amd64: Make KPDPphys local to pmap.c

[FreeBSD/FreeBSD.git] / sys / amd64 / amd64 / mp_machdep.c

/*-
 * SPDX-License-Identifier: BSD-2-Clause-FreeBSD
 *
 * Copyright (c) 1996, by Steve Passe
 * Copyright (c) 2003, by Peter Wemm
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. The name of the developer may NOT be used to endorse or promote products
 *    derived from this software without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 * SUCH DAMAGE.
 */

#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");

#include "opt_acpi.h"
#include "opt_cpu.h"
#include "opt_ddb.h"
#include "opt_kstack_pages.h"
#include "opt_sched.h"
#include "opt_smp.h"

#include <sys/param.h>
#include <sys/systm.h>
#include <sys/bus.h>
#include <sys/cpuset.h>
#include <sys/domainset.h>
#ifdef GPROF 
#include <sys/gmon.h>
#endif
#include <sys/kdb.h>
#include <sys/kernel.h>
#include <sys/ktr.h>
#include <sys/lock.h>
#include <sys/malloc.h>
#include <sys/memrange.h>
#include <sys/mutex.h>
#include <sys/pcpu.h>
#include <sys/proc.h>
#include <sys/sched.h>
#include <sys/smp.h>
#include <sys/sysctl.h>

#include <vm/vm.h>
#include <vm/vm_param.h>
#include <vm/pmap.h>
#include <vm/vm_kern.h>
#include <vm/vm_extern.h>
#include <vm/vm_page.h>
#include <vm/vm_phys.h>

#include <x86/apicreg.h>
#include <machine/clock.h>
#include <machine/cputypes.h>
#include <machine/cpufunc.h>
#include <x86/mca.h>
#include <machine/md_var.h>
#include <machine/pcb.h>
#include <machine/psl.h>
#include <machine/smp.h>
#include <machine/specialreg.h>
#include <machine/tss.h>
#include <x86/ucode.h>
#include <machine/cpu.h>
#include <x86/init.h>

#ifdef DEV_ACPI
#include <contrib/dev/acpica/include/acpi.h>
#include <dev/acpica/acpivar.h>
#endif

#define WARMBOOT_TARGET         0
#define WARMBOOT_OFF            (KERNBASE + 0x0467)
#define WARMBOOT_SEG            (KERNBASE + 0x0469)

#define CMOS_REG                (0x70)
#define CMOS_DATA               (0x71)
#define BIOS_RESET              (0x0f)
#define BIOS_WARM               (0x0a)

#define GiB(v)                  (v ## ULL << 30)

#define AP_BOOTPT_SZ            (PAGE_SIZE * 4)

/* Temporary variables for init_secondary()  */
char *doublefault_stack;
char *mce_stack;
char *nmi_stack;
char *dbg_stack;

extern u_int mptramp_la57;

/*
 * Local data and functions.
 */

static int      start_ap(int apic_id);

static bool
is_kernel_paddr(vm_paddr_t pa)
{

        return (pa >= trunc_2mpage(btext - KERNBASE) &&
           pa < round_page(_end - KERNBASE));
}

static bool
is_mpboot_good(vm_paddr_t start, vm_paddr_t end)
{

        return (start + AP_BOOTPT_SZ <= GiB(4) && atop(end) < Maxmem);
}

/*
 * Calculate usable address in base memory for AP trampoline code.
 */
void
mp_bootaddress(vm_paddr_t *physmap, unsigned int *physmap_idx)
{
        vm_paddr_t start, end;
        unsigned int i;
        bool allocated;

        alloc_ap_trampoline(physmap, physmap_idx);

        /*
         * Find a memory region big enough below the 4GB boundary to
         * store the initial page tables.  Region must be mapped by
         * the direct map.
         *
         * Note that it needs to be aligned to a page boundary.
         */
        allocated = false;
        for (i = *physmap_idx; i <= *physmap_idx; i -= 2) {
                /*
                 * First, try to chomp at the start of the physmap region.
                 * Kernel binary might claim it already.
                 */
                start = round_page(physmap[i]);
                end = start + AP_BOOTPT_SZ;
                if (start < end && end <= physmap[i + 1] &&
                    is_mpboot_good(start, end) &&
                    !is_kernel_paddr(start) && !is_kernel_paddr(end - 1)) {
                        allocated = true;
                        physmap[i] = end;
                        break;
                }

                /*
                 * Second, try to chomp at the end.  Again, check
                 * against kernel.
                 */
                end = trunc_page(physmap[i + 1]);
                start = end - AP_BOOTPT_SZ;
                if (start < end && start >= physmap[i] &&
                    is_mpboot_good(start, end) &&
                    !is_kernel_paddr(start) && !is_kernel_paddr(end - 1)) {
                        allocated = true;
                        physmap[i + 1] = start;
                        break;
                }
        }
        if (allocated) {
                mptramp_pagetables = start;
                if (physmap[i] == physmap[i + 1] && *physmap_idx != 0) {
                        memmove(&physmap[i], &physmap[i + 2],
                            sizeof(*physmap) * (*physmap_idx - i + 2));
                        *physmap_idx -= 2;
                }
        } else {
                mptramp_pagetables = trunc_page(boot_address) - AP_BOOTPT_SZ;
                if (bootverbose)
                        printf(
"Cannot find enough space for the initial AP page tables, placing them at %#x",
                            mptramp_pagetables);
        }
}

/*
 * Initialize the IPI handlers and start up the AP's.
 */
void
cpu_mp_start(void)
{
        int i;

        /* Initialize the logical ID to APIC ID table. */
        for (i = 0; i < MAXCPU; i++) {
                cpu_apic_ids[i] = -1;
        }

        /* Install an inter-CPU IPI for cache and TLB invalidations. */
        setidt(IPI_INVLOP, pti ? IDTVEC(invlop_pti) : IDTVEC(invlop),
            SDT_SYSIGT, SEL_KPL, 0);

        /* Install an inter-CPU IPI for all-CPU rendezvous */
        setidt(IPI_RENDEZVOUS, pti ? IDTVEC(rendezvous_pti) :
            IDTVEC(rendezvous), SDT_SYSIGT, SEL_KPL, 0);

        /* Install generic inter-CPU IPI handler */
        setidt(IPI_BITMAP_VECTOR, pti ? IDTVEC(ipi_intr_bitmap_handler_pti) :
            IDTVEC(ipi_intr_bitmap_handler), SDT_SYSIGT, SEL_KPL, 0);

        /* Install an inter-CPU IPI for CPU stop/restart */
        setidt(IPI_STOP, pti ? IDTVEC(cpustop_pti) : IDTVEC(cpustop),
            SDT_SYSIGT, SEL_KPL, 0);

        /* Install an inter-CPU IPI for CPU suspend/resume */
        setidt(IPI_SUSPEND, pti ? IDTVEC(cpususpend_pti) : IDTVEC(cpususpend),
            SDT_SYSIGT, SEL_KPL, 0);

        /* Install an IPI for calling delayed SWI */
        setidt(IPI_SWI, pti ? IDTVEC(ipi_swi_pti) : IDTVEC(ipi_swi),
            SDT_SYSIGT, SEL_KPL, 0);

        /* Set boot_cpu_id if needed. */
        if (boot_cpu_id == -1) {
                boot_cpu_id = PCPU_GET(apic_id);
                cpu_info[boot_cpu_id].cpu_bsp = 1;
        } else
                KASSERT(boot_cpu_id == PCPU_GET(apic_id),
                    ("BSP's APIC ID doesn't match boot_cpu_id"));

        /* Probe logical/physical core configuration. */
        topo_probe();

        assign_cpu_ids();

        mptramp_la57 = la57;

        /* Start each Application Processor */
        init_ops.start_all_aps();

        set_interrupt_apic_ids();

#if defined(DEV_ACPI) && MAXMEMDOM > 1
        acpi_pxm_set_cpu_locality();
#endif
}

/*
 * AP CPU's call this to initialize themselves.
 */
void
init_secondary(void)
{
        struct pcpu *pc;
        struct nmi_pcpu *np;
        struct user_segment_descriptor *gdt;
        struct region_descriptor ap_gdt;
        u_int64_t cr0;
        int cpu, gsel_tss, x;

        /* Set by the startup code for us to use */
        cpu = bootAP;

        /* Update microcode before doing anything else. */
        ucode_load_ap(cpu);

        /* Get per-cpu data and save  */
        pc = &__pcpu[cpu];

        /* prime data page for it to use */
        pcpu_init(pc, cpu, sizeof(struct pcpu));
        dpcpu_init(dpcpu, cpu);
        pc->pc_apic_id = cpu_apic_ids[cpu];
        pc->pc_prvspace = pc;
        pc->pc_curthread = 0;
        pc->pc_tssp = &pc->pc_common_tss;
        pc->pc_rsp0 = 0;
        pc->pc_pti_rsp0 = (((vm_offset_t)&pc->pc_pti_stack +
            PC_PTI_STACK_SZ * sizeof(uint64_t)) & ~0xful);
        gdt = pc->pc_gdt;
        pc->pc_tss = (struct system_segment_descriptor *)&gdt[GPROC0_SEL];
        pc->pc_fs32p = &gdt[GUFS32_SEL];
        pc->pc_gs32p = &gdt[GUGS32_SEL];
        pc->pc_ldt = (struct system_segment_descriptor *)&gdt[GUSERLDT_SEL];
        pc->pc_ucr3_load_mask = PMAP_UCR3_NOMASK;
        /* See comment in pmap_bootstrap(). */
        pc->pc_pcid_next = PMAP_PCID_KERN + 2;
        pc->pc_pcid_gen = 1;

        pc->pc_smp_tlb_gen = 1;

        /* Init tss */
        pc->pc_common_tss = __pcpu[0].pc_common_tss;
        pc->pc_common_tss.tss_iobase = sizeof(struct amd64tss) +
            IOPERM_BITMAP_SIZE;
        pc->pc_common_tss.tss_rsp0 = 0;

        /* The doublefault stack runs on IST1. */
        np = ((struct nmi_pcpu *)&doublefault_stack[DBLFAULT_STACK_SIZE]) - 1;
        np->np_pcpu = (register_t)pc;
        pc->pc_common_tss.tss_ist1 = (long)np;

        /* The NMI stack runs on IST2. */
        np = ((struct nmi_pcpu *)&nmi_stack[NMI_STACK_SIZE]) - 1;
        np->np_pcpu = (register_t)pc;
        pc->pc_common_tss.tss_ist2 = (long)np;

        /* The MC# stack runs on IST3. */
        np = ((struct nmi_pcpu *)&mce_stack[MCE_STACK_SIZE]) - 1;
        np->np_pcpu = (register_t)pc;
        pc->pc_common_tss.tss_ist3 = (long)np;

        /* The DB# stack runs on IST4. */
        np = ((struct nmi_pcpu *)&dbg_stack[DBG_STACK_SIZE]) - 1;
        np->np_pcpu = (register_t)pc;
        pc->pc_common_tss.tss_ist4 = (long)np;

        /* Prepare private GDT */
        gdt_segs[GPROC0_SEL].ssd_base = (long)&pc->pc_common_tss;
        for (x = 0; x < NGDT; x++) {
                if (x != GPROC0_SEL && x != GPROC0_SEL + 1 &&
                    x != GUSERLDT_SEL && x != GUSERLDT_SEL + 1)
                        ssdtosd(&gdt_segs[x], &gdt[x]);
        }
        ssdtosyssd(&gdt_segs[GPROC0_SEL],
            (struct system_segment_descriptor *)&gdt[GPROC0_SEL]);
        ap_gdt.rd_limit = NGDT * sizeof(gdt[0]) - 1;
        ap_gdt.rd_base = (u_long)gdt;
        lgdt(&ap_gdt);                  /* does magic intra-segment return */

        wrmsr(MSR_FSBASE, 0);           /* User value */
        wrmsr(MSR_GSBASE, (u_int64_t)pc);
        wrmsr(MSR_KGSBASE, (u_int64_t)pc);      /* XXX User value while we're in the kernel */
        fix_cpuid();

        lidt(&r_idt);

        gsel_tss = GSEL(GPROC0_SEL, SEL_KPL);
        ltr(gsel_tss);

        /*
         * Set to a known state:
         * Set by mpboot.s: CR0_PG, CR0_PE
         * Set by cpu_setregs: CR0_NE, CR0_MP, CR0_TS, CR0_WP, CR0_AM
         */
        cr0 = rcr0();
        cr0 &= ~(CR0_CD | CR0_NW | CR0_EM);
        load_cr0(cr0);

        amd64_conf_fast_syscall();

        /* signal our startup to the BSP. */
        mp_naps++;

        /* Spin until the BSP releases the AP's. */
        while (atomic_load_acq_int(&aps_ready) == 0)
                ia32_pause();

        init_secondary_tail();
}

/*******************************************************************
 * local functions and data
 */

#ifdef NUMA
static void
mp_realloc_pcpu(int cpuid, int domain)
{
        vm_page_t m;
        vm_offset_t oa, na;

        oa = (vm_offset_t)&__pcpu[cpuid];
        if (vm_phys_domain(pmap_kextract(oa)) == domain)
                return;
        m = vm_page_alloc_domain(NULL, 0, domain,
            VM_ALLOC_NORMAL | VM_ALLOC_NOOBJ);
        if (m == NULL)
                return;
        na = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m));
        pagecopy((void *)oa, (void *)na);
        pmap_qenter((vm_offset_t)&__pcpu[cpuid], &m, 1);
        /* XXX old pcpu page leaked. */
}
#endif

/*
 * start each AP in our list
 */
int
native_start_all_aps(void)
{
        u_int64_t *pt5, *pt4, *pt3, *pt2;
        u_int32_t mpbioswarmvec;
        int apic_id, cpu, domain, i, xo;
        u_char mpbiosreason;

        mtx_init(&ap_boot_mtx, "ap boot", NULL, MTX_SPIN);

        /* copy the AP 1st level boot code */
        bcopy(mptramp_start, (void *)PHYS_TO_DMAP(boot_address), bootMP_size);

        /* Locate the page tables, they'll be below the trampoline */
        if (la57) {
                pt5 = (uint64_t *)PHYS_TO_DMAP(mptramp_pagetables);
                xo = 1;
        } else {
                xo = 0;
        }
        pt4 = (uint64_t *)PHYS_TO_DMAP(mptramp_pagetables + xo * PAGE_SIZE);
        pt3 = pt4 + (PAGE_SIZE) / sizeof(u_int64_t);
        pt2 = pt3 + (PAGE_SIZE) / sizeof(u_int64_t);

        /* Create the initial 1GB replicated page tables */
        for (i = 0; i < 512; i++) {
                if (la57) {
                        pt5[i] = (u_int64_t)(uintptr_t)(mptramp_pagetables +
                            PAGE_SIZE);
                        pt5[i] |= PG_V | PG_RW | PG_U;
                }

                /*
                 * Each slot of the level 4 pages points to the same
                 * level 3 page.
                 */
                pt4[i] = (u_int64_t)(uintptr_t)(mptramp_pagetables +
                    (xo + 1) * PAGE_SIZE);
                pt4[i] |= PG_V | PG_RW | PG_U;

                /*
                 * Each slot of the level 3 pages points to the same
                 * level 2 page.
                 */
                pt3[i] = (u_int64_t)(uintptr_t)(mptramp_pagetables +
                    ((xo + 2) * PAGE_SIZE));
                pt3[i] |= PG_V | PG_RW | PG_U;

                /* The level 2 page slots are mapped with 2MB pages for 1GB. */
                pt2[i] = i * (2 * 1024 * 1024);
                pt2[i] |= PG_V | PG_RW | PG_PS | PG_U;
        }

        /* save the current value of the warm-start vector */
        mpbioswarmvec = *((u_int32_t *) WARMBOOT_OFF);
        outb(CMOS_REG, BIOS_RESET);
        mpbiosreason = inb(CMOS_DATA);

        /* setup a vector to our boot code */
        *((volatile u_short *) WARMBOOT_OFF) = WARMBOOT_TARGET;
        *((volatile u_short *) WARMBOOT_SEG) = (boot_address >> 4);
        outb(CMOS_REG, BIOS_RESET);
        outb(CMOS_DATA, BIOS_WARM);     /* 'warm-start' */

        /* Relocate pcpu areas to the correct domain. */
#ifdef NUMA
        if (vm_ndomains > 1)
                for (cpu = 1; cpu < mp_ncpus; cpu++) {
                        apic_id = cpu_apic_ids[cpu];
                        domain = acpi_pxm_get_cpu_locality(apic_id);
                        mp_realloc_pcpu(cpu, domain);
                }
#endif

        /* start each AP */
        domain = 0;
        for (cpu = 1; cpu < mp_ncpus; cpu++) {
                apic_id = cpu_apic_ids[cpu];
#ifdef NUMA
                if (vm_ndomains > 1)
                        domain = acpi_pxm_get_cpu_locality(apic_id);
#endif
                /* allocate and set up an idle stack data page */
                bootstacks[cpu] = (void *)kmem_malloc(kstack_pages * PAGE_SIZE,
                    M_WAITOK | M_ZERO);
                doublefault_stack = (char *)kmem_malloc(DBLFAULT_STACK_SIZE,
                    M_WAITOK | M_ZERO);
                mce_stack = (char *)kmem_malloc(MCE_STACK_SIZE,
                    M_WAITOK | M_ZERO);
                nmi_stack = (char *)kmem_malloc_domainset(
                    DOMAINSET_PREF(domain), NMI_STACK_SIZE, M_WAITOK | M_ZERO);
                dbg_stack = (char *)kmem_malloc_domainset(
                    DOMAINSET_PREF(domain), DBG_STACK_SIZE, M_WAITOK | M_ZERO);
                dpcpu = (void *)kmem_malloc_domainset(DOMAINSET_PREF(domain),
                    DPCPU_SIZE, M_WAITOK | M_ZERO);

                bootSTK = (char *)bootstacks[cpu] +
                    kstack_pages * PAGE_SIZE - 8;
                bootAP = cpu;

                /* attempt to start the Application Processor */
                if (!start_ap(apic_id)) {
                        /* restore the warmstart vector */
                        *(u_int32_t *) WARMBOOT_OFF = mpbioswarmvec;
                        panic("AP #%d (PHY# %d) failed!", cpu, apic_id);
                }

                CPU_SET(cpu, &all_cpus);        /* record AP in CPU map */
        }

        /* restore the warmstart vector */
        *(u_int32_t *) WARMBOOT_OFF = mpbioswarmvec;

        outb(CMOS_REG, BIOS_RESET);
        outb(CMOS_DATA, mpbiosreason);

        /* number of APs actually started */
        return (mp_naps);
}

/*
 * This function starts the AP (application processor) identified
 * by the APIC ID 'physicalCpu'.  It does quite a "song and dance"
 * to accomplish this.  This is necessary because of the nuances
 * of the different hardware we might encounter.  It isn't pretty,
 * but it seems to work.
 */
static int
start_ap(int apic_id)
{
        int vector, ms;
        int cpus;

        /* calculate the vector */
        vector = (boot_address >> 12) & 0xff;

        /* used as a watchpoint to signal AP startup */
        cpus = mp_naps;

        ipi_startup(apic_id, vector);

        /* Wait up to 5 seconds for it to start. */
        for (ms = 0; ms < 5000; ms++) {
                if (mp_naps > cpus)
                        return 1;       /* return SUCCESS */
                DELAY(1000);
        }
        return 0;               /* return FAILURE */
}

/*
 * Flush the TLB on other CPU's
 */

/*
 * Invalidation request.  PCPU pc_smp_tlb_op uses u_int instead of the
 * enum to avoid both namespace and ABI issues (with enums).
 */
enum invl_op_codes {
      INVL_OP_TLB               = 1,
      INVL_OP_TLB_INVPCID       = 2,
      INVL_OP_TLB_INVPCID_PTI   = 3,
      INVL_OP_TLB_PCID          = 4,
      INVL_OP_PGRNG             = 5,
      INVL_OP_PGRNG_INVPCID     = 6,
      INVL_OP_PGRNG_PCID        = 7,
      INVL_OP_PG                = 8,
      INVL_OP_PG_INVPCID        = 9,
      INVL_OP_PG_PCID           = 10,
      INVL_OP_CACHE             = 11,
};

/*
 * These variables are initialized at startup to reflect how each of
 * the different kinds of invalidations should be performed on the
 * current machine and environment.
 */
static enum invl_op_codes invl_op_tlb;
static enum invl_op_codes invl_op_pgrng;
static enum invl_op_codes invl_op_pg;

/*
 * Scoreboard of IPI completion notifications from target to IPI initiator.
 *
 * Each CPU can initiate shootdown IPI independently from other CPUs.
 * Initiator enters critical section, then fills its local PCPU
 * shootdown info (pc_smp_tlb_ vars), then clears scoreboard generation
 * at location (cpu, my_cpuid) for each target cpu.  After that IPI is
 * sent to all targets which scan for zeroed scoreboard generation
 * words.  Upon finding such word the shootdown data is read from
 * corresponding cpu's pcpu, and generation is set.  Meantime initiator
 * loops waiting for all zeroed generations in scoreboard to update.
 */
static uint32_t *invl_scoreboard;

static void
invl_scoreboard_init(void *arg __unused)
{
        u_int i;

        invl_scoreboard = malloc(sizeof(uint32_t) * (mp_maxid + 1) *
            (mp_maxid + 1), M_DEVBUF, M_WAITOK);
        for (i = 0; i < (mp_maxid + 1) * (mp_maxid + 1); i++)
                invl_scoreboard[i] = 1;

        if (pmap_pcid_enabled) {
                if (invpcid_works) {
                        if (pti)
                                invl_op_tlb = INVL_OP_TLB_INVPCID_PTI;
                        else
                                invl_op_tlb = INVL_OP_TLB_INVPCID;
                        invl_op_pgrng = INVL_OP_PGRNG_INVPCID;
                        invl_op_pg = INVL_OP_PG_INVPCID;
                } else {
                        invl_op_tlb = INVL_OP_TLB_PCID;
                        invl_op_pgrng = INVL_OP_PGRNG_PCID;
                        invl_op_pg = INVL_OP_PG_PCID;
                }
        } else {
                invl_op_tlb = INVL_OP_TLB;
                invl_op_pgrng = INVL_OP_PGRNG;
                invl_op_pg = INVL_OP_PG;
        }
}
SYSINIT(invl_ops, SI_SUB_SMP, SI_ORDER_FIRST, invl_scoreboard_init, NULL);

static uint32_t *
invl_scoreboard_getcpu(u_int cpu)
{
        return (invl_scoreboard + cpu * (mp_maxid + 1));
}

static uint32_t *
invl_scoreboard_slot(u_int cpu)
{
        return (invl_scoreboard_getcpu(cpu) + PCPU_GET(cpuid));
}

/*
 * Used by the pmap to request cache or TLB invalidation on local and
 * remote processors.  Mask provides the set of remote CPUs that are
 * to be signalled with the invalidation IPI.  As an optimization, the
 * curcpu_cb callback is invoked on the calling CPU in a critical
 * section while waiting for the remote CPUs to complete the operation.
 *
 * The callback function is called unconditionally on the caller's
 * underlying processor, even when this processor is not set in the
 * mask.  So, the callback function must be prepared to handle such
 * spurious invocations.
 *
 * Interrupts must be enabled when calling the function with smp
 * started, to avoid deadlock with other IPIs that are protected with
 * smp_ipi_mtx spinlock at the initiator side.
 *
 * Function must be called with the thread pinned, and it unpins on
 * completion.
 */
static void
smp_targeted_tlb_shootdown(cpuset_t mask, pmap_t pmap, vm_offset_t addr1,
    vm_offset_t addr2, smp_invl_cb_t curcpu_cb, enum invl_op_codes op)
{
        cpuset_t other_cpus, mask1;
        uint32_t generation, *p_cpudone;
        int cpu;
        bool is_all;

        /*
         * It is not necessary to signal other CPUs while booting or
         * when in the debugger.
         */
        if (kdb_active || KERNEL_PANICKED() || !smp_started)
                goto local_cb;

        KASSERT(curthread->td_pinned > 0, ("curthread not pinned"));

        /*
         * Check for other cpus.  Return if none.
         */
        is_all = !CPU_CMP(&mask, &all_cpus);
        CPU_CLR(PCPU_GET(cpuid), &mask);
        if (CPU_EMPTY(&mask))
                goto local_cb;

        /*
         * Initiator must have interrupts enabled, which prevents
         * non-invalidation IPIs that take smp_ipi_mtx spinlock,
         * from deadlocking with us.  On the other hand, preemption
         * must be disabled to pin initiator to the instance of the
         * pcpu pc_smp_tlb data and scoreboard line.
         */
        KASSERT((read_rflags() & PSL_I) != 0,
            ("smp_targeted_tlb_shootdown: interrupts disabled"));
        critical_enter();

        PCPU_SET(smp_tlb_addr1, addr1);
        PCPU_SET(smp_tlb_addr2, addr2);
        PCPU_SET(smp_tlb_pmap, pmap);
        generation = PCPU_GET(smp_tlb_gen);
        if (++generation == 0)
                generation = 1;
        PCPU_SET(smp_tlb_gen, generation);
        PCPU_SET(smp_tlb_op, op);
        /* Fence between filling smp_tlb fields and clearing scoreboard. */
        atomic_thread_fence_rel();

        mask1 = mask;
        while ((cpu = CPU_FFS(&mask1)) != 0) {
                cpu--;
                CPU_CLR(cpu, &mask1);
                KASSERT(*invl_scoreboard_slot(cpu) != 0,
                    ("IPI scoreboard is zero, initiator %d target %d",
                    PCPU_GET(cpuid), cpu));
                *invl_scoreboard_slot(cpu) = 0;
        }

        /*
         * IPI acts as a fence between writing to the scoreboard above
         * (zeroing slot) and reading from it below (wait for
         * acknowledgment).
         */
        if (is_all) {
                ipi_all_but_self(IPI_INVLOP);
                other_cpus = all_cpus;
                CPU_CLR(PCPU_GET(cpuid), &other_cpus);
        } else {
                other_cpus = mask;
                ipi_selected(mask, IPI_INVLOP);
        }
        curcpu_cb(pmap, addr1, addr2);
        while ((cpu = CPU_FFS(&other_cpus)) != 0) {
                cpu--;
                CPU_CLR(cpu, &other_cpus);
                p_cpudone = invl_scoreboard_slot(cpu);
                while (atomic_load_int(p_cpudone) != generation)
                        ia32_pause();
        }

        /*
         * Unpin before leaving critical section.  If the thread owes
         * preemption, this allows scheduler to select thread on any
         * CPU from its cpuset.
         */
        sched_unpin();
        critical_exit();

        return;

local_cb:
        critical_enter();
        curcpu_cb(pmap, addr1, addr2);
        sched_unpin();
        critical_exit();
}

void
smp_masked_invltlb(cpuset_t mask, pmap_t pmap, smp_invl_cb_t curcpu_cb)
{
        smp_targeted_tlb_shootdown(mask, pmap, 0, 0, curcpu_cb, invl_op_tlb);
#ifdef COUNT_XINVLTLB_HITS
        ipi_global++;
#endif
}

void
smp_masked_invlpg(cpuset_t mask, vm_offset_t addr, pmap_t pmap,
    smp_invl_cb_t curcpu_cb)
{
        smp_targeted_tlb_shootdown(mask, pmap, addr, 0, curcpu_cb, invl_op_pg);
#ifdef COUNT_XINVLTLB_HITS
        ipi_page++;
#endif
}

void
smp_masked_invlpg_range(cpuset_t mask, vm_offset_t addr1, vm_offset_t addr2,
    pmap_t pmap, smp_invl_cb_t curcpu_cb)
{
        smp_targeted_tlb_shootdown(mask, pmap, addr1, addr2, curcpu_cb,
            invl_op_pgrng);
#ifdef COUNT_XINVLTLB_HITS
        ipi_range++;
        ipi_range_size += (addr2 - addr1) / PAGE_SIZE;
#endif
}

void
smp_cache_flush(smp_invl_cb_t curcpu_cb)
{
        smp_targeted_tlb_shootdown(all_cpus, NULL, 0, 0, curcpu_cb,
            INVL_OP_CACHE);
}

/*
 * Handlers for TLB related IPIs
 */
static void
invltlb_handler(pmap_t smp_tlb_pmap)
{
#ifdef COUNT_XINVLTLB_HITS
        xhits_gbl[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invltlb_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        if (smp_tlb_pmap == kernel_pmap)
                invltlb_glob();
        else
                invltlb();
}

static void
invltlb_invpcid_handler(pmap_t smp_tlb_pmap)
{
        struct invpcid_descr d;

#ifdef COUNT_XINVLTLB_HITS
        xhits_gbl[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invltlb_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        d.pcid = smp_tlb_pmap->pm_pcids[PCPU_GET(cpuid)].pm_pcid;
        d.pad = 0;
        d.addr = 0;
        invpcid(&d, smp_tlb_pmap == kernel_pmap ? INVPCID_CTXGLOB :
            INVPCID_CTX);
}

static void
invltlb_invpcid_pti_handler(pmap_t smp_tlb_pmap)
{
        struct invpcid_descr d;

#ifdef COUNT_XINVLTLB_HITS
        xhits_gbl[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invltlb_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        d.pcid = smp_tlb_pmap->pm_pcids[PCPU_GET(cpuid)].pm_pcid;
        d.pad = 0;
        d.addr = 0;
        if (smp_tlb_pmap == kernel_pmap) {
                /*
                 * This invalidation actually needs to clear kernel
                 * mappings from the TLB in the current pmap, but
                 * since we were asked for the flush in the kernel
                 * pmap, achieve it by performing global flush.
                 */
                invpcid(&d, INVPCID_CTXGLOB);
        } else {
                invpcid(&d, INVPCID_CTX);
                if (smp_tlb_pmap == PCPU_GET(curpmap))
                        PCPU_SET(ucr3_load_mask, ~CR3_PCID_SAVE);
        }
}

static void
invltlb_pcid_handler(pmap_t smp_tlb_pmap)
{
        uint32_t pcid;
  
#ifdef COUNT_XINVLTLB_HITS
        xhits_gbl[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invltlb_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        if (smp_tlb_pmap == kernel_pmap) {
                invltlb_glob();
        } else {
                /*
                 * The current pmap might not be equal to
                 * smp_tlb_pmap.  The clearing of the pm_gen in
                 * pmap_invalidate_all() takes care of TLB
                 * invalidation when switching to the pmap on this
                 * CPU.
                 */
                if (smp_tlb_pmap == PCPU_GET(curpmap)) {
                        pcid = smp_tlb_pmap->pm_pcids[PCPU_GET(cpuid)].pm_pcid;
                        load_cr3(smp_tlb_pmap->pm_cr3 | pcid);
                        if (smp_tlb_pmap->pm_ucr3 != PMAP_NO_CR3)
                                PCPU_SET(ucr3_load_mask, ~CR3_PCID_SAVE);
                }
        }
}

static void
invlpg_handler(vm_offset_t smp_tlb_addr1)
{
#ifdef COUNT_XINVLTLB_HITS
        xhits_pg[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invlpg_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        invlpg(smp_tlb_addr1);
}

static void
invlpg_invpcid_handler(pmap_t smp_tlb_pmap, vm_offset_t smp_tlb_addr1)
{
        struct invpcid_descr d;

#ifdef COUNT_XINVLTLB_HITS
        xhits_pg[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invlpg_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        invlpg(smp_tlb_addr1);
        if (smp_tlb_pmap == PCPU_GET(curpmap) &&
            smp_tlb_pmap->pm_ucr3 != PMAP_NO_CR3 &&
            PCPU_GET(ucr3_load_mask) == PMAP_UCR3_NOMASK) {
                d.pcid = smp_tlb_pmap->pm_pcids[PCPU_GET(cpuid)].pm_pcid |
                    PMAP_PCID_USER_PT;
                d.pad = 0;
                d.addr = smp_tlb_addr1;
                invpcid(&d, INVPCID_ADDR);
        }
}

static void
invlpg_pcid_handler(pmap_t smp_tlb_pmap, vm_offset_t smp_tlb_addr1)
{
        uint64_t kcr3, ucr3;
        uint32_t pcid;

#ifdef COUNT_XINVLTLB_HITS
        xhits_pg[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invlpg_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        invlpg(smp_tlb_addr1);
        if (smp_tlb_pmap == PCPU_GET(curpmap) &&
            (ucr3 = smp_tlb_pmap->pm_ucr3) != PMAP_NO_CR3 &&
            PCPU_GET(ucr3_load_mask) == PMAP_UCR3_NOMASK) {
                pcid = smp_tlb_pmap->pm_pcids[PCPU_GET(cpuid)].pm_pcid;
                kcr3 = smp_tlb_pmap->pm_cr3 | pcid | CR3_PCID_SAVE;
                ucr3 |= pcid | PMAP_PCID_USER_PT | CR3_PCID_SAVE;
                pmap_pti_pcid_invlpg(ucr3, kcr3, smp_tlb_addr1);
        }
}

static void
invlrng_handler(vm_offset_t smp_tlb_addr1, vm_offset_t smp_tlb_addr2)
{
        vm_offset_t addr, addr2;

#ifdef COUNT_XINVLTLB_HITS
        xhits_rng[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invlrng_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        addr = smp_tlb_addr1;
        addr2 = smp_tlb_addr2;
        do {
                invlpg(addr);
                addr += PAGE_SIZE;
        } while (addr < addr2);
}

static void
invlrng_invpcid_handler(pmap_t smp_tlb_pmap, vm_offset_t smp_tlb_addr1,
    vm_offset_t smp_tlb_addr2)
{
        struct invpcid_descr d;
        vm_offset_t addr, addr2;

#ifdef COUNT_XINVLTLB_HITS
        xhits_rng[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invlrng_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        addr = smp_tlb_addr1;
        addr2 = smp_tlb_addr2;
        do {
                invlpg(addr);
                addr += PAGE_SIZE;
        } while (addr < addr2);
        if (smp_tlb_pmap == PCPU_GET(curpmap) &&
            smp_tlb_pmap->pm_ucr3 != PMAP_NO_CR3 &&
            PCPU_GET(ucr3_load_mask) == PMAP_UCR3_NOMASK) {
                d.pcid = smp_tlb_pmap->pm_pcids[PCPU_GET(cpuid)].pm_pcid |
                    PMAP_PCID_USER_PT;
                d.pad = 0;
                d.addr = smp_tlb_addr1;
                do {
                        invpcid(&d, INVPCID_ADDR);
                        d.addr += PAGE_SIZE;
                } while (d.addr < addr2);
        }
}

static void
invlrng_pcid_handler(pmap_t smp_tlb_pmap, vm_offset_t smp_tlb_addr1,
    vm_offset_t smp_tlb_addr2)
{
        vm_offset_t addr, addr2;
        uint64_t kcr3, ucr3;
        uint32_t pcid;

#ifdef COUNT_XINVLTLB_HITS
        xhits_rng[PCPU_GET(cpuid)]++;
#endif /* COUNT_XINVLTLB_HITS */
#ifdef COUNT_IPIS
        (*ipi_invlrng_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */

        addr = smp_tlb_addr1;
        addr2 = smp_tlb_addr2;
        do {
                invlpg(addr);
                addr += PAGE_SIZE;
        } while (addr < addr2);
        if (smp_tlb_pmap == PCPU_GET(curpmap) &&
            (ucr3 = smp_tlb_pmap->pm_ucr3) != PMAP_NO_CR3 &&
            PCPU_GET(ucr3_load_mask) == PMAP_UCR3_NOMASK) {
                pcid = smp_tlb_pmap->pm_pcids[PCPU_GET(cpuid)].pm_pcid;
                kcr3 = smp_tlb_pmap->pm_cr3 | pcid | CR3_PCID_SAVE;
                ucr3 |= pcid | PMAP_PCID_USER_PT | CR3_PCID_SAVE;
                pmap_pti_pcid_invlrng(ucr3, kcr3, smp_tlb_addr1, addr2);
        }
}

static void
invlcache_handler(void)
{
#ifdef COUNT_IPIS
        (*ipi_invlcache_counts[PCPU_GET(cpuid)])++;
#endif /* COUNT_IPIS */
        wbinvd();
}

static void
invlop_handler_one_req(enum invl_op_codes smp_tlb_op, pmap_t smp_tlb_pmap,
    vm_offset_t smp_tlb_addr1, vm_offset_t smp_tlb_addr2)
{
        switch (smp_tlb_op) {
        case INVL_OP_TLB:
                invltlb_handler(smp_tlb_pmap);
                break;
        case INVL_OP_TLB_INVPCID:
                invltlb_invpcid_handler(smp_tlb_pmap);
                break;
        case INVL_OP_TLB_INVPCID_PTI:
                invltlb_invpcid_pti_handler(smp_tlb_pmap);
                break;
        case INVL_OP_TLB_PCID:
                invltlb_pcid_handler(smp_tlb_pmap);
                break;
        case INVL_OP_PGRNG:
                invlrng_handler(smp_tlb_addr1, smp_tlb_addr2);
                break;
        case INVL_OP_PGRNG_INVPCID:
                invlrng_invpcid_handler(smp_tlb_pmap, smp_tlb_addr1,
                    smp_tlb_addr2);
                break;
        case INVL_OP_PGRNG_PCID:
                invlrng_pcid_handler(smp_tlb_pmap, smp_tlb_addr1,
                    smp_tlb_addr2);
                break;
        case INVL_OP_PG:
                invlpg_handler(smp_tlb_addr1);
                break;
        case INVL_OP_PG_INVPCID:
                invlpg_invpcid_handler(smp_tlb_pmap, smp_tlb_addr1);
                break;
        case INVL_OP_PG_PCID:
                invlpg_pcid_handler(smp_tlb_pmap, smp_tlb_addr1);
                break;
        case INVL_OP_CACHE:
                invlcache_handler();
                break;
        default:
                __assert_unreachable();
                break;
        }
}

void
invlop_handler(void)
{
        struct pcpu *initiator_pc;
        pmap_t smp_tlb_pmap;
        vm_offset_t smp_tlb_addr1, smp_tlb_addr2;
        u_int initiator_cpu_id;
        enum invl_op_codes smp_tlb_op;
        uint32_t *scoreboard, smp_tlb_gen;

        scoreboard = invl_scoreboard_getcpu(PCPU_GET(cpuid));
        for (;;) {
                for (initiator_cpu_id = 0; initiator_cpu_id <= mp_maxid;
                    initiator_cpu_id++) {
                        if (atomic_load_int(&scoreboard[initiator_cpu_id]) == 0)
                                break;
                }
                if (initiator_cpu_id > mp_maxid)
                        break;
                initiator_pc = cpuid_to_pcpu[initiator_cpu_id];

                /*
                 * This acquire fence and its corresponding release
                 * fence in smp_targeted_tlb_shootdown() is between
                 * reading zero scoreboard slot and accessing PCPU of
                 * initiator for pc_smp_tlb values.
                 */
                atomic_thread_fence_acq();
                smp_tlb_pmap = initiator_pc->pc_smp_tlb_pmap;
                smp_tlb_addr1 = initiator_pc->pc_smp_tlb_addr1;
                smp_tlb_addr2 = initiator_pc->pc_smp_tlb_addr2;
                smp_tlb_op = initiator_pc->pc_smp_tlb_op;
                smp_tlb_gen = initiator_pc->pc_smp_tlb_gen;

                /*
                 * Ensure that we do not make our scoreboard
                 * notification visible to the initiator until the
                 * pc_smp_tlb values are read.  The corresponding
                 * fence is implicitly provided by the barrier in the
                 * IPI send operation before the APIC ICR register
                 * write.
                 *
                 * As an optimization, the request is acknowledged
                 * before the actual invalidation is performed.  It is
                 * safe because target CPU cannot return to userspace
                 * before handler finishes. Only NMI can preempt the
                 * handler, but NMI would see the kernel handler frame
                 * and not touch not-invalidated user page table.
                 */
                atomic_thread_fence_acq();
                atomic_store_int(&scoreboard[initiator_cpu_id], smp_tlb_gen);

                invlop_handler_one_req(smp_tlb_op, smp_tlb_pmap, smp_tlb_addr1,
                    smp_tlb_addr2);
        }
}