sys/uvm/uvm_physseg.c

1.6.2.2  pgoyette /* $NetBSD: uvm_physseg.c,v 1.6.2.2 2017/01/07 08:56:53 pgoyette Exp $ */
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * Copyright (c) 1997 Charles D. Cranor and Washington University.
1.6.2.2  pgoyette  * Copyright (c) 1991, 1993, The Regents of the University of California.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * All rights reserved.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * This code is derived from software contributed to Berkeley by
1.6.2.2  pgoyette  * The Mach Operating System project at Carnegie-Mellon University.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * Redistribution and use in source and binary forms, with or without
1.6.2.2  pgoyette  * modification, are permitted provided that the following conditions
1.6.2.2  pgoyette  * are met:
1.6.2.2  pgoyette  * 1. Redistributions of source code must retain the above copyright
1.6.2.2  pgoyette  *    notice, this list of conditions and the following disclaimer.
1.6.2.2  pgoyette  * 2. Redistributions in binary form must reproduce the above copyright
1.6.2.2  pgoyette  *    notice, this list of conditions and the following disclaimer in the
1.6.2.2  pgoyette  *    documentation and/or other materials provided with the distribution.
1.6.2.2  pgoyette  * 3. Neither the name of the University nor the names of its contributors
1.6.2.2  pgoyette  *    may be used to endorse or promote products derived from this software
1.6.2.2  pgoyette  *    without specific prior written permission.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
1.6.2.2  pgoyette  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.6.2.2  pgoyette  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.6.2.2  pgoyette  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
1.6.2.2  pgoyette  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.6.2.2  pgoyette  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.6.2.2  pgoyette  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.6.2.2  pgoyette  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.6.2.2  pgoyette  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.6.2.2  pgoyette  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.6.2.2  pgoyette  * SUCH DAMAGE.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  *	@(#)vm_page.h   7.3 (Berkeley) 4/21/91
1.6.2.2  pgoyette  * from: Id: uvm_page.h,v 1.1.2.6 1998/02/04 02:31:42 chuck Exp
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * Copyright (c) 1987, 1990 Carnegie-Mellon University.
1.6.2.2  pgoyette  * All rights reserved.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * Permission to use, copy, modify and distribute this software and
1.6.2.2  pgoyette  * its documentation is hereby granted, provided that both the copyright
1.6.2.2  pgoyette  * notice and this permission notice appear in all copies of the
1.6.2.2  pgoyette  * software, derivative works or modified versions, and any portions
1.6.2.2  pgoyette  * thereof, and that both notices appear in supporting documentation.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
1.6.2.2  pgoyette  * CONDITION.  CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND
1.6.2.2  pgoyette  * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * Carnegie Mellon requests users of this software to return to
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  *  Software Distribution Coordinator  or  Software.Distribution (at) CS.CMU.EDU
1.6.2.2  pgoyette  *  School of Computer Science
1.6.2.2  pgoyette  *  Carnegie Mellon University
1.6.2.2  pgoyette  *  Pittsburgh PA 15213-3890
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * any improvements or extensions that they make and grant Carnegie the
1.6.2.2  pgoyette  * rights to redistribute these changes.
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * Consolidated API from uvm_page.c and others.
1.6.2.2  pgoyette  * Consolidated and designed by Cherry G. Mathew <cherry (at) zyx.in>
1.6.2.2  pgoyette  * rbtree(3) backing implementation by:
1.6.2.2  pgoyette  * Santhosh N. Raju <santhosh.raju (at) gmail.com>
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette
1.6.2.2  pgoyette #ifdef _KERNEL_OPT
1.6.2.2  pgoyette #include "opt_uvm.h"
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette
1.6.2.2  pgoyette #include <sys/param.h>
1.6.2.2  pgoyette #include <sys/types.h>
1.6.2.2  pgoyette #include <sys/extent.h>
1.6.2.2  pgoyette #include <sys/kmem.h>
1.6.2.2  pgoyette
1.6.2.2  pgoyette #include <uvm/uvm.h>
1.6.2.2  pgoyette #include <uvm/uvm_page.h>
1.6.2.2  pgoyette #include <uvm/uvm_param.h>
1.6.2.2  pgoyette #include <uvm/uvm_pdpolicy.h>
1.6.2.2  pgoyette #include <uvm/uvm_physseg.h>
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * uvm_physseg: describes one segment of physical memory
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette struct uvm_physseg {
1.6.2.2  pgoyette 	struct  rb_node rb_node;	/* tree information */
1.6.2.2  pgoyette 	paddr_t	start;			/* PF# of first page in segment */
1.6.2.2  pgoyette 	paddr_t	end;			/* (PF# of last page in segment) + 1 */
1.6.2.2  pgoyette 	paddr_t	avail_start;		/* PF# of first free page in segment */
1.6.2.2  pgoyette 	paddr_t	avail_end;		/* (PF# of last free page in segment) +1  */
1.6.2.2  pgoyette 	struct	vm_page *pgs;		/* vm_page structures (from start) */
1.6.2.2  pgoyette 	struct  extent *ext;		/* extent(9) structure to manage pgs[] */
1.6.2.2  pgoyette 	int	free_list;		/* which free list they belong on */
1.6.2.2  pgoyette 	u_int	start_hint;		/* start looking for free pages here */
1.6.2.2  pgoyette 					/* protected by uvm_fpageqlock */
1.6.2.2  pgoyette #ifdef __HAVE_PMAP_PHYSSEG
1.6.2.2  pgoyette 	struct	pmap_physseg pmseg;	/* pmap specific (MD) data */
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette };
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * These functions are reserved for uvm(9) internal use and are not
1.6.2.2  pgoyette  * exported in the header file uvm_physseg.h
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * Thus they are redefined here.
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette void uvm_physseg_init_seg(uvm_physseg_t, struct vm_page *);
1.6.2.2  pgoyette void uvm_physseg_seg_chomp_slab(uvm_physseg_t, struct vm_page *, size_t);
1.6.2.2  pgoyette
1.6.2.2  pgoyette /* returns a pgs array */
1.6.2.2  pgoyette struct vm_page *uvm_physseg_seg_alloc_from_slab(uvm_physseg_t, size_t);
1.6.2.2  pgoyette
1.6.2.2  pgoyette #if defined(UVM_HOTPLUG) /* rbtree impementation */
1.6.2.2  pgoyette
1.6.2.2  pgoyette #define		HANDLE_TO_PHYSSEG_NODE(h)	((struct uvm_physseg *)(h))
1.6.2.2  pgoyette #define		PHYSSEG_NODE_TO_HANDLE(u)	((uvm_physseg_t)(u))
1.6.2.2  pgoyette
1.6.2.2  pgoyette struct uvm_physseg_graph {
1.6.2.2  pgoyette 	struct rb_tree rb_tree;		/* Tree for entries */
1.6.2.2  pgoyette 	int            nentries;	/* Number of entries */
1.6.2.2  pgoyette };
1.6.2.2  pgoyette
1.6.2.2  pgoyette static struct uvm_physseg_graph uvm_physseg_graph;
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * Note on kmem(9) allocator usage:
1.6.2.2  pgoyette  * We take the conservative approach that plug/unplug are allowed to
1.6.2.2  pgoyette  * fail in high memory stress situations.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * We want to avoid re-entrant situations in which one plug/unplug
1.6.2.2  pgoyette  * operation is waiting on a previous one to complete, since this
1.6.2.2  pgoyette  * makes the design more complicated than necessary.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * We may review this and change its behaviour, once the use cases
1.6.2.2  pgoyette  * become more obvious.
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * Special alloc()/free() functions for boot time support:
1.6.2.2  pgoyette  * We assume that alloc() at boot time is only for new 'vm_physseg's
1.6.2.2  pgoyette  * This allows us to use a static array for memory allocation at boot
1.6.2.2  pgoyette  * time. Thus we avoid using kmem(9) which is not ready at this point
1.6.2.2  pgoyette  * in boot.
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * After kmem(9) is ready, we use it. We currently discard any free()s
1.6.2.2  pgoyette  * to this static array, since the size is small enough to be a
1.6.2.2  pgoyette  * trivial waste on all architectures we run on.
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette
1.6.2.2  pgoyette static size_t nseg = 0;
1.6.2.2  pgoyette static struct uvm_physseg uvm_physseg[VM_PHYSSEG_MAX];
1.6.2.2  pgoyette
1.6.2.2  pgoyette static void *
1.6.2.2  pgoyette uvm_physseg_alloc(size_t sz)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * During boot time, we only support allocating vm_physseg
1.6.2.2  pgoyette 	 * entries from the static array.
1.6.2.2  pgoyette 	 * We need to assert for this.
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (__predict_false(uvm.page_init_done == false)) {
1.6.2.2  pgoyette 		if (sz % sizeof(struct uvm_physseg))
1.6.2.2  pgoyette 			panic("%s: tried to alloc size other than multiple"
1.6.2.2  pgoyette 			    "of struct uvm_physseg at boot\n", __func__);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		size_t n = sz / sizeof(struct uvm_physseg);
1.6.2.2  pgoyette 		nseg += n;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		KASSERT(nseg > 0 && nseg <= VM_PHYSSEG_MAX);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		return &uvm_physseg[nseg - n];
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return kmem_zalloc(sz, KM_NOSLEEP);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette static void
1.6.2.2  pgoyette uvm_physseg_free(void *p, size_t sz)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * This is a bit tricky. We do allow simulation of free()
1.6.2.2  pgoyette 	 * during boot (for eg: when MD code is "steal"ing memory,
1.6.2.2  pgoyette 	 * and the segment has been exhausted (and thus needs to be
1.6.2.2  pgoyette 	 * free() - ed.
1.6.2.2  pgoyette 	 * free() also complicates things because we leak the
1.6.2.2  pgoyette 	 * free(). Therefore calling code can't assume that free()-ed
1.6.2.2  pgoyette 	 * memory is available for alloc() again, at boot time.
1.6.2.2  pgoyette 	 *
1.6.2.2  pgoyette 	 * Thus we can't explicitly disallow free()s during
1.6.2.2  pgoyette 	 * boot time. However, the same restriction for alloc()
1.6.2.2  pgoyette 	 * applies to free(). We only allow uvm_physseg related free()s
1.6.2.2  pgoyette 	 * via this function during boot time.
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (__predict_false(uvm.page_init_done == false)) {
1.6.2.2  pgoyette 		if (sz % sizeof(struct uvm_physseg))
1.6.2.2  pgoyette 			panic("%s: tried to free size other than struct uvm_physseg"
1.6.2.2  pgoyette 			    "at boot\n", __func__);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * Could have been in a single if(){} block - split for
1.6.2.2  pgoyette 	 * clarity
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if ((struct uvm_physseg *)p >= uvm_physseg &&
1.6.2.2  pgoyette 	    (struct uvm_physseg *)p < (uvm_physseg + VM_PHYSSEG_MAX)) {
1.6.2.2  pgoyette 		if (sz % sizeof(struct uvm_physseg))
1.6.2.2  pgoyette 			panic("%s: tried to free() other than struct uvm_physseg"
1.6.2.2  pgoyette 			    "from static array\n", __func__);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		if ((sz / sizeof(struct uvm_physseg)) >= VM_PHYSSEG_MAX)
1.6.2.2  pgoyette 			panic("%s: tried to free() the entire static array!", __func__);
1.6.2.2  pgoyette 		return; /* Nothing to free */
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	kmem_free(p, sz);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette /* XXX: Multi page size */
1.6.2.2  pgoyette bool
1.6.2.2  pgoyette uvm_physseg_plug(paddr_t pfn, size_t pages, uvm_physseg_t *psp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	int preload;
1.6.2.2  pgoyette 	size_t slabpages;
1.6.2.2  pgoyette 	struct uvm_physseg *ps, *current_ps = NULL;
1.6.2.2  pgoyette 	struct vm_page *slab = NULL, *pgs = NULL;
1.6.2.2  pgoyette
1.6.2.2  pgoyette #ifdef DEBUG
1.6.2.2  pgoyette 	paddr_t off;
1.6.2.2  pgoyette 	uvm_physseg_t upm;
1.6.2.2  pgoyette 	upm = uvm_physseg_find(pfn, &off);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (ps != NULL) /* XXX; do we allow "update" plugs ? */
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * do we have room?
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps = uvm_physseg_alloc(sizeof (struct uvm_physseg));
1.6.2.2  pgoyette 	if (ps == NULL) {
1.6.2.2  pgoyette 		printf("uvm_page_physload: unable to load physical memory "
1.6.2.2  pgoyette 		    "segment\n");
1.6.2.2  pgoyette 		printf("\t%d segments allocated, ignoring 0x%"PRIxPADDR" -> 0x%"PRIxPADDR"\n",
1.6.2.2  pgoyette 		    VM_PHYSSEG_MAX, pfn, pfn + pages + 1);
1.6.2.2  pgoyette 		printf("\tincrease VM_PHYSSEG_MAX\n");
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* span init */
1.6.2.2  pgoyette 	ps->start = pfn;
1.6.2.2  pgoyette 	ps->end = pfn + pages;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * XXX: Ugly hack because uvmexp.npages accounts for only
1.6.2.2  pgoyette 	 * those pages in the segment included below as well - this
1.6.2.2  pgoyette 	 * should be legacy and removed.
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps->avail_start = ps->start;
1.6.2.2  pgoyette 	ps->avail_end = ps->end;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * check to see if this is a "preload" (i.e. uvm_page_init hasn't been
1.6.2.2  pgoyette 	 * called yet, so kmem is not available).
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	preload = 1; /* We are going to assume it is a preload */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	RB_TREE_FOREACH(current_ps, &(uvm_physseg_graph.rb_tree)) {
1.6.2.2  pgoyette 		/* If there are non NULL pages then we are not in a preload */
1.6.2.2  pgoyette 		if (current_ps->pgs != NULL) {
1.6.2.2  pgoyette 			preload = 0;
1.6.2.2  pgoyette 			/* Try to scavenge from earlier unplug()s. */
1.6.2.2  pgoyette 			pgs = uvm_physseg_seg_alloc_from_slab(current_ps, pages);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 			if (pgs != NULL) {
1.6.2.2  pgoyette 				break;
1.6.2.2  pgoyette 			}
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * if VM is already running, attempt to kmem_alloc vm_page structures
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (!preload) {
1.6.2.2  pgoyette 		if (pgs == NULL) { /* Brand new */
1.6.2.2  pgoyette 			/* Iteratively try alloc down from uvmexp.npages */
1.6.2.2  pgoyette 			for (slabpages = (size_t) uvmexp.npages; slabpages >= pages; slabpages--) {
1.6.2.2  pgoyette 				slab = kmem_zalloc(sizeof *pgs * (long unsigned int)slabpages, KM_NOSLEEP);
1.6.2.2  pgoyette 				if (slab != NULL)
1.6.2.2  pgoyette 					break;
1.6.2.2  pgoyette 			}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 			if (slab == NULL) {
1.6.2.2  pgoyette 				uvm_physseg_free(ps, sizeof(struct uvm_physseg));
1.6.2.2  pgoyette 				return false;
1.6.2.2  pgoyette 			}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 			uvm_physseg_seg_chomp_slab(ps, slab, (size_t) slabpages);
1.6.2.2  pgoyette 			/* We allocate enough for this plug */
1.6.2.2  pgoyette 			pgs = uvm_physseg_seg_alloc_from_slab(ps, pages);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 			if (pgs == NULL) {
1.6.2.2  pgoyette 				printf("unable to uvm_physseg_seg_alloc_from_slab() from backend\n");
1.6.2.2  pgoyette 				return false;
1.6.2.2  pgoyette 			}
1.6.2.2  pgoyette 		} else {
1.6.2.2  pgoyette 			/* Reuse scavenged extent */
1.6.2.2  pgoyette 			ps->ext = current_ps->ext;
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		physmem += pages;
1.6.2.2  pgoyette 		uvmpdpol_reinit();
1.6.2.2  pgoyette 	} else { /* Boot time - see uvm_page.c:uvm_page_init() */
1.6.2.2  pgoyette 		pgs = NULL;
1.6.2.2  pgoyette 		ps->pgs = pgs;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * now insert us in the proper place in uvm_physseg_graph.rb_tree
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	current_ps = rb_tree_insert_node(&(uvm_physseg_graph.rb_tree), ps);
1.6.2.2  pgoyette 	if (current_ps != ps) {
1.6.2.2  pgoyette 		panic("uvm_page_physload: Duplicate address range detected!");
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette 	uvm_physseg_graph.nentries++;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * uvm_pagefree() requires the PHYS_TO_VM_PAGE(pgs[i]) on the
1.6.2.2  pgoyette 	 * newly allocated pgs[] to return the correct value. This is
1.6.2.2  pgoyette 	 * a bit of a chicken and egg problem, since it needs
1.6.2.2  pgoyette 	 * uvm_physseg_find() to succeed. For this, the node needs to
1.6.2.2  pgoyette 	 * be inserted *before* uvm_physseg_init_seg() happens.
1.6.2.2  pgoyette 	 *
1.6.2.2  pgoyette 	 * During boot, this happens anyway, since
1.6.2.2  pgoyette 	 * uvm_physseg_init_seg() is called later on and separately
1.6.2.2  pgoyette 	 * from uvm_page.c:uvm_page_init().
1.6.2.2  pgoyette 	 * In the case of hotplug we need to ensure this.
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (__predict_true(!preload))
1.6.2.2  pgoyette 		uvm_physseg_init_seg(ps, pgs);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (psp != NULL)
1.6.2.2  pgoyette 		*psp = ps;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return true;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette static int
1.6.2.2  pgoyette uvm_physseg_compare_nodes(void *ctx, const void *nnode1, const void *nnode2)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	const struct uvm_physseg *enode1 = nnode1;
1.6.2.2  pgoyette 	const struct uvm_physseg *enode2 = nnode2;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	KASSERT(enode1->start < enode2->start || enode1->start >= enode2->end);
1.6.2.2  pgoyette 	KASSERT(enode2->start < enode1->start || enode2->start >= enode1->end);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (enode1->start < enode2->start)
1.6.2.2  pgoyette 		return -1;
1.6.2.2  pgoyette 	if (enode1->start >= enode2->end)
1.6.2.2  pgoyette 		return 1;
1.6.2.2  pgoyette 	return 0;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette static int
1.6.2.2  pgoyette uvm_physseg_compare_key(void *ctx, const void *nnode, const void *pkey)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	const struct uvm_physseg *enode = nnode;
1.6.2.2  pgoyette 	const paddr_t pa = *(const paddr_t *) pkey;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if(enode->start <= pa && pa < enode->end)
1.6.2.2  pgoyette 		return 0;
1.6.2.2  pgoyette 	if (enode->start < pa)
1.6.2.2  pgoyette 		return -1;
1.6.2.2  pgoyette 	if (enode->end > pa)
1.6.2.2  pgoyette 		return 1;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return 0;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette static const rb_tree_ops_t uvm_physseg_tree_ops = {
1.6.2.2  pgoyette 	.rbto_compare_nodes = uvm_physseg_compare_nodes,
1.6.2.2  pgoyette 	.rbto_compare_key = uvm_physseg_compare_key,
1.6.2.2  pgoyette 	.rbto_node_offset = offsetof(struct uvm_physseg, rb_node),
1.6.2.2  pgoyette 	.rbto_context = NULL
1.6.2.2  pgoyette };
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * uvm_physseg_init: init the physmem
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * => physmem unit should not be in use at this point
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette
1.6.2.2  pgoyette void
1.6.2.2  pgoyette uvm_physseg_init(void)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	rb_tree_init(&(uvm_physseg_graph.rb_tree), &uvm_physseg_tree_ops);
1.6.2.2  pgoyette 	uvm_physseg_graph.nentries = 0;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette uvm_physseg_t
1.6.2.2  pgoyette uvm_physseg_get_next(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	/* next of invalid is invalid, not fatal */
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(upm) == false)
1.6.2.2  pgoyette 		return UVM_PHYSSEG_TYPE_INVALID;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return (uvm_physseg_t) rb_tree_iterate(&(uvm_physseg_graph.rb_tree), upm,
1.6.2.2  pgoyette 	    RB_DIR_RIGHT);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette uvm_physseg_t
1.6.2.2  pgoyette uvm_physseg_get_prev(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	/* prev of invalid is invalid, not fatal */
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(upm) == false)
1.6.2.2  pgoyette 		return UVM_PHYSSEG_TYPE_INVALID;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return (uvm_physseg_t) rb_tree_iterate(&(uvm_physseg_graph.rb_tree), upm,
1.6.2.2  pgoyette 	    RB_DIR_LEFT);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette uvm_physseg_t
1.6.2.2  pgoyette uvm_physseg_get_last(void)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	return (uvm_physseg_t) RB_TREE_MAX(&(uvm_physseg_graph.rb_tree));
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette uvm_physseg_t
1.6.2.2  pgoyette uvm_physseg_get_first(void)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	return (uvm_physseg_t) RB_TREE_MIN(&(uvm_physseg_graph.rb_tree));
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette paddr_t
1.6.2.2  pgoyette uvm_physseg_get_highest_frame(void)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	struct uvm_physseg *ps =
1.6.2.2  pgoyette 	    (uvm_physseg_t) RB_TREE_MAX(&(uvm_physseg_graph.rb_tree));
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return ps->end - 1;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * uvm_page_physunload: unload physical memory and return it to
1.6.2.2  pgoyette  * caller.
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette bool
1.6.2.2  pgoyette uvm_page_physunload(uvm_physseg_t upm, int freelist, paddr_t *paddrp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	struct uvm_physseg *seg;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (__predict_true(uvm.page_init_done == true))
1.6.2.2  pgoyette 		panic("%s: unload attempted after uvm_page_init()\n", __func__);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	seg = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (seg->free_list != freelist) {
1.6.2.2  pgoyette 		paddrp = NULL;
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * During cold boot, what we're about to unplug hasn't been
1.6.2.2  pgoyette 	 * put on the uvm freelist, nor has uvmexp.npages been
1.6.2.2  pgoyette 	 * updated. (This happens in uvm_page.c:uvm_page_init())
1.6.2.2  pgoyette 	 *
1.6.2.2  pgoyette 	 * For hotplug, we assume here that the pages being unloaded
1.6.2.2  pgoyette 	 * here are completely out of sight of uvm (ie; not on any uvm
1.6.2.2  pgoyette 	 * lists), and that  uvmexp.npages has been suitably
1.6.2.2  pgoyette 	 * decremented before we're called.
1.6.2.2  pgoyette 	 *
1.6.2.2  pgoyette 	 * XXX: will avail_end == start if avail_start < avail_end?
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* try from front */
1.6.2.2  pgoyette 	if (seg->avail_start == seg->start &&
1.6.2.2  pgoyette 	    seg->avail_start < seg->avail_end) {
1.6.2.2  pgoyette 		*paddrp = ctob(seg->avail_start);
1.6.2.2  pgoyette 		return uvm_physseg_unplug(seg->avail_start, 1);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* try from rear */
1.6.2.2  pgoyette 	if (seg->avail_end == seg->end &&
1.6.2.2  pgoyette 	    seg->avail_start < seg->avail_end) {
1.6.2.2  pgoyette 		*paddrp = ctob(seg->avail_end - 1);
1.6.2.2  pgoyette 		return uvm_physseg_unplug(seg->avail_end - 1, 1);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return false;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette bool
1.6.2.2  pgoyette uvm_page_physunload_force(uvm_physseg_t upm, int freelist, paddr_t *paddrp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	struct uvm_physseg *seg;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	seg = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (__predict_true(uvm.page_init_done == true))
1.6.2.2  pgoyette 		panic("%s: unload attempted after uvm_page_init()\n", __func__);
1.6.2.2  pgoyette 	/* any room in this bank? */
1.6.2.2  pgoyette 	if (seg->avail_start >= seg->avail_end) {
1.6.2.2  pgoyette 		paddrp = NULL;
1.6.2.2  pgoyette 		return false; /* nope */
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	*paddrp = ctob(seg->avail_start);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* Always unplug from front */
1.6.2.2  pgoyette 	return uvm_physseg_unplug(seg->avail_start, 1);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * vm_physseg_find: find vm_physseg structure that belongs to a PA
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette uvm_physseg_t
1.6.2.2  pgoyette uvm_physseg_find(paddr_t pframe, psize_t *offp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	struct uvm_physseg * ps = NULL;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps = rb_tree_find_node(&(uvm_physseg_graph.rb_tree), &pframe);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if(ps != NULL && offp != NULL)
1.6.2.2  pgoyette 		*offp = pframe - ps->start;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return ps;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette #else  /* UVM_HOTPLUG */
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * physical memory config is stored in vm_physmem.
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette
1.6.2.2  pgoyette #define	VM_PHYSMEM_PTR(i)	(&vm_physmem[i])
1.6.2.2  pgoyette #if VM_PHYSSEG_MAX == 1
1.6.2.2  pgoyette #define VM_PHYSMEM_PTR_SWAP(i, j) /* impossible */
1.6.2.2  pgoyette #else
1.6.2.2  pgoyette #define VM_PHYSMEM_PTR_SWAP(i, j)					      \
1.6.2.2  pgoyette 	do { vm_physmem[(i)] = vm_physmem[(j)]; } while (0)
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette
1.6.2.2  pgoyette #define		HANDLE_TO_PHYSSEG_NODE(h)	(VM_PHYSMEM_PTR((int)h))
1.6.2.2  pgoyette #define		PHYSSEG_NODE_TO_HANDLE(u)	((int)((vsize_t) (u - vm_physmem) / sizeof(struct uvm_physseg)))
1.6.2.2  pgoyette
1.6.2.2  pgoyette static struct uvm_physseg vm_physmem[VM_PHYSSEG_MAX];	/* XXXCDC: uvm.physmem */
1.6.2.2  pgoyette static int vm_nphysseg = 0;				/* XXXCDC: uvm.nphysseg */
1.6.2.2  pgoyette #define	vm_nphysmem	vm_nphysseg
1.6.2.2  pgoyette
1.6.2.2  pgoyette void
1.6.2.2  pgoyette uvm_physseg_init(void)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	/* XXX: Provisioning for rb_tree related init(s) */
1.6.2.2  pgoyette 	return;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette int
1.6.2.2  pgoyette uvm_physseg_get_next(uvm_physseg_t lcv)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	/* next of invalid is invalid, not fatal */
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(lcv) == false)
1.6.2.2  pgoyette 		return UVM_PHYSSEG_TYPE_INVALID;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return (lcv + 1);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette int
1.6.2.2  pgoyette uvm_physseg_get_prev(uvm_physseg_t lcv)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	/* prev of invalid is invalid, not fatal */
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(lcv) == false)
1.6.2.2  pgoyette 		return UVM_PHYSSEG_TYPE_INVALID;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return (lcv - 1);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette int
1.6.2.2  pgoyette uvm_physseg_get_last(void)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	return (vm_nphysseg - 1);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette int
1.6.2.2  pgoyette uvm_physseg_get_first(void)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	return 0;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette paddr_t
1.6.2.2  pgoyette uvm_physseg_get_highest_frame(void)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	int lcv;
1.6.2.2  pgoyette 	paddr_t last = 0;
1.6.2.2  pgoyette 	struct uvm_physseg *ps;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	for (lcv = 0; lcv < vm_nphysseg; lcv++) {
1.6.2.2  pgoyette 		ps = VM_PHYSMEM_PTR(lcv);
1.6.2.2  pgoyette 		if (last < ps->end)
1.6.2.2  pgoyette 			last = ps->end;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return last;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette
1.6.2.2  pgoyette static struct vm_page *
1.6.2.2  pgoyette uvm_post_preload_check(void)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	int preload, lcv;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * check to see if this is a "preload" (i.e. uvm_page_init hasn't been
1.6.2.2  pgoyette 	 * called yet, so kmem is not available).
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	for (lcv = 0 ; lcv < vm_nphysmem ; lcv++) {
1.6.2.2  pgoyette 		if (VM_PHYSMEM_PTR(lcv)->pgs)
1.6.2.2  pgoyette 			break;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette 	preload = (lcv == vm_nphysmem);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * if VM is already running, attempt to kmem_alloc vm_page structures
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (!preload) {
1.6.2.2  pgoyette 		panic("Tried to add RAM after uvm_page_init");
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return NULL;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * uvm_page_physunload: unload physical memory and return it to
1.6.2.2  pgoyette  * caller.
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette bool
1.6.2.2  pgoyette uvm_page_physunload(uvm_physseg_t psi, int freelist, paddr_t *paddrp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	int x;
1.6.2.2  pgoyette 	struct uvm_physseg *seg;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	uvm_post_preload_check();
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	seg = VM_PHYSMEM_PTR(psi);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (seg->free_list != freelist) {
1.6.2.2  pgoyette 		paddrp = NULL;
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* try from front */
1.6.2.2  pgoyette 	if (seg->avail_start == seg->start &&
1.6.2.2  pgoyette 	    seg->avail_start < seg->avail_end) {
1.6.2.2  pgoyette 		*paddrp = ctob(seg->avail_start);
1.6.2.2  pgoyette 		seg->avail_start++;
1.6.2.2  pgoyette 		seg->start++;
1.6.2.2  pgoyette 		/* nothing left?   nuke it */
1.6.2.2  pgoyette 		if (seg->avail_start == seg->end) {
1.6.2.2  pgoyette 			if (vm_nphysmem == 1)
1.6.2.2  pgoyette 				panic("uvm_page_physget: out of memory!");
1.6.2.2  pgoyette 			vm_nphysmem--;
1.6.2.2  pgoyette 			for (x = psi ; x < vm_nphysmem ; x++)
1.6.2.2  pgoyette 				/* structure copy */
1.6.2.2  pgoyette 				VM_PHYSMEM_PTR_SWAP(x, x + 1);
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette 		return (true);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* try from rear */
1.6.2.2  pgoyette 	if (seg->avail_end == seg->end &&
1.6.2.2  pgoyette 	    seg->avail_start < seg->avail_end) {
1.6.2.2  pgoyette 		*paddrp = ctob(seg->avail_end - 1);
1.6.2.2  pgoyette 		seg->avail_end--;
1.6.2.2  pgoyette 		seg->end--;
1.6.2.2  pgoyette 		/* nothing left?   nuke it */
1.6.2.2  pgoyette 		if (seg->avail_end == seg->start) {
1.6.2.2  pgoyette 			if (vm_nphysmem == 1)
1.6.2.2  pgoyette 				panic("uvm_page_physget: out of memory!");
1.6.2.2  pgoyette 			vm_nphysmem--;
1.6.2.2  pgoyette 			for (x = psi ; x < vm_nphysmem ; x++)
1.6.2.2  pgoyette 				/* structure copy */
1.6.2.2  pgoyette 				VM_PHYSMEM_PTR_SWAP(x, x + 1);
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette 		return (true);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return false;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette bool
1.6.2.2  pgoyette uvm_page_physunload_force(uvm_physseg_t psi, int freelist, paddr_t *paddrp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	int x;
1.6.2.2  pgoyette 	struct uvm_physseg *seg;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	uvm_post_preload_check();
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	seg = VM_PHYSMEM_PTR(psi);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* any room in this bank? */
1.6.2.2  pgoyette 	if (seg->avail_start >= seg->avail_end) {
1.6.2.2  pgoyette 		paddrp = NULL;
1.6.2.2  pgoyette 		return false; /* nope */
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	*paddrp = ctob(seg->avail_start);
1.6.2.2  pgoyette 	seg->avail_start++;
1.6.2.2  pgoyette 	/* truncate! */
1.6.2.2  pgoyette 	seg->start = seg->avail_start;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* nothing left?   nuke it */
1.6.2.2  pgoyette 	if (seg->avail_start == seg->end) {
1.6.2.2  pgoyette 		if (vm_nphysmem == 1)
1.6.2.2  pgoyette 			panic("uvm_page_physget: out of memory!");
1.6.2.2  pgoyette 		vm_nphysmem--;
1.6.2.2  pgoyette 		for (x = psi ; x < vm_nphysmem ; x++)
1.6.2.2  pgoyette 			/* structure copy */
1.6.2.2  pgoyette 			VM_PHYSMEM_PTR_SWAP(x, x + 1);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette 	return (true);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette bool
1.6.2.2  pgoyette uvm_physseg_plug(paddr_t pfn, size_t pages, uvm_physseg_t *psp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	int lcv;
1.6.2.2  pgoyette 	struct vm_page *pgs;
1.6.2.2  pgoyette 	struct uvm_physseg *ps;
1.6.2.2  pgoyette
1.6.2.2  pgoyette #ifdef DEBUG
1.6.2.2  pgoyette 	paddr_t off;
1.6.2.2  pgoyette 	uvm_physseg_t upm;
1.6.2.2  pgoyette 	upm = uvm_physseg_find(pfn, &off);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(upm)) /* XXX; do we allow "update" plugs ? */
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	paddr_t start = pfn;
1.6.2.2  pgoyette 	paddr_t end = pfn + pages;
1.6.2.2  pgoyette 	paddr_t avail_start = start;
1.6.2.2  pgoyette 	paddr_t avail_end = end;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (uvmexp.pagesize == 0)
1.6.2.2  pgoyette 		panic("uvm_page_physload: page size not set!");
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * do we have room?
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (vm_nphysmem == VM_PHYSSEG_MAX) {
1.6.2.2  pgoyette 		printf("uvm_page_physload: unable to load physical memory "
1.6.2.2  pgoyette 		    "segment\n");
1.6.2.2  pgoyette 		printf("\t%d segments allocated, ignoring 0x%llx -> 0x%llx\n",
1.6.2.2  pgoyette 		    VM_PHYSSEG_MAX, (long long)start, (long long)end);
1.6.2.2  pgoyette 		printf("\tincrease VM_PHYSSEG_MAX\n");
1.6.2.2  pgoyette 		if (psp != NULL)
1.6.2.2  pgoyette 			*psp = UVM_PHYSSEG_TYPE_INVALID_OVERFLOW;
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * check to see if this is a "preload" (i.e. uvm_page_init hasn't been
1.6.2.2  pgoyette 	 * called yet, so kmem is not available).
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette 	pgs = uvm_post_preload_check();
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * now insert us in the proper place in vm_physmem[]
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette #if (VM_PHYSSEG_STRAT == VM_PSTRAT_RANDOM)
1.6.2.2  pgoyette 	/* random: put it at the end (easy!) */
1.6.2.2  pgoyette 	ps = VM_PHYSMEM_PTR(vm_nphysmem);
1.6.2.2  pgoyette 	lcv = vm_nphysmem;
1.6.2.2  pgoyette #elif (VM_PHYSSEG_STRAT == VM_PSTRAT_BSEARCH)
1.6.2.2  pgoyette 	{
1.6.2.2  pgoyette 		int x;
1.6.2.2  pgoyette 		/* sort by address for binary search */
1.6.2.2  pgoyette 		for (lcv = 0 ; lcv < vm_nphysmem ; lcv++)
1.6.2.2  pgoyette 			if (start < VM_PHYSMEM_PTR(lcv)->start)
1.6.2.2  pgoyette 				break;
1.6.2.2  pgoyette 		ps = VM_PHYSMEM_PTR(lcv);
1.6.2.2  pgoyette 		/* move back other entries, if necessary ... */
1.6.2.2  pgoyette 		for (x = vm_nphysmem ; x > lcv ; x--)
1.6.2.2  pgoyette 			/* structure copy */
1.6.2.2  pgoyette 			VM_PHYSMEM_PTR_SWAP(x, x - 1);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette #elif (VM_PHYSSEG_STRAT == VM_PSTRAT_BIGFIRST)
1.6.2.2  pgoyette 	{
1.6.2.2  pgoyette 		int x;
1.6.2.2  pgoyette 		/* sort by largest segment first */
1.6.2.2  pgoyette 		for (lcv = 0 ; lcv < vm_nphysmem ; lcv++)
1.6.2.2  pgoyette 			if ((end - start) >
1.6.2.2  pgoyette 			    (VM_PHYSMEM_PTR(lcv)->end - VM_PHYSMEM_PTR(lcv)->start))
1.6.2.2  pgoyette 				break;
1.6.2.2  pgoyette 		ps = VM_PHYSMEM_PTR(lcv);
1.6.2.2  pgoyette 		/* move back other entries, if necessary ... */
1.6.2.2  pgoyette 		for (x = vm_nphysmem ; x > lcv ; x--)
1.6.2.2  pgoyette 			/* structure copy */
1.6.2.2  pgoyette 			VM_PHYSMEM_PTR_SWAP(x, x - 1);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette #else
1.6.2.2  pgoyette 	panic("uvm_page_physload: unknown physseg strategy selected!");
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps->start = start;
1.6.2.2  pgoyette 	ps->end = end;
1.6.2.2  pgoyette 	ps->avail_start = avail_start;
1.6.2.2  pgoyette 	ps->avail_end = avail_end;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps->pgs = pgs;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	vm_nphysmem++;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (psp != NULL)
1.6.2.2  pgoyette 		*psp = lcv;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return true;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * when VM_PHYSSEG_MAX is 1, we can simplify these functions
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette
1.6.2.2  pgoyette #if VM_PHYSSEG_MAX == 1
1.6.2.2  pgoyette static inline int vm_physseg_find_contig(struct uvm_physseg *, int, paddr_t, psize_t *);
1.6.2.2  pgoyette #elif (VM_PHYSSEG_STRAT == VM_PSTRAT_BSEARCH)
1.6.2.2  pgoyette static inline int vm_physseg_find_bsearch(struct uvm_physseg *, int, paddr_t, psize_t *);
1.6.2.2  pgoyette #else
1.6.2.2  pgoyette static inline int vm_physseg_find_linear(struct uvm_physseg *, int, paddr_t, psize_t *);
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * vm_physseg_find: find vm_physseg structure that belongs to a PA
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette int
1.6.2.2  pgoyette uvm_physseg_find(paddr_t pframe, psize_t *offp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette
1.6.2.2  pgoyette #if VM_PHYSSEG_MAX == 1
1.6.2.2  pgoyette 	return vm_physseg_find_contig(vm_physmem, vm_nphysseg, pframe, offp);
1.6.2.2  pgoyette #elif (VM_PHYSSEG_STRAT == VM_PSTRAT_BSEARCH)
1.6.2.2  pgoyette 	return vm_physseg_find_bsearch(vm_physmem, vm_nphysseg, pframe, offp);
1.6.2.2  pgoyette #else
1.6.2.2  pgoyette 	return vm_physseg_find_linear(vm_physmem, vm_nphysseg, pframe, offp);
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette #if VM_PHYSSEG_MAX == 1
1.6.2.2  pgoyette static inline int
1.6.2.2  pgoyette vm_physseg_find_contig(struct uvm_physseg *segs, int nsegs, paddr_t pframe, psize_t *offp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* 'contig' case */
1.6.2.2  pgoyette 	if (pframe >= segs[0].start && pframe < segs[0].end) {
1.6.2.2  pgoyette 		if (offp)
1.6.2.2  pgoyette 			*offp = pframe - segs[0].start;
1.6.2.2  pgoyette 		return(0);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette 	return(-1);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette #elif (VM_PHYSSEG_STRAT == VM_PSTRAT_BSEARCH)
1.6.2.2  pgoyette
1.6.2.2  pgoyette static inline int
1.6.2.2  pgoyette vm_physseg_find_bsearch(struct uvm_physseg *segs, int nsegs, paddr_t pframe, psize_t *offp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	/* binary search for it */
1.6.2.2  pgoyette 	int	start, len, guess;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * if try is too large (thus target is less than try) we reduce
1.6.2.2  pgoyette 	 * the length to trunc(len/2) [i.e. everything smaller than "try"]
1.6.2.2  pgoyette 	 *
1.6.2.2  pgoyette 	 * if the try is too small (thus target is greater than try) then
1.6.2.2  pgoyette 	 * we set the new start to be (try + 1).   this means we need to
1.6.2.2  pgoyette 	 * reduce the length to (round(len/2) - 1).
1.6.2.2  pgoyette 	 *
1.6.2.2  pgoyette 	 * note "adjust" below which takes advantage of the fact that
1.6.2.2  pgoyette 	 *  (round(len/2) - 1) == trunc((len - 1) / 2)
1.6.2.2  pgoyette 	 * for any value of len we may have
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	for (start = 0, len = nsegs ; len != 0 ; len = len / 2) {
1.6.2.2  pgoyette 		guess = start + (len / 2);	/* try in the middle */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		/* start past our try? */
1.6.2.2  pgoyette 		if (pframe >= segs[guess].start) {
1.6.2.2  pgoyette 			/* was try correct? */
1.6.2.2  pgoyette 			if (pframe < segs[guess].end) {
1.6.2.2  pgoyette 				if (offp)
1.6.2.2  pgoyette 					*offp = pframe - segs[guess].start;
1.6.2.2  pgoyette 				return guess;            /* got it */
1.6.2.2  pgoyette 			}
1.6.2.2  pgoyette 			start = guess + 1;	/* next time, start here */
1.6.2.2  pgoyette 			len--;			/* "adjust" */
1.6.2.2  pgoyette 		} else {
1.6.2.2  pgoyette 			/*
1.6.2.2  pgoyette 			 * pframe before try, just reduce length of
1.6.2.2  pgoyette 			 * region, done in "for" loop
1.6.2.2  pgoyette 			 */
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette 	return(-1);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette #else
1.6.2.2  pgoyette
1.6.2.2  pgoyette static inline int
1.6.2.2  pgoyette vm_physseg_find_linear(struct uvm_physseg *segs, int nsegs, paddr_t pframe, psize_t *offp)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	/* linear search for it */
1.6.2.2  pgoyette 	int	lcv;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	for (lcv = 0; lcv < nsegs; lcv++) {
1.6.2.2  pgoyette 		if (pframe >= segs[lcv].start &&
1.6.2.2  pgoyette 		    pframe < segs[lcv].end) {
1.6.2.2  pgoyette 			if (offp)
1.6.2.2  pgoyette 				*offp = pframe - segs[lcv].start;
1.6.2.2  pgoyette 			return(lcv);		   /* got it */
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette 	return(-1);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette #endif /* UVM_HOTPLUG */
1.6.2.2  pgoyette
1.6.2.2  pgoyette bool
1.6.2.2  pgoyette uvm_physseg_valid_p(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	struct uvm_physseg *ps;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (upm == UVM_PHYSSEG_TYPE_INVALID ||
1.6.2.2  pgoyette 	    upm == UVM_PHYSSEG_TYPE_INVALID_EMPTY ||
1.6.2.2  pgoyette 	    upm == UVM_PHYSSEG_TYPE_INVALID_OVERFLOW)
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/*
1.6.2.2  pgoyette 	 * This is the delicate init dance -
1.6.2.2  pgoyette 	 * needs to go with the dance.
1.6.2.2  pgoyette 	 */
1.6.2.2  pgoyette 	if (uvm.page_init_done != true)
1.6.2.2  pgoyette 		return true;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* Extra checks needed only post uvm_page_init() */
1.6.2.2  pgoyette 	if (ps->pgs == NULL)
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* XXX: etc. */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return true;
1.6.2.2  pgoyette
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * Boot protocol dictates that these must be able to return partially
1.6.2.2  pgoyette  * initialised segments.
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette paddr_t
1.6.2.2  pgoyette uvm_physseg_get_start(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(upm) == false)
1.6.2.2  pgoyette 		return (paddr_t) -1;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return HANDLE_TO_PHYSSEG_NODE(upm)->start;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette paddr_t
1.6.2.2  pgoyette uvm_physseg_get_end(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(upm) == false)
1.6.2.2  pgoyette 		return (paddr_t) -1;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return HANDLE_TO_PHYSSEG_NODE(upm)->end;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette paddr_t
1.6.2.2  pgoyette uvm_physseg_get_avail_start(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(upm) == false)
1.6.2.2  pgoyette 		return (paddr_t) -1;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return HANDLE_TO_PHYSSEG_NODE(upm)->avail_start;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette #if defined(UVM_PHYSSEG_LEGACY)
1.6.2.2  pgoyette void
1.6.2.2  pgoyette uvm_physseg_set_avail_start(uvm_physseg_t upm, paddr_t avail_start)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	struct uvm_physseg *ps = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette #if defined(DIAGNOSTIC)
1.6.2.2  pgoyette 	paddr_t avail_end;
1.6.2.2  pgoyette 	avail_end = uvm_physseg_get_avail_end(upm);
1.6.2.2  pgoyette 	KASSERT(uvm_physseg_valid_p(upm));
1.6.2.2  pgoyette 	KASSERT(avail_start < avail_end && avail_start >= ps->start);
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps->avail_start = avail_start;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette void uvm_physseg_set_avail_end(uvm_physseg_t upm, paddr_t avail_end)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	struct uvm_physseg *ps = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette #if defined(DIAGNOSTIC)
1.6.2.2  pgoyette 	paddr_t avail_start;
1.6.2.2  pgoyette 	avail_start = uvm_physseg_get_avail_start(upm);
1.6.2.2  pgoyette 	KASSERT(uvm_physseg_valid_p(upm));
1.6.2.2  pgoyette 	KASSERT(avail_end > avail_start && avail_end <= ps->end);
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps->avail_end = avail_end;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette #endif /* UVM_PHYSSEG_LEGACY */
1.6.2.2  pgoyette
1.6.2.2  pgoyette paddr_t
1.6.2.2  pgoyette uvm_physseg_get_avail_end(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(upm) == false)
1.6.2.2  pgoyette 		return (paddr_t) -1;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return HANDLE_TO_PHYSSEG_NODE(upm)->avail_end;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette struct vm_page *
1.6.2.2  pgoyette uvm_physseg_get_pg(uvm_physseg_t upm, paddr_t idx)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	KASSERT(uvm_physseg_valid_p(upm));
1.6.2.2  pgoyette 	return &HANDLE_TO_PHYSSEG_NODE(upm)->pgs[idx];
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette #ifdef __HAVE_PMAP_PHYSSEG
1.6.2.2  pgoyette struct pmap_physseg *
1.6.2.2  pgoyette uvm_physseg_get_pmseg(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	KASSERT(uvm_physseg_valid_p(upm));
1.6.2.2  pgoyette 	return &(HANDLE_TO_PHYSSEG_NODE(upm)->pmseg);
1.6.2.2  pgoyette }
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette
1.6.2.2  pgoyette int
1.6.2.2  pgoyette uvm_physseg_get_free_list(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	KASSERT(uvm_physseg_valid_p(upm));
1.6.2.2  pgoyette 	return HANDLE_TO_PHYSSEG_NODE(upm)->free_list;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette u_int
1.6.2.2  pgoyette uvm_physseg_get_start_hint(uvm_physseg_t upm)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	KASSERT(uvm_physseg_valid_p(upm));
1.6.2.2  pgoyette 	return HANDLE_TO_PHYSSEG_NODE(upm)->start_hint;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette bool
1.6.2.2  pgoyette uvm_physseg_set_start_hint(uvm_physseg_t upm, u_int start_hint)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	if (uvm_physseg_valid_p(upm) == false)
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	HANDLE_TO_PHYSSEG_NODE(upm)->start_hint = start_hint;
1.6.2.2  pgoyette 	return true;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette void
1.6.2.2  pgoyette uvm_physseg_init_seg(uvm_physseg_t upm, struct vm_page *pgs)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	psize_t i;
1.6.2.2  pgoyette 	psize_t n;
1.6.2.2  pgoyette 	paddr_t paddr;
1.6.2.2  pgoyette 	struct uvm_physseg *seg;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	KASSERT(upm != UVM_PHYSSEG_TYPE_INVALID && pgs != NULL);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	seg = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette 	KASSERT(seg != NULL);
1.6.2.2  pgoyette 	KASSERT(seg->pgs == NULL);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	n = seg->end - seg->start;
1.6.2.2  pgoyette 	seg->pgs = pgs;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* init and free vm_pages (we've already zeroed them) */
1.6.2.2  pgoyette 	paddr = ctob(seg->start);
1.6.2.2  pgoyette 	for (i = 0 ; i < n ; i++, paddr += PAGE_SIZE) {
1.6.2.2  pgoyette 		seg->pgs[i].phys_addr = paddr;
1.6.2.2  pgoyette #ifdef __HAVE_VM_PAGE_MD
1.6.2.2  pgoyette 		VM_MDPAGE_INIT(&seg->pgs[i]);
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette 		if (atop(paddr) >= seg->avail_start &&
1.6.2.2  pgoyette 		    atop(paddr) < seg->avail_end) {
1.6.2.2  pgoyette 			uvmexp.npages++;
1.6.2.2  pgoyette 			mutex_enter(&uvm_pageqlock);
1.6.2.2  pgoyette 			/* add page to free pool */
1.6.2.2  pgoyette 			uvm_pagefree(&seg->pgs[i]);
1.6.2.2  pgoyette 			mutex_exit(&uvm_pageqlock);
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette void
1.6.2.2  pgoyette uvm_physseg_seg_chomp_slab(uvm_physseg_t upm, struct vm_page *pgs, size_t n)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	struct uvm_physseg *seg = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* max number of pre-boot unplug()s allowed */
1.6.2.2  pgoyette #define UVM_PHYSSEG_BOOT_UNPLUG_MAX VM_PHYSSEG_MAX
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	static char btslab_ex_storage[EXTENT_FIXED_STORAGE_SIZE(UVM_PHYSSEG_BOOT_UNPLUG_MAX)];
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (__predict_false(uvm.page_init_done == false)) {
1.6.2.2  pgoyette 		seg->ext = extent_create("Boot time slab", (u_long) pgs, (u_long) (pgs + n),
1.6.2.2  pgoyette 		    (void *)btslab_ex_storage, sizeof(btslab_ex_storage), 0);
1.6.2.2  pgoyette 	} else {
1.6.2.2  pgoyette 		seg->ext = extent_create("Hotplug slab", (u_long) pgs, (u_long) (pgs + n), NULL, 0, 0);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	KASSERT(seg->ext != NULL);
1.6.2.2  pgoyette
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette struct vm_page *
1.6.2.2  pgoyette uvm_physseg_seg_alloc_from_slab(uvm_physseg_t upm, size_t pages)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	int err;
1.6.2.2  pgoyette 	struct uvm_physseg *seg;
1.6.2.2  pgoyette 	struct vm_page *pgs = NULL;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	seg = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	KASSERT(pages > 0);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (__predict_false(seg->ext == NULL)) {
1.6.2.2  pgoyette 		/*
1.6.2.2  pgoyette 		 * This is a situation unique to boot time.
1.6.2.2  pgoyette 		 * It shouldn't happen at any point other than from
1.6.2.2  pgoyette 		 * the first uvm_page.c:uvm_page_init() call
1.6.2.2  pgoyette 		 * Since we're in a loop, we can get away with the
1.6.2.2  pgoyette 		 * below.
1.6.2.2  pgoyette 		 */
1.6.2.2  pgoyette 		KASSERT(uvm.page_init_done != true);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		seg->ext = HANDLE_TO_PHYSSEG_NODE(uvm_physseg_get_prev(upm))->ext;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		KASSERT(seg->ext != NULL);
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* We allocate enough for this segment */
1.6.2.2  pgoyette 	err = extent_alloc(seg->ext, sizeof(*pgs) * pages, 1, 0, EX_BOUNDZERO, (u_long *)&pgs);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (err != 0) {
1.6.2.2  pgoyette #ifdef DEBUG
1.6.2.2  pgoyette 		printf("%s: extent_alloc failed with error: %d \n",
1.6.2.2  pgoyette 		    __func__, err);
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return pgs;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette /*
1.6.2.2  pgoyette  * uvm_page_physload: load physical memory into VM system
1.6.2.2  pgoyette  *
1.6.2.2  pgoyette  * => all args are PFs
1.6.2.2  pgoyette  * => all pages in start/end get vm_page structures
1.6.2.2  pgoyette  * => areas marked by avail_start/avail_end get added to the free page pool
1.6.2.2  pgoyette  * => we are limited to VM_PHYSSEG_MAX physical memory segments
1.6.2.2  pgoyette  */
1.6.2.2  pgoyette
1.6.2.2  pgoyette uvm_physseg_t
1.6.2.2  pgoyette uvm_page_physload(paddr_t start, paddr_t end, paddr_t avail_start,
1.6.2.2  pgoyette     paddr_t avail_end, int free_list)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	struct uvm_physseg *ps;
1.6.2.2  pgoyette 	uvm_physseg_t upm;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (__predict_true(uvm.page_init_done == true))
1.6.2.2  pgoyette 		panic("%s: unload attempted after uvm_page_init()\n", __func__);
1.6.2.2  pgoyette 	if (uvmexp.pagesize == 0)
1.6.2.2  pgoyette 		panic("uvm_page_physload: page size not set!");
1.6.2.2  pgoyette 	if (free_list >= VM_NFREELIST || free_list < VM_FREELIST_DEFAULT)
1.6.2.2  pgoyette 		panic("uvm_page_physload: bad free list %d", free_list);
1.6.2.2  pgoyette 	if (start >= end)
1.6.2.2  pgoyette 		panic("uvm_page_physload: start >= end");
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (uvm_physseg_plug(start, end - start, &upm) == false) {
1.6.2.2  pgoyette 		panic("uvm_physseg_plug() failed at boot.");
1.6.2.2  pgoyette 		/* NOTREACHED */
1.6.2.2  pgoyette 		return UVM_PHYSSEG_TYPE_INVALID; /* XXX: correct type */
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	/* Legacy */
1.6.2.2  pgoyette 	ps->avail_start = avail_start;
1.6.2.2  pgoyette 	ps->avail_end = avail_end;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	ps->free_list = free_list; /* XXX: */
1.6.2.2  pgoyette
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return upm;
1.6.2.2  pgoyette }
1.6.2.2  pgoyette
1.6.2.2  pgoyette bool
1.6.2.2  pgoyette uvm_physseg_unplug(paddr_t pfn, size_t pages)
1.6.2.2  pgoyette {
1.6.2.2  pgoyette 	uvm_physseg_t upm;
1.6.2.2  pgoyette 	paddr_t off = 0, start, end;
1.6.2.2  pgoyette 	struct uvm_physseg *seg;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	upm = uvm_physseg_find(pfn, &off);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (!uvm_physseg_valid_p(upm)) {
1.6.2.2  pgoyette 		printf("%s: Tried to unplug from unknown offset\n", __func__);
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	seg = HANDLE_TO_PHYSSEG_NODE(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	start = uvm_physseg_get_start(upm);
1.6.2.2  pgoyette 	end = uvm_physseg_get_end(upm);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (end < (pfn + pages)) {
1.6.2.2  pgoyette 		printf("%s: Tried to unplug oversized span \n", __func__);
1.6.2.2  pgoyette 		return false;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette #ifndef DIAGNOSTIC
1.6.2.2  pgoyette 	(void) start;
1.6.2.2  pgoyette #endif
1.6.2.2  pgoyette 	KASSERT(pfn == start + off); /* sanity */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (__predict_true(uvm.page_init_done == true)) {
1.6.2.2  pgoyette 		/* XXX: KASSERT() that seg->pgs[] are not on any uvm lists */
1.6.2.2  pgoyette 		if (extent_free(seg->ext, (u_long)(seg->pgs + off), sizeof(struct vm_page) * pages, EX_MALLOCOK | EX_NOWAIT) != 0)
1.6.2.2  pgoyette 			return false;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (off == 0 && (pfn + pages) == end) {
1.6.2.2  pgoyette #if defined(UVM_HOTPLUG) /* rbtree implementation */
1.6.2.2  pgoyette 		int segcount = 0;
1.6.2.2  pgoyette 		struct uvm_physseg *current_ps;
1.6.2.2  pgoyette 		/* Complete segment */
1.6.2.2  pgoyette 		if (uvm_physseg_graph.nentries == 1)
1.6.2.2  pgoyette 			panic("%s: out of memory!", __func__);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		if (__predict_true(uvm.page_init_done == true)) {
1.6.2.2  pgoyette 			RB_TREE_FOREACH(current_ps, &(uvm_physseg_graph.rb_tree)) {
1.6.2.2  pgoyette 				if (seg->ext == current_ps->ext)
1.6.2.2  pgoyette 					segcount++;
1.6.2.2  pgoyette 			}
1.6.2.2  pgoyette 			KASSERT(segcount > 0);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 			if (segcount == 1) {
1.6.2.2  pgoyette 				extent_destroy(seg->ext);
1.6.2.2  pgoyette 			}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 			/*
1.6.2.2  pgoyette 			 * We assume that the unplug will succeed from
1.6.2.2  pgoyette 			 *  this point onwards
1.6.2.2  pgoyette 			 */
1.6.2.2  pgoyette 			uvmexp.npages -= (int) pages;
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		rb_tree_remove_node(&(uvm_physseg_graph.rb_tree), upm);
1.6.2.2  pgoyette 		memset(seg, 0, sizeof(struct uvm_physseg));
1.6.2.2  pgoyette 		uvm_physseg_free(seg, sizeof(struct uvm_physseg));
1.6.2.2  pgoyette 		uvm_physseg_graph.nentries--;
1.6.2.2  pgoyette #else /* UVM_HOTPLUG */
1.6.2.2  pgoyette 		int x;
1.6.2.2  pgoyette 		if (vm_nphysmem == 1)
1.6.2.2  pgoyette 			panic("uvm_page_physget: out of memory!");
1.6.2.2  pgoyette 		vm_nphysmem--;
1.6.2.2  pgoyette 		for (x = upm ; x < vm_nphysmem ; x++)
1.6.2.2  pgoyette 			/* structure copy */
1.6.2.2  pgoyette 			VM_PHYSMEM_PTR_SWAP(x, x + 1);
1.6.2.2  pgoyette #endif /* UVM_HOTPLUG */
1.6.2.2  pgoyette 		/* XXX: KASSERT() that seg->pgs[] are not on any uvm lists */
1.6.2.2  pgoyette 		return true;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (off > 0 &&
1.6.2.2  pgoyette 	    (pfn + pages) < end) {
1.6.2.2  pgoyette #if defined(UVM_HOTPLUG) /* rbtree implementation */
1.6.2.2  pgoyette 		/* middle chunk - need a new segment */
1.6.2.2  pgoyette 		struct uvm_physseg *ps, *current_ps;
1.6.2.2  pgoyette 		ps = uvm_physseg_alloc(sizeof (struct uvm_physseg));
1.6.2.2  pgoyette 		if (ps == NULL) {
1.6.2.2  pgoyette 			printf("%s: Unable to allocated new fragment vm_physseg \n",
1.6.2.2  pgoyette 			    __func__);
1.6.2.2  pgoyette 			return false;
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		/* Remove middle chunk */
1.6.2.2  pgoyette 		if (__predict_true(uvm.page_init_done == true)) {
1.6.2.2  pgoyette 			KASSERT(seg->ext != NULL);
1.6.2.2  pgoyette 			ps->ext = seg->ext;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 			/* XXX: KASSERT() that seg->pgs[] are not on any uvm lists */
1.6.2.2  pgoyette 			/*
1.6.2.2  pgoyette 			 * We assume that the unplug will succeed from
1.6.2.2  pgoyette 			 *  this point onwards
1.6.2.2  pgoyette 			 */
1.6.2.2  pgoyette 			uvmexp.npages -= (int) pages;
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		ps->start = pfn + pages;
1.6.2.2  pgoyette 		ps->avail_start = ps->start; /* XXX: Legacy */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		ps->end = seg->end;
1.6.2.2  pgoyette 		ps->avail_end = ps->end; /* XXX: Legacy */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		seg->end = pfn;
1.6.2.2  pgoyette 		seg->avail_end = seg->end; /* XXX: Legacy */
1.6.2.2  pgoyette
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		/*
1.6.2.2  pgoyette 		 * The new pgs array points to the beginning of the
1.6.2.2  pgoyette 		 * tail fragment.
1.6.2.2  pgoyette 		 */
1.6.2.2  pgoyette 		if (__predict_true(uvm.page_init_done == true))
1.6.2.2  pgoyette 			ps->pgs = seg->pgs + off + pages;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		current_ps = rb_tree_insert_node(&(uvm_physseg_graph.rb_tree), ps);
1.6.2.2  pgoyette 		if (current_ps != ps) {
1.6.2.2  pgoyette 			panic("uvm_page_physload: Duplicate address range detected!");
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette 		uvm_physseg_graph.nentries++;
1.6.2.2  pgoyette #else /* UVM_HOTPLUG */
1.6.2.2  pgoyette 		panic("%s: can't unplug() from the middle of a segment without"
1.6.2.2  pgoyette 		    "UVM_HOTPLUG\n",  __func__);
1.6.2.2  pgoyette 		/* NOTREACHED */
1.6.2.2  pgoyette #endif /* UVM_HOTPLUG */
1.6.2.2  pgoyette 		return true;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (off == 0 && (pfn + pages) < end) {
1.6.2.2  pgoyette 		/* Remove front chunk */
1.6.2.2  pgoyette 		if (__predict_true(uvm.page_init_done == true)) {
1.6.2.2  pgoyette 			/* XXX: KASSERT() that seg->pgs[] are not on any uvm lists */
1.6.2.2  pgoyette 			/*
1.6.2.2  pgoyette 			 * We assume that the unplug will succeed from
1.6.2.2  pgoyette 			 *  this point onwards
1.6.2.2  pgoyette 			 */
1.6.2.2  pgoyette 			uvmexp.npages -= (int) pages;
1.6.2.2  pgoyette 		}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		/* Truncate */
1.6.2.2  pgoyette 		seg->start = pfn + pages;
1.6.2.2  pgoyette 		seg->avail_start = seg->start; /* XXX: Legacy */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		/*
1.6.2.2  pgoyette 		 * Move the pgs array start to the beginning of the
1.6.2.2  pgoyette 		 * tail end.
1.6.2.2  pgoyette 		 */
1.6.2.2  pgoyette 		if (__predict_true(uvm.page_init_done == true))
1.6.2.2  pgoyette 			seg->pgs += pages;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		return true;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	if (off > 0 && (pfn + pages) == end) {
1.6.2.2  pgoyette 		/* back chunk */
1.6.2.2  pgoyette
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		/* Truncate! */
1.6.2.2  pgoyette 		seg->end = pfn;
1.6.2.2  pgoyette 		seg->avail_end = seg->end; /* XXX: Legacy */
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		uvmexp.npages -= (int) pages;
1.6.2.2  pgoyette
1.6.2.2  pgoyette 		return true;
1.6.2.2  pgoyette 	}
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	printf("%s: Tried to unplug unknown range \n", __func__);
1.6.2.2  pgoyette
1.6.2.2  pgoyette 	return false;
1.6.2.2  pgoyette }