linux_dsm_epyc7002/arch/parisc/kernel/time.c

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/*
* linux/arch/parisc/kernel/time.c
*
* Copyright (C) 1991, 1992, 1995 Linus Torvalds
* Modifications for ARM (C) 1994, 1995, 1996,1997 Russell King
* Copyright (C) 1999 SuSE GmbH, (Philipp Rumpf, prumpf@tux.org)
*
* 1994-07-02 Alan Modra
* fixed set_rtc_mmss, fixed time.year for >= 2000, new mktime
* 1998-12-20 Updated NTP code according to technical memorandum Jan '96
* "A Kernel Model for Precision Timekeeping" by Dave Mills
*/
#include <linux/errno.h>
#include <linux/module.h>
#include <linux/rtc.h>
#include <linux/sched.h>
#include <linux/sched_clock.h>
#include <linux/kernel.h>
#include <linux/param.h>
#include <linux/string.h>
#include <linux/mm.h>
#include <linux/interrupt.h>
#include <linux/time.h>
#include <linux/init.h>
#include <linux/smp.h>
#include <linux/profile.h>
#include <linux/clocksource.h>
#include <linux/platform_device.h>
#include <linux/ftrace.h>
#include <linux/uaccess.h>
#include <asm/io.h>
#include <asm/irq.h>
#include <asm/page.h>
#include <asm/param.h>
#include <asm/pdc.h>
#include <asm/led.h>
#include <linux/timex.h>
static unsigned long clocktick __read_mostly; /* timer cycles per tick */
/*
* We keep time on PA-RISC Linux by using the Interval Timer which is
* a pair of registers; one is read-only and one is write-only; both
* accessed through CR16. The read-only register is 32 or 64 bits wide,
* and increments by 1 every CPU clock tick. The architecture only
* guarantees us a rate between 0.5 and 2, but all implementations use a
* rate of 1. The write-only register is 32-bits wide. When the lowest
* 32 bits of the read-only register compare equal to the write-only
* register, it raises a maskable external interrupt. Each processor has
* an Interval Timer of its own and they are not synchronised.
*
* We want to generate an interrupt every 1/HZ seconds. So we program
* CR16 to interrupt every @clocktick cycles. The it_value in cpu_data
* is programmed with the intended time of the next tick. We can be
* held off for an arbitrarily long period of time by interrupts being
* disabled, so we may miss one or more ticks.
*/
irqreturn_t __irq_entry timer_interrupt(int irq, void *dev_id)
{
unsigned long now;
unsigned long next_tick;
unsigned long ticks_elapsed = 0;
unsigned int cpu = smp_processor_id();
struct cpuinfo_parisc *cpuinfo = &per_cpu(cpu_data, cpu);
/* gcc can optimize for "read-only" case with a local clocktick */
unsigned long cpt = clocktick;
profile_tick(CPU_PROFILING);
/* Initialize next_tick to the old expected tick time. */
next_tick = cpuinfo->it_value;
/* Calculate how many ticks have elapsed. */
do {
++ticks_elapsed;
next_tick += cpt;
now = mfctl(16);
} while (next_tick - now > cpt);
/* Store (in CR16 cycles) up to when we are accounting right now. */
cpuinfo->it_value = next_tick;
/* Go do system house keeping. */
if (cpu == 0)
xtime_update(ticks_elapsed);
update_process_times(user_mode(get_irq_regs()));
/* Skip clockticks on purpose if we know we would miss those.
parisc: fix "delay!" timer handling Rewrote timer_interrupt() to properly handle the "delayed!" case. If we used floating point math to compute the number of ticks that had elapsed since the last timer interrupt, it could take up to 12K cycles (emperical!) to handle the interrupt. Existing code assumed it would never take more than 8k cycles. We end up programming Interval Timer to a value less than "current" cycle counter. Thus have to wait until Interval Timer "wrapped" and would then get the "delayed!" printk that I moved below. Since we don't really know what the upper limit is, I prefer to read CR16 again after we've programmed it to make sure we won't have to wait for CR16 to wrap. Further, the printk was between reading CR16 (cycle couner) and writing CR16 (the interval timer). This would cause us to continue to set the interval timer to a value that was "behind" the cycle counter. Rinse and repeat. So no printk's between reading CR16 and setting next interval timer. Tested on A500 (550 Mhz PA8600). Signed-off-by: Grant Grundler <grundler@parisc-linux.org> Tested-by: Kyle McMartin <kyle@mcmartin.ca> Signed-off-by: Kyle McMartin <kyle@mcmartin.ca> ---- Kyle, Helge, and other parisc's, Please test on 32-bit before committing. I think I have it right but recognize I might not. TODO: I wanted to use "do_div()" in order to get both remainder and value back with one division op. That should help with the latency alot but can be applied seperately from this patch. thanks, grant
2009-06-01 07:20:23 +07:00
* The new CR16 must be "later" than current CR16 otherwise
* itimer would not fire until CR16 wrapped - e.g 4 seconds
* later on a 1Ghz processor. We'll account for the missed
* ticks on the next timer interrupt.
* We want IT to fire modulo clocktick even if we miss/skip some.
* But those interrupts don't in fact get delivered that regularly.
parisc: fix "delay!" timer handling Rewrote timer_interrupt() to properly handle the "delayed!" case. If we used floating point math to compute the number of ticks that had elapsed since the last timer interrupt, it could take up to 12K cycles (emperical!) to handle the interrupt. Existing code assumed it would never take more than 8k cycles. We end up programming Interval Timer to a value less than "current" cycle counter. Thus have to wait until Interval Timer "wrapped" and would then get the "delayed!" printk that I moved below. Since we don't really know what the upper limit is, I prefer to read CR16 again after we've programmed it to make sure we won't have to wait for CR16 to wrap. Further, the printk was between reading CR16 (cycle couner) and writing CR16 (the interval timer). This would cause us to continue to set the interval timer to a value that was "behind" the cycle counter. Rinse and repeat. So no printk's between reading CR16 and setting next interval timer. Tested on A500 (550 Mhz PA8600). Signed-off-by: Grant Grundler <grundler@parisc-linux.org> Tested-by: Kyle McMartin <kyle@mcmartin.ca> Signed-off-by: Kyle McMartin <kyle@mcmartin.ca> ---- Kyle, Helge, and other parisc's, Please test on 32-bit before committing. I think I have it right but recognize I might not. TODO: I wanted to use "do_div()" in order to get both remainder and value back with one division op. That should help with the latency alot but can be applied seperately from this patch. thanks, grant
2009-06-01 07:20:23 +07:00
*
* "next_tick - now" will always give the difference regardless
* if one or the other wrapped. If "now" is "bigger" we'll end up
* with a very large unsigned number.
*/
while (next_tick - mfctl(16) > cpt)
next_tick += cpt;
parisc: fix "delay!" timer handling Rewrote timer_interrupt() to properly handle the "delayed!" case. If we used floating point math to compute the number of ticks that had elapsed since the last timer interrupt, it could take up to 12K cycles (emperical!) to handle the interrupt. Existing code assumed it would never take more than 8k cycles. We end up programming Interval Timer to a value less than "current" cycle counter. Thus have to wait until Interval Timer "wrapped" and would then get the "delayed!" printk that I moved below. Since we don't really know what the upper limit is, I prefer to read CR16 again after we've programmed it to make sure we won't have to wait for CR16 to wrap. Further, the printk was between reading CR16 (cycle couner) and writing CR16 (the interval timer). This would cause us to continue to set the interval timer to a value that was "behind" the cycle counter. Rinse and repeat. So no printk's between reading CR16 and setting next interval timer. Tested on A500 (550 Mhz PA8600). Signed-off-by: Grant Grundler <grundler@parisc-linux.org> Tested-by: Kyle McMartin <kyle@mcmartin.ca> Signed-off-by: Kyle McMartin <kyle@mcmartin.ca> ---- Kyle, Helge, and other parisc's, Please test on 32-bit before committing. I think I have it right but recognize I might not. TODO: I wanted to use "do_div()" in order to get both remainder and value back with one division op. That should help with the latency alot but can be applied seperately from this patch. thanks, grant
2009-06-01 07:20:23 +07:00
/* Program the IT when to deliver the next interrupt.
* Only bottom 32-bits of next_tick are writable in CR16!
* Timer interrupt will be delivered at least a few hundred cycles
* after the IT fires, so if we are too close (<= 500 cycles) to the
* next cycle, simply skip it.
*/
if (next_tick - mfctl(16) <= 500)
next_tick += cpt;
mtctl(next_tick, 16);
return IRQ_HANDLED;
}
unsigned long profile_pc(struct pt_regs *regs)
{
unsigned long pc = instruction_pointer(regs);
if (regs->gr[0] & PSW_N)
pc -= 4;
#ifdef CONFIG_SMP
if (in_lock_functions(pc))
pc = regs->gr[2];
#endif
return pc;
}
EXPORT_SYMBOL(profile_pc);
/* clock source code */
static u64 notrace read_cr16(struct clocksource *cs)
{
return get_cycles();
}
static struct clocksource clocksource_cr16 = {
.name = "cr16",
.rating = 300,
.read = read_cr16,
.mask = CLOCKSOURCE_MASK(BITS_PER_LONG),
.flags = CLOCK_SOURCE_IS_CONTINUOUS,
};
void __init start_cpu_itimer(void)
{
unsigned int cpu = smp_processor_id();
unsigned long next_tick = mfctl(16) + clocktick;
mtctl(next_tick, 16); /* kick off Interval Timer (CR16) */
per_cpu(cpu_data, cpu).it_value = next_tick;
}
#if IS_ENABLED(CONFIG_RTC_DRV_GENERIC)
static int rtc_generic_get_time(struct device *dev, struct rtc_time *tm)
{
struct pdc_tod tod_data;
memset(tm, 0, sizeof(*tm));
if (pdc_tod_read(&tod_data) < 0)
return -EOPNOTSUPP;
/* we treat tod_sec as unsigned, so this can work until year 2106 */
rtc_time64_to_tm(tod_data.tod_sec, tm);
return rtc_valid_tm(tm);
}
static int rtc_generic_set_time(struct device *dev, struct rtc_time *tm)
{
time64_t secs = rtc_tm_to_time64(tm);
if (pdc_tod_set(secs, 0) < 0)
return -EOPNOTSUPP;
return 0;
}
static const struct rtc_class_ops rtc_generic_ops = {
.read_time = rtc_generic_get_time,
.set_time = rtc_generic_set_time,
};
static int __init rtc_init(void)
{
struct platform_device *pdev;
pdev = platform_device_register_data(NULL, "rtc-generic", -1,
&rtc_generic_ops,
sizeof(rtc_generic_ops));
return PTR_ERR_OR_ZERO(pdev);
}
device_initcall(rtc_init);
#endif
void read_persistent_clock(struct timespec *ts)
{
static struct pdc_tod tod_data;
if (pdc_tod_read(&tod_data) == 0) {
ts->tv_sec = tod_data.tod_sec;
ts->tv_nsec = tod_data.tod_usec * 1000;
} else {
printk(KERN_ERR "Error reading tod clock\n");
ts->tv_sec = 0;
ts->tv_nsec = 0;
}
}
static u64 notrace read_cr16_sched_clock(void)
{
return get_cycles();
}
/*
* timer interrupt and sched_clock() initialization
*/
void __init time_init(void)
{
unsigned long cr16_hz;
clocktick = (100 * PAGE0->mem_10msec) / HZ;
start_cpu_itimer(); /* get CPU 0 started */
cr16_hz = 100 * PAGE0->mem_10msec; /* Hz */
/* register as sched_clock source */
sched_clock_register(read_cr16_sched_clock, BITS_PER_LONG, cr16_hz);
}
static int __init init_cr16_clocksource(void)
{
/*
* The cr16 interval timers are not syncronized across CPUs, so mark
* them unstable and lower rating on SMP systems.
*/
if (num_online_cpus() > 1) {
clocksource_cr16.flags = CLOCK_SOURCE_UNSTABLE;
clocksource_cr16.rating = 0;
}
/* register at clocksource framework */
clocksource_register_hz(&clocksource_cr16,
100 * PAGE0->mem_10msec);
return 0;
}
device_initcall(init_cr16_clocksource);