drivers/timer/apic_timer.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2019 Intel Corporation
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <drivers/timer/system_timer.h>
 #include <sys_clock.h>
 #include <spinlock.h>
 #include <drivers/interrupt_controller/loapic.h>

 BUILD_ASSERT(!IS_ENABLED(CONFIG_SMP), "APIC timer doesn't support SMP");

 /*
  * Overview:
  *
  * This driver enables the local APIC as the Zephyr system timer. It supports
  * both legacy ("tickful") mode as well as TICKLESS_KERNEL. The driver will
  * work with any APIC that has the ARAT "always running APIC timer" feature
  * (CPUID 0x06, EAX bit 2); for the more accurate z_timer_cycle_get_32(),
  * the invariant TSC feature (CPUID 0x80000007: EDX bit 8) is also required.
  * (Ultimately systems with invariant TSCs should use a TSC-based driver,
  * and the TSC-related parts should be stripped from this implementation.)
  *
  * Configuration:
  *
  * CONFIG_APIC_TIMER=y			enables this timer driver.
  * CONFIG_APIC_TIMER_IRQ=<irq>		which IRQ to configure for the timer.
  * CONFIG_APIC_TIMER_IRQ_PRIORITY=<p>	priority for IRQ_CONNECT()
  *
  * CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC=<hz> must contain the frequency seen
  *     by the local APIC timer block (before it gets to the timer divider).
  *
  * CONFIG_APIC_TIMER_TSC=y enables the more accurate TSC-based cycle counter
  *     for z_timer_cycle_get_32(). This also requires the next options be set.
  *
  * CONFIG_APIC_TIMER_TSC_N=<n>
  * CONFIG_APIC_TIMER_TSC_M=<m>
  *     When CONFIG_APIC_TIMER_TSC=y, these are set to indicate the ratio of
  *     the TSC frequency to CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC. This can be
  *     found via CPUID 0x15 (n = EBX, m = EAX) on most CPUs.
  */

 /* These should be merged into include/drivers/interrupt_controller/loapic.h. */

 #define DCR_DIVIDER_MASK	0x0000000F	/* divider bits */
 #define DCR_DIVIDER		0x0000000B	/* divide by 1 */
 #define LVT_MODE_MASK		0x00060000	/* timer mode bits */
 #define LVT_MODE		0x00000000	/* one-shot */

 /*
  * CYCLES_PER_TICK must always be at least '2', otherwise MAX_TICKS
  * will overflow int32_t, which is how 'ticks' are currently represented.
  */

 #define CYCLES_PER_TICK \
 	(CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC / CONFIG_SYS_CLOCK_TICKS_PER_SEC)

 BUILD_ASSERT(CYCLES_PER_TICK >= 2, "APIC timer: bad CYCLES_PER_TICK");

 /* max number of ticks we can load into the timer in one shot */

 #define MAX_TICKS (0xFFFFFFFFU / CYCLES_PER_TICK)

 /*
  * The spinlock protects all access to the local APIC timer registers,
  * as well as 'total_cycles', 'last_announcement', and 'cached_icr'.
  *
  * One important invariant that must be observed: `total_cycles` + `cached_icr`
  * is always an integral multiple of CYCLE_PER_TICK; this is, timer interrupts
  * are only ever scheduled to occur at tick boundaries.
  */

 static struct k_spinlock lock;
 static uint64_t total_cycles;
 static uint32_t cached_icr = CYCLES_PER_TICK;

 #ifdef CONFIG_TICKLESS_KERNEL

 static uint64_t last_announcement;	/* last time we called z_clock_announce() */

 void z_clock_set_timeout(int32_t n, bool idle)
 {
 	ARG_UNUSED(idle);

 	uint32_t ccr;
 	int   full_ticks;	/* number of complete ticks we'll wait */
 	uint32_t full_cycles;	/* full_ticks represented as cycles */
 	uint32_t partial_cycles;	/* number of cycles to first tick boundary */

 	if (n < 1) {
 		full_ticks = 0;
 	} else if ((n == K_TICKS_FOREVER) || (n > MAX_TICKS)) {
 		full_ticks = MAX_TICKS - 1;
 	} else {
 		full_ticks = n - 1;
 	}

 	full_cycles = full_ticks * CYCLES_PER_TICK;

 	/*
 	 * There's a wee race condition here. The timer may expire while
 	 * we're busy reprogramming it; an interrupt will be queued at the
 	 * local APIC and the ISR will be called too early, roughly right
 	 * after we unlock, and not because the count we just programmed has
 	 * counted down. Luckily this situation is easy to detect, which is
 	 * why the ISR actually checks to be sure the CCR is 0 before acting.
 	 */

 	k_spinlock_key_t key = k_spin_lock(&lock);

 	ccr = x86_read_loapic(LOAPIC_TIMER_CCR);
 	total_cycles += (cached_icr - ccr);
 	partial_cycles = CYCLES_PER_TICK - (total_cycles % CYCLES_PER_TICK);
 	cached_icr = full_cycles + partial_cycles;
 	x86_write_loapic(LOAPIC_TIMER_ICR, cached_icr);

 	k_spin_unlock(&lock, key);
 }

 uint32_t z_clock_elapsed(void)
 {
 	uint32_t ccr;
 	uint32_t ticks;

 	k_spinlock_key_t key = k_spin_lock(&lock);
 	ccr = x86_read_loapic(LOAPIC_TIMER_CCR);
 	ticks = total_cycles - last_announcement;
 	ticks += cached_icr - ccr;
 	k_spin_unlock(&lock, key);
 	ticks /= CYCLES_PER_TICK;

 	return ticks;
 }

 static void isr(const void *arg)
 {
 	ARG_UNUSED(arg);

 	uint32_t cycles;
 	int32_t ticks;

 	k_spinlock_key_t key = k_spin_lock(&lock);

 	/*
 	 * If we get here and the CCR isn't zero, then this interrupt is
 	 * stale: it was queued while z_clock_set_timeout() was setting
 	 * a new counter. Just ignore it. See above for more info.
 	 */

 	if (x86_read_loapic(LOAPIC_TIMER_CCR) != 0) {
 		k_spin_unlock(&lock, key);
 		return;
 	}

 	/* Restart the timer as early as possible to minimize drift... */
 	x86_write_loapic(LOAPIC_TIMER_ICR, MAX_TICKS * CYCLES_PER_TICK);

 	cycles = cached_icr;
 	cached_icr = MAX_TICKS * CYCLES_PER_TICK;
 	total_cycles += cycles;
 	ticks = (total_cycles - last_announcement) / CYCLES_PER_TICK;
 	last_announcement = total_cycles;
 	k_spin_unlock(&lock, key);
 	z_clock_announce(ticks);
 }

 #else

 static void isr(const void *arg)
 {
 	ARG_UNUSED(arg);

 	k_spinlock_key_t key = k_spin_lock(&lock);
 	total_cycles += CYCLES_PER_TICK;
 	x86_write_loapic(LOAPIC_TIMER_ICR, cached_icr);
 	k_spin_unlock(&lock, key);

 	z_clock_announce(1);
 }

 uint32_t z_clock_elapsed(void)
 {
 	return 0U;
 }

 #endif /* CONFIG_TICKLESS_KERNEL */

 #ifdef CONFIG_APIC_TIMER_TSC

 uint32_t z_timer_cycle_get_32(void)
 {
 	uint64_t tsc = z_tsc_read();
 	uint32_t cycles;

 	cycles = (tsc * CONFIG_APIC_TIMER_TSC_M) / CONFIG_APIC_TIMER_TSC_N;
 	return cycles;
 }

 #else

 uint32_t z_timer_cycle_get_32(void)
 {
 	uint32_t ret;
 	uint32_t ccr;

 	k_spinlock_key_t key = k_spin_lock(&lock);
 	ccr = x86_read_loapic(LOAPIC_TIMER_CCR);
 	ret = total_cycles + (cached_icr - ccr);
 	k_spin_unlock(&lock, key);

 	return ret;
 }

 #endif

 int z_clock_driver_init(const struct device *device)
 {
 	uint32_t val;

 	ARG_UNUSED(device);

 	val = x86_read_loapic(LOAPIC_TIMER_CONFIG);	/* set divider */
 	val &= ~DCR_DIVIDER_MASK;
 	val |= DCR_DIVIDER;
 	x86_write_loapic(LOAPIC_TIMER_CONFIG, val);

 	val = x86_read_loapic(LOAPIC_TIMER);		/* set timer mode */
 	val &= ~LVT_MODE_MASK;
 	val |= LVT_MODE;
 	x86_write_loapic(LOAPIC_TIMER, val);

 	/* remember, wiring up the interrupt will mess with the LVT, too */

 	IRQ_CONNECT(CONFIG_APIC_TIMER_IRQ,
 		CONFIG_APIC_TIMER_IRQ_PRIORITY,
 		isr, 0, 0);

 	x86_write_loapic(LOAPIC_TIMER_ICR, cached_icr);
 	irq_enable(CONFIG_APIC_TIMER_IRQ);

 	return 0;
 }
	/*
	* Copyright (c) 2019 Intel Corporation
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <drivers/timer/system_timer.h>
	#include <sys_clock.h>
	#include <spinlock.h>
	#include <drivers/interrupt_controller/loapic.h>

	BUILD_ASSERT(!IS_ENABLED(CONFIG_SMP), "APIC timer doesn't support SMP");

	/*
	* Overview:
	*
	* This driver enables the local APIC as the Zephyr system timer. It supports
	* both legacy ("tickful") mode as well as TICKLESS_KERNEL. The driver will
	* work with any APIC that has the ARAT "always running APIC timer" feature
	* (CPUID 0x06, EAX bit 2); for the more accurate z_timer_cycle_get_32(),
	* the invariant TSC feature (CPUID 0x80000007: EDX bit 8) is also required.
	* (Ultimately systems with invariant TSCs should use a TSC-based driver,
	* and the TSC-related parts should be stripped from this implementation.)
	*
	* Configuration:
	*
	* CONFIG_APIC_TIMER=y enables this timer driver.
	* CONFIG_APIC_TIMER_IRQ=<irq> which IRQ to configure for the timer.
	* CONFIG_APIC_TIMER_IRQ_PRIORITY=<p> priority for IRQ_CONNECT()
	*
	* CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC=<hz> must contain the frequency seen
	* by the local APIC timer block (before it gets to the timer divider).
	*
	* CONFIG_APIC_TIMER_TSC=y enables the more accurate TSC-based cycle counter
	* for z_timer_cycle_get_32(). This also requires the next options be set.
	*
	* CONFIG_APIC_TIMER_TSC_N=<n>
	* CONFIG_APIC_TIMER_TSC_M=<m>
	* When CONFIG_APIC_TIMER_TSC=y, these are set to indicate the ratio of
	* the TSC frequency to CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC. This can be
	* found via CPUID 0x15 (n = EBX, m = EAX) on most CPUs.
	*/

	/* These should be merged into include/drivers/interrupt_controller/loapic.h. */

	#define DCR_DIVIDER_MASK 0x0000000F /* divider bits */
	#define DCR_DIVIDER 0x0000000B /* divide by 1 */
	#define LVT_MODE_MASK 0x00060000 /* timer mode bits */
	#define LVT_MODE 0x00000000 /* one-shot */

	/*
	* CYCLES_PER_TICK must always be at least '2', otherwise MAX_TICKS
	* will overflow int32_t, which is how 'ticks' are currently represented.
	*/

	#define CYCLES_PER_TICK \
	(CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC / CONFIG_SYS_CLOCK_TICKS_PER_SEC)

	BUILD_ASSERT(CYCLES_PER_TICK >= 2, "APIC timer: bad CYCLES_PER_TICK");

	/* max number of ticks we can load into the timer in one shot */

	#define MAX_TICKS (0xFFFFFFFFU / CYCLES_PER_TICK)

	/*
	* The spinlock protects all access to the local APIC timer registers,
	* as well as 'total_cycles', 'last_announcement', and 'cached_icr'.
	*
	* One important invariant that must be observed: `total_cycles` + `cached_icr`
	* is always an integral multiple of CYCLE_PER_TICK; this is, timer interrupts
	* are only ever scheduled to occur at tick boundaries.
	*/

	static struct k_spinlock lock;
	static uint64_t total_cycles;
	static uint32_t cached_icr = CYCLES_PER_TICK;

	#ifdef CONFIG_TICKLESS_KERNEL

	static uint64_t last_announcement; /* last time we called z_clock_announce() */

	void z_clock_set_timeout(int32_t n, bool idle)
	{
	ARG_UNUSED(idle);

	uint32_t ccr;
	int full_ticks; /* number of complete ticks we'll wait */
	uint32_t full_cycles; /* full_ticks represented as cycles */
	uint32_t partial_cycles; /* number of cycles to first tick boundary */

	if (n < 1) {
	full_ticks = 0;
	} else if ((n == K_TICKS_FOREVER) \|\| (n > MAX_TICKS)) {
	full_ticks = MAX_TICKS - 1;
	} else {
	full_ticks = n - 1;
	}

	full_cycles = full_ticks * CYCLES_PER_TICK;

	/*
	* There's a wee race condition here. The timer may expire while
	* we're busy reprogramming it; an interrupt will be queued at the
	* local APIC and the ISR will be called too early, roughly right
	* after we unlock, and not because the count we just programmed has
	* counted down. Luckily this situation is easy to detect, which is
	* why the ISR actually checks to be sure the CCR is 0 before acting.
	*/

	k_spinlock_key_t key = k_spin_lock(&lock);

	ccr = x86_read_loapic(LOAPIC_TIMER_CCR);
	total_cycles += (cached_icr - ccr);
	partial_cycles = CYCLES_PER_TICK - (total_cycles % CYCLES_PER_TICK);
	cached_icr = full_cycles + partial_cycles;
	x86_write_loapic(LOAPIC_TIMER_ICR, cached_icr);

	k_spin_unlock(&lock, key);
	}

	uint32_t z_clock_elapsed(void)
	{
	uint32_t ccr;
	uint32_t ticks;

	k_spinlock_key_t key = k_spin_lock(&lock);
	ccr = x86_read_loapic(LOAPIC_TIMER_CCR);
	ticks = total_cycles - last_announcement;
	ticks += cached_icr - ccr;
	k_spin_unlock(&lock, key);
	ticks /= CYCLES_PER_TICK;

	return ticks;
	}

	static void isr(const void *arg)
	{
	ARG_UNUSED(arg);

	uint32_t cycles;
	int32_t ticks;

	k_spinlock_key_t key = k_spin_lock(&lock);

	/*
	* If we get here and the CCR isn't zero, then this interrupt is
	* stale: it was queued while z_clock_set_timeout() was setting
	* a new counter. Just ignore it. See above for more info.
	*/

	if (x86_read_loapic(LOAPIC_TIMER_CCR) != 0) {
	k_spin_unlock(&lock, key);
	return;
	}

	/* Restart the timer as early as possible to minimize drift... */
	x86_write_loapic(LOAPIC_TIMER_ICR, MAX_TICKS * CYCLES_PER_TICK);

	cycles = cached_icr;
	cached_icr = MAX_TICKS * CYCLES_PER_TICK;
	total_cycles += cycles;
	ticks = (total_cycles - last_announcement) / CYCLES_PER_TICK;
	last_announcement = total_cycles;
	k_spin_unlock(&lock, key);
	z_clock_announce(ticks);
	}

	#else

	static void isr(const void *arg)
	{
	ARG_UNUSED(arg);

	k_spinlock_key_t key = k_spin_lock(&lock);
	total_cycles += CYCLES_PER_TICK;
	x86_write_loapic(LOAPIC_TIMER_ICR, cached_icr);
	k_spin_unlock(&lock, key);

	z_clock_announce(1);
	}

	uint32_t z_clock_elapsed(void)
	{
	return 0U;
	}

	#endif /* CONFIG_TICKLESS_KERNEL */

	#ifdef CONFIG_APIC_TIMER_TSC

	uint32_t z_timer_cycle_get_32(void)
	{
	uint64_t tsc = z_tsc_read();
	uint32_t cycles;

	cycles = (tsc * CONFIG_APIC_TIMER_TSC_M) / CONFIG_APIC_TIMER_TSC_N;
	return cycles;
	}

	#else

	uint32_t z_timer_cycle_get_32(void)
	{
	uint32_t ret;
	uint32_t ccr;

	k_spinlock_key_t key = k_spin_lock(&lock);
	ccr = x86_read_loapic(LOAPIC_TIMER_CCR);
	ret = total_cycles + (cached_icr - ccr);
	k_spin_unlock(&lock, key);

	return ret;
	}

	#endif

	int z_clock_driver_init(const struct device *device)
	{
	uint32_t val;

	ARG_UNUSED(device);

	val = x86_read_loapic(LOAPIC_TIMER_CONFIG); /* set divider */
	val &= ~DCR_DIVIDER_MASK;
	val \|= DCR_DIVIDER;
	x86_write_loapic(LOAPIC_TIMER_CONFIG, val);

	val = x86_read_loapic(LOAPIC_TIMER); /* set timer mode */
	val &= ~LVT_MODE_MASK;
	val \|= LVT_MODE;
	x86_write_loapic(LOAPIC_TIMER, val);

	/* remember, wiring up the interrupt will mess with the LVT, too */

	IRQ_CONNECT(CONFIG_APIC_TIMER_IRQ,
	CONFIG_APIC_TIMER_IRQ_PRIORITY,
	isr, 0, 0);

	x86_write_loapic(LOAPIC_TIMER_ICR, cached_icr);
	irq_enable(CONFIG_APIC_TIMER_IRQ);

	return 0;
	}