// taskFunction: Task Function.
// arg: argument that will be passed to taskFunction.
void Execute(TaskFunction taskFunction, void *arg) {
if (corePoolSize_ > currentThreads_) {
NewThread();
std::cout << "if (corePoolSize_ > currentThreads_) {" << '\n';
} else if (currentThreads_ < maximumPoolSize_ && taskQueueSize_ + 1 > currentThreads_) {
NewThread();
std::cout << "} else if (currentThreads_ < maximumPoolSize_ && taskQueueSize_ + 1 > currentThreads_) {" << '\n';
}
Task newTask;
newTask.taskFunction = taskFunction;
newTask.arg = arg;
while (!taskQueue_.push(newTask))
;
// std::cout<<"push task ok.\n";
++ taskQueueSize_;
conditionVariable_.notify_one();
// conditionVariable_.notify_all();
std::cout<<"notify.\n";
}
// Initialize the IPsec server
IPSEC_SERVER *NewIPsecServer(CEDAR *cedar)
{
IPSEC_SERVER *s;
// Validate arguments
if (cedar == NULL)
{
return NULL;
}
s = ZeroMalloc(sizeof(IPSEC_SERVER));
s->LockSettings = NewLock();
s->Cedar = cedar;
AddRef(s->Cedar->ref);
s->L2TP = NewL2TPServer(cedar);
s->Ike = NewIKEServer(cedar, s);
StrCpy(s->Ike->Secret, sizeof(s->Ike->Secret), IPSEC_DEFAULT_SECRET);
s->UdpListener = NewUdpListener(IPsecServerUdpPacketRecvProc, s, &cedar->Server->ListenIP);
s->EtherIPIdList = NewList(CmpEtherIPId);
// Start an OS service monitoring thread
s->OsServiceCheckThreadEvent = NewEvent();
s->OsServiceCheckThread = NewThread(IPsecOsServiceCheckThread, s);
return s;
}
// Initialize the packet adapter
bool LinkPaInit(SESSION *s)
{
LINK *k;
THREAD *t;
// Validate arguments
if (s == NULL || (k = (LINK *)s->PacketAdapter->Param) == NULL)
{
return false;
}
if (k->Halting || (*k->StopAllLinkFlag))
{
return false;
}
// Create a transmission packet queue
k->SendPacketQueue = NewQueue();
// Creat a link server thread
t = NewThread(LinkServerSessionThread, (void *)k);
WaitThreadInit(t);
k->LastServerConnectionReceivedBlocksNum = 0;
k->CurrentSendPacketQueueSize = 0;
ReleaseThread(t);
return true;
}
bool wxThreadInternal::Create(wxThread *thread, unsigned int stackSize)
{
if ( s_threadEntry == NULL )
{
s_threadEntry = NewThreadEntryUPP( (ThreadEntryProcPtr) MacThreadStart ) ;
}
OSErr err = NewThread( kCooperativeThread,
s_threadEntry,
(void*) thread,
stackSize,
kNewSuspend,
&m_result,
&m_tid );
if ( err != noErr )
{
wxLogSysError(_("Can't create thread"));
return FALSE;
}
if ( m_priority != WXTHREAD_DEFAULT_PRIORITY )
{
SetPriority(m_priority);
}
m_state = STATE_NEW;
return TRUE;
}
// Restarting the server
void EiRebootServer()
{
THREAD *t;
t = NewThread(EiRebootServerThread, NULL);
ReleaseThread(t);
}
// Create a new SecureNAT
SNAT *SnNewSecureNAT(HUB *h, VH_OPTION *o)
{
SNAT *s;
THREAD *t;
// Validate arguments
if (h == NULL || o == NULL)
{
return NULL;
}
s = ZeroMalloc(sizeof(SNAT));
s->Cedar = h->Cedar;
s->Hub = h;
s->lock = NewLock();
// Create a NAT
s->Nat = NiNewNatEx(s, o);
// Initialize the virtual machine
VirtualInit(s->Nat->Virtual);
// Create a thread
t = NewThread(SnSecureNATThread, s);
WaitThreadInit(t);
ReleaseThread(t);
return s;
}
// Initialize the packet adapter
bool NullPaInit(SESSION *s)
{
NULL_LAN *n;
static UINT id_seed = 0;
// Validate arguments
if (s == NULL)
{
return false;
}
id_seed++;
n = ZeroMalloc(sizeof(NULL_LAN));
n->Id = id_seed;
s->PacketAdapter->Param = (void *)n;
n->Cancel = NewCancel();
n->PacketQueue = NewQueue();
n->Event = NewEvent();
NullGenerateMacAddress(n->MacAddr, n->Id, 0);
n->PacketGeneratorThread = NewThread(NullPacketGenerateThread, n);
return true;
}
// Start a Layer-3 switch
void L3SwStart(L3SW *s)
{
// Validate arguments
if (s == NULL)
{
return;
}
Lock(s->lock);
{
if (s->Active == false)
{
// Start if there is registered interface
if (LIST_NUM(s->IfList) >= 1)
{
s->Halt = false;
// Create a thread
s->Thread = NewThread(L3SwThread, s);
WaitThreadInit(s->Thread);
}
}
}
Unlock(s->lock);
}
// Create new VPN Azure client
AZURE_CLIENT *NewAzureClient(CEDAR *cedar, SERVER *server)
{
AZURE_CLIENT *ac;
// Validate arguments
if (cedar == NULL || server == NULL)
{
return NULL;
}
ac = ZeroMalloc(sizeof(AZURE_CLIENT));
ac->Cedar = cedar;
ac->Server = server;
ac->Lock = NewLock();
ac->IsEnabled = false;
ac->Event = NewEvent();
// Start main thread
ac->MainThread = NewThread(AcMainThread, ac);
return ac;
}
// Jump here if there is accepted connection in the TCP
void TCPAccepted(LISTENER *r, SOCK *s)
{
TCP_ACCEPTED_PARAM *data;
THREAD *t;
char tmp[MAX_SIZE];
UINT num_clients_from_this_ip = 0;
CEDAR *cedar;
// Validate arguments
if (r == NULL || s == NULL)
{
return;
}
cedar = r->Cedar;
num_clients_from_this_ip = GetNumIpClient(&s->RemoteIP);
IPToStr(tmp, sizeof(tmp), &s->RemoteIP);
data = ZeroMalloc(sizeof(TCP_ACCEPTED_PARAM));
data->r = r;
data->s = s;
if (r->ThreadProc == TCPAcceptedThread)
{
Inc(cedar->AcceptingSockets);
}
t = NewThread(r->ThreadProc, data);
WaitThreadInit(t);
Free(data);
ReleaseThread(t);
}
NetDownloader *FD_LoadPlugin()
{
FileDownload *dnload;
NetDownloader *plug = malloc(sizeof(NetDownloader));
memset(plug, 0, sizeof(NetDownloader));
M4_REG_PLUG(plug, M4FILEDOWNLOADER, "HTTP Downloader", "gpac distribution", 0);
plug->CanHandleURL = FD_CanHandleURL;
plug->GetMimeType = FD_GetMimeType;
plug->Connect = FD_Connect;
plug->FetchData = FD_FetchData;
plug->Close= FD_Close;
plug->GetCacheFileName = FD_GetCacheFileName;
dnload = malloc(sizeof(FileDownload));
memset(dnload, 0, sizeof(FileDownload));
dnload->service_thread = NewThread();
plug->net_status = DL_Unavailable;
plug->priv = dnload;
/*also init clock*/
M4_InitClock();
return plug;
}
BaseDecoder *NewISCodec(u32 PL)
{
ISPriv *priv;
SceneDecoder *tmp;
tmp = (SceneDecoder*) malloc(sizeof(SceneDecoder));
if (!tmp) return NULL;
memset(tmp, 0, sizeof(SceneDecoder));
priv = (ISPriv *) malloc(sizeof(ISPriv));
memset(priv, 0, sizeof(ISPriv));
priv->is_nodes = NewChain();
priv->ddf = NewChain();
tmp->privateStack = priv;
tmp->AttachStream = IS_AttachStream;
tmp->DetachStream = IS_DetachStream;
tmp->GetCapabilities = IS_GetCapabilities;
tmp->SetCapabilities = IS_SetCapabilities;
tmp->ProcessData = IS_ProcessData;
/*we don't use this...*/
tmp->AttachScene = NULL;
M4_REG_PLUG(tmp, M4SCENEDECODERINTERFACE, "GPAC InputSensor Decoder", "gpac distribution", 0)
#if M4_HTK_DEMO
priv->th = NewThread();
#endif
return (BaseDecoder *) tmp;
}
// Create a new stack
NATIVE_STACK *NewNativeStack(CEDAR *cedar, char *device_name, char *mac_address_seed)
{
ETH *eth;
NATIVE_STACK *a;
IP localhost;
char tmp[64];
bool release_cedar = false;
// Validate arguments
if (device_name == NULL || mac_address_seed == NULL)
{
return NULL;
}
GetLocalHostIP4(&localhost);
// Open the Eth device
eth = OpenEth(device_name, false, false, NULL);
if (eth == NULL)
{
return NULL;
}
if (cedar == NULL)
{
cedar = NewCedar(NULL, NULL);
release_cedar = true;
}
a = ZeroMalloc(sizeof(NATIVE_STACK));
NewSocketPair(&a->Sock1, &a->Sock2, &localhost, 1, &localhost, 1);
a->Cedar = cedar;
AddRef(a->Cedar->ref);
NsGenMacAddress(a->MacAddress, mac_address_seed, device_name);
BinToStr(tmp, sizeof(tmp), a->MacAddress, sizeof(a->MacAddress));
Debug("NewNativeStack: MAC Address = %s\n", tmp);
a->Ipc = NewIPCBySock(cedar, a->Sock2, a->MacAddress);
StrCpy(a->DeviceName, sizeof(a->DeviceName), device_name);
a->Eth = eth;
a->Cancel = EthGetCancel(eth);
a->MainThread = NewThread(NsMainThread, a);
if (release_cedar)
{
ReleaseCedar(cedar);
}
a->IsIpRawMode = a->Eth->IsRawIpMode;
return a;
}
Worker* NewWorker(char* pipeName, aio4c_size_t bufferSize) {
Worker* worker = NULL;
ErrorCode code = AIO4C_ERROR_CODE_INITIALIZER;
if ((worker = aio4c_malloc(sizeof(Worker))) == NULL) {
#ifndef AIO4C_WIN32
code.error = errno;
#else /* AIO4C_WIN32 */
code.source = AIO4C_ERRNO_SOURCE_SYS;
#endif /* AIO4C_WIN32 */
code.size = sizeof(Worker);
code.type = "Worker";
Raise(AIO4C_LOG_LEVEL_ERROR, AIO4C_ALLOC_ERROR_TYPE, AIO4C_ALLOC_ERROR, &code);
return NULL;
}
worker->queue = NULL;
worker->pool = NULL;
worker->writer = NULL;
worker->bufferSize = bufferSize;
if (pipeName != NULL) {
worker->pipe = pipeName;
worker->name = aio4c_malloc(strlen(pipeName) + 1 + 7);
if (worker->name != NULL) {
snprintf(worker->name, strlen(pipeName) + 1 + 7, "%s-worker", pipeName);
}
} else {
worker->pipe = NULL;
worker->name = NULL;
}
worker->thread = NewThread(
worker->name,
_WorkerInit,
_WorkerRun,
_WorkerExit,
(ThreadData)worker);
if (worker->thread == NULL) {
if (worker->name != NULL) {
aio4c_free(worker->name);
}
aio4c_free(worker);
return NULL;
}
if (!ThreadStart(worker->thread)) {
if (worker->name != NULL) {
aio4c_free(worker->name);
}
aio4c_free(worker);
return NULL;
}
return worker;
}
void
CPoolOfThreads_ForServer::Spawn(unsigned int num_threads)
{
for (unsigned int i = 0; i < num_threads; i++)
{
CRef<TThread> thr(NewThread());
thr->CountSelf();
thr->Run();
}
}
void
NsThreadMain(void *arg)
{
ThreadArg *argPtr = arg;
Thread *thrPtr;
thrPtr = NewThread(argPtr);
ns_free(argPtr);
(*thrPtr->proc) (thrPtr->arg);
}
// Start the download thread
void ViDownloadThreadStart(VI_INSTALL_DLG *d)
{
// Validate arguments
if (d == NULL)
{
return;
}
d->DownloadStarted = true;
d->DownloadThread = NewThread(ViDownloadThread, d);
}
static Thread *
GetThread(void)
{
Thread *thrPtr;
thrPtr = Ns_TlsGet(&key);
if (thrPtr == NULL) {
thrPtr = NewThread(NULL);
}
return thrPtr;
}
static Thread *
GetThread(void)
{
Thread *thrPtr;
thrPtr = pthread_getspecific(key);
if (thrPtr == NULL) {
thrPtr = NewThread();
SetKey("NsGetTls", thrPtr);
}
return thrPtr;
}
DWORD CWorker::CThreadWormThread::ThreadMain (PVOID lpParameter) {
CTrace::CEnter Enter(CTrace::Layer::CODINE, L"Worker::ThreadWormThread::ThreadMain(PVOID)");
static const DWORD dwLifetime = 2000;
CWorker *TheWorker = (CWorker*)lpParameter;
if (!TheWorker->m_bExit) {
Sleep(TheWorker->m_dwDelay);
CThreadWormThread NewThread(lpParameter);
NewThread.Resume();
Sleep(dwLifetime);
}
return 0;
}
// 管理コマンド受付初期化
void NiInitAdminAccept(NAT *n)
{
THREAD *t;
// 引数チェック
if (n == NULL)
{
return;
}
t = NewThread(NiListenThread, n);
WaitThreadInit(t);
n->AdminAcceptThread = t;
}
// Initialize receiving management command
void NiInitAdminAccept(NAT *n)
{
THREAD *t;
// Validate arguments
if (n == NULL)
{
return;
}
t = NewThread(NiListenThread, n);
WaitThreadInit(t);
n->AdminAcceptThread = t;
}
// アダプタを開く (Pcap)
ETH *OpenEthPcap(char *name, bool local, bool tapmode, char *tapaddr)
{
char errbuf[PCAP_ERRBUF_SIZE];
ETH *e;
pcap_t *p;
CANCEL *c;
// 引数チェック
if (name == NULL || tapmode != false)
{
return NULL;
}
// エラーメッセージバッファの初期化
errbuf[0] = 0;
// キャプチャデバイスを開く
p = pcap_open_live(name, 65535, (local == false), 1, errbuf);
if(p==NULL)
{
return NULL;
}
// ノンブロックモードに設定
// BSD系OSでは、BPFのselectが正常に動作しないのでブロックさせないとビジーループになる
/*
if(pcap_setnonblock(p, true, errbuf) == -1)
{
Debug("pcap_setnonblock:%s\n",errbuf);
pcap_close(p);
return NULL;
}
*/
e = ZeroMalloc(sizeof(ETH));
e->Name = CopyStr(name);
e->Title = CopyStr(name);
e->Queue = NewQueue();
e->QueueSize = 0;
e->Cancel = NewCancel();
e->IfIndex = -1;
e->Socket = pcap_get_selectable_fd(p);
e->Pcap = p;
e->CaptureThread = NewThread(PcapThread, e);
WaitThreadInit(e->CaptureThread);
return e;
}
// Open Ethernet adapter (Pcap)
ETH *OpenEthPcap(char *name, bool local, bool tapmode, char *tapaddr)
{
char errbuf[PCAP_ERRBUF_SIZE];
ETH *e;
pcap_t *p;
CANCEL *c;
// Validate arguments
if (name == NULL || tapmode != false)
{
return NULL;
}
// Initialize error message buffer
errbuf[0] = 0;
// Open capturing device
p = pcap_open_live(name, 65535, (local == false), 1, errbuf);
if(p==NULL)
{
return NULL;
}
// Set to non-block mode
// (In old BSD OSs, 'select(2)' don't block normally for BPF device. To prevent busy loop)
/*
if(pcap_setnonblock(p, true, errbuf) == -1)
{
Debug("pcap_setnonblock:%s\n",errbuf);
pcap_close(p);
return NULL;
}
*/
e = ZeroMalloc(sizeof(ETH));
e->Name = CopyStr(name);
e->Title = CopyStr(name);
e->Queue = NewQueue();
e->QueueSize = 0;
e->Cancel = NewCancel();
e->IfIndex = -1;
e->Socket = pcap_get_selectable_fd(p);
e->Pcap = p;
e->CaptureThread = NewThread(PcapThread, e);
WaitThreadInit(e->CaptureThread);
return e;
}
int ThreadCreate(ThreadData* aThreadData, void* aThreadId)
{
HarnessThread threadId;
int retval=0;
if(aThreadData->iSelf != EThreadMain)
{
retval = KNoPermission;
}
else
{
threadId = (HarnessThread)(int) aThreadId;
retval = NewThread(aThreadData,threadId);
}
return retval;
}
Boolean
SpawnSDThread(ThreadEntryProcPtr threadProc, ThreadID *tid)
{
OSErr err;
err = NewThread(kCooperativeThread, (ThreadEntryProcPtr)threadProc, (void*) nil,
0, kCreateIfNeeded, (void**)nil, tid);
// ^---- 0 means gimme the default stack size from Thread Manager
if (err == noErr)
YieldToThread(*tid); /* force ctx switch */
else
{
return false;
}
return true;
}
void ServerSocketListen(AbstractServerSocket abstractSocket, void ( onConnect)(void *)) {
abstractSocket->address_size = sizeof abstractSocket->pin;
while (1) {
abstractSocket->temp_sock_descriptor = accept(
abstractSocket->sock_descriptor,
(struct sockaddr *) &(abstractSocket->pin),
&(abstractSocket->address_size));
if (abstractSocket->temp_sock_descriptor == -1) {
perror("llamada para aceptar");
exit(1);
}
printf("Conexion aceptada ... \n");
AbstractThread threadConexion = NewThread();
runWithParam(threadConexion, onConnect,
(void *) NewClientConnection(abstractSocket->temp_sock_descriptor));
}
}
TestingSetup() {
fPrintToDebugger = true; // don't want to write to debug.log file
noui_connect();
bitdb.MakeMock();
pathTemp = GetTempPath() / strprintf("test_bytecoin_%lu_%i", (unsigned long)GetTime(), (int)(GetRand(100000)));
boost::filesystem::create_directories(pathTemp);
mapArgs["-datadir"] = pathTemp.string();
pblocktree = new CBlockTreeDB(1 << 20, true);
pcoinsdbview = new CCoinsViewDB(1 << 23, true);
pcoinsTip = new CCoinsViewCache(*pcoinsdbview);
InitBlockIndex();
bool fFirstRun;
pwalletMain = new CWallet("wallet.dat");
pwalletMain->LoadWallet(fFirstRun);
RegisterWallet(pwalletMain);
nScriptCheckThreads = 3;
for (int i=0; i < nScriptCheckThreads-1; i++)
NewThread(ThreadScriptCheck, NULL);
}
// Initialization of the Tick64
void InitTick64()
{
if (tk64 != NULL)
{
// Already initialized
return;
}
halt_tick_event = NewEvent();
// Initialize the structure
tk64 = ZeroMalloc(sizeof(TICK64));
tk64->TickLock = NewLock();
tk64->AdjustTime = NewList(NULL);
// Creating a thread
tk64->Thread = NewThread(Tick64Thread, NULL);
WaitThreadInit(tk64->Thread);
}
// Creating a DDNS client
DDNS_CLIENT *NewDDNSClient(CEDAR *cedar, UCHAR *key, INTERNET_SETTING *t)
{
DDNS_CLIENT *c;
UCHAR key_hash[SHA1_SIZE];
// Validate arguments
if (cedar == NULL)
{
return NULL;
}
c = ZeroMalloc(sizeof(DDNS_CLIENT));
c->Cedar = cedar;
AddRef(c->Cedar->ref);
c->Err_IPv4 = c->Err_IPv6 = ERR_TRYING_TO_CONNECT;
if (key == NULL)
{
// Create a new key
DCGenNewKey(c->Key);
}
else
{
// Set the key
Copy(c->Key, key, SHA1_SIZE);
}
HashSha1(key_hash, c->Key, sizeof(c->Key));
if (t != NULL)
{
Copy(&c->InternetSetting, t, sizeof(INTERNET_SETTING));
}
c->Lock = NewLock();
// Thread creation
c->Event = NewEvent();
c->Thread = NewThread(DCThread, c);
return c;
}
