208 lines
5.6 KiB
C
208 lines
5.6 KiB
C
/*
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* Copyright (c) 2021 Intel Corporation
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* SPDX-License-Identifier: Apache-2.0
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*/
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#include <zephyr/device.h>
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#include <zephyr/drivers/timer/system_timer.h>
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#include <zephyr/sys_clock.h>
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#include <zephyr/spinlock.h>
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#include <zephyr/drivers/interrupt_controller/loapic.h>
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#include <zephyr/irq.h>
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#define IA32_TSC_DEADLINE_MSR 0x6e0
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#define IA32_TSC_ADJUST_MSR 0x03b
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#define CYC_PER_TICK (CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC \
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/ (uint64_t) CONFIG_SYS_CLOCK_TICKS_PER_SEC)
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struct apic_timer_lvt {
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uint8_t vector : 8;
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uint8_t unused0 : 8;
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uint8_t masked : 1;
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enum { ONE_SHOT, PERIODIC, TSC_DEADLINE } mode: 2;
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uint32_t unused2 : 13;
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};
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static struct k_spinlock lock;
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static uint64_t last_announce;
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static union { uint32_t val; struct apic_timer_lvt lvt; } lvt_reg;
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static ALWAYS_INLINE uint64_t rdtsc(void)
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{
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uint32_t hi, lo;
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__asm__ volatile("rdtsc" : "=d"(hi), "=a"(lo));
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return lo + (((uint64_t)hi) << 32);
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}
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static void isr(const void *arg)
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{
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ARG_UNUSED(arg);
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k_spinlock_key_t key = k_spin_lock(&lock);
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uint32_t ticks = (rdtsc() - last_announce) / CYC_PER_TICK;
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last_announce += ticks * CYC_PER_TICK;
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k_spin_unlock(&lock, key);
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sys_clock_announce(ticks);
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if (!IS_ENABLED(CONFIG_TICKLESS_KERNEL)) {
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sys_clock_set_timeout(1, false);
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}
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}
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static inline void wrmsr(int32_t msr, uint64_t val)
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{
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uint32_t hi = (uint32_t) (val >> 32);
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uint32_t lo = (uint32_t) val;
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__asm__ volatile("wrmsr" :: "d"(hi), "a"(lo), "c"(msr));
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}
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void sys_clock_set_timeout(int32_t ticks, bool idle)
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{
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ARG_UNUSED(idle);
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uint64_t now = rdtsc();
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k_spinlock_key_t key = k_spin_lock(&lock);
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uint64_t expires = now + MAX(ticks - 1, 0) * CYC_PER_TICK;
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expires = last_announce + (((expires - last_announce + CYC_PER_TICK - 1)
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/ CYC_PER_TICK) * CYC_PER_TICK);
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/* The second condition is to catch the wraparound.
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* Interpreted strictly, the IA SDM description of the
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* TSC_DEADLINE MSR implies that it will trigger an immediate
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* interrupt if we try to set an expiration across the 64 bit
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* rollover. Unfortunately there's no way to test that as on
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* real hardware it requires more than a century of uptime,
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* but this is cheap and safe.
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*/
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if (ticks == K_TICKS_FOREVER || expires < last_announce) {
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expires = UINT64_MAX;
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}
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wrmsr(IA32_TSC_DEADLINE_MSR, expires);
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k_spin_unlock(&lock, key);
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}
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uint32_t sys_clock_elapsed(void)
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{
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k_spinlock_key_t key = k_spin_lock(&lock);
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uint32_t ret = (rdtsc() - last_announce) / CYC_PER_TICK;
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k_spin_unlock(&lock, key);
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return ret;
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}
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uint32_t sys_clock_cycle_get_32(void)
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{
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return (uint32_t) rdtsc();
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}
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uint64_t sys_clock_cycle_get_64(void)
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{
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return rdtsc();
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}
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static inline uint32_t timer_irq(void)
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{
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/* The Zephyr APIC API is... idiosyncratic. The timer is a
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* "local vector table" interrupt. These aren't system IRQs
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* presented to the IO-APIC, they're indices into a register
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* array in the local APIC. By Zephyr convention they come
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* after all the external IO-APIC interrupts, but that number
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* changes depending on device configuration so we have to
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* fetch it at runtime. The timer happens to be the first
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* entry in the table.
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*/
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return z_loapic_irq_base();
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}
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/* The TSC_ADJUST MSR implements a synchronized offset such that
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* multiple CPUs (within a socket, anyway) can synchronize exactly, or
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* implement managed timing spaces for guests in a recoverable way,
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* etc... We set it to zero on all cores for simplicity, because
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* firmware often leaves it in an inconsistent state between cores.
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*/
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static void clear_tsc_adjust(void)
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{
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/* But don't touch it on ACRN, where an hypervisor bug
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* confuses the APIC emulation and deadline interrupts don't
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* arrive.
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*/
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#ifndef CONFIG_BOARD_ACRN
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wrmsr(IA32_TSC_ADJUST_MSR, 0);
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#endif
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}
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void smp_timer_init(void)
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{
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/* Copy the LVT configuration from CPU0, because IRQ_CONNECT()
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* doesn't know how to manage LVT interrupts for anything
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* other than the calling/initial CPU. Same fence needed to
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* prevent later MSR writes from reordering before the APIC
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* configuration write.
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*/
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x86_write_loapic(LOAPIC_TIMER, lvt_reg.val);
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__asm__ volatile("mfence" ::: "memory");
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clear_tsc_adjust();
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irq_enable(timer_irq());
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}
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static inline void cpuid(uint32_t *eax, uint32_t *ebx, uint32_t *ecx, uint32_t *edx)
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{
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__asm__ volatile("cpuid"
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: "=b"(*ebx), "=c"(*ecx), "=d"(*edx)
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: "a"(*eax), "c"(*ecx));
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}
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static int sys_clock_driver_init(const struct device *dev)
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{
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#ifdef CONFIG_ASSERT
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uint32_t eax, ebx, ecx, edx;
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eax = 1; ecx = 0;
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cpuid(&eax, &ebx, &ecx, &edx);
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__ASSERT((ecx & BIT(24)) != 0, "No TSC Deadline support");
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eax = 0x80000007; ecx = 0;
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cpuid(&eax, &ebx, &ecx, &edx);
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__ASSERT((edx & BIT(8)) != 0, "No Invariant TSC support");
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eax = 7; ecx = 0;
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cpuid(&eax, &ebx, &ecx, &edx);
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__ASSERT((ebx & BIT(1)) != 0, "No TSC_ADJUST MSR support");
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#endif
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clear_tsc_adjust();
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/* Timer interrupt number is runtime-fetched, so can't use
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* static IRQ_CONNECT()
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*/
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irq_connect_dynamic(timer_irq(), CONFIG_APIC_TIMER_IRQ_PRIORITY, isr, 0, 0);
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lvt_reg.val = x86_read_loapic(LOAPIC_TIMER);
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lvt_reg.lvt.mode = TSC_DEADLINE;
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lvt_reg.lvt.masked = 0;
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x86_write_loapic(LOAPIC_TIMER, lvt_reg.val);
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/* Per the SDM, the TSC_DEADLINE MSR is not serializing, so
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* this fence is needed to be sure that an upcoming MSR write
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* (i.e. a timeout we're about to set) cannot possibly reorder
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* around the initialization we just did.
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*/
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__asm__ volatile("mfence" ::: "memory");
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last_announce = rdtsc();
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irq_enable(timer_irq());
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if (!IS_ENABLED(CONFIG_TICKLESS_KERNEL)) {
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sys_clock_set_timeout(1, false);
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}
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return 0;
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}
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SYS_INIT(sys_clock_driver_init, PRE_KERNEL_2,
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CONFIG_SYSTEM_CLOCK_INIT_PRIORITY);
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