Example #1
0
void
SimpleProperties::Reader::printAll(NdbOut& ndbout){
  char tmp[1024];
  for(first(); valid(); next()){
    switch(getValueType()){
    case SimpleProperties::Uint32Value:
      ndbout << "Key: " << getKey()
             << " value(" << getValueLen() << ") : " 
             << getUint32() << endl;
      break;
    case SimpleProperties::BinaryValue:
    case SimpleProperties::StringValue:
      if(getValueLen() < 1024){
	getString(tmp);
	ndbout << "Key: " << getKey()
	       << " value(" << getValueLen() << ") : " 
	       << "\"" << tmp << "\"" << endl;
      } else {
	ndbout << "Key: " << getKey()
	       << " value(" << getValueLen() << ") : " 
	       << "\"" << "<TOO LONG>" << "\"" << endl;
	
      }
      break;
    default:
      ndbout << "Unknown type for key: " << getKey() 
             << " type: " << (Uint32)getValueType() << endl;
    }
  }
}
Example #2
0
uint64_t TraderApi::insertOrder(dict req, uint64_t sessionid)
{
	XTPOrderInsertInfo myreq = XTPOrderInsertInfo();
	memset(&myreq, 0, sizeof(myreq));
	getDouble(req, "stop_price", &myreq.stop_price);
	getDouble(req, "price", &myreq.price);
	getStr(req, "ticker", myreq.ticker);

	getUint32(req, "order_client_id", &myreq.order_client_id);
	getUint64(req, "order_xtp_id", &myreq.order_xtp_id);
	getInt64(req, "quantity", &myreq.quantity);

	int price_type;
	int side;
	int market;
	int business_type;
	getInt(req, "price_type", &price_type);
	getInt(req, "side", &side);
	getInt(req, "market", &market);
	getInt(req, "business_type", &business_type);
	myreq.price_type = (XTP_PRICE_TYPE)price_type;
	myreq.side = (XTP_SIDE_TYPE)side;
	myreq.market = (XTP_MARKET_TYPE)market;
	myreq.business_type = (XTP_BUSINESS_TYPE)business_type;

	return this->api->InsertOrder(&myreq, sessionid);
};
Example #3
0
// Defined by the WebCrypto spec as:
//
//    dictionary RsaKeyGenParams : Algorithm {
//      unsigned long modulusLength;
//      BigInteger publicExponent;
//    };
bool parseRsaKeyGenParams(const Dictionary& raw, uint32_t& modulusLength, RefPtr<Uint8Array>& publicExponent, const ErrorContext& context, String& errorDetails)
{
    if (!getUint32(raw, "modulusLength", modulusLength, context, errorDetails))
        return false;

    if (!getBigInteger(raw, "publicExponent", publicExponent, context, errorDetails))
        return false;

    return true;
}
Example #4
0
bool ApplyTag::applyTagToBuffer() {
  quint32 peHeader             = getUint32(kPEHeaderOffset);
  quint32 certDirAddressOffset = 152;

  // Read certificate directory info.
  quint32 certDirOffset = getUint32(peHeader + certDirAddressOffset);
  if (certDirOffset == 0)
    return false;

  quint32 certDirSize = getUint32(peHeader + certDirAddressOffset + 4);

  // Increase the size of certificate directory.
  int newCertSize = certDirSize + m_tagBuffer.size();

  putUint32(newCertSize, peHeader + certDirAddressOffset + 4);

  // Increase the certificate struct size.
  putUint32(newCertSize, certDirOffset);

  return true;
}
Example #5
0
QByteArray MRAData::getBinaryString() {
    int len = getUint32();

    if (m_data.size() >= (m_pointer + len)) {

        if (len == 0) {
            return QByteArray();
        }

        QByteArray result = m_data.mid(m_pointer, len);

        m_pointer += len;

        return result;
    } else {
        return QByteArray();
    }
}
Example #6
0
void printCell(Cell *cell){
	switch(cell->ctype){
		case INT32:
			printf("%d\t",getInt32(cell->value));
			break;
		case UINT32:
			printf("%d\t",getUint32(cell->value));
			break;
		case INT64:
			printf("%ld\t",getInt64(cell->value));
			break;
		case UINT64:
			printf("%lu\t",getUint64(cell->value));
			break;
		case INT8:
			printf("%d",getInt8(cell->value));
			break;
		case INT16:
			printf("%d",getInt16(cell->value));
			break;
		case FLOAT:
			printf("%f\t",getFloat(cell->value));
			break;
		case DOUBLE:
			printf("%f\t",getDouble(cell->value));
			break;
		case STRING: //MySQL type BINARY may be STRING
			{   
				char *value =(char *) cell->value;
				printf("%s\t",(char*)value);
				break;

			}   
		case BINARY:
			printf("BINARY\t");
			break;
		default:
			printf("UNKNOW\t");
			break;

	}
}
Example #7
0
QString MRAData::getUnicodeString() {
    int len = getUint32();

    if (m_data.size() >= (m_pointer + len)) {

        if (len == 0) {
            return QString();
        }

        CodecHolder holder("UTF-16LE");

        QString result = QString::fromAscii( m_data.mid(m_pointer, len).constData(), len );

        m_pointer += len;

        return result;
    } else {
        return QString();
    }
}
Example #8
0
bool 
Babuino::withInt32()
{
	STACKPTR location, index;
	int32_t  rhs, lhs;

	switch (_regs.opCode)
	{
	case OP_ASHIFT:
	case OP_LSHIFT:
		{
			int8_t shift;
			popUint8(_stack, (uint8_t*)&shift);
			popUint32(_stack, (uint32_t*)&lhs);
			if (shift >= 0)
				pushUint32(_stack, (uint32_t)(lhs << shift));
			else
				pushUint32(_stack, (uint32_t)(lhs >> -shift));
			return true;
		}
	case OP_SET:
		//Serial.println("---set---");

		popStackPtr(_stack, &location);
		popUint32(_stack, (uint32_t*)&rhs);

		setUint32(_stack, location, (uint32_t)rhs);
		return true;

	case OP_GET:
		//Serial.println("---get---");
		popStackPtr(_stack, &location);
		getUint32(_stack, location, (uint32_t*)&rhs);
		pushUint32(_stack, (uint32_t)rhs);
		return true;

	case OP_ASET:
		//Serial.println("---aset---");
		popStackPtr(_stack, &location);
		popStackPtr(_stack, &index);
		popUint32(_stack, (uint32_t*)&rhs);
		setUint32(_stack, location + index * sizeof(int32_t), (uint32_t)rhs);
		return true;

	case OP_AGET:
		//Serial.println("---aget---");
		popStackPtr(_stack, &location);
		popStackPtr(_stack, &index);
		getUint32(_stack, location + index * sizeof(int32_t), (uint32_t*)&rhs);
		pushUint32(_stack, (uint32_t)rhs);
		return true;

	case OP_OUTPUT:
		{
			//Serial.print("output ");
			popUint32(_stack, (uint32_t*)&rhs);	// The return value
				// point to where the arguments size is on the stack.
			location = getArgsLocation();
			uint8_t argsSize;
			getUint8(_stack, location - sizeof(uint8_t), &argsSize); // Get size of args. 
				// If the size > 0 then step over the size location too. 
				// Otherwise keep pointing to the same place because the return
				// value should overwrite where the arguments size would be. 
			if (argsSize > 0)
				argsSize += sizeof(uint8_t);
			setUint32(_stack, location - (STACKPTR)argsSize - sizeof(int32_t), (uint32_t)rhs);
		}
		return true;

	case OP_SEND:
		{
			//Serial.println("---send---");
			popUint32(_stack, (uint32_t*)&rhs);
			uint8_t buf[sizeof(int32_t)];
			hton(rhs, buf);
			//_defaultStream->write(nbuf, sizeof(int32_t)); // Replaced for debugging
			_defaultStream->print(rhs);
		}
		return true;

	case OP_SENDN:
		{
			//Serial.println("---sendn---");
			uint8_t items;
			uint8_t port;
			STACKPTR bufLoc;
			popUint8(_stack, &items);
			popUint8(_stack, &port);
			popStackPtr(_stack, &bufLoc); 
			int32_t* buf = (int32_t*)getStackAddress(_stack, bufLoc);
			uint8_t nbuf[sizeof(int32_t)];
			for (int i = 0; i < items; i++)
			{
				rhs = *buf;
				hton(rhs, nbuf);
				//_defaultStream->write(nbuf, sizeof(int32_t)); // Replaced for debugging
				_defaultStream->print(rhs);
				buf++;
			}
		}
		return true;
#ifdef SUPPORT_STRING
	case OP_TOSTR:
		{
			//Serial.println("---tostr---");
			popUint32(_stack, (uint32_t*)&rhs);
				// ***KLUDGE WARNING***
				// Borrowing unused (hopefully) stack space as a buffer!
				// just to avoid having to allocate another buffer.
			
			char* psz = (char *)getTopAddress(_stack);
			itoa((int) rhs, psz, 10);
				// Logically this is wrong because I'm apparently 
				// pushing a string to a location that it already 
				// occupies. However, the stack implementation 
				// pushes strings onto a separate stack, then
				// pushes the location onto the main stack. So
				// the string doesn't get copied over itself, and
				// is already copied before the first characters are
				// overwritten by pushing the said location onto the
				// main stack.
			pushString(_stack, (uint8_t*)psz);
		}
		return true;
#endif
	case OP_FOREACH:
		{	
			//Serial.print("foreach ");
			PROGPTR blockAddr;
			popProgPtr(_stack, &blockAddr);		// Block address
			popStackPtr(_stack, &location);			// Iterator variable location (Variable contains a 'pointer')
			uint8_t itemsRemaining;
			popUint8(_stack, &itemsRemaining);			// Number of items remaining
				// If we've gone through the block then we need to pop the
				// previous list item off the stack
			if (hasBlockExecuted())
			{
				uint32_t tmpUint32;
				popUint32(_stack, &tmpUint32);
			}

			if (itemsRemaining > 0)				// Any items remaining
			{
					// Set the value of the variable to the location on the
					// stack of the next list item (ie the top)
				setStackPtr(_stack, location, getTop(_stack) - sizeof(int32_t));
				_regs.pc = blockAddr;	// Point to the top of the block for the next iteration
				itemsRemaining--;					// Decrement the number of items remaining
				pushUint8(_stack, itemsRemaining);		// Save number of items remaining for next time
				pushStackPtr(_stack, location);		// Save iterator variable location for next time
				pushProgPtr(_stack, blockAddr);	// Save block address for next time
			}
			else
			{
				ascendBlock();			// Leaving. Pop the block.
			}
		}
		return true;
	}

	popUint32(_stack, (uint32_t*)&rhs);

	switch (_regs.opCode)
	{
	case OP_BITNOT:
		pushUint32(_stack, (uint32_t)~rhs);
		return true;

	case OP_ABS:
		pushUint32(_stack, (uint32_t)abs(rhs));
		return true;

	case OP_NEG:
		pushUint32(_stack, (uint32_t)-rhs);
		return true;
	}

	popUint32(_stack, (uint32_t*)&lhs);

	switch (_regs.opCode)
	{
	case OP_ADD:
		pushUint32(_stack, (uint32_t)(lhs + rhs));
		return true;

	case OP_SUB:
		pushUint32(_stack, (uint32_t)(lhs - rhs));
		return true;

	case OP_MUL:
		pushUint32(_stack, (uint32_t)(lhs * rhs));
		return true;

	case OP_DIV:
		pushUint32(_stack, (uint32_t)(lhs / rhs));
		return true;

	case OP_MOD:
		pushUint32(_stack, (uint32_t)(lhs % rhs));
		return true;

	case OP_EQ:
		pushUint8(_stack, (uint8_t)(lhs == rhs));
		return true;


	case OP_GT:
		pushUint8(_stack, (uint8_t)(lhs > rhs));
		return true;

	case OP_LT:
		pushUint8(_stack, (uint8_t)(lhs < rhs));
		return true;

	case OP_LE:
		pushUint8(_stack, (uint8_t)(lhs <= rhs));
		return true;

	case OP_GE:
		pushUint8(_stack, (uint8_t)(lhs >= rhs));
		return true;

	case OP_NE:
		pushUint8(_stack, (uint8_t)(lhs != rhs));
		return true;

	case OP_BITAND:
		pushUint32(_stack, (uint32_t)(lhs & rhs));
		return true;

	case OP_BITOR:
		pushUint32(_stack, (uint32_t)(lhs | rhs));
		return true;

	case OP_BITXOR:
		pushUint32(_stack, (uint32_t)(lhs ^ rhs));
		return true;
	
	case OP_MIN:
		pushUint32(_stack, (uint32_t)min(lhs, rhs));
		return true;	
	case OP_MAX:
		pushUint32(_stack, (uint32_t)max(lhs, rhs));
		return true;
	}
	return false;
}
Example #9
0
static void handleAggDataUpdate(DDTypedBufferMsg_t *msg, PS_DataBuffer_t *data)
{
    char *ptr = data->buf;
    AccountDataExt_t aggData;
    PStask_ID_t logger;

    /* get logger's task ID */
    getInt32(&ptr, &logger);

    if (!findJobByLogger(logger)) {
	mlog("%s: update unknown logger %s\n", __func__, PSC_printTID(logger));
	return;
    }

    getUint64(&ptr, &aggData.maxThreadsTotal);
    getUint64(&ptr, &aggData.maxVsizeTotal);
    getUint64(&ptr, &aggData.maxRssTotal);
    getUint64(&ptr, &aggData.maxThreads);
    getUint64(&ptr, &aggData.maxVsize);
    getUint64(&ptr, &aggData.maxRss);

    getUint64(&ptr, &aggData.avgThreadsTotal);
    getUint64(&ptr, &aggData.avgThreadsCount);
    getUint64(&ptr, &aggData.avgVsizeTotal);
    getUint64(&ptr, &aggData.avgVsizeCount);
    getUint64(&ptr, &aggData.avgRssTotal);
    getUint64(&ptr, &aggData.avgRssCount);

    getUint64(&ptr, &aggData.cutime);
    getUint64(&ptr, &aggData.cstime);
    getUint64(&ptr, &aggData.minCputime);
    getUint64(&ptr, &aggData.pageSize);
    getUint32(&ptr, &aggData.numTasks);

    getUint64(&ptr, &aggData.maxMajflt);
    getUint64(&ptr, &aggData.totMajflt);
    getUint64(&ptr, &aggData.totCputime);
    getUint64(&ptr, &aggData.cpuFreq);

    getDouble(&ptr, &aggData.maxDiskRead);
    getDouble(&ptr, &aggData.totDiskRead);
    getDouble(&ptr, &aggData.maxDiskWrite);
    getDouble(&ptr, &aggData.totDiskWrite);

    getInt32(&ptr, &aggData.taskIds[ACCID_MAX_VSIZE]);
    getInt32(&ptr, &aggData.taskIds[ACCID_MAX_RSS]);
    getInt32(&ptr, &aggData.taskIds[ACCID_MAX_PAGES]);
    getInt32(&ptr, &aggData.taskIds[ACCID_MIN_CPU]);
    getInt32(&ptr, &aggData.taskIds[ACCID_MAX_DISKREAD]);
    getInt32(&ptr, &aggData.taskIds[ACCID_MAX_DISKWRITE]);

    getTime(&ptr, &aggData.rusage.ru_utime.tv_sec);
    getTime(&ptr, &aggData.rusage.ru_utime.tv_usec);
    getTime(&ptr, &aggData.rusage.ru_stime.tv_sec);
    getTime(&ptr, &aggData.rusage.ru_stime.tv_usec);

    setAggData(msg->header.sender, logger, &aggData);

    mdbg(PSACC_LOG_UPDATE_MSG, "%s: from %s maxThreadsTot %lu maxVsizeTot %lu"
	 " maxRsstot %lu maxThreads %lu maxVsize %lu maxRss %lu numTasks %u\n",
	 __func__, PSC_printTID(msg->header.sender), aggData.maxThreadsTotal,
	 aggData.maxVsizeTotal, aggData.maxRssTotal, aggData.maxThreads,
	 aggData.maxVsize, aggData.maxRss, aggData.numTasks);
}
Example #10
0
// Login request (http://mc.kev009.com/wiki/Protocol#Login_Request_.280x01.29)
int PacketHandler::login_request(User *user)
{
  //Check that we have enought data in the buffer
  if(user->buffer.size() < 12)
    return PACKET_NEED_MORE_DATA;

  uint32 curpos = 0;
  int i;

  //Client protocol version
  uint8 tmpIntArray[4] = {0};
  for(i = 0; i < 4; i++)
    tmpIntArray[i] = user->buffer[curpos+i];
  int version = getUint32(&tmpIntArray[0]);
  curpos += 4;

  //Player name length
  uint8 tmpShortArray[2] = {0};
  for(i = 0; i < 2; i++)
    tmpShortArray[i] = user->buffer[curpos+i];
  int len = getUint16(&tmpShortArray[0]);
  curpos += 2;

  //Check for data
  if(user->buffer.size() < curpos+len+2)
    return PACKET_NEED_MORE_DATA;


  std::string player;
  //Read player name
  for(int pos = 0; pos < len; pos++)
  {
    player += user->buffer[curpos+pos];
  }
  curpos += len;


  //Password length
  for(i = 0; i < 2; i++)
    tmpShortArray[i] = user->buffer[curpos+i];
  len     = getUint16(&tmpShortArray[0]);
  curpos += 2;

  std::string passwd;
  //Check for data
  if(user->buffer.size() < curpos+len)
    return PACKET_NEED_MORE_DATA;


  //Read password
  for(int pos = 0; pos < len; pos++)
  {
    passwd += user->buffer[curpos+pos];
  }
  curpos += len;

  //Package completely received, remove from buffer
  user->buffer.erase(user->buffer.begin(), user->buffer.begin()+curpos);

  std::cout << "Player " << user->UID << " login v." << version <<" : " << player <<":"<<
  passwd << std::endl;

  // If version is not 2 or 3
  if(version != 4 && version != 3 && version != 2)
  {
    user->kick(Conf::get().sValue("wrong_protocol_message"));
    return curpos;
  }

  // If userlimit is reached
  if((int)Users.size() >= Conf::get().iValue("userlimit"))
  {
    user->kick(Conf::get().sValue("server_full_message"));
    return curpos;
  }

  user->changeNick(player);

  //Load user data
  user->loadData();

  //Login OK package
  char data[9] = {0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
  putSint32((uint8 *)&data[1], user->UID);
  bufferevent_write(user->buf_ev, (char *)&data[0], 9);

  //Send server time (after dawn)
  uint8 data3[9] = {0x04, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x0e, 0x00};
  bufferevent_write(user->buf_ev, (char *)&data3[0], 9);

  //Inventory
  uint8 data4[7+36*5];
  data4[0] = 0x05;
  putSint32(&data4[1], -1);
  data4[5] = 0;
  data4[6] = 36;
  int curpos2 = 7;
  //Send main inventory
  for(i = 0; i < 36; i++)
  {
    if(user->inv.main[i].count)
    {
      putSint16(&data4[curpos2], user->inv.main[i].type);     //Type
      curpos2       += 2;
      data4[curpos2] = user->inv.main[i].count;               //Count
      curpos2++;
      putSint16(&data4[curpos2], user->inv.main[i].health); //Health
      curpos2 += 2;
    }
    else
    {
      //Empty slot
      putSint16(&data4[curpos2], -1);
      curpos2 += 2;
    }
  }
  bufferevent_write(user->buf_ev, (char *)&data4[0], curpos2);


  //Send equipped inventory
  putSint32(&data4[1], -3);
  data4[6] = 4;
  curpos2  = 7;
  for(i = 0; i < 4; i++)
  {
    if(user->inv.equipped[i].count)
    {
      putSint16(&data4[curpos2], user->inv.equipped[i].type);     //Type
      curpos2       += 2;
      data4[curpos2] = user->inv.equipped[i].count;               //Count
      curpos2++;
      putSint16(&data4[curpos2], user->inv.equipped[i].health); //Health
      curpos2 += 2;
    }
    else
    {
      //Empty slot
      putSint16(&data4[curpos2], -1);
      curpos2 += 2;
    }
  }
  bufferevent_write(user->buf_ev, (char *)&data4[0], curpos2);

  //Send crafting inventory
  putSint32(&data4[1], -2);
  data4[6] = 4;
  curpos2  = 7;
  for(i = 0; i < 4; i++)
  {
    if(user->inv.crafting[i].count)
    {
      putSint16(&data4[curpos2], user->inv.crafting[i].type);     //Type
      curpos2       += 2;
      data4[curpos2] = user->inv.crafting[i].count;               //Count
      curpos2++;
      putSint16(&data4[curpos2], user->inv.crafting[i].health); //Health
      curpos2 += 2;
    }
    else
    {
      //Empty slot
      putSint16(&data4[curpos2], -1);
      curpos2 += 2;
    }
  }
  bufferevent_write(user->buf_ev, (char *)&data4[0], curpos2);

  // Send motd
  std::ifstream motdfs( MOTDFILE.c_str());

  std::string temp;

  while(getline( motdfs, temp ))
  {
    // If not commentline
    if(temp[0] != COMMENTPREFIX)
      Chat::get().sendMsg(user, temp, Chat::USER);
  }
  motdfs.close();

  //Teleport player
  user->teleport(user->pos.x, user->pos.y+2, user->pos.z);

  //Put nearby chunks to queue
  for(int x = -user->viewDistance; x <= user->viewDistance; x++)
  {
    for(int z = -user->viewDistance; z <= user->viewDistance; z++)
    {
      user->addQueue((sint32)user->pos.x/16+x, (sint32)user->pos.z/16+z);
    }
  }
  // Push chunks to user
  user->pushMap();

  //Spawn this user to others
  user->spawnUser((sint32)user->pos.x*32, ((sint32)user->pos.y+2)*32, (sint32)user->pos.z*32);
  //Spawn other users for connected user
  user->spawnOthers();


  //Send "On Ground" signal
  char data6[2] = {0x0A, 0x01};
  bufferevent_write(user->buf_ev, (char *)&data6[0], 2);

  user->logged = true;

  Chat::get().sendMsg(user, player+" connected!", Chat::ALL);

  return curpos;
}
Example #11
0
luabridge::LuaRef CLuaBinary::getStruct(luabridge::LuaRef objAttr)
{
    assert(objAttr.isTable());

    DataType emType;
    int iSize = Q_INIT_NUMBER;
    std::string strName;
    luabridge::LuaRef objVal = luabridge::newTable(m_pLua);

    for (int i = 1; i <= objAttr.length(); i++)
    {
        luabridge::LuaRef objTmp = objAttr[i];
        if (!objTmp.isTable()
            || STATTRTAB_MINLENS > objTmp.length())
        {
            break;
        }

        luabridge::LuaRef objChildStAttr = getStructAttr(objTmp, strName, emType, iSize);
        switch(emType)
        {
        case DTYPE_SINT8:
            {
                objVal[strName] = getSint8();
            }
            break;
        case DTYPE_UINT8:
            {
                objVal[strName] = getUint8();
            }
            break;
        case DTYPE_BOOL:
            {
                objVal[strName] = getBool();
            }
            break;
        case DTYPE_SINT16:
            {
                objVal[strName] = getSint16();
            }
            break;
        case DTYPE_UINT16:
            {
                objVal[strName] = getUint16();
            }
            break;
        case DTYPE_SINT32:
            {
                objVal[strName] = getSint32();
            }
            break;
        case DTYPE_UINT32:
            {
                objVal[strName] = getUint32();
            }
            break;
        case DTYPE_SINT64:
            {
                objVal[strName] = getSint64();
            }
            break;
        case DTYPE_UINT64:
            {
                objVal[strName] = getUint64();
            }
            break;
        case DTYPE_FLOAT:
            {
                objVal[strName] = getFloat();
            }
            break;
        case DTYPE_DOUBLE:
            {
                objVal[strName] = getDouble();
            }
            break;
        case DTYPE_STRING:
            {
                std::string strVal = getString();
                objVal[strName] = strVal;
                skipRead((unsigned int)(iSize - (strVal.size() + 1)));
            }
            break;
        case DTYPE_BYTE:
            {
                objVal[strName] = getByte(iSize);
            }
            break;
        case DTYPE_STRUCT:
            {
                objVal[strName] = getStruct(objChildStAttr);
            }
            break;
        case DTYPE_SKIP:
            {
                if (iSize > Q_INIT_NUMBER)
                {
                    skipRead(iSize);
                }
            }
            break;

        default:
            break;
        }
    }

    return objVal;
}
Example #12
0
static void handlePrintChildMsg(Forwarder_Data_t *fwdata, char *ptr)
{
    Step_t *step = fwdata->userData;
    uint8_t type;
    uint32_t rank, lrank, i;
    size_t len;
    static IO_Msg_Buf_t *lineBuf;
    int32_t myNodeID = step->localNodeId;
    static int initBuf = 0;

    /* read message */
    getUint8(&ptr, &type);
    getUint32(&ptr, &rank);
    char *msg = getDataM(&ptr, &len);

    /* get local rank from rank */
    lrank = getLocalRankID(rank, step, myNodeID);
    if (lrank == (uint32_t )-1) {
	mlog("%s: invalid node rank for rank %i myNodeID %i step %u:%u\n",
		__func__, rank, myNodeID, step->jobid, step->stepid);
	ufree(msg);
	return;
    }

    /* track I/O channels */
    if (!len) {
	if (type == STDOUT && step->outChannels) {
	    if (step->outChannels[lrank] == 0) {
		ufree(msg);
		return;
	    }
	    step->outChannels[lrank] = 0;
	}
	if (type == STDERR && step->errChannels) {
	    if (step->errChannels[lrank] == 0) {
		ufree(msg);
		return;
	    }
	    step->errChannels[lrank] = 0;
	}
    }

    /* handle unbuffered IO */
    if (type == STDERR || (!(step->taskFlags & LAUNCH_LABEL_IO)
	&& !(step->taskFlags & LAUNCH_BUFFERED_IO))
	|| step->taskFlags & LAUNCH_PTY) {
	writeIOmsg(msg, len, rank, type, fwdata, step, lrank);
	ufree(msg);
	return;
    }

    /* handle buffered IO */
    if (!initBuf) {
	lineBuf = umalloc(sizeof(IO_Msg_Buf_t)
			  * step->globalTaskIdsLen[myNodeID]);
	for (i=0; i<step->globalTaskIdsLen[myNodeID]; i++) {
	    lineBuf[i].out.buf = lineBuf[i].err.buf = NULL;
	    lineBuf[i].out.bufUsed = lineBuf[i].err.bufUsed = 0;
	}
	initBuf = 1;
    }

   handleBufferedMsg(msg, len,
		    type == STDOUT ?  &lineBuf[lrank].out : &lineBuf[lrank].err,
		    fwdata, step, rank, type, lrank);

    ufree(msg);
}
Example #13
0
/*EventCousor reader*/
static uint32_t readUint32(EventCursor *evcur){
	uint32_t v = getUint32(evcur->ev+evcur->cur);
	evcur->cur += 4;
	return v;
}
Example #14
0
uint32_t MachOFile::readUint32() {
    unsigned int temp;
    readBytes((char*)&temp, sizeof(temp));
    return getUint32(temp);
}
Example #15
0
unsigned int KPaquet::timestamp(void)
{
	return getUint32(_data.data(), 4);
}
Example #16
0
unsigned int KPaquet::bodySize() const
{
	return getUint32(_data.data());
}
Example #17
0
 uint32_t ClientMessage::get() {
     return getUint32();
 }