405 lines
16 KiB
C
405 lines
16 KiB
C
/* $NetBSD: pmap.h,v 1.70 2003/08/16 19:21:23 pk Exp $ */
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/*
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* Copyright (c) 1996
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* The President and Fellows of Harvard College. All rights reserved.
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* Copyright (c) 1992, 1993
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* The Regents of the University of California. All rights reserved.
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*
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* This software was developed by the Computer Systems Engineering group
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* at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and
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* contributed to Berkeley.
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*
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* All advertising materials mentioning features or use of this software
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* must display the following acknowledgement:
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* This product includes software developed by Aaron Brown and
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* Harvard University.
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* This product includes software developed by the University of
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* California, Lawrence Berkeley Laboratory.
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*
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* @InsertRedistribution@
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* 3. All advertising materials mentioning features or use of this software
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* must display the following acknowledgement:
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* This product includes software developed by Aaron Brown and
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* Harvard University.
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* This product includes software developed by the University of
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* California, Berkeley and its contributors.
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* 4. Neither the name of the University nor the names of its contributors
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* may be used to endorse or promote products derived from this software
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* without specific prior written permission.
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*
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* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
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* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
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* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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* SUCH DAMAGE.
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*
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* @(#)pmap.h 8.1 (Berkeley) 6/11/93
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*/
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#ifndef _SPARC_PMAP_H_
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#define _SPARC_PMAP_H_
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#if defined(_KERNEL_OPT)
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#include "opt_sparc_arch.h"
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#endif
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#include <machine/pte.h>
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/*
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* Pmap structure.
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*
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* The pmap structure really comes in two variants, one---a single
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* instance---for kernel virtual memory and the other---up to nproc
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* instances---for user virtual memory. Unfortunately, we have to mash
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* both into the same structure. Fortunately, they are almost the same.
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*
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* The kernel begins at 0xf8000000 and runs to 0xffffffff (although
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* some of this is not actually used). Kernel space, including DVMA
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* space (for now?), is mapped identically into all user contexts.
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* There is no point in duplicating this mapping in each user process
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* so they do not appear in the user structures.
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*
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* User space begins at 0x00000000 and runs through 0x1fffffff,
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* then has a `hole', then resumes at 0xe0000000 and runs until it
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* hits the kernel space at 0xf8000000. This can be mapped
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* contiguously by ignorning the top two bits and pretending the
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* space goes from 0 to 37ffffff. Typically the lower range is
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* used for text+data and the upper for stack, but the code here
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* makes no such distinction.
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*
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* Since each virtual segment covers 256 kbytes, the user space
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* requires 3584 segments, while the kernel (including DVMA) requires
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* only 512 segments.
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*
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*
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** FOR THE SUN4/SUN4C
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*
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* The segment map entry for virtual segment vseg is offset in
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* pmap->pm_rsegmap by 0 if pmap is not the kernel pmap, or by
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* NUSEG if it is. We keep a pointer called pmap->pm_segmap
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* pre-offset by this value. pmap->pm_segmap thus contains the
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* values to be loaded into the user portion of the hardware segment
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* map so as to reach the proper PMEGs within the MMU. The kernel
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* mappings are `set early' and are always valid in every context
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* (every change is always propagated immediately).
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*
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* The PMEGs within the MMU are loaded `on demand'; when a PMEG is
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* taken away from context `c', the pmap for context c has its
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* corresponding pm_segmap[vseg] entry marked invalid (the MMU segment
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* map entry is also made invalid at the same time). Thus
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* pm_segmap[vseg] is the `invalid pmeg' number (127 or 511) whenever
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* the corresponding PTEs are not actually in the MMU. On the other
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* hand, pm_pte[vseg] is NULL only if no pages in that virtual segment
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* are in core; otherwise it points to a copy of the 32 or 64 PTEs that
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* must be loaded in the MMU in order to reach those pages.
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* pm_npte[vseg] counts the number of valid pages in each vseg.
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*
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* XXX performance: faster to count valid bits?
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*
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* The kernel pmap cannot malloc() PTEs since malloc() will sometimes
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* allocate a new virtual segment. Since kernel mappings are never
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* `stolen' out of the MMU, we just keep all its PTEs there, and have
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* no software copies. Its mmu entries are nonetheless kept on lists
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* so that the code that fiddles with mmu lists has something to fiddle.
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*
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** FOR THE SUN4M/SUN4D
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*
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* On this architecture, the virtual-to-physical translation (page) tables
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* are *not* stored within the MMU as they are in the earlier Sun architect-
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* ures; instead, they are maintained entirely within physical memory (there
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* is a TLB cache to prevent the high performance hit from keeping all page
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* tables in core). Thus there is no need to dynamically allocate PMEGs or
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* SMEGs; only contexts must be shared.
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*
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* We maintain two parallel sets of tables: one is the actual MMU-edible
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* hierarchy of page tables in allocated kernel memory; these tables refer
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* to each other by physical address pointers in SRMMU format (thus they
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* are not very useful to the kernel's management routines). The other set
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* of tables is similar to those used for the Sun4/100's 3-level MMU; it
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* is a hierarchy of regmap and segmap structures which contain kernel virtual
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* pointers to each other. These must (unfortunately) be kept in sync.
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*
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*/
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#define NKREG ((int)((-(unsigned)KERNBASE) / NBPRG)) /* i.e., 8 */
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#define NUREG (256 - NKREG) /* i.e., 248 */
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TAILQ_HEAD(mmuhd,mmuentry);
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/*
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* data appearing in both user and kernel pmaps
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*
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* note: if we want the same binaries to work on the 4/4c and 4m, we have to
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* include the fields for both to make sure that the struct kproc
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* is the same size.
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*/
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struct pmap {
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union ctxinfo *pm_ctx; /* current context, if any */
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int pm_ctxnum; /* current context's number */
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u_int pm_cpuset; /* CPU's this pmap has context on */
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struct simplelock pm_lock; /* spinlock */
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int pm_refcount; /* just what it says */
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struct mmuhd pm_reglist; /* MMU regions on this pmap (4/4c) */
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struct mmuhd pm_seglist; /* MMU segments on this pmap (4/4c) */
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struct regmap *pm_regmap;
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int **pm_reg_ptps; /* SRMMU-edible region tables for 4m */
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int *pm_reg_ptps_pa;/* _Physical_ address of pm_reg_ptps */
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int pm_gap_start; /* Starting with this vreg there's */
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int pm_gap_end; /* no valid mapping until here */
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struct pmap_statistics pm_stats; /* pmap statistics */
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u_int pm_flags;
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#define PMAP_USERCACHECLEAN 1
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};
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struct regmap {
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struct segmap *rg_segmap; /* point to NSGPRG PMEGs */
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int *rg_seg_ptps; /* SRMMU-edible segment tables (NULL
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* indicates invalid region (4m) */
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smeg_t rg_smeg; /* the MMU region number (4c) */
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u_char rg_nsegmap; /* number of valid PMEGS */
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};
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struct segmap {
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int *sg_pte; /* points to NPTESG PTEs */
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pmeg_t sg_pmeg; /* the MMU segment number (4c) */
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u_char sg_npte; /* number of valid PTEs per seg */
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int8_t sg_nwired; /* number of wired pages */
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};
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typedef struct pmap *pmap_t;
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#if 0
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struct kvm_cpustate {
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int kvm_npmemarr;
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struct memarr kvm_pmemarr[MA_SIZE];
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int kvm_seginval; /* [4,4c] */
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struct segmap kvm_segmap_store[NKREG*NSEGRG]; /* [4,4c] */
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}/*not yet used*/;
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#endif
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#ifdef _KERNEL
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#define PMAP_NULL ((pmap_t)0)
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extern struct pmap kernel_pmap_store;
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/*
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* Bounds on managed physical addresses. Used by (MD) users
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* of uvm_pglistalloc() to provide search hints.
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*/
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extern paddr_t vm_first_phys, vm_last_phys;
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extern psize_t vm_num_phys;
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/*
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* Since PTEs also contain type bits, we have to have some way
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* to tell pmap_enter `this is an IO page' or `this is not to
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* be cached'. Since physical addresses are always aligned, we
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* can do this with the low order bits.
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*
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* The ordering below is important: PMAP_PGTYPE << PG_TNC must give
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* exactly the PG_NC and PG_TYPE bits.
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*/
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#define PMAP_OBIO 1 /* tells pmap_enter to use PG_OBIO */
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#define PMAP_VME16 2 /* etc */
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#define PMAP_VME32 3 /* etc */
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#define PMAP_NC 4 /* tells pmap_enter to set PG_NC */
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#define PMAP_TNC_4 7 /* mask to get PG_TYPE & PG_NC */
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#define PMAP_T2PTE_4(x) (((x) & PMAP_TNC_4) << PG_TNC_SHIFT)
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#define PMAP_IOENC_4(io) (io)
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/*
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* On a SRMMU machine, the iospace is encoded in bits [3-6] of the
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* physical address passed to pmap_enter().
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*/
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#define PMAP_TYPE_SRMMU 0x78 /* mask to get 4m page type */
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#define PMAP_PTESHFT_SRMMU 25 /* right shift to put type in pte */
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#define PMAP_SHFT_SRMMU 3 /* left shift to extract iospace */
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#define PMAP_TNC_SRMMU 127 /* mask to get PG_TYPE & PG_NC */
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/*#define PMAP_IOC 0x00800000 -* IO cacheable, NOT shifted */
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#define PMAP_T2PTE_SRMMU(x) (((x) & PMAP_TYPE_SRMMU) << PMAP_PTESHFT_SRMMU)
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#define PMAP_IOENC_SRMMU(io) ((io) << PMAP_SHFT_SRMMU)
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/* Encode IO space for pmap_enter() */
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#define PMAP_IOENC(io) (CPU_HAS_SRMMU ? PMAP_IOENC_SRMMU(io) \
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: PMAP_IOENC_4(io))
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int pmap_dumpsize __P((void));
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int pmap_dumpmmu __P((int (*)__P((dev_t, daddr_t, caddr_t, size_t)),
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daddr_t));
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#define pmap_kernel() (&kernel_pmap_store)
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#define pmap_resident_count(pmap) pmap_count_ptes(pmap)
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#define PMAP_PREFER(fo, ap) pmap_prefer((fo), (ap))
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#define PMAP_EXCLUDE_DECLS /* tells MI pmap.h *not* to include decls */
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/* FUNCTION DECLARATIONS FOR COMMON PMAP MODULE */
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void pmap_activate __P((struct lwp *));
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void pmap_deactivate __P((struct lwp *));
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void pmap_bootstrap __P((int nmmu, int nctx, int nregion));
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int pmap_count_ptes __P((struct pmap *));
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void pmap_prefer __P((vaddr_t, vaddr_t *));
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int pmap_pa_exists __P((paddr_t));
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void pmap_unwire __P((pmap_t, vaddr_t));
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void pmap_collect __P((pmap_t));
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void pmap_copy __P((pmap_t, pmap_t, vaddr_t, vsize_t, vaddr_t));
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pmap_t pmap_create __P((void));
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void pmap_destroy __P((pmap_t));
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void pmap_init __P((void));
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vaddr_t pmap_map __P((vaddr_t, paddr_t, paddr_t, int));
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paddr_t pmap_phys_address __P((int));
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void pmap_reference __P((pmap_t));
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void pmap_remove __P((pmap_t, vaddr_t, vaddr_t));
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#define pmap_update(pmap) /* nothing (yet) */
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void pmap_virtual_space __P((vaddr_t *, vaddr_t *));
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#ifdef PMAP_GROWKERNEL
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vaddr_t pmap_growkernel __P((vaddr_t));
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#endif
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void pmap_redzone __P((void));
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void kvm_uncache __P((caddr_t, int));
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struct user;
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int mmu_pagein __P((struct pmap *pm, vaddr_t, int));
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void pmap_writetext __P((unsigned char *, int));
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void pmap_globalize_boot_cpuinfo __P((struct cpu_info *));
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void pmap_remove_all(struct pmap *pm);
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/* SUN4/SUN4C SPECIFIC DECLARATIONS */
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#if defined(SUN4) || defined(SUN4C)
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boolean_t pmap_clear_modify4_4c __P((struct vm_page *));
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boolean_t pmap_clear_reference4_4c __P((struct vm_page *));
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void pmap_copy_page4_4c __P((paddr_t, paddr_t));
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int pmap_enter4_4c __P((pmap_t, vaddr_t, paddr_t, vm_prot_t,
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int));
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boolean_t pmap_extract4_4c __P((pmap_t, vaddr_t, paddr_t *));
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boolean_t pmap_is_modified4_4c __P((struct vm_page *));
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boolean_t pmap_is_referenced4_4c __P((struct vm_page *));
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void pmap_kenter_pa4_4c __P((vaddr_t, paddr_t, vm_prot_t));
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void pmap_kremove4_4c __P((vaddr_t, vsize_t));
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void pmap_kprotect4_4c __P((vaddr_t, vsize_t, vm_prot_t));
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void pmap_page_protect4_4c __P((struct vm_page *, vm_prot_t));
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void pmap_protect4_4c __P((pmap_t, vaddr_t, vaddr_t, vm_prot_t));
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void pmap_zero_page4_4c __P((paddr_t));
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#endif /* defined SUN4 || defined SUN4C */
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/* SIMILAR DECLARATIONS FOR SUN4M/SUN4D MODULE */
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#if defined(SUN4M) || defined(SUN4D)
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boolean_t pmap_clear_modify4m __P((struct vm_page *));
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boolean_t pmap_clear_reference4m __P((struct vm_page *));
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void pmap_copy_page4m __P((paddr_t, paddr_t));
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void pmap_copy_page_viking_mxcc(paddr_t, paddr_t);
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void pmap_copy_page_hypersparc(paddr_t, paddr_t);
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int pmap_enter4m __P((pmap_t, vaddr_t, paddr_t, vm_prot_t, int));
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boolean_t pmap_extract4m __P((pmap_t, vaddr_t, paddr_t *));
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boolean_t pmap_is_modified4m __P((struct vm_page *));
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boolean_t pmap_is_referenced4m __P((struct vm_page *));
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void pmap_kenter_pa4m __P((vaddr_t, paddr_t, vm_prot_t));
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void pmap_kremove4m __P((vaddr_t, vsize_t));
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void pmap_kprotect4m __P((vaddr_t, vsize_t, vm_prot_t));
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void pmap_page_protect4m __P((struct vm_page *, vm_prot_t));
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void pmap_protect4m __P((pmap_t, vaddr_t, vaddr_t, vm_prot_t));
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void pmap_zero_page4m __P((paddr_t));
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void pmap_zero_page_viking_mxcc(paddr_t);
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void pmap_zero_page_hypersparc(paddr_t);
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#endif /* defined SUN4M || defined SUN4D */
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#if !(defined(SUN4M) || defined(SUN4D)) && (defined(SUN4) || defined(SUN4C))
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#define pmap_clear_modify pmap_clear_modify4_4c
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#define pmap_clear_reference pmap_clear_reference4_4c
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#define pmap_enter pmap_enter4_4c
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#define pmap_extract pmap_extract4_4c
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#define pmap_is_modified pmap_is_modified4_4c
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#define pmap_is_referenced pmap_is_referenced4_4c
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#define pmap_kenter_pa pmap_kenter_pa4_4c
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#define pmap_kremove pmap_kremove4_4c
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#define pmap_kprotect pmap_kprotect4_4c
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#define pmap_page_protect pmap_page_protect4_4c
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#define pmap_protect pmap_protect4_4c
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#elif (defined(SUN4M) || defined(SUN4D)) && !(defined(SUN4) || defined(SUN4C))
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#define pmap_clear_modify pmap_clear_modify4m
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#define pmap_clear_reference pmap_clear_reference4m
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#define pmap_enter pmap_enter4m
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#define pmap_extract pmap_extract4m
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#define pmap_is_modified pmap_is_modified4m
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#define pmap_is_referenced pmap_is_referenced4m
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#define pmap_kenter_pa pmap_kenter_pa4m
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#define pmap_kremove pmap_kremove4m
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#define pmap_kprotect pmap_kprotect4m
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#define pmap_page_protect pmap_page_protect4m
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#define pmap_protect pmap_protect4m
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#else /* must use function pointers */
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extern boolean_t(*pmap_clear_modify_p) __P((struct vm_page *));
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extern boolean_t(*pmap_clear_reference_p) __P((struct vm_page *));
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extern int (*pmap_enter_p) __P((pmap_t, vaddr_t, paddr_t, vm_prot_t,
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int));
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extern boolean_t (*pmap_extract_p) __P((pmap_t, vaddr_t, paddr_t *));
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extern boolean_t(*pmap_is_modified_p) __P((struct vm_page *));
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extern boolean_t(*pmap_is_referenced_p) __P((struct vm_page *));
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extern void (*pmap_kenter_pa_p) __P((vaddr_t, paddr_t, vm_prot_t));
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extern void (*pmap_kremove_p) __P((vaddr_t, vsize_t));
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extern void (*pmap_kprotect_p) __P((vaddr_t, vsize_t, vm_prot_t));
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extern void (*pmap_page_protect_p) __P((struct vm_page *, vm_prot_t));
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extern void (*pmap_protect_p) __P((pmap_t, vaddr_t, vaddr_t, vm_prot_t));
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#define pmap_clear_modify (*pmap_clear_modify_p)
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#define pmap_clear_reference (*pmap_clear_reference_p)
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#define pmap_enter (*pmap_enter_p)
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#define pmap_extract (*pmap_extract_p)
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#define pmap_is_modified (*pmap_is_modified_p)
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#define pmap_is_referenced (*pmap_is_referenced_p)
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#define pmap_kenter_pa (*pmap_kenter_pa_p)
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#define pmap_kremove (*pmap_kremove_p)
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#define pmap_kprotect (*pmap_kprotect_p)
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#define pmap_page_protect (*pmap_page_protect_p)
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#define pmap_protect (*pmap_protect_p)
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#endif
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/* pmap_{zero,copy}_page() may be assisted by specialized hardware */
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#define pmap_zero_page (*cpuinfo.zero_page)
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#define pmap_copy_page (*cpuinfo.copy_page)
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#if defined(SUN4M) || defined(SUN4D)
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/*
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* Macros which implement SRMMU TLB flushing/invalidation
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*/
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#define tlb_flush_page_real(va) \
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sta(((vaddr_t)(va) & 0xfffff000) | ASI_SRMMUFP_L3, ASI_SRMMUFP, 0)
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#define tlb_flush_segment_real(va) \
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sta(((vaddr_t)(va) & 0xfffc0000) | ASI_SRMMUFP_L2, ASI_SRMMUFP, 0)
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#define tlb_flush_region_real(va) \
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sta(((vaddr_t)(va) & 0xff000000) | ASI_SRMMUFP_L1, ASI_SRMMUFP, 0)
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#define tlb_flush_context_real() sta(ASI_SRMMUFP_L0, ASI_SRMMUFP, 0)
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#define tlb_flush_all_real() sta(ASI_SRMMUFP_LN, ASI_SRMMUFP, 0)
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#endif /* SUN4M || SUN4D */
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#endif /* _KERNEL */
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#endif /* _SPARC_PMAP_H_ */
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