uvm/pmap/pmap.c

1.41     skrll /*	$NetBSD: pmap.c,v 1.41 2019/06/19 09:56:17 skrll Exp $	*/
 1.1  christos
 1.1  christos /*-
 1.1  christos  * Copyright (c) 1998, 2001 The NetBSD Foundation, Inc.
 1.1  christos  * All rights reserved.
 1.1  christos  *
 1.1  christos  * This code is derived from software contributed to The NetBSD Foundation
 1.1  christos  * by Jason R. Thorpe of the Numerical Aerospace Simulation Facility,
 1.1  christos  * NASA Ames Research Center and by Chris G. Demetriou.
 1.1  christos  *
 1.1  christos  * Redistribution and use in source and binary forms, with or without
 1.1  christos  * modification, are permitted provided that the following conditions
 1.1  christos  * are met:
 1.1  christos  * 1. Redistributions of source code must retain the above copyright
 1.1  christos  *    notice, this list of conditions and the following disclaimer.
 1.1  christos  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  christos  *    notice, this list of conditions and the following disclaimer in the
 1.1  christos  *    documentation and/or other materials provided with the distribution.
 1.1  christos  *
 1.1  christos  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.1  christos  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.1  christos  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.1  christos  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.1  christos  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1  christos  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1  christos  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1  christos  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1  christos  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1  christos  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1  christos  * POSSIBILITY OF SUCH DAMAGE.
 1.1  christos  */
 1.1  christos
 1.1  christos /*
 1.1  christos  * Copyright (c) 1992, 1993
 1.1  christos  *	The Regents of the University of California.  All rights reserved.
 1.1  christos  *
 1.1  christos  * This code is derived from software contributed to Berkeley by
 1.1  christos  * the Systems Programming Group of the University of Utah Computer
 1.1  christos  * Science Department and Ralph Campbell.
 1.1  christos  *
 1.1  christos  * Redistribution and use in source and binary forms, with or without
 1.1  christos  * modification, are permitted provided that the following conditions
 1.1  christos  * are met:
 1.1  christos  * 1. Redistributions of source code must retain the above copyright
 1.1  christos  *    notice, this list of conditions and the following disclaimer.
 1.1  christos  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  christos  *    notice, this list of conditions and the following disclaimer in the
 1.1  christos  *    documentation and/or other materials provided with the distribution.
 1.1  christos  * 3. Neither the name of the University nor the names of its contributors
 1.1  christos  *    may be used to endorse or promote products derived from this software
 1.1  christos  *    without specific prior written permission.
 1.1  christos  *
 1.1  christos  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
 1.1  christos  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 1.1  christos  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 1.1  christos  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
 1.1  christos  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 1.1  christos  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 1.1  christos  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 1.1  christos  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 1.1  christos  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1  christos  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1  christos  * SUCH DAMAGE.
 1.1  christos  *
 1.1  christos  *	@(#)pmap.c	8.4 (Berkeley) 1/26/94
 1.1  christos  */
 1.1  christos
 1.1  christos #include <sys/cdefs.h>
 1.1  christos
1.41     skrll __KERNEL_RCSID(0, "$NetBSD: pmap.c,v 1.41 2019/06/19 09:56:17 skrll Exp $");
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Manages physical address maps.
 1.1  christos  *
 1.1  christos  *	In addition to hardware address maps, this
 1.1  christos  *	module is called upon to provide software-use-only
 1.1  christos  *	maps which may or may not be stored in the same
 1.1  christos  *	form as hardware maps.  These pseudo-maps are
 1.1  christos  *	used to store intermediate results from copy
 1.1  christos  *	operations to and from address spaces.
 1.1  christos  *
 1.1  christos  *	Since the information managed by this module is
 1.1  christos  *	also stored by the logical address mapping module,
 1.1  christos  *	this module may throw away valid virtual-to-physical
 1.1  christos  *	mappings at almost any time.  However, invalidations
 1.1  christos  *	of virtual-to-physical mappings must be done as
 1.1  christos  *	requested.
 1.1  christos  *
 1.1  christos  *	In order to cope with hardware architectures which
 1.1  christos  *	make virtual-to-physical map invalidates expensive,
 1.1  christos  *	this module may delay invalidate or reduced protection
 1.1  christos  *	operations until such time as they are actually
 1.1  christos  *	necessary.  This module is given full information as
 1.1  christos  *	to which processors are currently using which maps,
 1.1  christos  *	and to when physical maps must be made correct.
 1.1  christos  */
 1.1  christos
 1.1  christos #include "opt_modular.h"
 1.1  christos #include "opt_multiprocessor.h"
 1.1  christos #include "opt_sysv.h"
 1.1  christos
 1.1  christos #define __PMAP_PRIVATE
 1.1  christos
 1.1  christos #include <sys/param.h>
1.15      matt #include <sys/atomic.h>
 1.1  christos #include <sys/buf.h>
1.15      matt #include <sys/cpu.h>
1.15      matt #include <sys/mutex.h>
 1.1  christos #include <sys/pool.h>
 1.1  christos #include <sys/atomic.h>
 1.1  christos #include <sys/mutex.h>
 1.1  christos #include <sys/atomic.h>
 1.1  christos
 1.1  christos #include <uvm/uvm.h>
1.26    cherry #include <uvm/uvm_physseg.h>
 1.1  christos
1.15      matt #if defined(MULTIPROCESSOR) && defined(PMAP_VIRTUAL_CACHE_ALIASES) \
1.15      matt     && !defined(PMAP_NO_PV_UNCACHED)
1.15      matt #error PMAP_VIRTUAL_CACHE_ALIASES with MULTIPROCESSOR requires \
1.15      matt  PMAP_NO_PV_UNCACHED to be defined
1.15      matt #endif
 1.1  christos
 1.1  christos PMAP_COUNTER(remove_kernel_calls, "remove kernel calls");
 1.1  christos PMAP_COUNTER(remove_kernel_pages, "kernel pages unmapped");
 1.1  christos PMAP_COUNTER(remove_user_calls, "remove user calls");
 1.1  christos PMAP_COUNTER(remove_user_pages, "user pages unmapped");
 1.1  christos PMAP_COUNTER(remove_flushes, "remove cache flushes");
 1.1  christos PMAP_COUNTER(remove_tlb_ops, "remove tlb ops");
 1.1  christos PMAP_COUNTER(remove_pvfirst, "remove pv first");
 1.1  christos PMAP_COUNTER(remove_pvsearch, "remove pv search");
 1.1  christos
 1.1  christos PMAP_COUNTER(prefer_requests, "prefer requests");
 1.1  christos PMAP_COUNTER(prefer_adjustments, "prefer adjustments");
 1.1  christos
 1.1  christos PMAP_COUNTER(idlezeroed_pages, "pages idle zeroed");
 1.1  christos
 1.1  christos PMAP_COUNTER(kenter_pa, "kernel fast mapped pages");
 1.1  christos PMAP_COUNTER(kenter_pa_bad, "kernel fast mapped pages (bad color)");
 1.1  christos PMAP_COUNTER(kenter_pa_unmanaged, "kernel fast mapped unmanaged pages");
 1.1  christos PMAP_COUNTER(kremove_pages, "kernel fast unmapped pages");
 1.1  christos
 1.1  christos PMAP_COUNTER(page_cache_evictions, "pages changed to uncacheable");
 1.1  christos PMAP_COUNTER(page_cache_restorations, "pages changed to cacheable");
 1.1  christos
 1.1  christos PMAP_COUNTER(kernel_mappings_bad, "kernel pages mapped (bad color)");
 1.1  christos PMAP_COUNTER(user_mappings_bad, "user pages mapped (bad color)");
 1.1  christos PMAP_COUNTER(kernel_mappings, "kernel pages mapped");
 1.1  christos PMAP_COUNTER(user_mappings, "user pages mapped");
 1.1  christos PMAP_COUNTER(user_mappings_changed, "user mapping changed");
 1.1  christos PMAP_COUNTER(kernel_mappings_changed, "kernel mapping changed");
 1.1  christos PMAP_COUNTER(uncached_mappings, "uncached pages mapped");
 1.1  christos PMAP_COUNTER(unmanaged_mappings, "unmanaged pages mapped");
 1.1  christos PMAP_COUNTER(managed_mappings, "managed pages mapped");
 1.1  christos PMAP_COUNTER(mappings, "pages mapped");
 1.1  christos PMAP_COUNTER(remappings, "pages remapped");
 1.1  christos PMAP_COUNTER(unmappings, "pages unmapped");
 1.1  christos PMAP_COUNTER(primary_mappings, "page initial mappings");
 1.1  christos PMAP_COUNTER(primary_unmappings, "page final unmappings");
 1.1  christos PMAP_COUNTER(tlb_hit, "page mapping");
 1.1  christos
 1.1  christos PMAP_COUNTER(exec_mappings, "exec pages mapped");
 1.1  christos PMAP_COUNTER(exec_synced_mappings, "exec pages synced");
 1.1  christos PMAP_COUNTER(exec_synced_remove, "exec pages synced (PR)");
 1.1  christos PMAP_COUNTER(exec_synced_clear_modify, "exec pages synced (CM)");
 1.1  christos PMAP_COUNTER(exec_synced_page_protect, "exec pages synced (PP)");
 1.1  christos PMAP_COUNTER(exec_synced_protect, "exec pages synced (P)");
 1.1  christos PMAP_COUNTER(exec_uncached_page_protect, "exec pages uncached (PP)");
 1.1  christos PMAP_COUNTER(exec_uncached_clear_modify, "exec pages uncached (CM)");
 1.1  christos PMAP_COUNTER(exec_uncached_zero_page, "exec pages uncached (ZP)");
 1.1  christos PMAP_COUNTER(exec_uncached_copy_page, "exec pages uncached (CP)");
 1.1  christos PMAP_COUNTER(exec_uncached_remove, "exec pages uncached (PR)");
 1.1  christos
 1.1  christos PMAP_COUNTER(create, "creates");
 1.1  christos PMAP_COUNTER(reference, "references");
 1.1  christos PMAP_COUNTER(dereference, "dereferences");
 1.1  christos PMAP_COUNTER(destroy, "destroyed");
 1.1  christos PMAP_COUNTER(activate, "activations");
 1.1  christos PMAP_COUNTER(deactivate, "deactivations");
 1.1  christos PMAP_COUNTER(update, "updates");
 1.1  christos #ifdef MULTIPROCESSOR
 1.1  christos PMAP_COUNTER(shootdown_ipis, "shootdown IPIs");
 1.1  christos #endif
 1.1  christos PMAP_COUNTER(unwire, "unwires");
 1.1  christos PMAP_COUNTER(copy, "copies");
 1.1  christos PMAP_COUNTER(clear_modify, "clear_modifies");
 1.1  christos PMAP_COUNTER(protect, "protects");
 1.1  christos PMAP_COUNTER(page_protect, "page_protects");
 1.1  christos
 1.1  christos #define PMAP_ASID_RESERVED 0
 1.1  christos CTASSERT(PMAP_ASID_RESERVED == 0);
 1.1  christos
1.15      matt #ifndef PMAP_SEGTAB_ALIGN
1.15      matt #define PMAP_SEGTAB_ALIGN	/* nothing */
1.15      matt #endif
1.15      matt #ifdef _LP64
1.15      matt pmap_segtab_t	pmap_kstart_segtab PMAP_SEGTAB_ALIGN; /* first mid-level segtab for kernel */
1.15      matt #endif
1.15      matt pmap_segtab_t	pmap_kern_segtab PMAP_SEGTAB_ALIGN = { /* top level segtab for kernel */
1.15      matt #ifdef _LP64
1.15      matt 	.seg_seg[(VM_MIN_KERNEL_ADDRESS & XSEGOFSET) >> SEGSHIFT] = &pmap_kstart_segtab,
 1.1  christos #endif
1.15      matt };
 1.1  christos
 1.1  christos struct pmap_kernel kernel_pmap_store = {
 1.1  christos 	.kernel_pmap = {
 1.1  christos 		.pm_count = 1,
1.15      matt 		.pm_segtab = &pmap_kern_segtab,
 1.1  christos 		.pm_minaddr = VM_MIN_KERNEL_ADDRESS,
 1.1  christos 		.pm_maxaddr = VM_MAX_KERNEL_ADDRESS,
 1.1  christos 	},
 1.1  christos };
 1.1  christos
 1.1  christos struct pmap * const kernel_pmap_ptr = &kernel_pmap_store.kernel_pmap;
 1.1  christos
1.15      matt struct pmap_limits pmap_limits = {	/* VA and PA limits */
1.12      matt 	.virtual_start = VM_MIN_KERNEL_ADDRESS,
1.12      matt };
 1.1  christos
 1.1  christos #ifdef UVMHIST
 1.1  christos static struct kern_history_ent pmapexechistbuf[10000];
 1.1  christos static struct kern_history_ent pmaphistbuf[10000];
 1.8    nonaka UVMHIST_DEFINE(pmapexechist);
 1.8    nonaka UVMHIST_DEFINE(pmaphist);
 1.1  christos #endif
 1.1  christos
 1.1  christos /*
 1.1  christos  * The pools from which pmap structures and sub-structures are allocated.
 1.1  christos  */
 1.1  christos struct pool pmap_pmap_pool;
 1.1  christos struct pool pmap_pv_pool;
 1.1  christos
 1.1  christos #ifndef PMAP_PV_LOWAT
 1.1  christos #define	PMAP_PV_LOWAT	16
 1.1  christos #endif
1.15      matt int	pmap_pv_lowat = PMAP_PV_LOWAT;
 1.1  christos
1.15      matt bool	pmap_initialized = false;
 1.1  christos #define	PMAP_PAGE_COLOROK_P(a, b) \
 1.1  christos 		((((int)(a) ^ (int)(b)) & pmap_page_colormask) == 0)
1.15      matt u_int	pmap_page_colormask;
 1.1  christos
1.15      matt #define PAGE_IS_MANAGED(pa)	(pmap_initialized && uvm_pageismanaged(pa))
 1.1  christos
 1.1  christos #define PMAP_IS_ACTIVE(pm)						\
 1.1  christos 	((pm) == pmap_kernel() || 					\
 1.1  christos 	 (pm) == curlwp->l_proc->p_vmspace->vm_map.pmap)
 1.1  christos
 1.1  christos /* Forward function declarations */
1.15      matt void pmap_page_remove(struct vm_page *);
1.15      matt static void pmap_pvlist_check(struct vm_page_md *);
 1.1  christos void pmap_remove_pv(pmap_t, vaddr_t, struct vm_page *, bool);
1.15      matt void pmap_enter_pv(pmap_t, vaddr_t, struct vm_page *, pt_entry_t *, u_int);
 1.1  christos
 1.1  christos /*
 1.1  christos  * PV table management functions.
 1.1  christos  */
 1.1  christos void	*pmap_pv_page_alloc(struct pool *, int);
 1.1  christos void	pmap_pv_page_free(struct pool *, void *);
 1.1  christos
 1.1  christos struct pool_allocator pmap_pv_page_allocator = {
 1.1  christos 	pmap_pv_page_alloc, pmap_pv_page_free, 0,
 1.1  christos };
 1.1  christos
 1.1  christos #define	pmap_pv_alloc()		pool_get(&pmap_pv_pool, PR_NOWAIT)
 1.1  christos #define	pmap_pv_free(pv)	pool_put(&pmap_pv_pool, (pv))
 1.1  christos
1.10    nonaka #if !defined(MULTIPROCESSOR) || !defined(PMAP_MD_NEED_TLB_MISS_LOCK)
1.10    nonaka #define	pmap_md_tlb_miss_lock_enter()	do { } while(/*CONSTCOND*/0)
1.10    nonaka #define	pmap_md_tlb_miss_lock_exit()	do { } while(/*CONSTCOND*/0)
1.15      matt #endif /* !MULTIPROCESSOR || !PMAP_MD_NEED_TLB_MISS_LOCK */
1.15      matt
1.15      matt #ifndef MULTIPROCESSOR
1.15      matt kmutex_t pmap_pvlist_mutex	__cacheline_aligned;
1.15      matt #endif
1.15      matt
1.15      matt /*
1.15      matt  * Debug functions.
1.15      matt  */
1.15      matt
1.19  jakllsch #ifdef DEBUG
1.15      matt static inline void
1.15      matt pmap_asid_check(pmap_t pm, const char *func)
1.15      matt {
1.15      matt 	if (!PMAP_IS_ACTIVE(pm))
1.15      matt 		return;
1.15      matt
1.15      matt 	struct pmap_asid_info * const pai = PMAP_PAI(pm, cpu_tlb_info(curcpu()));
1.15      matt 	tlb_asid_t asid = tlb_get_asid();
1.15      matt 	if (asid != pai->pai_asid)
1.15      matt 		panic("%s: inconsistency for active TLB update: %u <-> %u",
1.15      matt 		    func, asid, pai->pai_asid);
1.19  jakllsch }
1.15      matt #endif
1.15      matt
1.15      matt static void
1.15      matt pmap_addr_range_check(pmap_t pmap, vaddr_t sva, vaddr_t eva, const char *func)
1.15      matt {
1.15      matt #ifdef DEBUG
1.15      matt 	if (pmap == pmap_kernel()) {
1.15      matt 		if (sva < VM_MIN_KERNEL_ADDRESS)
1.15      matt 			panic("%s: kva %#"PRIxVADDR" not in range",
1.15      matt 			    func, sva);
1.15      matt 		if (eva >= pmap_limits.virtual_end)
1.15      matt 			panic("%s: kva %#"PRIxVADDR" not in range",
1.15      matt 			    func, eva);
1.15      matt 	} else {
1.15      matt 		if (eva > VM_MAXUSER_ADDRESS)
1.15      matt 			panic("%s: uva %#"PRIxVADDR" not in range",
1.15      matt 			    func, eva);
1.15      matt 		pmap_asid_check(pmap, func);
1.15      matt 	}
1.15      matt #endif
1.15      matt }
1.10    nonaka
 1.1  christos /*
 1.1  christos  * Misc. functions.
 1.1  christos  */
 1.1  christos
 1.1  christos bool
 1.1  christos pmap_page_clear_attributes(struct vm_page_md *mdpg, u_int clear_attributes)
 1.1  christos {
1.15      matt 	volatile unsigned long * const attrp = &mdpg->mdpg_attrs;
 1.1  christos #ifdef MULTIPROCESSOR
 1.1  christos 	for (;;) {
 1.1  christos 		u_int old_attr = *attrp;
 1.1  christos 		if ((old_attr & clear_attributes) == 0)
 1.1  christos 			return false;
 1.1  christos 		u_int new_attr = old_attr & ~clear_attributes;
1.15      matt 		if (old_attr == atomic_cas_ulong(attrp, old_attr, new_attr))
 1.1  christos 			return true;
 1.1  christos 	}
 1.1  christos #else
1.15      matt 	unsigned long old_attr = *attrp;
 1.1  christos 	if ((old_attr & clear_attributes) == 0)
 1.1  christos 		return false;
 1.1  christos 	*attrp &= ~clear_attributes;
 1.1  christos 	return true;
 1.1  christos #endif
 1.1  christos }
 1.1  christos
 1.1  christos void
 1.1  christos pmap_page_set_attributes(struct vm_page_md *mdpg, u_int set_attributes)
 1.1  christos {
 1.1  christos #ifdef MULTIPROCESSOR
1.15      matt 	atomic_or_ulong(&mdpg->mdpg_attrs, set_attributes);
 1.1  christos #else
 1.1  christos 	mdpg->mdpg_attrs |= set_attributes;
 1.1  christos #endif
 1.1  christos }
 1.1  christos
 1.1  christos static void
 1.1  christos pmap_page_syncicache(struct vm_page *pg)
 1.1  christos {
 1.1  christos #ifndef MULTIPROCESSOR
1.15      matt 	struct pmap * const curpmap = curlwp->l_proc->p_vmspace->vm_map.pmap;
 1.1  christos #endif
 1.1  christos 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
 1.1  christos 	pv_entry_t pv = &mdpg->mdpg_first;
 1.2      matt 	kcpuset_t *onproc;
 1.2      matt #ifdef MULTIPROCESSOR
 1.2      matt 	kcpuset_create(&onproc, true);
1.15      matt 	KASSERT(onproc != NULL);
 1.3      matt #else
 1.3      matt 	onproc = NULL;
 1.2      matt #endif
1.15      matt 	VM_PAGEMD_PVLIST_READLOCK(mdpg);
1.15      matt 	pmap_pvlist_check(mdpg);
 1.2      matt
 1.1  christos 	if (pv->pv_pmap != NULL) {
 1.1  christos 		for (; pv != NULL; pv = pv->pv_next) {
 1.1  christos #ifdef MULTIPROCESSOR
 1.2      matt 			kcpuset_merge(onproc, pv->pv_pmap->pm_onproc);
 1.2      matt 			if (kcpuset_match(onproc, kcpuset_running)) {
 1.1  christos 				break;
 1.1  christos 			}
 1.1  christos #else
 1.1  christos 			if (pv->pv_pmap == curpmap) {
 1.2      matt 				onproc = curcpu()->ci_data.cpu_kcpuset;
 1.1  christos 				break;
 1.1  christos 			}
 1.1  christos #endif
 1.1  christos 		}
 1.1  christos 	}
1.15      matt 	pmap_pvlist_check(mdpg);
 1.1  christos 	VM_PAGEMD_PVLIST_UNLOCK(mdpg);
 1.1  christos 	kpreempt_disable();
 1.1  christos 	pmap_md_page_syncicache(pg, onproc);
1.15      matt 	kpreempt_enable();
 1.2      matt #ifdef MULTIPROCESSOR
 1.2      matt 	kcpuset_destroy(onproc);
 1.2      matt #endif
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  * Define the initial bounds of the kernel virtual address space.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_virtual_space(vaddr_t *vstartp, vaddr_t *vendp)
 1.1  christos {
 1.1  christos
1.12      matt 	*vstartp = pmap_limits.virtual_start;
1.12      matt 	*vendp = pmap_limits.virtual_end;
 1.1  christos }
 1.1  christos
 1.1  christos vaddr_t
 1.1  christos pmap_growkernel(vaddr_t maxkvaddr)
 1.1  christos {
1.14   msaitoh 	vaddr_t virtual_end = pmap_limits.virtual_end;
 1.1  christos 	maxkvaddr = pmap_round_seg(maxkvaddr) - 1;
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Reserve PTEs for the new KVA space.
 1.1  christos 	 */
 1.1  christos 	for (; virtual_end < maxkvaddr; virtual_end += NBSEG) {
 1.1  christos 		pmap_pte_reserve(pmap_kernel(), virtual_end, 0);
 1.1  christos 	}
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Don't exceed VM_MAX_KERNEL_ADDRESS!
 1.1  christos 	 */
 1.1  christos 	if (virtual_end == 0 || virtual_end > VM_MAX_KERNEL_ADDRESS)
 1.1  christos 		virtual_end = VM_MAX_KERNEL_ADDRESS;
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Update new end.
 1.1  christos 	 */
 1.1  christos 	pmap_limits.virtual_end = virtual_end;
 1.1  christos 	return virtual_end;
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  * Bootstrap memory allocator (alternative to vm_bootstrap_steal_memory()).
 1.1  christos  * This function allows for early dynamic memory allocation until the virtual
 1.1  christos  * memory system has been bootstrapped.  After that point, either kmem_alloc
 1.1  christos  * or malloc should be used.  This function works by stealing pages from the
 1.1  christos  * (to be) managed page pool, then implicitly mapping the pages (by using
1.41     skrll  * their direct mapped addresses) and zeroing them.
 1.1  christos  *
 1.1  christos  * It may be used once the physical memory segments have been pre-loaded
 1.1  christos  * into the vm_physmem[] array.  Early memory allocation MUST use this
 1.1  christos  * interface!  This cannot be used after vm_page_startup(), and will
 1.1  christos  * generate a panic if tried.
 1.1  christos  *
 1.1  christos  * Note that this memory will never be freed, and in essence it is wired
 1.1  christos  * down.
 1.1  christos  *
 1.1  christos  * We must adjust *vstartp and/or *vendp iff we use address space
 1.1  christos  * from the kernel virtual address range defined by pmap_virtual_space().
 1.1  christos  */
 1.1  christos vaddr_t
 1.1  christos pmap_steal_memory(vsize_t size, vaddr_t *vstartp, vaddr_t *vendp)
 1.1  christos {
1.15      matt 	size_t npgs;
 1.1  christos 	paddr_t pa;
 1.1  christos 	vaddr_t va;
1.26    cherry
1.27     skrll 	uvm_physseg_t maybe_bank = UVM_PHYSSEG_TYPE_INVALID;
 1.1  christos
 1.1  christos 	size = round_page(size);
 1.1  christos 	npgs = atop(size);
 1.1  christos
1.15      matt 	aprint_debug("%s: need %zu pages\n", __func__, npgs);
1.15      matt
1.26    cherry 	for (uvm_physseg_t bank = uvm_physseg_get_first();
1.26    cherry 	     uvm_physseg_valid_p(bank);
1.26    cherry 	     bank = uvm_physseg_get_next(bank)) {
1.26    cherry
 1.1  christos 		if (uvm.page_init_done == true)
 1.1  christos 			panic("pmap_steal_memory: called _after_ bootstrap");
 1.1  christos
1.27     skrll 		aprint_debug("%s: seg %"PRIxPHYSSEG": %#"PRIxPADDR" %#"PRIxPADDR" %#"PRIxPADDR" %#"PRIxPADDR"\n",
1.15      matt 		    __func__, bank,
1.26    cherry 		    uvm_physseg_get_avail_start(bank), uvm_physseg_get_start(bank),
1.26    cherry 		    uvm_physseg_get_avail_end(bank), uvm_physseg_get_end(bank));
1.15      matt
1.26    cherry 		if (uvm_physseg_get_avail_start(bank) != uvm_physseg_get_start(bank)
1.26    cherry 		    || uvm_physseg_get_avail_start(bank) >= uvm_physseg_get_avail_end(bank)) {
1.27     skrll 			aprint_debug("%s: seg %"PRIxPHYSSEG": bad start\n", __func__, bank);
 1.1  christos 			continue;
1.15      matt 		}
 1.1  christos
1.26    cherry 		if (uvm_physseg_get_avail_end(bank) - uvm_physseg_get_avail_start(bank) < npgs) {
1.27     skrll 			aprint_debug("%s: seg %"PRIxPHYSSEG": too small for %zu pages\n",
1.15      matt 			    __func__, bank, npgs);
 1.1  christos 			continue;
1.15      matt 		}
1.15      matt
1.26    cherry 		if (!pmap_md_ok_to_steal_p(bank, npgs)) {
1.15      matt 			continue;
1.15      matt 		}
1.15      matt
1.15      matt 		/*
1.15      matt 		 * Always try to allocate from the segment with the least
1.15      matt 		 * amount of space left.
1.15      matt 		 */
1.26    cherry #define VM_PHYSMEM_SPACE(b)	((uvm_physseg_get_avail_end(b)) - (uvm_physseg_get_avail_start(b)))
1.26    cherry 		if (uvm_physseg_valid_p(maybe_bank) == false
1.26    cherry 		    || VM_PHYSMEM_SPACE(bank) < VM_PHYSMEM_SPACE(maybe_bank)) {
1.15      matt 			maybe_bank = bank;
1.15      matt 		}
1.15      matt 	}
1.15      matt
1.26    cherry 	if (uvm_physseg_valid_p(maybe_bank)) {
1.26    cherry 		const uvm_physseg_t bank = maybe_bank;
1.29     skrll
 1.1  christos 		/*
 1.1  christos 		 * There are enough pages here; steal them!
 1.1  christos 		 */
1.26    cherry 		pa = ptoa(uvm_physseg_get_start(bank));
1.26    cherry 		uvm_physseg_unplug(atop(pa), npgs);
 1.1  christos
1.27     skrll 		aprint_debug("%s: seg %"PRIxPHYSSEG": %zu pages stolen (%#"PRIxPADDR" left)\n",
1.26    cherry 		    __func__, bank, npgs, VM_PHYSMEM_SPACE(bank));
 1.1  christos
 1.1  christos 		va = pmap_md_map_poolpage(pa, size);
 1.1  christos 		memset((void *)va, 0, size);
 1.1  christos 		return va;
 1.1  christos 	}
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * If we got here, there was no memory left.
 1.1  christos 	 */
1.15      matt 	panic("pmap_steal_memory: no memory to steal %zu pages", npgs);
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Initialize the pmap module.
 1.1  christos  *	Called by vm_init, to initialize any structures that the pmap
 1.1  christos  *	system needs to map virtual memory.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_init(void)
 1.1  christos {
 1.1  christos 	UVMHIST_INIT_STATIC(pmapexechist, pmapexechistbuf);
 1.1  christos 	UVMHIST_INIT_STATIC(pmaphist, pmaphistbuf);
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Initialize the segtab lock.
 1.1  christos 	 */
 1.1  christos 	mutex_init(&pmap_segtab_lock, MUTEX_DEFAULT, IPL_HIGH);
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Set a low water mark on the pv_entry pool, so that we are
 1.1  christos 	 * more likely to have these around even in extreme memory
 1.1  christos 	 * starvation.
 1.1  christos 	 */
 1.1  christos 	pool_setlowat(&pmap_pv_pool, pmap_pv_lowat);
 1.1  christos
1.15      matt 	/*
1.15      matt 	 * Set the page colormask but allow pmap_md_init to override it.
1.15      matt 	 */
1.15      matt 	pmap_page_colormask = ptoa(uvmexp.colormask);
1.15      matt
 1.1  christos 	pmap_md_init();
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Now it is safe to enable pv entry recording.
 1.1  christos 	 */
 1.1  christos 	pmap_initialized = true;
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Create and return a physical map.
 1.1  christos  *
 1.1  christos  *	If the size specified for the map
 1.1  christos  *	is zero, the map is an actual physical
 1.1  christos  *	map, and may be referenced by the
 1.1  christos  *	hardware.
 1.1  christos  *
 1.1  christos  *	If the size specified is non-zero,
 1.1  christos  *	the map will be used in software only, and
 1.1  christos  *	is bounded by that size.
 1.1  christos  */
 1.1  christos pmap_t
 1.1  christos pmap_create(void)
 1.1  christos {
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
 1.1  christos 	PMAP_COUNT(create);
 1.1  christos
1.15      matt 	pmap_t pmap = pool_get(&pmap_pmap_pool, PR_WAITOK);
 1.1  christos 	memset(pmap, 0, PMAP_SIZE);
 1.1  christos
 1.1  christos 	KASSERT(pmap->pm_pai[0].pai_link.le_prev == NULL);
 1.1  christos
 1.1  christos 	pmap->pm_count = 1;
 1.1  christos 	pmap->pm_minaddr = VM_MIN_ADDRESS;
 1.1  christos 	pmap->pm_maxaddr = VM_MAXUSER_ADDRESS;
 1.1  christos
 1.1  christos 	pmap_segtab_init(pmap);
 1.1  christos
 1.5    nonaka #ifdef MULTIPROCESSOR
 1.5    nonaka 	kcpuset_create(&pmap->pm_active, true);
 1.5    nonaka 	kcpuset_create(&pmap->pm_onproc, true);
1.15      matt 	KASSERT(pmap->pm_active != NULL);
1.15      matt 	KASSERT(pmap->pm_onproc != NULL);
 1.5    nonaka #endif
 1.5    nonaka
1.37  pgoyette 	UVMHIST_LOG(pmaphist, " <-- done (pmap=%#jx)", (uintptr_t)pmap,
1.37  pgoyette 	    0, 0, 0);
1.15      matt
 1.1  christos 	return pmap;
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Retire the given physical map from service.
 1.1  christos  *	Should only be called if the map contains
 1.1  christos  *	no valid mappings.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_destroy(pmap_t pmap)
 1.1  christos {
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pmap=%#jx)", (uintptr_t)pmap, 0, 0, 0);
 1.1  christos
 1.1  christos 	if (atomic_dec_uint_nv(&pmap->pm_count) > 0) {
 1.1  christos 		PMAP_COUNT(dereference);
1.15      matt 		UVMHIST_LOG(pmaphist, " <-- done (deref)", 0, 0, 0, 0);
 1.1  christos 		return;
 1.1  christos 	}
 1.1  christos
1.15      matt 	PMAP_COUNT(destroy);
 1.1  christos 	KASSERT(pmap->pm_count == 0);
 1.1  christos 	kpreempt_disable();
1.10    nonaka 	pmap_md_tlb_miss_lock_enter();
 1.1  christos 	pmap_tlb_asid_release_all(pmap);
 1.1  christos 	pmap_segtab_destroy(pmap, NULL, 0);
1.10    nonaka 	pmap_md_tlb_miss_lock_exit();
 1.1  christos
 1.6    nonaka #ifdef MULTIPROCESSOR
 1.7    nonaka 	kcpuset_destroy(pmap->pm_active);
 1.7    nonaka 	kcpuset_destroy(pmap->pm_onproc);
1.15      matt 	pmap->pm_active = NULL;
1.15      matt 	pmap->pm_onproc = NULL;
 1.6    nonaka #endif
 1.6    nonaka
 1.1  christos 	pool_put(&pmap_pmap_pool, pmap);
 1.1  christos 	kpreempt_enable();
 1.1  christos
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done (freed)", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Add a reference to the specified pmap.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_reference(pmap_t pmap)
 1.1  christos {
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pmap=%#jx)", (uintptr_t)pmap, 0, 0, 0);
 1.1  christos 	PMAP_COUNT(reference);
 1.1  christos
 1.1  christos 	if (pmap != NULL) {
 1.1  christos 		atomic_inc_uint(&pmap->pm_count);
 1.1  christos 	}
 1.1  christos
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Make a new pmap (vmspace) active for the given process.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_activate(struct lwp *l)
 1.1  christos {
 1.1  christos 	pmap_t pmap = l->l_proc->p_vmspace->vm_map.pmap;
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(l=%#jx pmap=%#jx)", (uintptr_t)l,
1.37  pgoyette 	    (uintptr_t)pmap, 0, 0);
 1.1  christos 	PMAP_COUNT(activate);
 1.1  christos
 1.1  christos 	kpreempt_disable();
1.10    nonaka 	pmap_md_tlb_miss_lock_enter();
 1.1  christos 	pmap_tlb_asid_acquire(pmap, l);
 1.1  christos 	if (l == curlwp) {
 1.1  christos 		pmap_segtab_activate(pmap, l);
 1.1  christos 	}
1.10    nonaka 	pmap_md_tlb_miss_lock_exit();
 1.1  christos 	kpreempt_enable();
 1.1  christos
1.37  pgoyette 	UVMHIST_LOG(pmaphist, " <-- done (%ju:%ju)", l->l_proc->p_pid,
1.37  pgoyette 	    l->l_lid, 0, 0);
1.15      matt }
1.15      matt
1.15      matt /*
1.15      matt  * Remove this page from all physical maps in which it resides.
1.15      matt  * Reflects back modify bits to the pager.
1.15      matt  */
1.15      matt void
1.15      matt pmap_page_remove(struct vm_page *pg)
1.15      matt {
1.15      matt 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
1.15      matt
1.15      matt 	kpreempt_disable();
1.15      matt 	VM_PAGEMD_PVLIST_LOCK(mdpg);
1.15      matt 	pmap_pvlist_check(mdpg);
1.15      matt
1.15      matt 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.15      matt
1.37  pgoyette 	UVMHIST_LOG(pmapexechist, "pg %#jx (pa %#jx) [page removed]: "
1.37  pgoyette 	    "execpage cleared", (uintptr_t)pg, VM_PAGE_TO_PHYS(pg), 0, 0);
1.22      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.22      matt 	pmap_page_clear_attributes(mdpg, VM_PAGEMD_EXECPAGE|VM_PAGEMD_UNCACHED);
1.22      matt #else
1.22      matt 	pmap_page_clear_attributes(mdpg, VM_PAGEMD_EXECPAGE);
1.22      matt #endif
1.22      matt 	PMAP_COUNT(exec_uncached_remove);
1.22      matt
1.15      matt 	pv_entry_t pv = &mdpg->mdpg_first;
1.15      matt 	if (pv->pv_pmap == NULL) {
1.15      matt 		VM_PAGEMD_PVLIST_UNLOCK(mdpg);
1.15      matt 		kpreempt_enable();
1.15      matt 		UVMHIST_LOG(pmaphist, " <-- done (empty)", 0, 0, 0, 0);
1.15      matt 		return;
1.15      matt 	}
1.15      matt
1.15      matt 	pv_entry_t npv;
1.15      matt 	pv_entry_t pvp = NULL;
1.15      matt
1.15      matt 	for (; pv != NULL; pv = npv) {
1.15      matt 		npv = pv->pv_next;
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 		if (pv->pv_va & PV_KENTER) {
1.37  pgoyette 			UVMHIST_LOG(pmaphist, " pv %#jx pmap %#jx va %jx"
1.37  pgoyette 			    " skip", (uintptr_t)pv, (uintptr_t)pv->pv_pmap,
1.37  pgoyette 			    pv->pv_va, 0);
1.15      matt
1.15      matt 			KASSERT(pv->pv_pmap == pmap_kernel());
1.15      matt
1.15      matt 			/* Assume no more - it'll get fixed if there are */
1.15      matt 			pv->pv_next = NULL;
1.15      matt
1.15      matt 			/*
1.15      matt 			 * pvp is non-null when we already have a PV_KENTER
1.15      matt 			 * pv in pvh_first; otherwise we haven't seen a
1.15      matt 			 * PV_KENTER pv and we need to copy this one to
1.15      matt 			 * pvh_first
1.15      matt 			 */
1.15      matt 			if (pvp) {
1.15      matt 				/*
1.15      matt 				 * The previous PV_KENTER pv needs to point to
1.15      matt 				 * this PV_KENTER pv
1.15      matt 				 */
1.15      matt 				pvp->pv_next = pv;
1.15      matt 			} else {
1.15      matt 				pv_entry_t fpv = &mdpg->mdpg_first;
1.15      matt 				*fpv = *pv;
1.15      matt 				KASSERT(fpv->pv_pmap == pmap_kernel());
1.15      matt 			}
1.15      matt 			pvp = pv;
1.15      matt 			continue;
1.15      matt 		}
1.15      matt #endif
1.15      matt 		const pmap_t pmap = pv->pv_pmap;
1.15      matt 		vaddr_t va = trunc_page(pv->pv_va);
1.15      matt 		pt_entry_t * const ptep = pmap_pte_lookup(pmap, va);
1.15      matt 		KASSERTMSG(ptep != NULL, "%#"PRIxVADDR " %#"PRIxVADDR, va,
1.15      matt 		    pmap_limits.virtual_end);
1.15      matt 		pt_entry_t pte = *ptep;
1.37  pgoyette 		UVMHIST_LOG(pmaphist, " pv %#jx pmap %#jx va %jx"
1.37  pgoyette 		    " pte %jx", (uintptr_t)pv, (uintptr_t)pmap, va,
1.37  pgoyette 		    pte_value(pte));
1.15      matt 		if (!pte_valid_p(pte))
1.15      matt 			continue;
1.15      matt 		const bool is_kernel_pmap_p = (pmap == pmap_kernel());
1.15      matt 		if (is_kernel_pmap_p) {
1.15      matt 			PMAP_COUNT(remove_kernel_pages);
1.15      matt 		} else {
1.15      matt 			PMAP_COUNT(remove_user_pages);
1.15      matt 		}
1.15      matt 		if (pte_wired_p(pte))
1.15      matt 			pmap->pm_stats.wired_count--;
1.15      matt 		pmap->pm_stats.resident_count--;
1.15      matt
1.15      matt 		pmap_md_tlb_miss_lock_enter();
1.15      matt 		const pt_entry_t npte = pte_nv_entry(is_kernel_pmap_p);
1.35     skrll 		pte_set(ptep, npte);
1.36     skrll 		if (__predict_true(!(pmap->pm_flags & PMAP_DEFERRED_ACTIVATE))) {
1.36     skrll 			/*
1.36     skrll 			 * Flush the TLB for the given address.
1.36     skrll 			 */
1.36     skrll 			pmap_tlb_invalidate_addr(pmap, va);
1.36     skrll 		}
1.15      matt 		pmap_md_tlb_miss_lock_exit();
1.15      matt
1.15      matt 		/*
1.15      matt 		 * non-null means this is a non-pvh_first pv, so we should
1.15      matt 		 * free it.
1.15      matt 		 */
1.15      matt 		if (pvp) {
1.15      matt 			KASSERT(pvp->pv_pmap == pmap_kernel());
1.15      matt 			KASSERT(pvp->pv_next == NULL);
1.15      matt 			pmap_pv_free(pv);
1.15      matt 		} else {
1.15      matt 			pv->pv_pmap = NULL;
1.15      matt 			pv->pv_next = NULL;
1.15      matt 		}
1.15      matt 	}
1.15      matt
1.15      matt 	pmap_pvlist_check(mdpg);
1.15      matt 	VM_PAGEMD_PVLIST_UNLOCK(mdpg);
1.15      matt 	kpreempt_enable();
1.15      matt
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
1.15      matt
 1.1  christos /*
 1.1  christos  *	Make a previously active pmap (vmspace) inactive.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_deactivate(struct lwp *l)
 1.1  christos {
 1.1  christos 	pmap_t pmap = l->l_proc->p_vmspace->vm_map.pmap;
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(l=%#jx pmap=%#jx)", (uintptr_t)l,
1.37  pgoyette 	    (uintptr_t)pmap, 0, 0);
 1.1  christos 	PMAP_COUNT(deactivate);
 1.1  christos
 1.1  christos 	kpreempt_disable();
1.15      matt 	KASSERT(l == curlwp || l->l_cpu == curlwp->l_cpu);
1.10    nonaka 	pmap_md_tlb_miss_lock_enter();
 1.1  christos 	curcpu()->ci_pmap_user_segtab = PMAP_INVALID_SEGTAB_ADDRESS;
1.15      matt #ifdef _LP64
1.15      matt 	curcpu()->ci_pmap_user_seg0tab = NULL;
1.15      matt #endif
 1.1  christos 	pmap_tlb_asid_deactivate(pmap);
1.10    nonaka 	pmap_md_tlb_miss_lock_exit();
 1.1  christos 	kpreempt_enable();
 1.1  christos
1.37  pgoyette 	UVMHIST_LOG(pmaphist, " <-- done (%ju:%ju)", l->l_proc->p_pid,
1.37  pgoyette 	    l->l_lid, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos void
 1.1  christos pmap_update(struct pmap *pmap)
 1.1  christos {
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pmap=%#jx)", (uintptr_t)pmap, 0, 0, 0);
 1.1  christos 	PMAP_COUNT(update);
 1.1  christos
 1.1  christos 	kpreempt_disable();
1.18     skrll #if defined(MULTIPROCESSOR) && defined(PMAP_TLB_NEED_SHOOTDOWN)
 1.1  christos 	u_int pending = atomic_swap_uint(&pmap->pm_shootdown_pending, 0);
 1.1  christos 	if (pending && pmap_tlb_shootdown_bystanders(pmap))
 1.1  christos 		PMAP_COUNT(shootdown_ipis);
 1.1  christos #endif
1.10    nonaka 	pmap_md_tlb_miss_lock_enter();
1.11    nonaka #if defined(DEBUG) && !defined(MULTIPROCESSOR)
 1.1  christos 	pmap_tlb_check(pmap, pmap_md_tlb_check_entry);
 1.1  christos #endif /* DEBUG */
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * If pmap_remove_all was called, we deactivated ourselves and nuked
 1.1  christos 	 * our ASID.  Now we have to reactivate ourselves.
 1.1  christos 	 */
 1.1  christos 	if (__predict_false(pmap->pm_flags & PMAP_DEFERRED_ACTIVATE)) {
 1.1  christos 		pmap->pm_flags ^= PMAP_DEFERRED_ACTIVATE;
 1.1  christos 		pmap_tlb_asid_acquire(pmap, curlwp);
 1.1  christos 		pmap_segtab_activate(pmap, curlwp);
 1.1  christos 	}
1.10    nonaka 	pmap_md_tlb_miss_lock_exit();
 1.1  christos 	kpreempt_enable();
 1.1  christos
1.37  pgoyette 	UVMHIST_LOG(pmaphist, " <-- done (kernel=%#jx)",
1.37  pgoyette 		    (pmap == pmap_kernel() ? 1 : 0), 0, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Remove the given range of addresses from the specified map.
 1.1  christos  *
 1.1  christos  *	It is assumed that the start and end are properly
 1.1  christos  *	rounded to the page size.
 1.1  christos  */
 1.1  christos
 1.1  christos static bool
 1.1  christos pmap_pte_remove(pmap_t pmap, vaddr_t sva, vaddr_t eva, pt_entry_t *ptep,
 1.1  christos 	uintptr_t flags)
 1.1  christos {
 1.1  christos 	const pt_entry_t npte = flags;
 1.1  christos 	const bool is_kernel_pmap_p = (pmap == pmap_kernel());
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.39  pgoyette 	UVMHIST_LOG(pmaphist, "(pmap=%#jx kernel=%c va=%#jx..%#jx)",
1.40  pgoyette 	    (uintptr_t)pmap, (is_kernel_pmap_p ? 1 : 0), sva, eva);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "ptep=%#jx, flags(npte)=%#jx",
1.37  pgoyette 	    (uintptr_t)ptep, flags, 0, 0);
 1.1  christos
 1.1  christos 	KASSERT(kpreempt_disabled());
 1.1  christos
 1.1  christos 	for (; sva < eva; sva += NBPG, ptep++) {
1.15      matt 		const pt_entry_t pte = *ptep;
1.15      matt 		if (!pte_valid_p(pte))
 1.1  christos 			continue;
1.15      matt 		if (is_kernel_pmap_p) {
1.15      matt 			PMAP_COUNT(remove_kernel_pages);
1.15      matt 		} else {
 1.1  christos 			PMAP_COUNT(remove_user_pages);
1.15      matt 		}
1.15      matt 		if (pte_wired_p(pte))
 1.1  christos 			pmap->pm_stats.wired_count--;
 1.1  christos 		pmap->pm_stats.resident_count--;
1.15      matt 		struct vm_page * const pg = PHYS_TO_VM_PAGE(pte_to_paddr(pte));
 1.1  christos 		if (__predict_true(pg != NULL)) {
1.15      matt 			pmap_remove_pv(pmap, sva, pg, pte_modified_p(pte));
 1.1  christos 		}
1.10    nonaka 		pmap_md_tlb_miss_lock_enter();
1.35     skrll 		pte_set(ptep, npte);
1.36     skrll 		if (__predict_true(!(pmap->pm_flags & PMAP_DEFERRED_ACTIVATE))) {
1.36     skrll
1.36     skrll 			/*
1.36     skrll 			 * Flush the TLB for the given address.
1.36     skrll 			 */
1.36     skrll 			pmap_tlb_invalidate_addr(pmap, sva);
1.36     skrll 		}
1.10    nonaka 		pmap_md_tlb_miss_lock_exit();
 1.1  christos 	}
1.15      matt
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
1.15      matt
 1.1  christos 	return false;
 1.1  christos }
 1.1  christos
 1.1  christos void
 1.1  christos pmap_remove(pmap_t pmap, vaddr_t sva, vaddr_t eva)
 1.1  christos {
 1.1  christos 	const bool is_kernel_pmap_p = (pmap == pmap_kernel());
 1.1  christos 	const pt_entry_t npte = pte_nv_entry(is_kernel_pmap_p);
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pmap=%#jx, va=%#jx..%#jx)",
1.37  pgoyette 	    (uintptr_t)pmap, sva, eva, 0);
 1.1  christos
1.15      matt 	if (is_kernel_pmap_p) {
 1.1  christos 		PMAP_COUNT(remove_kernel_calls);
1.15      matt 	} else {
 1.1  christos 		PMAP_COUNT(remove_user_calls);
 1.1  christos 	}
1.15      matt #ifdef PMAP_FAULTINFO
1.15      matt 	curpcb->pcb_faultinfo.pfi_faultaddr = 0;
1.15      matt 	curpcb->pcb_faultinfo.pfi_repeats = 0;
1.15      matt 	curpcb->pcb_faultinfo.pfi_faultpte = NULL;
 1.1  christos #endif
 1.1  christos 	kpreempt_disable();
1.15      matt 	pmap_addr_range_check(pmap, sva, eva, __func__);
 1.1  christos 	pmap_pte_process(pmap, sva, eva, pmap_pte_remove, npte);
 1.1  christos 	kpreempt_enable();
 1.1  christos
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	pmap_page_protect:
 1.1  christos  *
 1.1  christos  *	Lower the permission for all mappings to a given page.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_page_protect(struct vm_page *pg, vm_prot_t prot)
 1.1  christos {
 1.1  christos 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
 1.1  christos 	pv_entry_t pv;
 1.1  christos 	vaddr_t va;
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pg=%#jx (pa %#jx) prot=%#jx)",
1.37  pgoyette 	    (uintptr_t)pg, VM_PAGE_TO_PHYS(pg), prot, 0);
 1.1  christos 	PMAP_COUNT(page_protect);
 1.1  christos
 1.1  christos 	switch (prot) {
 1.1  christos 	case VM_PROT_READ|VM_PROT_WRITE:
 1.1  christos 	case VM_PROT_ALL:
 1.1  christos 		break;
 1.1  christos
 1.1  christos 	/* copy_on_write */
 1.1  christos 	case VM_PROT_READ:
 1.1  christos 	case VM_PROT_READ|VM_PROT_EXECUTE:
 1.1  christos 		pv = &mdpg->mdpg_first;
1.15      matt 		kpreempt_disable();
1.15      matt 		VM_PAGEMD_PVLIST_READLOCK(mdpg);
1.15      matt 		pmap_pvlist_check(mdpg);
 1.1  christos 		/*
1.33     skrll 		 * Loop over all current mappings setting/clearing as
1.33     skrll 		 * appropriate.
 1.1  christos 		 */
 1.1  christos 		if (pv->pv_pmap != NULL) {
 1.1  christos 			while (pv != NULL) {
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 				if (pv->pv_va & PV_KENTER) {
1.15      matt 					pv = pv->pv_next;
1.15      matt 					continue;
1.15      matt 				}
1.15      matt #endif
 1.1  christos 				const pmap_t pmap = pv->pv_pmap;
1.15      matt 				va = trunc_page(pv->pv_va);
1.15      matt 				const uintptr_t gen =
1.15      matt 				    VM_PAGEMD_PVLIST_UNLOCK(mdpg);
 1.1  christos 				pmap_protect(pmap, va, va + PAGE_SIZE, prot);
 1.1  christos 				KASSERT(pv->pv_pmap == pmap);
 1.1  christos 				pmap_update(pmap);
1.15      matt 				if (gen != VM_PAGEMD_PVLIST_READLOCK(mdpg)) {
 1.1  christos 					pv = &mdpg->mdpg_first;
 1.1  christos 				} else {
 1.1  christos 					pv = pv->pv_next;
 1.1  christos 				}
1.15      matt 				pmap_pvlist_check(mdpg);
 1.1  christos 			}
 1.1  christos 		}
1.15      matt 		pmap_pvlist_check(mdpg);
 1.1  christos 		VM_PAGEMD_PVLIST_UNLOCK(mdpg);
1.15      matt 		kpreempt_enable();
 1.1  christos 		break;
 1.1  christos
 1.1  christos 	/* remove_all */
 1.1  christos 	default:
1.15      matt 		pmap_page_remove(pg);
 1.1  christos 	}
 1.1  christos
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos static bool
 1.1  christos pmap_pte_protect(pmap_t pmap, vaddr_t sva, vaddr_t eva, pt_entry_t *ptep,
 1.1  christos 	uintptr_t flags)
 1.1  christos {
 1.1  christos 	const vm_prot_t prot = (flags & VM_PROT_ALL);
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pmap=%#jx kernel=%jx va=%#jx..%#jx)",
1.40  pgoyette 	    (uintptr_t)pmap, (pmap == pmap_kernel() ? 1 : 0), sva, eva);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "ptep=%#jx, flags(npte)=%#jx)",
1.37  pgoyette 	    (uintptr_t)ptep, flags, 0, 0);
 1.1  christos
 1.1  christos 	KASSERT(kpreempt_disabled());
 1.1  christos 	/*
 1.1  christos 	 * Change protection on every valid mapping within this segment.
 1.1  christos 	 */
 1.1  christos 	for (; sva < eva; sva += NBPG, ptep++) {
1.15      matt 		pt_entry_t pte = *ptep;
1.15      matt 		if (!pte_valid_p(pte))
 1.1  christos 			continue;
1.15      matt 		struct vm_page * const pg = PHYS_TO_VM_PAGE(pte_to_paddr(pte));
1.15      matt 		if (pg != NULL && pte_modified_p(pte)) {
 1.1  christos 			struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
 1.1  christos 			if (VM_PAGEMD_EXECPAGE_P(mdpg)) {
 1.1  christos 				KASSERT(mdpg->mdpg_first.pv_pmap != NULL);
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 				if (VM_PAGEMD_CACHED_P(mdpg)) {
1.15      matt #endif
 1.1  christos 					UVMHIST_LOG(pmapexechist,
1.37  pgoyette 					    "pg %#jx (pa %#jx): "
1.28       mrg 					    "syncicached performed",
1.37  pgoyette 					    (uintptr_t)pg, VM_PAGE_TO_PHYS(pg),
1.37  pgoyette 					    0, 0);
 1.1  christos 					pmap_page_syncicache(pg);
 1.1  christos 					PMAP_COUNT(exec_synced_protect);
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
 1.1  christos 				}
1.15      matt #endif
 1.1  christos 			}
 1.1  christos 		}
1.15      matt 		pte = pte_prot_downgrade(pte, prot);
1.15      matt 		if (*ptep != pte) {
1.10    nonaka 			pmap_md_tlb_miss_lock_enter();
1.35     skrll 			pte_set(ptep, pte);
 1.1  christos 			/*
 1.1  christos 			 * Update the TLB if needed.
 1.1  christos 			 */
1.15      matt 			pmap_tlb_update_addr(pmap, sva, pte, PMAP_TLB_NEED_IPI);
1.10    nonaka 			pmap_md_tlb_miss_lock_exit();
 1.1  christos 		}
 1.1  christos 	}
1.15      matt
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
1.15      matt
 1.1  christos 	return false;
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Set the physical protection on the
 1.1  christos  *	specified range of this map as requested.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_protect(pmap_t pmap, vaddr_t sva, vaddr_t eva, vm_prot_t prot)
 1.1  christos {
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pmap=%#jx, va=%#jx..%#jx, prot=%ju)",
1.37  pgoyette 	    (uintptr_t)pmap, sva, eva, prot);
 1.1  christos 	PMAP_COUNT(protect);
 1.1  christos
 1.1  christos 	if ((prot & VM_PROT_READ) == VM_PROT_NONE) {
 1.1  christos 		pmap_remove(pmap, sva, eva);
1.15      matt 		UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos 		return;
 1.1  christos 	}
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Change protection on every valid mapping within this segment.
 1.1  christos 	 */
 1.1  christos 	kpreempt_disable();
1.15      matt 	pmap_addr_range_check(pmap, sva, eva, __func__);
 1.1  christos 	pmap_pte_process(pmap, sva, eva, pmap_pte_protect, prot);
 1.1  christos 	kpreempt_enable();
 1.1  christos
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
1.15      matt #if defined(PMAP_VIRTUAL_CACHE_ALIASES) && !defined(PMAP_NO_PV_UNCACHED)
 1.1  christos /*
 1.1  christos  *	pmap_page_cache:
 1.1  christos  *
 1.1  christos  *	Change all mappings of a managed page to cached/uncached.
 1.1  christos  */
1.15      matt void
 1.1  christos pmap_page_cache(struct vm_page *pg, bool cached)
 1.1  christos {
 1.1  christos 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
1.15      matt
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pg=%#jx (pa %#jx) cached=%jd)",
1.37  pgoyette 	    (uintptr_t)pg, VM_PAGE_TO_PHYS(pg), cached, 0);
1.15      matt
 1.1  christos 	KASSERT(kpreempt_disabled());
1.15      matt 	KASSERT(VM_PAGEMD_PVLIST_LOCKED_P(mdpg));
 1.1  christos
 1.1  christos 	if (cached) {
 1.1  christos 		pmap_page_clear_attributes(mdpg, VM_PAGEMD_UNCACHED);
 1.1  christos 		PMAP_COUNT(page_cache_restorations);
 1.1  christos 	} else {
 1.1  christos 		pmap_page_set_attributes(mdpg, VM_PAGEMD_UNCACHED);
 1.1  christos 		PMAP_COUNT(page_cache_evictions);
 1.1  christos 	}
 1.1  christos
1.15      matt 	for (pv_entry_t pv = &mdpg->mdpg_first; pv != NULL; pv = pv->pv_next) {
 1.1  christos 		pmap_t pmap = pv->pv_pmap;
1.15      matt 		vaddr_t va = trunc_page(pv->pv_va);
 1.1  christos
 1.1  christos 		KASSERT(pmap != NULL);
 1.1  christos 		KASSERT(pmap != pmap_kernel() || !pmap_md_direct_mapped_vaddr_p(va));
 1.1  christos 		pt_entry_t * const ptep = pmap_pte_lookup(pmap, va);
 1.1  christos 		if (ptep == NULL)
 1.1  christos 			continue;
1.15      matt 		pt_entry_t pte = *ptep;
1.15      matt 		if (pte_valid_p(pte)) {
1.15      matt 			pte = pte_cached_change(pte, cached);
1.10    nonaka 			pmap_md_tlb_miss_lock_enter();
1.35     skrll 			pte_set(ptep, pte);
1.15      matt 			pmap_tlb_update_addr(pmap, va, pte, PMAP_TLB_NEED_IPI);
1.10    nonaka 			pmap_md_tlb_miss_lock_exit();
 1.1  christos 		}
 1.1  christos 	}
1.15      matt
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
1.15      matt #endif	/* PMAP_VIRTUAL_CACHE_ALIASES && !PMAP_NO_PV_UNCACHED */
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Insert the given physical page (p) at
 1.1  christos  *	the specified virtual address (v) in the
 1.1  christos  *	target physical map with the protection requested.
 1.1  christos  *
 1.1  christos  *	If specified, the page will be wired down, meaning
 1.1  christos  *	that the related pte can not be reclaimed.
 1.1  christos  *
 1.1  christos  *	NB:  This is the only routine which MAY NOT lazy-evaluate
 1.1  christos  *	or lose information.  That is, this routine must actually
 1.1  christos  *	insert this page into the given map NOW.
 1.1  christos  */
 1.1  christos int
 1.1  christos pmap_enter(pmap_t pmap, vaddr_t va, paddr_t pa, vm_prot_t prot, u_int flags)
 1.1  christos {
 1.1  christos 	const bool wired = (flags & PMAP_WIRED) != 0;
 1.1  christos 	const bool is_kernel_pmap_p = (pmap == pmap_kernel());
1.15      matt 	u_int update_flags = (flags & VM_PROT_ALL) != 0 ? PMAP_TLB_INSERT : 0;
 1.1  christos #ifdef UVMHIST
1.15      matt 	struct kern_history * const histp =
 1.1  christos 	    ((prot & VM_PROT_EXECUTE) ? &pmapexechist : &pmaphist);
 1.1  christos #endif
 1.1  christos
1.15      matt 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(*histp);
1.37  pgoyette 	UVMHIST_LOG(*histp, "(pmap=%#jx, va=%#jx, pa=%#jx",
1.37  pgoyette 	    (uintptr_t)pmap, va, pa, 0);
1.37  pgoyette 	UVMHIST_LOG(*histp, "prot=%#jx flags=%#jx)", prot, flags, 0, 0);
 1.1  christos
 1.1  christos 	const bool good_color = PMAP_PAGE_COLOROK_P(pa, va);
 1.1  christos 	if (is_kernel_pmap_p) {
 1.1  christos 		PMAP_COUNT(kernel_mappings);
 1.1  christos 		if (!good_color)
 1.1  christos 			PMAP_COUNT(kernel_mappings_bad);
 1.1  christos 	} else {
 1.1  christos 		PMAP_COUNT(user_mappings);
 1.1  christos 		if (!good_color)
 1.1  christos 			PMAP_COUNT(user_mappings_bad);
 1.1  christos 	}
1.15      matt 	pmap_addr_range_check(pmap, va, va, __func__);
 1.1  christos
1.15      matt 	KASSERTMSG(prot & VM_PROT_READ, "no READ (%#x) in prot %#x",
1.15      matt 	    VM_PROT_READ, prot);
 1.1  christos
 1.1  christos 	struct vm_page * const pg = PHYS_TO_VM_PAGE(pa);
1.15      matt 	struct vm_page_md * const mdpg = (pg ? VM_PAGE_TO_MD(pg) : NULL);
 1.1  christos
 1.1  christos 	if (pg) {
 1.1  christos 		/* Set page referenced/modified status based on flags */
1.15      matt 		if (flags & VM_PROT_WRITE) {
 1.1  christos 			pmap_page_set_attributes(mdpg, VM_PAGEMD_MODIFIED|VM_PAGEMD_REFERENCED);
1.15      matt 		} else if (flags & VM_PROT_ALL) {
 1.1  christos 			pmap_page_set_attributes(mdpg, VM_PAGEMD_REFERENCED);
1.15      matt 		}
 1.1  christos
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 		if (!VM_PAGEMD_CACHED_P(mdpg)) {
 1.1  christos 			flags |= PMAP_NOCACHE;
1.15      matt 			PMAP_COUNT(uncached_mappings);
1.15      matt 		}
 1.1  christos #endif
 1.1  christos
 1.1  christos 		PMAP_COUNT(managed_mappings);
 1.1  christos 	} else {
 1.1  christos 		/*
 1.1  christos 		 * Assumption: if it is not part of our managed memory
 1.1  christos 		 * then it must be device memory which may be volatile.
 1.1  christos 		 */
1.15      matt 		if ((flags & PMAP_CACHE_MASK) == 0)
1.15      matt 			flags |= PMAP_NOCACHE;
 1.1  christos 		PMAP_COUNT(unmanaged_mappings);
 1.1  christos 	}
 1.1  christos
1.15      matt 	pt_entry_t npte = pte_make_enter(pa, mdpg, prot, flags,
1.15      matt 	    is_kernel_pmap_p);
 1.1  christos
 1.1  christos 	kpreempt_disable();
1.15      matt
 1.1  christos 	pt_entry_t * const ptep = pmap_pte_reserve(pmap, va, flags);
 1.1  christos 	if (__predict_false(ptep == NULL)) {
 1.1  christos 		kpreempt_enable();
1.15      matt 		UVMHIST_LOG(*histp, " <-- ENOMEM", 0, 0, 0, 0);
 1.1  christos 		return ENOMEM;
 1.1  christos 	}
1.15      matt 	const pt_entry_t opte = *ptep;
1.24     skrll 	const bool resident = pte_valid_p(opte);
1.24     skrll 	bool remap = false;
1.24     skrll 	if (resident) {
1.24     skrll 		if (pte_to_paddr(opte) != pa) {
1.24     skrll 			KASSERT(!is_kernel_pmap_p);
1.24     skrll 		    	const pt_entry_t rpte = pte_nv_entry(false);
1.24     skrll
1.24     skrll 			pmap_addr_range_check(pmap, va, va + NBPG, __func__);
1.24     skrll 			pmap_pte_process(pmap, va, va + NBPG, pmap_pte_remove,
1.24     skrll 			    rpte);
1.24     skrll 			PMAP_COUNT(user_mappings_changed);
1.24     skrll 			remap = true;
1.24     skrll 		}
1.24     skrll 		update_flags |= PMAP_TLB_NEED_IPI;
1.24     skrll 	}
1.24     skrll
1.24     skrll 	if (!resident || remap) {
1.24     skrll 		pmap->pm_stats.resident_count++;
1.24     skrll 	}
 1.1  christos
 1.1  christos 	/* Done after case that may sleep/return. */
 1.1  christos 	if (pg)
1.15      matt 		pmap_enter_pv(pmap, va, pg, &npte, 0);
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Now validate mapping with desired protection/wiring.
 1.1  christos 	 * Assume uniform modified and referenced status for all
 1.1  christos 	 * MIPS pages in a MACH page.
 1.1  christos 	 */
 1.1  christos 	if (wired) {
 1.1  christos 		pmap->pm_stats.wired_count++;
 1.1  christos 		npte = pte_wire_entry(npte);
 1.1  christos 	}
 1.1  christos
1.37  pgoyette 	UVMHIST_LOG(*histp, "new pte %#jx (pa %#jx)",
1.15      matt 	    pte_value(npte), pa, 0, 0);
 1.1  christos
 1.1  christos 	KASSERT(pte_valid_p(npte));
1.15      matt
1.10    nonaka 	pmap_md_tlb_miss_lock_enter();
1.35     skrll 	pte_set(ptep, npte);
1.15      matt 	pmap_tlb_update_addr(pmap, va, npte, update_flags);
1.10    nonaka 	pmap_md_tlb_miss_lock_exit();
 1.1  christos 	kpreempt_enable();
 1.1  christos
 1.1  christos 	if (pg != NULL && (prot == (VM_PROT_READ | VM_PROT_EXECUTE))) {
 1.1  christos 		KASSERT(mdpg != NULL);
 1.1  christos 		PMAP_COUNT(exec_mappings);
 1.1  christos 		if (!VM_PAGEMD_EXECPAGE_P(mdpg) && pte_cached_p(npte)) {
 1.1  christos 			if (!pte_deferred_exec_p(npte)) {
1.37  pgoyette 				UVMHIST_LOG(*histp, "va=%#jx pg %#jx: "
1.37  pgoyette 				    "immediate syncicache",
1.37  pgoyette 				    va, (uintptr_t)pg, 0, 0);
 1.1  christos 				pmap_page_syncicache(pg);
 1.1  christos 				pmap_page_set_attributes(mdpg,
 1.1  christos 				    VM_PAGEMD_EXECPAGE);
 1.1  christos 				PMAP_COUNT(exec_synced_mappings);
 1.1  christos 			} else {
1.37  pgoyette 				UVMHIST_LOG(*histp, "va=%#jx pg %#jx: defer "
1.37  pgoyette 				    "syncicache: pte %#jx",
1.37  pgoyette 				    va, (uintptr_t)pg, npte, 0);
 1.1  christos 			}
 1.1  christos 		} else {
 1.1  christos 			UVMHIST_LOG(*histp,
1.37  pgoyette 			    "va=%#jx pg %#jx: no syncicache cached %jd",
1.37  pgoyette 			    va, (uintptr_t)pg, pte_cached_p(npte), 0);
 1.1  christos 		}
 1.1  christos 	} else if (pg != NULL && (prot & VM_PROT_EXECUTE)) {
 1.1  christos 		KASSERT(mdpg != NULL);
 1.1  christos 		KASSERT(prot & VM_PROT_WRITE);
 1.1  christos 		PMAP_COUNT(exec_mappings);
 1.1  christos 		pmap_page_syncicache(pg);
 1.1  christos 		pmap_page_clear_attributes(mdpg, VM_PAGEMD_EXECPAGE);
1.15      matt 		UVMHIST_LOG(*histp,
1.37  pgoyette 		    "va=%#jx pg %#jx: immediate syncicache (writeable)",
1.37  pgoyette 		    va, (uintptr_t)pg, 0, 0);
 1.1  christos 	}
 1.1  christos
1.15      matt 	UVMHIST_LOG(*histp, " <-- 0 (OK)", 0, 0, 0, 0);
 1.1  christos 	return 0;
 1.1  christos }
 1.1  christos
 1.1  christos void
 1.1  christos pmap_kenter_pa(vaddr_t va, paddr_t pa, vm_prot_t prot, u_int flags)
 1.1  christos {
1.15      matt 	pmap_t pmap = pmap_kernel();
 1.1  christos 	struct vm_page * const pg = PHYS_TO_VM_PAGE(pa);
1.15      matt 	struct vm_page_md * const mdpg = (pg ? VM_PAGE_TO_MD(pg) : NULL);
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(va=%#jx pa=%#jx prot=%ju, flags=%#jx)",
1.15      matt 	    va, pa, prot, flags);
 1.1  christos 	PMAP_COUNT(kenter_pa);
 1.1  christos
1.15      matt 	if (mdpg == NULL) {
 1.1  christos 		PMAP_COUNT(kenter_pa_unmanaged);
1.15      matt 		if ((flags & PMAP_CACHE_MASK) == 0)
1.15      matt 			flags |= PMAP_NOCACHE;
 1.1  christos 	} else {
1.15      matt 		if ((flags & PMAP_NOCACHE) == 0 && !PMAP_PAGE_COLOROK_P(pa, va))
1.15      matt 			PMAP_COUNT(kenter_pa_bad);
 1.1  christos 	}
 1.1  christos
1.15      matt 	pt_entry_t npte = pte_make_kenter_pa(pa, mdpg, prot, flags);
 1.1  christos 	kpreempt_disable();
1.15      matt 	pt_entry_t * const ptep = pmap_pte_lookup(pmap, va);
1.15      matt 	KASSERTMSG(ptep != NULL, "%#"PRIxVADDR " %#"PRIxVADDR, va,
1.15      matt 	    pmap_limits.virtual_end);
 1.1  christos 	KASSERT(!pte_valid_p(*ptep));
1.15      matt
1.15      matt 	/*
1.15      matt 	 * No need to track non-managed pages or PMAP_KMPAGEs pages for aliases
1.15      matt 	 */
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.20      matt 	if (pg != NULL && (flags & PMAP_KMPAGE) == 0
1.20      matt 	    && pmap_md_virtual_cache_aliasing_p()) {
1.15      matt 		pmap_enter_pv(pmap, va, pg, &npte, PV_KENTER);
1.15      matt 	}
1.15      matt #endif
1.15      matt
 1.1  christos 	/*
 1.1  christos 	 * We have the option to force this mapping into the TLB but we
 1.1  christos 	 * don't.  Instead let the next reference to the page do it.
 1.1  christos 	 */
1.15      matt 	pmap_md_tlb_miss_lock_enter();
1.35     skrll 	pte_set(ptep, npte);
 1.1  christos 	pmap_tlb_update_addr(pmap_kernel(), va, npte, 0);
1.10    nonaka 	pmap_md_tlb_miss_lock_exit();
 1.1  christos 	kpreempt_enable();
 1.1  christos #if DEBUG > 1
 1.1  christos 	for (u_int i = 0; i < PAGE_SIZE / sizeof(long); i++) {
 1.1  christos 		if (((long *)va)[i] != ((long *)pa)[i])
 1.1  christos 			panic("%s: contents (%lx) of va %#"PRIxVADDR
 1.1  christos 			    " != contents (%lx) of pa %#"PRIxPADDR, __func__,
 1.1  christos 			    ((long *)va)[i], va, ((long *)pa)[i], pa);
 1.1  christos 	}
 1.1  christos #endif
1.15      matt
1.37  pgoyette 	UVMHIST_LOG(pmaphist, " <-- done (ptep=%#jx)", (uintptr_t)ptep, 0, 0,
1.37  pgoyette 	    0);
 1.1  christos }
 1.1  christos
1.15      matt /*
1.15      matt  *	Remove the given range of addresses from the kernel map.
1.15      matt  *
1.15      matt  *	It is assumed that the start and end are properly
1.15      matt  *	rounded to the page size.
1.15      matt  */
1.15      matt
 1.1  christos static bool
 1.1  christos pmap_pte_kremove(pmap_t pmap, vaddr_t sva, vaddr_t eva, pt_entry_t *ptep,
 1.1  christos 	uintptr_t flags)
 1.1  christos {
1.15      matt 	const pt_entry_t new_pte = pte_nv_entry(true);
1.15      matt
1.15      matt 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.15      matt 	UVMHIST_LOG(pmaphist,
1.37  pgoyette 	    "(pmap=%#jx, sva=%#jx eva=%#jx ptep=%#jx)",
1.37  pgoyette 	    (uintptr_t)pmap, sva, eva, (uintptr_t)ptep);
 1.1  christos
 1.1  christos 	KASSERT(kpreempt_disabled());
 1.1  christos
 1.1  christos 	for (; sva < eva; sva += NBPG, ptep++) {
1.15      matt 		pt_entry_t pte = *ptep;
1.15      matt 		if (!pte_valid_p(pte))
 1.1  christos 			continue;
 1.1  christos
 1.1  christos 		PMAP_COUNT(kremove_pages);
1.21       mrg #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 		struct vm_page * const pg = PHYS_TO_VM_PAGE(pte_to_paddr(pte));
1.20      matt 		if (pg != NULL && pmap_md_virtual_cache_aliasing_p()) {
1.15      matt 			pmap_remove_pv(pmap, sva, pg, !pte_readonly_p(pte));
1.15      matt 		}
1.20      matt #endif
 1.1  christos
1.10    nonaka 		pmap_md_tlb_miss_lock_enter();
1.35     skrll 		pte_set(ptep, new_pte);
1.15      matt 		pmap_tlb_invalidate_addr(pmap, sva);
1.10    nonaka 		pmap_md_tlb_miss_lock_exit();
 1.1  christos 	}
 1.1  christos
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
1.15      matt
 1.1  christos 	return false;
 1.1  christos }
 1.1  christos
 1.1  christos void
 1.1  christos pmap_kremove(vaddr_t va, vsize_t len)
 1.1  christos {
 1.1  christos 	const vaddr_t sva = trunc_page(va);
 1.1  christos 	const vaddr_t eva = round_page(va + len);
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(va=%#jx len=%#jx)", va, len, 0, 0);
 1.1  christos
 1.1  christos 	kpreempt_disable();
 1.1  christos 	pmap_pte_process(pmap_kernel(), sva, eva, pmap_pte_kremove, 0);
 1.1  christos 	kpreempt_enable();
 1.1  christos
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos void
 1.1  christos pmap_remove_all(struct pmap *pmap)
 1.1  christos {
1.15      matt 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pm=%#jx)", (uintptr_t)pmap, 0, 0, 0);
1.15      matt
 1.1  christos 	KASSERT(pmap != pmap_kernel());
 1.1  christos
 1.1  christos 	kpreempt_disable();
 1.1  christos 	/*
 1.1  christos 	 * Free all of our ASIDs which means we can skip doing all the
 1.1  christos 	 * tlb_invalidate_addrs().
 1.1  christos 	 */
1.10    nonaka 	pmap_md_tlb_miss_lock_enter();
1.15      matt #ifdef MULTIPROCESSOR
1.15      matt 	// This should be the last CPU with this pmap onproc
1.15      matt 	KASSERT(!kcpuset_isotherset(pmap->pm_onproc, cpu_index(curcpu())));
1.15      matt 	if (kcpuset_isset(pmap->pm_onproc, cpu_index(curcpu())))
1.15      matt #endif
1.15      matt 		pmap_tlb_asid_deactivate(pmap);
1.15      matt #ifdef MULTIPROCESSOR
1.15      matt 	KASSERT(kcpuset_iszero(pmap->pm_onproc));
1.15      matt #endif
 1.1  christos 	pmap_tlb_asid_release_all(pmap);
1.10    nonaka 	pmap_md_tlb_miss_lock_exit();
 1.1  christos 	pmap->pm_flags |= PMAP_DEFERRED_ACTIVATE;
 1.1  christos
1.15      matt #ifdef PMAP_FAULTINFO
1.15      matt 	curpcb->pcb_faultinfo.pfi_faultaddr = 0;
1.15      matt 	curpcb->pcb_faultinfo.pfi_repeats = 0;
1.15      matt 	curpcb->pcb_faultinfo.pfi_faultpte = NULL;
1.15      matt #endif
 1.1  christos 	kpreempt_enable();
1.15      matt
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Routine:	pmap_unwire
 1.1  christos  *	Function:	Clear the wired attribute for a map/virtual-address
 1.1  christos  *			pair.
 1.1  christos  *	In/out conditions:
 1.1  christos  *			The mapping must already exist in the pmap.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_unwire(pmap_t pmap, vaddr_t va)
 1.1  christos {
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pmap=%#jx, va=%#jx)", (uintptr_t)pmap, va,
1.37  pgoyette 	    0, 0);
 1.1  christos 	PMAP_COUNT(unwire);
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Don't need to flush the TLB since PG_WIRED is only in software.
 1.1  christos 	 */
 1.1  christos 	kpreempt_disable();
1.15      matt 	pmap_addr_range_check(pmap, va, va, __func__);
 1.1  christos 	pt_entry_t * const ptep = pmap_pte_lookup(pmap, va);
1.15      matt 	KASSERTMSG(ptep != NULL, "pmap %p va %#"PRIxVADDR" invalid STE",
1.15      matt 	    pmap, va);
1.15      matt 	pt_entry_t pte = *ptep;
1.15      matt 	KASSERTMSG(pte_valid_p(pte),
1.15      matt 	    "pmap %p va %#"PRIxVADDR" invalid PTE %#"PRIxPTE" @ %p",
1.15      matt 	    pmap, va, pte_value(pte), ptep);
 1.1  christos
1.15      matt 	if (pte_wired_p(pte)) {
1.10    nonaka 		pmap_md_tlb_miss_lock_enter();
1.35     skrll 		pte_set(ptep, pte_unwire_entry(pte));
1.10    nonaka 		pmap_md_tlb_miss_lock_exit();
 1.1  christos 		pmap->pm_stats.wired_count--;
 1.1  christos 	}
 1.1  christos #ifdef DIAGNOSTIC
 1.1  christos 	else {
 1.1  christos 		printf("%s: wiring for pmap %p va %#"PRIxVADDR" unchanged!\n",
 1.1  christos 		    __func__, pmap, va);
 1.1  christos 	}
 1.1  christos #endif
 1.1  christos 	kpreempt_enable();
1.15      matt
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Routine:	pmap_extract
 1.1  christos  *	Function:
 1.1  christos  *		Extract the physical page address associated
 1.1  christos  *		with the given map/virtual_address pair.
 1.1  christos  */
 1.1  christos bool
 1.1  christos pmap_extract(pmap_t pmap, vaddr_t va, paddr_t *pap)
 1.1  christos {
 1.1  christos 	paddr_t pa;
 1.1  christos
 1.1  christos 	if (pmap == pmap_kernel()) {
 1.1  christos 		if (pmap_md_direct_mapped_vaddr_p(va)) {
 1.1  christos 			pa = pmap_md_direct_mapped_vaddr_to_paddr(va);
 1.1  christos 			goto done;
 1.1  christos 		}
 1.1  christos 		if (pmap_md_io_vaddr_p(va))
 1.1  christos 			panic("pmap_extract: io address %#"PRIxVADDR"", va);
1.15      matt
1.15      matt 		if (va >= pmap_limits.virtual_end)
1.15      matt 			panic("%s: illegal kernel mapped address %#"PRIxVADDR,
1.15      matt 			    __func__, va);
 1.1  christos 	}
 1.1  christos 	kpreempt_disable();
1.15      matt 	const pt_entry_t * const ptep = pmap_pte_lookup(pmap, va);
1.15      matt 	if (ptep == NULL || !pte_valid_p(*ptep)) {
 1.1  christos 		kpreempt_enable();
 1.1  christos 		return false;
 1.1  christos 	}
 1.1  christos 	pa = pte_to_paddr(*ptep) | (va & PGOFSET);
 1.1  christos 	kpreempt_enable();
 1.1  christos done:
 1.1  christos 	if (pap != NULL) {
 1.1  christos 		*pap = pa;
 1.1  christos 	}
 1.1  christos 	return true;
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Copy the range specified by src_addr/len
 1.1  christos  *	from the source map to the range dst_addr/len
 1.1  christos  *	in the destination map.
 1.1  christos  *
 1.1  christos  *	This routine is only advisory and need not do anything.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_copy(pmap_t dst_pmap, pmap_t src_pmap, vaddr_t dst_addr, vsize_t len,
 1.1  christos     vaddr_t src_addr)
 1.1  christos {
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
 1.1  christos 	PMAP_COUNT(copy);
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	pmap_clear_reference:
 1.1  christos  *
 1.1  christos  *	Clear the reference bit on the specified physical page.
 1.1  christos  */
 1.1  christos bool
 1.1  christos pmap_clear_reference(struct vm_page *pg)
 1.1  christos {
 1.1  christos 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pg=%#jx (pa %#jx))",
1.37  pgoyette 	   (uintptr_t)pg, VM_PAGE_TO_PHYS(pg), 0,0);
 1.1  christos
 1.1  christos 	bool rv = pmap_page_clear_attributes(mdpg, VM_PAGEMD_REFERENCED);
 1.1  christos
1.37  pgoyette 	UVMHIST_LOG(pmaphist, " <-- wasref %ju", rv, 0, 0, 0);
 1.1  christos
 1.1  christos 	return rv;
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	pmap_is_referenced:
 1.1  christos  *
 1.1  christos  *	Return whether or not the specified physical page is referenced
 1.1  christos  *	by any physical maps.
 1.1  christos  */
 1.1  christos bool
 1.1  christos pmap_is_referenced(struct vm_page *pg)
 1.1  christos {
 1.1  christos 	return VM_PAGEMD_REFERENCED_P(VM_PAGE_TO_MD(pg));
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	Clear the modify bits on the specified physical page.
 1.1  christos  */
 1.1  christos bool
 1.1  christos pmap_clear_modify(struct vm_page *pg)
 1.1  christos {
 1.1  christos 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
 1.1  christos 	pv_entry_t pv = &mdpg->mdpg_first;
 1.1  christos 	pv_entry_t pv_next;
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "(pg=%#jx (%#jx))",
1.37  pgoyette 	    (uintptr_t)pg, VM_PAGE_TO_PHYS(pg), 0,0);
 1.1  christos 	PMAP_COUNT(clear_modify);
 1.1  christos
 1.1  christos 	if (VM_PAGEMD_EXECPAGE_P(mdpg)) {
 1.1  christos 		if (pv->pv_pmap == NULL) {
 1.1  christos 			UVMHIST_LOG(pmapexechist,
1.37  pgoyette 			    "pg %#jx (pa %#jx): execpage cleared",
1.37  pgoyette 			    (uintptr_t)pg, VM_PAGE_TO_PHYS(pg), 0, 0);
 1.1  christos 			pmap_page_clear_attributes(mdpg, VM_PAGEMD_EXECPAGE);
 1.1  christos 			PMAP_COUNT(exec_uncached_clear_modify);
 1.1  christos 		} else {
 1.1  christos 			UVMHIST_LOG(pmapexechist,
1.37  pgoyette 			    "pg %#jx (pa %#jx): syncicache performed",
1.37  pgoyette 			    (uintptr_t)pg, VM_PAGE_TO_PHYS(pg), 0, 0);
 1.1  christos 			pmap_page_syncicache(pg);
 1.1  christos 			PMAP_COUNT(exec_synced_clear_modify);
 1.1  christos 		}
 1.1  christos 	}
 1.1  christos 	if (!pmap_page_clear_attributes(mdpg, VM_PAGEMD_MODIFIED)) {
1.15      matt 		UVMHIST_LOG(pmaphist, " <-- false", 0, 0, 0, 0);
 1.1  christos 		return false;
 1.1  christos 	}
 1.1  christos 	if (pv->pv_pmap == NULL) {
1.15      matt 		UVMHIST_LOG(pmaphist, " <-- true (no mappings)", 0, 0, 0, 0);
 1.1  christos 		return true;
 1.1  christos 	}
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * remove write access from any pages that are dirty
 1.1  christos 	 * so we can tell if they are written to again later.
 1.1  christos 	 * flush the VAC first if there is one.
 1.1  christos 	 */
 1.1  christos 	kpreempt_disable();
1.15      matt 	KASSERT(!VM_PAGEMD_PVLIST_LOCKED_P(mdpg));
1.15      matt 	VM_PAGEMD_PVLIST_READLOCK(mdpg);
1.15      matt 	pmap_pvlist_check(mdpg);
 1.1  christos 	for (; pv != NULL; pv = pv_next) {
 1.1  christos 		pmap_t pmap = pv->pv_pmap;
1.15      matt 		vaddr_t va = trunc_page(pv->pv_va);
1.15      matt
1.15      matt 		pv_next = pv->pv_next;
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 		if (pv->pv_va & PV_KENTER)
1.15      matt 			continue;
1.15      matt #endif
 1.1  christos 		pt_entry_t * const ptep = pmap_pte_lookup(pmap, va);
 1.1  christos 		KASSERT(ptep);
1.15      matt 		pt_entry_t pte = pte_prot_nowrite(*ptep);
1.15      matt 		if (*ptep == pte) {
 1.1  christos 			continue;
 1.1  christos 		}
1.15      matt 		KASSERT(pte_valid_p(pte));
1.15      matt 		const uintptr_t gen = VM_PAGEMD_PVLIST_UNLOCK(mdpg);
1.10    nonaka 		pmap_md_tlb_miss_lock_enter();
1.35     skrll 		pte_set(ptep, pte);
 1.1  christos 		pmap_tlb_invalidate_addr(pmap, va);
1.10    nonaka 		pmap_md_tlb_miss_lock_exit();
 1.1  christos 		pmap_update(pmap);
1.15      matt 		if (__predict_false(gen != VM_PAGEMD_PVLIST_READLOCK(mdpg))) {
 1.1  christos 			/*
 1.1  christos 			 * The list changed!  So restart from the beginning.
 1.1  christos 			 */
 1.1  christos 			pv_next = &mdpg->mdpg_first;
1.15      matt 			pmap_pvlist_check(mdpg);
 1.1  christos 		}
 1.1  christos 	}
1.15      matt 	pmap_pvlist_check(mdpg);
 1.1  christos 	VM_PAGEMD_PVLIST_UNLOCK(mdpg);
 1.1  christos 	kpreempt_enable();
 1.1  christos
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- true (mappings changed)", 0, 0, 0, 0);
 1.1  christos 	return true;
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	pmap_is_modified:
 1.1  christos  *
 1.1  christos  *	Return whether or not the specified physical page is modified
 1.1  christos  *	by any physical maps.
 1.1  christos  */
 1.1  christos bool
 1.1  christos pmap_is_modified(struct vm_page *pg)
 1.1  christos {
 1.1  christos 	return VM_PAGEMD_MODIFIED_P(VM_PAGE_TO_MD(pg));
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  *	pmap_set_modified:
 1.1  christos  *
 1.1  christos  *	Sets the page modified reference bit for the specified page.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_set_modified(paddr_t pa)
 1.1  christos {
 1.1  christos 	struct vm_page * const pg = PHYS_TO_VM_PAGE(pa);
 1.1  christos 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
 1.1  christos 	pmap_page_set_attributes(mdpg, VM_PAGEMD_MODIFIED|VM_PAGEMD_REFERENCED);
 1.1  christos }
 1.1  christos
 1.1  christos /******************** pv_entry management ********************/
 1.1  christos
 1.1  christos static void
1.15      matt pmap_pvlist_check(struct vm_page_md *mdpg)
 1.1  christos {
1.15      matt #ifdef DEBUG
1.15      matt 	pv_entry_t pv = &mdpg->mdpg_first;
 1.1  christos 	if (pv->pv_pmap != NULL) {
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 		const u_int colormask = uvmexp.colormask;
1.15      matt 		u_int colors = 0;
1.15      matt #endif
 1.1  christos 		for (; pv != NULL; pv = pv->pv_next) {
1.15      matt 			KASSERT(pv->pv_pmap != pmap_kernel() || !pmap_md_direct_mapped_vaddr_p(pv->pv_va));
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 			colors |= __BIT(atop(pv->pv_va) & colormask);
1.15      matt #endif
 1.1  christos 		}
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.30     skrll 		// Assert that if there is more than 1 color mapped, that the
1.30     skrll 		// page is uncached.
1.15      matt 		KASSERTMSG(!pmap_md_virtual_cache_aliasing_p()
1.15      matt 		    || colors == 0 || (colors & (colors-1)) == 0
1.15      matt 		    || VM_PAGEMD_UNCACHED_P(mdpg), "colors=%#x uncached=%u",
1.15      matt 		    colors, VM_PAGEMD_UNCACHED_P(mdpg));
1.15      matt #endif
1.34     skrll 	} else {
1.34     skrll     		KASSERT(pv->pv_next == NULL);
 1.1  christos 	}
1.15      matt #endif /* DEBUG */
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  * Enter the pmap and virtual address into the
 1.1  christos  * physical to virtual map table.
 1.1  christos  */
 1.1  christos void
1.15      matt pmap_enter_pv(pmap_t pmap, vaddr_t va, struct vm_page *pg, pt_entry_t *nptep,
1.15      matt     u_int flags)
 1.1  christos {
 1.1  christos 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
 1.1  christos 	pv_entry_t pv, npv, apv;
1.15      matt #ifdef UVMHIST
1.15      matt 	bool first = false;
1.15      matt #endif
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
 1.1  christos 	UVMHIST_LOG(pmaphist,
1.37  pgoyette 	    "(pmap=%#jx va=%#jx pg=%#jx (%#jx)",
1.37  pgoyette 	    (uintptr_t)pmap, va, (uintptr_t)pg, VM_PAGE_TO_PHYS(pg));
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "nptep=%#jx (%#jx))",
1.37  pgoyette 	    (uintptr_t)nptep, pte_value(*nptep), 0, 0);
 1.1  christos
 1.1  christos 	KASSERT(kpreempt_disabled());
 1.1  christos 	KASSERT(pmap != pmap_kernel() || !pmap_md_direct_mapped_vaddr_p(va));
1.15      matt 	KASSERTMSG(pmap != pmap_kernel() || !pmap_md_io_vaddr_p(va),
1.15      matt 	    "va %#"PRIxVADDR, va);
 1.1  christos
 1.1  christos 	apv = NULL;
1.15      matt 	VM_PAGEMD_PVLIST_LOCK(mdpg);
1.15      matt again:
 1.1  christos 	pv = &mdpg->mdpg_first;
1.15      matt 	pmap_pvlist_check(mdpg);
 1.1  christos 	if (pv->pv_pmap == NULL) {
 1.1  christos 		KASSERT(pv->pv_next == NULL);
 1.1  christos 		/*
 1.1  christos 		 * No entries yet, use header as the first entry
 1.1  christos 		 */
 1.1  christos 		PMAP_COUNT(primary_mappings);
 1.1  christos 		PMAP_COUNT(mappings);
1.15      matt #ifdef UVMHIST
 1.1  christos 		first = true;
1.15      matt #endif
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 		KASSERT(VM_PAGEMD_CACHED_P(mdpg));
1.15      matt 		// If the new mapping has an incompatible color the last
1.15      matt 		// mapping of this page, clean the page before using it.
1.15      matt 		if (!PMAP_PAGE_COLOROK_P(va, pv->pv_va)) {
1.15      matt 			pmap_md_vca_clean(pg, PMAP_WBINV);
1.15      matt 		}
 1.1  christos #endif
 1.1  christos 		pv->pv_pmap = pmap;
1.15      matt 		pv->pv_va = va | flags;
 1.1  christos 	} else {
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 		if (pmap_md_vca_add(pg, va, nptep)) {
 1.1  christos 			goto again;
1.15      matt 		}
1.15      matt #endif
 1.1  christos
 1.1  christos 		/*
 1.1  christos 		 * There is at least one other VA mapping this page.
 1.1  christos 		 * Place this entry after the header.
 1.1  christos 		 *
 1.1  christos 		 * Note: the entry may already be in the table if
 1.1  christos 		 * we are only changing the protection bits.
 1.1  christos 		 */
 1.1  christos
 1.1  christos #ifdef PARANOIADIAG
 1.1  christos 		const paddr_t pa = VM_PAGE_TO_PHYS(pg);
 1.1  christos #endif
 1.1  christos 		for (npv = pv; npv; npv = npv->pv_next) {
1.15      matt 			if (pmap == npv->pv_pmap
1.15      matt 			    && va == trunc_page(npv->pv_va)) {
 1.1  christos #ifdef PARANOIADIAG
 1.1  christos 				pt_entry_t *ptep = pmap_pte_lookup(pmap, va);
1.15      matt 				pt_entry_t pte = (ptep != NULL) ? *ptep : 0;
1.15      matt 				if (!pte_valid_p(pte) || pte_to_paddr(pte) != pa)
1.15      matt 					printf("%s: found va %#"PRIxVADDR
1.15      matt 					    " pa %#"PRIxPADDR
1.15      matt 					    " in pv_table but != %#"PRIxPTE"\n",
1.15      matt 					    __func__, va, pa, pte_value(pte));
 1.1  christos #endif
 1.1  christos 				PMAP_COUNT(remappings);
 1.1  christos 				VM_PAGEMD_PVLIST_UNLOCK(mdpg);
 1.1  christos 				if (__predict_false(apv != NULL))
 1.1  christos 					pmap_pv_free(apv);
1.15      matt
1.37  pgoyette 				UVMHIST_LOG(pmaphist,
1.37  pgoyette 				    " <-- done pv=%#jx (reused)",
1.37  pgoyette 				    (uintptr_t)pv, 0, 0, 0);
 1.1  christos 				return;
 1.1  christos 			}
 1.1  christos 		}
 1.1  christos 		if (__predict_true(apv == NULL)) {
 1.1  christos 			/*
 1.1  christos 			 * To allocate a PV, we have to release the PVLIST lock
 1.1  christos 			 * so get the page generation.  We allocate the PV, and
1.15      matt 			 * then reacquire the lock.
 1.1  christos 			 */
1.15      matt 			pmap_pvlist_check(mdpg);
1.15      matt 			const uintptr_t gen = VM_PAGEMD_PVLIST_UNLOCK(mdpg);
 1.1  christos
 1.1  christos 			apv = (pv_entry_t)pmap_pv_alloc();
 1.1  christos 			if (apv == NULL)
 1.1  christos 				panic("pmap_enter_pv: pmap_pv_alloc() failed");
 1.1  christos
 1.1  christos 			/*
 1.1  christos 			 * If the generation has changed, then someone else
1.15      matt 			 * tinkered with this page so we should start over.
 1.1  christos 			 */
1.15      matt 			if (gen != VM_PAGEMD_PVLIST_LOCK(mdpg))
 1.1  christos 				goto again;
 1.1  christos 		}
 1.1  christos 		npv = apv;
 1.1  christos 		apv = NULL;
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 		/*
1.15      matt 		 * If need to deal with virtual cache aliases, keep mappings
1.15      matt 		 * in the kernel pmap at the head of the list.  This allows
1.15      matt 		 * the VCA code to easily use them for cache operations if
1.15      matt 		 * present.
1.15      matt 		 */
1.15      matt 		pmap_t kpmap = pmap_kernel();
1.15      matt 		if (pmap != kpmap) {
1.15      matt 			while (pv->pv_pmap == kpmap && pv->pv_next != NULL) {
1.15      matt 				pv = pv->pv_next;
1.15      matt 			}
1.15      matt 		}
1.15      matt #endif
1.15      matt 		npv->pv_va = va | flags;
 1.1  christos 		npv->pv_pmap = pmap;
 1.1  christos 		npv->pv_next = pv->pv_next;
 1.1  christos 		pv->pv_next = npv;
 1.1  christos 		PMAP_COUNT(mappings);
 1.1  christos 	}
1.15      matt 	pmap_pvlist_check(mdpg);
 1.1  christos 	VM_PAGEMD_PVLIST_UNLOCK(mdpg);
 1.1  christos 	if (__predict_false(apv != NULL))
 1.1  christos 		pmap_pv_free(apv);
 1.1  christos
1.37  pgoyette 	UVMHIST_LOG(pmaphist, " <-- done pv=%#jx (first %ju)", (uintptr_t)pv,
1.37  pgoyette 	    first, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  * Remove a physical to virtual address translation.
 1.1  christos  * If cache was inhibited on this page, and there are no more cache
 1.1  christos  * conflicts, restore caching.
 1.1  christos  * Flush the cache if the last page is removed (should always be cached
 1.1  christos  * at this point).
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_remove_pv(pmap_t pmap, vaddr_t va, struct vm_page *pg, bool dirty)
 1.1  christos {
 1.1  christos 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
 1.1  christos 	pv_entry_t pv, npv;
 1.1  christos 	bool last;
 1.1  christos
 1.1  christos 	UVMHIST_FUNC(__func__); UVMHIST_CALLED(pmaphist);
 1.1  christos 	UVMHIST_LOG(pmaphist,
1.37  pgoyette 	    "(pmap=%#jx, va=%#jx, pg=%#jx (pa %#jx)",
1.37  pgoyette 	    (uintptr_t)pmap, va, (uintptr_t)pg, VM_PAGE_TO_PHYS(pg));
1.37  pgoyette 	UVMHIST_LOG(pmaphist, "dirty=%ju)", dirty, 0, 0, 0);
 1.1  christos
 1.1  christos 	KASSERT(kpreempt_disabled());
1.15      matt 	KASSERT((va & PAGE_MASK) == 0);
 1.1  christos 	pv = &mdpg->mdpg_first;
 1.1  christos
1.15      matt 	VM_PAGEMD_PVLIST_LOCK(mdpg);
1.15      matt 	pmap_pvlist_check(mdpg);
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * If it is the first entry on the list, it is actually
 1.1  christos 	 * in the header and we must copy the following entry up
 1.1  christos 	 * to the header.  Otherwise we must search the list for
 1.1  christos 	 * the entry.  In either case we free the now unused entry.
 1.1  christos 	 */
 1.1  christos
 1.1  christos 	last = false;
1.15      matt 	if (pmap == pv->pv_pmap && va == trunc_page(pv->pv_va)) {
 1.1  christos 		npv = pv->pv_next;
 1.1  christos 		if (npv) {
 1.1  christos 			*pv = *npv;
 1.1  christos 			KASSERT(pv->pv_pmap != NULL);
 1.1  christos 		} else {
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 			pmap_page_clear_attributes(mdpg, VM_PAGEMD_UNCACHED);
 1.1  christos #endif
 1.1  christos 			pv->pv_pmap = NULL;
 1.1  christos 			last = true;	/* Last mapping removed */
 1.1  christos 		}
 1.1  christos 		PMAP_COUNT(remove_pvfirst);
 1.1  christos 	} else {
 1.1  christos 		for (npv = pv->pv_next; npv; pv = npv, npv = npv->pv_next) {
 1.1  christos 			PMAP_COUNT(remove_pvsearch);
1.15      matt 			if (pmap == npv->pv_pmap && va == trunc_page(npv->pv_va))
 1.1  christos 				break;
 1.1  christos 		}
 1.1  christos 		if (npv) {
 1.1  christos 			pv->pv_next = npv->pv_next;
 1.1  christos 		}
 1.1  christos 	}
 1.1  christos
1.15      matt 	pmap_pvlist_check(mdpg);
 1.1  christos 	VM_PAGEMD_PVLIST_UNLOCK(mdpg);
 1.1  christos
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 	pmap_md_vca_remove(pg, va, dirty, last);
1.15      matt #endif
1.15      matt
 1.1  christos 	/*
 1.1  christos 	 * Free the pv_entry if needed.
 1.1  christos 	 */
 1.1  christos 	if (npv)
 1.1  christos 		pmap_pv_free(npv);
 1.1  christos 	if (VM_PAGEMD_EXECPAGE_P(mdpg) && dirty) {
 1.1  christos 		if (last) {
 1.1  christos 			/*
 1.1  christos 			 * If this was the page's last mapping, we no longer
 1.1  christos 			 * care about its execness.
 1.1  christos 			 */
 1.1  christos 			UVMHIST_LOG(pmapexechist,
1.37  pgoyette 			    "pg %#jx (pa %#jx)last %ju: execpage cleared",
1.37  pgoyette 			    (uintptr_t)pg, VM_PAGE_TO_PHYS(pg), last, 0);
 1.1  christos 			pmap_page_clear_attributes(mdpg, VM_PAGEMD_EXECPAGE);
 1.1  christos 			PMAP_COUNT(exec_uncached_remove);
 1.1  christos 		} else {
 1.1  christos 			/*
 1.1  christos 			 * Someone still has it mapped as an executable page
 1.1  christos 			 * so we must sync it.
 1.1  christos 			 */
 1.1  christos 			UVMHIST_LOG(pmapexechist,
1.37  pgoyette 			    "pg %#jx (pa %#jx) last %ju: performed syncicache",
1.37  pgoyette 			    (uintptr_t)pg, VM_PAGE_TO_PHYS(pg), last, 0);
 1.1  christos 			pmap_page_syncicache(pg);
 1.1  christos 			PMAP_COUNT(exec_synced_remove);
 1.1  christos 		}
 1.1  christos 	}
1.15      matt
1.15      matt 	UVMHIST_LOG(pmaphist, " <-- done", 0, 0, 0, 0);
 1.1  christos }
 1.1  christos
 1.1  christos #if defined(MULTIPROCESSOR)
 1.1  christos struct pmap_pvlist_info {
 1.1  christos 	kmutex_t *pli_locks[PAGE_SIZE / 32];
 1.1  christos 	volatile u_int pli_lock_refs[PAGE_SIZE / 32];
 1.1  christos 	volatile u_int pli_lock_index;
 1.1  christos 	u_int pli_lock_mask;
 1.1  christos } pmap_pvlist_info;
 1.1  christos
 1.1  christos void
 1.1  christos pmap_pvlist_lock_init(size_t cache_line_size)
 1.1  christos {
 1.1  christos 	struct pmap_pvlist_info * const pli = &pmap_pvlist_info;
 1.1  christos 	const vaddr_t lock_page = uvm_pageboot_alloc(PAGE_SIZE);
 1.1  christos 	vaddr_t lock_va = lock_page;
 1.1  christos 	if (sizeof(kmutex_t) > cache_line_size) {
 1.1  christos 		cache_line_size = roundup2(sizeof(kmutex_t), cache_line_size);
 1.1  christos 	}
 1.1  christos 	const size_t nlocks = PAGE_SIZE / cache_line_size;
 1.1  christos 	KASSERT((nlocks & (nlocks - 1)) == 0);
 1.1  christos 	/*
 1.1  christos 	 * Now divide the page into a number of mutexes, one per cacheline.
 1.1  christos 	 */
 1.1  christos 	for (size_t i = 0; i < nlocks; lock_va += cache_line_size, i++) {
 1.1  christos 		kmutex_t * const lock = (kmutex_t *)lock_va;
1.15      matt 		mutex_init(lock, MUTEX_DEFAULT, IPL_HIGH);
 1.1  christos 		pli->pli_locks[i] = lock;
 1.1  christos 	}
 1.1  christos 	pli->pli_lock_mask = nlocks - 1;
 1.1  christos }
 1.1  christos
1.15      matt kmutex_t *
1.15      matt pmap_pvlist_lock_addr(struct vm_page_md *mdpg)
 1.1  christos {
 1.1  christos 	struct pmap_pvlist_info * const pli = &pmap_pvlist_info;
 1.1  christos 	kmutex_t *lock = mdpg->mdpg_lock;
 1.1  christos
 1.1  christos 	/*
 1.1  christos 	 * Allocate a lock on an as-needed basis.  This will hopefully give us
 1.1  christos 	 * semi-random distribution not based on page color.
 1.1  christos 	 */
 1.1  christos 	if (__predict_false(lock == NULL)) {
 1.1  christos 		size_t locknum = atomic_add_int_nv(&pli->pli_lock_index, 37);
 1.1  christos 		size_t lockid = locknum & pli->pli_lock_mask;
 1.1  christos 		kmutex_t * const new_lock = pli->pli_locks[lockid];
 1.1  christos 		/*
 1.1  christos 		 * Set the lock.  If some other thread already did, just use
 1.1  christos 		 * the one they assigned.
 1.1  christos 		 */
 1.1  christos 		lock = atomic_cas_ptr(&mdpg->mdpg_lock, NULL, new_lock);
 1.1  christos 		if (lock == NULL) {
 1.1  christos 			lock = new_lock;
 1.1  christos 			atomic_inc_uint(&pli->pli_lock_refs[lockid]);
 1.1  christos 		}
 1.1  christos 	}
 1.1  christos
 1.1  christos 	/*
1.15      matt 	 * Now finally provide the lock.
 1.1  christos 	 */
1.15      matt 	return lock;
 1.1  christos }
 1.1  christos #else /* !MULTIPROCESSOR */
 1.1  christos void
 1.1  christos pmap_pvlist_lock_init(size_t cache_line_size)
 1.1  christos {
1.15      matt 	mutex_init(&pmap_pvlist_mutex, MUTEX_DEFAULT, IPL_HIGH);
 1.1  christos }
 1.1  christos
 1.1  christos #ifdef MODULAR
1.15      matt kmutex_t *
1.15      matt pmap_pvlist_lock_addr(struct vm_page_md *mdpg)
 1.1  christos {
 1.1  christos 	/*
 1.1  christos 	 * We just use a global lock.
 1.1  christos 	 */
 1.1  christos 	if (__predict_false(mdpg->mdpg_lock == NULL)) {
 1.1  christos 		mdpg->mdpg_lock = &pmap_pvlist_mutex;
 1.1  christos 	}
 1.1  christos
 1.1  christos 	/*
1.15      matt 	 * Now finally provide the lock.
 1.1  christos 	 */
1.15      matt 	return mdpg->mdpg_lock;
 1.1  christos }
 1.1  christos #endif /* MODULAR */
 1.1  christos #endif /* !MULTIPROCESSOR */
 1.1  christos
 1.1  christos /*
 1.1  christos  * pmap_pv_page_alloc:
 1.1  christos  *
 1.1  christos  *	Allocate a page for the pv_entry pool.
 1.1  christos  */
 1.1  christos void *
 1.1  christos pmap_pv_page_alloc(struct pool *pp, int flags)
 1.1  christos {
1.15      matt 	struct vm_page * const pg = PMAP_ALLOC_POOLPAGE(UVM_PGA_USERESERVE);
 1.1  christos 	if (pg == NULL)
 1.1  christos 		return NULL;
 1.1  christos
 1.1  christos 	return (void *)pmap_map_poolpage(VM_PAGE_TO_PHYS(pg));
 1.1  christos }
 1.1  christos
 1.1  christos /*
 1.1  christos  * pmap_pv_page_free:
 1.1  christos  *
 1.1  christos  *	Free a pv_entry pool page.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_pv_page_free(struct pool *pp, void *v)
 1.1  christos {
 1.1  christos 	vaddr_t va = (vaddr_t)v;
 1.1  christos
 1.1  christos 	KASSERT(pmap_md_direct_mapped_vaddr_p(va));
 1.1  christos 	const paddr_t pa = pmap_md_direct_mapped_vaddr_to_paddr(va);
 1.1  christos 	struct vm_page * const pg = PHYS_TO_VM_PAGE(pa);
1.15      matt 	KASSERT(pg != NULL);
1.15      matt #ifdef PMAP_VIRTUAL_CACHE_ALIASES
1.15      matt 	kpreempt_disable();
1.15      matt 	pmap_md_vca_remove(pg, va, true, true);
1.15      matt 	kpreempt_enable();
1.15      matt #endif
1.15      matt 	pmap_page_clear_attributes(VM_PAGE_TO_MD(pg), VM_PAGEMD_POOLPAGE);
1.34     skrll 	KASSERT(!VM_PAGEMD_EXECPAGE_P(VM_PAGE_TO_MD(pg)));
 1.1  christos 	uvm_pagefree(pg);
 1.1  christos }
 1.1  christos
 1.1  christos #ifdef PMAP_PREFER
 1.1  christos /*
 1.1  christos  * Find first virtual address >= *vap that doesn't cause
 1.1  christos  * a cache alias conflict.
 1.1  christos  */
 1.1  christos void
 1.1  christos pmap_prefer(vaddr_t foff, vaddr_t *vap, vsize_t sz, int td)
 1.1  christos {
 1.1  christos 	vsize_t prefer_mask = ptoa(uvmexp.colormask);
 1.1  christos
 1.1  christos 	PMAP_COUNT(prefer_requests);
 1.1  christos
 1.1  christos 	prefer_mask |= pmap_md_cache_prefer_mask();
 1.1  christos
 1.1  christos 	if (prefer_mask) {
1.15      matt 		vaddr_t	va = *vap;
1.15      matt 		vsize_t d = (foff - va) & prefer_mask;
 1.1  christos 		if (d) {
 1.1  christos 			if (td)
1.15      matt 				*vap = trunc_page(va - ((-d) & prefer_mask));
 1.1  christos 			else
 1.1  christos 				*vap = round_page(va + d);
 1.1  christos 			PMAP_COUNT(prefer_adjustments);
 1.1  christos 		}
 1.1  christos 	}
 1.1  christos }
 1.1  christos #endif /* PMAP_PREFER */
 1.1  christos
 1.1  christos #ifdef PMAP_MAP_POOLPAGE
 1.1  christos vaddr_t
 1.1  christos pmap_map_poolpage(paddr_t pa)
 1.1  christos {
 1.1  christos 	struct vm_page * const pg = PHYS_TO_VM_PAGE(pa);
 1.1  christos 	KASSERT(pg);
1.34     skrll
 1.1  christos 	struct vm_page_md * const mdpg = VM_PAGE_TO_MD(pg);
1.34     skrll 	KASSERT(!VM_PAGEMD_EXECPAGE_P(mdpg));
1.34     skrll
 1.1  christos 	pmap_page_set_attributes(mdpg, VM_PAGEMD_POOLPAGE);
 1.1  christos
1.15      matt 	return pmap_md_map_poolpage(pa, NBPG);
 1.1  christos }
 1.1  christos
 1.1  christos paddr_t
 1.1  christos pmap_unmap_poolpage(vaddr_t va)
 1.1  christos {
 1.1  christos 	KASSERT(pmap_md_direct_mapped_vaddr_p(va));
 1.1  christos 	paddr_t pa = pmap_md_direct_mapped_vaddr_to_paddr(va);
 1.1  christos
 1.1  christos 	struct vm_page * const pg = PHYS_TO_VM_PAGE(pa);
1.15      matt 	KASSERT(pg != NULL);
1.34     skrll 	KASSERT(!VM_PAGEMD_EXECPAGE_P(VM_PAGE_TO_MD(pg)));
1.34     skrll
1.15      matt 	pmap_page_clear_attributes(VM_PAGE_TO_MD(pg), VM_PAGEMD_POOLPAGE);
 1.1  christos 	pmap_md_unmap_poolpage(va, NBPG);
 1.1  christos
 1.1  christos 	return pa;
 1.1  christos }
 1.1  christos #endif /* PMAP_MAP_POOLPAGE */