powerpc: Use pr_devel() in arch/powerpc/mm/gup.c
[linux-2.6] / arch / x86 / mm / kmemcheck / error.c
1 #include <linux/interrupt.h>
2 #include <linux/kdebug.h>
3 #include <linux/kmemcheck.h>
4 #include <linux/kernel.h>
5 #include <linux/types.h>
6 #include <linux/ptrace.h>
7 #include <linux/stacktrace.h>
8 #include <linux/string.h>
9
10 #include "error.h"
11 #include "shadow.h"
12
13 enum kmemcheck_error_type {
14         KMEMCHECK_ERROR_INVALID_ACCESS,
15         KMEMCHECK_ERROR_BUG,
16 };
17
18 #define SHADOW_COPY_SIZE (1 << CONFIG_KMEMCHECK_SHADOW_COPY_SHIFT)
19
20 struct kmemcheck_error {
21         enum kmemcheck_error_type type;
22
23         union {
24                 /* KMEMCHECK_ERROR_INVALID_ACCESS */
25                 struct {
26                         /* Kind of access that caused the error */
27                         enum kmemcheck_shadow state;
28                         /* Address and size of the erroneous read */
29                         unsigned long   address;
30                         unsigned int    size;
31                 };
32         };
33
34         struct pt_regs          regs;
35         struct stack_trace      trace;
36         unsigned long           trace_entries[32];
37
38         /* We compress it to a char. */
39         unsigned char           shadow_copy[SHADOW_COPY_SIZE];
40         unsigned char           memory_copy[SHADOW_COPY_SIZE];
41 };
42
43 /*
44  * Create a ring queue of errors to output. We can't call printk() directly
45  * from the kmemcheck traps, since this may call the console drivers and
46  * result in a recursive fault.
47  */
48 static struct kmemcheck_error error_fifo[CONFIG_KMEMCHECK_QUEUE_SIZE];
49 static unsigned int error_count;
50 static unsigned int error_rd;
51 static unsigned int error_wr;
52 static unsigned int error_missed_count;
53
54 static struct kmemcheck_error *error_next_wr(void)
55 {
56         struct kmemcheck_error *e;
57
58         if (error_count == ARRAY_SIZE(error_fifo)) {
59                 ++error_missed_count;
60                 return NULL;
61         }
62
63         e = &error_fifo[error_wr];
64         if (++error_wr == ARRAY_SIZE(error_fifo))
65                 error_wr = 0;
66         ++error_count;
67         return e;
68 }
69
70 static struct kmemcheck_error *error_next_rd(void)
71 {
72         struct kmemcheck_error *e;
73
74         if (error_count == 0)
75                 return NULL;
76
77         e = &error_fifo[error_rd];
78         if (++error_rd == ARRAY_SIZE(error_fifo))
79                 error_rd = 0;
80         --error_count;
81         return e;
82 }
83
84 void kmemcheck_error_recall(void)
85 {
86         static const char *desc[] = {
87                 [KMEMCHECK_SHADOW_UNALLOCATED]          = "unallocated",
88                 [KMEMCHECK_SHADOW_UNINITIALIZED]        = "uninitialized",
89                 [KMEMCHECK_SHADOW_INITIALIZED]          = "initialized",
90                 [KMEMCHECK_SHADOW_FREED]                = "freed",
91         };
92
93         static const char short_desc[] = {
94                 [KMEMCHECK_SHADOW_UNALLOCATED]          = 'a',
95                 [KMEMCHECK_SHADOW_UNINITIALIZED]        = 'u',
96                 [KMEMCHECK_SHADOW_INITIALIZED]          = 'i',
97                 [KMEMCHECK_SHADOW_FREED]                = 'f',
98         };
99
100         struct kmemcheck_error *e;
101         unsigned int i;
102
103         e = error_next_rd();
104         if (!e)
105                 return;
106
107         switch (e->type) {
108         case KMEMCHECK_ERROR_INVALID_ACCESS:
109                 printk(KERN_ERR  "WARNING: kmemcheck: Caught %d-bit read "
110                         "from %s memory (%p)\n",
111                         8 * e->size, e->state < ARRAY_SIZE(desc) ?
112                                 desc[e->state] : "(invalid shadow state)",
113                         (void *) e->address);
114
115                 printk(KERN_INFO);
116                 for (i = 0; i < SHADOW_COPY_SIZE; ++i)
117                         printk("%02x", e->memory_copy[i]);
118                 printk("\n");
119
120                 printk(KERN_INFO);
121                 for (i = 0; i < SHADOW_COPY_SIZE; ++i) {
122                         if (e->shadow_copy[i] < ARRAY_SIZE(short_desc))
123                                 printk(" %c", short_desc[e->shadow_copy[i]]);
124                         else
125                                 printk(" ?");
126                 }
127                 printk("\n");
128                 printk(KERN_INFO "%*c\n", 2 + 2
129                         * (int) (e->address & (SHADOW_COPY_SIZE - 1)), '^');
130                 break;
131         case KMEMCHECK_ERROR_BUG:
132                 printk(KERN_EMERG "ERROR: kmemcheck: Fatal error\n");
133                 break;
134         }
135
136         __show_regs(&e->regs, 1);
137         print_stack_trace(&e->trace, 0);
138 }
139
140 static void do_wakeup(unsigned long data)
141 {
142         while (error_count > 0)
143                 kmemcheck_error_recall();
144
145         if (error_missed_count > 0) {
146                 printk(KERN_WARNING "kmemcheck: Lost %d error reports because "
147                         "the queue was too small\n", error_missed_count);
148                 error_missed_count = 0;
149         }
150 }
151
152 static DECLARE_TASKLET(kmemcheck_tasklet, &do_wakeup, 0);
153
154 /*
155  * Save the context of an error report.
156  */
157 void kmemcheck_error_save(enum kmemcheck_shadow state,
158         unsigned long address, unsigned int size, struct pt_regs *regs)
159 {
160         static unsigned long prev_ip;
161
162         struct kmemcheck_error *e;
163         void *shadow_copy;
164         void *memory_copy;
165
166         /* Don't report several adjacent errors from the same EIP. */
167         if (regs->ip == prev_ip)
168                 return;
169         prev_ip = regs->ip;
170
171         e = error_next_wr();
172         if (!e)
173                 return;
174
175         e->type = KMEMCHECK_ERROR_INVALID_ACCESS;
176
177         e->state = state;
178         e->address = address;
179         e->size = size;
180
181         /* Save regs */
182         memcpy(&e->regs, regs, sizeof(*regs));
183
184         /* Save stack trace */
185         e->trace.nr_entries = 0;
186         e->trace.entries = e->trace_entries;
187         e->trace.max_entries = ARRAY_SIZE(e->trace_entries);
188         e->trace.skip = 0;
189         save_stack_trace_bp(&e->trace, regs->bp);
190
191         /* Round address down to nearest 16 bytes */
192         shadow_copy = kmemcheck_shadow_lookup(address
193                 & ~(SHADOW_COPY_SIZE - 1));
194         BUG_ON(!shadow_copy);
195
196         memcpy(e->shadow_copy, shadow_copy, SHADOW_COPY_SIZE);
197
198         kmemcheck_show_addr(address);
199         memory_copy = (void *) (address & ~(SHADOW_COPY_SIZE - 1));
200         memcpy(e->memory_copy, memory_copy, SHADOW_COPY_SIZE);
201         kmemcheck_hide_addr(address);
202
203         tasklet_hi_schedule_first(&kmemcheck_tasklet);
204 }
205
206 /*
207  * Save the context of a kmemcheck bug.
208  */
209 void kmemcheck_error_save_bug(struct pt_regs *regs)
210 {
211         struct kmemcheck_error *e;
212
213         e = error_next_wr();
214         if (!e)
215                 return;
216
217         e->type = KMEMCHECK_ERROR_BUG;
218
219         memcpy(&e->regs, regs, sizeof(*regs));
220
221         e->trace.nr_entries = 0;
222         e->trace.entries = e->trace_entries;
223         e->trace.max_entries = ARRAY_SIZE(e->trace_entries);
224         e->trace.skip = 1;
225         save_stack_trace(&e->trace);
226
227         tasklet_hi_schedule_first(&kmemcheck_tasklet);
228 }