* Copyright (c) 2000-2013 Apple Inc. All rights reserved.
*
* @APPLE_OSREFERENCE_LICENSE_HEADER_START@
- *
+ *
* This file contains Original Code and/or Modifications of Original Code
* as defined in and that are subject to the Apple Public Source License
* Version 2.0 (the 'License'). You may not use this file except in
* unlawful or unlicensed copies of an Apple operating system, or to
* circumvent, violate, or enable the circumvention or violation of, any
* terms of an Apple operating system software license agreement.
- *
+ *
* Please obtain a copy of the License at
* http://www.opensource.apple.com/apsl/ and read it before using this file.
- *
+ *
* The Original Code and all software distributed under the License are
* distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
* EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
* FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
* Please see the License for the specific language governing rights and
* limitations under the License.
- *
+ *
* @APPLE_OSREFERENCE_LICENSE_HEADER_END@
*/
#include <vm/vm_map.h>
#include <vm/vm_pageout.h>
#include <vm/memory_object.h>
-#include <mach/mach_host.h> /* for host_info() */
+#include <vm/vm_compressor_algorithms.h>
+#include <vm/vm_fault.h>
+#include <vm/vm_protos.h>
+#include <mach/mach_host.h> /* for host_info() */
#include <kern/ledger.h>
+#include <kern/policy_internal.h>
+#include <kern/thread_group.h>
+#include <san/kasan.h>
-#include <default_pager/default_pager_alerts.h>
-#include <default_pager/default_pager_object_server.h>
+#if !CONFIG_EMBEDDED
+#include <i386/misc_protos.h>
+#endif
#include <IOKit/IOHibernatePrivate.h>
-/*
- * vm_compressor_mode has a heirarchy of control to set its value.
- * boot-args are checked first, then device-tree, and finally
- * the default value that is defined below. See vm_fault_init() for
- * the boot-arg & device-tree code.
- */
-
-extern ipc_port_t min_pages_trigger_port;
-extern lck_mtx_t paging_segments_lock;
-#define PSL_LOCK() lck_mtx_lock(&paging_segments_lock)
-#define PSL_UNLOCK() lck_mtx_unlock(&paging_segments_lock)
+extern boolean_t vm_darkwake_mode;
+#if POPCOUNT_THE_COMPRESSED_DATA
+boolean_t popcount_c_segs = TRUE;
-int vm_compressor_mode = VM_PAGER_COMPRESSOR_WITH_SWAP;
-int vm_scale = 16;
+static inline uint32_t
+vmc_pop(uintptr_t ins, int sz)
+{
+ uint32_t rv = 0;
+ if (__probable(popcount_c_segs == FALSE)) {
+ return 0xDEAD707C;
+ }
-int vm_compression_limit = 0;
+ while (sz >= 16) {
+ uint32_t rv1, rv2;
+ uint64_t *ins64 = (uint64_t *) ins;
+ uint64_t *ins642 = (uint64_t *) (ins + 8);
+ rv1 = __builtin_popcountll(*ins64);
+ rv2 = __builtin_popcountll(*ins642);
+ rv += rv1 + rv2;
+ sz -= 16;
+ ins += 16;
+ }
-extern boolean_t vm_swap_up;
-extern void vm_pageout_io_throttle(void);
+ while (sz >= 4) {
+ uint32_t *ins32 = (uint32_t *) ins;
+ rv += __builtin_popcount(*ins32);
+ sz -= 4;
+ ins += 4;
+ }
-#if CHECKSUM_THE_DATA || CHECKSUM_THE_SWAP || CHECKSUM_THE_COMPRESSED_DATA
-extern unsigned int hash_string(char *cp, int len);
+ while (sz > 0) {
+ char *ins8 = (char *)ins;
+ rv += __builtin_popcount(*ins8);
+ sz--;
+ ins++;
+ }
+ return rv;
+}
#endif
-
-struct c_slot {
- uint64_t c_offset:C_SEG_OFFSET_BITS,
- c_size:12,
- c_packed_ptr:36;
-#if CHECKSUM_THE_DATA
- unsigned int c_hash_data;
-#endif
-#if CHECKSUM_THE_COMPRESSED_DATA
- unsigned int c_hash_compressed_data;
+#if VALIDATE_C_SEGMENTS
+boolean_t validate_c_segs = TRUE;
#endif
+/*
+ * vm_compressor_mode has a heirarchy of control to set its value.
+ * boot-args are checked first, then device-tree, and finally
+ * the default value that is defined below. See vm_fault_init() for
+ * the boot-arg & device-tree code.
+ */
-};
-
-#define UNPACK_C_SIZE(cs) ((cs->c_size == (PAGE_SIZE-1)) ? PAGE_SIZE : cs->c_size)
-#define PACK_C_SIZE(cs, size) (cs->c_size = ((size == PAGE_SIZE) ? PAGE_SIZE - 1 : size))
-
-
-struct c_slot_mapping {
- uint32_t s_cseg:22, /* segment number + 1 */
- s_cindx:10; /* index in the segment */
-};
-
-typedef struct c_slot_mapping *c_slot_mapping_t;
-
-
-union c_segu {
- c_segment_t c_seg;
- uint32_t c_segno;
-};
+#if CONFIG_EMBEDDED
+#if CONFIG_FREEZE
+int vm_compressor_mode = VM_PAGER_FREEZER_DEFAULT;
+void *freezer_chead; /* The chead used to track c_segs allocated for the exclusive use of holding just one task's compressed memory.*/
+char *freezer_compressor_scratch_buf = NULL;
-#define C_SLOT_PACK_PTR(ptr) (((uintptr_t)ptr - (uintptr_t) VM_MIN_KERNEL_AND_KEXT_ADDRESS) >> 2)
-#define C_SLOT_UNPACK_PTR(cslot) ((uintptr_t)(cslot->c_packed_ptr << 2) + (uintptr_t) VM_MIN_KERNEL_AND_KEXT_ADDRESS)
+extern int c_freezer_swapout_page_count; /* This count keeps track of the # of compressed pages holding just one task's compressed memory on the swapout queue. This count is used during each freeze i.e. on a per-task basis.*/
+#else /* CONFIG_FREEZE */
+int vm_compressor_mode = VM_PAGER_NOT_CONFIGURED;
+#endif /* CONFIG_FREEZE */
-uint32_t c_segment_count = 0;
+int vm_scale = 1;
-uint64_t c_generation_id = 0;
-uint64_t c_generation_id_flush_barrier;
+#else /* CONFIG_EMBEDDED */
+int vm_compressor_mode = VM_PAGER_COMPRESSOR_WITH_SWAP;
+int vm_scale = 16;
+#endif /* CONFIG_EMBEDDED */
-#define HIBERNATE_FLUSHING_SECS_TO_COMPLETE 120
+int vm_compressor_is_active = 0;
+int vm_compression_limit = 0;
+int vm_compressor_available = 0;
-boolean_t hibernate_no_swapspace = FALSE;
-clock_sec_t hibernate_flushing_deadline = 0;
+extern void vm_pageout_io_throttle(void);
+#if CHECKSUM_THE_DATA || CHECKSUM_THE_SWAP || CHECKSUM_THE_COMPRESSED_DATA
+extern unsigned int hash_string(char *cp, int len);
+static unsigned int vmc_hash(char *, int);
+boolean_t checksum_c_segs = TRUE;
-#if TRACK_BAD_C_SEGMENTS
-queue_head_t c_bad_list_head;
-uint32_t c_bad_count = 0;
+unsigned int
+vmc_hash(char *cp, int len)
+{
+ if (__probable(checksum_c_segs == FALSE)) {
+ return 0xDEAD7A37;
+ }
+ return hash_string(cp, len);
+}
#endif
-queue_head_t c_age_list_head;
-queue_head_t c_swapout_list_head;
-queue_head_t c_swappedin_list_head;
-queue_head_t c_swappedout_list_head;
-queue_head_t c_swappedout_sparse_list_head;
+#define UNPACK_C_SIZE(cs) ((cs->c_size == (PAGE_SIZE-1)) ? PAGE_SIZE : cs->c_size)
+#define PACK_C_SIZE(cs, size) (cs->c_size = ((size == PAGE_SIZE) ? PAGE_SIZE - 1 : size))
-uint32_t c_age_count = 0;
-uint32_t c_swapout_count = 0;
-uint32_t c_swappedin_count = 0;
-uint32_t c_swappedout_count = 0;
-uint32_t c_swappedout_sparse_count = 0;
-queue_head_t c_minor_list_head;
-uint32_t c_minor_count = 0;
+struct c_sv_hash_entry {
+ union {
+ struct {
+ uint32_t c_sv_he_ref;
+ uint32_t c_sv_he_data;
+ } c_sv_he;
+ uint64_t c_sv_he_record;
+ } c_sv_he_un;
+};
-union c_segu *c_segments;
-caddr_t c_segments_next_page;
-boolean_t c_segments_busy;
-uint32_t c_segments_available;
-uint32_t c_segments_limit;
-uint32_t c_segments_nearing_limit;
-uint32_t c_segment_pages_compressed;
-uint32_t c_segment_pages_compressed_limit;
-uint32_t c_segment_pages_compressed_nearing_limit;
-uint32_t c_free_segno_head = (uint32_t)-1;
+#define he_ref c_sv_he_un.c_sv_he.c_sv_he_ref
+#define he_data c_sv_he_un.c_sv_he.c_sv_he_data
+#define he_record c_sv_he_un.c_sv_he_record
-uint32_t vm_compressor_minorcompact_threshold_divisor = 10;
-uint32_t vm_compressor_majorcompact_threshold_divisor = 10;
-uint32_t vm_compressor_unthrottle_threshold_divisor = 10;
-uint32_t vm_compressor_catchup_threshold_divisor = 10;
+#define C_SV_HASH_MAX_MISS 32
+#define C_SV_HASH_SIZE ((1 << 10))
+#define C_SV_HASH_MASK ((1 << 10) - 1)
+#define C_SV_CSEG_ID ((1 << 22) - 1)
-#define C_SEGMENTS_PER_PAGE (PAGE_SIZE / sizeof(union c_segu))
+union c_segu {
+ c_segment_t c_seg;
+ uintptr_t c_segno;
+};
-lck_grp_attr_t vm_compressor_lck_grp_attr;
-lck_attr_t vm_compressor_lck_attr;
-lck_grp_t vm_compressor_lck_grp;
-#if __i386__ || __x86_64__
-lck_mtx_t *c_list_lock;
-#else /* __i386__ || __x86_64__ */
-lck_spin_t *c_list_lock;
-#endif /* __i386__ || __x86_64__ */
+#define C_SLOT_PACK_PTR(ptr) (((uintptr_t)ptr - (uintptr_t) KERNEL_PMAP_HEAP_RANGE_START) >> 2)
+#define C_SLOT_UNPACK_PTR(cslot) ((uintptr_t)(cslot->c_packed_ptr << 2) + (uintptr_t) KERNEL_PMAP_HEAP_RANGE_START)
-lck_rw_t c_master_lock;
-boolean_t decompressions_blocked = FALSE;
-zone_t compressor_segment_zone;
-int c_compressor_swap_trigger = 0;
+uint32_t c_segment_count = 0;
+uint32_t c_segment_count_max = 0;
-uint32_t compressor_cpus;
-char *compressor_scratch_bufs;
+uint64_t c_generation_id = 0;
+uint64_t c_generation_id_flush_barrier;
-clock_sec_t start_of_sample_period_sec = 0;
-clock_nsec_t start_of_sample_period_nsec = 0;
-clock_sec_t start_of_eval_period_sec = 0;
-clock_nsec_t start_of_eval_period_nsec = 0;
-uint32_t sample_period_decompression_count = 0;
-uint32_t sample_period_compression_count = 0;
-uint32_t last_eval_decompression_count = 0;
-uint32_t last_eval_compression_count = 0;
+#define HIBERNATE_FLUSHING_SECS_TO_COMPLETE 120
-#define DECOMPRESSION_SAMPLE_MAX_AGE (60 * 30)
+boolean_t hibernate_no_swapspace = FALSE;
+clock_sec_t hibernate_flushing_deadline = 0;
-uint32_t swapout_target_age = 0;
-uint32_t age_of_decompressions_during_sample_period[DECOMPRESSION_SAMPLE_MAX_AGE];
-uint32_t overage_decompressions_during_sample_period = 0;
-void do_fastwake_warmup(void);
-boolean_t fastwake_warmup = FALSE;
-boolean_t fastwake_recording_in_progress = FALSE;
-clock_sec_t dont_trim_until_ts = 0;
+#if RECORD_THE_COMPRESSED_DATA
+char *c_compressed_record_sbuf;
+char *c_compressed_record_ebuf;
+char *c_compressed_record_cptr;
+#endif
+
+
+queue_head_t c_age_list_head;
+queue_head_t c_swappedin_list_head;
+queue_head_t c_swapout_list_head;
+queue_head_t c_swapio_list_head;
+queue_head_t c_swappedout_list_head;
+queue_head_t c_swappedout_sparse_list_head;
+queue_head_t c_major_list_head;
+queue_head_t c_filling_list_head;
+queue_head_t c_bad_list_head;
+
+uint32_t c_age_count = 0;
+uint32_t c_swappedin_count = 0;
+uint32_t c_swapout_count = 0;
+uint32_t c_swapio_count = 0;
+uint32_t c_swappedout_count = 0;
+uint32_t c_swappedout_sparse_count = 0;
+uint32_t c_major_count = 0;
+uint32_t c_filling_count = 0;
+uint32_t c_empty_count = 0;
+uint32_t c_bad_count = 0;
+
+
+queue_head_t c_minor_list_head;
+uint32_t c_minor_count = 0;
+
+int c_overage_swapped_count = 0;
+int c_overage_swapped_limit = 0;
+
+int c_seg_fixed_array_len;
+union c_segu *c_segments;
+vm_offset_t c_buffers;
+vm_size_t c_buffers_size;
+caddr_t c_segments_next_page;
+boolean_t c_segments_busy;
+uint32_t c_segments_available;
+uint32_t c_segments_limit;
+uint32_t c_segments_nearing_limit;
+
+uint32_t c_segment_svp_in_hash;
+uint32_t c_segment_svp_hash_succeeded;
+uint32_t c_segment_svp_hash_failed;
+uint32_t c_segment_svp_zero_compressions;
+uint32_t c_segment_svp_nonzero_compressions;
+uint32_t c_segment_svp_zero_decompressions;
+uint32_t c_segment_svp_nonzero_decompressions;
+
+uint32_t c_segment_noncompressible_pages;
+
+uint32_t c_segment_pages_compressed;
+uint32_t c_segment_pages_compressed_limit;
+uint32_t c_segment_pages_compressed_nearing_limit;
+uint32_t c_free_segno_head = (uint32_t)-1;
+
+uint32_t vm_compressor_minorcompact_threshold_divisor = 10;
+uint32_t vm_compressor_majorcompact_threshold_divisor = 10;
+uint32_t vm_compressor_unthrottle_threshold_divisor = 10;
+uint32_t vm_compressor_catchup_threshold_divisor = 10;
+
+uint32_t vm_compressor_minorcompact_threshold_divisor_overridden = 0;
+uint32_t vm_compressor_majorcompact_threshold_divisor_overridden = 0;
+uint32_t vm_compressor_unthrottle_threshold_divisor_overridden = 0;
+uint32_t vm_compressor_catchup_threshold_divisor_overridden = 0;
+
+#define C_SEGMENTS_PER_PAGE (PAGE_SIZE / sizeof(union c_segu))
+
+
+lck_grp_attr_t vm_compressor_lck_grp_attr;
+lck_attr_t vm_compressor_lck_attr;
+lck_grp_t vm_compressor_lck_grp;
+lck_mtx_t *c_list_lock;
+lck_rw_t c_master_lock;
+boolean_t decompressions_blocked = FALSE;
+
+zone_t compressor_segment_zone;
+int c_compressor_swap_trigger = 0;
+
+uint32_t compressor_cpus;
+char *compressor_scratch_bufs;
+char *kdp_compressor_scratch_buf;
+char *kdp_compressor_decompressed_page;
+addr64_t kdp_compressor_decompressed_page_paddr;
+ppnum_t kdp_compressor_decompressed_page_ppnum;
+
+clock_sec_t start_of_sample_period_sec = 0;
+clock_nsec_t start_of_sample_period_nsec = 0;
+clock_sec_t start_of_eval_period_sec = 0;
+clock_nsec_t start_of_eval_period_nsec = 0;
+uint32_t sample_period_decompression_count = 0;
+uint32_t sample_period_compression_count = 0;
+uint32_t last_eval_decompression_count = 0;
+uint32_t last_eval_compression_count = 0;
+
+#define DECOMPRESSION_SAMPLE_MAX_AGE (60 * 30)
+
+boolean_t vm_swapout_ripe_segments = FALSE;
+uint32_t vm_ripe_target_age = (60 * 60 * 48);
+
+uint32_t swapout_target_age = 0;
+uint32_t age_of_decompressions_during_sample_period[DECOMPRESSION_SAMPLE_MAX_AGE];
+uint32_t overage_decompressions_during_sample_period = 0;
+
+
+void do_fastwake_warmup(queue_head_t *, boolean_t);
+boolean_t fastwake_warmup = FALSE;
+boolean_t fastwake_recording_in_progress = FALSE;
+clock_sec_t dont_trim_until_ts = 0;
+
+uint64_t c_segment_warmup_count;
+uint64_t first_c_segment_to_warm_generation_id = 0;
+uint64_t last_c_segment_to_warm_generation_id = 0;
+boolean_t hibernate_flushing = FALSE;
+
+int64_t c_segment_input_bytes __attribute__((aligned(8))) = 0;
+int64_t c_segment_compressed_bytes __attribute__((aligned(8))) = 0;
+int64_t compressor_bytes_used __attribute__((aligned(8))) = 0;
-uint64_t c_segment_warmup_count;
-uint64_t first_c_segment_to_warm_generation_id = 0;
-uint64_t last_c_segment_to_warm_generation_id = 0;
-boolean_t hibernate_flushing = FALSE;
-int64_t c_segment_input_bytes __attribute__((aligned(8))) = 0;
-int64_t c_segment_compressed_bytes __attribute__((aligned(8))) = 0;
-int64_t compressor_bytes_used __attribute__((aligned(8))) = 0;
-uint64_t compressor_kvspace_used __attribute__((aligned(8))) = 0;
-uint64_t compressor_kvwaste_limit = 0;
+struct c_sv_hash_entry c_segment_sv_hash_table[C_SV_HASH_SIZE] __attribute__ ((aligned(8)));
static boolean_t compressor_needs_to_swap(void);
static void vm_compressor_swap_trigger_thread(void);
static void vm_compressor_compact_and_swap(boolean_t);
static void vm_compressor_age_swapped_in_segments(boolean_t);
-boolean_t vm_compressor_low_on_space(void);
+#if !CONFIG_EMBEDDED
+static void vm_compressor_take_paging_space_action(void);
+#endif
void compute_swapout_target_age(void);
int c_seg_minor_compaction_and_unlock(c_segment_t, boolean_t);
int c_seg_do_minor_compaction_and_unlock(c_segment_t, boolean_t, boolean_t, boolean_t);
void c_seg_try_minor_compaction_and_unlock(c_segment_t c_seg);
-void c_seg_need_delayed_compaction(c_segment_t);
void c_seg_move_to_sparse_list(c_segment_t);
void c_seg_insert_into_q(queue_head_t *, c_segment_t);
-boolean_t c_seg_try_free(c_segment_t);
-void c_seg_free(c_segment_t);
-void c_seg_free_locked(c_segment_t);
-
-
uint64_t vm_available_memory(void);
uint64_t vm_compressor_pages_compressed(void);
-extern unsigned int dp_pages_free, dp_pages_reserve;
+/*
+ * indicate the need to do a major compaction if
+ * the overall set of in-use compression segments
+ * becomes sparse... on systems that support pressure
+ * driven swapping, this will also cause swapouts to
+ * be initiated.
+ */
+static inline boolean_t
+vm_compressor_needs_to_major_compact()
+{
+ uint32_t incore_seg_count;
+
+ incore_seg_count = c_segment_count - c_swappedout_count - c_swappedout_sparse_count;
+
+ if ((c_segment_count >= (c_segments_nearing_limit / 8)) &&
+ ((incore_seg_count * C_SEG_MAX_PAGES) - VM_PAGE_COMPRESSOR_COUNT) >
+ ((incore_seg_count / 8) * C_SEG_MAX_PAGES)) {
+ return 1;
+ }
+ return 0;
+}
+
uint64_t
vm_available_memory(void)
{
- return (((uint64_t)AVAILABLE_NON_COMPRESSED_MEMORY) * PAGE_SIZE_64);
+ return ((uint64_t)AVAILABLE_NON_COMPRESSED_MEMORY) * PAGE_SIZE_64;
}
uint64_t
vm_compressor_pages_compressed(void)
{
- return (c_segment_pages_compressed * PAGE_SIZE_64);
+ return c_segment_pages_compressed * PAGE_SIZE_64;
}
boolean_t
-vm_compression_available(void)
+vm_compressor_low_on_space(void)
{
- if ( !(COMPRESSED_PAGER_IS_ACTIVE || DEFAULT_FREEZER_COMPRESSED_PAGER_IS_ACTIVE))
- return (FALSE);
-
- if (c_segments_available >= c_segments_limit || c_segment_pages_compressed >= c_segment_pages_compressed_limit)
- return (FALSE);
+ if ((c_segment_pages_compressed > c_segment_pages_compressed_nearing_limit) ||
+ (c_segment_count > c_segments_nearing_limit)) {
+ return TRUE;
+ }
- return (TRUE);
+ return FALSE;
}
boolean_t
-vm_compressor_low_on_space(void)
+vm_compressor_out_of_space(void)
{
- if ((c_segment_pages_compressed > c_segment_pages_compressed_nearing_limit) ||
- (c_segment_count > c_segments_nearing_limit))
- return (TRUE);
+ if ((c_segment_pages_compressed >= c_segment_pages_compressed_limit) ||
+ (c_segment_count >= c_segments_limit)) {
+ return TRUE;
+ }
- return (FALSE);
+ return FALSE;
}
-
+
int
vm_wants_task_throttled(task_t task)
{
- if (task == kernel_task)
- return (0);
+ if (task == kernel_task) {
+ return 0;
+ }
- if (vm_compressor_mode == COMPRESSED_PAGER_IS_ACTIVE || vm_compressor_mode == DEFAULT_FREEZER_COMPRESSED_PAGER_IS_ACTIVE) {
+ if (VM_CONFIG_SWAP_IS_ACTIVE) {
if ((vm_compressor_low_on_space() || HARD_THROTTLE_LIMIT_REACHED()) &&
- (unsigned int)pmap_compressed(task->map->pmap) > (c_segment_pages_compressed / 4))
- return (1);
- } else {
- if (((dp_pages_free + dp_pages_reserve < 2000) && VM_DYNAMIC_PAGING_ENABLED(memory_manager_default)) &&
- get_task_resident_size(task) > (((AVAILABLE_NON_COMPRESSED_MEMORY) * PAGE_SIZE) / 5))
- return (1);
+ (unsigned int)pmap_compressed(task->map->pmap) > (c_segment_pages_compressed / 4)) {
+ return 1;
+ }
+ }
+ return 0;
+}
+
+
+#if DEVELOPMENT || DEBUG
+boolean_t kill_on_no_paging_space = FALSE; /* On compressor/swap exhaustion, kill the largest process regardless of
+ * its chosen process policy. Controlled by a boot-arg of the same name. */
+#endif /* DEVELOPMENT || DEBUG */
+
+#if !CONFIG_EMBEDDED
+
+static uint32_t no_paging_space_action_in_progress = 0;
+extern void memorystatus_send_low_swap_note(void);
+
+static void
+vm_compressor_take_paging_space_action(void)
+{
+ if (no_paging_space_action_in_progress == 0) {
+ if (OSCompareAndSwap(0, 1, (UInt32 *)&no_paging_space_action_in_progress)) {
+ if (no_paging_space_action()) {
+#if DEVELOPMENT || DEBUG
+ if (kill_on_no_paging_space == TRUE) {
+ /*
+ * Since we are choosing to always kill a process, we don't need the
+ * "out of application memory" dialog box in this mode. And, hence we won't
+ * send the knote.
+ */
+ no_paging_space_action_in_progress = 0;
+ return;
+ }
+#endif /* DEVELOPMENT || DEBUG */
+ memorystatus_send_low_swap_note();
+ }
+
+ no_paging_space_action_in_progress = 0;
+ }
}
- return (0);
}
+#endif /* !CONFIG_EMBEDDED */
void
PAGE_REPLACEMENT_ALLOWED(TRUE);
decompressions_blocked = TRUE;
-
+
PAGE_REPLACEMENT_ALLOWED(FALSE);
}
thread_wakeup((event_t)&decompressions_blocked);
}
+static inline void
+cslot_copy(c_slot_t cdst, c_slot_t csrc)
+{
+#if CHECKSUM_THE_DATA
+ cdst->c_hash_data = csrc->c_hash_data;
+#endif
+#if CHECKSUM_THE_COMPRESSED_DATA
+ cdst->c_hash_compressed_data = csrc->c_hash_compressed_data;
+#endif
+#if POPCOUNT_THE_COMPRESSED_DATA
+ cdst->c_pop_cdata = csrc->c_pop_cdata;
+#endif
+ cdst->c_size = csrc->c_size;
+ cdst->c_packed_ptr = csrc->c_packed_ptr;
+#if defined(__arm__) || defined(__arm64__)
+ cdst->c_codec = csrc->c_codec;
+#endif
+}
+
+vm_map_t compressor_map;
+uint64_t compressor_pool_max_size;
+uint64_t compressor_pool_size;
+uint32_t compressor_pool_multiplier;
+#if DEVELOPMENT || DEBUG
+/*
+ * Compressor segments are write-protected in development/debug
+ * kernels to help debug memory corruption.
+ * In cases where performance is a concern, this can be disabled
+ * via the boot-arg "-disable_cseg_write_protection".
+ */
+boolean_t write_protect_c_segs = TRUE;
+int vm_compressor_test_seg_wp;
+uint32_t vm_ktrace_enabled;
+#endif /* DEVELOPMENT || DEBUG */
void
vm_compressor_init(void)
{
- thread_t thread;
- struct c_slot cs_dummy;
+ thread_t thread;
+ struct c_slot cs_dummy;
c_slot_t cs = &cs_dummy;
+ int c_segment_min_size;
+ int c_segment_padded_size;
+ int attempts = 1;
+ kern_return_t retval = KERN_SUCCESS;
+ vm_offset_t start_addr = 0;
+ vm_size_t c_segments_arr_size = 0, compressor_submap_size = 0;
+ vm_map_kernel_flags_t vmk_flags;
+#if RECORD_THE_COMPRESSED_DATA
+ vm_size_t c_compressed_record_sbuf_size = 0;
+#endif /* RECORD_THE_COMPRESSED_DATA */
+
+#if DEVELOPMENT || DEBUG
+ char bootarg_name[32];
+ if (PE_parse_boot_argn("-kill_on_no_paging_space", bootarg_name, sizeof(bootarg_name))) {
+ kill_on_no_paging_space = TRUE;
+ }
+ if (PE_parse_boot_argn("-disable_cseg_write_protection", bootarg_name, sizeof(bootarg_name))) {
+ write_protect_c_segs = FALSE;
+ }
+ int vmcval = 1;
+ PE_parse_boot_argn("vm_compressor_validation", &vmcval, sizeof(vmcval));
+
+ if (kern_feature_override(KF_COMPRSV_OVRD)) {
+ vmcval = 0;
+ }
+ if (vmcval == 0) {
+#if POPCOUNT_THE_COMPRESSED_DATA
+ popcount_c_segs = FALSE;
+#endif
+#if CHECKSUM_THE_DATA || CHECKSUM_THE_COMPRESSED_DATA
+ checksum_c_segs = FALSE;
+#endif
+#if VALIDATE_C_SEGMENTS
+ validate_c_segs = FALSE;
+#endif
+ write_protect_c_segs = FALSE;
+ }
+#endif /* DEVELOPMENT || DEBUG */
/*
* ensure that any pointer that gets created from
*/
cs->c_packed_ptr = C_SLOT_PACK_PTR(zone_map_min_address);
- if (C_SLOT_UNPACK_PTR(cs) != (uintptr_t)zone_map_min_address)
+ if (C_SLOT_UNPACK_PTR(cs) != (uintptr_t)zone_map_min_address) {
panic("C_SLOT_UNPACK_PTR failed on zone_map_min_address - %p", (void *)zone_map_min_address);
+ }
cs->c_packed_ptr = C_SLOT_PACK_PTR(zone_map_max_address);
- if (C_SLOT_UNPACK_PTR(cs) != (uintptr_t)zone_map_max_address)
+ if (C_SLOT_UNPACK_PTR(cs) != (uintptr_t)zone_map_max_address) {
panic("C_SLOT_UNPACK_PTR failed on zone_map_max_address - %p", (void *)zone_map_max_address);
+ }
assert((C_SEGMENTS_PER_PAGE * sizeof(union c_segu)) == PAGE_SIZE);
- PE_parse_boot_argn("vm_compression_limit", &vm_compression_limit, sizeof (vm_compression_limit));
+ PE_parse_boot_argn("vm_compression_limit", &vm_compression_limit, sizeof(vm_compression_limit));
+#ifdef CONFIG_EMBEDDED
+ vm_compressor_minorcompact_threshold_divisor = 20;
+ vm_compressor_majorcompact_threshold_divisor = 30;
+ vm_compressor_unthrottle_threshold_divisor = 40;
+ vm_compressor_catchup_threshold_divisor = 60;
+#else
if (max_mem <= (3ULL * 1024ULL * 1024ULL * 1024ULL)) {
vm_compressor_minorcompact_threshold_divisor = 11;
vm_compressor_majorcompact_threshold_divisor = 13;
vm_compressor_unthrottle_threshold_divisor = 35;
vm_compressor_catchup_threshold_divisor = 50;
}
+#endif
/*
* vm_page_init_lck_grp is now responsible for calling vm_compressor_init_locks
* c_master_lock needs to be available early so that "vm_page_find_contiguous" can
* use PAGE_REPLACEMENT_ALLOWED to coordinate with the compressor.
*/
-#if __i386__ || __x86_64__
c_list_lock = lck_mtx_alloc_init(&vm_compressor_lck_grp, &vm_compressor_lck_attr);
-#else /* __i386__ || __x86_64__ */
- c_list_lock = lck_spin_alloc_init(&vm_compressor_lck_grp, &vm_compressor_lck_attr);
-#endif /* __i386__ || __x86_64__ */
-#if TRACK_BAD_C_SEGMENTS
queue_init(&c_bad_list_head);
-#endif
queue_init(&c_age_list_head);
queue_init(&c_minor_list_head);
+ queue_init(&c_major_list_head);
+ queue_init(&c_filling_list_head);
queue_init(&c_swapout_list_head);
+ queue_init(&c_swapio_list_head);
queue_init(&c_swappedin_list_head);
queue_init(&c_swappedout_list_head);
queue_init(&c_swappedout_sparse_list_head);
- compressor_segment_zone = zinit(sizeof (struct c_segment),
- 128000 * sizeof (struct c_segment),
- 8192, "compressor_segment");
- zone_change(compressor_segment_zone, Z_CALLERACCT, FALSE);
- zone_change(compressor_segment_zone, Z_NOENCRYPT, TRUE);
-
-
c_free_segno_head = -1;
c_segments_available = 0;
- if (vm_compression_limit == 0) {
- c_segment_pages_compressed_limit = (uint32_t)((max_mem / PAGE_SIZE)) * vm_scale;
+ if (vm_compression_limit) {
+ compressor_pool_size = (uint64_t)vm_compression_limit * PAGE_SIZE_64;
+ }
+
+ compressor_pool_max_size = C_SEG_MAX_LIMIT;
+ compressor_pool_max_size *= C_SEG_BUFSIZE;
-#define OLD_SWAP_LIMIT (1024 * 1024 * 16)
-#define MAX_SWAP_LIMIT (1024 * 1024 * 128)
-
- if (c_segment_pages_compressed_limit > (OLD_SWAP_LIMIT))
- c_segment_pages_compressed_limit = OLD_SWAP_LIMIT;
+#if defined(__x86_64__)
- if (c_segment_pages_compressed_limit < (uint32_t)(max_mem / PAGE_SIZE_64))
- c_segment_pages_compressed_limit = (uint32_t)(max_mem / PAGE_SIZE_64);
+ if (vm_compression_limit == 0) {
+ if (max_mem <= (4ULL * 1024ULL * 1024ULL * 1024ULL)) {
+ compressor_pool_size = 16ULL * max_mem;
+ } else if (max_mem <= (8ULL * 1024ULL * 1024ULL * 1024ULL)) {
+ compressor_pool_size = 8ULL * max_mem;
+ } else if (max_mem <= (32ULL * 1024ULL * 1024ULL * 1024ULL)) {
+ compressor_pool_size = 4ULL * max_mem;
+ } else {
+ compressor_pool_size = 2ULL * max_mem;
+ }
+ }
+ if (max_mem <= (8ULL * 1024ULL * 1024ULL * 1024ULL)) {
+ compressor_pool_multiplier = 1;
+ } else if (max_mem <= (32ULL * 1024ULL * 1024ULL * 1024ULL)) {
+ compressor_pool_multiplier = 2;
} else {
- if (vm_compression_limit < MAX_SWAP_LIMIT)
- c_segment_pages_compressed_limit = vm_compression_limit;
- else
- c_segment_pages_compressed_limit = MAX_SWAP_LIMIT;
+ compressor_pool_multiplier = 4;
}
- if ((c_segments_limit = c_segment_pages_compressed_limit / (C_SEG_BUFSIZE / PAGE_SIZE)) > C_SEG_MAX_LIMIT)
- c_segments_limit = C_SEG_MAX_LIMIT;
- c_segment_pages_compressed_nearing_limit = (c_segment_pages_compressed_limit * 98) / 100;
- c_segments_nearing_limit = (c_segments_limit * 98) / 100;
+#elif defined(__arm__)
- compressor_kvwaste_limit = (vm_map_max(kernel_map) - vm_map_min(kernel_map)) / 16;
+#define VM_RESERVE_SIZE (1024 * 1024 * 256)
+#define MAX_COMPRESSOR_POOL_SIZE (1024 * 1024 * 450)
- c_segments_busy = FALSE;
+ if (compressor_pool_max_size > MAX_COMPRESSOR_POOL_SIZE) {
+ compressor_pool_max_size = MAX_COMPRESSOR_POOL_SIZE;
+ }
+
+ if (vm_compression_limit == 0) {
+ compressor_pool_size = ((kernel_map->max_offset - kernel_map->min_offset) - kernel_map->size) - VM_RESERVE_SIZE;
+ }
+ compressor_pool_multiplier = 1;
+#else
+ if (compressor_pool_max_size > max_mem) {
+ compressor_pool_max_size = max_mem;
+ }
+
+ if (vm_compression_limit == 0) {
+ compressor_pool_size = max_mem;
+ }
+ compressor_pool_multiplier = 1;
+#endif
+ if (compressor_pool_size > compressor_pool_max_size) {
+ compressor_pool_size = compressor_pool_max_size;
+ }
+
+try_again:
+ c_segments_limit = (uint32_t)(compressor_pool_size / (vm_size_t)(C_SEG_ALLOCSIZE));
+ c_segments_nearing_limit = (uint32_t)(((uint64_t)c_segments_limit * 98ULL) / 100ULL);
+
+ c_segment_pages_compressed_limit = (c_segments_limit * (C_SEG_BUFSIZE / PAGE_SIZE) * compressor_pool_multiplier);
+
+ if (c_segment_pages_compressed_limit < (uint32_t)(max_mem / PAGE_SIZE)) {
+ c_segment_pages_compressed_limit = (uint32_t)(max_mem / PAGE_SIZE);
+ }
+
+ c_segment_pages_compressed_nearing_limit = (uint32_t)(((uint64_t)c_segment_pages_compressed_limit * 98ULL) / 100ULL);
+
+ /*
+ * Submap needs space for:
+ * - c_segments
+ * - c_buffers
+ * - swap reclaimations -- C_SEG_BUFSIZE
+ */
+ c_segments_arr_size = vm_map_round_page((sizeof(union c_segu) * c_segments_limit), VM_MAP_PAGE_MASK(kernel_map));
+ c_buffers_size = vm_map_round_page(((vm_size_t)C_SEG_ALLOCSIZE * (vm_size_t)c_segments_limit), VM_MAP_PAGE_MASK(kernel_map));
+
+ compressor_submap_size = c_segments_arr_size + c_buffers_size + C_SEG_BUFSIZE;
+
+#if RECORD_THE_COMPRESSED_DATA
+ c_compressed_record_sbuf_size = (vm_size_t)C_SEG_ALLOCSIZE + (PAGE_SIZE * 2);
+ compressor_submap_size += c_compressed_record_sbuf_size;
+#endif /* RECORD_THE_COMPRESSED_DATA */
+
+ vmk_flags = VM_MAP_KERNEL_FLAGS_NONE;
+ vmk_flags.vmkf_permanent = TRUE;
+ retval = kmem_suballoc(kernel_map, &start_addr, compressor_submap_size,
+ FALSE, VM_FLAGS_ANYWHERE, vmk_flags, VM_KERN_MEMORY_COMPRESSOR,
+ &compressor_map);
+
+ if (retval != KERN_SUCCESS) {
+ if (++attempts > 3) {
+ panic("vm_compressor_init: kmem_suballoc failed - 0x%llx", (uint64_t)compressor_submap_size);
+ }
+
+ compressor_pool_size = compressor_pool_size / 2;
+
+ kprintf("retrying creation of the compressor submap at 0x%llx bytes\n", compressor_pool_size);
+ goto try_again;
+ }
+ if (kernel_memory_allocate(compressor_map, (vm_offset_t *)(&c_segments), (sizeof(union c_segu) * c_segments_limit), 0, KMA_KOBJECT | KMA_VAONLY | KMA_PERMANENT, VM_KERN_MEMORY_COMPRESSOR) != KERN_SUCCESS) {
+ panic("vm_compressor_init: kernel_memory_allocate failed - c_segments\n");
+ }
+ if (kernel_memory_allocate(compressor_map, &c_buffers, c_buffers_size, 0, KMA_COMPRESSOR | KMA_VAONLY | KMA_PERMANENT, VM_KERN_MEMORY_COMPRESSOR) != KERN_SUCCESS) {
+ panic("vm_compressor_init: kernel_memory_allocate failed - c_buffers\n");
+ }
+
+
+ c_segment_min_size = sizeof(struct c_segment) + (C_SEG_SLOT_VAR_ARRAY_MIN_LEN * sizeof(struct c_slot));
- if (kernel_memory_allocate(kernel_map, (vm_offset_t *)(&c_segments), (sizeof(union c_segu) * c_segments_limit), 0, KMA_KOBJECT | KMA_VAONLY) != KERN_SUCCESS)
- panic("vm_compressor_init: kernel_memory_allocate failed\n");
+ for (c_segment_padded_size = 128; c_segment_padded_size < c_segment_min_size; c_segment_padded_size = c_segment_padded_size << 1) {
+ ;
+ }
+
+ compressor_segment_zone = zinit(c_segment_padded_size, c_segments_limit * c_segment_padded_size, PAGE_SIZE, "compressor_segment");
+ zone_change(compressor_segment_zone, Z_CALLERACCT, FALSE);
+ zone_change(compressor_segment_zone, Z_NOENCRYPT, TRUE);
+
+ c_seg_fixed_array_len = (c_segment_padded_size - sizeof(struct c_segment)) / sizeof(struct c_slot);
+
+ c_segments_busy = FALSE;
c_segments_next_page = (caddr_t)c_segments;
+ vm_compressor_algorithm_init();
{
host_basic_info_data_t hinfo;
host_info((host_t)BSD_HOST, HOST_BASIC_INFO, (host_info_t)&hinfo, &count);
compressor_cpus = hinfo.max_cpus;
+ compressor_scratch_bufs = kalloc_tag(compressor_cpus * vm_compressor_get_decode_scratch_size(), VM_KERN_MEMORY_COMPRESSOR);
+
+ kdp_compressor_scratch_buf = kalloc_tag(vm_compressor_get_decode_scratch_size(), VM_KERN_MEMORY_COMPRESSOR);
- compressor_scratch_bufs = kalloc(compressor_cpus * WKdm_SCRATCH_BUF_SIZE);
+ /*
+ * kdp_compressor_decompressed_page must be page aligned because we access
+ * it through the physical apperture by page number. kalloc() does not
+ * guarantee alignment.
+ */
+ vm_offset_t addr;
+ if (kernel_memory_allocate(kernel_map, &addr, PAGE_SIZE, 0, KMA_KOBJECT, VM_KERN_MEMORY_COMPRESSOR) != KERN_SUCCESS) {
+ panic("vm_compressor_init: kernel_memory_allocate failed - kdp_compressor_decompressed_page\n");
+ }
+ assert((addr & PAGE_MASK) == 0);
+ kdp_compressor_decompressed_page = (void *)addr;
+ kdp_compressor_decompressed_page_paddr = kvtophys((vm_offset_t)kdp_compressor_decompressed_page);
+ kdp_compressor_decompressed_page_ppnum = (ppnum_t) atop(kdp_compressor_decompressed_page_paddr);
+ }
+#if CONFIG_FREEZE
+ freezer_compressor_scratch_buf = kalloc_tag(vm_compressor_get_encode_scratch_size(), VM_KERN_MEMORY_COMPRESSOR);
+#endif
+
+#if RECORD_THE_COMPRESSED_DATA
+ if (kernel_memory_allocate(compressor_map, (vm_offset_t *)&c_compressed_record_sbuf, c_compressed_record_sbuf_size, 0, KMA_KOBJECT, VM_KERN_MEMORY_COMPRESSOR) != KERN_SUCCESS) {
+ panic("vm_compressor_init: kernel_memory_allocate failed - c_compressed_record_sbuf\n");
}
+ c_compressed_record_cptr = c_compressed_record_sbuf;
+ c_compressed_record_ebuf = c_compressed_record_sbuf + c_compressed_record_sbuf_size;
+#endif
+
if (kernel_thread_start_priority((thread_continue_t)vm_compressor_swap_trigger_thread, NULL,
- BASEPRI_PREEMPT - 1, &thread) != KERN_SUCCESS) {
+ BASEPRI_VM, &thread) != KERN_SUCCESS) {
panic("vm_compressor_swap_trigger_thread: create failed");
}
- thread->options |= TH_OPT_VMPRIV;
-
thread_deallocate(thread);
- assert(default_pager_init_flag == 0);
-
if (vm_pageout_internal_start() != KERN_SUCCESS) {
panic("vm_compressor_init: Failed to start the internal pageout thread.\n");
}
-
- if ((vm_compressor_mode == VM_PAGER_COMPRESSOR_WITH_SWAP) ||
- (vm_compressor_mode == VM_PAGER_FREEZER_COMPRESSOR_WITH_SWAP)) {
+ if (VM_CONFIG_SWAP_IS_PRESENT) {
vm_compressor_swap_init();
}
+ if (VM_CONFIG_COMPRESSOR_IS_ACTIVE) {
+ vm_compressor_is_active = 1;
+ }
+
#if CONFIG_FREEZE
memorystatus_freeze_enabled = TRUE;
#endif /* CONFIG_FREEZE */
- default_pager_init_flag = 1;
+ vm_compressor_available = 1;
vm_page_reactivate_all_throttled();
}
static void
c_seg_validate(c_segment_t c_seg, boolean_t must_be_compact)
{
- int c_indx;
- int32_t bytes_used;
- int32_t bytes_unused;
- uint32_t c_rounded_size;
- uint32_t c_size;
- c_slot_t cs;
+ int c_indx;
+ int32_t bytes_used;
+ uint32_t c_rounded_size;
+ uint32_t c_size;
+ c_slot_t cs;
+ if (__probable(validate_c_segs == FALSE)) {
+ return;
+ }
if (c_seg->c_firstemptyslot < c_seg->c_nextslot) {
c_indx = c_seg->c_firstemptyslot;
cs = C_SEG_SLOT_FROM_INDEX(c_seg, c_indx);
- if (cs == NULL)
+ if (cs == NULL) {
panic("c_seg_validate: no slot backing c_firstemptyslot");
-
- if (cs->c_size)
+ }
+
+ if (cs->c_size) {
panic("c_seg_validate: c_firstemptyslot has non-zero size (%d)\n", cs->c_size);
+ }
}
bytes_used = 0;
- bytes_unused = 0;
for (c_indx = 0; c_indx < c_seg->c_nextslot; c_indx++) {
-
cs = C_SEG_SLOT_FROM_INDEX(c_seg, c_indx);
c_size = UNPACK_C_SIZE(cs);
bytes_used += c_rounded_size;
#if CHECKSUM_THE_COMPRESSED_DATA
- if (c_size && cs->c_hash_compressed_data != hash_string((char *)&c_seg->c_store.c_buffer[cs->c_offset], c_size))
- panic("compressed data doesn't match original");
+ unsigned csvhash;
+ if (c_size && cs->c_hash_compressed_data != (csvhash = vmc_hash((char *)&c_seg->c_store.c_buffer[cs->c_offset], c_size))) {
+ addr64_t csvphys = kvtophys((vm_offset_t)&c_seg->c_store.c_buffer[cs->c_offset]);
+ panic("Compressed data doesn't match original %p phys: 0x%llx %d %p %d %d 0x%x 0x%x", c_seg, csvphys, cs->c_offset, cs, c_indx, c_size, cs->c_hash_compressed_data, csvhash);
+ }
+#endif
+#if POPCOUNT_THE_COMPRESSED_DATA
+ unsigned csvpop;
+ if (c_size) {
+ uintptr_t csvaddr = (uintptr_t) &c_seg->c_store.c_buffer[cs->c_offset];
+ if (cs->c_pop_cdata != (csvpop = vmc_pop(csvaddr, c_size))) {
+ panic("Compressed data popcount doesn't match original, bit distance: %d %p (phys: %p) %p %p 0x%llx 0x%x 0x%x 0x%x", (csvpop - cs->c_pop_cdata), (void *)csvaddr, (void *) kvtophys(csvaddr), c_seg, cs, cs->c_offset, c_size, csvpop, cs->c_pop_cdata);
+ }
+ }
#endif
}
- if (bytes_used != c_seg->c_bytes_used)
+ if (bytes_used != c_seg->c_bytes_used) {
panic("c_seg_validate: bytes_used mismatch - found %d, segment has %d\n", bytes_used, c_seg->c_bytes_used);
+ }
- if (c_seg->c_bytes_used > C_SEG_OFFSET_TO_BYTES((int32_t)c_seg->c_nextoffset))
+ if (c_seg->c_bytes_used > C_SEG_OFFSET_TO_BYTES((int32_t)c_seg->c_nextoffset)) {
panic("c_seg_validate: c_bytes_used > c_nextoffset - c_nextoffset = %d, c_bytes_used = %d\n",
- (int32_t)C_SEG_OFFSET_TO_BYTES((int32_t)c_seg->c_nextoffset), c_seg->c_bytes_used);
+ (int32_t)C_SEG_OFFSET_TO_BYTES((int32_t)c_seg->c_nextoffset), c_seg->c_bytes_used);
+ }
if (must_be_compact) {
- if (c_seg->c_bytes_used != C_SEG_OFFSET_TO_BYTES((int32_t)c_seg->c_nextoffset))
+ if (c_seg->c_bytes_used != C_SEG_OFFSET_TO_BYTES((int32_t)c_seg->c_nextoffset)) {
panic("c_seg_validate: c_bytes_used doesn't match c_nextoffset - c_nextoffset = %d, c_bytes_used = %d\n",
- (int32_t)C_SEG_OFFSET_TO_BYTES((int32_t)c_seg->c_nextoffset), c_seg->c_bytes_used);
+ (int32_t)C_SEG_OFFSET_TO_BYTES((int32_t)c_seg->c_nextoffset), c_seg->c_bytes_used);
+ }
}
}
void
-c_seg_need_delayed_compaction(c_segment_t c_seg)
+c_seg_need_delayed_compaction(c_segment_t c_seg, boolean_t c_list_lock_held)
{
- boolean_t clear_busy = FALSE;
+ boolean_t clear_busy = FALSE;
- if ( !lck_mtx_try_lock_spin_always(c_list_lock)) {
- C_SEG_BUSY(c_seg);
-
- lck_mtx_unlock_always(&c_seg->c_lock);
- lck_mtx_lock_spin_always(c_list_lock);
- lck_mtx_lock_spin_always(&c_seg->c_lock);
+ if (c_list_lock_held == FALSE) {
+ if (!lck_mtx_try_lock_spin_always(c_list_lock)) {
+ C_SEG_BUSY(c_seg);
- clear_busy = TRUE;
+ lck_mtx_unlock_always(&c_seg->c_lock);
+ lck_mtx_lock_spin_always(c_list_lock);
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
+
+ clear_busy = TRUE;
+ }
}
- if (!c_seg->c_on_minorcompact_q && !c_seg->c_ondisk && !c_seg->c_on_swapout_q) {
+ assert(c_seg->c_state != C_IS_FILLING);
+
+ if (!c_seg->c_on_minorcompact_q && !(C_SEG_IS_ON_DISK_OR_SOQ(c_seg))) {
queue_enter(&c_minor_list_head, c_seg, c_segment_t, c_list);
c_seg->c_on_minorcompact_q = 1;
c_minor_count++;
}
- lck_mtx_unlock_always(c_list_lock);
-
- if (clear_busy == TRUE)
+ if (c_list_lock_held == FALSE) {
+ lck_mtx_unlock_always(c_list_lock);
+ }
+
+ if (clear_busy == TRUE) {
C_SEG_WAKEUP_DONE(c_seg);
+ }
}
void
c_seg_move_to_sparse_list(c_segment_t c_seg)
{
- boolean_t clear_busy = FALSE;
+ boolean_t clear_busy = FALSE;
- if ( !lck_mtx_try_lock_spin_always(c_list_lock)) {
+ if (!lck_mtx_try_lock_spin_always(c_list_lock)) {
C_SEG_BUSY(c_seg);
lck_mtx_unlock_always(&c_seg->c_lock);
lck_mtx_lock_spin_always(c_list_lock);
lck_mtx_lock_spin_always(&c_seg->c_lock);
-
+
clear_busy = TRUE;
}
- assert(c_seg->c_ondisk);
- assert(c_seg->c_on_swappedout_q);
- assert(!c_seg->c_on_swappedout_sparse_q);
-
- queue_remove(&c_swappedout_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swappedout_q = 0;
- c_swappedout_count--;
-
- c_seg_insert_into_q(&c_swappedout_sparse_list_head, c_seg);
- c_seg->c_on_swappedout_sparse_q = 1;
- c_swappedout_sparse_count++;
+ c_seg_switch_state(c_seg, C_ON_SWAPPEDOUTSPARSE_Q, FALSE);
c_seg_moved_to_sparse_list++;
lck_mtx_unlock_always(c_list_lock);
- if (clear_busy == TRUE)
+ if (clear_busy == TRUE) {
C_SEG_WAKEUP_DONE(c_seg);
+ }
}
c_seg_next = (c_segment_t)queue_first(qhead);
while (TRUE) {
-
if (c_seg->c_generation_id < c_seg_next->c_generation_id) {
queue_insert_before(qhead, c_seg, c_seg_next, c_segment_t, c_age_list);
break;
}
c_seg_next = (c_segment_t) queue_next(&c_seg_next->c_age_list);
-
+
if (queue_end(qhead, (queue_entry_t) c_seg_next)) {
queue_enter(qhead, c_seg, c_segment_t, c_age_list);
break;
void
c_seg_try_minor_compaction_and_unlock(c_segment_t c_seg)
{
-
assert(c_seg->c_on_minorcompact_q);
/*
* c_seg is currently on the delayed minor compaction
* because the lock order is c_list_lock then c_seg's lock)
* we'll pull it from the delayed list and free it directly
*/
- if ( !lck_mtx_try_lock_spin_always(c_list_lock)) {
+ if (!lck_mtx_try_lock_spin_always(c_list_lock)) {
/*
* c_list_lock is held, we need to bail
*/
int
c_seg_do_minor_compaction_and_unlock(c_segment_t c_seg, boolean_t clear_busy, boolean_t need_list_lock, boolean_t disallow_page_replacement)
{
- int c_seg_freed;
+ int c_seg_freed;
assert(c_seg->c_busy);
+ assert(!C_SEG_IS_ON_DISK_OR_SOQ(c_seg));
+ /*
+ * check for the case that can occur when we are not swapping
+ * and this segment has been major compacted in the past
+ * and moved to the majorcompact q to remove it from further
+ * consideration... if the occupancy falls too low we need
+ * to put it back on the age_q so that it will be considered
+ * in the next major compaction sweep... if we don't do this
+ * we will eventually run into the c_segments_limit
+ */
+ if (c_seg->c_state == C_ON_MAJORCOMPACT_Q && C_SEG_SHOULD_MAJORCOMPACT_NOW(c_seg)) {
+ c_seg_switch_state(c_seg, C_ON_AGE_Q, FALSE);
+ }
if (!c_seg->c_on_minorcompact_q) {
- if (clear_busy == TRUE)
+ if (clear_busy == TRUE) {
C_SEG_WAKEUP_DONE(c_seg);
+ }
lck_mtx_unlock_always(&c_seg->c_lock);
- return (0);
+ return 0;
}
queue_remove(&c_minor_list_head, c_seg, c_segment_t, c_list);
c_seg->c_on_minorcompact_q = 0;
c_minor_count--;
-
+
lck_mtx_unlock_always(c_list_lock);
if (disallow_page_replacement == TRUE) {
}
c_seg_freed = c_seg_minor_compaction_and_unlock(c_seg, clear_busy);
- if (disallow_page_replacement == TRUE)
+ if (disallow_page_replacement == TRUE) {
PAGE_REPLACEMENT_DISALLOWED(FALSE);
+ }
- if (need_list_lock == TRUE)
+ if (need_list_lock == TRUE) {
lck_mtx_lock_spin_always(c_list_lock);
+ }
- return (c_seg_freed);
+ return c_seg_freed;
}
}
-
-int try_free_succeeded = 0;
-int try_free_failed = 0;
-
-boolean_t
-c_seg_try_free(c_segment_t c_seg)
+void
+c_seg_switch_state(c_segment_t c_seg, int new_state, boolean_t insert_head)
{
- /*
- * c_seg is currently on the delayed minor compaction
- * or the spapped out sparse queue and we have c_seg locked...
- * if we can get the c_list_lock w/o blocking (if we blocked we
- * could deadlock because the lock order is c_list_lock then c_seg's lock)
- * we'll pull it from the appropriate queue and free it
- */
- if ( !lck_mtx_try_lock_spin_always(c_list_lock)) {
- /*
- * c_list_lock is held, we need to bail
- */
- try_free_failed++;
- return (FALSE);
- }
- if (c_seg->c_on_minorcompact_q) {
- queue_remove(&c_minor_list_head, c_seg, c_segment_t, c_list);
- c_seg->c_on_minorcompact_q = 0;
- c_minor_count--;
- } else {
- assert(c_seg->c_on_swappedout_sparse_q);
+ int old_state = c_seg->c_state;
- /*
- * c_seg_free_locked will remove it from the swappedout sparse list
- */
+#if __i386__ || __x86_64__
+ if (new_state != C_IS_FILLING) {
+ LCK_MTX_ASSERT(&c_seg->c_lock, LCK_MTX_ASSERT_OWNED);
}
- if (!c_seg->c_busy_swapping)
- C_SEG_BUSY(c_seg);
-
- c_seg_free_locked(c_seg);
+ LCK_MTX_ASSERT(c_list_lock, LCK_MTX_ASSERT_OWNED);
+#endif
+ switch (old_state) {
+ case C_IS_EMPTY:
+ assert(new_state == C_IS_FILLING || new_state == C_IS_FREE);
- try_free_succeeded++;
+ c_empty_count--;
+ break;
- return (TRUE);
-}
+ case C_IS_FILLING:
+ assert(new_state == C_ON_AGE_Q || new_state == C_ON_SWAPOUT_Q);
+ queue_remove(&c_filling_list_head, c_seg, c_segment_t, c_age_list);
+ c_filling_count--;
+ break;
-void
-c_seg_free(c_segment_t c_seg)
-{
- assert(c_seg->c_busy);
+ case C_ON_AGE_Q:
+ assert(new_state == C_ON_SWAPOUT_Q || new_state == C_ON_MAJORCOMPACT_Q ||
+ new_state == C_IS_FREE);
- lck_mtx_unlock_always(&c_seg->c_lock);
- lck_mtx_lock_spin_always(c_list_lock);
- lck_mtx_lock_spin_always(&c_seg->c_lock);
+ queue_remove(&c_age_list_head, c_seg, c_segment_t, c_age_list);
+ c_age_count--;
+ break;
- c_seg_free_locked(c_seg);
-}
+ case C_ON_SWAPPEDIN_Q:
+ assert(new_state == C_ON_AGE_Q || new_state == C_IS_FREE);
-
-void
-c_seg_free_locked(c_segment_t c_seg)
-{
- int segno, i;
- int pages_populated;
- int32_t *c_buffer = NULL;
- uint64_t c_swap_handle;
-
- assert(!c_seg->c_on_minorcompact_q);
-
- if (c_seg->c_on_age_q) {
- queue_remove(&c_age_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_age_q = 0;
- c_age_count--;
- } else if (c_seg->c_on_swappedin_q) {
queue_remove(&c_swappedin_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swappedin_q = 0;
c_swappedin_count--;
- } else if (c_seg->c_on_swapout_q) {
+ break;
+
+ case C_ON_SWAPOUT_Q:
+ assert(new_state == C_ON_AGE_Q || new_state == C_IS_FREE || new_state == C_IS_EMPTY || new_state == C_ON_SWAPIO_Q);
+
queue_remove(&c_swapout_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swapout_q = 0;
- c_swapout_count--;
thread_wakeup((event_t)&compaction_swapper_running);
- } else if (c_seg->c_on_swappedout_q) {
+ c_swapout_count--;
+ break;
+
+ case C_ON_SWAPIO_Q:
+ assert(new_state == C_ON_SWAPPEDOUT_Q || new_state == C_ON_SWAPPEDOUTSPARSE_Q || new_state == C_ON_AGE_Q);
+
+ queue_remove(&c_swapio_list_head, c_seg, c_segment_t, c_age_list);
+ c_swapio_count--;
+ break;
+
+ case C_ON_SWAPPEDOUT_Q:
+ assert(new_state == C_ON_SWAPPEDIN_Q || new_state == C_ON_AGE_Q ||
+ new_state == C_ON_SWAPPEDOUTSPARSE_Q ||
+ new_state == C_ON_BAD_Q || new_state == C_IS_EMPTY || new_state == C_IS_FREE);
+
queue_remove(&c_swappedout_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swappedout_q = 0;
c_swappedout_count--;
- } else if (c_seg->c_on_swappedout_sparse_q) {
+ break;
+
+ case C_ON_SWAPPEDOUTSPARSE_Q:
+ assert(new_state == C_ON_SWAPPEDIN_Q || new_state == C_ON_AGE_Q ||
+ new_state == C_ON_BAD_Q || new_state == C_IS_EMPTY || new_state == C_IS_FREE);
+
queue_remove(&c_swappedout_sparse_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swappedout_sparse_q = 0;
c_swappedout_sparse_count--;
- }
-#if TRACK_BAD_C_SEGMENTS
- else if (c_seg->c_on_bad_q) {
+ break;
+
+ case C_ON_MAJORCOMPACT_Q:
+ assert(new_state == C_ON_AGE_Q || new_state == C_IS_FREE);
+
+ queue_remove(&c_major_list_head, c_seg, c_segment_t, c_age_list);
+ c_major_count--;
+ break;
+
+ case C_ON_BAD_Q:
+ assert(new_state == C_IS_FREE);
+
queue_remove(&c_bad_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_bad_q = 0;
c_bad_count--;
+ break;
+
+ default:
+ panic("c_seg %p has bad c_state = %d\n", c_seg, old_state);
}
-#endif
- segno = c_seg->c_mysegno;
- c_segments[segno].c_segno = c_free_segno_head;
- c_free_segno_head = segno;
- c_segment_count--;
- lck_mtx_unlock_always(c_list_lock);
+ switch (new_state) {
+ case C_IS_FREE:
+ assert(old_state != C_IS_FILLING);
- if (c_seg->c_wanted) {
- thread_wakeup((event_t) (c_seg));
- c_seg->c_wanted = 0;
- }
- if (c_seg->c_busy_swapping) {
- c_seg->c_must_free = 1;
+ break;
- lck_mtx_unlock_always(&c_seg->c_lock);
- return;
+ case C_IS_EMPTY:
+ assert(old_state == C_ON_SWAPOUT_Q || old_state == C_ON_SWAPPEDOUT_Q || old_state == C_ON_SWAPPEDOUTSPARSE_Q);
+
+ c_empty_count++;
+ break;
+
+ case C_IS_FILLING:
+ assert(old_state == C_IS_EMPTY);
+
+ queue_enter(&c_filling_list_head, c_seg, c_segment_t, c_age_list);
+ c_filling_count++;
+ break;
+
+ case C_ON_AGE_Q:
+ assert(old_state == C_IS_FILLING || old_state == C_ON_SWAPPEDIN_Q ||
+ old_state == C_ON_SWAPOUT_Q || old_state == C_ON_SWAPIO_Q ||
+ old_state == C_ON_MAJORCOMPACT_Q || old_state == C_ON_SWAPPEDOUT_Q || old_state == C_ON_SWAPPEDOUTSPARSE_Q);
+
+ if (old_state == C_IS_FILLING) {
+ queue_enter(&c_age_list_head, c_seg, c_segment_t, c_age_list);
+ } else {
+ if (!queue_empty(&c_age_list_head)) {
+ c_segment_t c_first;
+
+ c_first = (c_segment_t)queue_first(&c_age_list_head);
+ c_seg->c_creation_ts = c_first->c_creation_ts;
+ }
+ queue_enter_first(&c_age_list_head, c_seg, c_segment_t, c_age_list);
+ }
+ c_age_count++;
+ break;
+
+ case C_ON_SWAPPEDIN_Q:
+ assert(old_state == C_ON_SWAPPEDOUT_Q || old_state == C_ON_SWAPPEDOUTSPARSE_Q);
+
+ if (insert_head == TRUE) {
+ queue_enter_first(&c_swappedin_list_head, c_seg, c_segment_t, c_age_list);
+ } else {
+ queue_enter(&c_swappedin_list_head, c_seg, c_segment_t, c_age_list);
+ }
+ c_swappedin_count++;
+ break;
+
+ case C_ON_SWAPOUT_Q:
+ assert(old_state == C_ON_AGE_Q || old_state == C_IS_FILLING);
+
+ if (insert_head == TRUE) {
+ queue_enter_first(&c_swapout_list_head, c_seg, c_segment_t, c_age_list);
+ } else {
+ queue_enter(&c_swapout_list_head, c_seg, c_segment_t, c_age_list);
+ }
+ c_swapout_count++;
+ break;
+
+ case C_ON_SWAPIO_Q:
+ assert(old_state == C_ON_SWAPOUT_Q);
+
+ if (insert_head == TRUE) {
+ queue_enter_first(&c_swapio_list_head, c_seg, c_segment_t, c_age_list);
+ } else {
+ queue_enter(&c_swapio_list_head, c_seg, c_segment_t, c_age_list);
+ }
+ c_swapio_count++;
+ break;
+
+ case C_ON_SWAPPEDOUT_Q:
+ assert(old_state == C_ON_SWAPIO_Q);
+
+ if (insert_head == TRUE) {
+ 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_swappedout_count++;
+ break;
+
+ case C_ON_SWAPPEDOUTSPARSE_Q:
+ assert(old_state == C_ON_SWAPIO_Q || old_state == C_ON_SWAPPEDOUT_Q);
+
+ if (insert_head == TRUE) {
+ queue_enter_first(&c_swappedout_sparse_list_head, c_seg, c_segment_t, c_age_list);
+ } else {
+ queue_enter(&c_swappedout_sparse_list_head, c_seg, c_segment_t, c_age_list);
+ }
+
+ c_swappedout_sparse_count++;
+ break;
+
+ case C_ON_MAJORCOMPACT_Q:
+ assert(old_state == C_ON_AGE_Q);
+
+ if (insert_head == TRUE) {
+ queue_enter_first(&c_major_list_head, c_seg, c_segment_t, c_age_list);
+ } else {
+ queue_enter(&c_major_list_head, c_seg, c_segment_t, c_age_list);
+ }
+ c_major_count++;
+ break;
+
+ case C_ON_BAD_Q:
+ assert(old_state == C_ON_SWAPPEDOUT_Q || old_state == C_ON_SWAPPEDOUTSPARSE_Q);
+
+ if (insert_head == TRUE) {
+ queue_enter_first(&c_bad_list_head, c_seg, c_segment_t, c_age_list);
+ } else {
+ queue_enter(&c_bad_list_head, c_seg, c_segment_t, c_age_list);
+ }
+ c_bad_count++;
+ break;
+
+ default:
+ panic("c_seg %p requesting bad c_state = %d\n", c_seg, new_state);
}
- if (c_seg->c_ondisk == 0) {
- pages_populated = (round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset))) / PAGE_SIZE;
+ c_seg->c_state = new_state;
+}
+
+
+
+void
+c_seg_free(c_segment_t c_seg)
+{
+ assert(c_seg->c_busy);
+
+ lck_mtx_unlock_always(&c_seg->c_lock);
+ lck_mtx_lock_spin_always(c_list_lock);
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
+
+ c_seg_free_locked(c_seg);
+}
+
+void
+c_seg_free_locked(c_segment_t c_seg)
+{
+ int segno;
+ int pages_populated = 0;
+ int32_t *c_buffer = NULL;
+ uint64_t c_swap_handle = 0;
+
+ assert(c_seg->c_busy);
+ assert(c_seg->c_slots_used == 0);
+ assert(!c_seg->c_on_minorcompact_q);
+ assert(!c_seg->c_busy_swapping);
+
+ if (c_seg->c_overage_swap == TRUE) {
+ c_overage_swapped_count--;
+ c_seg->c_overage_swap = FALSE;
+ }
+ if (!(C_SEG_IS_ONDISK(c_seg))) {
c_buffer = c_seg->c_store.c_buffer;
- c_seg->c_store.c_buffer = NULL;
} else {
- /*
- * Free swap space on disk.
- */
c_swap_handle = c_seg->c_store.c_swap_handle;
+ }
+
+ c_seg_switch_state(c_seg, C_IS_FREE, FALSE);
+
+ lck_mtx_unlock_always(c_list_lock);
+
+ if (c_buffer) {
+ pages_populated = (round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset))) / PAGE_SIZE;
+ c_seg->c_store.c_buffer = NULL;
+ } else {
c_seg->c_store.c_swap_handle = (uint64_t)-1;
}
+
lck_mtx_unlock_always(&c_seg->c_lock);
if (c_buffer) {
- if (pages_populated)
- kernel_memory_depopulate(kernel_map, (vm_offset_t) c_buffer, pages_populated * PAGE_SIZE, KMA_COMPRESSOR);
+ if (pages_populated) {
+ kernel_memory_depopulate(compressor_map, (vm_offset_t) c_buffer, pages_populated * PAGE_SIZE, KMA_COMPRESSOR);
+ }
+ } else if (c_swap_handle) {
+ /*
+ * Free swap space on disk.
+ */
+ vm_swap_free(c_swap_handle);
+ }
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
+ /*
+ * c_seg must remain busy until
+ * after the call to vm_swap_free
+ */
+ C_SEG_WAKEUP_DONE(c_seg);
+ lck_mtx_unlock_always(&c_seg->c_lock);
- kmem_free(kernel_map, (vm_offset_t) c_buffer, C_SEG_ALLOCSIZE);
- OSAddAtomic64(-C_SEG_ALLOCSIZE, &compressor_kvspace_used);
+ segno = c_seg->c_mysegno;
- } else if (c_swap_handle)
- vm_swap_free(c_swap_handle);
+ lck_mtx_lock_spin_always(c_list_lock);
+ /*
+ * because the c_buffer is now associated with the segno,
+ * we can't put the segno back on the free list until
+ * after we have depopulated the c_buffer range, or
+ * we run the risk of depopulating a range that is
+ * now being used in one of the compressor heads
+ */
+ c_segments[segno].c_segno = c_free_segno_head;
+ c_free_segno_head = segno;
+ c_segment_count--;
+ lck_mtx_unlock_always(c_list_lock);
-#if __i386__ || __x86_64__
lck_mtx_destroy(&c_seg->c_lock, &vm_compressor_lck_grp);
-#else /* __i386__ || __x86_64__ */
- lck_spin_destroy(&c_seg->c_lock, &vm_compressor_lck_grp);
-#endif /* __i386__ || __x86_64__ */
- for (i = 0; i < C_SEG_SLOT_ARRAYS; i++) {
- if (c_seg->c_slots[i] == 0)
- break;
-
- kfree((char *)c_seg->c_slots[i], sizeof(struct c_slot) * C_SEG_SLOT_ARRAY_SIZE);
+ if (c_seg->c_slot_var_array_len) {
+ kfree(c_seg->c_slot_var_array, sizeof(struct c_slot) * c_seg->c_slot_var_array_len);
}
+
zfree(compressor_segment_zone, c_seg);
}
-
+#if DEVELOPMENT || DEBUG
int c_seg_trim_page_count = 0;
+#endif
void
c_seg_trim_tail(c_segment_t c_seg)
{
- c_slot_t cs;
- uint32_t c_size;
- uint32_t c_offset;
- uint32_t c_rounded_size;
- uint16_t current_nextslot;
- uint32_t current_populated_offset;
+ c_slot_t cs;
+ uint32_t c_size;
+ uint32_t c_offset;
+ uint32_t c_rounded_size;
+ uint16_t current_nextslot;
+ uint32_t current_populated_offset;
- if (c_seg->c_bytes_used == 0)
+ if (c_seg->c_bytes_used == 0) {
return;
+ }
current_nextslot = c_seg->c_nextslot;
current_populated_offset = c_seg->c_populated_offset;
-
- while (c_seg->c_nextslot) {
+ while (c_seg->c_nextslot) {
cs = C_SEG_SLOT_FROM_INDEX(c_seg, (c_seg->c_nextslot - 1));
c_size = UNPACK_C_SIZE(cs);
c_offset = cs->c_offset + C_SEG_BYTES_TO_OFFSET(c_rounded_size);
c_seg->c_nextoffset = c_offset;
- c_seg->c_populated_offset = (c_offset + (C_SEG_BYTES_TO_OFFSET(PAGE_SIZE) - 1)) & ~(C_SEG_BYTES_TO_OFFSET(PAGE_SIZE) - 1);
+ c_seg->c_populated_offset = (c_offset + (C_SEG_BYTES_TO_OFFSET(PAGE_SIZE) - 1)) &
+ ~(C_SEG_BYTES_TO_OFFSET(PAGE_SIZE) - 1);
- if (c_seg->c_firstemptyslot > c_seg->c_nextslot)
+ if (c_seg->c_firstemptyslot > c_seg->c_nextslot) {
c_seg->c_firstemptyslot = c_seg->c_nextslot;
-
+ }
+#if DEVELOPMENT || DEBUG
c_seg_trim_page_count += ((round_page_32(C_SEG_OFFSET_TO_BYTES(current_populated_offset)) -
- round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset))) / PAGE_SIZE);
+ round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset))) /
+ PAGE_SIZE);
+#endif
}
break;
- }
+ }
c_seg->c_nextslot--;
}
assert(c_seg->c_nextslot);
c_seg_minor_compaction_and_unlock(c_segment_t c_seg, boolean_t clear_busy)
{
c_slot_mapping_t slot_ptr;
- uint32_t c_offset = 0;
- uint32_t old_populated_offset;
- uint32_t c_rounded_size;
- uint32_t c_size;
- int c_indx = 0;
- int i;
- c_slot_t c_dst;
- c_slot_t c_src;
- boolean_t need_unlock = TRUE;
+ uint32_t c_offset = 0;
+ uint32_t old_populated_offset;
+ uint32_t c_rounded_size;
+ uint32_t c_size;
+ int c_indx = 0;
+ int i;
+ c_slot_t c_dst;
+ c_slot_t c_src;
assert(c_seg->c_busy);
#endif
if (c_seg->c_bytes_used == 0) {
c_seg_free(c_seg);
- return (1);
+ return 1;
}
- if (c_seg->c_firstemptyslot >= c_seg->c_nextslot || C_SEG_UNUSED_BYTES(c_seg) < PAGE_SIZE)
+ lck_mtx_unlock_always(&c_seg->c_lock);
+
+ if (c_seg->c_firstemptyslot >= c_seg->c_nextslot || C_SEG_UNUSED_BYTES(c_seg) < PAGE_SIZE) {
goto done;
-
+ }
+
+/* TODO: assert first emptyslot's c_size is actually 0 */
+
+#if DEVELOPMENT || DEBUG
+ C_SEG_MAKE_WRITEABLE(c_seg);
+#endif
+
#if VALIDATE_C_SEGMENTS
c_seg->c_was_minor_compacted++;
#endif
c_indx = c_seg->c_firstemptyslot;
c_dst = C_SEG_SLOT_FROM_INDEX(c_seg, c_indx);
-
+
old_populated_offset = c_seg->c_populated_offset;
c_offset = c_dst->c_offset;
for (i = c_indx + 1; i < c_seg->c_nextslot && c_offset < c_seg->c_nextoffset; i++) {
-
c_src = C_SEG_SLOT_FROM_INDEX(c_seg, i);
c_size = UNPACK_C_SIZE(c_src);
- if (c_size == 0)
+ if (c_size == 0) {
continue;
+ }
- memcpy(&c_seg->c_store.c_buffer[c_offset], &c_seg->c_store.c_buffer[c_src->c_offset], c_size);
+ c_rounded_size = (c_size + C_SEG_OFFSET_ALIGNMENT_MASK) & ~C_SEG_OFFSET_ALIGNMENT_MASK;
+/* N.B.: This memcpy may be an overlapping copy */
+ memcpy(&c_seg->c_store.c_buffer[c_offset], &c_seg->c_store.c_buffer[c_src->c_offset], c_rounded_size);
-#if CHECKSUM_THE_DATA
- c_dst->c_hash_data = c_src->c_hash_data;
-#endif
-#if CHECKSUM_THE_COMPRESSED_DATA
- c_dst->c_hash_compressed_data = c_src->c_hash_compressed_data;
-#endif
- c_dst->c_size = c_src->c_size;
- c_dst->c_packed_ptr = c_src->c_packed_ptr;
+ cslot_copy(c_dst, c_src);
c_dst->c_offset = c_offset;
slot_ptr = (c_slot_mapping_t)C_SLOT_UNPACK_PTR(c_dst);
slot_ptr->s_cindx = c_indx;
- c_rounded_size = (c_size + C_SEG_OFFSET_ALIGNMENT_MASK) & ~C_SEG_OFFSET_ALIGNMENT_MASK;
-
c_offset += C_SEG_BYTES_TO_OFFSET(c_rounded_size);
PACK_C_SIZE(c_src, 0);
c_indx++;
#if VALIDATE_C_SEGMENTS
c_seg_validate(c_seg, TRUE);
#endif
-
if (old_populated_offset > c_seg->c_populated_offset) {
- uint32_t gc_size;
- int32_t *gc_ptr;
+ uint32_t gc_size;
+ int32_t *gc_ptr;
gc_size = C_SEG_OFFSET_TO_BYTES(old_populated_offset - c_seg->c_populated_offset);
gc_ptr = &c_seg->c_store.c_buffer[c_seg->c_populated_offset];
+ kernel_memory_depopulate(compressor_map, (vm_offset_t)gc_ptr, gc_size, KMA_COMPRESSOR);
+ }
+
+#if DEVELOPMENT || DEBUG
+ C_SEG_WRITE_PROTECT(c_seg);
+#endif
+
+done:
+ if (clear_busy == TRUE) {
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
+ C_SEG_WAKEUP_DONE(c_seg);
lck_mtx_unlock_always(&c_seg->c_lock);
+ }
+ return 0;
+}
- kernel_memory_depopulate(kernel_map, (vm_offset_t)gc_ptr, gc_size, KMA_COMPRESSOR);
- if (clear_busy == TRUE)
- lck_mtx_lock_spin_always(&c_seg->c_lock);
- else
- need_unlock = FALSE;
+static void
+c_seg_alloc_nextslot(c_segment_t c_seg)
+{
+ struct c_slot *old_slot_array = NULL;
+ struct c_slot *new_slot_array = NULL;
+ int newlen;
+ int oldlen;
+
+ if (c_seg->c_nextslot < c_seg_fixed_array_len) {
+ return;
}
-done:
- if (need_unlock == TRUE) {
- if (clear_busy == TRUE)
- C_SEG_WAKEUP_DONE(c_seg);
+
+ if ((c_seg->c_nextslot - c_seg_fixed_array_len) >= c_seg->c_slot_var_array_len) {
+ oldlen = c_seg->c_slot_var_array_len;
+ old_slot_array = c_seg->c_slot_var_array;
+
+ if (oldlen == 0) {
+ newlen = C_SEG_SLOT_VAR_ARRAY_MIN_LEN;
+ } else {
+ newlen = oldlen * 2;
+ }
+
+ new_slot_array = (struct c_slot *)kalloc(sizeof(struct c_slot) * newlen);
+
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
+
+ if (old_slot_array) {
+ memcpy((char *)new_slot_array, (char *)old_slot_array, sizeof(struct c_slot) * oldlen);
+ }
+
+ c_seg->c_slot_var_array_len = newlen;
+ c_seg->c_slot_var_array = new_slot_array;
lck_mtx_unlock_always(&c_seg->c_lock);
+
+ if (old_slot_array) {
+ kfree(old_slot_array, sizeof(struct c_slot) * oldlen);
+ }
}
- return (0);
}
uint64_t moved_bytes;
uint64_t wasted_space_in_swapouts;
uint64_t count_of_swapouts;
+ uint64_t count_of_freed_segs;
} c_seg_major_compact_stats;
-#define C_MAJOR_COMPACTION_AGE_APPROPRIATE 30
-#define C_MAJOR_COMPACTION_OLD_ENOUGH 300
-#define C_MAJOR_COMPACTION_SIZE_APPROPRIATE ((C_SEG_BUFSIZE * 80) / 100)
+#define C_MAJOR_COMPACTION_SIZE_APPROPRIATE ((C_SEG_BUFSIZE * 90) / 100)
boolean_t
c_segment_t c_seg_dst,
c_segment_t c_seg_src)
{
-
c_seg_major_compact_stats.asked_permission++;
- if (c_seg_src->c_filling) {
- /*
- * we're at or near the head... don't compact
- */
- return (FALSE);
- }
if (c_seg_src->c_bytes_used >= C_MAJOR_COMPACTION_SIZE_APPROPRIATE &&
- c_seg_dst->c_bytes_used >= C_MAJOR_COMPACTION_SIZE_APPROPRIATE)
- return (FALSE);
+ c_seg_dst->c_bytes_used >= C_MAJOR_COMPACTION_SIZE_APPROPRIATE) {
+ return FALSE;
+ }
- if (c_seg_dst->c_nextoffset >= C_SEG_OFF_LIMIT || c_seg_dst->c_nextslot >= C_SLOT_MAX) {
+ if (c_seg_dst->c_nextoffset >= C_SEG_OFF_LIMIT || c_seg_dst->c_nextslot >= C_SLOT_MAX_INDEX) {
/*
* destination segment is full... can't compact
*/
- return (FALSE);
+ return FALSE;
}
- return (TRUE);
+ return TRUE;
}
c_segment_t c_seg_src)
{
c_slot_mapping_t slot_ptr;
- uint32_t c_rounded_size;
- uint32_t c_size;
- uint16_t dst_slot;
- int i;
- c_slot_t c_dst;
- c_slot_t c_src;
- int slotarray;
- boolean_t keep_compacting = TRUE;
-
+ uint32_t c_rounded_size;
+ uint32_t c_size;
+ uint16_t dst_slot;
+ int i;
+ c_slot_t c_dst;
+ c_slot_t c_src;
+ boolean_t keep_compacting = TRUE;
+
/*
* segments are not locked but they are both marked c_busy
* which keeps c_decompress from working on them...
* from c_seg_src to c_seg_dst and update both c_segment's
* state w/o holding the master lock
*/
+#if DEVELOPMENT || DEBUG
+ C_SEG_MAKE_WRITEABLE(c_seg_dst);
+#endif
#if VALIDATE_C_SEGMENTS
c_seg_dst->c_was_major_compacted++;
dst_slot = c_seg_dst->c_nextslot;
for (i = 0; i < c_seg_src->c_nextslot; i++) {
-
c_src = C_SEG_SLOT_FROM_INDEX(c_seg_src, i);
c_size = UNPACK_C_SIZE(c_src);
}
if (C_SEG_OFFSET_TO_BYTES(c_seg_dst->c_populated_offset - c_seg_dst->c_nextoffset) < (unsigned) c_size) {
+ int size_to_populate;
+
/* doesn't fit */
- if ((C_SEG_OFFSET_TO_BYTES(c_seg_dst->c_populated_offset) == C_SEG_BUFSIZE)) {
+ size_to_populate = C_SEG_BUFSIZE - C_SEG_OFFSET_TO_BYTES(c_seg_dst->c_populated_offset);
+
+ if (size_to_populate == 0) {
/* can't fit */
keep_compacting = FALSE;
break;
}
- kernel_memory_populate(kernel_map,
- (vm_offset_t) &c_seg_dst->c_store.c_buffer[c_seg_dst->c_populated_offset],
- PAGE_SIZE,
- KMA_COMPRESSOR);
+ if (size_to_populate > C_SEG_MAX_POPULATE_SIZE) {
+ size_to_populate = C_SEG_MAX_POPULATE_SIZE;
+ }
- c_seg_dst->c_populated_offset += C_SEG_BYTES_TO_OFFSET(PAGE_SIZE);
+ kernel_memory_populate(compressor_map,
+ (vm_offset_t) &c_seg_dst->c_store.c_buffer[c_seg_dst->c_populated_offset],
+ size_to_populate,
+ KMA_COMPRESSOR,
+ VM_KERN_MEMORY_COMPRESSOR);
+
+ c_seg_dst->c_populated_offset += C_SEG_BYTES_TO_OFFSET(size_to_populate);
assert(C_SEG_OFFSET_TO_BYTES(c_seg_dst->c_populated_offset) <= C_SEG_BUFSIZE);
}
+ c_seg_alloc_nextslot(c_seg_dst);
- slotarray = C_SEG_SLOTARRAY_FROM_INDEX(c_seg_dst, c_seg_dst->c_nextslot);
-
- if (c_seg_dst->c_slots[slotarray] == 0) {
- KERNEL_DEBUG(0xe0400008 | DBG_FUNC_START, 0, 0, 0, 0, 0);
- c_seg_dst->c_slots[slotarray] = (struct c_slot *)
- kalloc(sizeof(struct c_slot) *
- C_SEG_SLOT_ARRAY_SIZE);
- KERNEL_DEBUG(0xe0400008 | DBG_FUNC_END, 0, 0, 0, 0, 0);
- }
c_dst = C_SEG_SLOT_FROM_INDEX(c_seg_dst, c_seg_dst->c_nextslot);
memcpy(&c_seg_dst->c_store.c_buffer[c_seg_dst->c_nextoffset], &c_seg_src->c_store.c_buffer[c_src->c_offset], c_size);
c_seg_major_compact_stats.moved_slots++;
c_seg_major_compact_stats.moved_bytes += c_size;
-#if CHECKSUM_THE_DATA
- c_dst->c_hash_data = c_src->c_hash_data;
-#endif
-#if CHECKSUM_THE_COMPRESSED_DATA
- c_dst->c_hash_compressed_data = c_src->c_hash_compressed_data;
-#endif
- c_dst->c_size = c_src->c_size;
- c_dst->c_packed_ptr = c_src->c_packed_ptr;
+ cslot_copy(c_dst, c_src);
c_dst->c_offset = c_seg_dst->c_nextoffset;
- if (c_seg_dst->c_firstemptyslot == c_seg_dst->c_nextslot)
+ if (c_seg_dst->c_firstemptyslot == c_seg_dst->c_nextslot) {
c_seg_dst->c_firstemptyslot++;
+ }
+ c_seg_dst->c_slots_used++;
c_seg_dst->c_nextslot++;
c_seg_dst->c_bytes_used += c_rounded_size;
c_seg_dst->c_nextoffset += C_SEG_BYTES_TO_OFFSET(c_rounded_size);
c_seg_src->c_bytes_unused += c_rounded_size;
c_seg_src->c_firstemptyslot = 0;
- if (c_seg_dst->c_nextoffset >= C_SEG_OFF_LIMIT || c_seg_dst->c_nextslot >= C_SLOT_MAX) {
+ assert(c_seg_src->c_slots_used);
+ c_seg_src->c_slots_used--;
+
+ if (c_seg_dst->c_nextoffset >= C_SEG_OFF_LIMIT || c_seg_dst->c_nextslot >= C_SLOT_MAX_INDEX) {
/* dest segment is now full */
keep_compacting = FALSE;
break;
}
}
+#if DEVELOPMENT || DEBUG
+ C_SEG_WRITE_PROTECT(c_seg_dst);
+#endif
if (dst_slot < c_seg_dst->c_nextslot) {
-
PAGE_REPLACEMENT_ALLOWED(TRUE);
/*
- * we've now locked out c_decompress from
+ * we've now locked out c_decompress from
* converting the slot passed into it into
- * a c_segment_t which allows us to use
+ * a c_segment_t which allows us to use
* the backptr to change which c_segment and
* index the slot points to
*/
while (dst_slot < c_seg_dst->c_nextslot) {
-
c_dst = C_SEG_SLOT_FROM_INDEX(c_seg_dst, dst_slot);
-
+
slot_ptr = (c_slot_mapping_t)C_SLOT_UNPACK_PTR(c_dst);
/* <csegno=0,indx=0> would mean "empty slot", so use csegno+1 */
slot_ptr->s_cseg = c_seg_dst->c_mysegno + 1;
}
PAGE_REPLACEMENT_ALLOWED(FALSE);
}
- return (keep_compacting);
+ return keep_compacting;
}
uint64_t
vm_compressor_compute_elapsed_msecs(clock_sec_t end_sec, clock_nsec_t end_nsec, clock_sec_t start_sec, clock_nsec_t start_nsec)
{
- uint64_t end_msecs;
- uint64_t start_msecs;
-
+ uint64_t end_msecs;
+ uint64_t start_msecs;
+
end_msecs = (end_sec * 1000) + end_nsec / 1000000;
start_msecs = (start_sec * 1000) + start_nsec / 1000000;
- return (end_msecs - start_msecs);
+ return end_msecs - start_msecs;
}
uint32_t compressor_thrashing_min_per_10msecs = 20;
/* When true, reset sample data next chance we get. */
-static boolean_t compressor_need_sample_reset = FALSE;
-
-extern uint32_t vm_page_filecache_min;
+static boolean_t compressor_need_sample_reset = FALSE;
void
compute_swapout_target_age(void)
{
- clock_sec_t cur_ts_sec;
- clock_nsec_t cur_ts_nsec;
- uint32_t min_operations_needed_in_this_sample;
- uint64_t elapsed_msecs_in_eval;
- uint64_t elapsed_msecs_in_sample;
- boolean_t need_eval_reset = FALSE;
+ clock_sec_t cur_ts_sec;
+ clock_nsec_t cur_ts_nsec;
+ uint32_t min_operations_needed_in_this_sample;
+ uint64_t elapsed_msecs_in_eval;
+ uint64_t elapsed_msecs_in_sample;
+ boolean_t need_eval_reset = FALSE;
clock_get_system_nanotime(&cur_ts_sec, &cur_ts_nsec);
goto done;
}
elapsed_msecs_in_eval = vm_compressor_compute_elapsed_msecs(cur_ts_sec, cur_ts_nsec, start_of_eval_period_sec, start_of_eval_period_nsec);
-
- if (elapsed_msecs_in_eval < compressor_eval_period_in_msecs)
+
+ if (elapsed_msecs_in_eval < compressor_eval_period_in_msecs) {
goto done;
+ }
need_eval_reset = TRUE;
KERNEL_DEBUG(0xe0400020 | DBG_FUNC_START, elapsed_msecs_in_eval, sample_period_compression_count, sample_period_decompression_count, 0, 0);
if ((sample_period_compression_count - last_eval_compression_count) < min_operations_needed_in_this_sample ||
(sample_period_decompression_count - last_eval_decompression_count) < min_operations_needed_in_this_sample) {
-
KERNEL_DEBUG(0xe0400020 | DBG_FUNC_END, sample_period_compression_count - last_eval_compression_count,
- sample_period_decompression_count - last_eval_decompression_count, 0, 1, 0);
+ sample_period_decompression_count - last_eval_decompression_count, 0, 1, 0);
swapout_target_age = 0;
last_eval_decompression_count = sample_period_decompression_count;
if (elapsed_msecs_in_sample < compressor_sample_min_in_msecs) {
-
KERNEL_DEBUG(0xe0400020 | DBG_FUNC_END, swapout_target_age, 0, 0, 5, 0);
goto done;
}
if (sample_period_decompression_count > ((compressor_thrashing_threshold_per_10msecs * elapsed_msecs_in_sample) / 10)) {
-
- uint64_t running_total;
- uint64_t working_target;
- uint64_t aging_target;
- uint32_t oldest_age_of_csegs_sampled = 0;
- uint64_t working_set_approximation = 0;
+ uint64_t running_total;
+ uint64_t working_target;
+ uint64_t aging_target;
+ uint32_t oldest_age_of_csegs_sampled = 0;
+ uint64_t working_set_approximation = 0;
swapout_target_age = 0;
- working_target = (sample_period_decompression_count / 100) * 95; /* 95 percent */
- aging_target = (sample_period_decompression_count / 100) * 1; /* 1 percent */
+ working_target = (sample_period_decompression_count / 100) * 95; /* 95 percent */
+ aging_target = (sample_period_decompression_count / 100) * 1; /* 1 percent */
running_total = 0;
for (oldest_age_of_csegs_sampled = 0; oldest_age_of_csegs_sampled < DECOMPRESSION_SAMPLE_MAX_AGE; oldest_age_of_csegs_sampled++) {
-
running_total += age_of_decompressions_during_sample_period[oldest_age_of_csegs_sampled];
working_set_approximation += oldest_age_of_csegs_sampled * age_of_decompressions_during_sample_period[oldest_age_of_csegs_sampled];
- if (running_total >= working_target)
+ if (running_total >= working_target) {
break;
+ }
}
if (oldest_age_of_csegs_sampled < DECOMPRESSION_SAMPLE_MAX_AGE) {
-
working_set_approximation = (working_set_approximation * 1000) / elapsed_msecs_in_sample;
if (working_set_approximation < VM_PAGE_COMPRESSOR_COUNT) {
-
running_total = overage_decompressions_during_sample_period;
for (oldest_age_of_csegs_sampled = DECOMPRESSION_SAMPLE_MAX_AGE - 1; oldest_age_of_csegs_sampled; oldest_age_of_csegs_sampled--) {
running_total += age_of_decompressions_during_sample_period[oldest_age_of_csegs_sampled];
- if (running_total >= aging_target)
+ if (running_total >= aging_target) {
break;
+ }
}
swapout_target_age = (uint32_t)cur_ts_sec - oldest_age_of_csegs_sampled;
} else {
KERNEL_DEBUG(0xe0400020 | DBG_FUNC_END, working_set_approximation, VM_PAGE_COMPRESSOR_COUNT, 0, 3, 0);
}
- } else
+ } else {
KERNEL_DEBUG(0xe0400020 | DBG_FUNC_END, working_target, running_total, 0, 4, 0);
+ }
compressor_need_sample_reset = TRUE;
need_eval_reset = TRUE;
- } else
+ } else {
KERNEL_DEBUG(0xe0400020 | DBG_FUNC_END, sample_period_decompression_count, (compressor_thrashing_threshold_per_10msecs * elapsed_msecs_in_sample) / 10, 0, 6, 0);
+ }
done:
if (compressor_need_sample_reset == TRUE) {
bzero(age_of_decompressions_during_sample_period, sizeof(age_of_decompressions_during_sample_period));
}
-int compaction_swapper_inited = 0;
-int compaction_swapper_init_now = 0;
-int compaction_swapper_running = 0;
-int compaction_swapper_abort = 0;
+int compaction_swapper_init_now = 0;
+int compaction_swapper_running = 0;
+int compaction_swapper_awakened = 0;
+int compaction_swapper_abort = 0;
#if CONFIG_JETSAM
-boolean_t memorystatus_kill_on_VM_thrashing(boolean_t);
-boolean_t memorystatus_kill_on_FC_thrashing(boolean_t);
-int compressor_thrashing_induced_jetsam = 0;
-int filecache_thrashing_induced_jetsam = 0;
-static boolean_t vm_compressor_thrashing_detected = FALSE;
+boolean_t memorystatus_kill_on_VM_compressor_thrashing(boolean_t);
+boolean_t memorystatus_kill_on_VM_compressor_space_shortage(boolean_t);
+boolean_t memorystatus_kill_on_FC_thrashing(boolean_t);
+int compressor_thrashing_induced_jetsam = 0;
+int filecache_thrashing_induced_jetsam = 0;
+static boolean_t vm_compressor_thrashing_detected = FALSE;
#endif /* CONFIG_JETSAM */
static boolean_t
compressor_needs_to_swap(void)
{
- boolean_t should_swap = FALSE;
+ boolean_t should_swap = FALSE;
+
+ if (vm_swapout_ripe_segments == TRUE && c_overage_swapped_count < c_overage_swapped_limit) {
+ c_segment_t c_seg;
+ clock_sec_t now;
+ clock_sec_t age;
+ clock_nsec_t nsec;
+
+ clock_get_system_nanotime(&now, &nsec);
+ age = 0;
+
+ lck_mtx_lock_spin_always(c_list_lock);
- if (vm_swap_up == TRUE) {
+ if (!queue_empty(&c_age_list_head)) {
+ c_seg = (c_segment_t) queue_first(&c_age_list_head);
+
+ age = now - c_seg->c_creation_ts;
+ }
+ lck_mtx_unlock_always(c_list_lock);
+
+ if (age >= vm_ripe_target_age) {
+ return TRUE;
+ }
+ }
+ if (VM_CONFIG_SWAP_IS_ACTIVE) {
if (COMPRESSOR_NEEDS_TO_SWAP()) {
- return (TRUE);
+ return TRUE;
}
if (VM_PAGE_Q_THROTTLED(&vm_pageout_queue_external) && vm_page_anonymous_count < (vm_page_inactive_count / 20)) {
- return (TRUE);
+ return TRUE;
+ }
+ if (vm_page_free_count < (vm_page_free_reserved - (COMPRESSOR_FREE_RESERVED_LIMIT * 2))) {
+ return TRUE;
}
- if (vm_page_free_count < (vm_page_free_reserved - COMPRESSOR_FREE_RESERVED_LIMIT))
- return (TRUE);
}
compute_swapout_target_age();
-
+
if (swapout_target_age) {
- c_segment_t c_seg;
+ c_segment_t c_seg;
lck_mtx_lock_spin_always(c_list_lock);
if (!queue_empty(&c_age_list_head)) {
-
c_seg = (c_segment_t) queue_first(&c_age_list_head);
- if (c_seg->c_creation_ts > swapout_target_age)
+ if (c_seg->c_creation_ts > swapout_target_age) {
swapout_target_age = 0;
+ }
}
lck_mtx_unlock_always(c_list_lock);
}
#if CONFIG_PHANTOM_CACHE
- if (vm_phantom_cache_check_pressure())
+ if (vm_phantom_cache_check_pressure()) {
should_swap = TRUE;
+ }
#endif
- if (swapout_target_age)
+ if (swapout_target_age) {
should_swap = TRUE;
+ }
- if (vm_swap_up == FALSE) {
-
- if (should_swap) {
#if CONFIG_JETSAM
- if (vm_compressor_thrashing_detected == FALSE) {
- vm_compressor_thrashing_detected = TRUE;
-
+ if (should_swap || vm_compressor_low_on_space() == TRUE) {
+ if (vm_compressor_thrashing_detected == FALSE) {
+ vm_compressor_thrashing_detected = TRUE;
+
+ if (swapout_target_age || vm_compressor_low_on_space() == TRUE) {
if (swapout_target_age) {
- memorystatus_kill_on_VM_thrashing(TRUE /* async */);
- compressor_thrashing_induced_jetsam++;
+ /* The compressor is thrashing. */
+ memorystatus_kill_on_VM_compressor_thrashing(TRUE /* async */);
} else {
- memorystatus_kill_on_FC_thrashing(TRUE /* async */);
- filecache_thrashing_induced_jetsam++;
+ /* The compressor is running low on space. */
+ memorystatus_kill_on_VM_compressor_space_shortage(TRUE /* async */);
}
- /*
- * let the jetsam take precedence over
- * any major compactions we might have
- * been able to do... otherwise we run
- * the risk of doing major compactions
- * on segments we're about to free up
- * due to the jetsam activity.
- */
- should_swap = FALSE;
+ compressor_thrashing_induced_jetsam++;
+ } else {
+ memorystatus_kill_on_FC_thrashing(TRUE /* async */);
+ filecache_thrashing_induced_jetsam++;
}
+ }
+ /*
+ * let the jetsam take precedence over
+ * any major compactions we might have
+ * been able to do... otherwise we run
+ * the risk of doing major compactions
+ * on segments we're about to free up
+ * due to the jetsam activity.
+ */
+ should_swap = FALSE;
+ }
+
#endif /* CONFIG_JETSAM */
- } else
- should_swap = COMPRESSOR_NEEDS_TO_MAJOR_COMPACT();
+
+ if (should_swap == FALSE) {
+ /*
+ * vm_compressor_needs_to_major_compact returns true only if we're
+ * about to run out of available compressor segments... in this
+ * case, we absolutely need to run a major compaction even if
+ * we've just kicked off a jetsam or we don't otherwise need to
+ * swap... terminating objects releases
+ * pages back to the uncompressed cache, but does not guarantee
+ * that we will free up even a single compression segment
+ */
+ should_swap = vm_compressor_needs_to_major_compact();
}
/*
* will cause the major compaction engine to
* run, but will not trigger any swapping...
* segments that have been major compacted
- * will be moved to the swapped_out_q
- * but will not have the c_ondisk flag set
+ * will be moved to the majorcompact queue
*/
- return (should_swap);
+ return should_swap;
}
#if CONFIG_JETSAM
#endif /* CONFIG_JETSAM */
uint32_t vm_wake_compactor_swapper_calls = 0;
+uint32_t vm_run_compactor_already_running = 0;
+uint32_t vm_run_compactor_empty_minor_q = 0;
+uint32_t vm_run_compactor_did_compact = 0;
+uint32_t vm_run_compactor_waited = 0;
void
-vm_wake_compactor_swapper(void)
+vm_run_compactor(void)
{
- boolean_t need_major_compaction = FALSE;
+ if (c_segment_count == 0) {
+ return;
+ }
+
+ lck_mtx_lock_spin_always(c_list_lock);
+
+ if (c_minor_count == 0) {
+ vm_run_compactor_empty_minor_q++;
+
+ lck_mtx_unlock_always(c_list_lock);
+ return;
+ }
+ if (compaction_swapper_running) {
+ if (vm_pageout_state.vm_restricted_to_single_processor == FALSE) {
+ vm_run_compactor_already_running++;
+
+ lck_mtx_unlock_always(c_list_lock);
+ return;
+ }
+ vm_run_compactor_waited++;
+
+ assert_wait((event_t)&compaction_swapper_running, THREAD_UNINT);
+
+ lck_mtx_unlock_always(c_list_lock);
+
+ thread_block(THREAD_CONTINUE_NULL);
- if (compaction_swapper_running)
return;
+ }
+ vm_run_compactor_did_compact++;
- if (c_minor_count == 0 && need_major_compaction == FALSE)
+ fastwake_warmup = FALSE;
+ compaction_swapper_running = 1;
+
+ vm_compressor_do_delayed_compactions(FALSE);
+
+ compaction_swapper_running = 0;
+
+ lck_mtx_unlock_always(c_list_lock);
+
+ thread_wakeup((event_t)&compaction_swapper_running);
+}
+
+
+void
+vm_wake_compactor_swapper(void)
+{
+ if (compaction_swapper_running || compaction_swapper_awakened || c_segment_count == 0) {
return;
+ }
+
+ if (c_minor_count || vm_compressor_needs_to_major_compact()) {
+ lck_mtx_lock_spin_always(c_list_lock);
+
+ fastwake_warmup = FALSE;
+
+ if (compaction_swapper_running == 0 && compaction_swapper_awakened == 0) {
+ vm_wake_compactor_swapper_calls++;
+
+ compaction_swapper_awakened = 1;
+ thread_wakeup((event_t)&c_compressor_swap_trigger);
+ }
+ lck_mtx_unlock_always(c_list_lock);
+ }
+}
+
+
+void
+vm_consider_swapping()
+{
+ c_segment_t c_seg, c_seg_next;
+ clock_sec_t now;
+ clock_nsec_t nsec;
+
+ assert(VM_CONFIG_SWAP_IS_PRESENT);
lck_mtx_lock_spin_always(c_list_lock);
- fastwake_warmup = FALSE;
+ compaction_swapper_abort = 1;
- if (compaction_swapper_running == 0) {
- vm_wake_compactor_swapper_calls++;
+ while (compaction_swapper_running) {
+ assert_wait((event_t)&compaction_swapper_running, THREAD_UNINT);
- thread_wakeup((event_t)&c_compressor_swap_trigger);
-
- compaction_swapper_running = 1;
+ lck_mtx_unlock_always(c_list_lock);
+
+ thread_block(THREAD_CONTINUE_NULL);
+
+ lck_mtx_lock_spin_always(c_list_lock);
+ }
+ compaction_swapper_abort = 0;
+ compaction_swapper_running = 1;
+
+ vm_swapout_ripe_segments = TRUE;
+
+ if (!queue_empty(&c_major_list_head)) {
+ clock_get_system_nanotime(&now, &nsec);
+
+ c_seg = (c_segment_t)queue_first(&c_major_list_head);
+
+ while (!queue_end(&c_major_list_head, (queue_entry_t)c_seg)) {
+ if (c_overage_swapped_count >= c_overage_swapped_limit) {
+ break;
+ }
+
+ c_seg_next = (c_segment_t) queue_next(&c_seg->c_age_list);
+
+ if ((now - c_seg->c_creation_ts) >= vm_ripe_target_age) {
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
+
+ c_seg_switch_state(c_seg, C_ON_AGE_Q, FALSE);
+
+ lck_mtx_unlock_always(&c_seg->c_lock);
+ }
+ c_seg = c_seg_next;
+ }
}
+ vm_compressor_compact_and_swap(FALSE);
+
+ compaction_swapper_running = 0;
+
+ vm_swapout_ripe_segments = FALSE;
+
lck_mtx_unlock_always(c_list_lock);
+
+ thread_wakeup((event_t)&compaction_swapper_running);
}
void
vm_consider_waking_compactor_swapper(void)
{
- boolean_t need_wakeup = FALSE;
+ boolean_t need_wakeup = FALSE;
- if (compaction_swapper_running)
+ if (c_segment_count == 0) {
return;
+ }
+
+ if (compaction_swapper_running || compaction_swapper_awakened) {
+ return;
+ }
if (!compaction_swapper_inited && !compaction_swapper_init_now) {
compaction_swapper_init_now = 1;
}
if (c_minor_count && (COMPRESSOR_NEEDS_TO_MINOR_COMPACT())) {
-
need_wakeup = TRUE;
-
} else if (compressor_needs_to_swap()) {
-
need_wakeup = TRUE;
-
} else if (c_minor_count) {
- uint64_t total_bytes;
+ uint64_t total_bytes;
total_bytes = compressor_object->resident_page_count * PAGE_SIZE_64;
- if ((total_bytes - compressor_bytes_used) > total_bytes / 10)
+ if ((total_bytes - compressor_bytes_used) > total_bytes / 10) {
need_wakeup = TRUE;
+ }
}
if (need_wakeup == TRUE) {
-
lck_mtx_lock_spin_always(c_list_lock);
fastwake_warmup = FALSE;
- if (compaction_swapper_running == 0) {
+ if (compaction_swapper_running == 0 && compaction_swapper_awakened == 0) {
memoryshot(VM_WAKEUP_COMPACTOR_SWAPPER, DBG_FUNC_NONE);
+ compaction_swapper_awakened = 1;
thread_wakeup((event_t)&c_compressor_swap_trigger);
-
- compaction_swapper_running = 1;
}
lck_mtx_unlock_always(c_list_lock);
}
}
-#define C_SWAPOUT_LIMIT 4
-#define DELAYED_COMPACTIONS_PER_PASS 30
+#define C_SWAPOUT_LIMIT 4
+#define DELAYED_COMPACTIONS_PER_PASS 30
void
vm_compressor_do_delayed_compactions(boolean_t flush_all)
{
- c_segment_t c_seg;
- int number_compacted = 0;
- boolean_t needs_to_swap = FALSE;
+ c_segment_t c_seg;
+ int number_compacted = 0;
+ boolean_t needs_to_swap = FALSE;
- lck_mtx_assert(c_list_lock, LCK_MTX_ASSERT_OWNED);
+#if !CONFIG_EMBEDDED
+ LCK_MTX_ASSERT(c_list_lock, LCK_MTX_ASSERT_OWNED);
+#endif /* !CONFIG_EMBEDDED */
while (!queue_empty(&c_minor_list_head) && needs_to_swap == FALSE) {
-
c_seg = (c_segment_t)queue_first(&c_minor_list_head);
-
+
lck_mtx_lock_spin_always(&c_seg->c_lock);
if (c_seg->c_busy) {
-
lck_mtx_unlock_always(c_list_lock);
c_seg_wait_on_busy(c_seg);
lck_mtx_lock_spin_always(c_list_lock);
c_seg_do_minor_compaction_and_unlock(c_seg, TRUE, FALSE, TRUE);
- if (vm_swap_up == TRUE && (number_compacted++ > DELAYED_COMPACTIONS_PER_PASS)) {
-
- if ((flush_all == TRUE || compressor_needs_to_swap() == TRUE) && c_swapout_count < C_SWAPOUT_LIMIT)
+ if (VM_CONFIG_SWAP_IS_ACTIVE && (number_compacted++ > DELAYED_COMPACTIONS_PER_PASS)) {
+ if ((flush_all == TRUE || compressor_needs_to_swap() == TRUE) && c_swapout_count < C_SWAPOUT_LIMIT) {
needs_to_swap = TRUE;
+ }
number_compacted = 0;
}
}
-#define C_SEGMENT_SWAPPEDIN_AGE_LIMIT 10
+#define C_SEGMENT_SWAPPEDIN_AGE_LIMIT 10
static void
vm_compressor_age_swapped_in_segments(boolean_t flush_all)
{
- c_segment_t c_seg;
- clock_sec_t now;
- clock_nsec_t nsec;
+ c_segment_t c_seg;
+ clock_sec_t now;
+ clock_nsec_t nsec;
- clock_get_system_nanotime(&now, &nsec);
-
- while (!queue_empty(&c_swappedin_list_head)) {
+ clock_get_system_nanotime(&now, &nsec);
+ while (!queue_empty(&c_swappedin_list_head)) {
c_seg = (c_segment_t)queue_first(&c_swappedin_list_head);
- if (flush_all == FALSE && (now - c_seg->c_swappedin_ts) < C_SEGMENT_SWAPPEDIN_AGE_LIMIT)
+ if (flush_all == FALSE && (now - c_seg->c_swappedin_ts) < C_SEGMENT_SWAPPEDIN_AGE_LIMIT) {
break;
-
- lck_mtx_lock_spin_always(&c_seg->c_lock);
+ }
- queue_remove(&c_swappedin_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swappedin_q = 0;
- c_swappedin_count--;
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
- c_seg_insert_into_q(&c_age_list_head, c_seg);
- c_seg->c_on_age_q = 1;
- c_age_count++;
+ c_seg_switch_state(c_seg, C_ON_AGE_Q, FALSE);
lck_mtx_unlock_always(&c_seg->c_lock);
}
}
+extern int vm_num_swap_files;
+extern int vm_num_pinned_swap_files;
+extern int vm_swappin_enabled;
+
+extern unsigned int vm_swapfile_total_segs_used;
+extern unsigned int vm_swapfile_total_segs_alloced;
+
+
void
vm_compressor_flush(void)
{
- uint64_t vm_swap_put_failures_at_start;
- wait_result_t wait_result = 0;
- AbsoluteTime startTime, endTime;
- clock_sec_t now_sec;
- clock_nsec_t now_nsec;
- uint64_t nsec;
+ uint64_t vm_swap_put_failures_at_start;
+ wait_result_t wait_result = 0;
+ AbsoluteTime startTime, endTime;
+ clock_sec_t now_sec;
+ clock_nsec_t now_nsec;
+ uint64_t nsec;
HIBLOG("vm_compressor_flush - starting\n");
assert_wait((event_t)&compaction_swapper_running, THREAD_UNINT);
lck_mtx_unlock_always(c_list_lock);
-
+
thread_block(THREAD_CONTINUE_NULL);
lck_mtx_lock_spin_always(c_list_lock);
vm_compressor_compact_and_swap(TRUE);
while (!queue_empty(&c_swapout_list_head)) {
-
- assert_wait_timeout((event_t) &compaction_swapper_running, THREAD_INTERRUPTIBLE, 5000, 1000*NSEC_PER_USEC);
+ assert_wait_timeout((event_t) &compaction_swapper_running, THREAD_INTERRUPTIBLE, 5000, 1000 * NSEC_PER_USEC);
lck_mtx_unlock_always(c_list_lock);
-
+
wait_result = thread_block(THREAD_CONTINUE_NULL);
lck_mtx_lock_spin_always(c_list_lock);
- if (wait_result == THREAD_TIMED_OUT)
+ if (wait_result == THREAD_TIMED_OUT) {
break;
+ }
}
hibernate_flushing = FALSE;
compaction_swapper_running = 0;
- if (vm_swap_put_failures > vm_swap_put_failures_at_start)
+ if (vm_swap_put_failures > vm_swap_put_failures_at_start) {
HIBLOG("vm_compressor_flush failed to clean %llu segments - vm_page_compressor_count(%d)\n",
- vm_swap_put_failures - vm_swap_put_failures_at_start, VM_PAGE_COMPRESSOR_COUNT);
-
+ vm_swap_put_failures - vm_swap_put_failures_at_start, VM_PAGE_COMPRESSOR_COUNT);
+ }
+
lck_mtx_unlock_always(c_list_lock);
- clock_get_uptime(&endTime);
- SUB_ABSOLUTETIME(&endTime, &startTime);
- absolutetime_to_nanoseconds(endTime, &nsec);
+ thread_wakeup((event_t)&compaction_swapper_running);
- HIBLOG("vm_compressor_flush completed - took %qd msecs\n", nsec / 1000000ULL);
-}
+ clock_get_uptime(&endTime);
+ SUB_ABSOLUTETIME(&endTime, &startTime);
+ absolutetime_to_nanoseconds(endTime, &nsec);
+ HIBLOG("vm_compressor_flush completed - took %qd msecs - vm_num_swap_files = %d, vm_num_pinned_swap_files = %d, vm_swappin_enabled = %d\n",
+ nsec / 1000000ULL, vm_num_swap_files, vm_num_pinned_swap_files, vm_swappin_enabled);
+}
-extern void vm_swap_file_set_tuneables(void);
-int compaction_swap_trigger_thread_awakened = 0;
+int compaction_swap_trigger_thread_awakened = 0;
static void
vm_compressor_swap_trigger_thread(void)
{
+ current_thread()->options |= TH_OPT_VMPRIV;
+
/*
* compaction_swapper_init_now is set when the first call to
- * vm_consider_waking_compactor_swapper is made from
- * vm_pageout_scan... since this function is called upon
+ * vm_consider_waking_compactor_swapper is made from
+ * vm_pageout_scan... since this function is called upon
* thread creation, we want to make sure to delay adjusting
* the tuneables until we are awakened via vm_pageout_scan
* so that we are at a point where the vm_swapfile_open will
* be operating on the correct directory (in case the default
- * of /var/vm/ is overridden by the dymanic_pager
+ * of /var/vm/ is overridden by the dymanic_pager
*/
- if (compaction_swapper_init_now && !compaction_swapper_inited) {
- if (vm_compressor_mode == VM_PAGER_COMPRESSOR_WITH_SWAP)
- vm_swap_file_set_tuneables();
+ if (compaction_swapper_init_now) {
+ vm_compaction_swapper_do_init();
- compaction_swapper_inited = 1;
+ if (vm_pageout_state.vm_restricted_to_single_processor == TRUE) {
+ thread_vm_bind_group_add();
+ }
+ thread_set_thread_name(current_thread(), "VM_cswap_trigger");
+ compaction_swapper_init_now = 0;
}
lck_mtx_lock_spin_always(c_list_lock);
compaction_swap_trigger_thread_awakened++;
+ compaction_swapper_awakened = 0;
- vm_compressor_compact_and_swap(FALSE);
+ if (compaction_swapper_running == 0) {
+ compaction_swapper_running = 1;
+ vm_compressor_compact_and_swap(FALSE);
+
+ compaction_swapper_running = 0;
+ }
assert_wait((event_t)&c_compressor_swap_trigger, THREAD_UNINT);
- compaction_swapper_running = 0;
- thread_wakeup((event_t)&compaction_swapper_running);
+ if (compaction_swapper_running == 0) {
+ thread_wakeup((event_t)&compaction_swapper_running);
+ }
lck_mtx_unlock_always(c_list_lock);
-
+
thread_block((thread_continue_t)vm_compressor_swap_trigger_thread);
-
+
/* NOTREACHED */
}
void
vm_compressor_record_warmup_start(void)
{
- c_segment_t c_seg;
+ c_segment_t c_seg;
lck_mtx_lock_spin_always(c_list_lock);
if (first_c_segment_to_warm_generation_id == 0) {
if (!queue_empty(&c_age_list_head)) {
-
c_seg = (c_segment_t)queue_last(&c_age_list_head);
first_c_segment_to_warm_generation_id = c_seg->c_generation_id;
- } else
+ } else {
first_c_segment_to_warm_generation_id = 0;
+ }
fastwake_recording_in_progress = TRUE;
}
}
-void
+void
vm_compressor_record_warmup_end(void)
{
- c_segment_t c_seg;
+ c_segment_t c_seg;
lck_mtx_lock_spin_always(c_list_lock);
if (fastwake_recording_in_progress == TRUE) {
-
if (!queue_empty(&c_age_list_head)) {
-
c_seg = (c_segment_t)queue_last(&c_age_list_head);
last_c_segment_to_warm_generation_id = c_seg->c_generation_id;
- } else
+ } else {
last_c_segment_to_warm_generation_id = first_c_segment_to_warm_generation_id;
+ }
fastwake_recording_in_progress = FALSE;
}
-#define DELAY_TRIM_ON_WAKE_SECS 4
+#define DELAY_TRIM_ON_WAKE_SECS 25
void
vm_compressor_delay_trim(void)
{
- clock_sec_t sec;
- clock_nsec_t nsec;
+ clock_sec_t sec;
+ clock_nsec_t nsec;
clock_get_system_nanotime(&sec, &nsec);
dont_trim_until_ts = sec + DELAY_TRIM_ON_WAKE_SECS;
vm_compressor_do_warmup(void)
{
lck_mtx_lock_spin_always(c_list_lock);
-
+
if (first_c_segment_to_warm_generation_id == last_c_segment_to_warm_generation_id) {
first_c_segment_to_warm_generation_id = last_c_segment_to_warm_generation_id = 0;
return;
}
- if (compaction_swapper_running == 0) {
-
+ if (compaction_swapper_running == 0 && compaction_swapper_awakened == 0) {
fastwake_warmup = TRUE;
- compaction_swapper_running = 1;
+
+ compaction_swapper_awakened = 1;
thread_wakeup((event_t)&c_compressor_swap_trigger);
}
lck_mtx_unlock_always(c_list_lock);
}
+void
+do_fastwake_warmup_all(void)
+{
+ lck_mtx_lock_spin_always(c_list_lock);
+
+ if (queue_empty(&c_swappedout_list_head) && queue_empty(&c_swappedout_sparse_list_head)) {
+ lck_mtx_unlock_always(c_list_lock);
+ return;
+ }
+
+ fastwake_warmup = TRUE;
+
+ do_fastwake_warmup(&c_swappedout_list_head, TRUE);
+
+ do_fastwake_warmup(&c_swappedout_sparse_list_head, TRUE);
+
+ fastwake_warmup = FALSE;
+
+ lck_mtx_unlock_always(c_list_lock);
+}
void
-do_fastwake_warmup(void)
+do_fastwake_warmup(queue_head_t *c_queue, boolean_t consider_all_cseg)
{
- uint64_t my_thread_id;
- c_segment_t c_seg = NULL;
- AbsoluteTime startTime, endTime;
- uint64_t nsec;
+ c_segment_t c_seg = NULL;
+ AbsoluteTime startTime, endTime;
+ uint64_t nsec;
HIBLOG("vm_compressor_fastwake_warmup (%qd - %qd) - starting\n", first_c_segment_to_warm_generation_id, last_c_segment_to_warm_generation_id);
lck_mtx_unlock_always(c_list_lock);
- my_thread_id = current_thread()->thread_id;
- proc_set_task_policy_thread(kernel_task, my_thread_id,
- TASK_POLICY_INTERNAL, TASK_POLICY_IO, THROTTLE_LEVEL_COMPRESSOR_TIER2);
+ proc_set_thread_policy(current_thread(),
+ TASK_POLICY_INTERNAL, TASK_POLICY_IO, THROTTLE_LEVEL_COMPRESSOR_TIER2);
PAGE_REPLACEMENT_DISALLOWED(TRUE);
lck_mtx_lock_spin_always(c_list_lock);
- while (!queue_empty(&c_swappedout_list_head) && fastwake_warmup == TRUE) {
+ while (!queue_empty(c_queue) && fastwake_warmup == TRUE) {
+ c_seg = (c_segment_t) queue_first(c_queue);
- c_seg = (c_segment_t) queue_first(&c_swappedout_list_head);
+ if (consider_all_cseg == FALSE) {
+ 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) {
+ break;
+ }
- 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)
- break;
+ if (vm_page_free_count < (AVAILABLE_MEMORY / 4)) {
+ break;
+ }
+ }
lck_mtx_lock_spin_always(&c_seg->c_lock);
lck_mtx_unlock_always(c_list_lock);
-
+
if (c_seg->c_busy) {
PAGE_REPLACEMENT_DISALLOWED(FALSE);
c_seg_wait_on_busy(c_seg);
PAGE_REPLACEMENT_DISALLOWED(TRUE);
} else {
- 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);
+ }
c_segment_warmup_count++;
PAGE_REPLACEMENT_DISALLOWED(FALSE);
PAGE_REPLACEMENT_DISALLOWED(FALSE);
- proc_set_task_policy_thread(kernel_task, my_thread_id,
- TASK_POLICY_INTERNAL, TASK_POLICY_IO, THROTTLE_LEVEL_COMPRESSOR_TIER0);
+ proc_set_thread_policy(current_thread(),
+ TASK_POLICY_INTERNAL, TASK_POLICY_IO, THROTTLE_LEVEL_COMPRESSOR_TIER0);
- clock_get_uptime(&endTime);
- SUB_ABSOLUTETIME(&endTime, &startTime);
- absolutetime_to_nanoseconds(endTime, &nsec);
+ clock_get_uptime(&endTime);
+ SUB_ABSOLUTETIME(&endTime, &startTime);
+ absolutetime_to_nanoseconds(endTime, &nsec);
HIBLOG("vm_compressor_fastwake_warmup completed - took %qd msecs\n", nsec / 1000000ULL);
lck_mtx_lock_spin_always(c_list_lock);
- first_c_segment_to_warm_generation_id = last_c_segment_to_warm_generation_id = 0;
+ if (consider_all_cseg == FALSE) {
+ first_c_segment_to_warm_generation_id = last_c_segment_to_warm_generation_id = 0;
+ }
}
void
vm_compressor_compact_and_swap(boolean_t flush_all)
{
- c_segment_t c_seg, c_seg_next;
- boolean_t keep_compacting;
+ c_segment_t c_seg, c_seg_next;
+ boolean_t keep_compacting;
+ clock_sec_t now;
+ clock_nsec_t nsec;
if (fastwake_warmup == TRUE) {
- uint64_t starting_warmup_count;
+ uint64_t starting_warmup_count;
starting_warmup_count = c_segment_warmup_count;
KERNEL_DEBUG_CONSTANT(IOKDBG_CODE(DBG_HIBERNATE, 11) | DBG_FUNC_START, c_segment_warmup_count,
- first_c_segment_to_warm_generation_id, last_c_segment_to_warm_generation_id, 0, 0);
- do_fastwake_warmup();
+ first_c_segment_to_warm_generation_id, last_c_segment_to_warm_generation_id, 0, 0);
+ do_fastwake_warmup(&c_swappedout_list_head, FALSE);
KERNEL_DEBUG_CONSTANT(IOKDBG_CODE(DBG_HIBERNATE, 11) | DBG_FUNC_END, c_segment_warmup_count, c_segment_warmup_count - starting_warmup_count, 0, 0, 0);
fastwake_warmup = FALSE;
vm_compressor_age_swapped_in_segments(flush_all);
+ /*
+ * we only need to grab the timestamp once per
+ * invocation of this function since the
+ * timescale we're interested in is measured
+ * in days
+ */
+ clock_get_system_nanotime(&now, &nsec);
while (!queue_empty(&c_age_list_head) && compaction_swapper_abort == 0) {
-
if (hibernate_flushing == TRUE) {
- clock_sec_t sec;
- clock_nsec_t nsec;
+ clock_sec_t sec;
if (hibernate_should_abort()) {
HIBLOG("vm_compressor_flush - hibernate_should_abort returned TRUE\n");
HIBLOG("vm_compressor_flush - out of swap space\n");
break;
}
+ if (vm_swap_files_pinned() == FALSE) {
+ HIBLOG("vm_compressor_flush - unpinned swap files\n");
+ break;
+ }
+ if (hibernate_in_progress_with_pinned_swap == TRUE &&
+ (vm_swapfile_total_segs_alloced == vm_swapfile_total_segs_used)) {
+ HIBLOG("vm_compressor_flush - out of pinned swap space\n");
+ break;
+ }
clock_get_system_nanotime(&sec, &nsec);
-
+
if (sec > hibernate_flushing_deadline) {
HIBLOG("vm_compressor_flush - failed to finish before deadline\n");
break;
}
}
if (c_swapout_count >= C_SWAPOUT_LIMIT) {
-
- assert_wait_timeout((event_t) &compaction_swapper_running, THREAD_INTERRUPTIBLE, 100, 1000*NSEC_PER_USEC);
+ assert_wait_timeout((event_t) &compaction_swapper_running, THREAD_INTERRUPTIBLE, 100, 1000 * NSEC_PER_USEC);
lck_mtx_unlock_always(c_list_lock);
* Swap out segments?
*/
if (flush_all == FALSE) {
- boolean_t needs_to_swap;
+ boolean_t needs_to_swap;
lck_mtx_unlock_always(c_list_lock);
needs_to_swap = compressor_needs_to_swap();
+#if !CONFIG_EMBEDDED
+ if (needs_to_swap == TRUE && vm_swap_low_on_space()) {
+ vm_compressor_take_paging_space_action();
+ }
+#endif /* !CONFIG_EMBEDDED */
+
lck_mtx_lock_spin_always(c_list_lock);
-
- if (needs_to_swap == FALSE)
+
+ if (needs_to_swap == FALSE) {
break;
+ }
}
- if (queue_empty(&c_age_list_head))
+ if (queue_empty(&c_age_list_head)) {
break;
+ }
c_seg = (c_segment_t) queue_first(&c_age_list_head);
- if (flush_all == TRUE && c_seg->c_generation_id > c_generation_id_flush_barrier)
- break;
+ assert(c_seg->c_state == C_ON_AGE_Q);
- if (c_seg->c_filling) {
- /*
- * we're at or near the head... no more work to do
- */
+ if (flush_all == TRUE && c_seg->c_generation_id > c_generation_id_flush_barrier) {
break;
}
+
lck_mtx_lock_spin_always(&c_seg->c_lock);
if (c_seg->c_busy) {
-
lck_mtx_unlock_always(c_list_lock);
c_seg_wait_on_busy(c_seg);
lck_mtx_lock_spin_always(c_list_lock);
* found an empty c_segment and freed it
* so go grab the next guy in the queue
*/
+ c_seg_major_compact_stats.count_of_freed_segs++;
continue;
}
/*
keep_compacting = TRUE;
while (keep_compacting == TRUE) {
-
assert(c_seg->c_busy);
/* look for another segment to consolidate */
c_seg_next = (c_segment_t) queue_next(&c_seg->c_age_list);
-
- if (queue_end(&c_age_list_head, (queue_entry_t)c_seg_next))
+
+ if (queue_end(&c_age_list_head, (queue_entry_t)c_seg_next)) {
break;
+ }
- if (c_seg_major_compact_ok(c_seg, c_seg_next) == FALSE)
+ assert(c_seg_next->c_state == C_ON_AGE_Q);
+
+ if (c_seg_major_compact_ok(c_seg, c_seg_next) == FALSE) {
break;
+ }
lck_mtx_lock_spin_always(&c_seg_next->c_lock);
if (c_seg_next->c_busy) {
-
lck_mtx_unlock_always(c_list_lock);
c_seg_wait_on_busy(c_seg_next);
lck_mtx_lock_spin_always(c_list_lock);
* found an empty c_segment and freed it
* so we can't continue to use c_seg_next
*/
+ c_seg_major_compact_stats.count_of_freed_segs++;
continue;
}
lck_mtx_lock_spin_always(&c_seg_next->c_lock);
/*
* run a minor compaction on the donor segment
- * since we pulled at least some of it's
+ * since we pulled at least some of it's
* data into our target... if we've emptied
* it, now is a good time to free it which
* c_seg_minor_compaction_and_unlock also takes care of
* by passing TRUE, we ask for c_busy to be cleared
* and c_wanted to be taken care of
*/
- c_seg_minor_compaction_and_unlock(c_seg_next, TRUE);
+ if (c_seg_minor_compaction_and_unlock(c_seg_next, TRUE)) {
+ c_seg_major_compact_stats.count_of_freed_segs++;
+ }
PAGE_REPLACEMENT_DISALLOWED(FALSE);
/* relock the list */
lck_mtx_lock_spin_always(c_list_lock);
-
} /* major compaction */
- c_seg_major_compact_stats.wasted_space_in_swapouts += C_SEG_BUFSIZE - c_seg->c_bytes_used;
- c_seg_major_compact_stats.count_of_swapouts++;
-
lck_mtx_lock_spin_always(&c_seg->c_lock);
assert(c_seg->c_busy);
- assert(c_seg->c_on_age_q);
assert(!c_seg->c_on_minorcompact_q);
- queue_remove(&c_age_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_age_q = 0;
- c_age_count--;
-
- if (vm_swap_up == TRUE) {
- queue_enter(&c_swapout_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swapout_q = 1;
- c_swapout_count++;
+ if (VM_CONFIG_SWAP_IS_ACTIVE) {
+ /*
+ * This mode of putting a generic c_seg on the swapout list is
+ * only supported when we have general swapping enabled
+ */
+ c_seg_switch_state(c_seg, C_ON_SWAPOUT_Q, FALSE);
} 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++;
+ if ((vm_swapout_ripe_segments == TRUE && c_overage_swapped_count < c_overage_swapped_limit)) {
+ assert(VM_CONFIG_SWAP_IS_PRESENT);
+ /*
+ * we are running compressor sweeps with swap-behind
+ * make sure the c_seg has aged enough before swapping it
+ * out...
+ */
+ if ((now - c_seg->c_creation_ts) >= vm_ripe_target_age) {
+ c_seg->c_overage_swap = TRUE;
+ c_overage_swapped_count++;
+ c_seg_switch_state(c_seg, C_ON_SWAPOUT_Q, FALSE);
+ }
+ }
+ }
+ if (c_seg->c_state == C_ON_AGE_Q) {
+ /*
+ * this c_seg didn't get moved to the swapout queue
+ * so we need to move it out of the way...
+ * we just did a major compaction on it so put it
+ * on that queue
+ */
+ c_seg_switch_state(c_seg, C_ON_MAJORCOMPACT_Q, FALSE);
+ } else {
+ c_seg_major_compact_stats.wasted_space_in_swapouts += C_SEG_BUFSIZE - c_seg->c_bytes_used;
+ c_seg_major_compact_stats.count_of_swapouts++;
}
C_SEG_WAKEUP_DONE(c_seg);
lck_mtx_unlock_always(c_list_lock);
thread_wakeup((event_t)&c_swapout_list_head);
-
+
lck_mtx_lock_spin_always(c_list_lock);
}
}
}
-static uint32_t no_paging_space_action_in_progress = 0;
-extern void memorystatus_send_low_swap_note(void);
-
-
static c_segment_t
c_seg_allocate(c_segment_t *current_chead)
{
- clock_sec_t sec;
- clock_nsec_t nsec;
- c_segment_t c_seg;
- int slotarray;
-
- if ( (c_seg = *current_chead) == NULL ) {
- uint32_t c_segno;
-
- if (vm_compressor_low_on_space() || vm_swap_low_on_space()) {
-
- if (no_paging_space_action_in_progress == 0) {
+ c_segment_t c_seg;
+ int min_needed;
+ int size_to_populate;
- if (OSCompareAndSwap(0, 1, (UInt32 *)&no_paging_space_action_in_progress)) {
-
- if (no_paging_space_action()) {
- memorystatus_send_low_swap_note();
- }
+#if !CONFIG_EMBEDDED
+ if (vm_compressor_low_on_space()) {
+ vm_compressor_take_paging_space_action();
+ }
+#endif /* !CONFIG_EMBEDDED */
- no_paging_space_action_in_progress = 0;
- }
- }
- }
- KERNEL_DEBUG(0xe0400004 | DBG_FUNC_START, 0, 0, 0, 0, 0);
+ if ((c_seg = *current_chead) == NULL) {
+ uint32_t c_segno;
lck_mtx_lock_spin_always(c_list_lock);
while (c_segments_busy == TRUE) {
assert_wait((event_t) (&c_segments_busy), THREAD_UNINT);
-
+
lck_mtx_unlock_always(c_list_lock);
thread_block(THREAD_CONTINUE_NULL);
lck_mtx_lock_spin_always(c_list_lock);
}
if (c_free_segno_head == (uint32_t)-1) {
+ uint32_t c_segments_available_new;
if (c_segments_available >= c_segments_limit || c_segment_pages_compressed >= c_segment_pages_compressed_limit) {
lck_mtx_unlock_always(c_list_lock);
- KERNEL_DEBUG(0xe0400004 | DBG_FUNC_END, 0, 0, 0, 1, 0);
- return (NULL);
+ return NULL;
}
c_segments_busy = TRUE;
lck_mtx_unlock_always(c_list_lock);
- kernel_memory_populate(kernel_map, (vm_offset_t)c_segments_next_page, PAGE_SIZE, KMA_KOBJECT);
+ kernel_memory_populate(compressor_map, (vm_offset_t)c_segments_next_page,
+ PAGE_SIZE, KMA_KOBJECT, VM_KERN_MEMORY_COMPRESSOR);
c_segments_next_page += PAGE_SIZE;
- for (c_segno = c_segments_available + 1; c_segno < (c_segments_available + C_SEGMENTS_PER_PAGE); c_segno++)
+ c_segments_available_new = c_segments_available + C_SEGMENTS_PER_PAGE;
+
+ if (c_segments_available_new > c_segments_limit) {
+ c_segments_available_new = c_segments_limit;
+ }
+
+ for (c_segno = c_segments_available + 1; c_segno < c_segments_available_new; c_segno++) {
c_segments[c_segno - 1].c_segno = c_segno;
+ }
lck_mtx_lock_spin_always(c_list_lock);
c_segments[c_segno - 1].c_segno = c_free_segno_head;
c_free_segno_head = c_segments_available;
- c_segments_available += C_SEGMENTS_PER_PAGE;
+ c_segments_available = c_segments_available_new;
c_segments_busy = FALSE;
thread_wakeup((event_t) (&c_segments_busy));
}
c_segno = c_free_segno_head;
- c_free_segno_head = c_segments[c_segno].c_segno;
+ assert(c_segno >= 0 && c_segno < c_segments_limit);
+
+ c_free_segno_head = (uint32_t)c_segments[c_segno].c_segno;
+
+ /*
+ * do the rest of the bookkeeping now while we're still behind
+ * the list lock and grab our generation id now into a local
+ * so that we can install it once we have the c_seg allocated
+ */
+ c_segment_count++;
+ if (c_segment_count > c_segment_count_max) {
+ c_segment_count_max = c_segment_count;
+ }
lck_mtx_unlock_always(c_list_lock);
c_seg = (c_segment_t)zalloc(compressor_segment_zone);
bzero((char *)c_seg, sizeof(struct c_segment));
- if (kernel_memory_allocate(kernel_map, (vm_offset_t *)(&c_seg->c_store.c_buffer), C_SEG_ALLOCSIZE, 0, KMA_COMPRESSOR | KMA_VAONLY) != KERN_SUCCESS) {
- zfree(compressor_segment_zone, c_seg);
+ c_seg->c_store.c_buffer = (int32_t *)C_SEG_BUFFER_ADDRESS(c_segno);
- lck_mtx_lock_spin_always(c_list_lock);
+ lck_mtx_init(&c_seg->c_lock, &vm_compressor_lck_grp, &vm_compressor_lck_attr);
- c_segments[c_segno].c_segno = c_free_segno_head;
- c_free_segno_head = c_segno;
-
- lck_mtx_unlock_always(c_list_lock);
-
- KERNEL_DEBUG(0xe0400004 | DBG_FUNC_END, 0, 0, 0, 2, 0);
-
- return (NULL);
- }
- OSAddAtomic64(C_SEG_ALLOCSIZE, &compressor_kvspace_used);
-
-#if __i386__ || __x86_64__
- lck_mtx_init(&c_seg->c_lock, &vm_compressor_lck_grp, &vm_compressor_lck_attr);
-#else /* __i386__ || __x86_64__ */
- lck_spin_init(&c_seg->c_lock, &vm_compressor_lck_grp, &vm_compressor_lck_attr);
-#endif /* __i386__ || __x86_64__ */
-
- kernel_memory_populate(kernel_map, (vm_offset_t)(c_seg->c_store.c_buffer), 3 * PAGE_SIZE, KMA_COMPRESSOR);
-
- c_seg->c_populated_offset = C_SEG_BYTES_TO_OFFSET(3 * PAGE_SIZE);
- c_seg->c_firstemptyslot = C_SLOT_MAX;
+ c_seg->c_state = C_IS_EMPTY;
+ c_seg->c_firstemptyslot = C_SLOT_MAX_INDEX;
c_seg->c_mysegno = c_segno;
- c_seg->c_filling = 1;
lck_mtx_lock_spin_always(c_list_lock);
-
- c_segment_count++;
+ c_empty_count++;
+ c_seg_switch_state(c_seg, C_IS_FILLING, FALSE);
c_segments[c_segno].c_seg = c_seg;
-
- c_seg->c_generation_id = c_generation_id++;
-
- queue_enter(&c_age_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_age_q = 1;
- c_age_count++;
-
+ assert(c_segments[c_segno].c_segno > c_segments_available);
lck_mtx_unlock_always(c_list_lock);
- clock_get_system_nanotime(&sec, &nsec);
- c_seg->c_creation_ts = (uint32_t)sec;
-
*current_chead = c_seg;
- KERNEL_DEBUG(0xe0400004 | DBG_FUNC_END, c_seg, 0, 0, 3, 0);
+#if DEVELOPMENT || DEBUG
+ C_SEG_MAKE_WRITEABLE(c_seg);
+#endif
}
- slotarray = C_SEG_SLOTARRAY_FROM_INDEX(c_seg, c_seg->c_nextslot);
+ c_seg_alloc_nextslot(c_seg);
- if (c_seg->c_slots[slotarray] == 0) {
- KERNEL_DEBUG(0xe0400008 | DBG_FUNC_START, 0, 0, 0, 0, 0);
+ size_to_populate = C_SEG_ALLOCSIZE - C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset);
- c_seg->c_slots[slotarray] = (struct c_slot *)kalloc(sizeof(struct c_slot) * C_SEG_SLOT_ARRAY_SIZE);
+ if (size_to_populate) {
+ min_needed = PAGE_SIZE + (C_SEG_ALLOCSIZE - C_SEG_BUFSIZE);
- KERNEL_DEBUG(0xe0400008 | DBG_FUNC_END, 0, 0, 0, 0, 0);
+ if (C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset - c_seg->c_nextoffset) < (unsigned) min_needed) {
+ if (size_to_populate > C_SEG_MAX_POPULATE_SIZE) {
+ size_to_populate = C_SEG_MAX_POPULATE_SIZE;
+ }
+
+ OSAddAtomic64(size_to_populate / PAGE_SIZE, &vm_pageout_vminfo.vm_compressor_pages_grabbed);
+
+ kernel_memory_populate(compressor_map,
+ (vm_offset_t) &c_seg->c_store.c_buffer[c_seg->c_populated_offset],
+ size_to_populate,
+ KMA_COMPRESSOR,
+ VM_KERN_MEMORY_COMPRESSOR);
+ } else {
+ size_to_populate = 0;
+ }
}
-
PAGE_REPLACEMENT_DISALLOWED(TRUE);
lck_mtx_lock_spin_always(&c_seg->c_lock);
- return (c_seg);
-}
+ if (size_to_populate) {
+ c_seg->c_populated_offset += C_SEG_BYTES_TO_OFFSET(size_to_populate);
+ }
+ return c_seg;
+}
+#if DEVELOPMENT || DEBUG
+#if CONFIG_FREEZE
+extern boolean_t memorystatus_freeze_to_memory;
+#endif /* CONFIG_FREEZE */
+#endif /* DEVELOPMENT || DEBUG */
static void
c_current_seg_filled(c_segment_t c_seg, c_segment_t *current_chead)
{
- uint32_t unused_bytes;
- uint32_t offset_to_depopulate;
+ uint32_t unused_bytes;
+ uint32_t offset_to_depopulate;
+ int new_state = C_ON_AGE_Q;
+ clock_sec_t sec;
+ clock_nsec_t nsec;
+ boolean_t head_insert = FALSE;
unused_bytes = trunc_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset - c_seg->c_nextoffset));
+#ifndef _OPEN_SOURCE
+ /* TODO: The HW codec can generate, lazily, a '2nd page not mapped'
+ * exception. So on such a platform, or platforms where we're confident
+ * the codec does not require a buffer page to absorb trailing writes,
+ * we can create an unmapped hole at the tail of the segment, rather
+ * than a populated mapping. This will also guarantee that the codec
+ * does not overwrite valid data past the edge of the segment and
+ * thus eliminate the depopulation overhead.
+ */
+#endif
if (unused_bytes) {
-
offset_to_depopulate = C_SEG_BYTES_TO_OFFSET(round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_nextoffset)));
/*
lck_mtx_unlock_always(&c_seg->c_lock);
kernel_memory_depopulate(
- kernel_map,
+ compressor_map,
(vm_offset_t) &c_seg->c_store.c_buffer[offset_to_depopulate],
unused_bytes,
KMA_COMPRESSOR);
c_seg->c_populated_offset = offset_to_depopulate;
}
- c_seg->c_filling = 0;
+ assert(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset) <= C_SEG_BUFSIZE);
- if (C_SEG_UNUSED_BYTES(c_seg) >= PAGE_SIZE)
- c_seg_need_delayed_compaction(c_seg);
+#if DEVELOPMENT || DEBUG
+ {
+ boolean_t c_seg_was_busy = FALSE;
- lck_mtx_unlock_always(&c_seg->c_lock);
+ if (!c_seg->c_busy) {
+ C_SEG_BUSY(c_seg);
+ } else {
+ c_seg_was_busy = TRUE;
+ }
+
+ lck_mtx_unlock_always(&c_seg->c_lock);
+
+ C_SEG_WRITE_PROTECT(c_seg);
+
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
+
+ if (c_seg_was_busy == FALSE) {
+ C_SEG_WAKEUP_DONE(c_seg);
+ }
+ }
+#endif
+
+#if CONFIG_FREEZE
+ if (current_chead == (c_segment_t*)&freezer_chead &&
+ VM_CONFIG_SWAP_IS_PRESENT &&
+ VM_CONFIG_FREEZER_SWAP_IS_ACTIVE
+#if DEVELOPMENT || DEBUG
+ && !memorystatus_freeze_to_memory
+#endif /* DEVELOPMENT || DEBUG */
+ ) {
+ new_state = C_ON_SWAPOUT_Q;
+ }
+#endif /* CONFIG_FREEZE */
+
+ if (vm_darkwake_mode == TRUE) {
+ new_state = C_ON_SWAPOUT_Q;
+ head_insert = TRUE;
+ }
+
+ clock_get_system_nanotime(&sec, &nsec);
+ c_seg->c_creation_ts = (uint32_t)sec;
+
+ lck_mtx_lock_spin_always(c_list_lock);
+
+ c_seg->c_generation_id = c_generation_id++;
+ c_seg_switch_state(c_seg, new_state, head_insert);
+
+#if CONFIG_FREEZE
+ if (c_seg->c_state == C_ON_SWAPOUT_Q) {
+ /*
+ * darkwake and freezer can't co-exist together
+ * We'll need to fix this accounting as a start.
+ */
+ assert(vm_darkwake_mode == FALSE);
+ c_freezer_swapout_page_count += (C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset)) / PAGE_SIZE_64;
+ }
+#endif /* CONFIG_FREEZE */
+
+ if (c_seg->c_state == C_ON_AGE_Q && C_SEG_UNUSED_BYTES(c_seg) >= PAGE_SIZE) {
+ c_seg_need_delayed_compaction(c_seg, TRUE);
+ }
+
+ lck_mtx_unlock_always(c_list_lock);
+
+ if (c_seg->c_state == C_ON_SWAPOUT_Q) {
+ thread_wakeup((event_t)&c_swapout_list_head);
+ }
*current_chead = NULL;
}
* returns with c_seg locked
*/
void
-c_seg_swapin_requeue(c_segment_t c_seg)
+c_seg_swapin_requeue(c_segment_t c_seg, boolean_t has_data, boolean_t minor_compact_ok, boolean_t age_on_swapin_q)
{
- clock_sec_t sec;
- clock_nsec_t nsec;
+ clock_sec_t sec;
+ clock_nsec_t nsec;
clock_get_system_nanotime(&sec, &nsec);
lck_mtx_lock_spin_always(c_list_lock);
lck_mtx_lock_spin_always(&c_seg->c_lock);
- if (c_seg->c_on_swappedout_q) {
- queue_remove(&c_swappedout_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swappedout_q = 0;
- c_swappedout_count--;
- } else {
- assert(c_seg->c_on_swappedout_sparse_q);
+ assert(c_seg->c_busy_swapping);
+ assert(c_seg->c_busy);
- queue_remove(&c_swappedout_sparse_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swappedout_sparse_q = 0;
- c_swappedout_sparse_count--;
- }
- if (c_seg->c_store.c_buffer) {
- queue_enter(&c_swappedin_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_swappedin_q = 1;
- c_swappedin_count++;
+ c_seg->c_busy_swapping = 0;
+
+ if (c_seg->c_overage_swap == TRUE) {
+ c_overage_swapped_count--;
+ c_seg->c_overage_swap = FALSE;
}
-#if TRACK_BAD_C_SEGMENTS
- else {
- queue_enter(&c_bad_list_head, c_seg, c_segment_t, c_age_list);
- c_seg->c_on_bad_q = 1;
- c_bad_count++;
+ if (has_data == TRUE) {
+ if (age_on_swapin_q == TRUE) {
+ c_seg_switch_state(c_seg, C_ON_SWAPPEDIN_Q, FALSE);
+ } else {
+ c_seg_switch_state(c_seg, C_ON_AGE_Q, FALSE);
+ }
+
+ if (minor_compact_ok == TRUE && !c_seg->c_on_minorcompact_q && C_SEG_UNUSED_BYTES(c_seg) >= PAGE_SIZE) {
+ c_seg_need_delayed_compaction(c_seg, TRUE);
+ }
+ } else {
+ c_seg->c_store.c_buffer = (int32_t*) NULL;
+ c_seg->c_populated_offset = C_SEG_BYTES_TO_OFFSET(0);
+
+ c_seg_switch_state(c_seg, C_ON_BAD_Q, FALSE);
}
-#endif
c_seg->c_swappedin_ts = (uint32_t)sec;
- c_seg->c_ondisk = 0;
- c_seg->c_was_swapped_in = 1;
lck_mtx_unlock_always(c_list_lock);
}
/*
- * c_seg has to be locked and is returned locked.
+ * c_seg has to be locked and is returned locked if the c_seg isn't freed
* PAGE_REPLACMENT_DISALLOWED has to be TRUE on entry and is returned TRUE
+ * c_seg_swapin returns 1 if the c_seg was freed, 0 otherwise
*/
-void
-c_seg_swapin(c_segment_t c_seg, boolean_t force_minor_compaction)
+int
+c_seg_swapin(c_segment_t c_seg, boolean_t force_minor_compaction, boolean_t age_on_swapin_q)
{
- vm_offset_t addr = 0;
- uint32_t io_size = 0;
- uint64_t f_offset;
+ vm_offset_t addr = 0;
+ uint32_t io_size = 0;
+ uint64_t f_offset;
+
+ assert(C_SEG_IS_ONDISK(c_seg));
#if !CHECKSUM_THE_SWAP
- if (c_seg->c_ondisk)
- c_seg_trim_tail(c_seg);
+ c_seg_trim_tail(c_seg);
#endif
io_size = round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset));
f_offset = c_seg->c_store.c_swap_handle;
C_SEG_BUSY(c_seg);
+ c_seg->c_busy_swapping = 1;
+
+ /*
+ * This thread is likely going to block for I/O.
+ * Make sure it is ready to run when the I/O completes because
+ * it needs to clear the busy bit on the c_seg so that other
+ * waiting threads can make progress too. To do that, boost
+ * the rwlock_count so that the priority is boosted.
+ */
+ set_thread_rwlock_boost();
lck_mtx_unlock_always(&c_seg->c_lock);
-
- if (c_seg->c_ondisk) {
- PAGE_REPLACEMENT_DISALLOWED(FALSE);
+ PAGE_REPLACEMENT_DISALLOWED(FALSE);
- if (kernel_memory_allocate(kernel_map, &addr, C_SEG_ALLOCSIZE, 0, KMA_COMPRESSOR | KMA_VAONLY) != KERN_SUCCESS)
- panic("c_seg_swapin: kernel_memory_allocate failed\n");
+ addr = (vm_offset_t)C_SEG_BUFFER_ADDRESS(c_seg->c_mysegno);
+ c_seg->c_store.c_buffer = (int32_t*) addr;
- kernel_memory_populate(kernel_map, addr, io_size, KMA_COMPRESSOR);
+ kernel_memory_populate(compressor_map, addr, io_size, KMA_COMPRESSOR, VM_KERN_MEMORY_COMPRESSOR);
- if (vm_swap_get(addr, f_offset, io_size) != KERN_SUCCESS) {
- PAGE_REPLACEMENT_DISALLOWED(TRUE);
+ if (vm_swap_get(c_seg, f_offset, io_size) != KERN_SUCCESS) {
+ PAGE_REPLACEMENT_DISALLOWED(TRUE);
- kernel_memory_depopulate(kernel_map, addr, io_size, KMA_COMPRESSOR);
- kmem_free(kernel_map, addr, C_SEG_ALLOCSIZE);
+ kernel_memory_depopulate(compressor_map, addr, io_size, KMA_COMPRESSOR);
- c_seg->c_store.c_buffer = (int32_t*) NULL;
- c_seg->c_populated_offset = C_SEG_BYTES_TO_OFFSET(0);
- } else {
- c_seg->c_store.c_buffer = (int32_t*) addr;
+ c_seg_swapin_requeue(c_seg, FALSE, TRUE, age_on_swapin_q);
+ } else {
#if ENCRYPTED_SWAP
- vm_swap_decrypt(c_seg);
+ vm_swap_decrypt(c_seg);
#endif /* ENCRYPTED_SWAP */
#if CHECKSUM_THE_SWAP
- if (c_seg->cseg_swap_size != io_size)
- panic("swapin size doesn't match swapout size");
+ if (c_seg->cseg_swap_size != io_size) {
+ panic("swapin size doesn't match swapout size");
+ }
- if (c_seg->cseg_hash != hash_string((char*) c_seg->c_store.c_buffer, (int)io_size)) {
- panic("c_seg_swapin - Swap hash mismatch\n");
- }
+ if (c_seg->cseg_hash != vmc_hash((char*) c_seg->c_store.c_buffer, (int)io_size)) {
+ panic("c_seg_swapin - Swap hash mismatch\n");
+ }
#endif /* CHECKSUM_THE_SWAP */
- PAGE_REPLACEMENT_DISALLOWED(TRUE);
+ PAGE_REPLACEMENT_DISALLOWED(TRUE);
- if (force_minor_compaction == TRUE) {
- lck_mtx_lock_spin_always(&c_seg->c_lock);
-
- c_seg_minor_compaction_and_unlock(c_seg, FALSE);
+ c_seg_swapin_requeue(c_seg, TRUE, force_minor_compaction == TRUE ? FALSE : TRUE, age_on_swapin_q);
+
+ OSAddAtomic64(c_seg->c_bytes_used, &compressor_bytes_used);
+
+ if (force_minor_compaction == TRUE) {
+ if (c_seg_minor_compaction_and_unlock(c_seg, FALSE)) {
+ /*
+ * c_seg was completely empty so it was freed,
+ * so be careful not to reference it again
+ *
+ * Drop the rwlock_count so that the thread priority
+ * is returned back to where it is supposed to be.
+ */
+ clear_thread_rwlock_boost();
+ return 1;
}
- OSAddAtomic64(c_seg->c_bytes_used, &compressor_bytes_used);
- OSAddAtomic64(C_SEG_ALLOCSIZE, &compressor_kvspace_used);
+
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
}
}
- c_seg_swapin_requeue(c_seg);
-
C_SEG_WAKEUP_DONE(c_seg);
+
+ /*
+ * Drop the rwlock_count so that the thread priority
+ * is returned back to where it is supposed to be.
+ */
+ clear_thread_rwlock_boost();
+
+ return 0;
+}
+
+
+static void
+c_segment_sv_hash_drop_ref(int hash_indx)
+{
+ struct c_sv_hash_entry o_sv_he, n_sv_he;
+
+ while (1) {
+ o_sv_he.he_record = c_segment_sv_hash_table[hash_indx].he_record;
+
+ n_sv_he.he_ref = o_sv_he.he_ref - 1;
+ n_sv_he.he_data = o_sv_he.he_data;
+
+ if (OSCompareAndSwap64((UInt64)o_sv_he.he_record, (UInt64)n_sv_he.he_record, (UInt64 *) &c_segment_sv_hash_table[hash_indx].he_record) == TRUE) {
+ if (n_sv_he.he_ref == 0) {
+ OSAddAtomic(-1, &c_segment_svp_in_hash);
+ }
+ break;
+ }
+ }
+}
+
+
+static int
+c_segment_sv_hash_insert(uint32_t data)
+{
+ int hash_sindx;
+ int misses;
+ struct c_sv_hash_entry o_sv_he, n_sv_he;
+ boolean_t got_ref = FALSE;
+
+ if (data == 0) {
+ OSAddAtomic(1, &c_segment_svp_zero_compressions);
+ } else {
+ OSAddAtomic(1, &c_segment_svp_nonzero_compressions);
+ }
+
+ hash_sindx = data & C_SV_HASH_MASK;
+
+ for (misses = 0; misses < C_SV_HASH_MAX_MISS; misses++) {
+ o_sv_he.he_record = c_segment_sv_hash_table[hash_sindx].he_record;
+
+ while (o_sv_he.he_data == data || o_sv_he.he_ref == 0) {
+ n_sv_he.he_ref = o_sv_he.he_ref + 1;
+ n_sv_he.he_data = data;
+
+ if (OSCompareAndSwap64((UInt64)o_sv_he.he_record, (UInt64)n_sv_he.he_record, (UInt64 *) &c_segment_sv_hash_table[hash_sindx].he_record) == TRUE) {
+ if (n_sv_he.he_ref == 1) {
+ OSAddAtomic(1, &c_segment_svp_in_hash);
+ }
+ got_ref = TRUE;
+ break;
+ }
+ o_sv_he.he_record = c_segment_sv_hash_table[hash_sindx].he_record;
+ }
+ if (got_ref == TRUE) {
+ break;
+ }
+ hash_sindx++;
+
+ if (hash_sindx == C_SV_HASH_SIZE) {
+ hash_sindx = 0;
+ }
+ }
+ if (got_ref == FALSE) {
+ return -1;
+ }
+
+ return hash_sindx;
+}
+
+
+#if RECORD_THE_COMPRESSED_DATA
+
+static void
+c_compressed_record_data(char *src, int c_size)
+{
+ if ((c_compressed_record_cptr + c_size + 4) >= c_compressed_record_ebuf) {
+ panic("c_compressed_record_cptr >= c_compressed_record_ebuf");
+ }
+
+ *(int *)((void *)c_compressed_record_cptr) = c_size;
+
+ c_compressed_record_cptr += 4;
+
+ memcpy(c_compressed_record_cptr, src, c_size);
+ c_compressed_record_cptr += c_size;
}
+#endif
static int
c_compress_page(char *src, c_slot_mapping_t slot_ptr, c_segment_t *current_chead, char *scratch_buf)
{
- int c_size;
- int c_rounded_size;
- int max_csize;
- c_slot_t cs;
- c_segment_t c_seg;
+ int c_size;
+ int c_rounded_size = 0;
+ int max_csize;
+ c_slot_t cs;
+ c_segment_t c_seg;
KERNEL_DEBUG(0xe0400000 | DBG_FUNC_START, *current_chead, 0, 0, 0, 0);
retry:
- if ((c_seg = c_seg_allocate(current_chead)) == NULL)
- return (1);
+ if ((c_seg = c_seg_allocate(current_chead)) == NULL) {
+ return 1;
+ }
/*
* returns with c_seg lock held
- * and PAGE_REPLACEMENT_DISALLOWED(TRUE)
+ * and PAGE_REPLACEMENT_DISALLOWED(TRUE)...
+ * c_nextslot has been allocated and
+ * c_store.c_buffer populated
*/
+ assert(c_seg->c_state == C_IS_FILLING);
+
cs = C_SEG_SLOT_FROM_INDEX(c_seg, c_seg->c_nextslot);
cs->c_packed_ptr = C_SLOT_PACK_PTR(slot_ptr);
max_csize = C_SEG_BUFSIZE - C_SEG_OFFSET_TO_BYTES((int32_t)cs->c_offset);
- if (max_csize > PAGE_SIZE)
+ if (max_csize > PAGE_SIZE) {
max_csize = PAGE_SIZE;
-
- if (C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset -
- c_seg->c_nextoffset)
- < (unsigned) max_csize + PAGE_SIZE &&
- (C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset)
- < C_SEG_ALLOCSIZE)) {
- lck_mtx_unlock_always(&c_seg->c_lock);
-
- kernel_memory_populate(kernel_map,
- (vm_offset_t) &c_seg->c_store.c_buffer[c_seg->c_populated_offset],
- PAGE_SIZE,
- KMA_COMPRESSOR);
-
- lck_mtx_lock_spin_always(&c_seg->c_lock);
-
- c_seg->c_populated_offset += C_SEG_BYTES_TO_OFFSET(PAGE_SIZE);
}
#if CHECKSUM_THE_DATA
- cs->c_hash_data = hash_string(src, PAGE_SIZE);
+ cs->c_hash_data = vmc_hash(src, PAGE_SIZE);
#endif
-
- c_size = WKdm_compress_new((WK_word *)(uintptr_t)src, (WK_word *)(uintptr_t)&c_seg->c_store.c_buffer[cs->c_offset],
- (WK_word *)(uintptr_t)scratch_buf, max_csize - 4);
- assert(c_size <= (max_csize - 4) && c_size >= -1);
+ boolean_t incomp_copy = FALSE;
+ int max_csize_adj = (max_csize - 4);
+
+ if (vm_compressor_algorithm() != VM_COMPRESSOR_DEFAULT_CODEC) {
+#if defined(__arm__) || defined(__arm64__)
+ uint16_t ccodec = CINVALID;
+
+ if (max_csize >= C_SEG_OFFSET_ALIGNMENT_BOUNDARY) {
+ c_size = metacompressor((const uint8_t *) src,
+ (uint8_t *) &c_seg->c_store.c_buffer[cs->c_offset],
+ max_csize_adj, &ccodec,
+ scratch_buf, &incomp_copy);
+#if C_SEG_OFFSET_ALIGNMENT_BOUNDARY > 4
+ if (c_size > max_csize_adj) {
+ c_size = -1;
+ }
+#endif
+ } else {
+ c_size = -1;
+ }
+ assert(ccodec == CCWK || ccodec == CCLZ4);
+ cs->c_codec = ccodec;
+#endif
+ } else {
+#if defined(__arm__) || defined(__arm64__)
+ cs->c_codec = CCWK;
+#endif
+#if defined(__arm64__)
+ __unreachable_ok_push
+ if (PAGE_SIZE == 4096) {
+ c_size = WKdm_compress_4k((WK_word *)(uintptr_t)src, (WK_word *)(uintptr_t)&c_seg->c_store.c_buffer[cs->c_offset],
+ (WK_word *)(uintptr_t)scratch_buf, max_csize_adj);
+ } else {
+ c_size = WKdm_compress_16k((WK_word *)(uintptr_t)src, (WK_word *)(uintptr_t)&c_seg->c_store.c_buffer[cs->c_offset],
+ (WK_word *)(uintptr_t)scratch_buf, max_csize_adj);
+ }
+ __unreachable_ok_pop
+#else
+ c_size = WKdm_compress_new((const WK_word *)(uintptr_t)src, (WK_word *)(uintptr_t)&c_seg->c_store.c_buffer[cs->c_offset],
+ (WK_word *)(uintptr_t)scratch_buf, max_csize_adj);
+#endif
+ }
+ assertf(((c_size <= max_csize_adj) && (c_size >= -1)),
+ "c_size invalid (%d, %d), cur compressions: %d", c_size, max_csize_adj, c_segment_pages_compressed);
if (c_size == -1) {
-
if (max_csize < PAGE_SIZE) {
c_current_seg_filled(c_seg, current_chead);
+ assert(*current_chead == NULL);
+ lck_mtx_unlock_always(&c_seg->c_lock);
+ /* TODO: it may be worth requiring codecs to distinguish
+ * between incompressible inputs and failures due to
+ * budget exhaustion.
+ */
PAGE_REPLACEMENT_DISALLOWED(FALSE);
-
goto retry;
}
c_size = PAGE_SIZE;
+ if (incomp_copy == FALSE) {
+ memcpy(&c_seg->c_store.c_buffer[cs->c_offset], src, c_size);
+ }
+
+ OSAddAtomic(1, &c_segment_noncompressible_pages);
+ } else if (c_size == 0) {
+ int hash_index;
+
+ /*
+ * special case - this is a page completely full of a single 32 bit value
+ */
+ hash_index = c_segment_sv_hash_insert(*(uint32_t *)(uintptr_t)src);
+
+ if (hash_index != -1) {
+ slot_ptr->s_cindx = hash_index;
+ slot_ptr->s_cseg = C_SV_CSEG_ID;
+
+ OSAddAtomic(1, &c_segment_svp_hash_succeeded);
+#if RECORD_THE_COMPRESSED_DATA
+ c_compressed_record_data(src, 4);
+#endif
+ goto sv_compression;
+ }
+ c_size = 4;
+
memcpy(&c_seg->c_store.c_buffer[cs->c_offset], src, c_size);
+
+ OSAddAtomic(1, &c_segment_svp_hash_failed);
}
+
+#if RECORD_THE_COMPRESSED_DATA
+ c_compressed_record_data((char *)&c_seg->c_store.c_buffer[cs->c_offset], c_size);
+#endif
#if CHECKSUM_THE_COMPRESSED_DATA
- cs->c_hash_compressed_data = hash_string((char *)&c_seg->c_store.c_buffer[cs->c_offset], c_size);
+ cs->c_hash_compressed_data = vmc_hash((char *)&c_seg->c_store.c_buffer[cs->c_offset], c_size);
+#endif
+#if POPCOUNT_THE_COMPRESSED_DATA
+ cs->c_pop_cdata = vmc_pop((uintptr_t) &c_seg->c_store.c_buffer[cs->c_offset], c_size);
#endif
c_rounded_size = (c_size + C_SEG_OFFSET_ALIGNMENT_MASK) & ~C_SEG_OFFSET_ALIGNMENT_MASK;
PACK_C_SIZE(cs, c_size);
c_seg->c_bytes_used += c_rounded_size;
c_seg->c_nextoffset += C_SEG_BYTES_TO_OFFSET(c_rounded_size);
+ c_seg->c_slots_used++;
slot_ptr->s_cindx = c_seg->c_nextslot++;
/* <csegno=0,indx=0> would mean "empty slot", so use csegno+1 */
- slot_ptr->s_cseg = c_seg->c_mysegno + 1;
+ slot_ptr->s_cseg = c_seg->c_mysegno + 1;
- if (c_seg->c_nextoffset >= C_SEG_OFF_LIMIT || c_seg->c_nextslot >= C_SLOT_MAX)
+sv_compression:
+ if (c_seg->c_nextoffset >= C_SEG_OFF_LIMIT || c_seg->c_nextslot >= C_SLOT_MAX_INDEX) {
c_current_seg_filled(c_seg, current_chead);
- else
- lck_mtx_unlock_always(&c_seg->c_lock);
+ assert(*current_chead == NULL);
+ }
+ lck_mtx_unlock_always(&c_seg->c_lock);
PAGE_REPLACEMENT_DISALLOWED(FALSE);
- OSAddAtomic64(c_rounded_size, &compressor_bytes_used);
+#if RECORD_THE_COMPRESSED_DATA
+ if ((c_compressed_record_cptr - c_compressed_record_sbuf) >= C_SEG_ALLOCSIZE) {
+ c_compressed_record_write(c_compressed_record_sbuf, (int)(c_compressed_record_cptr - c_compressed_record_sbuf));
+ c_compressed_record_cptr = c_compressed_record_sbuf;
+ }
+#endif
+ if (c_size) {
+ OSAddAtomic64(c_size, &c_segment_compressed_bytes);
+ OSAddAtomic64(c_rounded_size, &compressor_bytes_used);
+ }
OSAddAtomic64(PAGE_SIZE, &c_segment_input_bytes);
- OSAddAtomic64(c_size, &c_segment_compressed_bytes);
OSAddAtomic(1, &c_segment_pages_compressed);
OSAddAtomic(1, &sample_period_compression_count);
KERNEL_DEBUG(0xe0400000 | DBG_FUNC_END, *current_chead, c_size, c_segment_input_bytes, c_segment_compressed_bytes, 0);
- return (0);
+ return 0;
}
+static inline void
+sv_decompress(int32_t *ddst, int32_t pattern)
+{
+#if __x86_64__
+ memset_word(ddst, pattern, PAGE_SIZE / sizeof(int32_t));
+#else
+ size_t i;
+
+ /* Unroll the pattern fill loop 4x to encourage the
+ * compiler to emit NEON stores, cf.
+ * <rdar://problem/25839866> Loop autovectorization
+ * anomalies.
+ * We use separate loops for each PAGE_SIZE
+ * to allow the autovectorizer to engage, as PAGE_SIZE
+ * is currently not a constant.
+ */
+
+ __unreachable_ok_push
+ if (PAGE_SIZE == 4096) {
+ for (i = 0; i < (4096U / sizeof(int32_t)); i += 4) {
+ *ddst++ = pattern;
+ *ddst++ = pattern;
+ *ddst++ = pattern;
+ *ddst++ = pattern;
+ }
+ } else {
+ assert(PAGE_SIZE == 16384);
+ for (i = 0; i < (int)(16384U / sizeof(int32_t)); i += 4) {
+ *ddst++ = pattern;
+ *ddst++ = pattern;
+ *ddst++ = pattern;
+ *ddst++ = pattern;
+ }
+ }
+ __unreachable_ok_pop
+#endif
+}
static int
c_decompress_page(char *dst, volatile c_slot_mapping_t slot_ptr, int flags, int *zeroslot)
{
- c_slot_t cs;
- c_segment_t c_seg;
- int c_indx;
- int c_rounded_size;
- uint32_t c_size;
- int retval = 0;
- boolean_t c_seg_has_data = TRUE;
- boolean_t c_seg_swappedin = FALSE;
- boolean_t need_unlock = TRUE;
- boolean_t consider_defragmenting = FALSE;
+ c_slot_t cs;
+ c_segment_t c_seg;
+ uint32_t c_segno;
+ int c_indx;
+ int c_rounded_size;
+ uint32_t c_size;
+ int retval = 0;
+ boolean_t need_unlock = TRUE;
+ boolean_t consider_defragmenting = FALSE;
+ boolean_t kdp_mode = FALSE;
+
+ if (__improbable(flags & C_KDP)) {
+ if (not_in_kdp) {
+ panic("C_KDP passed to decompress page from outside of debugger context");
+ }
+
+ assert((flags & C_KEEP) == C_KEEP);
+ assert((flags & C_DONT_BLOCK) == C_DONT_BLOCK);
+
+ if ((flags & (C_DONT_BLOCK | C_KEEP)) != (C_DONT_BLOCK | C_KEEP)) {
+ return -2;
+ }
+
+ kdp_mode = TRUE;
+ *zeroslot = 0;
+ }
ReTry:
- PAGE_REPLACEMENT_DISALLOWED(TRUE);
+ if (__probable(!kdp_mode)) {
+ PAGE_REPLACEMENT_DISALLOWED(TRUE);
+ } else {
+ if (kdp_lck_rw_lock_is_acquired_exclusive(&c_master_lock)) {
+ return -2;
+ }
+ }
#if HIBERNATION
/*
* to disk... in this state we allow freeing of compressed
* pages and must honor the C_DONT_BLOCK case
*/
- if (dst && decompressions_blocked == TRUE) {
+ if (__improbable(dst && decompressions_blocked == TRUE)) {
if (flags & C_DONT_BLOCK) {
-
- PAGE_REPLACEMENT_DISALLOWED(FALSE);
+ if (__probable(!kdp_mode)) {
+ PAGE_REPLACEMENT_DISALLOWED(FALSE);
+ }
*zeroslot = 0;
- return (-2);
+ return -2;
}
/*
* it's safe to atomically assert and block behind the
}
#endif
/* s_cseg is actually "segno+1" */
- c_seg = c_segments[slot_ptr->s_cseg - 1].c_seg;
+ c_segno = slot_ptr->s_cseg - 1;
- lck_mtx_lock_spin_always(&c_seg->c_lock);
+ if (__improbable(c_segno >= c_segments_available)) {
+ panic("c_decompress_page: c_segno %d >= c_segments_available %d, slot_ptr(%p), slot_data(%x)",
+ c_segno, c_segments_available, slot_ptr, *(int *)((void *)slot_ptr));
+ }
- if (flags & C_DONT_BLOCK) {
- if (c_seg->c_busy || (c_seg->c_ondisk && dst)) {
+ if (__improbable(c_segments[c_segno].c_segno < c_segments_available)) {
+ panic("c_decompress_page: c_segno %d is free, slot_ptr(%p), slot_data(%x)",
+ c_segno, slot_ptr, *(int *)((void *)slot_ptr));
+ }
- retval = -2;
+ c_seg = c_segments[c_segno].c_seg;
+
+ if (__probable(!kdp_mode)) {
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
+ } else {
+ if (kdp_lck_mtx_lock_spin_is_acquired(&c_seg->c_lock)) {
+ return -2;
+ }
+ }
+
+ assert(c_seg->c_state != C_IS_EMPTY && c_seg->c_state != C_IS_FREE);
+
+ if (dst == NULL && c_seg->c_busy_swapping) {
+ assert(c_seg->c_busy);
+
+ goto bypass_busy_check;
+ }
+ if (flags & C_DONT_BLOCK) {
+ if (c_seg->c_busy || (C_SEG_IS_ONDISK(c_seg) && dst)) {
*zeroslot = 0;
+ retval = -2;
goto done;
}
}
if (c_seg->c_busy) {
-
PAGE_REPLACEMENT_DISALLOWED(FALSE);
c_seg_wait_on_busy(c_seg);
goto ReTry;
}
+bypass_busy_check:
+
c_indx = slot_ptr->s_cindx;
+ if (__improbable(c_indx >= c_seg->c_nextslot)) {
+ panic("c_decompress_page: c_indx %d >= c_nextslot %d, c_seg(%p), slot_ptr(%p), slot_data(%x)",
+ c_indx, c_seg->c_nextslot, c_seg, slot_ptr, *(int *)((void *)slot_ptr));
+ }
+
cs = C_SEG_SLOT_FROM_INDEX(c_seg, c_indx);
c_size = UNPACK_C_SIZE(cs);
+ if (__improbable(c_size == 0)) {
+ panic("c_decompress_page: c_size == 0, c_seg(%p), slot_ptr(%p), slot_data(%x)",
+ c_seg, slot_ptr, *(int *)((void *)slot_ptr));
+ }
+
c_rounded_size = (c_size + C_SEG_OFFSET_ALIGNMENT_MASK) & ~C_SEG_OFFSET_ALIGNMENT_MASK;
if (dst) {
- uint32_t age_of_cseg;
- clock_sec_t cur_ts_sec;
- clock_nsec_t cur_ts_nsec;
-
- if (c_seg->c_on_swappedout_q || c_seg->c_on_swappedout_sparse_q) {
- if (c_seg->c_ondisk)
- c_seg_swappedin = TRUE;
- c_seg_swapin(c_seg, FALSE);
- }
- if (c_seg->c_store.c_buffer == NULL) {
- c_seg_has_data = FALSE;
- goto c_seg_invalid_data;
+ uint32_t age_of_cseg;
+ clock_sec_t cur_ts_sec;
+ clock_nsec_t cur_ts_nsec;
+
+ if (C_SEG_IS_ONDISK(c_seg)) {
+ assert(kdp_mode == FALSE);
+ retval = c_seg_swapin(c_seg, FALSE, TRUE);
+ assert(retval == 0);
+
+ retval = 1;
+ }
+ if (c_seg->c_state == C_ON_BAD_Q) {
+ assert(c_seg->c_store.c_buffer == NULL);
+ *zeroslot = 0;
+
+ retval = -1;
+ goto done;
+ }
+
+#if POPCOUNT_THE_COMPRESSED_DATA
+ unsigned csvpop;
+ uintptr_t csvaddr = (uintptr_t) &c_seg->c_store.c_buffer[cs->c_offset];
+ if (cs->c_pop_cdata != (csvpop = vmc_pop(csvaddr, c_size))) {
+ panic("Compressed data popcount doesn't match original, bit distance: %d %p (phys: %p) %p %p 0x%llx 0x%x 0x%x 0x%x", (csvpop - cs->c_pop_cdata), (void *)csvaddr, (void *) kvtophys(csvaddr), c_seg, cs, cs->c_offset, c_size, csvpop, cs->c_pop_cdata);
}
+#endif
+
#if CHECKSUM_THE_COMPRESSED_DATA
- if (cs->c_hash_compressed_data != hash_string((char *)&c_seg->c_store.c_buffer[cs->c_offset], c_size))
- panic("compressed data doesn't match original");
+ unsigned csvhash;
+ if (cs->c_hash_compressed_data != (csvhash = vmc_hash((char *)&c_seg->c_store.c_buffer[cs->c_offset], c_size))) {
+ panic("Compressed data doesn't match original %p %p %u %u %u", c_seg, cs, c_size, cs->c_hash_compressed_data, csvhash);
+ }
#endif
if (c_rounded_size == PAGE_SIZE) {
/*
* page wasn't compressible... just copy it out
*/
memcpy(dst, &c_seg->c_store.c_buffer[cs->c_offset], PAGE_SIZE);
- } else {
- uint32_t my_cpu_no;
- char *scratch_buf;
+ } else if (c_size == 4) {
+ int32_t data;
+ int32_t *dptr;
/*
- * we're behind the c_seg lock held in spin mode
- * which means pre-emption is disabled... therefore
- * the following sequence is atomic and safe
+ * page was populated with a single value
+ * that didn't fit into our fast hash
+ * so we packed it in as a single non-compressed value
+ * that we need to populate the page with
*/
- my_cpu_no = cpu_number();
+ dptr = (int32_t *)(uintptr_t)dst;
+ data = *(int32_t *)(&c_seg->c_store.c_buffer[cs->c_offset]);
+ sv_decompress(dptr, data);
+ } else {
+ uint32_t my_cpu_no;
+ char *scratch_buf;
+
+ if (__probable(!kdp_mode)) {
+ /*
+ * we're behind the c_seg lock held in spin mode
+ * which means pre-emption is disabled... therefore
+ * the following sequence is atomic and safe
+ */
+ my_cpu_no = cpu_number();
+
+ assert(my_cpu_no < compressor_cpus);
- assert(my_cpu_no < compressor_cpus);
+ scratch_buf = &compressor_scratch_bufs[my_cpu_no * vm_compressor_get_decode_scratch_size()];
+ } else {
+ scratch_buf = kdp_compressor_scratch_buf;
+ }
- scratch_buf = &compressor_scratch_bufs[my_cpu_no * WKdm_SCRATCH_BUF_SIZE];
- WKdm_decompress_new((WK_word *)(uintptr_t)&c_seg->c_store.c_buffer[cs->c_offset],
+ if (vm_compressor_algorithm() != VM_COMPRESSOR_DEFAULT_CODEC) {
+#if defined(__arm__) || defined(__arm64__)
+ uint16_t c_codec = cs->c_codec;
+ metadecompressor((const uint8_t *) &c_seg->c_store.c_buffer[cs->c_offset],
+ (uint8_t *)dst, c_size, c_codec, (void *)scratch_buf);
+#endif
+ } else {
+#if defined(__arm64__)
+ __unreachable_ok_push
+ if (PAGE_SIZE == 4096) {
+ WKdm_decompress_4k((WK_word *)(uintptr_t)&c_seg->c_store.c_buffer[cs->c_offset],
+ (WK_word *)(uintptr_t)dst, (WK_word *)(uintptr_t)scratch_buf, c_size);
+ } else {
+ WKdm_decompress_16k((WK_word *)(uintptr_t)&c_seg->c_store.c_buffer[cs->c_offset],
(WK_word *)(uintptr_t)dst, (WK_word *)(uintptr_t)scratch_buf, c_size);
+ }
+ __unreachable_ok_pop
+#else
+ WKdm_decompress_new((WK_word *)(uintptr_t)&c_seg->c_store.c_buffer[cs->c_offset],
+ (WK_word *)(uintptr_t)dst, (WK_word *)(uintptr_t)scratch_buf, c_size);
+#endif
+ }
}
#if CHECKSUM_THE_DATA
- if (cs->c_hash_data != hash_string(dst, PAGE_SIZE))
- panic("decompressed data doesn't match original");
+ if (cs->c_hash_data != vmc_hash(dst, PAGE_SIZE)) {
+#if defined(__arm__) || defined(__arm64__)
+ int32_t *dinput = &c_seg->c_store.c_buffer[cs->c_offset];
+ panic("decompressed data doesn't match original cs: %p, hash: 0x%x, offset: %d, c_size: %d, c_rounded_size: %d, codec: %d, header: 0x%x 0x%x 0x%x", cs, cs->c_hash_data, cs->c_offset, c_size, c_rounded_size, cs->c_codec, *dinput, *(dinput + 1), *(dinput + 2));
+#else
+ panic("decompressed data doesn't match original cs: %p, hash: %d, offset: 0x%x, c_size: %d", cs, cs->c_hash_data, cs->c_offset, c_size);
#endif
- if (!c_seg->c_was_swapped_in) {
-
+ }
+#endif
+ if (c_seg->c_swappedin_ts == 0 && !kdp_mode) {
clock_get_system_nanotime(&cur_ts_sec, &cur_ts_nsec);
age_of_cseg = (uint32_t)cur_ts_sec - c_seg->c_creation_ts;
-
- if (age_of_cseg < DECOMPRESSION_SAMPLE_MAX_AGE)
+ if (age_of_cseg < DECOMPRESSION_SAMPLE_MAX_AGE) {
OSAddAtomic(1, &age_of_decompressions_during_sample_period[age_of_cseg]);
- else
+ } else {
OSAddAtomic(1, &overage_decompressions_during_sample_period);
+ }
OSAddAtomic(1, &sample_period_decompression_count);
}
- } else {
- if (c_seg->c_store.c_buffer == NULL)
- c_seg_has_data = FALSE;
}
-c_seg_invalid_data:
-
- if (c_seg_has_data == TRUE) {
- if (c_seg_swappedin == TRUE)
- retval = 1;
- else
- retval = 0;
- } else
- retval = -1;
-
if (flags & C_KEEP) {
*zeroslot = 0;
goto done;
}
+ assert(kdp_mode == FALSE);
+
c_seg->c_bytes_unused += c_rounded_size;
c_seg->c_bytes_used -= c_rounded_size;
+
+ assert(c_seg->c_slots_used);
+ c_seg->c_slots_used--;
+
PACK_C_SIZE(cs, 0);
- if (c_indx < c_seg->c_firstemptyslot)
+ if (c_indx < c_seg->c_firstemptyslot) {
c_seg->c_firstemptyslot = c_indx;
+ }
OSAddAtomic(-1, &c_segment_pages_compressed);
- if (c_seg_has_data == TRUE && !c_seg->c_ondisk) {
+ if (c_seg->c_state != C_ON_BAD_Q && !(C_SEG_IS_ONDISK(c_seg))) {
/*
- * c_ondisk == TRUE can occur when we're doing a
+ * C_SEG_IS_ONDISK == TRUE can occur when we're doing a
* free of a compressed page (i.e. dst == NULL)
*/
OSAddAtomic64(-c_rounded_size, &compressor_bytes_used);
}
- if (!c_seg->c_filling) {
+ if (c_seg->c_busy_swapping) {
+ /*
+ * bypass case for c_busy_swapping...
+ * let the swapin/swapout paths deal with putting
+ * the c_seg on the minor compaction queue if needed
+ */
+ assert(c_seg->c_busy);
+ goto done;
+ }
+ assert(!c_seg->c_busy);
+
+ if (c_seg->c_state != C_IS_FILLING) {
if (c_seg->c_bytes_used == 0) {
- if (!c_seg->c_ondisk) {
- int pages_populated;
+ if (!(C_SEG_IS_ONDISK(c_seg))) {
+ int pages_populated;
pages_populated = (round_page_32(C_SEG_OFFSET_TO_BYTES(c_seg->c_populated_offset))) / PAGE_SIZE;
c_seg->c_populated_offset = C_SEG_BYTES_TO_OFFSET(0);
if (pages_populated) {
+ assert(c_seg->c_state != C_ON_BAD_Q);
assert(c_seg->c_store.c_buffer != NULL);
C_SEG_BUSY(c_seg);
lck_mtx_unlock_always(&c_seg->c_lock);
- kernel_memory_depopulate(kernel_map, (vm_offset_t) c_seg->c_store.c_buffer, pages_populated * PAGE_SIZE, KMA_COMPRESSOR);
+ kernel_memory_depopulate(compressor_map, (vm_offset_t) c_seg->c_store.c_buffer, pages_populated * PAGE_SIZE, KMA_COMPRESSOR);
lck_mtx_lock_spin_always(&c_seg->c_lock);
C_SEG_WAKEUP_DONE(c_seg);
}
- if (!c_seg->c_on_minorcompact_q && !c_seg->c_on_swapout_q)
- c_seg_need_delayed_compaction(c_seg);
- } else
- assert(c_seg->c_on_swappedout_sparse_q);
-
+ if (!c_seg->c_on_minorcompact_q && c_seg->c_state != C_ON_SWAPOUT_Q && c_seg->c_state != C_ON_SWAPIO_Q) {
+ c_seg_need_delayed_compaction(c_seg, FALSE);
+ }
+ } else {
+ if (c_seg->c_state != C_ON_SWAPPEDOUTSPARSE_Q) {
+ c_seg_move_to_sparse_list(c_seg);
+ consider_defragmenting = TRUE;
+ }
+ }
} else if (c_seg->c_on_minorcompact_q) {
+ assert(c_seg->c_state != C_ON_BAD_Q);
+ assert(!C_SEG_IS_ON_DISK_OR_SOQ(c_seg));
- if (C_SEG_INCORE_IS_SPARSE(c_seg)) {
+ if (C_SEG_SHOULD_MINORCOMPACT_NOW(c_seg)) {
c_seg_try_minor_compaction_and_unlock(c_seg);
need_unlock = FALSE;
}
- } else if (!c_seg->c_ondisk) {
-
- if (c_seg_has_data == TRUE && !c_seg->c_on_swapout_q && C_SEG_UNUSED_BYTES(c_seg) >= PAGE_SIZE) {
- c_seg_need_delayed_compaction(c_seg);
+ } else if (!(C_SEG_IS_ONDISK(c_seg))) {
+ if (c_seg->c_state != C_ON_BAD_Q && c_seg->c_state != C_ON_SWAPOUT_Q && c_seg->c_state != C_ON_SWAPIO_Q &&
+ C_SEG_UNUSED_BYTES(c_seg) >= PAGE_SIZE) {
+ c_seg_need_delayed_compaction(c_seg, FALSE);
}
- } else if (!c_seg->c_on_swappedout_sparse_q && C_SEG_ONDISK_IS_SPARSE(c_seg)) {
-
+ } else if (c_seg->c_state != C_ON_SWAPPEDOUTSPARSE_Q && C_SEG_ONDISK_IS_SPARSE(c_seg)) {
c_seg_move_to_sparse_list(c_seg);
consider_defragmenting = TRUE;
}
}
done:
- if (need_unlock == TRUE)
+ if (__improbable(kdp_mode)) {
+ return retval;
+ }
+
+ if (need_unlock == TRUE) {
lck_mtx_unlock_always(&c_seg->c_lock);
+ }
PAGE_REPLACEMENT_DISALLOWED(FALSE);
- if (consider_defragmenting == TRUE)
- vm_swap_consider_defragmenting();
+ if (consider_defragmenting == TRUE) {
+ vm_swap_consider_defragmenting(VM_SWAP_FLAGS_NONE);
+ }
+#if CONFIG_EMBEDDED
+ if ((c_minor_count && COMPRESSOR_NEEDS_TO_MINOR_COMPACT()) || vm_compressor_needs_to_major_compact()) {
+ vm_wake_compactor_swapper();
+ }
+#endif
- return (retval);
+ return retval;
}
int
vm_compressor_get(ppnum_t pn, int *slot, int flags)
{
- char *dst;
- int zeroslot = 1;
- int retval;
+ c_slot_mapping_t slot_ptr;
+ char *dst;
+ int zeroslot = 1;
+ int retval;
+
+ dst = pmap_map_compressor_page(pn);
+ slot_ptr = (c_slot_mapping_t)slot;
+ assert(dst != NULL);
+
+ if (slot_ptr->s_cseg == C_SV_CSEG_ID) {
+ int32_t data;
+ int32_t *dptr;
+
+ /*
+ * page was populated with a single value
+ * that found a home in our hash table
+ * grab that value from the hash and populate the page
+ * that we need to populate the page with
+ */
+ dptr = (int32_t *)(uintptr_t)dst;
+ data = c_segment_sv_hash_table[slot_ptr->s_cindx].he_data;
#if __x86_64__
- dst = PHYSMAP_PTOV((uint64_t)pn << (uint64_t)PAGE_SHIFT);
+ memset_word(dptr, data, PAGE_SIZE / sizeof(int32_t));
#else
-#error "unsupported architecture"
+ {
+ int i;
+
+ for (i = 0; i < (int)(PAGE_SIZE / sizeof(int32_t)); i++) {
+ *dptr++ = data;
+ }
+ }
#endif
+ if (!(flags & C_KEEP)) {
+ c_segment_sv_hash_drop_ref(slot_ptr->s_cindx);
- retval = c_decompress_page(dst, (c_slot_mapping_t)slot, flags, &zeroslot);
+ OSAddAtomic(-1, &c_segment_pages_compressed);
+ *slot = 0;
+ }
+ if (data) {
+ OSAddAtomic(1, &c_segment_svp_nonzero_decompressions);
+ } else {
+ OSAddAtomic(1, &c_segment_svp_zero_decompressions);
+ }
+
+ pmap_unmap_compressor_page(pn, dst);
+ return 0;
+ }
+
+ retval = c_decompress_page(dst, slot_ptr, flags, &zeroslot);
/*
* zeroslot will be set to 0 by c_decompress_page if (flags & C_KEEP)
- * or (flags & C_DONT_BLOCK) and we found 'c_busy' or 'c_ondisk' set
+ * or (flags & C_DONT_BLOCK) and we found 'c_busy' or 'C_SEG_IS_ONDISK' to be TRUE
*/
if (zeroslot) {
*slot = 0;
}
+
+ pmap_unmap_compressor_page(pn, dst);
+
/*
* returns 0 if we successfully decompressed a page from a segment already in memory
* returns 1 if we had to first swap in the segment, before successfully decompressing the page
* returns -1 if we encountered an error swapping in the segment - decompression failed
- * returns -2 if (flags & C_DONT_BLOCK) and we found 'c_busy' or 'c_ondisk' set
+ * returns -2 if (flags & C_DONT_BLOCK) and we found 'c_busy' or 'C_SEG_IS_ONDISK' to be true
*/
- return (retval);
+ return retval;
}
int
vm_compressor_free(int *slot, int flags)
{
- int zeroslot = 1;
- int retval;
+ c_slot_mapping_t slot_ptr;
+ int zeroslot = 1;
+ int retval;
assert(flags == 0 || flags == C_DONT_BLOCK);
- retval = c_decompress_page(NULL, (c_slot_mapping_t)slot, flags, &zeroslot);
+ slot_ptr = (c_slot_mapping_t)slot;
+
+ if (slot_ptr->s_cseg == C_SV_CSEG_ID) {
+ c_segment_sv_hash_drop_ref(slot_ptr->s_cindx);
+ OSAddAtomic(-1, &c_segment_pages_compressed);
+
+ *slot = 0;
+ return 0;
+ }
+ retval = c_decompress_page(NULL, slot_ptr, flags, &zeroslot);
/*
* returns 0 if we successfully freed the specified compressed page
* returns -2 if (flags & C_DONT_BLOCK) and we found 'c_busy' set
*/
- if (retval == 0)
+ if (retval == 0) {
*slot = 0;
+ } else {
+ assert(retval == -2);
+ }
- return (retval);
+ return retval;
}
int
vm_compressor_put(ppnum_t pn, int *slot, void **current_chead, char *scratch_buf)
{
- char *src;
- int retval;
+ char *src;
+ int retval;
+
+ src = pmap_map_compressor_page(pn);
+ assert(src != NULL);
-#if __x86_64__
- src = PHYSMAP_PTOV((uint64_t)pn << (uint64_t)PAGE_SHIFT);
-#else
-#error "unsupported architecture"
-#endif
retval = c_compress_page(src, (c_slot_mapping_t)slot, (c_segment_t *)current_chead, scratch_buf);
+ pmap_unmap_compressor_page(pn, src);
- return (retval);
+ return retval;
}
void
vm_compressor_transfer(
- int *dst_slot_p,
- int *src_slot_p)
+ int *dst_slot_p,
+ int *src_slot_p)
{
- c_slot_mapping_t dst_slot, src_slot;
- c_segment_t c_seg;
- int c_indx;
- c_slot_t cs;
+ c_slot_mapping_t dst_slot, src_slot;
+ c_segment_t c_seg;
+ int c_indx;
+ c_slot_t cs;
- dst_slot = (c_slot_mapping_t) dst_slot_p;
src_slot = (c_slot_mapping_t) src_slot_p;
+ if (src_slot->s_cseg == C_SV_CSEG_ID) {
+ *dst_slot_p = *src_slot_p;
+ *src_slot_p = 0;
+ return;
+ }
+ dst_slot = (c_slot_mapping_t) dst_slot_p;
Retry:
PAGE_REPLACEMENT_DISALLOWED(TRUE);
/* get segment for src_slot */
- c_seg = c_segments[src_slot->s_cseg -1].c_seg;
+ c_seg = c_segments[src_slot->s_cseg - 1].c_seg;
/* lock segment */
lck_mtx_lock_spin_always(&c_seg->c_lock);
/* wait if it's busy */
- if (c_seg->c_busy) {
+ if (c_seg->c_busy && !c_seg->c_busy_swapping) {
PAGE_REPLACEMENT_DISALLOWED(FALSE);
c_seg_wait_on_busy(c_seg);
goto Retry;
lck_mtx_unlock_always(&c_seg->c_lock);
PAGE_REPLACEMENT_DISALLOWED(FALSE);
}
+
+#if CONFIG_FREEZE
+
+int freezer_finished_filling = 0;
+
+void
+vm_compressor_finished_filling(
+ void **current_chead)
+{
+ c_segment_t c_seg;
+
+ if ((c_seg = *(c_segment_t *)current_chead) == NULL) {
+ return;
+ }
+
+ assert(c_seg->c_state == C_IS_FILLING);
+
+ lck_mtx_lock_spin_always(&c_seg->c_lock);
+
+ c_current_seg_filled(c_seg, (c_segment_t *)current_chead);
+
+ lck_mtx_unlock_always(&c_seg->c_lock);
+
+ freezer_finished_filling++;
+}
+
+
+/*
+ * This routine is used to transfer the compressed chunks from
+ * the c_seg/cindx pointed to by slot_p into a new c_seg headed
+ * by the current_chead and a new cindx within that c_seg.
+ *
+ * Currently, this routine is only used by the "freezer backed by
+ * compressor with swap" mode to create a series of c_segs that
+ * only contain compressed data belonging to one task. So, we
+ * move a task's previously compressed data into a set of new
+ * c_segs which will also hold the task's yet to be compressed data.
+ */
+
+kern_return_t
+vm_compressor_relocate(
+ void **current_chead,
+ int *slot_p)
+{
+ c_slot_mapping_t slot_ptr;
+ c_slot_mapping_t src_slot;
+ uint32_t c_rounded_size;
+ uint32_t c_size;
+ uint16_t dst_slot;
+ c_slot_t c_dst;
+ c_slot_t c_src;
+ int c_indx;
+ c_segment_t c_seg_dst = NULL;
+ c_segment_t c_seg_src = NULL;
+ kern_return_t kr = KERN_SUCCESS;
+
+
+ src_slot = (c_slot_mapping_t) slot_p;
+
+ if (src_slot->s_cseg == C_SV_CSEG_ID) {
+ /*
+ * no need to relocate... this is a page full of a single
+ * value which is hashed to a single entry not contained
+ * in a c_segment_t
+ */
+ return kr;
+ }
+
+Relookup_dst:
+ c_seg_dst = c_seg_allocate((c_segment_t *)current_chead);
+ /*
+ * returns with c_seg lock held
+ * and PAGE_REPLACEMENT_DISALLOWED(TRUE)...
+ * c_nextslot has been allocated and
+ * c_store.c_buffer populated
+ */
+ if (c_seg_dst == NULL) {
+ /*
+ * Out of compression segments?
+ */
+ kr = KERN_RESOURCE_SHORTAGE;
+ goto out;
+ }
+
+ assert(c_seg_dst->c_busy == 0);
+
+ C_SEG_BUSY(c_seg_dst);
+
+ dst_slot = c_seg_dst->c_nextslot;
+
+ lck_mtx_unlock_always(&c_seg_dst->c_lock);
+
+Relookup_src:
+ c_seg_src = c_segments[src_slot->s_cseg - 1].c_seg;
+
+ assert(c_seg_dst != c_seg_src);
+
+ lck_mtx_lock_spin_always(&c_seg_src->c_lock);
+
+ if (C_SEG_IS_ONDISK(c_seg_src)) {
+ /*
+ * A "thaw" can mark a process as eligible for
+ * another freeze cycle without bringing any of
+ * its swapped out c_segs back from disk (because
+ * that is done on-demand).
+ *
+ * If the src c_seg we find for our pre-compressed
+ * data is already on-disk, then we are dealing
+ * with an app's data that is already packed and
+ * swapped out. Don't do anything.
+ */
+
+ PAGE_REPLACEMENT_DISALLOWED(FALSE);
+
+ lck_mtx_unlock_always(&c_seg_src->c_lock);
+
+ c_seg_src = NULL;
+
+ goto out;
+ }
+
+ if (c_seg_src->c_busy) {
+ PAGE_REPLACEMENT_DISALLOWED(FALSE);
+ c_seg_wait_on_busy(c_seg_src);
+
+ c_seg_src = NULL;
+
+ PAGE_REPLACEMENT_DISALLOWED(TRUE);
+
+ goto Relookup_src;
+ }
+
+ C_SEG_BUSY(c_seg_src);
+
+ lck_mtx_unlock_always(&c_seg_src->c_lock);
+
+ PAGE_REPLACEMENT_DISALLOWED(FALSE);
+
+ /* find the c_slot */
+ c_indx = src_slot->s_cindx;
+
+ c_src = C_SEG_SLOT_FROM_INDEX(c_seg_src, c_indx);
+
+ c_size = UNPACK_C_SIZE(c_src);
+
+ assert(c_size);
+
+ if (c_size > (uint32_t)(C_SEG_BUFSIZE - C_SEG_OFFSET_TO_BYTES((int32_t)c_seg_dst->c_nextoffset))) {
+ /*
+ * This segment is full. We need a new one.
+ */
+
+ PAGE_REPLACEMENT_DISALLOWED(TRUE);
+
+ lck_mtx_lock_spin_always(&c_seg_src->c_lock);
+ C_SEG_WAKEUP_DONE(c_seg_src);
+ lck_mtx_unlock_always(&c_seg_src->c_lock);
+
+ c_seg_src = NULL;
+
+ lck_mtx_lock_spin_always(&c_seg_dst->c_lock);
+
+ assert(c_seg_dst->c_busy);
+ assert(c_seg_dst->c_state == C_IS_FILLING);
+ assert(!c_seg_dst->c_on_minorcompact_q);
+
+ c_current_seg_filled(c_seg_dst, (c_segment_t *)current_chead);
+ assert(*current_chead == NULL);
+
+ C_SEG_WAKEUP_DONE(c_seg_dst);
+
+ lck_mtx_unlock_always(&c_seg_dst->c_lock);
+
+ c_seg_dst = NULL;
+
+ PAGE_REPLACEMENT_DISALLOWED(FALSE);
+
+ goto Relookup_dst;
+ }
+
+ c_dst = C_SEG_SLOT_FROM_INDEX(c_seg_dst, c_seg_dst->c_nextslot);
+
+ memcpy(&c_seg_dst->c_store.c_buffer[c_seg_dst->c_nextoffset], &c_seg_src->c_store.c_buffer[c_src->c_offset], c_size);
+//is platform alignment actually necessary since wkdm aligns its output?
+ c_rounded_size = (c_size + C_SEG_OFFSET_ALIGNMENT_MASK) & ~C_SEG_OFFSET_ALIGNMENT_MASK;
+
+ cslot_copy(c_dst, c_src);
+ c_dst->c_offset = c_seg_dst->c_nextoffset;
+
+ if (c_seg_dst->c_firstemptyslot == c_seg_dst->c_nextslot) {
+ c_seg_dst->c_firstemptyslot++;
+ }
+
+ c_seg_dst->c_slots_used++;
+ c_seg_dst->c_nextslot++;
+ c_seg_dst->c_bytes_used += c_rounded_size;
+ c_seg_dst->c_nextoffset += C_SEG_BYTES_TO_OFFSET(c_rounded_size);
+
+
+ PACK_C_SIZE(c_src, 0);
+
+ c_seg_src->c_bytes_used -= c_rounded_size;
+ c_seg_src->c_bytes_unused += c_rounded_size;
+
+ assert(c_seg_src->c_slots_used);
+ c_seg_src->c_slots_used--;
+
+ if (c_indx < c_seg_src->c_firstemptyslot) {
+ c_seg_src->c_firstemptyslot = c_indx;
+ }
+
+ c_dst = C_SEG_SLOT_FROM_INDEX(c_seg_dst, dst_slot);
+
+ PAGE_REPLACEMENT_ALLOWED(TRUE);
+ slot_ptr = (c_slot_mapping_t)C_SLOT_UNPACK_PTR(c_dst);
+ /* <csegno=0,indx=0> would mean "empty slot", so use csegno+1 */
+ slot_ptr->s_cseg = c_seg_dst->c_mysegno + 1;
+ slot_ptr->s_cindx = dst_slot;
+
+ PAGE_REPLACEMENT_ALLOWED(FALSE);
+
+out:
+ if (c_seg_src) {
+ lck_mtx_lock_spin_always(&c_seg_src->c_lock);
+
+ C_SEG_WAKEUP_DONE(c_seg_src);
+
+ if (c_seg_src->c_bytes_used == 0 && c_seg_src->c_state != C_IS_FILLING) {
+ if (!c_seg_src->c_on_minorcompact_q) {
+ c_seg_need_delayed_compaction(c_seg_src, FALSE);
+ }
+ }
+
+ lck_mtx_unlock_always(&c_seg_src->c_lock);
+ }
+
+ if (c_seg_dst) {
+ PAGE_REPLACEMENT_DISALLOWED(TRUE);
+
+ lck_mtx_lock_spin_always(&c_seg_dst->c_lock);
+
+ if (c_seg_dst->c_nextoffset >= C_SEG_OFF_LIMIT || c_seg_dst->c_nextslot >= C_SLOT_MAX_INDEX) {
+ /*
+ * Nearing or exceeded maximum slot and offset capacity.
+ */
+ assert(c_seg_dst->c_busy);
+ assert(c_seg_dst->c_state == C_IS_FILLING);
+ assert(!c_seg_dst->c_on_minorcompact_q);
+
+ c_current_seg_filled(c_seg_dst, (c_segment_t *)current_chead);
+ assert(*current_chead == NULL);
+ }
+
+ C_SEG_WAKEUP_DONE(c_seg_dst);
+
+ lck_mtx_unlock_always(&c_seg_dst->c_lock);
+
+ c_seg_dst = NULL;
+
+ PAGE_REPLACEMENT_DISALLOWED(FALSE);
+ }
+
+ return kr;
+}
+#endif /* CONFIG_FREEZE */
projects / apple / xnu.git / blobdiff