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linux/drivers/base/power/trace.c
James Hogan d33ac60bea PM: Add sysfs attr for rechecking dev hash from PM trace
If the device which fails to resume is part of a loadable kernel module
it won't be checked at startup against the magic number stored in the
RTC.

Add a read-only sysfs attribute /sys/power/pm_trace_dev_match which
contains a list of newline separated devices (usually just the one)
which currently match the last magic number. This allows the device
which is failing to resume to be found after the modules are loaded
again.

Signed-off-by: James Hogan <james@albanarts.com>
Signed-off-by: Rafael J. Wysocki <rjw@sisk.pl>
2010-10-17 01:57:50 +02:00

266 lines
6.9 KiB
C

/*
* drivers/base/power/trace.c
*
* Copyright (C) 2006 Linus Torvalds
*
* Trace facility for suspend/resume problems, when none of the
* devices may be working.
*/
#include <linux/resume-trace.h>
#include <linux/rtc.h>
#include <asm/rtc.h>
#include "power.h"
/*
* Horrid, horrid, horrid.
*
* It turns out that the _only_ piece of hardware that actually
* keeps its value across a hard boot (and, more importantly, the
* POST init sequence) is literally the realtime clock.
*
* Never mind that an RTC chip has 114 bytes (and often a whole
* other bank of an additional 128 bytes) of nice SRAM that is
* _designed_ to keep data - the POST will clear it. So we literally
* can just use the few bytes of actual time data, which means that
* we're really limited.
*
* It means, for example, that we can't use the seconds at all
* (since the time between the hang and the boot might be more
* than a minute), and we'd better not depend on the low bits of
* the minutes either.
*
* There are the wday fields etc, but I wouldn't guarantee those
* are dependable either. And if the date isn't valid, either the
* hw or POST will do strange things.
*
* So we're left with:
* - year: 0-99
* - month: 0-11
* - day-of-month: 1-28
* - hour: 0-23
* - min: (0-30)*2
*
* Giving us a total range of 0-16128000 (0xf61800), ie less
* than 24 bits of actual data we can save across reboots.
*
* And if your box can't boot in less than three minutes,
* you're screwed.
*
* Now, almost 24 bits of data is pitifully small, so we need
* to be pretty dense if we want to use it for anything nice.
* What we do is that instead of saving off nice readable info,
* we save off _hashes_ of information that we can hopefully
* regenerate after the reboot.
*
* In particular, this means that we might be unlucky, and hit
* a case where we have a hash collision, and we end up not
* being able to tell for certain exactly which case happened.
* But that's hopefully unlikely.
*
* What we do is to take the bits we can fit, and split them
* into three parts (16*997*1009 = 16095568), and use the values
* for:
* - 0-15: user-settable
* - 0-996: file + line number
* - 0-1008: device
*/
#define USERHASH (16)
#define FILEHASH (997)
#define DEVHASH (1009)
#define DEVSEED (7919)
static unsigned int dev_hash_value;
static int set_magic_time(unsigned int user, unsigned int file, unsigned int device)
{
unsigned int n = user + USERHASH*(file + FILEHASH*device);
// June 7th, 2006
static struct rtc_time time = {
.tm_sec = 0,
.tm_min = 0,
.tm_hour = 0,
.tm_mday = 7,
.tm_mon = 5, // June - counting from zero
.tm_year = 106,
.tm_wday = 3,
.tm_yday = 160,
.tm_isdst = 1
};
time.tm_year = (n % 100);
n /= 100;
time.tm_mon = (n % 12);
n /= 12;
time.tm_mday = (n % 28) + 1;
n /= 28;
time.tm_hour = (n % 24);
n /= 24;
time.tm_min = (n % 20) * 3;
n /= 20;
set_rtc_time(&time);
return n ? -1 : 0;
}
static unsigned int read_magic_time(void)
{
struct rtc_time time;
unsigned int val;
get_rtc_time(&time);
printk("Time: %2d:%02d:%02d Date: %02d/%02d/%02d\n",
time.tm_hour, time.tm_min, time.tm_sec,
time.tm_mon + 1, time.tm_mday, time.tm_year % 100);
val = time.tm_year; /* 100 years */
if (val > 100)
val -= 100;
val += time.tm_mon * 100; /* 12 months */
val += (time.tm_mday-1) * 100 * 12; /* 28 month-days */
val += time.tm_hour * 100 * 12 * 28; /* 24 hours */
val += (time.tm_min / 3) * 100 * 12 * 28 * 24; /* 20 3-minute intervals */
return val;
}
/*
* This is just the sdbm hash function with a user-supplied
* seed and final size parameter.
*/
static unsigned int hash_string(unsigned int seed, const char *data, unsigned int mod)
{
unsigned char c;
while ((c = *data++) != 0) {
seed = (seed << 16) + (seed << 6) - seed + c;
}
return seed % mod;
}
void set_trace_device(struct device *dev)
{
dev_hash_value = hash_string(DEVSEED, dev_name(dev), DEVHASH);
}
EXPORT_SYMBOL(set_trace_device);
/*
* We could just take the "tracedata" index into the .tracedata
* section instead. Generating a hash of the data gives us a
* chance to work across kernel versions, and perhaps more
* importantly it also gives us valid/invalid check (ie we will
* likely not give totally bogus reports - if the hash matches,
* it's not any guarantee, but it's a high _likelihood_ that
* the match is valid).
*/
void generate_resume_trace(const void *tracedata, unsigned int user)
{
unsigned short lineno = *(unsigned short *)tracedata;
const char *file = *(const char **)(tracedata + 2);
unsigned int user_hash_value, file_hash_value;
user_hash_value = user % USERHASH;
file_hash_value = hash_string(lineno, file, FILEHASH);
set_magic_time(user_hash_value, file_hash_value, dev_hash_value);
}
EXPORT_SYMBOL(generate_resume_trace);
extern char __tracedata_start, __tracedata_end;
static int show_file_hash(unsigned int value)
{
int match;
char *tracedata;
match = 0;
for (tracedata = &__tracedata_start ; tracedata < &__tracedata_end ;
tracedata += 2 + sizeof(unsigned long)) {
unsigned short lineno = *(unsigned short *)tracedata;
const char *file = *(const char **)(tracedata + 2);
unsigned int hash = hash_string(lineno, file, FILEHASH);
if (hash != value)
continue;
printk(" hash matches %s:%u\n", file, lineno);
match++;
}
return match;
}
static int show_dev_hash(unsigned int value)
{
int match = 0;
struct list_head *entry;
device_pm_lock();
entry = dpm_list.prev;
while (entry != &dpm_list) {
struct device * dev = to_device(entry);
unsigned int hash = hash_string(DEVSEED, dev_name(dev), DEVHASH);
if (hash == value) {
dev_info(dev, "hash matches\n");
match++;
}
entry = entry->prev;
}
device_pm_unlock();
return match;
}
static unsigned int hash_value_early_read;
int show_trace_dev_match(char *buf, size_t size)
{
unsigned int value = hash_value_early_read / (USERHASH * FILEHASH);
int ret = 0;
struct list_head *entry;
/*
* It's possible that multiple devices will match the hash and we can't
* tell which is the culprit, so it's best to output them all.
*/
device_pm_lock();
entry = dpm_list.prev;
while (size && entry != &dpm_list) {
struct device *dev = to_device(entry);
unsigned int hash = hash_string(DEVSEED, dev_name(dev),
DEVHASH);
if (hash == value) {
int len = snprintf(buf, size, "%s\n",
dev_driver_string(dev));
if (len > size)
len = size;
buf += len;
ret += len;
size -= len;
}
entry = entry->prev;
}
device_pm_unlock();
return ret;
}
static int early_resume_init(void)
{
hash_value_early_read = read_magic_time();
return 0;
}
static int late_resume_init(void)
{
unsigned int val = hash_value_early_read;
unsigned int user, file, dev;
user = val % USERHASH;
val = val / USERHASH;
file = val % FILEHASH;
val = val / FILEHASH;
dev = val /* % DEVHASH */;
printk(" Magic number: %d:%d:%d\n", user, file, dev);
show_file_hash(file);
show_dev_hash(dev);
return 0;
}
core_initcall(early_resume_init);
late_initcall(late_resume_init);