android_kernel_xiaomi_sm8350/arch/i386/kernel/timers/timer_tsc.c

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/*
* This code largely moved from arch/i386/kernel/time.c.
* See comments there for proper credits.
*
* 2004-06-25 Jesper Juhl
* moved mark_offset_tsc below cpufreq_delayed_get to avoid gcc 3.4
* failing to inline.
*/
#include <linux/spinlock.h>
#include <linux/init.h>
#include <linux/timex.h>
#include <linux/errno.h>
#include <linux/cpufreq.h>
#include <linux/string.h>
#include <linux/jiffies.h>
#include <asm/timer.h>
#include <asm/io.h>
/* processor.h for distable_tsc flag */
#include <asm/processor.h>
#include "io_ports.h"
#include "mach_timer.h"
#include <asm/hpet.h>
#include <asm/i8253.h>
#ifdef CONFIG_HPET_TIMER
static unsigned long hpet_usec_quotient;
static unsigned long hpet_last;
static struct timer_opts timer_tsc;
#endif
static inline void cpufreq_delayed_get(void);
int tsc_disable __devinitdata = 0;
static int use_tsc;
/* Number of usecs that the last interrupt was delayed */
static int delay_at_last_interrupt;
static unsigned long last_tsc_low; /* lsb 32 bits of Time Stamp Counter */
static unsigned long last_tsc_high; /* msb 32 bits of Time Stamp Counter */
static unsigned long long monotonic_base;
static seqlock_t monotonic_lock = SEQLOCK_UNLOCKED;
/* convert from cycles(64bits) => nanoseconds (64bits)
* basic equation:
* ns = cycles / (freq / ns_per_sec)
* ns = cycles * (ns_per_sec / freq)
* ns = cycles * (10^9 / (cpu_mhz * 10^6))
* ns = cycles * (10^3 / cpu_mhz)
*
* Then we use scaling math (suggested by george@mvista.com) to get:
* ns = cycles * (10^3 * SC / cpu_mhz) / SC
* ns = cycles * cyc2ns_scale / SC
*
* And since SC is a constant power of two, we can convert the div
* into a shift.
* -johnstul@us.ibm.com "math is hard, lets go shopping!"
*/
static unsigned long cyc2ns_scale;
#define CYC2NS_SCALE_FACTOR 10 /* 2^10, carefully chosen */
static inline void set_cyc2ns_scale(unsigned long cpu_mhz)
{
cyc2ns_scale = (1000 << CYC2NS_SCALE_FACTOR)/cpu_mhz;
}
static inline unsigned long long cycles_2_ns(unsigned long long cyc)
{
return (cyc * cyc2ns_scale) >> CYC2NS_SCALE_FACTOR;
}
static int count2; /* counter for mark_offset_tsc() */
/* Cached *multiplier* to convert TSC counts to microseconds.
* (see the equation below).
* Equal to 2^32 * (1 / (clocks per usec) ).
* Initialized in time_init.
*/
static unsigned long fast_gettimeoffset_quotient;
static unsigned long get_offset_tsc(void)
{
register unsigned long eax, edx;
/* Read the Time Stamp Counter */
rdtsc(eax,edx);
/* .. relative to previous jiffy (32 bits is enough) */
eax -= last_tsc_low; /* tsc_low delta */
/*
* Time offset = (tsc_low delta) * fast_gettimeoffset_quotient
* = (tsc_low delta) * (usecs_per_clock)
* = (tsc_low delta) * (usecs_per_jiffy / clocks_per_jiffy)
*
* Using a mull instead of a divl saves up to 31 clock cycles
* in the critical path.
*/
__asm__("mull %2"
:"=a" (eax), "=d" (edx)
:"rm" (fast_gettimeoffset_quotient),
"0" (eax));
/* our adjusted time offset in microseconds */
return delay_at_last_interrupt + edx;
}
static unsigned long long monotonic_clock_tsc(void)
{
unsigned long long last_offset, this_offset, base;
unsigned seq;
/* atomically read monotonic base & last_offset */
do {
seq = read_seqbegin(&monotonic_lock);
last_offset = ((unsigned long long)last_tsc_high<<32)|last_tsc_low;
base = monotonic_base;
} while (read_seqretry(&monotonic_lock, seq));
/* Read the Time Stamp Counter */
rdtscll(this_offset);
/* return the value in ns */
return base + cycles_2_ns(this_offset - last_offset);
}
/*
* Scheduler clock - returns current time in nanosec units.
*/
unsigned long long sched_clock(void)
{
unsigned long long this_offset;
/*
* In the NUMA case we dont use the TSC as they are not
* synchronized across all CPUs.
*/
#ifndef CONFIG_NUMA
if (!use_tsc)
#endif
/* no locking but a rare wrong value is not a big deal */
return jiffies_64 * (1000000000 / HZ);
/* Read the Time Stamp Counter */
rdtscll(this_offset);
/* return the value in ns */
return cycles_2_ns(this_offset);
}
static void delay_tsc(unsigned long loops)
{
unsigned long bclock, now;
rdtscl(bclock);
do
{
rep_nop();
rdtscl(now);
} while ((now-bclock) < loops);
}
#ifdef CONFIG_HPET_TIMER
static void mark_offset_tsc_hpet(void)
{
unsigned long long this_offset, last_offset;
unsigned long offset, temp, hpet_current;
write_seqlock(&monotonic_lock);
last_offset = ((unsigned long long)last_tsc_high<<32)|last_tsc_low;
/*
* It is important that these two operations happen almost at
* the same time. We do the RDTSC stuff first, since it's
* faster. To avoid any inconsistencies, we need interrupts
* disabled locally.
*/
/*
* Interrupts are just disabled locally since the timer irq
* has the SA_INTERRUPT flag set. -arca
*/
/* read Pentium cycle counter */
hpet_current = hpet_readl(HPET_COUNTER);
rdtsc(last_tsc_low, last_tsc_high);
/* lost tick compensation */
offset = hpet_readl(HPET_T0_CMP) - hpet_tick;
if (unlikely(((offset - hpet_last) > hpet_tick) && (hpet_last != 0))) {
int lost_ticks = (offset - hpet_last) / hpet_tick;
jiffies_64 += lost_ticks;
}
hpet_last = hpet_current;
/* update the monotonic base value */
this_offset = ((unsigned long long)last_tsc_high<<32)|last_tsc_low;
monotonic_base += cycles_2_ns(this_offset - last_offset);
write_sequnlock(&monotonic_lock);
/* calculate delay_at_last_interrupt */
/*
* Time offset = (hpet delta) * ( usecs per HPET clock )
* = (hpet delta) * ( usecs per tick / HPET clocks per tick)
* = (hpet delta) * ( hpet_usec_quotient ) / (2^32)
* Where,
* hpet_usec_quotient = (2^32 * usecs per tick)/HPET clocks per tick
*/
delay_at_last_interrupt = hpet_current - offset;
ASM_MUL64_REG(temp, delay_at_last_interrupt,
hpet_usec_quotient, delay_at_last_interrupt);
}
#endif
#ifdef CONFIG_CPU_FREQ
#include <linux/workqueue.h>
static unsigned int cpufreq_delayed_issched = 0;
static unsigned int cpufreq_init = 0;
static struct work_struct cpufreq_delayed_get_work;
static void handle_cpufreq_delayed_get(void *v)
{
unsigned int cpu;
for_each_online_cpu(cpu) {
cpufreq_get(cpu);
}
cpufreq_delayed_issched = 0;
}
/* if we notice lost ticks, schedule a call to cpufreq_get() as it tries
* to verify the CPU frequency the timing core thinks the CPU is running
* at is still correct.
*/
static inline void cpufreq_delayed_get(void)
{
if (cpufreq_init && !cpufreq_delayed_issched) {
cpufreq_delayed_issched = 1;
printk(KERN_DEBUG "Losing some ticks... checking if CPU frequency changed.\n");
schedule_work(&cpufreq_delayed_get_work);
}
}
/* If the CPU frequency is scaled, TSC-based delays will need a different
* loops_per_jiffy value to function properly.
*/
static unsigned int ref_freq = 0;
static unsigned long loops_per_jiffy_ref = 0;
#ifndef CONFIG_SMP
static unsigned long fast_gettimeoffset_ref = 0;
static unsigned int cpu_khz_ref = 0;
#endif
static int
time_cpufreq_notifier(struct notifier_block *nb, unsigned long val,
void *data)
{
struct cpufreq_freqs *freq = data;
if (val != CPUFREQ_RESUMECHANGE)
write_seqlock_irq(&xtime_lock);
if (!ref_freq) {
ref_freq = freq->old;
loops_per_jiffy_ref = cpu_data[freq->cpu].loops_per_jiffy;
#ifndef CONFIG_SMP
fast_gettimeoffset_ref = fast_gettimeoffset_quotient;
cpu_khz_ref = cpu_khz;
#endif
}
if ((val == CPUFREQ_PRECHANGE && freq->old < freq->new) ||
(val == CPUFREQ_POSTCHANGE && freq->old > freq->new) ||
(val == CPUFREQ_RESUMECHANGE)) {
if (!(freq->flags & CPUFREQ_CONST_LOOPS))
cpu_data[freq->cpu].loops_per_jiffy = cpufreq_scale(loops_per_jiffy_ref, ref_freq, freq->new);
#ifndef CONFIG_SMP
if (cpu_khz)
cpu_khz = cpufreq_scale(cpu_khz_ref, ref_freq, freq->new);
if (use_tsc) {
if (!(freq->flags & CPUFREQ_CONST_LOOPS)) {
fast_gettimeoffset_quotient = cpufreq_scale(fast_gettimeoffset_ref, freq->new, ref_freq);
set_cyc2ns_scale(cpu_khz/1000);
}
}
#endif
}
if (val != CPUFREQ_RESUMECHANGE)
write_sequnlock_irq(&xtime_lock);
return 0;
}
static struct notifier_block time_cpufreq_notifier_block = {
.notifier_call = time_cpufreq_notifier
};
static int __init cpufreq_tsc(void)
{
int ret;
INIT_WORK(&cpufreq_delayed_get_work, handle_cpufreq_delayed_get, NULL);
ret = cpufreq_register_notifier(&time_cpufreq_notifier_block,
CPUFREQ_TRANSITION_NOTIFIER);
if (!ret)
cpufreq_init = 1;
return ret;
}
core_initcall(cpufreq_tsc);
#else /* CONFIG_CPU_FREQ */
static inline void cpufreq_delayed_get(void) { return; }
#endif
int recalibrate_cpu_khz(void)
{
#ifndef CONFIG_SMP
unsigned int cpu_khz_old = cpu_khz;
if (cpu_has_tsc) {
init_cpu_khz();
cpu_data[0].loops_per_jiffy =
cpufreq_scale(cpu_data[0].loops_per_jiffy,
cpu_khz_old,
cpu_khz);
return 0;
} else
return -ENODEV;
#else
return -ENODEV;
#endif
}
EXPORT_SYMBOL(recalibrate_cpu_khz);
static void mark_offset_tsc(void)
{
unsigned long lost,delay;
unsigned long delta = last_tsc_low;
int count;
int countmp;
static int count1 = 0;
unsigned long long this_offset, last_offset;
static int lost_count = 0;
write_seqlock(&monotonic_lock);
last_offset = ((unsigned long long)last_tsc_high<<32)|last_tsc_low;
/*
* It is important that these two operations happen almost at
* the same time. We do the RDTSC stuff first, since it's
* faster. To avoid any inconsistencies, we need interrupts
* disabled locally.
*/
/*
* Interrupts are just disabled locally since the timer irq
* has the SA_INTERRUPT flag set. -arca
*/
/* read Pentium cycle counter */
rdtsc(last_tsc_low, last_tsc_high);
spin_lock(&i8253_lock);
outb_p(0x00, PIT_MODE); /* latch the count ASAP */
count = inb_p(PIT_CH0); /* read the latched count */
count |= inb(PIT_CH0) << 8;
/*
* VIA686a test code... reset the latch if count > max + 1
* from timer_pit.c - cjb
*/
if (count > LATCH) {
outb_p(0x34, PIT_MODE);
outb_p(LATCH & 0xff, PIT_CH0);
outb(LATCH >> 8, PIT_CH0);
count = LATCH - 1;
}
spin_unlock(&i8253_lock);
if (pit_latch_buggy) {
/* get center value of last 3 time lutch */
if ((count2 >= count && count >= count1)
|| (count1 >= count && count >= count2)) {
count2 = count1; count1 = count;
} else if ((count1 >= count2 && count2 >= count)
|| (count >= count2 && count2 >= count1)) {
countmp = count;count = count2;
count2 = count1;count1 = countmp;
} else {
count2 = count1; count1 = count; count = count1;
}
}
/* lost tick compensation */
delta = last_tsc_low - delta;
{
register unsigned long eax, edx;
eax = delta;
__asm__("mull %2"
:"=a" (eax), "=d" (edx)
:"rm" (fast_gettimeoffset_quotient),
"0" (eax));
delta = edx;
}
delta += delay_at_last_interrupt;
lost = delta/(1000000/HZ);
delay = delta%(1000000/HZ);
if (lost >= 2) {
jiffies_64 += lost-1;
/* sanity check to ensure we're not always losing ticks */
if (lost_count++ > 100) {
printk(KERN_WARNING "Losing too many ticks!\n");
printk(KERN_WARNING "TSC cannot be used as a timesource. \n");
printk(KERN_WARNING "Possible reasons for this are:\n");
printk(KERN_WARNING " You're running with Speedstep,\n");
printk(KERN_WARNING " You don't have DMA enabled for your hard disk (see hdparm),\n");
printk(KERN_WARNING " Incorrect TSC synchronization on an SMP system (see dmesg).\n");
printk(KERN_WARNING "Falling back to a sane timesource now.\n");
clock_fallback();
}
/* ... but give the TSC a fair chance */
if (lost_count > 25)
cpufreq_delayed_get();
} else
lost_count = 0;
/* update the monotonic base value */
this_offset = ((unsigned long long)last_tsc_high<<32)|last_tsc_low;
monotonic_base += cycles_2_ns(this_offset - last_offset);
write_sequnlock(&monotonic_lock);
/* calculate delay_at_last_interrupt */
count = ((LATCH-1) - count) * TICK_SIZE;
delay_at_last_interrupt = (count + LATCH/2) / LATCH;
/* catch corner case where tick rollover occured
* between tsc and pit reads (as noted when
* usec delta is > 90% # of usecs/tick)
*/
if (lost && abs(delay - delay_at_last_interrupt) > (900000/HZ))
jiffies_64++;
}
static int __init init_tsc(char* override)
{
/* check clock override */
if (override[0] && strncmp(override,"tsc",3)) {
#ifdef CONFIG_HPET_TIMER
if (is_hpet_enabled()) {
printk(KERN_ERR "Warning: clock= override failed. Defaulting to tsc\n");
} else
#endif
{
return -ENODEV;
}
}
/*
* If we have APM enabled or the CPU clock speed is variable
* (CPU stops clock on HLT or slows clock to save power)
* then the TSC timestamps may diverge by up to 1 jiffy from
* 'real time' but nothing will break.
* The most frequent case is that the CPU is "woken" from a halt
* state by the timer interrupt itself, so we get 0 error. In the
* rare cases where a driver would "wake" the CPU and request a
* timestamp, the maximum error is < 1 jiffy. But timestamps are
* still perfectly ordered.
* Note that the TSC counter will be reset if APM suspends
* to disk; this won't break the kernel, though, 'cuz we're
* smart. See arch/i386/kernel/apm.c.
*/
/*
* Firstly we have to do a CPU check for chips with
* a potentially buggy TSC. At this point we haven't run
* the ident/bugs checks so we must run this hook as it
* may turn off the TSC flag.
*
* NOTE: this doesn't yet handle SMP 486 machines where only
* some CPU's have a TSC. Thats never worked and nobody has
* moaned if you have the only one in the world - you fix it!
*/
count2 = LATCH; /* initialize counter for mark_offset_tsc() */
if (cpu_has_tsc) {
unsigned long tsc_quotient;
#ifdef CONFIG_HPET_TIMER
if (is_hpet_enabled() && hpet_use_timer) {
unsigned long result, remain;
printk("Using TSC for gettimeofday\n");
tsc_quotient = calibrate_tsc_hpet(NULL);
timer_tsc.mark_offset = &mark_offset_tsc_hpet;
/*
* Math to calculate hpet to usec multiplier
* Look for the comments at get_offset_tsc_hpet()
*/
ASM_DIV64_REG(result, remain, hpet_tick,
0, KERNEL_TICK_USEC);
if (remain > (hpet_tick >> 1))
result++; /* rounding the result */
hpet_usec_quotient = result;
} else
#endif
{
tsc_quotient = calibrate_tsc();
}
if (tsc_quotient) {
fast_gettimeoffset_quotient = tsc_quotient;
use_tsc = 1;
/*
* We could be more selective here I suspect
* and just enable this for the next intel chips ?
*/
/* report CPU clock rate in Hz.
* The formula is (10^6 * 2^32) / (2^32 * 1 / (clocks/us)) =
* clock/second. Our precision is about 100 ppm.
*/
{ unsigned long eax=0, edx=1000;
__asm__("divl %2"
:"=a" (cpu_khz), "=d" (edx)
:"r" (tsc_quotient),
"0" (eax), "1" (edx));
printk("Detected %u.%03u MHz processor.\n",
cpu_khz / 1000, cpu_khz % 1000);
}
set_cyc2ns_scale(cpu_khz/1000);
return 0;
}
}
return -ENODEV;
}
static int tsc_resume(void)
{
write_seqlock(&monotonic_lock);
/* Assume this is the last mark offset time */
rdtsc(last_tsc_low, last_tsc_high);
#ifdef CONFIG_HPET_TIMER
if (is_hpet_enabled() && hpet_use_timer)
hpet_last = hpet_readl(HPET_COUNTER);
#endif
write_sequnlock(&monotonic_lock);
return 0;
}
#ifndef CONFIG_X86_TSC
/* disable flag for tsc. Takes effect by clearing the TSC cpu flag
* in cpu/common.c */
static int __init tsc_setup(char *str)
{
tsc_disable = 1;
return 1;
}
#else
static int __init tsc_setup(char *str)
{
printk(KERN_WARNING "notsc: Kernel compiled with CONFIG_X86_TSC, "
"cannot disable TSC.\n");
return 1;
}
#endif
__setup("notsc", tsc_setup);
/************************************************************/
/* tsc timer_opts struct */
static struct timer_opts timer_tsc = {
.name = "tsc",
.mark_offset = mark_offset_tsc,
.get_offset = get_offset_tsc,
.monotonic_clock = monotonic_clock_tsc,
.delay = delay_tsc,
[PATCH] Platform SMIs and their interferance with tsc based delay calibration Issue: Current tsc based delay_calibration can result in significant errors in loops_per_jiffy count when the platform events like SMIs (System Management Interrupts that are non-maskable) are present. This could lead to potential kernel panic(). This issue is becoming more visible with 2.6 kernel (as default HZ is 1000) and on platforms with higher SMI handling latencies. During the boot time, SMIs are mostly used by BIOS (for things like legacy keyboard emulation). Description: The psuedocode for current delay calibration with tsc based delay looks like (0) Estimate a value for loops_per_jiffy (1) While (loops_per_jiffy estimate is accurate enough) (2) wait for jiffy transition (jiffy1) (3) Note down current tsc (tsc1) (4) loop until tsc becomes tsc1 + loops_per_jiffy (5) check whether jiffy changed since jiffy1 or not and refine loops_per_jiffy estimate Consider the following cases Case 1: If SMIs happen between (2) and (3) above, we can end up with a loops_per_jiffy value that is too low. This results in shorted delays and kernel can panic () during boot (Mostly at IOAPIC timer initialization timer_irq_works() as we don't have enough timer interrupts in a specified interval). Case 2: If SMIs happen between (3) and (4) above, then we can end up with a loops_per_jiffy value that is too high. And with current i386 code, too high lpj value (greater than 17M) can result in a overflow in delay.c:__const_udelay() again resulting in shorter delay and panic(). Solution: The patch below makes the calibration routine aware of asynchronous events like SMIs. We increase the delay calibration time and also identify any significant errors (greater than 12.5%) in the calibration and notify it to user. Patch below changes both i386 and x86-64 architectures to use this new and improved calibrate_delay_direct() routine. Signed-off-by: Venkatesh Pallipadi <venkatesh.pallipadi@intel.com> Signed-off-by: Adrian Bunk <bunk@stusta.de> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2005-06-23 03:08:13 -04:00
.read_timer = read_timer_tsc,
.resume = tsc_resume,
};
struct init_timer_opts __initdata timer_tsc_init = {
.init = init_tsc,
.opts = &timer_tsc,
};