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simplified merge_scheduler

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git-svn-id: svn+ssh://svn.corp.yahoo.com/yahoo/yrl/labs/pnuts/code/logstore@1479 8dad8b1f-cf64-0410-95b6-bcf113ffbcfe
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sears 2010-12-11 00:51:19 +00:00
parent 8dddc7e168
commit a00531ae6d
14 changed files with 168 additions and 255 deletions
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17
logstore.cpp
View file

@ -23,7 +23,7 @@ template<class TUPLE>
logtable<TUPLE>::logtable(pageid_t internal_region_size, pageid_t datapage_region_size, pageid_t datapage_size)
{
r_val = MIN_R;
r_val = 3.0; // MIN_R
tree_c0 = NULL;
tree_c0_mergeable = NULL;
c0_is_merging = false;
@ -36,8 +36,6 @@ logtable<TUPLE>::logtable(pageid_t internal_region_size, pageid_t datapage_regio
this->shutting_down_ = false;
flushing = false;
this->merge_mgr = new mergeManager(this);
this->mergedata = 0;
//tmerger = new tuplemerger(&append_merger);
tmerger = new tuplemerger(&replace_merger);
header_mut = rwlc_initlock();
@ -61,6 +59,8 @@ logtable<TUPLE>::logtable(pageid_t internal_region_size, pageid_t datapage_regio
template<class TUPLE>
logtable<TUPLE>::~logtable()
{
delete merge_mgr; // shuts down pretty print thread.
if(tree_c1 != NULL)
delete tree_c1;
if(tree_c2 != NULL)
@ -85,7 +85,7 @@ template<class TUPLE>
void logtable<TUPLE>::init_stasis() {
DataPage<datatuple>::register_stasis_page_impl();
stasis_buffer_manager_size = 768 * 1024; // 4GB = 2^10 pages:
//stasis_buffer_manager_size = 768 * 1024; // 4GB = 2^10 pages:
// XXX Workaround Stasis' (still broken) default concurrent buffer manager
// stasis_buffer_manager_factory = stasis_buffer_manager_hash_factory;
// stasis_buffer_manager_hint_writes_are_sequential = 0;
@ -112,6 +112,8 @@ recordid logtable<TUPLE>::allocTable(int xid)
merge_mgr->new_merge(0);
c0_stats->starting_merge();
tree_c0 = new memTreeComponent<datatuple>::rbtree_t;
update_persistent_header(xid, 1);
update_persistent_header(xid, 2);
@ -124,6 +126,7 @@ void logtable<TUPLE>::openTable(int xid, recordid rid) {
Tread(xid, table_rec, &tbl_header);
tree_c2 = new diskTreeComponent(xid, tbl_header.c2_root, tbl_header.c2_state, tbl_header.c2_dp_state, 0);
tree_c1 = new diskTreeComponent(xid, tbl_header.c1_root, tbl_header.c1_state, tbl_header.c1_dp_state, 0);
tree_c0 = new memTreeComponent<datatuple>::rbtree_t;
merge_mgr->get_merge_stats(1)->bytes_out = tbl_header.c1_base_size;
merge_mgr->get_merge_stats(1)->base_size = tbl_header.c1_base_size;
@ -160,12 +163,6 @@ void logtable<TUPLE>::update_persistent_header(int xid, int merge_level) {
Tset(xid, table_rec, &tbl_header);
}
template<class TUPLE>
void logtable<TUPLE>::setMergeData(logtable_mergedata * mdata){
this->mergedata = mdata;
bump_epoch();
}
template<class TUPLE>
void logtable<TUPLE>::flushTable()
{

5
logstore.h
View file

@ -100,9 +100,6 @@ public:
void set_tree_c0_mergeable(memTreeComponent<datatuple>::rbtree_ptr_t newtree){tree_c0_mergeable = newtree; bump_epoch(); }
void update_persistent_header(int xid, int merge_level);
void setMergeData(logtable_mergedata * mdata);
logtable_mergedata* getMergeData(){return mergedata;}
inline tuplemerger * gettuplemerger(){return tmerger;}
public:
@ -118,8 +115,6 @@ public:
pageid_t c1_mergeable_size;
pageid_t c1_base_size;
};
logtable_mergedata * mergedata;
rwlc * header_mut;
pthread_mutex_t tick_mut;
pthread_mutex_t rb_mut;

6
mergeManager.cpp
View file

@ -23,13 +23,13 @@ mergeStats* mergeManager:: get_merge_stats(int mergeLevel) {
}
mergeManager::~mergeManager() {
delete c0;
delete c1;
delete c2;
still_running = false;
pthread_cond_signal(&pp_cond);
pthread_join(pp_thread, 0);
pthread_cond_destroy(&pp_cond);
delete c0;
delete c1;
delete c2;
}
void mergeManager::new_merge(int mergeLevel) {

4
mergeManager.h
View file

@ -64,16 +64,14 @@ public:
private:
logtable<datatuple>* ltable;
double throttle_seconds;
// double elapsed_seconds;
double last_throttle_seconds;
// double last_elapsed_seconds;
mergeStats * c0;
mergeStats * c1;
mergeStats * c2;
bool sleeping[3];
bool still_running;
// Needed so that the pretty print thread can be woken up during shutdown.
pthread_cond_t pp_cond;
pthread_t pp_thread;
};
#endif /* MERGEMANAGER_H_ */

9
mergeStats.h
View file

@ -46,17 +46,13 @@ class mergeStats {
lifetime_elapsed(0),
lifetime_consumed(0),
bps(10.0*1024.0*1024.0),
print_skipped(0),
active(false) {
gettimeofday(&sleep,0);
gettimeofday(&last,0);
mergeManager::double_to_ts(&last_tick, mergeManager::tv_to_double(&last));
mergeManager::double_to_ts(&last_mini_tick, mergeManager::tv_to_double(&last));
pthread_mutex_init(&mut,0);
}
~mergeStats() {
pthread_mutex_destroy(&mut);
}
~mergeStats() { }
void new_merge2() {
if(just_handed_off) {
bytes_out = 0;
@ -151,11 +147,8 @@ class mergeStats {
double bps;
int print_skipped; // used by pretty print in mergeManager.
bool active;
pthread_mutex_t mut; // protects things touched in tick(), and nothing else.
public:
void pretty_print(FILE* fd) {

250
merger.cpp
View file

@ -1,78 +1,29 @@
#include <math.h>
#include "merger.h"
#include <stasis/transactional.h>
#undef try
#undef end
int merge_scheduler::addlogtable(logtable<datatuple> *ltable)
{
struct logtable_mergedata * mdata = new logtable_mergedata;
// initialize merge data
ltable->set_tree_c0_mergeable(NULL);
mergedata.push_back(std::make_pair(ltable, mdata));
return mergedata.size()-1;
static void* memMerge_thr(void* arg) {
return ((merge_scheduler*)arg)->memMergeThread();
}
static void* diskMerge_thr(void* arg) {
return ((merge_scheduler*)arg)->diskMergeThread();
}
merge_scheduler::~merge_scheduler()
{
mergedata.clear();
merge_scheduler::merge_scheduler(logtable<datatuple> *ltable) : ltable_(ltable), MIN_R(3.0) { }
merge_scheduler::~merge_scheduler() { }
void merge_scheduler::shutdown() {
ltable_->stop();
pthread_join(mem_merge_thread_, 0);
pthread_join(disk_merge_thread_, 0);
}
void merge_scheduler::shutdown()
{
//signal shutdown
for(size_t i=0; i<mergedata.size(); i++)
{
logtable<datatuple> *ltable = mergedata[i].first;
ltable->stop();
}
for(size_t i=0; i<mergedata.size(); i++)
{
logtable_mergedata *mdata = mergedata[i].second;
pthread_join(mdata->memmerge_thread,0);
pthread_join(mdata->diskmerge_thread,0);
}
}
void merge_scheduler::startlogtable(int index, int64_t MAX_C0_SIZE)
{
logtable<datatuple> * ltable = mergedata[index].first;
struct logtable_mergedata *mdata = mergedata[index].second;
//initialize rb-tree
ltable->set_tree_c0(new memTreeComponent<datatuple>::rbtree_t);
//disk merger args
#ifdef NO_SNOWSHOVEL
ltable->set_max_c0_size(MAX_C0_SIZE);
#else
ltable->set_max_c0_size(MAX_C0_SIZE*2); // XXX blatant hack.
#endif
diskTreeComponent ** block1_scratch = new diskTreeComponent*;
*block1_scratch=0;
DEBUG("Tree C1 is %lld\n", (long long)ltable->get_tree_c1()->get_root_rec().page);
DEBUG("Tree C2 is %lld\n", (long long)ltable->get_tree_c2()->get_root_rec().page);
void * (*diskmerger)(void*) = diskMergeThread;
void * (*memmerger)(void*) = memMergeThread;
pthread_create(&mdata->diskmerge_thread, 0, diskmerger, ltable);
pthread_create(&mdata->memmerge_thread, 0, memmerger, ltable);
void merge_scheduler::start() {
pthread_create(&mem_merge_thread_, 0, memMerge_thr, this);
pthread_create(&disk_merge_thread_, 0, diskMerge_thr, this);
}
template <class ITA, class ITB>
@ -106,51 +57,49 @@ void merge_iterators(int xid, diskTreeComponent * forceMe,
</pre>
Merge algorithm: actual order: 1 2 3 4 5 6 12 11.5 11 [7 8 (9) 10] 13
*/
void* memMergeThread(void*arg)
{
void * merge_scheduler::memMergeThread() {
int xid;
logtable<datatuple> * ltable = (logtable<datatuple>*)arg;
assert(ltable->get_tree_c1());
assert(ltable_->get_tree_c1());
int merge_count =0;
mergeStats * stats = ltable->merge_mgr->get_merge_stats(1);
mergeStats * stats = ltable_->merge_mgr->get_merge_stats(1);
while(true) // 1
{
rwlc_writelock(ltable->header_mut);
ltable->merge_mgr->new_merge(1);
rwlc_writelock(ltable_->header_mut);
ltable_->merge_mgr->new_merge(1);
int done = 0;
// 2: wait for c0_mergable
#ifdef NO_SNOWSHOVEL
while(!ltable->get_tree_c0_mergeable())
while(!ltable_->get_tree_c0_mergeable())
{
pthread_cond_signal(&ltable->c0_needed);
pthread_cond_signal(&ltable_->c0_needed);
if(!ltable->is_still_running()){
if(!ltable_->is_still_running()){
done = 1;
break;
}
DEBUG("mmt:\twaiting for block ready cond\n");
rwlc_cond_wait(&ltable->c0_ready, ltable->header_mut);
rwlc_cond_wait(&ltable_->c0_ready, ltable_->header_mut);
DEBUG("mmt:\tblock ready\n");
}
#else
// the merge iterator will wait until c0 is big enough for us to proceed.
if(!ltable->is_still_running()) {
if(!ltable_->is_still_running()) {
done = 1;
}
#endif
if(done==1)
{
pthread_cond_signal(&ltable->c1_ready); // no block is ready. this allows the other thread to wake up, and see that we're shutting down.
rwlc_unlock(ltable->header_mut);
pthread_cond_signal(&ltable_->c1_ready); // no block is ready. this allows the other thread to wake up, and see that we're shutting down.
rwlc_unlock(ltable_->header_mut);
break;
}
@ -162,40 +111,40 @@ void* memMergeThread(void*arg)
// 4: Merge
//create the iterators
diskTreeComponent::iterator *itrA = ltable->get_tree_c1()->open_iterator();
diskTreeComponent::iterator *itrA = ltable_->get_tree_c1()->open_iterator();
#ifdef NO_SNOWSHOVEL
memTreeComponent<datatuple>::iterator *itrB =
new memTreeComponent<datatuple>::iterator(ltable->get_tree_c0_mergeable());
new memTreeComponent<datatuple>::iterator(ltable_->get_tree_c0_mergeable());
#else
// memTreeComponent<datatuple>::revalidatingIterator *itrB =
// new memTreeComponent<datatuple>::revalidatingIterator(ltable->get_tree_c0(), &ltable->rb_mut);
// new memTreeComponent<datatuple>::revalidatingIterator(ltable_->get_tree_c0(), &ltable_->rb_mut);
// memTreeComponent<datatuple>::batchedRevalidatingIterator *itrB =
// new memTreeComponent<datatuple>::batchedRevalidatingIterator(ltable->get_tree_c0(), &ltable->tree_bytes, ltable->max_c0_size, &ltable->flushing, 100, &ltable->rb_mut);
// new memTreeComponent<datatuple>::batchedRevalidatingIterator(ltable_->get_tree_c0(), &ltable_->tree_bytes, ltable_->max_c0_size, &ltable_->flushing, 100, &ltable_->rb_mut);
#endif
const int64_t min_bloom_target = ltable->max_c0_size;
const int64_t min_bloom_target = ltable_->max_c0_size;
//create a new tree
diskTreeComponent * c1_prime = new diskTreeComponent(xid, ltable->internal_region_size, ltable->datapage_region_size, ltable->datapage_size, stats, (stats->target_size < min_bloom_target ? min_bloom_target : stats->target_size) / 100);
diskTreeComponent * c1_prime = new diskTreeComponent(xid, ltable_->internal_region_size, ltable_->datapage_region_size, ltable_->datapage_size, stats, (stats->target_size < min_bloom_target ? min_bloom_target : stats->target_size) / 100);
ltable->set_tree_c1_prime(c1_prime);
ltable_->set_tree_c1_prime(c1_prime);
rwlc_unlock(ltable->header_mut);
rwlc_unlock(ltable_->header_mut);
#ifndef NO_SNOWSHOVEL
// needs to be past the rwlc_unlock...
memTreeComponent<datatuple>::batchedRevalidatingIterator *itrB =
new memTreeComponent<datatuple>::batchedRevalidatingIterator(ltable->get_tree_c0(), &ltable->tree_bytes, ltable->max_c0_size, &ltable->flushing, 100, &ltable->rb_mut);
new memTreeComponent<datatuple>::batchedRevalidatingIterator(ltable_->get_tree_c0(), &ltable_->tree_bytes, ltable_->max_c0_size, &ltable_->flushing, 100, &ltable_->rb_mut);
#endif
//: do the merge
DEBUG("mmt:\tMerging:\n");
merge_iterators<typeof(*itrA),typeof(*itrB)>(xid, c1_prime, itrA, itrB, ltable, c1_prime, stats, false);
merge_iterators<typeof(*itrA),typeof(*itrB)>(xid, c1_prime, itrA, itrB, ltable_, c1_prime, stats, false);
delete itrA;
delete itrB;
// 5: force c1'
rwlc_writelock(ltable->header_mut);
rwlc_writelock(ltable_->header_mut);
//force write the new tree to disk
c1_prime->force(xid);
@ -208,24 +157,24 @@ void* memMergeThread(void*arg)
// first, we need to move the c1' into c1.
// 12: delete old c1
ltable->get_tree_c1()->dealloc(xid);
delete ltable->get_tree_c1();
ltable_->get_tree_c1()->dealloc(xid);
delete ltable_->get_tree_c1();
// 10: c1 = c1'
ltable->set_tree_c1(c1_prime);
ltable->set_tree_c1_prime(0);
ltable_->set_tree_c1(c1_prime);
ltable_->set_tree_c1_prime(0);
#ifdef NO_SNOWSHOVEL
// 11.5: delete old c0_mergeable
memTreeComponent<datatuple>::tearDownTree(ltable->get_tree_c0_mergeable());
memTreeComponent<datatuple>::tearDownTree(ltable_->get_tree_c0_mergeable());
// 11: c0_mergeable = NULL
ltable->set_tree_c0_mergeable(NULL);
ltable_->set_tree_c0_mergeable(NULL);
#endif
ltable->set_c0_is_merging(false);
ltable_->set_c0_is_merging(false);
double new_c1_size = stats->output_size();
pthread_cond_signal(&ltable->c0_needed);
pthread_cond_signal(&ltable_->c0_needed);
ltable->update_persistent_header(xid, 1);
ltable_->update_persistent_header(xid, 1);
Tcommit(xid);
//TODO: this is simplistic for now
@ -233,28 +182,28 @@ void* memMergeThread(void*arg)
// update c0 effective size.
double frac = 1.0/(double)merge_count;
ltable->num_c0_mergers = merge_count;
ltable->mean_c0_effective_size =
ltable_->num_c0_mergers = merge_count;
ltable_->mean_c0_effective_size =
(int64_t) (
((double)ltable->mean_c0_effective_size)*(1-frac) +
((double)ltable_->mean_c0_effective_size)*(1-frac) +
((double)stats->bytes_in_small*frac));
ltable->merge_mgr->get_merge_stats(0)->target_size = ltable->mean_c0_effective_size;
double target_R = *ltable->R();
ltable_->merge_mgr->get_merge_stats(0)->target_size = ltable_->mean_c0_effective_size;
double target_R = *ltable_->R();
printf("Merge done. R = %f MemSize = %lld Mean = %lld, This = %lld, Count = %d factor %3.3fcur%3.3favg\n", target_R, (long long)ltable->max_c0_size, (long long int)ltable->mean_c0_effective_size, stats->bytes_in_small, merge_count, ((double)stats->bytes_in_small) / (double)ltable->max_c0_size, ((double)ltable->mean_c0_effective_size) / (double)ltable->max_c0_size);
printf("Merge done. R = %f MemSize = %lld Mean = %lld, This = %lld, Count = %d factor %3.3fcur%3.3favg\n", target_R, (long long)ltable_->max_c0_size, (long long int)ltable_->mean_c0_effective_size, stats->bytes_in_small, merge_count, ((double)stats->bytes_in_small) / (double)ltable_->max_c0_size, ((double)ltable_->mean_c0_effective_size) / (double)ltable_->max_c0_size);
assert(target_R >= MIN_R);
bool signal_c2 = (new_c1_size / ltable->mean_c0_effective_size > target_R);
bool signal_c2 = (new_c1_size / ltable_->mean_c0_effective_size > target_R);
DEBUG("\nc1 size %f R %f\n", new_c1_size, target_R);
if( signal_c2 )
{
DEBUG("mmt:\tsignaling C2 for merge\n");
DEBUG("mmt:\tnew_c1_size %.2f\tMAX_C0_SIZE %lld\ta->max_size %lld\t targetr %.2f \n", new_c1_size,
ltable->max_c0_size, a->max_size, target_R);
ltable_->max_c0_size, a->max_size, target_R);
// XXX need to report backpressure here!
while(ltable->get_tree_c1_mergeable()) {
rwlc_cond_wait(&ltable->c1_needed, ltable->header_mut);
while(ltable_->get_tree_c1_mergeable()) {
rwlc_cond_wait(&ltable_->c1_needed, ltable_->header_mut);
}
xid = Tbegin();
@ -262,27 +211,27 @@ void* memMergeThread(void*arg)
// we just set c1 = c1'. Want to move c1 -> c1 mergeable, clean out c1.
// 7: and perhaps c1_mergeable
ltable->set_tree_c1_mergeable(ltable->get_tree_c1()); // c1_prime == c1.
ltable_->set_tree_c1_mergeable(ltable_->get_tree_c1()); // c1_prime == c1.
stats->handed_off_tree();
// 8: c1 = new empty.
ltable->set_tree_c1(new diskTreeComponent(xid, ltable->internal_region_size, ltable->datapage_region_size, ltable->datapage_size, stats));
ltable_->set_tree_c1(new diskTreeComponent(xid, ltable_->internal_region_size, ltable_->datapage_region_size, ltable_->datapage_size, stats));
pthread_cond_signal(&ltable->c1_ready);
pthread_cond_signal(&ltable_->c1_ready);
pageid_t old_bytes_out = stats->bytes_out;
stats->bytes_out = 0; // XXX HACK
ltable->update_persistent_header(xid, 1);
ltable_->update_persistent_header(xid, 1);
stats->bytes_out = old_bytes_out;
Tcommit(xid);
}
// DEBUG("mmt:\tUpdated C1's position on disk to %lld\n",ltable->get_tree_c1()->get_root_rec().page);
// DEBUG("mmt:\tUpdated C1's position on disk to %lld\n",ltable_->get_tree_c1()->get_root_rec().page);
// 13
rwlc_unlock(ltable->header_mut);
rwlc_unlock(ltable_->header_mut);
ltable->merge_mgr->finished_merge(1);
ltable_->merge_mgr->finished_merge(1);
// stats->pretty_print(stdout);
//TODO: get the freeing outside of the lock
@ -293,43 +242,42 @@ void* memMergeThread(void*arg)
}
void *diskMergeThread(void*arg)
void * merge_scheduler::diskMergeThread()
{
int xid;
logtable<datatuple> * ltable = (logtable<datatuple>*)arg;
assert(ltable->get_tree_c2());
assert(ltable_->get_tree_c2());
int merge_count =0;
mergeStats * stats = ltable->merge_mgr->get_merge_stats(2);
mergeStats * stats = ltable_->merge_mgr->get_merge_stats(2);
while(true)
{
// 2: wait for input
rwlc_writelock(ltable->header_mut);
ltable->merge_mgr->new_merge(2);
rwlc_writelock(ltable_->header_mut);
ltable_->merge_mgr->new_merge(2);
int done = 0;
// get a new input for merge
while(!ltable->get_tree_c1_mergeable())
while(!ltable_->get_tree_c1_mergeable())
{
pthread_cond_signal(&ltable->c1_needed);
pthread_cond_signal(&ltable_->c1_needed);
if(!ltable->is_still_running()){
if(!ltable_->is_still_running()){
done = 1;
break;
}
DEBUG("dmt:\twaiting for block ready cond\n");
rwlc_cond_wait(&ltable->c1_ready, ltable->header_mut);
rwlc_cond_wait(&ltable_->c1_ready, ltable_->header_mut);
DEBUG("dmt:\tblock ready\n");
}
if(done==1)
{
rwlc_unlock(ltable->header_mut);
rwlc_unlock(ltable_->header_mut);
break;
}
@ -340,23 +288,23 @@ void *diskMergeThread(void*arg)
// 4: do the merge.
//create the iterators
diskTreeComponent::iterator *itrA = ltable->get_tree_c2()->open_iterator();
diskTreeComponent::iterator *itrA = ltable_->get_tree_c2()->open_iterator();
#ifdef NO_SNOWSHOVEL
diskTreeComponent::iterator *itrB = ltable->get_tree_c1_mergeable()->open_iterator();
diskTreeComponent::iterator *itrB = ltable_->get_tree_c1_mergeable()->open_iterator();
#else
diskTreeComponent::iterator *itrB = ltable->get_tree_c1_mergeable()->open_iterator(&ltable->merge_mgr->cur_c1_c2_progress_delta, 0.05, &ltable->shutting_down_);
diskTreeComponent::iterator *itrB = ltable_->get_tree_c1_mergeable()->open_iterator(&ltable_->merge_mgr->cur_c1_c2_progress_delta, 0.05, &ltable_->shutting_down_);
#endif
//create a new tree
diskTreeComponent * c2_prime = new diskTreeComponent(xid, ltable->internal_region_size, ltable->datapage_region_size, ltable->datapage_size, stats, (ltable->max_c0_size * *ltable->R() + stats->base_size)/ 1000);
// diskTreeComponent * c2_prime = new diskTreeComponent(xid, ltable->internal_region_size, ltable->datapage_region_size, ltable->datapage_size, stats);
diskTreeComponent * c2_prime = new diskTreeComponent(xid, ltable_->internal_region_size, ltable_->datapage_region_size, ltable_->datapage_size, stats, (ltable_->max_c0_size * *ltable_->R() + stats->base_size)/ 1000);
// diskTreeComponent * c2_prime = new diskTreeComponent(xid, ltable_->internal_region_size, ltable_->datapage_region_size, ltable_->datapage_size, stats);
rwlc_unlock(ltable->header_mut);
rwlc_unlock(ltable_->header_mut);
//do the merge
DEBUG("dmt:\tMerging:\n");
merge_iterators<typeof(*itrA),typeof(*itrB)>(xid, c2_prime, itrA, itrB, ltable, c2_prime, stats, true);
merge_iterators<typeof(*itrA),typeof(*itrB)>(xid, c2_prime, itrA, itrB, ltable_, c2_prime, stats, true);
delete itrA;
delete itrB;
@ -366,15 +314,15 @@ void *diskMergeThread(void*arg)
// (skip 6, 7, 8, 8.5, 9))
rwlc_writelock(ltable->header_mut);
rwlc_writelock(ltable_->header_mut);
//12
ltable->get_tree_c2()->dealloc(xid);
delete ltable->get_tree_c2();
ltable_->get_tree_c2()->dealloc(xid);
delete ltable_->get_tree_c2();
//11.5
ltable->get_tree_c1_mergeable()->dealloc(xid);
ltable_->get_tree_c1_mergeable()->dealloc(xid);
//11
delete ltable->get_tree_c1_mergeable();
ltable->set_tree_c1_mergeable(0);
delete ltable_->get_tree_c1_mergeable();
ltable_->set_tree_c1_mergeable(0);
//writes complete
//now atomically replace the old c2 with new c2
@ -382,23 +330,23 @@ void *diskMergeThread(void*arg)
merge_count++;
//update the current optimal R value
*(ltable->R()) = std::max(MIN_R, sqrt( ((double)stats->output_size()) / ((double)ltable->mean_c0_effective_size) ) );
*(ltable_->R()) = std::max(MIN_R, sqrt( ((double)stats->output_size()) / ((double)ltable_->mean_c0_effective_size) ) );
DEBUG("\nR = %f\n", *(ltable->R()));
DEBUG("\nR = %f\n", *(ltable_->R()));
DEBUG("dmt:\tmerge_count %lld\t#written bytes: %lld\n optimal r %.2f", stats.merge_count, stats.output_size(), *(a->r_i));
// 10: C2 is never too big
ltable->set_tree_c2(c2_prime);
ltable_->set_tree_c2(c2_prime);
stats->handed_off_tree();
DEBUG("dmt:\tUpdated C2's position on disk to %lld\n",(long long)-1);
// 13
ltable->update_persistent_header(xid, 2);
ltable_->update_persistent_header(xid, 2);
Tcommit(xid);
rwlc_unlock(ltable->header_mut);
rwlc_unlock(ltable_->header_mut);
// stats->pretty_print(stdout);
ltable->merge_mgr->finished_merge(2);
ltable_->merge_mgr->finished_merge(2);
}
@ -413,14 +361,14 @@ static void periodically_force(int xid, int *i, diskTreeComponent * forceMe, sta
}
}
static int garbage_collect(logtable<datatuple> * ltable, datatuple ** garbage, int garbage_len, int next_garbage, bool force = false) {
static int garbage_collect(logtable<datatuple> * ltable_, datatuple ** garbage, int garbage_len, int next_garbage, bool force = false) {
if(next_garbage == garbage_len || force) {
pthread_mutex_lock(&ltable->rb_mut);
pthread_mutex_lock(&ltable_->rb_mut);
for(int i = 0; i < next_garbage; i++) {
datatuple * t2tmp = NULL;
{
memTreeComponent<datatuple>::rbtree_t::iterator rbitr = ltable->get_tree_c0()->find(garbage[i]);
if(rbitr != ltable->get_tree_c0()->end()) {
memTreeComponent<datatuple>::rbtree_t::iterator rbitr = ltable_->get_tree_c0()->find(garbage[i]);
if(rbitr != ltable_->get_tree_c0()->end()) {
t2tmp = *rbitr;
if((t2tmp->datalen() == garbage[i]->datalen()) &&
!memcmp(t2tmp->data(), garbage[i]->data(), garbage[i]->datalen())) {
@ -431,13 +379,13 @@ static int garbage_collect(logtable<datatuple> * ltable, datatuple ** garbage, i
}
} // close rbitr before touching the tree.
if(t2tmp) {
ltable->get_tree_c0()->erase(garbage[i]);
ltable->tree_bytes -= garbage[i]->byte_length();
ltable_->get_tree_c0()->erase(garbage[i]);
ltable_->tree_bytes -= garbage[i]->byte_length();
datatuple::freetuple(t2tmp);
}
datatuple::freetuple(garbage[i]);
}
pthread_mutex_unlock(&ltable->rb_mut);
pthread_mutex_unlock(&ltable_->rb_mut);
return 0;
} else {
return next_garbage;

35
merger.h
View file

@ -8,33 +8,22 @@
#undef try
#undef end
//TODO: 400 bytes overhead per tuple, this is nuts, check if this is true...
static const int RB_TREE_OVERHEAD = 400;
static const double MIN_R = 3.0;
struct logtable_mergedata
{
//merge threads
pthread_t diskmerge_thread;
pthread_t memmerge_thread;
};
class merge_scheduler
{
std::vector<std::pair<logtable<datatuple> *, logtable_mergedata*> > mergedata;
class merge_scheduler {
public:
merge_scheduler(logtable<datatuple> * ltable);
~merge_scheduler();
int addlogtable(logtable<datatuple> * ltable);
void startlogtable(int index, int64_t MAX_C0_SIZE = 100*1024*1024);
struct logtable_mergedata *getMergeData(int index){return mergedata[index].second;}
void start();
void shutdown();
void * memMergeThread();
void * diskMergeThread();
private:
pthread_t mem_merge_thread_;
pthread_t disk_merge_thread_;
logtable<datatuple> * ltable_;
const double MIN_R;
};
void* memMergeThread(void* arg);
void* diskMergeThread(void* arg);
#endif

9
newserver.cpp
View file

@ -21,7 +21,6 @@ int main(int argc, char *argv[])
int xid = Tbegin();
merge_scheduler * mscheduler = new merge_scheduler;
logtable<datatuple> ltable;
@ -51,11 +50,9 @@ int main(int argc, char *argv[])
}
Tcommit(xid);
int lindex = mscheduler->addlogtable(&ltable);
ltable.setMergeData(mscheduler->getMergeData(lindex));
mscheduler->startlogtable(lindex, c0_size);
ltable.set_max_c0_size(c0_size);
merge_scheduler * mscheduler = new merge_scheduler(&ltable);
mscheduler->start();
simpleServer *lserver = new simpleServer(&ltable);

7
server.cpp
View file

@ -54,7 +54,6 @@ int main(int argc, char *argv[])
int xid = Tbegin();
mscheduler = new merge_scheduler;
logtable<datatuple> ltable;
@ -72,8 +71,6 @@ int main(int argc, char *argv[])
Tcommit(xid);
int lindex = mscheduler->addlogtable(&ltable);
ltable.setMergeData(mscheduler->getMergeData(lindex));
int64_t c0_size = 1024 * 1024 * 512 * 1;
@ -89,7 +86,9 @@ int main(int argc, char *argv[])
printf("note: running w/ 2GB c0 for benchmarking"); // XXX build a separate test server and deployment server?
}
mscheduler->startlogtable(lindex, c0_size);
ltable.set_max_c0_size(c0_size);
mscheduler = new merge_scheduler(&ltable);
mscheduler->start();
lserver = new logserver(100, 32432);

8
test/check_gen.cpp
View file

@ -18,21 +18,21 @@ int main(int argc, char **argv)
int xid = Tbegin();
logtable<datatuple> ltable(1000, 10000, 5);
logtable<datatuple> *ltable = new logtable<datatuple>(1000, 10000, 5);
recordid table_root = ltable.allocTable(xid);
recordid table_root = ltable->allocTable(xid);
Tcommit(xid);
xid = Tbegin();
RegionAllocator * ro_alloc = new RegionAllocator();
diskTreeComponent::internalNodes::iterator * it = new diskTreeComponent::internalNodes::iterator(xid,ro_alloc, ltable.get_tree_c2()->get_root_rid() );
diskTreeComponent::internalNodes::iterator * it = new diskTreeComponent::internalNodes::iterator(xid,ro_alloc, ltable->get_tree_c2()->get_root_rid() );
it->close();
delete it;
delete ro_alloc;
Tcommit(xid);
delete ltable;
logtable<datatuple>::deinit_stasis();

17
test/check_merge.cpp
View file

@ -50,17 +50,15 @@ void insertProbeIter(size_t NUM_ENTRIES)
int xid = Tbegin();
merge_scheduler mscheduler;
logtable<datatuple> ltable(1000, 10000, 5);
logtable<datatuple> * ltable = new logtable<datatuple>(1000, 10000, 5);
ltable->set_max_c0_size(10 * 1024 * 1024);
merge_scheduler mscheduler(ltable);
recordid table_root = ltable.allocTable(xid);
recordid table_root = ltable->allocTable(xid);
Tcommit(xid);
int lindex = mscheduler.addlogtable(&ltable);
ltable.setMergeData(mscheduler.getMergeData(lindex));
mscheduler.startlogtable(lindex, 10 * 1024 * 1024);
mscheduler.start();
printf("Stage 1: Writing %llu keys\n", (unsigned long long)NUM_ENTRIES);
@ -85,7 +83,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
datasize += newtuple->byte_length();
gettimeofday(&ti_st,0);
ltable.insertTuple(newtuple);
ltable->insertTuple(newtuple);
gettimeofday(&ti_end,0);
insert_time += tv_to_double(ti_end) - tv_to_double(ti_st);
@ -122,7 +120,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
//rkey[keylen-1]='\0';
//find the key with the given tuple
datatuple *dt = ltable.findTuple(xid, rkey, keylen);
datatuple *dt = ltable->findTuple(xid, rkey, keylen);
assert(dt!=0);
//if(dt!=0)
@ -150,6 +148,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
Tcommit(xid);
delete ltable;
logtable<datatuple>::deinit_stasis();
}

16
test/check_mergelarge.cpp
View file

@ -44,17 +44,15 @@ void insertProbeIter(size_t NUM_ENTRIES)
int xid = Tbegin();
merge_scheduler mscheduler;
logtable<datatuple> ltable(1000, 10000, 100);
logtable<datatuple> *ltable = new logtable<datatuple>(1000, 10000, 100);
ltable->set_max_c0_size(10*1024*1024);
merge_scheduler mscheduler(ltable);
recordid table_root = ltable.allocTable(xid);
recordid table_root = ltable->allocTable(xid);
Tcommit(xid);
int lindex = mscheduler.addlogtable(&ltable);
ltable.setMergeData(mscheduler.getMergeData(lindex));
mscheduler.startlogtable(lindex, 10 * 1024 * 1024);
mscheduler.start();
printf("Stage 1: Writing %llu keys\n", (unsigned long long)NUM_ENTRIES);
@ -75,7 +73,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
datasize += newtuple->byte_length();
gettimeofday(&ti_st,0);
ltable.insertTuple(newtuple);
ltable->insertTuple(newtuple);
gettimeofday(&ti_end,0);
insert_time += tv_to_double(ti_end) - tv_to_double(ti_st);
@ -90,10 +88,10 @@ void insertProbeIter(size_t NUM_ENTRIES)
printf("datasize: %llu\n", (unsigned long long)datasize);
mscheduler.shutdown();
delete ltable;
printf("merge threads finished.\n");
gettimeofday(&stop_tv,0);
printf("run time: %6.1f\n", (tv_to_double(stop_tv) - tv_to_double(start_tv)));
logtable<datatuple>::deinit_stasis();
}

20
test/check_mergetuple.cpp
View file

@ -102,16 +102,15 @@ void insertProbeIter(size_t NUM_ENTRIES)
int xid = Tbegin();
merge_scheduler mscheduler;
logtable<datatuple> ltable(1000, 1000, 40);
logtable<datatuple> *ltable = new logtable<datatuple>(1000, 1000, 40);
ltable->set_max_c0_size(10 * 1024 * 1024);
merge_scheduler mscheduler(ltable);
recordid table_root = ltable.allocTable(xid);
recordid table_root = ltable->allocTable(xid);
Tcommit(xid);
int lindex = mscheduler.addlogtable(&ltable);
ltable.setMergeData(mscheduler.getMergeData(lindex));
mscheduler.startlogtable(lindex, 10 * 1024 * 1024);
mscheduler.start();
printf("Stage 1: Writing %llu keys\n", (unsigned long long)NUM_ENTRIES);
@ -134,7 +133,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
datasize += newtuple->byte_length();
gettimeofday(&ti_st,0);
ltable.insertTuple(newtuple);
ltable->insertTuple(newtuple);
gettimeofday(&ti_end,0);
insert_time += tv_to_double(ti_end) - tv_to_double(ti_st);
@ -151,7 +150,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
datatuple *deltuple = datatuple::create((*key_arr)[del_index].c_str(), (*key_arr)[del_index].length()+1);
gettimeofday(&ti_st,0);
ltable.insertTuple(deltuple);
ltable->insertTuple(deltuple);
gettimeofday(&ti_end,0);
insert_time += tv_to_double(ti_end) - tv_to_double(ti_st);
@ -172,7 +171,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
datatuple *uptuple = datatuple::create((*key_arr)[up_index].c_str(), (*key_arr)[up_index].length()+1,
ditem.c_str(), ditem.length()+1);
gettimeofday(&ti_st,0);
ltable.insertTuple(uptuple);
ltable->insertTuple(uptuple);
gettimeofday(&ti_end,0);
insert_time += tv_to_double(ti_end) - tv_to_double(ti_st);
@ -207,7 +206,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
memcpy((byte*)rkey, (*key_arr)[ri].c_str(), keylen);
//find the key with the given tuple
datatuple *dt = ltable.findTuple(xid, rkey, keylen);
datatuple *dt = ltable->findTuple(xid, rkey, keylen);
if(std::find(del_list.begin(), del_list.end(), i) == del_list.end())
{
@ -248,6 +247,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
Tcommit(xid);
delete ltable;
logtable<datatuple>::deinit_stasis();
}

20
test/check_testAndSet.cpp
View file

@ -27,7 +27,8 @@
#define NUM_THREADS 128
unsigned char vals[NUM_THREADS];
logtable<datatuple>* ltbl;
logtable<datatuple> * ltable;
int myucharcmp(const void * ap, const void * bp) {
unsigned char a = *(unsigned char*)ap;
@ -43,7 +44,7 @@ void * worker(void * idp) {
printf("id = %d key = %d\n", (int)id, (int)key);
datatuple * dt = datatuple::create(&key, sizeof(key), &id, sizeof(id));
datatuple * dtdelete = datatuple::create(&key, sizeof(key));
succ = ltbl->testAndSetTuple(dt, dtdelete);
succ = ltable->testAndSetTuple(dt, dtdelete);
datatuple::freetuple(dt);
datatuple::freetuple(dtdelete);
vals[id] = key;
@ -60,18 +61,16 @@ void insertProbeIter(size_t NUM_ENTRIES)
logtable<datatuple>::init_stasis();
int xid = Tbegin();
merge_scheduler mscheduler;
logtable<datatuple> ltable(1000, 10000, 5);
ltbl = &ltable;
ltable = new logtable<datatuple>(1000, 10000, 5);
ltable->set_max_c0_size(10*1024*1024);
recordid table_root = ltable.allocTable(xid);
merge_scheduler mscheduler(ltable);
recordid table_root = ltable->allocTable(xid);
Tcommit(xid);
int lindex = mscheduler.addlogtable(&ltable);
ltable.setMergeData(mscheduler.getMergeData(lindex));
mscheduler.startlogtable(lindex, 10 * 1024 * 1024);
mscheduler.start();
pthread_t *threads = (pthread_t*)malloc(NUM_THREADS * sizeof(pthread_t));
@ -92,6 +91,7 @@ void insertProbeIter(size_t NUM_ENTRIES)
}
mscheduler.shutdown();
delete ltable;
logtable<datatuple>::deinit_stasis();
printf("\npass\n");