Commit cf17cd22 authored by jonas@perch.ndb.mysql.com's avatar jonas@perch.ndb.mysql.com

Merge perch.ndb.mysql.com:/home/jonas/src/51-telco-gca

into  perch.ndb.mysql.com:/home/jonas/src/51-ndb
parents 13298bd8 0b2c8fa3
...@@ -179,7 +179,8 @@ Dbtup::dealloc_tuple(Signal* signal, ...@@ -179,7 +179,8 @@ Dbtup::dealloc_tuple(Signal* signal,
&disk, tmpptr, gci); &disk, tmpptr, gci);
} }
if (! (bits & Tuple_header::LCP_SKIP) && lcpScan_ptr_i != RNIL) if (! (bits & (Tuple_header::LCP_SKIP | Tuple_header::ALLOC)) &&
lcpScan_ptr_i != RNIL)
{ {
ScanOpPtr scanOp; ScanOpPtr scanOp;
c_scanOpPool.getPtr(scanOp, lcpScan_ptr_i); c_scanOpPool.getPtr(scanOp, lcpScan_ptr_i);
......
...@@ -20,7 +20,7 @@ ...@@ -20,7 +20,7 @@
#include <NDBT.hpp> #include <NDBT.hpp>
#include <HugoCalculator.hpp> #include <HugoCalculator.hpp>
#include <HugoOperations.hpp> #include <HugoOperations.hpp>
class NDBT_Stats;
class HugoTransactions : public HugoOperations { class HugoTransactions : public HugoOperations {
public: public:
...@@ -109,10 +109,24 @@ public: ...@@ -109,10 +109,24 @@ public:
void setRetryMax(int retryMax = 100) { m_retryMax = retryMax; } void setRetryMax(int retryMax = 100) { m_retryMax = retryMax; }
Uint32 m_latest_gci; Uint32 m_latest_gci;
void setStatsLatency(NDBT_Stats* stats) { m_stats_latency = stats; }
// allows multiple threads to update separate batches
void setThrInfo(int thr_count, int thr_no) {
m_thr_count = thr_count;
m_thr_no = thr_no;
}
protected: protected:
NDBT_ResultRow row; NDBT_ResultRow row;
int m_defaultScanUpdateMethod; int m_defaultScanUpdateMethod;
int m_retryMax; int m_retryMax;
NDBT_Stats* m_stats_latency;
int m_thr_count; // 0 if no separation between threads
int m_thr_no;
}; };
......
/* Copyright (C) 2003 MySQL AB
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */
#ifndef NDB_THREAD_HPP
#define NDB_THREAD_HPP
#include <NdbMutex.h>
#include <NdbCondition.h>
#include <NdbThread.h>
// NDBT_Thread ctor -> NDBT_Thread_run -> thr.run()
extern "C" {
static void* NDBT_Thread_run(void* arg);
}
// Function to run in a thread.
typedef void NDBT_ThreadFunc(class NDBT_Thread&);
/*
* NDBT_Thread
*
* Represents a thread. The thread pauses at startup.
* Main process sets a function to run. When the function
* returns, the thread pauses again to wait for a command.
* This allows main process to sync with the thread and
* exchange data with it.
*
* Input to thread is typically options. The input area
* is read-only in the thread. Output from thread is
* results such as statistics. Error code is handled
* separately.
*
* Pointer to Ndb object and method to create it are
* provided for convenience.
*/
class NDBT_ThreadSet;
class NDBT_Thread {
public:
NDBT_Thread();
NDBT_Thread(NDBT_ThreadSet* thread_set, int thread_no);
void create(NDBT_ThreadSet* thread_set, int thread_no);
~NDBT_Thread();
// if part of a set
inline NDBT_ThreadSet& get_thread_set() const {
assert(m_thread_set != 0);
return *m_thread_set;
}
inline int get_thread_no() const {
return m_thread_no;
}
// { Wait -> Start -> Stop }+ -> Exit
enum State {
Wait = 1, // wait for command
Start, // run current function
Stop, // stopped (paused) when current function done
Exit // exit thread
};
// tell thread to start running current function
void start();
// wait for thread to stop when function is done
void stop();
// tell thread to exit
void exit();
// collect thread after exit
void join();
// set function to run
inline void set_func(NDBT_ThreadFunc* func) {
m_func = func;
}
// input area
inline void set_input(const void* input) {
m_input = input;
}
inline const void* get_input() const {
return m_input;
}
// output area
inline void set_output(void* output) {
m_output = output;
}
inline void* get_output() const {
return m_output;
}
template <class T> inline void set_output() {
set_output(new T);
}
inline void delete_output() {
delete m_output;
m_output = 0;
}
// thread-specific Ndb object
inline class Ndb* get_ndb() const {
return m_ndb;
}
int connect(class Ndb_cluster_connection*, const char* db = "TEST_DB");
void disconnect();
// error code (OS, Ndb, other)
void clear_err() {
m_err = 0;
}
void set_err(int err) {
m_err = err;
}
int get_err() const {
return m_err;
}
private:
friend class NDBT_ThreadSet;
friend void* NDBT_Thread_run(void* arg);
enum { Magic = 0xabacadae };
Uint32 m_magic;
State m_state;
NDBT_ThreadSet* m_thread_set;
int m_thread_no;
NDBT_ThreadFunc* m_func;
const void* m_input;
void* m_output;
class Ndb* m_ndb;
int m_err;
// run the thread
void run();
void lock() {
NdbMutex_Lock(m_mutex);
}
void unlock() {
NdbMutex_Unlock(m_mutex);
}
void wait() {
NdbCondition_Wait(m_cond, m_mutex);
}
void signal() {
NdbCondition_Signal(m_cond);
}
NdbMutex* m_mutex;
NdbCondition* m_cond;
NdbThread* m_thread;
void* m_status;
};
/*
* A set of threads, indexed from 0 to count-1. Methods
* are applied to each thread (serially). Input area is
* common to all threads. Output areas are allocated
* separately according to a template class.
*/
class NDBT_ThreadSet {
public:
NDBT_ThreadSet(int count);
~NDBT_ThreadSet();
inline int get_count() const {
return m_count;
}
inline NDBT_Thread& get_thread(int n) {
assert(n < m_count && m_thread[n] != 0);
return *m_thread[n];
}
// tell each thread to start running
void start();
// wait for each thread to stop
void stop();
// tell each thread to exit
void exit();
// collect each thread after exit
void join();
// set function to run in each thread
void set_func(NDBT_ThreadFunc* func);
// set input area (same instance in each thread)
void set_input(const void* input);
// set output areas
template <class T> inline void set_output() {
for (int n = 0; n < m_count; n++) {
NDBT_Thread& thr = *m_thread[n];
thr.set_output<T>();
}
}
void delete_output();
// thread-specific Ndb objects
int connect(class Ndb_cluster_connection*, const char* db = "TEST_DB");
void disconnect();
int get_err() const;
private:
int m_count;
NDBT_Thread** m_thread;
};
#endif
...@@ -14,8 +14,9 @@ ...@@ -14,8 +14,9 @@
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */
#include "HugoTransactions.hpp" #include "HugoTransactions.hpp"
#include <NDBT_Stats.hpp>
#include <NdbSleep.h> #include <NdbSleep.h>
#include <NdbTick.h>
HugoTransactions::HugoTransactions(const NdbDictionary::Table& _tab, HugoTransactions::HugoTransactions(const NdbDictionary::Table& _tab,
const NdbDictionary::Index* idx): const NdbDictionary::Index* idx):
...@@ -24,6 +25,10 @@ HugoTransactions::HugoTransactions(const NdbDictionary::Table& _tab, ...@@ -24,6 +25,10 @@ HugoTransactions::HugoTransactions(const NdbDictionary::Table& _tab,
m_defaultScanUpdateMethod = 3; m_defaultScanUpdateMethod = 3;
setRetryMax(); setRetryMax();
m_stats_latency = 0;
m_thr_count = 0;
m_thr_no = -1;
} }
HugoTransactions::~HugoTransactions(){ HugoTransactions::~HugoTransactions(){
...@@ -820,6 +825,16 @@ HugoTransactions::pkReadRecords(Ndb* pNdb, ...@@ -820,6 +825,16 @@ HugoTransactions::pkReadRecords(Ndb* pNdb,
return NDBT_FAILED; return NDBT_FAILED;
} }
MicroSecondTimer timer_start;
MicroSecondTimer timer_stop;
bool timer_active =
m_stats_latency != 0 &&
r >= batch && // first batch is "warmup"
r + batch != records; // last batch is usually partial
if (timer_active)
NdbTick_getMicroTimer(&timer_start);
if(pkReadRecord(pNdb, r, batch, lm) != NDBT_OK) if(pkReadRecord(pNdb, r, batch, lm) != NDBT_OK)
{ {
ERR(pTrans->getNdbError()); ERR(pTrans->getNdbError());
...@@ -892,6 +907,12 @@ HugoTransactions::pkReadRecords(Ndb* pNdb, ...@@ -892,6 +907,12 @@ HugoTransactions::pkReadRecords(Ndb* pNdb,
} }
closeTransaction(pNdb); closeTransaction(pNdb);
if (timer_active) {
NdbTick_getMicroTimer(&timer_stop);
NDB_TICKS ticks = NdbTick_getMicrosPassed(timer_start, timer_stop);
m_stats_latency->addObservation((double)ticks);
}
} }
deallocRows(); deallocRows();
g_info << reads << " records read" << endl; g_info << reads << " records read" << endl;
...@@ -913,9 +934,17 @@ HugoTransactions::pkUpdateRecords(Ndb* pNdb, ...@@ -913,9 +934,17 @@ HugoTransactions::pkUpdateRecords(Ndb* pNdb,
allocRows(batch); allocRows(batch);
g_info << "|- Updating records (batch=" << batch << ")..." << endl; g_info << "|- Updating records (batch=" << batch << ")..." << endl;
int batch_no = 0;
while (r < records){ while (r < records){
if(r + batch > records) if(r + batch > records)
batch = records - r; batch = records - r;
if (m_thr_count != 0 && m_thr_no != batch_no % m_thr_count)
{
r += batch;
batch_no++;
continue;
}
if (retryAttempt >= m_retryMax){ if (retryAttempt >= m_retryMax){
g_info << "ERROR: has retried this operation " << retryAttempt g_info << "ERROR: has retried this operation " << retryAttempt
...@@ -963,6 +992,16 @@ HugoTransactions::pkUpdateRecords(Ndb* pNdb, ...@@ -963,6 +992,16 @@ HugoTransactions::pkUpdateRecords(Ndb* pNdb,
return NDBT_FAILED; return NDBT_FAILED;
} }
MicroSecondTimer timer_start;
MicroSecondTimer timer_stop;
bool timer_active =
m_stats_latency != 0 &&
r >= batch && // first batch is "warmup"
r + batch != records; // last batch is usually partial
if (timer_active)
NdbTick_getMicroTimer(&timer_start);
if(pIndexScanOp) if(pIndexScanOp)
{ {
int rows_found = 0; int rows_found = 0;
...@@ -1039,8 +1078,15 @@ HugoTransactions::pkUpdateRecords(Ndb* pNdb, ...@@ -1039,8 +1078,15 @@ HugoTransactions::pkUpdateRecords(Ndb* pNdb,
} }
closeTransaction(pNdb); closeTransaction(pNdb);
if (timer_active) {
NdbTick_getMicroTimer(&timer_stop);
NDB_TICKS ticks = NdbTick_getMicrosPassed(timer_start, timer_stop);
m_stats_latency->addObservation((double)ticks);
}
r += batch; // Read next record r += batch; // Read next record
batch_no++;
} }
deallocRows(); deallocRows();
...@@ -1228,10 +1274,18 @@ HugoTransactions::pkDelRecords(Ndb* pNdb, ...@@ -1228,10 +1274,18 @@ HugoTransactions::pkDelRecords(Ndb* pNdb,
int check; int check;
g_info << "|- Deleting records..." << endl; g_info << "|- Deleting records..." << endl;
int batch_no = 0;
while (r < records){ while (r < records){
if(r + batch > records) if(r + batch > records)
batch = records - r; batch = records - r;
if (m_thr_count != 0 && m_thr_no != batch_no % m_thr_count)
{
r += batch;
batch_no++;
continue;
}
if (retryAttempt >= m_retryMax){ if (retryAttempt >= m_retryMax){
g_info << "ERROR: has retried this operation " << retryAttempt g_info << "ERROR: has retried this operation " << retryAttempt
<< " times, failing!" << endl; << " times, failing!" << endl;
...@@ -1255,6 +1309,16 @@ HugoTransactions::pkDelRecords(Ndb* pNdb, ...@@ -1255,6 +1309,16 @@ HugoTransactions::pkDelRecords(Ndb* pNdb,
return NDBT_FAILED; return NDBT_FAILED;
} }
MicroSecondTimer timer_start;
MicroSecondTimer timer_stop;
bool timer_active =
m_stats_latency != 0 &&
r >= batch && // first batch is "warmup"
r + batch != records; // last batch is usually partial
if (timer_active)
NdbTick_getMicroTimer(&timer_start);
if(pkDeleteRecord(pNdb, r, batch) != NDBT_OK) if(pkDeleteRecord(pNdb, r, batch) != NDBT_OK)
{ {
ERR(pTrans->getNdbError()); ERR(pTrans->getNdbError());
...@@ -1303,9 +1367,15 @@ HugoTransactions::pkDelRecords(Ndb* pNdb, ...@@ -1303,9 +1367,15 @@ HugoTransactions::pkDelRecords(Ndb* pNdb,
m_latest_gci = pTrans->getGCI(); m_latest_gci = pTrans->getGCI();
} }
closeTransaction(pNdb); closeTransaction(pNdb);
r += batch; // Read next record
if (timer_active) {
NdbTick_getMicroTimer(&timer_stop);
NDB_TICKS ticks = NdbTick_getMicrosPassed(timer_start, timer_stop);
m_stats_latency->addObservation((double)ticks);
}
r += batch; // Read next record
batch_no++;
} }
g_info << "|- " << deleted << " records deleted" << endl; g_info << "|- " << deleted << " records deleted" << endl;
......
...@@ -24,7 +24,7 @@ libNDBT_a_SOURCES = \ ...@@ -24,7 +24,7 @@ libNDBT_a_SOURCES = \
NdbRestarter.cpp NdbRestarts.cpp NDBT_Output.cpp \ NdbRestarter.cpp NdbRestarts.cpp NDBT_Output.cpp \
NdbBackup.cpp NdbConfig.cpp NdbGrep.cpp NDBT_Table.cpp \ NdbBackup.cpp NdbConfig.cpp NdbGrep.cpp NDBT_Table.cpp \
NdbSchemaCon.cpp NdbSchemaOp.cpp getarg.c \ NdbSchemaCon.cpp NdbSchemaOp.cpp getarg.c \
CpcClient.cpp NdbMixRestarter.cpp CpcClient.cpp NdbMixRestarter.cpp NDBT_Thread.cpp
INCLUDES_LOC = -I$(top_srcdir)/storage/ndb/src/common/mgmcommon -I$(top_srcdir)/storage/ndb/include/mgmcommon -I$(top_srcdir)/storage/ndb/include/kernel -I$(top_srcdir)/storage/ndb/src/mgmapi INCLUDES_LOC = -I$(top_srcdir)/storage/ndb/src/common/mgmcommon -I$(top_srcdir)/storage/ndb/include/mgmcommon -I$(top_srcdir)/storage/ndb/include/kernel -I$(top_srcdir)/storage/ndb/src/mgmapi
......
/* Copyright (C) 2003 MySQL AB
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */
#include <ndb_global.h>
#include <NDBT_Thread.hpp>
#include <NdbApi.hpp>
NDBT_Thread::NDBT_Thread()
{
create(0, -1);
}
NDBT_Thread::NDBT_Thread(NDBT_ThreadSet* thread_set, int thread_no)
{
create(thread_set, thread_no);
}
void
NDBT_Thread::create(NDBT_ThreadSet* thread_set, int thread_no)
{
m_magic = NDBT_Thread::Magic;
m_state = Wait;
m_thread_set = thread_set;
m_thread_no = thread_no;
m_func = 0;
m_input = 0;
m_output = 0;
m_ndb = 0;
m_err = 0;
m_mutex = NdbMutex_Create();
assert(m_mutex != 0);
m_cond = NdbCondition_Create();
assert(m_cond != 0);
char buf[20];
sprintf(buf, "NDBT_%04u");
const char* name = strdup(buf);
assert(name != 0);
unsigned stacksize = 512 * 1024;
NDB_THREAD_PRIO prio = NDB_THREAD_PRIO_LOW;
m_thread = NdbThread_Create(NDBT_Thread_run,
(void**)this, stacksize, name, prio);
assert(m_thread != 0);
}
NDBT_Thread::~NDBT_Thread()
{
if (m_thread != 0) {
NdbThread_Destroy(&m_thread);
m_thread = 0;
}
if (m_cond != 0) {
NdbCondition_Destroy(m_cond);
m_cond = 0;
}
if (m_mutex != 0) {
NdbMutex_Destroy(m_mutex);
m_mutex = 0;
}
}
static void*
NDBT_Thread_run(void* arg)
{
assert(arg != 0);
NDBT_Thread& thr = *(NDBT_Thread*)arg;
assert(thr.m_magic == NDBT_Thread::Magic);
thr.run();
return 0;
}
void
NDBT_Thread::run()
{
while (1) {
lock();
while (m_state != Start && m_state != Exit) {
wait();
}
if (m_state == Exit) {
unlock();
break;
}
(*m_func)(*this);
m_state = Stop;
signal();
unlock();
}
}
// methods for main process
void
NDBT_Thread::start()
{
lock();
m_state = Start;
signal();
unlock();
}
void
NDBT_Thread::stop()
{
lock();
while (m_state != Stop)
wait();
m_state = Wait;
unlock();
}
void
NDBT_Thread::exit()
{
lock();
m_state = Exit;
signal();
unlock();
};
void
NDBT_Thread::join()
{
NdbThread_WaitFor(m_thread, &m_status);
m_thread = 0;
}
int
NDBT_Thread::connect(class Ndb_cluster_connection* ncc, const char* db)
{
m_ndb = new Ndb(ncc, db);
if (m_ndb->init() == -1 ||
m_ndb->waitUntilReady() == -1) {
m_err = m_ndb->getNdbError().code;
return -1;
}
return 0;
}
void
NDBT_Thread::disconnect()
{
delete m_ndb;
m_ndb = 0;
}
// set of threads
NDBT_ThreadSet::NDBT_ThreadSet(int count)
{
m_count = count;
m_thread = new NDBT_Thread* [count];
for (int n = 0; n < count; n++) {
m_thread[n] = new NDBT_Thread(this, n);
}
}
NDBT_ThreadSet::~NDBT_ThreadSet()
{
delete_output();
for (int n = 0; n < m_count; n++) {
delete m_thread[n];
m_thread[n] = 0;
}
delete [] m_thread;
}
void
NDBT_ThreadSet::start()
{
for (int n = 0; n < m_count; n++) {
NDBT_Thread& thr = *m_thread[n];
thr.start();
}
}
void
NDBT_ThreadSet::stop()
{
for (int n = 0; n < m_count; n++) {
NDBT_Thread& thr = *m_thread[n];
thr.stop();
}
}
void
NDBT_ThreadSet::exit()
{
for (int n = 0; n < m_count; n++) {
NDBT_Thread& thr = *m_thread[n];
thr.exit();
}
}
void
NDBT_ThreadSet::join()
{
for (int n = 0; n < m_count; n++) {
NDBT_Thread& thr = *m_thread[n];
thr.join();
}
}
void
NDBT_ThreadSet::set_func(NDBT_ThreadFunc* func)
{
for (int n = 0; n < m_count; n++) {
NDBT_Thread& thr = *m_thread[n];
thr.set_func(func);
}
}
void
NDBT_ThreadSet::set_input(const void* input)
{
for (int n = 0; n < m_count; n++) {
NDBT_Thread& thr = *m_thread[n];
thr.set_input(input);
}
}
void
NDBT_ThreadSet::delete_output()
{
for (int n = 0; n < m_count; n++) {
if (m_thread[n] != 0) {
NDBT_Thread& thr = *m_thread[n];
thr.delete_output();
}
}
}
int
NDBT_ThreadSet::connect(class Ndb_cluster_connection* ncc, const char* db)
{
for (int n = 0; n < m_count; n++) {
assert(m_thread[n] != 0);
NDBT_Thread& thr = *m_thread[n];
if (thr.connect(ncc, db) == -1)
return -1;
}
return 0;
}
void
NDBT_ThreadSet::disconnect()
{
for (int n = 0; n < m_count; n++) {
if (m_thread[n] != 0) {
NDBT_Thread& thr = *m_thread[n];
thr.disconnect();
}
}
}
int
NDBT_ThreadSet::get_err() const
{
for (int n = 0; n < m_count; n++) {
if (m_thread[n] != 0) {
NDBT_Thread& thr = *m_thread[n];
int err = thr.get_err();
if (err != 0)
return err;
}
}
return 0;
}
...@@ -20,22 +20,41 @@ ...@@ -20,22 +20,41 @@
#include <NdbApi.hpp> #include <NdbApi.hpp>
#include <NdbMain.h> #include <NdbMain.h>
#include <NDBT.hpp> #include <NDBT.hpp>
#include <NDBT_Thread.hpp>
#include <NDBT_Stats.hpp>
#include <NdbSleep.h> #include <NdbSleep.h>
#include <getarg.h> #include <getarg.h>
#include <HugoTransactions.hpp> #include <HugoTransactions.hpp>
static NDBT_ThreadFunc hugoPkDelete;
struct ThrInput {
const NdbDictionary::Table* pTab;
int records;
int batch;
int stats;
};
struct ThrOutput {
NDBT_Stats latency;
};
int main(int argc, const char** argv){ int main(int argc, const char** argv){
ndb_init(); ndb_init();
int _records = 0; int _records = 0;
int _loops = 1; int _loops = 1;
int _batch = 0; int _threads = 1;
int _stats = 0;
int _batch = 1;
const char* _tabname = NULL; const char* _tabname = NULL;
int _help = 0; int _help = 0;
struct getargs args[] = { struct getargs args[] = {
{ "loops", 'l', arg_integer, &_loops, "number of times to run this program(0=infinite loop)", "loops" }, { "loops", 'l', arg_integer, &_loops, "number of times to run this program(0=infinite loop)", "loops" },
{ "threads", 't', arg_integer, &_threads, "number of threads (default 1)", "threads" },
{ "stats", 's', arg_flag, &_stats, "report latency per batch", "stats" },
// { "batch", 'b', arg_integer, &_batch, "batch value", "batch" }, // { "batch", 'b', arg_integer, &_batch, "batch value", "batch" },
{ "records", 'r', arg_integer, &_records, "Number of records", "records" }, { "records", 'r', arg_integer, &_records, "Number of records", "records" },
{ "usage", '?', arg_flag, &_help, "Print help", "" } { "usage", '?', arg_flag, &_help, "Print help", "" }
...@@ -81,12 +100,57 @@ int main(int argc, const char** argv){ ...@@ -81,12 +100,57 @@ int main(int argc, const char** argv){
return NDBT_ProgramExit(NDBT_WRONGARGS); return NDBT_ProgramExit(NDBT_WRONGARGS);
} }
HugoTransactions hugoTrans(*pTab); // threads
NDBT_ThreadSet ths(_threads);
// create Ndb object for each thread
if (ths.connect(&con, "TEST_DB") == -1) {
ndbout << "connect failed: err=" << ths.get_err() << endl;
return NDBT_ProgramExit(NDBT_FAILED);
}
// input is options
ThrInput input;
ths.set_input(&input);
input.pTab = pTab;
input.records = _records;
input.batch = _batch;
input.stats = _stats;
// output is stats
ThrOutput output;
ths.set_output<ThrOutput>();
int i = 0; int i = 0;
while (i<_loops || _loops==0) { while (i < _loops || _loops == 0) {
ndbout << i << ": "; ndbout << i << ": ";
if (hugoTrans.pkDelRecords(&MyNdb, _records) != 0){
return NDBT_ProgramExit(NDBT_FAILED); ths.set_func(hugoPkDelete);
ths.start();
ths.stop();
if (ths.get_err())
NDBT_ProgramExit(NDBT_FAILED);
if (_stats) {
NDBT_Stats latency;
// add stats from each thread
int n;
for (n = 0; n < ths.get_count(); n++) {
NDBT_Thread& thr = ths.get_thread(n);
ThrOutput* output = (ThrOutput*)thr.get_output();
latency += output->latency;
}
ndbout
<< "latency per batch (us): "
<< " samples=" << latency.getCount()
<< " min=" << (int)latency.getMin()
<< " max=" << (int)latency.getMax()
<< " mean=" << (int)latency.getMean()
<< " stddev=" << (int)latency.getStddev()
<< endl;
} }
i++; i++;
} }
...@@ -94,3 +158,23 @@ int main(int argc, const char** argv){ ...@@ -94,3 +158,23 @@ int main(int argc, const char** argv){
return NDBT_ProgramExit(NDBT_OK); return NDBT_ProgramExit(NDBT_OK);
} }
static void hugoPkDelete(NDBT_Thread& thr)
{
const ThrInput* input = (const ThrInput*)thr.get_input();
ThrOutput* output = (ThrOutput*)thr.get_output();
HugoTransactions hugoTrans(*input->pTab);
output->latency.reset();
if (input->stats)
hugoTrans.setStatsLatency(&output->latency);
NDBT_ThreadSet& ths = thr.get_thread_set();
hugoTrans.setThrInfo(ths.get_count(), thr.get_thread_no());
int ret;
ret = hugoTrans.pkDelRecords(thr.get_ndb(),
input->records,
input->batch);
if (ret != 0)
thr.set_err(ret);
}
...@@ -20,17 +20,33 @@ ...@@ -20,17 +20,33 @@
#include <NdbApi.hpp> #include <NdbApi.hpp>
#include <NdbMain.h> #include <NdbMain.h>
#include <NDBT.hpp> #include <NDBT.hpp>
#include <NDBT_Thread.hpp>
#include <NDBT_Stats.hpp>
#include <NdbSleep.h> #include <NdbSleep.h>
#include <getarg.h> #include <getarg.h>
#include <HugoTransactions.hpp> #include <HugoTransactions.hpp>
static NDBT_ThreadFunc hugoPkRead;
struct ThrInput {
const NdbDictionary::Table* pTab;
int records;
int batch;
int stats;
};
struct ThrOutput {
NDBT_Stats latency;
};
int main(int argc, const char** argv){ int main(int argc, const char** argv){
ndb_init(); ndb_init();
int _records = 0; int _records = 0;
int _loops = 1; int _loops = 1;
int _threads = 1;
int _stats = 0;
int _abort = 0; int _abort = 0;
int _batch = 1; int _batch = 1;
const char* _tabname = NULL; const char* _tabname = NULL;
...@@ -39,6 +55,8 @@ int main(int argc, const char** argv){ ...@@ -39,6 +55,8 @@ int main(int argc, const char** argv){
struct getargs args[] = { struct getargs args[] = {
{ "aborts", 'a', arg_integer, &_abort, "percent of transactions that are aborted", "abort%" }, { "aborts", 'a', arg_integer, &_abort, "percent of transactions that are aborted", "abort%" },
{ "loops", 'l', arg_integer, &_loops, "number of times to run this program(0=infinite loop)", "loops" }, { "loops", 'l', arg_integer, &_loops, "number of times to run this program(0=infinite loop)", "loops" },
{ "threads", 't', arg_integer, &_threads, "number of threads (default 1)", "threads" },
{ "stats", 's', arg_flag, &_stats, "report latency per batch", "stats" },
{ "batch", 'b', arg_integer, &_batch, "batch value(not 0)", "batch" }, { "batch", 'b', arg_integer, &_batch, "batch value(not 0)", "batch" },
{ "records", 'r', arg_integer, &_records, "Number of records", "records" }, { "records", 'r', arg_integer, &_records, "Number of records", "records" },
{ "usage", '?', arg_flag, &_help, "Print help", "" } { "usage", '?', arg_flag, &_help, "Print help", "" }
...@@ -64,6 +82,7 @@ int main(int argc, const char** argv){ ...@@ -64,6 +82,7 @@ int main(int argc, const char** argv){
{ {
return NDBT_ProgramExit(NDBT_FAILED); return NDBT_ProgramExit(NDBT_FAILED);
} }
Ndb MyNdb(&con, "TEST_DB" ); Ndb MyNdb(&con, "TEST_DB" );
if(MyNdb.init() != 0){ if(MyNdb.init() != 0){
...@@ -81,12 +100,57 @@ int main(int argc, const char** argv){ ...@@ -81,12 +100,57 @@ int main(int argc, const char** argv){
return NDBT_ProgramExit(NDBT_WRONGARGS); return NDBT_ProgramExit(NDBT_WRONGARGS);
} }
HugoTransactions hugoTrans(*pTab); // threads
NDBT_ThreadSet ths(_threads);
// create Ndb object for each thread
if (ths.connect(&con, "TEST_DB") == -1) {
ndbout << "connect failed: err=" << ths.get_err() << endl;
return NDBT_ProgramExit(NDBT_FAILED);
}
// input is options
ThrInput input;
ths.set_input(&input);
input.pTab = pTab;
input.records = _records;
input.batch = _batch;
input.stats = _stats;
// output is stats
ThrOutput output;
ths.set_output<ThrOutput>();
int i = 0; int i = 0;
while (i<_loops || _loops==0) { while (i < _loops || _loops == 0) {
ndbout << i << ": "; ndbout << i << ": ";
if (hugoTrans.pkReadRecords(&MyNdb, _records, _batch) != 0){
return NDBT_ProgramExit(NDBT_FAILED); ths.set_func(hugoPkRead);
ths.start();
ths.stop();
if (ths.get_err())
NDBT_ProgramExit(NDBT_FAILED);
if (_stats) {
NDBT_Stats latency;
// add stats from each thread
int n;
for (n = 0; n < ths.get_count(); n++) {
NDBT_Thread& thr = ths.get_thread(n);
ThrOutput* output = (ThrOutput*)thr.get_output();
latency += output->latency;
}
ndbout
<< "latency per batch (us): "
<< " samples=" << latency.getCount()
<< " min=" << (int)latency.getMin()
<< " max=" << (int)latency.getMax()
<< " mean=" << (int)latency.getMean()
<< " stddev=" << (int)latency.getStddev()
<< endl;
} }
i++; i++;
} }
...@@ -94,3 +158,20 @@ int main(int argc, const char** argv){ ...@@ -94,3 +158,20 @@ int main(int argc, const char** argv){
return NDBT_ProgramExit(NDBT_OK); return NDBT_ProgramExit(NDBT_OK);
} }
static void hugoPkRead(NDBT_Thread& thr)
{
const ThrInput* input = (const ThrInput*)thr.get_input();
ThrOutput* output = (ThrOutput*)thr.get_output();
HugoTransactions hugoTrans(*input->pTab);
output->latency.reset();
if (input->stats)
hugoTrans.setStatsLatency(&output->latency);
int ret;
ret = hugoTrans.pkReadRecords(thr.get_ndb(),
input->records,
input->batch);
if (ret != 0)
thr.set_err(ret);
}
...@@ -20,24 +20,43 @@ ...@@ -20,24 +20,43 @@
#include <NdbApi.hpp> #include <NdbApi.hpp>
#include <NdbMain.h> #include <NdbMain.h>
#include <NDBT.hpp> #include <NDBT.hpp>
#include <NDBT_Thread.hpp>
#include <NDBT_Stats.hpp>
#include <NdbSleep.h> #include <NdbSleep.h>
#include <getarg.h> #include <getarg.h>
#include <HugoTransactions.hpp> #include <HugoTransactions.hpp>
static NDBT_ThreadFunc hugoPkUpdate;
struct ThrInput {
const NdbDictionary::Table* pTab;
int records;
int batch;
int stats;
};
struct ThrOutput {
NDBT_Stats latency;
};
int main(int argc, const char** argv){ int main(int argc, const char** argv){
ndb_init(); ndb_init();
int _records = 0; int _records = 0;
int _loops = 1; int _loops = 1;
int _threads = 1;
int _stats = 0;
int _abort = 0; int _abort = 0;
int _batch = 0; int _batch = 1;
const char* _tabname = NULL, *db = 0; const char* _tabname = NULL, *db = 0;
int _help = 0; int _help = 0;
struct getargs args[] = { struct getargs args[] = {
{ "aborts", 'a', arg_integer, &_abort, "percent of transactions that are aborted", "abort%" }, { "aborts", 'a', arg_integer, &_abort, "percent of transactions that are aborted", "abort%" },
{ "loops", 'l', arg_integer, &_loops, "number of times to run this program(0=infinite loop)", "loops" }, { "loops", 'l', arg_integer, &_loops, "number of times to run this program(0=infinite loop)", "loops" },
{ "threads", 't', arg_integer, &_threads, "number of threads (default 1)", "threads" },
{ "stats", 's', arg_flag, &_stats, "report latency per batch", "stats" },
// { "batch", 'b', arg_integer, &_batch, "batch value", "batch" }, // { "batch", 'b', arg_integer, &_batch, "batch value", "batch" },
{ "records", 'r', arg_integer, &_records, "Number of records", "records" }, { "records", 'r', arg_integer, &_records, "Number of records", "records" },
{ "usage", '?', arg_flag, &_help, "Print help", "" }, { "usage", '?', arg_flag, &_help, "Print help", "" },
...@@ -83,16 +102,81 @@ int main(int argc, const char** argv){ ...@@ -83,16 +102,81 @@ int main(int argc, const char** argv){
return NDBT_ProgramExit(NDBT_WRONGARGS); return NDBT_ProgramExit(NDBT_WRONGARGS);
} }
HugoTransactions hugoTrans(*pTab); // threads
NDBT_ThreadSet ths(_threads);
// create Ndb object for each thread
if (ths.connect(&con, "TEST_DB") == -1) {
ndbout << "connect failed: err=" << ths.get_err() << endl;
return NDBT_ProgramExit(NDBT_FAILED);
}
// input is options
ThrInput input;
ths.set_input(&input);
input.pTab = pTab;
input.records = _records;
input.batch = _batch;
input.stats = _stats;
// output is stats
ThrOutput output;
ths.set_output<ThrOutput>();
int i = 0; int i = 0;
while (i<_loops || _loops==0) { while (i < _loops || _loops == 0) {
ndbout << "loop " << i << ": "; ndbout << i << ": ";
if (hugoTrans.pkUpdateRecords(&MyNdb,
_records) != 0){ ths.set_func(hugoPkUpdate);
return NDBT_ProgramExit(NDBT_FAILED); ths.start();
ths.stop();
if (ths.get_err())
NDBT_ProgramExit(NDBT_FAILED);
if (_stats) {
NDBT_Stats latency;
// add stats from each thread
int n;
for (n = 0; n < ths.get_count(); n++) {
NDBT_Thread& thr = ths.get_thread(n);
ThrOutput* output = (ThrOutput*)thr.get_output();
latency += output->latency;
}
ndbout
<< "latency per batch (us): "
<< " samples=" << latency.getCount()
<< " min=" << (int)latency.getMin()
<< " max=" << (int)latency.getMax()
<< " mean=" << (int)latency.getMean()
<< " stddev=" << (int)latency.getStddev()
<< endl;
} }
i++; i++;
} }
return NDBT_ProgramExit(NDBT_OK); return NDBT_ProgramExit(NDBT_OK);
} }
static void hugoPkUpdate(NDBT_Thread& thr)
{
const ThrInput* input = (const ThrInput*)thr.get_input();
ThrOutput* output = (ThrOutput*)thr.get_output();
HugoTransactions hugoTrans(*input->pTab);
output->latency.reset();
if (input->stats)
hugoTrans.setStatsLatency(&output->latency);
NDBT_ThreadSet& ths = thr.get_thread_set();
hugoTrans.setThrInfo(ths.get_count(), thr.get_thread_no());
int ret;
ret = hugoTrans.pkUpdateRecords(thr.get_ndb(),
input->records,
input->batch);
if (ret != 0)
thr.set_err(ret);
}
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