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log.cc
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log.cc
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/* Masstree
* Eddie Kohler, Yandong Mao, Robert Morris
* Copyright (c) 2012-2014 President and Fellows of Harvard College
* Copyright (c) 2012-2014 Massachusetts Institute of Technology
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, subject to the conditions
* listed in the Masstree LICENSE file. These conditions include: you must
* preserve this copyright notice, and you cannot mention the copyright
* holders in advertising related to the Software without their permission.
* The Software is provided WITHOUT ANY WARRANTY, EXPRESS OR IMPLIED. This
* notice is a summary of the Masstree LICENSE file; the license in that file
* is legally binding.
*/
#include "log.hh"
#include "kvthread.hh"
#include "kvrow.hh"
#include "file.hh"
#include "query_masstree.hh"
#include "masstree_tcursor.hh"
#include "masstree_insert.hh"
#include "masstree_remove.hh"
#include "misc.hh"
#include "msgpack.hh"
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <errno.h>
using lcdf::String;
kvepoch_t global_log_epoch;
kvepoch_t global_wake_epoch;
struct timeval log_epoch_interval;
static struct timeval log_epoch_time;
extern Masstree::default_table* tree;
extern volatile bool recovering;
kvepoch_t rec_ckp_min_epoch;
kvepoch_t rec_ckp_max_epoch;
logreplay::info_type *rec_log_infos;
kvepoch_t rec_replay_min_epoch;
kvepoch_t rec_replay_max_epoch;
kvepoch_t rec_replay_min_quiescent_last_epoch;
struct logrec_base {
uint32_t command_;
uint32_t size_;
static size_t size() {
return sizeof(logrec_base);
}
static size_t store(char *buf, uint32_t command) {
// XXX check alignment on some architectures
logrec_base *lr = reinterpret_cast<logrec_base *>(buf);
lr->command_ = command;
lr->size_ = sizeof(*lr);
return sizeof(*lr);
}
static bool check(const char *buf) {
const logrec_base *lr = reinterpret_cast<const logrec_base *>(buf);
return lr->size_ >= sizeof(*lr);
}
static uint32_t command(const char *buf) {
const logrec_base *lr = reinterpret_cast<const logrec_base *>(buf);
return lr->command_;
}
};
struct logrec_epoch {
uint32_t command_;
uint32_t size_;
kvepoch_t epoch_;
static size_t size() {
return sizeof(logrec_epoch);
}
static size_t store(char *buf, uint32_t command, kvepoch_t epoch) {
// XXX check alignment on some architectures
logrec_epoch *lr = reinterpret_cast<logrec_epoch *>(buf);
lr->command_ = command;
lr->size_ = sizeof(*lr);
lr->epoch_ = epoch;
return sizeof(*lr);
}
static bool check(const char *buf) {
const logrec_epoch *lr = reinterpret_cast<const logrec_epoch *>(buf);
return lr->size_ >= sizeof(*lr);
}
};
struct logrec_kv {
uint32_t command_;
uint32_t size_;
kvtimestamp_t ts_;
uint32_t keylen_;
char buf_[0];
static size_t size(uint32_t keylen, uint32_t vallen) {
return sizeof(logrec_kv) + keylen + vallen;
}
static size_t store(char *buf, uint32_t command,
Str key, Str val,
kvtimestamp_t ts) {
// XXX check alignment on some architectures
logrec_kv *lr = reinterpret_cast<logrec_kv *>(buf);
lr->command_ = command;
lr->size_ = sizeof(*lr) + key.len + val.len;
lr->ts_ = ts;
lr->keylen_ = key.len;
memcpy(lr->buf_, key.s, key.len);
memcpy(lr->buf_ + key.len, val.s, val.len);
return sizeof(*lr) + key.len + val.len;
}
static bool check(const char *buf) {
const logrec_kv *lr = reinterpret_cast<const logrec_kv *>(buf);
return lr->size_ >= sizeof(*lr)
&& lr->size_ >= sizeof(*lr) + lr->keylen_;
}
};
struct logrec_kvdelta {
uint32_t command_;
uint32_t size_;
kvtimestamp_t ts_;
kvtimestamp_t prev_ts_;
uint32_t keylen_;
char buf_[0];
static size_t size(uint32_t keylen, uint32_t vallen) {
return sizeof(logrec_kvdelta) + keylen + vallen;
}
static size_t store(char *buf, uint32_t command,
Str key, Str val,
kvtimestamp_t prev_ts, kvtimestamp_t ts) {
// XXX check alignment on some architectures
logrec_kvdelta *lr = reinterpret_cast<logrec_kvdelta *>(buf);
lr->command_ = command;
lr->size_ = sizeof(*lr) + key.len + val.len;
lr->ts_ = ts;
lr->prev_ts_ = prev_ts;
lr->keylen_ = key.len;
memcpy(lr->buf_, key.s, key.len);
memcpy(lr->buf_ + key.len, val.s, val.len);
return sizeof(*lr) + key.len + val.len;
}
static bool check(const char *buf) {
const logrec_kvdelta *lr = reinterpret_cast<const logrec_kvdelta *>(buf);
return lr->size_ >= sizeof(*lr)
&& lr->size_ >= sizeof(*lr) + lr->keylen_;
}
};
logset* logset::make(int size) {
static_assert(sizeof(loginfo) == 2 * CACHE_LINE_SIZE, "unexpected sizeof(loginfo)");
assert(size > 0 && size <= 64);
char* x = new char[sizeof(loginfo) * size + sizeof(loginfo::logset_info) + CACHE_LINE_SIZE];
char* ls_pos = x + sizeof(loginfo::logset_info);
uintptr_t left = reinterpret_cast<uintptr_t>(ls_pos) % CACHE_LINE_SIZE;
if (left)
ls_pos += CACHE_LINE_SIZE - left;
logset* ls = reinterpret_cast<logset*>(ls_pos);
ls->li_[-1].lsi_.size_ = size;
ls->li_[-1].lsi_.allocation_offset_ = (int) (x - ls_pos);
for (int i = 0; i != size; ++i)
new((void*) &ls->li_[i]) loginfo(ls, i);
return ls;
}
void logset::free(logset* ls) {
for (int i = 0; i != ls->size(); ++i)
ls->li_[i].~loginfo();
delete[] (reinterpret_cast<char*>(ls) + ls->li_[-1].lsi_.allocation_offset_);
}
loginfo::loginfo(logset* ls, int logindex) {
f_.lock_ = 0;
f_.waiting_ = 0;
f_.filename_ = String().internal_rep();
f_.filename_.ref();
len_ = 20 * 1024 * 1024;
pos_ = 0;
buf_ = (char *) malloc(len_);
always_assert(buf_);
log_epoch_ = 0;
quiescent_epoch_ = 0;
wake_epoch_ = 0;
flushed_epoch_ = 0;
ti_ = 0;
f_.logset_ = ls;
logindex_ = logindex;
(void) padding1_;
}
loginfo::~loginfo() {
f_.filename_.deref();
free(buf_);
}
void* loginfo::trampoline(void* x) {
loginfo* li = reinterpret_cast<loginfo*>(x);
li->ti_->pthread() = pthread_self();
return li->run();
}
void loginfo::initialize(const String& logfile) {
assert(!ti_);
f_.filename_.deref();
f_.filename_ = logfile.internal_rep();
f_.filename_.ref();
ti_ = threadinfo::make(threadinfo::TI_LOG, logindex_);
int r = pthread_create(&ti_->pthread(), 0, trampoline, this);
always_assert(r == 0);
}
// one logger thread per logs[].
static void check_epoch() {
struct timeval tv;
gettimeofday(&tv, 0);
if (timercmp(&tv, &log_epoch_time, >)) {
log_epoch_time = tv;
timeradd(&log_epoch_time, &log_epoch_interval, &log_epoch_time);
global_log_epoch = global_log_epoch.next_nonzero(); // 0 isn't valid
}
}
void* loginfo::run() {
{
logreplay replayer(f_.filename_);
replayer.replay(ti_->index(), ti_);
}
int fd = open(String(f_.filename_).c_str(),
O_WRONLY | O_APPEND | O_CREAT, 0666);
always_assert(fd >= 0);
char *x_buf = (char *) malloc(len_);
always_assert(x_buf);
while (1) {
uint32_t nb = 0;
acquire();
kvepoch_t ge = global_log_epoch, we = global_wake_epoch;
if (wake_epoch_ != we) {
wake_epoch_ = we;
quiescent_epoch_ = 0;
}
// If the writing threads appear quiescent, and aren't about to write
// to the log (f_.waiting_ != 0), then write a quiescence
// notification.
if (!recovering && pos_ == 0 && !quiescent_epoch_
&& ge != log_epoch_ && ge != we && !f_.waiting_) {
quiescent_epoch_ = log_epoch_ = ge;
char *p = buf_;
p += logrec_epoch::store(p, logcmd_epoch, log_epoch_);
if (log_epoch_ == wake_epoch_)
p += logrec_base::store(p, logcmd_wake);
p += logrec_base::store(p, logcmd_quiesce);
pos_ = p - buf_;
}
if (!recovering && pos_ > 0) {
uint32_t x_pos = pos_;
std::swap(buf_, x_buf);
pos_ = 0;
kvepoch_t x_epoch = log_epoch_;
release();
ssize_t r = write(fd, x_buf, x_pos);
always_assert(r == ssize_t(x_pos));
fsync(fd);
flushed_epoch_ = x_epoch;
// printf("log %d %d\n", ti_->index(), x_pos);
nb = x_pos;
} else
release();
if (nb < len_ / 4)
napms(200);
if (ti_->index() == 0)
check_epoch();
}
return 0;
}
// log entry format: see log.hh
void loginfo::record(int command, const query_times& qtimes,
Str key, Str value) {
assert(!recovering);
size_t n = logrec_kvdelta::size(key.len, value.len)
+ logrec_epoch::size() + logrec_base::size();
waitlist wait = { &wait };
int stalls = 0;
while (1) {
if (len_ - pos_ >= n
&& (wait.next == &wait || f_.waiting_ == &wait)) {
kvepoch_t we = global_wake_epoch;
// Potentially record a new epoch.
if (qtimes.epoch != log_epoch_) {
log_epoch_ = qtimes.epoch;
pos_ += logrec_epoch::store(buf_ + pos_, logcmd_epoch, qtimes.epoch);
}
if (quiescent_epoch_) {
// We're recording a new log record on a log that's been
// quiescent for a while. If the quiescence marker has been
// flushed, then all epochs less than the query epoch are
// effectively on disk.
if (flushed_epoch_ == quiescent_epoch_)
flushed_epoch_ = qtimes.epoch;
quiescent_epoch_ = 0;
while (we < qtimes.epoch)
we = cmpxchg(&global_wake_epoch, we, qtimes.epoch);
}
// Log epochs should be recorded in monotonically increasing
// order, but the wake epoch may be ahead of the query epoch (if
// the query took a while). So potentially record an EARLIER
// wake_epoch. This will get fixed shortly by the next log
// record.
if (we != wake_epoch_ && qtimes.epoch < we)
we = qtimes.epoch;
if (we != wake_epoch_) {
wake_epoch_ = we;
pos_ += logrec_base::store(buf_ + pos_, logcmd_wake);
}
if (command == logcmd_put && qtimes.prev_ts
&& !(qtimes.prev_ts & 1))
pos_ += logrec_kvdelta::store(buf_ + pos_,
logcmd_modify, key, value,
qtimes.prev_ts, qtimes.ts);
else
pos_ += logrec_kv::store(buf_ + pos_,
command, key, value, qtimes.ts);
if (f_.waiting_ == &wait)
f_.waiting_ = wait.next;
release();
return;
}
// Otherwise must spin
if (wait.next == &wait) {
waitlist** p = &f_.waiting_;
while (*p)
p = &(*p)->next;
*p = &wait;
wait.next = 0;
}
release();
if (stalls == 0)
printf("stall\n");
else if (stalls % 25 == 0)
printf("stall %d\n", stalls);
++stalls;
napms(50);
acquire();
}
}
void loginfo::record(int command, const query_times& qtimes, Str key,
const lcdf::Json* req, const lcdf::Json* end_req) {
lcdf::StringAccum sa(128);
msgpack::unparser<lcdf::StringAccum> cu(sa);
cu.write_array_header(end_req - req);
for (; req != end_req; ++req)
cu << *req;
record(command, qtimes, key, Str(sa.data(), sa.length()));
}
// replay
logreplay::logreplay(const String &filename)
: filename_(filename), errno_(0), buf_()
{
int fd = open(filename_.c_str(), O_RDONLY);
if (fd == -1) {
fail:
errno_ = errno;
buf_ = 0;
if (fd != -1)
(void) close(fd);
return;
}
struct stat sb;
int r = fstat(fd, &sb);
if (r == -1)
goto fail;
size_ = sb.st_size;
if (size_ != 0) {
// XXX what if filename_ is too big to mmap in its entirety?
// XXX should support mmaping/writing in pieces
buf_ = (char *) ::mmap(0, size_, PROT_READ, MAP_FILE | MAP_PRIVATE,
fd, 0);
if (buf_ == MAP_FAILED)
goto fail;
}
(void) close(fd);
}
logreplay::~logreplay()
{
unmap();
}
int
logreplay::unmap()
{
int r = 0;
if (buf_) {
r = munmap(buf_, size_);
buf_ = 0;
}
return r;
}
struct logrecord {
uint32_t command;
Str key;
Str val;
kvtimestamp_t ts;
kvtimestamp_t prev_ts;
kvepoch_t epoch;
const char *extract(const char *buf, const char *end);
template <typename T>
void run(T& table, std::vector<lcdf::Json>& jrepo, threadinfo& ti);
private:
inline void apply(row_type*& value, bool found,
std::vector<lcdf::Json>& jrepo, threadinfo& ti);
};
const char *
logrecord::extract(const char *buf, const char *end)
{
const logrec_base *lr = reinterpret_cast<const logrec_base *>(buf);
if (unlikely(size_t(end - buf) < sizeof(*lr)
|| lr->size_ < sizeof(*lr)
|| size_t(end - buf) < lr->size_
|| lr->command_ == logcmd_none)) {
fail:
command = logcmd_none;
return end;
}
command = lr->command_;
if (command == logcmd_put || command == logcmd_replace
|| command == logcmd_remove) {
const logrec_kv *lk = reinterpret_cast<const logrec_kv *>(buf);
if (unlikely(lk->size_ < sizeof(*lk)
|| lk->keylen_ > MASSTREE_MAXKEYLEN
|| sizeof(*lk) + lk->keylen_ > lk->size_))
goto fail;
ts = lk->ts_;
key.assign(lk->buf_, lk->keylen_);
val.assign(lk->buf_ + lk->keylen_, lk->size_ - sizeof(*lk) - lk->keylen_);
} else if (command == logcmd_modify) {
const logrec_kvdelta *lk = reinterpret_cast<const logrec_kvdelta *>(buf);
if (unlikely(lk->keylen_ > MASSTREE_MAXKEYLEN
|| sizeof(*lk) + lk->keylen_ > lk->size_))
goto fail;
ts = lk->ts_;
prev_ts = lk->prev_ts_;
key.assign(lk->buf_, lk->keylen_);
val.assign(lk->buf_ + lk->keylen_, lk->size_ - sizeof(*lk) - lk->keylen_);
} else if (command == logcmd_epoch) {
const logrec_epoch *lre = reinterpret_cast<const logrec_epoch *>(buf);
if (unlikely(lre->size_ < logrec_epoch::size()))
goto fail;
epoch = lre->epoch_;
}
return buf + lr->size_;
}
template <typename T>
void logrecord::run(T& table, std::vector<lcdf::Json>& jrepo, threadinfo& ti) {
row_marker m;
if (command == logcmd_remove) {
ts |= 1;
m.marker_type_ = row_marker::mt_remove;
val = Str((const char*) &m, sizeof(m));
}
typename T::cursor_type lp(table, key);
bool found = lp.find_insert(ti);
if (!found)
ti.observe_phantoms(lp.node());
apply(lp.value(), found, jrepo, ti);
lp.finish(1, ti);
}
static lcdf::Json* parse_changeset(Str changeset,
std::vector<lcdf::Json>& jrepo) {
msgpack::parser mp(changeset.udata());
unsigned index = 0;
Str value;
size_t pos = 0;
while (mp.position() != changeset.end()) {
if (pos == jrepo.size())
jrepo.resize(pos + 2);
mp >> index >> value;
jrepo[pos] = index;
jrepo[pos + 1] = String::make_stable(value);
pos += 2;
}
return jrepo.data() + pos;
}
inline void logrecord::apply(row_type*& value, bool found,
std::vector<lcdf::Json>& jrepo, threadinfo& ti) {
row_type** cur_value = &value;
if (!found)
*cur_value = 0;
// find point to insert change (may be after some delta markers)
while (*cur_value && row_is_delta_marker(*cur_value)
&& (*cur_value)->timestamp() > ts)
cur_value = &row_get_delta_marker(*cur_value)->prev_;
// check out of date
if (*cur_value && (*cur_value)->timestamp() >= ts)
return;
// if not modifying, delete everything earlier
if (command != logcmd_modify)
while (row_type* old_value = *cur_value) {
if (row_is_delta_marker(old_value)) {
ti.mark(tc_replay_remove_delta);
*cur_value = row_get_delta_marker(old_value)->prev_;
} else
*cur_value = 0;
old_value->deallocate(ti);
}
// actually apply change
if (command == logcmd_replace)
*cur_value = row_type::create1(val, ts, ti);
else if (command != logcmd_modify
|| (*cur_value && (*cur_value)->timestamp() == prev_ts)) {
lcdf::Json* end_req = parse_changeset(val, jrepo);
if (command != logcmd_modify)
*cur_value = row_type::create(jrepo.data(), end_req, ts, ti);
else {
row_type* old_value = *cur_value;
*cur_value = old_value->update(jrepo.data(), end_req, ts, ti);
if (*cur_value != old_value)
old_value->deallocate(ti);
}
} else {
// XXX assume that memory exists before saved request -- it does
// in conventional log replay, but that's an ugly interface
val.s -= sizeof(row_delta_marker<row_type>);
val.len += sizeof(row_delta_marker<row_type>);
row_type* new_value = row_type::create1(val, ts | 1, ti);
row_delta_marker<row_type>* dm = row_get_delta_marker(new_value, true);
dm->marker_type_ = row_marker::mt_delta;
dm->prev_ts_ = prev_ts;
dm->prev_ = *cur_value;
*cur_value = new_value;
ti.mark(tc_replay_create_delta);
}
// clean up
while (value && row_is_delta_marker(value)) {
row_type **prev = 0, **trav = &value;
while (*trav && row_is_delta_marker(*trav)) {
prev = trav;
trav = &row_get_delta_marker(*trav)->prev_;
}
if (prev && *trav
&& row_get_delta_marker(*prev)->prev_ts_ == (*trav)->timestamp()) {
row_type *old_prev = *prev;
Str req = old_prev->col(0);
req.s += sizeof(row_delta_marker<row_type>);
req.len -= sizeof(row_delta_marker<row_type>);
const lcdf::Json* end_req = parse_changeset(req, jrepo);
*prev = (*trav)->update(jrepo.data(), end_req, old_prev->timestamp() - 1, ti);
if (*prev != *trav)
(*trav)->deallocate(ti);
old_prev->deallocate(ti);
ti.mark(tc_replay_remove_delta);
} else
break;
}
}
logreplay::info_type
logreplay::info() const
{
info_type x;
x.first_epoch = x.last_epoch = x.wake_epoch = x.min_post_quiescent_wake_epoch = 0;
x.quiescent = true;
const char *buf = buf_, *end = buf_ + size_;
off_t nr = 0;
bool log_corrupt = false;
while (buf + sizeof(logrec_base) <= end) {
const logrec_base *lr = reinterpret_cast<const logrec_base *>(buf);
if (unlikely(lr->size_ < sizeof(logrec_base))) {
log_corrupt = true;
break;
} else if (unlikely(buf + lr->size_ > end))
break;
x.quiescent = lr->command_ == logcmd_quiesce;
if (lr->command_ == logcmd_epoch) {
const logrec_epoch *lre =
reinterpret_cast<const logrec_epoch *>(buf);
if (unlikely(lre->size_ < sizeof(*lre))) {
log_corrupt = true;
break;
}
if (!x.first_epoch)
x.first_epoch = lre->epoch_;
x.last_epoch = lre->epoch_;
if (x.wake_epoch && x.wake_epoch > x.last_epoch) // wrap-around
x.wake_epoch = 0;
} else if (lr->command_ == logcmd_wake)
x.wake_epoch = x.last_epoch;
#if !NDEBUG
else if (lr->command_ != logcmd_put
&& lr->command_ != logcmd_replace
&& lr->command_ != logcmd_modify
&& lr->command_ != logcmd_remove
&& lr->command_ != logcmd_quiesce) {
log_corrupt = true;
break;
}
#endif
buf += lr->size_;
++nr;
}
fprintf(stderr, "replay %s: %" PRIdOFF_T " records, first %" PRIu64 ", last %" PRIu64 ", wake %" PRIu64 "%s%s @%zu\n",
filename_.c_str(), nr, x.first_epoch.value(),
x.last_epoch.value(), x.wake_epoch.value(),
x.quiescent ? ", quiescent" : "",
log_corrupt ? ", CORRUPT" : "", buf - buf_);
return x;
}
kvepoch_t
logreplay::min_post_quiescent_wake_epoch(kvepoch_t quiescent_epoch) const
{
kvepoch_t e = 0;
const char *buf = buf_, *end = buf_ + size_;
bool log_corrupt = false;
while (buf + sizeof(logrec_base) <= end) {
const logrec_base *lr = reinterpret_cast<const logrec_base *>(buf);
if (unlikely(lr->size_ < sizeof(logrec_base))) {
log_corrupt = true;
break;
} else if (unlikely(buf + lr->size_ > end))
break;
if (lr->command_ == logcmd_epoch) {
const logrec_epoch *lre =
reinterpret_cast<const logrec_epoch *>(buf);
if (unlikely(lre->size_ < sizeof(*lre))) {
log_corrupt = true;
break;
}
e = lre->epoch_;
} else if (lr->command_ == logcmd_wake
&& e
&& e >= quiescent_epoch)
return e;
buf += lr->size_;
}
(void) log_corrupt;
return 0;
}
uint64_t
logreplay::replayandclean1(kvepoch_t min_epoch, kvepoch_t max_epoch,
threadinfo *ti)
{
uint64_t nr = 0;
const char *pos = buf_, *end = buf_ + size_;
const char *repbegin = 0, *repend = 0;
logrecord lr;
std::vector<lcdf::Json> jrepo;
// XXX
while (pos < end) {
const char *nextpos = lr.extract(pos, end);
if (lr.command == logcmd_none) {
fprintf(stderr, "replay %s: %" PRIu64 " entries replayed, CORRUPT @%zu\n",
filename_.c_str(), nr, pos - buf_);
break;
}
if (lr.command == logcmd_epoch) {
if ((min_epoch && lr.epoch < min_epoch)
|| (!min_epoch && !repbegin))
repbegin = pos;
if (lr.epoch >= max_epoch) {
always_assert(repbegin);
repend = nextpos;
break;
}
}
if (!lr.epoch || (min_epoch && lr.epoch < min_epoch)) {
pos = nextpos;
if (repbegin)
repend = nextpos;
continue;
}
// replay only part of log after checkpoint
// could replay everything, the if() here tests
// correctness of checkpoint scheme.
assert(repbegin);
repend = nextpos;
if (lr.key.len) { // skip empty entry
if (lr.command == logcmd_put
|| lr.command == logcmd_replace
|| lr.command == logcmd_modify
|| lr.command == logcmd_remove)
lr.run(tree->table(), jrepo, *ti);
++nr;
if (nr % 100000 == 0)
fprintf(stderr,
"replay %s: %" PRIu64 " entries replayed\n",
filename_.c_str(), nr);
}
// XXX RCU
pos = nextpos;
}
// rewrite portion of log
if (!repbegin)
repbegin = repend = buf_;
else if (!repend) {
fprintf(stderr, "replay %s: surprise repend\n", filename_.c_str());
repend = pos;
}
char tmplog[256];
int r = snprintf(tmplog, sizeof(tmplog), "%s.tmp", filename_.c_str());
always_assert(r >= 0 && size_t(r) < sizeof(tmplog));
printf("replay %s: truncate from %" PRIdOFF_T " to %" PRIdSIZE_T " [%" PRIdSIZE_T ",%" PRIdSIZE_T ")\n",
filename_.c_str(), size_, repend - repbegin,
repbegin - buf_, repend - buf_);
bool need_copy = repbegin != buf_;
int fd;
if (!need_copy)
fd = replay_truncate(repend - repbegin);
else
fd = replay_copy(tmplog, repbegin, repend);
r = fsync(fd);
always_assert(r == 0);
r = close(fd);
always_assert(r == 0);
// replace old log with rewritten log
if (unmap() != 0)
abort();
if (need_copy) {
r = rename(tmplog, filename_.c_str());
if (r != 0) {
fprintf(stderr, "replay %s: %s\n", filename_.c_str(), strerror(errno));
abort();
}
}
return nr;
}
int
logreplay::replay_truncate(size_t len)
{
int fd = open(filename_.c_str(), O_RDWR);
if (fd < 0) {
fprintf(stderr, "replay %s: %s\n", filename_.c_str(), strerror(errno));
abort();
}
struct stat sb;
int r = fstat(fd, &sb);
if (r != 0) {
fprintf(stderr, "replay %s: %s\n", filename_.c_str(), strerror(errno));
abort();
} else if (sb.st_size < off_t(len)) {
fprintf(stderr, "replay %s: bad length %" PRIdOFF_T "\n", filename_.c_str(), sb.st_size);
abort();
}
r = ftruncate(fd, len);
if (r != 0) {
fprintf(stderr, "replay %s: truncate: %s\n", filename_.c_str(), strerror(errno));
abort();
}
off_t off = lseek(fd, len, SEEK_SET);
if (off == (off_t) -1) {
fprintf(stderr, "replay %s: seek: %s\n", filename_.c_str(), strerror(errno));
abort();
}
return fd;
}
int
logreplay::replay_copy(const char *tmpname, const char *first, const char *last)
{
int fd = creat(tmpname, 0666);
if (fd < 0) {
fprintf(stderr, "replay %s: create: %s\n", tmpname, strerror(errno));
abort();
}
ssize_t w = safe_write(fd, first, last - first);
always_assert(w >= 0 && w == last - first);
return fd;
}
void
logreplay::replay(int which, threadinfo *ti)
{
waituntilphase(REC_LOG_TS);
// find the maximum timestamp of entries in the log
if (buf_) {
info_type x = info();
pthread_mutex_lock(&rec_mu);
rec_log_infos[which] = x;
pthread_mutex_unlock(&rec_mu);
}
inactive();
waituntilphase(REC_LOG_ANALYZE_WAKE);
if (buf_) {
if (rec_replay_min_quiescent_last_epoch
&& rec_replay_min_quiescent_last_epoch <= rec_log_infos[which].wake_epoch)
rec_log_infos[which].min_post_quiescent_wake_epoch =
min_post_quiescent_wake_epoch(rec_replay_min_quiescent_last_epoch);
}
inactive();
waituntilphase(REC_LOG_REPLAY);
if (buf_) {
ti->rcu_start();
uint64_t nr = replayandclean1(rec_replay_min_epoch, rec_replay_max_epoch, ti);
ti->rcu_stop();
printf("recovered %" PRIu64 " records from %s\n", nr, filename_.c_str());
}
inactive();
}