stasis-bLSM/logserver.cpp

630 lines
19 KiB
C++
Raw Normal View History

#include "logserver.h"
#include "datatuple.h"
#include "logstore.h"
#include <sys/types.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <netinet/tcp.h>
#include <arpa/inet.h>
#include <sys/select.h>
#include <errno.h>
#undef begin
#undef end
#undef try
//server codes
uint8_t logserver::OP_SUCCESS = 1;
uint8_t logserver::OP_FAIL = 2;
uint8_t logserver::OP_SENDING_TUPLE = 3;
//client codes
uint8_t logserver::OP_FIND = 4;
uint8_t logserver::OP_INSERT = 5;
uint8_t logserver::OP_DONE = 6;
uint8_t logserver::OP_INVALID = 32;
void *serverLoop(void *args);
void logserver::startserver(logtable *ltable)
{
sys_alive = true;
this->ltable = ltable;
selcond = new pthread_cond_t;
pthread_cond_init(selcond, 0);
//initialize threads
for(int i=0; i<nthreads; i++)
{
struct pthread_item *worker_th = new pthread_item;
th_list.push_back(worker_th);
worker_th->th_handle = new pthread_t;
struct pthread_data *worker_data = new pthread_data;
worker_th->data = worker_data;
worker_data->idleth_queue = &idleth_queue;
worker_data->ready_queue = &ready_queue;
worker_data->work_queue = &work_queue;
worker_data->qlock = qlock;
worker_data->selcond = selcond;
worker_data->th_cond = new pthread_cond_t;
pthread_cond_init(worker_data->th_cond,0);
worker_data->th_mut = new pthread_mutex_t;
pthread_mutex_init(worker_data->th_mut,0);
worker_data->workitem = new int;
*(worker_data->workitem) = -1;
//worker_data->table_lock = lsmlock;
worker_data->ltable = ltable;
worker_data->sys_alive = &sys_alive;
pthread_create(worker_th->th_handle, 0, thread_work_fn, worker_th);
idleth_queue.push(*worker_th);
}
//start server socket
sdata = new serverth_data;
sdata->server_socket = &serversocket;
sdata->server_port = server_port;
sdata->idleth_queue = &idleth_queue;
sdata->ready_queue = &ready_queue;
sdata->selcond = selcond;
sdata->qlock = qlock;
pthread_create(&server_thread, 0, serverLoop, sdata);
//start monitoring loop
eventLoop();
}
void logserver::stopserver()
{
//close the server socket
//stops receiving data on the server socket
shutdown(serversocket, 0);
//wait for all threads to be idle
while(idleth_queue.size() != nthreads)
sleep(1);
#ifdef STATS_ENABLED
printf("\n\nSTATISTICS\n");
std::map<std::string, int> num_reqsc;
std::map<std::string, double> work_timec;
#endif
//set the system running flag to false
sys_alive = false;
for(int i=0; i<nthreads; i++)
{
pthread_item *idle_th = th_list[i];
//wake up the thread
pthread_mutex_lock(idle_th->data->th_mut);
pthread_cond_signal(idle_th->data->th_cond);
pthread_mutex_unlock(idle_th->data->th_mut);
//wait for it to join
pthread_join(*(idle_th->th_handle), 0);
//free the thread variables
pthread_cond_destroy(idle_th->data->th_cond);
#ifdef STATS_ENABLED
if(i == 0)
{
tot_threadwork_time = 0;
num_reqs = 0;
}
tot_threadwork_time += idle_th->data->work_time;
num_reqs += idle_th->data->num_reqs;
printf("thread %d: work_time %.3f\t#calls %d\tavg req process time:\t%.3f\n",
i,
idle_th->data->work_time,
idle_th->data->num_reqs,
(( idle_th->data->num_reqs == 0 ) ? 0 : idle_th->data->work_time / idle_th->data->num_reqs)
);
for(std::map<std::string, int>::const_iterator itr = idle_th->data->num_reqsc.begin();
itr != idle_th->data->num_reqsc.end(); itr++)
{
std::string ckey = (*itr).first;
printf("\t%s\t%d\t%.3f\t%.3f\n", ckey.c_str(), (*itr).second, idle_th->data->work_timec[ckey],
idle_th->data->work_timec[ckey] / (*itr).second);
if(num_reqsc.find(ckey) == num_reqsc.end()){
num_reqsc[ckey] = 0;
work_timec[ckey] = 0;
}
num_reqsc[ckey] += (*itr).second;
work_timec[ckey] += idle_th->data->work_timec[ckey];
}
#endif
delete idle_th->data->th_cond;
delete idle_th->data->th_mut;
delete idle_th->data->workitem;
delete idle_th->data;
delete idle_th->th_handle;
}
th_list.clear();
#ifdef STATS_ENABLED
printf("\n\nAggregated Stats:\n");
for(std::map<std::string, int>::const_iterator itr = num_reqsc.begin();
itr != num_reqsc.end(); itr++)
{
std::string ckey = (*itr).first;
printf("\t%s\t%d\t%.3f\t%.3f\n", ckey.c_str(), (*itr).second, work_timec[ckey],
work_timec[ckey] / (*itr).second);
}
tot_time = (stop_tv.tv_sec - start_tv.tv_sec) * 1000 +
(stop_tv.tv_usec / 1000 - start_tv.tv_usec / 1000);
printf("\ntot time:\t%f\n",tot_time);
printf("tot work time:\t%f\n", tot_threadwork_time);
printf("load avg:\t%f\n", tot_threadwork_time / tot_time);
printf("tot num reqs\t%d\n", num_reqs);
if(num_reqs!= 0)
{
printf("tot work time / num reqs:\t%.3f\n", tot_threadwork_time / num_reqs);
printf("tot time / num reqs:\t%.3f\n", tot_time / num_reqs );
}
#endif
//close(serversocket);
return;
}
void logserver::eventLoop()
{
fd_set readfs;
std::vector<int> sel_list;
int maxfd;
struct timespec ts;
while(true)
{
//clear readset
FD_ZERO(&readfs);
maxfd = -1;
ts.tv_nsec = 250000; //nanosec
ts.tv_sec = 0;
//Timeout.tv_usec = 250; /* microseconds */
//Timeout.tv_sec = 0; /* seconds */
//update select set
pthread_mutex_lock(qlock);
//while(ready_queue.size() == 0)
if(sel_list.size() == 0)
{
while(ready_queue.size() == 0)
pthread_cond_wait(selcond, qlock);
//pthread_cond_timedwait(selcond, qlock, &ts);
//printf("awoke\n");
}
//new connections + processed conns are in ready_queue
//add them to select list
while(ready_queue.size() > 0)
{
sel_list.push_back(ready_queue.front());
ready_queue.pop();
}
pthread_mutex_unlock(qlock);
//ready select set
for(std::vector<int>::const_iterator itr=sel_list.begin();
itr != sel_list.end(); itr++)
{
if(maxfd < *itr)
maxfd = *itr;
FD_SET(*itr, &readfs);
}
//select events
int sel_res = select(maxfd+1, &readfs, NULL, NULL, NULL);// &Timeout);
//printf("sel_res %d %d\n", sel_res, errno);
//fflush(stdout);
//job assignment to threads
//printf("sel_list size:\t%d ready_cnt\t%d\n", sel_list.size(), sel_res);
#ifdef STATS_ENABLED
if(num_selcalls == 0)
gettimeofday(&start_tv, 0);
num_selevents += sel_res;
num_selcalls++;
#endif
pthread_mutex_lock(qlock);
for(int i=0; i<sel_list.size(); i++ )
{
int currsock = sel_list[i];
if (FD_ISSET(currsock, &readfs))
{
//printf("sock %d ready\n", currsock);
// pthread_mutex_lock(qlock);
if(idleth_queue.size() > 0) //assign the job to an indle thread
{
pthread_item idle_th = idleth_queue.front();
idleth_queue.pop();
//wake up the thread to do work
pthread_mutex_lock(idle_th.data->th_mut);
//set the job of the idle thread
*(idle_th.data->workitem) = currsock;
pthread_cond_signal(idle_th.data->th_cond);
pthread_mutex_unlock(idle_th.data->th_mut);
//printf("%d:\tconn %d assigned.\n", i, currsock);
}
else
{
//insert the given element to the work queue
work_queue.push(currsock);
//printf("work queue size:\t%d\n", work_queue.size());
}
// pthread_mutex_unlock(qlock);
//remove from the sel_list
sel_list.erase(sel_list.begin()+i);
i--;
}
}
pthread_mutex_unlock(qlock);
#ifdef STATS_ENABLED
gettimeofday(&stop_tv, 0);
#endif
}
}
void *serverLoop(void *args)
{
serverth_data *sdata = (serverth_data*)args;
int sockfd; //socket descriptor
struct sockaddr_in serv_addr;
struct sockaddr_in cli_addr;
int newsockfd; //newly created
socklen_t clilen = sizeof(cli_addr);
//open a socket
sockfd = socket(AF_INET, SOCK_STREAM, 0);
if (sockfd < 0)
{
printf("ERROR opening socket\n");
return 0;
}
bzero((char *) &serv_addr, sizeof(serv_addr));
serv_addr.sin_family = AF_INET;
serv_addr.sin_addr.s_addr = htonl(INADDR_ANY);
serv_addr.sin_port = htons(sdata->server_port);
if (bind(sockfd, (struct sockaddr *) &serv_addr, sizeof(serv_addr)) < 0)
{
printf("ERROR on binding.\n");
return 0;
}
//start listening on the server socket
//second arg is the max number of coonections waiting in queue
if(listen(sockfd,SOMAXCONN)==-1)
{
printf("ERROR on listen.\n");
return 0;
}
printf("LSM Server listenning...\n");
*(sdata->server_socket) = sockfd;
int flag, result;
while(true)
{
newsockfd = accept(sockfd, (struct sockaddr *) &cli_addr, &clilen);
if (newsockfd < 0)
{
printf("ERROR on accept.\n");
return 0; // we probably want to continue instead of return here (when not debugging)
}
flag = 1;
result = setsockopt(newsockfd, /* socket affected */
IPPROTO_TCP, /* set option at TCP level */
TCP_NODELAY, /* name of option */
(char *) &flag, /* the cast is historical
cruft */
sizeof(int)); /* length of option value */
if (result < 0)
{
printf("ERROR on setting socket option TCP_NODELAY.\n");
return 0;
}
char clientip[20];
inet_ntop(AF_INET, (void*) &(cli_addr.sin_addr), clientip, 20);
printf("Connection from:\t%s\n", clientip);
//printf("Number of idle threads %d\n", idleth_queue.size());
pthread_mutex_lock(sdata->qlock);
//insert the given element to the ready queue
sdata->ready_queue->push(newsockfd);
if(sdata->ready_queue->size() == 1) //signal the event loop
pthread_cond_signal(sdata->selcond);
pthread_mutex_unlock(sdata->qlock);
}
}
void * thread_work_fn( void * args)
{
pthread_item * item = (pthread_item *) args;
pthread_mutex_lock(item->data->th_mut);
while(true)
{
while(*(item->data->workitem) == -1)
{
if(!*(item->data->sys_alive))
break;
pthread_cond_wait(item->data->th_cond, item->data->th_mut); //wait for job
}
#ifdef STATS_ENABLED
gettimeofday(& (item->data->start_tv), 0);
std::ostringstream ostr;
ostr << *(item->data->workitem) << "_";
#endif
if(!*(item->data->sys_alive))
{
//printf("thread quitted.\n");
break;
}
//step 1: read the opcode
uint8_t opcode;
ssize_t n = read(*(item->data->workitem), &opcode, sizeof(uint8_t));
assert( n == sizeof(uint8_t));
assert( opcode < logserver::OP_INVALID );
if( opcode == logserver::OP_DONE ) //close the conn on failure
{
pthread_mutex_lock(item->data->qlock);
printf("client done. conn closed. (%d, %d, %d, %d)\n",
n, errno, *(item->data->workitem), item->data->work_queue->size());
close(*(item->data->workitem));
if(item->data->work_queue->size() > 0)
{
int new_work = item->data->work_queue->front();
item->data->work_queue->pop();
//printf("work queue size:\t%d\n", item->data->work_queue->size());
*(item->data->workitem) = new_work;
}
else
{
//set work to -1
*(item->data->workitem) = -1;
//add self to idle queue
item->data->idleth_queue->push(*item);
}
pthread_mutex_unlock(item->data->qlock);
continue;
}
//step 2: read the tuple from client
datatuple tuple;
tuple.keylen = (uint32_t*)malloc(sizeof(uint32_t));
tuple.datalen = (uint32_t*)malloc(sizeof(uint32_t));
//read the key length
n = read(*(item->data->workitem), tuple.keylen, sizeof(uint32_t));
assert( n == sizeof(uint32_t));
//read the data length
n = read(*(item->data->workitem), tuple.datalen, sizeof(uint32_t));
assert( n == sizeof(uint32_t));
//read the key
tuple.key = (byte*) malloc(*tuple.keylen);
logserver::readfromsocket(*(item->data->workitem), (byte*) tuple.key, *tuple.keylen);
//read the data
if(!tuple.isDelete() && opcode != logserver::OP_FIND)
{
tuple.data = (byte*) malloc(*tuple.datalen);
logserver::readfromsocket(*(item->data->workitem), (byte*) tuple.data, *tuple.datalen);
}
else
tuple.data = 0;
//step 3: process the tuple
//pthread_mutex_lock(item->data->table_lock);
//readlock(item->data->table_lock,0);
if(opcode == logserver::OP_INSERT)
{
//insert/update/delete
item->data->ltable->insertTuple(tuple);
//unlock the lsmlock
//pthread_mutex_unlock(item->data->table_lock);
//unlock(item->data->table_lock);
//step 4: send response
uint8_t rcode = logserver::OP_SUCCESS;
n = write(*(item->data->workitem), &rcode, sizeof(uint8_t));
assert(n == sizeof(uint8_t));
}
else if(opcode == logserver::OP_FIND)
{
//find the tuple
datatuple *dt = item->data->ltable->findTuple(-1, tuple.key, *tuple.keylen);
//unlock the lsmlock
//pthread_mutex_unlock(item->data->table_lock);
//unlock(item->data->table_lock);
#ifdef STATS_ENABLED
if(dt == 0)
printf("key not found:\t%s\n", datatuple::key_to_str(tuple.key).c_str());
else if( *dt->datalen != 1024)
printf("data len for\t%s:\t%d\n", datatuple::key_to_str(tuple.key).c_str(),
*dt->datalen);
if(datatuple::compare(tuple.key, dt->key) != 0)
printf("key not equal:\t%s\t%s\n", datatuple::key_to_str(tuple.key).c_str(),
datatuple::key_to_str(dt->key).c_str());
#endif
if(dt == 0) //tuple deleted
{
dt = (datatuple*) malloc(sizeof(datatuple));
dt->keylen = (uint32_t*) malloc(2*sizeof(uint32_t) + *tuple.keylen);
*dt->keylen = *tuple.keylen;
dt->datalen = dt->keylen + 1;
dt->key = (datatuple::key_t) (dt->datalen+1);
memcpy((byte*) dt->key, (byte*) tuple.key, *tuple.keylen);
dt->setDelete();
}
//send the reply code
uint8_t rcode = logserver::OP_SENDING_TUPLE;
n = write(*(item->data->workitem), &rcode, sizeof(uint8_t));
assert(n == sizeof(uint8_t));
//send the tuple
logserver::writetosocket(*(item->data->workitem), (byte*) dt->keylen, dt->byte_length());
//free datatuple
free(dt->keylen);
free(dt);
}
//close the socket
//close(*(item->data->workitem));
//free the tuple
free(tuple.keylen);
free(tuple.datalen);
free(tuple.key);
free(tuple.data);
//printf("socket %d: work completed.", *(item->data->workitem));
pthread_mutex_lock(item->data->qlock);
//add conn desc to ready queue
item->data->ready_queue->push(*(item->data->workitem));
//printf("ready queue size: %d sock(%d)\n", item->data->ready_queue->size(), *(item->data->workitem));
if(item->data->ready_queue->size() == 1) //signal the event loop
pthread_cond_signal(item->data->selcond);
//printf("work complete, added to ready queue %d (size %d)\n", *(item->data->workitem),
// item->data->ready_queue->size());
if(item->data->work_queue->size() > 0)
{
int new_work = item->data->work_queue->front();
item->data->work_queue->pop();
//printf("work queue size:\t%d\n", item->data->work_queue->size());
*(item->data->workitem) = new_work;
}
else
{
//set work to -1
*(item->data->workitem) = -1;
//add self to idle queue
item->data->idleth_queue->push(*item);
}
pthread_mutex_unlock(item->data->qlock);
#ifdef STATS_ENABLED
if( item->data->num_reqs == 0 )
item->data->work_time = 0;
gettimeofday(& (item->data->stop_tv), 0);
(item->data->num_reqs)++;
//item->data->work_time += tv_to_double(item->data->stop_tv) - tv_to_double(item->data->start_tv);
item->data->work_time += (item->data->stop_tv.tv_sec - item->data->start_tv.tv_sec) * 1000 +
(item->data->stop_tv.tv_usec / 1000 - item->data->start_tv.tv_usec / 1000);
int iopcode = opcode;
ostr << iopcode;
std::string clientkey = ostr.str();
if(item->data->num_reqsc.find(clientkey) == item->data->num_reqsc.end())
{
item->data->num_reqsc[clientkey]=0;
item->data->work_timec[clientkey]=0;
}
item->data->num_reqsc[clientkey]++;
item->data->work_timec[clientkey] += (item->data->stop_tv.tv_sec - item->data->start_tv.tv_sec) * 1000 +
(item->data->stop_tv.tv_usec / 1000 - item->data->start_tv.tv_usec / 1000);;
#endif
}
pthread_mutex_unlock(item->data->th_mut);
return NULL;
}