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|
/*
* Mach Operating System
* Copyright (c) 1991,1990,1989,1988 Carnegie Mellon University
* All Rights Reserved.
*
* Permission to use, copy, modify and distribute this software and its
* documentation is hereby granted, provided that both the copyright
* notice and this permission notice appear in all copies of the
* software, derivative works or modified versions, and any portions
* thereof, and that both notices appear in supporting documentation.
*
* CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
* CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR
* ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
*
* Carnegie Mellon requests users of this software to return to
*
* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
* School of Computer Science
* Carnegie Mellon University
* Pittsburgh PA 15213-3890
*
* any improvements or extensions that they make and grant Carnegie Mellon
* the rights to redistribute these changes.
*/
/*
* File: pmap.c
* Author: Avadis Tevanian, Jr., Michael Wayne Young
* (These guys wrote the Vax version)
*
* Physical Map management code for Intel i386, and i486.
*
* Manages physical address maps.
*
* In addition to hardware address maps, this
* module is called upon to provide software-use-only
* maps which may or may not be stored in the same
* form as hardware maps. These pseudo-maps are
* used to store intermediate results from copy
* operations to and from address spaces.
*
* Since the information managed by this module is
* also stored by the logical address mapping module,
* this module may throw away valid virtual-to-physical
* mappings at almost any time. However, invalidations
* of virtual-to-physical mappings must be done as
* requested.
*
* In order to cope with hardware architectures which
* make virtual-to-physical map invalidates expensive,
* this module may delay invalidate or reduced protection
* operations until such time as they are actually
* necessary. This module is given full information as
* to which processors are currently using which maps,
* and to when physical maps must be made correct.
*/
#include <string.h>
#include <mach/machine/vm_types.h>
#include <mach/boolean.h>
#include <kern/debug.h>
#include <kern/printf.h>
#include <kern/thread.h>
#include <kern/slab.h>
#include <kern/lock.h>
#include <vm/pmap.h>
#include <vm/vm_map.h>
#include <vm/vm_kern.h>
#include <i386/vm_param.h>
#include <mach/vm_prot.h>
#include <vm/vm_object.h>
#include <vm/vm_page.h>
#include <vm/vm_user.h>
#include <mach/machine/vm_param.h>
#include <mach/xen.h>
#include <machine/thread.h>
#include <i386/cpu_number.h>
#include <i386/proc_reg.h>
#include <i386/locore.h>
#include <i386/model_dep.h>
#ifdef MACH_PSEUDO_PHYS
#define WRITE_PTE(pte_p, pte_entry) *(pte_p) = pte_entry?pa_to_ma(pte_entry):0;
#else /* MACH_PSEUDO_PHYS */
#define WRITE_PTE(pte_p, pte_entry) *(pte_p) = (pte_entry);
#endif /* MACH_PSEUDO_PHYS */
/*
* Private data structures.
*/
/*
* For each vm_page_t, there is a list of all currently
* valid virtual mappings of that page. An entry is
* a pv_entry_t; the list is the pv_table.
*/
typedef struct pv_entry {
struct pv_entry *next; /* next pv_entry */
pmap_t pmap; /* pmap where mapping lies */
vm_offset_t va; /* virtual address for mapping */
} *pv_entry_t;
#define PV_ENTRY_NULL ((pv_entry_t) 0)
pv_entry_t pv_head_table; /* array of entries, one per page */
/*
* pv_list entries are kept on a list that can only be accessed
* with the pmap system locked (at SPLVM, not in the cpus_active set).
* The list is refilled from the pv_list_cache if it becomes empty.
*/
pv_entry_t pv_free_list; /* free list at SPLVM */
decl_simple_lock_data(, pv_free_list_lock)
#define PV_ALLOC(pv_e) { \
simple_lock(&pv_free_list_lock); \
if ((pv_e = pv_free_list) != 0) { \
pv_free_list = pv_e->next; \
} \
simple_unlock(&pv_free_list_lock); \
}
#define PV_FREE(pv_e) { \
simple_lock(&pv_free_list_lock); \
pv_e->next = pv_free_list; \
pv_free_list = pv_e; \
simple_unlock(&pv_free_list_lock); \
}
struct kmem_cache pv_list_cache; /* cache of pv_entry structures */
/*
* Each entry in the pv_head_table is locked by a bit in the
* pv_lock_table. The lock bits are accessed by the physical
* address of the page they lock.
*/
char *pv_lock_table; /* pointer to array of bits */
#define pv_lock_table_size(n) (((n)+BYTE_SIZE-1)/BYTE_SIZE)
/* Has pmap_init completed? */
boolean_t pmap_initialized = FALSE;
/*
* Range of kernel virtual addresses available for kernel memory mapping.
* Does not include the virtual addresses used to map physical memory 1-1.
* Initialized by pmap_bootstrap.
*/
vm_offset_t kernel_virtual_start;
vm_offset_t kernel_virtual_end;
/*
* Index into pv_head table, its lock bits, and the modify/reference
* bits starting at phys_first_addr.
*/
#define pa_index(pa) (atop(pa - phys_first_addr))
#define pai_to_pvh(pai) (&pv_head_table[pai])
#define lock_pvh_pai(pai) (bit_lock(pai, pv_lock_table))
#define unlock_pvh_pai(pai) (bit_unlock(pai, pv_lock_table))
/*
* Array of physical page attribites for managed pages.
* One byte per physical page.
*/
char *pmap_phys_attributes;
/*
* Physical page attributes. Copy bits from PTE definition.
*/
#define PHYS_MODIFIED INTEL_PTE_MOD /* page modified */
#define PHYS_REFERENCED INTEL_PTE_REF /* page referenced */
/*
* Amount of virtual memory mapped by one
* page-directory entry.
*/
#define PDE_MAPPED_SIZE (pdenum2lin(1))
/*
* We allocate page table pages directly from the VM system
* through this object. It maps physical memory.
*/
vm_object_t pmap_object = VM_OBJECT_NULL;
/*
* Locking and TLB invalidation
*/
/*
* Locking Protocols:
*
* There are two structures in the pmap module that need locking:
* the pmaps themselves, and the per-page pv_lists (which are locked
* by locking the pv_lock_table entry that corresponds to the pv_head
* for the list in question.) Most routines want to lock a pmap and
* then do operations in it that require pv_list locking -- however
* pmap_remove_all and pmap_copy_on_write operate on a physical page
* basis and want to do the locking in the reverse order, i.e. lock
* a pv_list and then go through all the pmaps referenced by that list.
* To protect against deadlock between these two cases, the pmap_lock
* is used. There are three different locking protocols as a result:
*
* 1. pmap operations only (pmap_extract, pmap_access, ...) Lock only
* the pmap.
*
* 2. pmap-based operations (pmap_enter, pmap_remove, ...) Get a read
* lock on the pmap_lock (shared read), then lock the pmap
* and finally the pv_lists as needed [i.e. pmap lock before
* pv_list lock.]
*
* 3. pv_list-based operations (pmap_remove_all, pmap_copy_on_write, ...)
* Get a write lock on the pmap_lock (exclusive write); this
* also guaranteees exclusive access to the pv_lists. Lock the
* pmaps as needed.
*
* At no time may any routine hold more than one pmap lock or more than
* one pv_list lock. Because interrupt level routines can allocate
* mbufs and cause pmap_enter's, the pmap_lock and the lock on the
* kernel_pmap can only be held at splvm.
*/
#if NCPUS > 1
/*
* We raise the interrupt level to splvm, to block interprocessor
* interrupts during pmap operations. We must take the CPU out of
* the cpus_active set while interrupts are blocked.
*/
#define SPLVM(spl) { \
spl = splvm(); \
i_bit_clear(cpu_number(), &cpus_active); \
}
#define SPLX(spl) { \
i_bit_set(cpu_number(), &cpus_active); \
splx(spl); \
}
/*
* Lock on pmap system
*/
lock_data_t pmap_system_lock;
#define PMAP_READ_LOCK(pmap, spl) { \
SPLVM(spl); \
lock_read(&pmap_system_lock); \
simple_lock(&(pmap)->lock); \
}
#define PMAP_WRITE_LOCK(spl) { \
SPLVM(spl); \
lock_write(&pmap_system_lock); \
}
#define PMAP_READ_UNLOCK(pmap, spl) { \
simple_unlock(&(pmap)->lock); \
lock_read_done(&pmap_system_lock); \
SPLX(spl); \
}
#define PMAP_WRITE_UNLOCK(spl) { \
lock_write_done(&pmap_system_lock); \
SPLX(spl); \
}
#define PMAP_WRITE_TO_READ_LOCK(pmap) { \
simple_lock(&(pmap)->lock); \
lock_write_to_read(&pmap_system_lock); \
}
#define LOCK_PVH(index) (lock_pvh_pai(index))
#define UNLOCK_PVH(index) (unlock_pvh_pai(index))
#define PMAP_UPDATE_TLBS(pmap, s, e) \
{ \
cpu_set cpu_mask = 1 << cpu_number(); \
cpu_set users; \
\
/* Since the pmap is locked, other updates are locked */ \
/* out, and any pmap_activate has finished. */ \
\
/* find other cpus using the pmap */ \
users = (pmap)->cpus_using & ~cpu_mask; \
if (users) { \
/* signal them, and wait for them to finish */ \
/* using the pmap */ \
signal_cpus(users, (pmap), (s), (e)); \
while ((pmap)->cpus_using & cpus_active & ~cpu_mask) \
continue; \
} \
\
/* invalidate our own TLB if pmap is in use */ \
if ((pmap)->cpus_using & cpu_mask) { \
INVALIDATE_TLB((pmap), (s), (e)); \
} \
}
#else /* NCPUS > 1 */
#define SPLVM(spl) ((void)(spl))
#define SPLX(spl) ((void)(spl))
#define PMAP_READ_LOCK(pmap, spl) SPLVM(spl)
#define PMAP_WRITE_LOCK(spl) SPLVM(spl)
#define PMAP_READ_UNLOCK(pmap, spl) SPLX(spl)
#define PMAP_WRITE_UNLOCK(spl) SPLX(spl)
#define PMAP_WRITE_TO_READ_LOCK(pmap)
#define LOCK_PVH(index)
#define UNLOCK_PVH(index)
#define PMAP_UPDATE_TLBS(pmap, s, e) { \
/* invalidate our own TLB if pmap is in use */ \
if ((pmap)->cpus_using) { \
INVALIDATE_TLB((pmap), (s), (e)); \
} \
}
#endif /* NCPUS > 1 */
#define MAX_TBIS_SIZE 32 /* > this -> TBIA */ /* XXX */
#ifdef MACH_PV_PAGETABLES
#if 1
#define INVALIDATE_TLB(pmap, s, e) hyp_mmuext_op_void(MMUEXT_TLB_FLUSH_LOCAL)
#else
#define INVALIDATE_TLB(pmap, s, e) do { \
if (__builtin_constant_p((e) - (s)) \
&& (e) - (s) == PAGE_SIZE) \
hyp_invlpg((pmap) == kernel_pmap ? kvtolin(s) : (s)); \
else \
hyp_mmuext_op_void(MMUEXT_TLB_FLUSH_LOCAL); \
} while(0)
#endif
#else /* MACH_PV_PAGETABLES */
#if 0
/* It is hard to know when a TLB flush becomes less expensive than a bunch of
* invlpgs. But it surely is more expensive than just one invlpg. */
#define INVALIDATE_TLB(pmap, s, e) { \
if (__builtin_constant_p((e) - (s)) \
&& (e) - (s) == PAGE_SIZE) \
invlpg_linear(s); \
else \
flush_tlb(); \
}
#else
#define INVALIDATE_TLB(pmap, s, e) { \
(void) (pmap); \
(void) (s); \
(void) (e); \
flush_tlb(); \
}
#endif
#endif /* MACH_PV_PAGETABLES */
#if NCPUS > 1
/*
* Structures to keep track of pending TLB invalidations
*/
#define UPDATE_LIST_SIZE 4
struct pmap_update_item {
pmap_t pmap; /* pmap to invalidate */
vm_offset_t start; /* start address to invalidate */
vm_offset_t end; /* end address to invalidate */
} ;
typedef struct pmap_update_item *pmap_update_item_t;
/*
* List of pmap updates. If the list overflows,
* the last entry is changed to invalidate all.
*/
struct pmap_update_list {
decl_simple_lock_data(, lock)
int count;
struct pmap_update_item item[UPDATE_LIST_SIZE];
} ;
typedef struct pmap_update_list *pmap_update_list_t;
struct pmap_update_list cpu_update_list[NCPUS];
#endif /* NCPUS > 1 */
/*
* Other useful macros.
*/
#define current_pmap() (vm_map_pmap(current_thread()->task->map))
#define pmap_in_use(pmap, cpu) (((pmap)->cpus_using & (1 << (cpu))) != 0)
struct pmap kernel_pmap_store;
pmap_t kernel_pmap;
struct kmem_cache pmap_cache; /* cache of pmap structures */
boolean_t pmap_debug = FALSE; /* flag for debugging prints */
#if 0
int ptes_per_vm_page; /* number of hardware ptes needed
to map one VM page. */
#else
#define ptes_per_vm_page 1
#endif
unsigned int inuse_ptepages_count = 0; /* debugging */
/*
* Pointer to the basic page directory for the kernel.
* Initialized by pmap_bootstrap().
*/
pt_entry_t *kernel_page_dir;
/*
* Two slots for temporary physical page mapping, to allow for
* physical-to-physical transfers.
*/
static pmap_mapwindow_t mapwindows[PMAP_NMAPWINDOWS];
static inline pt_entry_t *
pmap_pde(const pmap_t pmap, vm_offset_t addr)
{
if (pmap == kernel_pmap)
addr = kvtolin(addr);
return &pmap->dirbase[lin2pdenum(addr)];
}
/*
* Given an offset and a map, compute the address of the
* pte. If the address is invalid with respect to the map
* then PT_ENTRY_NULL is returned (and the map may need to grow).
*
* This is only used internally.
*/
pt_entry_t *
pmap_pte(const pmap_t pmap, vm_offset_t addr)
{
pt_entry_t *ptp;
pt_entry_t pte;
if (pmap->dirbase == 0)
return(PT_ENTRY_NULL);
pte = *pmap_pde(pmap, addr);
if ((pte & INTEL_PTE_VALID) == 0)
return(PT_ENTRY_NULL);
ptp = (pt_entry_t *)ptetokv(pte);
return(&ptp[ptenum(addr)]);
}
#define DEBUG_PTE_PAGE 0
#if DEBUG_PTE_PAGE
void ptep_check(ptep_t ptep)
{
pt_entry_t *pte, *epte;
int ctu, ctw;
/* check the use and wired counts */
if (ptep == PTE_PAGE_NULL)
return;
pte = pmap_pte(ptep->pmap, ptep->va);
epte = pte + INTEL_PGBYTES/sizeof(pt_entry_t);
ctu = 0;
ctw = 0;
while (pte < epte) {
if (pte->pfn != 0) {
ctu++;
if (pte->wired)
ctw++;
}
pte += ptes_per_vm_page;
}
if (ctu != ptep->use_count || ctw != ptep->wired_count) {
printf("use %d wired %d - actual use %d wired %d\n",
ptep->use_count, ptep->wired_count, ctu, ctw);
panic("pte count");
}
}
#endif /* DEBUG_PTE_PAGE */
/*
* Map memory at initialization. The physical addresses being
* mapped are not managed and are never unmapped.
*
* For now, VM is already on, we only need to map the
* specified memory.
*/
vm_offset_t pmap_map(
vm_offset_t virt,
vm_offset_t start,
vm_offset_t end,
int prot)
{
int ps;
ps = PAGE_SIZE;
while (start < end) {
pmap_enter(kernel_pmap, virt, start, prot, FALSE);
virt += ps;
start += ps;
}
return(virt);
}
/*
* Back-door routine for mapping kernel VM at initialization.
* Useful for mapping memory outside the range
* [phys_first_addr, phys_last_addr) (i.e., devices).
* Otherwise like pmap_map.
*/
vm_offset_t pmap_map_bd(
vm_offset_t virt,
vm_offset_t start,
vm_offset_t end,
vm_prot_t prot)
{
pt_entry_t template;
pt_entry_t *pte;
int spl;
#ifdef MACH_PV_PAGETABLES
int n, i = 0;
struct mmu_update update[HYP_BATCH_MMU_UPDATES];
#endif /* MACH_PV_PAGETABLES */
template = pa_to_pte(start)
| INTEL_PTE_NCACHE|INTEL_PTE_WTHRU
| INTEL_PTE_VALID;
if (CPU_HAS_FEATURE(CPU_FEATURE_PGE))
template |= INTEL_PTE_GLOBAL;
if (prot & VM_PROT_WRITE)
template |= INTEL_PTE_WRITE;
PMAP_READ_LOCK(pmap, spl);
while (start < end) {
pte = pmap_pte(kernel_pmap, virt);
if (pte == PT_ENTRY_NULL)
panic("pmap_map_bd: Invalid kernel address\n");
#ifdef MACH_PV_PAGETABLES
update[i].ptr = kv_to_ma(pte);
update[i].val = pa_to_ma(template);
i++;
if (i == HYP_BATCH_MMU_UPDATES) {
hyp_mmu_update(kvtolin(&update), i, kvtolin(&n), DOMID_SELF);
if (n != i)
panic("couldn't pmap_map_bd\n");
i = 0;
}
#else /* MACH_PV_PAGETABLES */
WRITE_PTE(pte, template)
#endif /* MACH_PV_PAGETABLES */
pte_increment_pa(template);
virt += PAGE_SIZE;
start += PAGE_SIZE;
}
#ifdef MACH_PV_PAGETABLES
if (i > HYP_BATCH_MMU_UPDATES)
panic("overflowed array in pmap_map_bd");
hyp_mmu_update(kvtolin(&update), i, kvtolin(&n), DOMID_SELF);
if (n != i)
panic("couldn't pmap_map_bd\n");
#endif /* MACH_PV_PAGETABLES */
PMAP_READ_UNLOCK(pmap, spl);
return(virt);
}
/*
* Bootstrap the system enough to run with virtual memory.
* Allocate the kernel page directory and page tables,
* and direct-map all physical memory.
* Called with mapping off.
*/
void pmap_bootstrap(void)
{
/*
* Mapping is turned off; we must reference only physical addresses.
* The load image of the system is to be mapped 1-1 physical = virtual.
*/
/*
* Set ptes_per_vm_page for general use.
*/
#if 0
ptes_per_vm_page = PAGE_SIZE / INTEL_PGBYTES;
#endif
/*
* The kernel's pmap is statically allocated so we don't
* have to use pmap_create, which is unlikely to work
* correctly at this part of the boot sequence.
*/
kernel_pmap = &kernel_pmap_store;
#if NCPUS > 1
lock_init(&pmap_system_lock, FALSE); /* NOT a sleep lock */
#endif /* NCPUS > 1 */
simple_lock_init(&kernel_pmap->lock);
kernel_pmap->ref_count = 1;
/*
* Determine the kernel virtual address range.
* It starts at the end of the physical memory
* mapped into the kernel address space,
* and extends to a stupid arbitrary limit beyond that.
*/
kernel_virtual_start = phystokv(phys_last_addr);
kernel_virtual_end = phystokv(phys_last_addr) + VM_KERNEL_MAP_SIZE;
if (kernel_virtual_end < kernel_virtual_start
|| kernel_virtual_end > VM_MAX_KERNEL_ADDRESS)
kernel_virtual_end = VM_MAX_KERNEL_ADDRESS;
/*
* Allocate and clear a kernel page directory.
*/
/* Note: initial Xen mapping holds at least 512kB free mapped page.
* We use that for directly building our linear mapping. */
#if PAE
{
vm_offset_t addr;
init_alloc_aligned(PDPNUM * INTEL_PGBYTES, &addr);
kernel_pmap->dirbase = kernel_page_dir = (pt_entry_t*)phystokv(addr);
}
kernel_pmap->pdpbase = (pt_entry_t*)phystokv(pmap_grab_page());
{
int i;
for (i = 0; i < PDPNUM; i++)
WRITE_PTE(&kernel_pmap->pdpbase[i], pa_to_pte(_kvtophys((void *) kernel_pmap->dirbase + i * INTEL_PGBYTES)) | INTEL_PTE_VALID);
}
#else /* PAE */
kernel_pmap->dirbase = kernel_page_dir = (pt_entry_t*)phystokv(pmap_grab_page());
#endif /* PAE */
{
int i;
for (i = 0; i < NPDES; i++)
kernel_pmap->dirbase[i] = 0;
}
#ifdef MACH_PV_PAGETABLES
/* We don't actually deal with the CR3 register content at all */
hyp_vm_assist(VMASST_CMD_enable, VMASST_TYPE_pae_extended_cr3);
/*
* Xen may only provide as few as 512KB extra bootstrap linear memory,
* which is far from enough to map all available memory, so we need to
* map more bootstrap linear memory. We here map 1 (resp. 4 for PAE)
* other L1 table(s), thus 4MiB extra memory (resp. 8MiB), which is
* enough for a pagetable mapping 4GiB.
*/
#ifdef PAE
#define NSUP_L1 4
#else
#define NSUP_L1 1
#endif
pt_entry_t *l1_map[NSUP_L1];
{
pt_entry_t *base = (pt_entry_t*) boot_info.pt_base;
vm_offset_t la;
int n_l1map;
for (n_l1map = 0, la = VM_MIN_KERNEL_ADDRESS; la >= VM_MIN_KERNEL_ADDRESS; la += NPTES * PAGE_SIZE) {
#ifdef PAE
pt_entry_t *l2_map = (pt_entry_t*) ptetokv(base[lin2pdpnum(la)]);
#else /* PAE */
pt_entry_t *l2_map = base;
#endif /* PAE */
/* Like lin2pdenum, but works with non-contiguous boot L3 */
l2_map += (la >> PDESHIFT) & PDEMASK;
if (!(*l2_map & INTEL_PTE_VALID)) {
struct mmu_update update;
int j, n;
l1_map[n_l1map] = (pt_entry_t*) phystokv(pmap_grab_page());
for (j = 0; j < NPTES; j++)
l1_map[n_l1map][j] = (((pt_entry_t)pfn_to_mfn(lin2pdenum(la - VM_MIN_KERNEL_ADDRESS) * NPTES + j)) << PAGE_SHIFT) | INTEL_PTE_VALID | INTEL_PTE_WRITE;
pmap_set_page_readonly_init(l1_map[n_l1map]);
if (!hyp_mmuext_op_mfn (MMUEXT_PIN_L1_TABLE, kv_to_mfn (l1_map[n_l1map])))
panic("couldn't pin page %p(%p)", l1_map[n_l1map], (vm_offset_t) kv_to_ma (l1_map[n_l1map]));
update.ptr = kv_to_ma(l2_map);
update.val = kv_to_ma(l1_map[n_l1map]) | INTEL_PTE_VALID | INTEL_PTE_WRITE;
hyp_mmu_update(kv_to_la(&update), 1, kv_to_la(&n), DOMID_SELF);
if (n != 1)
panic("couldn't complete bootstrap map");
/* added the last L1 table, can stop */
if (++n_l1map >= NSUP_L1)
break;
}
}
}
#endif /* MACH_PV_PAGETABLES */
/*
* Allocate and set up the kernel page tables.
*/
{
vm_offset_t va;
pt_entry_t global = CPU_HAS_FEATURE(CPU_FEATURE_PGE) ? INTEL_PTE_GLOBAL : 0;
/*
* Map virtual memory for all known physical memory, 1-1,
* from phys_first_addr to phys_last_addr.
* Make any mappings completely in the kernel's text segment read-only.
*
* Also allocate some additional all-null page tables afterwards
* for kernel virtual memory allocation,
* because this PMAP module is too stupid
* to allocate new kernel page tables later.
* XX fix this
*/
for (va = phystokv(phys_first_addr); va >= phystokv(phys_first_addr) && va < kernel_virtual_end; )
{
pt_entry_t *pde = kernel_page_dir + lin2pdenum(kvtolin(va));
pt_entry_t *ptable = (pt_entry_t*)phystokv(pmap_grab_page());
pt_entry_t *pte;
/* Initialize the page directory entry. */
WRITE_PTE(pde, pa_to_pte((vm_offset_t)_kvtophys(ptable))
| INTEL_PTE_VALID | INTEL_PTE_WRITE);
/* Initialize the page table. */
for (pte = ptable; (va < phystokv(phys_last_addr)) && (pte < ptable+NPTES); pte++)
{
if ((pte - ptable) < ptenum(va))
{
WRITE_PTE(pte, 0);
}
else
#ifdef MACH_PV_PAGETABLES
if (va == (vm_offset_t) &hyp_shared_info)
{
*pte = boot_info.shared_info | INTEL_PTE_VALID | INTEL_PTE_WRITE;
va += INTEL_PGBYTES;
}
else
#endif /* MACH_PV_PAGETABLES */
{
extern char _start[], etext[];
if (((va >= (vm_offset_t) _start)
&& (va + INTEL_PGBYTES <= (vm_offset_t)etext))
#ifdef MACH_PV_PAGETABLES
|| (va >= (vm_offset_t) boot_info.pt_base
&& (va + INTEL_PGBYTES <=
(vm_offset_t) ptable + INTEL_PGBYTES))
#endif /* MACH_PV_PAGETABLES */
)
{
WRITE_PTE(pte, pa_to_pte(_kvtophys(va))
| INTEL_PTE_VALID | global);
}
else
{
#ifdef MACH_PV_PAGETABLES
/* Keep supplementary L1 pages read-only */
int i;
for (i = 0; i < NSUP_L1; i++)
if (va == (vm_offset_t) l1_map[i]) {
WRITE_PTE(pte, pa_to_pte(_kvtophys(va))
| INTEL_PTE_VALID | global);
break;
}
if (i == NSUP_L1)
#endif /* MACH_PV_PAGETABLES */
WRITE_PTE(pte, pa_to_pte(_kvtophys(va))
| INTEL_PTE_VALID | INTEL_PTE_WRITE | global)
}
va += INTEL_PGBYTES;
}
}
for (; pte < ptable+NPTES; pte++)
{
if (va >= kernel_virtual_end - PMAP_NMAPWINDOWS * PAGE_SIZE && va < kernel_virtual_end)
{
pmap_mapwindow_t *win = &mapwindows[atop(va - (kernel_virtual_end - PMAP_NMAPWINDOWS * PAGE_SIZE))];
win->entry = pte;
win->vaddr = va;
}
WRITE_PTE(pte, 0);
va += INTEL_PGBYTES;
}
#ifdef MACH_PV_PAGETABLES
pmap_set_page_readonly_init(ptable);
if (!hyp_mmuext_op_mfn (MMUEXT_PIN_L1_TABLE, kv_to_mfn (ptable)))
panic("couldn't pin page %p(%p)\n", ptable, (vm_offset_t) kv_to_ma (ptable));
#endif /* MACH_PV_PAGETABLES */
}
}
/* Architecture-specific code will turn on paging
soon after we return from here. */
}
#ifdef MACH_PV_PAGETABLES
/* These are only required because of Xen security policies */
/* Set back a page read write */
void pmap_set_page_readwrite(void *_vaddr) {
vm_offset_t vaddr = (vm_offset_t) _vaddr;
vm_offset_t paddr = kvtophys(vaddr);
vm_offset_t canon_vaddr = phystokv(paddr);
if (hyp_do_update_va_mapping (kvtolin(vaddr), pa_to_pte (pa_to_ma(paddr)) | INTEL_PTE_VALID | INTEL_PTE_WRITE, UVMF_NONE))
panic("couldn't set hiMMU readwrite for addr %p(%p)\n", vaddr, (vm_offset_t) pa_to_ma (paddr));
if (canon_vaddr != vaddr)
if (hyp_do_update_va_mapping (kvtolin(canon_vaddr), pa_to_pte (pa_to_ma(paddr)) | INTEL_PTE_VALID | INTEL_PTE_WRITE, UVMF_NONE))
panic("couldn't set hiMMU readwrite for paddr %p(%p)\n", canon_vaddr, (vm_offset_t) pa_to_ma (paddr));
}
/* Set a page read only (so as to pin it for instance) */
void pmap_set_page_readonly(void *_vaddr) {
vm_offset_t vaddr = (vm_offset_t) _vaddr;
vm_offset_t paddr = kvtophys(vaddr);
vm_offset_t canon_vaddr = phystokv(paddr);
if (*pmap_pde(kernel_pmap, vaddr) & INTEL_PTE_VALID) {
if (hyp_do_update_va_mapping (kvtolin(vaddr), pa_to_pte (pa_to_ma(paddr)) | INTEL_PTE_VALID, UVMF_NONE))
panic("couldn't set hiMMU readonly for vaddr %p(%p)\n", vaddr, (vm_offset_t) pa_to_ma (paddr));
}
if (canon_vaddr != vaddr &&
*pmap_pde(kernel_pmap, canon_vaddr) & INTEL_PTE_VALID) {
if (hyp_do_update_va_mapping (kvtolin(canon_vaddr), pa_to_pte (pa_to_ma(paddr)) | INTEL_PTE_VALID, UVMF_NONE))
panic("couldn't set hiMMU readonly for vaddr %p canon_vaddr %p paddr %p (%p)\n", vaddr, canon_vaddr, paddr, (vm_offset_t) pa_to_ma (paddr));
}
}
/* This needs to be called instead of pmap_set_page_readonly as long as RC3
* still points to the bootstrap dirbase, to also fix the bootstrap table. */
void pmap_set_page_readonly_init(void *_vaddr) {
vm_offset_t vaddr = (vm_offset_t) _vaddr;
#if PAE
pt_entry_t *pdpbase = (void*) boot_info.pt_base;
/* The bootstrap table does not necessarily use contiguous pages for the pde tables */
pt_entry_t *dirbase = (void*) ptetokv(pdpbase[lin2pdpnum(vaddr)]);
#else
pt_entry_t *dirbase = (void*) boot_info.pt_base;
#endif
pt_entry_t *pte = &dirbase[lin2pdenum(vaddr) & PTEMASK];
/* Modify our future kernel map (can't use update_va_mapping for this)... */
if (*pmap_pde(kernel_pmap, vaddr) & INTEL_PTE_VALID) {
if (!hyp_mmu_update_la (kvtolin(vaddr), pa_to_pte (kv_to_ma(vaddr)) | INTEL_PTE_VALID))
panic("couldn't set hiMMU readonly for vaddr %p(%p)\n", vaddr, (vm_offset_t) kv_to_ma (vaddr));
}
/* ... and the bootstrap map. */
if (*pte & INTEL_PTE_VALID) {
if (hyp_do_update_va_mapping (vaddr, pa_to_pte (kv_to_ma(vaddr)) | INTEL_PTE_VALID, UVMF_NONE))
panic("couldn't set MMU readonly for vaddr %p(%p)\n", vaddr, (vm_offset_t) kv_to_ma (vaddr));
}
}
void pmap_clear_bootstrap_pagetable(pt_entry_t *base) {
int i;
pt_entry_t *dir;
vm_offset_t va = 0;
#if PAE
int j;
#endif /* PAE */
if (!hyp_mmuext_op_mfn (MMUEXT_UNPIN_TABLE, kv_to_mfn(base)))
panic("pmap_clear_bootstrap_pagetable: couldn't unpin page %p(%p)\n", base, (vm_offset_t) kv_to_ma(base));
#if PAE
for (j = 0; j < PDPNUM; j++)
{
pt_entry_t pdpe = base[j];
if (pdpe & INTEL_PTE_VALID) {
dir = (pt_entry_t *) ptetokv(pdpe);
#else /* PAE */
dir = base;
#endif /* PAE */
for (i = 0; i < NPTES; i++) {
pt_entry_t pde = dir[i];
unsigned long pfn = atop(pte_to_pa(pde));
void *pgt = (void*) phystokv(ptoa(pfn));
if (pde & INTEL_PTE_VALID)
hyp_free_page(pfn, pgt);
va += NPTES * INTEL_PGBYTES;
if (va >= HYP_VIRT_START)
break;
}
#if PAE
hyp_free_page(atop(_kvtophys(dir)), dir);
} else
va += NPTES * NPTES * INTEL_PGBYTES;
if (va >= HYP_VIRT_START)
break;
}
#endif /* PAE */
hyp_free_page(atop(_kvtophys(base)), base);
}
#endif /* MACH_PV_PAGETABLES */
/*
* Create a temporary mapping for a given physical entry
*
* This can be used to access physical pages which are not mapped 1:1 by
* phystokv().
*/
pmap_mapwindow_t *pmap_get_mapwindow(pt_entry_t entry)
{
pmap_mapwindow_t *map;
/* Find an empty one. */
for (map = &mapwindows[0]; map < &mapwindows[sizeof (mapwindows) / sizeof (*mapwindows)]; map++)
if (!(*map->entry))
break;
assert(map < &mapwindows[sizeof (mapwindows) / sizeof (*mapwindows)]);
WRITE_PTE(map->entry, entry);
return map;
}
/*
* Destroy a temporary mapping for a physical entry
*/
void pmap_put_mapwindow(pmap_mapwindow_t *map)
{
WRITE_PTE(map->entry, 0);
PMAP_UPDATE_TLBS(kernel_pmap, map->vaddr, map->vaddr + PAGE_SIZE);
}
void pmap_virtual_space(
vm_offset_t *startp,
vm_offset_t *endp)
{
*startp = kernel_virtual_start;
*endp = kernel_virtual_end - PMAP_NMAPWINDOWS * PAGE_SIZE;
}
/*
* Initialize the pmap module.
* Called by vm_init, to initialize any structures that the pmap
* system needs to map virtual memory.
*/
void pmap_init(void)
{
long npages;
vm_offset_t addr;
vm_size_t s;
#if NCPUS > 1
int i;
#endif /* NCPUS > 1 */
/*
* Allocate memory for the pv_head_table and its lock bits,
* the modify bit array, and the pte_page table.
*/
npages = atop(phys_last_addr - phys_first_addr);
s = (vm_size_t) (sizeof(struct pv_entry) * npages
+ pv_lock_table_size(npages)
+ npages);
s = round_page(s);
if (kmem_alloc_wired(kernel_map, &addr, s) != KERN_SUCCESS)
panic("pmap_init");
memset((void *) addr, 0, s);
/*
* Allocate the structures first to preserve word-alignment.
*/
pv_head_table = (pv_entry_t) addr;
addr = (vm_offset_t) (pv_head_table + npages);
pv_lock_table = (char *) addr;
addr = (vm_offset_t) (pv_lock_table + pv_lock_table_size(npages));
pmap_phys_attributes = (char *) addr;
/*
* Create the cache of physical maps,
* and of the physical-to-virtual entries.
*/
s = (vm_size_t) sizeof(struct pmap);
kmem_cache_init(&pmap_cache, "pmap", s, 0, NULL, NULL, NULL, 0);
s = (vm_size_t) sizeof(struct pv_entry);
kmem_cache_init(&pv_list_cache, "pv_entry", s, 0, NULL, NULL, NULL, 0);
#if NCPUS > 1
/*
* Set up the pmap request lists
*/
for (i = 0; i < NCPUS; i++) {
pmap_update_list_t up = &cpu_update_list[i];
simple_lock_init(&up->lock);
up->count = 0;
}
#endif /* NCPUS > 1 */
/*
* Indicate that the PMAP module is now fully initialized.
*/
pmap_initialized = TRUE;
}
#define valid_page(x) (pmap_initialized && pmap_valid_page(x))
boolean_t pmap_verify_free(vm_offset_t phys)
{
pv_entry_t pv_h;
int pai;
int spl;
boolean_t result;
assert(phys != vm_page_fictitious_addr);
if (!pmap_initialized)
return(TRUE);
if (!pmap_valid_page(phys))
return(FALSE);
PMAP_WRITE_LOCK(spl);
pai = pa_index(phys);
pv_h = pai_to_pvh(pai);
result = (pv_h->pmap == PMAP_NULL);
PMAP_WRITE_UNLOCK(spl);
return(result);
}
/*
* Routine: pmap_page_table_page_alloc
*
* Allocates a new physical page to be used as a page-table page.
*
* Must be called with the pmap system and the pmap unlocked,
* since these must be unlocked to use vm_page_grab.
*/
vm_offset_t
pmap_page_table_page_alloc(void)
{
vm_page_t m;
vm_offset_t pa;
check_simple_locks();
/*
* We cannot allocate the pmap_object in pmap_init,
* because it is called before the cache package is up.
* Allocate it now if it is missing.
*/
if (pmap_object == VM_OBJECT_NULL)
pmap_object = vm_object_allocate(phys_last_addr - phys_first_addr);
/*
* Allocate a VM page for the level 2 page table entries.
*/
while ((m = vm_page_grab(FALSE)) == VM_PAGE_NULL)
VM_PAGE_WAIT((void (*)()) 0);
/*
* Map the page to its physical address so that it
* can be found later.
*/
pa = m->phys_addr;
vm_object_lock(pmap_object);
vm_page_insert(m, pmap_object, pa);
vm_page_lock_queues();
vm_page_wire(m);
inuse_ptepages_count++;
vm_page_unlock_queues();
vm_object_unlock(pmap_object);
/*
* Zero the page.
*/
memset((void *)phystokv(pa), 0, PAGE_SIZE);
return pa;
}
#ifdef MACH_XEN
void pmap_map_mfn(void *_addr, unsigned long mfn) {
vm_offset_t addr = (vm_offset_t) _addr;
pt_entry_t *pte, *pdp;
vm_offset_t ptp;
pt_entry_t ma = ((pt_entry_t) mfn) << PAGE_SHIFT;
/* Add a ptp if none exist yet for this pte */
if ((pte = pmap_pte(kernel_pmap, addr)) == PT_ENTRY_NULL) {
ptp = phystokv(pmap_page_table_page_alloc());
#ifdef MACH_PV_PAGETABLES
pmap_set_page_readonly((void*) ptp);
if (!hyp_mmuext_op_mfn (MMUEXT_PIN_L1_TABLE, pa_to_mfn(ptp)))
panic("couldn't pin page %p(%p)\n",ptp,(vm_offset_t) kv_to_ma(ptp));
#endif /* MACH_PV_PAGETABLES */
pdp = pmap_pde(kernel_pmap, addr);
#ifdef MACH_PV_PAGETABLES
if (!hyp_mmu_update_pte(kv_to_ma(pdp),
pa_to_pte(kv_to_ma(ptp)) | INTEL_PTE_VALID
| INTEL_PTE_USER
| INTEL_PTE_WRITE))
panic("%s:%d could not set pde %p(%p) to %p(%p)\n",__FILE__,__LINE__,kvtophys((vm_offset_t)pdp),(vm_offset_t) kv_to_ma(pdp), ptp, (vm_offset_t) pa_to_ma(ptp));
#else /* MACH_PV_PAGETABLES */
*pdp = pa_to_pte(kvtophys(ptp)) | INTEL_PTE_VALID
| INTEL_PTE_USER
| INTEL_PTE_WRITE;
#endif /* MACH_PV_PAGETABLES */
pte = pmap_pte(kernel_pmap, addr);
}
#ifdef MACH_PV_PAGETABLES
if (!hyp_mmu_update_pte(kv_to_ma(pte), ma | INTEL_PTE_VALID | INTEL_PTE_WRITE))
panic("%s:%d could not set pte %p(%p) to %p(%p)\n",__FILE__,__LINE__,pte,(vm_offset_t) kv_to_ma(pte), ma, ma_to_pa(ma));
#else /* MACH_PV_PAGETABLES */
/* Note: in this case, mfn is actually a pfn. */
WRITE_PTE(pte, ma | INTEL_PTE_VALID | INTEL_PTE_WRITE);
#endif /* MACH_PV_PAGETABLES */
}
#endif /* MACH_XEN */
/*
* Deallocate a page-table page.
* The page-table page must have all mappings removed,
* and be removed from its page directory.
*/
void
pmap_page_table_page_dealloc(vm_offset_t pa)
{
vm_page_t m;
vm_object_lock(pmap_object);
m = vm_page_lookup(pmap_object, pa);
vm_page_lock_queues();
vm_page_free(m);
inuse_ptepages_count--;
vm_page_unlock_queues();
vm_object_unlock(pmap_object);
}
/*
* Create and return a physical map.
*
* If the size specified for the map
* is zero, the map is an actual physical
* map, and may be referenced by the
* hardware.
*
* If the size specified is non-zero,
* the map will be used in software only, and
* is bounded by that size.
*/
pmap_t pmap_create(vm_size_t size)
{
pmap_t p;
pmap_statistics_t stats;
/*
* A software use-only map doesn't even need a map.
*/
if (size != 0) {
return(PMAP_NULL);
}
/*
* Allocate a pmap struct from the pmap_cache. Then allocate
* the page descriptor table.
*/
p = (pmap_t) kmem_cache_alloc(&pmap_cache);
if (p == PMAP_NULL)
panic("pmap_create");
if (kmem_alloc_wired(kernel_map,
(vm_offset_t *)&p->dirbase, PDPNUM * INTEL_PGBYTES)
!= KERN_SUCCESS)
panic("pmap_create");
memcpy(p->dirbase, kernel_page_dir, PDPNUM * INTEL_PGBYTES);
#ifdef LINUX_DEV
#if VM_MIN_KERNEL_ADDRESS != 0
/* Do not map BIOS in user tasks */
p->dirbase[lin2pdenum(LINEAR_MIN_KERNEL_ADDRESS - VM_MIN_KERNEL_ADDRESS)] = 0;
#endif
#endif
#ifdef MACH_PV_PAGETABLES
{
int i;
for (i = 0; i < PDPNUM; i++)
pmap_set_page_readonly((void*) p->dirbase + i * INTEL_PGBYTES);
}
#endif /* MACH_PV_PAGETABLES */
#if PAE
if (kmem_alloc_wired(kernel_map,
(vm_offset_t *)&p->pdpbase, INTEL_PGBYTES)
!= KERN_SUCCESS)
panic("pmap_create");
{
int i;
for (i = 0; i < PDPNUM; i++)
WRITE_PTE(&p->pdpbase[i], pa_to_pte(kvtophys((vm_offset_t) p->dirbase + i * INTEL_PGBYTES)) | INTEL_PTE_VALID);
}
#ifdef MACH_PV_PAGETABLES
pmap_set_page_readonly(p->pdpbase);
#endif /* MACH_PV_PAGETABLES */
#endif /* PAE */
p->ref_count = 1;
simple_lock_init(&p->lock);
p->cpus_using = 0;
/*
* Initialize statistics.
*/
stats = &p->stats;
stats->resident_count = 0;
stats->wired_count = 0;
return(p);
}
/*
* Retire the given physical map from service.
* Should only be called if the map contains
* no valid mappings.
*/
void pmap_destroy(pmap_t p)
{
pt_entry_t *pdep;
vm_offset_t pa;
int c, s;
vm_page_t m;
if (p == PMAP_NULL)
return;
SPLVM(s);
simple_lock(&p->lock);
c = --p->ref_count;
simple_unlock(&p->lock);
SPLX(s);
if (c != 0) {
return; /* still in use */
}
/*
* Free the memory maps, then the
* pmap structure.
*/
for (pdep = p->dirbase;
pdep < &p->dirbase[lin2pdenum(LINEAR_MIN_KERNEL_ADDRESS)];
pdep += ptes_per_vm_page) {
if (*pdep & INTEL_PTE_VALID) {
pa = pte_to_pa(*pdep);
vm_object_lock(pmap_object);
m = vm_page_lookup(pmap_object, pa);
if (m == VM_PAGE_NULL)
panic("pmap_destroy: pte page not in object");
vm_page_lock_queues();
#ifdef MACH_PV_PAGETABLES
if (!hyp_mmuext_op_mfn (MMUEXT_UNPIN_TABLE, pa_to_mfn(pa)))
panic("pmap_destroy: couldn't unpin page %p(%p)\n", pa, (vm_offset_t) kv_to_ma(pa));
pmap_set_page_readwrite((void*) phystokv(pa));
#endif /* MACH_PV_PAGETABLES */
vm_page_free(m);
inuse_ptepages_count--;
vm_page_unlock_queues();
vm_object_unlock(pmap_object);
}
}
#ifdef MACH_PV_PAGETABLES
{
int i;
for (i = 0; i < PDPNUM; i++)
pmap_set_page_readwrite((void*) p->dirbase + i * INTEL_PGBYTES);
}
#endif /* MACH_PV_PAGETABLES */
kmem_free(kernel_map, (vm_offset_t)p->dirbase, PDPNUM * INTEL_PGBYTES);
#if PAE
#ifdef MACH_PV_PAGETABLES
pmap_set_page_readwrite(p->pdpbase);
#endif /* MACH_PV_PAGETABLES */
kmem_free(kernel_map, (vm_offset_t)p->pdpbase, INTEL_PGBYTES);
#endif /* PAE */
kmem_cache_free(&pmap_cache, (vm_offset_t) p);
}
/*
* Add a reference to the specified pmap.
*/
void pmap_reference(pmap_t p)
{
int s;
if (p != PMAP_NULL) {
SPLVM(s);
simple_lock(&p->lock);
p->ref_count++;
simple_unlock(&p->lock);
SPLX(s);
}
}
/*
* Remove a range of hardware page-table entries.
* The entries given are the first (inclusive)
* and last (exclusive) entries for the VM pages.
* The virtual address is the va for the first pte.
*
* The pmap must be locked.
* If the pmap is not the kernel pmap, the range must lie
* entirely within one pte-page. This is NOT checked.
* Assumes that the pte-page exists.
*/
/* static */
void pmap_remove_range(
pmap_t pmap,
vm_offset_t va,
pt_entry_t *spte,
pt_entry_t *epte)
{
pt_entry_t *cpte;
int num_removed, num_unwired;
int pai;
vm_offset_t pa;
#ifdef MACH_PV_PAGETABLES
int n, ii = 0;
struct mmu_update update[HYP_BATCH_MMU_UPDATES];
#endif /* MACH_PV_PAGETABLES */
#if DEBUG_PTE_PAGE
if (pmap != kernel_pmap)
ptep_check(get_pte_page(spte));
#endif /* DEBUG_PTE_PAGE */
num_removed = 0;
num_unwired = 0;
for (cpte = spte; cpte < epte;
cpte += ptes_per_vm_page, va += PAGE_SIZE) {
if (*cpte == 0)
continue;
pa = pte_to_pa(*cpte);
num_removed++;
if (*cpte & INTEL_PTE_WIRED)
num_unwired++;
if (!valid_page(pa)) {
/*
* Outside range of managed physical memory.
* Just remove the mappings.
*/
int i = ptes_per_vm_page;
pt_entry_t *lpte = cpte;
do {
#ifdef MACH_PV_PAGETABLES
update[ii].ptr = kv_to_ma(lpte);
update[ii].val = 0;
ii++;
if (ii == HYP_BATCH_MMU_UPDATES) {
hyp_mmu_update(kvtolin(&update), ii, kvtolin(&n), DOMID_SELF);
if (n != ii)
panic("couldn't pmap_remove_range\n");
ii = 0;
}
#else /* MACH_PV_PAGETABLES */
*lpte = 0;
#endif /* MACH_PV_PAGETABLES */
lpte++;
} while (--i > 0);
continue;
}
pai = pa_index(pa);
LOCK_PVH(pai);
/*
* Get the modify and reference bits.
*/
{
int i;
pt_entry_t *lpte;
i = ptes_per_vm_page;
lpte = cpte;
do {
pmap_phys_attributes[pai] |=
*lpte & (PHYS_MODIFIED|PHYS_REFERENCED);
#ifdef MACH_PV_PAGETABLES
update[ii].ptr = kv_to_ma(lpte);
update[ii].val = 0;
ii++;
if (ii == HYP_BATCH_MMU_UPDATES) {
hyp_mmu_update(kvtolin(&update), ii, kvtolin(&n), DOMID_SELF);
if (n != ii)
panic("couldn't pmap_remove_range\n");
ii = 0;
}
#else /* MACH_PV_PAGETABLES */
*lpte = 0;
#endif /* MACH_PV_PAGETABLES */
lpte++;
} while (--i > 0);
}
/*
* Remove the mapping from the pvlist for
* this physical page.
*/
{
pv_entry_t pv_h, prev, cur;
pv_h = pai_to_pvh(pai);
if (pv_h->pmap == PMAP_NULL) {
panic("pmap_remove: null pv_list!");
}
if (pv_h->va == va && pv_h->pmap == pmap) {
/*
* Header is the pv_entry. Copy the next one
* to header and free the next one (we cannot
* free the header)
*/
cur = pv_h->next;
if (cur != PV_ENTRY_NULL) {
*pv_h = *cur;
PV_FREE(cur);
}
else {
pv_h->pmap = PMAP_NULL;
}
}
else {
cur = pv_h;
do {
prev = cur;
if ((cur = prev->next) == PV_ENTRY_NULL) {
panic("pmap-remove: mapping not in pv_list!");
}
} while (cur->va != va || cur->pmap != pmap);
prev->next = cur->next;
PV_FREE(cur);
}
UNLOCK_PVH(pai);
}
}
#ifdef MACH_PV_PAGETABLES
if (ii > HYP_BATCH_MMU_UPDATES)
panic("overflowed array in pmap_remove_range");
hyp_mmu_update(kvtolin(&update), ii, kvtolin(&n), DOMID_SELF);
if (n != ii)
panic("couldn't pmap_remove_range\n");
#endif /* MACH_PV_PAGETABLES */
/*
* Update the counts
*/
pmap->stats.resident_count -= num_removed;
pmap->stats.wired_count -= num_unwired;
}
/*
* Remove the given range of addresses
* from the specified map.
*
* It is assumed that the start and end are properly
* rounded to the hardware page size.
*/
void pmap_remove(
pmap_t map,
vm_offset_t s,
vm_offset_t e)
{
int spl;
pt_entry_t *pde;
pt_entry_t *spte, *epte;
vm_offset_t l;
vm_offset_t _s = s;
if (map == PMAP_NULL)
return;
PMAP_READ_LOCK(map, spl);
pde = pmap_pde(map, s);
while (s < e) {
l = (s + PDE_MAPPED_SIZE) & ~(PDE_MAPPED_SIZE-1);
if (l > e)
l = e;
if (*pde & INTEL_PTE_VALID) {
spte = (pt_entry_t *)ptetokv(*pde);
spte = &spte[ptenum(s)];
epte = &spte[intel_btop(l-s)];
pmap_remove_range(map, s, spte, epte);
}
s = l;
pde++;
}
PMAP_UPDATE_TLBS(map, _s, e);
PMAP_READ_UNLOCK(map, spl);
}
/*
* Routine: pmap_page_protect
*
* Function:
* Lower the permission for all mappings to a given
* page.
*/
void pmap_page_protect(
vm_offset_t phys,
vm_prot_t prot)
{
pv_entry_t pv_h, prev;
pv_entry_t pv_e;
pt_entry_t *pte;
int pai;
pmap_t pmap;
int spl;
boolean_t remove;
assert(phys != vm_page_fictitious_addr);
if (!valid_page(phys)) {
/*
* Not a managed page.
*/
return;
}
/*
* Determine the new protection.
*/
switch (prot) {
case VM_PROT_READ:
case VM_PROT_READ|VM_PROT_EXECUTE:
remove = FALSE;
break;
case VM_PROT_ALL:
return; /* nothing to do */
default:
remove = TRUE;
break;
}
/*
* Lock the pmap system first, since we will be changing
* several pmaps.
*/
PMAP_WRITE_LOCK(spl);
pai = pa_index(phys);
pv_h = pai_to_pvh(pai);
/*
* Walk down PV list, changing or removing all mappings.
* We do not have to lock the pv_list because we have
* the entire pmap system locked.
*/
if (pv_h->pmap != PMAP_NULL) {
prev = pv_e = pv_h;
do {
vm_offset_t va;
pmap = pv_e->pmap;
/*
* Lock the pmap to block pmap_extract and similar routines.
*/
simple_lock(&pmap->lock);
va = pv_e->va;
pte = pmap_pte(pmap, va);
/*
* Consistency checks.
*/
/* assert(*pte & INTEL_PTE_VALID); XXX */
/* assert(pte_to_phys(*pte) == phys); */
/*
* Remove the mapping if new protection is NONE
* or if write-protecting a kernel mapping.
*/
if (remove || pmap == kernel_pmap) {
/*
* Remove the mapping, collecting any modify bits.
*/
if (*pte & INTEL_PTE_WIRED)
panic("pmap_remove_all removing a wired page");
{
int i = ptes_per_vm_page;
do {
pmap_phys_attributes[pai] |=
*pte & (PHYS_MODIFIED|PHYS_REFERENCED);
#ifdef MACH_PV_PAGETABLES
if (!hyp_mmu_update_pte(kv_to_ma(pte++), 0))
panic("%s:%d could not clear pte %p\n",__FILE__,__LINE__,pte-1);
#else /* MACH_PV_PAGETABLES */
*pte++ = 0;
#endif /* MACH_PV_PAGETABLES */
} while (--i > 0);
}
pmap->stats.resident_count--;
/*
* Remove the pv_entry.
*/
if (pv_e == pv_h) {
/*
* Fix up head later.
*/
pv_h->pmap = PMAP_NULL;
}
else {
/*
* Delete this entry.
*/
prev->next = pv_e->next;
PV_FREE(pv_e);
}
}
else {
/*
* Write-protect.
*/
int i = ptes_per_vm_page;
do {
#ifdef MACH_PV_PAGETABLES
if (!hyp_mmu_update_pte(kv_to_ma(pte), *pte & ~INTEL_PTE_WRITE))
panic("%s:%d could not disable write on pte %p\n",__FILE__,__LINE__,pte);
#else /* MACH_PV_PAGETABLES */
*pte &= ~INTEL_PTE_WRITE;
#endif /* MACH_PV_PAGETABLES */
pte++;
} while (--i > 0);
/*
* Advance prev.
*/
prev = pv_e;
}
PMAP_UPDATE_TLBS(pmap, va, va + PAGE_SIZE);
simple_unlock(&pmap->lock);
} while ((pv_e = prev->next) != PV_ENTRY_NULL);
/*
* If pv_head mapping was removed, fix it up.
*/
if (pv_h->pmap == PMAP_NULL) {
pv_e = pv_h->next;
if (pv_e != PV_ENTRY_NULL) {
*pv_h = *pv_e;
PV_FREE(pv_e);
}
}
}
PMAP_WRITE_UNLOCK(spl);
}
/*
* Set the physical protection on the
* specified range of this map as requested.
* Will not increase permissions.
*/
void pmap_protect(
pmap_t map,
vm_offset_t s,
vm_offset_t e,
vm_prot_t prot)
{
pt_entry_t *pde;
pt_entry_t *spte, *epte;
vm_offset_t l;
int spl;
vm_offset_t _s = s;
if (map == PMAP_NULL)
return;
/*
* Determine the new protection.
*/
switch (prot) {
case VM_PROT_READ:
case VM_PROT_READ|VM_PROT_EXECUTE:
break;
case VM_PROT_READ|VM_PROT_WRITE:
case VM_PROT_ALL:
return; /* nothing to do */
default:
pmap_remove(map, s, e);
return;
}
/*
* If write-protecting in the kernel pmap,
* remove the mappings; the i386 ignores
* the write-permission bit in kernel mode.
*
* XXX should be #if'd for i386
*/
if (map == kernel_pmap) {
pmap_remove(map, s, e);
return;
}
SPLVM(spl);
simple_lock(&map->lock);
pde = pmap_pde(map, s);
while (s < e) {
l = (s + PDE_MAPPED_SIZE) & ~(PDE_MAPPED_SIZE-1);
if (l > e)
l = e;
if (*pde & INTEL_PTE_VALID) {
spte = (pt_entry_t *)ptetokv(*pde);
spte = &spte[ptenum(s)];
epte = &spte[intel_btop(l-s)];
#ifdef MACH_PV_PAGETABLES
int n, i = 0;
struct mmu_update update[HYP_BATCH_MMU_UPDATES];
#endif /* MACH_PV_PAGETABLES */
while (spte < epte) {
if (*spte & INTEL_PTE_VALID) {
#ifdef MACH_PV_PAGETABLES
update[i].ptr = kv_to_ma(spte);
update[i].val = *spte & ~INTEL_PTE_WRITE;
i++;
if (i == HYP_BATCH_MMU_UPDATES) {
hyp_mmu_update(kvtolin(&update), i, kvtolin(&n), DOMID_SELF);
if (n != i)
panic("couldn't pmap_protect\n");
i = 0;
}
#else /* MACH_PV_PAGETABLES */
*spte &= ~INTEL_PTE_WRITE;
#endif /* MACH_PV_PAGETABLES */
}
spte++;
}
#ifdef MACH_PV_PAGETABLES
if (i > HYP_BATCH_MMU_UPDATES)
panic("overflowed array in pmap_protect");
hyp_mmu_update(kvtolin(&update), i, kvtolin(&n), DOMID_SELF);
if (n != i)
panic("couldn't pmap_protect\n");
#endif /* MACH_PV_PAGETABLES */
}
s = l;
pde++;
}
PMAP_UPDATE_TLBS(map, _s, e);
simple_unlock(&map->lock);
SPLX(spl);
}
/*
* Insert the given physical page (p) at
* the specified virtual address (v) in the
* target physical map with the protection requested.
*
* If specified, the page will be wired down, meaning
* that the related pte can not be reclaimed.
*
* NB: This is the only routine which MAY NOT lazy-evaluate
* or lose information. That is, this routine must actually
* insert this page into the given map NOW.
*/
void pmap_enter(
pmap_t pmap,
vm_offset_t v,
vm_offset_t pa,
vm_prot_t prot,
boolean_t wired)
{
pt_entry_t *pte;
pv_entry_t pv_h;
int i, pai;
pv_entry_t pv_e;
pt_entry_t template;
int spl;
vm_offset_t old_pa;
assert(pa != vm_page_fictitious_addr);
if (pmap_debug) printf("pmap(%lx, %lx)\n", v, pa);
if (pmap == PMAP_NULL)
return;
#if !MACH_KDB
if (pmap == kernel_pmap && (v < kernel_virtual_start || v >= kernel_virtual_end))
panic("pmap_enter(%p, %p) falls in physical memory area!\n", v, pa);
#endif
if (pmap == kernel_pmap && (prot & VM_PROT_WRITE) == 0
&& !wired /* hack for io_wire */ ) {
/*
* Because the 386 ignores write protection in kernel mode,
* we cannot enter a read-only kernel mapping, and must
* remove an existing mapping if changing it.
*
* XXX should be #if'd for i386
*/
PMAP_READ_LOCK(pmap, spl);
pte = pmap_pte(pmap, v);
if (pte != PT_ENTRY_NULL && *pte != 0) {
/*
* Invalidate the translation buffer,
* then remove the mapping.
*/
pmap_remove_range(pmap, v, pte,
pte + ptes_per_vm_page);
PMAP_UPDATE_TLBS(pmap, v, v + PAGE_SIZE);
}
PMAP_READ_UNLOCK(pmap, spl);
return;
}
/*
* Must allocate a new pvlist entry while we're unlocked;
* Allocating may cause pageout (which will lock the pmap system).
* If we determine we need a pvlist entry, we will unlock
* and allocate one. Then we will retry, throughing away
* the allocated entry later (if we no longer need it).
*/
pv_e = PV_ENTRY_NULL;
Retry:
PMAP_READ_LOCK(pmap, spl);
/*
* Expand pmap to include this pte. Assume that
* pmap is always expanded to include enough hardware
* pages to map one VM page.
*/
while ((pte = pmap_pte(pmap, v)) == PT_ENTRY_NULL) {
/*
* Need to allocate a new page-table page.
*/
vm_offset_t ptp;
pt_entry_t *pdp;
int i;
if (pmap == kernel_pmap) {
/*
* Would have to enter the new page-table page in
* EVERY pmap.
*/
panic("pmap_expand kernel pmap to %#x", v);
}
/*
* Unlock the pmap and allocate a new page-table page.
*/
PMAP_READ_UNLOCK(pmap, spl);
ptp = phystokv(pmap_page_table_page_alloc());
/*
* Re-lock the pmap and check that another thread has
* not already allocated the page-table page. If it
* has, discard the new page-table page (and try
* again to make sure).
*/
PMAP_READ_LOCK(pmap, spl);
if (pmap_pte(pmap, v) != PT_ENTRY_NULL) {
/*
* Oops...
*/
PMAP_READ_UNLOCK(pmap, spl);
pmap_page_table_page_dealloc(kvtophys(ptp));
PMAP_READ_LOCK(pmap, spl);
continue;
}
/*
* Enter the new page table page in the page directory.
*/
i = ptes_per_vm_page;
/*XX pdp = &pmap->dirbase[pdenum(v) & ~(i-1)];*/
pdp = pmap_pde(pmap, v);
do {
#ifdef MACH_PV_PAGETABLES
pmap_set_page_readonly((void *) ptp);
if (!hyp_mmuext_op_mfn (MMUEXT_PIN_L1_TABLE, kv_to_mfn(ptp)))
panic("couldn't pin page %p(%p)\n",ptp,(vm_offset_t) kv_to_ma(ptp));
if (!hyp_mmu_update_pte(pa_to_ma(kvtophys((vm_offset_t)pdp)),
pa_to_pte(pa_to_ma(kvtophys(ptp))) | INTEL_PTE_VALID
| INTEL_PTE_USER
| INTEL_PTE_WRITE))
panic("%s:%d could not set pde %p(%p,%p) to %p(%p,%p) %p\n",__FILE__,__LINE__, pdp, kvtophys((vm_offset_t)pdp), (vm_offset_t) pa_to_ma(kvtophys((vm_offset_t)pdp)), ptp, kvtophys(ptp), (vm_offset_t) pa_to_ma(kvtophys(ptp)), (vm_offset_t) pa_to_pte(kv_to_ma(ptp)));
#else /* MACH_PV_PAGETABLES */
*pdp = pa_to_pte(kvtophys(ptp)) | INTEL_PTE_VALID
| INTEL_PTE_USER
| INTEL_PTE_WRITE;
#endif /* MACH_PV_PAGETABLES */
pdp++;
ptp += INTEL_PGBYTES;
} while (--i > 0);
/*
* Now, get the address of the page-table entry.
*/
continue;
}
/*
* Special case if the physical page is already mapped
* at this address.
*/
old_pa = pte_to_pa(*pte);
if (*pte && old_pa == pa) {
/*
* May be changing its wired attribute or protection
*/
if (wired && !(*pte & INTEL_PTE_WIRED))
pmap->stats.wired_count++;
else if (!wired && (*pte & INTEL_PTE_WIRED))
pmap->stats.wired_count--;
template = pa_to_pte(pa) | INTEL_PTE_VALID;
if (pmap != kernel_pmap)
template |= INTEL_PTE_USER;
if (prot & VM_PROT_WRITE)
template |= INTEL_PTE_WRITE;
if (machine_slot[cpu_number()].cpu_type >= CPU_TYPE_I486
&& pa >= phys_last_addr)
template |= INTEL_PTE_NCACHE|INTEL_PTE_WTHRU;
if (wired)
template |= INTEL_PTE_WIRED;
i = ptes_per_vm_page;
do {
if (*pte & INTEL_PTE_MOD)
template |= INTEL_PTE_MOD;
#ifdef MACH_PV_PAGETABLES
if (!hyp_mmu_update_pte(kv_to_ma(pte), pa_to_ma(template)))
panic("%s:%d could not set pte %p to %p\n",__FILE__,__LINE__,pte,template);
#else /* MACH_PV_PAGETABLES */
WRITE_PTE(pte, template)
#endif /* MACH_PV_PAGETABLES */
pte++;
pte_increment_pa(template);
} while (--i > 0);
PMAP_UPDATE_TLBS(pmap, v, v + PAGE_SIZE);
}
else {
/*
* Remove old mapping from the PV list if necessary.
*/
if (*pte) {
/*
* Don't free the pte page if removing last
* mapping - we will immediately replace it.
*/
pmap_remove_range(pmap, v, pte,
pte + ptes_per_vm_page);
PMAP_UPDATE_TLBS(pmap, v, v + PAGE_SIZE);
}
if (valid_page(pa)) {
/*
* Enter the mapping in the PV list for this
* physical page.
*/
pai = pa_index(pa);
LOCK_PVH(pai);
pv_h = pai_to_pvh(pai);
if (pv_h->pmap == PMAP_NULL) {
/*
* No mappings yet
*/
pv_h->va = v;
pv_h->pmap = pmap;
pv_h->next = PV_ENTRY_NULL;
}
else {
#if DEBUG
{
/* check that this mapping is not already there */
pv_entry_t e = pv_h;
while (e != PV_ENTRY_NULL) {
if (e->pmap == pmap && e->va == v)
panic("pmap_enter: already in pv_list");
e = e->next;
}
}
#endif /* DEBUG */
/*
* Add new pv_entry after header.
*/
if (pv_e == PV_ENTRY_NULL) {
PV_ALLOC(pv_e);
if (pv_e == PV_ENTRY_NULL) {
UNLOCK_PVH(pai);
PMAP_READ_UNLOCK(pmap, spl);
/*
* Refill from cache.
*/
pv_e = (pv_entry_t) kmem_cache_alloc(&pv_list_cache);
goto Retry;
}
}
pv_e->va = v;
pv_e->pmap = pmap;
pv_e->next = pv_h->next;
pv_h->next = pv_e;
/*
* Remember that we used the pvlist entry.
*/
pv_e = PV_ENTRY_NULL;
}
UNLOCK_PVH(pai);
}
/*
* And count the mapping.
*/
pmap->stats.resident_count++;
if (wired)
pmap->stats.wired_count++;
/*
* Build a template to speed up entering -
* only the pfn changes.
*/
template = pa_to_pte(pa) | INTEL_PTE_VALID;
if (pmap != kernel_pmap)
template |= INTEL_PTE_USER;
if (prot & VM_PROT_WRITE)
template |= INTEL_PTE_WRITE;
if (machine_slot[cpu_number()].cpu_type >= CPU_TYPE_I486
&& pa >= phys_last_addr)
template |= INTEL_PTE_NCACHE|INTEL_PTE_WTHRU;
if (wired)
template |= INTEL_PTE_WIRED;
i = ptes_per_vm_page;
do {
#ifdef MACH_PV_PAGETABLES
if (!(hyp_mmu_update_pte(kv_to_ma(pte), pa_to_ma(template))))
panic("%s:%d could not set pte %p to %p\n",__FILE__,__LINE__,pte,template);
#else /* MACH_PV_PAGETABLES */
WRITE_PTE(pte, template)
#endif /* MACH_PV_PAGETABLES */
pte++;
pte_increment_pa(template);
} while (--i > 0);
}
if (pv_e != PV_ENTRY_NULL) {
PV_FREE(pv_e);
}
PMAP_READ_UNLOCK(pmap, spl);
}
/*
* Routine: pmap_change_wiring
* Function: Change the wiring attribute for a map/virtual-address
* pair.
* In/out conditions:
* The mapping must already exist in the pmap.
*/
void pmap_change_wiring(
pmap_t map,
vm_offset_t v,
boolean_t wired)
{
pt_entry_t *pte;
int i;
int spl;
/*
* We must grab the pmap system lock because we may
* change a pte_page queue.
*/
PMAP_READ_LOCK(map, spl);
if ((pte = pmap_pte(map, v)) == PT_ENTRY_NULL)
panic("pmap_change_wiring: pte missing");
if (wired && !(*pte & INTEL_PTE_WIRED)) {
/*
* wiring down mapping
*/
map->stats.wired_count++;
i = ptes_per_vm_page;
do {
*pte++ |= INTEL_PTE_WIRED;
} while (--i > 0);
}
else if (!wired && (*pte & INTEL_PTE_WIRED)) {
/*
* unwiring mapping
*/
map->stats.wired_count--;
i = ptes_per_vm_page;
do {
#ifdef MACH_PV_PAGETABLES
if (!(hyp_mmu_update_pte(kv_to_ma(pte), *pte & ~INTEL_PTE_WIRED)))
panic("%s:%d could not wire down pte %p\n",__FILE__,__LINE__,pte);
#else /* MACH_PV_PAGETABLES */
*pte &= ~INTEL_PTE_WIRED;
#endif /* MACH_PV_PAGETABLES */
pte++;
} while (--i > 0);
}
PMAP_READ_UNLOCK(map, spl);
}
/*
* Routine: pmap_extract
* Function:
* Extract the physical page address associated
* with the given map/virtual_address pair.
*/
vm_offset_t pmap_extract(
pmap_t pmap,
vm_offset_t va)
{
pt_entry_t *pte;
vm_offset_t pa;
int spl;
SPLVM(spl);
simple_lock(&pmap->lock);
if ((pte = pmap_pte(pmap, va)) == PT_ENTRY_NULL)
pa = (vm_offset_t) 0;
else if (!(*pte & INTEL_PTE_VALID))
pa = (vm_offset_t) 0;
else
pa = pte_to_pa(*pte) + (va & INTEL_OFFMASK);
simple_unlock(&pmap->lock);
SPLX(spl);
return(pa);
}
/*
* Copy the range specified by src_addr/len
* from the source map to the range dst_addr/len
* in the destination map.
*
* This routine is only advisory and need not do anything.
*/
#if 0
void pmap_copy(dst_pmap, src_pmap, dst_addr, len, src_addr)
pmap_t dst_pmap;
pmap_t src_pmap;
vm_offset_t dst_addr;
vm_size_t len;
vm_offset_t src_addr;
{
}
#endif /* 0 */
/*
* Routine: pmap_collect
* Function:
* Garbage collects the physical map system for
* pages which are no longer used.
* Success need not be guaranteed -- that is, there
* may well be pages which are not referenced, but
* others may be collected.
* Usage:
* Called by the pageout daemon when pages are scarce.
*/
void pmap_collect(pmap_t p)
{
pt_entry_t *pdp, *ptp;
pt_entry_t *eptp;
vm_offset_t pa;
int spl, wired;
if (p == PMAP_NULL)
return;
if (p == kernel_pmap)
return;
/*
* Garbage collect map.
*/
PMAP_READ_LOCK(p, spl);
for (pdp = p->dirbase;
pdp < &p->dirbase[lin2pdenum(LINEAR_MIN_KERNEL_ADDRESS)];
pdp += ptes_per_vm_page)
{
if (*pdp & INTEL_PTE_VALID) {
pa = pte_to_pa(*pdp);
ptp = (pt_entry_t *)phystokv(pa);
eptp = ptp + NPTES*ptes_per_vm_page;
/*
* If the pte page has any wired mappings, we cannot
* free it.
*/
wired = 0;
{
pt_entry_t *ptep;
for (ptep = ptp; ptep < eptp; ptep++) {
if (*ptep & INTEL_PTE_WIRED) {
wired = 1;
break;
}
}
}
if (!wired) {
/*
* Remove the virtual addresses mapped by this pte page.
*/
{ /*XXX big hack*/
vm_offset_t va = pdenum2lin(pdp - p->dirbase);
if (p == kernel_pmap)
va = lintokv(va);
pmap_remove_range(p,
va,
ptp,
eptp);
}
/*
* Invalidate the page directory pointer.
*/
{
int i = ptes_per_vm_page;
pt_entry_t *pdep = pdp;
do {
#ifdef MACH_PV_PAGETABLES
unsigned long pte = *pdep;
void *ptable = (void*) ptetokv(pte);
if (!(hyp_mmu_update_pte(pa_to_ma(kvtophys((vm_offset_t)pdep++)), 0)))
panic("%s:%d could not clear pde %p\n",__FILE__,__LINE__,pdep-1);
if (!hyp_mmuext_op_mfn (MMUEXT_UNPIN_TABLE, kv_to_mfn(ptable)))
panic("couldn't unpin page %p(%p)\n", ptable, (vm_offset_t) pa_to_ma(kvtophys((vm_offset_t)ptable)));
pmap_set_page_readwrite(ptable);
#else /* MACH_PV_PAGETABLES */
*pdep++ = 0;
#endif /* MACH_PV_PAGETABLES */
} while (--i > 0);
}
PMAP_READ_UNLOCK(p, spl);
/*
* And free the pte page itself.
*/
{
vm_page_t m;
vm_object_lock(pmap_object);
m = vm_page_lookup(pmap_object, pa);
if (m == VM_PAGE_NULL)
panic("pmap_collect: pte page not in object");
vm_page_lock_queues();
vm_page_free(m);
inuse_ptepages_count--;
vm_page_unlock_queues();
vm_object_unlock(pmap_object);
}
PMAP_READ_LOCK(p, spl);
}
}
}
PMAP_UPDATE_TLBS(p, VM_MIN_ADDRESS, VM_MAX_ADDRESS);
PMAP_READ_UNLOCK(p, spl);
return;
}
/*
* Routine: pmap_activate
* Function:
* Binds the given physical map to the given
* processor, and returns a hardware map description.
*/
#if 0
void pmap_activate(my_pmap, th, my_cpu)
register pmap_t my_pmap;
thread_t th;
int my_cpu;
{
PMAP_ACTIVATE(my_pmap, th, my_cpu);
}
#endif /* 0 */
/*
* Routine: pmap_deactivate
* Function:
* Indicates that the given physical map is no longer
* in use on the specified processor. (This is a macro
* in pmap.h)
*/
#if 0
void pmap_deactivate(pmap, th, which_cpu)
pmap_t pmap;
thread_t th;
int which_cpu;
{
PMAP_DEACTIVATE(pmap, th, which_cpu);
}
#endif /* 0 */
/*
* Routine: pmap_kernel
* Function:
* Returns the physical map handle for the kernel.
*/
#if 0
pmap_t pmap_kernel()
{
return (kernel_pmap);
}
#endif /* 0 */
/*
* pmap_zero_page zeros the specified (machine independent) page.
* See machine/phys.c or machine/phys.s for implementation.
*/
#if 0
pmap_zero_page(phys)
register vm_offset_t phys;
{
register int i;
assert(phys != vm_page_fictitious_addr);
i = PAGE_SIZE / INTEL_PGBYTES;
phys = intel_pfn(phys);
while (i--)
zero_phys(phys++);
}
#endif /* 0 */
/*
* pmap_copy_page copies the specified (machine independent) page.
* See machine/phys.c or machine/phys.s for implementation.
*/
#if 0
pmap_copy_page(src, dst)
vm_offset_t src, dst;
{
int i;
assert(src != vm_page_fictitious_addr);
assert(dst != vm_page_fictitious_addr);
i = PAGE_SIZE / INTEL_PGBYTES;
while (i--) {
copy_phys(intel_pfn(src), intel_pfn(dst));
src += INTEL_PGBYTES;
dst += INTEL_PGBYTES;
}
}
#endif /* 0 */
/*
* Routine: pmap_pageable
* Function:
* Make the specified pages (by pmap, offset)
* pageable (or not) as requested.
*
* A page which is not pageable may not take
* a fault; therefore, its page table entry
* must remain valid for the duration.
*
* This routine is merely advisory; pmap_enter
* will specify that these pages are to be wired
* down (or not) as appropriate.
*/
void
pmap_pageable(
pmap_t pmap,
vm_offset_t start,
vm_offset_t end,
boolean_t pageable)
{
}
/*
* Clear specified attribute bits.
*/
void
phys_attribute_clear(
vm_offset_t phys,
int bits)
{
pv_entry_t pv_h;
pv_entry_t pv_e;
pt_entry_t *pte;
int pai;
pmap_t pmap;
int spl;
assert(phys != vm_page_fictitious_addr);
if (!valid_page(phys)) {
/*
* Not a managed page.
*/
return;
}
/*
* Lock the pmap system first, since we will be changing
* several pmaps.
*/
PMAP_WRITE_LOCK(spl);
pai = pa_index(phys);
pv_h = pai_to_pvh(pai);
/*
* Walk down PV list, clearing all modify or reference bits.
* We do not have to lock the pv_list because we have
* the entire pmap system locked.
*/
if (pv_h->pmap != PMAP_NULL) {
/*
* There are some mappings.
*/
for (pv_e = pv_h; pv_e != PV_ENTRY_NULL; pv_e = pv_e->next) {
vm_offset_t va;
pmap = pv_e->pmap;
/*
* Lock the pmap to block pmap_extract and similar routines.
*/
simple_lock(&pmap->lock);
va = pv_e->va;
pte = pmap_pte(pmap, va);
#if 0
/*
* Consistency checks.
*/
assert(*pte & INTEL_PTE_VALID);
/* assert(pte_to_phys(*pte) == phys); */
#endif
/*
* Clear modify or reference bits.
*/
{
int i = ptes_per_vm_page;
do {
#ifdef MACH_PV_PAGETABLES
if (!(hyp_mmu_update_pte(kv_to_ma(pte), *pte & ~bits)))
panic("%s:%d could not clear bits %lx from pte %p\n",__FILE__,__LINE__,bits,pte);
#else /* MACH_PV_PAGETABLES */
*pte &= ~bits;
#endif /* MACH_PV_PAGETABLES */
} while (--i > 0);
}
PMAP_UPDATE_TLBS(pmap, va, va + PAGE_SIZE);
simple_unlock(&pmap->lock);
}
}
pmap_phys_attributes[pai] &= ~bits;
PMAP_WRITE_UNLOCK(spl);
}
/*
* Check specified attribute bits.
*/
boolean_t
phys_attribute_test(
vm_offset_t phys,
int bits)
{
pv_entry_t pv_h;
pv_entry_t pv_e;
pt_entry_t *pte;
int pai;
pmap_t pmap;
int spl;
assert(phys != vm_page_fictitious_addr);
if (!valid_page(phys)) {
/*
* Not a managed page.
*/
return (FALSE);
}
/*
* Lock the pmap system first, since we will be checking
* several pmaps.
*/
PMAP_WRITE_LOCK(spl);
pai = pa_index(phys);
pv_h = pai_to_pvh(pai);
if (pmap_phys_attributes[pai] & bits) {
PMAP_WRITE_UNLOCK(spl);
return (TRUE);
}
/*
* Walk down PV list, checking all mappings.
* We do not have to lock the pv_list because we have
* the entire pmap system locked.
*/
if (pv_h->pmap != PMAP_NULL) {
/*
* There are some mappings.
*/
for (pv_e = pv_h; pv_e != PV_ENTRY_NULL; pv_e = pv_e->next) {
pmap = pv_e->pmap;
/*
* Lock the pmap to block pmap_extract and similar routines.
*/
simple_lock(&pmap->lock);
{
vm_offset_t va;
va = pv_e->va;
pte = pmap_pte(pmap, va);
#if 0
/*
* Consistency checks.
*/
assert(*pte & INTEL_PTE_VALID);
/* assert(pte_to_phys(*pte) == phys); */
#endif
}
/*
* Check modify or reference bits.
*/
{
int i = ptes_per_vm_page;
do {
if (*pte & bits) {
simple_unlock(&pmap->lock);
PMAP_WRITE_UNLOCK(spl);
return (TRUE);
}
} while (--i > 0);
}
simple_unlock(&pmap->lock);
}
}
PMAP_WRITE_UNLOCK(spl);
return (FALSE);
}
/*
* Clear the modify bits on the specified physical page.
*/
void pmap_clear_modify(vm_offset_t phys)
{
phys_attribute_clear(phys, PHYS_MODIFIED);
}
/*
* pmap_is_modified:
*
* Return whether or not the specified physical page is modified
* by any physical maps.
*/
boolean_t pmap_is_modified(vm_offset_t phys)
{
return (phys_attribute_test(phys, PHYS_MODIFIED));
}
/*
* pmap_clear_reference:
*
* Clear the reference bit on the specified physical page.
*/
void pmap_clear_reference(vm_offset_t phys)
{
phys_attribute_clear(phys, PHYS_REFERENCED);
}
/*
* pmap_is_referenced:
*
* Return whether or not the specified physical page is referenced
* by any physical maps.
*/
boolean_t pmap_is_referenced(vm_offset_t phys)
{
return (phys_attribute_test(phys, PHYS_REFERENCED));
}
#if NCPUS > 1
/*
* TLB Coherence Code (TLB "shootdown" code)
*
* Threads that belong to the same task share the same address space and
* hence share a pmap. However, they may run on distinct cpus and thus
* have distinct TLBs that cache page table entries. In order to guarantee
* the TLBs are consistent, whenever a pmap is changed, all threads that
* are active in that pmap must have their TLB updated. To keep track of
* this information, the set of cpus that are currently using a pmap is
* maintained within each pmap structure (cpus_using). Pmap_activate() and
* pmap_deactivate add and remove, respectively, a cpu from this set.
* Since the TLBs are not addressable over the bus, each processor must
* flush its own TLB; a processor that needs to invalidate another TLB
* needs to interrupt the processor that owns that TLB to signal the
* update.
*
* Whenever a pmap is updated, the lock on that pmap is locked, and all
* cpus using the pmap are signaled to invalidate. All threads that need
* to activate a pmap must wait for the lock to clear to await any updates
* in progress before using the pmap. They must ACQUIRE the lock to add
* their cpu to the cpus_using set. An implicit assumption made
* throughout the TLB code is that all kernel code that runs at or higher
* than splvm blocks out update interrupts, and that such code does not
* touch pageable pages.
*
* A shootdown interrupt serves another function besides signaling a
* processor to invalidate. The interrupt routine (pmap_update_interrupt)
* waits for the both the pmap lock (and the kernel pmap lock) to clear,
* preventing user code from making implicit pmap updates while the
* sending processor is performing its update. (This could happen via a
* user data write reference that turns on the modify bit in the page
* table). It must wait for any kernel updates that may have started
* concurrently with a user pmap update because the IPC code
* changes mappings.
* Spinning on the VALUES of the locks is sufficient (rather than
* having to acquire the locks) because any updates that occur subsequent
* to finding the lock unlocked will be signaled via another interrupt.
* (This assumes the interrupt is cleared before the low level interrupt code
* calls pmap_update_interrupt()).
*
* The signaling processor must wait for any implicit updates in progress
* to terminate before continuing with its update. Thus it must wait for an
* acknowledgement of the interrupt from each processor for which such
* references could be made. For maintaining this information, a set
* cpus_active is used. A cpu is in this set if and only if it can
* use a pmap. When pmap_update_interrupt() is entered, a cpu is removed from
* this set; when all such cpus are removed, it is safe to update.
*
* Before attempting to acquire the update lock on a pmap, a cpu (A) must
* be at least at the priority of the interprocessor interrupt
* (splip<=splvm). Otherwise, A could grab a lock and be interrupted by a
* kernel update; it would spin forever in pmap_update_interrupt() trying
* to acquire the user pmap lock it had already acquired. Furthermore A
* must remove itself from cpus_active. Otherwise, another cpu holding
* the lock (B) could be in the process of sending an update signal to A,
* and thus be waiting for A to remove itself from cpus_active. If A is
* spinning on the lock at priority this will never happen and a deadlock
* will result.
*/
/*
* Signal another CPU that it must flush its TLB
*/
void signal_cpus(
cpu_set use_list,
pmap_t pmap,
vm_offset_t start,
vm_offset_t end)
{
int which_cpu, j;
pmap_update_list_t update_list_p;
while ((which_cpu = ffs(use_list)) != 0) {
which_cpu -= 1; /* convert to 0 origin */
update_list_p = &cpu_update_list[which_cpu];
simple_lock(&update_list_p->lock);
j = update_list_p->count;
if (j >= UPDATE_LIST_SIZE) {
/*
* list overflowed. Change last item to
* indicate overflow.
*/
update_list_p->item[UPDATE_LIST_SIZE-1].pmap = kernel_pmap;
update_list_p->item[UPDATE_LIST_SIZE-1].start = VM_MIN_ADDRESS;
update_list_p->item[UPDATE_LIST_SIZE-1].end = VM_MAX_KERNEL_ADDRESS;
}
else {
update_list_p->item[j].pmap = pmap;
update_list_p->item[j].start = start;
update_list_p->item[j].end = end;
update_list_p->count = j+1;
}
cpu_update_needed[which_cpu] = TRUE;
simple_unlock(&update_list_p->lock);
if ((cpus_idle & (1 << which_cpu)) == 0)
interrupt_processor(which_cpu);
use_list &= ~(1 << which_cpu);
}
}
void process_pmap_updates(pmap_t my_pmap)
{
int my_cpu = cpu_number();
pmap_update_list_t update_list_p;
int j;
pmap_t pmap;
update_list_p = &cpu_update_list[my_cpu];
simple_lock(&update_list_p->lock);
for (j = 0; j < update_list_p->count; j++) {
pmap = update_list_p->item[j].pmap;
if (pmap == my_pmap ||
pmap == kernel_pmap) {
INVALIDATE_TLB(pmap,
update_list_p->item[j].start,
update_list_p->item[j].end);
}
}
update_list_p->count = 0;
cpu_update_needed[my_cpu] = FALSE;
simple_unlock(&update_list_p->lock);
}
/*
* Interrupt routine for TBIA requested from other processor.
*/
void pmap_update_interrupt(void)
{
int my_cpu;
pmap_t my_pmap;
int s;
my_cpu = cpu_number();
/*
* Exit now if we're idle. We'll pick up the update request
* when we go active, and we must not put ourselves back in
* the active set because we'll never process the interrupt
* while we're idle (thus hanging the system).
*/
if (cpus_idle & (1 << my_cpu))
return;
if (current_thread() == THREAD_NULL)
my_pmap = kernel_pmap;
else {
my_pmap = current_pmap();
if (!pmap_in_use(my_pmap, my_cpu))
my_pmap = kernel_pmap;
}
/*
* Raise spl to splvm (above splip) to block out pmap_extract
* from IO code (which would put this cpu back in the active
* set).
*/
s = splvm();
do {
/*
* Indicate that we're not using either user or kernel
* pmap.
*/
i_bit_clear(my_cpu, &cpus_active);
/*
* Wait for any pmap updates in progress, on either user
* or kernel pmap.
*/
while (*(volatile int *)&my_pmap->lock.lock_data ||
*(volatile int *)&kernel_pmap->lock.lock_data)
continue;
process_pmap_updates(my_pmap);
i_bit_set(my_cpu, &cpus_active);
} while (cpu_update_needed[my_cpu]);
splx(s);
}
#else /* NCPUS > 1 */
/*
* Dummy routine to satisfy external reference.
*/
void pmap_update_interrupt(void)
{
/* should never be called. */
}
#endif /* NCPUS > 1 */
#if defined(__i386__)
/* Unmap page 0 to trap NULL references. */
void
pmap_unmap_page_zero (void)
{
int *pte;
pte = (int *) pmap_pte (kernel_pmap, 0);
if (!pte)
return;
assert (pte);
#ifdef MACH_PV_PAGETABLES
if (!hyp_mmu_update_pte(kv_to_ma(pte), 0))
printf("couldn't unmap page 0\n");
#else /* MACH_PV_PAGETABLES */
*pte = 0;
INVALIDATE_TLB(kernel_pmap, 0, PAGE_SIZE);
#endif /* MACH_PV_PAGETABLES */
}
#endif /* __i386__ */
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