pwm period is now 200us instead of the default 20ms veml6040 config is now AF_BIT | TRIG_BIT
Dependencies: mbed MMA8451Q USBDevice WakeUp vt100
Fork of afero_node_suntory_2017_06_15 by
afLib/afLib.cpp
- Committer:
- wataloh
- Date:
- 2017-02-28
- Revision:
- 5:9d5c7ee80f3b
- Parent:
- 2:dfe671e31221
- Child:
- 6:88cc04eb613a
File content as of revision 5:9d5c7ee80f3b:
/** * Copyright 2015 Afero, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "mbed.h" #include "afLib.h" #include "afErrors.h" #include "msg_types.h" #define IS_MCU_ATTR(x) (x >= 0 && x < 1024) extern Timer t; static iafLib *_iaflib = NULL; #define MAX_SYNC_RETRIES 10 static long lastSync = 0; static int syncRetries = 0; /** * create * * The public constructor for the afLib. This allows us to create the afLib object once and hold a reference to it. */ iafLib *iafLib::create(PinName mcuInterrupt, isr isrWrapper, onAttributeSet attrSet, onAttributeSetComplete attrSetComplete, afSPI *theSPI) { if (_iaflib == NULL) { _iaflib = new afLib( mcuInterrupt, isrWrapper, attrSet, attrSetComplete, theSPI); } return _iaflib; } void iafLib::destroy() { afLib *p = (afLib*)_iaflib; delete p; _iaflib = NULL; } /** * afLib * * The private constructor for the afLib. This one actually initializes the afLib and prepares it for use. */ afLib::afLib(PinName mcuInterrupt, isr isrWrapper, onAttributeSet attrSet, onAttributeSetComplete attrSetComplete, afSPI *theSPI) : fco(mcuInterrupt) { queueInit(); _theSPI= theSPI; _request.p_value = NULL; //_spiSettings = SPISettings(1000000, LSBFIRST, SPI_MODE0); _interrupts_pending = 0; _state = STATE_IDLE; _writeCmd = NULL; _writeCmdOffset = 0; _outstandingSetGetAttrId = 0; _readCmd = NULL; _readCmdOffset = 0; _readBufferLen = 0; _txStatus = new StatusCommand(); _rxStatus = new StatusCommand(); _onAttrSet = attrSet; _onAttrSetComplete = attrSetComplete; _theSPI->begin(); // AJS where does this get moved to?? #ifdef ARDUINO pinMode(mcuInterrupt, INPUT); attachInterrupt(mcuInterrupt, isrWrapper, FALLING); #endif fco.fall(isrWrapper); SERIAL_PRINT_DBG_ASR("afLib init done!!\n"); } //wsugi 20161128 afLib::~afLib() { SERIAL_PRINT_DBG_ASR("deleted\n"); if(_readBuffer != NULL) { delete[] (_readBuffer); _readBuffer = NULL; } if(_writeBuffer != NULL) { delete[] (_writeBuffer); _writeBuffer = NULL; } if(_readCmd != NULL) { delete (_readCmd); _readCmd = NULL; } if(_writeCmd != NULL) { delete (_writeCmd); _writeCmd = NULL; } if(_txStatus != NULL) { delete (_txStatus); _txStatus = NULL; } if(_rxStatus != NULL) { delete (_rxStatus); _rxStatus = NULL; } for (int i = 0; i < REQUEST_QUEUE_SIZE; i++) { if (_requestQueue[i].p_value != NULL) { delete[] (_requestQueue[i].p_value); _requestQueue[i].p_value = NULL; } } _iaflib = NULL; } //wsugi 20161128 /** * loop * * This is how the afLib gets time to run its state machine. This method should be called periodically from the * loop() function of the Arduino sketch. * This function pulls pending attribute operations from the queue. It takes approximately 4 calls to loop() to * complete one attribute operation. */ void afLib::loop(void) { if (isIdle() && (queueGet(&_request.messageType, &_request.requestId, &_request.attrId, &_request.valueLen, &_request.p_value) == afSUCCESS)) { switch (_request.messageType) { case MSG_TYPE_GET: doGetAttribute(_request.requestId, _request.attrId); break; case MSG_TYPE_SET: doSetAttribute(_request.requestId, _request.attrId, _request.valueLen, _request.p_value); break; case MSG_TYPE_UPDATE: doUpdateAttribute(_request.requestId, _request.attrId, 0, _request.valueLen, _request.p_value); break; default: SERIAL_PRINT_DBG_ASR("%s\n","loop: request type!"); } } if (_request.p_value != NULL) { delete[] (_request.p_value); //wsugi delete (_request.p_value); _request.p_value = NULL; } runStateMachine(); } /** * updateIntsPending * * Interrupt-safe method for updating the interrupt count. This is called to increment and decrement the interrupt count * as interrupts are received and handled. */ void afLib::updateIntsPending(int amount) { fco.disable_irq(); _interrupts_pending += amount; fco.enable_irq(); } /** * sendCommand * * This increments the interrupt count to kick off the state machine in the next call to loop(). */ void afLib::sendCommand(void) { fco.disable_irq(); if (_interrupts_pending == 0 && _state == STATE_IDLE) { updateIntsPending(1); } fco.enable_irq(); } /** * getAttribute * * The public getAttribute method. This method queues the operation and returns immediately. Applications must call * loop() for the operation to complete. */ int afLib::getAttribute(const uint16_t attrId) { _requestId++; uint8_t dummy; // This value isn't actually used. return queuePut(MSG_TYPE_GET, _requestId++, attrId, 0, &dummy); } /** * The many moods of setAttribute * * These are the public versions of the setAttribute method. * These methods queue the operation and return immediately. Applications must call loop() for the operation to complete. */ int afLib::setAttributeBool(const uint16_t attrId, const bool value) { _requestId++; uint8_t val = value ? 1 : 0; return queuePut(IS_MCU_ATTR(attrId) ? MSG_TYPE_UPDATE : MSG_TYPE_SET, _requestId, attrId, sizeof(val), (uint8_t *)&val); } int afLib::setAttribute8(const uint16_t attrId, const int8_t value) { _requestId++; return queuePut(IS_MCU_ATTR(attrId) ? MSG_TYPE_UPDATE : MSG_TYPE_SET, _requestId, attrId, sizeof(value), (uint8_t *)&value); } int afLib::setAttribute16(const uint16_t attrId, const int16_t value) { _requestId++; return queuePut(IS_MCU_ATTR(attrId) ? MSG_TYPE_UPDATE : MSG_TYPE_SET, _requestId, attrId, sizeof(value), (uint8_t *) &value); } int afLib::setAttribute32(const uint16_t attrId, const int32_t value) { _requestId++; return queuePut(IS_MCU_ATTR(attrId) ? MSG_TYPE_UPDATE : MSG_TYPE_SET, _requestId, attrId, sizeof(value), (uint8_t *) &value); } int afLib::setAttribute64(const uint16_t attrId, const int64_t value) { _requestId++; return queuePut(IS_MCU_ATTR(attrId) ? MSG_TYPE_UPDATE : MSG_TYPE_SET, _requestId, attrId, sizeof(value), (uint8_t *) &value); } int afLib::setAttribute(const uint16_t attrId, const string &value) { _requestId++; return queuePut(IS_MCU_ATTR(attrId) ? MSG_TYPE_UPDATE : MSG_TYPE_SET, _requestId, attrId, value.length(), (uint8_t *) value.c_str()); } int afLib::setAttribute(const uint16_t attrId, const uint16_t valueLen, const char *value) { if (valueLen > MAX_ATTRIBUTE_SIZE) { return afERROR_INVALID_PARAM; } if (value == NULL) { return afERROR_INVALID_PARAM; } _requestId++; return queuePut(IS_MCU_ATTR(attrId) ? MSG_TYPE_UPDATE : MSG_TYPE_SET, _requestId, attrId, valueLen, (const uint8_t *) value); } int afLib::setAttribute(const uint16_t attrId, const uint16_t valueLen, const uint8_t *value) { if (valueLen > MAX_ATTRIBUTE_SIZE) { return afERROR_INVALID_PARAM; } if (value == NULL) { return afERROR_INVALID_PARAM; } _requestId++; return queuePut(IS_MCU_ATTR(attrId) ? MSG_TYPE_UPDATE : MSG_TYPE_SET, _requestId, attrId, valueLen, value); } int afLib::setAttributeComplete(uint8_t requestId, const uint16_t attrId, const uint16_t valueLen, const uint8_t *value) { if (valueLen > MAX_ATTRIBUTE_SIZE) { return afERROR_INVALID_PARAM; } if (value == NULL) { return afERROR_INVALID_PARAM; } return queuePut(MSG_TYPE_UPDATE, requestId, attrId, valueLen, value); } /** * doGetAttribute * * The private version of getAttribute. This version actually calls sendCommand() to kick off the state machine and * execute the operation. */ int afLib::doGetAttribute(uint8_t requestId, uint16_t attrId) { if (_interrupts_pending > 0 || _writeCmd != NULL) { return afERROR_BUSY; } _writeCmd = new Command(requestId, MSG_TYPE_GET, attrId); if (!_writeCmd->isValid()) { SERIAL_PRINT_DBG_ASR("getAttribute invalid command:"); _writeCmd->dumpBytes(); _writeCmd->dump(); delete (_writeCmd); _writeCmd = NULL; return afERROR_INVALID_COMMAND; } _outstandingSetGetAttrId = attrId; // Start the transmission. sendCommand(); return afSUCCESS; } /** * doSetAttribute * * The private version of setAttribute. This version actually calls sendCommand() to kick off the state machine and * execute the operation. */ int afLib::doSetAttribute(uint8_t requestId, uint16_t attrId, uint16_t valueLen, uint8_t *value) { if (_interrupts_pending > 0 || _writeCmd != NULL) { return afERROR_BUSY; } _writeCmd = new Command(requestId, MSG_TYPE_SET, attrId, valueLen, value); if (!_writeCmd->isValid()) { SERIAL_PRINT_DBG_ASR("setAttributeComplete invalid command:"); _writeCmd->dumpBytes(); _writeCmd->dump(); delete (_writeCmd); _writeCmd = NULL; return afERROR_INVALID_COMMAND; } _outstandingSetGetAttrId = attrId; // Start the transmission. sendCommand(); return afSUCCESS; } /** * doUpdateAttribute * * setAttribute calls on MCU attributes turn into updateAttribute calls. See documentation on the SPI protocol for * more information. This method calls sendCommand() to kick off the state machine and execute the operation. */ int afLib::doUpdateAttribute(uint8_t requestId, uint16_t attrId, uint8_t status, uint16_t valueLen, uint8_t *value) { if (_interrupts_pending > 0 || _writeCmd != NULL) { return afERROR_BUSY; } _writeCmd = new Command(requestId, MSG_TYPE_UPDATE, attrId, status, 3 /* MCU Set it */, valueLen, value); if (!_writeCmd->isValid()) { SERIAL_PRINT_DBG_ASR("updateAttribute invalid command:"); _writeCmd->dumpBytes(); _writeCmd->dump(); delete (_writeCmd); return afERROR_INVALID_COMMAND; } // Start the transmission. sendCommand(); return afSUCCESS; } /** * parseCommand * * A debug method for parsing a string into a command. This is not required for library operation and is only supplied * as an example of how to execute attribute operations from a command line interface. */ #ifdef ATTRIBUTE_CLI int afLib::parseCommand(const char *cmd) { if (_interrupts_pending > 0 || _writeCmd != NULL) { _theLog->print("Busy: "); _theLog->print(_interrupts_pending); _theLog->print(", "); _theLog->println(_writeCmd != NULL); return afERROR_BUSY; } int reqId = _requestId++; _writeCmd = new Command(_theLog,reqId, cmd); if (!_writeCmd->isValid()) { _theLog->print("BAD: "); _theLog->println(cmd); _writeCmd->dumpBytes(); _writeCmd->dump(); delete (_writeCmd); _writeCmd = NULL; return afERROR_INVALID_COMMAND; } // Start the transmission. sendCommand(); return afSUCCESS; } #endif /** * runStateMachine * * The state machine for afLib. This state machine is responsible for implementing the KSP SPI protocol and executing * attribute operations. * This method is run: * 1. In response to receiving an interrupt from the ASR-1. * 2. When an attribute operation is pulled out of the queue and executed. */ void afLib::runStateMachine(void) { if (_interrupts_pending > 0) { switch (_state) { case STATE_IDLE: onStateIdle(); return; case STATE_STATUS_SYNC: onStateSync(); break; case STATE_STATUS_ACK: onStateAck(); break; case STATE_SEND_BYTES: onStateSendBytes(); break; case STATE_RECV_BYTES: onStateRecvBytes(); break; case STATE_CMD_COMPLETE: onStateCmdComplete(); break; } updateIntsPending(-1); } else { if (syncRetries > 0 && syncRetries < MAX_SYNC_RETRIES && t.read_ms() - lastSync > 1000) { updateIntsPending(1); } else if (syncRetries >= MAX_SYNC_RETRIES) { SERIAL_PRINT_DBG_ASR("No response from ASR-1 - does profile have MCU enabled?\n"); syncRetries = 0; _state = STATE_IDLE; } } } /** * onStateIdle * * If there is a command to be written, update the bytes to send. Otherwise we're sending a zero-sync message. * Either way advance the state to send a sync message. */ void afLib::onStateIdle(void) { if (_writeCmd != NULL) { // Include 2 bytes for length _bytesToSend = _writeCmd->getSize() + 2; } else { _bytesToSend = 0; } _state = STATE_STATUS_SYNC; printState(_state); } /** * onStateSync * * Write a sync message over SPI to let the ASR-1 know that we want to send some data. * Check for a "collision" which occurs if the ASR-1 is trying to send us data at the same time. */ void afLib::onStateSync(void) { int result; _txStatus->setAck(false); _txStatus->setBytesToSend(_bytesToSend); _txStatus->setBytesToRecv(0); result = exchangeStatus(_txStatus, _rxStatus); if (result == afSUCCESS && _rxStatus->isValid() && inSync(_txStatus, _rxStatus)) { syncRetries = 0; // Flag that sync completed. _state = STATE_STATUS_ACK; if (_txStatus->getBytesToSend() == 0 && _rxStatus->getBytesToRecv() > 0) { _bytesToRecv = _rxStatus->getBytesToRecv(); } } else { // Try resending the preamble _state = STATE_STATUS_SYNC; lastSync = t.read_ms(); syncRetries++; // _txStatus->dumpBytes(); // _rxStatus->dumpBytes(); } printState(_state); } /** * onStateAck * * Acknowledge the previous sync message and advance the state. * If there are bytes to send, advance to send bytes state. * If there are bytes to receive, advance to receive bytes state. * Otherwise it was a zero-sync so advance to command complete. */ void afLib::onStateAck(void) { int result; _txStatus->setAck(true); _txStatus->setBytesToRecv(_rxStatus->getBytesToRecv()); _bytesToRecv = _rxStatus->getBytesToRecv(); result = writeStatus(_txStatus); if (result != afSUCCESS) { _state = STATE_STATUS_SYNC; printState(_state); return; } if (_bytesToSend > 0) { _writeBufferLen = (uint16_t) _writeCmd->getSize(); _writeBuffer = new uint8_t[_bytesToSend]; memcpy(_writeBuffer, (uint8_t * ) & _writeBufferLen, 2); _writeCmd->getBytes(&_writeBuffer[2]); _state = STATE_SEND_BYTES; } else if (_bytesToRecv > 0) { _state = STATE_RECV_BYTES; } else { _state = STATE_CMD_COMPLETE; } printState(_state); } /** * onStateSendBytes * * Send the required number of bytes to the ASR-1 and then advance to command complete. */ void afLib::onStateSendBytes(void) { // _theLog->print("send bytes: "); _theLog->println(_bytesToSend); sendBytes(); if (_bytesToSend == 0) { _writeBufferLen = 0; delete[] (_writeBuffer); //wsugi delete (_writeBuffer); _writeBuffer = NULL; _state = STATE_CMD_COMPLETE; printState(_state); } } /** * onStateRecvBytes * * Receive the required number of bytes from the ASR-1 and then advance to command complete. */ void afLib::onStateRecvBytes(void) { // _theLog->print("receive bytes: "); _theLog->println(_bytesToRecv); recvBytes(); if (_bytesToRecv == 0) { _state = STATE_CMD_COMPLETE; printState(_state); _readCmd = new Command(_readBufferLen, &_readBuffer[2]); delete[] (_readBuffer); //wsugi delete (_readBuffer); _readBuffer = NULL; } } /** * onStateCmdComplete * * Call the appropriate sketch callback to report the result of the command. * Clear the command object and go back to waiting for the next interrupt or command. */ void afLib::onStateCmdComplete(void) { _state = STATE_IDLE; printState(_state); if (_readCmd != NULL) { uint8_t *val = new uint8_t[_readCmd->getValueLen()]; _readCmd->getValue(val); switch (_readCmd->getCommand()) { case MSG_TYPE_SET: _onAttrSet(_readCmd->getReqId(), _readCmd->getAttrId(), _readCmd->getValueLen(), val); break; case MSG_TYPE_UPDATE: if (_readCmd->getAttrId() == _outstandingSetGetAttrId) { _outstandingSetGetAttrId = 0; } _onAttrSetComplete(_readCmd->getReqId(), _readCmd->getAttrId(), _readCmd->getValueLen(), val); break; default: break; } delete[] (val); //wsugi delete (val); delete (_readCmd); _readCmdOffset = 0; _readCmd = NULL; } if (_writeCmd != NULL) { // Fake a callback here for MCU attributes as we don't get one from the module. if (_writeCmd->getCommand() == MSG_TYPE_UPDATE && IS_MCU_ATTR(_writeCmd->getAttrId())) { _onAttrSetComplete(_writeCmd->getReqId(), _writeCmd->getAttrId(), _writeCmd->getValueLen(), _writeCmd->getValueP()); } delete (_writeCmd); _writeCmdOffset = 0; _writeCmd = NULL; } } /** * exchangeStatus * * Write a status command object to the ASR-1 and clock in a status object from the ASR-1 at the same time. */ int afLib::exchangeStatus(StatusCommand *tx, StatusCommand *rx) { int result = afSUCCESS; uint16_t len = tx->getSize(); int bytes[len]; char rbytes[len+1]; int index = 0; tx->getBytes(bytes); // _theSPI->beginSPI(); for (int i=0;i<len;i++) { rbytes[i]=bytes[i]; } rbytes[len]=tx->getChecksum(); printTransaction((uint8_t*)rbytes,len+1); _theSPI->beginSPI(); _theSPI->transfer(rbytes,len+1); _theSPI->endSPI(); printTransaction((uint8_t*)rbytes,len+1); uint8_t cmd = bytes[index++]; if (cmd != 0x30 && cmd != 0x31) { SERIAL_PRINT_DBG_ASR("exchangeStatus bad cmd: 0x%02x\n",cmd); result = afERROR_INVALID_COMMAND; } rx->setBytesToSend(rbytes[index + 0] | (rbytes[index + 1] << 8)); rx->setBytesToRecv(rbytes[index + 2] | (rbytes[index + 3] << 8)); rx->setChecksum(rbytes[index+4]); //_theSPI->endSPI(); return result; } /** * inSync * * Check to make sure the Arduino and the ASR-1 aren't trying to send data at the same time. * Return true only if there is no collision. */ bool afLib::inSync(StatusCommand *tx, StatusCommand *rx) { return (tx->getBytesToSend() == 0 && rx->getBytesToRecv() == 0) || (tx->getBytesToSend() > 0 && rx->getBytesToRecv() == 0) || (tx->getBytesToSend() == 0 && rx->getBytesToRecv() > 0); } /** * writeStatus * * Write a status command to the ASR-1 and ignore the result. If you want to read bytes at the same time, use * exchangeStatus instead. */ int afLib::writeStatus(StatusCommand *c) { int result = afSUCCESS; uint16_t len = c->getSize(); int bytes[len]; char rbytes[len+1]; int index = 0; c->getBytes(bytes); _theSPI->beginSPI(); for (int i=0;i<len;i++) { rbytes[i]=bytes[i]; } rbytes[len]=c->getChecksum(); printTransaction((uint8_t*)rbytes,len+1); _theSPI->transfer(rbytes,len+1); printTransaction((uint8_t*)rbytes,len+1); uint8_t cmd = rbytes[index++]; if (cmd != 0x30 && cmd != 0x31) { SERIAL_PRINT_DBG_ASR("writeStatus bad cmd: 0x%02x\n",cmd); result = afERROR_INVALID_COMMAND; } _theSPI->endSPI(); // c->dump(); // c->dumpBytes(); return result; } /** * sendBytes * * Send the specified number of data bytes to the ASR-1. Do this in chunks of SPI_FRAME_LEN bytes. */ void afLib::sendBytes() { uint16_t len = _bytesToSend > SPI_FRAME_LEN ? SPI_FRAME_LEN : _bytesToSend; uint8_t bytes[SPI_FRAME_LEN]; memset(bytes, 0xff, sizeof(bytes)); memcpy(bytes, &_writeBuffer[_writeCmdOffset], len); _theSPI->beginSPI(); printTransaction(bytes,len+1); _theSPI->transfer((char *)bytes,len); printTransaction(bytes,len+1); _theSPI->endSPI(); // dumpBytes("Sending:", len, bytes); _writeCmdOffset += len; _bytesToSend -= len; } /** * recvBytes * * Receive the specified number of data bytes from the ASR-1. Do this in chunks of SPI_FRAME_LEN bytes. */ void afLib::recvBytes() { uint16_t len = _bytesToRecv > SPI_FRAME_LEN ? SPI_FRAME_LEN : _bytesToRecv; if (_readCmdOffset == 0) { _readBufferLen = _bytesToRecv; _readBuffer = new uint8_t[_readBufferLen]; } _theSPI->beginSPI(); char * start =(char*)_readBuffer + _readCmdOffset; printTransaction((uint8_t*)start,len+1); _theSPI->transfer(start,len); printTransaction((uint8_t*)start,len+1); _theSPI->endSPI(); // dumpBytes("Receiving:", len, _readBuffer); _readCmdOffset += len; _bytesToRecv -= len; } /** * isIdle * * Provide a way for the sketch to know if we're idle. Returns true if there are no attribute operations in progress. */ bool afLib::isIdle() { return _interrupts_pending == 0 && _state == STATE_IDLE && _outstandingSetGetAttrId == 0; } /** * These methods are required to disable/enable interrupts for the Linux version of afLib. * They are no-ops on Arduino. */ #ifndef ARDUINO void noInterrupts(){} void interrupts(){} #endif void afLib::mcuISR() { // _theLog->println("mcu"); updateIntsPending(1); } /**************************************************************************** * Queue Methods * ****************************************************************************/ /** * queueInit * * Create a small queue to prevent flooding the ASR-1 with attribute operations. * The initial size is small to allow running on small boards like UNO. * Size can be increased on larger boards. */ void afLib::queueInit() { for (int i = 0; i < REQUEST_QUEUE_SIZE; i++) { _requestQueue[i].p_value = NULL; } } /** * queuePut * * Add an item to the end of the queue. Return an error if we're out of space in the queue. */ int afLib::queuePut(uint8_t messageType, uint8_t requestId, const uint16_t attributeId, uint16_t valueLen, const uint8_t *value) { for (int i = 0; i < REQUEST_QUEUE_SIZE; i++) { if (_requestQueue[i].p_value == NULL) { _requestQueue[i].messageType = messageType; _requestQueue[i].attrId = attributeId; _requestQueue[i].requestId = requestId; _requestQueue[i].valueLen = valueLen; _requestQueue[i].p_value = new uint8_t[valueLen]; memcpy(_requestQueue[i].p_value, value, valueLen); return afSUCCESS; } } return afERROR_QUEUE_OVERFLOW; } /** * queueGet * * Pull and return the oldest item from the queue. Return an error if the queue is empty. */ int afLib::queueGet(uint8_t *messageType, uint8_t *requestId, uint16_t *attributeId, uint16_t *valueLen, uint8_t **value) { for (int i = 0; i < REQUEST_QUEUE_SIZE; i++) { if (_requestQueue[i].p_value != NULL) { *messageType = _requestQueue[i].messageType; *attributeId = _requestQueue[i].attrId; *requestId = _requestQueue[i].requestId; *valueLen = _requestQueue[i].valueLen; *value = new uint8_t[*valueLen]; memcpy(*value, _requestQueue[i].p_value, *valueLen); delete[] (_requestQueue[i].p_value); //wsugi delete (_requestQueue[i].p_value); _requestQueue[i].p_value = NULL; return afSUCCESS; } } return afERROR_QUEUE_UNDERFLOW; } /**************************************************************************** * Debug Methods * ****************************************************************************/ /** * dumpBytes * * Dump a byte buffer to the debug log. */ void afLib::dumpBytes(char *label, int len, uint8_t *bytes) { SERIAL_PRINT_DBG_ASR("%s\n",label); for (int i = 0; i < len; i++) { if (i > 0) { SERIAL_PRINT_DBG_ASR(", "); } uint8_t b = bytes[i] & 0xff; if (b < 0x10) { SERIAL_PRINT_DBG_ASR("0x02x", b); } else { //_theLog->print("0x"); SERIAL_PRINT_DBG_ASR("0x02x",b);//, HEX); } } SERIAL_PRINT_DBG_ASR("\n"); } /** * printState * * Print the current state of the afLib state machine. For debugging, just remove the return statement. */ void afLib::printState(int state) { // return; switch (state) { case STATE_IDLE: SERIAL_PRINT_DBG_ASR("STATE_IDLE\n"); break; case STATE_STATUS_SYNC: SERIAL_PRINT_DBG_ASR("STATE_STATUS_SYNC\n"); break; case STATE_STATUS_ACK: SERIAL_PRINT_DBG_ASR("STATE_STATUS_ACK\n"); break; case STATE_SEND_BYTES: SERIAL_PRINT_DBG_ASR("STATE_SEND_BYTES\n"); break; case STATE_RECV_BYTES: SERIAL_PRINT_DBG_ASR("STATE_RECV_BYTES\n"); break; case STATE_CMD_COMPLETE: SERIAL_PRINT_DBG_ASR("STATE_CMD_COMPLETE\n"); break; default: SERIAL_PRINT_DBG_ASR("Unknown State!\n"); break; } } void afLib::printTransaction(uint8_t *rbytes, int len) { //return; int i = 0; for(;i<=len;++i) { SERIAL_PRINT_DBG_ASR("0x%02x:",rbytes[i]); } SERIAL_PRINT_DBG_ASR("\n"); }