DVD_RESP_TYPE CDVDongleController::getResponse(unsigned char* buffer, unsigned int length)
{
wxASSERT(buffer != NULL);
wxASSERT(length >= DVD_AUDIO_LENGTH_BYTES);
unsigned char c1, c2;
int len = m_controller->read(&c1, 1U);
if (len == 0)
return DVDRT_NONE;
if (len < 0) {
wxLogError(wxT("Unable to receive the DVD header: len=%d"), len);
return DVDRT_ERROR;
}
switch (c1) {
case 0xA0U: // DVD_AMBE_HEADER
wxLogMessage(wxT("Re-synchronising with the DV-Dongle"));
buffer[0U] = 0x32U;
buffer[1U] = c1;
return processResponse(buffer, length);
case 0x81U: // DVD_AUDIO_HEADER
wxLogMessage(wxT("Re-synchronising with the DV-Dongle"));
buffer[0U] = 0x42U;
buffer[1U] = c1;
return processResponse(buffer, length);
default:
m_controller->read(&c2, 1U);
buffer[0U] = c1;
buffer[1U] = c2;
return processResponse(buffer, length);
}
}
void LocalClient::run()
{
QLocalSocket *socket = new QLocalSocket(this);
socket->connectToServer("/tmp/testservice");
if (!socket->waitForConnected()) {
qDebug() << "could not connect to server: " << socket->errorString();
return;
}
m_client = new QJsonRpcSocket(socket, this);
QJsonRpcServiceReply *reply = m_client->invokeRemoteMethod("agent.testMethod");
connect(reply, SIGNAL(finished()), this, SLOT(processResponse()));
reply = m_client->invokeRemoteMethod("agent.testMethodWithParams", "one", false, 10);
connect(reply, SIGNAL(finished()), this, SLOT(processResponse()));
reply = m_client->invokeRemoteMethod("agent.testMethodWithVariantParams", "one", false, 10, QVariant(2.5));
connect(reply, SIGNAL(finished()), this, SLOT(processResponse()));
reply = m_client->invokeRemoteMethod("agent.testMethodWithParamsAndReturnValue", "matt");
connect(reply, SIGNAL(finished()), this, SLOT(processResponse()));
// test bulk messages
/*
QJsonRpcMessage first = QJsonRpcMessage::createRequest("agent.testMethodWithParamsAndReturnValue", "testSendMessage");
m_client->sendMessage(first);
QJsonRpcMessage second = QJsonRpcMessage::createRequest("agent.testMethodWithParamsAndReturnValue", "testSendMessages1");
QJsonRpcMessage third = QJsonRpcMessage::createRequest("agent.testMethodWithParamsAndReturnValue", "testSendMessages2");
m_client->sendMessage(QList<QJsonRpcMessage>() << second << third);
*/
}
void PowerMonitor::applyDefaultSettings() // U, note: CE must be disabled before sending U, and reenabled afterwards
{
//_cell << "AT+CGREG?" << crl << endl;
Serial << "CE0" <<crl;// stop CE
processResponse("CE0");
Serial << ")U" <<crl;// apply defaults
processResponse(")U");
Serial << "CE1" <<crl;// start CE
processResponse("CE1");
Serial.flush();
}
int PowerMonitor::iMaxSet(int channel,double value) // set the external RMS current corresponding to 250 mVpk input of the ADC (A2)(A4)
{
switch (channel)
{
case 1: // first channel
Serial << ")A2=+" << value <<crl;// set current when ADC reads maximum
return int(processResponse(")A2"));
// process response and determine return value
break;
case 2: // second channel
Serial << ")A4=+" << value <<crl;// set current when ADC reads maximum
return int(processResponse(")A4"));
break;
}
}
//********************************************************************************************************//
// Multi channel coommands
//********************************************************************************************************//
double PowerMonitor::Temperature(int channel) // returns temperature of internals (20),(60)
{
switch(channel)
{
case 1:
Serial << ")20?" << crl;// get channel 1 temperature
return processResponse(")20")+22;
break;
case 2:
Serial << ")60?" << crl;// get channel 2 temperature
return processResponse(")60")+22;
break;
}
}
double PowerMonitor::power(int channel) // returns active power second +WWW.www (27) (67)
{
switch(channel)
{
case 1:
Serial << ")27?" << crl;// get channel 1
return processResponse(")27");
break;
case 2:
Serial << ")67?" << crl;// get channel 2
return processResponse(")67");
break;
}
}
double PowerMonitor::powerFactor(int channel) // returns the power factor between -0.950 and 1 (2D) (6D)
{
switch(channel)
{
case 1:
Serial << ")2D?" << crl;// get channel 1
return processResponse(")2D");
break;
case 2:
Serial << ")6D?" << crl;// get channel 2
return processResponse(")6D");
break;
}
}
double PowerMonitor::irms(int channel) // returns rms Current +III.iii (2A) (6A)
{
switch(channel)
{
case 1:
Serial << ")2A?" << crl;// get channel 1
return processResponse(")2A");
break;
case 2:
Serial << ")6A?" << crl;// get channel 2
return processResponse(")6A");
break;
}
}
void TTRssFetcher::finishedSignIn()
{
Settings *s = Settings::instance();
if (!processResponse()) {
s->setSignedIn(false);
sessionId = "";
apiLevel = 0;
return;
} else {
s->setSignedIn(true);
#if QT_VERSION >= QT_VERSION_CHECK(5,0,0)
sessionId = jsonObj["content"].toObject()["session_id"].toString();
apiLevel = jsonObj["content"].toObject()["api_level"].toInt();
#else
sessionId = jsonObj["content"].toMap()["session_id"].toString();
apiLevel = jsonObj["content"].toMap()["api_level"].toInt();
#endif
if (busyType == Fetcher::CheckingCredentials) {
emit credentialsValid();
setBusy(false);
} else {
sendApiCall("getConfig", FETCHER_SLOT(finishedConfig));
}
}
}
void WiFlyRNXV::listenAndProcess(){
uint8_t resp=0;
if(uart.available()){
if(checkBufferResponse(NULL,5000)){
Serial.println("TCP OPEN");
Serial.print("RESP:");
resp=processResponse(true);
Serial.println(resp,DEC);
Serial.print("RECV:");
responseBuffer.trim();
Serial.println(responseBuffer);
//Send some data
uart.println(processActualResponse(resp));
if(checkBufferResponse("*CLOS*",5000)){
Serial.println("TCP CLOSE");
}
}
}
}
void EPDStreamer::post(const char *host, const char *path, const char *data)
{
if (connState != STATE_CONN_CONNECTED) {
return;
}
Serial.print("POST ");
Serial.print(path);
Serial.print(" data=");
Serial.println(data);
client.print("POST ");
client.print(path);
client.println(" HTTP/1.0");
client.print("Host: ");
client.println(host);
client.println("Connection: close");
client.println("Content-Type: application/x-www-form-urlencoded");
client.print("Content-Length: ");
client.println(strlen(data));
client.println();
client.print(data);
httpState = STATE_HTTP_HEADER_STATUS;
processResponse();
}
Controller::Controller()
try
: num_connect_attempts_ { 2 },
response_schema_ { getResponseMessageSchema() },
connector_ptr_ { new PCPClient::Connector { BROKER_URL,
CONTROLLER_CLIENT_TYPE,
CA,
CERT,
KEY } } {
// Connector::registerMessageCallback()
connector_ptr_->registerMessageCallback(
response_schema_,
[this](const PCPClient::ParsedChunks& parsed_chunks) {
processResponse(parsed_chunks);
});
connector_ptr_->setPCPErrorCallback(
[this](const PCPClient::ParsedChunks& parsed_chunks) {
processError(parsed_chunks);
});
} catch (PCPClient::connection_config_error& e) {
std::string err_msg { "failed to configure the PCP Connector: " };
throw controller_error { err_msg + e.what() };
}
//read data on the arduino
int CQboduinoDriver::read(cereal::CerealPort *port, std::string& read, long timeout)
{
std::string buf;
try
{
if(!port->readBetween(&buf,INPUT_FLAG,OUTPUT_FLAG,timeout))
{
return -1;
}
}
catch(const std::exception & e)
{
std::cerr<<"qboduino driver : exception while trying to read" << e.what();
return -1;
}
//check if packet is correct
int code=processResponse((uint8_t*)buf.c_str(),buf.size(),read);
if( code != 1) {
read.clear();
}
return code;
}
// Worker thread
void HttpClient::networkThreadAlone(HttpRequest* request, HttpResponse* response)
{
increaseThreadCount();
char responseMessage[RESPONSE_BUFFER_SIZE] = { 0 };
processResponse(response, responseMessage);
_schedulerMutex.lock();
if (nullptr != _scheduler)
{
_scheduler->performFunctionInCocosThread([this, response, request]{
const ccHttpRequestCallback& callback = request->getCallback();
Ref* pTarget = request->getTarget();
SEL_HttpResponse pSelector = request->getSelector();
if (callback != nullptr)
{
callback(this, response);
}
else if (pTarget && pSelector)
{
(pTarget->*pSelector)(this, response);
}
response->release();
// do not release in other thread
request->release();
});
}
_schedulerMutex.unlock();
decreaseThreadCountAndMayDeleteThis();
}
void Connection::readyRead()
{
while (m_socket && m_socket->bytesAvailable()) {
long length;
{
QByteArray data;
char c;
while(m_socket->getChar(&c)) {
if(c==0) break;
data.append(c);
}
length = data.toLong();
}
QByteArray data;
while (data.length() <= length) {
if (!data.isEmpty() && !m_socket->waitForReadyRead()) {
return;
}
data += m_socket->read(length - data.length() + 1);
}
//kDebug() << data;
QDomDocument doc;
doc.setContent(data);
if (doc.documentElement().tagName() == "init") {
processInit(doc);
} else if (doc.documentElement().tagName() == "response") {
processResponse(doc);
} else if (doc.documentElement().tagName() == "stream") {
processStream(doc);
} else {
//kWarning() << "unknown element" << xml->name();
}
}
}
int nuvotonTask(void * dummy)
{
daemonize("nuvotonTask");
allow_signal(SIGTERM);
while(1)
{
int dataAvailable = 0;
if (wait_event_interruptible(rx_wq, (RCVBufferStart != RCVBufferEnd)))
{
printk("wait_event_interruptible failed\n");
continue;
}
if (RCVBufferStart != RCVBufferEnd)
dataAvailable = 1;
while (dataAvailable)
{
processResponse();
if (RCVBufferStart == RCVBufferEnd)
dataAvailable = 0;
dprintk(150, "start %d end %d\n", RCVBufferStart, RCVBufferEnd);
}
}
printk("nuvotonTask died!\n");
return 0;
}
std::int32_t CmdAcknowledgeBailment::run(
std::string server,
std::string mynym,
std::string hisnym,
std::string mypurse)
{
if (!checkServer("server", server)) { return -1; }
if (!checkNym("mynym", mynym)) { return -1; }
if (!checkNym("hisnym", hisnym)) { return -1; }
std::string terms = inputText("Deposit instructions");
if (0 == terms.size()) { return -1; }
std::string response;
{
response = Opentxs::
Client()
.ServerAction()
.AcknowledgeBailment(
Identifier::Factory(mynym),
Identifier::Factory(server),
Identifier::Factory(hisnym),
Identifier::Factory(mypurse),
terms)
->Run();
}
return processResponse(response, "acknowledge bailment");
}
// Worker thread
void HttpClient::networkThreadAlone(HttpRequest* request)
{
// Create a HttpResponse object, the default setting is http access failed
HttpResponse *response = new (std::nothrow) HttpResponse(request);
char errorBuffer[CURL_ERROR_SIZE] = { 0 };
processResponse(response, errorBuffer);
auto scheduler = Director::getInstance()->getScheduler();
scheduler->performFunctionInCocosThread([response, request]{
const ccHttpRequestCallback& callback = request->getCallback();
Ref* pTarget = request->getTarget();
SEL_HttpResponse pSelector = request->getSelector();
if (callback != nullptr)
{
callback(s_pHttpClient, response);
}
else if (pTarget && pSelector)
{
(pTarget->*pSelector)(s_pHttpClient, response);
}
response->release();
// do not release in other thread
request->release();
});
}
void TTRssFetcher::finishedCategories()
{
if (!processResponse()) {
return;
}
startJob(StoreCategories);
}
void TTRssFetcher::finishedFeeds()
{
if (!processResponse()) {
return;
}
startJob(StoreFeeds);
}
void TTRssFetcher::finishedStream()
{
if (!processResponse()) {
return;
}
startJob(StoreStream);
}
double PowerMonitor::lineFrequency(int channel) // returns line freq in Hz.hz (21)(61)
{
double returnvalue ;
switch(channel)
{
case 1:
Serial << ")21?" << crl;// get channel 1 temperature
returnvalue = processResponse(")21");
return returnvalue;
break;
case 2:
Serial << ")61?" << crl;// get channel 2 temperature
returnvalue = processResponse(")61");
return returnvalue;
break;
}
}
void ofxTwitter::newResponse(ofxHttpResponse &response) {
data = processResponse(response);
// ok, send back results
if (delegate) {
delegate->searchResult(data, tweetQueryIdentifier);
}
}
void Client::listenFds(fd_set *bitField)
{
if (select((_socket > 0 ? _socket : 0) + 1, bitField, NULL, NULL, NULL) == -1)
throw std::exception();
if (FD_ISSET(STDIN_FILENO, bitField))
request_server();
else if (FD_ISSET(_socket, bitField))
processResponse();
}
double PowerMonitor::vrms(int channel) // returns rms Voltage +VVV.vvv (26) (66)
{
double returnvalue;
switch(channel)
{
case 1:
Serial << ")26?" << crl;// get channel 1
returnvalue = processResponse(")26");
return returnvalue;
break;
case 2:
Serial << ")66?" << crl;// get channel 2
returnvalue = processResponse(")66");
return returnvalue;
break;
}
}
// Worker thread
void HttpClient::networkThread()
{
increaseThreadCount();
while (true)
{
HttpRequest *request;
// step 1: send http request if the requestQueue isn't empty
{
std::lock_guard<std::mutex> lock(_requestQueueMutex);
while (_requestQueue.empty())
{
_sleepCondition.wait(_requestQueueMutex);
}
request = _requestQueue.at(0);
_requestQueue.erase(0);
}
if (request == _requestSentinel) {
break;
}
// step 2: libcurl sync access
// Create a HttpResponse object, the default setting is http access failed
HttpResponse *response = new (std::nothrow) HttpResponse(request);
processResponse(response, _responseMessage);
// add response packet into queue
_responseQueueMutex.lock();
_responseQueue.pushBack(response);
_responseQueueMutex.unlock();
_schedulerMutex.lock();
if (nullptr != _scheduler)
{
_scheduler->performFunctionInCocosThread(CC_CALLBACK_0(HttpClient::dispatchResponseCallbacks, this));
}
_schedulerMutex.unlock();
}
// cleanup: if worker thread received quit signal, clean up un-completed request queue
_requestQueueMutex.lock();
_requestQueue.clear();
_requestQueueMutex.unlock();
_responseQueueMutex.lock();
_responseQueue.clear();
_responseQueueMutex.unlock();
decreaseThreadCountAndMayDeleteThis();
}
// Worker thread
void HttpClient::networkThread()
{
auto scheduler = Director::getInstance()->getScheduler();
while (true)
{
HttpRequest *request;
// step 1: send http request if the requestQueue isn't empty
{
std::lock_guard<std::mutex> lock(s_requestQueueMutex);
while (s_requestQueue->empty()) {
s_SleepCondition.wait(s_requestQueueMutex);
}
request = s_requestQueue->at(0);
s_requestQueue->erase(0);
}
if (request == s_requestSentinel) {
break;
}
// step 2: libcurl sync access
// Create a HttpResponse object, the default setting is http access failed
HttpResponse *response = new (std::nothrow) HttpResponse(request);
processResponse(response, s_errorBuffer);
// add response packet into queue
s_responseQueueMutex.lock();
s_responseQueue->pushBack(response);
s_responseQueueMutex.unlock();
if (nullptr != s_pHttpClient) {
scheduler->performFunctionInCocosThread(CC_CALLBACK_0(HttpClient::dispatchResponseCallbacks, this));
}
}
// cleanup: if worker thread received quit signal, clean up un-completed request queue
s_requestQueueMutex.lock();
s_requestQueue->clear();
s_requestQueueMutex.unlock();
if (s_requestQueue != nullptr) {
delete s_requestQueue;
s_requestQueue = nullptr;
delete s_responseQueue;
s_responseQueue = nullptr;
}
}
KeyExchangeMessage SessionBuilder::process(QSharedPointer<KeyExchangeMessage> message)
{
if (!identityKeyStore->isTrustedIdentity(recipientId, message->getIdentityKey())) {
throw UntrustedIdentityException(QString("Untrusted identity: %1").arg(recipientId));
}
KeyExchangeMessage responseMessage;
if (message->isInitiate()) responseMessage = processInitiate(message);
else processResponse(message);
return responseMessage;
}
void HomeI2CMaster::read(uint8_t address, size_t messageSize, uint8_t messageID) {
uint8_t bytesReceived;
uint8_t retryCount = 0;
bool retry = true;
bool readSuccesful = true;
I2CMessage response;
DBUG_LOG(F("Receiving response: size, messageID"));
DBUG_LOG(messageSize);
DBUG_LOG(messageID);
while (retry) {
bytesReceived = 0;
DBUG_LOG(F("Request Attempt:"));
DBUG_LOG(retryCount+1);
Wire.requestFrom(address, messageSize);
DBUG_LOG(F("Response received"));
while (Wire.available()) {
if (bytesReceived == 0) {
response.messageID = Wire.read();
if (response.messageID != messageID) {
DBUG_LOG(F("mesageID invalid. retrying"));
DBUG_LOG(response.messageID);
retryCount++;
if (retryCount < I2C_TIMEOUT) {
delay(I2C_TIMEOUT_DELAY);
} else {
ERROR_LOG(F("I2C Timeout"));
readSuccesful = false;
retry = false;
}
} else {
DBUG_LOG(F("messageID valid:"));
DBUG_LOG(response.messageID);
retry = false;
}
} else {
if (bytesReceived <= MAX_I2C_MESSAGE_SIZE) {
response.buffer[bytesReceived-1] = Wire.read();
DBUG_LOG(F("Data received:"));
DBUG_LOG(response.buffer[bytesReceived-1], HEX);
}
}
bytesReceived++;
}
}
if (readSuccesful) {
processResponse(response);
} else {
peripheral->sendMessageNack(messageID);
}
}
void TTRssFetcher::finishedConfig()
{
if (!processResponse()) {
return;
}
#if QT_VERSION >= QT_VERSION_CHECK(5,0,0)
iconsUrl = jsonObj["content"].toObject()["icons_url"].toString();
#else
iconsUrl = jsonObj["content"].toMap()["icons_url"].toString();
#endif
prepareUploadActions();
}
