reactos/base/services/nfsd/pnfs_layout.c

1289 lines
39 KiB
C

/* NFSv4.1 client for Windows
* Copyright © 2012 The Regents of the University of Michigan
*
* Olga Kornievskaia <aglo@umich.edu>
* Casey Bodley <cbodley@umich.edu>
*
* This library is free software; you can redistribute it and/or modify it
* under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation; either version 2.1 of the License, or (at
* your option) any later version.
*
* This library is distributed in the hope that it will be useful, but
* without any warranty; without even the implied warranty of merchantability
* or fitness for a particular purpose. See the GNU Lesser General Public
* License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this library; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA
*/
#include <stdio.h>
#include "nfs41_ops.h"
#include "nfs41_callback.h"
#include "util.h"
#include "daemon_debug.h"
#define FLLVL 2 /* dprintf level for file layout logging */
/* pnfs_layout_list */
struct pnfs_layout_list {
struct list_entry head;
CRITICAL_SECTION lock;
};
#define state_entry(pos) list_container(pos, pnfs_layout_state, entry)
#define layout_entry(pos) list_container(pos, pnfs_layout, entry)
#define file_layout_entry(pos) list_container(pos, pnfs_file_layout, layout.entry)
static enum pnfs_status layout_state_create(
IN const nfs41_fh *meta_fh,
OUT pnfs_layout_state **layout_out)
{
pnfs_layout_state *layout;
enum pnfs_status status = PNFS_SUCCESS;
layout = calloc(1, sizeof(pnfs_layout_state));
if (layout == NULL) {
status = PNFSERR_RESOURCES;
goto out;
}
fh_copy(&layout->meta_fh, meta_fh);
list_init(&layout->layouts);
list_init(&layout->recalls);
InitializeSRWLock(&layout->lock);
InitializeConditionVariable(&layout->cond);
*layout_out = layout;
out:
return status;
}
static void file_layout_free(
IN pnfs_file_layout *layout)
{
if (layout->device) pnfs_file_device_put(layout->device);
free(layout->filehandles.arr);
free(layout);
}
static void layout_state_free_layouts(
IN pnfs_layout_state *state)
{
struct list_entry *entry, *tmp;
list_for_each_tmp(entry, tmp, &state->layouts)
file_layout_free(file_layout_entry(entry));
list_init(&state->layouts);
}
static void layout_state_free_recalls(
IN pnfs_layout_state *state)
{
struct list_entry *entry, *tmp;
list_for_each_tmp(entry, tmp, &state->recalls)
free(layout_entry(entry));
list_init(&state->recalls);
}
static void layout_state_free(
IN pnfs_layout_state *state)
{
layout_state_free_layouts(state);
layout_state_free_recalls(state);
free(state);
}
static int layout_entry_compare(
IN const struct list_entry *entry,
IN const void *value)
{
const pnfs_layout_state *layout = state_entry(entry);
const nfs41_fh *meta_fh = (const nfs41_fh*)value;
const nfs41_fh *layout_fh = (const nfs41_fh*)&layout->meta_fh;
const uint32_t diff = layout_fh->len - meta_fh->len;
return diff ? diff : memcmp(layout_fh->fh, meta_fh->fh, meta_fh->len);
}
static enum pnfs_status layout_entry_find(
IN struct pnfs_layout_list *layouts,
IN const nfs41_fh *meta_fh,
OUT struct list_entry **entry_out)
{
*entry_out = list_search(&layouts->head, meta_fh, layout_entry_compare);
return *entry_out ? PNFS_SUCCESS : PNFSERR_NO_LAYOUT;
}
enum pnfs_status pnfs_layout_list_create(
OUT struct pnfs_layout_list **layouts_out)
{
struct pnfs_layout_list *layouts;
enum pnfs_status status = PNFS_SUCCESS;
layouts = calloc(1, sizeof(struct pnfs_layout_list));
if (layouts == NULL) {
status = PNFSERR_RESOURCES;
goto out;
}
list_init(&layouts->head);
InitializeCriticalSection(&layouts->lock);
*layouts_out = layouts;
out:
return status;
}
void pnfs_layout_list_free(
IN struct pnfs_layout_list *layouts)
{
struct list_entry *entry, *tmp;
EnterCriticalSection(&layouts->lock);
list_for_each_tmp(entry, tmp, &layouts->head)
layout_state_free(state_entry(entry));
LeaveCriticalSection(&layouts->lock);
DeleteCriticalSection(&layouts->lock);
free(layouts);
}
static enum pnfs_status layout_state_find_or_create(
IN struct pnfs_layout_list *layouts,
IN const nfs41_fh *meta_fh,
OUT pnfs_layout_state **layout_out)
{
struct list_entry *entry;
enum pnfs_status status;
dprintf(FLLVL, "--> layout_state_find_or_create()\n");
EnterCriticalSection(&layouts->lock);
/* search for an existing layout */
status = layout_entry_find(layouts, meta_fh, &entry);
if (status) {
/* create a new layout */
pnfs_layout_state *layout;
status = layout_state_create(meta_fh, &layout);
if (status == PNFS_SUCCESS) {
/* add it to the list */
list_add_head(&layouts->head, &layout->entry);
*layout_out = layout;
dprintf(FLLVL, "<-- layout_state_find_or_create() "
"returning new layout %p\n", layout);
} else {
dprintf(FLLVL, "<-- layout_state_find_or_create() "
"returning %s\n", pnfs_error_string(status));
}
} else {
*layout_out = state_entry(entry);
dprintf(FLLVL, "<-- layout_state_find_or_create() "
"returning existing layout %p\n", *layout_out);
}
LeaveCriticalSection(&layouts->lock);
return status;
}
static enum pnfs_status layout_state_find_and_delete(
IN struct pnfs_layout_list *layouts,
IN const nfs41_fh *meta_fh)
{
struct list_entry *entry;
enum pnfs_status status;
dprintf(FLLVL, "--> layout_state_find_and_delete()\n");
EnterCriticalSection(&layouts->lock);
status = layout_entry_find(layouts, meta_fh, &entry);
if (status == PNFS_SUCCESS) {
list_remove(entry);
layout_state_free(state_entry(entry));
}
LeaveCriticalSection(&layouts->lock);
dprintf(FLLVL, "<-- layout_state_find_and_delete() "
"returning %s\n", pnfs_error_string(status));
return status;
}
/* pnfs_file_layout */
static uint64_t range_max(
IN const pnfs_layout *layout)
{
uint64_t result = layout->offset + layout->length;
return result < layout->offset ? NFS4_UINT64_MAX : result;
}
static bool_t layout_sanity_check(
IN pnfs_file_layout *layout)
{
/* prevent div/0 */
if (layout->layout.length == 0 ||
layout->layout.iomode < PNFS_IOMODE_READ ||
layout->layout.iomode > PNFS_IOMODE_RW ||
layout_unit_size(layout) == 0)
return FALSE;
/* put a cap on layout.length to prevent overflow */
layout->layout.length = range_max(&layout->layout) - layout->layout.offset;
return TRUE;
}
static int layout_filehandles_cmp(
IN const pnfs_file_layout_handles *lhs,
IN const pnfs_file_layout_handles *rhs)
{
const uint32_t diff = rhs->count - lhs->count;
return diff ? diff : memcmp(rhs->arr, lhs->arr,
rhs->count * sizeof(nfs41_path_fh));
}
static bool_t layout_merge_segments(
IN pnfs_file_layout *to,
IN pnfs_file_layout *from)
{
const uint64_t to_max = range_max(&to->layout);
const uint64_t from_max = range_max(&from->layout);
/* cannot merge a segment with itself */
if (to == from)
return FALSE;
/* the ranges must meet or overlap */
if (to_max < from->layout.offset || from_max < to->layout.offset)
return FALSE;
/* the following fields must match: */
if (to->layout.iomode != from->layout.iomode ||
to->layout.type != from->layout.type ||
layout_filehandles_cmp(&to->filehandles, &from->filehandles) != 0 ||
memcmp(to->deviceid, from->deviceid, PNFS_DEVICEID_SIZE) != 0 ||
to->pattern_offset != from->pattern_offset ||
to->first_index != from->first_index ||
to->util != from->util)
return FALSE;
dprintf(FLLVL, "merging layout range {%llu, %llu} with {%llu, %llu}\n",
to->layout.offset, to->layout.length,
from->layout.offset, from->layout.length);
/* calculate the union of the two ranges */
to->layout.offset = min(to->layout.offset, from->layout.offset);
to->layout.length = max(to_max, from_max) - to->layout.offset;
return TRUE;
}
static enum pnfs_status layout_state_merge(
IN pnfs_layout_state *state,
IN pnfs_file_layout *from)
{
struct list_entry *entry, *tmp;
pnfs_file_layout *to;
enum pnfs_status status = PNFSERR_NO_LAYOUT;
/* attempt to merge the new segment with each existing segment */
list_for_each_tmp(entry, tmp, &state->layouts) {
to = file_layout_entry(entry);
if (!layout_merge_segments(to, from))
continue;
/* on success, remove/free the new segment */
list_remove(&from->layout.entry);
file_layout_free(from);
status = PNFS_SUCCESS;
/* because the existing segment 'to' has grown, we may
* be able to merge it with later segments */
from = to;
/* but if there could be io threads referencing this segment,
* we can't free it until io is finished */
if (state->io_count)
break;
}
return status;
}
static void layout_ordered_insert(
IN pnfs_layout_state *state,
IN pnfs_layout *layout)
{
struct list_entry *entry;
list_for_each(entry, &state->layouts) {
pnfs_layout *existing = layout_entry(entry);
/* maintain an order of increasing offset */
if (existing->offset < layout->offset)
continue;
/* when offsets are equal, prefer a longer segment first */
if (existing->offset == layout->offset &&
existing->length > layout->length)
continue;
list_add(&layout->entry, existing->entry.prev, &existing->entry);
return;
}
list_add_tail(&state->layouts, &layout->entry);
}
static enum pnfs_status layout_update_range(
IN OUT pnfs_layout_state *state,
IN const struct list_entry *layouts)
{
struct list_entry *entry, *tmp;
pnfs_file_layout *layout;
enum pnfs_status status = PNFSERR_NO_LAYOUT;
list_for_each_tmp(entry, tmp, layouts) {
layout = file_layout_entry(entry);
/* don't know what to do with non-file layouts */
if (layout->layout.type != PNFS_LAYOUTTYPE_FILE)
continue;
if (!layout_sanity_check(layout)) {
file_layout_free(layout);
continue;
}
/* attempt to merge the range with existing segments */
status = layout_state_merge(state, layout);
if (status) {
dprintf(FLLVL, "saving new layout:\n");
dprint_layout(FLLVL, layout);
layout_ordered_insert(state, &layout->layout);
status = PNFS_SUCCESS;
}
}
return status;
}
static enum pnfs_status layout_update_stateid(
IN OUT pnfs_layout_state *state,
IN const stateid4 *stateid)
{
enum pnfs_status status = PNFS_SUCCESS;
if (state->stateid.seqid == 0) {
/* save a new layout stateid */
memcpy(&state->stateid, stateid, sizeof(stateid4));
} else if (memcmp(&state->stateid.other, stateid->other,
NFS4_STATEID_OTHER) == 0) {
/* update an existing layout stateid */
state->stateid.seqid = stateid->seqid;
} else {
status = PNFSERR_NO_LAYOUT;
}
return status;
}
static enum pnfs_status layout_update(
IN OUT pnfs_layout_state *state,
IN const pnfs_layoutget_res_ok *layoutget_res)
{
enum pnfs_status status;
/* update the layout ranges held by the client */
status = layout_update_range(state, &layoutget_res->layouts);
if (status) {
eprintf("LAYOUTGET didn't return any file layouts\n");
goto out;
}
/* update the layout stateid */
status = layout_update_stateid(state, &layoutget_res->stateid);
if (status) {
eprintf("LAYOUTGET returned a new stateid when we already had one\n");
goto out;
}
/* if a previous LAYOUTGET set return_on_close, don't overwrite it */
if (!state->return_on_close)
state->return_on_close = layoutget_res->return_on_close;
out:
return status;
}
static enum pnfs_status file_layout_fetch(
IN OUT pnfs_layout_state *state,
IN nfs41_session *session,
IN nfs41_path_fh *meta_file,
IN stateid_arg *stateid,
IN enum pnfs_iomode iomode,
IN uint64_t offset,
IN uint64_t minlength,
IN uint64_t length)
{
pnfs_layoutget_res_ok layoutget_res = { 0 };
enum pnfs_status pnfsstat = PNFS_SUCCESS;
enum nfsstat4 nfsstat;
dprintf(FLLVL, "--> file_layout_fetch(%s, seqid=%u)\n",
pnfs_iomode_string(iomode), state->stateid.seqid);
list_init(&layoutget_res.layouts);
/* drop the lock during the rpc call */
ReleaseSRWLockExclusive(&state->lock);
nfsstat = pnfs_rpc_layoutget(session, meta_file, stateid,
iomode, offset, minlength, length, &layoutget_res);
AcquireSRWLockExclusive(&state->lock);
if (nfsstat) {
dprintf(FLLVL, "pnfs_rpc_layoutget() failed with %s\n",
nfs_error_string(nfsstat));
pnfsstat = PNFSERR_NOT_SUPPORTED;
}
switch (nfsstat) {
case NFS4_OK:
/* use the LAYOUTGET results to update our view of the layout */
pnfsstat = layout_update(state, &layoutget_res);
break;
case NFS4ERR_BADIOMODE:
/* don't try RW again */
if (iomode == PNFS_IOMODE_RW)
state->status |= PNFS_LAYOUT_NOT_RW;
break;
case NFS4ERR_LAYOUTUNAVAILABLE:
case NFS4ERR_UNKNOWN_LAYOUTTYPE:
case NFS4ERR_BADLAYOUT:
/* don't try again at all */
state->status |= PNFS_LAYOUT_UNAVAILABLE;
break;
}
dprintf(FLLVL, "<-- file_layout_fetch() returning %s\n",
pnfs_error_string(pnfsstat));
return pnfsstat;
}
/* returns PNFS_SUCCESS if the client holds valid layouts that cover
* the entire range requested. otherwise, returns PNFS_PENDING and
* sets 'offset_missing' to the lowest offset that is not covered */
static enum pnfs_status layout_coverage_status(
IN pnfs_layout_state *state,
IN enum pnfs_iomode iomode,
IN uint64_t offset,
IN uint64_t length,
OUT uint64_t *offset_missing)
{
uint64_t position = offset;
struct list_entry *entry;
list_for_each(entry, &state->layouts) {
/* if the current position intersects with a compatible
* layout, move the position to the end of that layout */
pnfs_layout *layout = layout_entry(entry);
if (layout->iomode >= iomode &&
layout->offset <= position &&
position < layout->offset + layout->length)
position = layout->offset + layout->length;
}
if (position >= offset + length)
return PNFS_SUCCESS;
*offset_missing = position;
return PNFS_PENDING;
}
static enum pnfs_status layout_fetch(
IN pnfs_layout_state *state,
IN nfs41_session *session,
IN nfs41_path_fh *meta_file,
IN stateid_arg *stateid,
IN enum pnfs_iomode iomode,
IN uint64_t offset,
IN uint64_t length)
{
stateid_arg layout_stateid = { 0 };
enum pnfs_status status = PNFS_PENDING;
/* check for previous errors from LAYOUTGET */
if ((state->status & PNFS_LAYOUT_UNAVAILABLE) ||
((state->status & PNFS_LAYOUT_NOT_RW) && iomode == PNFS_IOMODE_RW)) {
status = PNFSERR_NO_LAYOUT;
goto out;
}
/* wait for any pending LAYOUTGETs/LAYOUTRETURNs */
while (state->pending)
SleepConditionVariableSRW(&state->cond, &state->lock, INFINITE, 0);
state->pending = TRUE;
/* if there's an existing layout stateid, use it */
if (state->stateid.seqid) {
memcpy(&layout_stateid.stateid, &state->stateid, sizeof(stateid4));
layout_stateid.type = STATEID_LAYOUT;
stateid = &layout_stateid;
}
if ((state->status & PNFS_LAYOUT_NOT_RW) == 0) {
/* try to get a RW layout first */
status = file_layout_fetch(state, session, meta_file,
stateid, PNFS_IOMODE_RW, offset, length, NFS4_UINT64_MAX);
}
if (status && iomode == PNFS_IOMODE_READ) {
/* fall back on READ if necessary */
status = file_layout_fetch(state, session, meta_file,
stateid, iomode, offset, length, NFS4_UINT64_MAX);
}
state->pending = FALSE;
WakeConditionVariable(&state->cond);
out:
return status;
}
static enum pnfs_status device_status(
IN pnfs_layout_state *state,
IN uint64_t offset,
IN uint64_t length,
OUT unsigned char *deviceid)
{
struct list_entry *entry;
enum pnfs_status status = PNFS_SUCCESS;
list_for_each(entry, &state->layouts) {
pnfs_file_layout *layout = file_layout_entry(entry);
if (layout->device == NULL) {
/* copy missing deviceid */
memcpy(deviceid, layout->deviceid, PNFS_DEVICEID_SIZE);
status = PNFS_PENDING;
break;
}
}
return status;
}
static void device_assign(
IN pnfs_layout_state *state,
IN const unsigned char *deviceid,
IN pnfs_file_device *device)
{
struct list_entry *entry;
list_for_each(entry, &state->layouts) {
pnfs_file_layout *layout = file_layout_entry(entry);
/* assign the device to any matching layouts */
if (layout->device == NULL &&
memcmp(layout->deviceid, deviceid, PNFS_DEVICEID_SIZE) == 0) {
layout->device = device;
/* XXX: only assign the device to a single segment, because
* pnfs_file_device_get() only gives us a single reference */
break;
}
}
}
static enum pnfs_status device_fetch(
IN pnfs_layout_state *state,
IN nfs41_session *session,
IN unsigned char *deviceid)
{
pnfs_file_device *device;
enum pnfs_status status;
/* drop the layoutstate lock for the rpc call */
ReleaseSRWLockExclusive(&state->lock);
status = pnfs_file_device_get(session,
session->client->devices, deviceid, &device);
AcquireSRWLockExclusive(&state->lock);
if (status == PNFS_SUCCESS)
device_assign(state, deviceid, device);
return status;
}
/* nfs41_open_state */
static enum pnfs_status client_supports_pnfs(
IN nfs41_client *client)
{
enum pnfs_status status;
AcquireSRWLockShared(&client->exid_lock);
status = client->roles & EXCHGID4_FLAG_USE_PNFS_MDS
? PNFS_SUCCESS : PNFSERR_NOT_SUPPORTED;
ReleaseSRWLockShared(&client->exid_lock);
return status;
}
static enum pnfs_status fs_supports_layout(
IN const nfs41_superblock *superblock,
IN enum pnfs_layout_type type)
{
const uint32_t flag = 1 << (type - 1);
return (superblock->layout_types & flag) == 0
? PNFSERR_NOT_SUPPORTED : PNFS_SUCCESS;
}
static enum pnfs_status open_state_layout_cached(
IN nfs41_open_state *state,
OUT pnfs_layout_state **layout_out)
{
enum pnfs_status status = PNFSERR_NO_LAYOUT;
if (state->layout) {
status = PNFS_SUCCESS;
*layout_out = state->layout;
dprintf(FLLVL, "pnfs_open_state_layout() found "
"cached layout %p\n", *layout_out);
}
return status;
}
enum pnfs_status pnfs_layout_state_open(
IN nfs41_open_state *state,
OUT pnfs_layout_state **layout_out)
{
struct pnfs_layout_list *layouts = state->session->client->layouts;
nfs41_session *session = state->session;
pnfs_layout_state *layout;
enum pnfs_status status;
dprintf(FLLVL, "--> pnfs_layout_state_open()\n");
status = client_supports_pnfs(session->client);
if (status)
goto out;
status = fs_supports_layout(state->file.fh.superblock, PNFS_LAYOUTTYPE_FILE);
if (status)
goto out;
/* under shared lock, check open state for cached layouts */
AcquireSRWLockShared(&state->lock);
status = open_state_layout_cached(state, &layout);
ReleaseSRWLockShared(&state->lock);
if (status) {
/* under exclusive lock, find or create a layout for this file */
AcquireSRWLockExclusive(&state->lock);
status = open_state_layout_cached(state, &layout);
if (status) {
status = layout_state_find_or_create(layouts, &state->file.fh, &layout);
if (status == PNFS_SUCCESS) {
LONG open_count = InterlockedIncrement(&layout->open_count);
state->layout = layout;
dprintf(FLLVL, "pnfs_layout_state_open() caching layout %p "
"(%u opens)\n", state->layout, open_count);
}
}
ReleaseSRWLockExclusive(&state->lock);
if (status)
goto out;
}
*layout_out = layout;
out:
dprintf(FLLVL, "<-- pnfs_layout_state_open() returning %s\n",
pnfs_error_string(status));
return status;
}
/* expects caller to hold an exclusive lock on pnfs_layout_state */
enum pnfs_status pnfs_layout_state_prepare(
IN pnfs_layout_state *state,
IN nfs41_session *session,
IN nfs41_path_fh *meta_file,
IN stateid_arg *stateid,
IN enum pnfs_iomode iomode,
IN uint64_t offset,
IN uint64_t length)
{
unsigned char deviceid[PNFS_DEVICEID_SIZE];
struct list_entry *entry;
uint64_t missing;
enum pnfs_status status;
/* fail if the range intersects any pending recalls */
list_for_each(entry, &state->recalls) {
const pnfs_layout *recall = layout_entry(entry);
if (offset <= recall->offset + recall->length
&& recall->offset <= offset + length) {
status = PNFSERR_LAYOUT_RECALLED;
goto out;
}
}
/* if part of the given range is not covered by a layout,
* attempt to fetch it with LAYOUTGET */
status = layout_coverage_status(state, iomode, offset, length, &missing);
if (status == PNFS_PENDING) {
status = layout_fetch(state, session, meta_file, stateid,
iomode, missing, offset + length - missing);
/* return pending because layout_fetch() dropped the lock */
if (status == PNFS_SUCCESS)
status = PNFS_PENDING;
goto out;
}
/* if any layouts in the range are missing device info,
* fetch them with GETDEVICEINFO */
status = device_status(state, offset, length, deviceid);
if (status == PNFS_PENDING) {
status = device_fetch(state, session, deviceid);
/* return pending because device_fetch() dropped the lock */
if (status == PNFS_SUCCESS)
status = PNFS_PENDING;
goto out;
}
out:
return status;
}
static enum pnfs_status layout_return_status(
IN const pnfs_layout_state *state)
{
/* return the layout if we have a stateid */
return state->stateid.seqid ? PNFS_SUCCESS : PNFS_PENDING;
}
static enum pnfs_status file_layout_return(
IN nfs41_session *session,
IN nfs41_path_fh *file,
IN pnfs_layout_state *state)
{
enum pnfs_status status;
enum nfsstat4 nfsstat;
dprintf(FLLVL, "--> file_layout_return()\n");
/* under shared lock, determine whether we need to return the layout */
AcquireSRWLockShared(&state->lock);
status = layout_return_status(state);
ReleaseSRWLockShared(&state->lock);
if (status != PNFS_PENDING)
goto out;
/* under exclusive lock, return the layout and reset status flags */
AcquireSRWLockExclusive(&state->lock);
/* wait for any pending LAYOUTGETs/LAYOUTRETURNs */
while (state->pending)
SleepConditionVariableSRW(&state->cond, &state->lock, INFINITE, 0);
state->pending = TRUE;
status = layout_return_status(state);
if (status == PNFS_PENDING) {
pnfs_layoutreturn_res layoutreturn_res = { 0 };
stateid4 stateid;
memcpy(&stateid, &state->stateid, sizeof(stateid));
/* drop the lock during the rpc call */
ReleaseSRWLockExclusive(&state->lock);
nfsstat = pnfs_rpc_layoutreturn(session, file, PNFS_LAYOUTTYPE_FILE,
PNFS_IOMODE_ANY, 0, NFS4_UINT64_MAX, &stateid, &layoutreturn_res);
AcquireSRWLockExclusive(&state->lock);
if (nfsstat) {
eprintf("pnfs_rpc_layoutreturn() failed with %s\n",
nfs_error_string(nfsstat));
status = PNFSERR_NO_LAYOUT;
} else {
status = PNFS_SUCCESS;
/* update the layout range held by the client */
layout_state_free_layouts(state);
/* 12.5.3. Layout Stateid: Once a client has no more
* layouts on a file, the layout stateid is no longer
* valid and MUST NOT be used. */
ZeroMemory(&state->stateid, sizeof(stateid4));
}
}
state->pending = FALSE;
WakeConditionVariable(&state->cond);
ReleaseSRWLockExclusive(&state->lock);
out:
dprintf(FLLVL, "<-- file_layout_return() returning %s\n",
pnfs_error_string(status));
return status;
}
void pnfs_layout_state_close(
IN nfs41_session *session,
IN nfs41_open_state *state,
IN bool_t remove)
{
pnfs_layout_state *layout;
bool_t return_layout;
enum pnfs_status status;
AcquireSRWLockExclusive(&state->lock);
layout = state->layout;
state->layout = NULL;
ReleaseSRWLockExclusive(&state->lock);
if (layout) {
LONG open_count = InterlockedDecrement(&layout->open_count);
AcquireSRWLockShared(&layout->lock);
/* only return on close if it's the last close */
return_layout = layout->return_on_close && (open_count <= 0);
ReleaseSRWLockShared(&layout->lock);
if (return_layout) {
status = file_layout_return(session, &state->file, layout);
if (status)
eprintf("file_layout_return() failed with %s\n",
pnfs_error_string(status));
}
}
if (remove && session->client->layouts) {
/* free the layout when the file is removed */
layout_state_find_and_delete(session->client->layouts, &state->file.fh);
}
}
/* pnfs_layout_recall */
struct layout_recall {
pnfs_layout layout;
bool_t changed;
};
#define recall_entry(pos) list_container(pos, struct layout_recall, layout.entry)
static bool_t layout_recall_compatible(
IN const pnfs_layout *layout,
IN const pnfs_layout *recall)
{
return layout->type == recall->type
&& layout->offset <= (recall->offset + recall->length)
&& recall->offset <= (layout->offset + layout->length)
&& (recall->iomode == PNFS_IOMODE_ANY ||
layout->iomode == recall->iomode);
}
static pnfs_file_layout* layout_allocate_copy(
IN const pnfs_file_layout *existing)
{
/* allocate a segment to cover the end of the range */
pnfs_file_layout *layout = calloc(1, sizeof(pnfs_file_layout));
if (layout == NULL)
goto out;
memcpy(layout, existing, sizeof(pnfs_file_layout));
/* XXX: don't use the device from existing layout;
* we need to get a reference for ourselves */
layout->device = NULL;
/* allocate a copy of the filehandle array */
layout->filehandles.arr = calloc(layout->filehandles.count,
sizeof(nfs41_path_fh));
if (layout->filehandles.arr == NULL)
goto out_free;
memcpy(layout->filehandles.arr, existing->filehandles.arr,
layout->filehandles.count * sizeof(nfs41_path_fh));
out:
return layout;
out_free:
file_layout_free(layout);
layout = NULL;
goto out;
}
static void layout_recall_range(
IN pnfs_layout_state *state,
IN const pnfs_layout *recall)
{
struct list_entry *entry, *tmp;
list_for_each_tmp(entry, tmp, &state->layouts) {
pnfs_file_layout *layout = file_layout_entry(entry);
const uint64_t layout_end = layout->layout.offset + layout->layout.length;
if (!layout_recall_compatible(&layout->layout, recall))
continue;
if (recall->offset > layout->layout.offset) {
/* segment starts before recall; shrink length */
layout->layout.length = recall->offset - layout->layout.offset;
if (layout_end > recall->offset + recall->length) {
/* middle chunk of the segment is recalled;
* allocate a new segment to cover the end */
pnfs_file_layout *remainder = layout_allocate_copy(layout);
if (remainder == NULL) {
/* silently ignore allocation errors here. behave
* as if we 'forgot' this last segment */
} else {
layout->layout.offset = recall->offset + recall->length;
layout->layout.length = layout_end - layout->layout.offset;
layout_ordered_insert(state, &remainder->layout);
}
}
} else {
/* segment starts after recall */
if (layout_end <= recall->offset + recall->length) {
/* entire segment is recalled */
list_remove(&layout->layout.entry);
file_layout_free(layout);
} else {
/* beginning of segment is recalled; shrink offset/length */
layout->layout.offset = recall->offset + recall->length;
layout->layout.length = layout_end - layout->layout.offset;
}
}
}
}
static void layout_state_deferred_recalls(
IN pnfs_layout_state *state)
{
struct list_entry *entry, *tmp;
list_for_each_tmp(entry, tmp, &state->recalls) {
/* process each deferred layout recall */
pnfs_layout *recall = layout_entry(entry);
layout_recall_range(state, recall);
/* remove/free the recall entry */
list_remove(&recall->entry);
free(recall);
}
}
static void layout_recall_entry_init(
OUT struct layout_recall *lrc,
IN const struct cb_layoutrecall_args *recall)
{
list_init(&lrc->layout.entry);
if (recall->recall.type == PNFS_RETURN_FILE) {
lrc->layout.offset = recall->recall.args.file.offset;
lrc->layout.length = recall->recall.args.file.length;
} else {
lrc->layout.offset = 0;
lrc->layout.length = NFS4_UINT64_MAX;
}
lrc->layout.iomode = recall->iomode;
lrc->layout.type = PNFS_LAYOUTTYPE_FILE;
lrc->changed = recall->changed;
}
static enum pnfs_status layout_recall_merge(
IN struct list_entry *list,
IN pnfs_layout *from)
{
struct list_entry *entry, *tmp;
enum pnfs_status status = PNFSERR_NO_LAYOUT;
/* attempt to merge the new recall with each existing recall */
list_for_each_tmp(entry, tmp, list) {
pnfs_layout *to = layout_entry(entry);
const uint64_t to_max = to->offset + to->length;
const uint64_t from_max = from->offset + from->length;
/* the ranges must meet or overlap */
if (to_max < from->offset || from_max < to->offset)
continue;
/* the following fields must match: */
if (to->iomode != from->iomode || to->type != from->type)
continue;
dprintf(FLLVL, "merging recalled range {%llu, %llu} with {%llu, %llu}\n",
to->offset, to->length, from->offset, from->length);
/* calculate the union of the two ranges */
to->offset = min(to->offset, from->offset);
to->length = max(to_max, from_max) - to->offset;
/* on success, remove/free the new segment */
list_remove(&from->entry);
free(from);
status = PNFS_SUCCESS;
/* because the existing segment 'to' has grown, we may
* be able to merge it with later segments */
from = to;
}
return status;
}
static enum pnfs_status file_layout_recall(
IN pnfs_layout_state *state,
IN const struct cb_layoutrecall_args *recall)
{
const stateid4 *stateid = &recall->recall.args.file.stateid;
enum pnfs_status status = PNFS_SUCCESS;
/* under an exclusive lock, flag the layout as recalled */
AcquireSRWLockExclusive(&state->lock);
if (state->stateid.seqid == 0) {
/* return NOMATCHINGLAYOUT if it wasn't actually granted */
status = PNFSERR_NO_LAYOUT;
goto out;
}
if (recall->recall.type == PNFS_RETURN_FILE) {
/* detect races between CB_LAYOUTRECALL and LAYOUTGET/LAYOUTRETURN */
if (stateid->seqid > state->stateid.seqid + 1) {
/* the server has processed an outstanding LAYOUTGET or
* LAYOUTRETURN; we must return ERR_DELAY until we get the
* response and update our view of the layout */
status = PNFS_PENDING;
goto out;
}
/* save the updated seqid */
state->stateid.seqid = stateid->seqid;
}
if (state->io_count) {
/* save an entry for this recall, and process it once io finishes */
struct layout_recall *lrc = calloc(1, sizeof(struct layout_recall));
if (lrc == NULL) {
/* on failure to allocate, we'll have to respond
* to the CB_LAYOUTRECALL with NFS4ERR_DELAY */
status = PNFS_PENDING;
goto out;
}
layout_recall_entry_init(lrc, recall);
if (layout_recall_merge(&state->recalls, &lrc->layout) != PNFS_SUCCESS)
list_add_tail(&state->recalls, &lrc->layout.entry);
} else {
/* if there is no pending io, process the recall immediately */
struct layout_recall lrc = { 0 };
layout_recall_entry_init(&lrc, recall);
layout_recall_range(state, &lrc.layout);
}
out:
ReleaseSRWLockExclusive(&state->lock);
return status;
}
static enum pnfs_status file_layout_recall_file(
IN nfs41_client *client,
IN const struct cb_layoutrecall_args *recall)
{
struct list_entry *entry;
enum pnfs_status status;
dprintf(FLLVL, "--> file_layout_recall_file()\n");
EnterCriticalSection(&client->layouts->lock);
status = layout_entry_find(client->layouts, &recall->recall.args.file.fh, &entry);
if (status == PNFS_SUCCESS)
status = file_layout_recall(state_entry(entry), recall);
LeaveCriticalSection(&client->layouts->lock);
dprintf(FLLVL, "<-- file_layout_recall_file() returning %s\n",
pnfs_error_string(status));
return status;
}
static bool_t fsid_matches(
IN const nfs41_fsid *lhs,
IN const nfs41_fsid *rhs)
{
return lhs->major == rhs->major && lhs->minor == rhs->minor;
}
static enum pnfs_status file_layout_recall_fsid(
IN nfs41_client *client,
IN const struct cb_layoutrecall_args *recall)
{
struct list_entry *entry;
pnfs_layout_state *state;
nfs41_fh *fh;
enum pnfs_status status = PNFSERR_NO_LAYOUT;
dprintf(FLLVL, "--> file_layout_recall_fsid(%llu, %llu)\n",
recall->recall.args.fsid.major, recall->recall.args.fsid.minor);
EnterCriticalSection(&client->layouts->lock);
list_for_each(entry, &client->layouts->head) {
state = state_entry(entry);
/* no locks needed to read layout.meta_fh or superblock.fsid,
* because they are only written once on creation */
fh = &state->meta_fh;
if (fsid_matches(&recall->recall.args.fsid, &fh->superblock->fsid))
status = file_layout_recall(state, recall);
}
LeaveCriticalSection(&client->layouts->lock);
/* bulk recalls require invalidation of cached device info */
pnfs_file_device_list_invalidate(client->devices);
dprintf(FLLVL, "<-- file_layout_recall_fsid() returning %s\n",
pnfs_error_string(status));
return status;
}
static enum pnfs_status file_layout_recall_all(
IN nfs41_client *client,
IN const struct cb_layoutrecall_args *recall)
{
struct list_entry *entry;
enum pnfs_status status = PNFSERR_NO_LAYOUT;
dprintf(FLLVL, "--> file_layout_recall_all()\n");
EnterCriticalSection(&client->layouts->lock);
list_for_each(entry, &client->layouts->head)
status = file_layout_recall(state_entry(entry), recall);
LeaveCriticalSection(&client->layouts->lock);
/* bulk recalls require invalidation of cached device info */
pnfs_file_device_list_invalidate(client->devices);
dprintf(FLLVL, "<-- file_layout_recall_all() returning %s\n",
pnfs_error_string(status));
return status;
}
enum pnfs_status pnfs_file_layout_recall(
IN nfs41_client *client,
IN const struct cb_layoutrecall_args *recall)
{
enum pnfs_status status = PNFS_SUCCESS;
dprintf(FLLVL, "--> pnfs_file_layout_recall(%u, %s, %u)\n",
recall->recall.type, pnfs_iomode_string(recall->iomode),
recall->changed);
if (recall->type != PNFS_LAYOUTTYPE_FILE) {
dprintf(FLLVL, "invalid layout type %u (%s)!\n",
recall->type, pnfs_layout_type_string(recall->type));
status = PNFSERR_NOT_SUPPORTED;
goto out;
}
switch (recall->recall.type) {
case PNFS_RETURN_FILE:
status = file_layout_recall_file(client, recall);
break;
case PNFS_RETURN_FSID:
status = file_layout_recall_fsid(client, recall);
break;
case PNFS_RETURN_ALL:
status = file_layout_recall_all(client, recall);
break;
default:
dprintf(FLLVL, "invalid return type %u!\n", recall->recall);
status = PNFSERR_NOT_SUPPORTED;
goto out;
}
out:
dprintf(FLLVL, "<-- pnfs_file_layout_recall() returning %s\n",
pnfs_error_string(status));
return status;
}
/* expects caller to hold a shared lock on pnfs_layout_state */
enum pnfs_status pnfs_layout_recall_status(
IN const pnfs_layout_state *state,
IN const pnfs_layout *layout)
{
struct list_entry *entry;
enum pnfs_status status = PNFS_SUCCESS;
/* search for a pending recall that intersects with the given segment */
list_for_each(entry, &state->recalls) {
const struct layout_recall *recall = recall_entry(entry);
if (!layout_recall_compatible(layout, &recall->layout))
continue;
if (recall->changed)
status = PNFSERR_LAYOUT_CHANGED;
else
status = PNFSERR_LAYOUT_RECALLED;
break;
}
return status;
}
void pnfs_layout_recall_fenced(
IN pnfs_layout_state *state,
IN const pnfs_layout *layout)
{
struct layout_recall *lrc = calloc(1, sizeof(struct layout_recall));
if (lrc == NULL)
return;
AcquireSRWLockExclusive(&state->lock);
list_init(&lrc->layout.entry);
lrc->layout.offset = layout->offset;
lrc->layout.length = layout->length;
lrc->layout.iomode = layout->iomode;
lrc->layout.type = layout->type;
lrc->changed = TRUE;
if (layout_recall_merge(&state->recalls, &lrc->layout) != PNFS_SUCCESS)
list_add_tail(&state->recalls, &lrc->layout.entry);
ReleaseSRWLockExclusive(&state->lock);
}
/* expects caller to hold an exclusive lock on pnfs_layout_state */
void pnfs_layout_io_start(
IN pnfs_layout_state *state)
{
/* take a reference on the layout, so that it won't be recalled
* until all io is finished */
state->io_count++;
dprintf(FLLVL, "pnfs_layout_io_start(): count -> %u\n",
state->io_count);
}
void pnfs_layout_io_finished(
IN pnfs_layout_state *state)
{
AcquireSRWLockExclusive(&state->lock);
/* return the reference to signify that an io request is finished */
state->io_count--;
dprintf(FLLVL, "pnfs_layout_io_finished() count -> %u\n",
state->io_count);
if (state->io_count > 0) /* more io pending */
goto out_unlock;
/* once all io is finished, process any layout recalls */
layout_state_deferred_recalls(state);
/* finish any segment merging that was delayed during io */
if (!list_empty(&state->layouts))
layout_state_merge(state, file_layout_entry(state->layouts.next));
out_unlock:
ReleaseSRWLockExclusive(&state->lock);
}