2330

2331
	if (argc > 1)
2332
		return KDB_ARGCOUNT;
2333

2334
	if (argc) {
2335
		if (strcmp(argv[1], "R") == 0) {
2336
			p = KDB_TSK(kdb_initial_cpu);
2337
		} else {
2338
			diag = kdbgetularg(argv[1], &val);
2339
			if (diag)
2340
				return KDB_BADINT;
2341

2342
			p = find_task_by_pid_ns((pid_t)val,	&init_pid_ns);
2343
			if (!p) {
2344
				kdb_printf("No task with pid=%d\n", (pid_t)val);
2345
				return 0;
2346
			}
2347
		}
2348
		kdb_set_current_task(p);
2349
	}
2350
	kdb_printf("KDB current process is %s(pid=%d)\n",
2351
		   kdb_current_task->comm,
2352
		   kdb_current_task->pid);
2353

2354
	return 0;
2355
}
2356

2357
/*
2358
 * kdb_ll - This function implements the 'll' command which follows a
2359
 *	linked list and executes an arbitrary command for each
2360
 *	element.
2361
 */
2362
static int kdb_ll(int argc, const char **argv)
2363
{
2364
	int diag = 0;
2365
	unsigned long addr;
2366
	long offset = 0;
2367
	unsigned long va;
2368
	unsigned long linkoffset;
2369
	int nextarg;
2370
	const char *command;
2371

2372
	if (argc != 3)
2373
		return KDB_ARGCOUNT;
2374

2375
	nextarg = 1;
2376
	diag = kdbgetaddrarg(argc, argv, &nextarg, &addr, &offset, NULL);
2377
	if (diag)
2378
		return diag;
2379

2380
	diag = kdbgetularg(argv[2], &linkoffset);
2381
	if (diag)
2382
		return diag;
2383

2384
	/*
2385
	 * Using the starting address as
2386
	 * the first element in the list, and assuming that
2387
	 * the list ends with a null pointer.
2388
	 */
2389

2390
	va = addr;
2391
	command = kdb_strdup(argv[3], GFP_KDB);
2392
	if (!command) {
2393
		kdb_printf("%s: cannot duplicate command\n", __func__);
2394
		return 0;
2395
	}
2396
	/* Recursive use of kdb_parse, do not use argv after this point */
2397
	argv = NULL;
2398

2399
	while (va) {
2400
		char buf[80];
2401

2402
		if (KDB_FLAG(CMD_INTERRUPT))
2403
			goto out;
2404

2405
		sprintf(buf, "%s " kdb_machreg_fmt "\n", command, va);
2406
		diag = kdb_parse(buf);
2407
		if (diag)
2408
			goto out;
2409

2410
		addr = va + linkoffset;
2411
		if (kdb_getword(&va, addr, sizeof(va)))
2412
			goto out;
2413
	}
2414

2415
out:
2416
	kfree(command);
2417
	return diag;
2418
}
2419

2420
static int kdb_kgdb(int argc, const char **argv)
2421
{
2422
	return KDB_CMD_KGDB;
2423
}
2424

2425
/*
2426
 * kdb_help - This function implements the 'help' and '?' commands.
2427
 */
2428
static int kdb_help(int argc, const char **argv)
2429
{
2430
	kdbtab_t *kt;
2431
	int i;
2432

2433
	kdb_printf("%-15.15s %-20.20s %s\n", "Command", "Usage", "Description");
2434
	kdb_printf("-----------------------------"
2435
		   "-----------------------------\n");
2436
	for_each_kdbcmd(kt, i) {
2437
		if (kt->cmd_name)
2438
			kdb_printf("%-15.15s %-20.20s %s\n", kt->cmd_name,
2439
				   kt->cmd_usage, kt->cmd_help);
2440
		if (KDB_FLAG(CMD_INTERRUPT))
2441
			return 0;
2442
	}
2443
	return 0;
2444
}
2445

2446
/*
2447
 * kdb_kill - This function implements the 'kill' commands.
2448
 */
2449
static int kdb_kill(int argc, const char **argv)
2450
{
2451
	long sig, pid;
2452
	char *endp;
2453
	struct task_struct *p;
2454
	struct siginfo info;
2455

2456
	if (argc != 2)
2457
		return KDB_ARGCOUNT;
2458

2459
	sig = simple_strtol(argv[1], &endp, 0);
2460
	if (*endp)
2461
		return KDB_BADINT;
2462
	if (sig >= 0) {
2463
		kdb_printf("Invalid signal parameter.<-signal>\n");
2464
		return 0;
2465
	}
2466
	sig = -sig;
2467

2468
	pid = simple_strtol(argv[2], &endp, 0);
2469
	if (*endp)
2470
		return KDB_BADINT;
2471
	if (pid <= 0) {
2472
		kdb_printf("Process ID must be large than 0.\n");
2473
		return 0;
2474
	}
2475

2476
	/* Find the process. */
2477
	p = find_task_by_pid_ns(pid, &init_pid_ns);
2478
	if (!p) {
2479
		kdb_printf("The specified process isn't found.\n");
2480
		return 0;
2481
	}
2482
	p = p->group_leader;
2483
	info.si_signo = sig;
2484
	info.si_errno = 0;
2485
	info.si_code = SI_USER;
2486
	info.si_pid = pid;  /* same capabilities as process being signalled */
2487
	info.si_uid = 0;    /* kdb has root authority */
2488
	kdb_send_sig_info(p, &info);
2489
	return 0;
2490
}
2491

2492
struct kdb_tm {
2493
	int tm_sec;	/* seconds */
2494
	int tm_min;	/* minutes */
2495
	int tm_hour;	/* hours */
2496
	int tm_mday;	/* day of the month */
2497
	int tm_mon;	/* month */
2498
	int tm_year;	/* year */
2499
};
2500

2501
static void kdb_gmtime(struct timespec *tv, struct kdb_tm *tm)
2502
{
2503
	/* This will work from 1970-2099, 2100 is not a leap year */
2504
	static int mon_day[] = { 31, 29, 31, 30, 31, 30, 31,
2505
				 31, 30, 31, 30, 31 };
2506
	memset(tm, 0, sizeof(*tm));
2507
	tm->tm_sec  = tv->tv_sec % (24 * 60 * 60);
2508
	tm->tm_mday = tv->tv_sec / (24 * 60 * 60) +
2509
		(2 * 365 + 1); /* shift base from 1970 to 1968 */
2510
	tm->tm_min =  tm->tm_sec / 60 % 60;
2511
	tm->tm_hour = tm->tm_sec / 60 / 60;
2512
	tm->tm_sec =  tm->tm_sec % 60;
2513
	tm->tm_year = 68 + 4*(tm->tm_mday / (4*365+1));
2514
	tm->tm_mday %= (4*365+1);
2515
	mon_day[1] = 29;
2516
	while (tm->tm_mday >= mon_day[tm->tm_mon]) {
2517
		tm->tm_mday -= mon_day[tm->tm_mon];
2518
		if (++tm->tm_mon == 12) {
2519
			tm->tm_mon = 0;
2520
			++tm->tm_year;
2521
			mon_day[1] = 28;
2522
		}
2523
	}
2524
	++tm->tm_mday;
2525
}
2526

2527
/*
2528
 * Most of this code has been lifted from kernel/timer.c::sys_sysinfo().
2529
 * I cannot call that code directly from kdb, it has an unconditional
2530
 * cli()/sti() and calls routines that take locks which can stop the debugger.
2531
 */
2532
static void kdb_sysinfo(struct sysinfo *val)
2533
{
2534
	struct timespec uptime;
2535
	do_posix_clock_monotonic_gettime(&uptime);
2536
	memset(val, 0, sizeof(*val));
2537
	val->uptime = uptime.tv_sec;
2538
	val->loads[0] = avenrun[0];
2539
	val->loads[1] = avenrun[1];
2540
	val->loads[2] = avenrun[2];
2541
	val->procs = nr_threads-1;
2542
	si_meminfo(val);
2543

2544
	return;
2545
}
2546

2547
/*
2548
 * kdb_summary - This function implements the 'summary' command.
2549
 */
2550
static int kdb_summary(int argc, const char **argv)
2551
{
2552
	struct timespec now;
2553
	struct kdb_tm tm;
2554
	struct sysinfo val;
2555

2556
	if (argc)
2557
		return KDB_ARGCOUNT;
2558

2559
	kdb_printf("sysname    %s\n", init_uts_ns.name.sysname);
2560
	kdb_printf("release    %s\n", init_uts_ns.name.release);
2561
	kdb_printf("version    %s\n", init_uts_ns.name.version);
2562
	kdb_printf("machine    %s\n", init_uts_ns.name.machine);
2563
	kdb_printf("nodename   %s\n", init_uts_ns.name.nodename);
2564
	kdb_printf("domainname %s\n", init_uts_ns.name.domainname);
2565
	kdb_printf("ccversion  %s\n", __stringify(CCVERSION));
2566

2567
	now = __current_kernel_time();
2568
	kdb_gmtime(&now, &tm);
2569
	kdb_printf("date       %04d-%02d-%02d %02d:%02d:%02d "
2570
		   "tz_minuteswest %d\n",
2571
		1900+tm.tm_year, tm.tm_mon+1, tm.tm_mday,
2572
		tm.tm_hour, tm.tm_min, tm.tm_sec,
2573
		sys_tz.tz_minuteswest);
2574

2575
	kdb_sysinfo(&val);
2576
	kdb_printf("uptime     ");
2577
	if (val.uptime > (24*60*60)) {
2578
		int days = val.uptime / (24*60*60);
2579
		val.uptime %= (24*60*60);
2580
		kdb_printf("%d day%s ", days, days == 1 ? "" : "s");
2581
	}
2582
	kdb_printf("%02ld:%02ld\n", val.uptime/(60*60), (val.uptime/60)%60);
2583

2584
	/* lifted from fs/proc/proc_misc.c::loadavg_read_proc() */
2585

2586
#define LOAD_INT(x) ((x) >> FSHIFT)
2587
#define LOAD_FRAC(x) LOAD_INT(((x) & (FIXED_1-1)) * 100)
2588
	kdb_printf("load avg   %ld.%02ld %ld.%02ld %ld.%02ld\n",
2589
		LOAD_INT(val.loads[0]), LOAD_FRAC(val.loads[0]),
2590
		LOAD_INT(val.loads[1]), LOAD_FRAC(val.loads[1]),
2591
		LOAD_INT(val.loads[2]), LOAD_FRAC(val.loads[2]));
2592
#undef LOAD_INT
2593
#undef LOAD_FRAC
2594
	/* Display in kilobytes */
2595
#define K(x) ((x) << (PAGE_SHIFT - 10))
2596
	kdb_printf("\nMemTotal:       %8lu kB\nMemFree:        %8lu kB\n"
2597
		   "Buffers:        %8lu kB\n",
2598
		   val.totalram, val.freeram, val.bufferram);
2599
	return 0;
2600
}
2601

2602
/*
2603
 * kdb_per_cpu - This function implements the 'per_cpu' command.
2604
 */
2605
static int kdb_per_cpu(int argc, const char **argv)
2606
{
2607
	char fmtstr[64];
2608
	int cpu, diag, nextarg = 1;
2609
	unsigned long addr, symaddr, val, bytesperword = 0, whichcpu = ~0UL;
2610

2611
	if (argc < 1 || argc > 3)
2612
		return KDB_ARGCOUNT;
2613

2614
	diag = kdbgetaddrarg(argc, argv, &nextarg, &symaddr, NULL, NULL);
2615
	if (diag)
2616
		return diag;
2617

2618
	if (argc >= 2) {
2619
		diag = kdbgetularg(argv[2], &bytesperword);
2620
		if (diag)
2621
			return diag;
2622
	}
2623
	if (!bytesperword)
2624
		bytesperword = KDB_WORD_SIZE;
2625
	else if (bytesperword > KDB_WORD_SIZE)
2626
		return KDB_BADWIDTH;
2627
	sprintf(fmtstr, "%%0%dlx ", (int)(2*bytesperword));
2628
	if (argc >= 3) {
2629
		diag = kdbgetularg(argv[3], &whichcpu);
2630
		if (diag)
2631
			return diag;
2632
		if (!cpu_online(whichcpu)) {
2633
			kdb_printf("cpu %ld is not online\n", whichcpu);
2634
			return KDB_BADCPUNUM;
2635
		}
2636
	}
2637

2638
	/* Most architectures use __per_cpu_offset[cpu], some use
2639
	 * __per_cpu_offset(cpu), smp has no __per_cpu_offset.
2640
	 */
2641
#ifdef	__per_cpu_offset
2642
#define KDB_PCU(cpu) __per_cpu_offset(cpu)
2643
#else
2644
#ifdef	CONFIG_SMP
2645
#define KDB_PCU(cpu) __per_cpu_offset[cpu]
2646
#else
2647
#define KDB_PCU(cpu) 0
2648
#endif
2649
#endif
2650
	for_each_online_cpu(cpu) {
2651
		if (KDB_FLAG(CMD_INTERRUPT))
2652
			return 0;
2653

2654
		if (whichcpu != ~0UL && whichcpu != cpu)
2655
			continue;
2656
		addr = symaddr + KDB_PCU(cpu);
2657
		diag = kdb_getword(&val, addr, bytesperword);
2658
		if (diag) {
2659
			kdb_printf("%5d " kdb_bfd_vma_fmt0 " - unable to "
2660
				   "read, diag=%d\n", cpu, addr, diag);
2661
			continue;
2662
		}
2663
		kdb_printf("%5d ", cpu);
2664
		kdb_md_line(fmtstr, addr,
2665
			bytesperword == KDB_WORD_SIZE,
2666
			1, bytesperword, 1, 1, 0);
2667
	}
2668
#undef KDB_PCU
2669
	return 0;
2670
}
2671

2672
/*
2673
 * display help for the use of cmd | grep pattern
2674
 */
2675
static int kdb_grep_help(int argc, const char **argv)
2676
{
2677
	kdb_printf("Usage of  cmd args | grep pattern:\n");
2678
	kdb_printf("  Any command's output may be filtered through an ");
2679
	kdb_printf("emulated 'pipe'.\n");
2680
	kdb_printf("  'grep' is just a key word.\n");
2681
	kdb_printf("  The pattern may include a very limited set of "
2682
		   "metacharacters:\n");
2683
	kdb_printf("   pattern or ^pattern or pattern$ or ^pattern$\n");
2684
	kdb_printf("  And if there are spaces in the pattern, you may "
2685
		   "quote it:\n");
2686
	kdb_printf("   \"pat tern\" or \"^pat tern\" or \"pat tern$\""
2687
		   " or \"^pat tern$\"\n");
2688
	return 0;
2689
}
2690

2691
/*
2692
 * kdb_register_repeat - This function is used to register a kernel
2693
 * 	debugger command.
2694
 * Inputs:
2695
 *	cmd	Command name
2696
 *	func	Function to execute the command
2697
 *	usage	A simple usage string showing arguments
2698
 *	help	A simple help string describing command
2699
 *	repeat	Does the command auto repeat on enter?
2700
 * Returns:
2701
 *	zero for success, one if a duplicate command.
2702
 */
2703
#define kdb_command_extend 50	/* arbitrary */
2704
int kdb_register_repeat(char *cmd,
2705
			kdb_func_t func,
2706
			char *usage,
2707
			char *help,
2708
			short minlen,
2709
			kdb_repeat_t repeat)
2710
{
2711
	int i;
2712
	kdbtab_t *kp;
2713

2714
	/*
2715
	 *  Brute force method to determine duplicates
2716
	 */
2717
	for_each_kdbcmd(kp, i) {
2718
		if (kp->cmd_name && (strcmp(kp->cmd_name, cmd) == 0)) {
2719
			kdb_printf("Duplicate kdb command registered: "
2720
				"%s, func %p help %s\n", cmd, func, help);
2721
			return 1;
2722
		}
2723
	}
2724

2725
	/*
2726
	 * Insert command into first available location in table
2727
	 */
2728
	for_each_kdbcmd(kp, i) {
2729
		if (kp->cmd_name == NULL)
2730
			break;
2731
	}
2732

2733
	if (i >= kdb_max_commands) {
2734
		kdbtab_t *new = kmalloc((kdb_max_commands - KDB_BASE_CMD_MAX +
2735
			 kdb_command_extend) * sizeof(*new), GFP_KDB);
2736
		if (!new) {
2737
			kdb_printf("Could not allocate new kdb_command "
2738
				   "table\n");
2739
			return 1;
2740
		}
2741
		if (kdb_commands) {
2742
			memcpy(new, kdb_commands,
2743
			  (kdb_max_commands - KDB_BASE_CMD_MAX) * sizeof(*new));
2744
			kfree(kdb_commands);
2745
		}
2746
		memset(new + kdb_max_commands, 0,
2747
		       kdb_command_extend * sizeof(*new));
2748
		kdb_commands = new;
2749
		kp = kdb_commands + kdb_max_commands - KDB_BASE_CMD_MAX;
2750
		kdb_max_commands += kdb_command_extend;
2751
	}
2752

2753
	kp->cmd_name   = cmd;
2754
	kp->cmd_func   = func;
2755
	kp->cmd_usage  = usage;
2756
	kp->cmd_help   = help;
2757
	kp->cmd_flags  = 0;
2758
	kp->cmd_minlen = minlen;
2759
	kp->cmd_repeat = repeat;
2760

2761
	return 0;
2762
}
2763
EXPORT_SYMBOL_GPL(kdb_register_repeat);
2764

2765

2766
/*
2767
 * kdb_register - Compatibility register function for commands that do
2768
 *	not need to specify a repeat state.  Equivalent to
2769
 *	kdb_register_repeat with KDB_REPEAT_NONE.
2770
 * Inputs:
2771
 *	cmd	Command name
2772
 *	func	Function to execute the command
2773
 *	usage	A simple usage string showing arguments
2774
 *	help	A simple help string describing command
2775
 * Returns:
2776
 *	zero for success, one if a duplicate command.
2777
 */
2778
int kdb_register(char *cmd,
2779
	     kdb_func_t func,
2780
	     char *usage,
2781
	     char *help,
2782
	     short minlen)
2783
{
2784
	return kdb_register_repeat(cmd, func, usage, help, minlen,
2785
				   KDB_REPEAT_NONE);
2786
}
2787
EXPORT_SYMBOL_GPL(kdb_register);
2788

2789
/*
2790
 * kdb_unregister - This function is used to unregister a kernel
2791
 *	debugger command.  It is generally called when a module which
2792
 *	implements kdb commands is unloaded.
2793
 * Inputs:
2794
 *	cmd	Command name
2795
 * Returns:
2796
 *	zero for success, one command not registered.
2797
 */
2798
int kdb_unregister(char *cmd)
2799
{
2800
	int i;
2801
	kdbtab_t *kp;
2802

2803
	/*
2804
	 *  find the command.
2805
	 */
2806
	for_each_kdbcmd(kp, i) {
2807
		if (kp->cmd_name && (strcmp(kp->cmd_name, cmd) == 0)) {
2808
			kp->cmd_name = NULL;
2809
			return 0;
2810
		}
2811
	}
2812

2813
	/* Couldn't find it.  */
2814
	return 1;
2815
}
2816
EXPORT_SYMBOL_GPL(kdb_unregister);
2817

2818
/* Initialize the kdb command table. */
2819
static void __init kdb_inittab(void)
2820
{
2821
	int i;
2822
	kdbtab_t *kp;
2823

2824
	for_each_kdbcmd(kp, i)
2825
		kp->cmd_name = NULL;
2826

2827
	kdb_register_repeat("md", kdb_md, "<vaddr>",
2828
	  "Display Memory Contents, also mdWcN, e.g. md8c1", 1,
2829
			    KDB_REPEAT_NO_ARGS);
2830
	kdb_register_repeat("mdr", kdb_md, "<vaddr> <bytes>",
2831
	  "Display Raw Memory", 0, KDB_REPEAT_NO_ARGS);
2832
	kdb_register_repeat("mdp", kdb_md, "<paddr> <bytes>",
2833
	  "Display Physical Memory", 0, KDB_REPEAT_NO_ARGS);
2834
	kdb_register_repeat("mds", kdb_md, "<vaddr>",
2835
	  "Display Memory Symbolically", 0, KDB_REPEAT_NO_ARGS);
2836
	kdb_register_repeat("mm", kdb_mm, "<vaddr> <contents>",
2837
	  "Modify Memory Contents", 0, KDB_REPEAT_NO_ARGS);
2838
	kdb_register_repeat("go", kdb_go, "[<vaddr>]",
2839
	  "Continue Execution", 1, KDB_REPEAT_NONE);
2840
	kdb_register_repeat("rd", kdb_rd, "",
2841
	  "Display Registers", 0, KDB_REPEAT_NONE);
2842
	kdb_register_repeat("rm", kdb_rm, "<reg> <contents>",
2843
	  "Modify Registers", 0, KDB_REPEAT_NONE);
2844
	kdb_register_repeat("ef", kdb_ef, "<vaddr>",
2845
	  "Display exception frame", 0, KDB_REPEAT_NONE);
2846
	kdb_register_repeat("bt", kdb_bt, "[<vaddr>]",
2847
	  "Stack traceback", 1, KDB_REPEAT_NONE);
2848
	kdb_register_repeat("btp", kdb_bt, "<pid>",
2849
	  "Display stack for process <pid>", 0, KDB_REPEAT_NONE);
2850
	kdb_register_repeat("bta", kdb_bt, "[DRSTCZEUIMA]",
2851
	  "Display stack all processes", 0, KDB_REPEAT_NONE);
2852
	kdb_register_repeat("btc", kdb_bt, "",
2853
	  "Backtrace current process on each cpu", 0, KDB_REPEAT_NONE);
2854
	kdb_register_repeat("btt", kdb_bt, "<vaddr>",
2855
	  "Backtrace process given its struct task address", 0,
2856
			    KDB_REPEAT_NONE);
2857
	kdb_register_repeat("ll", kdb_ll, "<first-element> <linkoffset> <cmd>",
2858
	  "Execute cmd for each element in linked list", 0, KDB_REPEAT_NONE);
2859
	kdb_register_repeat("env", kdb_env, "",
2860
	  "Show environment variables", 0, KDB_REPEAT_NONE);
2861
	kdb_register_repeat("set", kdb_set, "",
2862
	  "Set environment variables", 0, KDB_REPEAT_NONE);
2863
	kdb_register_repeat("help", kdb_help, "",
2864
	  "Display Help Message", 1, KDB_REPEAT_NONE);
2865
	kdb_register_repeat("?", kdb_help, "",
2866
	  "Display Help Message", 0, KDB_REPEAT_NONE);
2867
	kdb_register_repeat("cpu", kdb_cpu, "<cpunum>",
2868
	  "Switch to new cpu", 0, KDB_REPEAT_NONE);
2869
	kdb_register_repeat("kgdb", kdb_kgdb, "",
2870
	  "Enter kgdb mode", 0, KDB_REPEAT_NONE);
2871
	kdb_register_repeat("ps", kdb_ps, "[<flags>|A]",
2872
	  "Display active task list", 0, KDB_REPEAT_NONE);
2873
	kdb_register_repeat("pid", kdb_pid, "<pidnum>",
2874
	  "Switch to another task", 0, KDB_REPEAT_NONE);
2875
	kdb_register_repeat("reboot", kdb_reboot, "",
2876
	  "Reboot the machine immediately", 0, KDB_REPEAT_NONE);
2877
#if defined(CONFIG_MODULES)
2878
	kdb_register_repeat("lsmod", kdb_lsmod, "",
2879
	  "List loaded kernel modules", 0, KDB_REPEAT_NONE);
2880
#endif
2881
#if defined(CONFIG_MAGIC_SYSRQ)
2882
	kdb_register_repeat("sr", kdb_sr, "<key>",
2883
	  "Magic SysRq key", 0, KDB_REPEAT_NONE);
2884
#endif
2885
#if defined(CONFIG_PRINTK)
2886
	kdb_register_repeat("dmesg", kdb_dmesg, "[lines]",
2887
	  "Display syslog buffer", 0, KDB_REPEAT_NONE);
2888
#endif
2889
	kdb_register_repeat("defcmd", kdb_defcmd, "name \"usage\" \"help\"",
2890
	  "Define a set of commands, down to endefcmd", 0, KDB_REPEAT_NONE);
2891
	kdb_register_repeat("kill", kdb_kill, "<-signal> <pid>",
2892
	  "Send a signal to a process", 0, KDB_REPEAT_NONE);
2893
	kdb_register_repeat("summary", kdb_summary, "",
2894
	  "Summarize the system", 4, KDB_REPEAT_NONE);
2895
	kdb_register_repeat("per_cpu", kdb_per_cpu, "<sym> [<bytes>] [<cpu>]",
2896
	  "Display per_cpu variables", 3, KDB_REPEAT_NONE);
2897
	kdb_register_repeat("grephelp", kdb_grep_help, "",
2898
	  "Display help on | grep", 0, KDB_REPEAT_NONE);
2899
}
2900

2901
/* Execute any commands defined in kdb_cmds.  */
2902
static void __init kdb_cmd_init(void)
2903
{
2904
	int i, diag;
2905
	for (i = 0; kdb_cmds[i]; ++i) {
2906
		diag = kdb_parse(kdb_cmds[i]);
2907
		if (diag)
2908
			kdb_printf("kdb command %s failed, kdb diag %d\n",
2909
				kdb_cmds[i], diag);
2910
	}
2911
	if (defcmd_in_progress) {
2912
		kdb_printf("Incomplete 'defcmd' set, forcing endefcmd\n");
2913
		kdb_parse("endefcmd");
2914
	}
2915
}
2916

2917
/* Initialize kdb_printf, breakpoint tables and kdb state */
2918
void __init kdb_init(int lvl)
2919
{
2920
	static int kdb_init_lvl = KDB_NOT_INITIALIZED;
2921
	int i;
2922

2923
	if (kdb_init_lvl == KDB_INIT_FULL || lvl <= kdb_init_lvl)
2924
		return;
2925
	for (i = kdb_init_lvl; i < lvl; i++) {
2926
		switch (i) {
2927
		case KDB_NOT_INITIALIZED:
2928
			kdb_inittab();		/* Initialize Command Table */
2929
			kdb_initbptab();	/* Initialize Breakpoints */
2930
			break;
2931
		case KDB_INIT_EARLY:
2932
			kdb_cmd_init();		/* Build kdb_cmds tables */
2933
			break;
2934
		}
2935
	}
2936
	kdb_init_lvl = lvl;
2937
}
2938

2939