arm/arm32/pmap.c

1.14.2.6  jdolecek /*	$NetBSD: pmap.c,v 1.14.2.6 2002/03/16 15:56:04 jdolecek Exp $	*/
    1.12     chris
    1.12     chris /*
1.14.2.6  jdolecek  * Copyright (c) 2002 Wasabi Systems, Inc.
    1.12     chris  * Copyright (c) 2001 Richard Earnshaw
    1.12     chris  * Copyright (c) 2001 Christopher Gilbert
    1.12     chris  * All rights reserved.
    1.12     chris  *
    1.12     chris  * 1. Redistributions of source code must retain the above copyright
    1.12     chris  *    notice, this list of conditions and the following disclaimer.
    1.12     chris  * 2. Redistributions in binary form must reproduce the above copyright
    1.12     chris  *    notice, this list of conditions and the following disclaimer in the
    1.12     chris  *    documentation and/or other materials provided with the distribution.
    1.12     chris  * 3. The name of the company nor the name of the author may be used to
    1.12     chris  *    endorse or promote products derived from this software without specific
    1.12     chris  *    prior written permission.
    1.12     chris  *
    1.12     chris  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
    1.12     chris  * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
    1.12     chris  * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
    1.12     chris  * IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT,
    1.12     chris  * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
    1.12     chris  * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
    1.12     chris  * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
    1.12     chris  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
    1.12     chris  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
    1.12     chris  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
    1.12     chris  * SUCH DAMAGE.
    1.12     chris  */
     1.1      matt
     1.1      matt /*-
     1.1      matt  * Copyright (c) 1999 The NetBSD Foundation, Inc.
     1.1      matt  * All rights reserved.
     1.1      matt  *
     1.1      matt  * This code is derived from software contributed to The NetBSD Foundation
     1.1      matt  * by Charles M. Hannum.
     1.1      matt  *
     1.1      matt  * Redistribution and use in source and binary forms, with or without
     1.1      matt  * modification, are permitted provided that the following conditions
     1.1      matt  * are met:
     1.1      matt  * 1. Redistributions of source code must retain the above copyright
     1.1      matt  *    notice, this list of conditions and the following disclaimer.
     1.1      matt  * 2. Redistributions in binary form must reproduce the above copyright
     1.1      matt  *    notice, this list of conditions and the following disclaimer in the
     1.1      matt  *    documentation and/or other materials provided with the distribution.
     1.1      matt  * 3. All advertising materials mentioning features or use of this software
     1.1      matt  *    must display the following acknowledgement:
     1.1      matt  *        This product includes software developed by the NetBSD
     1.1      matt  *        Foundation, Inc. and its contributors.
     1.1      matt  * 4. Neither the name of The NetBSD Foundation nor the names of its
     1.1      matt  *    contributors may be used to endorse or promote products derived
     1.1      matt  *    from this software without specific prior written permission.
     1.1      matt  *
     1.1      matt  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
     1.1      matt  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
     1.1      matt  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
     1.1      matt  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
     1.1      matt  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
     1.1      matt  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
     1.1      matt  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
     1.1      matt  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
     1.1      matt  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
     1.1      matt  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
     1.1      matt  * POSSIBILITY OF SUCH DAMAGE.
     1.1      matt  */
     1.1      matt
     1.1      matt /*
     1.1      matt  * Copyright (c) 1994-1998 Mark Brinicombe.
     1.1      matt  * Copyright (c) 1994 Brini.
     1.1      matt  * All rights reserved.
     1.1      matt  *
     1.1      matt  * This code is derived from software written for Brini by Mark Brinicombe
     1.1      matt  *
     1.1      matt  * Redistribution and use in source and binary forms, with or without
     1.1      matt  * modification, are permitted provided that the following conditions
     1.1      matt  * are met:
     1.1      matt  * 1. Redistributions of source code must retain the above copyright
     1.1      matt  *    notice, this list of conditions and the following disclaimer.
     1.1      matt  * 2. Redistributions in binary form must reproduce the above copyright
     1.1      matt  *    notice, this list of conditions and the following disclaimer in the
     1.1      matt  *    documentation and/or other materials provided with the distribution.
     1.1      matt  * 3. All advertising materials mentioning features or use of this software
     1.1      matt  *    must display the following acknowledgement:
     1.1      matt  *	This product includes software developed by Mark Brinicombe.
     1.1      matt  * 4. The name of the author may not be used to endorse or promote products
     1.1      matt  *    derived from this software without specific prior written permission.
     1.1      matt  *
     1.1      matt  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
     1.1      matt  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
     1.1      matt  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
     1.1      matt  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
     1.1      matt  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
     1.1      matt  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
     1.1      matt  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
     1.1      matt  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
     1.1      matt  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
     1.1      matt  *
     1.1      matt  * RiscBSD kernel project
     1.1      matt  *
     1.1      matt  * pmap.c
     1.1      matt  *
     1.1      matt  * Machine dependant vm stuff
     1.1      matt  *
     1.1      matt  * Created      : 20/09/94
     1.1      matt  */
     1.1      matt
     1.1      matt /*
     1.1      matt  * Performance improvements, UVM changes, overhauls and part-rewrites
     1.1      matt  * were contributed by Neil A. Carson <neil (at) causality.com>.
     1.1      matt  */
     1.1      matt
     1.1      matt /*
     1.1      matt  * The dram block info is currently referenced from the bootconfig.
     1.1      matt  * This should be placed in a separate structure.
     1.1      matt  */
     1.1      matt
     1.1      matt /*
     1.1      matt  * Special compilation symbols
     1.1      matt  * PMAP_DEBUG		- Build in pmap_debug_level code
     1.1      matt  */
     1.1      matt
     1.1      matt /* Include header files */
     1.1      matt
     1.1      matt #include "opt_pmap_debug.h"
     1.1      matt #include "opt_ddb.h"
     1.1      matt
     1.1      matt #include <sys/types.h>
     1.1      matt #include <sys/param.h>
     1.1      matt #include <sys/kernel.h>
     1.1      matt #include <sys/systm.h>
     1.1      matt #include <sys/proc.h>
     1.1      matt #include <sys/malloc.h>
     1.1      matt #include <sys/user.h>
    1.10     chris #include <sys/pool.h>
1.14.2.1     lukem #include <sys/cdefs.h>
1.14.2.1     lukem
     1.1      matt #include <uvm/uvm.h>
     1.1      matt
     1.1      matt #include <machine/bootconfig.h>
     1.1      matt #include <machine/bus.h>
     1.1      matt #include <machine/pmap.h>
     1.1      matt #include <machine/pcb.h>
     1.1      matt #include <machine/param.h>
1.14.2.4   thorpej #include <arm/arm32/katelib.h>
1.14.2.4   thorpej
1.14.2.6  jdolecek __KERNEL_RCSID(0, "$NetBSD: pmap.c,v 1.14.2.6 2002/03/16 15:56:04 jdolecek Exp $");
1.14.2.1     lukem
     1.1      matt #ifdef PMAP_DEBUG
     1.1      matt #define	PDEBUG(_lev_,_stat_) \
     1.1      matt 	if (pmap_debug_level >= (_lev_)) \
     1.1      matt         	((_stat_))
     1.1      matt int pmap_debug_level = -2;
1.14.2.6  jdolecek void pmap_dump_pvlist(vaddr_t phys, char *m);
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * for switching to potentially finer grained debugging
1.14.2.2   thorpej  */
1.14.2.2   thorpej #define	PDB_FOLLOW	0x0001
1.14.2.2   thorpej #define	PDB_INIT	0x0002
1.14.2.2   thorpej #define	PDB_ENTER	0x0004
1.14.2.2   thorpej #define	PDB_REMOVE	0x0008
1.14.2.2   thorpej #define	PDB_CREATE	0x0010
1.14.2.2   thorpej #define	PDB_PTPAGE	0x0020
1.14.2.6  jdolecek #define	PDB_GROWKERN	0x0040
1.14.2.2   thorpej #define	PDB_BITS	0x0080
1.14.2.2   thorpej #define	PDB_COLLECT	0x0100
1.14.2.2   thorpej #define	PDB_PROTECT	0x0200
1.14.2.6  jdolecek #define	PDB_MAP_L1	0x0400
1.14.2.2   thorpej #define	PDB_BOOTSTRAP	0x1000
1.14.2.2   thorpej #define	PDB_PARANOIA	0x2000
1.14.2.2   thorpej #define	PDB_WIRING	0x4000
1.14.2.2   thorpej #define	PDB_PVDUMP	0x8000
1.14.2.2   thorpej
1.14.2.2   thorpej int debugmap = 0;
1.14.2.2   thorpej int pmapdebug = PDB_PARANOIA | PDB_FOLLOW;
1.14.2.2   thorpej #define	NPDEBUG(_lev_,_stat_) \
1.14.2.2   thorpej 	if (pmapdebug & (_lev_)) \
1.14.2.2   thorpej         	((_stat_))
1.14.2.2   thorpej
     1.1      matt #else	/* PMAP_DEBUG */
     1.1      matt #define	PDEBUG(_lev_,_stat_) /* Nothing */
1.14.2.6  jdolecek #define NPDEBUG(_lev_,_stat_) /* Nothing */
     1.1      matt #endif	/* PMAP_DEBUG */
     1.1      matt
     1.1      matt struct pmap     kernel_pmap_store;
     1.1      matt
    1.10     chris /*
1.14.2.6  jdolecek  * linked list of all non-kernel pmaps
1.14.2.6  jdolecek  */
1.14.2.6  jdolecek
1.14.2.6  jdolecek static struct pmap_head pmaps;
1.14.2.6  jdolecek
1.14.2.6  jdolecek /*
    1.10     chris  * pool that pmap structures are allocated from
    1.10     chris  */
    1.10     chris
    1.10     chris struct pool pmap_pmap_pool;
    1.10     chris
     1.1      matt pagehook_t page_hook0;
     1.1      matt pagehook_t page_hook1;
     1.1      matt char *memhook;
     1.1      matt pt_entry_t msgbufpte;
     1.1      matt extern caddr_t msgbufaddr;
     1.1      matt
     1.1      matt boolean_t pmap_initialized = FALSE;	/* Has pmap_init completed? */
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * locking data structures
1.14.2.2   thorpej  */
     1.1      matt
1.14.2.2   thorpej static struct lock pmap_main_lock;
1.14.2.2   thorpej static struct simplelock pvalloc_lock;
1.14.2.6  jdolecek static struct simplelock pmaps_lock;
1.14.2.2   thorpej #ifdef LOCKDEBUG
1.14.2.2   thorpej #define PMAP_MAP_TO_HEAD_LOCK() \
1.14.2.2   thorpej      (void) spinlockmgr(&pmap_main_lock, LK_SHARED, NULL)
1.14.2.2   thorpej #define PMAP_MAP_TO_HEAD_UNLOCK() \
1.14.2.2   thorpej      (void) spinlockmgr(&pmap_main_lock, LK_RELEASE, NULL)
1.14.2.2   thorpej
1.14.2.2   thorpej #define PMAP_HEAD_TO_MAP_LOCK() \
1.14.2.2   thorpej      (void) spinlockmgr(&pmap_main_lock, LK_EXCLUSIVE, NULL)
1.14.2.2   thorpej #define PMAP_HEAD_TO_MAP_UNLOCK() \
1.14.2.2   thorpej      (void) spinlockmgr(&pmap_main_lock, LK_RELEASE, NULL)
1.14.2.2   thorpej #else
1.14.2.2   thorpej #define	PMAP_MAP_TO_HEAD_LOCK()		/* nothing */
1.14.2.2   thorpej #define	PMAP_MAP_TO_HEAD_UNLOCK()	/* nothing */
1.14.2.2   thorpej #define	PMAP_HEAD_TO_MAP_LOCK()		/* nothing */
1.14.2.2   thorpej #define	PMAP_HEAD_TO_MAP_UNLOCK()	/* nothing */
1.14.2.2   thorpej #endif /* LOCKDEBUG */
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pv_page management structures: locked by pvalloc_lock
1.14.2.2   thorpej  */
     1.1      matt
1.14.2.2   thorpej TAILQ_HEAD(pv_pagelist, pv_page);
1.14.2.2   thorpej static struct pv_pagelist pv_freepages;	/* list of pv_pages with free entrys */
1.14.2.2   thorpej static struct pv_pagelist pv_unusedpgs; /* list of unused pv_pages */
1.14.2.2   thorpej static int pv_nfpvents;			/* # of free pv entries */
1.14.2.2   thorpej static struct pv_page *pv_initpage;	/* bootstrap page from kernel_map */
1.14.2.2   thorpej static vaddr_t pv_cachedva;		/* cached VA for later use */
1.14.2.2   thorpej
1.14.2.2   thorpej #define PVE_LOWAT (PVE_PER_PVPAGE / 2)	/* free pv_entry low water mark */
1.14.2.2   thorpej #define PVE_HIWAT (PVE_LOWAT + (PVE_PER_PVPAGE * 2))
1.14.2.2   thorpej 					/* high water mark */
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * local prototypes
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej static struct pv_entry	*pmap_add_pvpage __P((struct pv_page *, boolean_t));
1.14.2.2   thorpej static struct pv_entry	*pmap_alloc_pv __P((struct pmap *, int)); /* see codes below */
1.14.2.2   thorpej #define ALLOCPV_NEED	0	/* need PV now */
1.14.2.2   thorpej #define ALLOCPV_TRY	1	/* just try to allocate, don't steal */
1.14.2.2   thorpej #define ALLOCPV_NONEED	2	/* don't need PV, just growing cache */
1.14.2.2   thorpej static struct pv_entry	*pmap_alloc_pvpage __P((struct pmap *, int));
1.14.2.6  jdolecek static void		 pmap_enter_pv __P((struct vm_page *,
1.14.2.2   thorpej 					    struct pv_entry *, struct pmap *,
1.14.2.2   thorpej 					    vaddr_t, struct vm_page *, int));
1.14.2.2   thorpej static void		 pmap_free_pv __P((struct pmap *, struct pv_entry *));
1.14.2.2   thorpej static void		 pmap_free_pvs __P((struct pmap *, struct pv_entry *));
1.14.2.2   thorpej static void		 pmap_free_pv_doit __P((struct pv_entry *));
1.14.2.2   thorpej static void		 pmap_free_pvpage __P((void));
1.14.2.2   thorpej static boolean_t	 pmap_is_curpmap __P((struct pmap *));
1.14.2.6  jdolecek static struct pv_entry	*pmap_remove_pv __P((struct vm_page *, struct pmap *,
1.14.2.2   thorpej 			vaddr_t));
1.14.2.2   thorpej #define PMAP_REMOVE_ALL		0	/* remove all mappings */
1.14.2.2   thorpej #define PMAP_REMOVE_SKIPWIRED	1	/* skip wired mappings */
     1.1      matt
1.14.2.6  jdolecek static u_int pmap_modify_pv __P((struct pmap *, vaddr_t, struct vm_page *,
1.14.2.4   thorpej 	u_int, u_int));
1.14.2.4   thorpej
1.14.2.4   thorpej static void pmap_free_l1pt __P((struct l1pt *));
1.14.2.4   thorpej static int pmap_allocpagedir __P((struct pmap *));
1.14.2.4   thorpej static int pmap_clean_page __P((struct pv_entry *, boolean_t));
1.14.2.6  jdolecek static void pmap_remove_all __P((struct vm_page *));
1.14.2.4   thorpej
1.14.2.4   thorpej
     1.2      matt vsize_t npages;
     1.1      matt
1.14.2.2   thorpej static struct vm_page	*pmap_alloc_ptp __P((struct pmap *, vaddr_t, boolean_t));
1.14.2.2   thorpej static struct vm_page	*pmap_get_ptp __P((struct pmap *, vaddr_t, boolean_t));
1.14.2.6  jdolecek __inline static void pmap_clearbit __P((struct vm_page *, unsigned int));
1.14.2.2   thorpej
     1.2      matt extern paddr_t physical_start;
     1.2      matt extern paddr_t physical_freestart;
     1.2      matt extern paddr_t physical_end;
     1.2      matt extern paddr_t physical_freeend;
     1.1      matt extern unsigned int free_pages;
     1.1      matt extern int max_processes;
     1.1      matt
     1.1      matt vaddr_t virtual_start;
     1.1      matt vaddr_t virtual_end;
1.14.2.6  jdolecek vaddr_t pmap_curmaxkvaddr;
     1.1      matt
     1.1      matt vaddr_t avail_start;
     1.1      matt vaddr_t avail_end;
     1.1      matt
     1.1      matt extern pv_addr_t systempage;
     1.1      matt
     1.1      matt #define ALLOC_PAGE_HOOK(x, s) \
     1.1      matt 	x.va = virtual_start; \
1.14.2.1     lukem 	x.pte = (pt_entry_t *)pmap_pte(pmap_kernel(), virtual_start); \
     1.1      matt 	virtual_start += s;
     1.1      matt
     1.1      matt /* Variables used by the L1 page table queue code */
     1.1      matt SIMPLEQ_HEAD(l1pt_queue, l1pt);
     1.1      matt struct l1pt_queue l1pt_static_queue;	/* head of our static l1 queue */
     1.1      matt int l1pt_static_queue_count;		/* items in the static l1 queue */
     1.1      matt int l1pt_static_create_count;		/* static l1 items created */
     1.1      matt struct l1pt_queue l1pt_queue;		/* head of our l1 queue */
     1.1      matt int l1pt_queue_count;			/* items in the l1 queue */
     1.1      matt int l1pt_create_count;			/* stat - L1's create count */
     1.1      matt int l1pt_reuse_count;			/* stat - L1's reused count */
     1.1      matt
     1.1      matt /* Local function prototypes (not used outside this file) */
1.14.2.1     lukem pt_entry_t *pmap_pte __P((struct pmap *pmap, vaddr_t va));
1.14.2.6  jdolecek void pmap_copy_on_write __P((struct vm_page *));
1.14.2.1     lukem void pmap_pinit __P((struct pmap *));
1.14.2.1     lukem void pmap_freepagedir __P((struct pmap *));
     1.1      matt
     1.1      matt /* Other function prototypes */
     1.1      matt extern void bzero_page __P((vaddr_t));
     1.1      matt extern void bcopy_page __P((vaddr_t, vaddr_t));
     1.1      matt
     1.1      matt struct l1pt *pmap_alloc_l1pt __P((void));
1.14.2.1     lukem static __inline void pmap_map_in_l1 __P((struct pmap *pmap, vaddr_t va,
1.14.2.2   thorpej      vaddr_t l2pa, boolean_t));
     1.1      matt
    1.11     chris static pt_entry_t *pmap_map_ptes __P((struct pmap *));
1.14.2.2   thorpej static void pmap_unmap_ptes __P((struct pmap *));
    1.11     chris
1.14.2.6  jdolecek __inline static void pmap_vac_me_harder __P((struct pmap *, struct vm_page *,
1.14.2.4   thorpej     pt_entry_t *, boolean_t));
1.14.2.6  jdolecek static void pmap_vac_me_kpmap __P((struct pmap *, struct vm_page *,
1.14.2.4   thorpej     pt_entry_t *, boolean_t));
1.14.2.6  jdolecek static void pmap_vac_me_user __P((struct pmap *, struct vm_page *,
1.14.2.4   thorpej     pt_entry_t *, boolean_t));
1.14.2.4   thorpej
1.14.2.4   thorpej /*
1.14.2.4   thorpej  * Cache enable bits in PTE to use on pages that are cacheable.
1.14.2.4   thorpej  * On most machines this is cacheable/bufferable, but on some, eg arm10, we
1.14.2.4   thorpej  * can chose between write-through and write-back cacheing.
1.14.2.4   thorpej  */
1.14.2.4   thorpej pt_entry_t pte_cache_mode = (PT_C | PT_B);
    1.11     chris
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * real definition of pv_entry.
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej struct pv_entry {
1.14.2.2   thorpej 	struct pv_entry *pv_next;       /* next pv_entry */
1.14.2.2   thorpej 	struct pmap     *pv_pmap;        /* pmap where mapping lies */
1.14.2.2   thorpej 	vaddr_t         pv_va;          /* virtual address for mapping */
1.14.2.2   thorpej 	int             pv_flags;       /* flags */
1.14.2.2   thorpej 	struct vm_page	*pv_ptp;	/* vm_page for the ptp */
1.14.2.2   thorpej };
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pv_entrys are dynamically allocated in chunks from a single page.
1.14.2.2   thorpej  * we keep track of how many pv_entrys are in use for each page and
1.14.2.2   thorpej  * we can free pv_entry pages if needed.  there is one lock for the
1.14.2.2   thorpej  * entire allocation system.
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej struct pv_page_info {
1.14.2.2   thorpej 	TAILQ_ENTRY(pv_page) pvpi_list;
1.14.2.2   thorpej 	struct pv_entry *pvpi_pvfree;
1.14.2.2   thorpej 	int pvpi_nfree;
1.14.2.2   thorpej };
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * number of pv_entry's in a pv_page
1.14.2.2   thorpej  * (note: won't work on systems where NPBG isn't a constant)
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej #define PVE_PER_PVPAGE ((NBPG - sizeof(struct pv_page_info)) / \
1.14.2.2   thorpej 			sizeof(struct pv_entry))
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * a pv_page: where pv_entrys are allocated from
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej struct pv_page {
1.14.2.2   thorpej 	struct pv_page_info pvinfo;
1.14.2.2   thorpej 	struct pv_entry pvents[PVE_PER_PVPAGE];
1.14.2.2   thorpej };
1.14.2.2   thorpej
     1.1      matt #ifdef MYCROFT_HACK
     1.1      matt int mycroft_hack = 0;
     1.1      matt #endif
     1.1      matt
     1.1      matt /* Function to set the debug level of the pmap code */
     1.1      matt
     1.1      matt #ifdef PMAP_DEBUG
     1.1      matt void
     1.1      matt pmap_debug(level)
     1.1      matt 	int level;
     1.1      matt {
     1.1      matt 	pmap_debug_level = level;
     1.1      matt 	printf("pmap_debug: level=%d\n", pmap_debug_level);
     1.1      matt }
     1.1      matt #endif	/* PMAP_DEBUG */
     1.1      matt
1.14.2.4   thorpej __inline static boolean_t
1.14.2.2   thorpej pmap_is_curpmap(struct pmap *pmap)
1.14.2.2   thorpej {
1.14.2.2   thorpej     if ((curproc && curproc->p_vmspace->vm_map.pmap == pmap)
1.14.2.2   thorpej 	    || (pmap == pmap_kernel()))
1.14.2.2   thorpej 	return (TRUE);
1.14.2.2   thorpej     return (FALSE);
1.14.2.2   thorpej }
     1.1      matt #include "isadma.h"
     1.1      matt
     1.1      matt #if NISADMA > 0
     1.1      matt /*
     1.1      matt  * Used to protect memory for ISA DMA bounce buffers.  If, when loading
     1.1      matt  * pages into the system, memory intersects with any of these ranges,
     1.1      matt  * the intersecting memory will be loaded into a lower-priority free list.
     1.1      matt  */
     1.1      matt bus_dma_segment_t *pmap_isa_dma_ranges;
     1.1      matt int pmap_isa_dma_nranges;
     1.1      matt
     1.2      matt boolean_t pmap_isa_dma_range_intersect __P((paddr_t, psize_t,
     1.2      matt 	    paddr_t *, psize_t *));
     1.1      matt
     1.1      matt /*
     1.1      matt  * Check if a memory range intersects with an ISA DMA range, and
     1.1      matt  * return the page-rounded intersection if it does.  The intersection
     1.1      matt  * will be placed on a lower-priority free list.
     1.1      matt  */
     1.1      matt boolean_t
     1.1      matt pmap_isa_dma_range_intersect(pa, size, pap, sizep)
     1.2      matt 	paddr_t pa;
     1.2      matt 	psize_t size;
     1.2      matt 	paddr_t *pap;
     1.2      matt 	psize_t *sizep;
     1.1      matt {
     1.1      matt 	bus_dma_segment_t *ds;
     1.1      matt 	int i;
     1.1      matt
     1.1      matt 	if (pmap_isa_dma_ranges == NULL)
     1.1      matt 		return (FALSE);
     1.1      matt
     1.1      matt 	for (i = 0, ds = pmap_isa_dma_ranges;
     1.1      matt 	     i < pmap_isa_dma_nranges; i++, ds++) {
     1.1      matt 		if (ds->ds_addr <= pa && pa < (ds->ds_addr + ds->ds_len)) {
     1.1      matt 			/*
     1.1      matt 			 * Beginning of region intersects with this range.
     1.1      matt 			 */
     1.1      matt 			*pap = trunc_page(pa);
     1.1      matt 			*sizep = round_page(min(pa + size,
     1.1      matt 			    ds->ds_addr + ds->ds_len) - pa);
     1.1      matt 			return (TRUE);
     1.1      matt 		}
     1.1      matt 		if (pa < ds->ds_addr && ds->ds_addr < (pa + size)) {
     1.1      matt 			/*
     1.1      matt 			 * End of region intersects with this range.
     1.1      matt 			 */
     1.1      matt 			*pap = trunc_page(ds->ds_addr);
     1.1      matt 			*sizep = round_page(min((pa + size) - ds->ds_addr,
     1.1      matt 			    ds->ds_len));
     1.1      matt 			return (TRUE);
     1.1      matt 		}
     1.1      matt 	}
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * No intersection found.
     1.1      matt 	 */
     1.1      matt 	return (FALSE);
     1.1      matt }
     1.1      matt #endif /* NISADMA > 0 */
     1.1      matt
     1.1      matt /*
1.14.2.2   thorpej  * p v _ e n t r y   f u n c t i o n s
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pv_entry allocation functions:
1.14.2.2   thorpej  *   the main pv_entry allocation functions are:
1.14.2.2   thorpej  *     pmap_alloc_pv: allocate a pv_entry structure
1.14.2.2   thorpej  *     pmap_free_pv: free one pv_entry
1.14.2.2   thorpej  *     pmap_free_pvs: free a list of pv_entrys
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * the rest are helper functions
     1.1      matt  */
     1.1      matt
     1.1      matt /*
1.14.2.2   thorpej  * pmap_alloc_pv: inline function to allocate a pv_entry structure
1.14.2.2   thorpej  * => we lock pvalloc_lock
1.14.2.2   thorpej  * => if we fail, we call out to pmap_alloc_pvpage
1.14.2.2   thorpej  * => 3 modes:
1.14.2.2   thorpej  *    ALLOCPV_NEED   = we really need a pv_entry, even if we have to steal it
1.14.2.2   thorpej  *    ALLOCPV_TRY    = we want a pv_entry, but not enough to steal
1.14.2.2   thorpej  *    ALLOCPV_NONEED = we are trying to grow our free list, don't really need
1.14.2.2   thorpej  *			one now
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * "try" is for optional functions like pmap_copy().
     1.1      matt  */
1.14.2.2   thorpej
1.14.2.2   thorpej __inline static struct pv_entry *
1.14.2.2   thorpej pmap_alloc_pv(pmap, mode)
1.14.2.2   thorpej 	struct pmap *pmap;
1.14.2.2   thorpej 	int mode;
     1.1      matt {
1.14.2.2   thorpej 	struct pv_page *pvpage;
     1.1      matt 	struct pv_entry *pv;
     1.1      matt
1.14.2.2   thorpej 	simple_lock(&pvalloc_lock);
     1.1      matt
1.14.2.6  jdolecek 	pvpage = TAILQ_FIRST(&pv_freepages);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	if (pvpage != NULL) {
1.14.2.2   thorpej 		pvpage->pvinfo.pvpi_nfree--;
1.14.2.2   thorpej 		if (pvpage->pvinfo.pvpi_nfree == 0) {
1.14.2.2   thorpej 			/* nothing left in this one? */
1.14.2.2   thorpej 			TAILQ_REMOVE(&pv_freepages, pvpage, pvinfo.pvpi_list);
     1.1      matt 		}
1.14.2.2   thorpej 		pv = pvpage->pvinfo.pvpi_pvfree;
1.14.2.6  jdolecek 		KASSERT(pv);
1.14.2.2   thorpej 		pvpage->pvinfo.pvpi_pvfree = pv->pv_next;
1.14.2.2   thorpej 		pv_nfpvents--;  /* took one from pool */
1.14.2.2   thorpej 	} else {
1.14.2.2   thorpej 		pv = NULL;		/* need more of them */
     1.1      matt 	}
1.14.2.2   thorpej
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * if below low water mark or we didn't get a pv_entry we try and
1.14.2.2   thorpej 	 * create more pv_entrys ...
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej
1.14.2.2   thorpej 	if (pv_nfpvents < PVE_LOWAT || pv == NULL) {
1.14.2.2   thorpej 		if (pv == NULL)
1.14.2.2   thorpej 			pv = pmap_alloc_pvpage(pmap, (mode == ALLOCPV_TRY) ?
1.14.2.2   thorpej 					       mode : ALLOCPV_NEED);
1.14.2.2   thorpej 		else
1.14.2.2   thorpej 			(void) pmap_alloc_pvpage(pmap, ALLOCPV_NONEED);
1.14.2.2   thorpej 	}
1.14.2.2   thorpej
1.14.2.2   thorpej 	simple_unlock(&pvalloc_lock);
1.14.2.2   thorpej 	return(pv);
     1.1      matt }
     1.1      matt
     1.1      matt /*
1.14.2.2   thorpej  * pmap_alloc_pvpage: maybe allocate a new pvpage
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * if need_entry is false: try and allocate a new pv_page
1.14.2.2   thorpej  * if need_entry is true: try and allocate a new pv_page and return a
1.14.2.2   thorpej  *	new pv_entry from it.   if we are unable to allocate a pv_page
1.14.2.2   thorpej  *	we make a last ditch effort to steal a pv_page from some other
1.14.2.2   thorpej  *	mapping.    if that fails, we panic...
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => we assume that the caller holds pvalloc_lock
     1.1      matt  */
     1.1      matt
1.14.2.2   thorpej static struct pv_entry *
1.14.2.2   thorpej pmap_alloc_pvpage(pmap, mode)
1.14.2.2   thorpej 	struct pmap *pmap;
1.14.2.2   thorpej 	int mode;
     1.1      matt {
1.14.2.2   thorpej 	struct vm_page *pg;
1.14.2.2   thorpej 	struct pv_page *pvpage;
1.14.2.2   thorpej 	struct pv_entry *pv;
1.14.2.2   thorpej 	int s;
     1.1      matt
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * if we need_entry and we've got unused pv_pages, allocate from there
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej
1.14.2.6  jdolecek 	pvpage = TAILQ_FIRST(&pv_unusedpgs);
1.14.2.6  jdolecek 	if (mode != ALLOCPV_NONEED && pvpage != NULL) {
1.14.2.2   thorpej
1.14.2.2   thorpej 		/* move it to pv_freepages list */
1.14.2.2   thorpej 		TAILQ_REMOVE(&pv_unusedpgs, pvpage, pvinfo.pvpi_list);
1.14.2.2   thorpej 		TAILQ_INSERT_HEAD(&pv_freepages, pvpage, pvinfo.pvpi_list);
1.14.2.2   thorpej
1.14.2.2   thorpej 		/* allocate a pv_entry */
1.14.2.2   thorpej 		pvpage->pvinfo.pvpi_nfree--;	/* can't go to zero */
1.14.2.2   thorpej 		pv = pvpage->pvinfo.pvpi_pvfree;
1.14.2.6  jdolecek 		KASSERT(pv);
1.14.2.2   thorpej 		pvpage->pvinfo.pvpi_pvfree = pv->pv_next;
1.14.2.2   thorpej
1.14.2.2   thorpej 		pv_nfpvents--;  /* took one from pool */
1.14.2.2   thorpej 		return(pv);
1.14.2.2   thorpej 	}
1.14.2.2   thorpej
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 *  see if we've got a cached unmapped VA that we can map a page in.
1.14.2.2   thorpej 	 * if not, try to allocate one.
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej
1.14.2.4   thorpej
1.14.2.2   thorpej 	if (pv_cachedva == 0) {
1.14.2.4   thorpej 		s = splvm();
1.14.2.4   thorpej 		pv_cachedva = uvm_km_kmemalloc(kmem_map, NULL,
1.14.2.2   thorpej 		    PAGE_SIZE, UVM_KMF_TRYLOCK|UVM_KMF_VALLOC);
1.14.2.4   thorpej 		splx(s);
1.14.2.2   thorpej 		if (pv_cachedva == 0) {
1.14.2.2   thorpej 			return (NULL);
1.14.2.2   thorpej 		}
1.14.2.2   thorpej 	}
1.14.2.2   thorpej
1.14.2.4   thorpej 	pg = uvm_pagealloc(NULL, pv_cachedva - vm_map_min(kernel_map), NULL,
1.14.2.4   thorpej 	    UVM_PGA_USERESERVE);
1.14.2.2   thorpej
1.14.2.2   thorpej 	if (pg == NULL)
1.14.2.2   thorpej 		return (NULL);
1.14.2.6  jdolecek 	pg->flags &= ~PG_BUSY;	/* never busy */
1.14.2.2   thorpej
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * add a mapping for our new pv_page and free its entrys (save one!)
1.14.2.2   thorpej 	 *
1.14.2.2   thorpej 	 * NOTE: If we are allocating a PV page for the kernel pmap, the
1.14.2.2   thorpej 	 * pmap is already locked!  (...but entering the mapping is safe...)
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej
1.14.2.6  jdolecek 	pmap_kenter_pa(pv_cachedva, VM_PAGE_TO_PHYS(pg),
1.14.2.6  jdolecek 		VM_PROT_READ|VM_PROT_WRITE);
1.14.2.3   thorpej 	pmap_update(pmap_kernel());
1.14.2.2   thorpej 	pvpage = (struct pv_page *) pv_cachedva;
1.14.2.2   thorpej 	pv_cachedva = 0;
1.14.2.2   thorpej 	return (pmap_add_pvpage(pvpage, mode != ALLOCPV_NONEED));
     1.1      matt }
     1.1      matt
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pmap_add_pvpage: add a pv_page's pv_entrys to the free list
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => caller must hold pvalloc_lock
1.14.2.2   thorpej  * => if need_entry is true, we allocate and return one pv_entry
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej static struct pv_entry *
1.14.2.2   thorpej pmap_add_pvpage(pvp, need_entry)
1.14.2.2   thorpej 	struct pv_page *pvp;
1.14.2.2   thorpej 	boolean_t need_entry;
     1.1      matt {
1.14.2.2   thorpej 	int tofree, lcv;
     1.1      matt
1.14.2.2   thorpej 	/* do we need to return one? */
1.14.2.2   thorpej 	tofree = (need_entry) ? PVE_PER_PVPAGE - 1 : PVE_PER_PVPAGE;
     1.1      matt
1.14.2.2   thorpej 	pvp->pvinfo.pvpi_pvfree = NULL;
1.14.2.2   thorpej 	pvp->pvinfo.pvpi_nfree = tofree;
1.14.2.2   thorpej 	for (lcv = 0 ; lcv < tofree ; lcv++) {
1.14.2.2   thorpej 		pvp->pvents[lcv].pv_next = pvp->pvinfo.pvpi_pvfree;
1.14.2.2   thorpej 		pvp->pvinfo.pvpi_pvfree = &pvp->pvents[lcv];
     1.1      matt 	}
1.14.2.2   thorpej 	if (need_entry)
1.14.2.2   thorpej 		TAILQ_INSERT_TAIL(&pv_freepages, pvp, pvinfo.pvpi_list);
1.14.2.2   thorpej 	else
1.14.2.2   thorpej 		TAILQ_INSERT_TAIL(&pv_unusedpgs, pvp, pvinfo.pvpi_list);
1.14.2.2   thorpej 	pv_nfpvents += tofree;
1.14.2.2   thorpej 	return((need_entry) ? &pvp->pvents[lcv] : NULL);
1.14.2.2   thorpej }
     1.1      matt
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pmap_free_pv_doit: actually free a pv_entry
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => do not call this directly!  instead use either
1.14.2.2   thorpej  *    1. pmap_free_pv ==> free a single pv_entry
1.14.2.2   thorpej  *    2. pmap_free_pvs => free a list of pv_entrys
1.14.2.2   thorpej  * => we must be holding pvalloc_lock
1.14.2.2   thorpej  */
     1.1      matt
1.14.2.2   thorpej __inline static void
1.14.2.2   thorpej pmap_free_pv_doit(pv)
1.14.2.2   thorpej 	struct pv_entry *pv;
1.14.2.2   thorpej {
1.14.2.2   thorpej 	struct pv_page *pvp;
1.14.2.2   thorpej
1.14.2.2   thorpej 	pvp = (struct pv_page *) arm_trunc_page((vaddr_t)pv);
1.14.2.2   thorpej 	pv_nfpvents++;
1.14.2.2   thorpej 	pvp->pvinfo.pvpi_nfree++;
1.14.2.2   thorpej
1.14.2.2   thorpej 	/* nfree == 1 => fully allocated page just became partly allocated */
1.14.2.2   thorpej 	if (pvp->pvinfo.pvpi_nfree == 1) {
1.14.2.2   thorpej 		TAILQ_INSERT_HEAD(&pv_freepages, pvp, pvinfo.pvpi_list);
     1.1      matt 	}
     1.1      matt
1.14.2.2   thorpej 	/* free it */
1.14.2.2   thorpej 	pv->pv_next = pvp->pvinfo.pvpi_pvfree;
1.14.2.2   thorpej 	pvp->pvinfo.pvpi_pvfree = pv;
1.14.2.2   thorpej
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * are all pv_page's pv_entry's free?  move it to unused queue.
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej
1.14.2.2   thorpej 	if (pvp->pvinfo.pvpi_nfree == PVE_PER_PVPAGE) {
1.14.2.2   thorpej 		TAILQ_REMOVE(&pv_freepages, pvp, pvinfo.pvpi_list);
1.14.2.2   thorpej 		TAILQ_INSERT_HEAD(&pv_unusedpgs, pvp, pvinfo.pvpi_list);
     1.1      matt 	}
     1.1      matt }
     1.1      matt
     1.1      matt /*
1.14.2.2   thorpej  * pmap_free_pv: free a single pv_entry
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => we gain the pvalloc_lock
     1.1      matt  */
     1.1      matt
1.14.2.2   thorpej __inline static void
1.14.2.2   thorpej pmap_free_pv(pmap, pv)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	struct pv_entry *pv;
     1.1      matt {
1.14.2.2   thorpej 	simple_lock(&pvalloc_lock);
1.14.2.2   thorpej 	pmap_free_pv_doit(pv);
     1.1      matt
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * Can't free the PV page if the PV entries were associated with
1.14.2.2   thorpej 	 * the kernel pmap; the pmap is already locked.
1.14.2.2   thorpej 	 */
1.14.2.6  jdolecek 	if (pv_nfpvents > PVE_HIWAT && TAILQ_FIRST(&pv_unusedpgs) != NULL &&
1.14.2.2   thorpej 	    pmap != pmap_kernel())
1.14.2.2   thorpej 		pmap_free_pvpage();
     1.1      matt
1.14.2.2   thorpej 	simple_unlock(&pvalloc_lock);
1.14.2.2   thorpej }
     1.1      matt
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pmap_free_pvs: free a list of pv_entrys
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => we gain the pvalloc_lock
1.14.2.2   thorpej  */
     1.1      matt
1.14.2.2   thorpej __inline static void
1.14.2.2   thorpej pmap_free_pvs(pmap, pvs)
1.14.2.2   thorpej 	struct pmap *pmap;
1.14.2.2   thorpej 	struct pv_entry *pvs;
1.14.2.2   thorpej {
1.14.2.2   thorpej 	struct pv_entry *nextpv;
1.14.2.2   thorpej
1.14.2.2   thorpej 	simple_lock(&pvalloc_lock);
1.14.2.2   thorpej
1.14.2.2   thorpej 	for ( /* null */ ; pvs != NULL ; pvs = nextpv) {
1.14.2.2   thorpej 		nextpv = pvs->pv_next;
1.14.2.2   thorpej 		pmap_free_pv_doit(pvs);
     1.1      matt 	}
     1.1      matt
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * Can't free the PV page if the PV entries were associated with
1.14.2.2   thorpej 	 * the kernel pmap; the pmap is already locked.
1.14.2.2   thorpej 	 */
1.14.2.6  jdolecek 	if (pv_nfpvents > PVE_HIWAT && TAILQ_FIRST(&pv_unusedpgs) != NULL &&
1.14.2.2   thorpej 	    pmap != pmap_kernel())
1.14.2.2   thorpej 		pmap_free_pvpage();
     1.1      matt
1.14.2.2   thorpej 	simple_unlock(&pvalloc_lock);
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
1.14.2.2   thorpej  * pmap_free_pvpage: try and free an unused pv_page structure
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => assume caller is holding the pvalloc_lock and that
1.14.2.2   thorpej  *	there is a page on the pv_unusedpgs list
1.14.2.2   thorpej  * => if we can't get a lock on the kmem_map we try again later
     1.1      matt  */
     1.1      matt
1.14.2.2   thorpej static void
1.14.2.2   thorpej pmap_free_pvpage()
     1.1      matt {
1.14.2.2   thorpej 	int s;
1.14.2.2   thorpej 	struct vm_map *map;
1.14.2.2   thorpej 	struct vm_map_entry *dead_entries;
1.14.2.2   thorpej 	struct pv_page *pvp;
     1.1      matt
1.14.2.2   thorpej 	s = splvm(); /* protect kmem_map */
1.14.2.2   thorpej
1.14.2.6  jdolecek 	pvp = TAILQ_FIRST(&pv_unusedpgs);
     1.1      matt
     1.1      matt 	/*
1.14.2.2   thorpej 	 * note: watch out for pv_initpage which is allocated out of
1.14.2.2   thorpej 	 * kernel_map rather than kmem_map.
     1.1      matt 	 */
1.14.2.2   thorpej 	if (pvp == pv_initpage)
1.14.2.2   thorpej 		map = kernel_map;
1.14.2.2   thorpej 	else
1.14.2.2   thorpej 		map = kmem_map;
1.14.2.2   thorpej 	if (vm_map_lock_try(map)) {
1.14.2.2   thorpej
1.14.2.2   thorpej 		/* remove pvp from pv_unusedpgs */
1.14.2.2   thorpej 		TAILQ_REMOVE(&pv_unusedpgs, pvp, pvinfo.pvpi_list);
1.14.2.2   thorpej
1.14.2.2   thorpej 		/* unmap the page */
1.14.2.2   thorpej 		dead_entries = NULL;
1.14.2.2   thorpej 		uvm_unmap_remove(map, (vaddr_t)pvp, ((vaddr_t)pvp) + PAGE_SIZE,
1.14.2.2   thorpej 		    &dead_entries);
1.14.2.2   thorpej 		vm_map_unlock(map);
1.14.2.2   thorpej
1.14.2.2   thorpej 		if (dead_entries != NULL)
1.14.2.2   thorpej 			uvm_unmap_detach(dead_entries, 0);
1.14.2.2   thorpej
1.14.2.2   thorpej 		pv_nfpvents -= PVE_PER_PVPAGE;  /* update free count */
     1.1      matt 	}
1.14.2.2   thorpej 	if (pvp == pv_initpage)
1.14.2.2   thorpej 		/* no more initpage, we've freed it */
1.14.2.2   thorpej 		pv_initpage = NULL;
     1.1      matt
     1.1      matt 	splx(s);
     1.1      matt }
     1.1      matt
     1.1      matt /*
1.14.2.2   thorpej  * main pv_entry manipulation functions:
1.14.2.6  jdolecek  *   pmap_enter_pv: enter a mapping onto a vm_page list
1.14.2.6  jdolecek  *   pmap_remove_pv: remove a mappiing from a vm_page list
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * NOTE: pmap_enter_pv expects to lock the pvh itself
1.14.2.2   thorpej  *       pmap_remove_pv expects te caller to lock the pvh before calling
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.6  jdolecek  * pmap_enter_pv: enter a mapping onto a vm_page lst
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => caller should hold the proper lock on pmap_main_lock
1.14.2.2   thorpej  * => caller should have pmap locked
1.14.2.6  jdolecek  * => we will gain the lock on the vm_page and allocate the new pv_entry
1.14.2.2   thorpej  * => caller should adjust ptp's wire_count before calling
1.14.2.2   thorpej  * => caller should not adjust pmap's wire_count
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej __inline static void
1.14.2.6  jdolecek pmap_enter_pv(pg, pve, pmap, va, ptp, flags)
1.14.2.6  jdolecek 	struct vm_page *pg;
1.14.2.2   thorpej 	struct pv_entry *pve;	/* preallocated pve for us to use */
1.14.2.2   thorpej 	struct pmap *pmap;
1.14.2.2   thorpej 	vaddr_t va;
1.14.2.2   thorpej 	struct vm_page *ptp;	/* PTP in pmap that maps this VA */
1.14.2.2   thorpej 	int flags;
1.14.2.2   thorpej {
1.14.2.2   thorpej 	pve->pv_pmap = pmap;
1.14.2.2   thorpej 	pve->pv_va = va;
1.14.2.2   thorpej 	pve->pv_ptp = ptp;			/* NULL for kernel pmap */
1.14.2.2   thorpej 	pve->pv_flags = flags;
1.14.2.6  jdolecek 	simple_lock(&pg->mdpage.pvh_slock);	/* lock vm_page */
1.14.2.6  jdolecek 	pve->pv_next = pg->mdpage.pvh_list;	/* add to ... */
1.14.2.6  jdolecek 	pg->mdpage.pvh_list = pve;		/* ... locked list */
1.14.2.6  jdolecek 	simple_unlock(&pg->mdpage.pvh_slock);	/* unlock, done! */
1.14.2.2   thorpej 	if (pve->pv_flags & PT_W)
1.14.2.2   thorpej 		++pmap->pm_stats.wired_count;
1.14.2.2   thorpej }
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pmap_remove_pv: try to remove a mapping from a pv_list
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => caller should hold proper lock on pmap_main_lock
1.14.2.2   thorpej  * => pmap should be locked
1.14.2.6  jdolecek  * => caller should hold lock on vm_page [so that attrs can be adjusted]
1.14.2.2   thorpej  * => caller should adjust ptp's wire_count and free PTP if needed
1.14.2.2   thorpej  * => caller should NOT adjust pmap's wire_count
1.14.2.2   thorpej  * => we return the removed pve
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej __inline static struct pv_entry *
1.14.2.6  jdolecek pmap_remove_pv(pg, pmap, va)
1.14.2.6  jdolecek 	struct vm_page *pg;
1.14.2.2   thorpej 	struct pmap *pmap;
1.14.2.2   thorpej 	vaddr_t va;
1.14.2.2   thorpej {
1.14.2.2   thorpej 	struct pv_entry *pve, **prevptr;
1.14.2.2   thorpej
1.14.2.6  jdolecek 	prevptr = &pg->mdpage.pvh_list;		/* previous pv_entry pointer */
1.14.2.2   thorpej 	pve = *prevptr;
1.14.2.2   thorpej 	while (pve) {
1.14.2.2   thorpej 		if (pve->pv_pmap == pmap && pve->pv_va == va) {	/* match? */
1.14.2.2   thorpej 			*prevptr = pve->pv_next;		/* remove it! */
1.14.2.2   thorpej 			if (pve->pv_flags & PT_W)
1.14.2.2   thorpej 			    --pmap->pm_stats.wired_count;
1.14.2.2   thorpej 			break;
1.14.2.2   thorpej 		}
1.14.2.2   thorpej 		prevptr = &pve->pv_next;		/* previous pointer */
1.14.2.2   thorpej 		pve = pve->pv_next;			/* advance */
1.14.2.2   thorpej 	}
1.14.2.2   thorpej 	return(pve);				/* return removed pve */
1.14.2.2   thorpej }
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * pmap_modify_pv: Update pv flags
1.14.2.2   thorpej  *
1.14.2.6  jdolecek  * => caller should hold lock on vm_page [so that attrs can be adjusted]
1.14.2.2   thorpej  * => caller should NOT adjust pmap's wire_count
1.14.2.4   thorpej  * => caller must call pmap_vac_me_harder() if writable status of a page
1.14.2.4   thorpej  *    may have changed.
1.14.2.2   thorpej  * => we return the old flags
1.14.2.2   thorpej  *
     1.1      matt  * Modify a physical-virtual mapping in the pv table
     1.1      matt  */
     1.1      matt
1.14.2.4   thorpej /*__inline */
1.14.2.4   thorpej static u_int
1.14.2.6  jdolecek pmap_modify_pv(pmap, va, pg, bic_mask, eor_mask)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
1.14.2.6  jdolecek 	struct vm_page *pg;
     1.1      matt 	u_int bic_mask;
     1.1      matt 	u_int eor_mask;
     1.1      matt {
     1.1      matt 	struct pv_entry *npv;
     1.1      matt 	u_int flags, oflags;
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * There is at least one VA mapping this page.
     1.1      matt 	 */
     1.1      matt
1.14.2.6  jdolecek 	for (npv = pg->mdpage.pvh_list; npv; npv = npv->pv_next) {
     1.1      matt 		if (pmap == npv->pv_pmap && va == npv->pv_va) {
     1.1      matt 			oflags = npv->pv_flags;
     1.1      matt 			npv->pv_flags = flags =
     1.1      matt 			    ((oflags & ~bic_mask) ^ eor_mask);
     1.1      matt 			if ((flags ^ oflags) & PT_W) {
     1.1      matt 				if (flags & PT_W)
     1.1      matt 					++pmap->pm_stats.wired_count;
     1.1      matt 				else
     1.1      matt 					--pmap->pm_stats.wired_count;
     1.1      matt 			}
     1.1      matt 			return (oflags);
     1.1      matt 		}
     1.1      matt 	}
     1.1      matt 	return (0);
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * Map the specified level 2 pagetable into the level 1 page table for
     1.1      matt  * the given pmap to cover a chunk of virtual address space starting from the
     1.1      matt  * address specified.
     1.1      matt  */
     1.1      matt static /*__inline*/ void
1.14.2.2   thorpej pmap_map_in_l1(pmap, va, l2pa, selfref)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va, l2pa;
1.14.2.2   thorpej 	boolean_t selfref;
     1.1      matt {
     1.1      matt 	vaddr_t ptva;
     1.1      matt
     1.1      matt 	/* Calculate the index into the L1 page table. */
     1.1      matt 	ptva = (va >> PDSHIFT) & ~3;
     1.1      matt
1.14.2.6  jdolecek 	NPDEBUG(PDB_MAP_L1, printf("wiring %08lx in to pd%p pte0x%lx va0x%lx\n", l2pa,
     1.1      matt 	    pmap->pm_pdir, L1_PTE(l2pa), ptva));
     1.1      matt
     1.1      matt 	/* Map page table into the L1. */
     1.1      matt 	pmap->pm_pdir[ptva + 0] = L1_PTE(l2pa + 0x000);
     1.1      matt 	pmap->pm_pdir[ptva + 1] = L1_PTE(l2pa + 0x400);
     1.1      matt 	pmap->pm_pdir[ptva + 2] = L1_PTE(l2pa + 0x800);
     1.1      matt 	pmap->pm_pdir[ptva + 3] = L1_PTE(l2pa + 0xc00);
     1.1      matt
     1.1      matt 	/* Map the page table into the page table area. */
1.14.2.2   thorpej 	if (selfref) {
1.14.2.6  jdolecek 	    NPDEBUG(PDB_MAP_L1, printf("pt self reference %lx in %lx\n",
1.14.2.6  jdolecek 			L2_PTE_NC_NB(l2pa, AP_KRW), pmap->pm_vptpt));
1.14.2.6  jdolecek 	    *((pt_entry_t *)(pmap->pm_vptpt + ptva)) =
1.14.2.6  jdolecek 		L2_PTE_NC_NB(l2pa, AP_KRW);
1.14.2.2   thorpej 	}
     1.1      matt 	/* XXX should be a purge */
     1.1      matt /*	cpu_tlb_flushD();*/
     1.1      matt }
     1.1      matt
     1.1      matt #if 0
     1.1      matt static /*__inline*/ void
     1.1      matt pmap_unmap_in_l1(pmap, va)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
     1.1      matt {
     1.1      matt 	vaddr_t ptva;
     1.1      matt
     1.1      matt 	/* Calculate the index into the L1 page table. */
     1.1      matt 	ptva = (va >> PDSHIFT) & ~3;
     1.1      matt
     1.1      matt 	/* Unmap page table from the L1. */
     1.1      matt 	pmap->pm_pdir[ptva + 0] = 0;
     1.1      matt 	pmap->pm_pdir[ptva + 1] = 0;
     1.1      matt 	pmap->pm_pdir[ptva + 2] = 0;
     1.1      matt 	pmap->pm_pdir[ptva + 3] = 0;
     1.1      matt
     1.1      matt 	/* Unmap the page table from the page table area. */
     1.1      matt 	*((pt_entry_t *)(pmap->pm_vptpt + ptva)) = 0;
     1.1      matt
     1.1      matt 	/* XXX should be a purge */
     1.1      matt /*	cpu_tlb_flushD();*/
     1.1      matt }
     1.1      matt #endif
     1.1      matt
     1.1      matt /*
     1.1      matt  *	Used to map a range of physical addresses into kernel
     1.1      matt  *	virtual address space.
     1.1      matt  *
     1.1      matt  *	For now, VM is already on, we only need to map the
     1.1      matt  *	specified memory.
     1.1      matt  */
     1.1      matt vaddr_t
     1.1      matt pmap_map(va, spa, epa, prot)
     1.1      matt 	vaddr_t va, spa, epa;
     1.1      matt 	int prot;
     1.1      matt {
     1.1      matt 	while (spa < epa) {
1.14.2.3   thorpej 		pmap_kenter_pa(va, spa, prot);
     1.1      matt 		va += NBPG;
     1.1      matt 		spa += NBPG;
     1.1      matt 	}
1.14.2.3   thorpej 	pmap_update(pmap_kernel());
     1.1      matt 	return(va);
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
     1.3      matt  * void pmap_bootstrap(pd_entry_t *kernel_l1pt, pv_addr_t kernel_ptpt)
     1.1      matt  *
     1.1      matt  * bootstrap the pmap system. This is called from initarm and allows
     1.1      matt  * the pmap system to initailise any structures it requires.
     1.1      matt  *
     1.1      matt  * Currently this sets up the kernel_pmap that is statically allocated
     1.1      matt  * and also allocated virtual addresses for certain page hooks.
     1.1      matt  * Currently the only one page hook is allocated that is used
     1.1      matt  * to zero physical pages of memory.
     1.1      matt  * It also initialises the start and end address of the kernel data space.
     1.1      matt  */
     1.2      matt extern paddr_t physical_freestart;
     1.2      matt extern paddr_t physical_freeend;
     1.1      matt
1.14.2.2   thorpej char *boot_head;
     1.1      matt
     1.1      matt void
     1.1      matt pmap_bootstrap(kernel_l1pt, kernel_ptpt)
     1.1      matt 	pd_entry_t *kernel_l1pt;
     1.1      matt 	pv_addr_t kernel_ptpt;
     1.1      matt {
     1.1      matt 	int loop;
     1.2      matt 	paddr_t start, end;
     1.1      matt #if NISADMA > 0
     1.2      matt 	paddr_t istart;
     1.2      matt 	psize_t isize;
     1.1      matt #endif
     1.1      matt
1.14.2.1     lukem 	pmap_kernel()->pm_pdir = kernel_l1pt;
1.14.2.1     lukem 	pmap_kernel()->pm_pptpt = kernel_ptpt.pv_pa;
1.14.2.1     lukem 	pmap_kernel()->pm_vptpt = kernel_ptpt.pv_va;
1.14.2.1     lukem 	simple_lock_init(&pmap_kernel()->pm_lock);
1.14.2.1     lukem 	pmap_kernel()->pm_obj.pgops = NULL;
1.14.2.1     lukem 	TAILQ_INIT(&(pmap_kernel()->pm_obj.memq));
1.14.2.1     lukem 	pmap_kernel()->pm_obj.uo_npages = 0;
1.14.2.1     lukem 	pmap_kernel()->pm_obj.uo_refs = 1;
1.14.2.1     lukem
     1.1      matt 	/*
     1.1      matt 	 * Initialize PAGE_SIZE-dependent variables.
     1.1      matt 	 */
     1.1      matt 	uvm_setpagesize();
     1.1      matt
     1.1      matt 	npages = 0;
     1.1      matt 	loop = 0;
     1.1      matt 	while (loop < bootconfig.dramblocks) {
     1.2      matt 		start = (paddr_t)bootconfig.dram[loop].address;
     1.1      matt 		end = start + (bootconfig.dram[loop].pages * NBPG);
     1.1      matt 		if (start < physical_freestart)
     1.1      matt 			start = physical_freestart;
     1.1      matt 		if (end > physical_freeend)
     1.1      matt 			end = physical_freeend;
     1.1      matt #if 0
     1.1      matt 		printf("%d: %lx -> %lx\n", loop, start, end - 1);
     1.1      matt #endif
     1.1      matt #if NISADMA > 0
     1.1      matt 		if (pmap_isa_dma_range_intersect(start, end - start,
     1.1      matt 		    &istart, &isize)) {
     1.1      matt 			/*
     1.1      matt 			 * Place the pages that intersect with the
     1.1      matt 			 * ISA DMA range onto the ISA DMA free list.
     1.1      matt 			 */
     1.1      matt #if 0
     1.1      matt 			printf("    ISADMA 0x%lx -> 0x%lx\n", istart,
     1.1      matt 			    istart + isize - 1);
     1.1      matt #endif
     1.1      matt 			uvm_page_physload(atop(istart),
     1.1      matt 			    atop(istart + isize), atop(istart),
     1.1      matt 			    atop(istart + isize), VM_FREELIST_ISADMA);
     1.1      matt 			npages += atop(istart + isize) - atop(istart);
     1.1      matt
     1.1      matt 			/*
     1.1      matt 			 * Load the pieces that come before
     1.1      matt 			 * the intersection into the default
     1.1      matt 			 * free list.
     1.1      matt 			 */
     1.1      matt 			if (start < istart) {
     1.1      matt #if 0
     1.1      matt 				printf("    BEFORE 0x%lx -> 0x%lx\n",
     1.1      matt 				    start, istart - 1);
     1.1      matt #endif
     1.1      matt 				uvm_page_physload(atop(start),
     1.1      matt 				    atop(istart), atop(start),
     1.1      matt 				    atop(istart), VM_FREELIST_DEFAULT);
     1.1      matt 				npages += atop(istart) - atop(start);
     1.1      matt 			}
     1.1      matt
     1.1      matt 			/*
     1.1      matt 			 * Load the pieces that come after
     1.1      matt 			 * the intersection into the default
     1.1      matt 			 * free list.
     1.1      matt 			 */
     1.1      matt 			if ((istart + isize) < end) {
     1.1      matt #if 0
     1.1      matt 				printf("     AFTER 0x%lx -> 0x%lx\n",
     1.1      matt 				    (istart + isize), end - 1);
     1.1      matt #endif
     1.1      matt 				uvm_page_physload(atop(istart + isize),
     1.1      matt 				    atop(end), atop(istart + isize),
     1.1      matt 				    atop(end), VM_FREELIST_DEFAULT);
     1.1      matt 				npages += atop(end) - atop(istart + isize);
     1.1      matt 			}
     1.1      matt 		} else {
     1.1      matt 			uvm_page_physload(atop(start), atop(end),
     1.1      matt 			    atop(start), atop(end), VM_FREELIST_DEFAULT);
     1.1      matt 			npages += atop(end) - atop(start);
     1.1      matt 		}
     1.1      matt #else	/* NISADMA > 0 */
     1.1      matt 		uvm_page_physload(atop(start), atop(end),
     1.1      matt 		    atop(start), atop(end), VM_FREELIST_DEFAULT);
     1.1      matt 		npages += atop(end) - atop(start);
     1.1      matt #endif /* NISADMA > 0 */
     1.1      matt 		++loop;
     1.1      matt 	}
     1.1      matt
     1.1      matt #ifdef MYCROFT_HACK
     1.1      matt 	printf("npages = %ld\n", npages);
     1.1      matt #endif
     1.1      matt
     1.1      matt 	virtual_start = KERNEL_VM_BASE;
1.14.2.6  jdolecek 	virtual_end = KERNEL_VM_BASE + KERNEL_VM_SIZE - 1;
     1.1      matt
     1.1      matt 	ALLOC_PAGE_HOOK(page_hook0, NBPG);
     1.1      matt 	ALLOC_PAGE_HOOK(page_hook1, NBPG);
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * The mem special device needs a virtual hook but we don't
     1.1      matt 	 * need a pte
     1.1      matt 	 */
     1.1      matt 	memhook = (char *)virtual_start;
     1.1      matt 	virtual_start += NBPG;
     1.1      matt
     1.1      matt 	msgbufaddr = (caddr_t)virtual_start;
1.14.2.1     lukem 	msgbufpte = (pt_entry_t)pmap_pte(pmap_kernel(), virtual_start);
     1.1      matt 	virtual_start += round_page(MSGBUFSIZE);
     1.1      matt
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * init the static-global locks and global lists.
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej 	spinlockinit(&pmap_main_lock, "pmaplk", 0);
1.14.2.2   thorpej 	simple_lock_init(&pvalloc_lock);
1.14.2.6  jdolecek 	simple_lock_init(&pmaps_lock);
1.14.2.6  jdolecek 	LIST_INIT(&pmaps);
1.14.2.2   thorpej 	TAILQ_INIT(&pv_freepages);
1.14.2.2   thorpej 	TAILQ_INIT(&pv_unusedpgs);
     1.1      matt
    1.10     chris 	/*
    1.10     chris 	 * initialize the pmap pool.
    1.10     chris 	 */
    1.10     chris
    1.10     chris 	pool_init(&pmap_pmap_pool, sizeof(struct pmap), 0, 0, 0, "pmappl",
1.14.2.6  jdolecek 		  &pool_allocator_nointr);
    1.10     chris
1.14.2.5  jdolecek 	cpu_dcache_wbinv_all();
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * void pmap_init(void)
     1.1      matt  *
     1.1      matt  * Initialize the pmap module.
     1.1      matt  * Called by vm_init() in vm/vm_init.c in order to initialise
     1.1      matt  * any structures that the pmap system needs to map virtual memory.
     1.1      matt  */
     1.1      matt
     1.1      matt extern int physmem;
     1.1      matt
     1.1      matt void
     1.1      matt pmap_init()
     1.1      matt {
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * Set the available memory vars - These do not map to real memory
     1.1      matt 	 * addresses and cannot as the physical memory is fragmented.
     1.1      matt 	 * They are used by ps for %mem calculations.
     1.1      matt 	 * One could argue whether this should be the entire memory or just
     1.1      matt 	 * the memory that is useable in a user process.
     1.1      matt 	 */
     1.1      matt 	avail_start = 0;
     1.1      matt 	avail_end = physmem * NBPG;
     1.1      matt
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * now we need to free enough pv_entry structures to allow us to get
1.14.2.2   thorpej 	 * the kmem_map/kmem_object allocated and inited (done after this
1.14.2.2   thorpej 	 * function is finished).  to do this we allocate one bootstrap page out
1.14.2.2   thorpej 	 * of kernel_map and use it to provide an initial pool of pv_entry
1.14.2.2   thorpej 	 * structures.   we never free this page.
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej
1.14.2.2   thorpej 	pv_initpage = (struct pv_page *) uvm_km_alloc(kernel_map, PAGE_SIZE);
1.14.2.2   thorpej 	if (pv_initpage == NULL)
1.14.2.2   thorpej 		panic("pmap_init: pv_initpage");
1.14.2.2   thorpej 	pv_cachedva = 0;   /* a VA we have allocated but not used yet */
1.14.2.2   thorpej 	pv_nfpvents = 0;
1.14.2.2   thorpej 	(void) pmap_add_pvpage(pv_initpage, FALSE);
1.14.2.2   thorpej
     1.1      matt 	pmap_initialized = TRUE;
     1.1      matt
     1.1      matt 	/* Initialise our L1 page table queues and counters */
     1.1      matt 	SIMPLEQ_INIT(&l1pt_static_queue);
     1.1      matt 	l1pt_static_queue_count = 0;
     1.1      matt 	l1pt_static_create_count = 0;
     1.1      matt 	SIMPLEQ_INIT(&l1pt_queue);
     1.1      matt 	l1pt_queue_count = 0;
     1.1      matt 	l1pt_create_count = 0;
     1.1      matt 	l1pt_reuse_count = 0;
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * pmap_postinit()
     1.1      matt  *
     1.1      matt  * This routine is called after the vm and kmem subsystems have been
     1.1      matt  * initialised. This allows the pmap code to perform any initialisation
     1.1      matt  * that can only be done one the memory allocation is in place.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_postinit()
     1.1      matt {
     1.1      matt 	int loop;
     1.1      matt 	struct l1pt *pt;
     1.1      matt
     1.1      matt #ifdef PMAP_STATIC_L1S
     1.1      matt 	for (loop = 0; loop < PMAP_STATIC_L1S; ++loop) {
     1.1      matt #else	/* PMAP_STATIC_L1S */
     1.1      matt 	for (loop = 0; loop < max_processes; ++loop) {
     1.1      matt #endif	/* PMAP_STATIC_L1S */
     1.1      matt 		/* Allocate a L1 page table */
     1.1      matt 		pt = pmap_alloc_l1pt();
     1.1      matt 		if (!pt)
     1.1      matt 			panic("Cannot allocate static L1 page tables\n");
     1.1      matt
     1.1      matt 		/* Clean it */
     1.1      matt 		bzero((void *)pt->pt_va, PD_SIZE);
     1.1      matt 		pt->pt_flags |= (PTFLAG_STATIC | PTFLAG_CLEAN);
     1.1      matt 		/* Add the page table to the queue */
     1.1      matt 		SIMPLEQ_INSERT_TAIL(&l1pt_static_queue, pt, pt_queue);
     1.1      matt 		++l1pt_static_queue_count;
     1.1      matt 		++l1pt_static_create_count;
     1.1      matt 	}
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
     1.1      matt  * Create and return a physical map.
     1.1      matt  *
     1.1      matt  * If the size specified for the map is zero, the map is an actual physical
     1.1      matt  * map, and may be referenced by the hardware.
     1.1      matt  *
     1.1      matt  * If the size specified is non-zero, the map will be used in software only,
     1.1      matt  * and is bounded by that size.
     1.1      matt  */
     1.1      matt
     1.1      matt pmap_t
     1.1      matt pmap_create()
     1.1      matt {
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt
    1.10     chris 	/*
    1.10     chris 	 * Fetch pmap entry from the pool
    1.10     chris 	 */
    1.10     chris
    1.10     chris 	pmap = pool_get(&pmap_pmap_pool, PR_WAITOK);
1.14.2.2   thorpej 	/* XXX is this really needed! */
1.14.2.2   thorpej 	memset(pmap, 0, sizeof(*pmap));
     1.1      matt
1.14.2.1     lukem 	simple_lock_init(&pmap->pm_obj.vmobjlock);
1.14.2.1     lukem 	pmap->pm_obj.pgops = NULL;	/* currently not a mappable object */
1.14.2.1     lukem 	TAILQ_INIT(&pmap->pm_obj.memq);
1.14.2.1     lukem 	pmap->pm_obj.uo_npages = 0;
1.14.2.1     lukem 	pmap->pm_obj.uo_refs = 1;
1.14.2.1     lukem 	pmap->pm_stats.wired_count = 0;
1.14.2.1     lukem 	pmap->pm_stats.resident_count = 1;
1.14.2.1     lukem
     1.1      matt 	/* Now init the machine part of the pmap */
     1.1      matt 	pmap_pinit(pmap);
     1.1      matt 	return(pmap);
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * pmap_alloc_l1pt()
     1.1      matt  *
     1.1      matt  * This routine allocates physical and virtual memory for a L1 page table
     1.1      matt  * and wires it.
     1.1      matt  * A l1pt structure is returned to describe the allocated page table.
     1.1      matt  *
     1.1      matt  * This routine is allowed to fail if the required memory cannot be allocated.
     1.1      matt  * In this case NULL is returned.
     1.1      matt  */
     1.1      matt
     1.1      matt struct l1pt *
     1.1      matt pmap_alloc_l1pt(void)
     1.1      matt {
     1.2      matt 	paddr_t pa;
     1.2      matt 	vaddr_t va;
     1.1      matt 	struct l1pt *pt;
     1.1      matt 	int error;
     1.9       chs 	struct vm_page *m;
    1.11     chris 	pt_entry_t *ptes;
     1.1      matt
     1.1      matt 	/* Allocate virtual address space for the L1 page table */
     1.1      matt 	va = uvm_km_valloc(kernel_map, PD_SIZE);
     1.1      matt 	if (va == 0) {
     1.1      matt #ifdef DIAGNOSTIC
1.14.2.4   thorpej 		PDEBUG(0,
1.14.2.4   thorpej 		    printf("pmap: Cannot allocate pageable memory for L1\n"));
     1.1      matt #endif	/* DIAGNOSTIC */
     1.1      matt 		return(NULL);
     1.1      matt 	}
     1.1      matt
     1.1      matt 	/* Allocate memory for the l1pt structure */
     1.1      matt 	pt = (struct l1pt *)malloc(sizeof(struct l1pt), M_VMPMAP, M_WAITOK);
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * Allocate pages from the VM system.
     1.1      matt 	 */
     1.1      matt 	TAILQ_INIT(&pt->pt_plist);
     1.1      matt 	error = uvm_pglistalloc(PD_SIZE, physical_start, physical_end,
     1.1      matt 	    PD_SIZE, 0, &pt->pt_plist, 1, M_WAITOK);
     1.1      matt 	if (error) {
     1.1      matt #ifdef DIAGNOSTIC
1.14.2.4   thorpej 		PDEBUG(0,
1.14.2.4   thorpej 		    printf("pmap: Cannot allocate physical mem for L1 (%d)\n",
1.14.2.4   thorpej 		    error));
     1.1      matt #endif	/* DIAGNOSTIC */
     1.1      matt 		/* Release the resources we already have claimed */
     1.1      matt 		free(pt, M_VMPMAP);
     1.1      matt 		uvm_km_free(kernel_map, va, PD_SIZE);
     1.1      matt 		return(NULL);
     1.1      matt 	}
     1.1      matt
     1.1      matt 	/* Map our physical pages into our virtual space */
     1.1      matt 	pt->pt_va = va;
1.14.2.6  jdolecek 	m = TAILQ_FIRST(&pt->pt_plist);
    1.11     chris 	ptes = pmap_map_ptes(pmap_kernel());
     1.1      matt 	while (m && va < (pt->pt_va + PD_SIZE)) {
     1.1      matt 		pa = VM_PAGE_TO_PHYS(m);
     1.1      matt
1.14.2.3   thorpej 		pmap_kenter_pa(va, pa, VM_PROT_READ | VM_PROT_WRITE);
     1.1      matt
     1.1      matt 		/* Revoke cacheability and bufferability */
     1.1      matt 		/* XXX should be done better than this */
    1.11     chris 		ptes[arm_byte_to_page(va)] &= ~(PT_C | PT_B);
     1.1      matt
     1.1      matt 		va += NBPG;
     1.1      matt 		m = m->pageq.tqe_next;
     1.1      matt 	}
    1.11     chris 	pmap_unmap_ptes(pmap_kernel());
1.14.2.3   thorpej 	pmap_update(pmap_kernel());
     1.1      matt
     1.1      matt #ifdef DIAGNOSTIC
     1.1      matt 	if (m)
     1.1      matt 		panic("pmap_alloc_l1pt: pglist not empty\n");
     1.1      matt #endif	/* DIAGNOSTIC */
     1.1      matt
     1.1      matt 	pt->pt_flags = 0;
     1.1      matt 	return(pt);
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * Free a L1 page table previously allocated with pmap_alloc_l1pt().
     1.1      matt  */
1.14.2.4   thorpej static void
     1.1      matt pmap_free_l1pt(pt)
     1.1      matt 	struct l1pt *pt;
     1.1      matt {
     1.1      matt 	/* Separate the physical memory for the virtual space */
1.14.2.3   thorpej 	pmap_kremove(pt->pt_va, PD_SIZE);
1.14.2.3   thorpej 	pmap_update(pmap_kernel());
     1.1      matt
     1.1      matt 	/* Return the physical memory */
     1.1      matt 	uvm_pglistfree(&pt->pt_plist);
     1.1      matt
     1.1      matt 	/* Free the virtual space */
     1.1      matt 	uvm_km_free(kernel_map, pt->pt_va, PD_SIZE);
     1.1      matt
     1.1      matt 	/* Free the l1pt structure */
     1.1      matt 	free(pt, M_VMPMAP);
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * Allocate a page directory.
     1.1      matt  * This routine will either allocate a new page directory from the pool
     1.1      matt  * of L1 page tables currently held by the kernel or it will allocate
     1.1      matt  * a new one via pmap_alloc_l1pt().
     1.1      matt  * It will then initialise the l1 page table for use.
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  * XXX must tidy up and fix this code, not happy about how it does the pmaps_locking
     1.1      matt  */
1.14.2.4   thorpej static int
     1.1      matt pmap_allocpagedir(pmap)
     1.1      matt 	struct pmap *pmap;
     1.1      matt {
     1.2      matt 	paddr_t pa;
     1.1      matt 	struct l1pt *pt;
     1.1      matt 	pt_entry_t *pte;
     1.1      matt
     1.1      matt 	PDEBUG(0, printf("pmap_allocpagedir(%p)\n", pmap));
     1.1      matt
     1.1      matt 	/* Do we have any spare L1's lying around ? */
     1.1      matt 	if (l1pt_static_queue_count) {
     1.1      matt 		--l1pt_static_queue_count;
     1.1      matt 		pt = l1pt_static_queue.sqh_first;
     1.1      matt 		SIMPLEQ_REMOVE_HEAD(&l1pt_static_queue, pt, pt_queue);
     1.1      matt 	} else if (l1pt_queue_count) {
     1.1      matt 		--l1pt_queue_count;
     1.1      matt 		pt = l1pt_queue.sqh_first;
     1.1      matt 		SIMPLEQ_REMOVE_HEAD(&l1pt_queue, pt, pt_queue);
     1.1      matt 		++l1pt_reuse_count;
     1.1      matt 	} else {
     1.1      matt 		pt = pmap_alloc_l1pt();
     1.1      matt 		if (!pt)
     1.1      matt 			return(ENOMEM);
     1.1      matt 		++l1pt_create_count;
     1.1      matt 	}
     1.1      matt
     1.1      matt 	/* Store the pointer to the l1 descriptor in the pmap. */
     1.1      matt 	pmap->pm_l1pt = pt;
     1.1      matt
     1.1      matt 	/* Get the physical address of the start of the l1 */
1.14.2.6  jdolecek 	pa = VM_PAGE_TO_PHYS(TAILQ_FIRST(&pt->pt_plist));
     1.1      matt
     1.1      matt 	/* Store the virtual address of the l1 in the pmap. */
     1.1      matt 	pmap->pm_pdir = (pd_entry_t *)pt->pt_va;
     1.1      matt
     1.1      matt 	/* Clean the L1 if it is dirty */
     1.1      matt 	if (!(pt->pt_flags & PTFLAG_CLEAN))
     1.1      matt 		bzero((void *)pmap->pm_pdir, (PD_SIZE - KERNEL_PD_SIZE));
     1.1      matt
     1.1      matt 	/* Allocate a page table to map all the page tables for this pmap */
     1.1      matt
     1.1      matt #ifdef DIAGNOSTIC
     1.1      matt 	if (pmap->pm_vptpt) {
     1.1      matt 		/* XXX What if we have one already ? */
     1.1      matt 		panic("pmap_allocpagedir: have pt already\n");
     1.1      matt 	}
     1.1      matt #endif	/* DIAGNOSTIC */
     1.1      matt 	pmap->pm_vptpt = uvm_km_zalloc(kernel_map, NBPG);
     1.5    toshii 	if (pmap->pm_vptpt == 0) {
1.14.2.6  jdolecek 	    pmap_freepagedir(pmap);
1.14.2.6  jdolecek     	    return(ENOMEM);
     1.5    toshii 	}
     1.5    toshii
1.14.2.6  jdolecek 	/* need to lock this all up  for growkernel */
1.14.2.6  jdolecek 	simple_lock(&pmaps_lock);
1.14.2.6  jdolecek 	/* wish we didn't have to keep this locked... */
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	/* Duplicate the kernel mapping i.e. all mappings 0xf0000000+ */
1.14.2.6  jdolecek 	bcopy((char *)pmap_kernel()->pm_pdir + (PD_SIZE - KERNEL_PD_SIZE),
1.14.2.6  jdolecek 		(char *)pmap->pm_pdir + (PD_SIZE - KERNEL_PD_SIZE),
1.14.2.6  jdolecek 		KERNEL_PD_SIZE);
1.14.2.6  jdolecek
1.14.2.1     lukem 	(void) pmap_extract(pmap_kernel(), pmap->pm_vptpt, &pmap->pm_pptpt);
     1.1      matt 	pmap->pm_pptpt &= PG_FRAME;
     1.1      matt 	/* Revoke cacheability and bufferability */
     1.1      matt 	/* XXX should be done better than this */
1.14.2.1     lukem 	pte = pmap_pte(pmap_kernel(), pmap->pm_vptpt);
     1.1      matt 	*pte = *pte & ~(PT_C | PT_B);
     1.1      matt
     1.1      matt 	/* Wire in this page table */
1.14.2.2   thorpej 	pmap_map_in_l1(pmap, PROCESS_PAGE_TBLS_BASE, pmap->pm_pptpt, TRUE);
     1.1      matt
     1.1      matt 	pt->pt_flags &= ~PTFLAG_CLEAN;	/* L1 is dirty now */
1.14.2.6  jdolecek
     1.1      matt 	/*
     1.1      matt 	 * Map the kernel page tables for 0xf0000000 +
     1.1      matt 	 * into the page table used to map the
     1.1      matt 	 * pmap's page tables
     1.1      matt 	 */
     1.1      matt 	bcopy((char *)(PROCESS_PAGE_TBLS_BASE
     1.1      matt 	    + (PROCESS_PAGE_TBLS_BASE >> (PGSHIFT - 2))
     1.1      matt 	    + ((PD_SIZE - KERNEL_PD_SIZE) >> 2)),
     1.1      matt 	    (char *)pmap->pm_vptpt + ((PD_SIZE - KERNEL_PD_SIZE) >> 2),
     1.1      matt 	    (KERNEL_PD_SIZE >> 2));
     1.1      matt
1.14.2.6  jdolecek 	LIST_INSERT_HEAD(&pmaps, pmap, pm_list);
1.14.2.6  jdolecek 	simple_unlock(&pmaps_lock);
1.14.2.6  jdolecek
     1.1      matt 	return(0);
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
     1.1      matt  * Initialize a preallocated and zeroed pmap structure,
     1.1      matt  * such as one in a vmspace structure.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_pinit(pmap)
     1.1      matt 	struct pmap *pmap;
     1.1      matt {
1.14.2.4   thorpej 	int backoff = 6;
1.14.2.4   thorpej 	int retry = 10;
1.14.2.4   thorpej
     1.1      matt 	PDEBUG(0, printf("pmap_pinit(%p)\n", pmap));
     1.1      matt
     1.1      matt 	/* Keep looping until we succeed in allocating a page directory */
     1.1      matt 	while (pmap_allocpagedir(pmap) != 0) {
     1.1      matt 		/*
     1.1      matt 		 * Ok we failed to allocate a suitable block of memory for an
     1.1      matt 		 * L1 page table. This means that either:
     1.1      matt 		 * 1. 16KB of virtual address space could not be allocated
     1.1      matt 		 * 2. 16KB of physically contiguous memory on a 16KB boundary
     1.1      matt 		 *    could not be allocated.
     1.1      matt 		 *
     1.1      matt 		 * Since we cannot fail we will sleep for a while and try
1.14.2.2   thorpej 		 * again.
1.14.2.4   thorpej 		 *
1.14.2.4   thorpej 		 * Searching for a suitable L1 PT is expensive:
1.14.2.4   thorpej 		 * to avoid hogging the system when memory is really
1.14.2.4   thorpej 		 * scarce, use an exponential back-off so that
1.14.2.4   thorpej 		 * eventually we won't retry more than once every 8
1.14.2.4   thorpej 		 * seconds.  This should allow other processes to run
1.14.2.4   thorpej 		 * to completion and free up resources.
     1.1      matt 		 */
1.14.2.4   thorpej 		(void) ltsleep(&lbolt, PVM, "l1ptwait", (hz << 3) >> backoff,
1.14.2.4   thorpej 		    NULL);
1.14.2.4   thorpej 		if (--retry == 0) {
1.14.2.4   thorpej 			retry = 10;
1.14.2.4   thorpej 			if (backoff)
1.14.2.4   thorpej 				--backoff;
1.14.2.4   thorpej 		}
     1.1      matt 	}
     1.1      matt
     1.1      matt 	/* Map zero page for the pmap. This will also map the L2 for it */
     1.1      matt 	pmap_enter(pmap, 0x00000000, systempage.pv_pa,
     1.1      matt 	    VM_PROT_READ, VM_PROT_READ | PMAP_WIRED);
1.14.2.3   thorpej 	pmap_update(pmap);
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt void
     1.1      matt pmap_freepagedir(pmap)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt {
     1.1      matt 	/* Free the memory used for the page table mapping */
     1.5    toshii 	if (pmap->pm_vptpt != 0)
     1.5    toshii 		uvm_km_free(kernel_map, (vaddr_t)pmap->pm_vptpt, NBPG);
     1.1      matt
     1.1      matt 	/* junk the L1 page table */
     1.1      matt 	if (pmap->pm_l1pt->pt_flags & PTFLAG_STATIC) {
     1.1      matt 		/* Add the page table to the queue */
     1.1      matt 		SIMPLEQ_INSERT_TAIL(&l1pt_static_queue, pmap->pm_l1pt, pt_queue);
     1.1      matt 		++l1pt_static_queue_count;
     1.1      matt 	} else if (l1pt_queue_count < 8) {
     1.1      matt 		/* Add the page table to the queue */
     1.1      matt 		SIMPLEQ_INSERT_TAIL(&l1pt_queue, pmap->pm_l1pt, pt_queue);
     1.1      matt 		++l1pt_queue_count;
     1.1      matt 	} else
     1.1      matt 		pmap_free_l1pt(pmap->pm_l1pt);
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
     1.1      matt  * Retire the given physical map from service.
     1.1      matt  * Should only be called if the map contains no valid mappings.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_destroy(pmap)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt {
1.14.2.2   thorpej 	struct vm_page *page;
     1.1      matt 	int count;
     1.1      matt
     1.1      matt 	if (pmap == NULL)
     1.1      matt 		return;
     1.1      matt
     1.1      matt 	PDEBUG(0, printf("pmap_destroy(%p)\n", pmap));
1.14.2.2   thorpej
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * Drop reference count
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej 	simple_lock(&pmap->pm_obj.vmobjlock);
1.14.2.1     lukem 	count = --pmap->pm_obj.uo_refs;
1.14.2.2   thorpej 	simple_unlock(&pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 	if (count > 0) {
1.14.2.2   thorpej 		return;
     1.1      matt 	}
     1.1      matt
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * reference count is zero, free pmap resources and then free pmap.
1.14.2.2   thorpej 	 */
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	/*
1.14.2.6  jdolecek 	 * remove it from global list of pmaps
1.14.2.6  jdolecek 	 */
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	simple_lock(&pmaps_lock);
1.14.2.6  jdolecek 	LIST_REMOVE(pmap, pm_list);
1.14.2.6  jdolecek 	simple_unlock(&pmaps_lock);
1.14.2.2   thorpej
     1.1      matt 	/* Remove the zero page mapping */
     1.1      matt 	pmap_remove(pmap, 0x00000000, 0x00000000 + NBPG);
1.14.2.3   thorpej 	pmap_update(pmap);
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * Free any page tables still mapped
     1.1      matt 	 * This is only temporay until pmap_enter can count the number
     1.1      matt 	 * of mappings made in a page table. Then pmap_remove() can
     1.1      matt 	 * reduce the count and free the pagetable when the count
1.14.2.1     lukem 	 * reaches zero.  Note that entries in this list should match the
1.14.2.1     lukem 	 * contents of the ptpt, however this is faster than walking a 1024
1.14.2.1     lukem 	 * entries looking for pt's
1.14.2.1     lukem 	 * taken from i386 pmap.c
     1.1      matt 	 */
1.14.2.6  jdolecek 	while ((page = TAILQ_FIRST(&pmap->pm_obj.memq)) != NULL) {
1.14.2.6  jdolecek 		KASSERT((page->flags & PG_BUSY) == 0);
1.14.2.1     lukem 		page->wire_count = 0;
1.14.2.1     lukem 		uvm_pagefree(page);
     1.1      matt 	}
1.14.2.1     lukem
     1.1      matt 	/* Free the page dir */
     1.1      matt 	pmap_freepagedir(pmap);
1.14.2.2   thorpej
1.14.2.2   thorpej 	/* return the pmap to the pool */
1.14.2.2   thorpej 	pool_put(&pmap_pmap_pool, pmap);
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
1.14.2.1     lukem  * void pmap_reference(struct pmap *pmap)
     1.1      matt  *
     1.1      matt  * Add a reference to the specified pmap.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_reference(pmap)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt {
     1.1      matt 	if (pmap == NULL)
     1.1      matt 		return;
     1.1      matt
     1.1      matt 	simple_lock(&pmap->pm_lock);
1.14.2.1     lukem 	pmap->pm_obj.uo_refs++;
     1.1      matt 	simple_unlock(&pmap->pm_lock);
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * void pmap_virtual_space(vaddr_t *start, vaddr_t *end)
     1.1      matt  *
     1.1      matt  * Return the start and end addresses of the kernel's virtual space.
     1.1      matt  * These values are setup in pmap_bootstrap and are updated as pages
     1.1      matt  * are allocated.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_virtual_space(start, end)
     1.1      matt 	vaddr_t *start;
     1.1      matt 	vaddr_t *end;
     1.1      matt {
     1.1      matt 	*start = virtual_start;
     1.1      matt 	*end = virtual_end;
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
     1.1      matt  * Activate the address space for the specified process.  If the process
     1.1      matt  * is the current process, load the new MMU context.
     1.1      matt  */
     1.1      matt void
     1.1      matt pmap_activate(p)
     1.1      matt 	struct proc *p;
     1.1      matt {
1.14.2.1     lukem 	struct pmap *pmap = p->p_vmspace->vm_map.pmap;
     1.1      matt 	struct pcb *pcb = &p->p_addr->u_pcb;
     1.1      matt
1.14.2.1     lukem 	(void) pmap_extract(pmap_kernel(), (vaddr_t)pmap->pm_pdir,
     1.1      matt 	    (paddr_t *)&pcb->pcb_pagedir);
     1.1      matt
     1.1      matt 	PDEBUG(0, printf("pmap_activate: p=%p pmap=%p pcb=%p pdir=%p l1=%p\n",
     1.1      matt 	    p, pmap, pcb, pmap->pm_pdir, pcb->pcb_pagedir));
     1.1      matt
     1.1      matt 	if (p == curproc) {
     1.1      matt 		PDEBUG(0, printf("pmap_activate: setting TTB\n"));
     1.1      matt 		setttb((u_int)pcb->pcb_pagedir);
     1.1      matt 	}
     1.1      matt #if 0
     1.1      matt 	pmap->pm_pdchanged = FALSE;
     1.1      matt #endif
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
     1.1      matt  * Deactivate the address space of the specified process.
     1.1      matt  */
     1.1      matt void
     1.1      matt pmap_deactivate(p)
     1.1      matt 	struct proc *p;
     1.1      matt {
     1.1      matt }
     1.1      matt
1.14.2.4   thorpej /*
1.14.2.4   thorpej  * Perform any deferred pmap operations.
1.14.2.4   thorpej  */
1.14.2.4   thorpej void
1.14.2.4   thorpej pmap_update(struct pmap *pmap)
1.14.2.4   thorpej {
1.14.2.4   thorpej
1.14.2.4   thorpej 	/*
1.14.2.4   thorpej 	 * We haven't deferred any pmap operations, but we do need to
1.14.2.4   thorpej 	 * make sure TLB/cache operations have completed.
1.14.2.4   thorpej 	 */
1.14.2.4   thorpej 	cpu_cpwait();
1.14.2.4   thorpej }
     1.1      matt
     1.1      matt /*
     1.1      matt  * pmap_clean_page()
     1.1      matt  *
     1.1      matt  * This is a local function used to work out the best strategy to clean
     1.1      matt  * a single page referenced by its entry in the PV table. It's used by
     1.1      matt  * pmap_copy_page, pmap_zero page and maybe some others later on.
     1.1      matt  *
     1.1      matt  * Its policy is effectively:
     1.1      matt  *  o If there are no mappings, we don't bother doing anything with the cache.
     1.1      matt  *  o If there is one mapping, we clean just that page.
     1.1      matt  *  o If there are multiple mappings, we clean the entire cache.
     1.1      matt  *
     1.1      matt  * So that some functions can be further optimised, it returns 0 if it didn't
     1.1      matt  * clean the entire cache, or 1 if it did.
     1.1      matt  *
     1.1      matt  * XXX One bug in this routine is that if the pv_entry has a single page
     1.1      matt  * mapped at 0x00000000 a whole cache clean will be performed rather than
     1.1      matt  * just the 1 page. Since this should not occur in everyday use and if it does
     1.1      matt  * it will just result in not the most efficient clean for the page.
     1.1      matt  */
     1.1      matt static int
1.14.2.2   thorpej pmap_clean_page(pv, is_src)
     1.1      matt 	struct pv_entry *pv;
1.14.2.2   thorpej 	boolean_t is_src;
     1.1      matt {
1.14.2.2   thorpej 	struct pmap *pmap;
1.14.2.2   thorpej 	struct pv_entry *npv;
     1.1      matt 	int cache_needs_cleaning = 0;
     1.1      matt 	vaddr_t page_to_clean = 0;
     1.1      matt
1.14.2.2   thorpej 	if (pv == NULL)
1.14.2.2   thorpej 		/* nothing mapped in so nothing to flush */
1.14.2.2   thorpej 		return (0);
1.14.2.2   thorpej
1.14.2.2   thorpej 	/* Since we flush the cache each time we change curproc, we
1.14.2.2   thorpej 	 * only need to flush the page if it is in the current pmap.
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej 	if (curproc)
1.14.2.2   thorpej 		pmap = curproc->p_vmspace->vm_map.pmap;
1.14.2.2   thorpej 	else
1.14.2.2   thorpej 		pmap = pmap_kernel();
1.14.2.2   thorpej
1.14.2.2   thorpej 	for (npv = pv; npv; npv = npv->pv_next) {
1.14.2.2   thorpej 		if (npv->pv_pmap == pmap) {
1.14.2.2   thorpej 			/* The page is mapped non-cacheable in
1.14.2.2   thorpej 			 * this map.  No need to flush the cache.
1.14.2.2   thorpej 			 */
1.14.2.2   thorpej 			if (npv->pv_flags & PT_NC) {
1.14.2.2   thorpej #ifdef DIAGNOSTIC
1.14.2.2   thorpej 				if (cache_needs_cleaning)
1.14.2.2   thorpej 					panic("pmap_clean_page: "
1.14.2.2   thorpej 							"cache inconsistency");
1.14.2.2   thorpej #endif
1.14.2.2   thorpej 				break;
1.14.2.2   thorpej 			}
1.14.2.2   thorpej #if 0
1.14.2.2   thorpej 			/* This doesn't work, because pmap_protect
1.14.2.2   thorpej 			   doesn't flush changes on pages that it
1.14.2.2   thorpej 			   has write-protected.  */
1.14.2.4   thorpej
1.14.2.4   thorpej 			/* If the page is not writable and this
1.14.2.2   thorpej 			   is the source, then there is no need
1.14.2.2   thorpej 			   to flush it from the cache.  */
1.14.2.2   thorpej 			else if (is_src && ! (npv->pv_flags & PT_Wr))
1.14.2.2   thorpej 				continue;
1.14.2.2   thorpej #endif
1.14.2.2   thorpej 			if (cache_needs_cleaning){
1.14.2.2   thorpej 				page_to_clean = 0;
1.14.2.2   thorpej 				break;
1.14.2.2   thorpej 			}
1.14.2.2   thorpej 			else
1.14.2.2   thorpej 				page_to_clean = npv->pv_va;
1.14.2.2   thorpej 			cache_needs_cleaning = 1;
1.14.2.2   thorpej 		}
     1.1      matt 	}
     1.1      matt
     1.1      matt 	if (page_to_clean)
1.14.2.5  jdolecek 		cpu_idcache_wbinv_range(page_to_clean, NBPG);
     1.1      matt 	else if (cache_needs_cleaning) {
1.14.2.5  jdolecek 		cpu_idcache_wbinv_all();
     1.1      matt 		return (1);
     1.1      matt 	}
     1.1      matt 	return (0);
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * pmap_zero_page()
     1.1      matt  *
     1.1      matt  * Zero a given physical page by mapping it at a page hook point.
     1.1      matt  * In doing the zero page op, the page we zero is mapped cachable, as with
     1.1      matt  * StrongARM accesses to non-cached pages are non-burst making writing
     1.1      matt  * _any_ bulk data very slow.
     1.1      matt  */
     1.1      matt void
     1.1      matt pmap_zero_page(phys)
     1.2      matt 	paddr_t phys;
     1.1      matt {
1.14.2.6  jdolecek 	struct vm_page *pg;
     1.1      matt
     1.1      matt 	/* Get an entry for this page, and clean it it. */
1.14.2.6  jdolecek 	pg = PHYS_TO_VM_PAGE(phys);
1.14.2.6  jdolecek 	simple_lock(&pg->mdpage.pvh_slock);
1.14.2.6  jdolecek 	pmap_clean_page(pg->mdpage.pvh_list, FALSE);
1.14.2.6  jdolecek 	simple_unlock(&pg->mdpage.pvh_slock);
1.14.2.2   thorpej
     1.1      matt 	/*
     1.1      matt 	 * Hook in the page, zero it, and purge the cache for that
     1.1      matt 	 * zeroed page. Invalidate the TLB as needed.
     1.1      matt 	 */
     1.1      matt 	*page_hook0.pte = L2_PTE(phys & PG_FRAME, AP_KRW);
     1.1      matt 	cpu_tlb_flushD_SE(page_hook0.va);
1.14.2.4   thorpej 	cpu_cpwait();
     1.1      matt 	bzero_page(page_hook0.va);
1.14.2.5  jdolecek 	cpu_dcache_wbinv_range(page_hook0.va, NBPG);
     1.1      matt }
     1.1      matt
1.14.2.2   thorpej /* pmap_pageidlezero()
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * The same as above, except that we assume that the page is not
1.14.2.2   thorpej  * mapped.  This means we never have to flush the cache first.  Called
1.14.2.2   thorpej  * from the idle loop.
1.14.2.2   thorpej  */
1.14.2.2   thorpej boolean_t
1.14.2.2   thorpej pmap_pageidlezero(phys)
1.14.2.2   thorpej     paddr_t phys;
1.14.2.2   thorpej {
1.14.2.2   thorpej 	int i, *ptr;
1.14.2.2   thorpej 	boolean_t rv = TRUE;
1.14.2.2   thorpej
1.14.2.2   thorpej #ifdef DIAGNOSTIC
1.14.2.6  jdolecek 	struct vm_page *pg;
1.14.2.2   thorpej
1.14.2.6  jdolecek 	pg = PHYS_TO_VM_PAGE(phys);
1.14.2.6  jdolecek 	if (pg->mdpage.pvh_list != NULL)
1.14.2.2   thorpej 		panic("pmap_pageidlezero: zeroing mapped page\n");
1.14.2.2   thorpej #endif
1.14.2.2   thorpej
1.14.2.2   thorpej 	/*
1.14.2.2   thorpej 	 * Hook in the page, zero it, and purge the cache for that
1.14.2.2   thorpej 	 * zeroed page. Invalidate the TLB as needed.
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej 	*page_hook0.pte = L2_PTE(phys & PG_FRAME, AP_KRW);
1.14.2.2   thorpej 	cpu_tlb_flushD_SE(page_hook0.va);
1.14.2.4   thorpej 	cpu_cpwait();
1.14.2.4   thorpej
1.14.2.2   thorpej 	for (i = 0, ptr = (int *)page_hook0.va;
1.14.2.2   thorpej 			i < (NBPG / sizeof(int)); i++) {
1.14.2.2   thorpej 		if (sched_whichqs != 0) {
1.14.2.2   thorpej 			/*
1.14.2.2   thorpej 			 * A process has become ready.  Abort now,
1.14.2.2   thorpej 			 * so we don't keep it waiting while we
1.14.2.2   thorpej 			 * do slow memory access to finish this
1.14.2.2   thorpej 			 * page.
1.14.2.2   thorpej 			 */
1.14.2.2   thorpej 			rv = FALSE;
1.14.2.2   thorpej 			break;
1.14.2.2   thorpej 		}
1.14.2.2   thorpej 		*ptr++ = 0;
1.14.2.2   thorpej 	}
1.14.2.2   thorpej
1.14.2.2   thorpej 	if (rv)
1.14.2.2   thorpej 		/*
1.14.2.2   thorpej 		 * if we aborted we'll rezero this page again later so don't
1.14.2.2   thorpej 		 * purge it unless we finished it
1.14.2.2   thorpej 		 */
1.14.2.5  jdolecek 		cpu_dcache_wbinv_range(page_hook0.va, NBPG);
1.14.2.2   thorpej 	return (rv);
1.14.2.2   thorpej }
1.14.2.2   thorpej
     1.1      matt /*
     1.1      matt  * pmap_copy_page()
     1.1      matt  *
     1.1      matt  * Copy one physical page into another, by mapping the pages into
     1.1      matt  * hook points. The same comment regarding cachability as in
     1.1      matt  * pmap_zero_page also applies here.
     1.1      matt  */
     1.1      matt void
     1.1      matt pmap_copy_page(src, dest)
     1.2      matt 	paddr_t src;
     1.2      matt 	paddr_t dest;
     1.1      matt {
1.14.2.6  jdolecek 	struct vm_page *src_pg, *dest_pg;
1.14.2.3   thorpej 	boolean_t cleanedcache;
     1.1      matt
     1.1      matt 	/* Get PV entries for the pages, and clean them if needed. */
1.14.2.6  jdolecek 	src_pg = PHYS_TO_VM_PAGE(src);
1.14.2.2   thorpej
1.14.2.6  jdolecek 	simple_lock(&src_pg->mdpage.pvh_slock);
1.14.2.6  jdolecek 	cleanedcache = pmap_clean_page(src_pg->mdpage.pvh_list, TRUE);
1.14.2.6  jdolecek 	simple_unlock(&src_pg->mdpage.pvh_slock);
     1.1      matt
1.14.2.3   thorpej 	if (cleanedcache == 0) {
1.14.2.6  jdolecek 		dest_pg = PHYS_TO_VM_PAGE(dest);
1.14.2.6  jdolecek 		simple_lock(&dest_pg->mdpage.pvh_slock);
1.14.2.6  jdolecek 		pmap_clean_page(dest_pg->mdpage.pvh_list, FALSE);
1.14.2.6  jdolecek 		simple_unlock(&dest_pg->mdpage.pvh_slock);
1.14.2.3   thorpej 	}
     1.1      matt 	/*
     1.1      matt 	 * Map the pages into the page hook points, copy them, and purge
     1.1      matt 	 * the cache for the appropriate page. Invalidate the TLB
     1.1      matt 	 * as required.
     1.1      matt 	 */
     1.1      matt 	*page_hook0.pte = L2_PTE(src & PG_FRAME, AP_KRW);
     1.1      matt 	*page_hook1.pte = L2_PTE(dest & PG_FRAME, AP_KRW);
     1.1      matt 	cpu_tlb_flushD_SE(page_hook0.va);
     1.1      matt 	cpu_tlb_flushD_SE(page_hook1.va);
1.14.2.4   thorpej 	cpu_cpwait();
     1.1      matt 	bcopy_page(page_hook0.va, page_hook1.va);
1.14.2.5  jdolecek 	cpu_dcache_wbinv_range(page_hook0.va, NBPG);
1.14.2.5  jdolecek 	cpu_dcache_wbinv_range(page_hook1.va, NBPG);
     1.1      matt }
     1.1      matt
     1.1      matt #if 0
     1.1      matt void
     1.1      matt pmap_pte_addref(pmap, va)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
     1.1      matt {
     1.1      matt 	pd_entry_t *pde;
     1.2      matt 	paddr_t pa;
     1.1      matt 	struct vm_page *m;
     1.1      matt
     1.1      matt 	if (pmap == pmap_kernel())
     1.1      matt 		return;
     1.1      matt
     1.1      matt 	pde = pmap_pde(pmap, va & ~(3 << PDSHIFT));
     1.1      matt 	pa = pmap_pte_pa(pde);
     1.1      matt 	m = PHYS_TO_VM_PAGE(pa);
     1.1      matt 	++m->wire_count;
     1.1      matt #ifdef MYCROFT_HACK
     1.1      matt 	printf("addref pmap=%p va=%08lx pde=%p pa=%08lx m=%p wire=%d\n",
     1.1      matt 	    pmap, va, pde, pa, m, m->wire_count);
     1.1      matt #endif
     1.1      matt }
     1.1      matt
     1.1      matt void
     1.1      matt pmap_pte_delref(pmap, va)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
     1.1      matt {
     1.1      matt 	pd_entry_t *pde;
     1.2      matt 	paddr_t pa;
     1.1      matt 	struct vm_page *m;
     1.1      matt
     1.1      matt 	if (pmap == pmap_kernel())
     1.1      matt 		return;
     1.1      matt
     1.1      matt 	pde = pmap_pde(pmap, va & ~(3 << PDSHIFT));
     1.1      matt 	pa = pmap_pte_pa(pde);
     1.1      matt 	m = PHYS_TO_VM_PAGE(pa);
     1.1      matt 	--m->wire_count;
     1.1      matt #ifdef MYCROFT_HACK
     1.1      matt 	printf("delref pmap=%p va=%08lx pde=%p pa=%08lx m=%p wire=%d\n",
     1.1      matt 	    pmap, va, pde, pa, m, m->wire_count);
     1.1      matt #endif
     1.1      matt 	if (m->wire_count == 0) {
     1.1      matt #ifdef MYCROFT_HACK
     1.1      matt 		printf("delref pmap=%p va=%08lx pde=%p pa=%08lx m=%p\n",
     1.1      matt 		    pmap, va, pde, pa, m);
     1.1      matt #endif
     1.1      matt 		pmap_unmap_in_l1(pmap, va);
     1.1      matt 		uvm_pagefree(m);
     1.1      matt 		--pmap->pm_stats.resident_count;
     1.1      matt 	}
     1.1      matt }
     1.1      matt #else
     1.1      matt #define	pmap_pte_addref(pmap, va)
     1.1      matt #define	pmap_pte_delref(pmap, va)
     1.1      matt #endif
     1.1      matt
     1.1      matt /*
     1.1      matt  * Since we have a virtually indexed cache, we may need to inhibit caching if
     1.1      matt  * there is more than one mapping and at least one of them is writable.
     1.1      matt  * Since we purge the cache on every context switch, we only need to check for
     1.1      matt  * other mappings within the same pmap, or kernel_pmap.
     1.1      matt  * This function is also called when a page is unmapped, to possibly reenable
     1.1      matt  * caching on any remaining mappings.
    1.11     chris  *
1.14.2.4   thorpej  * The code implements the following logic, where:
1.14.2.4   thorpej  *
1.14.2.4   thorpej  * KW = # of kernel read/write pages
1.14.2.4   thorpej  * KR = # of kernel read only pages
1.14.2.4   thorpej  * UW = # of user read/write pages
1.14.2.4   thorpej  * UR = # of user read only pages
1.14.2.4   thorpej  * OW = # of user read/write pages in another pmap, then
1.14.2.4   thorpej  *
1.14.2.4   thorpej  * KC = kernel mapping is cacheable
1.14.2.4   thorpej  * UC = user mapping is cacheable
1.14.2.4   thorpej  *
1.14.2.4   thorpej  *                     KW=0,KR=0  KW=0,KR>0  KW=1,KR=0  KW>1,KR>=0
1.14.2.4   thorpej  *                   +---------------------------------------------
1.14.2.4   thorpej  * UW=0,UR=0,OW=0    | ---        KC=1       KC=1       KC=0
1.14.2.4   thorpej  * UW=0,UR>0,OW=0    | UC=1       KC=1,UC=1  KC=0,UC=0  KC=0,UC=0
1.14.2.4   thorpej  * UW=0,UR>0,OW>0    | UC=1       KC=0,UC=1  KC=0,UC=0  KC=0,UC=0
1.14.2.4   thorpej  * UW=1,UR=0,OW=0    | UC=1       KC=0,UC=0  KC=0,UC=0  KC=0,UC=0
1.14.2.4   thorpej  * UW>1,UR>=0,OW>=0  | UC=0       KC=0,UC=0  KC=0,UC=0  KC=0,UC=0
1.14.2.4   thorpej  *
    1.11     chris  * Note that the pmap must have it's ptes mapped in, and passed with ptes.
     1.1      matt  */
1.14.2.4   thorpej __inline static void
1.14.2.6  jdolecek pmap_vac_me_harder(struct pmap *pmap, struct vm_page *pg, pt_entry_t *ptes,
    1.12     chris 	boolean_t clear_cache)
     1.1      matt {
1.14.2.4   thorpej 	if (pmap == pmap_kernel())
1.14.2.6  jdolecek 		pmap_vac_me_kpmap(pmap, pg, ptes, clear_cache);
1.14.2.4   thorpej 	else
1.14.2.6  jdolecek 		pmap_vac_me_user(pmap, pg, ptes, clear_cache);
1.14.2.4   thorpej }
1.14.2.4   thorpej
1.14.2.4   thorpej static void
1.14.2.6  jdolecek pmap_vac_me_kpmap(struct pmap *pmap, struct vm_page *pg, pt_entry_t *ptes,
1.14.2.4   thorpej 	boolean_t clear_cache)
1.14.2.4   thorpej {
1.14.2.4   thorpej 	int user_entries = 0;
1.14.2.4   thorpej 	int user_writable = 0;
1.14.2.4   thorpej 	int user_cacheable = 0;
1.14.2.4   thorpej 	int kernel_entries = 0;
1.14.2.4   thorpej 	int kernel_writable = 0;
1.14.2.4   thorpej 	int kernel_cacheable = 0;
1.14.2.4   thorpej 	struct pv_entry *pv;
1.14.2.4   thorpej 	struct pmap *last_pmap = pmap;
1.14.2.4   thorpej
1.14.2.4   thorpej #ifdef DIAGNOSTIC
1.14.2.4   thorpej 	if (pmap != pmap_kernel())
1.14.2.4   thorpej 		panic("pmap_vac_me_kpmap: pmap != pmap_kernel()");
1.14.2.4   thorpej #endif
1.14.2.4   thorpej
1.14.2.4   thorpej 	/*
1.14.2.4   thorpej 	 * Pass one, see if there are both kernel and user pmaps for
1.14.2.4   thorpej 	 * this page.  Calculate whether there are user-writable or
1.14.2.4   thorpej 	 * kernel-writable pages.
1.14.2.4   thorpej 	 */
1.14.2.6  jdolecek 	for (pv = pg->mdpage.pvh_list; pv != NULL; pv = pv->pv_next) {
1.14.2.4   thorpej 		if (pv->pv_pmap != pmap) {
1.14.2.4   thorpej 			user_entries++;
1.14.2.4   thorpej 			if (pv->pv_flags & PT_Wr)
1.14.2.4   thorpej 				user_writable++;
1.14.2.4   thorpej 			if ((pv->pv_flags & PT_NC) == 0)
1.14.2.4   thorpej 				user_cacheable++;
1.14.2.4   thorpej 		} else {
1.14.2.4   thorpej 			kernel_entries++;
1.14.2.4   thorpej 			if (pv->pv_flags & PT_Wr)
1.14.2.4   thorpej 				kernel_writable++;
1.14.2.4   thorpej 			if ((pv->pv_flags & PT_NC) == 0)
1.14.2.4   thorpej 				kernel_cacheable++;
1.14.2.4   thorpej 		}
1.14.2.4   thorpej 	}
1.14.2.4   thorpej
1.14.2.4   thorpej 	/*
1.14.2.4   thorpej 	 * We know we have just been updating a kernel entry, so if
1.14.2.4   thorpej 	 * all user pages are already cacheable, then there is nothing
1.14.2.4   thorpej 	 * further to do.
1.14.2.4   thorpej 	 */
1.14.2.4   thorpej 	if (kernel_entries == 0 &&
1.14.2.4   thorpej 	    user_cacheable == user_entries)
1.14.2.4   thorpej 		return;
1.14.2.4   thorpej
1.14.2.4   thorpej 	if (user_entries) {
1.14.2.4   thorpej 		/*
1.14.2.4   thorpej 		 * Scan over the list again, for each entry, if it
1.14.2.4   thorpej 		 * might not be set correctly, call pmap_vac_me_user
1.14.2.4   thorpej 		 * to recalculate the settings.
1.14.2.4   thorpej 		 */
1.14.2.6  jdolecek 		for (pv = pg->mdpage.pvh_list; pv; pv = pv->pv_next) {
1.14.2.4   thorpej 			/*
1.14.2.4   thorpej 			 * We know kernel mappings will get set
1.14.2.4   thorpej 			 * correctly in other calls.  We also know
1.14.2.4   thorpej 			 * that if the pmap is the same as last_pmap
1.14.2.4   thorpej 			 * then we've just handled this entry.
1.14.2.4   thorpej 			 */
1.14.2.4   thorpej 			if (pv->pv_pmap == pmap || pv->pv_pmap == last_pmap)
1.14.2.4   thorpej 				continue;
1.14.2.4   thorpej 			/*
1.14.2.4   thorpej 			 * If there are kernel entries and this page
1.14.2.4   thorpej 			 * is writable but non-cacheable, then we can
1.14.2.4   thorpej 			 * skip this entry also.
1.14.2.4   thorpej 			 */
1.14.2.4   thorpej 			if (kernel_entries > 0 &&
1.14.2.4   thorpej 			    (pv->pv_flags & (PT_NC | PT_Wr)) ==
1.14.2.4   thorpej 			    (PT_NC | PT_Wr))
1.14.2.4   thorpej 				continue;
1.14.2.4   thorpej 			/*
1.14.2.4   thorpej 			 * Similarly if there are no kernel-writable
1.14.2.4   thorpej 			 * entries and the page is already
1.14.2.4   thorpej 			 * read-only/cacheable.
1.14.2.4   thorpej 			 */
1.14.2.4   thorpej 			if (kernel_writable == 0 &&
1.14.2.4   thorpej 			    (pv->pv_flags & (PT_NC | PT_Wr)) == 0)
1.14.2.4   thorpej 				continue;
1.14.2.4   thorpej 			/*
1.14.2.4   thorpej 			 * For some of the remaining cases, we know
1.14.2.4   thorpej 			 * that we must recalculate, but for others we
1.14.2.4   thorpej 			 * can't tell if they are correct or not, so
1.14.2.4   thorpej 			 * we recalculate anyway.
1.14.2.4   thorpej 			 */
1.14.2.4   thorpej 			pmap_unmap_ptes(last_pmap);
1.14.2.4   thorpej 			last_pmap = pv->pv_pmap;
1.14.2.4   thorpej 			ptes = pmap_map_ptes(last_pmap);
1.14.2.6  jdolecek 			pmap_vac_me_user(last_pmap, pg, ptes,
1.14.2.4   thorpej 			    pmap_is_curpmap(last_pmap));
1.14.2.4   thorpej 		}
1.14.2.4   thorpej 		/* Restore the pte mapping that was passed to us.  */
1.14.2.4   thorpej 		if (last_pmap != pmap) {
1.14.2.4   thorpej 			pmap_unmap_ptes(last_pmap);
1.14.2.4   thorpej 			ptes = pmap_map_ptes(pmap);
1.14.2.4   thorpej 		}
1.14.2.4   thorpej 		if (kernel_entries == 0)
1.14.2.4   thorpej 			return;
1.14.2.4   thorpej 	}
1.14.2.4   thorpej
1.14.2.6  jdolecek 	pmap_vac_me_user(pmap, pg, ptes, clear_cache);
1.14.2.4   thorpej 	return;
1.14.2.4   thorpej }
1.14.2.4   thorpej
1.14.2.4   thorpej static void
1.14.2.6  jdolecek pmap_vac_me_user(struct pmap *pmap, struct vm_page *pg, pt_entry_t *ptes,
1.14.2.4   thorpej 	boolean_t clear_cache)
1.14.2.4   thorpej {
1.14.2.4   thorpej 	struct pmap *kpmap = pmap_kernel();
1.14.2.2   thorpej 	struct pv_entry *pv, *npv;
     1.1      matt 	int entries = 0;
1.14.2.4   thorpej 	int writable = 0;
    1.12     chris 	int cacheable_entries = 0;
1.14.2.4   thorpej 	int kern_cacheable = 0;
1.14.2.4   thorpej 	int other_writable = 0;
     1.1      matt
1.14.2.6  jdolecek 	pv = pg->mdpage.pvh_list;
    1.11     chris 	KASSERT(ptes != NULL);
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * Count mappings and writable mappings in this pmap.
1.14.2.4   thorpej 	 * Include kernel mappings as part of our own.
     1.1      matt 	 * Keep a pointer to the first one.
     1.1      matt 	 */
     1.1      matt 	for (npv = pv; npv; npv = npv->pv_next) {
     1.1      matt 		/* Count mappings in the same pmap */
1.14.2.4   thorpej 		if (pmap == npv->pv_pmap ||
1.14.2.4   thorpej 		    kpmap == npv->pv_pmap) {
     1.1      matt 			if (entries++ == 0)
     1.1      matt 				pv = npv;
    1.12     chris 			/* Cacheable mappings */
1.14.2.4   thorpej 			if ((npv->pv_flags & PT_NC) == 0) {
    1.12     chris 				cacheable_entries++;
1.14.2.4   thorpej 				if (kpmap == npv->pv_pmap)
1.14.2.4   thorpej 					kern_cacheable++;
1.14.2.4   thorpej 			}
1.14.2.4   thorpej 			/* Writable mappings */
     1.1      matt 			if (npv->pv_flags & PT_Wr)
1.14.2.4   thorpej 				++writable;
1.14.2.4   thorpej 		} else if (npv->pv_flags & PT_Wr)
1.14.2.4   thorpej 			other_writable = 1;
     1.1      matt 	}
     1.1      matt
    1.12     chris 	PDEBUG(3,printf("pmap_vac_me_harder: pmap %p Entries %d, "
1.14.2.4   thorpej 		"writable %d cacheable %d %s\n", pmap, entries, writable,
    1.12     chris 	    	cacheable_entries, clear_cache ? "clean" : "no clean"));
    1.12     chris
     1.1      matt 	/*
     1.1      matt 	 * Enable or disable caching as necessary.
1.14.2.4   thorpej 	 * Note: the first entry might be part of the kernel pmap,
1.14.2.4   thorpej 	 * so we can't assume this is indicative of the state of the
1.14.2.4   thorpej 	 * other (maybe non-kpmap) entries.
     1.1      matt 	 */
1.14.2.4   thorpej 	if ((entries > 1 && writable) ||
1.14.2.4   thorpej 	    (entries > 0 && pmap == kpmap && other_writable)) {
    1.12     chris 		if (cacheable_entries == 0)
    1.12     chris 		    return;
1.14.2.4   thorpej 		for (npv = pv; npv; npv = npv->pv_next) {
1.14.2.4   thorpej 			if ((pmap == npv->pv_pmap
1.14.2.4   thorpej 			    || kpmap == npv->pv_pmap) &&
    1.12     chris 			    (npv->pv_flags & PT_NC) == 0) {
    1.12     chris 				ptes[arm_byte_to_page(npv->pv_va)] &=
    1.11     chris 				    ~(PT_C | PT_B);
    1.12     chris  				npv->pv_flags |= PT_NC;
1.14.2.4   thorpej 				/*
1.14.2.4   thorpej 				 * If this page needs flushing from the
1.14.2.4   thorpej 				 * cache, and we aren't going to do it
1.14.2.4   thorpej 				 * below, do it now.
1.14.2.4   thorpej 				 */
1.14.2.4   thorpej 				if ((cacheable_entries < 4 &&
1.14.2.4   thorpej 				    (clear_cache || npv->pv_pmap == kpmap)) ||
1.14.2.4   thorpej 				    (npv->pv_pmap == kpmap &&
1.14.2.4   thorpej 				    !clear_cache && kern_cacheable < 4)) {
1.14.2.5  jdolecek 					cpu_idcache_wbinv_range(npv->pv_va,
    1.12     chris 					    NBPG);
    1.12     chris 					cpu_tlb_flushID_SE(npv->pv_va);
    1.12     chris 				}
     1.1      matt 			}
     1.1      matt 		}
1.14.2.4   thorpej 		if ((clear_cache && cacheable_entries >= 4) ||
1.14.2.4   thorpej 		    kern_cacheable >= 4) {
1.14.2.5  jdolecek 			cpu_idcache_wbinv_all();
    1.12     chris 			cpu_tlb_flushID();
    1.12     chris 		}
1.14.2.4   thorpej 		cpu_cpwait();
     1.1      matt 	} else if (entries > 0) {
1.14.2.4   thorpej 		/*
1.14.2.4   thorpej 		 * Turn cacheing back on for some pages.  If it is a kernel
1.14.2.4   thorpej 		 * page, only do so if there are no other writable pages.
1.14.2.4   thorpej 		 */
1.14.2.4   thorpej 		for (npv = pv; npv; npv = npv->pv_next) {
1.14.2.4   thorpej 			if ((pmap == npv->pv_pmap ||
1.14.2.4   thorpej 			    (kpmap == npv->pv_pmap && other_writable == 0)) &&
1.14.2.4   thorpej 			    (npv->pv_flags & PT_NC)) {
    1.11     chris 				ptes[arm_byte_to_page(npv->pv_va)] |=
1.14.2.4   thorpej 				    pte_cache_mode;
    1.12     chris 				npv->pv_flags &= ~PT_NC;
     1.1      matt 			}
     1.1      matt 		}
     1.1      matt 	}
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * pmap_remove()
     1.1      matt  *
     1.1      matt  * pmap_remove is responsible for nuking a number of mappings for a range
     1.1      matt  * of virtual address space in the current pmap. To do this efficiently
     1.1      matt  * is interesting, because in a number of cases a wide virtual address
     1.1      matt  * range may be supplied that contains few actual mappings. So, the
     1.1      matt  * optimisations are:
     1.1      matt  *  1. Try and skip over hunks of address space for which an L1 entry
     1.1      matt  *     does not exist.
     1.1      matt  *  2. Build up a list of pages we've hit, up to a maximum, so we can
     1.1      matt  *     maybe do just a partial cache clean. This path of execution is
     1.1      matt  *     complicated by the fact that the cache must be flushed _before_
     1.1      matt  *     the PTE is nuked, being a VAC :-)
     1.1      matt  *  3. Maybe later fast-case a single page, but I don't think this is
     1.1      matt  *     going to make _that_ much difference overall.
     1.1      matt  */
     1.1      matt
     1.1      matt #define PMAP_REMOVE_CLEAN_LIST_SIZE	3
     1.1      matt
     1.1      matt void
     1.1      matt pmap_remove(pmap, sva, eva)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t sva;
     1.1      matt 	vaddr_t eva;
     1.1      matt {
     1.1      matt 	int cleanlist_idx = 0;
     1.1      matt 	struct pagelist {
     1.1      matt 		vaddr_t va;
     1.1      matt 		pt_entry_t *pte;
     1.1      matt 	} cleanlist[PMAP_REMOVE_CLEAN_LIST_SIZE];
    1.11     chris 	pt_entry_t *pte = 0, *ptes;
     1.2      matt 	paddr_t pa;
     1.1      matt 	int pmap_active;
1.14.2.6  jdolecek 	struct vm_page *pg;
     1.1      matt
     1.1      matt 	/* Exit quick if there is no pmap */
     1.1      matt 	if (!pmap)
     1.1      matt 		return;
     1.1      matt
     1.1      matt 	PDEBUG(0, printf("pmap_remove: pmap=%p sva=%08lx eva=%08lx\n", pmap, sva, eva));
     1.1      matt
     1.1      matt 	sva &= PG_FRAME;
     1.1      matt 	eva &= PG_FRAME;
     1.1      matt
1.14.2.2   thorpej 	/*
1.14.2.6  jdolecek 	 * we lock in the pmap => vm_page direction
1.14.2.2   thorpej 	 */
1.14.2.2   thorpej 	PMAP_MAP_TO_HEAD_LOCK();
1.14.2.2   thorpej
    1.11     chris 	ptes = pmap_map_ptes(pmap);
     1.1      matt 	/* Get a page table pointer */
     1.1      matt 	while (sva < eva) {
1.14.2.4   thorpej 		if (pmap_pde_page(pmap_pde(pmap, sva)))
     1.1      matt 			break;
     1.1      matt 		sva = (sva & PD_MASK) + NBPD;
     1.1      matt 	}
    1.11     chris
    1.11     chris 	pte = &ptes[arm_byte_to_page(sva)];
     1.1      matt 	/* Note if the pmap is active thus require cache and tlb cleans */
     1.1      matt 	if ((curproc && curproc->p_vmspace->vm_map.pmap == pmap)
1.14.2.1     lukem 	    || (pmap == pmap_kernel()))
     1.1      matt 		pmap_active = 1;
     1.1      matt 	else
     1.1      matt 		pmap_active = 0;
     1.1      matt
     1.1      matt 	/* Now loop along */
     1.1      matt 	while (sva < eva) {
     1.1      matt 		/* Check if we can move to the next PDE (l1 chunk) */
     1.1      matt 		if (!(sva & PT_MASK))
1.14.2.4   thorpej 			if (!pmap_pde_page(pmap_pde(pmap, sva))) {
     1.1      matt 				sva += NBPD;
     1.1      matt 				pte += arm_byte_to_page(NBPD);
     1.1      matt 				continue;
     1.1      matt 			}
     1.1      matt
     1.1      matt 		/* We've found a valid PTE, so this page of PTEs has to go. */
     1.1      matt 		if (pmap_pte_v(pte)) {
     1.1      matt 			/* Update statistics */
     1.1      matt 			--pmap->pm_stats.resident_count;
     1.1      matt
     1.1      matt 			/*
     1.1      matt 			 * Add this page to our cache remove list, if we can.
     1.1      matt 			 * If, however the cache remove list is totally full,
     1.1      matt 			 * then do a complete cache invalidation taking note
     1.1      matt 			 * to backtrack the PTE table beforehand, and ignore
     1.1      matt 			 * the lists in future because there's no longer any
     1.1      matt 			 * point in bothering with them (we've paid the
     1.1      matt 			 * penalty, so will carry on unhindered). Otherwise,
     1.1      matt 			 * when we fall out, we just clean the list.
     1.1      matt 			 */
     1.1      matt 			PDEBUG(10, printf("remove: inv pte at %p(%x) ", pte, *pte));
     1.1      matt 			pa = pmap_pte_pa(pte);
     1.1      matt
     1.1      matt 			if (cleanlist_idx < PMAP_REMOVE_CLEAN_LIST_SIZE) {
     1.1      matt 				/* Add to the clean list. */
     1.1      matt 				cleanlist[cleanlist_idx].pte = pte;
     1.1      matt 				cleanlist[cleanlist_idx].va = sva;
     1.1      matt 				cleanlist_idx++;
     1.1      matt 			} else if (cleanlist_idx == PMAP_REMOVE_CLEAN_LIST_SIZE) {
     1.1      matt 				int cnt;
     1.1      matt
     1.1      matt 				/* Nuke everything if needed. */
     1.1      matt 				if (pmap_active) {
1.14.2.5  jdolecek 					cpu_idcache_wbinv_all();
     1.1      matt 					cpu_tlb_flushID();
     1.1      matt 				}
     1.1      matt
     1.1      matt 				/*
     1.1      matt 				 * Roll back the previous PTE list,
     1.1      matt 				 * and zero out the current PTE.
     1.1      matt 				 */
     1.1      matt 				for (cnt = 0; cnt < PMAP_REMOVE_CLEAN_LIST_SIZE; cnt++) {
     1.1      matt 					*cleanlist[cnt].pte = 0;
     1.1      matt 					pmap_pte_delref(pmap, cleanlist[cnt].va);
     1.1      matt 				}
     1.1      matt 				*pte = 0;
     1.1      matt 				pmap_pte_delref(pmap, sva);
     1.1      matt 				cleanlist_idx++;
     1.1      matt 			} else {
     1.1      matt 				/*
     1.1      matt 				 * We've already nuked the cache and
     1.1      matt 				 * TLB, so just carry on regardless,
     1.1      matt 				 * and we won't need to do it again
     1.1      matt 				 */
     1.1      matt 				*pte = 0;
     1.1      matt 				pmap_pte_delref(pmap, sva);
     1.1      matt 			}
     1.1      matt
     1.1      matt 			/*
     1.1      matt 			 * Update flags. In a number of circumstances,
     1.1      matt 			 * we could cluster a lot of these and do a
     1.1      matt 			 * number of sequential pages in one go.
     1.1      matt 			 */
1.14.2.6  jdolecek 			if ((pg = PHYS_TO_VM_PAGE(pa)) != NULL) {
1.14.2.2   thorpej 				struct pv_entry *pve;
1.14.2.6  jdolecek 				simple_lock(&pg->mdpage.pvh_slock);
1.14.2.6  jdolecek 				pve = pmap_remove_pv(pg, pmap, sva);
1.14.2.2   thorpej 				pmap_free_pv(pmap, pve);
1.14.2.6  jdolecek 				pmap_vac_me_harder(pmap, pg, ptes, FALSE);
1.14.2.6  jdolecek 				simple_unlock(&pg->mdpage.pvh_slock);
     1.1      matt 			}
     1.1      matt 		}
     1.1      matt 		sva += NBPG;
     1.1      matt 		pte++;
     1.1      matt 	}
     1.1      matt
    1.11     chris 	pmap_unmap_ptes(pmap);
     1.1      matt 	/*
     1.1      matt 	 * Now, if we've fallen through down to here, chances are that there
     1.1      matt 	 * are less than PMAP_REMOVE_CLEAN_LIST_SIZE mappings left.
     1.1      matt 	 */
     1.1      matt 	if (cleanlist_idx <= PMAP_REMOVE_CLEAN_LIST_SIZE) {
     1.1      matt 		u_int cnt;
     1.1      matt
     1.1      matt 		for (cnt = 0; cnt < cleanlist_idx; cnt++) {
     1.1      matt 			if (pmap_active) {
1.14.2.5  jdolecek 				cpu_idcache_wbinv_range(cleanlist[cnt].va,
1.14.2.5  jdolecek 				    NBPG);
     1.1      matt 				*cleanlist[cnt].pte = 0;
     1.1      matt 				cpu_tlb_flushID_SE(cleanlist[cnt].va);
     1.1      matt 			} else
     1.1      matt 				*cleanlist[cnt].pte = 0;
     1.1      matt 			pmap_pte_delref(pmap, cleanlist[cnt].va);
     1.1      matt 		}
     1.1      matt 	}
1.14.2.2   thorpej 	PMAP_MAP_TO_HEAD_UNLOCK();
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * Routine:	pmap_remove_all
     1.1      matt  * Function:
     1.1      matt  *		Removes this physical page from
     1.1      matt  *		all physical maps in which it resides.
     1.1      matt  *		Reflects back modify bits to the pager.
     1.1      matt  */
     1.1      matt
1.14.2.4   thorpej static void
1.14.2.6  jdolecek pmap_remove_all(pg)
1.14.2.6  jdolecek 	struct vm_page *pg;
     1.1      matt {
1.14.2.2   thorpej 	struct pv_entry *pv, *npv;
1.14.2.1     lukem 	struct pmap *pmap;
    1.11     chris 	pt_entry_t *pte, *ptes;
     1.1      matt
1.14.2.6  jdolecek 	PDEBUG(0, printf("pmap_remove_all: pa=%lx ", VM_PAGE_TO_PHYS(pg)));
     1.1      matt
1.14.2.6  jdolecek 	/* set vm_page => pmap locking */
1.14.2.2   thorpej 	PMAP_HEAD_TO_MAP_LOCK();
     1.1      matt
1.14.2.6  jdolecek 	simple_lock(&pg->mdpage.pvh_slock);
1.14.2.2   thorpej
1.14.2.6  jdolecek 	pv = pg->mdpage.pvh_list;
1.14.2.6  jdolecek 	if (pv == NULL) {
1.14.2.6  jdolecek 		PDEBUG(0, printf("free page\n"));
1.14.2.6  jdolecek 		simple_unlock(&pg->mdpage.pvh_slock);
1.14.2.6  jdolecek 		PMAP_HEAD_TO_MAP_UNLOCK();
1.14.2.6  jdolecek 		return;
     1.1      matt 	}
1.14.2.2   thorpej 	pmap_clean_page(pv, FALSE);
     1.1      matt
     1.1      matt 	while (pv) {
     1.1      matt 		pmap = pv->pv_pmap;
    1.11     chris 		ptes = pmap_map_ptes(pmap);
    1.11     chris 		pte = &ptes[arm_byte_to_page(pv->pv_va)];
     1.1      matt
     1.1      matt 		PDEBUG(0, printf("[%p,%08x,%08lx,%08x] ", pmap, *pte,
     1.1      matt 		    pv->pv_va, pv->pv_flags));
     1.1      matt #ifdef DEBUG
1.14.2.4   thorpej 		if (!pmap_pde_page(pmap_pde(pmap, pv->pv_va)) ||
1.14.2.4   thorpej 		    !pmap_pte_v(pte) || pmap_pte_pa(pte) != pa)
     1.1      matt 			panic("pmap_remove_all: bad mapping");
     1.1      matt #endif	/* DEBUG */
     1.1      matt
     1.1      matt 		/*
     1.1      matt 		 * Update statistics
     1.1      matt 		 */
     1.1      matt 		--pmap->pm_stats.resident_count;
     1.1      matt
     1.1      matt 		/* Wired bit */
     1.1      matt 		if (pv->pv_flags & PT_W)
     1.1      matt 			--pmap->pm_stats.wired_count;
     1.1      matt
     1.1      matt 		/*
     1.1      matt 		 * Invalidate the PTEs.
     1.1      matt 		 * XXX: should cluster them up and invalidate as many
     1.1      matt 		 * as possible at once.
     1.1      matt 		 */
     1.1      matt
     1.1      matt #ifdef needednotdone
     1.1      matt reduce wiring count on page table pages as references drop
     1.1      matt #endif
     1.1      matt
     1.1      matt 		*pte = 0;
     1.1      matt 		pmap_pte_delref(pmap, pv->pv_va);
     1.1      matt
     1.1      matt 		npv = pv->pv_next;
1.14.2.2   thorpej 		pmap_free_pv(pmap, pv);
     1.1      matt 		pv = npv;
    1.11     chris 		pmap_unmap_ptes(pmap);
     1.1      matt 	}
1.14.2.6  jdolecek 	pg->mdpage.pvh_list = NULL;
1.14.2.6  jdolecek 	simple_unlock(&pg->mdpage.pvh_slock);
1.14.2.2   thorpej 	PMAP_HEAD_TO_MAP_UNLOCK();
     1.1      matt
     1.1      matt 	PDEBUG(0, printf("done\n"));
     1.1      matt 	cpu_tlb_flushID();
1.14.2.4   thorpej 	cpu_cpwait();
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
     1.1      matt  * Set the physical protection on the specified range of this map as requested.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_protect(pmap, sva, eva, prot)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t sva;
     1.1      matt 	vaddr_t eva;
     1.1      matt 	vm_prot_t prot;
     1.1      matt {
    1.11     chris 	pt_entry_t *pte = NULL, *ptes;
1.14.2.6  jdolecek 	struct vm_page *pg;
     1.1      matt 	int armprot;
     1.1      matt 	int flush = 0;
     1.2      matt 	paddr_t pa;
     1.1      matt
     1.1      matt 	PDEBUG(0, printf("pmap_protect: pmap=%p %08lx->%08lx %x\n",
     1.1      matt 	    pmap, sva, eva, prot));
     1.1      matt
     1.1      matt 	if (~prot & VM_PROT_READ) {
     1.1      matt 		/* Just remove the mappings. */
     1.1      matt 		pmap_remove(pmap, sva, eva);
1.14.2.4   thorpej 		/* pmap_update not needed as it should be called by the caller
1.14.2.4   thorpej 		 * of pmap_protect */
     1.1      matt 		return;
     1.1      matt 	}
     1.1      matt 	if (prot & VM_PROT_WRITE) {
     1.1      matt 		/*
     1.1      matt 		 * If this is a read->write transition, just ignore it and let
     1.1      matt 		 * uvm_fault() take care of it later.
     1.1      matt 		 */
     1.1      matt 		return;
     1.1      matt 	}
     1.1      matt
     1.1      matt 	sva &= PG_FRAME;
     1.1      matt 	eva &= PG_FRAME;
     1.1      matt
1.14.2.2   thorpej 	/* Need to lock map->head */
1.14.2.2   thorpej 	PMAP_MAP_TO_HEAD_LOCK();
1.14.2.2   thorpej
    1.11     chris 	ptes = pmap_map_ptes(pmap);
     1.1      matt 	/*
     1.1      matt 	 * We need to acquire a pointer to a page table page before entering
     1.1      matt 	 * the following loop.
     1.1      matt 	 */
     1.1      matt 	while (sva < eva) {
1.14.2.4   thorpej 		if (pmap_pde_page(pmap_pde(pmap, sva)))
     1.1      matt 			break;
     1.1      matt 		sva = (sva & PD_MASK) + NBPD;
     1.1      matt 	}
    1.11     chris
    1.11     chris 	pte = &ptes[arm_byte_to_page(sva)];
1.14.2.2   thorpej
     1.1      matt 	while (sva < eva) {
     1.1      matt 		/* only check once in a while */
     1.1      matt 		if ((sva & PT_MASK) == 0) {
1.14.2.4   thorpej 			if (!pmap_pde_page(pmap_pde(pmap, sva))) {
     1.1      matt 				/* We can race ahead here, to the next pde. */
     1.1      matt 				sva += NBPD;
     1.1      matt 				pte += arm_byte_to_page(NBPD);
     1.1      matt 				continue;
     1.1      matt 			}
     1.1      matt 		}
     1.1      matt
     1.1      matt 		if (!pmap_pte_v(pte))
     1.1      matt 			goto next;
     1.1      matt
     1.1      matt 		flush = 1;
     1.1      matt
     1.1      matt 		armprot = 0;
     1.1      matt 		if (sva < VM_MAXUSER_ADDRESS)
     1.1      matt 			armprot |= PT_AP(AP_U);
     1.1      matt 		else if (sva < VM_MAX_ADDRESS)
     1.1      matt 			armprot |= PT_AP(AP_W);  /* XXX Ekk what is this ? */
     1.1      matt 		*pte = (*pte & 0xfffff00f) | armprot;
     1.1      matt
     1.1      matt 		pa = pmap_pte_pa(pte);
     1.1      matt
     1.1      matt 		/* Get the physical page index */
     1.1      matt
     1.1      matt 		/* Clear write flag */
1.14.2.6  jdolecek 		if ((pg = PHYS_TO_VM_PAGE(pa)) != NULL) {
1.14.2.6  jdolecek 			simple_lock(&pg->mdpage.pvh_slock);
1.14.2.6  jdolecek 			(void) pmap_modify_pv(pmap, sva, pg, PT_Wr, 0);
1.14.2.6  jdolecek 			pmap_vac_me_harder(pmap, pg, ptes, FALSE);
1.14.2.6  jdolecek 			simple_unlock(&pg->mdpage.pvh_slock);
     1.1      matt 		}
     1.1      matt
     1.1      matt next:
     1.1      matt 		sva += NBPG;
     1.1      matt 		pte++;
     1.1      matt 	}
    1.11     chris 	pmap_unmap_ptes(pmap);
1.14.2.2   thorpej 	PMAP_MAP_TO_HEAD_UNLOCK();
     1.1      matt 	if (flush)
     1.1      matt 		cpu_tlb_flushID();
     1.1      matt }
     1.1      matt
     1.1      matt /*
1.14.2.1     lukem  * void pmap_enter(struct pmap *pmap, vaddr_t va, paddr_t pa, vm_prot_t prot,
     1.1      matt  * int flags)
     1.1      matt  *
     1.1      matt  *      Insert the given physical page (p) at
     1.1      matt  *      the specified virtual address (v) in the
     1.1      matt  *      target physical map with the protection requested.
     1.1      matt  *
     1.1      matt  *      If specified, the page will be wired down, meaning
     1.1      matt  *      that the related pte can not be reclaimed.
     1.1      matt  *
     1.1      matt  *      NB:  This is the only routine which MAY NOT lazy-evaluate
     1.1      matt  *      or lose information.  That is, this routine must actually
     1.1      matt  *      insert this page into the given map NOW.
     1.1      matt  */
     1.1      matt
     1.1      matt int
     1.1      matt pmap_enter(pmap, va, pa, prot, flags)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
     1.2      matt 	paddr_t pa;
     1.1      matt 	vm_prot_t prot;
     1.1      matt 	int flags;
     1.1      matt {
    1.11     chris 	pt_entry_t *pte, *ptes;
     1.1      matt 	u_int npte;
     1.2      matt 	paddr_t opa;
     1.1      matt 	int nflags;
     1.1      matt 	boolean_t wired = (flags & PMAP_WIRED) != 0;
1.14.2.6  jdolecek 	struct vm_page *pg;
1.14.2.2   thorpej 	struct pv_entry *pve;
1.14.2.2   thorpej 	int error;
     1.1      matt
     1.1      matt 	PDEBUG(5, printf("pmap_enter: V%08lx P%08lx in pmap %p prot=%08x, wired = %d\n",
     1.1      matt 	    va, pa, pmap, prot, wired));
     1.1      matt
     1.1      matt #ifdef DIAGNOSTIC
     1.1      matt 	/* Valid address ? */
1.14.2.6  jdolecek 	if (va >= (pmap_curmaxkvaddr))
     1.1      matt 		panic("pmap_enter: too big");
     1.1      matt 	if (pmap != pmap_kernel() && va != 0) {
     1.1      matt 		if (va < VM_MIN_ADDRESS || va >= VM_MAXUSER_ADDRESS)
     1.1      matt 			panic("pmap_enter: kernel page in user map");
     1.1      matt 	} else {
     1.1      matt 		if (va >= VM_MIN_ADDRESS && va < VM_MAXUSER_ADDRESS)
     1.1      matt 			panic("pmap_enter: user page in kernel map");
     1.1      matt 		if (va >= VM_MAXUSER_ADDRESS && va < VM_MAX_ADDRESS)
     1.1      matt 			panic("pmap_enter: entering PT page");
     1.1      matt 	}
     1.1      matt #endif
1.14.2.6  jdolecek 	/*
1.14.2.6  jdolecek 	 * Get a pointer to the page.  Later on in this function, we
1.14.2.6  jdolecek 	 * test for a managed page by checking pg != NULL.
1.14.2.6  jdolecek 	 */
1.14.2.6  jdolecek 	pg = PHYS_TO_VM_PAGE(pa);
1.14.2.6  jdolecek
1.14.2.2   thorpej 	/* get lock */
1.14.2.2   thorpej 	PMAP_MAP_TO_HEAD_LOCK();
     1.1      matt 	/*
     1.1      matt 	 * Get a pointer to the pte for this virtual address. If the
     1.1      matt 	 * pte pointer is NULL then we are missing the L2 page table
     1.1      matt 	 * so we need to create one.
     1.1      matt 	 */
1.14.2.4   thorpej 	/* XXX horrible hack to get us working with lockdebug */
1.14.2.4   thorpej 	simple_lock(&pmap->pm_obj.vmobjlock);
     1.1      matt 	pte = pmap_pte(pmap, va);
     1.1      matt 	if (!pte) {
1.14.2.2   thorpej 		struct vm_page *ptp;
1.14.2.6  jdolecek 		KASSERT(pmap != pmap_kernel()); /* kernel should have pre-grown */
     1.1      matt
1.14.2.2   thorpej 		/* if failure is allowed then don't try too hard */
1.14.2.2   thorpej 		ptp = pmap_get_ptp(pmap, va, flags & PMAP_CANFAIL);
1.14.2.2   thorpej 		if (ptp == NULL) {
1.14.2.2   thorpej 			if (flags & PMAP_CANFAIL) {
1.14.2.2   thorpej 				error = ENOMEM;
1.14.2.2   thorpej 				goto out;
1.14.2.2   thorpej 			}
1.14.2.2   thorpej 			panic("pmap_enter: get ptp failed");
1.14.2.2   thorpej 		}
1.14.2.1     lukem
     1.1      matt 		pte = pmap_pte(pmap, va);
     1.1      matt #ifdef DIAGNOSTIC
     1.1      matt 		if (!pte)
     1.1      matt 			panic("pmap_enter: no pte");
     1.1      matt #endif
     1.1      matt 	}
     1.1      matt
     1.1      matt 	nflags = 0;
     1.1      matt 	if (prot & VM_PROT_WRITE)
     1.1      matt 		nflags |= PT_Wr;
     1.1      matt 	if (wired)
     1.1      matt 		nflags |= PT_W;
     1.1      matt
     1.1      matt 	/* More debugging info */
     1.1      matt 	PDEBUG(5, printf("pmap_enter: pte for V%08lx = V%p (%08x)\n", va, pte,
     1.1      matt 	    *pte));
     1.1      matt
     1.1      matt 	/* Is the pte valid ? If so then this page is already mapped */
     1.1      matt 	if (pmap_pte_v(pte)) {
     1.1      matt 		/* Get the physical address of the current page mapped */
     1.1      matt 		opa = pmap_pte_pa(pte);
     1.1      matt
     1.1      matt #ifdef MYCROFT_HACK
     1.1      matt 		printf("pmap_enter: pmap=%p va=%lx pa=%lx opa=%lx\n", pmap, va, pa, opa);
     1.1      matt #endif
     1.1      matt
     1.1      matt 		/* Are we mapping the same page ? */
     1.1      matt 		if (opa == pa) {
     1.1      matt 			/* All we must be doing is changing the protection */
     1.1      matt 			PDEBUG(0, printf("Case 02 in pmap_enter (V%08lx P%08lx)\n",
     1.1      matt 			    va, pa));
     1.1      matt
     1.1      matt 			/* Has the wiring changed ? */
1.14.2.6  jdolecek 			if (pg != NULL) {
1.14.2.6  jdolecek 				simple_lock(&pg->mdpage.pvh_slock);
1.14.2.6  jdolecek 				(void) pmap_modify_pv(pmap, va, pg,
     1.1      matt 				    PT_Wr | PT_W, nflags);
1.14.2.6  jdolecek 				simple_unlock(&pg->mdpage.pvh_slock);
1.14.2.6  jdolecek  			}
     1.1      matt 		} else {
1.14.2.6  jdolecek 			struct vm_page *opg;
1.14.2.6  jdolecek
     1.1      matt 			/* We are replacing the page with a new one. */
1.14.2.5  jdolecek 			cpu_idcache_wbinv_range(va, NBPG);
     1.1      matt
     1.1      matt 			PDEBUG(0, printf("Case 03 in pmap_enter (V%08lx P%08lx P%08lx)\n",
     1.1      matt 			    va, pa, opa));
     1.1      matt
     1.1      matt 			/*
     1.1      matt 			 * If it is part of our managed memory then we
     1.1      matt 			 * must remove it from the PV list
     1.1      matt 			 */
1.14.2.6  jdolecek 			if ((opg = PHYS_TO_VM_PAGE(opa)) != NULL) {
1.14.2.6  jdolecek 				simple_lock(&opg->mdpage.pvh_slock);
1.14.2.6  jdolecek 				pve = pmap_remove_pv(opg, pmap, va);
1.14.2.6  jdolecek 				simple_unlock(&opg->mdpage.pvh_slock);
1.14.2.2   thorpej 			} else {
1.14.2.2   thorpej 				pve = NULL;
     1.1      matt 			}
     1.1      matt
     1.1      matt 			goto enter;
     1.1      matt 		}
     1.1      matt 	} else {
     1.1      matt 		opa = 0;
1.14.2.2   thorpej 		pve = NULL;
     1.1      matt 		pmap_pte_addref(pmap, va);
     1.1      matt
     1.1      matt 		/* pte is not valid so we must be hooking in a new page */
     1.1      matt 		++pmap->pm_stats.resident_count;
     1.1      matt
     1.1      matt 	enter:
     1.1      matt 		/*
     1.1      matt 		 * Enter on the PV list if part of our managed memory
     1.1      matt 		 */
1.14.2.6  jdolecek 		if (pmap_initialized && pg != NULL) {
1.14.2.2   thorpej 			if (pve == NULL) {
1.14.2.2   thorpej 				pve = pmap_alloc_pv(pmap, ALLOCPV_NEED);
1.14.2.2   thorpej 				if (pve == NULL) {
1.14.2.2   thorpej 					if (flags & PMAP_CANFAIL) {
1.14.2.2   thorpej 						error = ENOMEM;
1.14.2.2   thorpej 						goto out;
1.14.2.2   thorpej 					}
1.14.2.2   thorpej 					panic("pmap_enter: no pv entries available");
1.14.2.2   thorpej 				}
1.14.2.2   thorpej 			}
1.14.2.2   thorpej 			/* enter_pv locks pvh when adding */
1.14.2.6  jdolecek 			pmap_enter_pv(pg, pve, pmap, va, NULL, nflags);
1.14.2.2   thorpej 		} else {
1.14.2.6  jdolecek 			pg = NULL;
1.14.2.2   thorpej 			if (pve != NULL)
1.14.2.2   thorpej 				pmap_free_pv(pmap, pve);
     1.1      matt 		}
     1.1      matt 	}
     1.1      matt
     1.1      matt #ifdef MYCROFT_HACK
     1.1      matt 	if (mycroft_hack)
     1.1      matt 		printf("pmap_enter: pmap=%p va=%lx pa=%lx opa=%lx bank=%d off=%d pv=%p\n", pmap, va, pa, opa, bank, off, pv);
     1.1      matt #endif
     1.1      matt
     1.1      matt 	/* Construct the pte, giving the correct access. */
     1.1      matt 	npte = (pa & PG_FRAME);
     1.1      matt
     1.1      matt 	/* VA 0 is magic. */
     1.1      matt 	if (pmap != pmap_kernel() && va != 0)
     1.1      matt 		npte |= PT_AP(AP_U);
     1.1      matt
1.14.2.6  jdolecek 	if (pmap_initialized && pg != NULL) {
     1.1      matt #ifdef DIAGNOSTIC
     1.1      matt 		if ((flags & VM_PROT_ALL) & ~prot)
     1.1      matt 			panic("pmap_enter: access_type exceeds prot");
     1.1      matt #endif
1.14.2.4   thorpej 		npte |= pte_cache_mode;
     1.1      matt 		if (flags & VM_PROT_WRITE) {
     1.1      matt 			npte |= L2_SPAGE | PT_AP(AP_W);
1.14.2.6  jdolecek 			pg->mdpage.pvh_attrs |= PT_H | PT_M;
     1.1      matt 		} else if (flags & VM_PROT_ALL) {
     1.1      matt 			npte |= L2_SPAGE;
1.14.2.6  jdolecek 			pg->mdpage.pvh_attrs |= PT_H;
     1.1      matt 		} else
     1.1      matt 			npte |= L2_INVAL;
     1.1      matt 	} else {
     1.1      matt 		if (prot & VM_PROT_WRITE)
     1.1      matt 			npte |= L2_SPAGE | PT_AP(AP_W);
     1.1      matt 		else if (prot & VM_PROT_ALL)
     1.1      matt 			npte |= L2_SPAGE;
     1.1      matt 		else
     1.1      matt 			npte |= L2_INVAL;
     1.1      matt 	}
     1.1      matt
     1.1      matt #ifdef MYCROFT_HACK
     1.1      matt 	if (mycroft_hack)
     1.1      matt 		printf("pmap_enter: pmap=%p va=%lx pa=%lx prot=%x wired=%d access_type=%x npte=%08x\n", pmap, va, pa, prot, wired, flags & VM_PROT_ALL, npte);
     1.1      matt #endif
     1.1      matt
     1.1      matt 	*pte = npte;
     1.1      matt
1.14.2.6  jdolecek 	if (pmap_initialized && pg != NULL) {
    1.12     chris 		boolean_t pmap_active = FALSE;
    1.11     chris 		/* XXX this will change once the whole of pmap_enter uses
    1.11     chris 		 * map_ptes
    1.11     chris 		 */
    1.11     chris 		ptes = pmap_map_ptes(pmap);
    1.12     chris 		if ((curproc && curproc->p_vmspace->vm_map.pmap == pmap)
1.14.2.1     lukem 		    || (pmap == pmap_kernel()))
    1.12     chris 			pmap_active = TRUE;
1.14.2.6  jdolecek 		simple_lock(&pg->mdpage.pvh_slock);
1.14.2.6  jdolecek  		pmap_vac_me_harder(pmap, pg, ptes, pmap_active);
1.14.2.6  jdolecek 		simple_unlock(&pg->mdpage.pvh_slock);
    1.11     chris 		pmap_unmap_ptes(pmap);
    1.11     chris 	}
     1.1      matt
     1.1      matt 	/* Better flush the TLB ... */
     1.1      matt 	cpu_tlb_flushID_SE(va);
1.14.2.2   thorpej 	error = 0;
1.14.2.2   thorpej out:
1.14.2.4   thorpej 	simple_unlock(&pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 	PMAP_MAP_TO_HEAD_UNLOCK();
     1.1      matt 	PDEBUG(5, printf("pmap_enter: pte = V%p %08x\n", pte, *pte));
     1.1      matt
1.14.2.2   thorpej 	return error;
     1.1      matt }
     1.1      matt
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * pmap_kenter_pa: enter a kernel mapping
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  * => no need to lock anything assume va is already allocated
1.14.2.6  jdolecek  * => should be faster than normal pmap enter function
1.14.2.6  jdolecek  */
     1.1      matt void
     1.1      matt pmap_kenter_pa(va, pa, prot)
     1.1      matt 	vaddr_t va;
     1.1      matt 	paddr_t pa;
     1.1      matt 	vm_prot_t prot;
     1.1      matt {
    1.13     chris 	pt_entry_t *pte;
    1.13     chris
    1.13     chris 	pte = vtopte(va);
    1.14       chs 	KASSERT(!pmap_pte_v(pte));
    1.13     chris 	*pte = L2_PTE(pa, AP_KRW);
     1.1      matt }
     1.1      matt
     1.1      matt void
     1.1      matt pmap_kremove(va, len)
     1.1      matt 	vaddr_t va;
     1.1      matt 	vsize_t len;
     1.1      matt {
    1.14       chs 	pt_entry_t *pte;
    1.14       chs
     1.1      matt 	for (len >>= PAGE_SHIFT; len > 0; len--, va += PAGE_SIZE) {
    1.13     chris
    1.14       chs 		/*
    1.14       chs 		 * We assume that we will only be called with small
    1.14       chs 		 * regions of memory.
    1.14       chs 		 */
    1.14       chs
1.14.2.4   thorpej 		KASSERT(pmap_pde_page(pmap_pde(pmap_kernel(), va)));
    1.13     chris 		pte = vtopte(va);
1.14.2.5  jdolecek 		cpu_idcache_wbinv_range(va, PAGE_SIZE);
    1.13     chris 		*pte = 0;
    1.13     chris 		cpu_tlb_flushID_SE(va);
     1.1      matt 	}
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * pmap_page_protect:
     1.1      matt  *
     1.1      matt  * Lower the permission for all mappings to a given page.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_page_protect(pg, prot)
     1.1      matt 	struct vm_page *pg;
     1.1      matt 	vm_prot_t prot;
     1.1      matt {
     1.1      matt
1.14.2.6  jdolecek 	PDEBUG(0, printf("pmap_page_protect(pa=%lx, prot=%d)\n",
1.14.2.6  jdolecek 	    VM_PAGE_TO_PHYS(pg), prot));
     1.1      matt
     1.1      matt 	switch(prot) {
1.14.2.2   thorpej 	case VM_PROT_READ|VM_PROT_WRITE|VM_PROT_EXECUTE:
1.14.2.2   thorpej 	case VM_PROT_READ|VM_PROT_WRITE:
1.14.2.2   thorpej 		return;
1.14.2.2   thorpej
     1.1      matt 	case VM_PROT_READ:
     1.1      matt 	case VM_PROT_READ|VM_PROT_EXECUTE:
1.14.2.6  jdolecek 		pmap_copy_on_write(pg);
     1.1      matt 		break;
     1.1      matt
     1.1      matt 	default:
1.14.2.6  jdolecek 		pmap_remove_all(pg);
     1.1      matt 		break;
     1.1      matt 	}
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
     1.1      matt  * Routine:	pmap_unwire
     1.1      matt  * Function:	Clear the wired attribute for a map/virtual-address
     1.1      matt  *		pair.
     1.1      matt  * In/out conditions:
     1.1      matt  *		The mapping must already exist in the pmap.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_unwire(pmap, va)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
     1.1      matt {
     1.1      matt 	pt_entry_t *pte;
     1.2      matt 	paddr_t pa;
1.14.2.6  jdolecek 	struct vm_page *pg;
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * Make sure pmap is valid. -dct
     1.1      matt 	 */
     1.1      matt 	if (pmap == NULL)
     1.1      matt 		return;
     1.1      matt
     1.1      matt 	/* Get the pte */
     1.1      matt 	pte = pmap_pte(pmap, va);
     1.1      matt 	if (!pte)
     1.1      matt 		return;
     1.1      matt
     1.1      matt 	/* Extract the physical address of the page */
     1.1      matt 	pa = pmap_pte_pa(pte);
     1.1      matt
1.14.2.6  jdolecek 	if ((pg = PHYS_TO_VM_PAGE(pa)) == NULL)
     1.1      matt 		return;
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	simple_lock(&pg->mdpage.pvh_slock);
     1.1      matt 	/* Update the wired bit in the pv entry for this page. */
1.14.2.6  jdolecek 	(void) pmap_modify_pv(pmap, va, pg, PT_W, 0);
1.14.2.6  jdolecek 	simple_unlock(&pg->mdpage.pvh_slock);
     1.1      matt }
     1.1      matt
     1.1      matt /*
1.14.2.1     lukem  * pt_entry_t *pmap_pte(struct pmap *pmap, vaddr_t va)
     1.1      matt  *
     1.1      matt  * Return the pointer to a page table entry corresponding to the supplied
     1.1      matt  * virtual address.
     1.1      matt  *
     1.1      matt  * The page directory is first checked to make sure that a page table
     1.1      matt  * for the address in question exists and if it does a pointer to the
     1.1      matt  * entry is returned.
     1.1      matt  *
     1.1      matt  * The way this works is that that the kernel page tables are mapped
     1.1      matt  * into the memory map at ALT_PAGE_TBLS_BASE to ALT_PAGE_TBLS_BASE+4MB.
     1.1      matt  * This allows page tables to be located quickly.
     1.1      matt  */
     1.1      matt pt_entry_t *
     1.1      matt pmap_pte(pmap, va)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
     1.1      matt {
     1.1      matt 	pt_entry_t *ptp;
     1.1      matt 	pt_entry_t *result;
     1.1      matt
     1.1      matt 	/* The pmap must be valid */
     1.1      matt 	if (!pmap)
     1.1      matt 		return(NULL);
     1.1      matt
     1.1      matt 	/* Return the address of the pte */
     1.1      matt 	PDEBUG(10, printf("pmap_pte: pmap=%p va=V%08lx pde = V%p (%08X)\n",
     1.1      matt 	    pmap, va, pmap_pde(pmap, va), *(pmap_pde(pmap, va))));
     1.1      matt
     1.1      matt 	/* Do we have a valid pde ? If not we don't have a page table */
1.14.2.4   thorpej 	if (!pmap_pde_page(pmap_pde(pmap, va))) {
     1.1      matt 		PDEBUG(0, printf("pmap_pte: failed - pde = %p\n",
     1.1      matt 		    pmap_pde(pmap, va)));
     1.1      matt 		return(NULL);
     1.1      matt 	}
     1.1      matt
     1.1      matt 	PDEBUG(10, printf("pmap pagetable = P%08lx current = P%08x\n",
     1.1      matt 	    pmap->pm_pptpt, (*((pt_entry_t *)(PROCESS_PAGE_TBLS_BASE
     1.1      matt 	    + (PROCESS_PAGE_TBLS_BASE >> (PGSHIFT - 2)) +
     1.1      matt 	    (PROCESS_PAGE_TBLS_BASE >> PDSHIFT))) & PG_FRAME)));
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * If the pmap is the kernel pmap or the pmap is the active one
     1.1      matt 	 * then we can just return a pointer to entry relative to
     1.1      matt 	 * PROCESS_PAGE_TBLS_BASE.
     1.1      matt 	 * Otherwise we need to map the page tables to an alternative
     1.1      matt 	 * address and reference them there.
     1.1      matt 	 */
1.14.2.1     lukem 	if (pmap == pmap_kernel() || pmap->pm_pptpt
     1.1      matt 	    == (*((pt_entry_t *)(PROCESS_PAGE_TBLS_BASE
     1.1      matt 	    + ((PROCESS_PAGE_TBLS_BASE >> (PGSHIFT - 2)) &
     1.1      matt 	    ~3) + (PROCESS_PAGE_TBLS_BASE >> PDSHIFT))) & PG_FRAME)) {
     1.1      matt 		ptp = (pt_entry_t *)PROCESS_PAGE_TBLS_BASE;
     1.1      matt 	} else {
     1.1      matt 		struct proc *p = curproc;
     1.1      matt
     1.1      matt 		/* If we don't have a valid curproc use proc0 */
     1.1      matt 		/* Perhaps we should just use kernel_pmap instead */
     1.1      matt 		if (p == NULL)
     1.1      matt 			p = &proc0;
     1.1      matt #ifdef DIAGNOSTIC
     1.1      matt 		/*
     1.1      matt 		 * The pmap should always be valid for the process so
     1.1      matt 		 * panic if it is not.
     1.1      matt 		 */
     1.1      matt 		if (!p->p_vmspace || !p->p_vmspace->vm_map.pmap) {
     1.1      matt 			printf("pmap_pte: va=%08lx p=%p vm=%p\n",
     1.1      matt 			    va, p, p->p_vmspace);
     1.1      matt 			console_debugger();
     1.1      matt 		}
     1.1      matt 		/*
     1.1      matt 		 * The pmap for the current process should be mapped. If it
     1.1      matt 		 * is not then we have a problem.
     1.1      matt 		 */
     1.1      matt 		if (p->p_vmspace->vm_map.pmap->pm_pptpt !=
     1.1      matt 		    (*((pt_entry_t *)(PROCESS_PAGE_TBLS_BASE
     1.1      matt 		    + (PROCESS_PAGE_TBLS_BASE >> (PGSHIFT - 2)) +
     1.1      matt 		    (PROCESS_PAGE_TBLS_BASE >> PDSHIFT))) & PG_FRAME)) {
     1.1      matt 			printf("pmap pagetable = P%08lx current = P%08x ",
     1.1      matt 			    pmap->pm_pptpt, (*((pt_entry_t *)(PROCESS_PAGE_TBLS_BASE
     1.1      matt 			    + (PROCESS_PAGE_TBLS_BASE >> (PGSHIFT - 2)) +
     1.1      matt 			    (PROCESS_PAGE_TBLS_BASE >> PDSHIFT))) &
     1.1      matt 			    PG_FRAME));
     1.1      matt 			printf("pptpt=%lx\n", p->p_vmspace->vm_map.pmap->pm_pptpt);
     1.1      matt 			panic("pmap_pte: current and pmap mismatch\n");
     1.1      matt 		}
     1.1      matt #endif
     1.1      matt
     1.1      matt 		ptp = (pt_entry_t *)ALT_PAGE_TBLS_BASE;
     1.1      matt 		pmap_map_in_l1(p->p_vmspace->vm_map.pmap, ALT_PAGE_TBLS_BASE,
1.14.2.2   thorpej 		    pmap->pm_pptpt, FALSE);
     1.1      matt 		cpu_tlb_flushD();
1.14.2.4   thorpej 		cpu_cpwait();
     1.1      matt 	}
     1.1      matt 	PDEBUG(10, printf("page tables base = %p offset=%lx\n", ptp,
     1.1      matt 	    ((va >> (PGSHIFT-2)) & ~3)));
     1.1      matt 	result = (pt_entry_t *)((char *)ptp + ((va >> (PGSHIFT-2)) & ~3));
     1.1      matt 	return(result);
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * Routine:  pmap_extract
     1.1      matt  * Function:
     1.1      matt  *           Extract the physical page address associated
     1.1      matt  *           with the given map/virtual_address pair.
     1.1      matt  */
     1.1      matt boolean_t
     1.1      matt pmap_extract(pmap, va, pap)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
     1.1      matt 	paddr_t *pap;
     1.1      matt {
1.14.2.5  jdolecek 	pd_entry_t *pde;
    1.11     chris 	pt_entry_t *pte, *ptes;
     1.1      matt 	paddr_t pa;
1.14.2.5  jdolecek 	boolean_t rv = TRUE;
     1.1      matt
     1.1      matt 	PDEBUG(5, printf("pmap_extract: pmap=%p, va=V%08lx\n", pmap, va));
     1.1      matt
     1.1      matt 	/*
    1.11     chris 	 * Get the pte for this virtual address.
     1.1      matt 	 */
1.14.2.5  jdolecek 	pde = pmap_pde(pmap, va);
    1.11     chris 	ptes = pmap_map_ptes(pmap);
    1.11     chris 	pte = &ptes[arm_byte_to_page(va)];
     1.1      matt
1.14.2.5  jdolecek 	if (pmap_pde_section(pde)) {
1.14.2.5  jdolecek 		pa = (*pde & PD_MASK) | (va & (L1_SEC_SIZE - 1));
1.14.2.5  jdolecek 		goto out;
1.14.2.5  jdolecek 	} else if (pmap_pde_page(pde) == 0 || pmap_pte_v(pte) == 0) {
1.14.2.5  jdolecek 		rv = FALSE;
1.14.2.5  jdolecek 		goto out;
    1.11     chris 	}
     1.1      matt
1.14.2.5  jdolecek 	if ((*pte & L2_MASK) == L2_LPAGE) {
     1.1      matt 		/* Extract the physical address from the pte */
1.14.2.5  jdolecek 		pa = *pte & ~(L2_LPAGE_SIZE - 1);
     1.1      matt
     1.1      matt 		PDEBUG(5, printf("pmap_extract: LPAGE pa = P%08lx\n",
     1.1      matt 		    (pa | (va & (L2_LPAGE_SIZE - 1)))));
     1.1      matt
     1.1      matt 		if (pap != NULL)
     1.1      matt 			*pap = pa | (va & (L2_LPAGE_SIZE - 1));
1.14.2.5  jdolecek 		goto out;
1.14.2.5  jdolecek 	}
     1.1      matt
1.14.2.5  jdolecek 	/* Extract the physical address from the pte */
1.14.2.5  jdolecek 	pa = pmap_pte_pa(pte);
     1.1      matt
1.14.2.5  jdolecek 	PDEBUG(5, printf("pmap_extract: SPAGE pa = P%08lx\n",
1.14.2.5  jdolecek 	    (pa | (va & ~PG_FRAME))));
1.14.2.5  jdolecek
1.14.2.5  jdolecek 	if (pap != NULL)
1.14.2.5  jdolecek 		*pap = pa | (va & ~PG_FRAME);
1.14.2.5  jdolecek  out:
    1.11     chris 	pmap_unmap_ptes(pmap);
1.14.2.5  jdolecek 	return (rv);
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt /*
     1.1      matt  * Copy the range specified by src_addr/len from the source map to the
     1.1      matt  * range dst_addr/len in the destination map.
     1.1      matt  *
     1.1      matt  * This routine is only advisory and need not do anything.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_copy(dst_pmap, src_pmap, dst_addr, len, src_addr)
1.14.2.1     lukem 	struct pmap *dst_pmap;
1.14.2.1     lukem 	struct pmap *src_pmap;
     1.1      matt 	vaddr_t dst_addr;
     1.2      matt 	vsize_t len;
     1.1      matt 	vaddr_t src_addr;
     1.1      matt {
     1.1      matt 	PDEBUG(0, printf("pmap_copy(%p, %p, %lx, %lx, %lx)\n",
     1.1      matt 	    dst_pmap, src_pmap, dst_addr, len, src_addr));
     1.1      matt }
     1.1      matt
     1.1      matt #if defined(PMAP_DEBUG)
     1.1      matt void
     1.1      matt pmap_dump_pvlist(phys, m)
     1.1      matt 	vaddr_t phys;
     1.1      matt 	char *m;
     1.1      matt {
1.14.2.6  jdolecek 	struct vm_page *pg;
     1.1      matt 	struct pv_entry *pv;
     1.1      matt
1.14.2.6  jdolecek 	if ((pg = PHYS_TO_VM_PAGE(phys)) == NULL) {
     1.1      matt 		printf("INVALID PA\n");
     1.1      matt 		return;
     1.1      matt 	}
1.14.2.6  jdolecek 	simple_lock(&pg->mdpage.pvh_slock);
     1.1      matt 	printf("%s %08lx:", m, phys);
1.14.2.6  jdolecek 	if (pg->mdpage.pvh_list == NULL) {
     1.1      matt 		printf(" no mappings\n");
     1.1      matt 		return;
     1.1      matt 	}
     1.1      matt
1.14.2.6  jdolecek 	for (pv = pg->mdpage.pvh_list; pv; pv = pv->pv_next)
     1.1      matt 		printf(" pmap %p va %08lx flags %08x", pv->pv_pmap,
     1.1      matt 		    pv->pv_va, pv->pv_flags);
     1.1      matt
     1.1      matt 	printf("\n");
1.14.2.6  jdolecek 	simple_unlock(&pg->mdpage.pvh_slock);
     1.1      matt }
     1.1      matt
     1.1      matt #endif	/* PMAP_DEBUG */
     1.1      matt
    1.11     chris static pt_entry_t *
    1.11     chris pmap_map_ptes(struct pmap *pmap)
    1.11     chris {
1.14.2.2   thorpej     	struct proc *p;
1.14.2.2   thorpej
1.14.2.2   thorpej     	/* the kernel's pmap is always accessible */
1.14.2.2   thorpej 	if (pmap == pmap_kernel()) {
1.14.2.2   thorpej 		return (pt_entry_t *)PROCESS_PAGE_TBLS_BASE ;
1.14.2.2   thorpej 	}
1.14.2.2   thorpej
1.14.2.2   thorpej 	if (pmap_is_curpmap(pmap)) {
1.14.2.2   thorpej 		simple_lock(&pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 		return (pt_entry_t *)PROCESS_PAGE_TBLS_BASE;
1.14.2.2   thorpej 	}
1.14.2.2   thorpej
1.14.2.2   thorpej 	p = curproc;
1.14.2.2   thorpej
1.14.2.2   thorpej 	if (p == NULL)
1.14.2.2   thorpej 		p = &proc0;
1.14.2.2   thorpej
1.14.2.2   thorpej 	/* need to lock both curpmap and pmap: use ordered locking */
1.14.2.2   thorpej 	if ((unsigned) pmap < (unsigned) curproc->p_vmspace->vm_map.pmap) {
1.14.2.2   thorpej 		simple_lock(&pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 		simple_lock(&curproc->p_vmspace->vm_map.pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 	} else {
1.14.2.2   thorpej 		simple_lock(&curproc->p_vmspace->vm_map.pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 		simple_lock(&pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 	}
    1.11     chris
1.14.2.2   thorpej 	pmap_map_in_l1(p->p_vmspace->vm_map.pmap, ALT_PAGE_TBLS_BASE,
1.14.2.2   thorpej 			pmap->pm_pptpt, FALSE);
1.14.2.2   thorpej 	cpu_tlb_flushD();
1.14.2.4   thorpej 	cpu_cpwait();
1.14.2.2   thorpej 	return (pt_entry_t *)ALT_PAGE_TBLS_BASE;
1.14.2.2   thorpej }
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pmap_unmap_ptes: unlock the PTE mapping of "pmap"
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej static void
1.14.2.2   thorpej pmap_unmap_ptes(pmap)
1.14.2.2   thorpej 	struct pmap *pmap;
1.14.2.2   thorpej {
1.14.2.2   thorpej 	if (pmap == pmap_kernel()) {
1.14.2.2   thorpej 		return;
1.14.2.2   thorpej 	}
1.14.2.2   thorpej 	if (pmap_is_curpmap(pmap)) {
1.14.2.2   thorpej 		simple_unlock(&pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 	} else {
1.14.2.2   thorpej 		simple_unlock(&pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 		simple_unlock(&curproc->p_vmspace->vm_map.pmap->pm_obj.vmobjlock);
1.14.2.2   thorpej 	}
    1.11     chris }
     1.1      matt
     1.1      matt /*
     1.1      matt  * Modify pte bits for all ptes corresponding to the given physical address.
     1.1      matt  * We use `maskbits' rather than `clearbits' because we're always passing
     1.1      matt  * constants and the latter would require an extra inversion at run-time.
     1.1      matt  */
     1.1      matt
1.14.2.4   thorpej static void
1.14.2.6  jdolecek pmap_clearbit(pg, maskbits)
1.14.2.6  jdolecek 	struct vm_page *pg;
1.14.2.4   thorpej 	unsigned int maskbits;
     1.1      matt {
     1.1      matt 	struct pv_entry *pv;
     1.1      matt 	pt_entry_t *pte;
     1.1      matt 	vaddr_t va;
1.14.2.6  jdolecek 	int tlbentry;
     1.1      matt
     1.1      matt 	PDEBUG(1, printf("pmap_clearbit: pa=%08lx mask=%08x\n",
1.14.2.6  jdolecek 	    VM_PAGE_TO_PHYS(pg), maskbits));
1.14.2.4   thorpej
1.14.2.4   thorpej 	tlbentry = 0;
1.14.2.4   thorpej
1.14.2.2   thorpej 	PMAP_HEAD_TO_MAP_LOCK();
1.14.2.6  jdolecek 	simple_lock(&pg->mdpage.pvh_slock);
1.14.2.2   thorpej
     1.1      matt 	/*
     1.1      matt 	 * Clear saved attributes (modify, reference)
     1.1      matt 	 */
1.14.2.6  jdolecek 	pg->mdpage.pvh_attrs &= ~maskbits;
     1.1      matt
1.14.2.6  jdolecek 	if (pg->mdpage.pvh_list == NULL) {
1.14.2.6  jdolecek 		simple_unlock(&pg->mdpage.pvh_slock);
1.14.2.2   thorpej 		PMAP_HEAD_TO_MAP_UNLOCK();
     1.1      matt 		return;
     1.1      matt 	}
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * Loop over all current mappings setting/clearing as appropos
     1.1      matt 	 */
1.14.2.6  jdolecek 	for (pv = pg->mdpage.pvh_list; pv; pv = pv->pv_next) {
     1.1      matt 		va = pv->pv_va;
     1.1      matt 		pv->pv_flags &= ~maskbits;
     1.1      matt 		pte = pmap_pte(pv->pv_pmap, va);
1.14.2.2   thorpej 		KASSERT(pte != NULL);
1.14.2.4   thorpej 		if (maskbits & (PT_Wr|PT_M)) {
1.14.2.4   thorpej 			if ((pv->pv_flags & PT_NC)) {
1.14.2.4   thorpej 				/*
1.14.2.4   thorpej 				 * Entry is not cacheable: reenable
1.14.2.4   thorpej 				 * the cache, nothing to flush
1.14.2.4   thorpej 				 *
1.14.2.4   thorpej 				 * Don't turn caching on again if this
1.14.2.4   thorpej 				 * is a modified emulation.  This
1.14.2.4   thorpej 				 * would be inconsitent with the
1.14.2.4   thorpej 				 * settings created by
1.14.2.4   thorpej 				 * pmap_vac_me_harder().
1.14.2.4   thorpej 				 *
1.14.2.4   thorpej 				 * There's no need to call
1.14.2.4   thorpej 				 * pmap_vac_me_harder() here: all
1.14.2.4   thorpej 				 * pages are loosing their write
1.14.2.4   thorpej 				 * permission.
1.14.2.4   thorpej 				 *
1.14.2.4   thorpej 				 */
1.14.2.4   thorpej 				if (maskbits & PT_Wr) {
1.14.2.4   thorpej 					*pte |= pte_cache_mode;
1.14.2.4   thorpej 					pv->pv_flags &= ~PT_NC;
1.14.2.4   thorpej 				}
1.14.2.4   thorpej 			} else if (pmap_is_curpmap(pv->pv_pmap))
1.14.2.4   thorpej 				/*
1.14.2.4   thorpej 				 * Entry is cacheable: check if pmap is
1.14.2.4   thorpej 				 * current if it is flush it,
1.14.2.4   thorpej 				 * otherwise it won't be in the cache
1.14.2.4   thorpej 				 */
1.14.2.5  jdolecek 				cpu_idcache_wbinv_range(pv->pv_va, NBPG);
1.14.2.4   thorpej
1.14.2.4   thorpej 			/* make the pte read only */
1.14.2.2   thorpej 			*pte &= ~PT_AP(AP_W);
1.14.2.4   thorpej 		}
1.14.2.4   thorpej
     1.1      matt 		if (maskbits & PT_H)
     1.1      matt 			*pte = (*pte & ~L2_MASK) | L2_INVAL;
1.14.2.4   thorpej
1.14.2.4   thorpej 		if (pmap_is_curpmap(pv->pv_pmap))
1.14.2.4   thorpej 			/*
1.14.2.4   thorpej 			 * if we had cacheable pte's we'd clean the
1.14.2.4   thorpej 			 * pte out to memory here
1.14.2.4   thorpej 			 *
1.14.2.4   thorpej 			 * flush tlb entry as it's in the current pmap
1.14.2.4   thorpej 			 */
1.14.2.4   thorpej 			cpu_tlb_flushID_SE(pv->pv_va);
     1.1      matt 	}
1.14.2.4   thorpej 	cpu_cpwait();
1.14.2.4   thorpej
1.14.2.6  jdolecek 	simple_unlock(&pg->mdpage.pvh_slock);
1.14.2.2   thorpej 	PMAP_HEAD_TO_MAP_UNLOCK();
     1.1      matt }
     1.1      matt
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * pmap_clear_modify:
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  *	Clear the "modified" attribute for a page.
1.14.2.6  jdolecek  */
     1.1      matt boolean_t
     1.1      matt pmap_clear_modify(pg)
     1.1      matt 	struct vm_page *pg;
     1.1      matt {
     1.1      matt 	boolean_t rv;
     1.1      matt
1.14.2.6  jdolecek 	if (pg->mdpage.pvh_attrs & PT_M) {
1.14.2.6  jdolecek 		rv = TRUE;
1.14.2.6  jdolecek 		pmap_clearbit(pg, PT_M);
1.14.2.6  jdolecek 	} else
1.14.2.6  jdolecek 		rv = FALSE;
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	PDEBUG(0, printf("pmap_clear_modify pa=%08lx -> %d\n",
1.14.2.6  jdolecek 	    VM_PAGE_TO_PHYS(pg), rv));
     1.1      matt
1.14.2.6  jdolecek 	return (rv);
1.14.2.6  jdolecek }
     1.1      matt
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * pmap_clear_reference:
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  *	Clear the "referenced" attribute for a page.
1.14.2.6  jdolecek  */
     1.1      matt boolean_t
     1.1      matt pmap_clear_reference(pg)
     1.1      matt 	struct vm_page *pg;
     1.1      matt {
     1.1      matt 	boolean_t rv;
     1.1      matt
1.14.2.6  jdolecek 	if (pg->mdpage.pvh_attrs & PT_H) {
1.14.2.6  jdolecek 		rv = TRUE;
1.14.2.6  jdolecek 		pmap_clearbit(pg, PT_H);
1.14.2.6  jdolecek 	} else
1.14.2.6  jdolecek 		rv = FALSE;
     1.1      matt
1.14.2.6  jdolecek 	PDEBUG(0, printf("pmap_clear_reference pa=%08lx -> %d\n",
1.14.2.6  jdolecek 	    VM_PAGE_TO_PHYS(pg), rv));
     1.1      matt
1.14.2.6  jdolecek 	return (rv);
     1.1      matt }
     1.1      matt
     1.1      matt
1.14.2.6  jdolecek void
1.14.2.6  jdolecek pmap_copy_on_write(pg)
     1.1      matt 	struct vm_page *pg;
     1.1      matt {
1.14.2.6  jdolecek 	PDEBUG(0, printf("pmap_copy_on_write pa=%08lx\n", VM_PAGE_TO_PHYS(pg)));
1.14.2.6  jdolecek 	pmap_clearbit(pg, PT_Wr);
     1.1      matt }
     1.1      matt
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * pmap_is_modified:
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  *	Test if a page has the "modified" attribute.
1.14.2.6  jdolecek  */
1.14.2.6  jdolecek /* See <arm/arm32/pmap.h> */
     1.1      matt
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * pmap_is_referenced:
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  *	Test if a page has the "referenced" attribute.
1.14.2.6  jdolecek  */
1.14.2.6  jdolecek /* See <arm/arm32/pmap.h> */
     1.1      matt
     1.1      matt int
     1.1      matt pmap_modified_emulation(pmap, va)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
     1.1      matt {
     1.1      matt 	pt_entry_t *pte;
     1.2      matt 	paddr_t pa;
1.14.2.6  jdolecek 	struct vm_page *pg;
     1.1      matt 	u_int flags;
     1.1      matt
     1.1      matt 	PDEBUG(2, printf("pmap_modified_emulation\n"));
     1.1      matt
     1.1      matt 	/* Get the pte */
     1.1      matt 	pte = pmap_pte(pmap, va);
     1.1      matt 	if (!pte) {
     1.1      matt 		PDEBUG(2, printf("no pte\n"));
     1.1      matt 		return(0);
     1.1      matt 	}
     1.1      matt
     1.1      matt 	PDEBUG(1, printf("*pte=%08x\n", *pte));
     1.1      matt
     1.1      matt 	/* Check for a zero pte */
     1.1      matt 	if (*pte == 0)
     1.1      matt 		return(0);
     1.1      matt
     1.1      matt 	/* This can happen if user code tries to access kernel memory. */
     1.1      matt 	if ((*pte & PT_AP(AP_W)) != 0)
     1.1      matt 		return (0);
     1.1      matt
     1.1      matt 	/* Extract the physical address of the page */
     1.1      matt 	pa = pmap_pte_pa(pte);
1.14.2.6  jdolecek 	if ((pg = PHYS_TO_VM_PAGE(pa)) == NULL)
     1.1      matt 		return(0);
     1.1      matt
     1.1      matt 	/* Get the current flags for this page. */
1.14.2.6  jdolecek 	PMAP_HEAD_TO_MAP_LOCK();
1.14.2.6  jdolecek 	simple_lock(&pg->mdpage.pvh_slock);
1.14.2.2   thorpej
1.14.2.6  jdolecek 	flags = pmap_modify_pv(pmap, va, pg, 0, 0);
     1.1      matt 	PDEBUG(2, printf("pmap_modified_emulation: flags = %08x\n", flags));
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * Do the flags say this page is writable ? If not then it is a
     1.1      matt 	 * genuine write fault. If yes then the write fault is our fault
     1.1      matt 	 * as we did not reflect the write access in the PTE. Now we know
     1.1      matt 	 * a write has occurred we can correct this and also set the
     1.1      matt 	 * modified bit
     1.1      matt 	 */
1.14.2.2   thorpej 	if (~flags & PT_Wr) {
1.14.2.6  jdolecek 	    	simple_unlock(&pg->mdpage.pvh_slock);
1.14.2.2   thorpej 		PMAP_HEAD_TO_MAP_UNLOCK();
     1.1      matt 		return(0);
1.14.2.2   thorpej 	}
     1.1      matt
     1.1      matt 	PDEBUG(0, printf("pmap_modified_emulation: Got a hit va=%08lx, pte = %p (%08x)\n",
     1.1      matt 	    va, pte, *pte));
1.14.2.6  jdolecek 	pg->mdpage.pvh_attrs |= PT_H | PT_M;
1.14.2.4   thorpej
1.14.2.4   thorpej 	/*
1.14.2.4   thorpej 	 * Re-enable write permissions for the page.  No need to call
1.14.2.4   thorpej 	 * pmap_vac_me_harder(), since this is just a
1.14.2.4   thorpej 	 * modified-emulation fault, and the PT_Wr bit isn't changing.  We've
1.14.2.4   thorpej 	 * already set the cacheable bits based on the assumption that we
1.14.2.4   thorpej 	 * can write to this page.
1.14.2.4   thorpej 	 */
     1.1      matt 	*pte = (*pte & ~L2_MASK) | L2_SPAGE | PT_AP(AP_W);
     1.1      matt 	PDEBUG(0, printf("->(%08x)\n", *pte));
     1.1      matt
1.14.2.6  jdolecek 	simple_unlock(&pg->mdpage.pvh_slock);
1.14.2.2   thorpej 	PMAP_HEAD_TO_MAP_UNLOCK();
     1.1      matt 	/* Return, indicating the problem has been dealt with */
     1.1      matt 	cpu_tlb_flushID_SE(va);
1.14.2.4   thorpej 	cpu_cpwait();
     1.1      matt 	return(1);
     1.1      matt }
     1.1      matt
     1.1      matt
     1.1      matt int
     1.1      matt pmap_handled_emulation(pmap, va)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt 	vaddr_t va;
     1.1      matt {
     1.1      matt 	pt_entry_t *pte;
     1.2      matt 	paddr_t pa;
1.14.2.6  jdolecek 	struct vm_page *pg;
     1.1      matt
     1.1      matt 	PDEBUG(2, printf("pmap_handled_emulation\n"));
     1.1      matt
     1.1      matt 	/* Get the pte */
     1.1      matt 	pte = pmap_pte(pmap, va);
     1.1      matt 	if (!pte) {
     1.1      matt 		PDEBUG(2, printf("no pte\n"));
     1.1      matt 		return(0);
     1.1      matt 	}
     1.1      matt
     1.1      matt 	PDEBUG(1, printf("*pte=%08x\n", *pte));
     1.1      matt
     1.1      matt 	/* Check for a zero pte */
     1.1      matt 	if (*pte == 0)
     1.1      matt 		return(0);
     1.1      matt
     1.1      matt 	/* This can happen if user code tries to access kernel memory. */
     1.1      matt 	if ((*pte & L2_MASK) != L2_INVAL)
     1.1      matt 		return (0);
     1.1      matt
     1.1      matt 	/* Extract the physical address of the page */
     1.1      matt 	pa = pmap_pte_pa(pte);
1.14.2.6  jdolecek 	if ((pg = PHYS_TO_VM_PAGE(pa)) == NULL)
1.14.2.6  jdolecek 		return (0);
     1.1      matt
     1.1      matt 	/*
     1.1      matt 	 * Ok we just enable the pte and mark the attibs as handled
     1.1      matt 	 */
     1.1      matt 	PDEBUG(0, printf("pmap_handled_emulation: Got a hit va=%08lx pte = %p (%08x)\n",
     1.1      matt 	    va, pte, *pte));
1.14.2.6  jdolecek 	pg->mdpage.pvh_attrs |= PT_H;
     1.1      matt 	*pte = (*pte & ~L2_MASK) | L2_SPAGE;
     1.1      matt 	PDEBUG(0, printf("->(%08x)\n", *pte));
     1.1      matt
     1.1      matt 	/* Return, indicating the problem has been dealt with */
     1.1      matt 	cpu_tlb_flushID_SE(va);
1.14.2.4   thorpej 	cpu_cpwait();
     1.1      matt 	return(1);
     1.1      matt }
     1.1      matt
1.14.2.2   thorpej
1.14.2.2   thorpej
1.14.2.2   thorpej
     1.1      matt /*
     1.1      matt  * pmap_collect: free resources held by a pmap
     1.1      matt  *
     1.1      matt  * => optional function.
     1.1      matt  * => called when a process is swapped out to free memory.
     1.1      matt  */
     1.1      matt
     1.1      matt void
     1.1      matt pmap_collect(pmap)
1.14.2.1     lukem 	struct pmap *pmap;
     1.1      matt {
     1.1      matt }
     1.1      matt
     1.1      matt /*
     1.1      matt  * Routine:	pmap_procwr
     1.1      matt  *
     1.1      matt  * Function:
     1.1      matt  *	Synchronize caches corresponding to [addr, addr+len) in p.
     1.1      matt  *
     1.1      matt  */
     1.1      matt void
     1.1      matt pmap_procwr(p, va, len)
     1.1      matt 	struct proc	*p;
     1.1      matt 	vaddr_t		va;
     1.3      matt 	int		len;
     1.1      matt {
     1.1      matt 	/* We only need to do anything if it is the current process. */
     1.1      matt 	if (p == curproc)
1.14.2.5  jdolecek 		cpu_icache_sync_range(va, len);
1.14.2.2   thorpej }
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * PTP functions
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pmap_steal_ptp: Steal a PTP from somewhere else.
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * This is just a placeholder, for now we never steal.
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej static struct vm_page *
1.14.2.2   thorpej pmap_steal_ptp(struct pmap *pmap, vaddr_t va)
1.14.2.2   thorpej {
1.14.2.2   thorpej     return (NULL);
1.14.2.2   thorpej }
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pmap_get_ptp: get a PTP (if there isn't one, allocate a new one)
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => pmap should NOT be pmap_kernel()
1.14.2.2   thorpej  * => pmap should be locked
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej static struct vm_page *
1.14.2.2   thorpej pmap_get_ptp(struct pmap *pmap, vaddr_t va, boolean_t just_try)
1.14.2.2   thorpej {
1.14.2.2   thorpej     struct vm_page *ptp;
1.14.2.2   thorpej
1.14.2.4   thorpej     if (pmap_pde_page(pmap_pde(pmap, va))) {
1.14.2.2   thorpej
1.14.2.2   thorpej 	/* valid... check hint (saves us a PA->PG lookup) */
1.14.2.2   thorpej #if 0
1.14.2.2   thorpej 	if (pmap->pm_ptphint &&
1.14.2.2   thorpej     		((unsigned)pmap_pde(pmap, va) & PG_FRAME) ==
1.14.2.2   thorpej 		VM_PAGE_TO_PHYS(pmap->pm_ptphint))
1.14.2.2   thorpej 	    return (pmap->pm_ptphint);
1.14.2.2   thorpej #endif
1.14.2.2   thorpej 	ptp = uvm_pagelookup(&pmap->pm_obj, va);
1.14.2.2   thorpej #ifdef DIAGNOSTIC
1.14.2.2   thorpej 	if (ptp == NULL)
1.14.2.2   thorpej     	    panic("pmap_get_ptp: unmanaged user PTP");
1.14.2.2   thorpej #endif
1.14.2.2   thorpej //	pmap->pm_ptphint = ptp;
1.14.2.2   thorpej 	return(ptp);
1.14.2.2   thorpej     }
1.14.2.2   thorpej
1.14.2.2   thorpej     /* allocate a new PTP (updates ptphint) */
1.14.2.2   thorpej     return(pmap_alloc_ptp(pmap, va, just_try));
1.14.2.2   thorpej }
1.14.2.2   thorpej
1.14.2.2   thorpej /*
1.14.2.2   thorpej  * pmap_alloc_ptp: allocate a PTP for a PMAP
1.14.2.2   thorpej  *
1.14.2.2   thorpej  * => pmap should already be locked by caller
1.14.2.2   thorpej  * => we use the ptp's wire_count to count the number of active mappings
1.14.2.2   thorpej  *	in the PTP (we start it at one to prevent any chance this PTP
1.14.2.2   thorpej  *	will ever leak onto the active/inactive queues)
1.14.2.2   thorpej  */
1.14.2.2   thorpej
1.14.2.2   thorpej /*__inline */ static struct vm_page *
1.14.2.2   thorpej pmap_alloc_ptp(struct pmap *pmap, vaddr_t va, boolean_t just_try)
1.14.2.2   thorpej {
1.14.2.2   thorpej 	struct vm_page *ptp;
1.14.2.2   thorpej
1.14.2.2   thorpej 	ptp = uvm_pagealloc(&pmap->pm_obj, va, NULL,
1.14.2.2   thorpej 		UVM_PGA_USERESERVE|UVM_PGA_ZERO);
1.14.2.2   thorpej 	if (ptp == NULL) {
1.14.2.2   thorpej 	    if (just_try)
1.14.2.2   thorpej 		return (NULL);
1.14.2.2   thorpej
1.14.2.2   thorpej 	    ptp = pmap_steal_ptp(pmap, va);
1.14.2.2   thorpej
1.14.2.2   thorpej 	    if (ptp == NULL)
1.14.2.2   thorpej 		return (NULL);
1.14.2.2   thorpej 	    /* Stole a page, zero it.  */
1.14.2.2   thorpej 	    pmap_zero_page(VM_PAGE_TO_PHYS(ptp));
1.14.2.2   thorpej 	}
1.14.2.2   thorpej
1.14.2.2   thorpej 	/* got one! */
1.14.2.2   thorpej 	ptp->flags &= ~PG_BUSY;	/* never busy */
1.14.2.2   thorpej 	ptp->wire_count = 1;	/* no mappings yet */
1.14.2.2   thorpej 	pmap_map_in_l1(pmap, va, VM_PAGE_TO_PHYS(ptp), TRUE);
1.14.2.2   thorpej 	pmap->pm_stats.resident_count++;	/* count PTP as resident */
1.14.2.2   thorpej //	pmap->pm_ptphint = ptp;
1.14.2.2   thorpej 	return (ptp);
     1.1      matt }
     1.1      matt
1.14.2.6  jdolecek vaddr_t
1.14.2.6  jdolecek pmap_growkernel(maxkvaddr)
1.14.2.6  jdolecek 	vaddr_t maxkvaddr;
1.14.2.6  jdolecek {
1.14.2.6  jdolecek 	struct pmap *kpm = pmap_kernel(), *pm;
1.14.2.6  jdolecek 	int s;
1.14.2.6  jdolecek 	paddr_t ptaddr;
1.14.2.6  jdolecek 	struct vm_page *ptp;
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	if (maxkvaddr <= pmap_curmaxkvaddr)
1.14.2.6  jdolecek 		goto out;		/* we are OK */
1.14.2.6  jdolecek 	NPDEBUG(PDB_GROWKERN, printf("pmap_growkernel: growing kernel from %lx to %lx\n",
1.14.2.6  jdolecek 		    pmap_curmaxkvaddr, maxkvaddr));
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	/*
1.14.2.6  jdolecek 	 * whoops!   we need to add kernel PTPs
1.14.2.6  jdolecek 	 */
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	s = splhigh();	/* to be safe */
1.14.2.6  jdolecek 	simple_lock(&kpm->pm_obj.vmobjlock);
1.14.2.6  jdolecek 	/* due to the way the arm pmap works we map 4MB at a time */
1.14.2.6  jdolecek 	for (/*null*/ ; pmap_curmaxkvaddr < maxkvaddr ; pmap_curmaxkvaddr += 4 * NBPD) {
1.14.2.6  jdolecek
1.14.2.6  jdolecek 		if (uvm.page_init_done == FALSE) {
1.14.2.6  jdolecek
1.14.2.6  jdolecek 			/*
1.14.2.6  jdolecek 			 * we're growing the kernel pmap early (from
1.14.2.6  jdolecek 			 * uvm_pageboot_alloc()).  this case must be
1.14.2.6  jdolecek 			 * handled a little differently.
1.14.2.6  jdolecek 			 */
1.14.2.6  jdolecek
1.14.2.6  jdolecek 			if (uvm_page_physget(&ptaddr) == FALSE)
1.14.2.6  jdolecek 				panic("pmap_growkernel: out of memory");
1.14.2.6  jdolecek 			pmap_zero_page(ptaddr);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 			/* map this page in */
1.14.2.6  jdolecek 			pmap_map_in_l1(kpm, (pmap_curmaxkvaddr + 1), ptaddr, TRUE);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 			/* count PTP as resident */
1.14.2.6  jdolecek 			kpm->pm_stats.resident_count++;
1.14.2.6  jdolecek 			continue;
1.14.2.6  jdolecek 		}
1.14.2.6  jdolecek
1.14.2.6  jdolecek 		/*
1.14.2.6  jdolecek 		 * THIS *MUST* BE CODED SO AS TO WORK IN THE
1.14.2.6  jdolecek 		 * pmap_initialized == FALSE CASE!  WE MAY BE
1.14.2.6  jdolecek 		 * INVOKED WHILE pmap_init() IS RUNNING!
1.14.2.6  jdolecek 		 */
1.14.2.6  jdolecek
1.14.2.6  jdolecek 		if ((ptp = pmap_alloc_ptp(kpm, (pmap_curmaxkvaddr + 1), FALSE)) == NULL) {
1.14.2.6  jdolecek 			panic("pmap_growkernel: alloc ptp failed");
1.14.2.6  jdolecek 		}
1.14.2.6  jdolecek
1.14.2.6  jdolecek 		/* distribute new kernel PTP to all active pmaps */
1.14.2.6  jdolecek 		simple_lock(&pmaps_lock);
1.14.2.6  jdolecek 		LIST_FOREACH(pm, &pmaps, pm_list) {
1.14.2.6  jdolecek 		    pmap_map_in_l1(pm, (pmap_curmaxkvaddr + 1), VM_PAGE_TO_PHYS(ptp), TRUE);
1.14.2.6  jdolecek 		}
1.14.2.6  jdolecek
1.14.2.6  jdolecek 		simple_unlock(&pmaps_lock);
1.14.2.6  jdolecek 	}
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	/*
1.14.2.6  jdolecek 	 * flush out the cache, expensive but growkernel will happen so
1.14.2.6  jdolecek 	 * rarely
1.14.2.6  jdolecek 	 */
1.14.2.6  jdolecek 	cpu_tlb_flushD();
1.14.2.6  jdolecek 	cpu_cpwait();
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	simple_unlock(&kpm->pm_obj.vmobjlock);
1.14.2.6  jdolecek 	splx(s);
1.14.2.6  jdolecek
1.14.2.6  jdolecek out:
1.14.2.6  jdolecek 	return (pmap_curmaxkvaddr);
1.14.2.6  jdolecek }
1.14.2.6  jdolecek
1.14.2.6  jdolecek
1.14.2.6  jdolecek
1.14.2.6  jdolecek /************************ Bootstrapping routines ****************************/
1.14.2.6  jdolecek
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * This list exists for the benefit of pmap_map_chunk().  It keeps track
1.14.2.6  jdolecek  * of the kernel L2 tables during bootstrap, so that pmap_map_chunk() can
1.14.2.6  jdolecek  * find them as necessary.
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  * Note that the data on this list is not valid after initarm() returns.
1.14.2.6  jdolecek  */
1.14.2.6  jdolecek SLIST_HEAD(, pv_addr) kernel_pt_list = SLIST_HEAD_INITIALIZER(kernel_pt_list);
1.14.2.6  jdolecek
1.14.2.6  jdolecek static vaddr_t
1.14.2.6  jdolecek kernel_pt_lookup(paddr_t pa)
1.14.2.6  jdolecek {
1.14.2.6  jdolecek 	pv_addr_t *pv;
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	SLIST_FOREACH(pv, &kernel_pt_list, pv_list) {
1.14.2.6  jdolecek 		if (pv->pv_pa == pa)
1.14.2.6  jdolecek 			return (pv->pv_va);
1.14.2.6  jdolecek 	}
1.14.2.6  jdolecek 	return (0);
1.14.2.6  jdolecek }
1.14.2.6  jdolecek
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * pmap_map_section:
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  *	Create a single section mapping.
1.14.2.6  jdolecek  */
1.14.2.6  jdolecek void
1.14.2.6  jdolecek pmap_map_section(vaddr_t l1pt, vaddr_t va, paddr_t pa, int prot, int cache)
1.14.2.6  jdolecek {
1.14.2.6  jdolecek 	pd_entry_t *pde = (pd_entry_t *) l1pt;
1.14.2.6  jdolecek 	pd_entry_t ap = (prot & VM_PROT_WRITE) ? AP_KRW : AP_KR;
1.14.2.6  jdolecek 	pd_entry_t fl = (cache == PTE_CACHE) ? pte_cache_mode : 0;
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	KASSERT(((va | pa) & (L1_SEC_SIZE - 1)) == 0);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	pde[va >> PDSHIFT] = L1_SECPTE(pa & PD_MASK, ap, fl);
1.14.2.6  jdolecek }
1.14.2.6  jdolecek
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * pmap_map_entry:
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  *	Create a single page mapping.
1.14.2.6  jdolecek  */
1.14.2.6  jdolecek void
1.14.2.6  jdolecek pmap_map_entry(vaddr_t l1pt, vaddr_t va, paddr_t pa, int prot, int cache)
1.14.2.6  jdolecek {
1.14.2.6  jdolecek 	pd_entry_t *pde = (pd_entry_t *) l1pt;
1.14.2.6  jdolecek 	pt_entry_t ap = (prot & VM_PROT_WRITE) ? AP_KRW : AP_KR;
1.14.2.6  jdolecek 	pt_entry_t fl = (cache == PTE_CACHE) ? pte_cache_mode : 0;
1.14.2.6  jdolecek 	pt_entry_t *pte;
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	KASSERT(((va | pa) & PGOFSET) == 0);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	if ((pde[va >> PDSHIFT] & L1_MASK) != L1_PAGE)
1.14.2.6  jdolecek 		panic("pmap_map_entry: no L2 table for VA 0x%08lx", va);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	pte = (pt_entry_t *)
1.14.2.6  jdolecek 	    kernel_pt_lookup(pde[va >> PDSHIFT] & PG_FRAME);
1.14.2.6  jdolecek 	if (pte == NULL)
1.14.2.6  jdolecek 		panic("pmap_map_entry: can't find L2 table for VA 0x%08lx", va);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	pte[(va >> PGSHIFT) & 0x3ff] = L2_SPTE(pa & PG_FRAME, ap, fl);
1.14.2.6  jdolecek }
1.14.2.6  jdolecek
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * pmap_link_l2pt:
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  *	Link the L2 page table specified by "pa" into the L1
1.14.2.6  jdolecek  *	page table at the slot for "va".
1.14.2.6  jdolecek  */
1.14.2.6  jdolecek void
1.14.2.6  jdolecek pmap_link_l2pt(vaddr_t l1pt, vaddr_t va, pv_addr_t *l2pv)
1.14.2.6  jdolecek {
1.14.2.6  jdolecek 	pd_entry_t *pde = (pd_entry_t *) l1pt;
1.14.2.6  jdolecek 	u_int slot = va >> PDSHIFT;
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	KASSERT((l2pv->pv_pa & PGOFSET) == 0);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	pde[slot + 0] = L1_PTE(l2pv->pv_pa + 0x000);
1.14.2.6  jdolecek 	pde[slot + 1] = L1_PTE(l2pv->pv_pa + 0x400);
1.14.2.6  jdolecek 	pde[slot + 2] = L1_PTE(l2pv->pv_pa + 0x800);
1.14.2.6  jdolecek 	pde[slot + 3] = L1_PTE(l2pv->pv_pa + 0xc00);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	SLIST_INSERT_HEAD(&kernel_pt_list, l2pv, pv_list);
1.14.2.6  jdolecek }
1.14.2.6  jdolecek
1.14.2.6  jdolecek /*
1.14.2.6  jdolecek  * pmap_map_chunk:
1.14.2.6  jdolecek  *
1.14.2.6  jdolecek  *	Map a chunk of memory using the most efficient mappings
1.14.2.6  jdolecek  *	possible (section, large page, small page) into the
1.14.2.6  jdolecek  *	provided L1 and L2 tables at the specified virtual address.
1.14.2.6  jdolecek  */
1.14.2.6  jdolecek vsize_t
1.14.2.6  jdolecek pmap_map_chunk(vaddr_t l1pt, vaddr_t va, paddr_t pa, vsize_t size,
1.14.2.6  jdolecek     int prot, int cache)
1.14.2.6  jdolecek {
1.14.2.6  jdolecek 	pd_entry_t *pde = (pd_entry_t *) l1pt;
1.14.2.6  jdolecek 	pt_entry_t ap = (prot & VM_PROT_WRITE) ? AP_KRW : AP_KR;
1.14.2.6  jdolecek 	pt_entry_t fl = (cache == PTE_CACHE) ? pte_cache_mode : 0;
1.14.2.6  jdolecek 	pt_entry_t *pte;
1.14.2.6  jdolecek 	vsize_t resid;
1.14.2.6  jdolecek 	int i;
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	resid = (size + (NBPG - 1)) & ~(NBPG - 1);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	if (l1pt == 0)
1.14.2.6  jdolecek 		panic("pmap_map_chunk: no L1 table provided");
1.14.2.6  jdolecek
1.14.2.6  jdolecek #ifdef VERBOSE_INIT_ARM
1.14.2.6  jdolecek 	printf("pmap_map_chunk: pa=0x%lx va=0x%lx size=0x%lx resid=0x%lx "
1.14.2.6  jdolecek 	    "prot=0x%x cache=%d\n", pa, va, size, resid, prot, cache);
1.14.2.6  jdolecek #endif
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	size = resid;
1.14.2.6  jdolecek
1.14.2.6  jdolecek 	while (resid > 0) {
1.14.2.6  jdolecek 		/* See if we can use a section mapping. */
1.14.2.6  jdolecek 		if (((pa | va) & (L1_SEC_SIZE - 1)) == 0 &&
1.14.2.6  jdolecek 		    resid >= L1_SEC_SIZE) {
1.14.2.6  jdolecek #ifdef VERBOSE_INIT_ARM
1.14.2.6  jdolecek 			printf("S");
1.14.2.6  jdolecek #endif
1.14.2.6  jdolecek 			pde[va >> PDSHIFT] = L1_SECPTE(pa, ap, fl);
1.14.2.6  jdolecek 			va += L1_SEC_SIZE;
1.14.2.6  jdolecek 			pa += L1_SEC_SIZE;
1.14.2.6  jdolecek 			resid -= L1_SEC_SIZE;
1.14.2.6  jdolecek 			continue;
1.14.2.6  jdolecek 		}
1.14.2.6  jdolecek
1.14.2.6  jdolecek 		/*
1.14.2.6  jdolecek 		 * Ok, we're going to use an L2 table.  Make sure
1.14.2.6  jdolecek 		 * one is actually in the corresponding L1 slot
1.14.2.6  jdolecek 		 * for the current VA.
1.14.2.6  jdolecek 		 */
1.14.2.6  jdolecek 		if ((pde[va >> PDSHIFT] & L1_MASK) != L1_PAGE)
1.14.2.6  jdolecek 			panic("pmap_map_chunk: no L2 table for VA 0x%08lx", va);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 		pte = (pt_entry_t *)
1.14.2.6  jdolecek 		    kernel_pt_lookup(pde[va >> PDSHIFT] & PG_FRAME);
1.14.2.6  jdolecek 		if (pte == NULL)
1.14.2.6  jdolecek 			panic("pmap_map_chunk: can't find L2 table for VA"
1.14.2.6  jdolecek 			    "0x%08lx", va);
1.14.2.6  jdolecek
1.14.2.6  jdolecek 		/* See if we can use a L2 large page mapping. */
1.14.2.6  jdolecek 		if (((pa | va) & (L2_LPAGE_SIZE - 1)) == 0 &&
1.14.2.6  jdolecek 		    resid >= L2_LPAGE_SIZE) {
1.14.2.6  jdolecek #ifdef VERBOSE_INIT_ARM
1.14.2.6  jdolecek 			printf("L");
1.14.2.6  jdolecek #endif
1.14.2.6  jdolecek 			for (i = 0; i < 16; i++) {
1.14.2.6  jdolecek 				pte[((va >> PGSHIFT) & 0x3f0) + i] =
1.14.2.6  jdolecek 				    L2_LPTE(pa, ap, fl);
1.14.2.6  jdolecek 			}
1.14.2.6  jdolecek 			va += L2_LPAGE_SIZE;
1.14.2.6  jdolecek 			pa += L2_LPAGE_SIZE;
1.14.2.6  jdolecek 			resid -= L2_LPAGE_SIZE;
1.14.2.6  jdolecek 			continue;
1.14.2.6  jdolecek 		}
1.14.2.6  jdolecek
1.14.2.6  jdolecek 		/* Use a small page mapping. */
1.14.2.6  jdolecek #ifdef VERBOSE_INIT_ARM
1.14.2.6  jdolecek 		printf("P");
1.14.2.6  jdolecek #endif
1.14.2.6  jdolecek 		pte[(va >> PGSHIFT) & 0x3ff] = L2_SPTE(pa, ap, fl);
1.14.2.6  jdolecek 		va += NBPG;
1.14.2.6  jdolecek 		pa += NBPG;
1.14.2.6  jdolecek 		resid -= NBPG;
1.14.2.6  jdolecek 	}
1.14.2.6  jdolecek #ifdef VERBOSE_INIT_ARM
1.14.2.6  jdolecek 	printf("\n");
1.14.2.6  jdolecek #endif
1.14.2.6  jdolecek 	return (size);
1.14.2.6  jdolecek }