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|
/*
* Mach Operating System
* Copyright (c) 1991,1990,1989,1988,1987 Carnegie Mellon University.
* Copyright (c) 1993,1994 The University of Utah and
* the Computer Systems Laboratory (CSL).
* 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, THE UNIVERSITY OF UTAH AND CSL ALLOW FREE USE OF
* THIS SOFTWARE IN ITS "AS IS" CONDITION, AND DISCLAIM 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: vm/memory_object.c
* Author: Michael Wayne Young
*
* External memory management interface control functions.
*/
/*
* Interface dependencies:
*/
#include <mach/std_types.h> /* For pointer_t */
#include <mach/mach_types.h>
#include <mach/kern_return.h>
#include <vm/vm_object.h>
#include <mach/memory_object.h>
#include <mach/boolean.h>
#include <mach/vm_prot.h>
#include <mach/message.h>
#include "memory_object_user.h"
#include "memory_object_default.h"
/*
* Implementation dependencies:
*/
#include <vm/memory_object.h>
#include <vm/vm_page.h>
#include <vm/vm_pageout.h>
#include <vm/pmap.h> /* For copy_to_phys, pmap_clear_modify */
#include <kern/thread.h> /* For current_thread() */
#include <kern/host.h>
#include <vm/vm_kern.h> /* For kernel_map, vm_move */
#include <vm/vm_map.h> /* For vm_map_pageable */
#include <ipc/ipc_port.h>
#include <mach_pagemap.h>
#if MACH_PAGEMAP
#include <vm/vm_external.h>
#endif /* MACH_PAGEMAP */
typedef int memory_object_lock_result_t; /* moved from below */
ipc_port_t memory_manager_default = IP_NULL;
decl_simple_lock_data(,memory_manager_default_lock)
/*
* Important note:
* All of these routines gain a reference to the
* object (first argument) as part of the automatic
* argument conversion. Explicit deallocation is necessary.
*/
/*
* If successful, destroys the map copy object.
*/
kern_return_t memory_object_data_provided(object, offset, data, data_cnt,
lock_value)
vm_object_t object;
vm_offset_t offset;
pointer_t data;
unsigned int data_cnt;
vm_prot_t lock_value;
{
return memory_object_data_supply(object, offset, (vm_map_copy_t) data,
data_cnt, lock_value, FALSE, IP_NULL,
0);
}
kern_return_t memory_object_data_supply(object, offset, data_copy, data_cnt,
lock_value, precious, reply_to, reply_to_type)
register
vm_object_t object;
register
vm_offset_t offset;
vm_map_copy_t data_copy;
unsigned int data_cnt;
vm_prot_t lock_value;
boolean_t precious;
ipc_port_t reply_to;
mach_msg_type_name_t reply_to_type;
{
kern_return_t result = KERN_SUCCESS;
vm_offset_t error_offset = 0;
register
vm_page_t m;
register
vm_page_t data_m;
vm_size_t original_length;
vm_offset_t original_offset;
vm_page_t *page_list;
boolean_t was_absent;
vm_map_copy_t orig_copy = data_copy;
/*
* Look for bogus arguments
*/
if (object == VM_OBJECT_NULL) {
return(KERN_INVALID_ARGUMENT);
}
if (lock_value & ~VM_PROT_ALL) {
vm_object_deallocate(object);
return(KERN_INVALID_ARGUMENT);
}
if ((data_cnt % PAGE_SIZE) != 0) {
vm_object_deallocate(object);
return(KERN_INVALID_ARGUMENT);
}
/*
* Adjust the offset from the memory object to the offset
* within the vm_object.
*/
original_length = data_cnt;
original_offset = offset;
assert(data_copy->type == VM_MAP_COPY_PAGE_LIST);
page_list = &data_copy->cpy_page_list[0];
vm_object_lock(object);
vm_object_paging_begin(object);
offset -= object->paging_offset;
/*
* Loop over copy stealing pages for pagein.
*/
for (; data_cnt > 0 ; data_cnt -= PAGE_SIZE, offset += PAGE_SIZE) {
assert(data_copy->cpy_npages > 0);
data_m = *page_list;
if (data_m == VM_PAGE_NULL || data_m->tabled ||
data_m->error || data_m->absent || data_m->fictitious) {
panic("Data_supply: bad page");
}
/*
* Look up target page and check its state.
*/
retry_lookup:
m = vm_page_lookup(object,offset);
if (m == VM_PAGE_NULL) {
was_absent = FALSE;
}
else {
if (m->absent && m->busy) {
/*
* Page was requested. Free the busy
* page waiting for it. Insertion
* of new page happens below.
*/
VM_PAGE_FREE(m);
was_absent = TRUE;
}
else {
/*
* Have to wait for page that is busy and
* not absent. This is probably going to
* be an error, but go back and check.
*/
if (m->busy) {
PAGE_ASSERT_WAIT(m, FALSE);
vm_object_unlock(object);
thread_block((void (*)()) 0);
vm_object_lock(object);
goto retry_lookup;
}
/*
* Page already present; error.
* This is an error if data is precious.
*/
result = KERN_MEMORY_PRESENT;
error_offset = offset + object->paging_offset;
break;
}
}
/*
* Ok to pagein page. Target object now has no page
* at offset. Set the page parameters, then drop
* in new page and set up pageout state. Object is
* still locked here.
*
* Must clear busy bit in page before inserting it.
* Ok to skip wakeup logic because nobody else
* can possibly know about this page.
*/
data_m->busy = FALSE;
data_m->dirty = FALSE;
pmap_clear_modify(data_m->phys_addr);
data_m->page_lock = lock_value;
data_m->unlock_request = VM_PROT_NONE;
data_m->precious = precious;
vm_page_lock_queues();
vm_page_insert(data_m, object, offset);
if (was_absent)
vm_page_activate(data_m);
else
vm_page_deactivate(data_m);
vm_page_unlock_queues();
/*
* Null out this page list entry, and advance to next
* page.
*/
*page_list++ = VM_PAGE_NULL;
if (--(data_copy->cpy_npages) == 0 &&
vm_map_copy_has_cont(data_copy)) {
vm_map_copy_t new_copy;
vm_object_unlock(object);
vm_map_copy_invoke_cont(data_copy, &new_copy, &result);
if (result == KERN_SUCCESS) {
/*
* Consume on success requires that
* we keep the original vm_map_copy
* around in case something fails.
* Free the old copy if it's not the original
*/
if (data_copy != orig_copy) {
vm_map_copy_discard(data_copy);
}
if ((data_copy = new_copy) != VM_MAP_COPY_NULL)
page_list = &data_copy->cpy_page_list[0];
vm_object_lock(object);
}
else {
vm_object_lock(object);
error_offset = offset + object->paging_offset +
PAGE_SIZE;
break;
}
}
}
/*
* Send reply if one was requested.
*/
vm_object_paging_end(object);
vm_object_unlock(object);
if (vm_map_copy_has_cont(data_copy))
vm_map_copy_abort_cont(data_copy);
if (IP_VALID(reply_to)) {
memory_object_supply_completed(
reply_to, reply_to_type,
object->pager_request,
original_offset,
original_length,
result,
error_offset);
}
vm_object_deallocate(object);
/*
* Consume on success: The final data copy must be
* be discarded if it is not the original. The original
* gets discarded only if this routine succeeds.
*/
if (data_copy != orig_copy)
vm_map_copy_discard(data_copy);
if (result == KERN_SUCCESS)
vm_map_copy_discard(orig_copy);
return(result);
}
kern_return_t memory_object_data_error(object, offset, size, error_value)
vm_object_t object;
vm_offset_t offset;
vm_size_t size;
kern_return_t error_value;
{
if (object == VM_OBJECT_NULL)
return(KERN_INVALID_ARGUMENT);
if (size != round_page(size))
return(KERN_INVALID_ARGUMENT);
#ifdef lint
/* Error value is ignored at this time */
error_value++;
#endif
vm_object_lock(object);
offset -= object->paging_offset;
while (size != 0) {
register vm_page_t m;
m = vm_page_lookup(object, offset);
if ((m != VM_PAGE_NULL) && m->busy && m->absent) {
m->error = TRUE;
m->absent = FALSE;
vm_object_absent_release(object);
PAGE_WAKEUP_DONE(m);
vm_page_lock_queues();
vm_page_activate(m);
vm_page_unlock_queues();
}
size -= PAGE_SIZE;
offset += PAGE_SIZE;
}
vm_object_unlock(object);
vm_object_deallocate(object);
return(KERN_SUCCESS);
}
kern_return_t memory_object_data_unavailable(object, offset, size)
vm_object_t object;
vm_offset_t offset;
vm_size_t size;
{
#if MACH_PAGEMAP
vm_external_t existence_info = VM_EXTERNAL_NULL;
#endif /* MACH_PAGEMAP */
if (object == VM_OBJECT_NULL)
return(KERN_INVALID_ARGUMENT);
if (size != round_page(size))
return(KERN_INVALID_ARGUMENT);
#if MACH_PAGEMAP
if ((offset == 0) && (size > VM_EXTERNAL_LARGE_SIZE) &&
(object->existence_info == VM_EXTERNAL_NULL)) {
existence_info = vm_external_create(VM_EXTERNAL_SMALL_SIZE);
}
#endif /* MACH_PAGEMAP */
vm_object_lock(object);
#if MACH_PAGEMAP
if (existence_info != VM_EXTERNAL_NULL) {
object->existence_info = existence_info;
}
if ((offset == 0) && (size > VM_EXTERNAL_LARGE_SIZE)) {
vm_object_unlock(object);
vm_object_deallocate(object);
return(KERN_SUCCESS);
}
#endif /* MACH_PAGEMAP */
offset -= object->paging_offset;
while (size != 0) {
register vm_page_t m;
/*
* We're looking for pages that are both busy and
* absent (waiting to be filled), converting them
* to just absent.
*
* Pages that are just busy can be ignored entirely.
*/
m = vm_page_lookup(object, offset);
if ((m != VM_PAGE_NULL) && m->busy && m->absent) {
PAGE_WAKEUP_DONE(m);
vm_page_lock_queues();
vm_page_activate(m);
vm_page_unlock_queues();
}
size -= PAGE_SIZE;
offset += PAGE_SIZE;
}
vm_object_unlock(object);
vm_object_deallocate(object);
return(KERN_SUCCESS);
}
/*
* Routine: memory_object_lock_page
*
* Description:
* Perform the appropriate lock operations on the
* given page. See the description of
* "memory_object_lock_request" for the meanings
* of the arguments.
*
* Returns an indication that the operation
* completed, blocked, or that the page must
* be cleaned.
*/
#define MEMORY_OBJECT_LOCK_RESULT_DONE 0
#define MEMORY_OBJECT_LOCK_RESULT_MUST_BLOCK 1
#define MEMORY_OBJECT_LOCK_RESULT_MUST_CLEAN 2
#define MEMORY_OBJECT_LOCK_RESULT_MUST_RETURN 3
memory_object_lock_result_t memory_object_lock_page(m, should_return,
should_flush, prot)
vm_page_t m;
memory_object_return_t should_return;
boolean_t should_flush;
vm_prot_t prot;
{
/*
* Don't worry about pages for which the kernel
* does not have any data.
*/
if (m->absent)
return(MEMORY_OBJECT_LOCK_RESULT_DONE);
/*
* If we cannot change access to the page,
* either because a mapping is in progress
* (busy page) or because a mapping has been
* wired, then give up.
*/
if (m->busy)
return(MEMORY_OBJECT_LOCK_RESULT_MUST_BLOCK);
assert(!m->fictitious);
if (m->wire_count != 0) {
/*
* If no change would take place
* anyway, return successfully.
*
* No change means:
* Not flushing AND
* No change to page lock [2 checks] AND
* Don't need to send page to manager
*
* Don't need to send page to manager means:
* No clean or return request OR (
* Page is not dirty [2 checks] AND (
* Page is not precious OR
* No request to return precious pages ))
*
* Now isn't that straightforward and obvious ?? ;-)
*
* XXX This doesn't handle sending a copy of a wired
* XXX page to the pager, but that will require some
* XXX significant surgery.
*/
if (!should_flush &&
((m->page_lock == prot) || (prot == VM_PROT_NO_CHANGE)) &&
((should_return == MEMORY_OBJECT_RETURN_NONE) ||
(!m->dirty && !pmap_is_modified(m->phys_addr) &&
(!m->precious ||
should_return != MEMORY_OBJECT_RETURN_ALL)))) {
/*
* Restart page unlock requests,
* even though no change took place.
* [Memory managers may be expecting
* to see new requests.]
*/
m->unlock_request = VM_PROT_NONE;
PAGE_WAKEUP(m);
return(MEMORY_OBJECT_LOCK_RESULT_DONE);
}
return(MEMORY_OBJECT_LOCK_RESULT_MUST_BLOCK);
}
/*
* If the page is to be flushed, allow
* that to be done as part of the protection.
*/
if (should_flush)
prot = VM_PROT_ALL;
/*
* Set the page lock.
*
* If we are decreasing permission, do it now;
* let the fault handler take care of increases
* (pmap_page_protect may not increase protection).
*/
if (prot != VM_PROT_NO_CHANGE) {
if ((m->page_lock ^ prot) & prot) {
pmap_page_protect(m->phys_addr, VM_PROT_ALL & ~prot);
}
m->page_lock = prot;
/*
* Restart any past unlock requests, even if no
* change resulted. If the manager explicitly
* requested no protection change, then it is assumed
* to be remembering past requests.
*/
m->unlock_request = VM_PROT_NONE;
PAGE_WAKEUP(m);
}
/*
* Handle cleaning.
*/
if (should_return != MEMORY_OBJECT_RETURN_NONE) {
/*
* Check whether the page is dirty. If
* write permission has not been removed,
* this may have unpredictable results.
*/
if (!m->dirty)
m->dirty = pmap_is_modified(m->phys_addr);
if (m->dirty || (m->precious &&
should_return == MEMORY_OBJECT_RETURN_ALL)) {
/*
* If we weren't planning
* to flush the page anyway,
* we may need to remove the
* page from the pageout
* system and from physical
* maps now.
*/
vm_page_lock_queues();
VM_PAGE_QUEUES_REMOVE(m);
vm_page_unlock_queues();
if (!should_flush)
pmap_page_protect(m->phys_addr,
VM_PROT_NONE);
/*
* Cleaning a page will cause
* it to be flushed.
*/
if (m->dirty)
return(MEMORY_OBJECT_LOCK_RESULT_MUST_CLEAN);
else
return(MEMORY_OBJECT_LOCK_RESULT_MUST_RETURN);
}
}
/*
* Handle flushing
*/
if (should_flush) {
VM_PAGE_FREE(m);
} else {
extern boolean_t vm_page_deactivate_hint;
/*
* XXX Make clean but not flush a paging hint,
* and deactivate the pages. This is a hack
* because it overloads flush/clean with
* implementation-dependent meaning. This only
* happens to pages that are already clean.
*/
if (vm_page_deactivate_hint &&
(should_return != MEMORY_OBJECT_RETURN_NONE)) {
vm_page_lock_queues();
vm_page_deactivate(m);
vm_page_unlock_queues();
}
}
return(MEMORY_OBJECT_LOCK_RESULT_DONE);
}
/*
* Routine: memory_object_lock_request [user interface]
*
* Description:
* Control use of the data associated with the given
* memory object. For each page in the given range,
* perform the following operations, in order:
* 1) restrict access to the page (disallow
* forms specified by "prot");
* 2) return data to the manager (if "should_return"
* is RETURN_DIRTY and the page is dirty, or
* "should_return" is RETURN_ALL and the page
* is either dirty or precious); and,
* 3) flush the cached copy (if "should_flush"
* is asserted).
* The set of pages is defined by a starting offset
* ("offset") and size ("size"). Only pages with the
* same page alignment as the starting offset are
* considered.
*
* A single acknowledgement is sent (to the "reply_to"
* port) when these actions are complete. If successful,
* the naked send right for reply_to is consumed.
*/
kern_return_t
memory_object_lock_request(object, offset, size,
should_return, should_flush, prot,
reply_to, reply_to_type)
register vm_object_t object;
register vm_offset_t offset;
register vm_size_t size;
memory_object_return_t should_return;
boolean_t should_flush;
vm_prot_t prot;
ipc_port_t reply_to;
mach_msg_type_name_t reply_to_type;
{
register vm_page_t m;
vm_offset_t original_offset = offset;
vm_size_t original_size = size;
vm_offset_t paging_offset = 0;
vm_object_t new_object = VM_OBJECT_NULL;
vm_offset_t new_offset = 0;
vm_offset_t last_offset = offset;
int page_lock_result;
int pageout_action = 0; /* '=0' to quiet lint */
#define DATA_WRITE_MAX 32
vm_page_t holding_pages[DATA_WRITE_MAX];
/*
* Check for bogus arguments.
*/
if (object == VM_OBJECT_NULL ||
((prot & ~VM_PROT_ALL) != 0 && prot != VM_PROT_NO_CHANGE))
return (KERN_INVALID_ARGUMENT);
size = round_page(size);
/*
* Lock the object, and acquire a paging reference to
* prevent the memory_object and control ports from
* being destroyed.
*/
vm_object_lock(object);
vm_object_paging_begin(object);
offset -= object->paging_offset;
/*
* To avoid blocking while scanning for pages, save
* dirty pages to be cleaned all at once.
*
* XXXO A similar strategy could be used to limit the
* number of times that a scan must be restarted for
* other reasons. Those pages that would require blocking
* could be temporarily collected in another list, or
* their offsets could be recorded in a small array.
*/
/*
* XXX NOTE: May want to consider converting this to a page list
* XXX vm_map_copy interface. Need to understand object
* XXX coalescing implications before doing so.
*/
#define PAGEOUT_PAGES \
MACRO_BEGIN \
vm_map_copy_t copy; \
register int i; \
register vm_page_t hp; \
\
vm_object_unlock(object); \
\
(void) vm_map_copyin_object(new_object, 0, new_offset, ©); \
\
if (object->use_old_pageout) { \
assert(pageout_action == MEMORY_OBJECT_LOCK_RESULT_MUST_CLEAN); \
(void) memory_object_data_write( \
object->pager, \
object->pager_request, \
paging_offset, \
(pointer_t) copy, \
new_offset); \
} \
else { \
(void) memory_object_data_return( \
object->pager, \
object->pager_request, \
paging_offset, \
(pointer_t) copy, \
new_offset, \
(pageout_action == MEMORY_OBJECT_LOCK_RESULT_MUST_CLEAN), \
!should_flush); \
} \
\
vm_object_lock(object); \
\
for (i = 0; i < atop(new_offset); i++) { \
hp = holding_pages[i]; \
if (hp != VM_PAGE_NULL) \
VM_PAGE_FREE(hp); \
} \
\
new_object = VM_OBJECT_NULL; \
MACRO_END
for (;
size != 0;
size -= PAGE_SIZE, offset += PAGE_SIZE)
{
/*
* Limit the number of pages to be cleaned at once.
*/
if (new_object != VM_OBJECT_NULL &&
new_offset >= PAGE_SIZE * DATA_WRITE_MAX)
{
PAGEOUT_PAGES;
}
while ((m = vm_page_lookup(object, offset)) != VM_PAGE_NULL) {
switch ((page_lock_result = memory_object_lock_page(m,
should_return,
should_flush,
prot)))
{
case MEMORY_OBJECT_LOCK_RESULT_DONE:
/*
* End of a cluster of dirty pages.
*/
if (new_object != VM_OBJECT_NULL) {
PAGEOUT_PAGES;
continue;
}
break;
case MEMORY_OBJECT_LOCK_RESULT_MUST_BLOCK:
/*
* Since it is necessary to block,
* clean any dirty pages now.
*/
if (new_object != VM_OBJECT_NULL) {
PAGEOUT_PAGES;
continue;
}
PAGE_ASSERT_WAIT(m, FALSE);
vm_object_unlock(object);
thread_block((void (*)()) 0);
vm_object_lock(object);
continue;
case MEMORY_OBJECT_LOCK_RESULT_MUST_CLEAN:
case MEMORY_OBJECT_LOCK_RESULT_MUST_RETURN:
/*
* The clean and return cases are similar.
*
* Mark the page busy since we unlock the
* object below.
*/
m->busy = TRUE;
/*
* if this would form a discontiguous block,
* clean the old pages and start anew.
*
* NOTE: The first time through here, new_object
* is null, hiding the fact that pageout_action
* is not initialized.
*/
if (new_object != VM_OBJECT_NULL &&
(last_offset != offset ||
pageout_action != page_lock_result)) {
PAGEOUT_PAGES;
}
vm_object_unlock(object);
/*
* If we have not already allocated an object
* for a range of pages to be written, do so
* now.
*/
if (new_object == VM_OBJECT_NULL) {
new_object = vm_object_allocate(original_size);
new_offset = 0;
paging_offset = m->offset +
object->paging_offset;
pageout_action = page_lock_result;
}
/*
* Move or copy the dirty page into the
* new object.
*/
m = vm_pageout_setup(m,
m->offset + object->paging_offset,
new_object,
new_offset,
should_flush);
/*
* Save the holding page if there is one.
*/
holding_pages[atop(new_offset)] = m;
new_offset += PAGE_SIZE;
last_offset = offset + PAGE_SIZE;
vm_object_lock(object);
break;
}
break;
}
}
/*
* We have completed the scan for applicable pages.
* Clean any pages that have been saved.
*/
if (new_object != VM_OBJECT_NULL) {
PAGEOUT_PAGES;
}
if (IP_VALID(reply_to)) {
vm_object_unlock(object);
/* consumes our naked send-once/send right for reply_to */
(void) memory_object_lock_completed(reply_to, reply_to_type,
object->pager_request, original_offset, original_size);
vm_object_lock(object);
}
vm_object_paging_end(object);
vm_object_unlock(object);
vm_object_deallocate(object);
return (KERN_SUCCESS);
}
/*
* Old version of memory_object_lock_request.
*/
kern_return_t
xxx_memory_object_lock_request(object, offset, size,
should_clean, should_flush, prot,
reply_to, reply_to_type)
register vm_object_t object;
register vm_offset_t offset;
register vm_size_t size;
boolean_t should_clean;
boolean_t should_flush;
vm_prot_t prot;
ipc_port_t reply_to;
mach_msg_type_name_t reply_to_type;
{
register int should_return;
if (should_clean)
should_return = MEMORY_OBJECT_RETURN_DIRTY;
else
should_return = MEMORY_OBJECT_RETURN_NONE;
return(memory_object_lock_request(object,offset,size,
should_return, should_flush, prot,
reply_to, reply_to_type));
}
kern_return_t
memory_object_set_attributes_common(object, object_ready, may_cache,
copy_strategy, use_old_pageout)
vm_object_t object;
boolean_t object_ready;
boolean_t may_cache;
memory_object_copy_strategy_t copy_strategy;
boolean_t use_old_pageout;
{
if (object == VM_OBJECT_NULL)
return(KERN_INVALID_ARGUMENT);
/*
* Verify the attributes of importance
*/
switch(copy_strategy) {
case MEMORY_OBJECT_COPY_NONE:
case MEMORY_OBJECT_COPY_CALL:
case MEMORY_OBJECT_COPY_DELAY:
case MEMORY_OBJECT_COPY_TEMPORARY:
break;
default:
vm_object_deallocate(object);
return(KERN_INVALID_ARGUMENT);
}
if (object_ready)
object_ready = TRUE;
if (may_cache)
may_cache = TRUE;
vm_object_lock(object);
/*
* Wake up anyone waiting for the ready attribute
* to become asserted.
*/
if (object_ready && !object->pager_ready) {
object->use_old_pageout = use_old_pageout;
vm_object_wakeup(object, VM_OBJECT_EVENT_PAGER_READY);
}
/*
* Copy the attributes
*/
object->can_persist = may_cache;
object->pager_ready = object_ready;
if (copy_strategy == MEMORY_OBJECT_COPY_TEMPORARY) {
object->temporary = TRUE;
} else {
object->copy_strategy = copy_strategy;
}
vm_object_unlock(object);
vm_object_deallocate(object);
return(KERN_SUCCESS);
}
/*
* XXX rpd claims that reply_to could be obviated in favor of a client
* XXX stub that made change_attributes an RPC. Need investigation.
*/
kern_return_t memory_object_change_attributes(object, may_cache,
copy_strategy, reply_to, reply_to_type)
vm_object_t object;
boolean_t may_cache;
memory_object_copy_strategy_t copy_strategy;
ipc_port_t reply_to;
mach_msg_type_name_t reply_to_type;
{
kern_return_t result;
/*
* Do the work and throw away our object reference. It
* is important that the object reference be deallocated
* BEFORE sending the reply. The whole point of the reply
* is that it shows up after the terminate message that
* may be generated by setting the object uncacheable.
*
* XXX may_cache may become a tri-valued variable to handle
* XXX uncache if not in use.
*/
result = memory_object_set_attributes_common(object, TRUE,
may_cache, copy_strategy,
FALSE);
if (IP_VALID(reply_to)) {
/* consumes our naked send-once/send right for reply_to */
(void) memory_object_change_completed(reply_to, reply_to_type,
may_cache, copy_strategy);
}
return(result);
}
kern_return_t
memory_object_set_attributes(object, object_ready, may_cache, copy_strategy)
vm_object_t object;
boolean_t object_ready;
boolean_t may_cache;
memory_object_copy_strategy_t copy_strategy;
{
return memory_object_set_attributes_common(object, object_ready,
may_cache, copy_strategy,
TRUE);
}
kern_return_t memory_object_ready(object, may_cache, copy_strategy)
vm_object_t object;
boolean_t may_cache;
memory_object_copy_strategy_t copy_strategy;
{
return memory_object_set_attributes_common(object, TRUE,
may_cache, copy_strategy,
FALSE);
}
kern_return_t memory_object_get_attributes(object, object_ready,
may_cache, copy_strategy)
vm_object_t object;
boolean_t *object_ready;
boolean_t *may_cache;
memory_object_copy_strategy_t *copy_strategy;
{
if (object == VM_OBJECT_NULL)
return(KERN_INVALID_ARGUMENT);
vm_object_lock(object);
*may_cache = object->can_persist;
*object_ready = object->pager_ready;
*copy_strategy = object->copy_strategy;
vm_object_unlock(object);
vm_object_deallocate(object);
return(KERN_SUCCESS);
}
/*
* If successful, consumes the supplied naked send right.
*/
kern_return_t vm_set_default_memory_manager(host, default_manager)
host_t host;
ipc_port_t *default_manager;
{
ipc_port_t current_manager;
ipc_port_t new_manager;
ipc_port_t returned_manager;
if (host == HOST_NULL)
return(KERN_INVALID_HOST);
new_manager = *default_manager;
simple_lock(&memory_manager_default_lock);
current_manager = memory_manager_default;
if (new_manager == IP_NULL) {
/*
* Retrieve the current value.
*/
returned_manager = ipc_port_copy_send(current_manager);
} else {
/*
* Retrieve the current value,
* and replace it with the supplied value.
* We consume the supplied naked send right.
*/
returned_manager = current_manager;
memory_manager_default = new_manager;
/*
* In case anyone's been waiting for a memory
* manager to be established, wake them up.
*/
thread_wakeup((event_t) &memory_manager_default);
}
simple_unlock(&memory_manager_default_lock);
*default_manager = returned_manager;
return(KERN_SUCCESS);
}
/*
* Routine: memory_manager_default_reference
* Purpose:
* Returns a naked send right for the default
* memory manager. The returned right is always
* valid (not IP_NULL or IP_DEAD).
*/
ipc_port_t memory_manager_default_reference()
{
ipc_port_t current_manager;
simple_lock(&memory_manager_default_lock);
while (current_manager = ipc_port_copy_send(memory_manager_default),
!IP_VALID(current_manager)) {
thread_sleep((event_t) &memory_manager_default,
simple_lock_addr(memory_manager_default_lock),
FALSE);
simple_lock(&memory_manager_default_lock);
}
simple_unlock(&memory_manager_default_lock);
return current_manager;
}
/*
* Routine: memory_manager_default_port
* Purpose:
* Returns true if the receiver for the port
* is the default memory manager.
*
* This is a hack to let ds_read_done
* know when it should keep memory wired.
*/
boolean_t memory_manager_default_port(port)
ipc_port_t port;
{
ipc_port_t current;
boolean_t result;
simple_lock(&memory_manager_default_lock);
current = memory_manager_default;
if (IP_VALID(current)) {
/*
* There is no point in bothering to lock
* both ports, which would be painful to do.
* If the receive rights are moving around,
* we might be inaccurate.
*/
result = port->ip_receiver == current->ip_receiver;
} else
result = FALSE;
simple_unlock(&memory_manager_default_lock);
return result;
}
void memory_manager_default_init()
{
memory_manager_default = IP_NULL;
simple_lock_init(&memory_manager_default_lock);
}
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