minix/kernel/arch/i386/apic.c

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/*
* APIC handling routines. APIC is a requirement for SMP
*/
#include "../../kernel.h"
#include <unistd.h>
#include <minix/portio.h>
#include <minix/syslib.h>
#include "../../proc.h"
#include "../..//glo.h"
#include "proto.h"
#include <minix/u64.h>
#include "apic.h"
#include "apic_asm.h"
#include "../../clock.h"
#include "glo.h"
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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#ifdef CONFIG_WATCHDOG
#include "../../watchdog.h"
#endif
#define IA32_APIC_BASE 0x1b
#define IA32_APIC_BASE_ENABLE_BIT 11
/* currently only 2 interrupt priority levels are used */
#define SPL0 0x0
#define SPLHI 0xF
/*
* to make APIC work if SMP is not configured, we need to set the maximal number
* of CPUS to 1, cpuid to return 0 and the current cpu is always BSP
*/
#define CONFIG_MAX_CPUS 1
#define cpu_is_bsp(x) 1
#define lapic_write_icr1(val) lapic_write(LAPIC_ICR1, val)
#define lapic_write_icr2(val) lapic_write(LAPIC_ICR2, val)
#define lapic_read_icr1(x) lapic_read(LAPIC_ICR1)
#define lapic_read_icr2(x) lapic_read(LAPIC_ICR2)
#define VERBOSE_APIC(x) x
PUBLIC int reboot_type;
PUBLIC int ioapic_enabled;
PUBLIC u32_t ioapic_id_mask[8], lapic_id_mask[8];
PUBLIC u32_t lapic_addr_vaddr;
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PUBLIC vir_bytes lapic_addr;
PUBLIC u32_t lapic_eoi_addr;
PUBLIC u32_t lapic_taskpri_addr;
PUBLIC int bsp_lapic_id;
PRIVATE volatile int probe_ticks;
PRIVATE u64_t tsc0, tsc1;
PRIVATE u32_t lapic_tctr0, lapic_tctr1;
u8_t apicid2cpuid[MAX_NR_APICIDS+1];
unsigned apic_imcrp;
unsigned nioapics;
unsigned nbuses;
unsigned nintrs;
unsigned nlints;
/*
* FIXME this should be a cpulocal variable but there are some problems with
* arch specific cpulocals. As this variable is write-once-read-only it is ok to
* have at as an array until we resolve the cpulocals properly
*/
PRIVATE u32_t lapic_bus_freq[CONFIG_MAX_CPUS];
/* the probe period will be roughly 100ms */
#define PROBE_TICKS (system_hz / 10)
PRIVATE u32_t pci_config_intr_data;
PRIVATE u32_t ioapic_extint_assigned = 0;
PRIVATE int lapic_extint_assigned = 0;
PRIVATE int calib_clk_handler(irq_hook_t * hook)
{
u32_t tcrt;
u64_t tsc;
probe_ticks++;
read_tsc_64(&tsc);
tcrt = lapic_read(LAPIC_TIMER_CCR);
if (probe_ticks == 1) {
lapic_tctr0 = tcrt;
tsc0 = tsc;
}
else if (probe_ticks == PROBE_TICKS) {
lapic_tctr1 = tcrt;
tsc1 = tsc;
}
return 1;
}
PUBLIC void apic_calibrate_clocks(void)
{
u32_t lvtt, val, lapic_delta;
u64_t tsc_delta;
u32_t cpu_freq;
irq_hook_t calib_clk;
BOOT_VERBOSE(printf("Calibrating clock\n"));
/*
* Set Initial count register to the highest value so it does not
* underflow during the testing period
* */
val = 0xffffffff;
lapic_write (LAPIC_TIMER_ICR, val);
/* Set Current count register */
val = 0;
lapic_write (LAPIC_TIMER_CCR, val);
lvtt = lapic_read(LAPIC_TIMER_DCR) & ~0x0b;
/* Set Divide configuration register to 1 */
lvtt = APIC_TDCR_1;
lapic_write(LAPIC_TIMER_DCR, lvtt);
/*
* mask the APIC timer interrupt in the LVT Timer Register so that we
* don't get an interrupt upon underflow which we don't know how to
* handle right know. If underflow happens, the system will not continue
* as something is wrong with the clock IRQ 0 and we cannot calibrate
* the clock which mean that we cannot run processes
*/
lvtt = lapic_read (LAPIC_LVTTR);
lvtt |= APIC_LVTT_MASK;
lapic_write (LAPIC_LVTTR, lvtt);
/* set the probe, we use the legacy timer, IRQ 0 */
put_irq_handler(&calib_clk, CLOCK_IRQ, calib_clk_handler);
/* set the PIC timer to get some time */
intr_enable();
init_8253A_timer(system_hz);
/* loop for some time to get a sample */
while(probe_ticks < PROBE_TICKS) {
intr_enable();
}
intr_disable();
stop_8253A_timer();
/* remove the probe */
rm_irq_handler(&calib_clk);
lapic_delta = lapic_tctr0 - lapic_tctr1;
tsc_delta = sub64(tsc1, tsc0);
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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lapic_bus_freq[cpuid] = system_hz * lapic_delta / (PROBE_TICKS - 1);
BOOT_VERBOSE(printf("APIC bus freq %lu MHz\n",
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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lapic_bus_freq[cpuid] / 1000000));
cpu_freq = div64u(tsc_delta, PROBE_TICKS - 1) * system_hz;
BOOT_VERBOSE(printf("CPU %d freq %lu MHz\n", cpuid,
cpu_freq / 1000000));
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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cpu_set_freq(cpuid, cpu_freq);
}
PRIVATE void lapic_set_timer_one_shot(u32_t value)
{
/* sleep in micro seconds */
u32_t lvtt;
u32_t ticks_per_us;
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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u8_t cpu = cpuid;
ticks_per_us = lapic_bus_freq[cpu] / 1000000;
/* calculate divisor and count from value */
lvtt = APIC_TDCR_1;
lapic_write(LAPIC_TIMER_DCR, lvtt);
/* configure timer as one-shot */
lvtt = APIC_TIMER_INT_VECTOR;
lapic_write(LAPIC_LVTTR, lvtt);
lapic_write(LAPIC_TIMER_ICR, value * ticks_per_us);
}
PUBLIC void lapic_set_timer_periodic(unsigned freq)
{
/* sleep in micro seconds */
u32_t lvtt;
u32_t lapic_ticks_per_clock_tick;
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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u8_t cpu = cpuid;
lapic_ticks_per_clock_tick = lapic_bus_freq[cpu] / freq;
lvtt = APIC_TDCR_1;
lapic_write(LAPIC_TIMER_DCR, lvtt);
/* configure timer as periodic */
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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lvtt = APIC_LVTT_TM | APIC_TIMER_INT_VECTOR;
lapic_write(LAPIC_LVTTR, lvtt);
lapic_write(LAPIC_TIMER_ICR, lapic_ticks_per_clock_tick);
}
PUBLIC void lapic_stop_timer(void)
{
u32_t lvtt;
lvtt = lapic_read(LAPIC_LVTTR);
lapic_write(LAPIC_LVTTR, lvtt | APIC_LVTT_MASK);
}
PUBLIC void lapic_microsec_sleep(unsigned count)
{
lapic_set_timer_one_shot(count);
while (lapic_read (LAPIC_TIMER_CCR));
}
PUBLIC u32_t lapic_errstatus (void)
{
lapic_write(LAPIC_ESR, 0);
return lapic_read(LAPIC_ESR);
}
PUBLIC void lapic_disable(void)
{
/* Disable current APIC and close interrupts from PIC */
u32_t val;
if (!lapic_addr)
return;
{
/* leave it enabled if imcr is not set */
val = lapic_read(LAPIC_LINT0);
val &= ~(APIC_ICR_DM_MASK|APIC_ICR_INT_MASK);
val |= APIC_ICR_DM_EXTINT; /* ExtINT at LINT0 */
lapic_write (LAPIC_LINT0, val);
return;
}
val = lapic_read(LAPIC_LINT0) & 0xFFFE58FF;
val |= APIC_ICR_INT_MASK;
lapic_write (LAPIC_LINT0, val);
val = lapic_read(LAPIC_LINT1) & 0xFFFE58FF;
val |= APIC_ICR_INT_MASK;
lapic_write (LAPIC_LINT1, val);
val = lapic_read(LAPIC_SIVR) & 0xFFFFFF00;
val &= ~APIC_ENABLE;
lapic_write(LAPIC_SIVR, val);
}
PRIVATE void lapic_enable_no_lints(void)
{
u32_t val;
val = lapic_read(LAPIC_LINT0);
lapic_extint_assigned = (val & APIC_ICR_DM_MASK) == APIC_ICR_DM_EXTINT;
val &= ~(APIC_ICR_DM_MASK|APIC_ICR_INT_MASK);
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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if (!ioapic_enabled && cpu_is_bsp(cpuid))
val |= (APIC_ICR_DM_EXTINT); /* ExtINT at LINT0 */
else
val |= (APIC_ICR_DM_EXTINT|APIC_ICR_INT_MASK); /* Masked ExtINT at LINT0 */
lapic_write (LAPIC_LINT0, val);
val = lapic_read(LAPIC_LINT1);
val &= ~(APIC_ICR_DM_MASK|APIC_ICR_INT_MASK);
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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if (!ioapic_enabled && cpu_is_bsp(cpuid))
val |= APIC_ICR_DM_NMI;
else
val |= (APIC_ICR_DM_NMI | APIC_ICR_INT_MASK); /* NMI at LINT1 */
lapic_write (LAPIC_LINT1, val);
}
PRIVATE int lapic_enable_in_msr(void)
{
u64_t msr;
u32_t addr;
ia32_msr_read(IA32_APIC_BASE, &msr.hi, &msr.lo);
/*
* FIXME if the location is different (unlikely) then the one we expect,
* update it
*/
addr = (msr.lo >> 12) | ((msr.hi & 0xf) << 20);
if (phys2vir(addr) != (lapic_addr >> 12)) {
if (msr.hi & 0xf) {
printf("ERROR : APIC address needs more then 32 bits\n");
return 0;
}
lapic_addr = phys2vir(msr.lo & ~((1 << 12) - 1));
}
msr.lo |= (1 << IA32_APIC_BASE_ENABLE_BIT);
ia32_msr_write(IA32_APIC_BASE, msr.hi, msr.lo);
return 1;
}
PUBLIC int lapic_enable(void)
{
u32_t val, nlvt;
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
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unsigned cpu = cpuid;
if (!lapic_addr)
return 0;
cpu_has_tsc = _cpufeature(_CPUF_I386_TSC);
if (!cpu_has_tsc) {
printf("CPU lacks timestamp counter, "
"cannot calibrate LAPIC timer\n");
return 0;
}
if (!lapic_enable_in_msr())
return 0;
lapic_eoi_addr = LAPIC_EOI;
/* clear error state register. */
val = lapic_errstatus ();
/* Enable Local APIC and set the spurious vector to 0xff. */
val = lapic_read(LAPIC_SIVR) & 0xFFFFFF00;
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
2010-01-16 21:53:55 +01:00
val |= APIC_ENABLE | APIC_SPURIOUS_INT_VECTOR;
val &= ~APIC_FOCUS_DISABLED;
lapic_write(LAPIC_SIVR, val);
lapic_read(LAPIC_SIVR);
*((u32_t *)lapic_eoi_addr) = 0;
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
2010-01-16 21:53:55 +01:00
cpu = cpuid;
/* Program Logical Destination Register. */
val = lapic_read(LAPIC_LDR) & ~0xFF000000;
val |= (cpu & 0xFF) << 24;
lapic_write(LAPIC_LDR, val);
/* Program Destination Format Register for Flat mode. */
val = lapic_read(LAPIC_DFR) | 0xF0000000;
lapic_write (LAPIC_DFR, val);
if (nlints == 0) {
lapic_enable_no_lints();
}
val = lapic_read (LAPIC_LVTER) & 0xFFFFFF00;
lapic_write (LAPIC_LVTER, val);
nlvt = (lapic_read(LAPIC_VERSION)>>16) & 0xFF;
if(nlvt >= 4) {
val = lapic_read(LAPIC_LVTTMR);
lapic_write(LAPIC_LVTTMR, val | APIC_ICR_INT_MASK);
}
if(nlvt >= 5) {
val = lapic_read(LAPIC_LVTPCR);
lapic_write(LAPIC_LVTPCR, val | APIC_ICR_INT_MASK);
}
/* setup TPR to allow all interrupts. */
val = lapic_read (LAPIC_TPR);
/* accept all interrupts */
lapic_write (LAPIC_TPR, val & ~0xFF);
lapic_read (LAPIC_SIVR);
*((u32_t *)lapic_eoi_addr) = 0;
apic_calibrate_clocks();
BOOT_VERBOSE(printf("APIC timer calibrated\n"));
return 1;
}
PRIVATE void apic_spurios_intr(void)
{
printf("WARNING spurious interrupt\n");
for(;;);
}
PRIVATE struct gate_table_s gate_table_ioapic[] = {
{ apic_hwint00, VECTOR( 0), INTR_PRIVILEGE },
{ apic_hwint01, VECTOR( 1), INTR_PRIVILEGE },
{ apic_hwint02, VECTOR( 2), INTR_PRIVILEGE },
{ apic_hwint03, VECTOR( 3), INTR_PRIVILEGE },
{ apic_hwint04, VECTOR( 4), INTR_PRIVILEGE },
{ apic_hwint05, VECTOR( 5), INTR_PRIVILEGE },
{ apic_hwint06, VECTOR( 6), INTR_PRIVILEGE },
{ apic_hwint07, VECTOR( 7), INTR_PRIVILEGE },
{ apic_hwint08, VECTOR( 8), INTR_PRIVILEGE },
{ apic_hwint09, VECTOR( 9), INTR_PRIVILEGE },
{ apic_hwint10, VECTOR(10), INTR_PRIVILEGE },
{ apic_hwint11, VECTOR(11), INTR_PRIVILEGE },
{ apic_hwint12, VECTOR(12), INTR_PRIVILEGE },
{ apic_hwint13, VECTOR(13), INTR_PRIVILEGE },
{ apic_hwint14, VECTOR(14), INTR_PRIVILEGE },
{ apic_hwint15, VECTOR(15), INTR_PRIVILEGE },
{ apic_spurios_intr, APIC_SPURIOUS_INT_VECTOR, INTR_PRIVILEGE },
{ NULL, 0, 0}
};
PRIVATE struct gate_table_s gate_table_common[] = {
{ ipc_entry, IPC_VECTOR, USER_PRIVILEGE },
{ kernel_call_entry, KERN_CALL_VECTOR, USER_PRIVILEGE },
{ NULL, 0, 0}
};
#ifdef CONFIG_APIC_DEBUG
PRIVATE void lapic_set_dummy_handlers(void)
{
char * handler;
int vect = 32;
handler = &lapic_intr_dummy_handles_start;
handler += vect * LAPIC_INTR_DUMMY_HANDLER_SIZE;
for(; handler < &lapic_intr_dummy_handles_end;
handler += LAPIC_INTR_DUMMY_HANDLER_SIZE) {
int_gate(vect++, (vir_bytes) handler,
PRESENT | INT_GATE_TYPE |
(INTR_PRIVILEGE << DPL_SHIFT));
}
}
#endif
/* Build descriptors for interrupt gates in IDT. */
PUBLIC void apic_idt_init(int reset)
{
/* Set up idt tables for smp mode.
*/
vir_bytes local_timer_intr_handler;
if (reset) {
idt_copy_vectors(gate_table_pic);
idt_copy_vectors(gate_table_common);
return;
}
#ifdef CONFIG_APIC_DEBUG
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
2010-01-16 21:53:55 +01:00
if (cpu_is_bsp(cpuid))
printf("APIC debugging is enabled\n");
lapic_set_dummy_handlers();
#endif
/* Build descriptors for interrupt gates in IDT. */
if (ioapic_enabled)
idt_copy_vectors(gate_table_ioapic);
else
idt_copy_vectors(gate_table_pic);
idt_copy_vectors(gate_table_common);
/* configure the timer interupt handler */
NMI watchdog is an awesome feature for debugging locked up kernels. There is not that much use for it on a single CPU, however, deadlock between kernel and system task can be delected. Or a runaway loop. If a kernel gets locked up the timer interrupts don't occure (as all interrupts are disabled in kernel mode). The only chance is to interrupt the kernel by a non-maskable interrupt. This patch generates NMIs using performance counters. It uses the most widely available performace counters. As the performance counters are highly model-specific this patch is not guaranteed to work on every machine. Unfortunately this is also true for KVM :-/ On the other hand adding this feature for other models is not extremely difficult and the framework makes it hopefully easy enough. Depending on the frequency of the CPU an NMI is generated at most about every 0.5s If the cpu's speed is less then 2Ghz it is generated at most every 1s. In general an NMI is generated much less often as the performance counter counts down only if the cpu is not idle. Therefore the overhead of this feature is fairly minimal even if the load is high. Uppon detecting that the kernel is locked up the kernel dumps the state of the kernel registers and panics. Local APIC must be enabled for the watchdog to work. The code is _always_ compiled in, however, it is only enabled if watchdog=<non-zero> is set in the boot monitor. One corner case is serial console debugging. As dumping a lot of stuff to the serial link may take a lot of time, the watchdog does not detect lockups during this time!!! as it would result in too many false positives. 10 nmi have to be handled before the lockup is detected. This means something between ~5s to 10s. Another corner case is that the watchdog is enabled only after the paging is enabled as it would be pure madness to try to get it right.
2010-01-16 21:53:55 +01:00
if (cpu_is_bsp(cpuid)) {
local_timer_intr_handler = (vir_bytes) lapic_bsp_timer_int_handler;
BOOT_VERBOSE(printf("Initiating BSP timer handler\n"));
} else {
local_timer_intr_handler = (vir_bytes) lapic_ap_timer_int_handler;
BOOT_VERBOSE(printf("Initiating AP timer handler\n"));
}
/* register the timer interrupt handler for this CPU */
int_gate(APIC_TIMER_INT_VECTOR, (vir_bytes) local_timer_intr_handler,
PRESENT | INT_GATE_TYPE | (INTR_PRIVILEGE << DPL_SHIFT));
}
PUBLIC int apic_single_cpu_init(void)
{
if (!cpu_feature_apic_on_chip())
return 0;
lapic_addr = phys2vir(LOCAL_APIC_DEF_ADDR);
ioapic_enabled = 0;
if (!lapic_enable()) {
lapic_addr = 0x0;
return 0;
}
apic_idt_init(0); /* Not a reset ! */
idt_reload();
return 1;
}