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|
// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab
#include <limits.h>
#include "msg/Messenger.h"
#include "ObjectCacher.h"
#include "WritebackHandler.h"
#include "common/errno.h"
#include "common/perf_counters.h"
#include "include/assert.h"
#define MAX_FLUSH_UNDER_LOCK 20 ///< max bh's we start writeback on while holding the lock
/*** ObjectCacher::BufferHead ***/
/*** ObjectCacher::Object ***/
#define dout_subsys ceph_subsys_objectcacher
#undef dout_prefix
#define dout_prefix *_dout << "objectcacher.object(" << oid << ") "
ObjectCacher::BufferHead *ObjectCacher::Object::split(BufferHead *left, loff_t off)
{
assert(oc->lock.is_locked());
ldout(oc->cct, 20) << "split " << *left << " at " << off << dendl;
// split off right
ObjectCacher::BufferHead *right = new BufferHead(this);
right->last_write_tid = left->last_write_tid;
right->last_read_tid = left->last_read_tid;
right->set_state(left->get_state());
right->snapc = left->snapc;
loff_t newleftlen = off - left->start();
right->set_start(off);
right->set_length(left->length() - newleftlen);
// shorten left
oc->bh_stat_sub(left);
left->set_length(newleftlen);
oc->bh_stat_add(left);
// add right
oc->bh_add(this, right);
// split buffers too
bufferlist bl;
bl.claim(left->bl);
if (bl.length()) {
assert(bl.length() == (left->length() + right->length()));
right->bl.substr_of(bl, left->length(), right->length());
left->bl.substr_of(bl, 0, left->length());
}
// move read waiters
if (!left->waitfor_read.empty()) {
map<loff_t, list<Context*> >::iterator start_remove = left->waitfor_read.begin();
while (start_remove != left->waitfor_read.end() &&
start_remove->first < right->start())
++start_remove;
for (map<loff_t, list<Context*> >::iterator p = start_remove;
p != left->waitfor_read.end(); ++p) {
ldout(oc->cct, 20) << "split moving waiters at byte " << p->first << " to right bh" << dendl;
right->waitfor_read[p->first].swap( p->second );
assert(p->second.empty());
}
left->waitfor_read.erase(start_remove, left->waitfor_read.end());
}
ldout(oc->cct, 20) << "split left is " << *left << dendl;
ldout(oc->cct, 20) << "split right is " << *right << dendl;
return right;
}
void ObjectCacher::Object::merge_left(BufferHead *left, BufferHead *right)
{
assert(oc->lock.is_locked());
assert(left->end() == right->start());
assert(left->get_state() == right->get_state());
ldout(oc->cct, 10) << "merge_left " << *left << " + " << *right << dendl;
oc->bh_remove(this, right);
oc->bh_stat_sub(left);
left->set_length(left->length() + right->length());
oc->bh_stat_add(left);
// data
left->bl.claim_append(right->bl);
// version
// note: this is sorta busted, but should only be used for dirty buffers
left->last_write_tid = MAX( left->last_write_tid, right->last_write_tid );
left->last_write = MAX( left->last_write, right->last_write );
// waiters
for (map<loff_t, list<Context*> >::iterator p = right->waitfor_read.begin();
p != right->waitfor_read.end();
++p)
left->waitfor_read[p->first].splice( left->waitfor_read[p->first].begin(),
p->second );
// hose right
delete right;
ldout(oc->cct, 10) << "merge_left result " << *left << dendl;
}
void ObjectCacher::Object::try_merge_bh(BufferHead *bh)
{
assert(oc->lock.is_locked());
ldout(oc->cct, 10) << "try_merge_bh " << *bh << dendl;
// do not merge rx buffers; last_read_tid may not match
if (bh->is_rx())
return;
// to the left?
map<loff_t,BufferHead*>::iterator p = data.find(bh->start());
assert(p->second == bh);
if (p != data.begin()) {
--p;
if (p->second->end() == bh->start() &&
p->second->get_state() == bh->get_state()) {
merge_left(p->second, bh);
bh = p->second;
} else {
++p;
}
}
// to the right?
assert(p->second == bh);
++p;
if (p != data.end() &&
p->second->start() == bh->end() &&
p->second->get_state() == bh->get_state())
merge_left(bh, p->second);
}
/*
* count bytes we have cached in given range
*/
bool ObjectCacher::Object::is_cached(loff_t cur, loff_t left)
{
assert(oc->lock.is_locked());
map<loff_t, BufferHead*>::iterator p = data_lower_bound(cur);
while (left > 0) {
if (p == data.end())
return false;
if (p->first <= cur) {
// have part of it
loff_t lenfromcur = MIN(p->second->end() - cur, left);
cur += lenfromcur;
left -= lenfromcur;
++p;
continue;
} else if (p->first > cur) {
// gap
return false;
} else
assert(0);
}
return true;
}
/*
* map a range of bytes into buffer_heads.
* - create missing buffer_heads as necessary.
*/
int ObjectCacher::Object::map_read(OSDRead *rd,
map<loff_t, BufferHead*>& hits,
map<loff_t, BufferHead*>& missing,
map<loff_t, BufferHead*>& rx,
map<loff_t, BufferHead*>& errors)
{
assert(oc->lock.is_locked());
for (vector<ObjectExtent>::iterator ex_it = rd->extents.begin();
ex_it != rd->extents.end();
++ex_it) {
if (ex_it->oid != oid.oid)
continue;
ldout(oc->cct, 10) << "map_read " << ex_it->oid
<< " " << ex_it->offset << "~" << ex_it->length
<< dendl;
loff_t cur = ex_it->offset;
loff_t left = ex_it->length;
map<loff_t, BufferHead*>::iterator p = data_lower_bound(ex_it->offset);
while (left > 0) {
// at end?
if (p == data.end()) {
// rest is a miss.
BufferHead *n = new BufferHead(this);
n->set_start(cur);
n->set_length(left);
oc->bh_add(this, n);
if (complete) {
oc->mark_zero(n);
hits[cur] = n;
ldout(oc->cct, 20) << "map_read miss+complete+zero " << left << " left, " << *n << dendl;
} else {
missing[cur] = n;
ldout(oc->cct, 20) << "map_read miss " << left << " left, " << *n << dendl;
}
cur += left;
left = 0;
assert(cur == (loff_t)ex_it->offset + (loff_t)ex_it->length);
break; // no more.
}
if (p->first <= cur) {
// have it (or part of it)
BufferHead *e = p->second;
if (e->is_clean() ||
e->is_dirty() ||
e->is_tx() ||
e->is_zero()) {
hits[cur] = e; // readable!
ldout(oc->cct, 20) << "map_read hit " << *e << dendl;
} else if (e->is_rx()) {
rx[cur] = e; // missing, not readable.
ldout(oc->cct, 20) << "map_read rx " << *e << dendl;
} else if (e->is_error()) {
errors[cur] = e;
ldout(oc->cct, 20) << "map_read error " << *e << dendl;
} else {
assert(0);
}
loff_t lenfromcur = MIN(e->end() - cur, left);
cur += lenfromcur;
left -= lenfromcur;
++p;
continue; // more?
} else if (p->first > cur) {
// gap.. miss
loff_t next = p->first;
BufferHead *n = new BufferHead(this);
loff_t len = MIN(next - cur, left);
n->set_start(cur);
n->set_length(len);
oc->bh_add(this,n);
if (complete) {
oc->mark_zero(n);
hits[cur] = n;
ldout(oc->cct, 20) << "map_read gap+complete+zero " << *n << dendl;
} else {
missing[cur] = n;
ldout(oc->cct, 20) << "map_read gap " << *n << dendl;
}
cur += MIN(left, n->length());
left -= MIN(left, n->length());
continue; // more?
} else {
assert(0);
}
}
}
return 0;
}
void ObjectCacher::Object::audit_buffers()
{
loff_t offset = 0;
for (map<loff_t, BufferHead*>::const_iterator it = data.begin();
it != data.end(); ++it) {
if (it->first != it->second->start()) {
lderr(oc->cct) << "AUDIT FAILURE: map position " << it->first
<< " does not match bh start position: "
<< *it->second << dendl;
assert(it->first == it->second->start());
}
if (it->first < offset) {
lderr(oc->cct) << "AUDIT FAILURE: " << it->first << " " << *it->second
<< " overlaps with previous bh " << *((--it)->second)
<< dendl;
assert(it->first >= offset);
}
BufferHead *bh = it->second;
map<loff_t, list<Context*> >::const_iterator w_it;
for (w_it = bh->waitfor_read.begin();
w_it != bh->waitfor_read.end(); ++w_it) {
if (w_it->first < bh->start() ||
w_it->first >= bh->start() + bh->length()) {
lderr(oc->cct) << "AUDIT FAILURE: waiter at " << w_it->first
<< " is not within bh " << *bh << dendl;
assert(w_it->first >= bh->start());
assert(w_it->first < bh->start() + bh->length());
}
}
offset = it->first + it->second->length();
}
}
/*
* map a range of extents on an object's buffer cache.
* - combine any bh's we're writing into one
* - break up bufferheads that don't fall completely within the range
* //no! - return a bh that includes the write. may also include other dirty data to left and/or right.
*/
ObjectCacher::BufferHead *ObjectCacher::Object::map_write(OSDWrite *wr)
{
assert(oc->lock.is_locked());
BufferHead *final = 0;
for (vector<ObjectExtent>::iterator ex_it = wr->extents.begin();
ex_it != wr->extents.end();
++ex_it) {
if (ex_it->oid != oid.oid) continue;
ldout(oc->cct, 10) << "map_write oex " << ex_it->oid
<< " " << ex_it->offset << "~" << ex_it->length << dendl;
loff_t cur = ex_it->offset;
loff_t left = ex_it->length;
map<loff_t, BufferHead*>::iterator p = data_lower_bound(ex_it->offset);
while (left > 0) {
loff_t max = left;
// at end ?
if (p == data.end()) {
if (final == NULL) {
final = new BufferHead(this);
final->set_start( cur );
final->set_length( max );
oc->bh_add(this, final);
ldout(oc->cct, 10) << "map_write adding trailing bh " << *final << dendl;
} else {
oc->bh_stat_sub(final);
final->set_length(final->length() + max);
oc->bh_stat_add(final);
}
left -= max;
cur += max;
continue;
}
ldout(oc->cct, 10) << "cur is " << cur << ", p is " << *p->second << dendl;
//oc->verify_stats();
if (p->first <= cur) {
BufferHead *bh = p->second;
ldout(oc->cct, 10) << "map_write bh " << *bh << " intersected" << dendl;
if (p->first < cur) {
assert(final == 0);
if (cur + max >= p->first + p->second->length()) {
// we want right bit (one splice)
final = split(bh, cur); // just split it, take right half.
++p;
assert(p->second == final);
} else {
// we want middle bit (two splices)
final = split(bh, cur);
++p;
assert(p->second == final);
split(final, cur+max);
}
} else {
assert(p->first == cur);
if (p->second->length() <= max) {
// whole bufferhead, piece of cake.
} else {
// we want left bit (one splice)
split(bh, cur + max); // just split
}
if (final) {
oc->mark_dirty(bh);
oc->mark_dirty(final);
--p; // move iterator back to final
assert(p->second == final);
merge_left(final, bh);
} else {
final = bh;
}
}
// keep going.
loff_t lenfromcur = final->end() - cur;
cur += lenfromcur;
left -= lenfromcur;
++p;
continue;
} else {
// gap!
loff_t next = p->first;
loff_t glen = MIN(next - cur, max);
ldout(oc->cct, 10) << "map_write gap " << cur << "~" << glen << dendl;
if (final) {
oc->bh_stat_sub(final);
final->set_length(final->length() + glen);
oc->bh_stat_add(final);
} else {
final = new BufferHead(this);
final->set_start( cur );
final->set_length( glen );
oc->bh_add(this, final);
}
cur += glen;
left -= glen;
continue; // more?
}
}
}
// set versoin
assert(final);
ldout(oc->cct, 10) << "map_write final is " << *final << dendl;
return final;
}
void ObjectCacher::Object::truncate(loff_t s)
{
assert(oc->lock.is_locked());
ldout(oc->cct, 10) << "truncate " << *this << " to " << s << dendl;
while (!data.empty()) {
BufferHead *bh = data.rbegin()->second;
if (bh->end() <= s)
break;
// split bh at truncation point?
if (bh->start() < s) {
split(bh, s);
continue;
}
// remove bh entirely
assert(bh->start() >= s);
oc->bh_remove(this, bh);
delete bh;
}
}
void ObjectCacher::Object::discard(loff_t off, loff_t len)
{
assert(oc->lock.is_locked());
ldout(oc->cct, 10) << "discard " << *this << " " << off << "~" << len << dendl;
if (!exists) {
ldout(oc->cct, 10) << " setting exists on " << *this << dendl;
exists = true;
}
if (complete) {
ldout(oc->cct, 10) << " clearing complete on " << *this << dendl;
complete = false;
}
map<loff_t, BufferHead*>::iterator p = data_lower_bound(off);
while (p != data.end()) {
BufferHead *bh = p->second;
if (bh->start() >= off + len)
break;
// split bh at truncation point?
if (bh->start() < off) {
split(bh, off);
++p;
continue;
}
assert(bh->start() >= off);
if (bh->end() > off + len) {
split(bh, off + len);
}
++p;
ldout(oc->cct, 10) << "discard " << *this << " bh " << *bh << dendl;
oc->bh_remove(this, bh);
delete bh;
}
}
/*** ObjectCacher ***/
#undef dout_prefix
#define dout_prefix *_dout << "objectcacher "
ObjectCacher::ObjectCacher(CephContext *cct_, string name, WritebackHandler& wb, Mutex& l,
flush_set_callback_t flush_callback,
void *flush_callback_arg,
uint64_t max_bytes, uint64_t max_objects,
uint64_t max_dirty, uint64_t target_dirty,
double max_dirty_age, bool block_writes_upfront)
: perfcounter(NULL),
cct(cct_), writeback_handler(wb), name(name), lock(l),
max_dirty(max_dirty), target_dirty(target_dirty),
max_size(max_bytes), max_objects(max_objects),
block_writes_upfront(block_writes_upfront),
flush_set_callback(flush_callback), flush_set_callback_arg(flush_callback_arg),
last_read_tid(0),
flusher_stop(false), flusher_thread(this), finisher(cct),
stat_clean(0), stat_zero(0), stat_dirty(0), stat_rx(0), stat_tx(0), stat_missing(0),
stat_error(0), stat_dirty_waiting(0), reads_outstanding(0)
{
this->max_dirty_age.set_from_double(max_dirty_age);
perf_start();
finisher.start();
}
ObjectCacher::~ObjectCacher()
{
finisher.stop();
perf_stop();
// we should be empty.
for (vector<hash_map<sobject_t, Object *> >::iterator i = objects.begin();
i != objects.end();
++i)
assert(i->empty());
assert(bh_lru_rest.lru_get_size() == 0);
assert(bh_lru_dirty.lru_get_size() == 0);
assert(ob_lru.lru_get_size() == 0);
assert(dirty_bh.empty());
}
void ObjectCacher::perf_start()
{
string n = "objectcacher-" + name;
PerfCountersBuilder plb(cct, n, l_objectcacher_first, l_objectcacher_last);
plb.add_u64_counter(l_objectcacher_cache_ops_hit, "cache_ops_hit");
plb.add_u64_counter(l_objectcacher_cache_ops_miss, "cache_ops_miss");
plb.add_u64_counter(l_objectcacher_cache_bytes_hit, "cache_bytes_hit");
plb.add_u64_counter(l_objectcacher_cache_bytes_miss, "cache_bytes_miss");
plb.add_u64_counter(l_objectcacher_data_read, "data_read");
plb.add_u64_counter(l_objectcacher_data_written, "data_written");
plb.add_u64_counter(l_objectcacher_data_flushed, "data_flushed");
plb.add_u64_counter(l_objectcacher_overwritten_in_flush,
"data_overwritten_while_flushing");
plb.add_u64_counter(l_objectcacher_write_ops_blocked, "write_ops_blocked");
plb.add_u64_counter(l_objectcacher_write_bytes_blocked, "write_bytes_blocked");
plb.add_time(l_objectcacher_write_time_blocked, "write_time_blocked");
perfcounter = plb.create_perf_counters();
cct->get_perfcounters_collection()->add(perfcounter);
}
void ObjectCacher::perf_stop()
{
assert(perfcounter);
cct->get_perfcounters_collection()->remove(perfcounter);
delete perfcounter;
}
/* private */
ObjectCacher::Object *ObjectCacher::get_object(sobject_t oid, ObjectSet *oset,
object_locator_t &l,
uint64_t truncate_size,
uint64_t truncate_seq)
{
// XXX: Add handling of nspace in object_locator_t in cache
assert(lock.is_locked());
// have it?
if ((uint32_t)l.pool < objects.size()) {
if (objects[l.pool].count(oid)) {
Object *o = objects[l.pool][oid];
o->truncate_size = truncate_size;
o->truncate_seq = truncate_seq;
return o;
}
} else {
objects.resize(l.pool+1);
}
// create it.
Object *o = new Object(this, oid, oset, l, truncate_size, truncate_seq);
objects[l.pool][oid] = o;
ob_lru.lru_insert_top(o);
return o;
}
void ObjectCacher::close_object(Object *ob)
{
assert(lock.is_locked());
ldout(cct, 10) << "close_object " << *ob << dendl;
assert(ob->can_close());
// ok!
ob_lru.lru_remove(ob);
objects[ob->oloc.pool].erase(ob->get_soid());
ob->set_item.remove_myself();
delete ob;
}
void ObjectCacher::bh_read(BufferHead *bh)
{
assert(lock.is_locked());
ldout(cct, 7) << "bh_read on " << *bh << " outstanding reads "
<< reads_outstanding << dendl;
mark_rx(bh);
bh->last_read_tid = ++last_read_tid;
// finisher
C_ReadFinish *onfinish = new C_ReadFinish(this, bh->ob, bh->last_read_tid,
bh->start(), bh->length());
// go
writeback_handler.read(bh->ob->get_oid(), bh->ob->get_oloc(),
bh->start(), bh->length(), bh->ob->get_snap(),
&onfinish->bl, bh->ob->truncate_size, bh->ob->truncate_seq,
onfinish);
++reads_outstanding;
}
void ObjectCacher::bh_read_finish(int64_t poolid, sobject_t oid, tid_t tid,
loff_t start, uint64_t length,
bufferlist &bl, int r,
bool trust_enoent)
{
assert(lock.is_locked());
ldout(cct, 7) << "bh_read_finish "
<< oid
<< " tid " << tid
<< " " << start << "~" << length
<< " (bl is " << bl.length() << ")"
<< " returned " << r
<< " outstanding reads " << reads_outstanding
<< dendl;
if (bl.length() < length) {
bufferptr bp(length - bl.length());
bp.zero();
ldout(cct, 7) << "bh_read_finish " << oid << " padding " << start << "~" << length
<< " with " << bp.length() << " bytes of zeroes" << dendl;
bl.push_back(bp);
}
list<Context*> ls;
int err = 0;
if (objects[poolid].count(oid) == 0) {
ldout(cct, 7) << "bh_read_finish no object cache" << dendl;
} else {
Object *ob = objects[poolid][oid];
if (r == -ENOENT && !ob->complete) {
// wake up *all* rx waiters, or else we risk reordering identical reads. e.g.
// read 1~1
// reply to unrelated 3~1 -> !exists
// read 1~1 -> immediate ENOENT
// reply to first 1~1 -> ooo ENOENT
bool allzero = true;
for (map<loff_t, BufferHead*>::iterator p = ob->data.begin(); p != ob->data.end(); ++p) {
BufferHead *bh = p->second;
for (map<loff_t, list<Context*> >::iterator p = bh->waitfor_read.begin();
p != bh->waitfor_read.end();
++p)
ls.splice(ls.end(), p->second);
bh->waitfor_read.clear();
if (!bh->is_zero() && !bh->is_rx())
allzero = false;
}
// just pass through and retry all waiters if we don't trust
// -ENOENT for this read
if (trust_enoent) {
ldout(cct, 7) << "bh_read_finish ENOENT, marking complete and !exists on " << *ob << dendl;
ob->complete = true;
ob->exists = false;
/* If all the bhs are effectively zero, get rid of them. All
* the waiters will be retried and get -ENOENT immediately, so
* it's safe to clean up the unneeded bh's now. Since we know
* it's safe to remove them now, do so, so they aren't hanging
*around waiting for more -ENOENTs from rados while the cache
* is being shut down.
*
* Only do this when all the bhs are rx or clean, to match the
* condition in _readx(). If there are any non-rx or non-clean
* bhs, _readx() will wait for the final result instead of
* returning -ENOENT immediately.
*/
if (allzero) {
ldout(cct, 10) << "bh_read_finish ENOENT and allzero, getting rid of "
<< "bhs for " << *ob << dendl;
map<loff_t, BufferHead*>::iterator p = ob->data.begin();
while (p != ob->data.end()) {
BufferHead *bh = p->second;
// current iterator will be invalidated by bh_remove()
++p;
bh_remove(ob, bh);
delete bh;
}
}
}
}
// apply to bh's!
loff_t opos = start;
while (true) {
map<loff_t, BufferHead*>::iterator p = ob->data_lower_bound(opos);
if (p == ob->data.end())
break;
if (opos >= start+(loff_t)length) {
ldout(cct, 20) << "break due to opos " << opos << " >= start+length "
<< start << "+" << length << "=" << start+(loff_t)length
<< dendl;
break;
}
BufferHead *bh = p->second;
ldout(cct, 20) << "checking bh " << *bh << dendl;
// finishers?
for (map<loff_t, list<Context*> >::iterator it = bh->waitfor_read.begin();
it != bh->waitfor_read.end();
++it)
ls.splice(ls.end(), it->second);
bh->waitfor_read.clear();
if (bh->start() > opos) {
ldout(cct, 1) << "bh_read_finish skipping gap "
<< opos << "~" << bh->start() - opos
<< dendl;
opos = bh->start();
continue;
}
if (!bh->is_rx()) {
ldout(cct, 10) << "bh_read_finish skipping non-rx " << *bh << dendl;
opos = bh->end();
continue;
}
if (bh->last_read_tid != tid) {
ldout(cct, 10) << "bh_read_finish bh->last_read_tid " << bh->last_read_tid
<< " != tid " << tid << ", skipping" << dendl;
opos = bh->end();
continue;
}
assert(opos >= bh->start());
assert(bh->start() == opos); // we don't merge rx bh's... yet!
assert(bh->length() <= start+(loff_t)length-opos);
if (bh->error < 0)
err = bh->error;
loff_t oldpos = opos;
opos = bh->end();
if (r == -ENOENT) {
if (trust_enoent) {
ldout(cct, 10) << "bh_read_finish removing " << *bh << dendl;
bh_remove(ob, bh);
delete bh;
} else {
ldout(cct, 10) << "skipping unstrusted -ENOENT and will retry for "
<< *bh << dendl;
}
continue;
}
if (r < 0) {
bh->error = r;
mark_error(bh);
} else {
bh->bl.substr_of(bl,
oldpos-bh->start(),
bh->length());
mark_clean(bh);
}
ldout(cct, 10) << "bh_read_finish read " << *bh << dendl;
ob->try_merge_bh(bh);
}
}
// called with lock held.
ldout(cct, 20) << "finishing waiters " << ls << dendl;
finish_contexts(cct, ls, err);
--reads_outstanding;
read_cond.Signal();
}
void ObjectCacher::bh_write(BufferHead *bh)
{
assert(lock.is_locked());
ldout(cct, 7) << "bh_write " << *bh << dendl;
bh->ob->get();
// finishers
C_WriteCommit *oncommit = new C_WriteCommit(this, bh->ob->oloc.pool,
bh->ob->get_soid(), bh->start(), bh->length());
// go
tid_t tid = writeback_handler.write(bh->ob->get_oid(), bh->ob->get_oloc(),
bh->start(), bh->length(),
bh->snapc, bh->bl, bh->last_write,
bh->ob->truncate_size, bh->ob->truncate_seq,
oncommit);
ldout(cct, 20) << " tid " << tid << " on " << bh->ob->get_oid() << dendl;
// set bh last_write_tid
oncommit->tid = tid;
bh->ob->last_write_tid = tid;
bh->last_write_tid = tid;
if (perfcounter) {
perfcounter->inc(l_objectcacher_data_flushed, bh->length());
}
mark_tx(bh);
}
void ObjectCacher::bh_write_commit(int64_t poolid, sobject_t oid, loff_t start,
uint64_t length, tid_t tid, int r)
{
assert(lock.is_locked());
ldout(cct, 7) << "bh_write_commit "
<< oid
<< " tid " << tid
<< " " << start << "~" << length
<< " returned " << r
<< dendl;
if (objects[poolid].count(oid) == 0) {
ldout(cct, 7) << "bh_write_commit no object cache" << dendl;
} else {
Object *ob = objects[poolid][oid];
int was_dirty_or_tx = ob->oset->dirty_or_tx;
if (!ob->exists) {
ldout(cct, 10) << "bh_write_commit marking exists on " << *ob << dendl;
ob->exists = true;
if (writeback_handler.may_copy_on_write(ob->get_oid(), start, length, ob->get_snap())) {
ldout(cct, 10) << "bh_write_commit may copy on write, clearing complete on " << *ob << dendl;
ob->complete = false;
}
}
// apply to bh's!
for (map<loff_t, BufferHead*>::iterator p = ob->data_lower_bound(start);
p != ob->data.end();
++p) {
BufferHead *bh = p->second;
if (bh->start() > start+(loff_t)length)
break;
if (bh->start() < start &&
bh->end() > start+(loff_t)length) {
ldout(cct, 20) << "bh_write_commit skipping " << *bh << dendl;
continue;
}
// make sure bh is tx
if (!bh->is_tx()) {
ldout(cct, 10) << "bh_write_commit skipping non-tx " << *bh << dendl;
continue;
}
// make sure bh tid matches
if (bh->last_write_tid != tid) {
assert(bh->last_write_tid > tid);
ldout(cct, 10) << "bh_write_commit newer tid on " << *bh << dendl;
continue;
}
if (r >= 0) {
// ok! mark bh clean and error-free
mark_clean(bh);
ldout(cct, 10) << "bh_write_commit clean " << *bh << dendl;
} else {
mark_dirty(bh);
ldout(cct, 10) << "bh_write_commit marking dirty again due to error "
<< *bh << " r = " << r << " " << cpp_strerror(-r)
<< dendl;
}
}
// update last_commit.
assert(ob->last_commit_tid < tid);
ob->last_commit_tid = tid;
// waiters?
list<Context*> ls;
if (ob->waitfor_commit.count(tid)) {
ls.splice(ls.begin(), ob->waitfor_commit[tid]);
ob->waitfor_commit.erase(tid);
}
// is the entire object set now clean and fully committed?
ObjectSet *oset = ob->oset;
ob->put();
if (flush_set_callback &&
was_dirty_or_tx > 0 &&
oset->dirty_or_tx == 0) { // nothing dirty/tx
flush_set_callback(flush_set_callback_arg, oset);
}
if (!ls.empty())
finish_contexts(cct, ls, r);
}
}
void ObjectCacher::flush(loff_t amount)
{
assert(lock.is_locked());
utime_t cutoff = ceph_clock_now(cct);
ldout(cct, 10) << "flush " << amount << dendl;
/*
* NOTE: we aren't actually pulling things off the LRU here, just looking at the
* tail item. Then we call bh_write, which moves it to the other LRU, so that we
* can call lru_dirty.lru_get_next_expire() again.
*/
loff_t did = 0;
while (amount == 0 || did < amount) {
BufferHead *bh = static_cast<BufferHead*>(bh_lru_dirty.lru_get_next_expire());
if (!bh) break;
if (bh->last_write > cutoff) break;
did += bh->length();
bh_write(bh);
}
}
void ObjectCacher::trim(loff_t max_bytes, loff_t max_ob)
{
assert(lock.is_locked());
if (max_bytes < 0)
max_bytes = max_size;
if (max_ob < 0)
max_ob = max_objects;
ldout(cct, 10) << "trim start: bytes: max " << max_bytes << " clean " << get_stat_clean()
<< ", objects: max " << max_ob << " current " << ob_lru.lru_get_size()
<< dendl;
while (get_stat_clean() > max_bytes) {
BufferHead *bh = static_cast<BufferHead*>(bh_lru_rest.lru_expire());
if (!bh)
break;
ldout(cct, 10) << "trim trimming " << *bh << dendl;
assert(bh->is_clean() || bh->is_zero());
Object *ob = bh->ob;
bh_remove(ob, bh);
delete bh;
if (ob->complete) {
ldout(cct, 10) << "trim clearing complete on " << *ob << dendl;
ob->complete = false;
}
}
while (ob_lru.lru_get_size() > max_ob) {
Object *ob = static_cast<Object*>(ob_lru.lru_expire());
if (!ob)
break;
ldout(cct, 10) << "trim trimming " << *ob << dendl;
close_object(ob);
}
ldout(cct, 10) << "trim finish: max " << max_bytes << " clean " << get_stat_clean()
<< ", objects: max " << max_ob << " current " << ob_lru.lru_get_size()
<< dendl;
}
/* public */
bool ObjectCacher::is_cached(ObjectSet *oset, vector<ObjectExtent>& extents, snapid_t snapid)
{
assert(lock.is_locked());
for (vector<ObjectExtent>::iterator ex_it = extents.begin();
ex_it != extents.end();
++ex_it) {
ldout(cct, 10) << "is_cached " << *ex_it << dendl;
// get Object cache
sobject_t soid(ex_it->oid, snapid);
Object *o = get_object_maybe(soid, ex_it->oloc);
if (!o)
return false;
if (!o->is_cached(ex_it->offset, ex_it->length))
return false;
}
return true;
}
/*
* returns # bytes read (if in cache). onfinish is untouched (caller must delete it)
* returns 0 if doing async read
*/
int ObjectCacher::readx(OSDRead *rd, ObjectSet *oset, Context *onfinish)
{
return _readx(rd, oset, onfinish, true);
}
int ObjectCacher::_readx(OSDRead *rd, ObjectSet *oset, Context *onfinish,
bool external_call)
{
assert(lock.is_locked());
bool success = true;
int error = 0;
list<BufferHead*> hit_ls;
uint64_t bytes_in_cache = 0;
uint64_t bytes_not_in_cache = 0;
uint64_t total_bytes_read = 0;
map<uint64_t, bufferlist> stripe_map; // final buffer offset -> substring
for (vector<ObjectExtent>::iterator ex_it = rd->extents.begin();
ex_it != rd->extents.end();
++ex_it) {
ldout(cct, 10) << "readx " << *ex_it << dendl;
total_bytes_read += ex_it->length;
// get Object cache
sobject_t soid(ex_it->oid, rd->snap);
Object *o = get_object(soid, oset, ex_it->oloc, ex_it->truncate_size, oset->truncate_seq);
touch_ob(o);
// does not exist and no hits?
if (oset->return_enoent && !o->exists) {
// WARNING: we can only meaningfully return ENOENT if the read request
// passed in a single ObjectExtent. Any caller who wants ENOENT instead of
// zeroed buffers needs to feed single extents into readx().
assert(rd->extents.size() == 1);
ldout(cct, 10) << "readx object !exists, 1 extent..." << dendl;
// should we worry about COW underneaeth us?
if (writeback_handler.may_copy_on_write(soid.oid, ex_it->offset, ex_it->length, soid.snap)) {
ldout(cct, 20) << "readx may copy on write" << dendl;
bool wait = false;
for (map<loff_t, BufferHead*>::iterator bh_it = o->data.begin();
bh_it != o->data.end();
++bh_it) {
BufferHead *bh = bh_it->second;
if (bh->is_dirty() || bh->is_tx()) {
ldout(cct, 10) << "readx flushing " << *bh << dendl;
wait = true;
if (bh->is_dirty())
bh_write(bh);
}
}
if (wait) {
ldout(cct, 10) << "readx waiting on tid " << o->last_write_tid << " on " << *o << dendl;
o->waitfor_commit[o->last_write_tid].push_back(new C_RetryRead(this, rd, oset, onfinish));
// FIXME: perfcounter!
return 0;
}
}
// can we return ENOENT?
bool allzero = true;
for (map<loff_t, BufferHead*>::iterator bh_it = o->data.begin();
bh_it != o->data.end();
++bh_it) {
ldout(cct, 20) << "readx ob has bh " << *bh_it->second << dendl;
if (!bh_it->second->is_zero() && !bh_it->second->is_rx()) {
allzero = false;
break;
}
}
if (allzero) {
ldout(cct, 10) << "readx ob has all zero|rx, returning ENOENT" << dendl;
delete rd;
return -ENOENT;
}
}
// map extent into bufferheads
map<loff_t, BufferHead*> hits, missing, rx, errors;
o->map_read(rd, hits, missing, rx, errors);
if (external_call) {
// retry reading error buffers
missing.insert(errors.begin(), errors.end());
} else {
// some reads had errors, fail later so completions
// are cleaned up up properly
// TODO: make read path not call _readx for every completion
hits.insert(errors.begin(), errors.end());
}
if (!missing.empty() || !rx.empty()) {
// read missing
for (map<loff_t, BufferHead*>::iterator bh_it = missing.begin();
bh_it != missing.end();
++bh_it) {
bh_read(bh_it->second);
if (success && onfinish) {
ldout(cct, 10) << "readx missed, waiting on " << *bh_it->second
<< " off " << bh_it->first << dendl;
bh_it->second->waitfor_read[bh_it->first].push_back( new C_RetryRead(this, rd, oset, onfinish) );
}
bytes_not_in_cache += bh_it->second->length();
success = false;
}
// bump rx
for (map<loff_t, BufferHead*>::iterator bh_it = rx.begin();
bh_it != rx.end();
++bh_it) {
touch_bh(bh_it->second); // bump in lru, so we don't lose it.
if (success && onfinish) {
ldout(cct, 10) << "readx missed, waiting on " << *bh_it->second
<< " off " << bh_it->first << dendl;
bh_it->second->waitfor_read[bh_it->first].push_back( new C_RetryRead(this, rd, oset, onfinish) );
}
bytes_not_in_cache += bh_it->second->length();
success = false;
}
} else {
assert(!hits.empty());
// make a plain list
for (map<loff_t, BufferHead*>::iterator bh_it = hits.begin();
bh_it != hits.end();
++bh_it) {
ldout(cct, 10) << "readx hit bh " << *bh_it->second << dendl;
if (bh_it->second->is_error() && bh_it->second->error)
error = bh_it->second->error;
hit_ls.push_back(bh_it->second);
bytes_in_cache += bh_it->second->length();
}
// create reverse map of buffer offset -> object for the eventual result.
// this is over a single ObjectExtent, so we know that
// - the bh's are contiguous
// - the buffer frags need not be (and almost certainly aren't)
loff_t opos = ex_it->offset;
map<loff_t, BufferHead*>::iterator bh_it = hits.begin();
assert(bh_it->second->start() <= opos);
uint64_t bhoff = opos - bh_it->second->start();
vector<pair<uint64_t,uint64_t> >::iterator f_it = ex_it->buffer_extents.begin();
uint64_t foff = 0;
while (1) {
BufferHead *bh = bh_it->second;
assert(opos == (loff_t)(bh->start() + bhoff));
uint64_t len = MIN(f_it->second - foff, bh->length() - bhoff);
ldout(cct, 10) << "readx rmap opos " << opos
<< ": " << *bh << " +" << bhoff
<< " frag " << f_it->first << "~" << f_it->second << " +" << foff << "~" << len
<< dendl;
bufferlist bit; // put substr here first, since substr_of clobbers, and
// we may get multiple bh's at this stripe_map position
if (bh->is_zero()) {
bufferptr bp(len);
bp.zero();
stripe_map[f_it->first].push_back(bp);
} else {
bit.substr_of(bh->bl,
opos - bh->start(),
len);
stripe_map[f_it->first].claim_append(bit);
}
opos += len;
bhoff += len;
foff += len;
if (opos == bh->end()) {
++bh_it;
bhoff = 0;
}
if (foff == f_it->second) {
++f_it;
foff = 0;
}
if (bh_it == hits.end()) break;
if (f_it == ex_it->buffer_extents.end())
break;
}
assert(f_it == ex_it->buffer_extents.end());
assert(opos == (loff_t)ex_it->offset + (loff_t)ex_it->length);
}
}
// bump hits in lru
for (list<BufferHead*>::iterator bhit = hit_ls.begin();
bhit != hit_ls.end();
++bhit)
touch_bh(*bhit);
if (!success) {
if (perfcounter && external_call) {
perfcounter->inc(l_objectcacher_data_read, total_bytes_read);
perfcounter->inc(l_objectcacher_cache_bytes_miss, bytes_not_in_cache);
perfcounter->inc(l_objectcacher_cache_ops_miss);
}
if (onfinish) {
ldout(cct, 20) << "readx defer " << rd << dendl;
} else {
ldout(cct, 20) << "readx drop " << rd << " (no complete, but no waiter)" << dendl;
delete rd;
}
return 0; // wait!
}
if (perfcounter && external_call) {
perfcounter->inc(l_objectcacher_data_read, total_bytes_read);
perfcounter->inc(l_objectcacher_cache_bytes_hit, bytes_in_cache);
perfcounter->inc(l_objectcacher_cache_ops_hit);
}
// no misses... success! do the read.
assert(!hit_ls.empty());
ldout(cct, 10) << "readx has all buffers" << dendl;
// ok, assemble into result buffer.
uint64_t pos = 0;
if (rd->bl && !error) {
rd->bl->clear();
for (map<uint64_t,bufferlist>::iterator i = stripe_map.begin();
i != stripe_map.end();
++i) {
assert(pos == i->first);
ldout(cct, 10) << "readx adding buffer len " << i->second.length() << " at " << pos << dendl;
pos += i->second.length();
rd->bl->claim_append(i->second);
assert(rd->bl->length() == pos);
}
ldout(cct, 10) << "readx result is " << rd->bl->length() << dendl;
} else {
ldout(cct, 10) << "readx no bufferlist ptr (readahead?), done." << dendl;
}
// done with read.
int ret = error ? error : pos;
ldout(cct, 20) << "readx done " << rd << " " << ret << dendl;
assert(pos <= (uint64_t) INT_MAX);
delete rd;
trim();
return ret;
}
int ObjectCacher::writex(OSDWrite *wr, ObjectSet *oset, Mutex& wait_on_lock,
Context *onfreespace)
{
assert(lock.is_locked());
utime_t now = ceph_clock_now(cct);
uint64_t bytes_written = 0;
uint64_t bytes_written_in_flush = 0;
for (vector<ObjectExtent>::iterator ex_it = wr->extents.begin();
ex_it != wr->extents.end();
++ex_it) {
// get object cache
sobject_t soid(ex_it->oid, CEPH_NOSNAP);
Object *o = get_object(soid, oset, ex_it->oloc, ex_it->truncate_size, oset->truncate_seq);
// map it all into a single bufferhead.
BufferHead *bh = o->map_write(wr);
bh->snapc = wr->snapc;
bytes_written += bh->length();
if (bh->is_tx()) {
bytes_written_in_flush += bh->length();
}
// adjust buffer pointers (ie "copy" data into my cache)
// this is over a single ObjectExtent, so we know that
// - there is one contiguous bh
// - the buffer frags need not be (and almost certainly aren't)
// note: i assume striping is monotonic... no jumps backwards, ever!
loff_t opos = ex_it->offset;
for (vector<pair<uint64_t, uint64_t> >::iterator f_it = ex_it->buffer_extents.begin();
f_it != ex_it->buffer_extents.end();
++f_it) {
ldout(cct, 10) << "writex writing " << f_it->first << "~" << f_it->second << " into " << *bh << " at " << opos << dendl;
uint64_t bhoff = bh->start() - opos;
assert(f_it->second <= bh->length() - bhoff);
// get the frag we're mapping in
bufferlist frag;
frag.substr_of(wr->bl,
f_it->first, f_it->second);
// keep anything left of bhoff
bufferlist newbl;
if (bhoff)
newbl.substr_of(bh->bl, 0, bhoff);
newbl.claim_append(frag);
bh->bl.swap(newbl);
opos += f_it->second;
}
// ok, now bh is dirty.
mark_dirty(bh);
touch_bh(bh);
bh->last_write = now;
o->try_merge_bh(bh);
}
if (perfcounter) {
perfcounter->inc(l_objectcacher_data_written, bytes_written);
if (bytes_written_in_flush) {
perfcounter->inc(l_objectcacher_overwritten_in_flush,
bytes_written_in_flush);
}
}
int r = _wait_for_write(wr, bytes_written, oset, wait_on_lock, onfreespace);
delete wr;
//verify_stats();
trim();
return r;
}
void ObjectCacher::C_WaitForWrite::finish(int r)
{
Mutex::Locker l(m_oc->lock);
m_oc->maybe_wait_for_writeback(m_len);
m_onfinish->complete(r);
}
void ObjectCacher::maybe_wait_for_writeback(uint64_t len)
{
assert(lock.is_locked());
utime_t start = ceph_clock_now(cct);
int blocked = 0;
// wait for writeback?
// - wait for dirty and tx bytes (relative to the max_dirty threshold)
// - do not wait for bytes other waiters are waiting on. this means that
// threads do not wait for each other. this effectively allows the cache
// size to balloon proportional to the data that is in flight.
while (get_stat_dirty() + get_stat_tx() >= max_dirty + get_stat_dirty_waiting()) {
ldout(cct, 10) << __func__ << " waiting for dirty|tx "
<< (get_stat_dirty() + get_stat_tx()) << " >= max "
<< max_dirty << " + dirty_waiting "
<< get_stat_dirty_waiting() << dendl;
flusher_cond.Signal();
stat_dirty_waiting += len;
stat_cond.Wait(lock);
stat_dirty_waiting -= len;
++blocked;
ldout(cct, 10) << __func__ << " woke up" << dendl;
}
if (blocked && perfcounter) {
perfcounter->inc(l_objectcacher_write_ops_blocked);
perfcounter->inc(l_objectcacher_write_bytes_blocked, len);
utime_t blocked = ceph_clock_now(cct) - start;
perfcounter->tinc(l_objectcacher_write_time_blocked, blocked);
}
}
// blocking wait for write.
int ObjectCacher::_wait_for_write(OSDWrite *wr, uint64_t len, ObjectSet *oset, Mutex& lock, Context *onfreespace)
{
assert(lock.is_locked());
int ret = 0;
if (max_dirty > 0) {
if (block_writes_upfront) {
maybe_wait_for_writeback(len);
if (onfreespace)
onfreespace->complete(0);
} else {
assert(onfreespace);
finisher.queue(new C_WaitForWrite(this, len, onfreespace));
}
} else {
// write-thru! flush what we just wrote.
Cond cond;
bool done;
Context *fin = block_writes_upfront ?
new C_Cond(&cond, &done, &ret) : onfreespace;
assert(fin);
bool flushed = flush_set(oset, wr->extents, fin);
assert(!flushed); // we just dirtied it, and didn't drop our lock!
ldout(cct, 10) << "wait_for_write waiting on write-thru of " << len << " bytes" << dendl;
if (block_writes_upfront) {
while (!done)
cond.Wait(lock);
ldout(cct, 10) << "wait_for_write woke up, ret " << ret << dendl;
if (onfreespace)
onfreespace->complete(ret);
}
}
// start writeback anyway?
if (get_stat_dirty() > target_dirty) {
ldout(cct, 10) << "wait_for_write " << get_stat_dirty() << " > target "
<< target_dirty << ", nudging flusher" << dendl;
flusher_cond.Signal();
}
return ret;
}
void ObjectCacher::flusher_entry()
{
ldout(cct, 10) << "flusher start" << dendl;
lock.Lock();
while (!flusher_stop) {
loff_t all = get_stat_tx() + get_stat_rx() + get_stat_clean() + get_stat_dirty();
ldout(cct, 11) << "flusher "
<< all << " / " << max_size << ": "
<< get_stat_tx() << " tx, "
<< get_stat_rx() << " rx, "
<< get_stat_clean() << " clean, "
<< get_stat_dirty() << " dirty ("
<< target_dirty << " target, "
<< max_dirty << " max)"
<< dendl;
loff_t actual = get_stat_dirty() + get_stat_dirty_waiting();
if (actual > target_dirty) {
// flush some dirty pages
ldout(cct, 10) << "flusher "
<< get_stat_dirty() << " dirty + " << get_stat_dirty_waiting()
<< " dirty_waiting > target "
<< target_dirty
<< ", flushing some dirty bhs" << dendl;
flush(actual - target_dirty);
} else {
// check tail of lru for old dirty items
utime_t cutoff = ceph_clock_now(cct);
cutoff -= max_dirty_age;
BufferHead *bh = 0;
int max = MAX_FLUSH_UNDER_LOCK;
while ((bh = static_cast<BufferHead*>(bh_lru_dirty.lru_get_next_expire())) != 0 &&
bh->last_write < cutoff &&
--max > 0) {
ldout(cct, 10) << "flusher flushing aged dirty bh " << *bh << dendl;
bh_write(bh);
}
}
if (flusher_stop)
break;
flusher_cond.WaitInterval(cct, lock, utime_t(1,0));
}
/* Wait for reads to finish. This is only possible if handling
* -ENOENT made some read completions finish before their rados read
* came back. If we don't wait for them, and destroy the cache, when
* the rados reads do come back their callback will try to access the
* no-longer-valid ObjectCacher.
*/
while (reads_outstanding > 0) {
ldout(cct, 10) << "Waiting for all reads to complete. Number left: "
<< reads_outstanding << dendl;
read_cond.Wait(lock);
}
lock.Unlock();
ldout(cct, 10) << "flusher finish" << dendl;
}
// -------------------------------------------------
bool ObjectCacher::set_is_cached(ObjectSet *oset)
{
assert(lock.is_locked());
if (oset->objects.empty())
return false;
for (xlist<Object*>::iterator p = oset->objects.begin();
!p.end(); ++p) {
Object *ob = *p;
for (map<loff_t,BufferHead*>::iterator q = ob->data.begin();
q != ob->data.end();
++q) {
BufferHead *bh = q->second;
if (!bh->is_dirty() && !bh->is_tx())
return true;
}
}
return false;
}
bool ObjectCacher::set_is_dirty_or_committing(ObjectSet *oset)
{
assert(lock.is_locked());
if (oset->objects.empty())
return false;
for (xlist<Object*>::iterator i = oset->objects.begin();
!i.end(); ++i) {
Object *ob = *i;
for (map<loff_t,BufferHead*>::iterator p = ob->data.begin();
p != ob->data.end();
++p) {
BufferHead *bh = p->second;
if (bh->is_dirty() || bh->is_tx())
return true;
}
}
return false;
}
// purge. non-blocking. violently removes dirty buffers from cache.
void ObjectCacher::purge(Object *ob)
{
assert(lock.is_locked());
ldout(cct, 10) << "purge " << *ob << dendl;
ob->truncate(0);
}
// flush. non-blocking. no callback.
// true if clean, already flushed.
// false if we wrote something.
// be sloppy about the ranges and flush any buffer it touches
bool ObjectCacher::flush(Object *ob, loff_t offset, loff_t length)
{
assert(lock.is_locked());
bool clean = true;
ldout(cct, 10) << "flush " << *ob << " " << offset << "~" << length << dendl;
for (map<loff_t,BufferHead*>::iterator p = ob->data_lower_bound(offset); p != ob->data.end(); ++p) {
BufferHead *bh = p->second;
ldout(cct, 20) << "flush " << *bh << dendl;
if (length && bh->start() > offset+length) {
break;
}
if (bh->is_tx()) {
clean = false;
continue;
}
if (!bh->is_dirty()) {
continue;
}
bh_write(bh);
clean = false;
}
return clean;
}
bool ObjectCacher::_flush_set_finish(C_GatherBuilder *gather, Context *onfinish)
{
assert(lock.is_locked());
if (gather->has_subs()) {
gather->set_finisher(onfinish);
gather->activate();
return false;
}
ldout(cct, 10) << "flush_set has no dirty|tx bhs" << dendl;
onfinish->complete(0);
return true;
}
// flush. non-blocking, takes callback.
// returns true if already flushed
bool ObjectCacher::flush_set(ObjectSet *oset, Context *onfinish)
{
assert(lock.is_locked());
assert(onfinish != NULL);
if (oset->objects.empty()) {
ldout(cct, 10) << "flush_set on " << oset << " dne" << dendl;
onfinish->complete(0);
return true;
}
ldout(cct, 10) << "flush_set " << oset << dendl;
// we'll need to wait for all objects to flush!
C_GatherBuilder gather(cct);
for (xlist<Object*>::iterator i = oset->objects.begin();
!i.end(); ++i) {
Object *ob = *i;
if (!flush(ob, 0, 0)) {
// we'll need to gather...
ldout(cct, 10) << "flush_set " << oset << " will wait for ack tid "
<< ob->last_write_tid
<< " on " << *ob
<< dendl;
ob->waitfor_commit[ob->last_write_tid].push_back(gather.new_sub());
}
}
return _flush_set_finish(&gather, onfinish);
}
// flush. non-blocking, takes callback.
// returns true if already flushed
bool ObjectCacher::flush_set(ObjectSet *oset, vector<ObjectExtent>& exv, Context *onfinish)
{
assert(lock.is_locked());
assert(onfinish != NULL);
if (oset->objects.empty()) {
ldout(cct, 10) << "flush_set on " << oset << " dne" << dendl;
onfinish->complete(0);
return true;
}
ldout(cct, 10) << "flush_set " << oset << " on " << exv.size()
<< " ObjectExtents" << dendl;
// we'll need to wait for all objects to flush!
C_GatherBuilder gather(cct);
for (vector<ObjectExtent>::iterator p = exv.begin();
p != exv.end();
++p) {
ObjectExtent &ex = *p;
sobject_t soid(ex.oid, CEPH_NOSNAP);
if (objects[oset->poolid].count(soid) == 0)
continue;
Object *ob = objects[oset->poolid][soid];
ldout(cct, 20) << "flush_set " << oset << " ex " << ex << " ob " << soid << " " << ob << dendl;
if (!flush(ob, ex.offset, ex.length)) {
// we'll need to gather...
ldout(cct, 10) << "flush_set " << oset << " will wait for ack tid "
<< ob->last_write_tid << " on " << *ob << dendl;
ob->waitfor_commit[ob->last_write_tid].push_back(gather.new_sub());
}
}
return _flush_set_finish(&gather, onfinish);
}
void ObjectCacher::purge_set(ObjectSet *oset)
{
assert(lock.is_locked());
if (oset->objects.empty()) {
ldout(cct, 10) << "purge_set on " << oset << " dne" << dendl;
return;
}
ldout(cct, 10) << "purge_set " << oset << dendl;
for (xlist<Object*>::iterator i = oset->objects.begin();
!i.end(); ++i) {
Object *ob = *i;
purge(ob);
}
}
loff_t ObjectCacher::release(Object *ob)
{
assert(lock.is_locked());
list<BufferHead*> clean;
loff_t o_unclean = 0;
for (map<loff_t,BufferHead*>::iterator p = ob->data.begin();
p != ob->data.end();
++p) {
BufferHead *bh = p->second;
if (bh->is_clean() || bh->is_zero())
clean.push_back(bh);
else
o_unclean += bh->length();
}
for (list<BufferHead*>::iterator p = clean.begin();
p != clean.end();
++p) {
bh_remove(ob, *p);
delete *p;
}
if (ob->can_close()) {
ldout(cct, 10) << "release trimming " << *ob << dendl;
close_object(ob);
assert(o_unclean == 0);
return 0;
}
if (ob->complete) {
ldout(cct, 10) << "release clearing complete on " << *ob << dendl;
ob->complete = false;
}
if (!ob->exists) {
ldout(cct, 10) << "release setting exists on " << *ob << dendl;
ob->exists = true;
}
return o_unclean;
}
loff_t ObjectCacher::release_set(ObjectSet *oset)
{
assert(lock.is_locked());
// return # bytes not clean (and thus not released).
loff_t unclean = 0;
if (oset->objects.empty()) {
ldout(cct, 10) << "release_set on " << oset << " dne" << dendl;
return 0;
}
ldout(cct, 10) << "release_set " << oset << dendl;
xlist<Object*>::iterator q;
for (xlist<Object*>::iterator p = oset->objects.begin();
!p.end(); ) {
q = p;
++q;
Object *ob = *p;
loff_t o_unclean = release(ob);
unclean += o_unclean;
if (o_unclean)
ldout(cct, 10) << "release_set " << oset << " " << *ob
<< " has " << o_unclean << " bytes left"
<< dendl;
p = q;
}
if (unclean) {
ldout(cct, 10) << "release_set " << oset
<< ", " << unclean << " bytes left" << dendl;
}
return unclean;
}
uint64_t ObjectCacher::release_all()
{
assert(lock.is_locked());
ldout(cct, 10) << "release_all" << dendl;
uint64_t unclean = 0;
vector<hash_map<sobject_t, Object*> >::iterator i = objects.begin();
while (i != objects.end()) {
hash_map<sobject_t, Object*>::iterator p = i->begin();
while (p != i->end()) {
hash_map<sobject_t, Object*>::iterator n = p;
++n;
Object *ob = p->second;
loff_t o_unclean = release(ob);
unclean += o_unclean;
if (o_unclean)
ldout(cct, 10) << "release_all " << *ob
<< " has " << o_unclean << " bytes left"
<< dendl;
p = n;
}
++i;
}
if (unclean) {
ldout(cct, 10) << "release_all unclean " << unclean << " bytes left" << dendl;
}
return unclean;
}
void ObjectCacher::clear_nonexistence(ObjectSet *oset)
{
assert(lock.is_locked());
ldout(cct, 10) << "clear_nonexistence() " << oset << dendl;
for (xlist<Object*>::iterator p = oset->objects.begin();
!p.end(); ++p) {
Object *ob = *p;
if (!ob->exists) {
ldout(cct, 10) << " setting exists and complete on " << *ob << dendl;
ob->exists = true;
ob->complete = false;
}
for (xlist<C_ReadFinish*>::iterator q = ob->reads.begin();
!q.end(); ++q) {
C_ReadFinish *comp = *q;
comp->distrust_enoent();
}
}
}
/**
* discard object extents from an ObjectSet by removing the objects in exls from the in-memory oset.
*/
void ObjectCacher::discard_set(ObjectSet *oset, vector<ObjectExtent>& exls)
{
assert(lock.is_locked());
if (oset->objects.empty()) {
ldout(cct, 10) << "discard_set on " << oset << " dne" << dendl;
return;
}
ldout(cct, 10) << "discard_set " << oset << dendl;
bool were_dirty = oset->dirty_or_tx > 0;
for (vector<ObjectExtent>::iterator p = exls.begin();
p != exls.end();
++p) {
ldout(cct, 10) << "discard_set " << oset << " ex " << *p << dendl;
ObjectExtent &ex = *p;
sobject_t soid(ex.oid, CEPH_NOSNAP);
if (objects[oset->poolid].count(soid) == 0)
continue;
Object *ob = objects[oset->poolid][soid];
ob->discard(ex.offset, ex.length);
}
// did we truncate off dirty data?
if (flush_set_callback &&
were_dirty && oset->dirty_or_tx == 0)
flush_set_callback(flush_set_callback_arg, oset);
}
void ObjectCacher::verify_stats() const
{
assert(lock.is_locked());
ldout(cct, 10) << "verify_stats" << dendl;
loff_t clean = 0, zero = 0, dirty = 0, rx = 0, tx = 0, missing = 0, error = 0;
for (vector<hash_map<sobject_t, Object*> >::const_iterator i = objects.begin();
i != objects.end();
++i) {
for (hash_map<sobject_t, Object*>::const_iterator p = i->begin();
p != i->end();
++p) {
Object *ob = p->second;
for (map<loff_t, BufferHead*>::const_iterator q = ob->data.begin();
q != ob->data.end();
++q) {
BufferHead *bh = q->second;
switch (bh->get_state()) {
case BufferHead::STATE_MISSING:
missing += bh->length();
break;
case BufferHead::STATE_CLEAN:
clean += bh->length();
break;
case BufferHead::STATE_ZERO:
zero += bh->length();
break;
case BufferHead::STATE_DIRTY:
dirty += bh->length();
break;
case BufferHead::STATE_TX:
tx += bh->length();
break;
case BufferHead::STATE_RX:
rx += bh->length();
break;
case BufferHead::STATE_ERROR:
error += bh->length();
break;
default:
assert(0);
}
}
}
}
ldout(cct, 10) << " clean " << clean
<< " rx " << rx
<< " tx " << tx
<< " dirty " << dirty
<< " missing " << missing
<< " error " << error
<< dendl;
assert(clean == stat_clean);
assert(rx == stat_rx);
assert(tx == stat_tx);
assert(dirty == stat_dirty);
assert(missing == stat_missing);
assert(zero == stat_zero);
assert(error == stat_error);
}
void ObjectCacher::bh_stat_add(BufferHead *bh)
{
assert(lock.is_locked());
switch (bh->get_state()) {
case BufferHead::STATE_MISSING:
stat_missing += bh->length();
break;
case BufferHead::STATE_CLEAN:
stat_clean += bh->length();
break;
case BufferHead::STATE_ZERO:
stat_zero += bh->length();
break;
case BufferHead::STATE_DIRTY:
stat_dirty += bh->length();
bh->ob->dirty_or_tx += bh->length();
bh->ob->oset->dirty_or_tx += bh->length();
break;
case BufferHead::STATE_TX:
stat_tx += bh->length();
bh->ob->dirty_or_tx += bh->length();
bh->ob->oset->dirty_or_tx += bh->length();
break;
case BufferHead::STATE_RX:
stat_rx += bh->length();
break;
case BufferHead::STATE_ERROR:
stat_error += bh->length();
break;
default:
assert(0 == "bh_stat_add: invalid bufferhead state");
}
if (get_stat_dirty_waiting() > 0)
stat_cond.Signal();
}
void ObjectCacher::bh_stat_sub(BufferHead *bh)
{
assert(lock.is_locked());
switch (bh->get_state()) {
case BufferHead::STATE_MISSING:
stat_missing -= bh->length();
break;
case BufferHead::STATE_CLEAN:
stat_clean -= bh->length();
break;
case BufferHead::STATE_ZERO:
stat_zero -= bh->length();
break;
case BufferHead::STATE_DIRTY:
stat_dirty -= bh->length();
bh->ob->dirty_or_tx -= bh->length();
bh->ob->oset->dirty_or_tx -= bh->length();
break;
case BufferHead::STATE_TX:
stat_tx -= bh->length();
bh->ob->dirty_or_tx -= bh->length();
bh->ob->oset->dirty_or_tx -= bh->length();
break;
case BufferHead::STATE_RX:
stat_rx -= bh->length();
break;
case BufferHead::STATE_ERROR:
stat_error -= bh->length();
break;
default:
assert(0 == "bh_stat_sub: invalid bufferhead state");
}
}
void ObjectCacher::bh_set_state(BufferHead *bh, int s)
{
assert(lock.is_locked());
// move between lru lists?
if (s == BufferHead::STATE_DIRTY && bh->get_state() != BufferHead::STATE_DIRTY) {
bh_lru_rest.lru_remove(bh);
bh_lru_dirty.lru_insert_top(bh);
dirty_bh.insert(bh);
}
if (s != BufferHead::STATE_DIRTY && bh->get_state() == BufferHead::STATE_DIRTY) {
bh_lru_dirty.lru_remove(bh);
bh_lru_rest.lru_insert_top(bh);
dirty_bh.erase(bh);
}
if (s != BufferHead::STATE_ERROR && bh->get_state() == BufferHead::STATE_ERROR) {
bh->error = 0;
}
// set state
bh_stat_sub(bh);
bh->set_state(s);
bh_stat_add(bh);
}
void ObjectCacher::bh_add(Object *ob, BufferHead *bh)
{
assert(lock.is_locked());
ldout(cct, 30) << "bh_add " << *ob << " " << *bh << dendl;
ob->add_bh(bh);
if (bh->is_dirty()) {
bh_lru_dirty.lru_insert_top(bh);
dirty_bh.insert(bh);
} else {
bh_lru_rest.lru_insert_top(bh);
}
bh_stat_add(bh);
}
void ObjectCacher::bh_remove(Object *ob, BufferHead *bh)
{
assert(lock.is_locked());
ldout(cct, 30) << "bh_remove " << *ob << " " << *bh << dendl;
ob->remove_bh(bh);
if (bh->is_dirty()) {
bh_lru_dirty.lru_remove(bh);
dirty_bh.erase(bh);
} else {
bh_lru_rest.lru_remove(bh);
}
bh_stat_sub(bh);
}
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