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nest-open-source / nest-learning-thermostat / 5.1.8 / iperf / refs/heads/master / . / iperf-2.0.5 / src / Listener.cpp
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/*---------------------------------------------------------------
* Copyright (c) 1999,2000,2001,2002,2003
* The Board of Trustees of the University of Illinois
* All Rights Reserved.
*---------------------------------------------------------------
* Permission is hereby granted, free of charge, to any person
* obtaining a copy of this software (Iperf) and associated
* documentation files (the "Software"), to deal in the Software
* without restriction, including without limitation the
* rights to use, copy, modify, merge, publish, distribute,
* sublicense, and/or sell copies of the Software, and to permit
* persons to whom the Software is furnished to do
* so, subject to the following conditions:
*
*
* Redistributions of source code must retain the above
* copyright notice, this list of conditions and
* the following disclaimers.
*
*
* Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimers in the documentation and/or other materials
* provided with the distribution.
*
*
* Neither the names of the University of Illinois, NCSA,
* nor the names of its contributors may be used to endorse
* or promote products derived from this Software without
* specific prior written permission.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES
* OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE CONTIBUTORS OR COPYRIGHT
* HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
* WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
* ARISING FROM, OUT OF OR IN CONNECTION WITH THE
* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
* ________________________________________________________________
* National Laboratory for Applied Network Research
* National Center for Supercomputing Applications
* University of Illinois at Urbana-Champaign
* http://www.ncsa.uiuc.edu
* ________________________________________________________________
*
* Listener.cpp
* by Mark Gates <mgates@nlanr.net>
* & Ajay Tirumala <tirumala@ncsa.uiuc.edu>
* -------------------------------------------------------------------
* Listener sets up a socket listening on the server host. For each
* connected socket that accept() returns, this creates a Server
* socket and spawns a thread for it.
*
* Changes to the latest version. Listener will run as a daemon
* Multicast Server is now Multi-threaded
* -------------------------------------------------------------------
* headers
* uses
* <stdlib.h>
* <stdio.h>
* <string.h>
* <errno.h>
*
* <sys/types.h>
* <unistd.h>
*
* <netdb.h>
* <netinet/in.h>
* <sys/socket.h>
* ------------------------------------------------------------------- */
#define HEADERS()
#include "headers.h"
#include "Listener.hpp"
#include "SocketAddr.h"
#include "PerfSocket.hpp"
#include "List.h"
#include "util.h"
/* -------------------------------------------------------------------
* Stores local hostname and socket info.
* ------------------------------------------------------------------- */
Listener::Listener( thread_Settings *inSettings ) {
mClients = inSettings->mThreads;
mBuf = NULL;
mSettings = inSettings;
// initialize buffer
mBuf = new char[ mSettings->mBufLen ];
// open listening socket
Listen( );
ReportSettings( inSettings );
} // end Listener
/* -------------------------------------------------------------------
* Delete memory (buffer).
* ------------------------------------------------------------------- */
Listener::~Listener() {
if ( mSettings->mSock != INVALID_SOCKET ) {
int rc = close( mSettings->mSock );
WARN_errno( rc == SOCKET_ERROR, "close" );
mSettings->mSock = INVALID_SOCKET;
}
DELETE_ARRAY( mBuf );
} // end ~Listener
/* -------------------------------------------------------------------
* Listens for connections and starts Servers to handle data.
* For TCP, each accepted connection spawns a Server thread.
* For UDP, handle all data in this thread for Win32 Only, otherwise
* spawn a new Server thread.
* ------------------------------------------------------------------- */
void Listener::Run( void ) {
#ifdef WIN32
if ( isUDP( mSettings ) && !isSingleUDP( mSettings ) ) {
UDPSingleServer();
} else
#else
#ifdef sun
if ( ( isUDP( mSettings ) &&
isMulticast( mSettings ) &&
!isSingleUDP( mSettings ) ) ||
isSingleUDP( mSettings ) ) {
UDPSingleServer();
} else
#else
if ( isSingleUDP( mSettings ) ) {
UDPSingleServer();
} else
#endif
#endif
{
bool client = false, UDP = isUDP( mSettings ), mCount = (mSettings->mThreads != 0);
thread_Settings *tempSettings = NULL;
Iperf_ListEntry *exist, *listtemp;
client_hdr* hdr = ( UDP ? (client_hdr*) (((UDP_datagram*)mBuf) + 1) :
(client_hdr*) mBuf);
if ( mSettings->mHost != NULL ) {
client = true;
SockAddr_remoteAddr( mSettings );
}
Settings_Copy( mSettings, &server );
server->mThreadMode = kMode_Server;
// Accept each packet,
// If there is no existing client, then start
// a new thread to service the new client
// The listener runs in a single thread
// Thread per client model is followed
do {
// Get a new socket
Accept( server );
if ( server->mSock == INVALID_SOCKET ) {
break;
}
if ( sInterupted != 0 ) {
close( server->mSock );
break;
}
// Reset Single Client Stuff
if ( isSingleClient( mSettings ) && clients == NULL ) {
mSettings->peer = server->peer;
mClients--;
client = true;
// Once all the server threads exit then quit
// Must keep going in case this client sends
// more streams
if ( mClients == 0 ) {
thread_release_nonterm( 0 );
mClients = 1;
}
}
// Verify that it is allowed
if ( client ) {
if ( !SockAddr_Hostare_Equal( (sockaddr*) &mSettings->peer,
(sockaddr*) &server->peer ) ) {
// Not allowed try again
close( server->mSock );
if ( isUDP( mSettings ) ) {
mSettings->mSock = -1;
Listen();
}
continue;
}
}
// Create an entry for the connection list
listtemp = new Iperf_ListEntry;
memcpy(listtemp, &server->peer, sizeof(iperf_sockaddr));
listtemp->next = NULL;
// See if we need to do summing
Mutex_Lock( &clients_mutex );
exist = Iperf_hostpresent( &server->peer, clients);
if ( exist != NULL ) {
// Copy group ID
listtemp->holder = exist->holder;
server->multihdr = exist->holder;
} else {
server->mThreads = 0;
Mutex_Lock( &groupCond );
groupID--;
listtemp->holder = InitMulti( server, groupID );
server->multihdr = listtemp->holder;
Mutex_Unlock( &groupCond );
}
// Store entry in connection list
Iperf_pushback( listtemp, &clients );
Mutex_Unlock( &clients_mutex );
tempSettings = NULL;
if ( !isCompat( mSettings ) && !isMulticast( mSettings ) ) {
if ( !UDP ) {
// TCP does not have the info yet
if ( recv( server->mSock, (char*)hdr, sizeof(client_hdr), 0) > 0 ) {
Settings_GenerateClientSettings( server, &tempSettings,
hdr );
}
} else {
Settings_GenerateClientSettings( server, &tempSettings,
hdr );
}
}
if ( tempSettings != NULL ) {
client_init( tempSettings );
if ( tempSettings->mMode == kTest_DualTest ) {
#ifdef HAVE_THREAD
server->runNow = tempSettings;
#else
server->runNext = tempSettings;
#endif
} else {
server->runNext = tempSettings;
}
}
// Start the server
#if defined(WIN32) && defined(HAVE_THREAD)
if ( UDP ) {
// WIN32 does bad UDP handling so run single threaded
if ( server->runNow != NULL ) {
thread_start( server->runNow );
}
server_spawn( server );
if ( server->runNext != NULL ) {
thread_start( server->runNext );
}
} else
#endif
thread_start( server );
// create a new socket
if ( UDP ) {
mSettings->mSock = -1;
Listen( );
}
// Prep for next connection
if ( !isSingleClient( mSettings ) ) {
mClients--;
}
Settings_Copy( mSettings, &server );
server->mThreadMode = kMode_Server;
} while ( !sInterupted && (!mCount || ( mCount && mClients > 0 )) );
Settings_Destroy( server );
}
} // end Run
/* -------------------------------------------------------------------
* Setup a socket listening on a port.
* For TCP, this calls bind() and listen().
* For UDP, this just calls bind().
* If inLocalhost is not null, bind to that address rather than the
* wildcard server address, specifying what incoming interface to
* accept connections on.
* ------------------------------------------------------------------- */
void Listener::Listen( ) {
int rc;
SockAddr_localAddr( mSettings );
// create an internet TCP socket
int type = (isUDP( mSettings ) ? SOCK_DGRAM : SOCK_STREAM);
int domain = (SockAddr_isIPv6( &mSettings->local ) ?
#ifdef HAVE_IPV6
AF_INET6
#else
AF_INET
#endif
: AF_INET);
#ifdef WIN32
if ( SockAddr_isMulticast( &mSettings->local ) ) {
// Multicast on Win32 requires special handling
mSettings->mSock = WSASocket( domain, type, 0, 0, 0, WSA_FLAG_MULTIPOINT_C_LEAF | WSA_FLAG_MULTIPOINT_D_LEAF );
WARN_errno( mSettings->mSock == INVALID_SOCKET, "socket" );
} else
#endif
{
mSettings->mSock = socket( domain, type, 0 );
WARN_errno( mSettings->mSock == INVALID_SOCKET, "socket" );
}
SetSocketOptions( mSettings );
// reuse the address, so we can run if a former server was killed off
int boolean = 1;
Socklen_t len = sizeof(boolean);
setsockopt( mSettings->mSock, SOL_SOCKET, SO_REUSEADDR, (char*) &boolean, len );
// bind socket to server address
#ifdef WIN32
if ( SockAddr_isMulticast( &mSettings->local ) ) {
// Multicast on Win32 requires special handling
rc = WSAJoinLeaf( mSettings->mSock, (sockaddr*) &mSettings->local, mSettings->size_local,0,0,0,0,JL_BOTH);
WARN_errno( rc == SOCKET_ERROR, "WSAJoinLeaf (aka bind)" );
} else
#endif
{
rc = bind( mSettings->mSock, (sockaddr*) &mSettings->local, mSettings->size_local );
WARN_errno( rc == SOCKET_ERROR, "bind" );
}
// listen for connections (TCP only).
// default backlog traditionally 5
if ( !isUDP( mSettings ) ) {
rc = listen( mSettings->mSock, 5 );
WARN_errno( rc == SOCKET_ERROR, "listen" );
}
#ifndef WIN32
// if multicast, join the group
if ( SockAddr_isMulticast( &mSettings->local ) ) {
McastJoin( );
}
#endif
} // end Listen
/* -------------------------------------------------------------------
* Joins the multicast group, with the default interface.
* ------------------------------------------------------------------- */
void Listener::McastJoin( ) {
#ifdef HAVE_MULTICAST
if ( !SockAddr_isIPv6( &mSettings->local ) ) {
struct ip_mreq mreq;
memcpy( &mreq.imr_multiaddr, SockAddr_get_in_addr( &mSettings->local ),
sizeof(mreq.imr_multiaddr));
mreq.imr_interface.s_addr = htonl( INADDR_ANY );
int rc = setsockopt( mSettings->mSock, IPPROTO_IP, IP_ADD_MEMBERSHIP,
(char*) &mreq, sizeof(mreq));
WARN_errno( rc == SOCKET_ERROR, "multicast join" );
}
#ifdef HAVE_IPV6_MULTICAST
else {
struct ipv6_mreq mreq;
memcpy( &mreq.ipv6mr_multiaddr, SockAddr_get_in6_addr( &mSettings->local ),
sizeof(mreq.ipv6mr_multiaddr));
mreq.ipv6mr_interface = 0;
int rc = setsockopt( mSettings->mSock, IPPROTO_IPV6, IPV6_ADD_MEMBERSHIP,
(char*) &mreq, sizeof(mreq));
WARN_errno( rc == SOCKET_ERROR, "multicast join" );
}
#endif
#endif
}
// end McastJoin
/* -------------------------------------------------------------------
* Sets the Multicast TTL for outgoing packets.
* ------------------------------------------------------------------- */
void Listener::McastSetTTL( int val ) {
#ifdef HAVE_MULTICAST
if ( !SockAddr_isIPv6( &mSettings->local ) ) {
int rc = setsockopt( mSettings->mSock, IPPROTO_IP, IP_MULTICAST_TTL,
(char*) &val, sizeof(val));
WARN_errno( rc == SOCKET_ERROR, "multicast ttl" );
}
#ifdef HAVE_IPV6_MULTICAST
else {
int rc = setsockopt( mSettings->mSock, IPPROTO_IPV6, IPV6_MULTICAST_HOPS,
(char*) &val, sizeof(val));
WARN_errno( rc == SOCKET_ERROR, "multicast ttl" );
}
#endif
#endif
}
// end McastSetTTL
/* -------------------------------------------------------------------
* After Listen() has setup mSock, this will block
* until a new connection arrives.
* ------------------------------------------------------------------- */
void Listener::Accept( thread_Settings *server ) {
server->size_peer = sizeof(iperf_sockaddr);
if ( isUDP( server ) ) {
/* -------------------------------------------------------------------
* Do the equivalent of an accept() call for UDP sockets. This waits
* on a listening UDP socket until we get a datagram.
* ------------------------------------------------------------------- */
int rc;
Iperf_ListEntry *exist;
int32_t datagramID;
server->mSock = INVALID_SOCKET;
while ( server->mSock == INVALID_SOCKET ) {
rc = recvfrom( mSettings->mSock, mBuf, mSettings->mBufLen, 0,
(struct sockaddr*) &server->peer, &server->size_peer );
FAIL_errno( rc == SOCKET_ERROR, "recvfrom", mSettings );
Mutex_Lock( &clients_mutex );
// Handle connection for UDP sockets.
exist = Iperf_present( &server->peer, clients);
datagramID = ntohl( ((UDP_datagram*) mBuf)->id );
if ( exist == NULL && datagramID >= 0 ) {
server->mSock = mSettings->mSock;
int rc = connect( server->mSock, (struct sockaddr*) &server->peer,
server->size_peer );
FAIL_errno( rc == SOCKET_ERROR, "connect UDP", mSettings );
} else {
server->mSock = INVALID_SOCKET;
}
Mutex_Unlock( &clients_mutex );
}
} else {
// Handles interupted accepts. Returns the newly connected socket.
server->mSock = INVALID_SOCKET;
while ( server->mSock == INVALID_SOCKET ) {
// accept a connection
server->mSock = accept( mSettings->mSock,
(sockaddr*) &server->peer, &server->size_peer );
if ( server->mSock == INVALID_SOCKET && errno == EINTR ) {
continue;
}
}
}
server->size_local = sizeof(iperf_sockaddr);
getsockname( server->mSock, (sockaddr*) &server->local,
&server->size_local );
} // end Accept
void Listener::UDPSingleServer( ) {
bool client = false, UDP = isUDP( mSettings ), mCount = (mSettings->mThreads != 0);
thread_Settings *tempSettings = NULL;
Iperf_ListEntry *exist, *listtemp;
int rc;
int32_t datagramID;
client_hdr* hdr = ( UDP ? (client_hdr*) (((UDP_datagram*)mBuf) + 1) :
(client_hdr*) mBuf);
ReportStruct *reportstruct = new ReportStruct;
if ( mSettings->mHost != NULL ) {
client = true;
SockAddr_remoteAddr( mSettings );
}
Settings_Copy( mSettings, &server );
server->mThreadMode = kMode_Server;
// Accept each packet,
// If there is no existing client, then start
// a new report to service the new client
// The listener runs in a single thread
Mutex_Lock( &clients_mutex );
do {
// Get next packet
while ( sInterupted == 0) {
server->size_peer = sizeof( iperf_sockaddr );
rc = recvfrom( mSettings->mSock, mBuf, mSettings->mBufLen, 0,
(struct sockaddr*) &server->peer, &server->size_peer );
WARN_errno( rc == SOCKET_ERROR, "recvfrom" );
if ( rc == SOCKET_ERROR ) {
return;
}
// Handle connection for UDP sockets.
exist = Iperf_present( &server->peer, clients);
datagramID = ntohl( ((UDP_datagram*) mBuf)->id );
if ( datagramID >= 0 ) {
if ( exist != NULL ) {
// read the datagram ID and sentTime out of the buffer
reportstruct->packetID = datagramID;
reportstruct->sentTime.tv_sec = ntohl( ((UDP_datagram*) mBuf)->tv_sec );
reportstruct->sentTime.tv_usec = ntohl( ((UDP_datagram*) mBuf)->tv_usec );
reportstruct->packetLen = rc;
gettimeofday( &(reportstruct->packetTime), NULL );
ReportPacket( exist->server->reporthdr, reportstruct );
} else {
Mutex_Lock( &groupCond );
groupID--;
server->mSock = -groupID;
Mutex_Unlock( &groupCond );
server->size_local = sizeof(iperf_sockaddr);
getsockname( mSettings->mSock, (sockaddr*) &server->local,
&server->size_local );
break;
}
} else {
if ( exist != NULL ) {
// read the datagram ID and sentTime out of the buffer
reportstruct->packetID = -datagramID;
reportstruct->sentTime.tv_sec = ntohl( ((UDP_datagram*) mBuf)->tv_sec );
reportstruct->sentTime.tv_usec = ntohl( ((UDP_datagram*) mBuf)->tv_usec );
reportstruct->packetLen = rc;
gettimeofday( &(reportstruct->packetTime), NULL );
ReportPacket( exist->server->reporthdr, reportstruct );
// stop timing
gettimeofday( &(reportstruct->packetTime), NULL );
CloseReport( exist->server->reporthdr, reportstruct );
if ( rc > (int) ( sizeof( UDP_datagram )
+ sizeof( server_hdr ) ) ) {
UDP_datagram *UDP_Hdr;
server_hdr *hdr;
UDP_Hdr = (UDP_datagram*) mBuf;
Transfer_Info *stats = GetReport( exist->server->reporthdr );
hdr = (server_hdr*) (UDP_Hdr+1);
hdr->flags = htonl( HEADER_VERSION1 );
hdr->total_len1 = htonl( (long) (stats->TotalLen >> 32) );
hdr->total_len2 = htonl( (long) (stats->TotalLen & 0xFFFFFFFF) );
hdr->stop_sec = htonl( (long) stats->endTime );
hdr->stop_usec = htonl( (long)((stats->endTime - (long)stats->endTime)
* rMillion));
hdr->error_cnt = htonl( stats->cntError );
hdr->outorder_cnt = htonl( stats->cntOutofOrder );
hdr->datagrams = htonl( stats->cntDatagrams );
hdr->jitter1 = htonl( (long) stats->jitter );
hdr->jitter2 = htonl( (long) ((stats->jitter - (long)stats->jitter)
* rMillion) );
}
EndReport( exist->server->reporthdr );
exist->server->reporthdr = NULL;
Iperf_delete( &(exist->server->peer), &clients );
} else if ( rc > (int) ( sizeof( UDP_datagram )
+ sizeof( server_hdr ) ) ) {
UDP_datagram *UDP_Hdr;
server_hdr *hdr;
UDP_Hdr = (UDP_datagram*) mBuf;
hdr = (server_hdr*) (UDP_Hdr+1);
hdr->flags = htonl( 0 );
}
sendto( mSettings->mSock, mBuf, mSettings->mBufLen, 0,
(struct sockaddr*) &server->peer, server->size_peer);
}
}
if ( server->mSock == INVALID_SOCKET ) {
break;
}
if ( sInterupted != 0 ) {
close( server->mSock );
break;
}
// Reset Single Client Stuff
if ( isSingleClient( mSettings ) && clients == NULL ) {
mSettings->peer = server->peer;
mClients--;
client = true;
// Once all the server threads exit then quit
// Must keep going in case this client sends
// more streams
if ( mClients == 0 ) {
thread_release_nonterm( 0 );
mClients = 1;
}
}
// Verify that it is allowed
if ( client ) {
if ( !SockAddr_Hostare_Equal( (sockaddr*) &mSettings->peer,
(sockaddr*) &server->peer ) ) {
// Not allowed try again
connect( mSettings->mSock,
(sockaddr*) &server->peer,
server->size_peer );
close( mSettings->mSock );
mSettings->mSock = -1;
Listen( );
continue;
}
}
// Create an entry for the connection list
listtemp = new Iperf_ListEntry;
memcpy(listtemp, &server->peer, sizeof(iperf_sockaddr));
listtemp->server = server;
listtemp->next = NULL;
// See if we need to do summing
exist = Iperf_hostpresent( &server->peer, clients);
if ( exist != NULL ) {
// Copy group ID
listtemp->holder = exist->holder;
server->multihdr = exist->holder;
} else {
server->mThreads = 0;
Mutex_Lock( &groupCond );
groupID--;
listtemp->holder = InitMulti( server, groupID );
server->multihdr = listtemp->holder;
Mutex_Unlock( &groupCond );
}
// Store entry in connection list
Iperf_pushback( listtemp, &clients );
tempSettings = NULL;
if ( !isCompat( mSettings ) && !isMulticast( mSettings ) ) {
Settings_GenerateClientSettings( server, &tempSettings,
hdr );
}
if ( tempSettings != NULL ) {
client_init( tempSettings );
if ( tempSettings->mMode == kTest_DualTest ) {
#ifdef HAVE_THREAD
thread_start( tempSettings );
#else
server->runNext = tempSettings;
#endif
} else {
server->runNext = tempSettings;
}
}
server->reporthdr = InitReport( server );
// Prep for next connection
if ( !isSingleClient( mSettings ) ) {
mClients--;
}
Settings_Copy( mSettings, &server );
server->mThreadMode = kMode_Server;
} while ( !sInterupted && (!mCount || ( mCount && mClients > 0 )) );
Mutex_Unlock( &clients_mutex );
Settings_Destroy( server );
}
/* --------------------------------------------------------------------
* Run the server as a daemon
* --------------------------------------------------------------------*/
void Listener::runAsDaemon(const char *pname, int facility) {
#ifndef WIN32
pid_t pid;
/* Create a child process & if successful, exit from the parent process */
if ( (pid = fork()) == -1 ) {
fprintf( stderr, "error in first child create\n");
exit(0);
} else if ( pid != 0 ) {
exit(0);
}
/* Try becoming the session leader, once the parent exits */
if ( setsid() == -1 ) { /* Become the session leader */
fprintf( stderr, "Cannot change the session group leader\n");
} else {
}
signal(SIGHUP,SIG_IGN);
/* Now fork() and get released from the terminal */
if ( (pid = fork()) == -1 ) {
fprintf( stderr, "error\n");
exit(0);
} else if ( pid != 0 ) {
exit(0);
}
chdir(".");
fprintf( stderr, "Running Iperf Server as a daemon\n");
fprintf( stderr, "The Iperf daemon process ID : %d\n",((int)getpid()));
fflush(stderr);
fclose(stdin);
#else
fprintf( stderr, "Use the precompiled windows version for service (daemon) option\n");
#endif
}