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// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab
/*
* Ceph - scalable distributed file system
*
* Copyright (C) 2004-2006 Sage Weil <sage@newdream.net>
*
* This is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License version 2.1, as published by the Free Software
* Foundation. See file COPYING.
*
*/
#ifndef CEPH_SCATTERLOCK_H
#define CEPH_SCATTERLOCK_H
#include "SimpleLock.h"
#include "MDSContext.h"
class ScatterLock : public SimpleLock {
public:
ScatterLock(MDSCacheObject *o, LockType *lt) :
SimpleLock(o, lt) {}
~ScatterLock() override {
ceph_assert(!_more);
}
bool is_scatterlock() const override {
return true;
}
bool is_sync_and_unlocked() const {
return
SimpleLock::is_sync_and_unlocked() &&
!is_dirty() &&
!is_flushing();
}
bool can_scatter_pin(client_t loner) {
/*
LOCK : NOT okay because it can MIX and force replicas to journal something
TSYN : also not okay for same reason
EXCL : also not okay
MIX : okay, replica can stall before sending AC_SYNCACK
SYNC : okay, replica can stall before sending AC_MIXACK or AC_LOCKACK
*/
return
get_state() == LOCK_SYNC ||
get_state() == LOCK_MIX;
}
void set_xlock_snap_sync(MDSContext *c)
{
ceph_assert(get_type() == CEPH_LOCK_IFILE);
ceph_assert(state == LOCK_XLOCK || state == LOCK_XLOCKDONE);
state = LOCK_XLOCKSNAP;
add_waiter(WAIT_STABLE, c);
}
xlist<ScatterLock*>::item *get_updated_item() { return &more()->item_updated; }
utime_t get_update_stamp() {
return _more ? _more->update_stamp : utime_t();
}
void set_update_stamp(utime_t t) { more()->update_stamp = t; }
void set_scatter_wanted() {
state_flags |= SCATTER_WANTED;
}
void set_unscatter_wanted() {
state_flags |= UNSCATTER_WANTED;
}
void clear_scatter_wanted() {
state_flags &= ~SCATTER_WANTED;
}
void clear_unscatter_wanted() {
state_flags &= ~UNSCATTER_WANTED;
}
bool get_scatter_wanted() const {
return state_flags & SCATTER_WANTED;
}
bool get_unscatter_wanted() const {
return state_flags & UNSCATTER_WANTED;
}
bool is_dirty() const override {
return state_flags & DIRTY;
}
bool is_flushing() const override {
return state_flags & FLUSHING;
}
bool is_flushed() const override {
return state_flags & FLUSHED;
}
bool is_dirty_or_flushing() const {
return is_dirty() || is_flushing();
}
void mark_dirty() {
if (!is_dirty()) {
if (!is_flushing())
parent->get(MDSCacheObject::PIN_DIRTYSCATTERED);
set_dirty();
}
}
void start_flush() {
if (is_dirty()) {
set_flushing();
clear_dirty();
}
}
void finish_flush() {
if (is_flushing()) {
clear_flushing();
set_flushed();
if (!is_dirty()) {
parent->put(MDSCacheObject::PIN_DIRTYSCATTERED);
parent->clear_dirty_scattered(get_type());
}
}
}
void clear_flushed() override {
state_flags &= ~FLUSHED;
}
void remove_dirty() {
start_flush();
finish_flush();
clear_flushed();
}
void infer_state_from_strong_rejoin(int rstate, bool locktoo) {
if (rstate == LOCK_MIX ||
rstate == LOCK_MIX_LOCK || // replica still has wrlocks?
rstate == LOCK_MIX_SYNC)
state = LOCK_MIX;
else if (locktoo && rstate == LOCK_LOCK)
state = LOCK_LOCK;
}
void encode_state_for_rejoin(ceph::buffer::list& bl, int rep) {
__s16 s = get_replica_state();
if (is_gathering(rep)) {
// the recovering mds may hold rejoined wrlocks
if (state == LOCK_MIX_SYNC)
s = LOCK_MIX_SYNC;
else
s = LOCK_MIX_LOCK;
}
// If there is a recovering mds who replcated an object when it failed
// and scatterlock in the object was in MIX state, It's possible that
// the recovering mds needs to take wrlock on the scatterlock when it
// replays unsafe requests. So this mds should delay taking rdlock on
// the scatterlock until the recovering mds finishes replaying unsafe.
// Otherwise unsafe requests may get replayed after current request.
//
// For example:
// The recovering mds is auth mds of a dirfrag, this mds is auth mds
// of corresponding inode. when 'rm -rf' the direcotry, this mds should
// delay the rmdir request until the recovering mds has replayed unlink
// requests.
if (s == LOCK_MIX || s == LOCK_MIX_LOCK || s == LOCK_MIX_SYNC)
mark_need_recover();
using ceph::encode;
encode(s, bl);
}
void decode_state_rejoin(ceph::buffer::list::const_iterator& p, MDSContext::vec& waiters, bool survivor) {
SimpleLock::decode_state_rejoin(p, waiters, survivor);
if (is_flushing()) {
set_dirty();
clear_flushing();
}
}
bool remove_replica(int from, bool rejoin) {
if (rejoin &&
(state == LOCK_MIX ||
state == LOCK_MIX_SYNC ||
state == LOCK_MIX_LOCK2 ||
state == LOCK_MIX_TSYN ||
state == LOCK_MIX_EXCL))
return false;
return SimpleLock::remove_replica(from);
}
void print(std::ostream& out) const override {
out << "(";
_print(out);
if (is_dirty())
out << " dirty";
if (is_flushing())
out << " flushing";
if (is_flushed())
out << " flushed";
if (get_scatter_wanted())
out << " scatter_wanted";
out << ")";
}
private:
struct more_bits_t {
xlist<ScatterLock*>::item item_updated;
utime_t update_stamp;
explicit more_bits_t(ScatterLock *lock) :
item_updated(lock)
{}
};
more_bits_t *more() {
if (!_more)
_more.reset(new more_bits_t(this));
return _more.get();
}
enum {
SCATTER_WANTED = 1 << 8,
UNSCATTER_WANTED = 1 << 9,
DIRTY = 1 << 10,
FLUSHING = 1 << 11,
FLUSHED = 1 << 12,
};
void set_flushing() {
state_flags |= FLUSHING;
}
void clear_flushing() {
state_flags &= ~FLUSHING;
}
void set_flushed() {
state_flags |= FLUSHED;
}
void set_dirty() {
state_flags |= DIRTY;
}
void clear_dirty() {
state_flags &= ~DIRTY;
if (_more) {
_more->item_updated.remove_myself();
_more.reset();
}
}
mutable std::unique_ptr<more_bits_t> _more;
};
#endif
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