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pmap.c revision 1.1.2.6 
      1  1.1.2.6  jdolecek /*	$NetBSD: pmap.c,v 1.1.2.6 2002/09/06 08:39:04 jdolecek Exp $	*/
      2      1.1    simonb 
      3      1.1    simonb /*
      4      1.1    simonb  * Copyright 2001 Wasabi Systems, Inc.
      5      1.1    simonb  * All rights reserved.
      6      1.1    simonb  *
      7      1.1    simonb  * Written by Eduardo Horvath and Simon Burge for Wasabi Systems, Inc.
      8      1.1    simonb  *
      9      1.1    simonb  * Redistribution and use in source and binary forms, with or without
     10      1.1    simonb  * modification, are permitted provided that the following conditions
     11      1.1    simonb  * are met:
     12      1.1    simonb  * 1. Redistributions of source code must retain the above copyright
     13      1.1    simonb  *    notice, this list of conditions and the following disclaimer.
     14      1.1    simonb  * 2. Redistributions in binary form must reproduce the above copyright
     15      1.1    simonb  *    notice, this list of conditions and the following disclaimer in the
     16      1.1    simonb  *    documentation and/or other materials provided with the distribution.
     17      1.1    simonb  * 3. All advertising materials mentioning features or use of this software
     18      1.1    simonb  *    must display the following acknowledgement:
     19      1.1    simonb  *      This product includes software developed for the NetBSD Project by
     20      1.1    simonb  *      Wasabi Systems, Inc.
     21      1.1    simonb  * 4. The name of Wasabi Systems, Inc. may not be used to endorse
     22      1.1    simonb  *    or promote products derived from this software without specific prior
     23      1.1    simonb  *    written permission.
     24      1.1    simonb  *
     25      1.1    simonb  * THIS SOFTWARE IS PROVIDED BY WASABI SYSTEMS, INC. ``AS IS'' AND
     26      1.1    simonb  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
     27      1.1    simonb  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
     28      1.1    simonb  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL WASABI SYSTEMS, INC
     29      1.1    simonb  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
     30      1.1    simonb  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
     31      1.1    simonb  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
     32      1.1    simonb  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
     33      1.1    simonb  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
     34      1.1    simonb  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
     35      1.1    simonb  * POSSIBILITY OF SUCH DAMAGE.
     36      1.1    simonb  */
     37      1.1    simonb 
     38      1.1    simonb /*
     39      1.1    simonb  * Copyright (C) 1995, 1996 Wolfgang Solfrank.
     40      1.1    simonb  * Copyright (C) 1995, 1996 TooLs GmbH.
     41      1.1    simonb  * All rights reserved.
     42      1.1    simonb  *
     43      1.1    simonb  * Redistribution and use in source and binary forms, with or without
     44      1.1    simonb  * modification, are permitted provided that the following conditions
     45      1.1    simonb  * are met:
     46      1.1    simonb  * 1. Redistributions of source code must retain the above copyright
     47      1.1    simonb  *    notice, this list of conditions and the following disclaimer.
     48      1.1    simonb  * 2. Redistributions in binary form must reproduce the above copyright
     49      1.1    simonb  *    notice, this list of conditions and the following disclaimer in the
     50      1.1    simonb  *    documentation and/or other materials provided with the distribution.
     51      1.1    simonb  * 3. All advertising materials mentioning features or use of this software
     52      1.1    simonb  *    must display the following acknowledgement:
     53      1.1    simonb  *	This product includes software developed by TooLs GmbH.
     54      1.1    simonb  * 4. The name of TooLs GmbH may not be used to endorse or promote products
     55      1.1    simonb  *    derived from this software without specific prior written permission.
     56      1.1    simonb  *
     57      1.1    simonb  * THIS SOFTWARE IS PROVIDED BY TOOLS GMBH ``AS IS'' AND ANY EXPRESS OR
     58      1.1    simonb  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
     59      1.1    simonb  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
     60      1.1    simonb  * IN NO EVENT SHALL TOOLS GMBH BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
     61      1.1    simonb  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
     62      1.1    simonb  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
     63      1.1    simonb  * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
     64      1.1    simonb  * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
     65      1.1    simonb  * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
     66      1.1    simonb  * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
     67      1.1    simonb  */
     68      1.1    simonb 
     69  1.1.2.3   thorpej #undef PPC_4XX_NOCACHE
     70      1.1    simonb 
     71      1.1    simonb #include <sys/param.h>
     72      1.1    simonb #include <sys/malloc.h>
     73      1.1    simonb #include <sys/proc.h>
     74      1.1    simonb #include <sys/user.h>
     75      1.1    simonb #include <sys/queue.h>
     76      1.1    simonb #include <sys/systm.h>
     77      1.1    simonb #include <sys/pool.h>
     78      1.1    simonb #include <sys/device.h>
     79      1.1    simonb 
     80      1.1    simonb #include <uvm/uvm.h>
     81      1.1    simonb 
     82  1.1.2.4  jdolecek #include <machine/cpu.h>
     83      1.1    simonb #include <machine/pcb.h>
     84      1.1    simonb #include <machine/powerpc.h>
     85      1.1    simonb 
     86      1.1    simonb #include <powerpc/spr.h>
     87  1.1.2.4  jdolecek #include <machine/tlb.h>
     88      1.1    simonb 
     89      1.1    simonb /*
     90      1.1    simonb  * kernmap is an array of PTEs large enough to map in
     91      1.1    simonb  * 4GB.  At 16KB/page it is 256K entries or 2MB.
     92      1.1    simonb  */
     93      1.1    simonb #define KERNMAP_SIZE	((0xffffffffU/NBPG)+1)
     94      1.1    simonb caddr_t kernmap;
     95      1.1    simonb 
     96      1.1    simonb #define MINCTX		2
     97      1.1    simonb #define NUMCTX		256
     98      1.1    simonb volatile struct pmap *ctxbusy[NUMCTX];
     99      1.1    simonb 
    100      1.1    simonb #define TLBF_USED	0x1
    101      1.1    simonb #define	TLBF_REF	0x2
    102      1.1    simonb #define	TLBF_LOCKED	0x4
    103      1.1    simonb #define	TLB_LOCKED(i)	(tlb_info[(i)].ti_flags & TLBF_LOCKED)
    104      1.1    simonb typedef struct tlb_info_s {
    105      1.1    simonb 	char	ti_flags;
    106      1.1    simonb 	char	ti_ctx;		/* TLB_PID assiciated with the entry */
    107      1.1    simonb 	u_int	ti_va;
    108      1.1    simonb } tlb_info_t;
    109      1.1    simonb 
    110      1.1    simonb volatile tlb_info_t tlb_info[NTLB];
    111      1.1    simonb /* We'll use a modified FIFO replacement policy cause it's cheap */
    112      1.1    simonb volatile int tlbnext = TLB_NRESERVED;
    113      1.1    simonb 
    114      1.1    simonb u_long dtlb_miss_count = 0;
    115      1.1    simonb u_long itlb_miss_count = 0;
    116      1.1    simonb u_long ktlb_miss_count = 0;
    117      1.1    simonb u_long utlb_miss_count = 0;
    118      1.1    simonb 
    119      1.1    simonb /* Event counters -- XXX type `INTR' so we can see them with vmstat -i */
    120      1.1    simonb struct evcnt tlbmiss_ev = EVCNT_INITIALIZER(EVCNT_TYPE_INTR,
    121      1.1    simonb 	NULL, "cpu", "tlbmiss");
    122      1.1    simonb struct evcnt tlbhit_ev = EVCNT_INITIALIZER(EVCNT_TYPE_INTR,
    123      1.1    simonb 	NULL, "cpu", "tlbhit");
    124      1.1    simonb struct evcnt tlbflush_ev = EVCNT_INITIALIZER(EVCNT_TYPE_INTR,
    125      1.1    simonb 	NULL, "cpu", "tlbflush");
    126      1.1    simonb struct evcnt tlbenter_ev = EVCNT_INITIALIZER(EVCNT_TYPE_INTR,
    127      1.1    simonb 	NULL, "cpu", "tlbenter");
    128      1.1    simonb 
    129      1.1    simonb struct pmap kernel_pmap_;
    130      1.1    simonb 
    131      1.1    simonb int physmem;
    132      1.1    simonb static int npgs;
    133      1.1    simonb static u_int nextavail;
    134      1.1    simonb #ifndef MSGBUFADDR
    135      1.1    simonb extern paddr_t msgbuf_paddr;
    136      1.1    simonb #endif
    137      1.1    simonb 
    138      1.1    simonb static struct mem_region *mem, *avail;
    139      1.1    simonb 
    140      1.1    simonb /*
    141      1.1    simonb  * This is a cache of referenced/modified bits.
    142      1.1    simonb  * Bits herein are shifted by ATTRSHFT.
    143      1.1    simonb  */
    144      1.1    simonb static char *pmap_attrib;
    145      1.1    simonb 
    146      1.1    simonb #define PV_WIRED	0x1
    147      1.1    simonb #define PV_WIRE(pv)	((pv)->pv_va |= PV_WIRED)
    148      1.1    simonb #define	PV_CMPVA(va,pv)	(!(((pv)->pv_va^(va))&(~PV_WIRED)))
    149      1.1    simonb 
    150      1.1    simonb struct pv_entry {
    151      1.1    simonb 	struct pv_entry *pv_next;	/* Linked list of mappings */
    152      1.1    simonb 	vaddr_t pv_va;			/* virtual address of mapping */
    153      1.1    simonb 	struct pmap *pv_pm;
    154      1.1    simonb };
    155      1.1    simonb 
    156      1.1    simonb struct pv_entry *pv_table;
    157      1.1    simonb static struct pool pv_pool;
    158      1.1    simonb 
    159      1.1    simonb static int pmap_initialized;
    160      1.1    simonb 
    161      1.1    simonb static int ctx_flush(int);
    162      1.1    simonb 
    163      1.1    simonb inline struct pv_entry *pa_to_pv(paddr_t);
    164      1.1    simonb static inline char *pa_to_attr(paddr_t);
    165      1.1    simonb 
    166      1.1    simonb static inline volatile u_int *pte_find(struct pmap *, vaddr_t);
    167      1.1    simonb static inline int pte_enter(struct pmap *, vaddr_t, u_int);
    168      1.1    simonb 
    169      1.1    simonb static void pmap_pinit(pmap_t);
    170      1.1    simonb static void pmap_release(pmap_t);
    171      1.1    simonb static inline int pmap_enter_pv(struct pmap *, vaddr_t, paddr_t);
    172      1.1    simonb static void pmap_remove_pv(struct pmap *, vaddr_t, paddr_t);
    173      1.1    simonb 
    174      1.1    simonb 
    175      1.1    simonb inline struct pv_entry *
    176      1.1    simonb pa_to_pv(paddr_t pa)
    177      1.1    simonb {
    178      1.1    simonb 	int bank, pg;
    179      1.1    simonb 
    180      1.1    simonb 	bank = vm_physseg_find(atop(pa), &pg);
    181      1.1    simonb 	if (bank == -1)
    182      1.1    simonb 		return NULL;
    183      1.1    simonb 	return &vm_physmem[bank].pmseg.pvent[pg];
    184      1.1    simonb }
    185      1.1    simonb 
    186      1.1    simonb static inline char *
    187      1.1    simonb pa_to_attr(paddr_t pa)
    188      1.1    simonb {
    189      1.1    simonb 	int bank, pg;
    190      1.1    simonb 
    191      1.1    simonb 	bank = vm_physseg_find(atop(pa), &pg);
    192      1.1    simonb 	if (bank == -1)
    193      1.1    simonb 		return NULL;
    194      1.1    simonb 	return &vm_physmem[bank].pmseg.attrs[pg];
    195      1.1    simonb }
    196      1.1    simonb 
    197      1.1    simonb /*
    198      1.1    simonb  * Insert PTE into page table.
    199      1.1    simonb  */
    200      1.1    simonb int
    201      1.1    simonb pte_enter(struct pmap *pm, vaddr_t va, u_int pte)
    202      1.1    simonb {
    203      1.1    simonb 	int seg = STIDX(va);
    204      1.1    simonb 	int ptn = PTIDX(va);
    205      1.1    simonb 	paddr_t pa;
    206      1.1    simonb 
    207      1.1    simonb 	if (!pm->pm_ptbl[seg]) {
    208      1.1    simonb 		/* Don't allocate a page to clear a non-existent mapping. */
    209      1.1    simonb 		if (!pte) return (1);
    210      1.1    simonb 		/* Allocate a page XXXX this will sleep! */
    211      1.1    simonb 		pa = 0;
    212      1.1    simonb 		pm->pm_ptbl[seg] = (uint *)uvm_km_alloc1(kernel_map, NBPG, 1);
    213      1.1    simonb 	}
    214      1.1    simonb 	pm->pm_ptbl[seg][ptn] = pte;
    215      1.1    simonb 
    216      1.1    simonb 	/* Flush entry. */
    217      1.1    simonb 	ppc4xx_tlb_flush(va, pm->pm_ctx);
    218      1.1    simonb 	return (1);
    219      1.1    simonb }
    220      1.1    simonb 
    221      1.1    simonb /*
    222      1.1    simonb  * Get a pointer to a PTE in a page table.
    223      1.1    simonb  */
    224      1.1    simonb volatile u_int *
    225      1.1    simonb pte_find(struct pmap *pm, vaddr_t va)
    226      1.1    simonb {
    227      1.1    simonb 	int seg = STIDX(va);
    228      1.1    simonb 	int ptn = PTIDX(va);
    229      1.1    simonb 
    230      1.1    simonb 	if (pm->pm_ptbl[seg])
    231      1.1    simonb 		return (&pm->pm_ptbl[seg][ptn]);
    232      1.1    simonb 
    233      1.1    simonb 	return (NULL);
    234      1.1    simonb }
    235      1.1    simonb 
    236      1.1    simonb /*
    237      1.1    simonb  * This is called during initppc, before the system is really initialized.
    238      1.1    simonb  */
    239      1.1    simonb void
    240      1.1    simonb pmap_bootstrap(u_int kernelstart, u_int kernelend)
    241      1.1    simonb {
    242      1.1    simonb 	struct mem_region *mp, *mp1;
    243      1.1    simonb 	int cnt, i;
    244      1.1    simonb 	u_int s, e, sz;
    245      1.1    simonb 
    246      1.1    simonb 	/*
    247      1.1    simonb 	 * Allocate the kernel page table at the end of
    248      1.1    simonb 	 * kernel space so it's in the locked TTE.
    249      1.1    simonb 	 */
    250      1.1    simonb 	kernmap = (caddr_t)kernelend;
    251      1.1    simonb 
    252      1.1    simonb 	/*
    253      1.1    simonb 	 * Initialize kernel page table.
    254      1.1    simonb 	 */
    255      1.1    simonb 	for (i = 0; i < STSZ; i++) {
    256  1.1.2.4  jdolecek 		pmap_kernel()->pm_ptbl[i] = 0;
    257      1.1    simonb 	}
    258      1.1    simonb 	ctxbusy[0] = ctxbusy[1] = pmap_kernel();
    259      1.1    simonb 
    260      1.1    simonb 	/*
    261      1.1    simonb 	 * Announce page-size to the VM-system
    262      1.1    simonb 	 */
    263      1.1    simonb 	uvmexp.pagesize = NBPG;
    264      1.1    simonb 	uvm_setpagesize();
    265      1.1    simonb 
    266      1.1    simonb 	/*
    267      1.1    simonb 	 * Get memory.
    268      1.1    simonb 	 */
    269      1.1    simonb 	mem_regions(&mem, &avail);
    270      1.1    simonb 	for (mp = mem; mp->size; mp++) {
    271      1.1    simonb 		physmem += btoc(mp->size);
    272      1.1    simonb 		printf("+%lx,",mp->size);
    273      1.1    simonb 	}
    274      1.1    simonb 	printf("\n");
    275      1.1    simonb 	ppc4xx_tlb_init();
    276      1.1    simonb 	/*
    277      1.1    simonb 	 * Count the number of available entries.
    278      1.1    simonb 	 */
    279      1.1    simonb 	for (cnt = 0, mp = avail; mp->size; mp++)
    280      1.1    simonb 		cnt++;
    281      1.1    simonb 
    282      1.1    simonb 	/*
    283      1.1    simonb 	 * Page align all regions.
    284      1.1    simonb 	 * Non-page aligned memory isn't very interesting to us.
    285      1.1    simonb 	 * Also, sort the entries for ascending addresses.
    286      1.1    simonb 	 */
    287      1.1    simonb 	kernelstart &= ~PGOFSET;
    288      1.1    simonb 	kernelend = (kernelend + PGOFSET) & ~PGOFSET;
    289      1.1    simonb 	for (mp = avail; mp->size; mp++) {
    290      1.1    simonb 		s = mp->start;
    291      1.1    simonb 		e = mp->start + mp->size;
    292      1.1    simonb 		printf("%08x-%08x -> ",s,e);
    293      1.1    simonb 		/*
    294      1.1    simonb 		 * Check whether this region holds all of the kernel.
    295      1.1    simonb 		 */
    296      1.1    simonb 		if (s < kernelstart && e > kernelend) {
    297      1.1    simonb 			avail[cnt].start = kernelend;
    298      1.1    simonb 			avail[cnt++].size = e - kernelend;
    299      1.1    simonb 			e = kernelstart;
    300      1.1    simonb 		}
    301      1.1    simonb 		/*
    302      1.1    simonb 		 * Look whether this regions starts within the kernel.
    303      1.1    simonb 		 */
    304      1.1    simonb 		if (s >= kernelstart && s < kernelend) {
    305      1.1    simonb 			if (e <= kernelend)
    306      1.1    simonb 				goto empty;
    307      1.1    simonb 			s = kernelend;
    308      1.1    simonb 		}
    309      1.1    simonb 		/*
    310      1.1    simonb 		 * Now look whether this region ends within the kernel.
    311      1.1    simonb 		 */
    312      1.1    simonb 		if (e > kernelstart && e <= kernelend) {
    313      1.1    simonb 			if (s >= kernelstart)
    314      1.1    simonb 				goto empty;
    315      1.1    simonb 			e = kernelstart;
    316      1.1    simonb 		}
    317      1.1    simonb 		/*
    318      1.1    simonb 		 * Now page align the start and size of the region.
    319      1.1    simonb 		 */
    320      1.1    simonb 		s = round_page(s);
    321      1.1    simonb 		e = trunc_page(e);
    322      1.1    simonb 		if (e < s)
    323      1.1    simonb 			e = s;
    324      1.1    simonb 		sz = e - s;
    325      1.1    simonb 		printf("%08x-%08x = %x\n",s,e,sz);
    326      1.1    simonb 		/*
    327      1.1    simonb 		 * Check whether some memory is left here.
    328      1.1    simonb 		 */
    329      1.1    simonb 		if (sz == 0) {
    330      1.1    simonb 		empty:
    331  1.1.2.1     lukem 			memmove(mp, mp + 1,
    332  1.1.2.1     lukem 				(cnt - (mp - avail)) * sizeof *mp);
    333      1.1    simonb 			cnt--;
    334      1.1    simonb 			mp--;
    335      1.1    simonb 			continue;
    336      1.1    simonb 		}
    337      1.1    simonb 		/*
    338      1.1    simonb 		 * Do an insertion sort.
    339      1.1    simonb 		 */
    340      1.1    simonb 		npgs += btoc(sz);
    341      1.1    simonb 		for (mp1 = avail; mp1 < mp; mp1++)
    342      1.1    simonb 			if (s < mp1->start)
    343      1.1    simonb 				break;
    344      1.1    simonb 		if (mp1 < mp) {
    345  1.1.2.1     lukem 			memmove(mp1 + 1, mp1, (char *)mp - (char *)mp1);
    346      1.1    simonb 			mp1->start = s;
    347      1.1    simonb 			mp1->size = sz;
    348      1.1    simonb 		} else {
    349      1.1    simonb 			mp->start = s;
    350      1.1    simonb 			mp->size = sz;
    351      1.1    simonb 		}
    352      1.1    simonb 	}
    353      1.1    simonb 
    354      1.1    simonb 	/*
    355      1.1    simonb 	 * We cannot do pmap_steal_memory here,
    356      1.1    simonb 	 * since we don't run with translation enabled yet.
    357      1.1    simonb 	 */
    358      1.1    simonb #ifndef MSGBUFADDR
    359      1.1    simonb 	/*
    360      1.1    simonb 	 * allow for msgbuf
    361      1.1    simonb 	 */
    362      1.1    simonb 	sz = round_page(MSGBUFSIZE);
    363      1.1    simonb 	mp = NULL;
    364      1.1    simonb 	for (mp1 = avail; mp1->size; mp1++)
    365      1.1    simonb 		if (mp1->size >= sz)
    366      1.1    simonb 			mp = mp1;
    367      1.1    simonb 	if (mp == NULL)
    368      1.1    simonb 		panic("not enough memory?");
    369      1.1    simonb 
    370      1.1    simonb 	npgs -= btoc(sz);
    371      1.1    simonb 	msgbuf_paddr = mp->start + mp->size - sz;
    372      1.1    simonb 	mp->size -= sz;
    373      1.1    simonb 	if (mp->size <= 0)
    374  1.1.2.1     lukem 		memmove(mp, mp + 1, (cnt - (mp - avail)) * sizeof *mp);
    375      1.1    simonb #endif
    376      1.1    simonb 
    377      1.1    simonb 	printf("Loading pages\n");
    378      1.1    simonb 	for (mp = avail; mp->size; mp++)
    379      1.1    simonb 		uvm_page_physload(atop(mp->start), atop(mp->start + mp->size),
    380      1.1    simonb 			atop(mp->start), atop(mp->start + mp->size),
    381      1.1    simonb 			VM_FREELIST_DEFAULT);
    382      1.1    simonb 
    383      1.1    simonb 	/*
    384      1.1    simonb 	 * Initialize kernel pmap and hardware.
    385      1.1    simonb 	 */
    386      1.1    simonb 	/* Setup TLB pid allocator so it knows we alreadu using PID 1 */
    387      1.1    simonb 	pmap_kernel()->pm_ctx = KERNEL_PID;
    388      1.1    simonb 	nextavail = avail->start;
    389      1.1    simonb 
    390      1.1    simonb 
    391      1.1    simonb 	evcnt_attach_static(&tlbhit_ev);
    392      1.1    simonb 	evcnt_attach_static(&tlbmiss_ev);
    393      1.1    simonb 	evcnt_attach_static(&tlbflush_ev);
    394      1.1    simonb 	evcnt_attach_static(&tlbenter_ev);
    395      1.1    simonb 	printf("Done\n");
    396      1.1    simonb }
    397      1.1    simonb 
    398      1.1    simonb /*
    399      1.1    simonb  * Restrict given range to physical memory
    400      1.1    simonb  *
    401      1.1    simonb  * (Used by /dev/mem)
    402      1.1    simonb  */
    403      1.1    simonb void
    404      1.1    simonb pmap_real_memory(paddr_t *start, psize_t *size)
    405      1.1    simonb {
    406      1.1    simonb 	struct mem_region *mp;
    407      1.1    simonb 
    408      1.1    simonb 	for (mp = mem; mp->size; mp++) {
    409      1.1    simonb 		if (*start + *size > mp->start &&
    410      1.1    simonb 		    *start < mp->start + mp->size) {
    411      1.1    simonb 			if (*start < mp->start) {
    412      1.1    simonb 				*size -= mp->start - *start;
    413      1.1    simonb 				*start = mp->start;
    414      1.1    simonb 			}
    415      1.1    simonb 			if (*start + *size > mp->start + mp->size)
    416      1.1    simonb 				*size = mp->start + mp->size - *start;
    417      1.1    simonb 			return;
    418      1.1    simonb 		}
    419      1.1    simonb 	}
    420      1.1    simonb 	*size = 0;
    421      1.1    simonb }
    422      1.1    simonb 
    423      1.1    simonb /*
    424      1.1    simonb  * Initialize anything else for pmap handling.
    425      1.1    simonb  * Called during vm_init().
    426      1.1    simonb  */
    427      1.1    simonb void
    428      1.1    simonb pmap_init(void)
    429      1.1    simonb {
    430      1.1    simonb 	struct pv_entry *pv;
    431      1.1    simonb 	vsize_t sz;
    432      1.1    simonb 	vaddr_t addr;
    433      1.1    simonb 	int i, s;
    434      1.1    simonb 	int bank;
    435      1.1    simonb 	char *attr;
    436      1.1    simonb 
    437      1.1    simonb 	sz = (vsize_t)((sizeof(struct pv_entry) + 1) * npgs);
    438      1.1    simonb 	sz = round_page(sz);
    439      1.1    simonb 	addr = uvm_km_zalloc(kernel_map, sz);
    440      1.1    simonb 	s = splvm();
    441      1.1    simonb 	pv = pv_table = (struct pv_entry *)addr;
    442      1.1    simonb 	for (i = npgs; --i >= 0;)
    443      1.1    simonb 		pv++->pv_pm = NULL;
    444      1.1    simonb 	pmap_attrib = (char *)pv;
    445  1.1.2.1     lukem 	memset(pv, 0, npgs);
    446      1.1    simonb 
    447      1.1    simonb 	pv = pv_table;
    448      1.1    simonb 	attr = pmap_attrib;
    449      1.1    simonb 	for (bank = 0; bank < vm_nphysseg; bank++) {
    450      1.1    simonb 		sz = vm_physmem[bank].end - vm_physmem[bank].start;
    451      1.1    simonb 		vm_physmem[bank].pmseg.pvent = pv;
    452      1.1    simonb 		vm_physmem[bank].pmseg.attrs = attr;
    453      1.1    simonb 		pv += sz;
    454      1.1    simonb 		attr += sz;
    455      1.1    simonb 	}
    456      1.1    simonb 
    457      1.1    simonb 	pmap_initialized = 1;
    458      1.1    simonb 	splx(s);
    459      1.1    simonb 
    460      1.1    simonb 	/* Setup a pool for additional pvlist structures */
    461  1.1.2.4  jdolecek 	pool_init(&pv_pool, sizeof(struct pv_entry), 0, 0, 0, "pv_entry", NULL);
    462      1.1    simonb }
    463      1.1    simonb 
    464      1.1    simonb /*
    465      1.1    simonb  * How much virtual space is available to the kernel?
    466      1.1    simonb  */
    467      1.1    simonb void
    468      1.1    simonb pmap_virtual_space(vaddr_t *start, vaddr_t *end)
    469      1.1    simonb {
    470      1.1    simonb 
    471      1.1    simonb #if 0
    472      1.1    simonb 	/*
    473      1.1    simonb 	 * Reserve one segment for kernel virtual memory
    474      1.1    simonb 	 */
    475      1.1    simonb 	*start = (vaddr_t)(KERNEL_SR << ADDR_SR_SHFT);
    476      1.1    simonb 	*end = *start + SEGMENT_LENGTH;
    477      1.1    simonb #else
    478      1.1    simonb 	*start = (vaddr_t) VM_MIN_KERNEL_ADDRESS;
    479      1.1    simonb 	*end = (vaddr_t) VM_MAX_KERNEL_ADDRESS;
    480      1.1    simonb #endif
    481      1.1    simonb }
    482      1.1    simonb 
    483  1.1.2.2   thorpej #ifdef PMAP_GROWKERNEL
    484  1.1.2.2   thorpej /*
    485  1.1.2.2   thorpej  * Preallocate kernel page tables to a specified VA.
    486  1.1.2.2   thorpej  * This simply loops through the first TTE for each
    487  1.1.2.6  jdolecek  * page table from the beginning of the kernel pmap,
    488  1.1.2.2   thorpej  * reads the entry, and if the result is
    489  1.1.2.2   thorpej  * zero (either invalid entry or no page table) it stores
    490  1.1.2.2   thorpej  * a zero there, populating page tables in the process.
    491  1.1.2.2   thorpej  * This is not the most efficient technique but i don't
    492  1.1.2.2   thorpej  * expect it to be called that often.
    493  1.1.2.2   thorpej  */
    494  1.1.2.2   thorpej extern struct vm_page *vm_page_alloc1 __P((void));
    495  1.1.2.2   thorpej extern void vm_page_free1 __P((struct vm_page *));
    496  1.1.2.2   thorpej 
    497  1.1.2.2   thorpej vaddr_t kbreak = VM_MIN_KERNEL_ADDRESS;
    498  1.1.2.2   thorpej 
    499  1.1.2.6  jdolecek vaddr_t
    500  1.1.2.2   thorpej pmap_growkernel(maxkvaddr)
    501  1.1.2.6  jdolecek 	vaddr_t maxkvaddr;
    502  1.1.2.2   thorpej {
    503  1.1.2.2   thorpej 	int s;
    504  1.1.2.2   thorpej 	int seg;
    505  1.1.2.2   thorpej 	paddr_t pg;
    506  1.1.2.2   thorpej 	struct pmap *pm = pmap_kernel();
    507  1.1.2.6  jdolecek 
    508  1.1.2.2   thorpej 	s = splvm();
    509  1.1.2.2   thorpej 
    510  1.1.2.2   thorpej 	/* Align with the start of a page table */
    511  1.1.2.2   thorpej 	for (kbreak &= ~(PTMAP-1); kbreak < maxkvaddr;
    512  1.1.2.2   thorpej 	     kbreak += PTMAP) {
    513  1.1.2.2   thorpej 		seg = STIDX(kbreak);
    514  1.1.2.2   thorpej 
    515  1.1.2.2   thorpej 		if (pte_find(pm, kbreak)) continue;
    516  1.1.2.6  jdolecek 
    517  1.1.2.2   thorpej 		if (uvm.page_init_done) {
    518  1.1.2.2   thorpej 			pg = (paddr_t)VM_PAGE_TO_PHYS(vm_page_alloc1());
    519  1.1.2.2   thorpej 		} else {
    520  1.1.2.2   thorpej 			if (!uvm_page_physget(&pg))
    521  1.1.2.2   thorpej 				panic("pmap_growkernel: no memory");
    522  1.1.2.2   thorpej 		}
    523  1.1.2.2   thorpej 		if (!pg) panic("pmap_growkernel: no pages");
    524  1.1.2.2   thorpej 		pmap_zero_page((paddr_t)pg);
    525  1.1.2.2   thorpej 
    526  1.1.2.2   thorpej 		/* XXX This is based on all phymem being addressable */
    527  1.1.2.2   thorpej 		pm->pm_ptbl[seg] = (u_int *)pg;
    528  1.1.2.2   thorpej 	}
    529  1.1.2.2   thorpej 	splx(s);
    530  1.1.2.2   thorpej 	return (kbreak);
    531  1.1.2.2   thorpej }
    532  1.1.2.2   thorpej 
    533  1.1.2.2   thorpej /*
    534  1.1.2.2   thorpej  *	vm_page_alloc1:
    535  1.1.2.2   thorpej  *
    536  1.1.2.2   thorpej  *	Allocate and return a memory cell with no associated object.
    537  1.1.2.2   thorpej  */
    538  1.1.2.2   thorpej struct vm_page *
    539  1.1.2.2   thorpej vm_page_alloc1()
    540  1.1.2.2   thorpej {
    541  1.1.2.2   thorpej 	struct vm_page *pg = uvm_pagealloc(NULL, 0, NULL, UVM_PGA_USERESERVE);
    542  1.1.2.2   thorpej 	if (pg) {
    543  1.1.2.2   thorpej 		pg->wire_count = 1;	/* no mappings yet */
    544  1.1.2.2   thorpej 		pg->flags &= ~PG_BUSY;	/* never busy */
    545  1.1.2.2   thorpej 	}
    546  1.1.2.2   thorpej 	return pg;
    547  1.1.2.2   thorpej }
    548  1.1.2.2   thorpej 
    549  1.1.2.2   thorpej /*
    550  1.1.2.2   thorpej  *	vm_page_free1:
    551  1.1.2.2   thorpej  *
    552  1.1.2.2   thorpej  *	Returns the given page to the free list,
    553  1.1.2.2   thorpej  *	disassociating it with any VM object.
    554  1.1.2.2   thorpej  *
    555  1.1.2.2   thorpej  *	Object and page must be locked prior to entry.
    556  1.1.2.2   thorpej  */
    557  1.1.2.2   thorpej void
    558  1.1.2.2   thorpej vm_page_free1(mem)
    559  1.1.2.2   thorpej 	struct vm_page *mem;
    560  1.1.2.2   thorpej {
    561  1.1.2.4  jdolecek #ifdef DIAGNOSTIC
    562  1.1.2.2   thorpej 	if (mem->flags != (PG_CLEAN|PG_FAKE)) {
    563  1.1.2.2   thorpej 		printf("Freeing invalid page %p\n", mem);
    564  1.1.2.2   thorpej 		printf("pa = %llx\n", (unsigned long long)VM_PAGE_TO_PHYS(mem));
    565  1.1.2.4  jdolecek #ifdef DDB
    566  1.1.2.2   thorpej 		Debugger();
    567  1.1.2.4  jdolecek #endif
    568  1.1.2.2   thorpej 		return;
    569  1.1.2.2   thorpej 	}
    570  1.1.2.4  jdolecek #endif
    571  1.1.2.2   thorpej 	mem->flags |= PG_BUSY;
    572  1.1.2.2   thorpej 	mem->wire_count = 0;
    573  1.1.2.2   thorpej 	uvm_pagefree(mem);
    574  1.1.2.2   thorpej }
    575  1.1.2.2   thorpej #endif
    576  1.1.2.2   thorpej 
    577      1.1    simonb /*
    578      1.1    simonb  * Create and return a physical map.
    579      1.1    simonb  */
    580      1.1    simonb struct pmap *
    581      1.1    simonb pmap_create(void)
    582      1.1    simonb {
    583      1.1    simonb 	struct pmap *pm;
    584      1.1    simonb 
    585      1.1    simonb 	pm = (struct pmap *)malloc(sizeof *pm, M_VMPMAP, M_WAITOK);
    586  1.1.2.1     lukem 	memset((caddr_t)pm, 0, sizeof *pm);
    587      1.1    simonb 	pmap_pinit(pm);
    588      1.1    simonb 	return pm;
    589      1.1    simonb }
    590      1.1    simonb 
    591      1.1    simonb /*
    592      1.1    simonb  * Initialize a preallocated and zeroed pmap structure.
    593      1.1    simonb  */
    594      1.1    simonb void
    595      1.1    simonb pmap_pinit(struct pmap *pm)
    596      1.1    simonb {
    597      1.1    simonb 	int i;
    598      1.1    simonb 
    599      1.1    simonb 	/*
    600      1.1    simonb 	 * Allocate some segment registers for this pmap.
    601      1.1    simonb 	 */
    602      1.1    simonb 	pm->pm_refs = 1;
    603      1.1    simonb 	for (i = 0; i < STSZ; i++)
    604      1.1    simonb 		pm->pm_ptbl[i] = NULL;
    605      1.1    simonb }
    606      1.1    simonb 
    607      1.1    simonb /*
    608      1.1    simonb  * Add a reference to the given pmap.
    609      1.1    simonb  */
    610      1.1    simonb void
    611      1.1    simonb pmap_reference(struct pmap *pm)
    612      1.1    simonb {
    613      1.1    simonb 
    614      1.1    simonb 	pm->pm_refs++;
    615      1.1    simonb }
    616      1.1    simonb 
    617      1.1    simonb /*
    618      1.1    simonb  * Retire the given pmap from service.
    619      1.1    simonb  * Should only be called if the map contains no valid mappings.
    620      1.1    simonb  */
    621      1.1    simonb void
    622      1.1    simonb pmap_destroy(struct pmap *pm)
    623      1.1    simonb {
    624      1.1    simonb 
    625      1.1    simonb 	if (--pm->pm_refs == 0) {
    626      1.1    simonb 		pmap_release(pm);
    627      1.1    simonb 		free((caddr_t)pm, M_VMPMAP);
    628      1.1    simonb 	}
    629      1.1    simonb }
    630      1.1    simonb 
    631      1.1    simonb /*
    632      1.1    simonb  * Release any resources held by the given physical map.
    633      1.1    simonb  * Called when a pmap initialized by pmap_pinit is being released.
    634      1.1    simonb  */
    635      1.1    simonb static void
    636      1.1    simonb pmap_release(struct pmap *pm)
    637      1.1    simonb {
    638      1.1    simonb 	int i;
    639      1.1    simonb 
    640      1.1    simonb 	for (i = 0; i < STSZ; i++)
    641      1.1    simonb 		if (pm->pm_ptbl[i]) {
    642      1.1    simonb 			uvm_km_free(kernel_map, (vaddr_t)pm->pm_ptbl[i], NBPG);
    643      1.1    simonb 			pm->pm_ptbl[i] = NULL;
    644      1.1    simonb 		}
    645      1.1    simonb 	if (pm->pm_ctx) ctx_free(pm);
    646      1.1    simonb }
    647      1.1    simonb 
    648      1.1    simonb /*
    649      1.1    simonb  * Copy the range specified by src_addr/len
    650      1.1    simonb  * from the source map to the range dst_addr/len
    651      1.1    simonb  * in the destination map.
    652      1.1    simonb  *
    653      1.1    simonb  * This routine is only advisory and need not do anything.
    654      1.1    simonb  */
    655      1.1    simonb void
    656      1.1    simonb pmap_copy(struct pmap *dst_pmap, struct pmap *src_pmap, vaddr_t dst_addr,
    657      1.1    simonb 	  vsize_t len, vaddr_t src_addr)
    658      1.1    simonb {
    659      1.1    simonb }
    660      1.1    simonb 
    661      1.1    simonb /*
    662      1.1    simonb  * Require that all active physical maps contain no
    663      1.1    simonb  * incorrect entries NOW.
    664      1.1    simonb  */
    665      1.1    simonb void
    666  1.1.2.2   thorpej pmap_update(struct pmap *pmap)
    667      1.1    simonb {
    668      1.1    simonb }
    669      1.1    simonb 
    670      1.1    simonb /*
    671      1.1    simonb  * Garbage collects the physical map system for
    672      1.1    simonb  * pages which are no longer used.
    673      1.1    simonb  * Success need not be guaranteed -- that is, there
    674      1.1    simonb  * may well be pages which are not referenced, but
    675      1.1    simonb  * others may be collected.
    676      1.1    simonb  * Called by the pageout daemon when pages are scarce.
    677      1.1    simonb  */
    678      1.1    simonb void
    679      1.1    simonb pmap_collect(struct pmap *pm)
    680      1.1    simonb {
    681      1.1    simonb }
    682      1.1    simonb 
    683      1.1    simonb /*
    684      1.1    simonb  * Fill the given physical page with zeroes.
    685      1.1    simonb  */
    686      1.1    simonb void
    687      1.1    simonb pmap_zero_page(paddr_t pa)
    688      1.1    simonb {
    689      1.1    simonb 
    690  1.1.2.3   thorpej #ifdef PPC_4XX_NOCACHE
    691  1.1.2.1     lukem 	memset((caddr_t)pa, 0, NBPG);
    692      1.1    simonb #else
    693      1.1    simonb 	int i;
    694      1.1    simonb 
    695      1.1    simonb 	for (i = NBPG/CACHELINESIZE; i > 0; i--) {
    696      1.1    simonb 		__asm __volatile ("dcbz 0,%0" :: "r"(pa));
    697      1.1    simonb 		pa += CACHELINESIZE;
    698      1.1    simonb 	}
    699      1.1    simonb #endif
    700      1.1    simonb }
    701      1.1    simonb 
    702      1.1    simonb /*
    703      1.1    simonb  * Copy the given physical source page to its destination.
    704      1.1    simonb  */
    705      1.1    simonb void
    706      1.1    simonb pmap_copy_page(paddr_t src, paddr_t dst)
    707      1.1    simonb {
    708      1.1    simonb 
    709  1.1.2.1     lukem 	memcpy((caddr_t)dst, (caddr_t)src, NBPG);
    710      1.1    simonb 	dcache_flush_page(dst);
    711      1.1    simonb }
    712      1.1    simonb 
    713      1.1    simonb /*
    714      1.1    simonb  * This returns whether this is the first mapping of a page.
    715      1.1    simonb  */
    716      1.1    simonb static inline int
    717      1.1    simonb pmap_enter_pv(struct pmap *pm, vaddr_t va, paddr_t pa)
    718      1.1    simonb {
    719      1.1    simonb 	struct pv_entry *pv, *npv = NULL;
    720      1.1    simonb 	int s;
    721      1.1    simonb 
    722      1.1    simonb 	if (!pmap_initialized)
    723      1.1    simonb 		return 0;
    724      1.1    simonb 
    725      1.1    simonb 	s = splvm();
    726      1.1    simonb 
    727      1.1    simonb 	pv = pa_to_pv(pa);
    728  1.1.2.4  jdolecek for (npv = pv; npv; npv = npv->pv_next)
    729  1.1.2.4  jdolecek if (npv->pv_va == va && npv->pv_pm == pm) {
    730  1.1.2.4  jdolecek printf("Duplicate pv: va %lx pm %p\n", va, pm);
    731  1.1.2.4  jdolecek Debugger();
    732  1.1.2.4  jdolecek return (1);
    733  1.1.2.4  jdolecek }
    734  1.1.2.4  jdolecek 
    735      1.1    simonb 	if (!pv->pv_pm) {
    736      1.1    simonb 		/*
    737      1.1    simonb 		 * No entries yet, use header as the first entry.
    738      1.1    simonb 		 */
    739      1.1    simonb 		pv->pv_va = va;
    740      1.1    simonb 		pv->pv_pm = pm;
    741      1.1    simonb 		pv->pv_next = NULL;
    742      1.1    simonb 	} else {
    743      1.1    simonb 		/*
    744      1.1    simonb 		 * There is at least one other VA mapping this page.
    745      1.1    simonb 		 * Place this entry after the header.
    746      1.1    simonb 		 */
    747      1.1    simonb 		npv = pool_get(&pv_pool, PR_WAITOK);
    748      1.1    simonb 		if (!npv) return (0);
    749      1.1    simonb 		npv->pv_va = va;
    750      1.1    simonb 		npv->pv_pm = pm;
    751      1.1    simonb 		npv->pv_next = pv->pv_next;
    752      1.1    simonb 		pv->pv_next = npv;
    753      1.1    simonb 	}
    754      1.1    simonb 	splx(s);
    755      1.1    simonb 	return (1);
    756      1.1    simonb }
    757      1.1    simonb 
    758      1.1    simonb static void
    759      1.1    simonb pmap_remove_pv(struct pmap *pm, vaddr_t va, paddr_t pa)
    760      1.1    simonb {
    761      1.1    simonb 	struct pv_entry *pv, *npv;
    762      1.1    simonb 
    763      1.1    simonb 	/*
    764      1.1    simonb 	 * Remove from the PV table.
    765      1.1    simonb 	 */
    766      1.1    simonb 	pv = pa_to_pv(pa);
    767      1.1    simonb 	if (!pv) return;
    768      1.1    simonb 
    769      1.1    simonb 	/*
    770      1.1    simonb 	 * If it is the first entry on the list, it is actually
    771      1.1    simonb 	 * in the header and we must copy the following entry up
    772      1.1    simonb 	 * to the header.  Otherwise we must search the list for
    773      1.1    simonb 	 * the entry.  In either case we free the now unused entry.
    774      1.1    simonb 	 */
    775      1.1    simonb 	if (pm == pv->pv_pm && PV_CMPVA(va, pv)) {
    776      1.1    simonb 		if ((npv = pv->pv_next)) {
    777      1.1    simonb 			*pv = *npv;
    778      1.1    simonb 			pool_put(&pv_pool, npv);
    779      1.1    simonb 		} else
    780      1.1    simonb 			pv->pv_pm = NULL;
    781      1.1    simonb 	} else {
    782      1.1    simonb 		for (; (npv = pv->pv_next) != NULL; pv = npv)
    783      1.1    simonb 			if (pm == npv->pv_pm && PV_CMPVA(va, npv))
    784      1.1    simonb 				break;
    785      1.1    simonb 		if (npv) {
    786      1.1    simonb 			pv->pv_next = npv->pv_next;
    787      1.1    simonb 			pool_put(&pv_pool, npv);
    788      1.1    simonb 		}
    789      1.1    simonb 	}
    790      1.1    simonb }
    791      1.1    simonb 
    792      1.1    simonb /*
    793      1.1    simonb  * Insert physical page at pa into the given pmap at virtual address va.
    794      1.1    simonb  */
    795      1.1    simonb int
    796      1.1    simonb pmap_enter(struct pmap *pm, vaddr_t va, paddr_t pa, vm_prot_t prot, int flags)
    797      1.1    simonb {
    798      1.1    simonb 	int s;
    799      1.1    simonb 	u_int tte;
    800      1.1    simonb 	int managed;
    801      1.1    simonb 
    802      1.1    simonb 	/*
    803      1.1    simonb 	 * Have to remove any existing mapping first.
    804      1.1    simonb 	 */
    805      1.1    simonb 	pmap_remove(pm, va, va + NBPG);
    806      1.1    simonb 
    807      1.1    simonb 	if (flags & PMAP_WIRED) flags |= prot;
    808      1.1    simonb 
    809      1.1    simonb 	/* If it has no protections don't bother w/the rest */
    810      1.1    simonb 	if (!(flags & VM_PROT_ALL))
    811      1.1    simonb 		return (0);
    812      1.1    simonb 
    813      1.1    simonb 	managed = 0;
    814      1.1    simonb 	if (vm_physseg_find(atop(pa), NULL) != -1)
    815      1.1    simonb 		managed = 1;
    816      1.1    simonb 
    817      1.1    simonb 	/*
    818      1.1    simonb 	 * Generate TTE.
    819      1.1    simonb 	 *
    820      1.1    simonb 	 * XXXX
    821      1.1    simonb 	 *
    822      1.1    simonb 	 * Since the kernel does not handle execution privileges properly,
    823      1.1    simonb 	 * we will handle read and execute permissions together.
    824      1.1    simonb 	 */
    825      1.1    simonb 	tte = TTE_PA(pa) | TTE_EX;
    826      1.1    simonb 	/* XXXX -- need to support multiple page sizes. */
    827      1.1    simonb 	tte |= TTE_SZ_16K;
    828      1.1    simonb #ifdef	DIAGNOSTIC
    829      1.1    simonb 	if ((flags & (PME_NOCACHE | PME_WRITETHROUG)) ==
    830      1.1    simonb 		(PME_NOCACHE | PME_WRITETHROUG))
    831      1.1    simonb 		panic("pmap_enter: uncached & writethrough\n");
    832      1.1    simonb #endif
    833      1.1    simonb 	if (flags & PME_NOCACHE)
    834      1.1    simonb 		/* Must be I/O mapping */
    835      1.1    simonb 		tte |= TTE_I | TTE_G;
    836  1.1.2.3   thorpej #ifdef PPC_4XX_NOCACHE
    837      1.1    simonb 	tte |= TTE_I;
    838      1.1    simonb #else
    839      1.1    simonb 	else if (flags & PME_WRITETHROUG)
    840      1.1    simonb 		/* Uncached and writethrough are not compatible */
    841      1.1    simonb 		tte |= TTE_W;
    842      1.1    simonb #endif
    843      1.1    simonb 	if (pm == pmap_kernel())
    844      1.1    simonb 		tte |= TTE_ZONE(ZONE_PRIV);
    845      1.1    simonb 	else
    846      1.1    simonb 		tte |= TTE_ZONE(ZONE_USER);
    847      1.1    simonb 
    848      1.1    simonb 	if (flags & VM_PROT_WRITE)
    849      1.1    simonb 		tte |= TTE_WR;
    850      1.1    simonb 
    851      1.1    simonb 	/*
    852      1.1    simonb 	 * Now record mapping for later back-translation.
    853      1.1    simonb 	 */
    854      1.1    simonb 	if (pmap_initialized && managed) {
    855      1.1    simonb 		char *attr;
    856      1.1    simonb 
    857      1.1    simonb 		if (!pmap_enter_pv(pm, va, pa)) {
    858      1.1    simonb 			/* Could not enter pv on a managed page */
    859      1.1    simonb 			return 1;
    860      1.1    simonb 		}
    861      1.1    simonb 
    862      1.1    simonb 		/* Now set attributes. */
    863      1.1    simonb 		attr = pa_to_attr(pa);
    864      1.1    simonb #ifdef DIAGNOSTIC
    865      1.1    simonb 		if (!attr)
    866      1.1    simonb 			panic("managed but no attr\n");
    867      1.1    simonb #endif
    868      1.1    simonb 		if (flags & VM_PROT_ALL)
    869      1.1    simonb 			*attr |= PTE_HI_REF;
    870      1.1    simonb 		if (flags & VM_PROT_WRITE)
    871      1.1    simonb 			*attr |= PTE_HI_CHG;
    872      1.1    simonb 	}
    873      1.1    simonb 
    874      1.1    simonb 	s = splvm();
    875      1.1    simonb 	pm->pm_stats.resident_count++;
    876      1.1    simonb 
    877      1.1    simonb 	/* Insert page into page table. */
    878      1.1    simonb 	pte_enter(pm, va, tte);
    879      1.1    simonb 
    880      1.1    simonb 	/* If this is a real fault, enter it in the tlb */
    881      1.1    simonb 	if (tte && ((flags & PMAP_WIRED) == 0)) {
    882      1.1    simonb 		ppc4xx_tlb_enter(pm->pm_ctx, va, tte);
    883      1.1    simonb 	}
    884      1.1    simonb 	splx(s);
    885  1.1.2.3   thorpej 
    886  1.1.2.3   thorpej 	/* Flush the real memory from the instruction cache. */
    887  1.1.2.3   thorpej 	if ((prot & VM_PROT_EXECUTE) && (tte & TTE_I) == 0)
    888  1.1.2.3   thorpej 		__syncicache((void *)pa, PAGE_SIZE);
    889  1.1.2.3   thorpej 
    890      1.1    simonb 	return 0;
    891      1.1    simonb }
    892      1.1    simonb 
    893      1.1    simonb void
    894      1.1    simonb pmap_unwire(struct pmap *pm, vaddr_t va)
    895      1.1    simonb {
    896      1.1    simonb 	struct pv_entry *pv, *npv;
    897      1.1    simonb 	paddr_t pa;
    898      1.1    simonb 	int s = splvm();
    899      1.1    simonb 
    900  1.1.2.6  jdolecek 	if (pm == NULL) {
    901  1.1.2.6  jdolecek 		return;
    902  1.1.2.6  jdolecek 	}
    903      1.1    simonb 
    904      1.1    simonb 	if (!pmap_extract(pm, va, &pa)) {
    905      1.1    simonb 		return;
    906      1.1    simonb 	}
    907      1.1    simonb 
    908      1.1    simonb 	va |= PV_WIRED;
    909      1.1    simonb 
    910      1.1    simonb 	pv = pa_to_pv(pa);
    911      1.1    simonb 	if (!pv) return;
    912      1.1    simonb 
    913      1.1    simonb 	/*
    914      1.1    simonb 	 * If it is the first entry on the list, it is actually
    915      1.1    simonb 	 * in the header and we must copy the following entry up
    916      1.1    simonb 	 * to the header.  Otherwise we must search the list for
    917      1.1    simonb 	 * the entry.  In either case we free the now unused entry.
    918      1.1    simonb 	 */
    919      1.1    simonb 	for (npv = pv; (npv = pv->pv_next) != NULL; pv = npv) {
    920      1.1    simonb 		if (pm == npv->pv_pm && PV_CMPVA(va, npv)) {
    921      1.1    simonb 			npv->pv_va &= ~PV_WIRED;
    922      1.1    simonb 			break;
    923      1.1    simonb 		}
    924      1.1    simonb 	}
    925      1.1    simonb 	splx(s);
    926      1.1    simonb }
    927      1.1    simonb 
    928      1.1    simonb void
    929      1.1    simonb pmap_kenter_pa(vaddr_t va, paddr_t pa, vm_prot_t prot)
    930      1.1    simonb {
    931      1.1    simonb 	int s;
    932      1.1    simonb 	u_int tte;
    933      1.1    simonb 	struct pmap *pm = pmap_kernel();
    934      1.1    simonb 
    935      1.1    simonb 	/*
    936      1.1    simonb 	 * Have to remove any existing mapping first.
    937      1.1    simonb 	 */
    938      1.1    simonb 
    939      1.1    simonb 	/*
    940      1.1    simonb 	 * Generate TTE.
    941      1.1    simonb 	 *
    942      1.1    simonb 	 * XXXX
    943      1.1    simonb 	 *
    944      1.1    simonb 	 * Since the kernel does not handle execution privileges properly,
    945      1.1    simonb 	 * we will handle read and execute permissions together.
    946      1.1    simonb 	 */
    947      1.1    simonb 	tte = 0;
    948      1.1    simonb 	if (prot & VM_PROT_ALL) {
    949      1.1    simonb 
    950      1.1    simonb 		tte = TTE_PA(pa) | TTE_EX | TTE_ZONE(ZONE_PRIV);
    951      1.1    simonb 		/* XXXX -- need to support multiple page sizes. */
    952      1.1    simonb 		tte |= TTE_SZ_16K;
    953      1.1    simonb #ifdef DIAGNOSTIC
    954      1.1    simonb 		if ((prot & (PME_NOCACHE | PME_WRITETHROUG)) ==
    955      1.1    simonb 			(PME_NOCACHE | PME_WRITETHROUG))
    956      1.1    simonb 			panic("pmap_kenter_pa: uncached & writethrough\n");
    957      1.1    simonb #endif
    958      1.1    simonb 		if (prot & PME_NOCACHE)
    959      1.1    simonb 			/* Must be I/O mapping */
    960      1.1    simonb 			tte |= TTE_I | TTE_G;
    961  1.1.2.3   thorpej #ifdef PPC_4XX_NOCACHE
    962      1.1    simonb 		tte |= TTE_I;
    963      1.1    simonb #else
    964      1.1    simonb 		else if (prot & PME_WRITETHROUG)
    965      1.1    simonb 			/* Uncached and writethrough are not compatible */
    966      1.1    simonb 			tte |= TTE_W;
    967      1.1    simonb #endif
    968      1.1    simonb 		if (prot & VM_PROT_WRITE)
    969      1.1    simonb 			tte |= TTE_WR;
    970      1.1    simonb 	}
    971      1.1    simonb 
    972      1.1    simonb 	s = splvm();
    973      1.1    simonb 	pm->pm_stats.resident_count++;
    974      1.1    simonb 
    975      1.1    simonb 	/* Insert page into page table. */
    976      1.1    simonb 	pte_enter(pm, va, tte);
    977      1.1    simonb 	splx(s);
    978      1.1    simonb }
    979      1.1    simonb 
    980      1.1    simonb void
    981      1.1    simonb pmap_kremove(vaddr_t va, vsize_t len)
    982      1.1    simonb {
    983      1.1    simonb 
    984      1.1    simonb 	while (len > 0) {
    985      1.1    simonb 		pte_enter(pmap_kernel(), va, 0);
    986      1.1    simonb 		va += PAGE_SIZE;
    987      1.1    simonb 		len -= PAGE_SIZE;
    988      1.1    simonb 	}
    989      1.1    simonb }
    990      1.1    simonb 
    991      1.1    simonb /*
    992      1.1    simonb  * Remove the given range of mapping entries.
    993      1.1    simonb  */
    994      1.1    simonb void
    995      1.1    simonb pmap_remove(struct pmap *pm, vaddr_t va, vaddr_t endva)
    996      1.1    simonb {
    997      1.1    simonb 	int s;
    998      1.1    simonb 	paddr_t pa;
    999      1.1    simonb 	volatile u_int *ptp;
   1000      1.1    simonb 
   1001      1.1    simonb 	s = splvm();
   1002      1.1    simonb 	while (va < endva) {
   1003      1.1    simonb 
   1004      1.1    simonb 		if ((ptp = pte_find(pm, va)) && (pa = *ptp)) {
   1005      1.1    simonb 			pa = TTE_PA(pa);
   1006      1.1    simonb 			pmap_remove_pv(pm, va, pa);
   1007      1.1    simonb 			*ptp = 0;
   1008      1.1    simonb 			ppc4xx_tlb_flush(va, pm->pm_ctx);
   1009      1.1    simonb 			pm->pm_stats.resident_count--;
   1010      1.1    simonb 		}
   1011      1.1    simonb 		va += NBPG;
   1012      1.1    simonb 	}
   1013      1.1    simonb 
   1014      1.1    simonb 	splx(s);
   1015      1.1    simonb }
   1016      1.1    simonb 
   1017      1.1    simonb /*
   1018      1.1    simonb  * Get the physical page address for the given pmap/virtual address.
   1019      1.1    simonb  */
   1020      1.1    simonb boolean_t
   1021      1.1    simonb pmap_extract(struct pmap *pm, vaddr_t va, paddr_t *pap)
   1022      1.1    simonb {
   1023      1.1    simonb 	int seg = STIDX(va);
   1024      1.1    simonb 	int ptn = PTIDX(va);
   1025      1.1    simonb 	u_int pa = 0;
   1026      1.1    simonb 	int s = splvm();
   1027      1.1    simonb 
   1028      1.1    simonb 	if (pm->pm_ptbl[seg] && (pa = pm->pm_ptbl[seg][ptn])) {
   1029      1.1    simonb 		*pap = TTE_PA(pa) | (va & PGOFSET);
   1030      1.1    simonb 	}
   1031      1.1    simonb 	splx(s);
   1032      1.1    simonb 	return (pa != 0);
   1033      1.1    simonb }
   1034      1.1    simonb 
   1035      1.1    simonb /*
   1036      1.1    simonb  * Lower the protection on the specified range of this pmap.
   1037      1.1    simonb  *
   1038      1.1    simonb  * There are only two cases: either the protection is going to 0,
   1039      1.1    simonb  * or it is going to read-only.
   1040      1.1    simonb  */
   1041      1.1    simonb void
   1042      1.1    simonb pmap_protect(struct pmap *pm, vaddr_t sva, vaddr_t eva, vm_prot_t prot)
   1043      1.1    simonb {
   1044      1.1    simonb 	volatile u_int *ptp;
   1045      1.1    simonb 	int s;
   1046      1.1    simonb 
   1047      1.1    simonb 	if (prot & VM_PROT_READ) {
   1048      1.1    simonb 		s = splvm();
   1049      1.1    simonb 		while (sva < eva) {
   1050      1.1    simonb 			if ((ptp = pte_find(pm, sva)) != NULL) {
   1051      1.1    simonb 				*ptp &= ~TTE_WR;
   1052      1.1    simonb 				ppc4xx_tlb_flush(sva, pm->pm_ctx);
   1053      1.1    simonb 			}
   1054      1.1    simonb 			sva += NBPG;
   1055      1.1    simonb 		}
   1056      1.1    simonb 		splx(s);
   1057      1.1    simonb 		return;
   1058      1.1    simonb 	}
   1059      1.1    simonb 	pmap_remove(pm, sva, eva);
   1060      1.1    simonb }
   1061      1.1    simonb 
   1062      1.1    simonb boolean_t
   1063      1.1    simonb check_attr(struct vm_page *pg, u_int mask, int clear)
   1064      1.1    simonb {
   1065      1.1    simonb 	paddr_t pa = VM_PAGE_TO_PHYS(pg);
   1066      1.1    simonb 	int s;
   1067      1.1    simonb 	char *attr;
   1068      1.1    simonb 	int rv;
   1069      1.1    simonb 
   1070      1.1    simonb 	/*
   1071      1.1    simonb 	 * First modify bits in cache.
   1072      1.1    simonb 	 */
   1073      1.1    simonb 	s = splvm();
   1074      1.1    simonb 	attr = pa_to_attr(pa);
   1075      1.1    simonb 	if (attr == NULL)
   1076      1.1    simonb 		return FALSE;
   1077      1.1    simonb 
   1078      1.1    simonb 	rv = ((*attr & mask) != 0);
   1079  1.1.2.5  jdolecek 	if (clear) {
   1080      1.1    simonb 		*attr &= ~mask;
   1081  1.1.2.5  jdolecek 		pmap_page_protect(pg, (mask == PTE_HI_CHG) ? VM_PROT_READ : 0);
   1082  1.1.2.5  jdolecek 	}
   1083      1.1    simonb 	splx(s);
   1084      1.1    simonb 	return rv;
   1085      1.1    simonb }
   1086      1.1    simonb 
   1087      1.1    simonb 
   1088      1.1    simonb /*
   1089      1.1    simonb  * Lower the protection on the specified physical page.
   1090      1.1    simonb  *
   1091      1.1    simonb  * There are only two cases: either the protection is going to 0,
   1092      1.1    simonb  * or it is going to read-only.
   1093      1.1    simonb  */
   1094      1.1    simonb void
   1095      1.1    simonb pmap_page_protect(struct vm_page *pg, vm_prot_t prot)
   1096      1.1    simonb {
   1097      1.1    simonb 	paddr_t pa = VM_PAGE_TO_PHYS(pg);
   1098      1.1    simonb 	vaddr_t va;
   1099      1.1    simonb 	struct pv_entry *pvh, *pv, *npv;
   1100      1.1    simonb 	struct pmap *pm;
   1101      1.1    simonb 
   1102      1.1    simonb 	pvh = pa_to_pv(pa);
   1103      1.1    simonb 	if (pvh == NULL)
   1104      1.1    simonb 		return;
   1105      1.1    simonb 
   1106      1.1    simonb 	/* Handle extra pvs which may be deleted in the operation */
   1107      1.1    simonb 	for (pv = pvh->pv_next; pv; pv = npv) {
   1108      1.1    simonb 		npv = pv->pv_next;
   1109      1.1    simonb 
   1110      1.1    simonb 		pm = pv->pv_pm;
   1111      1.1    simonb 		va = pv->pv_va;
   1112      1.1    simonb 		pmap_protect(pm, va, va+NBPG, prot);
   1113      1.1    simonb 	}
   1114      1.1    simonb 	/* Now check the head pv */
   1115      1.1    simonb 	if (pvh->pv_pm) {
   1116      1.1    simonb 		pv = pvh;
   1117      1.1    simonb 		pm = pv->pv_pm;
   1118      1.1    simonb 		va = pv->pv_va;
   1119      1.1    simonb 		pmap_protect(pm, va, va+NBPG, prot);
   1120      1.1    simonb 	}
   1121      1.1    simonb }
   1122      1.1    simonb 
   1123      1.1    simonb /*
   1124      1.1    simonb  * Activate the address space for the specified process.  If the process
   1125      1.1    simonb  * is the current process, load the new MMU context.
   1126      1.1    simonb  */
   1127      1.1    simonb void
   1128      1.1    simonb pmap_activate(struct proc *p)
   1129      1.1    simonb {
   1130      1.1    simonb #if 0
   1131      1.1    simonb 	struct pcb *pcb = &p->p_addr->u_pcb;
   1132      1.1    simonb 	pmap_t pmap = p->p_vmspace->vm_map.pmap;
   1133      1.1    simonb 
   1134      1.1    simonb 	/*
   1135      1.1    simonb 	 * XXX Normally performed in cpu_fork().
   1136      1.1    simonb 	 */
   1137      1.1    simonb 	printf("pmap_activate(%p), pmap=%p\n",p,pmap);
   1138      1.1    simonb 	if (pcb->pcb_pm != pmap) {
   1139      1.1    simonb 		pcb->pcb_pm = pmap;
   1140      1.1    simonb 		(void) pmap_extract(pmap_kernel(), (vaddr_t)pcb->pcb_pm,
   1141      1.1    simonb 		    (paddr_t *)&pcb->pcb_pmreal);
   1142      1.1    simonb 	}
   1143      1.1    simonb 
   1144      1.1    simonb 	if (p == curproc) {
   1145      1.1    simonb 		/* Store pointer to new current pmap. */
   1146      1.1    simonb 		curpm = pcb->pcb_pmreal;
   1147      1.1    simonb 	}
   1148      1.1    simonb #endif
   1149      1.1    simonb }
   1150      1.1    simonb 
   1151      1.1    simonb /*
   1152      1.1    simonb  * Deactivate the specified process's address space.
   1153      1.1    simonb  */
   1154      1.1    simonb void
   1155      1.1    simonb pmap_deactivate(struct proc *p)
   1156      1.1    simonb {
   1157      1.1    simonb }
   1158      1.1    simonb 
   1159      1.1    simonb /*
   1160      1.1    simonb  * Synchronize caches corresponding to [addr, addr+len) in p.
   1161      1.1    simonb  */
   1162      1.1    simonb void
   1163      1.1    simonb pmap_procwr(struct proc *p, vaddr_t va, size_t len)
   1164      1.1    simonb {
   1165      1.1    simonb 	struct pmap *pm = p->p_vmspace->vm_map.pmap;
   1166      1.1    simonb 	int msr, ctx, opid;
   1167      1.1    simonb 
   1168      1.1    simonb 
   1169      1.1    simonb 	/*
   1170      1.1    simonb 	 * Need to turn off IMMU and switch to user context.
   1171      1.1    simonb 	 * (icbi uses DMMU).
   1172      1.1    simonb 	 */
   1173      1.1    simonb 	if (!(ctx = pm->pm_ctx)) {
   1174      1.1    simonb 		/* No context -- assign it one */
   1175      1.1    simonb 		ctx_alloc(pm);
   1176      1.1    simonb 		ctx = pm->pm_ctx;
   1177      1.1    simonb 	}
   1178      1.1    simonb 	__asm __volatile("mfmsr %0;"
   1179      1.1    simonb 		"li %1, 0x20;"
   1180      1.1    simonb 		"andc %1,%0,%1;"
   1181      1.1    simonb 		"mtmsr %1;"
   1182      1.1    simonb 		"sync;isync;"
   1183      1.1    simonb 		"mfpid %1;"
   1184      1.1    simonb 		"mtpid %2;"
   1185      1.1    simonb 		"sync; isync;"
   1186  1.1.2.6  jdolecek 		"1:"
   1187      1.1    simonb 		"dcbf 0,%3;"
   1188      1.1    simonb 		"icbi 0,%3;"
   1189      1.1    simonb 		"addi %3,%3,32;"
   1190      1.1    simonb 		"addic. %4,%4,-32;"
   1191      1.1    simonb 		"bge 1b;"
   1192      1.1    simonb 		"mtpid %1;"
   1193      1.1    simonb 		"mtmsr %0;"
   1194      1.1    simonb 		"sync; isync"
   1195      1.1    simonb 		: "=&r" (msr), "=&r" (opid)
   1196      1.1    simonb 		: "r" (ctx), "r" (va), "r" (len));
   1197      1.1    simonb }
   1198      1.1    simonb 
   1199      1.1    simonb 
   1200      1.1    simonb /* This has to be done in real mode !!! */
   1201      1.1    simonb void
   1202      1.1    simonb ppc4xx_tlb_flush(vaddr_t va, int pid)
   1203      1.1    simonb {
   1204      1.1    simonb 	u_long i, found;
   1205      1.1    simonb 	u_long msr;
   1206      1.1    simonb 
   1207      1.1    simonb 	/* If there's no context then it can't be mapped. */
   1208      1.1    simonb 	if (!pid) return;
   1209      1.1    simonb 
   1210      1.1    simonb 	asm("mfpid %1;"			/* Save PID */
   1211      1.1    simonb 		"mfmsr %2;"		/* Save MSR */
   1212      1.1    simonb 		"li %0,0;"		/* Now clear MSR */
   1213      1.1    simonb 		"mtmsr %0;"
   1214      1.1    simonb 		"mtpid %4;"		/* Set PID */
   1215      1.1    simonb 		"sync;"
   1216      1.1    simonb 		"tlbsx. %0,0,%3;"	/* Search TLB */
   1217      1.1    simonb 		"sync;"
   1218      1.1    simonb 		"mtpid %1;"		/* Restore PID */
   1219      1.1    simonb 		"mtmsr %2;"		/* Restore MSR */
   1220      1.1    simonb 		"sync;isync;"
   1221      1.1    simonb 		"li %1,1;"
   1222      1.1    simonb 		"beq 1f;"
   1223      1.1    simonb 		"li %1,0;"
   1224      1.1    simonb 		"1:"
   1225      1.1    simonb 		: "=&r" (i), "=&r" (found), "=&r" (msr)
   1226      1.1    simonb 		: "r" (va), "r" (pid));
   1227      1.1    simonb 	if (found && !TLB_LOCKED(i)) {
   1228      1.1    simonb 
   1229      1.1    simonb 		/* Now flush translation */
   1230      1.1    simonb 		asm volatile(
   1231      1.1    simonb 			"tlbwe %0,%1,0;"
   1232      1.1    simonb 			"sync;isync;"
   1233      1.1    simonb 			: : "r" (0), "r" (i));
   1234      1.1    simonb 
   1235      1.1    simonb 		tlb_info[i].ti_ctx = 0;
   1236      1.1    simonb 		tlb_info[i].ti_flags = 0;
   1237      1.1    simonb 		tlbnext = i;
   1238      1.1    simonb 		/* Successful flushes */
   1239      1.1    simonb 		tlbflush_ev.ev_count++;
   1240      1.1    simonb 	}
   1241      1.1    simonb }
   1242      1.1    simonb 
   1243      1.1    simonb void
   1244      1.1    simonb ppc4xx_tlb_flush_all(void)
   1245      1.1    simonb {
   1246      1.1    simonb 	u_long i;
   1247      1.1    simonb 
   1248      1.1    simonb 	for (i = 0; i < NTLB; i++)
   1249      1.1    simonb 		if (!TLB_LOCKED(i)) {
   1250      1.1    simonb 			asm volatile(
   1251      1.1    simonb 				"tlbwe %0,%1,0;"
   1252      1.1    simonb 				"sync;isync;"
   1253      1.1    simonb 				: : "r" (0), "r" (i));
   1254      1.1    simonb 			tlb_info[i].ti_ctx = 0;
   1255      1.1    simonb 			tlb_info[i].ti_flags = 0;
   1256      1.1    simonb 		}
   1257      1.1    simonb 
   1258      1.1    simonb 	asm volatile("sync;isync");
   1259      1.1    simonb }
   1260      1.1    simonb 
   1261      1.1    simonb /* Find a TLB entry to evict. */
   1262      1.1    simonb static int
   1263      1.1    simonb ppc4xx_tlb_find_victim(void)
   1264      1.1    simonb {
   1265      1.1    simonb 	int flags;
   1266      1.1    simonb 
   1267      1.1    simonb 	for (;;) {
   1268      1.1    simonb 		if (++tlbnext >= NTLB)
   1269      1.1    simonb 			tlbnext = TLB_NRESERVED;
   1270      1.1    simonb 		flags = tlb_info[tlbnext].ti_flags;
   1271  1.1.2.6  jdolecek 		if (!(flags & TLBF_USED) ||
   1272      1.1    simonb 			(flags & (TLBF_LOCKED | TLBF_REF)) == 0) {
   1273      1.1    simonb 			u_long va, stack = (u_long)&va;
   1274      1.1    simonb 
   1275      1.1    simonb 			if (!((tlb_info[tlbnext].ti_va ^ stack) & (~PGOFSET)) &&
   1276      1.1    simonb 			    (tlb_info[tlbnext].ti_ctx == KERNEL_PID) &&
   1277      1.1    simonb 			     (flags & TLBF_USED)) {
   1278      1.1    simonb 				/* Kernel stack page */
   1279      1.1    simonb 				flags |= TLBF_USED;
   1280      1.1    simonb 				tlb_info[tlbnext].ti_flags = flags;
   1281      1.1    simonb 			} else {
   1282      1.1    simonb 				/* Found it! */
   1283      1.1    simonb 				return (tlbnext);
   1284      1.1    simonb 			}
   1285      1.1    simonb 		} else {
   1286      1.1    simonb 			tlb_info[tlbnext].ti_flags = (flags & ~TLBF_REF);
   1287      1.1    simonb 		}
   1288      1.1    simonb 	}
   1289      1.1    simonb }
   1290      1.1    simonb 
   1291      1.1    simonb void
   1292      1.1    simonb ppc4xx_tlb_enter(int ctx, vaddr_t va, u_int pte)
   1293      1.1    simonb {
   1294      1.1    simonb 	u_long th, tl, idx;
   1295      1.1    simonb 	tlbpid_t pid;
   1296      1.1    simonb 	u_short msr;
   1297  1.1.2.4  jdolecek 	paddr_t pa;
   1298  1.1.2.4  jdolecek 	int s, sz;
   1299  1.1.2.4  jdolecek 
   1300      1.1    simonb 	tlbenter_ev.ev_count++;
   1301      1.1    simonb 
   1302  1.1.2.4  jdolecek 	sz = (pte & TTE_SZ_MASK) >> TTE_SZ_SHIFT;
   1303  1.1.2.4  jdolecek 	pa = (pte & TTE_RPN_MASK(sz));
   1304  1.1.2.4  jdolecek 	th = (va & TLB_EPN_MASK) | (sz << TLB_SIZE_SHFT) | TLB_VALID;
   1305  1.1.2.4  jdolecek 	tl = (pte & ~TLB_RPN_MASK) | pa;
   1306  1.1.2.4  jdolecek 	tl |= ppc4xx_tlbflags(va, pa);
   1307      1.1    simonb 
   1308      1.1    simonb 	s = splhigh();
   1309      1.1    simonb 	idx = ppc4xx_tlb_find_victim();
   1310      1.1    simonb 
   1311      1.1    simonb #ifdef DIAGNOSTIC
   1312      1.1    simonb 	if ((idx < TLB_NRESERVED) || (idx >= NTLB)) {
   1313      1.1    simonb 		panic("ppc4xx_tlb_enter: repacing entry %ld\n", idx);
   1314      1.1    simonb 	}
   1315      1.1    simonb #endif
   1316  1.1.2.6  jdolecek 
   1317      1.1    simonb 	tlb_info[idx].ti_va = (va & TLB_EPN_MASK);
   1318      1.1    simonb 	tlb_info[idx].ti_ctx = ctx;
   1319      1.1    simonb 	tlb_info[idx].ti_flags = TLBF_USED | TLBF_REF;
   1320      1.1    simonb 
   1321      1.1    simonb 	asm volatile(
   1322      1.1    simonb 		"mfmsr %0;"			/* Save MSR */
   1323      1.1    simonb 		"li %1,0;"
   1324      1.1    simonb 		"tlbwe %1,%3,0;"		/* Invalidate old entry. */
   1325      1.1    simonb 		"mtmsr %1;"			/* Clear MSR */
   1326      1.1    simonb 		"mfpid %1;"			/* Save old PID */
   1327      1.1    simonb 		"mtpid %2;"			/* Load translation ctx */
   1328      1.1    simonb 		"sync; isync;"
   1329      1.1    simonb #ifdef DEBUG
   1330      1.1    simonb 		"andi. %3,%3,63;"
   1331      1.1    simonb 		"tweqi %3,0;" 			/* XXXXX DEBUG trap on index 0 */
   1332      1.1    simonb #endif
   1333      1.1    simonb 		"tlbwe %4,%3,1; tlbwe %5,%3,0;"	/* Set TLB */
   1334      1.1    simonb 		"sync; isync;"
   1335      1.1    simonb 		"mtpid %1; mtmsr %0;"		/* Restore PID and MSR */
   1336      1.1    simonb 		"sync; isync;"
   1337      1.1    simonb 	: "=&r" (msr), "=&r" (pid)
   1338      1.1    simonb 	: "r" (ctx), "r" (idx), "r" (tl), "r" (th));
   1339      1.1    simonb 	splx(s);
   1340      1.1    simonb }
   1341      1.1    simonb 
   1342      1.1    simonb void
   1343      1.1    simonb ppc4xx_tlb_unpin(int i)
   1344      1.1    simonb {
   1345      1.1    simonb 
   1346      1.1    simonb 	if (i == -1)
   1347      1.1    simonb 		for (i = 0; i < TLB_NRESERVED; i++)
   1348      1.1    simonb 			tlb_info[i].ti_flags &= ~TLBF_LOCKED;
   1349      1.1    simonb 	else
   1350      1.1    simonb 		tlb_info[i].ti_flags &= ~TLBF_LOCKED;
   1351      1.1    simonb }
   1352      1.1    simonb 
   1353      1.1    simonb void
   1354      1.1    simonb ppc4xx_tlb_init(void)
   1355      1.1    simonb {
   1356      1.1    simonb 	int i;
   1357      1.1    simonb 
   1358      1.1    simonb 	/* Mark reserved TLB entries */
   1359      1.1    simonb 	for (i = 0; i < TLB_NRESERVED; i++) {
   1360      1.1    simonb 		tlb_info[i].ti_flags = TLBF_LOCKED | TLBF_USED;
   1361      1.1    simonb 		tlb_info[i].ti_ctx = KERNEL_PID;
   1362      1.1    simonb 	}
   1363      1.1    simonb 
   1364      1.1    simonb 	/* Setup security zones */
   1365      1.1    simonb 	/* Z0 - accessible by kernel only if TLB entry permissions allow
   1366      1.1    simonb 	 * Z1,Z2 - access is controlled by TLB entry permissions
   1367      1.1    simonb 	 * Z3 - full access regardless of TLB entry permissions
   1368      1.1    simonb 	 */
   1369      1.1    simonb 
   1370      1.1    simonb 	asm volatile(
   1371      1.1    simonb 		"mtspr %0,%1;"
   1372      1.1    simonb 		"sync;"
   1373      1.1    simonb 		::  "K"(SPR_ZPR), "r" (0x1b000000));
   1374      1.1    simonb }
   1375      1.1    simonb 
   1376      1.1    simonb 
   1377      1.1    simonb /*
   1378      1.1    simonb  * We should pass the ctx in from trap code.
   1379      1.1    simonb  */
   1380      1.1    simonb int
   1381      1.1    simonb pmap_tlbmiss(vaddr_t va, int ctx)
   1382      1.1    simonb {
   1383      1.1    simonb 	volatile u_int *pte;
   1384      1.1    simonb 	u_long tte;
   1385      1.1    simonb 
   1386      1.1    simonb 	tlbmiss_ev.ev_count++;
   1387      1.1    simonb 
   1388      1.1    simonb 	/*
   1389      1.1    simonb 	 * XXXX We will reserve 0-0x80000000 for va==pa mappings.
   1390      1.1    simonb 	 */
   1391      1.1    simonb 	if (ctx != KERNEL_PID || (va & 0x80000000)) {
   1392      1.1    simonb 		pte = pte_find((struct pmap *)ctxbusy[ctx], va);
   1393      1.1    simonb 		if (pte == NULL) {
   1394      1.1    simonb 			/* Map unmanaged addresses directly for kernel access */
   1395      1.1    simonb 			return 1;
   1396      1.1    simonb 		}
   1397      1.1    simonb 		tte = *pte;
   1398      1.1    simonb 		if (tte == 0) {
   1399      1.1    simonb 			return 1;
   1400      1.1    simonb 		}
   1401      1.1    simonb 	} else {
   1402      1.1    simonb 		/* Create a 16MB writeable mapping. */
   1403  1.1.2.3   thorpej #ifdef PPC_4XX_NOCACHE
   1404      1.1    simonb 		tte = TTE_PA(va) | TTE_ZONE(ZONE_PRIV) | TTE_SZ_16M | TTE_I | TTE_WR;
   1405      1.1    simonb #else
   1406      1.1    simonb 		tte = TTE_PA(va) | TTE_ZONE(ZONE_PRIV) | TTE_SZ_16M | TTE_WR;
   1407      1.1    simonb #endif
   1408      1.1    simonb 	}
   1409      1.1    simonb 	tlbhit_ev.ev_count++;
   1410      1.1    simonb 	ppc4xx_tlb_enter(ctx, va, tte);
   1411      1.1    simonb 
   1412      1.1    simonb 	return 0;
   1413      1.1    simonb }
   1414      1.1    simonb 
   1415      1.1    simonb /*
   1416      1.1    simonb  * Flush all the entries matching a context from the TLB.
   1417      1.1    simonb  */
   1418      1.1    simonb static int
   1419      1.1    simonb ctx_flush(int cnum)
   1420      1.1    simonb {
   1421      1.1    simonb 	int i;
   1422      1.1    simonb 
   1423      1.1    simonb 	/* We gotta steal this context */
   1424      1.1    simonb 	for (i = TLB_NRESERVED; i < NTLB; i++) {
   1425      1.1    simonb 		if (tlb_info[i].ti_ctx == cnum) {
   1426      1.1    simonb 			/* Can't steal ctx if it has a locked entry. */
   1427      1.1    simonb 			if (TLB_LOCKED(i)) {
   1428      1.1    simonb #ifdef DIAGNOSTIC
   1429      1.1    simonb 				printf("ctx_flush: can't invalidate "
   1430      1.1    simonb 					"locked mapping %d "
   1431      1.1    simonb 					"for context %d\n", i, cnum);
   1432  1.1.2.4  jdolecek #ifdef DDB
   1433      1.1    simonb 				Debugger();
   1434      1.1    simonb #endif
   1435  1.1.2.4  jdolecek #endif
   1436      1.1    simonb 				return (1);
   1437      1.1    simonb 			}
   1438      1.1    simonb #ifdef DIAGNOSTIC
   1439      1.1    simonb 			if (i < TLB_NRESERVED)
   1440      1.1    simonb 				panic("TLB entry %d not locked\n", i);
   1441      1.1    simonb #endif
   1442      1.1    simonb 			/* Invalidate particular TLB entry regardless of locked status */
   1443      1.1    simonb 			asm volatile("tlbwe %0,%1,0" : :"r"(0),"r"(i));
   1444      1.1    simonb 			tlb_info[i].ti_flags = 0;
   1445      1.1    simonb 		}
   1446      1.1    simonb 	}
   1447      1.1    simonb 	return (0);
   1448      1.1    simonb }
   1449      1.1    simonb 
   1450      1.1    simonb /*
   1451      1.1    simonb  * Allocate a context.  If necessary, steal one from someone else.
   1452      1.1    simonb  *
   1453      1.1    simonb  * The new context is flushed from the TLB before returning.
   1454      1.1    simonb  */
   1455      1.1    simonb int
   1456      1.1    simonb ctx_alloc(struct pmap *pm)
   1457      1.1    simonb {
   1458      1.1    simonb 	int s, cnum;
   1459      1.1    simonb 	static int next = MINCTX;
   1460      1.1    simonb 
   1461      1.1    simonb 	if (pm == pmap_kernel()) {
   1462      1.1    simonb #ifdef DIAGNOSTIC
   1463      1.1    simonb 		printf("ctx_alloc: kernel pmap!\n");
   1464      1.1    simonb #endif
   1465      1.1    simonb 		return (0);
   1466      1.1    simonb 	}
   1467      1.1    simonb 	s = splvm();
   1468      1.1    simonb 
   1469      1.1    simonb 	/* Find a likely context. */
   1470      1.1    simonb 	cnum = next;
   1471      1.1    simonb 	do {
   1472      1.1    simonb 		if ((++cnum) > NUMCTX)
   1473      1.1    simonb 			cnum = MINCTX;
   1474      1.1    simonb 	} while (ctxbusy[cnum] != NULL && cnum != next);
   1475      1.1    simonb 
   1476      1.1    simonb 	/* Now clean it out */
   1477      1.1    simonb oops:
   1478      1.1    simonb 	if (cnum < MINCTX)
   1479      1.1    simonb 		cnum = MINCTX; /* Never steal ctx 0 or 1 */
   1480      1.1    simonb 	if (ctx_flush(cnum)) {
   1481      1.1    simonb 		/* oops -- something's wired. */
   1482      1.1    simonb 		if ((++cnum) > NUMCTX)
   1483      1.1    simonb 			cnum = MINCTX;
   1484      1.1    simonb 		goto oops;
   1485      1.1    simonb 	}
   1486      1.1    simonb 
   1487      1.1    simonb 	if (ctxbusy[cnum]) {
   1488      1.1    simonb #ifdef DEBUG
   1489      1.1    simonb 		/* We should identify this pmap and clear it */
   1490      1.1    simonb 		printf("Warning: stealing context %d\n", cnum);
   1491      1.1    simonb #endif
   1492      1.1    simonb 		ctxbusy[cnum]->pm_ctx = 0;
   1493      1.1    simonb 	}
   1494      1.1    simonb 	ctxbusy[cnum] = pm;
   1495      1.1    simonb 	next = cnum;
   1496      1.1    simonb 	splx(s);
   1497      1.1    simonb 	pm->pm_ctx = cnum;
   1498      1.1    simonb 
   1499      1.1    simonb 	return cnum;
   1500      1.1    simonb }
   1501      1.1    simonb 
   1502      1.1    simonb /*
   1503      1.1    simonb  * Give away a context.
   1504      1.1    simonb  */
   1505      1.1    simonb void
   1506      1.1    simonb ctx_free(struct pmap *pm)
   1507      1.1    simonb {
   1508      1.1    simonb 	int oldctx;
   1509      1.1    simonb 
   1510      1.1    simonb 	oldctx = pm->pm_ctx;
   1511      1.1    simonb 
   1512      1.1    simonb 	if (oldctx == 0)
   1513      1.1    simonb 		panic("ctx_free: freeing kernel context");
   1514      1.1    simonb #ifdef DIAGNOSTIC
   1515      1.1    simonb 	if (ctxbusy[oldctx] == 0)
   1516      1.1    simonb 		printf("ctx_free: freeing free context %d\n", oldctx);
   1517      1.1    simonb 	if (ctxbusy[oldctx] != pm) {
   1518      1.1    simonb 		printf("ctx_free: freeing someone esle's context\n "
   1519      1.1    simonb 		       "ctxbusy[%d] = %p, pm->pm_ctx = %p\n",
   1520      1.1    simonb 		       oldctx, (void *)(u_long)ctxbusy[oldctx], pm);
   1521  1.1.2.4  jdolecek #ifdef DDB
   1522      1.1    simonb 		Debugger();
   1523  1.1.2.4  jdolecek #endif
   1524      1.1    simonb 	}
   1525      1.1    simonb #endif
   1526      1.1    simonb 	/* We should verify it has not been stolen and reallocated... */
   1527      1.1    simonb 	ctxbusy[oldctx] = NULL;
   1528      1.1    simonb 	ctx_flush(oldctx);
   1529      1.1    simonb }
   1530      1.1    simonb 
   1531  1.1.2.2   thorpej 
   1532      1.1    simonb #ifdef DEBUG
   1533      1.1    simonb /*
   1534      1.1    simonb  * Test ref/modify handling.
   1535      1.1    simonb  */
   1536      1.1    simonb void pmap_testout __P((void));
   1537      1.1    simonb void
   1538      1.1    simonb pmap_testout()
   1539      1.1    simonb {
   1540      1.1    simonb 	vaddr_t va;
   1541      1.1    simonb 	volatile int *loc;
   1542      1.1    simonb 	int val = 0;
   1543      1.1    simonb 	paddr_t pa;
   1544      1.1    simonb 	struct vm_page *pg;
   1545      1.1    simonb 	int ref, mod;
   1546      1.1    simonb 
   1547      1.1    simonb 	/* Allocate a page */
   1548      1.1    simonb 	va = (vaddr_t)uvm_km_alloc1(kernel_map, NBPG, 1);
   1549      1.1    simonb 	loc = (int*)va;
   1550      1.1    simonb 
   1551      1.1    simonb 	pmap_extract(pmap_kernel(), va, &pa);
   1552      1.1    simonb 	pg = PHYS_TO_VM_PAGE(pa);
   1553      1.1    simonb 	pmap_unwire(pmap_kernel(), va);
   1554      1.1    simonb 
   1555      1.1    simonb 	pmap_remove(pmap_kernel(), va, va+1);
   1556      1.1    simonb 	pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0);
   1557  1.1.2.2   thorpej 	pmap_update(pmap_kernel());
   1558      1.1    simonb 
   1559      1.1    simonb 	/* Now clear reference and modify */
   1560      1.1    simonb 	ref = pmap_clear_reference(pg);
   1561      1.1    simonb 	mod = pmap_clear_modify(pg);
   1562      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1563      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1564      1.1    simonb 	       ref, mod);
   1565      1.1    simonb 
   1566      1.1    simonb 	/* Check it's properly cleared */
   1567      1.1    simonb 	ref = pmap_is_referenced(pg);
   1568      1.1    simonb 	mod = pmap_is_modified(pg);
   1569      1.1    simonb 	printf("Checking cleared page: ref %d, mod %d\n",
   1570      1.1    simonb 	       ref, mod);
   1571      1.1    simonb 
   1572      1.1    simonb 	/* Reference page */
   1573      1.1    simonb 	val = *loc;
   1574      1.1    simonb 
   1575      1.1    simonb 	ref = pmap_is_referenced(pg);
   1576      1.1    simonb 	mod = pmap_is_modified(pg);
   1577      1.1    simonb 	printf("Referenced page: ref %d, mod %d val %x\n",
   1578      1.1    simonb 	       ref, mod, val);
   1579      1.1    simonb 
   1580      1.1    simonb 	/* Now clear reference and modify */
   1581      1.1    simonb 	ref = pmap_clear_reference(pg);
   1582      1.1    simonb 	mod = pmap_clear_modify(pg);
   1583      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1584      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1585      1.1    simonb 	       ref, mod);
   1586  1.1.2.6  jdolecek 
   1587      1.1    simonb 	/* Modify page */
   1588      1.1    simonb 	*loc = 1;
   1589      1.1    simonb 
   1590      1.1    simonb 	ref = pmap_is_referenced(pg);
   1591      1.1    simonb 	mod = pmap_is_modified(pg);
   1592      1.1    simonb 	printf("Modified page: ref %d, mod %d\n",
   1593      1.1    simonb 	       ref, mod);
   1594      1.1    simonb 
   1595      1.1    simonb 	/* Now clear reference and modify */
   1596      1.1    simonb 	ref = pmap_clear_reference(pg);
   1597      1.1    simonb 	mod = pmap_clear_modify(pg);
   1598      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1599      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1600      1.1    simonb 	       ref, mod);
   1601      1.1    simonb 
   1602      1.1    simonb 	/* Check it's properly cleared */
   1603      1.1    simonb 	ref = pmap_is_referenced(pg);
   1604      1.1    simonb 	mod = pmap_is_modified(pg);
   1605      1.1    simonb 	printf("Checking cleared page: ref %d, mod %d\n",
   1606      1.1    simonb 	       ref, mod);
   1607      1.1    simonb 
   1608      1.1    simonb 	/* Modify page */
   1609      1.1    simonb 	*loc = 1;
   1610      1.1    simonb 
   1611      1.1    simonb 	ref = pmap_is_referenced(pg);
   1612      1.1    simonb 	mod = pmap_is_modified(pg);
   1613      1.1    simonb 	printf("Modified page: ref %d, mod %d\n",
   1614      1.1    simonb 	       ref, mod);
   1615      1.1    simonb 
   1616      1.1    simonb 	/* Check pmap_protect() */
   1617      1.1    simonb 	pmap_protect(pmap_kernel(), va, va+1, VM_PROT_READ);
   1618  1.1.2.2   thorpej 	pmap_update(pmap_kernel());
   1619      1.1    simonb 	ref = pmap_is_referenced(pg);
   1620      1.1    simonb 	mod = pmap_is_modified(pg);
   1621      1.1    simonb 	printf("pmap_protect(VM_PROT_READ): ref %d, mod %d\n",
   1622      1.1    simonb 	       ref, mod);
   1623      1.1    simonb 
   1624      1.1    simonb 	/* Now clear reference and modify */
   1625      1.1    simonb 	ref = pmap_clear_reference(pg);
   1626      1.1    simonb 	mod = pmap_clear_modify(pg);
   1627      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1628      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1629      1.1    simonb 	       ref, mod);
   1630      1.1    simonb 
   1631      1.1    simonb 	/* Reference page */
   1632      1.1    simonb 	val = *loc;
   1633      1.1    simonb 
   1634      1.1    simonb 	ref = pmap_is_referenced(pg);
   1635      1.1    simonb 	mod = pmap_is_modified(pg);
   1636      1.1    simonb 	printf("Referenced page: ref %d, mod %d val %x\n",
   1637      1.1    simonb 	       ref, mod, val);
   1638      1.1    simonb 
   1639      1.1    simonb 	/* Now clear reference and modify */
   1640      1.1    simonb 	ref = pmap_clear_reference(pg);
   1641      1.1    simonb 	mod = pmap_clear_modify(pg);
   1642      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1643      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1644      1.1    simonb 	       ref, mod);
   1645  1.1.2.6  jdolecek 
   1646      1.1    simonb 	/* Modify page */
   1647      1.1    simonb #if 0
   1648      1.1    simonb 	pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0);
   1649  1.1.2.2   thorpej 	pmap_update(pmap_kernel());
   1650      1.1    simonb #endif
   1651      1.1    simonb 	*loc = 1;
   1652      1.1    simonb 
   1653      1.1    simonb 	ref = pmap_is_referenced(pg);
   1654      1.1    simonb 	mod = pmap_is_modified(pg);
   1655      1.1    simonb 	printf("Modified page: ref %d, mod %d\n",
   1656      1.1    simonb 	       ref, mod);
   1657      1.1    simonb 
   1658      1.1    simonb 	/* Check pmap_protect() */
   1659      1.1    simonb 	pmap_protect(pmap_kernel(), va, va+1, VM_PROT_NONE);
   1660  1.1.2.2   thorpej 	pmap_update(pmap_kernel());
   1661      1.1    simonb 	ref = pmap_is_referenced(pg);
   1662      1.1    simonb 	mod = pmap_is_modified(pg);
   1663      1.1    simonb 	printf("pmap_protect(): ref %d, mod %d\n",
   1664      1.1    simonb 	       ref, mod);
   1665      1.1    simonb 
   1666      1.1    simonb 	/* Now clear reference and modify */
   1667      1.1    simonb 	ref = pmap_clear_reference(pg);
   1668      1.1    simonb 	mod = pmap_clear_modify(pg);
   1669      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1670      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1671      1.1    simonb 	       ref, mod);
   1672      1.1    simonb 
   1673      1.1    simonb 	/* Reference page */
   1674      1.1    simonb 	val = *loc;
   1675      1.1    simonb 
   1676      1.1    simonb 	ref = pmap_is_referenced(pg);
   1677      1.1    simonb 	mod = pmap_is_modified(pg);
   1678      1.1    simonb 	printf("Referenced page: ref %d, mod %d val %x\n",
   1679      1.1    simonb 	       ref, mod, val);
   1680      1.1    simonb 
   1681      1.1    simonb 	/* Now clear reference and modify */
   1682      1.1    simonb 	ref = pmap_clear_reference(pg);
   1683      1.1    simonb 	mod = pmap_clear_modify(pg);
   1684      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1685      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1686      1.1    simonb 	       ref, mod);
   1687  1.1.2.6  jdolecek 
   1688      1.1    simonb 	/* Modify page */
   1689      1.1    simonb #if 0
   1690      1.1    simonb 	pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0);
   1691  1.1.2.2   thorpej 	pmap_update(pmap_kernel());
   1692      1.1    simonb #endif
   1693      1.1    simonb 	*loc = 1;
   1694      1.1    simonb 
   1695      1.1    simonb 	ref = pmap_is_referenced(pg);
   1696      1.1    simonb 	mod = pmap_is_modified(pg);
   1697      1.1    simonb 	printf("Modified page: ref %d, mod %d\n",
   1698      1.1    simonb 	       ref, mod);
   1699      1.1    simonb 
   1700      1.1    simonb 	/* Check pmap_pag_protect() */
   1701      1.1    simonb 	pmap_page_protect(pg, VM_PROT_READ);
   1702      1.1    simonb 	ref = pmap_is_referenced(pg);
   1703      1.1    simonb 	mod = pmap_is_modified(pg);
   1704      1.1    simonb 	printf("pmap_page_protect(VM_PROT_READ): ref %d, mod %d\n",
   1705      1.1    simonb 	       ref, mod);
   1706      1.1    simonb 
   1707      1.1    simonb 	/* Now clear reference and modify */
   1708      1.1    simonb 	ref = pmap_clear_reference(pg);
   1709      1.1    simonb 	mod = pmap_clear_modify(pg);
   1710      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1711      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1712      1.1    simonb 	       ref, mod);
   1713      1.1    simonb 
   1714      1.1    simonb 	/* Reference page */
   1715      1.1    simonb 	val = *loc;
   1716      1.1    simonb 
   1717      1.1    simonb 	ref = pmap_is_referenced(pg);
   1718      1.1    simonb 	mod = pmap_is_modified(pg);
   1719      1.1    simonb 	printf("Referenced page: ref %d, mod %d val %x\n",
   1720      1.1    simonb 	       ref, mod, val);
   1721      1.1    simonb 
   1722      1.1    simonb 	/* Now clear reference and modify */
   1723      1.1    simonb 	ref = pmap_clear_reference(pg);
   1724      1.1    simonb 	mod = pmap_clear_modify(pg);
   1725      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1726      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1727      1.1    simonb 	       ref, mod);
   1728  1.1.2.6  jdolecek 
   1729      1.1    simonb 	/* Modify page */
   1730      1.1    simonb #if 0
   1731      1.1    simonb 	pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0);
   1732  1.1.2.2   thorpej 	pmap_update(pmap_kernel());
   1733      1.1    simonb #endif
   1734      1.1    simonb 	*loc = 1;
   1735      1.1    simonb 
   1736      1.1    simonb 	ref = pmap_is_referenced(pg);
   1737      1.1    simonb 	mod = pmap_is_modified(pg);
   1738      1.1    simonb 	printf("Modified page: ref %d, mod %d\n",
   1739      1.1    simonb 	       ref, mod);
   1740      1.1    simonb 
   1741      1.1    simonb 	/* Check pmap_pag_protect() */
   1742      1.1    simonb 	pmap_page_protect(pg, VM_PROT_NONE);
   1743      1.1    simonb 	ref = pmap_is_referenced(pg);
   1744      1.1    simonb 	mod = pmap_is_modified(pg);
   1745      1.1    simonb 	printf("pmap_page_protect(): ref %d, mod %d\n",
   1746      1.1    simonb 	       ref, mod);
   1747      1.1    simonb 
   1748      1.1    simonb 	/* Now clear reference and modify */
   1749      1.1    simonb 	ref = pmap_clear_reference(pg);
   1750      1.1    simonb 	mod = pmap_clear_modify(pg);
   1751      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1752      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1753      1.1    simonb 	       ref, mod);
   1754      1.1    simonb 
   1755      1.1    simonb 
   1756      1.1    simonb 	/* Reference page */
   1757      1.1    simonb 	val = *loc;
   1758      1.1    simonb 
   1759      1.1    simonb 	ref = pmap_is_referenced(pg);
   1760      1.1    simonb 	mod = pmap_is_modified(pg);
   1761      1.1    simonb 	printf("Referenced page: ref %d, mod %d val %x\n",
   1762      1.1    simonb 	       ref, mod, val);
   1763      1.1    simonb 
   1764      1.1    simonb 	/* Now clear reference and modify */
   1765      1.1    simonb 	ref = pmap_clear_reference(pg);
   1766      1.1    simonb 	mod = pmap_clear_modify(pg);
   1767      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1768      1.1    simonb 	       (void *)(u_long)va, (long)pa,
   1769      1.1    simonb 	       ref, mod);
   1770  1.1.2.6  jdolecek 
   1771      1.1    simonb 	/* Modify page */
   1772      1.1    simonb #if 0
   1773      1.1    simonb 	pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0);
   1774  1.1.2.2   thorpej 	pmap_update(pmap_kernel());
   1775      1.1    simonb #endif
   1776      1.1    simonb 	*loc = 1;
   1777      1.1    simonb 
   1778      1.1    simonb 	ref = pmap_is_referenced(pg);
   1779      1.1    simonb 	mod = pmap_is_modified(pg);
   1780      1.1    simonb 	printf("Modified page: ref %d, mod %d\n",
   1781      1.1    simonb 	       ref, mod);
   1782      1.1    simonb 
   1783      1.1    simonb 	/* Unmap page */
   1784      1.1    simonb 	pmap_remove(pmap_kernel(), va, va+1);
   1785  1.1.2.2   thorpej 	pmap_update(pmap_kernel());
   1786      1.1    simonb 	ref = pmap_is_referenced(pg);
   1787      1.1    simonb 	mod = pmap_is_modified(pg);
   1788      1.1    simonb 	printf("Unmapped page: ref %d, mod %d\n", ref, mod);
   1789      1.1    simonb 
   1790      1.1    simonb 	/* Now clear reference and modify */
   1791      1.1    simonb 	ref = pmap_clear_reference(pg);
   1792      1.1    simonb 	mod = pmap_clear_modify(pg);
   1793      1.1    simonb 	printf("Clearing page va %p pa %lx: ref %d, mod %d\n",
   1794      1.1    simonb 	       (void *)(u_long)va, (long)pa, ref, mod);
   1795      1.1    simonb 
   1796      1.1    simonb 	/* Check it's properly cleared */
   1797      1.1    simonb 	ref = pmap_is_referenced(pg);
   1798      1.1    simonb 	mod = pmap_is_modified(pg);
   1799      1.1    simonb 	printf("Checking cleared page: ref %d, mod %d\n",
   1800      1.1    simonb 	       ref, mod);
   1801      1.1    simonb 
   1802  1.1.2.6  jdolecek 	pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL,
   1803      1.1    simonb 		VM_PROT_ALL|PMAP_WIRED);
   1804      1.1    simonb 	uvm_km_free(kernel_map, (vaddr_t)va, NBPG);
   1805      1.1    simonb }
   1806      1.1    simonb #endif
   1807