/*--------------------------------------------------------------- * 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 * ________________________________________________________________ * * Launch.cpp * by Kevin Gibbs * ------------------------------------------------------------------- * Functions to launch new server and client threads from C while * the server and client are in C++. * The launch function for reporters is in Reporter.c since it is * in C and does not need a special launching function. * ------------------------------------------------------------------- */ #include "headers.h" #include "Thread.h" #include "Settings.hpp" #include "Client.hpp" #include "Listener.hpp" #include "Server.hpp" #include "PerfSocket.hpp" #include "active_hosts.h" #include "SocketAddr.h" #include "delay.h" static int fullduplex_startstop_barrier (struct BarrierMutex *barrier) { int rc = 0; assert(barrier != NULL); Condition_Lock(barrier->await); ++barrier->count; #ifdef HAVE_THREAD_DEBUG thread_debug("Fullduplex barrier incr to %d %p ", barrier->count, (void *)&barrier->await, rc); #endif if (barrier->count == 2) { rc = 1; // last one wake's up everyone else' #ifdef HAVE_THREAD_DEBUG thread_debug("Fullduplex startstop broadcast on condition %p ", (void *)&barrier->await, rc); #endif Condition_Broadcast(&barrier->await); } else { int timeout = barrier->timeout; while ((barrier->count != 2) && (timeout > 0)) { #ifdef HAVE_THREAD_DEBUG thread_debug("Fullduplex startstop barrier wait %p %d/2 (%d)", (void *)&barrier->await, barrier->count, timeout); #endif Condition_TimedWait(&barrier->await, 1); timeout--; if ((timeout == 0) && (barrier->count != 2)) { fprintf(stdout, "Barrier timeout per full duplex traffic\n"); Condition_Unlock(barrier->await); return -1; } } barrier->count=0; } Condition_Unlock(barrier->await); return rc; } int fullduplex_start_barrier (struct BarrierMutex *barrier) { int rc = fullduplex_startstop_barrier(barrier); #ifdef HAVE_THREAD_DEBUG thread_debug("Fullduplex start barrier done on condition %p rc=%d", (void *)&barrier->await, rc); #endif return rc; } int fullduplex_stop_barrier (struct BarrierMutex *barrier) { int rc = fullduplex_startstop_barrier(barrier); #ifdef HAVE_THREAD_DEBUG thread_debug("Fullduplex stop barrier done on condition %p rc=%d", (void *)&barrier->await, rc); #endif return rc; } /* * listener_spawn is responsible for creating a Listener class * and launching the listener. It is provided as a means for * the C thread subsystem to launch the listener C++ object. */ void listener_spawn(struct thread_Settings *thread) { Listener *theListener = NULL; // the Listener need to trigger a settings report setReport(thread); // start up a listener theListener = new Listener(thread); // Start listening theListener->Run(); DELETE_PTR(theListener); } /* * server_spawn is responsible for creating a Server class * and launching the server. It is provided as a means for * the C thread subsystem to launch the server C++ object. */ void server_spawn(struct thread_Settings *thread) { Server *theServer = NULL; #ifdef HAVE_THREAD_DEBUG if (isBounceBack(thread)) { thread_debug("spawn server bounce-back"); } else { thread_debug("spawn server settings=%p GroupSumReport=%p sock=%d", \ (void *) thread, (void *)thread->mSumReport, thread->mSock); } #endif // set traffic thread to realtime if needed #if HAVE_SCHED_SETSCHEDULER thread_setscheduler(thread); #endif // Start up the server theServer = new Server(thread); if (isTxStartTime(thread)) { clock_usleep_abstime(&thread->txstart_epoch); } // Run the test if (isUDP(thread)) { theServer->RunUDP(); } else { if (isBounceBack(thread)) { theServer->RunBounceBackTCP(); } else { theServer->RunTCP(); } } DELETE_PTR(theServer); } static void clientside_client_basic (struct thread_Settings *thread, Client *theClient) { setTransferID(thread, 0); #ifdef HAVE_THREAD_DEBUG if (isBounceBack(thread)) { thread_debug("Launch: spawn client bounce-back mode, size = %d", thread->mBurstSize); } else { thread_debug("Launch: client spawn thread basic (sock=%d)", thread->mSock); } #endif SockAddr_remoteAddr(thread); // Bounceback start delays the connect too if (isBounceBack(thread)) { if (isTxStartTime(thread)) { theClient->mySockInit(); clock_usleep_abstime(&thread->txstart_epoch); } else if (isTxHoldback(thread)) { unsetTxHoldback(thread); theClient->mySockInit(); clock_usleep(&thread->txholdback_timer); } } theClient->my_connect(true); if ((thread->mThreads > 1) && !isNoConnectSync(thread) && !isCompat(thread)) // When -P > 1 then all threads finish connect before starting traffic theClient->BarrierClient(thread->connects_done); if (theClient->isConnected()) { if ((thread->mThreads > 1) || isSumOnly(thread)) Iperf_push_host(thread); theClient->StartSynch(); theClient->Run(); } } static void clientside_client_reverse (struct thread_Settings *thread, \ struct thread_Settings *reverse_client, Client *theClient) { setTransferID(thread, 0); SockAddr_remoteAddr(thread); theClient->my_connect(true); #ifdef HAVE_THREAD_DEBUG thread_debug("Launch: client spawn thread reverse (sock=%d)", thread->mSock); #endif if ((thread->mThreads > 1) && !isNoConnectSync(thread)) // When -P > 1 then all threads finish connect before starting traffic theClient->BarrierClient(thread->connects_done); if (theClient->isConnected()) { FAIL((!reverse_client || !(thread->mSock > 0)), "Reverse test failed to start per thread settings or socket problem", thread); setTransferID(reverse_client, 1); theClient->StartSynch(); reverse_client->mSock = thread->mSock; // use the same socket for both directions reverse_client->mThreadMode = kMode_Server; setReverse(reverse_client); setNoUDPfin(reverse_client); // disable the fin report - no need reverse_client->size_local = sizeof(iperf_sockaddr); getsockname(reverse_client->mSock, reinterpret_cast(&reverse_client->local), &reverse_client->size_local); if ((thread->mThreads > 1) || isSumOnly(thread)) Iperf_push_host(reverse_client); thread_start(reverse_client); if (theClient->myJob) FreeReport(theClient->myJob); } } static void clientside_client_fullduplex (struct thread_Settings *thread, \ struct thread_Settings *reverse_client, Client *theClient) { setTransferID(thread, 0); SockAddr_remoteAddr(thread); if (!isBounceBack(thread)) { thread->mFullDuplexReport = InitSumReport(thread, -1, 1); } Settings_Copy(thread, &reverse_client, SHALLOW_COPY); if ((thread->mThreads > 1) || isSumOnly(thread) || \ (!(thread->mThreads > 1) && !isEnhanced(thread))) { Iperf_push_host(thread); Iperf_push_host(reverse_client); } assert(reverse_client != NULL); setTransferID(reverse_client, 1); theClient->my_connect(true); #ifdef HAVE_THREAD_DEBUG thread_debug("Launch: client spawn thread fullduplex (sock=%d)", thread->mSock); #endif if ((thread->mThreads > 1) && !isNoConnectSync(thread)) // When -P > 1 then all threads finish connect before starting traffic theClient->BarrierClient(thread->connects_done); if (theClient->isConnected()) { thread->mFullDuplexReport->info.common->socket = thread->mSock; FAIL((!reverse_client || !(thread->mSock > 0)), "Reverse test failed to start per thread settings or socket problem", thread); reverse_client->mSock = thread->mSock; // use the same socket for both directions reverse_client->mThreadMode = kMode_Server; setReverse(reverse_client); if (isModeTime(reverse_client)) { reverse_client->mAmount += (SLOPSECS * 100); // add 2 sec for slop on reverse, units are 10 ms } thread_start(reverse_client); if (theClient->StartSynch() != -1) { theClient->Run(); } } } static void serverside_client_fullduplex (struct thread_Settings *thread, Client *theClient) { #ifdef HAVE_THREAD_DEBUG thread_debug("Launch: Listener spawn client thread (fd sock=%d)", thread->mSock); #endif setTransferID(thread, 1); if (theClient->StartSynch() != -1) { theClient->Run(); } } static void serverside_client_bidir (struct thread_Settings *thread, Client *theClient) { #ifdef HAVE_THREAD_DEBUG thread_debug("Launch: Listener spawn client thread (bidir sock=%d)", thread->mSock); #endif setTransferID(thread, 1); SockAddr_zeroAddress(&thread->peer); SockAddr_remoteAddr(thread); if (thread->mReportMode == kReport_CSV) { setNoSettReport(thread); setNoConnReport(thread); } else { unsetNoSettReport(thread); unsetNoConnReport(thread); } setReport(thread); theClient->my_connect(false); if (theClient->isConnected()) { Iperf_push_host(thread); if (theClient->StartSynch() != -1) { theClient->Run(); } } } /* * client_spawn is responsible for creating a Client class * and launching the client. It is provided as a means for * the C thread subsystem to launch the client C++ object. * * There are a few different client startup modes * o) Normal * o) Dual (-d or -r) (legacy) * o) Reverse (Client side) (client acts like server) * o) FullDuplex (Client side) client starts server * o) ServerReverse (Server side) (listener starts a client) * o) FullDuplex (Server side) (listener starts server & client) * o) WriteAck * * Note: This runs in client thread context */ void client_spawn (struct thread_Settings *thread) { Client *theClient = NULL; // set traffic thread to realtime if needed #if HAVE_SCHED_SETSCHEDULER thread_setscheduler(thread); #endif // start up the client setTransferID(thread, 0); theClient = new Client(thread); // let the reporter thread go first in the case of -P greater than 1 Condition_Lock(reporter_state.await); while (!reporter_state.ready) { Condition_TimedWait(&reporter_state.await, 1); } Condition_Unlock(reporter_state.await); if (isConnectOnly(thread)) { theClient->ConnectPeriodic(); } else if (!isServerReverse(thread)) { // These are the client side spawning of clients if (!isReverse(thread) && !isFullDuplex(thread)) { clientside_client_basic(thread, theClient); } else if (isReverse(thread) && !isFullDuplex(thread)) { struct thread_Settings *reverse_thread = NULL; Settings_Copy(thread, &reverse_thread, DEEP_COPY); FAIL((reverse_thread == NULL), "Reverse thread alloc failed", thread); clientside_client_reverse(thread, reverse_thread, theClient); } else if (isFullDuplex(thread)) { struct thread_Settings *reverse_thread = NULL; Settings_Copy(thread, &reverse_thread, DEEP_COPY); FAIL((reverse_thread == NULL), "Reverse in full-duplex thread alloc failed", thread); clientside_client_fullduplex(thread, reverse_thread, theClient); } else { fprintf(stdout, "Program error in client side client_spawn"); _exit(-1); } } else { if (thread->mMode != kTest_Normal) { setCompat(thread); // These are the server or listener side spawning of clients serverside_client_bidir(thread, theClient); } else { serverside_client_fullduplex(thread, theClient); } } // Call the client's destructor DELETE_PTR(theClient); } /* * client_init handles multiple threaded connects. It creates * a listener object if either the dual test or tradeoff were * specified. It also creates settings structures for all the * threads and arranges them so they can be managed and started * via the one settings structure that was passed in. * * Note: This runs in main thread context */ void client_init(struct thread_Settings *clients) { struct thread_Settings *itr = NULL; struct thread_Settings *next = NULL; itr = clients; setReport(clients); // See if we need to start a listener as well Settings_GenerateListenerSettings(clients, &next); #ifdef HAVE_THREAD if (next != NULL) { // We have threads and we need to start a listener so // have it ran before the client is launched itr->runNow = next; itr = next; } // For each of the needed threads create a copy of the // provided settings, unsetting the report flag and add // to the list of threads to start for (int i = 1; i < clients->mThreads; i++) { Settings_Copy(clients, &next, DEEP_COPY); // printf("*****port/thread = %d/%d\n", next->mPort + i, i); if (next) { if (isIncrSrcIP(clients) && (clients->mLocalhost != NULL)) { next->incrsrcip = i; } if (isIncrDstIP(clients)) { next->incrdstip = i; // force a setHostname SockAddr_zeroAddress(&next->peer); } else if (clients->mBindPort) { // Increment the source port of none of the quintuple is being change or the user requests it if ((!isIncrDstPort(clients) && !isIncrDstIP(clients) && !isIncrSrcIP(clients)) || isIncrSrcPort(clients)) { // case -B with src port and -P > 1 next->incrsrcport = i; } } if (isIncrDstPort(clients)) { next->mPort += i; SockAddr_zeroAddress(&next->peer); } } itr->runNow = next; itr = next; } if ((isBounceBack(clients) || isConnectOnly(clients) || isPeriodicBurst(clients)) \ && (isWorkingLoadUp(clients) || isWorkingLoadDown(clients))) { int working_load_threads = (clients->mWorkingLoadThreads == 0) ? 1 : clients->mWorkingLoadThreads; while (working_load_threads--) { Settings_Copy(clients, &next, DEEP_COPY); if (next != NULL) { unsetBounceBack(next); unsetConnectOnly(next); unsetPeriodicBurst(next); unsetTxHoldback(next); // don't delay working load threads next->mTOS = 0; // disable any QoS on the congestion stream #if HAVE_DECL_TCP_NOTSENT_LOWAT next->mWritePrefetch = SMALL_WRITE_PREFETCH; setWritePrefetch(next); #endif if (isWorkingLoadUp(clients) && isWorkingLoadDown(clients)) { setFullDuplex(next); } else if (isWorkingLoadDown(clients)) { setReverse(next); } if (isBounceBack(clients) && (clients->mWorkingLoadThreads > 1)) { Iperf_push_host(clients); } // Bump the bounceback time to include the delay time if (next->txholdback_timer.tv_sec || next->txholdback_timer.tv_usec) { // mAmount units are 10 ms next->mAmount += (next->txholdback_timer.tv_sec * 100); next->mAmount += (next->txholdback_timer.tv_usec / 10000); } itr->runNow = next; itr = next; } } } #else if (next != NULL) { // We don't have threads and we need to start a listener so // have it ran after the client is finished itr->runNext = next; } #endif } void listeners_init(struct thread_Settings *listener) { struct thread_Settings *itr = listener; struct thread_Settings *next = NULL; for (int ix = 1; ix < (listener->mPortLast - listener->mPort + 1); ix++) { Settings_Copy(listener, &next, DEEP_COPY); if (next != NULL) { setNoSettReport(next); next->mPort = listener->mPort + ix; next->mThreadMode = kMode_Listener; itr->runNow = next; itr = next; } } }