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|
/* $OpenBSD: pmap.c,v 1.120 2007/11/16 16:16:06 deraadt Exp $ */
/* $NetBSD: pmap.c,v 1.91 2000/06/02 17:46:37 thorpej Exp $ */
/*
*
* Copyright (c) 1997 Charles D. Cranor and Washington University.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by Charles D. Cranor and
* Washington University.
* 4. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/*
* pmap.c: i386 pmap module rewrite
* Chuck Cranor <chuck@ccrc.wustl.edu>
* 11-Aug-97
*
* history of this pmap module: in addition to my own input, i used
* the following references for this rewrite of the i386 pmap:
*
* [1] the NetBSD i386 pmap. this pmap appears to be based on the
* BSD hp300 pmap done by Mike Hibler at University of Utah.
* it was then ported to the i386 by William Jolitz of UUNET
* Technologies, Inc. Then Charles M. Hannum of the NetBSD
* project fixed some bugs and provided some speed ups.
*
* [2] the FreeBSD i386 pmap. this pmap seems to be the
* Hibler/Jolitz pmap, as modified for FreeBSD by John S. Dyson
* and David Greenman.
*
* [3] the Mach pmap. this pmap, from CMU, seems to have migrated
* between several processors. the VAX version was done by
* Avadis Tevanian, Jr., and Michael Wayne Young. the i386
* version was done by Lance Berc, Mike Kupfer, Bob Baron,
* David Golub, and Richard Draves. the alpha version was
* done by Alessandro Forin (CMU/Mach) and Chris Demetriou
* (NetBSD/alpha).
*/
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/proc.h>
#include <sys/malloc.h>
#include <sys/pool.h>
#include <sys/user.h>
#include <sys/kernel.h>
#include <sys/mutex.h>
#include <uvm/uvm.h>
#include <machine/atomic.h>
#include <machine/cpu.h>
#include <machine/specialreg.h>
#include <machine/gdt.h>
#include <dev/isa/isareg.h>
#include <sys/msgbuf.h>
#include <stand/boot/bootarg.h>
/*
* general info:
*
* - for an explanation of how the i386 MMU hardware works see
* the comments in <machine/pte.h>.
*
* - for an explanation of the general memory structure used by
* this pmap (including the recursive mapping), see the comments
* in <machine/pmap.h>.
*
* this file contains the code for the "pmap module." the module's
* job is to manage the hardware's virtual to physical address mappings.
* note that there are two levels of mapping in the VM system:
*
* [1] the upper layer of the VM system uses vm_map's and vm_map_entry's
* to map ranges of virtual address space to objects/files. for
* example, the vm_map may say: "map VA 0x1000 to 0x22000 read-only
* to the file /bin/ls starting at offset zero." note that
* the upper layer mapping is not concerned with how individual
* vm_pages are mapped.
*
* [2] the lower layer of the VM system (the pmap) maintains the mappings
* from virtual addresses. it is concerned with which vm_page is
* mapped where. for example, when you run /bin/ls and start
* at page 0x1000 the fault routine may lookup the correct page
* of the /bin/ls file and then ask the pmap layer to establish
* a mapping for it.
*
* note that information in the lower layer of the VM system can be
* thrown away since it can easily be reconstructed from the info
* in the upper layer.
*
* data structures we use include:
*
* - struct pmap: describes the address space of one thread
* - struct pv_entry: describes one <PMAP,VA> mapping of a PA
* - struct pv_head: there is one pv_head per managed page of
* physical memory. the pv_head points to a list of pv_entry
* structures which describe all the <PMAP,VA> pairs that this
* page is mapped in. this is critical for page based operations
* such as pmap_page_protect() [change protection on _all_ mappings
* of a page]
* - pv_page/pv_page_info: pv_entry's are allocated out of pv_page's.
* if we run out of pv_entry's we allocate a new pv_page and free
* its pv_entrys.
*/
/*
* memory allocation
*
* - there are three data structures that we must dynamically allocate:
*
* [A] new process' page directory page (PDP)
* - plan 1: done at pmap_create() we use
* uvm_km_alloc(kernel_map, PAGE_SIZE) [fka kmem_alloc] to do this
* allocation.
*
* if we are low in free physical memory then we sleep in
* uvm_km_alloc -- in this case this is ok since we are creating
* a new pmap and should not be holding any locks.
*
* if the kernel is totally out of virtual space
* (i.e. uvm_km_alloc returns NULL), then we panic.
*
* XXX: the fork code currently has no way to return an "out of
* memory, try again" error code since uvm_fork [fka vm_fork]
* is a void function.
*
* [B] new page tables pages (PTP)
* call uvm_pagealloc()
* => success: zero page, add to pm_pdir
* => failure: we are out of free vm_pages, let pmap_enter()
* tell UVM about it.
*
* note: for kernel PTPs, we start with NKPTP of them. as we map
* kernel memory (at uvm_map time) we check to see if we've grown
* the kernel pmap. if so, we call the optional function
* pmap_growkernel() to grow the kernel PTPs in advance.
*
* [C] pv_entry structures
* - plan 1: try to allocate one off the free list
* => success: done!
* => failure: no more free pv_entrys on the list
* - plan 2: try to allocate a new pv_page to add a chunk of
* pv_entrys to the free list
* [a] obtain a free, unmapped, VA in kmem_map. either
* we have one saved from a previous call, or we allocate
* one now using a "vm_map_lock_try" in uvm_map
* => success: we have an unmapped VA, continue to [b]
* => failure: unable to lock kmem_map or out of VA in it.
* move on to plan 3.
* [b] allocate a page for the VA
* => success: map it in, free the pv_entry's, DONE!
* => failure: no free vm_pages, etc.
* save VA for later call to [a], go to plan 3.
* If we fail, we simply let pmap_enter() tell UVM about it.
*/
/*
* locking
*
* we have the following locks that we must contend with:
*
* "simple" locks:
*
* - pmap lock (per pmap, part of uvm_object)
* this lock protects the fields in the pmap structure including
* the non-kernel PDEs in the PDP, and the PTEs. it also locks
* in the alternate PTE space (since that is determined by the
* entry in the PDP).
*
* - pvalloc_lock
* this lock protects the data structures which are used to manage
* the free list of pv_entry structures.
*
* - pmaps_lock
* this lock protects the list of active pmaps (headed by "pmaps").
* we lock it when adding or removing pmaps from this list.
*
*/
/*
* locking data structures
*/
struct simplelock pvalloc_lock;
struct simplelock pmaps_lock;
#define PMAP_MAP_TO_HEAD_LOCK() /* null */
#define PMAP_MAP_TO_HEAD_UNLOCK() /* null */
#define PMAP_HEAD_TO_MAP_LOCK() /* null */
#define PMAP_HEAD_TO_MAP_UNLOCK() /* null */
/*
* global data structures
*/
struct pmap kernel_pmap_store; /* the kernel's pmap (proc0) */
/*
* nkpde is the number of kernel PTPs allocated for the kernel at
* boot time (NKPTP is a compile time override). this number can
* grow dynamically as needed (but once allocated, we never free
* kernel PTPs).
*/
int nkpde = NKPTP;
#ifdef NKPDE
#error "obsolete NKPDE: use NKPTP"
#endif
/*
* pmap_pg_g: if our processor supports PG_G in the PTE then we
* set pmap_pg_g to PG_G (otherwise it is zero).
*/
int pmap_pg_g = 0;
/*
* i386 physical memory comes in a big contig chunk with a small
* hole toward the front of it... the following 4 paddr_t's
* (shared with machdep.c) describe the physical address space
* of this machine.
*/
paddr_t avail_start; /* PA of first available physical page */
paddr_t hole_start; /* PA of start of "hole" */
paddr_t hole_end; /* PA of end of "hole" */
/*
* other data structures
*/
static pt_entry_t protection_codes[8]; /* maps MI prot to i386 prot code */
static boolean_t pmap_initialized = FALSE; /* pmap_init done yet? */
/*
* the following two vaddr_t's are used during system startup
* to keep track of how much of the kernel's VM space we have used.
* once the system is started, the management of the remaining kernel
* VM space is turned over to the kernel_map vm_map.
*/
static vaddr_t virtual_avail; /* VA of first free KVA */
static vaddr_t virtual_end; /* VA of last free KVA */
/*
* pv_page management structures: locked by pvalloc_lock
*/
TAILQ_HEAD(pv_pagelist, pv_page);
static struct pv_pagelist pv_freepages; /* list of pv_pages with free entries */
static struct pv_pagelist pv_unusedpgs; /* list of unused pv_pages */
static int pv_nfpvents; /* # of free pv entries */
static struct pv_page *pv_initpage; /* bootstrap page from kernel_map */
static vaddr_t pv_cachedva; /* cached VA for later use */
#define PVE_LOWAT (PVE_PER_PVPAGE / 2) /* free pv_entry low water mark */
#define PVE_HIWAT (PVE_LOWAT + (PVE_PER_PVPAGE * 2))
/* high water mark */
/*
* linked list of all non-kernel pmaps
*/
struct pmap_head pmaps;
/*
* pool that pmap structures are allocated from
*/
struct pool pmap_pmap_pool;
/*
* MULTIPROCESSOR: special VA's/ PTE's are actually allocated inside a
* MAXCPUS*NPTECL array of PTE's, to avoid cache line thrashing
* due to false sharing.
*/
#ifdef MULTIPROCESSOR
#define PTESLEW(pte, id) ((pte)+(id)*NPTECL)
#define VASLEW(va,id) ((va)+(id)*NPTECL*NBPG)
#else
#define PTESLEW(pte, id) (pte)
#define VASLEW(va,id) (va)
#endif
/*
* special VAs and the PTEs that map them
*/
static pt_entry_t *csrc_pte, *cdst_pte, *zero_pte, *ptp_pte;
static caddr_t csrcp, cdstp, zerop, ptpp;
caddr_t vmmap; /* XXX: used by mem.c... it should really uvm_map_reserve it */
#if defined(I586_CPU)
/* stuff to fix the pentium f00f bug */
extern vaddr_t pentium_idt_vaddr;
#endif
/*
* local prototypes
*/
struct pv_entry *pmap_add_pvpage(struct pv_page *, boolean_t);
struct vm_page *pmap_alloc_ptp(struct pmap *, int, boolean_t, pt_entry_t);
struct pv_entry *pmap_alloc_pv(struct pmap *, int); /* see codes below */
#define ALLOCPV_NEED 0 /* need PV now */
#define ALLOCPV_TRY 1 /* just try to allocate */
#define ALLOCPV_NONEED 2 /* don't need PV, just growing cache */
struct pv_entry *pmap_alloc_pvpage(struct pmap *, int);
void pmap_enter_pv(struct vm_page *, struct pv_entry *,
struct pmap *, vaddr_t, struct vm_page *);
void pmap_free_pv(struct pmap *, struct pv_entry *);
void pmap_free_pvs(struct pmap *, struct pv_entry *);
void pmap_free_pv_doit(struct pv_entry *);
void pmap_free_pvpage(void);
struct vm_page *pmap_get_ptp(struct pmap *, int, boolean_t);
boolean_t pmap_is_curpmap(struct pmap *);
boolean_t pmap_is_active(struct pmap *, int);
void pmap_sync_flags_pte(struct vm_page *, u_long);
pt_entry_t *pmap_map_ptes(struct pmap *);
struct pv_entry *pmap_remove_pv(struct vm_page *, struct pmap *, vaddr_t);
void pmap_do_remove(struct pmap *, vaddr_t, vaddr_t, int);
boolean_t pmap_remove_pte(struct pmap *, struct vm_page *, pt_entry_t *,
vaddr_t, int);
void pmap_remove_ptes(struct pmap *, struct vm_page *, vaddr_t,
vaddr_t, vaddr_t, int);
#define PMAP_REMOVE_ALL 0
#define PMAP_REMOVE_SKIPWIRED 1
vaddr_t pmap_tmpmap_pa(paddr_t);
pt_entry_t *pmap_tmpmap_pvepte(struct pv_entry *);
void pmap_tmpunmap_pa(void);
void pmap_tmpunmap_pvepte(struct pv_entry *);
void pmap_apte_flush(struct pmap *);
void pmap_unmap_ptes(struct pmap *);
void pmap_exec_account(struct pmap *, vaddr_t, pt_entry_t,
pt_entry_t);
void pmap_pinit(pmap_t);
void pmap_release(pmap_t);
void pmap_zero_phys(paddr_t);
void setcslimit(struct pmap *, struct trapframe *, struct pcb *, vaddr_t);
/*
* p m a p i n l i n e h e l p e r f u n c t i o n s
*/
/*
* pmap_is_curpmap: is this pmap the one currently loaded [in %cr3]?
* of course the kernel is always loaded
*/
boolean_t
pmap_is_curpmap(pmap)
struct pmap *pmap;
{
return((pmap == pmap_kernel()) ||
(pmap->pm_pdirpa == (paddr_t) rcr3()));
}
/*
* pmap_is_active: is this pmap loaded into the specified processor's %cr3?
*/
boolean_t
pmap_is_active(pmap, cpu_id)
struct pmap *pmap;
int cpu_id;
{
return (pmap == pmap_kernel() ||
(pmap->pm_cpus & (1U << cpu_id)) != 0);
}
static __inline u_int
pmap_pte2flags(u_long pte)
{
return (((pte & PG_U) ? PG_PMAP_REF : 0) |
((pte & PG_M) ? PG_PMAP_MOD : 0));
}
static __inline u_int
pmap_flags2pte(u_long pte)
{
return (((pte & PG_PMAP_REF) ? PG_U : 0) |
((pte & PG_PMAP_MOD) ? PG_M : 0));
}
void
pmap_sync_flags_pte(struct vm_page *pg, u_long pte)
{
if (pte & (PG_U|PG_M)) {
atomic_setbits_int(&pg->pg_flags, pmap_pte2flags(pte));
}
}
/*
* pmap_tmpmap_pa: map a page in for tmp usage
*/
vaddr_t
pmap_tmpmap_pa(paddr_t pa)
{
#ifdef MULTIPROCESSOR
int id = cpu_number();
#endif
pt_entry_t *ptpte = PTESLEW(ptp_pte, id);
caddr_t ptpva = VASLEW(ptpp, id);
#if defined(DIAGNOSTIC)
if (*ptpte)
panic("pmap_tmpmap_pa: ptp_pte in use?");
#endif
*ptpte = PG_V | PG_RW | pa; /* always a new mapping */
return((vaddr_t)ptpva);
}
/*
* pmap_tmpunmap_pa: unmap a tmp use page (undoes pmap_tmpmap_pa)
*/
void
pmap_tmpunmap_pa()
{
#ifdef MULTIPROCESSOR
int id = cpu_number();
#endif
pt_entry_t *ptpte = PTESLEW(ptp_pte, id);
caddr_t ptpva = VASLEW(ptpp, id);
#if defined(DIAGNOSTIC)
if (!pmap_valid_entry(*ptpte))
panic("pmap_tmpunmap_pa: our pte invalid?");
#endif
*ptpte = 0; /* zap! */
pmap_update_pg((vaddr_t)ptpva);
#ifdef MULTIPROCESSOR
/*
* No need for tlb shootdown here, since ptp_pte is per-CPU.
*/
#endif
}
/*
* pmap_tmpmap_pvepte: get a quick mapping of a PTE for a pv_entry
*
* => do NOT use this on kernel mappings [why? because pv_ptp may be NULL]
*/
pt_entry_t *
pmap_tmpmap_pvepte(struct pv_entry *pve)
{
#ifdef DIAGNOSTIC
if (pve->pv_pmap == pmap_kernel())
panic("pmap_tmpmap_pvepte: attempt to map kernel");
#endif
/* is it current pmap? use direct mapping... */
if (pmap_is_curpmap(pve->pv_pmap))
return(vtopte(pve->pv_va));
return(((pt_entry_t *)pmap_tmpmap_pa(VM_PAGE_TO_PHYS(pve->pv_ptp)))
+ ptei((unsigned)pve->pv_va));
}
/*
* pmap_tmpunmap_pvepte: release a mapping obtained with pmap_tmpmap_pvepte
*/
void
pmap_tmpunmap_pvepte(struct pv_entry *pve)
{
/* was it current pmap? if so, return */
if (pmap_is_curpmap(pve->pv_pmap))
return;
pmap_tmpunmap_pa();
}
void
pmap_apte_flush(struct pmap *pmap)
{
pmap_tlb_shoottlb();
pmap_tlb_shootwait();
}
/*
* pmap_map_ptes: map a pmap's PTEs into KVM and lock them in
*
* => we lock enough pmaps to keep things locked in
* => must be undone with pmap_unmap_ptes before returning
*/
pt_entry_t *
pmap_map_ptes(struct pmap *pmap)
{
pd_entry_t opde;
/* the kernel's pmap is always accessible */
if (pmap == pmap_kernel()) {
return(PTE_BASE);
}
/* if curpmap then we are always mapped */
if (pmap_is_curpmap(pmap)) {
simple_lock(&pmap->pm_obj.vmobjlock);
return(PTE_BASE);
}
/* need to lock both curpmap and pmap: use ordered locking */
if ((unsigned) pmap < (unsigned) curpcb->pcb_pmap) {
simple_lock(&pmap->pm_obj.vmobjlock);
simple_lock(&curpcb->pcb_pmap->pm_obj.vmobjlock);
} else {
simple_lock(&curpcb->pcb_pmap->pm_obj.vmobjlock);
simple_lock(&pmap->pm_obj.vmobjlock);
}
/* need to load a new alternate pt space into curpmap? */
opde = *APDP_PDE;
if (!pmap_valid_entry(opde) || (opde & PG_FRAME) != pmap->pm_pdirpa) {
*APDP_PDE = (pd_entry_t) (pmap->pm_pdirpa | PG_RW | PG_V |
PG_U | PG_M);
if (pmap_valid_entry(opde))
pmap_apte_flush(curpcb->pcb_pmap);
}
return(APTE_BASE);
}
/*
* pmap_unmap_ptes: unlock the PTE mapping of "pmap"
*/
void
pmap_unmap_ptes(struct pmap *pmap)
{
if (pmap == pmap_kernel())
return;
if (pmap_is_curpmap(pmap)) {
simple_unlock(&pmap->pm_obj.vmobjlock);
} else {
#if defined(MULTIPROCESSOR)
*APDP_PDE = 0;
pmap_apte_flush(curpcb->pcb_pmap);
#endif
simple_unlock(&pmap->pm_obj.vmobjlock);
simple_unlock(&curpcb->pcb_pmap->pm_obj.vmobjlock);
}
}
void
pmap_exec_account(struct pmap *pm, vaddr_t va,
pt_entry_t opte, pt_entry_t npte)
{
if (pm == pmap_kernel())
return;
if (curproc == NULL || curproc->p_vmspace == NULL ||
pm != vm_map_pmap(&curproc->p_vmspace->vm_map))
return;
if ((opte ^ npte) & PG_X)
pmap_tlb_shootpage(pm, va);
/*
* Executability was removed on the last executable change.
* Reset the code segment to something conservative and
* let the trap handler deal with setting the right limit.
* We can't do that because of locking constraints on the vm map.
*
* XXX - floating cs - set this _really_ low.
*/
if ((opte & PG_X) && (npte & PG_X) == 0 && va == pm->pm_hiexec) {
struct trapframe *tf = curproc->p_md.md_regs;
struct pcb *pcb = &curproc->p_addr->u_pcb;
pm->pm_hiexec = I386_MAX_EXE_ADDR;
setcslimit(pm, tf, pcb, I386_MAX_EXE_ADDR);
}
}
/*
* Fixup the code segment to cover all potential executable mappings.
* Called by kernel SEGV trap handler.
* returns 0 if no changes to the code segment were made.
*/
int
pmap_exec_fixup(struct vm_map *map, struct trapframe *tf, struct pcb *pcb)
{
struct vm_map_entry *ent;
struct pmap *pm = vm_map_pmap(map);
vaddr_t va = 0;
vm_map_lock(map);
for (ent = (&map->header)->next; ent != &map->header; ent = ent->next) {
/*
* This entry has greater va than the entries before.
* We need to make it point to the last page, not past it.
*/
if (ent->protection & VM_PROT_EXECUTE)
va = trunc_page(ent->end - 1);
}
vm_map_unlock(map);
if (va <= pm->pm_hiexec) {
return (0);
}
pm->pm_hiexec = va;
/*
* We have a new 'highest executable' va, so we need to update
* the value for the code segment limit, which is stored in the
* PCB.
*/
setcslimit(pm, tf, pcb, va);
return (1);
}
void
setcslimit(struct pmap *pm, struct trapframe *tf, struct pcb *pcb,
vaddr_t limit)
{
/*
* Called when we have a new 'highest executable' va, so we need
* to update the value for the code segment limit, which is stored
* in the PCB.
*
* There are no caching issues to be concerned with: the
* processor reads the whole descriptor from the GDT when the
* appropriate selector is loaded into a segment register, and
* this only happens on the return to userland.
*
* This also works in the MP case, since whichever CPU gets to
* run the process will pick up the right descriptor value from
* the PCB.
*/
limit = min(limit, VM_MAXUSER_ADDRESS - 1);
setsegment(&pm->pm_codeseg, 0, atop(limit),
SDT_MEMERA, SEL_UPL, 1, 1);
/* And update the GDT and LDT since we may be called by the
* trap handler (cpu_switch won't get a chance).
*/
curcpu()->ci_gdt[GUCODE_SEL].sd = pcb->pcb_ldt[LUCODE_SEL].sd =
pm->pm_codeseg;
pcb->pcb_cs = tf->tf_cs = GSEL(GUCODE_SEL, SEL_UPL);
}
/*
* p m a p k e n t e r f u n c t i o n s
*
* functions to quickly enter/remove pages from the kernel address
* space. pmap_kremove is exported to MI kernel. we make use of
* the recursive PTE mappings.
*/
/*
* pmap_kenter_pa: enter a kernel mapping without R/M (pv_entry) tracking
*
* => no need to lock anything, assume va is already allocated
* => should be faster than normal pmap enter function
*/
void
pmap_kenter_pa(vaddr_t va, paddr_t pa, vm_prot_t prot)
{
pt_entry_t *pte, opte, npte;
pte = vtopte(va);
npte = pa | ((prot & VM_PROT_WRITE)? PG_RW : PG_RO) | PG_V |
pmap_pg_g | PG_U | PG_M;
opte = i386_atomic_testset_ul(pte, npte); /* zap! */
if (pmap_valid_entry(opte)) {
/* NB. - this should not happen. */
pmap_tlb_shootpage(pmap_kernel(), va);
pmap_tlb_shootwait();
}
}
/*
* pmap_kremove: remove a kernel mapping(s) without R/M (pv_entry) tracking
*
* => no need to lock anything
* => caller must dispose of any vm_page mapped in the va range
* => note: not an inline function
* => we assume the va is page aligned and the len is a multiple of PAGE_SIZE
*/
void
pmap_kremove(vaddr_t sva, vsize_t len)
{
pt_entry_t *pte, opte;
vaddr_t va, eva;
eva = sva + len;
for (va = sva; va != eva; va += PAGE_SIZE) {
pte = kvtopte(va);
opte = i386_atomic_testset_ul(pte, 0);
#ifdef DIAGNOSTIC
if (opte & PG_PVLIST)
panic("pmap_kremove: PG_PVLIST mapping for 0x%lx", va);
#endif
}
pmap_tlb_shootrange(pmap_kernel(), sva, eva);
pmap_tlb_shootwait();
}
/*
* p m a p i n i t f u n c t i o n s
*
* pmap_bootstrap and pmap_init are called during system startup
* to init the pmap module. pmap_bootstrap() does a low level
* init just to get things rolling. pmap_init() finishes the job.
*/
/*
* pmap_bootstrap: get the system in a state where it can run with VM
* properly enabled (called before main()). the VM system is
* fully init'd later...
*
* => on i386, locore.s has already enabled the MMU by allocating
* a PDP for the kernel, and nkpde PTP's for the kernel.
* => kva_start is the first free virtual address in kernel space
*/
void
pmap_bootstrap(vaddr_t kva_start)
{
extern paddr_t avail_end;
struct pmap *kpm;
vaddr_t kva;
pt_entry_t *pte;
/*
* set the page size (default value is 4K which is ok)
*/
uvm_setpagesize();
/*
* a quick sanity check
*/
if (PAGE_SIZE != NBPG)
panic("pmap_bootstrap: PAGE_SIZE != NBPG");
/*
* use the very last page of physical memory for the message buffer
*/
avail_end -= round_page(MSGBUFSIZE);
/*
* The arguments passed in from /boot needs space too.
*/
avail_end -= round_page(bootargc);
/*
* set up our local static global vars that keep track of the
* usage of KVM before kernel_map is set up
*/
virtual_avail = kva_start; /* first free KVA */
virtual_end = VM_MAX_KERNEL_ADDRESS; /* last KVA */
/*
* set up protection_codes: we need to be able to convert from
* a MI protection code (some combo of VM_PROT...) to something
* we can jam into a i386 PTE.
*/
protection_codes[UVM_PROT_NONE] = 0; /* --- */
protection_codes[UVM_PROT_EXEC] = PG_X; /* --x */
protection_codes[UVM_PROT_READ] = PG_RO; /* -r- */
protection_codes[UVM_PROT_RX] = PG_X; /* -rx */
protection_codes[UVM_PROT_WRITE] = PG_RW; /* w-- */
protection_codes[UVM_PROT_WX] = PG_RW|PG_X; /* w-x */
protection_codes[UVM_PROT_RW] = PG_RW; /* wr- */
protection_codes[UVM_PROT_RWX] = PG_RW|PG_X; /* wrx */
/*
* now we init the kernel's pmap
*
* the kernel pmap's pm_obj is not used for much. however, in
* user pmaps the pm_obj contains the list of active PTPs.
* the pm_obj currently does not have a pager. it might be possible
* to add a pager that would allow a process to read-only mmap its
* own page tables (fast user level vtophys?). this may or may not
* be useful.
*/
kpm = pmap_kernel();
simple_lock_init(&kpm->pm_obj.vmobjlock);
kpm->pm_obj.pgops = NULL;
TAILQ_INIT(&kpm->pm_obj.memq);
kpm->pm_obj.uo_npages = 0;
kpm->pm_obj.uo_refs = 1;
bzero(&kpm->pm_list, sizeof(kpm->pm_list)); /* pm_list not used */
kpm->pm_pdir = (pd_entry_t *)(proc0.p_addr->u_pcb.pcb_cr3 + KERNBASE);
kpm->pm_pdirpa = (u_int32_t) proc0.p_addr->u_pcb.pcb_cr3;
kpm->pm_stats.wired_count = kpm->pm_stats.resident_count =
atop(kva_start - VM_MIN_KERNEL_ADDRESS);
/*
* the above is just a rough estimate and not critical to the proper
* operation of the system.
*/
/*
* enable global TLB entries if they are supported
*/
if (cpu_feature & CPUID_PGE) {
lcr4(rcr4() | CR4_PGE); /* enable hardware (via %cr4) */
pmap_pg_g = PG_G; /* enable software */
/* add PG_G attribute to already mapped kernel pages */
for (kva = VM_MIN_KERNEL_ADDRESS ; kva < virtual_avail ;
kva += PAGE_SIZE)
if (pmap_valid_entry(PTE_BASE[atop(kva)]))
PTE_BASE[atop(kva)] |= PG_G;
}
/*
* now we allocate the "special" VAs which are used for tmp mappings
* by the pmap (and other modules). we allocate the VAs by advancing
* virtual_avail (note that there are no pages mapped at these VAs).
* we find the PTE that maps the allocated VA via the linear PTE
* mapping.
*/
pte = PTE_BASE + atop(virtual_avail);
#ifdef MULTIPROCESSOR
/*
* Waste some VA space to avoid false sharing of cache lines
* for page table pages: Give each possible CPU a cache line
* of PTE's (8) to play with, though we only need 4. We could
* recycle some of this waste by putting the idle stacks here
* as well; we could waste less space if we knew the largest
* CPU ID beforehand.
*/
csrcp = (caddr_t) virtual_avail; csrc_pte = pte;
cdstp = (caddr_t) virtual_avail+PAGE_SIZE; cdst_pte = pte+1;
zerop = (caddr_t) virtual_avail+PAGE_SIZE*2; zero_pte = pte+2;
ptpp = (caddr_t) virtual_avail+PAGE_SIZE*3; ptp_pte = pte+3;
virtual_avail += PAGE_SIZE * MAXCPUS * NPTECL;
pte += MAXCPUS * NPTECL;
#else
csrcp = (caddr_t) virtual_avail; csrc_pte = pte; /* allocate */
virtual_avail += PAGE_SIZE; pte++; /* advance */
cdstp = (caddr_t) virtual_avail; cdst_pte = pte;
virtual_avail += PAGE_SIZE; pte++;
zerop = (caddr_t) virtual_avail; zero_pte = pte;
virtual_avail += PAGE_SIZE; pte++;
ptpp = (caddr_t) virtual_avail; ptp_pte = pte;
virtual_avail += PAGE_SIZE; pte++;
#endif
/* XXX: vmmap used by mem.c... should be uvm_map_reserve */
vmmap = (char *)virtual_avail; /* don't need pte */
virtual_avail += PAGE_SIZE;
msgbufp = (struct msgbuf *)virtual_avail; /* don't need pte */
virtual_avail += round_page(MSGBUFSIZE); pte++;
bootargp = (bootarg_t *)virtual_avail;
virtual_avail += round_page(bootargc); pte++;
/*
* now we reserve some VM for mapping pages when doing a crash dump
*/
virtual_avail = reserve_dumppages(virtual_avail);
/*
* init the static-global locks and global lists.
*/
simple_lock_init(&pvalloc_lock);
simple_lock_init(&pmaps_lock);
LIST_INIT(&pmaps);
TAILQ_INIT(&pv_freepages);
TAILQ_INIT(&pv_unusedpgs);
/*
* initialize the pmap pool.
*/
pool_init(&pmap_pmap_pool, sizeof(struct pmap), 0, 0, 0, "pmappl",
&pool_allocator_nointr);
/*
* ensure the TLB is sync'd with reality by flushing it...
*/
tlbflush();
}
/*
* pmap_init: called from uvm_init, our job is to get the pmap
* system ready to manage mappings... this mainly means initing
* the pv_entry stuff.
*/
void
pmap_init(void)
{
/*
* now we need to free enough pv_entry structures to allow us to get
* the kmem_map allocated and inited (done after this function is
* finished). to do this we allocate one bootstrap page out of
* kernel_map and use it to provide an initial pool of pv_entry
* structures. we never free this page.
*/
pv_initpage = (struct pv_page *) uvm_km_alloc(kernel_map, PAGE_SIZE);
if (pv_initpage == NULL)
panic("pmap_init: pv_initpage");
pv_cachedva = 0; /* a VA we have allocated but not used yet */
pv_nfpvents = 0;
(void) pmap_add_pvpage(pv_initpage, FALSE);
/*
* done: pmap module is up (and ready for business)
*/
pmap_initialized = TRUE;
}
/*
* p v _ e n t r y f u n c t i o n s
*/
/*
* pv_entry allocation functions:
* the main pv_entry allocation functions are:
* pmap_alloc_pv: allocate a pv_entry structure
* pmap_free_pv: free one pv_entry
* pmap_free_pvs: free a list of pv_entrys
*
* the rest are helper functions
*/
/*
* pmap_alloc_pv: inline function to allocate a pv_entry structure
* => we lock pvalloc_lock
* => if we fail, we call out to pmap_alloc_pvpage
* => 3 modes:
* ALLOCPV_NEED = we really need a pv_entry
* ALLOCPV_TRY = we want a pv_entry
* ALLOCPV_NONEED = we are trying to grow our free list, don't really need
* one now
*
* "try" is for optional functions like pmap_copy().
*/
struct pv_entry *
pmap_alloc_pv(struct pmap *pmap, int mode)
{
struct pv_page *pvpage;
struct pv_entry *pv;
simple_lock(&pvalloc_lock);
if (!TAILQ_EMPTY(&pv_freepages)) {
pvpage = TAILQ_FIRST(&pv_freepages);
pvpage->pvinfo.pvpi_nfree--;
if (pvpage->pvinfo.pvpi_nfree == 0) {
/* nothing left in this one? */
TAILQ_REMOVE(&pv_freepages, pvpage, pvinfo.pvpi_list);
}
pv = pvpage->pvinfo.pvpi_pvfree;
#ifdef DIAGNOSTIC
if (pv == NULL)
panic("pmap_alloc_pv: pvpi_nfree off");
#endif
pvpage->pvinfo.pvpi_pvfree = pv->pv_next;
pv_nfpvents--; /* took one from pool */
} else {
pv = NULL; /* need more of them */
}
/*
* if below low water mark or we didn't get a pv_entry we try and
* create more pv_entrys ...
*/
if (pv_nfpvents < PVE_LOWAT || pv == NULL) {
if (pv == NULL)
pv = pmap_alloc_pvpage(pmap, (mode == ALLOCPV_TRY) ?
mode : ALLOCPV_NEED);
else
(void) pmap_alloc_pvpage(pmap, ALLOCPV_NONEED);
}
simple_unlock(&pvalloc_lock);
return(pv);
}
/*
* pmap_alloc_pvpage: maybe allocate a new pvpage
*
* if need_entry is false: try and allocate a new pv_page
* if need_entry is true: try and allocate a new pv_page and return a
* new pv_entry from it.
*
* => we assume that the caller holds pvalloc_lock
*/
struct pv_entry *
pmap_alloc_pvpage(struct pmap *pmap, int mode)
{
struct vm_page *pg;
struct pv_page *pvpage;
struct pv_entry *pv;
int s;
/*
* if we need_entry and we've got unused pv_pages, allocate from there
*/
if (mode != ALLOCPV_NONEED && !TAILQ_EMPTY(&pv_unusedpgs)) {
/* move it to pv_freepages list */
pvpage = TAILQ_FIRST(&pv_unusedpgs);
TAILQ_REMOVE(&pv_unusedpgs, pvpage, pvinfo.pvpi_list);
TAILQ_INSERT_HEAD(&pv_freepages, pvpage, pvinfo.pvpi_list);
/* allocate a pv_entry */
pvpage->pvinfo.pvpi_nfree--; /* can't go to zero */
pv = pvpage->pvinfo.pvpi_pvfree;
#ifdef DIAGNOSTIC
if (pv == NULL)
panic("pmap_alloc_pvpage: pvpi_nfree off");
#endif
pvpage->pvinfo.pvpi_pvfree = pv->pv_next;
pv_nfpvents--; /* took one from pool */
return(pv);
}
/*
* see if we've got a cached unmapped VA that we can map a page in.
* if not, try to allocate one.
*/
s = splvm(); /* must protect kmem_map with splvm! */
if (pv_cachedva == 0) {
pv_cachedva = uvm_km_kmemalloc(kmem_map, NULL,
NBPG, UVM_KMF_TRYLOCK|UVM_KMF_VALLOC);
}
splx(s);
if (pv_cachedva == 0)
return (NULL);
pg = uvm_pagealloc(NULL, 0, NULL, UVM_PGA_USERESERVE);
if (pg == NULL)
return (NULL);
atomic_clearbits_int(&pg->pg_flags, PG_BUSY);
/*
* add a mapping for our new pv_page and free its entries (save one!)
*
* NOTE: If we are allocating a PV page for the kernel pmap, the
* pmap is already locked! (...but entering the mapping is safe...)
*/
pmap_kenter_pa(pv_cachedva, VM_PAGE_TO_PHYS(pg),
VM_PROT_READ|VM_PROT_WRITE);
pvpage = (struct pv_page *) pv_cachedva;
pv_cachedva = 0;
return (pmap_add_pvpage(pvpage, mode != ALLOCPV_NONEED));
}
/*
* pmap_add_pvpage: add a pv_page's pv_entrys to the free list
*
* => caller must hold pvalloc_lock
* => if need_entry is true, we allocate and return one pv_entry
*/
struct pv_entry *
pmap_add_pvpage(struct pv_page *pvp, boolean_t need_entry)
{
int tofree, lcv;
/* do we need to return one? */
tofree = (need_entry) ? PVE_PER_PVPAGE - 1 : PVE_PER_PVPAGE;
pvp->pvinfo.pvpi_pvfree = NULL;
pvp->pvinfo.pvpi_nfree = tofree;
for (lcv = 0 ; lcv < tofree ; lcv++) {
pvp->pvents[lcv].pv_next = pvp->pvinfo.pvpi_pvfree;
pvp->pvinfo.pvpi_pvfree = &pvp->pvents[lcv];
}
if (need_entry)
TAILQ_INSERT_TAIL(&pv_freepages, pvp, pvinfo.pvpi_list);
else
TAILQ_INSERT_TAIL(&pv_unusedpgs, pvp, pvinfo.pvpi_list);
pv_nfpvents += tofree;
return((need_entry) ? &pvp->pvents[lcv] : NULL);
}
/*
* pmap_free_pv_doit: actually free a pv_entry
*
* => do not call this directly! instead use either
* 1. pmap_free_pv ==> free a single pv_entry
* 2. pmap_free_pvs => free a list of pv_entrys
* => we must be holding pvalloc_lock
*/
void
pmap_free_pv_doit(struct pv_entry *pv)
{
struct pv_page *pvp;
pvp = (struct pv_page*)trunc_page((vaddr_t)pv);
pv_nfpvents++;
pvp->pvinfo.pvpi_nfree++;
/* nfree == 1 => fully allocated page just became partly allocated */
if (pvp->pvinfo.pvpi_nfree == 1) {
TAILQ_INSERT_HEAD(&pv_freepages, pvp, pvinfo.pvpi_list);
}
/* free it */
pv->pv_next = pvp->pvinfo.pvpi_pvfree;
pvp->pvinfo.pvpi_pvfree = pv;
/*
* are all pv_page's pv_entry's free? move it to unused queue.
*/
if (pvp->pvinfo.pvpi_nfree == PVE_PER_PVPAGE) {
TAILQ_REMOVE(&pv_freepages, pvp, pvinfo.pvpi_list);
TAILQ_INSERT_HEAD(&pv_unusedpgs, pvp, pvinfo.pvpi_list);
}
}
/*
* pmap_free_pv: free a single pv_entry
*
* => we gain the pvalloc_lock
*/
void
pmap_free_pv(struct pmap *pmap, struct pv_entry *pv)
{
simple_lock(&pvalloc_lock);
pmap_free_pv_doit(pv);
/*
* Can't free the PV page if the PV entries were associated with
* the kernel pmap; the pmap is already locked.
*/
if (pv_nfpvents > PVE_HIWAT && TAILQ_FIRST(&pv_unusedpgs) != NULL &&
pmap != pmap_kernel())
pmap_free_pvpage();
simple_unlock(&pvalloc_lock);
}
/*
* pmap_free_pvs: free a list of pv_entrys
*
* => we gain the pvalloc_lock
*/
void
pmap_free_pvs(struct pmap *pmap, struct pv_entry *pvs)
{
struct pv_entry *nextpv;
simple_lock(&pvalloc_lock);
for ( /* null */ ; pvs != NULL ; pvs = nextpv) {
nextpv = pvs->pv_next;
pmap_free_pv_doit(pvs);
}
/*
* Can't free the PV page if the PV entries were associated with
* the kernel pmap; the pmap is already locked.
*/
if (pv_nfpvents > PVE_HIWAT && TAILQ_FIRST(&pv_unusedpgs) != NULL &&
pmap != pmap_kernel())
pmap_free_pvpage();
simple_unlock(&pvalloc_lock);
}
/*
* pmap_free_pvpage: try and free an unused pv_page structure
*
* => assume caller is holding the pvalloc_lock and that
* there is a page on the pv_unusedpgs list
* => if we can't get a lock on the kmem_map we try again later
*/
void
pmap_free_pvpage(void)
{
int s;
struct vm_map *map;
struct vm_map_entry *dead_entries;
struct pv_page *pvp;
s = splvm(); /* protect kmem_map */
pvp = TAILQ_FIRST(&pv_unusedpgs);
/*
* note: watch out for pv_initpage which is allocated out of
* kernel_map rather than kmem_map.
*/
if (pvp == pv_initpage)
map = kernel_map;
else
map = kmem_map;
if (vm_map_lock_try(map)) {
/* remove pvp from pv_unusedpgs */
TAILQ_REMOVE(&pv_unusedpgs, pvp, pvinfo.pvpi_list);
/* unmap the page */
dead_entries = NULL;
uvm_unmap_remove(map, (vaddr_t)pvp, ((vaddr_t)pvp) + PAGE_SIZE,
&dead_entries, NULL);
vm_map_unlock(map);
if (dead_entries != NULL)
uvm_unmap_detach(dead_entries, 0);
pv_nfpvents -= PVE_PER_PVPAGE; /* update free count */
}
if (pvp == pv_initpage)
/* no more initpage, we've freed it */
pv_initpage = NULL;
splx(s);
}
/*
* main pv_entry manipulation functions:
* pmap_enter_pv: enter a mapping onto a pv list
* pmap_remove_pv: remove a mappiing from a pv list
*/
/*
* pmap_enter_pv: enter a mapping onto a pv list
*
* => caller should have pmap locked
* => we will gain the lock on the pv and allocate the new pv_entry
* => caller should adjust ptp's wire_count before calling
*
* pve: preallocated pve for us to use
* ptp: PTP in pmap that maps this VA
*/
void
pmap_enter_pv(struct vm_page *pg, struct pv_entry *pve, struct pmap *pmap,
vaddr_t va, struct vm_page *ptp)
{
pve->pv_pmap = pmap;
pve->pv_va = va;
pve->pv_ptp = ptp; /* NULL for kernel pmap */
pve->pv_next = pg->mdpage.pv_list; /* add to ... */
pg->mdpage.pv_list = pve; /* ... locked list */
}
/*
* pmap_remove_pv: try to remove a mapping from a pv_list
*
* => pmap should be locked
* => caller should hold lock on pv [so that attrs can be adjusted]
* => caller should adjust ptp's wire_count and free PTP if needed
* => we return the removed pve
*/
struct pv_entry *
pmap_remove_pv(struct vm_page *pg, struct pmap *pmap, vaddr_t va)
{
struct pv_entry *pve, **prevptr;
prevptr = &pg->mdpage.pv_list; /* previous pv_entry pointer */
while ((pve = *prevptr) != NULL) {
if (pve->pv_pmap == pmap && pve->pv_va == va) { /* match? */
*prevptr = pve->pv_next; /* remove it! */
break;
}
prevptr = &pve->pv_next; /* previous pointer */
}
return(pve); /* return removed pve */
}
/*
* p t p f u n c t i o n s
*/
/*
* pmap_alloc_ptp: allocate a PTP for a PMAP
*
* => pmap should already be locked by caller
* => we use the ptp's wire_count to count the number of active mappings
* in the PTP (we start it at one to prevent any chance this PTP
* will ever leak onto the active/inactive queues)
* => we may need to lock pv lists if we have to steal a PTP
* => just_try: true if we want a PTP, but not enough to steal one
* from another pmap (e.g. during optional functions like pmap_copy)
*/
struct vm_page *
pmap_alloc_ptp(struct pmap *pmap, int pde_index, boolean_t just_try,
pt_entry_t pde_flags)
{
struct vm_page *ptp;
ptp = uvm_pagealloc(&pmap->pm_obj, ptp_i2o(pde_index), NULL,
UVM_PGA_USERESERVE|UVM_PGA_ZERO);
if (ptp == NULL)
return (NULL);
/* got one! */
atomic_clearbits_int(&ptp->pg_flags, PG_BUSY);
ptp->wire_count = 1; /* no mappings yet */
pmap->pm_pdir[pde_index] = (pd_entry_t)(VM_PAGE_TO_PHYS(ptp) |
PG_RW | PG_V | PG_M | PG_U | pde_flags);
pmap->pm_stats.resident_count++; /* count PTP as resident */
pmap->pm_ptphint = ptp;
return(ptp);
}
/*
* pmap_get_ptp: get a PTP (if there isn't one, allocate a new one)
*
* => pmap should NOT be pmap_kernel()
* => pmap should be locked
*/
struct vm_page *
pmap_get_ptp(struct pmap *pmap, int pde_index, boolean_t just_try)
{
struct vm_page *ptp;
if (pmap_valid_entry(pmap->pm_pdir[pde_index])) {
/* valid... check hint (saves us a PA->PG lookup) */
if (pmap->pm_ptphint &&
(pmap->pm_pdir[pde_index] & PG_FRAME) ==
VM_PAGE_TO_PHYS(pmap->pm_ptphint))
return(pmap->pm_ptphint);
ptp = uvm_pagelookup(&pmap->pm_obj, ptp_i2o(pde_index));
#ifdef DIAGNOSTIC
if (ptp == NULL)
panic("pmap_get_ptp: unmanaged user PTP");
#endif
pmap->pm_ptphint = ptp;
return(ptp);
}
/* allocate a new PTP (updates ptphint) */
return (pmap_alloc_ptp(pmap, pde_index, just_try, PG_u));
}
/*
* p m a p l i f e c y c l e f u n c t i o n s
*/
/*
* pmap_create: create a pmap
*
* => note: old pmap interface took a "size" args which allowed for
* the creation of "software only" pmaps (not in bsd).
*/
struct pmap *
pmap_create(void)
{
struct pmap *pmap;
pmap = pool_get(&pmap_pmap_pool, PR_WAITOK);
pmap_pinit(pmap);
return(pmap);
}
/*
* pmap_pinit: given a zero'd pmap structure, init it.
*/
void
pmap_pinit(struct pmap *pmap)
{
/* init uvm_object */
simple_lock_init(&pmap->pm_obj.vmobjlock);
pmap->pm_obj.pgops = NULL; /* currently not a mappable object */
TAILQ_INIT(&pmap->pm_obj.memq);
pmap->pm_obj.uo_npages = 0;
pmap->pm_obj.uo_refs = 1;
pmap->pm_stats.wired_count = 0;
pmap->pm_stats.resident_count = 1; /* count the PDP allocd below */
pmap->pm_ptphint = NULL;
pmap->pm_hiexec = 0;
pmap->pm_flags = 0;
pmap->pm_cpus = 0;
setsegment(&pmap->pm_codeseg, 0, atop(I386_MAX_EXE_ADDR) - 1,
SDT_MEMERA, SEL_UPL, 1, 1);
/* allocate PDP */
pmap->pm_pdir = (pd_entry_t *) uvm_km_alloc(kernel_map, NBPG);
if (pmap->pm_pdir == NULL)
panic("pmap_pinit: kernel_map out of virtual space!");
(void) pmap_extract(pmap_kernel(), (vaddr_t)pmap->pm_pdir,
(paddr_t *)&pmap->pm_pdirpa);
/* init PDP */
/* zero init area */
bzero(pmap->pm_pdir, PDSLOT_PTE * sizeof(pd_entry_t));
/* put in recursive PDE to map the PTEs */
pmap->pm_pdir[PDSLOT_PTE] = pmap->pm_pdirpa | PG_V | PG_KW | PG_U |
PG_M;
/* init the LDT */
pmap->pm_ldt = NULL;
pmap->pm_ldt_len = 0;
pmap->pm_ldt_sel = GSEL(GLDT_SEL, SEL_KPL);
/*
* we need to lock pmaps_lock to prevent nkpde from changing on
* us. note that there is no need to splvm to protect us from
* malloc since malloc allocates out of a submap and we should have
* already allocated kernel PTPs to cover the range...
*/
simple_lock(&pmaps_lock);
/* put in kernel VM PDEs */
bcopy(&PDP_BASE[PDSLOT_KERN], &pmap->pm_pdir[PDSLOT_KERN],
nkpde * sizeof(pd_entry_t));
/* zero the rest */
bzero(&pmap->pm_pdir[PDSLOT_KERN + nkpde],
NBPG - ((PDSLOT_KERN + nkpde) * sizeof(pd_entry_t)));
LIST_INSERT_HEAD(&pmaps, pmap, pm_list);
simple_unlock(&pmaps_lock);
}
/*
* pmap_destroy: drop reference count on pmap. free pmap if
* reference count goes to zero.
*/
void
pmap_destroy(struct pmap *pmap)
{
int refs;
/*
* drop reference count
*/
simple_lock(&pmap->pm_obj.vmobjlock);
refs = --pmap->pm_obj.uo_refs;
simple_unlock(&pmap->pm_obj.vmobjlock);
if (refs > 0)
return;
/*
* reference count is zero, free pmap resources and then free pmap.
*/
pmap_release(pmap);
pool_put(&pmap_pmap_pool, pmap);
}
/*
* pmap_release: release all resources held by a pmap
*
* => if pmap is still referenced it should be locked
* => XXX: we currently don't expect any busy PTPs because we don't
* allow anything to map them (except for the kernel's private
* recursive mapping) or make them busy.
*/
void
pmap_release(struct pmap *pmap)
{
struct vm_page *pg;
/*
* remove it from global list of pmaps
*/
simple_lock(&pmaps_lock);
LIST_REMOVE(pmap, pm_list);
simple_unlock(&pmaps_lock);
/*
* Before we free the pmap just make sure it's not cached anywhere.
*/
tlbflushg();
/*
* free any remaining PTPs
*/
while (!TAILQ_EMPTY(&pmap->pm_obj.memq)) {
pg = TAILQ_FIRST(&pmap->pm_obj.memq);
#ifdef DIAGNOSTIC
if (pg->pg_flags & PG_BUSY)
panic("pmap_release: busy page table page");
#endif
/* pmap_page_protect? currently no need for it. */
pg->wire_count = 0;
uvm_pagefree(pg);
}
/*
* MULTIPROCESSOR -- no need to flush out of other processors'
* APTE space because we do that in pmap_unmap_ptes().
*/
uvm_km_free(kernel_map, (vaddr_t)pmap->pm_pdir, NBPG);
#ifdef USER_LDT
if (pmap->pm_flags & PMF_USER_LDT) {
/*
* no need to switch the LDT; this address space is gone,
* nothing is using it.
*
* No need to lock the pmap for ldt_free (or anything else),
* we're the last one to use it.
*/
ldt_free(pmap);
uvm_km_free(kernel_map, (vaddr_t)pmap->pm_ldt,
pmap->pm_ldt_len * sizeof(union descriptor));
}
#endif
}
/*
* Add a reference to the specified pmap.
*/
void
pmap_reference(struct pmap *pmap)
{
simple_lock(&pmap->pm_obj.vmobjlock);
pmap->pm_obj.uo_refs++;
simple_unlock(&pmap->pm_obj.vmobjlock);
}
#if defined(PMAP_FORK)
/*
* pmap_fork: perform any necessary data structure manipulation when
* a VM space is forked.
*/
void
pmap_fork(struct pmap *pmap1, struct pmap *pmap2)
{
simple_lock(&pmap1->pm_obj.vmobjlock);
simple_lock(&pmap2->pm_obj.vmobjlock);
#ifdef USER_LDT
/* Copy the LDT, if necessary. */
if (pmap1->pm_flags & PMF_USER_LDT) {
union descriptor *new_ldt;
size_t len;
len = pmap1->pm_ldt_len * sizeof(union descriptor);
new_ldt = (union descriptor *)uvm_km_alloc(kernel_map, len);
bcopy(pmap1->pm_ldt, new_ldt, len);
pmap2->pm_ldt = new_ldt;
pmap2->pm_ldt_len = pmap1->pm_ldt_len;
pmap2->pm_flags |= PMF_USER_LDT;
ldt_alloc(pmap2, new_ldt, len);
}
#endif /* USER_LDT */
simple_unlock(&pmap2->pm_obj.vmobjlock);
simple_unlock(&pmap1->pm_obj.vmobjlock);
}
#endif /* PMAP_FORK */
#ifdef USER_LDT
/*
* pmap_ldt_cleanup: if the pmap has a local LDT, deallocate it, and
* restore the default.
*/
void
pmap_ldt_cleanup(struct proc *p)
{
struct pcb *pcb = &p->p_addr->u_pcb;
pmap_t pmap = p->p_vmspace->vm_map.pmap;
union descriptor *old_ldt = NULL;
size_t len = 0;
simple_lock(&pmap->pm_obj.vmobjlock);
if (pmap->pm_flags & PMF_USER_LDT) {
ldt_free(pmap);
pmap->pm_ldt_sel = GSEL(GLDT_SEL, SEL_KPL);
pcb->pcb_ldt_sel = pmap->pm_ldt_sel;
/* Reset the cached address of the LDT that this process uses */
#ifdef MULTIPROCESSOR
pcb->pcb_ldt = curcpu()->ci_ldt;
#else
pcb->pcb_ldt = ldt;
#endif
if (pcb == curpcb)
lldt(pcb->pcb_ldt_sel);
old_ldt = pmap->pm_ldt;
len = pmap->pm_ldt_len * sizeof(union descriptor);
pmap->pm_ldt = NULL;
pmap->pm_ldt_len = 0;
pmap->pm_flags &= ~PMF_USER_LDT;
}
simple_unlock(&pmap->pm_obj.vmobjlock);
if (old_ldt != NULL)
uvm_km_free(kernel_map, (vaddr_t)old_ldt, len);
}
#endif /* USER_LDT */
/*
* pmap_activate: activate a process' pmap (fill in %cr3 and LDT info)
*
* => called from cpu_switch()
* => if proc is the curproc, then load it into the MMU
*/
void
pmap_activate(struct proc *p)
{
struct pcb *pcb = &p->p_addr->u_pcb;
struct pmap *pmap = p->p_vmspace->vm_map.pmap;
struct cpu_info *self = curcpu();
pcb->pcb_pmap = pmap;
/* Get the LDT that this process will actually use */
#ifdef MULTIPROCESSOR
pcb->pcb_ldt = pmap->pm_ldt == NULL ? self->ci_ldt : pmap->pm_ldt;
#else
pcb->pcb_ldt = pmap->pm_ldt == NULL ? ldt : pmap->pm_ldt;
#endif
pcb->pcb_ldt_sel = pmap->pm_ldt_sel;
pcb->pcb_cr3 = pmap->pm_pdirpa;
if (p == curproc) {
/*
* Set the correct descriptor value (i.e. with the
* correct code segment X limit) in the GDT and the LDT.
*/
self->ci_gdt[GUCODE_SEL].sd = pcb->pcb_ldt[LUCODE_SEL].sd =
pmap->pm_codeseg;
lcr3(pcb->pcb_cr3);
lldt(pcb->pcb_ldt_sel);
/*
* mark the pmap in use by this processor.
*/
i386_atomic_setbits_l(&pmap->pm_cpus, (1U << cpu_number()));
}
}
/*
* pmap_deactivate: deactivate a process' pmap
*/
void
pmap_deactivate(struct proc *p)
{
struct pmap *pmap = p->p_vmspace->vm_map.pmap;
/*
* mark the pmap no longer in use by this processor.
*/
i386_atomic_clearbits_l(&pmap->pm_cpus, (1U << cpu_number()));
}
/*
* end of lifecycle functions
*/
/*
* some misc. functions
*/
/*
* pmap_extract: extract a PA for the given VA
*/
boolean_t
pmap_extract(struct pmap *pmap, vaddr_t va, paddr_t *pap)
{
pt_entry_t *ptes, pte;
if (pmap_valid_entry(pmap->pm_pdir[pdei(va)])) {
ptes = pmap_map_ptes(pmap);
pte = ptes[atop(va)];
pmap_unmap_ptes(pmap);
if (!pmap_valid_entry(pte))
return (FALSE);
if (pap != NULL)
*pap = (pte & PG_FRAME) | (va & ~PG_FRAME);
return (TRUE);
}
return (FALSE);
}
/*
* pmap_virtual_space: used during bootup [pmap_steal_memory] to
* determine the bounds of the kernel virtual address space.
*/
void
pmap_virtual_space(vaddr_t *startp, vaddr_t *endp)
{
*startp = virtual_avail;
*endp = virtual_end;
}
/*
* pmap_zero_page: zero a page
*/
void (*pagezero)(void *, size_t) = bzero;
void
pmap_zero_page(struct vm_page *pg)
{
pmap_zero_phys(VM_PAGE_TO_PHYS(pg));
}
/*
* pmap_zero_phys: same as pmap_zero_page, but for use before vm_pages are
* initialized.
*/
void
pmap_zero_phys(paddr_t pa)
{
#ifdef MULTIPROCESSOR
int id = cpu_number();
#endif
pt_entry_t *zpte = PTESLEW(zero_pte, id);
caddr_t zerova = VASLEW(zerop, id);
#ifdef DIAGNOSTIC
if (*zpte)
panic("pmap_zero_phys: lock botch");
#endif
*zpte = (pa & PG_FRAME) | PG_V | PG_RW; /* map in */
pmap_update_pg((vaddr_t)zerova); /* flush TLB */
pagezero(zerova, PAGE_SIZE); /* zero */
*zpte = 0; /* zap! */
}
/*
* pmap_zero_page_uncached: the same, except uncached.
*/
boolean_t
pmap_zero_page_uncached(paddr_t pa)
{
#ifdef MULTIPROCESSOR
int id = cpu_number();
#endif
pt_entry_t *zpte = PTESLEW(zero_pte, id);
caddr_t zerova = VASLEW(zerop, id);
#ifdef DIAGNOSTIC
if (*zpte)
panic("pmap_zero_page_uncached: lock botch");
#endif
*zpte = (pa & PG_FRAME) | PG_V | PG_RW | PG_N; /* map in */
pmap_update_pg((vaddr_t)zerova); /* flush TLB */
pagezero(zerova, PAGE_SIZE); /* zero */
*zpte = 0; /* zap! */
return (TRUE);
}
/*
* pmap_copy_page: copy a page
*/
void
pmap_copy_page(struct vm_page *srcpg, struct vm_page *dstpg)
{
paddr_t srcpa = VM_PAGE_TO_PHYS(srcpg);
paddr_t dstpa = VM_PAGE_TO_PHYS(dstpg);
#ifdef MULTIPROCESSOR
int id = cpu_number();
#endif
pt_entry_t *spte = PTESLEW(csrc_pte, id);
pt_entry_t *dpte = PTESLEW(cdst_pte, id);
caddr_t csrcva = VASLEW(csrcp, id);
caddr_t cdstva = VASLEW(cdstp, id);
#ifdef DIAGNOSTIC
if (*spte || *dpte)
panic("pmap_copy_page: lock botch");
#endif
*spte = (srcpa & PG_FRAME) | PG_V | PG_RW;
*dpte = (dstpa & PG_FRAME) | PG_V | PG_RW;
pmap_update_2pg((vaddr_t)csrcva, (vaddr_t)cdstva);
bcopy(csrcva, cdstva, PAGE_SIZE);
*spte = *dpte = 0; /* zap! */
pmap_update_2pg((vaddr_t)csrcva, (vaddr_t)cdstva);
}
/*
* p m a p r e m o v e f u n c t i o n s
*
* functions that remove mappings
*/
/*
* pmap_remove_ptes: remove PTEs from a PTP
*
* => must have proper locking on pmap_master_lock
* => caller must hold pmap's lock
* => PTP must be mapped into KVA
* => PTP should be null if pmap == pmap_kernel()
*/
void
pmap_remove_ptes(struct pmap *pmap, struct vm_page *ptp, vaddr_t ptpva,
vaddr_t startva, vaddr_t endva, int flags)
{
struct pv_entry *pv_tofree = NULL; /* list of pv_entrys to free */
struct pv_entry *pve;
pt_entry_t *pte = (pt_entry_t *) ptpva;
struct vm_page *pg;
pt_entry_t opte;
/*
* note that ptpva points to the PTE that maps startva. this may
* or may not be the first PTE in the PTP.
*
* we loop through the PTP while there are still PTEs to look at
* and the wire_count is greater than 1 (because we use the wire_count
* to keep track of the number of real PTEs in the PTP).
*/
for (/*null*/; startva < endva && (ptp == NULL || ptp->wire_count > 1)
; pte++, startva += NBPG) {
if (!pmap_valid_entry(*pte))
continue; /* VA not mapped */
if ((flags & PMAP_REMOVE_SKIPWIRED) && (*pte & PG_W))
continue;
/* atomically save the old PTE and zap! it */
opte = i386_atomic_testset_ul(pte, 0);
if (opte & PG_W)
pmap->pm_stats.wired_count--;
pmap->pm_stats.resident_count--;
if (ptp)
ptp->wire_count--; /* dropping a PTE */
/*
* Unnecessary work if not PG_VLIST.
*/
pg = PHYS_TO_VM_PAGE(opte & PG_FRAME);
/*
* if we are not on a pv list we are done.
*/
if ((opte & PG_PVLIST) == 0) {
#ifdef DIAGNOSTIC
if (pg != NULL)
panic("pmap_remove_ptes: managed page without "
"PG_PVLIST for 0x%lx", startva);
#endif
continue;
}
#ifdef DIAGNOSTIC
if (pg == NULL)
panic("pmap_remove_ptes: unmanaged page marked "
"PG_PVLIST, va = 0x%lx, pa = 0x%lx",
startva, (u_long)(opte & PG_FRAME));
#endif
/* sync R/M bits */
pmap_sync_flags_pte(pg, opte);
pve = pmap_remove_pv(pg, pmap, startva);
if (pve) {
pve->pv_next = pv_tofree;
pv_tofree = pve;
}
/* end of "for" loop: time for next pte */
}
if (pv_tofree)
pmap_free_pvs(pmap, pv_tofree);
}
/*
* pmap_remove_pte: remove a single PTE from a PTP
*
* => must have proper locking on pmap_master_lock
* => caller must hold pmap's lock
* => PTP must be mapped into KVA
* => PTP should be null if pmap == pmap_kernel()
* => returns true if we removed a mapping
*/
boolean_t
pmap_remove_pte(struct pmap *pmap, struct vm_page *ptp, pt_entry_t *pte,
vaddr_t va, int flags)
{
struct pv_entry *pve;
struct vm_page *pg;
pt_entry_t opte;
if (!pmap_valid_entry(*pte))
return (FALSE); /* VA not mapped */
if ((flags & PMAP_REMOVE_SKIPWIRED) && (*pte & PG_W))
return (FALSE);
opte = *pte; /* save the old PTE */
*pte = 0; /* zap! */
pmap_exec_account(pmap, va, opte, 0);
if (opte & PG_W)
pmap->pm_stats.wired_count--;
pmap->pm_stats.resident_count--;
if (ptp)
ptp->wire_count--; /* dropping a PTE */
pg = PHYS_TO_VM_PAGE(opte & PG_FRAME);
/*
* if we are not on a pv list we are done.
*/
if ((opte & PG_PVLIST) == 0) {
#ifdef DIAGNOSTIC
if (pg != NULL)
panic("pmap_remove_pte: managed page without "
"PG_PVLIST for 0x%lx", va);
#endif
return(TRUE);
}
#ifdef DIAGNOSTIC
if (pg == NULL)
panic("pmap_remove_pte: unmanaged page marked "
"PG_PVLIST, va = 0x%lx, pa = 0x%lx", va,
(u_long)(opte & PG_FRAME));
#endif
pmap_sync_flags_pte(pg, opte);
pve = pmap_remove_pv(pg, pmap, va);
if (pve)
pmap_free_pv(pmap, pve);
return(TRUE);
}
/*
* pmap_remove: top level mapping removal function
*
* => caller should not be holding any pmap locks
*/
void
pmap_remove(struct pmap *pmap, vaddr_t sva, vaddr_t eva)
{
pmap_do_remove(pmap, sva, eva, PMAP_REMOVE_ALL);
}
void
pmap_do_remove(struct pmap *pmap, vaddr_t sva, vaddr_t eva, int flags)
{
pt_entry_t *ptes, opte;
boolean_t result;
paddr_t ptppa;
vaddr_t blkendva;
struct vm_page *ptp;
TAILQ_HEAD(, vm_page) empty_ptps;
int shootall;
vaddr_t va;
TAILQ_INIT(&empty_ptps);
PMAP_MAP_TO_HEAD_LOCK();
ptes = pmap_map_ptes(pmap); /* locks pmap */
/*
* removing one page? take shortcut function.
*/
if (sva + PAGE_SIZE == eva) {
if (pmap_valid_entry(pmap->pm_pdir[pdei(sva)])) {
/* PA of the PTP */
ptppa = pmap->pm_pdir[pdei(sva)] & PG_FRAME;
/* get PTP if non-kernel mapping */
if (pmap == pmap_kernel()) {
/* we never free kernel PTPs */
ptp = NULL;
} else {
if (pmap->pm_ptphint &&
VM_PAGE_TO_PHYS(pmap->pm_ptphint) ==
ptppa) {
ptp = pmap->pm_ptphint;
} else {
ptp = PHYS_TO_VM_PAGE(ptppa);
#ifdef DIAGNOSTIC
if (ptp == NULL)
panic("pmap_remove: unmanaged "
"PTP detected");
#endif
}
}
/* do it! */
result = pmap_remove_pte(pmap, ptp, &ptes[atop(sva)],
sva, flags);
/*
* if mapping removed and the PTP is no longer
* being used, free it!
*/
if (result && ptp && ptp->wire_count <= 1) {
opte = i386_atomic_testset_ul(
&pmap->pm_pdir[pdei(sva)], 0);
#ifdef MULTIPROCESSOR
/*
* XXXthorpej Redundant shootdown can happen
* here if we're using APTE space.
*/
#endif
pmap_tlb_shootpage(curpcb->pcb_pmap,
((vaddr_t)ptes) + ptp->offset);
#ifdef MULTIPROCESSOR
/*
* Always shoot down the pmap's self-mapping
* of the PTP.
* XXXthorpej Redundant shootdown can happen
* here if pmap == curpcb->pcb_pmap (not APTE
* space).
*/
pmap_tlb_shootpage(pmap,
((vaddr_t)PTE_BASE) + ptp->offset);
#endif
pmap->pm_stats.resident_count--;
if (pmap->pm_ptphint == ptp)
pmap->pm_ptphint =
TAILQ_FIRST(&pmap->pm_obj.memq);
ptp->wire_count = 0;
/* Postpone free to after shootdown. */
uvm_pagerealloc(ptp, NULL, 0);
TAILQ_INSERT_TAIL(&empty_ptps, ptp, listq);
}
/*
* Shoot the tlb after any updates to the PDE.
*/
pmap_tlb_shootpage(pmap, sva);
}
pmap_tlb_shootwait();
pmap_unmap_ptes(pmap); /* unlock pmap */
PMAP_MAP_TO_HEAD_UNLOCK();
while ((ptp = TAILQ_FIRST(&empty_ptps)) != NULL) {
TAILQ_REMOVE(&empty_ptps, ptp, listq);
uvm_pagefree(ptp);
}
return;
}
/*
* Decide if we want to shoot the whole tlb or just the range.
* Right now, we simply shoot everything when we remove more
* than 32 pages, but never in the kernel pmap. XXX - tune.
*/
if ((eva - sva > 32 * PAGE_SIZE) && pmap != pmap_kernel())
shootall = 1;
else
shootall = 0;
for (va = sva ; va < eva ; va = blkendva) {
/* determine range of block */
blkendva = i386_round_pdr(va + 1);
if (blkendva > eva)
blkendva = eva;
/*
* XXXCDC: our PTE mappings should never be removed
* with pmap_remove! if we allow this (and why would
* we?) then we end up freeing the pmap's page
* directory page (PDP) before we are finished using
* it when we hit in in the recursive mapping. this
* is BAD.
*
* long term solution is to move the PTEs out of user
* address space. and into kernel address space (up
* with APTE). then we can set VM_MAXUSER_ADDRESS to
* be VM_MAX_ADDRESS.
*/
if (pdei(va) == PDSLOT_PTE)
/* XXXCDC: ugly hack to avoid freeing PDP here */
continue;
if (!pmap_valid_entry(pmap->pm_pdir[pdei(va)]))
/* valid block? */
continue;
/* PA of the PTP */
ptppa = (pmap->pm_pdir[pdei(va)] & PG_FRAME);
/* get PTP if non-kernel mapping */
if (pmap == pmap_kernel()) {
/* we never free kernel PTPs */
ptp = NULL;
} else {
if (pmap->pm_ptphint &&
VM_PAGE_TO_PHYS(pmap->pm_ptphint) == ptppa) {
ptp = pmap->pm_ptphint;
} else {
ptp = PHYS_TO_VM_PAGE(ptppa);
#ifdef DIAGNOSTIC
if (ptp == NULL)
panic("pmap_remove: unmanaged PTP "
"detected");
#endif
}
}
pmap_remove_ptes(pmap, ptp, (vaddr_t)&ptes[atop(va)],
va, blkendva, flags);
/* if PTP is no longer being used, free it! */
if (ptp && ptp->wire_count <= 1) {
opte = i386_atomic_testset_ul(
&pmap->pm_pdir[pdei(va)], 0);
#if defined(MULTIPROCESSOR)
/*
* XXXthorpej Redundant shootdown can happen here
* if we're using APTE space.
*/
#endif
pmap_tlb_shootpage(curpcb->pcb_pmap,
((vaddr_t)ptes) + ptp->offset);
#if defined(MULTIPROCESSOR)
/*
* Always shoot down the pmap's self-mapping
* of the PTP.
* XXXthorpej Redundant shootdown can happen here
* if pmap == curpcb->pcb_pmap (not APTE space).
*/
pmap_tlb_shootpage(pmap,
((vaddr_t)PTE_BASE) + ptp->offset);
#endif
pmap->pm_stats.resident_count--;
if (pmap->pm_ptphint == ptp) /* update hint? */
pmap->pm_ptphint =
TAILQ_FIRST(&pmap->pm_obj.memq);
ptp->wire_count = 0;
/* Postpone free to after shootdown. */
uvm_pagerealloc(ptp, NULL, 0);
TAILQ_INSERT_TAIL(&empty_ptps, ptp, listq);
}
}
if (!shootall)
pmap_tlb_shootrange(pmap, sva, eva);
else
pmap_tlb_shoottlb();
pmap_tlb_shootwait();
pmap_unmap_ptes(pmap);
PMAP_MAP_TO_HEAD_UNLOCK();
while ((ptp = TAILQ_FIRST(&empty_ptps)) != NULL) {
TAILQ_REMOVE(&empty_ptps, ptp, listq);
uvm_pagefree(ptp);
}
}
/*
* pmap_page_remove: remove a managed vm_page from all pmaps that map it
*
* => R/M bits are sync'd back to attrs
*/
void
pmap_page_remove(struct vm_page *pg)
{
struct pv_entry *pve;
pt_entry_t *ptes, opte;
TAILQ_HEAD(, vm_page) empty_ptps;
struct vm_page *ptp;
if (pg->mdpage.pv_list == NULL)
return;
TAILQ_INIT(&empty_ptps);
PMAP_HEAD_TO_MAP_LOCK();
for (pve = pg->mdpage.pv_list ; pve != NULL ; pve = pve->pv_next) {
ptes = pmap_map_ptes(pve->pv_pmap); /* locks pmap */
#ifdef DIAGNOSTIC
if (pve->pv_va >= uvm.pager_sva && pve->pv_va < uvm.pager_eva)
printf("pmap_page_remove: found pager VA on pv_list\n");
if (pve->pv_ptp && (pve->pv_pmap->pm_pdir[pdei(pve->pv_va)] &
PG_FRAME)
!= VM_PAGE_TO_PHYS(pve->pv_ptp)) {
printf("pmap_page_remove: pg=%p: va=%lx, pv_ptp=%p\n",
pg, pve->pv_va, pve->pv_ptp);
printf("pmap_page_remove: PTP's phys addr: "
"actual=%x, recorded=%lx\n",
(pve->pv_pmap->pm_pdir[pdei(pve->pv_va)] &
PG_FRAME), VM_PAGE_TO_PHYS(pve->pv_ptp));
panic("pmap_page_remove: mapped managed page has "
"invalid pv_ptp field");
}
#endif
opte = i386_atomic_testset_ul(&ptes[atop(pve->pv_va)], 0);
if (opte & PG_W)
pve->pv_pmap->pm_stats.wired_count--;
pve->pv_pmap->pm_stats.resident_count--;
/* sync R/M bits */
pmap_sync_flags_pte(pg, opte);
/* update the PTP reference count. free if last reference. */
if (pve->pv_ptp) {
pve->pv_ptp->wire_count--;
if (pve->pv_ptp->wire_count <= 1) {
opte = i386_atomic_testset_ul(
&pve->pv_pmap->pm_pdir[pdei(pve->pv_va)],
0);
pmap_tlb_shootpage(curpcb->pcb_pmap,
((vaddr_t)ptes) + pve->pv_ptp->offset);
#if defined(MULTIPROCESSOR)
/*
* Always shoot down the other pmap's
* self-mapping of the PTP.
*/
pmap_tlb_shootpage(pve->pv_pmap,
((vaddr_t)PTE_BASE) + pve->pv_ptp->offset);
#endif
pve->pv_pmap->pm_stats.resident_count--;
/* update hint? */
if (pve->pv_pmap->pm_ptphint == pve->pv_ptp)
pve->pv_pmap->pm_ptphint =
TAILQ_FIRST(&pve->pv_pmap->pm_obj.memq);
pve->pv_ptp->wire_count = 0;
/* Postpone free to after shootdown. */
uvm_pagerealloc(pve->pv_ptp, NULL, 0);
TAILQ_INSERT_TAIL(&empty_ptps, pve->pv_ptp,
listq);
}
}
pmap_tlb_shootpage(pve->pv_pmap, pve->pv_va);
pmap_unmap_ptes(pve->pv_pmap); /* unlocks pmap */
}
pmap_free_pvs(NULL, pg->mdpage.pv_list);
pg->mdpage.pv_list = NULL;
PMAP_HEAD_TO_MAP_UNLOCK();
pmap_tlb_shootwait();
while ((ptp = TAILQ_FIRST(&empty_ptps)) != NULL) {
TAILQ_REMOVE(&empty_ptps, ptp, listq);
uvm_pagefree(ptp);
}
}
/*
* p m a p a t t r i b u t e f u n c t i o n s
* functions that test/change managed page's attributes
* since a page can be mapped multiple times we must check each PTE that
* maps it by going down the pv lists.
*/
/*
* pmap_test_attrs: test a page's attributes
*/
boolean_t
pmap_test_attrs(struct vm_page *pg, int testbits)
{
struct pv_entry *pve;
pt_entry_t *ptes, pte;
u_long mybits, testflags;
testflags = pmap_pte2flags(testbits);
if (pg->pg_flags & testflags)
return (TRUE);
PMAP_HEAD_TO_MAP_LOCK();
mybits = 0;
for (pve = pg->mdpage.pv_list; pve != NULL && mybits == 0;
pve = pve->pv_next) {
ptes = pmap_map_ptes(pve->pv_pmap);
pte = ptes[atop(pve->pv_va)];
pmap_unmap_ptes(pve->pv_pmap);
mybits |= (pte & testbits);
}
PMAP_HEAD_TO_MAP_UNLOCK();
if (mybits == 0)
return (FALSE);
atomic_setbits_int(&pg->pg_flags, pmap_pte2flags(mybits));
return (TRUE);
}
/*
* pmap_clear_attrs: change a page's attributes
*
* => we return TRUE if we cleared one of the bits we were asked to
*/
boolean_t
pmap_clear_attrs(struct vm_page *pg, int clearbits)
{
struct pv_entry *pve;
pt_entry_t *ptes, npte, opte;
u_long clearflags;
int result;
clearflags = pmap_pte2flags(clearbits);
PMAP_HEAD_TO_MAP_LOCK();
result = pg->pg_flags & clearflags;
if (result)
atomic_clearbits_int(&pg->pg_flags, clearflags);
for (pve = pg->mdpage.pv_list; pve != NULL; pve = pve->pv_next) {
#ifdef DIAGNOSTIC
if (!pmap_valid_entry(pve->pv_pmap->pm_pdir[pdei(pve->pv_va)]))
panic("pmap_change_attrs: mapping without PTP "
"detected");
#endif
ptes = pmap_map_ptes(pve->pv_pmap); /* locks pmap */
npte = ptes[atop(pve->pv_va)];
if (npte & clearbits) {
result = TRUE;
npte &= ~clearbits;
opte = i386_atomic_testset_ul(
&ptes[atop(pve->pv_va)], npte);
pmap_tlb_shootpage(pve->pv_pmap, pve->pv_va);
}
pmap_unmap_ptes(pve->pv_pmap); /* unlocks pmap */
}
PMAP_HEAD_TO_MAP_UNLOCK();
pmap_tlb_shootwait();
return (result != 0);
}
/*
* p m a p p r o t e c t i o n f u n c t i o n s
*/
/*
* pmap_page_protect: change the protection of all recorded mappings
* of a managed page
*
* => NOTE: this is an inline function in pmap.h
*/
/* see pmap.h */
/*
* pmap_protect: set the protection in of the pages in a pmap
*
* => NOTE: this is an inline function in pmap.h
*/
/* see pmap.h */
/*
* pmap_write_protect: write-protect pages in a pmap
*/
void
pmap_write_protect(struct pmap *pmap, vaddr_t sva, vaddr_t eva,
vm_prot_t prot)
{
pt_entry_t *ptes, *spte, *epte, npte;
vaddr_t blockend;
u_int32_t md_prot;
vaddr_t va;
int shootall = 0;
ptes = pmap_map_ptes(pmap); /* locks pmap */
/* should be ok, but just in case ... */
sva &= PG_FRAME;
eva &= PG_FRAME;
if ((eva - sva > 32 * PAGE_SIZE) && pmap != pmap_kernel())
shootall = 1;
for (va = sva; va < eva; va = blockend) {
blockend = (va & PD_MASK) + NBPD;
if (blockend > eva)
blockend = eva;
/*
* XXXCDC: our PTE mappings should never be write-protected!
*
* long term solution is to move the PTEs out of user
* address space. and into kernel address space (up
* with APTE). then we can set VM_MAXUSER_ADDRESS to
* be VM_MAX_ADDRESS.
*/
/* XXXCDC: ugly hack to avoid freeing PDP here */
if (pdei(va) == PDSLOT_PTE)
continue;
/* empty block? */
if (!pmap_valid_entry(pmap->pm_pdir[pdei(va)]))
continue;
md_prot = protection_codes[prot];
if (va < VM_MAXUSER_ADDRESS)
md_prot |= PG_u;
else if (va < VM_MAX_ADDRESS)
/* XXX: write-prot our PTES? never! */
md_prot |= (PG_u | PG_RW);
spte = &ptes[atop(va)];
epte = &ptes[atop(blockend)];
for (/*null */; spte < epte ; spte++, va += PAGE_SIZE) {
if (!pmap_valid_entry(*spte)) /* no mapping? */
continue;
npte = (*spte & ~PG_PROT) | md_prot;
if (npte != *spte) {
pmap_exec_account(pmap, va, *spte, npte);
i386_atomic_testset_ul(spte, npte);
}
}
}
if (shootall)
pmap_tlb_shoottlb();
else
pmap_tlb_shootrange(pmap, sva, eva);
pmap_tlb_shootwait();
pmap_unmap_ptes(pmap); /* unlocks pmap */
}
/*
* end of protection functions
*/
/*
* pmap_unwire: clear the wired bit in the PTE
*
* => mapping should already be in map
*/
void
pmap_unwire(struct pmap *pmap, vaddr_t va)
{
pt_entry_t *ptes;
if (pmap_valid_entry(pmap->pm_pdir[pdei(va)])) {
ptes = pmap_map_ptes(pmap); /* locks pmap */
#ifdef DIAGNOSTIC
if (!pmap_valid_entry(ptes[atop(va)]))
panic("pmap_unwire: invalid (unmapped) va 0x%lx", va);
#endif
if ((ptes[atop(va)] & PG_W) != 0) {
ptes[atop(va)] &= ~PG_W;
pmap->pm_stats.wired_count--;
}
#ifdef DIAGNOSTIC
else {
printf("pmap_unwire: wiring for pmap %p va 0x%lx "
"didn't change!\n", pmap, va);
}
#endif
pmap_unmap_ptes(pmap); /* unlocks map */
}
#ifdef DIAGNOSTIC
else {
panic("pmap_unwire: invalid PDE");
}
#endif
}
/*
* pmap_collect: free resources held by a pmap
*
* => optional function.
* => called when a process is swapped out to free memory.
*/
void
pmap_collect(struct pmap *pmap)
{
/*
* free all of the pt pages by removing the physical mappings
* for its entire address space.
*/
pmap_do_remove(pmap, VM_MIN_ADDRESS, VM_MAX_ADDRESS,
PMAP_REMOVE_SKIPWIRED);
}
/*
* pmap_copy: copy mappings from one pmap to another
*
* => optional function
* void pmap_copy(dst_pmap, src_pmap, dst_addr, len, src_addr)
*/
/*
* defined as macro in pmap.h
*/
/*
* pmap_enter: enter a mapping into a pmap
*
* => must be done "now" ... no lazy-evaluation
*/
int
pmap_enter(struct pmap *pmap, vaddr_t va, paddr_t pa,
vm_prot_t prot, int flags)
{
pt_entry_t *ptes, opte, npte;
struct vm_page *ptp;
struct pv_entry *pve = NULL;
boolean_t wired = (flags & PMAP_WIRED) != 0;
struct vm_page *pg = NULL;
int error;
#ifdef DIAGNOSTIC
/* sanity check: totally out of range? */
if (va >= VM_MAX_KERNEL_ADDRESS)
panic("pmap_enter: too big");
if (va == (vaddr_t) PDP_BASE || va == (vaddr_t) APDP_BASE)
panic("pmap_enter: trying to map over PDP/APDP!");
/* sanity check: kernel PTPs should already have been pre-allocated */
if (va >= VM_MIN_KERNEL_ADDRESS &&
!pmap_valid_entry(pmap->pm_pdir[pdei(va)]))
panic("pmap_enter: missing kernel PTP!");
#endif
/* get lock */
PMAP_MAP_TO_HEAD_LOCK();
/*
* map in ptes and get a pointer to our PTP (unless we are the kernel)
*/
ptes = pmap_map_ptes(pmap); /* locks pmap */
if (pmap == pmap_kernel()) {
ptp = NULL;
} else {
ptp = pmap_get_ptp(pmap, pdei(va), FALSE);
if (ptp == NULL) {
if (flags & PMAP_CANFAIL) {
error = ENOMEM;
goto out;
}
panic("pmap_enter: get ptp failed");
}
}
opte = ptes[atop(va)]; /* old PTE */
/*
* is there currently a valid mapping at our VA?
*/
if (pmap_valid_entry(opte)) {
/*
* first, update pm_stats. resident count will not
* change since we are replacing/changing a valid
* mapping. wired count might change...
*/
if (wired && (opte & PG_W) == 0)
pmap->pm_stats.wired_count++;
else if (!wired && (opte & PG_W) != 0)
pmap->pm_stats.wired_count--;
/*
* is the currently mapped PA the same as the one we
* want to map?
*/
if ((opte & PG_FRAME) == pa) {
/* if this is on the PVLIST, sync R/M bit */
if (opte & PG_PVLIST) {
pg = PHYS_TO_VM_PAGE(pa);
#ifdef DIAGNOSTIC
if (pg == NULL)
panic("pmap_enter: same pa PG_PVLIST "
"mapping with unmanaged page "
"pa = 0x%lx (0x%lx)", pa,
atop(pa));
#endif
pmap_sync_flags_pte(pg, opte);
}
goto enter_now;
}
/*
* changing PAs: we must remove the old one first
*/
/*
* if current mapping is on a pvlist,
* remove it (sync R/M bits)
*/
if (opte & PG_PVLIST) {
pg = PHYS_TO_VM_PAGE(opte & PG_FRAME);
#ifdef DIAGNOSTIC
if (pg == NULL)
panic("pmap_enter: PG_PVLIST mapping with "
"unmanaged page "
"pa = 0x%lx (0x%lx)", pa, atop(pa));
#endif
pmap_sync_flags_pte(pg, opte);
pve = pmap_remove_pv(pg, pmap, va);
pg = NULL; /* This is not page we are looking for */
}
} else { /* opte not valid */
pmap->pm_stats.resident_count++;
if (wired)
pmap->pm_stats.wired_count++;
if (ptp)
ptp->wire_count++; /* count # of valid entries */
}
/*
* at this point pm_stats has been updated. pve is either NULL
* or points to a now-free pv_entry structure (the latter case is
* if we called pmap_remove_pv above).
*
* if this entry is to be on a pvlist, enter it now.
*/
if (pmap_initialized && pg == NULL)
pg = PHYS_TO_VM_PAGE(pa);
if (pg != NULL) {
if (pve == NULL) {
pve = pmap_alloc_pv(pmap, ALLOCPV_NEED);
if (pve == NULL) {
if (flags & PMAP_CANFAIL) {
/*
* XXX - Back out stats changes!
*/
error = ENOMEM;
goto out;
}
panic("pmap_enter: no pv entries available");
}
}
/* lock pvh when adding */
pmap_enter_pv(pg, pve, pmap, va, ptp);
} else {
/* new mapping is not PG_PVLIST. free pve if we've got one */
if (pve)
pmap_free_pv(pmap, pve);
}
enter_now:
/*
* at this point pvh is !NULL if we want the PG_PVLIST bit set
*/
npte = pa | protection_codes[prot] | PG_V;
pmap_exec_account(pmap, va, opte, npte);
if (wired)
npte |= PG_W;
if (va < VM_MAXUSER_ADDRESS)
npte |= PG_u;
else if (va < VM_MAX_ADDRESS)
npte |= (PG_u | PG_RW); /* XXXCDC: no longer needed? */
if (pmap == pmap_kernel())
npte |= pmap_pg_g;
if (flags & VM_PROT_READ)
npte |= PG_U;
if (flags & VM_PROT_WRITE)
npte |= PG_M;
if (pg) {
npte |= PG_PVLIST;
pmap_sync_flags_pte(pg, npte);
}
opte = i386_atomic_testset_ul(&ptes[atop(va)], npte);
if (opte & PG_V) {
pmap_tlb_shootpage(pmap, va);
pmap_tlb_shootwait();
}
error = 0;
out:
pmap_unmap_ptes(pmap);
PMAP_MAP_TO_HEAD_UNLOCK();
return error;
}
/*
* pmap_growkernel: increase usage of KVM space
*
* => we allocate new PTPs for the kernel and install them in all
* the pmaps on the system.
*/
vaddr_t
pmap_growkernel(vaddr_t maxkvaddr)
{
struct pmap *kpm = pmap_kernel(), *pm;
int needed_kpde; /* needed number of kernel PTPs */
int s;
paddr_t ptaddr;
needed_kpde = (int)(maxkvaddr - VM_MIN_KERNEL_ADDRESS + (NBPD-1))
/ NBPD;
if (needed_kpde <= nkpde)
goto out; /* we are OK */
/*
* whoops! we need to add kernel PTPs
*/
s = splhigh(); /* to be safe */
simple_lock(&kpm->pm_obj.vmobjlock);
for (/*null*/ ; nkpde < needed_kpde ; nkpde++) {
if (uvm.page_init_done == FALSE) {
/*
* we're growing the kernel pmap early (from
* uvm_pageboot_alloc()). this case must be
* handled a little differently.
*/
if (uvm_page_physget(&ptaddr) == FALSE)
panic("pmap_growkernel: out of memory");
pmap_zero_phys(ptaddr);
kpm->pm_pdir[PDSLOT_KERN + nkpde] =
ptaddr | PG_RW | PG_V | PG_U | PG_M;
/* count PTP as resident */
kpm->pm_stats.resident_count++;
continue;
}
/*
* THIS *MUST* BE CODED SO AS TO WORK IN THE
* pmap_initialized == FALSE CASE! WE MAY BE
* INVOKED WHILE pmap_init() IS RUNNING!
*/
while (!pmap_alloc_ptp(kpm, PDSLOT_KERN + nkpde, FALSE, 0))
uvm_wait("pmap_growkernel");
/* distribute new kernel PTP to all active pmaps */
simple_lock(&pmaps_lock);
LIST_FOREACH(pm, &pmaps, pm_list) {
pm->pm_pdir[PDSLOT_KERN + nkpde] =
kpm->pm_pdir[PDSLOT_KERN + nkpde];
}
simple_unlock(&pmaps_lock);
}
simple_unlock(&kpm->pm_obj.vmobjlock);
splx(s);
out:
return (VM_MIN_KERNEL_ADDRESS + (nkpde * NBPD));
}
#ifdef DEBUG
void pmap_dump(struct pmap *, vaddr_t, vaddr_t);
/*
* pmap_dump: dump all the mappings from a pmap
*
* => caller should not be holding any pmap locks
*/
void
pmap_dump(struct pmap *pmap, vaddr_t sva, vaddr_t eva)
{
pt_entry_t *ptes, *pte;
vaddr_t blkendva;
/*
* if end is out of range truncate.
* if (end == start) update to max.
*/
if (eva > VM_MAXUSER_ADDRESS || eva <= sva)
eva = VM_MAXUSER_ADDRESS;
PMAP_MAP_TO_HEAD_LOCK();
ptes = pmap_map_ptes(pmap); /* locks pmap */
/*
* dumping a range of pages: we dump in PTP sized blocks (4MB)
*/
for (/* null */ ; sva < eva ; sva = blkendva) {
/* determine range of block */
blkendva = i386_round_pdr(sva+1);
if (blkendva > eva)
blkendva = eva;
/* valid block? */
if (!pmap_valid_entry(pmap->pm_pdir[pdei(sva)]))
continue;
pte = &ptes[atop(sva)];
for (/* null */; sva < blkendva ; sva += NBPG, pte++) {
if (!pmap_valid_entry(*pte))
continue;
printf("va %#lx -> pa %#x (pte=%#x)\n",
sva, *pte, *pte & PG_FRAME);
}
}
pmap_unmap_ptes(pmap);
PMAP_MAP_TO_HEAD_UNLOCK();
}
#endif
#ifdef MULTIPROCESSOR
/*
* Locking for tlb shootdown.
*
* We lock by setting tlb_shoot_wait to the number of cpus that will
* receive our tlb shootdown. After sending the IPIs, we don't need to
* worry about locking order or interrupts spinning for the lock because
* the call that grabs the "lock" isn't the one that releases it. And
* there is nothing that can block the IPI that releases the lock.
*
* The functions are organized so that we first count the number of
* cpus we need to send the IPI to, then we grab the counter, then
* we send the IPIs, then we finally do our own shootdown.
*
* Our shootdown is last to make it parallell with the other cpus
* to shorten the spin time.
*
* Notice that we depend on failures to send IPIs only being able to
* happen during boot. If they happen later, the above assumption
* doesn't hold since we can end up in situations where noone will
* release the lock if we get an interrupt in a bad moment.
*/
volatile int tlb_shoot_wait;
volatile vaddr_t tlb_shoot_addr1;
volatile vaddr_t tlb_shoot_addr2;
void
pmap_tlb_shootpage(struct pmap *pm, vaddr_t va)
{
struct cpu_info *ci, *self = curcpu();
CPU_INFO_ITERATOR cii;
int wait = 0;
int mask = 0;
CPU_INFO_FOREACH(cii, ci) {
if (ci == self || !pmap_is_active(pm, ci->ci_cpuid) ||
!(ci->ci_flags & CPUF_RUNNING))
continue;
mask |= 1 << ci->ci_cpuid;
wait++;
}
if (wait > 0) {
int s = splvm();
while (i486_atomic_cas_int(&tlb_shoot_wait, 0, wait) != 0) {
while (tlb_shoot_wait != 0)
SPINLOCK_SPIN_HOOK;
}
tlb_shoot_addr1 = va;
CPU_INFO_FOREACH(cii, ci) {
if ((mask & 1 << ci->ci_cpuid) == 0)
continue;
if (i386_fast_ipi(ci, LAPIC_IPI_INVLPG) != 0)
panic("pmap_tlb_shootpage: ipi failed");
}
splx(s);
}
if (pmap_is_curpmap(pm))
pmap_update_pg(va);
}
void
pmap_tlb_shootrange(struct pmap *pm, vaddr_t sva, vaddr_t eva)
{
struct cpu_info *ci, *self = curcpu();
CPU_INFO_ITERATOR cii;
int wait = 0;
int mask = 0;
vaddr_t va;
CPU_INFO_FOREACH(cii, ci) {
if (ci == self || !pmap_is_active(pm, ci->ci_cpuid) ||
!(ci->ci_flags & CPUF_RUNNING))
continue;
mask |= 1 << ci->ci_cpuid;
wait++;
}
if (wait > 0) {
int s = splvm();
while (i486_atomic_cas_int(&tlb_shoot_wait, 0, wait) != 0) {
while (tlb_shoot_wait != 0)
SPINLOCK_SPIN_HOOK;
}
tlb_shoot_addr1 = sva;
tlb_shoot_addr2 = eva;
CPU_INFO_FOREACH(cii, ci) {
if ((mask & 1 << ci->ci_cpuid) == 0)
continue;
if (i386_fast_ipi(ci, LAPIC_IPI_INVLRANGE) != 0)
panic("pmap_tlb_shootrange: ipi failed");
}
splx(s);
}
if (pmap_is_curpmap(pm))
for (va = sva; va < eva; va += PAGE_SIZE)
pmap_update_pg(va);
}
void
pmap_tlb_shoottlb(void)
{
struct cpu_info *ci, *self = curcpu();
CPU_INFO_ITERATOR cii;
int wait = 0;
int mask = 0;
CPU_INFO_FOREACH(cii, ci) {
if (ci == self || !(ci->ci_flags & CPUF_RUNNING))
continue;
mask |= 1 << ci->ci_cpuid;
wait++;
}
if (wait) {
int s = splvm();
while (i486_atomic_cas_int(&tlb_shoot_wait, 0, wait) != 0) {
while (tlb_shoot_wait != 0)
SPINLOCK_SPIN_HOOK;
}
CPU_INFO_FOREACH(cii, ci) {
if ((mask & 1 << ci->ci_cpuid) == 0)
continue;
if (i386_fast_ipi(ci, LAPIC_IPI_INVLTLB) != 0)
panic("pmap_tlb_shoottlb: ipi failed");
}
splx(s);
}
tlbflush();
}
void
pmap_tlb_shootwait(void)
{
while (tlb_shoot_wait != 0)
SPINLOCK_SPIN_HOOK;
}
#else
void
pmap_tlb_shootpage(struct pmap *pm, vaddr_t va)
{
if (pmap_is_curpmap(pm))
pmap_update_pg(va);
}
void
pmap_tlb_shootrange(struct pmap *pm, vaddr_t sva, vaddr_t eva)
{
vaddr_t va;
for (va = sva; va < eva; va += PAGE_SIZE)
pmap_update_pg(va);
}
void
pmap_tlb_shoottlb(void)
{
tlbflush();
}
#endif /* MULTIPROCESSOR */
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