*/
#include "vm_compressor_backing_store.h"
+#include <vm/vm_pageout.h>
#include <vm/vm_protos.h>
#include <IOKit/IOHibernatePrivate.h>
+#include <kern/policy_internal.h>
boolean_t compressor_store_stop_compaction = FALSE;
-boolean_t vm_swap_up = FALSE;
boolean_t vm_swapfile_create_needed = FALSE;
boolean_t vm_swapfile_gc_needed = FALSE;
-int swapper_throttle = -1;
-boolean_t swapper_throttle_inited = FALSE;
+int vm_swapper_throttle = -1;
uint64_t vm_swapout_thread_id;
uint64_t vm_swap_put_failures = 0;
uint64_t vm_swap_get_failures = 0;
+int vm_num_swap_files_config = 0;
int vm_num_swap_files = 0;
+int vm_num_pinned_swap_files = 0;
int vm_swapout_thread_processed_segments = 0;
int vm_swapout_thread_awakened = 0;
int vm_swapfile_create_thread_awakened = 0;
int vm_swapfile_gc_thread_awakened = 0;
int vm_swapfile_gc_thread_running = 0;
+int64_t vm_swappin_avail = 0;
+boolean_t vm_swappin_enabled = FALSE;
unsigned int vm_swapfile_total_segs_alloced = 0;
unsigned int vm_swapfile_total_segs_used = 0;
+char swapfilename[MAX_SWAPFILENAME_LEN + 1] = SWAP_FILE_NAME;
+
+extern vm_map_t compressor_map;
+
#define SWAP_READY 0x1 /* Swap file is ready to be used */
#define SWAP_RECLAIM 0x2 /* Swap file is marked to be reclaimed */
#define SWAP_WANTED 0x4 /* Swap file has waiters */
#define SWAP_REUSE 0x8 /* Swap file is on the Q and has a name. Reuse after init-ing.*/
+#define SWAP_PINNED 0x10 /* Swap file is pinned (FusionDrive) */
+
struct swapfile{
queue_head_t swp_queue; /* list of swap files */
queue_head_t swf_global_queue;
boolean_t swp_trim_supported = FALSE;
-#define VM_SWAPFILE_DELAYED_TRIM_MAX 128
-
extern clock_sec_t dont_trim_until_ts;
clock_sec_t vm_swapfile_last_failed_to_create_ts = 0;
clock_sec_t vm_swapfile_last_successful_create_ts = 0;
int vm_swapfile_can_be_created = FALSE;
boolean_t delayed_trim_handling_in_progress = FALSE;
+boolean_t hibernate_in_progress_with_pinned_swap = FALSE;
+
static void vm_swapout_thread_throttle_adjust(void);
static void vm_swap_free_now(struct swapfile *swf, uint64_t f_offset);
static void vm_swapout_thread(void);
static void vm_swapfile_create_thread(void);
static void vm_swapfile_gc_thread(void);
-static void vm_swap_defragment();
+static void vm_swap_defragment(void);
static void vm_swap_handle_delayed_trims(boolean_t);
-static void vm_swap_do_delayed_trim();
+static void vm_swap_do_delayed_trim(struct swapfile *);
static void vm_swap_wait_on_trim_handling_in_progress(void);
+boolean_t vm_swap_force_defrag = FALSE, vm_swap_force_reclaim = FALSE;
+
+#if CONFIG_EMBEDDED
+
+#if DEVELOPMENT || DEBUG
+#define VM_MAX_SWAP_FILE_NUM 100
+#else /* DEVELOPMENT || DEBUG */
+#define VM_MAX_SWAP_FILE_NUM 5
+#endif /* DEVELOPMENT || DEBUG */
+
+#define VM_SWAPFILE_DELAYED_TRIM_MAX 4
-#define VM_SWAP_SHOULD_DEFRAGMENT() (c_swappedout_sparse_count > (vm_swapfile_total_segs_used / 4) ? 1 : 0)
-#define VM_SWAP_SHOULD_RECLAIM() (((vm_swapfile_total_segs_alloced - vm_swapfile_total_segs_used) >= SWAPFILE_RECLAIM_THRESHOLD_SEGS) ? 1 : 0)
-#define VM_SWAP_SHOULD_ABORT_RECLAIM() (((vm_swapfile_total_segs_alloced - vm_swapfile_total_segs_used) <= SWAPFILE_RECLAIM_MINIMUM_SEGS) ? 1 : 0)
-#define VM_SWAP_SHOULD_CREATE(cur_ts) (((vm_swapfile_total_segs_alloced - vm_swapfile_total_segs_used) < (unsigned int)VM_SWAPFILE_HIWATER_SEGS) && \
+#define VM_SWAP_SHOULD_DEFRAGMENT() (((vm_swap_force_defrag == TRUE) || (c_swappedout_sparse_count > (vm_swapfile_total_segs_used / 16))) ? 1 : 0)
+#define VM_SWAP_SHOULD_PIN(_size) FALSE
+#define VM_SWAP_SHOULD_CREATE(cur_ts) ((vm_num_swap_files < vm_num_swap_files_config) && ((vm_swapfile_total_segs_alloced - vm_swapfile_total_segs_used) < (unsigned int)VM_SWAPFILE_HIWATER_SEGS) && \
((cur_ts - vm_swapfile_last_failed_to_create_ts) > VM_SWAPFILE_DELAYED_CREATE) ? 1 : 0)
#define VM_SWAP_SHOULD_TRIM(swf) ((swf->swp_delayed_trim_count >= VM_SWAPFILE_DELAYED_TRIM_MAX) ? 1 : 0)
+#else /* CONFIG_EMBEDDED */
+#define VM_MAX_SWAP_FILE_NUM 100
+#define VM_SWAPFILE_DELAYED_TRIM_MAX 128
+
+#define VM_SWAP_SHOULD_DEFRAGMENT() (((vm_swap_force_defrag == TRUE) || (c_swappedout_sparse_count > (vm_swapfile_total_segs_used / 4))) ? 1 : 0)
+#define VM_SWAP_SHOULD_PIN(_size) (vm_swappin_avail > 0 && vm_swappin_avail >= (int64_t)(_size))
+#define VM_SWAP_SHOULD_CREATE(cur_ts) ((vm_num_swap_files < vm_num_swap_files_config) && ((vm_swapfile_total_segs_alloced - vm_swapfile_total_segs_used) < (unsigned int)VM_SWAPFILE_HIWATER_SEGS) && \
+ ((cur_ts - vm_swapfile_last_failed_to_create_ts) > VM_SWAPFILE_DELAYED_CREATE) ? 1 : 0)
+#define VM_SWAP_SHOULD_TRIM(swf) ((swf->swp_delayed_trim_count >= VM_SWAPFILE_DELAYED_TRIM_MAX) ? 1 : 0)
+
+#endif /* CONFIG_EMBEDDED */
+
+#define VM_SWAP_SHOULD_RECLAIM() (((vm_swap_force_reclaim == TRUE) || ((vm_swapfile_total_segs_alloced - vm_swapfile_total_segs_used) >= SWAPFILE_RECLAIM_THRESHOLD_SEGS)) ? 1 : 0)
+#define VM_SWAP_SHOULD_ABORT_RECLAIM() (((vm_swap_force_reclaim == FALSE) && ((vm_swapfile_total_segs_alloced - vm_swapfile_total_segs_used) <= SWAPFILE_RECLAIM_MINIMUM_SEGS)) ? 1 : 0)
#define VM_SWAPFILE_DELAYED_CREATE 15
-#define VM_SWAP_BUSY() ((c_swapout_count && (swapper_throttle == THROTTLE_LEVEL_COMPRESSOR_TIER1 || swapper_throttle == THROTTLE_LEVEL_COMPRESSOR_TIER0)) ? 1 : 0)
+#define VM_SWAP_BUSY() ((c_swapout_count && (vm_swapper_throttle == THROTTLE_LEVEL_COMPRESSOR_TIER0)) ? 1 : 0)
#if CHECKSUM_THE_SWAP
extern unsigned int hash_string(char *cp, int len);
#endif
-#if ENCRYPTED_SWAP
-extern boolean_t swap_crypt_ctx_initialized;
-extern void swap_crypt_ctx_initialize(void);
-extern const unsigned char swap_crypt_null_iv[AES_BLOCK_SIZE];
-extern aes_ctx swap_crypt_ctx;
-extern unsigned long vm_page_encrypt_counter;
-extern unsigned long vm_page_decrypt_counter;
-#endif /* ENCRYPTED_SWAP */
+#if RECORD_THE_COMPRESSED_DATA
+boolean_t c_compressed_record_init_done = FALSE;
+int c_compressed_record_write_error = 0;
+struct vnode *c_compressed_record_vp = NULL;
+uint64_t c_compressed_record_file_offset = 0;
+void c_compressed_record_init(void);
+void c_compressed_record_write(char *, int);
+#endif
extern void vm_pageout_io_throttle(void);
-extern void vm_pageout_reinit_tuneables(void);
-extern void vm_swap_file_set_tuneables(void);
-struct swapfile *vm_swapfile_for_handle(uint64_t);
+static struct swapfile *vm_swapfile_for_handle(uint64_t);
/*
* Called with the vm_swap_data_lock held.
*/
-struct swapfile *
+static struct swapfile *
vm_swapfile_for_handle(uint64_t f_offset)
{
return swf;
}
+#if ENCRYPTED_SWAP
+
+#include <libkern/crypto/aesxts.h>
+
+extern int cc_rand_generate(void *, size_t); /* from libkern/cyrpto/rand.h> */
+
+boolean_t swap_crypt_initialized;
+void swap_crypt_initialize(void);
+
+symmetric_xts xts_modectx;
+uint32_t swap_crypt_key1[8]; /* big enough for a 256 bit random key */
+uint32_t swap_crypt_key2[8]; /* big enough for a 256 bit random key */
+
+#if DEVELOPMENT || DEBUG
+boolean_t swap_crypt_xts_tested = FALSE;
+unsigned char swap_crypt_test_page_ref[4096] __attribute__((aligned(4096)));
+unsigned char swap_crypt_test_page_encrypt[4096] __attribute__((aligned(4096)));
+unsigned char swap_crypt_test_page_decrypt[4096] __attribute__((aligned(4096)));
+#endif /* DEVELOPMENT || DEBUG */
+
+unsigned long vm_page_encrypt_counter;
+unsigned long vm_page_decrypt_counter;
+
+
+void
+swap_crypt_initialize(void)
+{
+ uint8_t *enckey1, *enckey2;
+ int keylen1, keylen2;
+ int error;
+
+ assert(swap_crypt_initialized == FALSE);
+
+ keylen1 = sizeof(swap_crypt_key1);
+ enckey1 = (uint8_t *)&swap_crypt_key1;
+ keylen2 = sizeof(swap_crypt_key2);
+ enckey2 = (uint8_t *)&swap_crypt_key2;
+
+ error = cc_rand_generate((void *)enckey1, keylen1);
+ assert(!error);
+
+ error = cc_rand_generate((void *)enckey2, keylen2);
+ assert(!error);
+
+ error = xts_start(0, NULL, enckey1, keylen1, enckey2, keylen2, 0, 0, &xts_modectx);
+ assert(!error);
+
+ swap_crypt_initialized = TRUE;
+
+#if DEVELOPMENT || DEBUG
+ uint8_t *encptr;
+ uint8_t *decptr;
+ uint8_t *refptr;
+ uint8_t *iv;
+ uint64_t ivnum[2];
+ int size = 0;
+ int i = 0;
+ int rc = 0;
+
+ assert(swap_crypt_xts_tested == FALSE);
+
+ /*
+ * Validate the encryption algorithms.
+ *
+ * First initialize the test data.
+ */
+ for (i = 0; i < 4096; i++) {
+ swap_crypt_test_page_ref[i] = (char) i;
+ }
+ ivnum[0] = (uint64_t)0xaa;
+ ivnum[1] = 0;
+ iv = (uint8_t *)ivnum;
+
+ refptr = (uint8_t *)swap_crypt_test_page_ref;
+ encptr = (uint8_t *)swap_crypt_test_page_encrypt;
+ decptr = (uint8_t *)swap_crypt_test_page_decrypt;
+ size = 4096;
+
+ /* encrypt */
+ rc = xts_encrypt(refptr, size, encptr, iv, &xts_modectx);
+ assert(!rc);
+
+ /* compare result with original - should NOT match */
+ for (i = 0; i < 4096; i ++) {
+ if (swap_crypt_test_page_encrypt[i] !=
+ swap_crypt_test_page_ref[i]) {
+ break;
+ }
+ }
+ assert(i != 4096);
+
+ /* decrypt */
+ rc = xts_decrypt(encptr, size, decptr, iv, &xts_modectx);
+ assert(!rc);
+
+ /* compare result with original */
+ for (i = 0; i < 4096; i ++) {
+ if (swap_crypt_test_page_decrypt[i] !=
+ swap_crypt_test_page_ref[i]) {
+ panic("encryption test failed");
+ }
+ }
+ /* encrypt in place */
+ rc = xts_encrypt(decptr, size, decptr, iv, &xts_modectx);
+ assert(!rc);
+
+ /* decrypt in place */
+ rc = xts_decrypt(decptr, size, decptr, iv, &xts_modectx);
+ assert(!rc);
+
+ for (i = 0; i < 4096; i ++) {
+ if (swap_crypt_test_page_decrypt[i] !=
+ swap_crypt_test_page_ref[i]) {
+ panic("in place encryption test failed");
+ }
+ }
+ swap_crypt_xts_tested = TRUE;
+#endif /* DEVELOPMENT || DEBUG */
+}
+
+
+void
+vm_swap_encrypt(c_segment_t c_seg)
+{
+ uint8_t *ptr;
+ uint8_t *iv;
+ uint64_t ivnum[2];
+ int size = 0;
+ int rc = 0;
+
+ if (swap_crypt_initialized == FALSE)
+ swap_crypt_initialize();
+
+#if DEVELOPMENT || DEBUG
+ C_SEG_MAKE_WRITEABLE(c_seg);
+#endif
+ ptr = (uint8_t *)c_seg->c_store.c_buffer;
+ size = round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset));
+
+ ivnum[0] = (uint64_t)c_seg;
+ ivnum[1] = 0;
+ iv = (uint8_t *)ivnum;
+
+ rc = xts_encrypt(ptr, size, ptr, iv, &xts_modectx);
+ assert(!rc);
+
+ vm_page_encrypt_counter += (size/PAGE_SIZE_64);
+
+#if DEVELOPMENT || DEBUG
+ C_SEG_WRITE_PROTECT(c_seg);
+#endif
+}
+
+void
+vm_swap_decrypt(c_segment_t c_seg)
+{
+ uint8_t *ptr;
+ uint8_t *iv;
+ uint64_t ivnum[2];
+ int size = 0;
+ int rc = 0;
+
+ assert(swap_crypt_initialized);
+
+#if DEVELOPMENT || DEBUG
+ C_SEG_MAKE_WRITEABLE(c_seg);
+#endif
+ ptr = (uint8_t *)c_seg->c_store.c_buffer;
+ size = round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset));
+
+ ivnum[0] = (uint64_t)c_seg;
+ ivnum[1] = 0;
+ iv = (uint8_t *)ivnum;
+
+ rc = xts_decrypt(ptr, size, ptr, iv, &xts_modectx);
+ assert(!rc);
+
+ vm_page_decrypt_counter += (size/PAGE_SIZE_64);
+
+#if DEVELOPMENT || DEBUG
+ C_SEG_WRITE_PROTECT(c_seg);
+#endif
+}
+#endif /* ENCRYPTED_SWAP */
+
+
void
vm_compressor_swap_init()
{
if (kernel_thread_start_priority((thread_continue_t)vm_swapout_thread, NULL,
- BASEPRI_PREEMPT - 1, &thread) != KERN_SUCCESS) {
+ BASEPRI_VM, &thread) != KERN_SUCCESS) {
panic("vm_swapout_thread: create failed");
}
- thread->options |= TH_OPT_VMPRIV;
+ thread_set_thread_name(thread, "VM_swapout");
vm_swapout_thread_id = thread->thread_id;
thread_deallocate(thread);
if (kernel_thread_start_priority((thread_continue_t)vm_swapfile_create_thread, NULL,
- BASEPRI_PREEMPT - 1, &thread) != KERN_SUCCESS) {
+ BASEPRI_VM, &thread) != KERN_SUCCESS) {
panic("vm_swapfile_create_thread: create failed");
}
- thread->options |= TH_OPT_VMPRIV;
+ thread_set_thread_name(thread, "VM_swapfile_create");
thread_deallocate(thread);
-
if (kernel_thread_start_priority((thread_continue_t)vm_swapfile_gc_thread, NULL,
- BASEPRI_PREEMPT - 1, &thread) != KERN_SUCCESS) {
+ BASEPRI_VM, &thread) != KERN_SUCCESS) {
panic("vm_swapfile_gc_thread: create failed");
}
+ thread_set_thread_name(thread, "VM_swapfile_gc");
thread_deallocate(thread);
- proc_set_task_policy_thread(kernel_task, thread->thread_id,
- TASK_POLICY_INTERNAL, TASK_POLICY_IO, THROTTLE_LEVEL_COMPRESSOR_TIER2);
- proc_set_task_policy_thread(kernel_task, thread->thread_id,
- TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
-
-#if ENCRYPTED_SWAP
- if (swap_crypt_ctx_initialized == FALSE) {
- swap_crypt_ctx_initialize();
- }
-#endif /* ENCRYPTED_SWAP */
-
- memset(swapfilename, 0, MAX_SWAPFILENAME_LEN + 1);
+ proc_set_thread_policy_with_tid(kernel_task, thread->thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_IO, THROTTLE_LEVEL_COMPRESSOR_TIER2);
+ proc_set_thread_policy_with_tid(kernel_task, thread->thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
+
+#if CONFIG_EMBEDDED
+ /*
+ * dummy value until the swap file gets created
+ * when we drive the first c_segment_t to the
+ * swapout queue... at that time we will
+ * know the true size we have to work with
+ */
+ c_overage_swapped_limit = 16;
+#endif
- vm_swap_up = TRUE;
+ vm_num_swap_files_config = VM_MAX_SWAP_FILE_NUM;
- printf("VM Swap Subsystem is %s\n", (vm_swap_up == TRUE) ? "ON" : "OFF");
+ printf("VM Swap Subsystem is ON\n");
}
+#if RECORD_THE_COMPRESSED_DATA
+
void
-vm_swap_file_set_tuneables()
+c_compressed_record_init()
{
- struct vnode *vp;
- char *pathname;
- int namelen;
-
- if (strlen(swapfilename) == 0) {
- /*
- * If no swapfile name has been set, we'll
- * use the default name.
- *
- * Also, this function is only called from the vm_pageout_scan thread
- * via vm_consider_waking_compactor_swapper,
- * so we don't need to worry about a race in checking/setting the name here.
- */
- strlcpy(swapfilename, SWAP_FILE_NAME, MAX_SWAPFILENAME_LEN);
+ if (c_compressed_record_init_done == FALSE) {
+ vm_swapfile_open("/tmp/compressed_data", &c_compressed_record_vp);
+ c_compressed_record_init_done = TRUE;
}
- namelen = (int)strlen(swapfilename) + SWAPFILENAME_INDEX_LEN + 1;
- pathname = (char*)kalloc(namelen);
- memset(pathname, 0, namelen);
- snprintf(pathname, namelen, "%s%d", swapfilename, 0);
-
- vm_swapfile_open(pathname, &vp);
-
- if (vp == NULL)
- goto done;
-
- if (vnode_pager_isSSD(vp) == FALSE)
- vm_pageout_reinit_tuneables();
- vnode_setswapmount(vp);
- vm_swapfile_close((uint64_t)pathname, vp);
-done:
- kfree(pathname, namelen);
}
-
-#if ENCRYPTED_SWAP
void
-vm_swap_encrypt(c_segment_t c_seg)
+c_compressed_record_write(char *buf, int size)
{
- vm_offset_t kernel_vaddr = 0;
- uint64_t size = 0;
-
- union {
- unsigned char aes_iv[AES_BLOCK_SIZE];
- void *c_seg;
- } encrypt_iv;
-
- assert(swap_crypt_ctx_initialized);
-
- bzero(&encrypt_iv.aes_iv[0], sizeof (encrypt_iv.aes_iv));
-
- encrypt_iv.c_seg = (void*)c_seg;
-
- /* encrypt the "initial vector" */
- aes_encrypt_cbc((const unsigned char *) &encrypt_iv.aes_iv[0],
- swap_crypt_null_iv,
- 1,
- &encrypt_iv.aes_iv[0],
- &swap_crypt_ctx.encrypt);
-
- kernel_vaddr = (vm_offset_t) c_seg->c_store.c_buffer;
- size = round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset));
+ if (c_compressed_record_write_error == 0) {
+ c_compressed_record_write_error = vm_record_file_write(c_compressed_record_vp, c_compressed_record_file_offset, buf, size);
+ c_compressed_record_file_offset += size;
+ }
+}
+#endif
- /*
- * Encrypt the c_segment.
- */
- aes_encrypt_cbc((const unsigned char *) kernel_vaddr,
- &encrypt_iv.aes_iv[0],
- (unsigned int)(size / AES_BLOCK_SIZE),
- (unsigned char *) kernel_vaddr,
- &swap_crypt_ctx.encrypt);
- vm_page_encrypt_counter += (size/PAGE_SIZE_64);
-}
+int compaction_swapper_inited = 0;
void
-vm_swap_decrypt(c_segment_t c_seg)
+vm_compaction_swapper_do_init(void)
{
+ struct vnode *vp;
+ char *pathname;
+ int namelen;
- vm_offset_t kernel_vaddr = 0;
- uint64_t size = 0;
+ if (compaction_swapper_inited)
+ return;
- union {
- unsigned char aes_iv[AES_BLOCK_SIZE];
- void *c_seg;
- } decrypt_iv;
-
-
- assert(swap_crypt_ctx_initialized);
+ if (vm_compressor_mode != VM_PAGER_COMPRESSOR_WITH_SWAP) {
+ compaction_swapper_inited = 1;
+ return;
+ }
+ lck_mtx_lock(&vm_swap_data_lock);
- /*
- * Prepare an "initial vector" for the decryption.
- * It has to be the same as the "initial vector" we
- * used to encrypt that page.
- */
- bzero(&decrypt_iv.aes_iv[0], sizeof (decrypt_iv.aes_iv));
+ if ( !compaction_swapper_inited) {
- decrypt_iv.c_seg = (void*)c_seg;
+ namelen = (int)strlen(swapfilename) + SWAPFILENAME_INDEX_LEN + 1;
+ pathname = (char*)kalloc(namelen);
+ memset(pathname, 0, namelen);
+ snprintf(pathname, namelen, "%s%d", swapfilename, 0);
- /* encrypt the "initial vector" */
- aes_encrypt_cbc((const unsigned char *) &decrypt_iv.aes_iv[0],
- swap_crypt_null_iv,
- 1,
- &decrypt_iv.aes_iv[0],
- &swap_crypt_ctx.encrypt);
-
- kernel_vaddr = (vm_offset_t) c_seg->c_store.c_buffer;
- size = round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset));
+ vm_swapfile_open(pathname, &vp);
- /*
- * Decrypt the c_segment.
- */
- aes_decrypt_cbc((const unsigned char *) kernel_vaddr,
- &decrypt_iv.aes_iv[0],
- (unsigned int) (size / AES_BLOCK_SIZE),
- (unsigned char *) kernel_vaddr,
- &swap_crypt_ctx.decrypt);
+ if (vp) {
+
+ if (vnode_pager_isSSD(vp) == FALSE) {
+ /*
+ * swap files live on an HDD, so let's make sure to start swapping
+ * much earlier since we're not worried about SSD write-wear and
+ * we have so little write bandwidth to work with
+ * these values were derived expermentially by running the performance
+ * teams stock test for evaluating HDD performance against various
+ * combinations and looking and comparing overall results.
+ * Note that the > relationship between these 4 values must be maintained
+ */
+ if (vm_compressor_minorcompact_threshold_divisor_overridden == 0)
+ vm_compressor_minorcompact_threshold_divisor = 15;
+ if (vm_compressor_majorcompact_threshold_divisor_overridden == 0)
+ vm_compressor_majorcompact_threshold_divisor = 18;
+ if (vm_compressor_unthrottle_threshold_divisor_overridden == 0)
+ vm_compressor_unthrottle_threshold_divisor = 24;
+ if (vm_compressor_catchup_threshold_divisor_overridden == 0)
+ vm_compressor_catchup_threshold_divisor = 30;
+ }
+#if !CONFIG_EMBEDDED
+ vnode_setswapmount(vp);
+ vm_swappin_avail = vnode_getswappin_avail(vp);
- vm_page_decrypt_counter += (size/PAGE_SIZE_64);
+ if (vm_swappin_avail)
+ vm_swappin_enabled = TRUE;
+#endif
+ vm_swapfile_close((uint64_t)pathname, vp);
+ }
+ kfree(pathname, namelen);
+
+ compaction_swapper_inited = 1;
+ }
+ lck_mtx_unlock(&vm_swap_data_lock);
}
-#endif /* ENCRYPTED_SWAP */
void
-vm_swap_consider_defragmenting()
+vm_swap_consider_defragmenting(int flags)
{
+ boolean_t force_defrag = (flags & VM_SWAP_FLAGS_FORCE_DEFRAG);
+ boolean_t force_reclaim = (flags & VM_SWAP_FLAGS_FORCE_RECLAIM);
+
if (compressor_store_stop_compaction == FALSE && !VM_SWAP_BUSY() &&
- (VM_SWAP_SHOULD_DEFRAGMENT() || VM_SWAP_SHOULD_RECLAIM())) {
+ (force_defrag || force_reclaim || VM_SWAP_SHOULD_DEFRAGMENT() || VM_SWAP_SHOULD_RECLAIM())) {
- if (!vm_swapfile_gc_thread_running) {
+ if (!vm_swapfile_gc_thread_running || force_defrag || force_reclaim) {
lck_mtx_lock(&vm_swap_data_lock);
+ if (force_defrag) {
+ vm_swap_force_defrag = TRUE;
+ }
+
+ if (force_reclaim) {
+ vm_swap_force_reclaim = TRUE;
+ }
+
if (!vm_swapfile_gc_thread_running)
thread_wakeup((event_t) &vm_swapfile_gc_needed);
lck_mtx_lock_spin_always(&c_seg->c_lock);
- assert(c_seg->c_on_swappedout_sparse_q);
+ assert(c_seg->c_state == C_ON_SWAPPEDOUTSPARSE_Q);
if (c_seg->c_busy) {
lck_mtx_unlock_always(c_list_lock);
* c_seg_free_locked consumes the c_list_lock
* and c_seg->c_lock
*/
+ C_SEG_BUSY(c_seg);
c_seg_free_locked(c_seg);
vm_swap_defragment_free++;
} else {
lck_mtx_unlock_always(c_list_lock);
- c_seg_swapin(c_seg, TRUE);
- lck_mtx_unlock_always(&c_seg->c_lock);
+ if (c_seg_swapin(c_seg, TRUE, FALSE) == 0)
+ lck_mtx_unlock_always(&c_seg->c_lock);
vm_swap_defragment_swapin++;
}
clock_sec_t sec;
clock_nsec_t nsec;
+ current_thread()->options |= TH_OPT_VMPRIV;
+
vm_swapfile_create_thread_awakened++;
vm_swapfile_create_thread_running = 1;
lck_mtx_lock(&vm_swap_data_lock);
+ if (hibernate_in_progress_with_pinned_swap == TRUE)
+ break;
+
clock_get_system_nanotime(&sec, &nsec);
if (VM_SWAP_SHOULD_CREATE(sec) == 0)
}
vm_swapfile_create_thread_running = 0;
+ if (hibernate_in_progress_with_pinned_swap == TRUE)
+ thread_wakeup((event_t)&hibernate_in_progress_with_pinned_swap);
+
assert_wait((event_t)&vm_swapfile_create_needed, THREAD_UNINT);
lck_mtx_unlock(&vm_swap_data_lock);
}
+#if HIBERNATION
+
+kern_return_t
+hibernate_pin_swap(boolean_t start)
+{
+ vm_compaction_swapper_do_init();
+
+ if (start == FALSE) {
+
+ lck_mtx_lock(&vm_swap_data_lock);
+ hibernate_in_progress_with_pinned_swap = FALSE;
+ lck_mtx_unlock(&vm_swap_data_lock);
+
+ return (KERN_SUCCESS);
+ }
+ if (vm_swappin_enabled == FALSE)
+ return (KERN_SUCCESS);
+
+ lck_mtx_lock(&vm_swap_data_lock);
+
+ hibernate_in_progress_with_pinned_swap = TRUE;
+
+ while (vm_swapfile_create_thread_running || vm_swapfile_gc_thread_running) {
+
+ assert_wait((event_t)&hibernate_in_progress_with_pinned_swap, THREAD_UNINT);
+
+ lck_mtx_unlock(&vm_swap_data_lock);
+
+ thread_block(THREAD_CONTINUE_NULL);
+
+ lck_mtx_lock(&vm_swap_data_lock);
+ }
+ if (vm_num_swap_files > vm_num_pinned_swap_files) {
+ hibernate_in_progress_with_pinned_swap = FALSE;
+ lck_mtx_unlock(&vm_swap_data_lock);
+
+ HIBLOG("hibernate_pin_swap failed - vm_num_swap_files = %d, vm_num_pinned_swap_files = %d\n",
+ vm_num_swap_files, vm_num_pinned_swap_files);
+ return (KERN_FAILURE);
+ }
+ lck_mtx_unlock(&vm_swap_data_lock);
+
+ while (VM_SWAP_SHOULD_PIN(MAX_SWAP_FILE_SIZE)) {
+ if (vm_swap_create_file() == FALSE)
+ break;
+ }
+ return (KERN_SUCCESS);
+}
+#endif
+
static void
vm_swapfile_gc_thread(void)
+
{
boolean_t need_defragment;
boolean_t need_reclaim;
lck_mtx_lock(&vm_swap_data_lock);
+ if (hibernate_in_progress_with_pinned_swap == TRUE)
+ break;
+
if (VM_SWAP_BUSY() || compressor_store_stop_compaction == TRUE)
break;
if (need_defragment == FALSE && need_reclaim == FALSE)
break;
+ vm_swap_force_defrag = FALSE;
+ vm_swap_force_reclaim = FALSE;
+
lck_mtx_unlock(&vm_swap_data_lock);
if (need_defragment == TRUE)
}
vm_swapfile_gc_thread_running = 0;
+ if (hibernate_in_progress_with_pinned_swap == TRUE)
+ thread_wakeup((event_t)&hibernate_in_progress_with_pinned_swap);
+
assert_wait((event_t)&vm_swapfile_gc_needed, THREAD_UNINT);
lck_mtx_unlock(&vm_swap_data_lock);
-int swapper_entered_T0 = 0;
-int swapper_entered_T1 = 0;
-int swapper_entered_T2 = 0;
+#define VM_SWAPOUT_LIMIT_T2P 4
+#define VM_SWAPOUT_LIMIT_T1P 4
+#define VM_SWAPOUT_LIMIT_T0P 6
+#define VM_SWAPOUT_LIMIT_T0 8
+#define VM_SWAPOUT_LIMIT_MAX 8
+
+#define VM_SWAPOUT_START 0
+#define VM_SWAPOUT_T2_PASSIVE 1
+#define VM_SWAPOUT_T1_PASSIVE 2
+#define VM_SWAPOUT_T0_PASSIVE 3
+#define VM_SWAPOUT_T0 4
+
+int vm_swapout_state = VM_SWAPOUT_START;
+int vm_swapout_limit = 1;
+
+int vm_swapper_entered_T0 = 0;
+int vm_swapper_entered_T0P = 0;
+int vm_swapper_entered_T1P = 0;
+int vm_swapper_entered_T2P = 0;
+
static void
vm_swapout_thread_throttle_adjust(void)
{
- int swapper_throttle_new;
- if (swapper_throttle_inited == FALSE) {
- /*
- * force this thread to be set to the correct
- * throttling tier
- */
- swapper_throttle_new = THROTTLE_LEVEL_COMPRESSOR_TIER2;
- swapper_throttle = THROTTLE_LEVEL_COMPRESSOR_TIER1;
- swapper_throttle_inited = TRUE;
- swapper_entered_T2++;
- goto done;
- }
- swapper_throttle_new = swapper_throttle;
+ switch(vm_swapout_state) {
+ case VM_SWAPOUT_START:
+
+ vm_swapper_throttle = THROTTLE_LEVEL_COMPRESSOR_TIER2;
+ vm_swapper_entered_T2P++;
- switch(swapper_throttle) {
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_IO, vm_swapper_throttle);
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
+ vm_swapout_limit = VM_SWAPOUT_LIMIT_T2P;
+ vm_swapout_state = VM_SWAPOUT_T2_PASSIVE;
+
+ break;
- case THROTTLE_LEVEL_COMPRESSOR_TIER2:
+ case VM_SWAPOUT_T2_PASSIVE:
+
+ if (SWAPPER_NEEDS_TO_UNTHROTTLE()) {
+ vm_swapper_throttle = THROTTLE_LEVEL_COMPRESSOR_TIER0;
+ vm_swapper_entered_T0P++;
+
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_IO, vm_swapper_throttle);
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
+ vm_swapout_limit = VM_SWAPOUT_LIMIT_T0P;
+ vm_swapout_state = VM_SWAPOUT_T0_PASSIVE;
- if (SWAPPER_NEEDS_TO_UNTHROTTLE() || swapout_target_age || hibernate_flushing == TRUE) {
- swapper_throttle_new = THROTTLE_LEVEL_COMPRESSOR_TIER1;
- swapper_entered_T1++;
break;
}
+ if (swapout_target_age || hibernate_flushing == TRUE) {
+ vm_swapper_throttle = THROTTLE_LEVEL_COMPRESSOR_TIER1;
+ vm_swapper_entered_T1P++;
+
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_IO, vm_swapper_throttle);
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
+ vm_swapout_limit = VM_SWAPOUT_LIMIT_T1P;
+ vm_swapout_state = VM_SWAPOUT_T1_PASSIVE;
+ }
break;
- case THROTTLE_LEVEL_COMPRESSOR_TIER1:
+ case VM_SWAPOUT_T1_PASSIVE:
+
+ if (SWAPPER_NEEDS_TO_UNTHROTTLE()) {
+ vm_swapper_throttle = THROTTLE_LEVEL_COMPRESSOR_TIER0;
+ vm_swapper_entered_T0P++;
+
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_IO, vm_swapper_throttle);
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
+ vm_swapout_limit = VM_SWAPOUT_LIMIT_T0P;
+ vm_swapout_state = VM_SWAPOUT_T0_PASSIVE;
- if (VM_PAGEOUT_SCAN_NEEDS_TO_THROTTLE()) {
- swapper_throttle_new = THROTTLE_LEVEL_COMPRESSOR_TIER0;
- swapper_entered_T0++;
break;
}
- if (COMPRESSOR_NEEDS_TO_SWAP() == 0 && swapout_target_age == 0 && hibernate_flushing == FALSE) {
- swapper_throttle_new = THROTTLE_LEVEL_COMPRESSOR_TIER2;
- swapper_entered_T2++;
- break;
+ if (swapout_target_age == 0 && hibernate_flushing == FALSE) {
+
+ vm_swapper_throttle = THROTTLE_LEVEL_COMPRESSOR_TIER2;
+ vm_swapper_entered_T2P++;
+
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_IO, vm_swapper_throttle);
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
+ vm_swapout_limit = VM_SWAPOUT_LIMIT_T2P;
+ vm_swapout_state = VM_SWAPOUT_T2_PASSIVE;
}
- break;
+ break;
+
+ case VM_SWAPOUT_T0_PASSIVE:
- case THROTTLE_LEVEL_COMPRESSOR_TIER0:
+ if (SWAPPER_NEEDS_TO_RETHROTTLE()) {
+ vm_swapper_throttle = THROTTLE_LEVEL_COMPRESSOR_TIER2;
+ vm_swapper_entered_T2P++;
+
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_IO, vm_swapper_throttle);
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
+ vm_swapout_limit = VM_SWAPOUT_LIMIT_T2P;
+ vm_swapout_state = VM_SWAPOUT_T2_PASSIVE;
- if (COMPRESSOR_NEEDS_TO_SWAP() == 0) {
- swapper_throttle_new = THROTTLE_LEVEL_COMPRESSOR_TIER2;
- swapper_entered_T2++;
break;
}
- if (SWAPPER_NEEDS_TO_UNTHROTTLE() == 0) {
- swapper_throttle_new = THROTTLE_LEVEL_COMPRESSOR_TIER1;
- swapper_entered_T1++;
- break;
+ if (SWAPPER_NEEDS_TO_CATCHUP()) {
+ vm_swapper_entered_T0++;
+
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_DISABLE);
+ vm_swapout_limit = VM_SWAPOUT_LIMIT_T0;
+ vm_swapout_state = VM_SWAPOUT_T0;
+ }
+ break;
+
+ case VM_SWAPOUT_T0:
+
+ if (SWAPPER_HAS_CAUGHTUP()) {
+ vm_swapper_entered_T0P++;
+
+ proc_set_thread_policy_with_tid(kernel_task, vm_swapout_thread_id,
+ TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
+ vm_swapout_limit = VM_SWAPOUT_LIMIT_T0P;
+ vm_swapout_state = VM_SWAPOUT_T0_PASSIVE;
}
break;
}
-done:
- if (swapper_throttle != swapper_throttle_new) {
- proc_set_task_policy_thread(kernel_task, vm_swapout_thread_id,
- TASK_POLICY_INTERNAL, TASK_POLICY_IO, swapper_throttle_new);
- proc_set_task_policy_thread(kernel_task, vm_swapout_thread_id,
- TASK_POLICY_INTERNAL, TASK_POLICY_PASSIVE_IO, TASK_POLICY_ENABLE);
+}
+
+int vm_swapout_found_empty = 0;
+
+struct swapout_io_completion vm_swapout_ctx[VM_SWAPOUT_LIMIT_MAX];
+
+int vm_swapout_soc_busy = 0;
+int vm_swapout_soc_done = 0;
+
- swapper_throttle = swapper_throttle_new;
+static struct swapout_io_completion *
+vm_swapout_find_free_soc(void)
+{ int i;
+
+ for (i = 0; i < VM_SWAPOUT_LIMIT_MAX; i++) {
+ if (vm_swapout_ctx[i].swp_io_busy == 0)
+ return (&vm_swapout_ctx[i]);
+ }
+ assert(vm_swapout_soc_busy == VM_SWAPOUT_LIMIT_MAX);
+
+ return NULL;
+}
+
+static struct swapout_io_completion *
+vm_swapout_find_done_soc(void)
+{ int i;
+
+ if (vm_swapout_soc_done) {
+ for (i = 0; i < VM_SWAPOUT_LIMIT_MAX; i++) {
+ if (vm_swapout_ctx[i].swp_io_done)
+ return (&vm_swapout_ctx[i]);
+ }
}
+ return NULL;
+}
+
+static void
+vm_swapout_complete_soc(struct swapout_io_completion *soc)
+{
+ kern_return_t kr;
+
+ if (soc->swp_io_error)
+ kr = KERN_FAILURE;
+ else
+ kr = KERN_SUCCESS;
+
+ lck_mtx_unlock_always(c_list_lock);
+
+ vm_swap_put_finish(soc->swp_swf, &soc->swp_f_offset, soc->swp_io_error);
+ vm_swapout_finish(soc->swp_c_seg, soc->swp_f_offset, soc->swp_c_size, kr);
+
+ lck_mtx_lock_spin_always(c_list_lock);
+
+ soc->swp_io_done = 0;
+ soc->swp_io_busy = 0;
+
+ vm_swapout_soc_busy--;
+ vm_swapout_soc_done--;
}
static void
vm_swapout_thread(void)
{
- uint64_t f_offset = 0;
uint32_t size = 0;
c_segment_t c_seg = NULL;
kern_return_t kr = KERN_SUCCESS;
- vm_offset_t addr = 0;
+ struct swapout_io_completion *soc;
+
+ current_thread()->options |= TH_OPT_VMPRIV;
vm_swapout_thread_awakened++;
lck_mtx_lock_spin_always(c_list_lock);
-
- while (!queue_empty(&c_swapout_list_head)) {
+again:
+ while (!queue_empty(&c_swapout_list_head) && vm_swapout_soc_busy < vm_swapout_limit) {
c_seg = (c_segment_t)queue_first(&c_swapout_list_head);
lck_mtx_lock_spin_always(&c_seg->c_lock);
- assert(c_seg->c_on_swapout_q);
+ assert(c_seg->c_state == C_ON_SWAPOUT_Q);
if (c_seg->c_busy) {
lck_mtx_unlock_always(c_list_lock);
continue;
}
- queue_remove(&c_swapout_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swapout_q = 0;
- c_swapout_count--;
-
vm_swapout_thread_processed_segments++;
- thread_wakeup((event_t)&compaction_swapper_running);
-
size = round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset));
if (size == 0) {
- c_seg_free_locked(c_seg);
- goto c_seg_was_freed;
+ assert(c_seg->c_bytes_used == 0);
+
+ if (!c_seg->c_on_minorcompact_q)
+ c_seg_need_delayed_compaction(c_seg, TRUE);
+
+ c_seg_switch_state(c_seg, C_IS_EMPTY, FALSE);
+ lck_mtx_unlock_always(&c_seg->c_lock);
+ lck_mtx_unlock_always(c_list_lock);
+
+ vm_swapout_found_empty++;
+ goto c_seg_is_empty;
}
C_SEG_BUSY(c_seg);
c_seg->c_busy_swapping = 1;
- lck_mtx_unlock_always(c_list_lock);
-
- addr = (vm_offset_t) c_seg->c_store.c_buffer;
+ c_seg_switch_state(c_seg, C_ON_SWAPIO_Q, FALSE);
+ lck_mtx_unlock_always(c_list_lock);
lck_mtx_unlock_always(&c_seg->c_lock);
#if CHECKSUM_THE_SWAP
- c_seg->cseg_hash = hash_string((char*)addr, (int)size);
+ c_seg->cseg_hash = hash_string((char *)c_seg->c_store.c_buffer, (int)size);
c_seg->cseg_swap_size = size;
#endif /* CHECKSUM_THE_SWAP */
vm_swap_encrypt(c_seg);
#endif /* ENCRYPTED_SWAP */
- vm_swapout_thread_throttle_adjust();
+ soc = vm_swapout_find_free_soc();
+ assert(soc);
- kr = vm_swap_put((vm_offset_t) addr, &f_offset, size, c_seg);
+ soc->swp_upl_ctx.io_context = (void *)soc;
+ soc->swp_upl_ctx.io_done = (void *)vm_swapout_iodone;
+ soc->swp_upl_ctx.io_error = 0;
- PAGE_REPLACEMENT_DISALLOWED(TRUE);
+ kr = vm_swap_put((vm_offset_t)c_seg->c_store.c_buffer, &soc->swp_f_offset, size, c_seg, soc);
+
+ if (kr != KERN_SUCCESS) {
+ if (soc->swp_io_done) {
+ lck_mtx_lock_spin_always(c_list_lock);
+
+ soc->swp_io_done = 0;
+ vm_swapout_soc_done--;
+
+ lck_mtx_unlock_always(c_list_lock);
+ }
+ vm_swapout_finish(c_seg, soc->swp_f_offset, size, kr);
+ } else {
+ soc->swp_io_busy = 1;
+ vm_swapout_soc_busy++;
+ }
+ vm_swapout_thread_throttle_adjust();
+ vm_pageout_io_throttle();
+
+c_seg_is_empty:
+ if (c_swapout_count == 0)
+ vm_swap_consider_defragmenting(VM_SWAP_FLAGS_NONE);
lck_mtx_lock_spin_always(c_list_lock);
- lck_mtx_lock_spin_always(&c_seg->c_lock);
- if (kr == KERN_SUCCESS) {
+ if ((soc = vm_swapout_find_done_soc()))
+ vm_swapout_complete_soc(soc);
+ }
+ if ((soc = vm_swapout_find_done_soc())) {
+ vm_swapout_complete_soc(soc);
+ goto again;
+ }
+ assert_wait((event_t)&c_swapout_list_head, THREAD_UNINT);
+
+ lck_mtx_unlock_always(c_list_lock);
+
+ thread_block((thread_continue_t)vm_swapout_thread);
+
+ /* NOTREACHED */
+}
- if (C_SEG_ONDISK_IS_SPARSE(c_seg) && hibernate_flushing == FALSE) {
- c_seg_insert_into_q(&c_swappedout_sparse_list_head, c_seg);
- c_seg->c_on_swappedout_sparse_q = 1;
- c_swappedout_sparse_count++;
+void
+vm_swapout_iodone(void *io_context, int error)
+{
+ struct swapout_io_completion *soc;
- } else {
- if (hibernate_flushing == TRUE && (c_seg->c_generation_id >= first_c_segment_to_warm_generation_id &&
- c_seg->c_generation_id <= last_c_segment_to_warm_generation_id))
- queue_enter_first(&c_swappedout_list_head, c_seg, c_segment_t, c_age_list);
- else
- queue_enter(&c_swappedout_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swappedout_q = 1;
- c_swappedout_count++;
- }
- c_seg->c_store.c_swap_handle = f_offset;
- c_seg->c_ondisk = 1;
+ soc = (struct swapout_io_completion *)io_context;
- VM_STAT_INCR_BY(swapouts, size >> PAGE_SHIFT);
-
- if (c_seg->c_bytes_used)
- OSAddAtomic64(-c_seg->c_bytes_used, &compressor_bytes_used);
- } else {
+ lck_mtx_lock_spin_always(c_list_lock);
+
+ soc->swp_io_done = 1;
+ soc->swp_io_error = error;
+ vm_swapout_soc_done++;
+
+ thread_wakeup((event_t)&c_swapout_list_head);
+
+ lck_mtx_unlock_always(c_list_lock);
+}
+
+
+static void
+vm_swapout_finish(c_segment_t c_seg, uint64_t f_offset, uint32_t size, kern_return_t kr)
+{
+
+ PAGE_REPLACEMENT_DISALLOWED(TRUE);
+
+ if (kr == KERN_SUCCESS) {
+ kernel_memory_depopulate(compressor_map, (vm_offset_t)c_seg->c_store.c_buffer, size, KMA_COMPRESSOR);
+ }
#if ENCRYPTED_SWAP
- vm_swap_decrypt(c_seg);
+ else {
+ vm_swap_decrypt(c_seg);
+ }
#endif /* ENCRYPTED_SWAP */
- c_seg_insert_into_q(&c_age_list_head, c_seg);
- c_seg->c_on_age_q = 1;
- c_age_count++;
+ lck_mtx_lock_spin_always(c_list_lock);
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
- vm_swap_put_failures++;
- }
- lck_mtx_unlock_always(c_list_lock);
+ if (kr == KERN_SUCCESS) {
+ int new_state = C_ON_SWAPPEDOUT_Q;
+ boolean_t insert_head = FALSE;
- if (c_seg->c_must_free)
- c_seg_free(c_seg);
- else {
- c_seg->c_busy_swapping = 0;
- C_SEG_WAKEUP_DONE(c_seg);
- lck_mtx_unlock_always(&c_seg->c_lock);
- }
+ if (hibernate_flushing == TRUE) {
+ if (c_seg->c_generation_id >= first_c_segment_to_warm_generation_id &&
+ c_seg->c_generation_id <= last_c_segment_to_warm_generation_id)
+ insert_head = TRUE;
+ } else if (C_SEG_ONDISK_IS_SPARSE(c_seg))
+ new_state = C_ON_SWAPPEDOUTSPARSE_Q;
- if (kr == KERN_SUCCESS)
- kernel_memory_depopulate(kernel_map, (vm_offset_t) addr, size, KMA_COMPRESSOR);
+ c_seg_switch_state(c_seg, new_state, insert_head);
- PAGE_REPLACEMENT_DISALLOWED(FALSE);
+ c_seg->c_store.c_swap_handle = f_offset;
- if (kr == KERN_SUCCESS) {
- kmem_free(kernel_map, (vm_offset_t) addr, C_SEG_ALLOCSIZE);
- OSAddAtomic64(-C_SEG_ALLOCSIZE, &compressor_kvspace_used);
+ VM_STAT_INCR_BY(swapouts, size >> PAGE_SHIFT);
+
+ if (c_seg->c_bytes_used)
+ OSAddAtomic64(-c_seg->c_bytes_used, &compressor_bytes_used);
+ } else {
+ if (c_seg->c_overage_swap == TRUE) {
+ c_seg->c_overage_swap = FALSE;
+ c_overage_swapped_count--;
}
- vm_pageout_io_throttle();
-c_seg_was_freed:
- if (c_swapout_count == 0)
- vm_swap_consider_defragmenting();
+ c_seg_switch_state(c_seg, C_ON_AGE_Q, FALSE);
- lck_mtx_lock_spin_always(c_list_lock);
+ if (!c_seg->c_on_minorcompact_q && C_SEG_UNUSED_BYTES(c_seg) >= PAGE_SIZE)
+ c_seg_need_delayed_compaction(c_seg, TRUE);
}
+ assert(c_seg->c_busy_swapping);
+ assert(c_seg->c_busy);
- assert_wait((event_t)&c_swapout_list_head, THREAD_UNINT);
-
+ c_seg->c_busy_swapping = 0;
lck_mtx_unlock_always(c_list_lock);
- thread_block((thread_continue_t)vm_swapout_thread);
-
- /* NOTREACHED */
+ C_SEG_WAKEUP_DONE(c_seg);
+ lck_mtx_unlock_always(&c_seg->c_lock);
+
+ PAGE_REPLACEMENT_DISALLOWED(FALSE);
}
+
boolean_t
vm_swap_create_file()
{
int namelen = 0;
boolean_t swap_file_created = FALSE;
boolean_t swap_file_reuse = FALSE;
+ boolean_t swap_file_pin = FALSE;
struct swapfile *swf = NULL;
+ /*
+ * make sure we've got all the info we need
+ * to potentially pin a swap file... we could
+ * be swapping out due to hibernation w/o ever
+ * having run vm_pageout_scan, which is normally
+ * the trigger to do the init
+ */
+ vm_compaction_swapper_do_init();
+
/*
* Any swapfile structure ready for re-use?
*/
if (swap_file_reuse == FALSE) {
- if (strlen(swapfilename) == 0) {
- /*
- * If no swapfile name has been set, we'll
- * use the default name.
- *
- * Also, this function is only called from the swapfile management thread.
- * So we don't need to worry about a race in checking/setting the name here.
- */
-
- strlcpy(swapfilename, SWAP_FILE_NAME, MAX_SWAPFILENAME_LEN);
- }
-
namelen = (int)strlen(swapfilename) + SWAPFILENAME_INDEX_LEN + 1;
swf = (struct swapfile*) kalloc(sizeof *swf);
while (size >= MIN_SWAP_FILE_SIZE) {
- if (vm_swapfile_preallocate(swf->swp_vp, &size) == 0) {
+ swap_file_pin = VM_SWAP_SHOULD_PIN(size);
+
+ if (vm_swapfile_preallocate(swf->swp_vp, &size, &swap_file_pin) == 0) {
int num_bytes_for_bitmap = 0;
vm_swapfile_total_segs_alloced += swf->swp_nsegs;
+ if (swap_file_pin == TRUE) {
+ vm_num_pinned_swap_files++;
+ swf->swp_flags |= SWAP_PINNED;
+ vm_swappin_avail -= swf->swp_size;
+ }
+
lck_mtx_unlock(&vm_swap_data_lock);
thread_wakeup((event_t) &vm_num_swap_files);
+#if CONFIG_EMBEDDED
+ if (vm_num_swap_files == 1) {
+
+ c_overage_swapped_limit = (uint32_t)size / C_SEG_BUFSIZE;
+ if (VM_CONFIG_FREEZER_SWAP_IS_ACTIVE)
+ c_overage_swapped_limit /= 2;
+ }
+#endif
break;
} else {
kern_return_t
-vm_swap_get(vm_offset_t addr, uint64_t f_offset, uint64_t size)
+vm_swap_get(c_segment_t c_seg, uint64_t f_offset, uint64_t size)
{
struct swapfile *swf = NULL;
uint64_t file_offset = 0;
int retval = 0;
- if (addr == 0) {
- return KERN_FAILURE;
- }
+ assert(c_seg->c_store.c_buffer);
lck_mtx_lock(&vm_swap_data_lock);
lck_mtx_unlock(&vm_swap_data_lock);
+#if DEVELOPMENT || DEBUG
+ C_SEG_MAKE_WRITEABLE(c_seg);
+#endif
file_offset = (f_offset & SWAP_SLOT_MASK);
- retval = vm_swapfile_io(swf->swp_vp, file_offset, addr, (int)(size / PAGE_SIZE_64), SWAP_READ);
+ retval = vm_swapfile_io(swf->swp_vp, file_offset, (uint64_t)c_seg->c_store.c_buffer, (int)(size / PAGE_SIZE_64), SWAP_READ, NULL);
+#if DEVELOPMENT || DEBUG
+ C_SEG_WRITE_PROTECT(c_seg);
+#endif
if (retval == 0)
VM_STAT_INCR_BY(swapins, size >> PAGE_SHIFT);
else
}
kern_return_t
-vm_swap_put(vm_offset_t addr, uint64_t *f_offset, uint64_t size, c_segment_t c_seg)
+vm_swap_put(vm_offset_t addr, uint64_t *f_offset, uint32_t size, c_segment_t c_seg, struct swapout_io_completion *soc)
{
unsigned int segidx = 0;
struct swapfile *swf = NULL;
int error = 0;
clock_sec_t sec;
clock_nsec_t nsec;
+ void *upl_ctx = NULL;
if (addr == 0 || f_offset == NULL) {
return KERN_FAILURE;
file_offset = segidx * COMPRESSED_SWAP_CHUNK_SIZE;
swf->swp_nseginuse++;
swf->swp_io_count++;
- swapfile_index = swf->swp_index;
+ swf->swp_csegs[segidx] = c_seg;
+ swapfile_index = swf->swp_index;
vm_swapfile_total_segs_used++;
clock_get_system_nanotime(&sec, &nsec);
lck_mtx_unlock(&vm_swap_data_lock);
- goto done;
+ goto issue_io;
}
}
swf = (struct swapfile*) queue_next(&swf->swp_queue);
goto retry;
}
}
+ vm_swap_put_failures++;
return KERN_FAILURE;
-done:
- error = vm_swapfile_io(swf->swp_vp, file_offset, addr, (int) (size / PAGE_SIZE_64), SWAP_WRITE);
+issue_io:
+ assert(c_seg->c_busy_swapping);
+ assert(c_seg->c_busy);
+ assert(!c_seg->c_on_minorcompact_q);
- lck_mtx_lock(&vm_swap_data_lock);
+ *f_offset = (swapfile_index << SWAP_DEVICE_SHIFT) | file_offset;
- swf->swp_csegs[segidx] = c_seg;
+ if (soc) {
+ soc->swp_c_seg = c_seg;
+ soc->swp_c_size = size;
- swf->swp_io_count--;
+ soc->swp_swf = swf;
- *f_offset = (swapfile_index << SWAP_DEVICE_SHIFT) | file_offset;
+ soc->swp_io_error = 0;
+ soc->swp_io_done = 0;
+
+ upl_ctx = (void *)&soc->swp_upl_ctx;
+ }
+ error = vm_swapfile_io(swf->swp_vp, file_offset, addr, (int) (size / PAGE_SIZE_64), SWAP_WRITE, upl_ctx);
+
+ if (error || upl_ctx == NULL)
+ return (vm_swap_put_finish(swf, f_offset, error));
+
+ return KERN_SUCCESS;
+}
+
+kern_return_t
+vm_swap_put_finish(struct swapfile *swf, uint64_t *f_offset, int error)
+{
+ lck_mtx_lock(&vm_swap_data_lock);
+
+ swf->swp_io_count--;
if ((swf->swp_flags & SWAP_WANTED) && swf->swp_io_count == 0) {
swf->swp_flags &= ~SWAP_WANTED;
thread_wakeup((event_t) &swf->swp_flags);
}
-
lck_mtx_unlock(&vm_swap_data_lock);
if (error) {
vm_swap_free(*f_offset);
+ vm_swap_put_failures++;
return KERN_FAILURE;
}
}
-
static void
vm_swap_free_now(struct swapfile *swf, uint64_t f_offset)
{
c_segment_t c_seg = NULL;
- if (kernel_memory_allocate(kernel_map, (vm_offset_t *)(&addr), C_SEG_BUFSIZE, 0, KMA_KOBJECT) != KERN_SUCCESS) {
+ if (kernel_memory_allocate(compressor_map, (vm_offset_t *)(&addr), C_SEG_BUFSIZE, 0, KMA_KOBJECT, VM_KERN_MEMORY_COMPRESSOR) != KERN_SUCCESS) {
panic("vm_swap_reclaim: kernel_memory_allocate failed\n");
}
}
c_seg = swf->swp_csegs[segidx];
+ assert(c_seg);
lck_mtx_lock_spin_always(&c_seg->c_lock);
- assert(c_seg->c_ondisk);
-
if (c_seg->c_busy) {
-
+ /*
+ * a swapped out c_segment in the process of being freed will remain in the
+ * busy state until after the vm_swap_free is called on it... vm_swap_free
+ * takes the vm_swap_data_lock, so can't change the swap state until after
+ * we drop the vm_swap_data_lock... once we do, vm_swap_free will complete
+ * which will allow c_seg_free_locked to clear busy and wake up this thread...
+ * at that point, we re-look up the swap state which will now indicate that
+ * this c_segment no longer exists.
+ */
c_seg->c_wanted = 1;
assert_wait((event_t) (c_seg), THREAD_UNINT);
(swf->swp_bitmap)[byte_for_segidx] &= ~(1 << offset_within_byte);
f_offset = segidx * COMPRESSED_SWAP_CHUNK_SIZE;
-
+
+ assert(c_seg == swf->swp_csegs[segidx]);
swf->swp_csegs[segidx] = NULL;
swf->swp_nseginuse--;
vm_swapfile_total_segs_used--;
lck_mtx_unlock(&vm_swap_data_lock);
-
- if (c_seg->c_must_free) {
- C_SEG_BUSY(c_seg);
- c_seg_free(c_seg);
- } else {
- C_SEG_BUSY(c_seg);
- c_seg->c_busy_swapping = 1;
+ assert(C_SEG_IS_ONDISK(c_seg));
+
+ C_SEG_BUSY(c_seg);
+ c_seg->c_busy_swapping = 1;
#if !CHECKSUM_THE_SWAP
- c_seg_trim_tail(c_seg);
+ c_seg_trim_tail(c_seg);
#endif
- c_size = round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset));
+ c_size = round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset));
- assert(c_size <= C_SEG_BUFSIZE);
+ assert(c_size <= C_SEG_BUFSIZE && c_size);
- lck_mtx_unlock_always(&c_seg->c_lock);
+ lck_mtx_unlock_always(&c_seg->c_lock);
- if (vm_swapfile_io(swf->swp_vp, f_offset, addr, (int)(c_size / PAGE_SIZE_64), SWAP_READ)) {
+ if (vm_swapfile_io(swf->swp_vp, f_offset, addr, (int)(c_size / PAGE_SIZE_64), SWAP_READ, NULL)) {
- /*
- * reading the data back in failed, so convert c_seg
- * to a swapped in c_segment that contains no data
- */
- c_seg->c_store.c_buffer = (int32_t *)NULL;
- c_seg_swapin_requeue(c_seg);
+ /*
+ * reading the data back in failed, so convert c_seg
+ * to a swapped in c_segment that contains no data
+ */
+ c_seg_swapin_requeue(c_seg, FALSE, TRUE, FALSE);
+ /*
+ * returns with c_busy_swapping cleared
+ */
- goto swap_io_failed;
- }
- VM_STAT_INCR_BY(swapins, c_size >> PAGE_SHIFT);
+ vm_swap_get_failures++;
+ goto swap_io_failed;
+ }
+ VM_STAT_INCR_BY(swapins, c_size >> PAGE_SHIFT);
- if (vm_swap_put(addr, &f_offset, c_size, c_seg)) {
- vm_offset_t c_buffer;
+ if (vm_swap_put(addr, &f_offset, c_size, c_seg, NULL)) {
+ vm_offset_t c_buffer;
- /*
- * the put failed, so convert c_seg to a fully swapped in c_segment
- * with valid data
- */
- if (kernel_memory_allocate(kernel_map, &c_buffer, C_SEG_ALLOCSIZE, 0, KMA_COMPRESSOR | KMA_VAONLY) != KERN_SUCCESS)
- panic("vm_swap_reclaim: kernel_memory_allocate failed\n");
- OSAddAtomic64(C_SEG_ALLOCSIZE, &compressor_kvspace_used);
+ /*
+ * the put failed, so convert c_seg to a fully swapped in c_segment
+ * with valid data
+ */
+ c_buffer = (vm_offset_t)C_SEG_BUFFER_ADDRESS(c_seg->c_mysegno);
- kernel_memory_populate(kernel_map, c_buffer, c_size, KMA_COMPRESSOR);
+ kernel_memory_populate(compressor_map, c_buffer, c_size, KMA_COMPRESSOR, VM_KERN_MEMORY_COMPRESSOR);
- memcpy((char *)c_buffer, (char *)addr, c_size);
+ memcpy((char *)c_buffer, (char *)addr, c_size);
- c_seg->c_store.c_buffer = (int32_t *)c_buffer;
+ c_seg->c_store.c_buffer = (int32_t *)c_buffer;
#if ENCRYPTED_SWAP
- vm_swap_decrypt(c_seg);
+ vm_swap_decrypt(c_seg);
#endif /* ENCRYPTED_SWAP */
- c_seg_swapin_requeue(c_seg);
-
- OSAddAtomic64(c_seg->c_bytes_used, &compressor_bytes_used);
+ c_seg_swapin_requeue(c_seg, TRUE, TRUE, FALSE);
+ /*
+ * returns with c_busy_swapping cleared
+ */
+ OSAddAtomic64(c_seg->c_bytes_used, &compressor_bytes_used);
- goto swap_io_failed;
- }
- VM_STAT_INCR_BY(swapouts, c_size >> PAGE_SHIFT);
+ goto swap_io_failed;
+ }
+ VM_STAT_INCR_BY(swapouts, c_size >> PAGE_SHIFT);
- lck_mtx_lock_spin_always(&c_seg->c_lock);
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
- assert(c_seg->c_ondisk);
- /*
- * The c_seg will now know about the new location on disk.
- */
- c_seg->c_store.c_swap_handle = f_offset;
+ assert(C_SEG_IS_ONDISK(c_seg));
+ /*
+ * The c_seg will now know about the new location on disk.
+ */
+ c_seg->c_store.c_swap_handle = f_offset;
+
+ assert(c_seg->c_busy_swapping);
+ c_seg->c_busy_swapping = 0;
swap_io_failed:
- c_seg->c_busy_swapping = 0;
-
- if (c_seg->c_must_free)
- c_seg_free(c_seg);
- else {
- C_SEG_WAKEUP_DONE(c_seg);
+ assert(c_seg->c_busy);
+ C_SEG_WAKEUP_DONE(c_seg);
- lck_mtx_unlock_always(&c_seg->c_lock);
- }
- }
+ lck_mtx_unlock_always(&c_seg->c_lock);
lck_mtx_lock(&vm_swap_data_lock);
}
lck_mtx_lock(&vm_swap_data_lock);
+ if (swf->swp_flags & SWAP_PINNED) {
+ vm_num_pinned_swap_files--;
+ vm_swappin_avail += swf->swp_size;
+ }
+
swf->swp_vp = NULL;
swf->swp_size = 0;
swf->swp_free_hint = 0;
thread_wakeup((event_t) &swf->swp_flags);
lck_mtx_unlock(&vm_swap_data_lock);
- kmem_free(kernel_map, (vm_offset_t) addr, C_SEG_BUFSIZE);
+ kmem_free(compressor_map, (vm_offset_t) addr, C_SEG_BUFSIZE);
}
}
return (0);
}
+
+boolean_t
+vm_swap_files_pinned(void)
+{
+ boolean_t result;
+
+ if (vm_swappin_enabled == FALSE)
+ return (TRUE);
+
+ result = (vm_num_pinned_swap_files == vm_num_swap_files);
+
+ return (result);
+}
+
+#if CONFIG_FREEZE
+boolean_t
+vm_swap_max_budget(uint64_t *freeze_daily_budget)
+{
+ boolean_t use_device_value = FALSE;
+ struct swapfile *swf = NULL;
+
+ if (vm_num_swap_files) {
+ lck_mtx_lock(&vm_swap_data_lock);
+
+ swf = (struct swapfile*) queue_first(&swf_global_queue);
+
+ if (swf) {
+ while(queue_end(&swf_global_queue, (queue_entry_t)swf) == FALSE) {
+
+ if (swf->swp_flags == SWAP_READY) {
+
+ assert(swf->swp_vp);
+
+ if (vm_swap_vol_get_budget(swf->swp_vp, freeze_daily_budget) == 0) {
+ use_device_value = TRUE;
+ }
+ break;
+ }
+ swf = (struct swapfile*) queue_next(&swf->swp_queue);
+ }
+ }
+
+ lck_mtx_unlock(&vm_swap_data_lock);
+
+ } else {
+
+ /*
+ * This block is used for the initial budget value before any swap files
+ * are created. We create a temp swap file to get the budget.
+ */
+
+ struct vnode *temp_vp = NULL;
+
+ vm_swapfile_open(swapfilename, &temp_vp);
+
+ if (temp_vp) {
+
+ if (vm_swap_vol_get_budget(temp_vp, freeze_daily_budget) == 0) {
+ use_device_value = TRUE;
+ }
+
+ vm_swapfile_close((uint64_t)&swapfilename, temp_vp);
+ temp_vp = NULL;
+ } else {
+ *freeze_daily_budget = 0;
+ }
+ }
+
+ return use_device_value;
+}
+#endif /* CONFIG_FREEZE */
projects / apple / xnu.git / blobdiff