/*
- * Copyright (c) 2000-2008 Apple Inc. All rights reserved.
+ * Copyright (c) 2000-2014 Apple Inc. All rights reserved.
*
* @APPLE_OSREFERENCE_LICENSE_HEADER_START@
*
#include <mach/vm_map.h>
#include <mach/upl.h>
#include <kern/task.h>
+#include <kern/policy_internal.h>
#include <vm/vm_kern.h>
#include <vm/vm_map.h>
#include <vm/vm_pageout.h>
+#include <vm/vm_fault.h>
#include <sys/kdebug.h>
#include <libkern/OSAtomic.h>
#include <sys/sdt.h>
+#include <stdbool.h>
+
#if 0
#undef KERNEL_DEBUG
#define KERNEL_DEBUG KERNEL_DEBUG_CONSTANT
#define CL_NOCACHE 0x40000
#define MAX_VECTOR_UPL_ELEMENTS 8
-#define MAX_VECTOR_UPL_SIZE (2 * MAX_UPL_SIZE) * PAGE_SIZE
+#define MAX_VECTOR_UPL_SIZE (2 * MAX_UPL_SIZE_BYTES)
+
+#define CLUSTER_IO_WAITING ((buf_t)1)
extern upl_t vector_upl_create(vm_offset_t);
extern boolean_t vector_upl_is_valid(upl_t);
int io_wanted; /* someone is sleeping waiting for a change in state */
};
+struct cl_direct_read_lock {
+ LIST_ENTRY(cl_direct_read_lock) chain;
+ int32_t ref_count;
+ vnode_t vp;
+ lck_rw_t rw_lock;
+};
+
+#define CL_DIRECT_READ_LOCK_BUCKETS 61
+
+static LIST_HEAD(cl_direct_read_locks, cl_direct_read_lock)
+ cl_direct_read_locks[CL_DIRECT_READ_LOCK_BUCKETS];
+
+static lck_spin_t cl_direct_read_spin_lock;
+
static lck_grp_t *cl_mtx_grp;
static lck_attr_t *cl_mtx_attr;
static lck_grp_attr_t *cl_mtx_grp_attr;
static lck_mtx_t *cl_transaction_mtxp;
-
#define IO_UNKNOWN 0
#define IO_DIRECT 1
#define IO_CONTIG 2
static int cluster_io(vnode_t vp, upl_t upl, vm_offset_t upl_offset, off_t f_offset, int non_rounded_size,
int flags, buf_t real_bp, struct clios *iostate, int (*)(buf_t, void *), void *callback_arg);
static int cluster_iodone(buf_t bp, void *callback_arg);
-static int cluster_ioerror(upl_t upl, int upl_offset, int abort_size, int error, int io_flags);
-static int cluster_hard_throttle_on(vnode_t vp, uint32_t);
+static int cluster_ioerror(upl_t upl, int upl_offset, int abort_size, int error, int io_flags, vnode_t vp);
+static int cluster_is_throttled(vnode_t vp);
static void cluster_iostate_wait(struct clios *iostate, u_int target, const char *wait_name);
-static void cluster_syncup(vnode_t vp, off_t newEOF, int (*)(buf_t, void *), void *callback_arg);
+static void cluster_syncup(vnode_t vp, off_t newEOF, int (*)(buf_t, void *), void *callback_arg, int flags);
static void cluster_read_upl_release(upl_t upl, int start_pg, int last_pg, int take_reference);
static int cluster_copy_ubc_data_internal(vnode_t vp, struct uio *uio, int *io_resid, int mark_dirty, int take_reference);
static int cluster_push_now(vnode_t vp, struct cl_extent *, off_t EOF, int flags, int (*)(buf_t, void *), void *callback_arg);
-static int cluster_try_push(struct cl_writebehind *, vnode_t vp, off_t EOF, int push_flag, int flags, int (*)(buf_t, void *), void *callback_arg);
+static int cluster_try_push(struct cl_writebehind *, vnode_t vp, off_t EOF, int push_flag, int flags, int (*)(buf_t, void *), void *callback_arg, int *err);
static void sparse_cluster_switch(struct cl_writebehind *, vnode_t vp, off_t EOF, int (*)(buf_t, void *), void *callback_arg);
-static void sparse_cluster_push(void **cmapp, vnode_t vp, off_t EOF, int push_flag, int io_flags, int (*)(buf_t, void *), void *callback_arg);
+static int sparse_cluster_push(void **cmapp, vnode_t vp, off_t EOF, int push_flag, int io_flags, int (*)(buf_t, void *), void *callback_arg);
static void sparse_cluster_add(void **cmapp, vnode_t vp, struct cl_extent *, off_t EOF, int (*)(buf_t, void *), void *callback_arg);
static kern_return_t vfs_drt_mark_pages(void **cmapp, off_t offset, u_int length, u_int *setcountp);
* can represent it in a 32 bit int
*/
#define MAX_IO_REQUEST_SIZE (1024 * 1024 * 512)
-#define MAX_IO_CONTIG_SIZE (MAX_UPL_SIZE * PAGE_SIZE)
+#define MAX_IO_CONTIG_SIZE MAX_UPL_SIZE_BYTES
#define MAX_VECTS 16
-#define MIN_DIRECT_WRITE_SIZE (4 * PAGE_SIZE)
+/*
+ * The MIN_DIRECT_WRITE_SIZE governs how much I/O should be issued before we consider
+ * allowing the caller to bypass the buffer cache. For small I/Os (less than 16k),
+ * we have not historically allowed the write to bypass the UBC.
+ */
+#define MIN_DIRECT_WRITE_SIZE (16384)
#define WRITE_THROTTLE 6
#define WRITE_THROTTLE_SSD 2
#define WRITE_BEHIND 1
#define WRITE_BEHIND_SSD 1
-#if CONFIG_EMBEDDED
-#define PREFETCH 1
-#define PREFETCH_SSD 1
-uint32_t speculative_prefetch_max = 512; /* maximum number of pages to use for a specluative read-ahead */
-uint32_t speculative_prefetch_max_iosize = (512 * 1024); /* maximum I/O size to use for a specluative read-ahead */
-#else
#define PREFETCH 3
-#define PREFETCH_SSD 1
-uint32_t speculative_prefetch_max = (MAX_UPL_SIZE * 3);
-uint32_t speculative_prefetch_max_iosize = (512 * 1024); /* maximum I/O size to use for a specluative read-ahead on SSDs*/
-#endif
+#define PREFETCH_SSD 2
+uint32_t speculative_prefetch_max = (MAX_UPL_SIZE_BYTES * 3); /* maximum bytes in a specluative read-ahead */
+uint32_t speculative_prefetch_max_iosize = (512 * 1024); /* maximum I/O size to use in a specluative read-ahead on SSDs*/
#define IO_SCALE(vp, base) (vp->v_mount->mnt_ioscale * (base))
* can be outstanding on a single vnode
* before we issue a synchronous write
*/
-#define HARD_THROTTLE_MAXCNT 0
-#define HARD_THROTTLE_MAX_IOSIZE (128 * 1024)
-#define LEGACY_HARD_THROTTLE_MAX_IOSIZE (512 * 1024)
-
-extern int32_t throttle_legacy_process_count;
-int hard_throttle_on_root = 0;
-uint32_t hard_throttle_max_iosize = HARD_THROTTLE_MAX_IOSIZE;
-uint32_t legacy_hard_throttle_max_iosize = LEGACY_HARD_THROTTLE_MAX_IOSIZE;
-struct timeval priority_IO_timestamp_for_root;
-
-#if CONFIG_EMBEDDED
-#define THROTTLE_MAX_IOSIZE (hard_throttle_max_iosize)
-#else
-#define THROTTLE_MAX_IOSIZE (throttle_legacy_process_count == 0 ? hard_throttle_max_iosize : legacy_hard_throttle_max_iosize)
-#endif
+#define THROTTLE_MAXCNT 0
+
+uint32_t throttle_max_iosize = (128 * 1024);
+#define THROTTLE_MAX_IOSIZE (throttle_max_iosize)
-SYSCTL_INT(_debug, OID_AUTO, lowpri_throttle_max_iosize, CTLFLAG_RW | CTLFLAG_LOCKED, &hard_throttle_max_iosize, 0, "");
-SYSCTL_INT(_debug, OID_AUTO, lowpri_legacy_throttle_max_iosize, CTLFLAG_RW | CTLFLAG_LOCKED, &legacy_hard_throttle_max_iosize, 0, "");
+SYSCTL_INT(_debug, OID_AUTO, lowpri_throttle_max_iosize, CTLFLAG_RW | CTLFLAG_LOCKED, &throttle_max_iosize, 0, "");
void
if (cl_transaction_mtxp == NULL)
panic("cluster_init: failed to allocate cl_transaction_mtxp");
+
+ lck_spin_init(&cl_direct_read_spin_lock, cl_mtx_grp, cl_mtx_attr);
+
+ for (int i = 0; i < CL_DIRECT_READ_LOCK_BUCKETS; ++i)
+ LIST_INIT(&cl_direct_read_locks[i]);
}
maxcnt = min(mp->mnt_maxreadcnt, mp->mnt_maxwritecnt);
break;
}
- if (segcnt > MAX_UPL_SIZE) {
+ if (segcnt > (MAX_UPL_SIZE_BYTES >> PAGE_SHIFT)) {
/*
* don't allow a size beyond the max UPL size we can create
*/
- segcnt = MAX_UPL_SIZE;
+ segcnt = MAX_UPL_SIZE_BYTES >> PAGE_SHIFT;
}
max_io_size = min((segcnt * PAGE_SIZE), maxcnt);
- if (max_io_size < (MAX_UPL_TRANSFER * PAGE_SIZE)) {
+ if (max_io_size < MAX_UPL_TRANSFER_BYTES) {
/*
* don't allow a size smaller than the old fixed limit
*/
- max_io_size = (MAX_UPL_TRANSFER * PAGE_SIZE);
+ max_io_size = MAX_UPL_TRANSFER_BYTES;
} else {
/*
* make sure the size specified is a multiple of PAGE_SIZE
static void
-cluster_syncup(vnode_t vp, off_t newEOF, int (*callback)(buf_t, void *), void *callback_arg)
+cluster_syncup(vnode_t vp, off_t newEOF, int (*callback)(buf_t, void *), void *callback_arg, int flags)
{
struct cl_writebehind *wbp;
if (wbp->cl_number) {
lck_mtx_lock(&wbp->cl_lockw);
- cluster_try_push(wbp, vp, newEOF, PUSH_ALL | PUSH_SYNC, 0, callback, callback_arg);
+ cluster_try_push(wbp, vp, newEOF, PUSH_ALL | flags, 0, callback, callback_arg, NULL);
lck_mtx_unlock(&wbp->cl_lockw);
}
static int
-cluster_hard_throttle_on(vnode_t vp, uint32_t hard_throttle)
+cluster_is_throttled(vnode_t vp)
{
- int throttle_type = 0;
-
- if ( (throttle_type = throttle_io_will_be_throttled(-1, vp->v_mount)) )
- return(throttle_type);
-
- if (hard_throttle && (vp->v_mount->mnt_kern_flag & MNTK_ROOTDEV)) {
- static struct timeval hard_throttle_maxelapsed = { 0, 100000 };
- struct timeval elapsed;
-
- if (hard_throttle_on_root)
- return(1);
-
- microuptime(&elapsed);
- timevalsub(&elapsed, &priority_IO_timestamp_for_root);
-
- if (timevalcmp(&elapsed, &hard_throttle_maxelapsed, <))
- return(1);
- }
- return(0);
+ return (throttle_io_will_be_throttled(-1, vp->v_mount));
}
lck_mtx_unlock(&iostate->io_mtxp);
}
+static void cluster_handle_associated_upl(struct clios *iostate, upl_t upl,
+ upl_offset_t upl_offset, upl_size_t size)
+{
+ if (!size)
+ return;
+
+ upl_t associated_upl = upl_associated_upl(upl);
+
+ if (!associated_upl)
+ return;
+
+#if 0
+ printf("1: %d %d\n", upl_offset, upl_offset + size);
+#endif
+
+ /*
+ * The associated UPL is page aligned to file offsets whereas the
+ * UPL it's attached to has different alignment requirements. The
+ * upl_offset that we have refers to @upl. The code that follows
+ * has to deal with the first and last pages in this transaction
+ * which might straddle pages in the associated UPL. To keep
+ * track of these pages, we use the mark bits: if the mark bit is
+ * set, we know another transaction has completed its part of that
+ * page and so we can unlock that page here.
+ *
+ * The following illustrates what we have to deal with:
+ *
+ * MEM u <------------ 1 PAGE ------------> e
+ * +-------------+----------------------+-----------------
+ * | |######################|#################
+ * +-------------+----------------------+-----------------
+ * FILE | <--- a ---> o <------------ 1 PAGE ------------>
+ *
+ * So here we show a write to offset @o. The data that is to be
+ * written is in a buffer that is not page aligned; it has offset
+ * @a in the page. The upl that carries the data starts in memory
+ * at @u. The associated upl starts in the file at offset @o. A
+ * transaction will always end on a page boundary (like @e above)
+ * except for the very last transaction in the group. We cannot
+ * unlock the page at @o in the associated upl until both the
+ * transaction ending at @e and the following transaction (that
+ * starts at @e) has completed.
+ */
+
+ /*
+ * We record whether or not the two UPLs are aligned as the mark
+ * bit in the first page of @upl.
+ */
+ upl_page_info_t *pl = UPL_GET_INTERNAL_PAGE_LIST(upl);
+ bool is_unaligned = upl_page_get_mark(pl, 0);
+
+ if (is_unaligned) {
+ upl_page_info_t *assoc_pl = UPL_GET_INTERNAL_PAGE_LIST(associated_upl);
+
+ upl_offset_t upl_end = upl_offset + size;
+ assert(upl_end >= PAGE_SIZE);
+
+ upl_size_t assoc_upl_size = upl_get_size(associated_upl);
+
+ /*
+ * In the very first transaction in the group, upl_offset will
+ * not be page aligned, but after that it will be and in that
+ * case we want the preceding page in the associated UPL hence
+ * the minus one.
+ */
+ assert(upl_offset);
+ if (upl_offset)
+ upl_offset = trunc_page_32(upl_offset - 1);
+
+ lck_mtx_lock_spin(&iostate->io_mtxp);
+
+ // Look at the first page...
+ if (upl_offset
+ && !upl_page_get_mark(assoc_pl, upl_offset >> PAGE_SHIFT)) {
+ /*
+ * The first page isn't marked so let another transaction
+ * completion handle it.
+ */
+ upl_page_set_mark(assoc_pl, upl_offset >> PAGE_SHIFT, true);
+ upl_offset += PAGE_SIZE;
+ }
+
+ // And now the last page...
+
+ /*
+ * This needs to be > rather than >= because if it's equal, it
+ * means there's another transaction that is sharing the last
+ * page.
+ */
+ if (upl_end > assoc_upl_size)
+ upl_end = assoc_upl_size;
+ else {
+ upl_end = trunc_page_32(upl_end);
+ const int last_pg = (upl_end >> PAGE_SHIFT) - 1;
+
+ if (!upl_page_get_mark(assoc_pl, last_pg)) {
+ /*
+ * The last page isn't marked so mark the page and let another
+ * transaction completion handle it.
+ */
+ upl_page_set_mark(assoc_pl, last_pg, true);
+ upl_end -= PAGE_SIZE;
+ }
+ }
+
+ lck_mtx_unlock(&iostate->io_mtxp);
+
+#if 0
+ printf("2: %d %d\n", upl_offset, upl_end);
+#endif
+
+ if (upl_end <= upl_offset)
+ return;
+
+ size = upl_end - upl_offset;
+ } else {
+ assert(!(upl_offset & PAGE_MASK));
+ assert(!(size & PAGE_MASK));
+ }
+
+ boolean_t empty;
+
+ /*
+ * We can unlock these pages now and as this is for a
+ * direct/uncached write, we want to dump the pages too.
+ */
+ kern_return_t kr = upl_abort_range(associated_upl, upl_offset, size,
+ UPL_ABORT_DUMP_PAGES, &empty);
+
+ assert(!kr);
+
+ if (!kr && empty) {
+ upl_set_associated_upl(upl, NULL);
+ upl_deallocate(associated_upl);
+ }
+}
static int
-cluster_ioerror(upl_t upl, int upl_offset, int abort_size, int error, int io_flags)
+cluster_ioerror(upl_t upl, int upl_offset, int abort_size, int error, int io_flags, vnode_t vp)
{
int upl_abort_code = 0;
int page_in = 0;
* leave pages in the cache unchanged on error
*/
upl_abort_code = UPL_ABORT_FREE_ON_EMPTY;
- else if (page_out && (error != ENXIO))
+ else if (page_out && ((error != ENXIO) || vnode_isswap(vp)))
/*
* transient error... leave pages unchanged
*/
buf_t cbp_head;
buf_t cbp_next;
buf_t real_bp;
+ vnode_t vp;
struct clios *iostate;
boolean_t transaction_complete = FALSE;
- cbp_head = (buf_t)(bp->b_trans_head);
+ __IGNORE_WCASTALIGN(cbp_head = (buf_t)(bp->b_trans_head));
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 20)) | DBG_FUNC_START,
cbp_head, bp->b_lblkno, bp->b_bcount, bp->b_flags, 0);
if (cbp_head->b_trans_next || !(cbp_head->b_flags & B_EOT)) {
- boolean_t need_wakeup = FALSE;
-
lck_mtx_lock_spin(cl_transaction_mtxp);
bp->b_flags |= B_TDONE;
-
- if (bp->b_flags & B_TWANTED) {
- CLR(bp->b_flags, B_TWANTED);
- need_wakeup = TRUE;
- }
+
for (cbp = cbp_head; cbp; cbp = cbp->b_trans_next) {
/*
* all I/O requests that are part of this transaction
lck_mtx_unlock(cl_transaction_mtxp);
- if (need_wakeup == TRUE)
- wakeup(bp);
+ return 0;
+ }
+
+ if (cbp->b_trans_next == CLUSTER_IO_WAITING) {
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 20)) | DBG_FUNC_END,
+ cbp_head, cbp, cbp->b_bcount, cbp->b_flags, 0);
+
+ lck_mtx_unlock(cl_transaction_mtxp);
+ wakeup(cbp);
return 0;
}
+
if (cbp->b_flags & B_EOT)
transaction_complete = TRUE;
}
lck_mtx_unlock(cl_transaction_mtxp);
- if (need_wakeup == TRUE)
- wakeup(bp);
-
if (transaction_complete == FALSE) {
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 20)) | DBG_FUNC_END,
cbp_head, 0, 0, 0, 0);
total_resid = 0;
cbp = cbp_head;
+ vp = cbp->b_vp;
upl_offset = cbp->b_uploffset;
upl = cbp->b_upl;
b_flags = cbp->b_flags;
cbp = cbp_next;
}
+
+ if (ISSET(b_flags, B_COMMIT_UPL)) {
+ cluster_handle_associated_upl(iostate,
+ cbp_head->b_upl,
+ upl_offset,
+ transaction_size);
+ }
+
if (error == 0 && total_resid)
error = EIO;
}
if (b_flags & B_COMMIT_UPL) {
-
- pg_offset = upl_offset & PAGE_MASK;
+ pg_offset = upl_offset & PAGE_MASK;
commit_size = (pg_offset + transaction_size + (PAGE_SIZE - 1)) & ~PAGE_MASK;
if (error)
- upl_flags = cluster_ioerror(upl, upl_offset - pg_offset, commit_size, error, b_flags);
+ upl_flags = cluster_ioerror(upl, upl_offset - pg_offset, commit_size, error, b_flags, vp);
else {
- upl_flags = UPL_COMMIT_FREE_ON_EMPTY;
+ upl_flags = UPL_COMMIT_FREE_ON_EMPTY;
if ((b_flags & B_PHYS) && (b_flags & B_READ))
upl_flags |= UPL_COMMIT_SET_DIRTY;
uint32_t
-cluster_hard_throttle_limit(vnode_t vp, uint32_t *limit, uint32_t hard_throttle)
+cluster_throttle_io_limit(vnode_t vp, uint32_t *limit)
{
- if (cluster_hard_throttle_on(vp, hard_throttle)) {
+ if (cluster_is_throttled(vp)) {
*limit = THROTTLE_MAX_IOSIZE;
return 1;
}
pl = ubc_upl_pageinfo(upl);
if (upl_device_page(pl) == TRUE) {
- zero_addr = ((addr64_t)upl_phys_page(pl, 0) << 12) + upl_offset;
+ zero_addr = ((addr64_t)upl_phys_page(pl, 0) << PAGE_SHIFT) + upl_offset;
bzero_phys_nc(zero_addr, size);
} else {
page_index = upl_offset / PAGE_SIZE;
page_offset = upl_offset & PAGE_MASK;
- zero_addr = ((addr64_t)upl_phys_page(pl, page_index) << 12) + page_offset;
+ zero_addr = ((addr64_t)upl_phys_page(pl, page_index) << PAGE_SHIFT) + page_offset;
zero_cnt = min(PAGE_SIZE - page_offset, size);
bzero_phys(zero_addr, zero_cnt);
buf_t cbp;
if (async) {
- /*
- * async callback completion will not normally
- * generate a wakeup upon I/O completion...
- * by setting B_TWANTED, we will force a wakeup
- * to occur as any outstanding I/Os complete...
- * I/Os already completed will have B_TDONE already
- * set and we won't cause us to block
- * note that we're actually waiting for the bp to have
- * completed the callback function... only then
- * can we safely take back ownership of the bp
+ /*
+ * Async callback completion will not normally generate a
+ * wakeup upon I/O completion. To get woken up, we set
+ * b_trans_next (which is safe for us to modify) on the last
+ * buffer to CLUSTER_IO_WAITING so that cluster_iodone knows
+ * to wake us up when all buffers as part of this transaction
+ * are completed. This is done under the umbrella of
+ * cl_transaction_mtxp which is also taken in cluster_iodone.
*/
+ bool done = true;
+ buf_t last = NULL;
+
lck_mtx_lock_spin(cl_transaction_mtxp);
- for (cbp = cbp_head; cbp; cbp = cbp->b_trans_next)
- cbp->b_flags |= B_TWANTED;
+ for (cbp = cbp_head; cbp; last = cbp, cbp = cbp->b_trans_next) {
+ if (!ISSET(cbp->b_flags, B_TDONE))
+ done = false;
+ }
- lck_mtx_unlock(cl_transaction_mtxp);
- }
- for (cbp = cbp_head; cbp; cbp = cbp->b_trans_next) {
+ if (!done) {
+ last->b_trans_next = CLUSTER_IO_WAITING;
- if (async) {
- while (!ISSET(cbp->b_flags, B_TDONE)) {
+ DTRACE_IO1(wait__start, buf_t, last);
+ do {
+ msleep(last, cl_transaction_mtxp, PSPIN | (PRIBIO+1), "cluster_wait_IO", NULL);
- lck_mtx_lock_spin(cl_transaction_mtxp);
+ /*
+ * We should only have been woken up if all the
+ * buffers are completed, but just in case...
+ */
+ done = true;
+ for (cbp = cbp_head; cbp != CLUSTER_IO_WAITING; cbp = cbp->b_trans_next) {
+ if (!ISSET(cbp->b_flags, B_TDONE)) {
+ done = false;
+ break;
+ }
+ }
+ } while (!done);
+ DTRACE_IO1(wait__done, buf_t, last);
- if (!ISSET(cbp->b_flags, B_TDONE)) {
- DTRACE_IO1(wait__start, buf_t, cbp);
- (void) msleep(cbp, cl_transaction_mtxp, PDROP | (PRIBIO+1), "cluster_wait_IO", NULL);
- DTRACE_IO1(wait__done, buf_t, cbp);
- } else
- lck_mtx_unlock(cl_transaction_mtxp);
- }
- } else
- buf_biowait(cbp);
+ last->b_trans_next = NULL;
+ }
+
+ lck_mtx_unlock(cl_transaction_mtxp);
+ } else { // !async
+ for (cbp = cbp_head; cbp; cbp = cbp->b_trans_next)
+ buf_biowait(cbp);
}
}
{
buf_t cbp;
int error;
+ boolean_t isswapout = FALSE;
/*
* cluster_complete_transaction will
*/
for (cbp = *cbp_head; cbp; cbp = cbp->b_trans_next)
cbp->b_flags |= B_TDONE;
+ cbp = *cbp_head;
+
+ if ((flags & (CL_ASYNC | CL_PAGEOUT)) == CL_PAGEOUT && vnode_isswap(cbp->b_vp))
+ isswapout = TRUE;
- error = cluster_iodone(*cbp_head, callback_arg);
+ error = cluster_iodone(cbp, callback_arg);
if ( !(flags & CL_ASYNC) && error && *retval == 0) {
- if (((flags & (CL_PAGEOUT | CL_KEEPCACHED)) != CL_PAGEOUT) || (error != ENXIO))
- *retval = error;
+ if (((flags & (CL_PAGEOUT | CL_KEEPCACHED)) != CL_PAGEOUT) || (error != ENXIO))
+ *retval = error;
+ else if (isswapout == TRUE)
+ *retval = error;
}
*cbp_head = (buf_t)NULL;
}
max_iosize = PAGE_SIZE;
if (flags & CL_THROTTLE) {
- if ( !(flags & CL_PAGEOUT) && cluster_hard_throttle_on(vp, 1)) {
+ if ( !(flags & CL_PAGEOUT) && cluster_is_throttled(vp)) {
if (max_iosize > THROTTLE_MAX_IOSIZE)
max_iosize = THROTTLE_MAX_IOSIZE;
- async_throttle = HARD_THROTTLE_MAXCNT;
+ async_throttle = THROTTLE_MAXCNT;
} else {
if ( (flags & CL_DEV_MEMORY) )
async_throttle = IO_SCALE(vp, VNODE_ASYNC_THROTTLE);
u_int max_cluster_size;
u_int scale;
- max_cluster_size = MAX_CLUSTER_SIZE(vp);
+ if (vp->v_mount->mnt_minsaturationbytecount) {
+ max_cluster_size = vp->v_mount->mnt_minsaturationbytecount;
+
+ scale = 1;
+ } else {
+ max_cluster_size = MAX_CLUSTER_SIZE(vp);
+ if ((vp->v_mount->mnt_kern_flag & MNTK_SSD) && !ignore_is_ssd)
+ scale = WRITE_THROTTLE_SSD;
+ else
+ scale = WRITE_THROTTLE;
+ }
if (max_iosize > max_cluster_size)
max_cluster = max_cluster_size;
else
if (size < max_cluster)
max_cluster = size;
- if ((vp->v_mount->mnt_kern_flag & MNTK_SSD) && !ignore_is_ssd)
- scale = WRITE_THROTTLE_SSD;
- else
- scale = WRITE_THROTTLE;
-
if (flags & CL_CLOSE)
scale += MAX_CLUSTERS;
-
+
async_throttle = min(IO_SCALE(vp, VNODE_ASYNC_THROTTLE), ((scale * max_cluster_size) / max_cluster) - 1);
}
}
io_flags |= B_PASSIVE;
if (flags & CL_ENCRYPTED)
io_flags |= B_ENCRYPTED_IO;
+
if (vp->v_flag & VSYSTEM)
io_flags |= B_META;
* read in from the file
*/
zero_offset = upl_offset + non_rounded_size;
+ } else if (!ISSET(flags, CL_READ) && ISSET(flags, CL_DIRECT_IO)) {
+ assert(ISSET(flags, CL_COMMIT));
+
+ // For a direct/uncached write, we need to lock pages...
+
+ upl_t cached_upl;
+
+ /*
+ * Create a UPL to lock the pages in the cache whilst the
+ * write is in progress.
+ */
+ ubc_create_upl(vp, f_offset, non_rounded_size, &cached_upl,
+ NULL, UPL_SET_LITE);
+
+ /*
+ * Attach this UPL to the other UPL so that we can find it
+ * later.
+ */
+ upl_set_associated_upl(upl, cached_upl);
+
+ if (upl_offset & PAGE_MASK) {
+ /*
+ * The two UPLs are not aligned, so mark the first page in
+ * @upl so that cluster_handle_associated_upl can handle
+ * it accordingly.
+ */
+ upl_page_info_t *pl = UPL_GET_INTERNAL_PAGE_LIST(upl);
+ upl_page_set_mark(pl, 0, true);
+ }
}
+
while (size) {
daddr64_t blkno;
daddr64_t lblkno;
*
* go direct to vnode_pageout so that we don't have to
* unbusy the page from the UPL... we used to do this
- * so that we could call ubc_sync_range, but that results
+ * so that we could call ubc_msync, but that results
* in a potential deadlock if someone else races us to acquire
* that page and wins and in addition needs one of the pages
* we're continuing to hold in the UPL
pageout_flags |= UPL_NOCOMMIT;
if (cbp_head) {
- buf_t last_cbp;
+ buf_t prev_cbp;
+ int bytes_in_last_page;
/*
* first we have to wait for the the current outstanding I/Os
* to complete... EOT hasn't been set yet on this transaction
- * so the pages won't be released just because all of the current
- * I/O linked to this transaction has completed...
+ * so the pages won't be released
*/
cluster_wait_IO(cbp_head, (flags & CL_ASYNC));
- /*
- * we've got a transcation that
- * includes the page we're about to push out through vnode_pageout...
- * find the last bp in the list which will be the one that
- * includes the head of this page and round it's iosize down
- * to a page boundary...
- */
- for (last_cbp = cbp = cbp_head; cbp->b_trans_next; cbp = cbp->b_trans_next)
- last_cbp = cbp;
-
- cbp->b_bcount &= ~PAGE_MASK;
-
- if (cbp->b_bcount == 0) {
- /*
- * this buf no longer has any I/O associated with it
+ bytes_in_last_page = cbp_head->b_uploffset & PAGE_MASK;
+ for (cbp = cbp_head; cbp; cbp = cbp->b_trans_next)
+ bytes_in_last_page += cbp->b_bcount;
+ bytes_in_last_page &= PAGE_MASK;
+
+ while (bytes_in_last_page) {
+ /*
+ * we've got a transcation that
+ * includes the page we're about to push out through vnode_pageout...
+ * find the bp's in the list which intersect this page and either
+ * remove them entirely from the transaction (there could be multiple bp's), or
+ * round it's iosize down to the page boundary (there can only be one)...
+ *
+ * find the last bp in the list and act on it
*/
- free_io_buf(cbp);
+ for (prev_cbp = cbp = cbp_head; cbp->b_trans_next; cbp = cbp->b_trans_next)
+ prev_cbp = cbp;
- if (cbp == cbp_head) {
- /*
- * the buf we just freed was the only buf in
- * this transaction... so there's no I/O to do
+ if (bytes_in_last_page >= cbp->b_bcount) {
+ /*
+ * this buf no longer has any I/O associated with it
*/
- cbp_head = NULL;
+ bytes_in_last_page -= cbp->b_bcount;
+ cbp->b_bcount = 0;
+
+ free_io_buf(cbp);
+
+ if (cbp == cbp_head) {
+ assert(bytes_in_last_page == 0);
+ /*
+ * the buf we just freed was the only buf in
+ * this transaction... so there's no I/O to do
+ */
+ cbp_head = NULL;
+ cbp_tail = NULL;
+ } else {
+ /*
+ * remove the buf we just freed from
+ * the transaction list
+ */
+ prev_cbp->b_trans_next = NULL;
+ cbp_tail = prev_cbp;
+ }
} else {
- /*
- * remove the buf we just freed from
- * the transaction list
+ /*
+ * this is the last bp that has I/O
+ * intersecting the page of interest
+ * only some of the I/O is in the intersection
+ * so clip the size but keep it in the transaction list
*/
- last_cbp->b_trans_next = NULL;
- cbp_tail = last_cbp;
+ cbp->b_bcount -= bytes_in_last_page;
+ cbp_tail = cbp;
+ bytes_in_last_page = 0;
}
}
if (cbp_head) {
}
continue;
}
- lblkno = (daddr64_t)(f_offset / PAGE_SIZE_64);
+ lblkno = (daddr64_t)(f_offset / 0x1000);
/*
* we have now figured out how much I/O we can do - this is in 'io_size'
* pg_offset is the starting point in the first page for the I/O
commit_offset = upl_offset & ~PAGE_MASK;
}
+
+ // Associated UPL is currently only used in the direct write path
+ assert(!upl_associated_upl(upl));
+
if ( (flags & CL_COMMIT) && pg_count) {
ubc_upl_commit_range(upl, commit_offset, pg_count * PAGE_SIZE,
UPL_COMMIT_CLEAR_DIRTY | UPL_COMMIT_FREE_ON_EMPTY);
if (flags & CL_PAGEOUT) {
u_int i;
- for (i = 0; i < pg_count; i++) {
- if (buf_invalblkno(vp, lblkno + i, 0) == EBUSY)
- panic("BUSY bp found in cluster_io");
+ /*
+ * since blocks are in offsets of 0x1000, scale
+ * iteration to (PAGE_SIZE * pg_count) of blks.
+ */
+ for (i = 0; i < (PAGE_SIZE * pg_count)/0x1000; i++) {
+ if (buf_invalblkno(vp, lblkno + i, 0) == EBUSY)
+ panic("BUSY bp found in cluster_io");
}
}
if (flags & CL_ASYNC) {
if (buf_setupl(cbp, upl, upl_offset))
panic("buf_setupl failed\n");
-
+#if CONFIG_IOSCHED
+ upl_set_blkno(upl, upl_offset, io_size, blkno);
+#endif
cbp->b_trans_next = (buf_t)NULL;
if ((cbp->b_iostate = (void *)iostate))
}
}
if (error) {
- int abort_size;
+ int abort_size;
io_size = 0;
-
+
if (cbp_head) {
- /*
- * first wait until all of the outstanding I/O
- * for this partial transaction has completed
- */
- cluster_wait_IO(cbp_head, (flags & CL_ASYNC));
+ /*
+ * Wait until all of the outstanding I/O
+ * for this partial transaction has completed
+ */
+ cluster_wait_IO(cbp_head, (flags & CL_ASYNC));
/*
* Rewind the upl offset to the beginning of the
* transaction.
*/
upl_offset = cbp_head->b_uploffset;
+ }
- for (cbp = cbp_head; cbp;) {
- buf_t cbp_next;
-
- size += cbp->b_bcount;
- io_size += cbp->b_bcount;
+ if (ISSET(flags, CL_COMMIT)) {
+ cluster_handle_associated_upl(iostate, upl, upl_offset,
+ upl_end_offset - upl_offset);
+ }
- cbp_next = cbp->b_trans_next;
- free_io_buf(cbp);
- cbp = cbp_next;
- }
+ // Free all the IO buffers in this transaction
+ for (cbp = cbp_head; cbp;) {
+ buf_t cbp_next;
+
+ size += cbp->b_bcount;
+ io_size += cbp->b_bcount;
+
+ cbp_next = cbp->b_trans_next;
+ free_io_buf(cbp);
+ cbp = cbp_next;
}
+
if (iostate) {
int need_wakeup = 0;
if (need_wakeup)
wakeup((caddr_t)&iostate->io_wanted);
}
+
if (flags & CL_COMMIT) {
int upl_flags;
- pg_offset = upl_offset & PAGE_MASK;
+ pg_offset = upl_offset & PAGE_MASK;
abort_size = (upl_end_offset - upl_offset + PAGE_MASK) & ~PAGE_MASK;
-
- upl_flags = cluster_ioerror(upl, upl_offset - pg_offset, abort_size, error, io_flags);
+
+ upl_flags = cluster_ioerror(upl, upl_offset - pg_offset, abort_size, error, io_flags, vp);
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 28)) | DBG_FUNC_NONE,
upl, upl_offset - pg_offset, abort_size, (error << 24) | upl_flags, 0);
}
max_prefetch = MAX_PREFETCH(vp, cluster_max_io_size(vp->v_mount, CL_READ), (vp->v_mount->mnt_kern_flag & MNTK_SSD));
- if ((max_prefetch / PAGE_SIZE) > speculative_prefetch_max)
- max_prefetch = (speculative_prefetch_max * PAGE_SIZE);
+ if (max_prefetch > speculative_prefetch_max)
+ max_prefetch = speculative_prefetch_max;
if (max_prefetch <= PAGE_SIZE) {
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 48)) | DBG_FUNC_END,
rap->cl_ralen, (int)rap->cl_maxra, (int)rap->cl_lastr, 6, 0);
return;
}
- if (extent->e_addr < rap->cl_maxra) {
- if ((rap->cl_maxra - extent->e_addr) > ((max_prefetch / PAGE_SIZE) / 4)) {
+ if (extent->e_addr < rap->cl_maxra && rap->cl_ralen >= 4) {
+ if ((rap->cl_maxra - extent->e_addr) > (rap->cl_ralen / 4)) {
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 48)) | DBG_FUNC_END,
rap->cl_ralen, (int)rap->cl_maxra, (int)rap->cl_lastr, 2, 0);
upl_size_t upl_size, vector_upl_size = 0;
vm_size_t upl_needed_size;
mach_msg_type_number_t pages_in_pl;
- int upl_flags;
+ upl_control_flags_t upl_flags;
kern_return_t kret;
mach_msg_type_number_t i;
int force_data_sync;
u_int32_t max_io_size;
u_int32_t max_upl_size;
u_int32_t max_vector_size;
+ u_int32_t bytes_outstanding_limit;
boolean_t io_throttled = FALSE;
u_int32_t vector_upl_iosize = 0;
if (flags & IO_NOCACHE)
io_flag |= CL_NOCACHE;
+ if (flags & IO_SKIP_ENCRYPTION)
+ io_flag |= CL_ENCRYPTED;
+
iostate.io_completed = 0;
iostate.io_issued = 0;
iostate.io_error = 0;
goto wait_for_dwrites;
}
+ task_update_logical_writes(current_task(), (io_req_size & ~PAGE_MASK), TASK_WRITE_IMMEDIATE, vp);
while (io_req_size >= PAGE_SIZE && uio->uio_offset < newEOF && retval == 0) {
int throttle_type;
- if ( (throttle_type = cluster_hard_throttle_on(vp, 1)) ) {
+ if ( (throttle_type = cluster_is_throttled(vp)) ) {
/*
* we're in the throttle window, at the very least
* we want to limit the size of the I/O we're about
* to issue
*/
- if ( (flags & IO_RETURN_ON_THROTTLE) && throttle_type == 2) {
+ if ( (flags & IO_RETURN_ON_THROTTLE) && throttle_type == THROTTLE_NOW) {
/*
* we're in the throttle window and at least 1 I/O
* has already been issued by a throttleable thread
}
if (first_IO) {
- cluster_syncup(vp, newEOF, callback, callback_arg);
+ cluster_syncup(vp, newEOF, callback, callback_arg, callback ? PUSH_SYNC : 0);
first_IO = 0;
}
io_size = io_req_size & ~PAGE_MASK;
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 76)) | DBG_FUNC_START,
(int)upl_offset, upl_needed_size, (int)iov_base, io_size, 0);
+ vm_map_t map = UIO_SEG_IS_USER_SPACE(uio->uio_segflg) ? current_map() : kernel_map;
for (force_data_sync = 0; force_data_sync < 3; force_data_sync++) {
pages_in_pl = 0;
upl_size = upl_needed_size;
upl_flags = UPL_FILE_IO | UPL_COPYOUT_FROM | UPL_NO_SYNC |
- UPL_CLEAN_IN_PLACE | UPL_SET_INTERNAL | UPL_SET_LITE | UPL_SET_IO_WIRE;
+ UPL_CLEAN_IN_PLACE | UPL_SET_INTERNAL | UPL_SET_LITE | UPL_SET_IO_WIRE
+ | UPL_MEMORY_TAG_MAKE(VM_KERN_MEMORY_FILE);
- kret = vm_map_get_upl(current_map(),
+ kret = vm_map_get_upl(map,
(vm_map_offset_t)(iov_base & ~((user_addr_t)PAGE_MASK)),
&upl_size,
&upl,
*/
}
- /*
- * Now look for pages already in the cache
- * and throw them away.
- * uio->uio_offset is page aligned within the file
- * io_size is a multiple of PAGE_SIZE
- */
- ubc_range_op(vp, uio->uio_offset, uio->uio_offset + io_size, UPL_ROP_DUMP, NULL);
-
/*
* we want push out these writes asynchronously so that we can overlap
* the preparation of the next I/O
* if there are already too many outstanding writes
* wait until some complete before issuing the next
*/
- if (iostate.io_issued > iostate.io_completed)
- cluster_iostate_wait(&iostate, max_upl_size * IO_SCALE(vp, 2), "cluster_write_direct");
+ if (vp->v_mount->mnt_minsaturationbytecount)
+ bytes_outstanding_limit = vp->v_mount->mnt_minsaturationbytecount;
+ else
+ bytes_outstanding_limit = max_upl_size * IO_SCALE(vp, 2);
+
+ cluster_iostate_wait(&iostate, bytes_outstanding_limit, "cluster_write_direct");
if (iostate.io_error) {
/*
retval = vector_cluster_io(vp, vector_upl, vector_upl_offset, v_upl_uio_offset, vector_upl_iosize, io_flag, (buf_t)NULL, &iostate, callback, callback_arg);
reset_vector_run_state();
}
+ /*
+ * make sure all async writes issued as part of this stream
+ * have completed before we return
+ */
+ cluster_iostate_wait(&iostate, 0, "cluster_write_direct");
- if (iostate.io_issued > iostate.io_completed) {
- /*
- * make sure all async writes issued as part of this stream
- * have completed before we return
- */
- cluster_iostate_wait(&iostate, 0, "cluster_write_direct");
- }
if (iostate.io_error)
retval = iostate.io_error;
upl_size_t upl_size;
vm_size_t upl_needed_size;
mach_msg_type_number_t pages_in_pl;
- int upl_flags;
+ upl_control_flags_t upl_flags;
kern_return_t kret;
struct clios iostate;
int error = 0;
* -- the io_req_size will not exceed iov_len
* -- the target address is physically contiguous
*/
- cluster_syncup(vp, newEOF, callback, callback_arg);
+ cluster_syncup(vp, newEOF, callback, callback_arg, callback ? PUSH_SYNC : 0);
devblocksize = (u_int32_t)vp->v_mount->mnt_devblocksize;
mem_alignment_mask = (u_int32_t)vp->v_mount->mnt_alignmentmask;
pages_in_pl = 0;
upl_size = upl_needed_size;
upl_flags = UPL_FILE_IO | UPL_COPYOUT_FROM | UPL_NO_SYNC |
- UPL_CLEAN_IN_PLACE | UPL_SET_INTERNAL | UPL_SET_LITE | UPL_SET_IO_WIRE;
+ UPL_CLEAN_IN_PLACE | UPL_SET_INTERNAL | UPL_SET_LITE | UPL_SET_IO_WIRE
+ | UPL_MEMORY_TAG_MAKE(VM_KERN_MEMORY_FILE);
- kret = vm_map_get_upl(current_map(),
+ vm_map_t map = UIO_SEG_IS_USER_SPACE(uio->uio_segflg) ? current_map() : kernel_map;
+ kret = vm_map_get_upl(map,
(vm_map_offset_t)(iov_base & ~((user_addr_t)PAGE_MASK)),
&upl_size, &upl[cur_upl], NULL, &pages_in_pl, &upl_flags, 0);
}
pl = ubc_upl_pageinfo(upl[cur_upl]);
- src_paddr = ((addr64_t)upl_phys_page(pl, 0) << 12) + (addr64_t)upl_offset;
+ src_paddr = ((addr64_t)upl_phys_page(pl, 0) << PAGE_SHIFT) + (addr64_t)upl_offset;
while (((uio->uio_offset & (devblocksize - 1)) || io_size < devblocksize) && io_size) {
u_int32_t head_size;
* if there are already too many outstanding writes
* wait until some have completed before issuing the next
*/
- if (iostate.io_issued > iostate.io_completed)
- cluster_iostate_wait(&iostate, MAX_IO_CONTIG_SIZE * IO_SCALE(vp, 2), "cluster_write_contig");
+ cluster_iostate_wait(&iostate, MAX_IO_CONTIG_SIZE * IO_SCALE(vp, 2), "cluster_write_contig");
if (iostate.io_error) {
/*
* make sure all async writes that are part of this stream
* have completed before we proceed
*/
- if (iostate.io_issued > iostate.io_completed)
- cluster_iostate_wait(&iostate, 0, "cluster_write_contig");
+ cluster_iostate_wait(&iostate, 0, "cluster_write_contig");
if (iostate.io_error)
error = iostate.io_error;
if (flags & IO_NOCACHE)
bflag |= CL_NOCACHE;
+ if (flags & IO_SKIP_ENCRYPTION)
+ bflag |= CL_ENCRYPTED;
+
zero_cnt = 0;
zero_cnt1 = 0;
zero_off = 0;
wbp->cl_seq_written >= (MAX_CLUSTERS * (max_cluster_pgcount * PAGE_SIZE))) {
uint32_t n;
- if (vp->v_mount->mnt_kern_flag & MNTK_SSD)
- n = WRITE_BEHIND_SSD;
- else
- n = WRITE_BEHIND;
+ if (vp->v_mount->mnt_minsaturationbytecount) {
+ n = vp->v_mount->mnt_minsaturationbytecount / MAX_CLUSTER_SIZE(vp);
+
+ if (n > MAX_CLUSTERS)
+ n = MAX_CLUSTERS;
+ } else
+ n = 0;
+ if (n == 0) {
+ if (vp->v_mount->mnt_kern_flag & MNTK_SSD)
+ n = WRITE_BEHIND_SSD;
+ else
+ n = WRITE_BEHIND;
+ }
while (n--)
- cluster_try_push(wbp, vp, newEOF, 0, 0, callback, callback_arg);
+ cluster_try_push(wbp, vp, newEOF, 0, 0, callback, callback_arg, NULL);
}
if (wbp->cl_number < MAX_CLUSTERS) {
/*
*/
if (!((unsigned int)vfs_flags(vp->v_mount) & MNT_DEFWRITE)) {
- ret_cluster_try_push = cluster_try_push(wbp, vp, newEOF, (flags & IO_NOCACHE) ? 0 : PUSH_DELAY, 0, callback, callback_arg);
+ ret_cluster_try_push = cluster_try_push(wbp, vp, newEOF, (flags & IO_NOCACHE) ? 0 : PUSH_DELAY, 0, callback, callback_arg, NULL);
}
/*
flags |= IO_NOCACHE;
if ((vp->v_flag & VRAOFF) || speculative_reads_disabled)
flags |= IO_RAOFF;
-
- /*
- * If we're doing an encrypted IO, then first check to see
- * if the IO requested was page aligned. If not, then bail
- * out immediately.
- */
- if (flags & IO_ENCRYPTED) {
- if (read_length & PAGE_MASK) {
- retval = EINVAL;
- return retval;
- }
- }
+
+ if (flags & IO_SKIP_ENCRYPTION)
+ flags |= IO_ENCRYPTED;
/*
* do a read through the cache if one of the following is true....
* otherwise, find out if we want the direct or contig variant for
* the first vector in the uio request
*/
- if (((flags & IO_NOCACHE) || (flags & IO_ENCRYPTED)) && UIO_SEG_IS_USER_SPACE(uio->uio_segflg)) {
+ if ( ((flags & IO_NOCACHE) && UIO_SEG_IS_USER_SPACE(uio->uio_segflg)) || (flags & IO_ENCRYPTED) ) {
+
retval = cluster_io_type(uio, &read_type, &read_length, 0);
}
-
+
while ((cur_resid = uio_resid(uio)) && uio->uio_offset < filesize && retval == 0) {
switch (read_type) {
panic ("encrypted blocks will hit UBC!");
}
- policy = proc_get_task_selfdiskacc();
+ policy = throttle_get_io_policy(NULL);
- if (policy == IOPOL_THROTTLE || policy == IOPOL_UTILITY || (flags & IO_NOCACHE))
+ if (policy == THROTTLE_LEVEL_TIER3 || policy == THROTTLE_LEVEL_TIER2 || (flags & IO_NOCACHE))
take_reference = 0;
if (flags & IO_PASSIVE)
if (flags & IO_NOCACHE)
bflag |= CL_NOCACHE;
+ if (flags & IO_SKIP_ENCRYPTION)
+ bflag |= CL_ENCRYPTED;
+
max_io_size = cluster_max_io_size(vp->v_mount, CL_READ);
max_prefetch = MAX_PREFETCH(vp, max_io_size, (vp->v_mount->mnt_kern_flag & MNTK_SSD));
max_rd_size = max_prefetch;
rd_ahead_enabled = 0;
rap = NULL;
} else {
- if (cluster_hard_throttle_on(vp, 1)) {
+ if (cluster_is_throttled(vp)) {
/*
* we're in the throttle window, at the very least
* we want to limit the size of the I/O we're about
iostate.io_wanted = 0;
if ( (flags & IO_RETURN_ON_THROTTLE) ) {
- if (cluster_hard_throttle_on(vp, 0) == 2) {
+ if (cluster_is_throttled(vp) == THROTTLE_NOW) {
if ( !cluster_io_present_in_BC(vp, uio->uio_offset)) {
/*
* we're in the throttle window and at least 1 I/O
if (upl_size > max_io_size)
upl_size = max_io_size;
} else {
- if (upl_size > max_io_size / 4)
+ if (upl_size > max_io_size / 4) {
upl_size = max_io_size / 4;
+ upl_size &= ~PAGE_MASK;
+
+ if (upl_size == 0)
+ upl_size = PAGE_SIZE;
+ }
}
pages_in_upl = upl_size / PAGE_SIZE;
rap->cl_lastr = extent.e_addr;
}
}
- if (iostate.io_issued > iostate.io_completed)
+ if (iolock_inited == TRUE)
cluster_iostate_wait(&iostate, 0, "cluster_read_copy");
if (iostate.io_error)
io_req_size -= (val_size - io_requested);
}
} else {
- if (iostate.io_issued > iostate.io_completed)
+ if (iolock_inited == TRUE)
cluster_iostate_wait(&iostate, 0, "cluster_read_copy");
}
if (start_pg < last_pg) {
retval = error;
if (io_req_size) {
- if (cluster_hard_throttle_on(vp, 1)) {
+ if (cluster_is_throttled(vp)) {
/*
* we're in the throttle window, at the very least
* we want to limit the size of the I/O we're about
/*
* coming out of throttled state
*/
- if (policy != IOPOL_THROTTLE && policy != IOPOL_UTILITY) {
+ if (policy != THROTTLE_LEVEL_TIER3 && policy != THROTTLE_LEVEL_TIER2) {
if (rap != NULL)
rd_ahead_enabled = 1;
prefetch_enabled = 1;
}
}
if (iolock_inited == TRUE) {
- if (iostate.io_issued > iostate.io_completed) {
- /*
- * cluster_io returned an error after it
- * had already issued some I/O. we need
- * to wait for that I/O to complete before
- * we can destroy the iostate mutex...
- * 'retval' already contains the early error
- * so no need to pick it up from iostate.io_error
- */
- cluster_iostate_wait(&iostate, 0, "cluster_read_copy");
- }
+ /*
+ * cluster_io returned an error after it
+ * had already issued some I/O. we need
+ * to wait for that I/O to complete before
+ * we can destroy the iostate mutex...
+ * 'retval' already contains the early error
+ * so no need to pick it up from iostate.io_error
+ */
+ cluster_iostate_wait(&iostate, 0, "cluster_read_copy");
+
lck_mtx_destroy(&iostate.io_mtxp, cl_mtx_grp);
}
if (rap != NULL) {
return (retval);
}
+/*
+ * We don't want another read/write lock for every vnode in the system
+ * so we keep a hash of them here. There should never be very many of
+ * these around at any point in time.
+ */
+cl_direct_read_lock_t *cluster_lock_direct_read(vnode_t vp, lck_rw_type_t type)
+{
+ struct cl_direct_read_locks *head
+ = &cl_direct_read_locks[(uintptr_t)vp / sizeof(*vp)
+ % CL_DIRECT_READ_LOCK_BUCKETS];
+
+ struct cl_direct_read_lock *lck, *new_lck = NULL;
+
+ for (;;) {
+ lck_spin_lock(&cl_direct_read_spin_lock);
+
+ LIST_FOREACH(lck, head, chain) {
+ if (lck->vp == vp) {
+ ++lck->ref_count;
+ lck_spin_unlock(&cl_direct_read_spin_lock);
+ if (new_lck) {
+ // Someone beat us to it, ditch the allocation
+ lck_rw_destroy(&new_lck->rw_lock, cl_mtx_grp);
+ FREE(new_lck, M_TEMP);
+ }
+ lck_rw_lock(&lck->rw_lock, type);
+ return lck;
+ }
+ }
+
+ if (new_lck) {
+ // Use the lock we allocated
+ LIST_INSERT_HEAD(head, new_lck, chain);
+ lck_spin_unlock(&cl_direct_read_spin_lock);
+ lck_rw_lock(&new_lck->rw_lock, type);
+ return new_lck;
+ }
+
+ lck_spin_unlock(&cl_direct_read_spin_lock);
+
+ // Allocate a new lock
+ MALLOC(new_lck, cl_direct_read_lock_t *, sizeof(*new_lck),
+ M_TEMP, M_WAITOK);
+ lck_rw_init(&new_lck->rw_lock, cl_mtx_grp, cl_mtx_attr);
+ new_lck->vp = vp;
+ new_lck->ref_count = 1;
+
+ // Got to go round again
+ }
+}
+
+void cluster_unlock_direct_read(cl_direct_read_lock_t *lck)
+{
+ lck_rw_done(&lck->rw_lock);
+
+ lck_spin_lock(&cl_direct_read_spin_lock);
+ if (lck->ref_count == 1) {
+ LIST_REMOVE(lck, chain);
+ lck_spin_unlock(&cl_direct_read_spin_lock);
+ lck_rw_destroy(&lck->rw_lock, cl_mtx_grp);
+ FREE(lck, M_TEMP);
+ } else {
+ --lck->ref_count;
+ lck_spin_unlock(&cl_direct_read_spin_lock);
+ }
+}
static int
cluster_read_direct(vnode_t vp, struct uio *uio, off_t filesize, int *read_type, u_int32_t *read_length,
upl_size_t upl_size, vector_upl_size = 0;
vm_size_t upl_needed_size;
unsigned int pages_in_pl;
- int upl_flags;
+ upl_control_flags_t upl_flags;
kern_return_t kret;
unsigned int i;
int force_data_sync;
off_t v_upl_uio_offset = 0;
int vector_upl_index=0;
upl_t vector_upl = NULL;
+ cl_direct_read_lock_t *lock = NULL;
+
+ user_addr_t orig_iov_base = 0;
+ user_addr_t last_iov_base = 0;
+ user_addr_t next_iov_base = 0;
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 70)) | DBG_FUNC_START,
(int)uio->uio_offset, (int)filesize, *read_type, *read_length, 0);
io_flag |= CL_NOCACHE;
}
+ if (flags & IO_SKIP_ENCRYPTION)
+ io_flag |= CL_ENCRYPTED;
+
iostate.io_completed = 0;
iostate.io_issued = 0;
iostate.io_error = 0;
strict_uncached_IO = ubc_strict_uncached_IO(vp);
+ orig_iov_base = uio_curriovbase(uio);
+ last_iov_base = orig_iov_base;
+
next_dread:
io_req_size = *read_length;
iov_base = uio_curriovbase(uio);
- max_io_size = filesize - uio->uio_offset;
-
- if ((off_t)io_req_size > max_io_size)
- io_req_size = max_io_size;
-
offset_in_file = (u_int32_t)uio->uio_offset & (devblocksize - 1);
offset_in_iovbase = (u_int32_t)iov_base & mem_alignment_mask;
misaligned = 1;
}
+ max_io_size = filesize - uio->uio_offset;
+
/*
* The user must request IO in aligned chunks. If the
* offset into the file is bad, or the userland pointer
* is non-aligned, then we cannot service the encrypted IO request.
*/
- if ((flags & IO_ENCRYPTED) && (misaligned)) {
- retval = EINVAL;
+ if (flags & IO_ENCRYPTED) {
+ if (misaligned || (io_req_size & (devblocksize - 1)))
+ retval = EINVAL;
+
+ max_io_size = roundup(max_io_size, devblocksize);
}
+ if ((off_t)io_req_size > max_io_size)
+ io_req_size = max_io_size;
+
/*
* When we get to this point, we know...
* -- the offset into the file is on a devblocksize boundary
while (io_req_size && retval == 0) {
u_int32_t io_start;
- if (cluster_hard_throttle_on(vp, 1)) {
+ if (cluster_is_throttled(vp)) {
/*
* we're in the throttle window, at the very least
* we want to limit the size of the I/O we're about
* (which overlaps the end of the direct read) in order to
* get at the overhang bytes
*/
- if (io_size & (devblocksize - 1)) {
- if (flags & IO_ENCRYPTED) {
- /*
- * Normally, we'd round down to the previous page boundary to
- * let the UBC manage the zero-filling of the file past the EOF.
- * But if we're doing encrypted IO, we can't let any of
- * the data hit the UBC. This means we have to do the full
- * IO to the upper block boundary of the device block that
- * contains the EOF. The user will be responsible for not
- * interpreting data PAST the EOF in its buffer.
- *
- * So just bump the IO back up to a multiple of devblocksize
- */
- io_size = ((io_size + devblocksize) & ~(devblocksize - 1));
- io_min = io_size;
- }
- else {
- /*
- * Clip the request to the previous page size boundary
- * since request does NOT end on a device block boundary
- */
- io_size &= ~PAGE_MASK;
- io_min = PAGE_SIZE;
- }
-
+ if (io_size & (devblocksize - 1)) {
+ assert(!(flags & IO_ENCRYPTED));
+ /*
+ * Clip the request to the previous page size boundary
+ * since request does NOT end on a device block boundary
+ */
+ io_size &= ~PAGE_MASK;
+ io_min = PAGE_SIZE;
}
if (retval || io_size < io_min) {
/*
goto wait_for_dreads;
}
- /*
+ /*
* Don't re-check the UBC data if we are looking for uncached IO
* or asking for encrypted blocks.
*/
io_size = 0;
+ if (!lock) {
+ /*
+ * We hold a lock here between the time we check the
+ * cache and the time we issue I/O. This saves us
+ * from having to lock the pages in the cache. Not
+ * all clients will care about this lock but some
+ * clients may want to guarantee stability between
+ * here and when the I/O is issued in which case they
+ * will take the lock exclusively.
+ */
+ lock = cluster_lock_direct_read(vp, LCK_RW_TYPE_SHARED);
+ }
+
ubc_range_op(vp, uio->uio_offset, uio->uio_offset + xsize, UPL_ROP_ABSENT, (int *)&io_size);
if (io_size == 0) {
}
}
if ( (flags & IO_RETURN_ON_THROTTLE) ) {
- if (cluster_hard_throttle_on(vp, 0) == 2) {
+ if (cluster_is_throttled(vp) == THROTTLE_NOW) {
if ( !cluster_io_present_in_BC(vp, uio->uio_offset)) {
/*
* we're in the throttle window and at least 1 I/O
else
no_zero_fill = 0;
+ vm_map_t map = UIO_SEG_IS_USER_SPACE(uio->uio_segflg) ? current_map() : kernel_map;
for (force_data_sync = 0; force_data_sync < 3; force_data_sync++) {
pages_in_pl = 0;
upl_size = upl_needed_size;
- upl_flags = UPL_FILE_IO | UPL_NO_SYNC | UPL_SET_INTERNAL | UPL_SET_LITE | UPL_SET_IO_WIRE;
-
+ upl_flags = UPL_FILE_IO | UPL_NO_SYNC | UPL_SET_INTERNAL | UPL_SET_LITE | UPL_SET_IO_WIRE
+ | UPL_MEMORY_TAG_MAKE(VM_KERN_MEMORY_FILE);
if (no_zero_fill)
upl_flags |= UPL_NOZEROFILL;
if (force_data_sync)
upl_flags |= UPL_FORCE_DATA_SYNC;
- kret = vm_map_create_upl(current_map(),
+ kret = vm_map_create_upl(map,
(vm_map_offset_t)(iov_base & ~((user_addr_t)PAGE_MASK)),
&upl_size, &upl, NULL, &pages_in_pl, &upl_flags);
* if there are already too many outstanding reads
* wait until some have completed before issuing the next read
*/
- if (iostate.io_issued > iostate.io_completed)
- cluster_iostate_wait(&iostate, max_rd_ahead, "cluster_read_direct");
+ cluster_iostate_wait(&iostate, max_rd_ahead, "cluster_read_direct");
if (iostate.io_error) {
/*
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 73)) | DBG_FUNC_START,
upl, (int)upl_offset, (int)uio->uio_offset, io_size, 0);
-
if(!useVectorUPL) {
if (no_zero_fill)
io_flag &= ~CL_PRESERVE;
retval = vector_cluster_io(vp, vector_upl, vector_upl_offset, v_upl_uio_offset, vector_upl_iosize, io_flag, (buf_t)NULL, &iostate, callback, callback_arg);
reset_vector_run_state();
}
- }
+ }
+ last_iov_base = iov_base + io_size;
+
+ if (lock) {
+ // We don't need to wait for the I/O to complete
+ cluster_unlock_direct_read(lock);
+ lock = NULL;
+ }
+
/*
* update the uio structure
*/
else {
uio_update(uio, (user_size_t)io_size);
}
- /*
- * Under normal circumstances, the io_size should not be
- * bigger than the io_req_size, but we may have had to round up
- * to the end of the page in the encrypted IO case. In that case only,
- * ensure that we only decrement io_req_size to 0.
- */
- if ((flags & IO_ENCRYPTED) && (io_size > io_req_size)) {
- io_req_size = 0;
- }
- else {
- io_req_size -= io_size;
- }
+
+ io_req_size -= io_size;
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 73)) | DBG_FUNC_END,
upl, (int)uio->uio_offset, io_req_size, retval, 0);
retval = vector_cluster_io(vp, vector_upl, vector_upl_offset, v_upl_uio_offset, vector_upl_iosize, io_flag, (buf_t)NULL, &iostate, callback, callback_arg);
reset_vector_run_state();
}
+
+ // We don't need to wait for the I/O to complete
+ if (lock)
+ cluster_unlock_direct_read(lock);
+
/*
* make sure all async reads that are part of this stream
* have completed before we return
*/
- if (iostate.io_issued > iostate.io_completed)
- cluster_iostate_wait(&iostate, 0, "cluster_read_direct");
+ cluster_iostate_wait(&iostate, 0, "cluster_read_direct");
if (iostate.io_error)
retval = iostate.io_error;
if (io_throttled == TRUE && retval == 0)
retval = EAGAIN;
+ for (next_iov_base = orig_iov_base; next_iov_base < last_iov_base; next_iov_base += PAGE_SIZE) {
+ /*
+ * This is specifically done for pmap accounting purposes.
+ * vm_pre_fault() will call vm_fault() to enter the page into
+ * the pmap if there isn't _a_ physical page for that VA already.
+ */
+ vm_pre_fault(vm_map_trunc_page(next_iov_base, PAGE_MASK));
+ }
+
if (io_req_size && retval == 0) {
/*
* we couldn't handle the tail of this request in DIRECT mode
upl_size_t upl_size;
vm_size_t upl_needed_size;
mach_msg_type_number_t pages_in_pl;
- int upl_flags;
+ upl_control_flags_t upl_flags;
kern_return_t kret;
struct clios iostate;
int error= 0;
* -- the read_length will not exceed the current iov_len
* -- the target address is physically contiguous for read_length
*/
- cluster_syncup(vp, filesize, callback, callback_arg);
+ cluster_syncup(vp, filesize, callback, callback_arg, PUSH_SYNC);
devblocksize = (u_int32_t)vp->v_mount->mnt_devblocksize;
mem_alignment_mask = (u_int32_t)vp->v_mount->mnt_alignmentmask;
pages_in_pl = 0;
upl_size = upl_needed_size;
- upl_flags = UPL_FILE_IO | UPL_NO_SYNC | UPL_CLEAN_IN_PLACE | UPL_SET_INTERNAL | UPL_SET_LITE | UPL_SET_IO_WIRE;
+ upl_flags = UPL_FILE_IO | UPL_NO_SYNC | UPL_CLEAN_IN_PLACE | UPL_SET_INTERNAL | UPL_SET_LITE | UPL_SET_IO_WIRE
+ | UPL_MEMORY_TAG_MAKE(VM_KERN_MEMORY_FILE);
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 92)) | DBG_FUNC_START,
(int)upl_offset, (int)upl_size, (int)iov_base, io_size, 0);
- kret = vm_map_get_upl(current_map(),
+ vm_map_t map = UIO_SEG_IS_USER_SPACE(uio->uio_segflg) ? current_map() : kernel_map;
+ kret = vm_map_get_upl(map,
(vm_map_offset_t)(iov_base & ~((user_addr_t)PAGE_MASK)),
&upl_size, &upl[cur_upl], NULL, &pages_in_pl, &upl_flags, 0);
}
pl = ubc_upl_pageinfo(upl[cur_upl]);
- dst_paddr = ((addr64_t)upl_phys_page(pl, 0) << 12) + (addr64_t)upl_offset;
+ dst_paddr = ((addr64_t)upl_phys_page(pl, 0) << PAGE_SHIFT) + (addr64_t)upl_offset;
while (((uio->uio_offset & (devblocksize - 1)) || io_size < devblocksize) && io_size) {
u_int32_t head_size;
* if there are already too many outstanding reads
* wait until some have completed before issuing the next
*/
- if (iostate.io_issued > iostate.io_completed)
- cluster_iostate_wait(&iostate, MAX_IO_CONTIG_SIZE * IO_SCALE(vp, 2), "cluster_read_contig");
+ cluster_iostate_wait(&iostate, MAX_IO_CONTIG_SIZE * IO_SCALE(vp, 2), "cluster_read_contig");
if (iostate.io_error) {
/*
* make sure all async reads that are part of this stream
* have completed before we proceed
*/
- if (iostate.io_issued > iostate.io_completed)
- cluster_iostate_wait(&iostate, 0, "cluster_read_contig");
+ cluster_iostate_wait(&iostate, 0, "cluster_read_contig");
if (iostate.io_error)
error = iostate.io_error;
user_addr_t iov_base = 0;
upl_t upl;
upl_size_t upl_size;
- int upl_flags;
+ upl_control_flags_t upl_flags;
int retval = 0;
/*
else
upl_size = (u_int32_t)iov_len;
- upl_flags = UPL_QUERY_OBJECT_TYPE;
-
- if ((vm_map_get_upl(current_map(),
+ upl_flags = UPL_QUERY_OBJECT_TYPE | UPL_MEMORY_TAG_MAKE(VM_KERN_MEMORY_FILE);
+
+ vm_map_t map = UIO_SEG_IS_USER_SPACE(uio->uio_segflg) ? current_map() : kernel_map;
+ if ((vm_map_get_upl(map,
(vm_map_offset_t)(iov_base & ~((user_addr_t)PAGE_MASK)),
&upl_size, &upl, NULL, NULL, &upl_flags, 0)) != KERN_SUCCESS) {
/*
max_io_size = cluster_max_io_size(vp->v_mount, CL_READ);
-#if CONFIG_EMBEDDED
- if (max_io_size > speculative_prefetch_max_iosize)
- max_io_size = speculative_prefetch_max_iosize;
-#else
if ((vp->v_mount->mnt_kern_flag & MNTK_SSD) && !ignore_is_ssd) {
if (max_io_size > speculative_prefetch_max_iosize)
max_io_size = speculative_prefetch_max_iosize;
}
-#endif
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 60)) | DBG_FUNC_START,
(int)f_offset, resid, (int)filesize, 0, 0);
int
cluster_push_ext(vnode_t vp, int flags, int (*callback)(buf_t, void *), void *callback_arg)
+{
+ return cluster_push_err(vp, flags, callback, callback_arg, NULL);
+}
+
+/* write errors via err, but return the number of clusters written */
+int
+cluster_push_err(vnode_t vp, int flags, int (*callback)(buf_t, void *), void *callback_arg, int *err)
{
int retval;
int my_sparse_wait = 0;
struct cl_writebehind *wbp;
+ if (err)
+ *err = 0;
+
if ( !UBCINFOEXISTS(vp)) {
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 53)) | DBG_FUNC_NONE, vp, flags, 0, -1, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 53)) | DBG_FUNC_NONE, kdebug_vnode(vp), flags, 0, -1, 0);
return (0);
}
/* return if deferred write is set */
return (0);
}
if ((wbp = cluster_get_wbp(vp, CLW_RETURNLOCKED)) == NULL) {
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 53)) | DBG_FUNC_NONE, vp, flags, 0, -2, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 53)) | DBG_FUNC_NONE, kdebug_vnode(vp), flags, 0, -2, 0);
return (0);
}
- if (wbp->cl_number == 0 && wbp->cl_scmap == NULL) {
+ if (!ISSET(flags, IO_SYNC) && wbp->cl_number == 0 && wbp->cl_scmap == NULL) {
lck_mtx_unlock(&wbp->cl_lockw);
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 53)) | DBG_FUNC_NONE, vp, flags, 0, -3, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 53)) | DBG_FUNC_NONE, kdebug_vnode(vp), flags, 0, -3, 0);
return(0);
}
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 53)) | DBG_FUNC_START,
* in the sparse map case
*/
while (wbp->cl_sparse_wait) {
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 97)) | DBG_FUNC_START, vp, 0, 0, 0, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 97)) | DBG_FUNC_START, kdebug_vnode(vp), 0, 0, 0, 0);
msleep((caddr_t)&wbp->cl_sparse_wait, &wbp->cl_lockw, PRIBIO + 1, "cluster_push_ext", NULL);
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 97)) | DBG_FUNC_END, vp, 0, 0, 0, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 97)) | DBG_FUNC_END, kdebug_vnode(vp), 0, 0, 0, 0);
}
if (flags & IO_SYNC) {
my_sparse_wait = 1;
* fsync actually get cleaned to the disk before this fsync returns
*/
while (wbp->cl_sparse_pushes) {
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 98)) | DBG_FUNC_START, vp, 0, 0, 0, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 98)) | DBG_FUNC_START, kdebug_vnode(vp), 0, 0, 0, 0);
msleep((caddr_t)&wbp->cl_sparse_pushes, &wbp->cl_lockw, PRIBIO + 1, "cluster_push_ext", NULL);
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 98)) | DBG_FUNC_END, vp, 0, 0, 0, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 98)) | DBG_FUNC_END, kdebug_vnode(vp), 0, 0, 0, 0);
}
}
if (wbp->cl_scmap) {
lck_mtx_unlock(&wbp->cl_lockw);
- sparse_cluster_push(&scmap, vp, ubc_getsize(vp), PUSH_ALL, flags | IO_PASSIVE, callback, callback_arg);
+ retval = sparse_cluster_push(&scmap, vp, ubc_getsize(vp), PUSH_ALL, flags, callback, callback_arg);
lck_mtx_lock(&wbp->cl_lockw);
if (wbp->cl_sparse_wait && wbp->cl_sparse_pushes == 0)
wakeup((caddr_t)&wbp->cl_sparse_pushes);
} else {
- sparse_cluster_push(&(wbp->cl_scmap), vp, ubc_getsize(vp), PUSH_ALL, flags | IO_PASSIVE, callback, callback_arg);
+ retval = sparse_cluster_push(&(wbp->cl_scmap), vp, ubc_getsize(vp), PUSH_ALL, flags, callback, callback_arg);
}
+ if (err)
+ *err = retval;
retval = 1;
- } else {
- retval = cluster_try_push(wbp, vp, ubc_getsize(vp), PUSH_ALL, flags | IO_PASSIVE, callback, callback_arg);
+ } else {
+ retval = cluster_try_push(wbp, vp, ubc_getsize(vp), PUSH_ALL, flags, callback, callback_arg, err);
}
lck_mtx_unlock(&wbp->cl_lockw);
static int
-cluster_try_push(struct cl_writebehind *wbp, vnode_t vp, off_t EOF, int push_flag, int io_flags, int (*callback)(buf_t, void *), void *callback_arg)
+cluster_try_push(struct cl_writebehind *wbp, vnode_t vp, off_t EOF, int push_flag, int io_flags, int (*callback)(buf_t, void *), void *callback_arg, int *err)
{
int cl_index;
int cl_index1;
int cl_pushed = 0;
struct cl_wextent l_clusters[MAX_CLUSTERS];
u_int max_cluster_pgcount;
-
+ int error = 0;
max_cluster_pgcount = MAX_CLUSTER_SIZE(vp) / PAGE_SIZE;
/*
cl_len = cl_index;
- if ( (push_flag & PUSH_DELAY) && cl_len == MAX_CLUSTERS ) {
+ /* skip switching to the sparse cluster mechanism if on diskimage */
+ if ( ((push_flag & PUSH_DELAY) && cl_len == MAX_CLUSTERS ) &&
+ !(vp->v_mount->mnt_kern_flag & MNTK_VIRTUALDEV) ) {
int i;
/*
for (cl_index = 0; cl_index < cl_len; cl_index++) {
int flags;
struct cl_extent cl;
+ int retval;
flags = io_flags & (IO_PASSIVE|IO_CLOSE);
cl.b_addr = l_clusters[cl_index].b_addr;
cl.e_addr = l_clusters[cl_index].e_addr;
- cluster_push_now(vp, &cl, EOF, flags, callback, callback_arg);
+ retval = cluster_push_now(vp, &cl, EOF, flags, callback, callback_arg);
+
+ if (error == 0 && retval)
+ error = retval;
l_clusters[cl_index].b_addr = 0;
l_clusters[cl_index].e_addr = 0;
if ( !(push_flag & PUSH_ALL) )
break;
}
+ if (err)
+ *err = error;
+
dont_try:
if (cl_len > cl_pushed) {
/*
else
bflag = 0;
+ if (flags & IO_SKIP_ENCRYPTION)
+ bflag |= CL_ENCRYPTED;
+
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 51)) | DBG_FUNC_START,
(int)cl->b_addr, (int)cl->e_addr, (int)EOF, flags, 0);
{
int cl_index;
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 78)) | DBG_FUNC_START, vp, wbp->cl_scmap, 0, 0, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 78)) | DBG_FUNC_START, kdebug_vnode(vp), wbp->cl_scmap, 0, 0, 0);
for (cl_index = 0; cl_index < wbp->cl_number; cl_index++) {
int flags;
}
wbp->cl_number = 0;
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 78)) | DBG_FUNC_END, vp, wbp->cl_scmap, 0, 0, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 78)) | DBG_FUNC_END, kdebug_vnode(vp), wbp->cl_scmap, 0, 0, 0);
}
* still associated with the write-behind context... however, if the scmap has been disassociated
* from the write-behind context (the cluster_push case), the wb lock is not held
*/
-static void
+static int
sparse_cluster_push(void **scmap, vnode_t vp, off_t EOF, int push_flag, int io_flags, int (*callback)(buf_t, void *), void *callback_arg)
{
struct cl_extent cl;
off_t offset;
u_int length;
+ int error = 0;
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 79)) | DBG_FUNC_START, vp, (*scmap), 0, push_flag, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 79)) | DBG_FUNC_START, kdebug_vnode(vp), (*scmap), 0, push_flag, 0);
if (push_flag & PUSH_ALL)
vfs_drt_control(scmap, 1);
for (;;) {
+ int retval;
if (vfs_drt_get_cluster(scmap, &offset, &length) != KERN_SUCCESS)
break;
cl.b_addr = (daddr64_t)(offset / PAGE_SIZE_64);
cl.e_addr = (daddr64_t)((offset + length) / PAGE_SIZE_64);
- cluster_push_now(vp, &cl, EOF, io_flags & (IO_PASSIVE|IO_CLOSE), callback, callback_arg);
+ retval = cluster_push_now(vp, &cl, EOF, io_flags & (IO_PASSIVE|IO_CLOSE), callback, callback_arg);
+ if (error == 0 && retval)
+ error = retval;
if ( !(push_flag & PUSH_ALL) )
break;
}
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 79)) | DBG_FUNC_END, vp, (*scmap), 0, 0, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 79)) | DBG_FUNC_END, kdebug_vnode(vp), (*scmap), 0, 0, 0);
+
+ return error;
}
offset += (new_dirty * PAGE_SIZE_64);
length -= (new_dirty * PAGE_SIZE);
}
- KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 80)) | DBG_FUNC_END, vp, (*scmap), 0, 0, 0);
+ KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 80)) | DBG_FUNC_END, kdebug_vnode(vp), (*scmap), 0, 0, 0);
}
}
did_read = 1;
}
- ubc_paddr = ((addr64_t)upl_phys_page(pl, 0) << 12) + (addr64_t)(uio->uio_offset & PAGE_MASK_64);
+ ubc_paddr = ((addr64_t)upl_phys_page(pl, 0) << PAGE_SHIFT) + (addr64_t)(uio->uio_offset & PAGE_MASK_64);
/*
* NOTE: There is no prototype for the following in BSD. It, and the definitions
return (error);
}
-
-
int
cluster_copy_upl_data(struct uio *uio, upl_t upl, int upl_offset, int *io_resid)
{
int retval = 0;
int xsize;
upl_page_info_t *pl;
+ int dirty_count;
xsize = *io_resid;
pg_offset = upl_offset & PAGE_MASK;
csize = min(PAGE_SIZE - pg_offset, xsize);
+ dirty_count = 0;
while (xsize && retval == 0) {
addr64_t paddr;
- paddr = ((addr64_t)upl_phys_page(pl, pg_index) << 12) + pg_offset;
+ paddr = ((addr64_t)upl_phys_page(pl, pg_index) << PAGE_SHIFT) + pg_offset;
+ if ((uio->uio_rw == UIO_WRITE) && (upl_dirty_page(pl, pg_index) == FALSE))
+ dirty_count++;
retval = uiomove64(paddr, csize, uio);
uio->uio_segflg = segflg;
+ task_update_logical_writes(current_task(), (dirty_count * PAGE_SIZE), TASK_WRITE_DEFERRED, upl_lookup_vnode(upl));
KERNEL_DEBUG((FSDBG_CODE(DBG_FSRW, 34)) | DBG_FUNC_END,
(int)uio->uio_offset, xsize, retval, segflg, 0);
-
+
return (retval);
}
* single hashtable entry. Each hashtable entry is aligned to this
* size within the file.
*/
-#define DRT_BITVECTOR_PAGES 256
+#define DRT_BITVECTOR_PAGES ((1024 * 1024) / PAGE_SIZE)
/*
* File offset handling.
*
- * DRT_ADDRESS_MASK is dependent on DRT_BITVECTOR_PAGES;
- * the correct formula is (~(DRT_BITVECTOR_PAGES * PAGE_SIZE) - 1)
+ * DRT_ADDRESS_MASK is dependent on DRT_BITVECTOR_PAGES;
+ * the correct formula is (~((DRT_BITVECTOR_PAGES * PAGE_SIZE) - 1))
*/
-#define DRT_ADDRESS_MASK (~((1 << 20) - 1))
+#define DRT_ADDRESS_MASK (~((DRT_BITVECTOR_PAGES * PAGE_SIZE) - 1))
#define DRT_ALIGN_ADDRESS(addr) ((addr) & DRT_ADDRESS_MASK)
/*
*/
struct vfs_drt_hashentry {
u_int64_t dhe_control;
- u_int32_t dhe_bitvector[DRT_BITVECTOR_PAGES / 32];
+/*
+* dhe_bitvector was declared as dhe_bitvector[DRT_BITVECTOR_PAGES / 32];
+* DRT_BITVECTOR_PAGES is defined as ((1024 * 1024) / PAGE_SIZE)
+* Since PAGE_SIZE is only known at boot time,
+* -define MAX_DRT_BITVECTOR_PAGES for smallest supported page size (4k)
+* -declare dhe_bitvector array for largest possible length
+*/
+#define MAX_DRT_BITVECTOR_PAGES (1024 * 1024)/( 4 * 1024)
+ u_int32_t dhe_bitvector[MAX_DRT_BITVECTOR_PAGES/32];
};
/*
*/
kret = kmem_alloc(kernel_map, (vm_offset_t *)&cmap,
- (nsize == DRT_HASH_SMALL_MODULUS) ? DRT_SMALL_ALLOCATION : DRT_LARGE_ALLOCATION);
+ (nsize == DRT_HASH_SMALL_MODULUS) ? DRT_SMALL_ALLOCATION : DRT_LARGE_ALLOCATION, VM_KERN_MEMORY_FILE);
if (kret != KERN_SUCCESS)
return(kret);
cmap->scm_magic = DRT_SCM_MAGIC;