Connectivity
Dependencies: fsl_phy_mcr20a fsl_smac mbed-rtos mbed
Fork of mcr20_connectivity_test_FRDMk64f by
Source/Connectivity_TestApp.cpp
- Committer:
- andreikovacs
- Date:
- 2015-07-30
- Revision:
- 3:b9e209eca377
- Parent:
- 2:aaffc5d91884
- Child:
- 4:fb5e683a878c
File content as of revision 3:b9e209eca377:
/*! * Copyright (c) 2015, Freescale Semiconductor, Inc. * All rights reserved. * * \file Connectivity_TestApp.c * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * * o Redistributions of source code must retain the above copyright notice, this list * of conditions and the following disclaimer. * * o Redistributions in binary form must reproduce the above copyright notice, this * list of conditions and the following disclaimer in the documentation and/or * other materials provided with the distribution. * * o Neither the name of Freescale Semiconductor, Inc. nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /************************************************************************************ ************************************************************************************* * Include ************************************************************************************* ************************************************************************************/ #include "Application_Interface.h" #include "Connectivity_Test_Platform.h" /************************************************************************************ ************************************************************************************* * Private type definitions ************************************************************************************* ************************************************************************************/ /************************************************************************************ ************************************************************************************* * Macros ************************************************************************************* ************************************************************************************/ #define gPrbs9BufferLength_c ( 65 ) #define gContTxModSelectPN9_c ( 2 ) #define gContTxModSelectOnes_c ( 1 ) #define gContTxModSelectZeros_c ( 0 ) #define SelfNotificationEvent() \ do \ { \ gTaskEventFlags |= gCTSelf_EVENT_c; \ mainTask->signal_set(gEventsAny_c); \ }while(0); #define ResetMCU() NVIC_SystemReset() #define gUART_RX_EVENT_c (1<<0) #define gMcps_Cnf_EVENT_c (1<<1) #define gMcps_Ind_EVENT_c (1<<2) #define gMlme_EdCnf_EVENT_c (1<<3) #define gMlme_CcaCnf_EVENT_c (1<<4) #define gMlme_TimeoutInd_EVENT_c (1<<5) #define gRangeTest_EVENT_c (1<<6) #define gCTSelf_EVENT_c (1<<7) #define gTimePassed_EVENT_c (1<<8) #define gEventsAny_c (1<<9) #define Delay_ms(a) #define FlaggedDelay_ms(a) ConnTestTimeout.attach_us(DelayTimeElapsed, (a) * 1000) #ifdef gPHY_802_15_4g_d #define GetTimestampUS() PhyTime_GetTimestampUs() #define GetTransmissionTime(payload, bitrate) ((((gPhyFSKPreambleLength_c + \ gPhyMRFSKPHRLength_c + gPhyMRFSKSFDLength_c + \ sizeof(smacHeader_t) + payload + gPhyFCSSize_c )*8000 )/ bitrate)) #else #define GetTimestampUS() (16*PhyTime_GetTimestamp()) #define GetTransmissionTime(payload, bitrate) (((6 + sizeof(smacHeader_t) + payload + 2)*32)) //bitrate is fixed for 2.4 GHz #define crtBitrate (0) #endif /************************************************************************************ ************************************************************************************* * Public memory declarations ************************************************************************************* ************************************************************************************/ uint32_t gTaskEventFlags; /*smac related variables*/ bool_t bTxDone; bool_t bRxDone; bool_t bScanDone; bool_t gCCaGotResult; bool_t gIsChannelIdle; bool_t bEdDone; bool_t failedPRBS9; uint8_t u8LastRxRssiValue; bool_t evTestParameters; uint8_t au8ScanResults[129]; /*serial manager related variables*/ uint8_t gu8UartData; bool_t evDataFromUART; uint8_t mAppSer; /*connectivity test state machine variables*/ operationModes_t testOpMode; operationModes_t prevOpMode; channels_t testChannel; uint8_t testPower; uint8_t testPayloadLen; uint8_t contTxModBitValue; uint8_t ccaThresh; bool_t shortCutsEnabled; ConnectivityStates_t connState; ContinuousTxRxTestStates_t cTxRxState; PerTxStates_t perTxState; PerRxStates_t perRxState; RangeTxStates_t rangeTxState; RangeRxStates_t rangeRxState; EditRegsStates_t eRState; oRStates_t oRState; rRStates_t rRState; dRStates_t dRState; CSenseTCtrlStates_t cstcState; uint8_t ChannelToScan; smacTestMode_t contTestRunning; /*asp related variables*/ AppToAspMessage_t aspTestRequestMsg; extern uint8_t u8Prbs9Buffer[gPrbs9BufferLength_c]; Serial uart(USBTX,USBRX); Thread *mainTask; /************************************************************************************ ************************************************************************************* * Private memory declarations ************************************************************************************* ************************************************************************************/ static uint8_t gau8RxDataBuffer[gMaxSmacSDULength_c + sizeof(txPacket_t)]; static uint8_t gau8TxDataBuffer[gMaxSmacSDULength_c + sizeof(rxPacket_t)]; static txPacket_t * gAppTxPacket; static rxPacket_t * gAppRxPacket; static uint8_t timePassed; Timeout RangeTestTmr; Timeout ConnTestTimeout; Timer AppDelayTmr; /************************************************************************************ ************************************************************************************* * Private prototypes ************************************************************************************* ************************************************************************************/ #if CT_Feature_Calibration extern void StoreTrimValueToFlash (uint32_t trimValue, CalibrationOptionSelect_t option); #endif /*platform independent functions*/ static void SerialUIStateMachine(void); static bool_t SerialContinuousTxRxTest(void); static bool_t PacketErrorRateTx(void); static bool_t PacketErrorRateRx(void); static void SetRadioRxOnNoTimeOut(void); static void HandleEvents(int32_t evSignals); static void PrintTestParameters(bool_t bEraseLine); static void PrintPerRxFinalLine(uint16_t u16Received, uint16_t u16Total); extern uint32_t HexString2Dec(uint8_t * au8String); static bool_t stringComp(uint8_t * au8leftString, uint8_t * au8RightString, uint8_t bytesToCompare); /********************************/ static void RangeTest_Timer_CallBack (); static bool_t RangeTx(void); static bool_t RangeRx(void); static bool_t EditRegisters(void); #if CT_Feature_Direct_Registers || CT_Feature_Indirect_Registers bool_t OverrideRegisters(void); bool_t ReadRegisters(void); bool_t DumpRegisters(void); bool_t bIsRegisterDirect = TRUE; #endif static bool_t CSenseAndTCtrl(void); static void TransmissionControlHandler(void); static void CarrierSenseHandler(void); static smacErrors_t TestMode ( smacTestMode_t mode); static void PacketHandler_Prbs9(void); static void DelayTimeElapsed(); static void IncrementChannelOnEdEvent(); extern void ReadRFRegs(registerAddressSize_t, registerAddressSize_t); extern void PrintTestParameters(bool_t bEraseLine); /*************************************/ /************************************************************************************ ************************************************************************************* * Public functions ************************************************************************************* ************************************************************************************/ void InitProject(void); void InitSmac(void); void main_task(void const *argument); void UartRxCallBack(void); void PrintMenu(char * const pu8Menu[], uint8_t port); /************************************************************************************ * * InitProject * ************************************************************************************/ void InitProject(void) { /*Global Data init*/ testPayloadLen = gMaxSmacSDULength_c; testOpMode = gDefaultOperationMode_c; testChannel = gDefaultChannelNumber_c; testPower = gDefaultOutputPower_c; testPayloadLen = gDefaultPayload_c; contTestRunning = gTestModeForceIdle_c; shortCutsEnabled = FALSE; connState = gConnInitState_c; cTxRxState = gCTxRxStateInit_c; perTxState = gPerTxStateInit_c; perRxState = gPerRxStateInit_c; rangeTxState = gRangeTxStateInit_c; rangeRxState = gRangeRxStateInit_c; prevOpMode = gDefaultOperationMode_c; oRState = gORStateInit_c; rRState = gRRStateInit_c; dRState = gDRStateInit_c; ccaThresh = gDefaultCCAThreshold_c; bEdDone = FALSE; evDataFromUART = FALSE; InitProject_custom(); } /************************************************************************************ ************************************************************************************* * SAP functions ************************************************************************************* ************************************************************************************/ //(Management) Sap handler for managing timeout indication and ED confirm smacErrors_t smacToAppMlmeSap(smacToAppMlmeMessage_t* pMsg, instanceId_t instance) { switch(pMsg->msgType) { case gMlmeEdCnf_c: au8ScanResults[pMsg->msgData.edCnf.scannedChannel] = pMsg->msgData.edCnf.energyLeveldB; gTaskEventFlags |= gMlme_EdCnf_EVENT_c; mainTask->signal_set(gEventsAny_c); break; case gMlmeCcaCnf_c: gTaskEventFlags |= gMlme_CcaCnf_EVENT_c; mainTask->signal_set(gEventsAny_c); if(pMsg->msgData.ccaCnf.status == gErrorNoError_c) gIsChannelIdle = TRUE; else gIsChannelIdle = FALSE; break; case gMlmeTimeoutInd_c: gTaskEventFlags |= gMlme_TimeoutInd_EVENT_c; mainTask->signal_set(gEventsAny_c); break; default: break; } MEM_BufferFree(pMsg); return gErrorNoError_c; } //(Data) Sap handler for managing data confirm and data indication smacErrors_t smacToAppMcpsSap(smacToAppDataMessage_t* pMsg, instanceId_t instance) { switch(pMsg->msgType) { case gMcpsDataInd_c: if(pMsg->msgData.dataInd.pRxPacket->rxStatus == rxSuccessStatus_c) { u8LastRxRssiValue = pMsg->msgData.dataInd.u8LastRxRssi; gTaskEventFlags |= gMcps_Ind_EVENT_c; mainTask->signal_set(gEventsAny_c); } break; case gMcpsDataCnf_c: if(pMsg->msgData.dataCnf.status == gErrorNoError_c) { gTaskEventFlags |= gMcps_Cnf_EVENT_c; mainTask->signal_set(gEventsAny_c); } break; default: break; } MEM_BufferFree(pMsg); return gErrorNoError_c; } static void HandleEvents(int32_t evSignals) { if(evSignals & gUART_RX_EVENT_c) { if(shortCutsEnabled) { ShortCutsParser(gu8UartData); } else { evDataFromUART = TRUE; } } if(evSignals & gMcps_Cnf_EVENT_c) { bTxDone = TRUE; } if(evSignals & gMcps_Ind_EVENT_c) { bRxDone = TRUE; } if(evSignals & gMlme_TimeoutInd_EVENT_c) { } if(evSignals & gRangeTest_EVENT_c) { bRxDone=TRUE; } if(evSignals & gMlme_EdCnf_EVENT_c) { if (cTxRxState == gCTxRxStateRunnigScanTest_c) { IncrementChannelOnEdEvent(); } if (cTxRxState == gCTxRxStateRunnigEdTest_c) { cTxRxState = gCTxRxStateRunningEdTestGotResult_c; } if (connState == gConnCSenseAndTCtrl_c) { bScanDone = TRUE; } bEdDone = TRUE; } if(evSignals & gMlme_CcaCnf_EVENT_c) { gCCaGotResult = TRUE; uart.printf("Channel %d is", (uint32_t)testChannel); if(gIsChannelIdle) uart.printf("Idle\r\n"); else uart.printf("Busy\r\n"); } if(evSignals & gCTSelf_EVENT_c) { } } /*************************************************************************/ /*Main Task: Application entry point*/ /*************************************************************************/ void main_task(void const *argument) { static bool_t bIsInitialized = FALSE; static bool_t bUserInteraction = FALSE; //Initialize Memory Manager, Timer Manager and LEDs. if( !bIsInitialized ) { MEM_Init(); //initialize PHY Phy_Init(); InitApp(); uart.attach(&UartRxCallBack); /*Prints the Welcome screens in the terminal*/ PrintMenu(cu8FreescaleLogo, mAppSer); connState = gConnIdleState_c; bIsInitialized = TRUE; } if(!bUserInteraction) { while(1) { Thread::signal_wait(gEventsAny_c); if(gu8UartData == '\r') { SelfNotificationEvent(); bUserInteraction = TRUE; break; } else { PrintMenu(cu8FreescaleLogo, mAppSer); } } } if(bUserInteraction) { while(1) { Thread::signal_wait(gEventsAny_c); HandleEvents(gTaskEventFlags); SerialUIStateMachine(); } } } /*************************************************************************/ /*InitApp: Initializes application mdoules and data*/ /*************************************************************************/ void InitApp() { gAppTxPacket = (txPacket_t*)gau8TxDataBuffer; //Map TX packet to buffer gAppRxPacket = (rxPacket_t*)gau8RxDataBuffer; //Map Rx packet to buffer gAppRxPacket->u8MaxDataLength = gMaxSmacSDULength_c; uart.baud(115200); //Initialise SMAC InitSmac(); //Tell SMAC who to call when it needs to pass a message to the application thread. Smac_RegisterSapHandlers((SMAC_APP_MCPS_SapHandler_t)smacToAppMcpsSap,(SMAC_APP_MLME_SapHandler_t)smacToAppMlmeSap,0); InitProject(); InitApp_custom(); ASP_Init(0, mAppSer); SMACFillHeader(&(gAppTxPacket->smacHeader), gBroadcastAddress_c); //@CMA, Conn Test. Start with broadcast address default (void)MLMEPAOutputAdjust(testPower); (void)MLMESetChannelRequest(testChannel); //@CMA, Conn Test. Start Foperation at default channel } /************************************************************************************ * * Connectivity Test State Machine * ************************************************************************************/ void SerialUIStateMachine(void) { if((gConnSelectTest_c == connState) && evTestParameters) { #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMESetChannelRequest(testChannel); (void)MLMEPAOutputAdjust(testPower); PrintTestParameters(TRUE); evTestParameters = FALSE; } switch(connState) { case gConnIdleState_c: PrintMenu(cu8MainMenu, mAppSer); PrintTestParameters(FALSE); shortCutsEnabled = TRUE; connState = gConnSelectTest_c; break; case gConnSelectTest_c: if(evDataFromUART){ if('1' == gu8UartData) { cTxRxState = gCTxRxStateInit_c; connState = gConnContinuousTxRxState_c; } else if('2' == gu8UartData) { perTxState = gPerTxStateInit_c; perRxState = gPerRxStateInit_c; connState = gConnPerState_c; } else if('3' == gu8UartData) { rangeTxState = gRangeTxStateInit_c; rangeRxState = gRangeRxStateInit_c; connState = gConnRangeState_c; } else if('4' == gu8UartData) { cstcState = gCsTcStateInit_c; connState = gConnCSenseAndTCtrl_c; } #if CT_Feature_Direct_Registers || CT_Feature_Indirect_Registers else if('5' == gu8UartData) { eRState = gERStateInit_c; connState = gConnRegEditState_c; } #endif #if CT_Feature_Bitrate_Select else if('6' == gu8UartData) { bsState = gBSStateInit_c; connState = gConnBitrateSelectState_c; } #endif #if CT_Feature_Calibration else if('7' == gu8UartData) { connState = gConnEDMeasCalib_c; edCalState= gEdCalStateInit_c; } #endif else if('!' == gu8UartData) { ResetMCU(); } evDataFromUART = FALSE; SelfNotificationEvent(); } break; case gConnContinuousTxRxState_c: if(SerialContinuousTxRxTest()) { connState = gConnIdleState_c; SelfNotificationEvent(); } break; case gConnPerState_c: if(mTxOperation_c == testOpMode) { if(PacketErrorRateTx()) { connState = gConnIdleState_c; SelfNotificationEvent(); } } else { if(PacketErrorRateRx()) { connState = gConnIdleState_c; SelfNotificationEvent(); } } break; case gConnRangeState_c: if(mTxOperation_c == testOpMode) { if(RangeTx()) { connState = gConnIdleState_c; SelfNotificationEvent(); } } else { if(RangeRx()) { connState = gConnIdleState_c; SelfNotificationEvent(); } } break; case gConnRegEditState_c: if(EditRegisters()) { connState = gConnIdleState_c; SelfNotificationEvent(); } break; #if CT_Feature_Bitrate_Select case gConnBitrateSelectState_c: if(Bitrate_Select()) { connState = gConnIdleState_c; } break; #endif case gConnCSenseAndTCtrl_c: if(CSenseAndTCtrl()) { connState = gConnIdleState_c; SelfNotificationEvent(); } break; #if CT_Feature_Calibration case gConnEDMeasCalib_c: if(EDCalibrationMeasurement()) { connState = gConnIdleState_c; SelfNotificationEvent(); } break; #endif default: break; } if(prevOpMode != testOpMode) { perTxState = gPerTxStateInit_c; perRxState = gPerRxStateInit_c; rangeTxState = gRangeTxStateInit_c; rangeRxState = gRangeRxStateInit_c; prevOpMode = testOpMode; SelfNotificationEvent(); } } /************************************************************************************ * * Continuous Tests State Machine * ************************************************************************************/ bool_t SerialContinuousTxRxTest(void) { bool_t bBackFlag = FALSE; uint8_t u8Index, u8TempEnergyValue, u8TempScanValue; if(evTestParameters) { (void)TestMode(gTestModeForceIdle_c); #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMESetChannelRequest(testChannel); (void)MLMEPAOutputAdjust(testPower); if(gTestModePRBS9_c == contTestRunning) { cTxRxState = gCTxRxStateRunningPRBS9Test_c; } (void)TestMode(contTestRunning); if(gCTxRxStateSelectTest_c == cTxRxState) { PrintTestParameters(TRUE); } else { PrintTestParameters(FALSE); uart.printf("\r\n"); } if(gCTxRxStateRunnigRxTest_c == cTxRxState) { bRxDone = FALSE; gAppRxPacket->u8MaxDataLength = gMaxSmacSDULength_c; (void)MLMERXEnableRequest(gAppRxPacket, 0); } evTestParameters = FALSE; } switch(cTxRxState) { case gCTxRxStateIdle_c: if((evDataFromUART) && ('\r' == gu8UartData)) { cTxRxState = gCTxRxStateInit_c; evDataFromUART = FALSE; SelfNotificationEvent(); } break; case gCTxRxStateInit_c: PrintMenu(cu8ShortCutsBar, mAppSer); PrintMenu(cu8ContinuousTestMenu, mAppSer); //Phy in StandBy, smacstate in Idle. (void)TestMode(gTestModeForceIdle_c); while(MLMESetChannelRequest(testChannel)); uart.printf(cu8ContinuousTestTags[contTestRunning]); if(contTestRunning == gTestModeContinuousTxModulated_c) { uart.printf(cu8TxModTestTags[contTxModBitValue]); } (void)TestMode(contTestRunning); uart.printf("\r\n\r\n"); PrintTestParameters(FALSE); shortCutsEnabled = TRUE; cTxRxState = gCTxRxStateSelectTest_c; break; case gCTxRxStateSelectTest_c: if(evDataFromUART) { if('1' == gu8UartData) { contTestRunning = gTestModeForceIdle_c; cTxRxState = gCTxRxStateInit_c; SelfNotificationEvent(); } else if('2' == gu8UartData) { shortCutsEnabled = FALSE; (void)TestMode(gTestModeForceIdle_c); contTestRunning = gTestModePRBS9_c; MLMESetChannelRequest(testChannel); uart.printf("\f\r\nPress [p] to stop the Continuous PRBS9 test\r\n"); (void)TestMode(contTestRunning); cTxRxState = gCTxRxStateRunningPRBS9Test_c; } else if('3' == gu8UartData) { contTestRunning = gTestModeContinuousTxModulated_c; cTxRxState = gCTxRxStateRunningTXModSelectOpt; // uart.printf( "\f\r\n To use this mode shunt pins 3-4 on J18"); uart.printf("\f\r\nPress 2 for PN9, 1 to modulate values of 1 and 0 to modulate values of 0"); } else if('4' == gu8UartData) { if(gTestModeContinuousTxUnmodulated_c != contTestRunning) { contTestRunning = gTestModeContinuousTxUnmodulated_c; cTxRxState = gCTxRxStateInit_c; SelfNotificationEvent(); } } else if('5' == gu8UartData) { shortCutsEnabled = FALSE; (void)TestMode(gTestModeForceIdle_c); MLMESetChannelRequest(testChannel); contTestRunning = gTestModeForceIdle_c; uart.printf("\f\r\nPress [p] to stop receiving broadcast packets \r\n"); bRxDone = FALSE; gAppRxPacket->u8MaxDataLength = gMaxSmacSDULength_c; (void)MLMERXEnableRequest(gAppRxPacket, 0); cTxRxState = gCTxRxStateRunnigRxTest_c; } else if('6' == gu8UartData) { (void)TestMode(gTestModeForceIdle_c); contTestRunning = gTestModeForceIdle_c; uart.printf("\f\r\nPress [p] to stop the Continuous ED test\r\n"); cTxRxState = gCTxRxStateRunnigEdTest_c; FlaggedDelay_ms(200); } else if('7' == gu8UartData) { (void)TestMode(gTestModeForceIdle_c); contTestRunning = gTestModeForceIdle_c; ChannelToScan= gDefaultChannelNumber_c; uart.printf("\f\r\nPress [p] to stop the Continuous SCAN test\r\n"); bScanDone = FALSE; cTxRxState = gCTxRxStateRunnigScanTest_c; SelfNotificationEvent(); } else if('8' == gu8UartData) { (void)TestMode(gTestModeForceIdle_c); uart.printf("\f\r\nPress [p] to stop the Continuous CCA test\r\n"); contTestRunning = gTestModeForceIdle_c; cTxRxState = gCTxRxStateRunnigCcaTest_c; FlaggedDelay_ms(100); MLMECcaRequest(); } #if CT_Feature_BER_Test else if ('9' == gu8UartData) { uart.printf( "\f\r\nPress [p] to stop the Continuous BER test\r\n"); contTestRunning = gTestModeContinuousRxBER_c; cTxRxState = gCTxRxStateInit_c; SelfNotificationEvent(); } #endif else if('p' == gu8UartData) { (void)TestMode(gTestModeForceIdle_c); (void)MLMESetChannelRequest(testChannel); AppDelayTmr.stop(); timePassed = FALSE; bBackFlag = TRUE; } evDataFromUART = FALSE; } break; case gCTxRxStateRunningTXModSelectOpt: if(evDataFromUART) { if(gu8UartData == '2') contTxModBitValue = gContTxModSelectPN9_c; else if(gu8UartData == '1') contTxModBitValue = gContTxModSelectOnes_c; else if(gu8UartData == '0') contTxModBitValue = gContTxModSelectZeros_c; evDataFromUART = FALSE; cTxRxState = gCTxRxStateInit_c; SelfNotificationEvent(); } break; case gCTxRxStateRunningPRBS9Test_c: if(bTxDone || failedPRBS9) { failedPRBS9 = FALSE; bTxDone = FALSE; PacketHandler_Prbs9(); } if(evDataFromUART && 'p' == gu8UartData) { contTestRunning = gTestModeForceIdle_c; (void)TestMode(gTestModeForceIdle_c); (void)MLMESetChannelRequest(testChannel); AppDelayTmr.stop(); timePassed = FALSE; uart.printf("\r\n\r\n Press [enter] to go back to the Continuous test menu "); cTxRxState = gCTxRxStateIdle_c; evDataFromUART = FALSE; shortCutsEnabled = TRUE; } break; case gCTxRxStateRunnigRxTest_c: if(bRxDone) { if (gAppRxPacket->rxStatus == rxSuccessStatus_c) { uart.printf("New Packet: "); for(u8Index = 0; u8Index < (gAppRxPacket->u8DataLength); u8Index++){ uart.printf( (const char *)(&(gAppRxPacket->smacPdu.smacPdu[u8Index]))); } uart.printf(" \r\n"); } bRxDone = FALSE; gAppRxPacket->u8MaxDataLength = gMaxSmacSDULength_c; (void)MLMERXEnableRequest(gAppRxPacket, 0); } if((evDataFromUART) && ('p' == gu8UartData)) { (void)MLMERXDisableRequest(); (void)TestMode(gTestModeForceIdle_c); uart.printf("\r\n\r\n Press [enter] to go back to the Continuous test menu "); cTxRxState = gCTxRxStateIdle_c; evDataFromUART = FALSE; } break; case gCTxRxStateRunnigEdTest_c: if(timePassed) { timePassed = FALSE; FlaggedDelay_ms(100); MLMEScanRequest(testChannel); } if((evDataFromUART) && ('p' == gu8UartData)) { uart.printf("\r\n\r\n Press [enter] to go back to the Continuous test menu "); cTxRxState = gCTxRxStateIdle_c; evDataFromUART = FALSE; timePassed = FALSE; AppDelayTmr.stop(); } break; case gCTxRxStateRunningEdTestGotResult_c: uart.printf("Energy on the Channel %d : ", (uint32_t)testChannel); u8TempEnergyValue = au8ScanResults[testChannel]; if(u8TempEnergyValue != 0) uart.printf( "-"); uart.printf("%d dBm\r\n ",(uint32_t)u8TempEnergyValue); cTxRxState = gCTxRxStateRunnigEdTest_c; break; case gCTxRxStateRunnigCcaTest_c: if(timePassed && gCCaGotResult) { gCCaGotResult = FALSE; timePassed = FALSE; MLMECcaRequest(); FlaggedDelay_ms(100); } if((evDataFromUART) && ('p' == gu8UartData)) { uart.printf("\r\n\r\n Press [enter] to go back to the Continuous test menu "); cTxRxState = gCTxRxStateIdle_c; evDataFromUART = FALSE; timePassed = FALSE; AppDelayTmr.stop(); } break; case gCTxRxStateRunnigScanTest_c: if(bScanDone && timePassed) { //Enters here until all channels have been scanned. Then starts to print. uart.printf("Results : "); for(u8Index = gMinChannel_c; u8Index <= gMaxChannel_c ; u8Index++) { u8TempScanValue= au8ScanResults[u8Index]; if(u8TempScanValue != 0) uart.printf("-"); uart.printf("%d, ", (uint32_t) u8TempScanValue); } uart.printf("\b \r\n"); bScanDone = FALSE; ChannelToScan = gDefaultChannelNumber_c; // Restart channel count timePassed = FALSE; } if((evDataFromUART) && ('p' == gu8UartData)) { uart.printf("\r\n\r\n Press [enter] to go back to the Continuous test menu "); cTxRxState = gCTxRxStateIdle_c; evDataFromUART = FALSE; } else { if(ChannelToScan == gDefaultChannelNumber_c) { smacErrors_t err = MLMEScanRequest((channels_t)ChannelToScan); if(err == gErrorNoError_c) ChannelToScan++; } //Each of the other channels is scanned after SMAC notifies us that //it has obtained the energy value on the currently scanned channel //(channel scanning is performed asynchronously). See IncrementChannelOnEdEvent(). } break; default: break; } return bBackFlag; } /************************************************************************************ * * PER Handler for board that is performing TX * ************************************************************************************/ bool_t PacketErrorRateTx(void) { const uint16_t u16TotalPacketsOptions[] = {1,25,100,500,1000,2000,5000,10000,65535}; static uint16_t u16TotalPackets; static uint16_t u16SentPackets; static uint32_t miliSecDelay; static uint32_t u32MinDelay = 4; uint8_t u8Index; bool_t bBackFlag = FALSE; if(evTestParameters) { (void)MLMERXDisableRequest(); #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMESetChannelRequest(testChannel); (void)MLMEPAOutputAdjust(testPower); PrintTestParameters(TRUE); evTestParameters = FALSE; } switch(perTxState) { case gPerTxStateInit_c: PrintMenu(cu8ShortCutsBar, mAppSer); PrintMenu(cu8PerTxTestMenu, mAppSer); PrintTestParameters(FALSE); shortCutsEnabled = TRUE; perTxState = gPerTxStateSelectPacketNum_c; miliSecDelay = 0; u32MinDelay = 4; (void)MLMERXDisableRequest(); break; case gPerTxStateSelectPacketNum_c: if(evDataFromUART) { if((gu8UartData >= '0') && (gu8UartData <= '8')) { u16TotalPackets = u16TotalPacketsOptions[gu8UartData - '0']; shortCutsEnabled = FALSE; u32MinDelay += (GetTransmissionTime(testPayloadLen, crtBitrate) / 1000); uart.printf("\r\n\r\n Please type TX interval in miliseconds ( > %d ms ) and press [ENTER]\r\n", u32MinDelay); perTxState = gPerTxStateInputPacketDelay_c; } else if('p' == gu8UartData) { bBackFlag = TRUE; } evDataFromUART = FALSE; } break; case gPerTxStateInputPacketDelay_c: if(evDataFromUART) { if(gu8UartData == '\r') { if(miliSecDelay < u32MinDelay) { uart.printf("\r\n\tError: TX Interval too small\r\n"); perTxState = gPerTxStateInit_c; SelfNotificationEvent(); } else { perTxState = gPerTxStateStartTest_c; SelfNotificationEvent(); } } else if((gu8UartData >= '0') && (gu8UartData <='9')) { miliSecDelay = miliSecDelay*10 + (gu8UartData - '0'); uart.printf("%d", (uint32_t)(gu8UartData - '0')); } else if('p' == gu8UartData) { perTxState = gPerTxStateInit_c; SelfNotificationEvent(); } evDataFromUART = FALSE; } break; case gPerTxStateStartTest_c: gAppTxPacket->u8DataLength = testPayloadLen; u16SentPackets = 0; gAppTxPacket->smacPdu.smacPdu[0] = (u16TotalPackets >> 8); gAppTxPacket->smacPdu.smacPdu[1] = (uint8_t)u16TotalPackets; gAppTxPacket->smacPdu.smacPdu[2] = ((u16SentPackets+1) >> 8); gAppTxPacket->smacPdu.smacPdu[3] = (uint8_t)(u16SentPackets+1); FLib_MemCpy(&(gAppTxPacket->smacPdu.smacPdu[4]), (void*)"SMAC PER Demo",13); if(17 < testPayloadLen) { for(u8Index=17;u8Index<testPayloadLen;u8Index++) { gAppTxPacket->smacPdu.smacPdu[u8Index] = (u8Index%10)+'0'; } } bTxDone = FALSE; (void)MCPSDataRequest(gAppTxPacket); u16SentPackets++; uart.printf("\f\r\n Running PER Tx, Sending %d Packets",(uint32_t)u16TotalPackets); perTxState = gPerTxStateRunningTest_c; FlaggedDelay_ms(miliSecDelay); break; case gPerTxStateRunningTest_c: if(bTxDone && timePassed) { uart.printf("\r\n Packet %d ",(uint32_t)u16SentPackets); if(u16SentPackets == u16TotalPackets) { uart.printf("\r\n\r\nSending last %d frames \r\n",(uint32_t)mTotalFinalFrames_c); FLib_MemCpy(&(gAppTxPacket->smacPdu.smacPdu[4]), (void *)"DONE",4); gAppTxPacket->u8DataLength = 8; u16SentPackets = 0; u16TotalPackets = mTotalFinalFrames_c; gAppTxPacket->u8DataLength = 8; perTxState = gPerTxStateSendingLastFrames_c; } else { gAppTxPacket->smacPdu.smacPdu[2] = ((u16SentPackets+1) >> 8); gAppTxPacket->smacPdu.smacPdu[3] = (uint8_t)(u16SentPackets+1); gAppTxPacket->u8DataLength = testPayloadLen; } bTxDone = FALSE; (void)MCPSDataRequest(gAppTxPacket); u16SentPackets++; timePassed = FALSE; FlaggedDelay_ms(miliSecDelay); } if(evDataFromUART && gu8UartData == ' ') { uart.printf("\r\n\r\n-Test interrupted by user. Press [ENTER] to continue\r\n\r\n"); perTxState = gPerTxStateIdle_c; } break; case gPerTxStateSendingLastFrames_c: if(bTxDone && timePassed) { bTxDone = FALSE; timePassed = FALSE; uart.printf("\r\n Final Packet %d",(uint32_t)u16SentPackets); if(u16SentPackets == u16TotalPackets) { uart.printf( "\r\n PER Tx DONE \r\n"); uart.printf( "\r\n\r\n Press [enter] to go back to the PER Tx test menu "); perTxState = gPerTxStateIdle_c; AppDelayTmr.stop(); timePassed = FALSE; } else { gAppTxPacket->u8DataLength = 8; (void)MCPSDataRequest(gAppTxPacket); u16SentPackets++; FlaggedDelay_ms(miliSecDelay); } } if(evDataFromUART && gu8UartData == ' ') { uart.printf("\r\n\r\n-Test interrupted by user. Press [ENTER] to continue\r\n\r\n"); perTxState = gPerTxStateIdle_c; } break; case gPerTxStateIdle_c: if((evDataFromUART) && ('\r' == gu8UartData)) { perTxState = gPerTxStateInit_c; evDataFromUART = FALSE; SelfNotificationEvent(); } break; default: break; } return bBackFlag; } /************************************************************************************ * * PER Handler for board that is performing RX * ************************************************************************************/ bool_t PacketErrorRateRx(void) { static uint16_t u16ReceivedPackets; static uint16_t u16PacketsIndex; static uint16_t u16TotalPackets; static uint16_t u16FinalPacketsCount; static uint32_t u32RssiSum; static uint8_t u8AverageRssi; uint8_t u8TempRssivalue; bool_t bBackFlag = FALSE; if(evTestParameters) { #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMESetChannelRequest(testChannel); (void)MLMEPAOutputAdjust(testPower); PrintTestParameters(TRUE); evTestParameters = FALSE; } switch(perRxState) { case gPerRxStateInit_c: u16TotalPackets = 0; u16ReceivedPackets = 0; u16PacketsIndex = 0; u32RssiSum = 0; PrintMenu(cu8ShortCutsBar, mAppSer); PrintMenu(cu8PerRxTestMenu, mAppSer); PrintTestParameters(FALSE); shortCutsEnabled = TRUE; perRxState = gPerRxWaitStartTest_c; break; case gPerRxWaitStartTest_c: if(evDataFromUART) { if(' ' == gu8UartData) { uart.printf("\f\n\rPER Test Rx Running\r\n\r\n"); SetRadioRxOnNoTimeOut(); shortCutsEnabled = FALSE; perRxState = gPerRxStateStartTest_c; } else if('p' == gu8UartData) { bBackFlag = TRUE; } evDataFromUART = FALSE; } break; case gPerRxStateStartTest_c: if(bRxDone) { if (gAppRxPacket->rxStatus == rxSuccessStatus_c) { if(stringComp((uint8_t*)"SMAC PER Demo",&gAppRxPacket->smacPdu.smacPdu[4],13)) { u16TotalPackets = ((uint16_t)gAppRxPacket->smacPdu.smacPdu[0] <<8) + gAppRxPacket->smacPdu.smacPdu[1]; u16PacketsIndex = ((uint16_t)gAppRxPacket->smacPdu.smacPdu[2] <<8) + gAppRxPacket->smacPdu.smacPdu[3]; u16ReceivedPackets++; u8TempRssivalue= u8LastRxRssiValue; //@CMA, Conn Test. New line u32RssiSum += u8TempRssivalue; u8AverageRssi = (uint8_t)(u32RssiSum/u16ReceivedPackets); uart.printf("Packet %d . Packet index: %d . Rssi during RX: - %d\r\n",(uint32_t)u16ReceivedPackets, (uint32_t)u16PacketsIndex, (uint32_t)u8LastRxRssiValue); if(u16PacketsIndex == u16TotalPackets) { u16FinalPacketsCount = 0; perRxState = gPerRxStateReceivingLastFrames_c; } } else if(stringComp((uint8_t*)"DONE",&gAppRxPacket->smacPdu.smacPdu[4],4)) { u16FinalPacketsCount = 0; perRxState = gPerRxStateReceivingLastFrames_c; } } else { if(u16TotalPackets) { u16PacketsIndex++; if(u16PacketsIndex == u16TotalPackets) { u16FinalPacketsCount = 0; perRxState = gPerRxStateReceivingLastFrames_c; } } } SetRadioRxOnNoTimeOut(); } if(evDataFromUART) { if(' ' == gu8UartData) { (void)MLMERXDisableRequest(); uart.printf("\r\nAverage Rssi during PER: -"); uart.printf("%d",(uint32_t)u8AverageRssi); uart.printf(" dBm\r\n"); uart.printf( "\n\rPER Test Rx Stopped\r\n\r\n"); PrintPerRxFinalLine(u16ReceivedPackets,u16TotalPackets); perRxState = gPerRxStateIdle_c; } evDataFromUART = FALSE; } break; case gPerRxStateReceivingLastFrames_c: if(bRxDone) { u16FinalPacketsCount++; if(mTotalFinalFrames_c == u16FinalPacketsCount) { uart.printf("\r\nAverage Rssi during PER: -"); uart.printf("%d",(uint32_t)u8AverageRssi); uart.printf(" dBm\r\n"); uart.printf( "\n\rPER Test Finished\r\n\r\n"); PrintPerRxFinalLine(u16ReceivedPackets,u16TotalPackets); perRxState = gPerRxStateIdle_c; } else { SetRadioRxOnNoTimeOut(); } } if(evDataFromUART) { if(' ' == gu8UartData) { (void)MLMERXDisableRequest(); uart.printf("\r\nAverage Rssi during PER: -"); uart.printf("%d",(uint32_t)u8AverageRssi); uart.printf(" dBm\r\n"); uart.printf( "\n\rPER Test Rx Stopped\r\n\r\n"); PrintPerRxFinalLine(u16ReceivedPackets,u16TotalPackets); perRxState = gPerRxStateIdle_c; } evDataFromUART = FALSE; } break; case gPerRxStateIdle_c: if((evDataFromUART) && ('\r' == gu8UartData)) { perRxState = gPerRxStateInit_c; SelfNotificationEvent(); } evDataFromUART = FALSE; break; default: break; } return bBackFlag; } /************************************************************************************ * * Range Test Handler for board that is performing TX * ************************************************************************************/ bool_t RangeTx(void) { bool_t bBackFlag = FALSE; static uint32_t u32RSSISum; static uint16_t u16ReceivedPackets; static uint16_t u16PacketsDropped; uint8_t u8AverageRSSI; uint8_t u8CurrentRSSI; if(evTestParameters) { #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMESetChannelRequest(testChannel); (void)MLMEPAOutputAdjust(testPower); PrintTestParameters(TRUE); evTestParameters = FALSE; } switch(rangeTxState) { case gRangeTxStateInit_c: u32RSSISum = 0; u16ReceivedPackets = 0; u16PacketsDropped = 0; PrintMenu(cu8ShortCutsBar, mAppSer); PrintMenu(cu8RangeTxTestMenu, mAppSer); PrintTestParameters(FALSE); shortCutsEnabled = TRUE; rangeTxState = gRangeTxWaitStartTest_c; break; case gRangeTxWaitStartTest_c: if(evDataFromUART) { if(' ' == gu8UartData) { shortCutsEnabled = FALSE; uart.printf( "\f\r\nRange Test Tx Running\r\n"); rangeTxState = gRangeTxStateStartTest_c; FlaggedDelay_ms(200); } else if('p' == gu8UartData) { bBackFlag = TRUE; } evDataFromUART = FALSE; } break; case gRangeTxStateStartTest_c: if(!timePassed) //waiting 200 ms break; timePassed = FALSE; bTxDone = FALSE; gAppTxPacket->u8DataLength = 16; gAppTxPacket->smacPdu.smacPdu[0] = 0; FLib_MemCpy(&(gAppTxPacket->smacPdu.smacPdu[1]), (void*)"SMAC Range Demo",15); MLMERXDisableRequest(); //RangeTestTmr.stop(); //@CMA, Conn Test. Stop Rx timer (void)MCPSDataRequest(gAppTxPacket); rangeTxState = gRangeTxStateRunningTest_c; break; case gRangeTxStateRunningTest_c: if(bTxDone) { RangeTestTmr.attach_us(RangeTest_Timer_CallBack, 80000); //@CMA, Conn Test. Start Timer SetRadioRxOnNoTimeOut(); rangeTxState = gRangeTxStatePrintTestResults_c; } break; case gRangeTxStatePrintTestResults_c: if(bRxDone) { if(gAppRxPacket->rxStatus == rxSuccessStatus_c) { if(stringComp((uint8_t*)"SMAC Range Demo",&gAppRxPacket->smacPdu.smacPdu[1],15)) { u8CurrentRSSI = (gAppRxPacket->smacPdu.smacPdu[0]); u32RSSISum += u8CurrentRSSI; u16ReceivedPackets++; u8AverageRSSI = (uint8_t)(u32RSSISum/u16ReceivedPackets); uart.printf( "\r\n RSSI = -"); uart.printf("%d", (uint32_t)u8CurrentRSSI); uart.printf(" dBm"); } else { RangeTestTmr.attach_us(RangeTest_Timer_CallBack, 80000); //@CMA, Conn Test. Start Timer SetRadioRxOnNoTimeOut(); } } else { u16PacketsDropped++; uart.printf( "\r\nPacket Dropped"); bRxDone= FALSE; //@CMA, Conn Test. Added } if(evDataFromUART && (' ' == gu8UartData)) { uart.printf( "\n\r\n\rRange Test Tx Stopped\r\n\r\n"); u8AverageRSSI = (uint8_t)(u32RSSISum/u16ReceivedPackets); uart.printf( "Average RSSI -"); uart.printf("%d", (uint32_t)u8AverageRSSI); uart.printf(" dBm"); uart.printf( "\r\nPackets dropped "); uart.printf("%d", (uint32_t)u16PacketsDropped); uart.printf( "\r\n\r\n Press [enter] to go back to the Range Tx test menu"); rangeTxState = gRangeTxStateIdle_c; (void)MLMERXDisableRequest(); AppDelayTmr.stop(); timePassed = FALSE; } else { rangeTxState = gRangeTxStateStartTest_c; FlaggedDelay_ms(200); } evDataFromUART = FALSE; } break; case gRangeTxStateIdle_c: if((evDataFromUART) && ('\r' == gu8UartData)) { rangeTxState = gRangeTxStateInit_c; SelfNotificationEvent(); } evDataFromUART = FALSE; break; default: break; } return bBackFlag; } /************************************************************************************ * * Range Test Handler for board that is performing RX * ************************************************************************************/ bool_t RangeRx(void) { bool_t bBackFlag = FALSE; static uint32_t u32RSSISum; static uint16_t u16ReceivedPackets; uint8_t u8AverageRSSI, u8TempRSSIvalue; uint8_t u8CurrentRSSI; if(evTestParameters) { #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMESetChannelRequest(testChannel); (void)MLMEPAOutputAdjust(testPower); PrintTestParameters(TRUE); evTestParameters = FALSE; } switch(rangeRxState) { case gRangeRxStateInit_c: u32RSSISum = 0; u16ReceivedPackets = 0; PrintMenu(cu8ShortCutsBar, mAppSer); PrintMenu(cu8RangeRxTestMenu, mAppSer); PrintTestParameters(FALSE); shortCutsEnabled = TRUE; rangeRxState = gRangeRxWaitStartTest_c; break; case gRangeRxWaitStartTest_c: if(evDataFromUART) { if(' ' == gu8UartData) { shortCutsEnabled = FALSE; uart.printf( "\f\r\nRange Test Rx Running\r\n"); rangeRxState = gRangeRxStateStartTest_c; } else if('p' == gu8UartData) { bBackFlag = TRUE; } evDataFromUART = FALSE; SelfNotificationEvent(); } break; case gRangeRxStateStartTest_c: SetRadioRxOnNoTimeOut(); rangeRxState = gRangeRxStateRunningTest_c; break; case gRangeRxStateRunningTest_c: if(evDataFromUART && (' ' == gu8UartData)) { (void)MLMERXDisableRequest(); uart.printf( "\n\r\n\rRange Test Rx Stopped\r\n\r\n"); u8AverageRSSI = (uint8_t)(u32RSSISum/u16ReceivedPackets); uart.printf( "Average RSSI "); if(u8AverageRSSI != 0) { uart.printf("-"); } uart.printf("%d", (uint32_t)u8AverageRSSI); uart.printf(" dBm"); uart.printf( "\r\n\r\n Press [enter] to go back to the Range Rx test menu"); rangeRxState = gRangeRxStateIdle_c; } evDataFromUART = FALSE; if(bRxDone) { if(gAppRxPacket->rxStatus == rxSuccessStatus_c) { if(stringComp((uint8_t*)"SMAC Range Demo",&gAppRxPacket->smacPdu.smacPdu[1],15)) { bRxDone = FALSE; FlaggedDelay_ms(4); } else { SetRadioRxOnNoTimeOut(); } } else { SetRadioRxOnNoTimeOut(); } } if(timePassed) { timePassed = FALSE; bTxDone = FALSE; u8TempRSSIvalue= u8LastRxRssiValue; gAppTxPacket->smacPdu.smacPdu[0] = u8TempRSSIvalue; FLib_MemCpy(&(gAppTxPacket->smacPdu.smacPdu[1]), (void *)"SMAC Range Demo",15); gAppTxPacket->u8DataLength = 16; (void)MCPSDataRequest(gAppTxPacket); rangeRxState = gRangeRxStatePrintTestResults_c; } break; case gRangeRxStatePrintTestResults_c: if(bTxDone) { u8CurrentRSSI= u8LastRxRssiValue; u32RSSISum += u8CurrentRSSI; u16ReceivedPackets++; u8AverageRSSI = (uint8_t)(u32RSSISum/u16ReceivedPackets); uart.printf( "\r\n RSSI = -"); uart.printf("%d", (uint32_t)u8CurrentRSSI); uart.printf(" dBm"); rangeRxState = gRangeRxStateStartTest_c; SelfNotificationEvent(); } break; case gRangeRxStateIdle_c: if((evDataFromUART) && ('\r' == gu8UartData)) { rangeRxState = gRangeRxStateInit_c; SelfNotificationEvent(); } evDataFromUART = FALSE; break; default: break; } return bBackFlag; } /************************************************************************************ * * Handler for viewing/modifying XCVR registers * ************************************************************************************/ bool_t EditRegisters(void) { bool_t bBackFlag = FALSE; if(evTestParameters) { #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMESetChannelRequest(testChannel); (void)MLMEPAOutputAdjust(testPower); PrintTestParameters(TRUE); evTestParameters = FALSE; } switch(eRState) { case gERStateInit_c: PrintMenu(cu8ShortCutsBar, mAppSer); PrintMenu(cu8RadioRegistersEditMenu, mAppSer); PrintTestParameters(FALSE); shortCutsEnabled = TRUE; eRState = gERWaitSelection_c; break; case gERWaitSelection_c: if(evDataFromUART) { #if CT_Feature_Direct_Registers if('1' == gu8UartData) { bIsRegisterDirect = TRUE; oRState = gORStateInit_c; eRState = gERStateOverrideReg_c; SelfNotificationEvent(); } else if('2' == gu8UartData) { bIsRegisterDirect = TRUE; rRState = gRRStateInit_c; eRState = gERStateReadReg_c; SelfNotificationEvent(); } #if CT_Feature_Indirect_Registers else if('3' == gu8UartData) { bIsRegisterDirect = FALSE; oRState = gORStateInit_c; eRState = gERStateOverrideReg_c; SelfNotificationEvent(); } else if('4' == gu8UartData) { bIsRegisterDirect = FALSE; rRState = gRRStateInit_c; eRState = gERStateReadReg_c; SelfNotificationEvent(); } else if('5' == gu8UartData) { dRState = gDRStateInit_c; eRState = gERStateDumpAllRegs_c; SelfNotificationEvent(); } #else else if('3' == gu8UartData) { dRState = gDRStateInit_c; eRState = gERStateDumpAllRegs_c; SelfNotificationEvent(); } #endif else #endif if('p' == gu8UartData) { bBackFlag = TRUE; } evDataFromUART = FALSE; } break; case gERStateOverrideReg_c: if(OverrideRegisters()) { eRState = gERStateInit_c; SelfNotificationEvent(); } break; case gERStateReadReg_c: if(ReadRegisters()) { eRState = gERStateInit_c; SelfNotificationEvent(); } break; case gERStateDumpAllRegs_c: if(DumpRegisters()) { eRState = gERStateInit_c; SelfNotificationEvent(); } break; default: break; } return bBackFlag; } /************************************************************************************ * * Dump registers * ************************************************************************************/ bool_t DumpRegisters(void) { bool_t bBackFlag = FALSE; switch(dRState) { case gDRStateInit_c: uart.printf( "\f\r\rDump Registers\r\n"); uart.printf( "\r\n-Press [space] to dump registers\r\n"); uart.printf( "\r\n-Press [p] Previous Menu\r\n"); shortCutsEnabled = FALSE; dRState = gDRStateDumpRegs_c; SelfNotificationEvent(); break; case gDRStateDumpRegs_c: if(evDataFromUART){ if(gu8UartData == 'p') { bBackFlag = TRUE; } else if (gu8UartData == ' ') { uart.printf( "\r\n -Dumping registers... \r\n"); const registerLimits_t* interval = registerIntervals; while(!((*interval).regStart == 0 && (*interval).regEnd == 0)) { uart.printf( "\r\n -Access type: "); if( (*interval).bIsRegisterDirect ) uart.printf("direct\r\n"); else uart.printf("indirect\r\n"); bIsRegisterDirect = (*interval).bIsRegisterDirect; ReadRFRegs((*interval).regStart, (*interval).regEnd); interval++; } dRState = gDRStateInit_c; SelfNotificationEvent(); } } evDataFromUART = FALSE; break; default: break; } return bBackFlag; } /************************************************************************************ * * Read and print register values with addresses from u8RegStartAddress * to u8RegStopAddress * ************************************************************************************/ void ReadRFRegs(registerAddressSize_t rasRegStartAddress, registerAddressSize_t rasRegStopAddress) { static uint16_t rasRegAddress; registerSize_t rsRegValue; uart.printf( " --------------------------------------- "); for(rasRegAddress = rasRegStartAddress; rasRegAddress <= rasRegStopAddress; rasRegAddress+=(gRegisterSize_c)) { uart.printf( "\r\n| Address : 0x"); uart.printf("%x", (uint8_t*)&rasRegAddress); aspTestRequestMsg.msgType = aspMsgTypeXcvrReadReq_c; aspTestRequestMsg.msgData.aspXcvrData.addr = (uint16_t)rasRegAddress; aspTestRequestMsg.msgData.aspXcvrData.len = gRegisterSize_c; aspTestRequestMsg.msgData.aspXcvrData.mode = !bIsRegisterDirect; APP_ASP_SapHandler(&aspTestRequestMsg, 0); rsRegValue = *((registerSize_t*)aspTestRequestMsg.msgData.aspXcvrData.data); uart.printf( " Data value : 0x"); uart.printf("%x", (uint8_t*)&rsRegValue); uart.printf( " |"); } uart.printf( "\r\n --------------------------------------- \r\n"); } /************************************************************************************ * * Read register * ************************************************************************************/ bool_t ReadRegisters(void) { bool_t bBackFlag = FALSE; static uint8_t au8RxString[5]; static uint8_t u8Index; static registerAddressSize_t rasRegAddress; static registerSize_t rsRegValue; static char auxToPrint[2]; switch(rRState) { case gRRStateInit_c: uart.printf( "\f\r\rRead Registers\r\n"); uart.printf( "\r\n-Press [p] Previous Menu\r\n"); shortCutsEnabled = FALSE; rRState = gRRStateStart_c; SelfNotificationEvent(); break; case gRRStateStart_c: uart.printf( "\r\n -write the Register address in Hex and [enter]: 0x"); u8Index = 0; rRState = gRRWaitForTheAddress_c; break; case gRRWaitForTheAddress_c: if(evDataFromUART) { if((!isAsciiHex(gu8UartData)) && ('\r' != gu8UartData)) { if('p' == gu8UartData) { bBackFlag = TRUE; } else { uart.printf( "\r\n -Invalid Character!! "); rRState = gRRStateStart_c; SelfNotificationEvent(); } } else if((gRegisterAddressASCII_c == u8Index) && ('\r' != gu8UartData)) { uart.printf( "\r\n -Value out of Range!! "); rRState = gRRStateStart_c; SelfNotificationEvent(); } else if(isAsciiHex(gu8UartData)) { au8RxString[u8Index++] = gu8UartData; auxToPrint[0] = gu8UartData; auxToPrint[1] = '\0'; uart.printf( auxToPrint); } else { au8RxString[u8Index] = 0; rasRegAddress = (registerAddressSize_t)HexString2Dec(au8RxString); aspTestRequestMsg.msgType = aspMsgTypeXcvrReadReq_c; aspTestRequestMsg.msgData.aspXcvrData.addr = (uint16_t)rasRegAddress; aspTestRequestMsg.msgData.aspXcvrData.len = gRegisterSize_c; aspTestRequestMsg.msgData.aspXcvrData.mode = !bIsRegisterDirect; APP_ASP_SapHandler(&aspTestRequestMsg, 0); rsRegValue = *((registerSize_t*)aspTestRequestMsg.msgData.aspXcvrData.data); uart.printf( "\r\n -Register value : 0x"); uart.printf("%x", (uint8_t*)&rsRegValue); uart.printf( "\r\n"); rRState = gRRStateStart_c; SelfNotificationEvent(); } evDataFromUART = FALSE; } break; default: break; } return bBackFlag; } /************************************************************************************ * * Override Register * ************************************************************************************/ bool_t OverrideRegisters(void) { bool_t bBackFlag = FALSE; static uint8_t au8RxString[5]; static uint8_t u8Index; static registerAddressSize_t rasRegAddress; static registerSize_t rsRegValue; static char auxToPrint[2]; switch(oRState) { case gORStateInit_c: uart.printf("\f\r\nWrite Registers\r\n"); uart.printf("\r\n-Press [p] Previous Menu\r\n"); shortCutsEnabled = FALSE; oRState = gORStateStart_c; SelfNotificationEvent(); break; case gORStateStart_c: uart.printf("\r\n -write the Register address in Hex and [enter]: 0x"); u8Index = 0; oRState = gORWaitForTheAddress_c; break; case gORWaitForTheAddress_c: if(evDataFromUART){ if((!isAsciiHex(gu8UartData)) && ('\r' != gu8UartData)) { if('p' == gu8UartData) { bBackFlag = TRUE; } else { uart.printf("\r\n -Invalid Character!! "); oRState = gORStateStart_c; SelfNotificationEvent(); } } else if((gRegisterAddressASCII_c == u8Index) && ('\r' != gu8UartData)) { uart.printf("\r\n -Value out of Range!! "); oRState = gORStateStart_c; SelfNotificationEvent(); } else if(isAsciiHex(gu8UartData)) { au8RxString[u8Index++] = gu8UartData; auxToPrint[0] = gu8UartData; auxToPrint[1] = '\0'; uart.printf(auxToPrint); } else { au8RxString[u8Index] = 0; rasRegAddress = (registerAddressSize_t)HexString2Dec(au8RxString); uart.printf("\r\n -write the Register value to override in Hex and [enter]: 0x"); u8Index = 0; oRState = gORWaitForTheValue_c; } evDataFromUART = FALSE; } break; case gORWaitForTheValue_c: if(evDataFromUART) { if((!isAsciiHex(gu8UartData)) && ('\r' != gu8UartData)) { if('p' == gu8UartData) { bBackFlag = TRUE; } else { uart.printf("\r\n -Invalid Character!! "); oRState = gORStateStart_c; SelfNotificationEvent(); } } else if((2 == u8Index) && ('\r' != gu8UartData)) { uart.printf("\r\n -Value out of Range!! "); oRState = gORStateStart_c; SelfNotificationEvent(); } else if(isAsciiHex(gu8UartData)) { au8RxString[u8Index++] = gu8UartData; auxToPrint[0] = gu8UartData; auxToPrint[1] = '\0'; uart.printf(auxToPrint); } else { au8RxString[u8Index] = 0; rsRegValue = (registerSize_t)HexString2Dec(au8RxString); aspTestRequestMsg.msgType = aspMsgTypeXcvrWriteReq_c; aspTestRequestMsg.msgData.aspXcvrData.addr = (uint16_t)rasRegAddress; aspTestRequestMsg.msgData.aspXcvrData.len = gRegisterAddress_c; aspTestRequestMsg.msgData.aspXcvrData.mode = !bIsRegisterDirect; FLib_MemCpy(aspTestRequestMsg.msgData.aspXcvrData.data, &rsRegValue, gRegisterSize_c); APP_ASP_SapHandler(&aspTestRequestMsg, 0); uart.printf("\r\n Register overridden \r\n"); u8Index = 0; oRState = gORStateStart_c; SelfNotificationEvent(); } evDataFromUART = FALSE; } break; default: break; } return bBackFlag; } /************************************************************************************ * * Handler for Carrier Sense Test and Transmission Control Test * ************************************************************************************/ bool_t CSenseAndTCtrl(void) { bool_t bBackFlag = FALSE; static uint8_t testSelector = 0; if(evTestParameters){ (void)MLMESetChannelRequest(testChannel); #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMEPAOutputAdjust(testPower); PrintTestParameters(TRUE); evTestParameters = FALSE; } switch(cstcState) { case gCsTcStateInit_c: TestMode(gTestModeForceIdle_c); PrintMenu(cu8ShortCutsBar, mAppSer); PrintMenu(cu8RadioCSTCSelectMenu, mAppSer); PrintTestParameters(FALSE); shortCutsEnabled = TRUE; bTxDone = FALSE; bScanDone = FALSE; timePassed = FALSE; cstcState = gCsTcStateSelectTest_c; break; case gCsTcStateSelectTest_c: if(evDataFromUART) { if('1' == gu8UartData) { cstcState = gCsTcStateCarrierSenseStart_c; testSelector = 1; SelfNotificationEvent(); } else if ('2' == gu8UartData) { cstcState = gCsTcStateTransmissionControlStart_c; testSelector = 2; SelfNotificationEvent(); } else if( 'p' == gu8UartData) { cstcState = gCsTcStateInit_c; testSelector = 0; bBackFlag = TRUE; } evDataFromUART = FALSE; } break; default: if(testSelector == 1) CarrierSenseHandler(); else if(testSelector == 2) TransmissionControlHandler(); break; } return bBackFlag; } /************************************************************************************ * * Handler for Transmission Control Test called by above function * ************************************************************************************/ void TransmissionControlHandler(void) { const uint16_t u16TotalPacketsOptions[] = {1,25,100,500,1000,2000,5000,10000,65535}; static uint16_t u16TotalPackets; static uint16_t u16PacketCounter = 0; static uint16_t miliSecDelay = 0; static phyTime_t startTime; int8_t fillIndex = 0; uint8_t* smacPduPtr; uint32_t totalTimeMs; switch(cstcState) { case gCsTcStateTransmissionControlStart_c: PrintMenu(cu8ShortCutsBar, mAppSer); PrintMenu(cu8CsTcTestMenu, mAppSer); PrintTestParameters(FALSE); miliSecDelay = 0; u16TotalPackets = 0; u16PacketCounter = 0; fillIndex = testPayloadLen / gPrbs9BufferLength_c; while(fillIndex > 0) { fillIndex--; smacPduPtr = gAppTxPacket->smacPdu.smacPdu + fillIndex * gPrbs9BufferLength_c; FLib_MemCpy(smacPduPtr, u8Prbs9Buffer, gPrbs9BufferLength_c); } smacPduPtr = gAppTxPacket->smacPdu.smacPdu + ((testPayloadLen / gPrbs9BufferLength_c)*gPrbs9BufferLength_c); FLib_MemCpy(smacPduPtr, u8Prbs9Buffer, (testPayloadLen % gPrbs9BufferLength_c)); gAppTxPacket->u8DataLength = testPayloadLen; cstcState = gCsTcStateTransmissionControlSelectNumOfPackets_c; break; case gCsTcStateTransmissionControlSelectNumOfPackets_c: if(evDataFromUART) { if((gu8UartData >= '0') && (gu8UartData <= '8')) { u16TotalPackets = u16TotalPacketsOptions[gu8UartData - '0']; cstcState = gCsTcStateTransmissionControlSelectInterpacketDelay_c; uart.printf("\r\n\r\n Please type InterPacket delay in miliseconds and press [ENTER]"); uart.printf("\r\n(During test, exit by pressing [SPACE])\r\n\r\n"); SelfNotificationEvent(); } else if('p' == gu8UartData) { cstcState = gCsTcStateInit_c; SelfNotificationEvent(); } evDataFromUART = FALSE; } break; case gCsTcStateTransmissionControlSelectInterpacketDelay_c: if(evDataFromUART) { if(gu8UartData == '\r' && miliSecDelay != 0) { cstcState = gCsTcStateTransmissionControlPerformingTest_c; startTime = GetTimestampUS(); (void)MLMEScanRequest(testChannel); } else if((gu8UartData >= '0') && (gu8UartData <='9')) { miliSecDelay = miliSecDelay*10 + (gu8UartData - '0'); uart.printf("%d",(uint32_t)(gu8UartData - '0')); } else if('p' == gu8UartData) { cstcState = gCsTcStateInit_c; SelfNotificationEvent(); } evDataFromUART = FALSE; } break; case gCsTcStateTransmissionControlPerformingTest_c: if(bScanDone) { bScanDone = FALSE; (void)MCPSDataRequest(gAppTxPacket); } if(bTxDone) { bTxDone = FALSE; u16PacketCounter++; uart.printf("\r\n\tPacket number: "); uart.printf("%d", (uint32_t)(u16PacketCounter)); uart.printf("; RSSI value: -"); uart.printf("%d",(uint32_t)au8ScanResults[testChannel]); uart.printf(" dBm\r\n"); if(u16PacketCounter < u16TotalPackets) { totalTimeMs = (uint32_t)(GetTimestampUS() - startTime); totalTimeMs -= GetTransmissionTime(testPayloadLen, crtBitrate); totalTimeMs = (totalTimeMs % 1000 < 500) ? totalTimeMs/1000 : (totalTimeMs/1000)+1; if(totalTimeMs > miliSecDelay) { uart.printf( " Overhead + Transmission + ED = ~"); uart.printf("%d", totalTimeMs); uart.printf("ms\r\n Interpacket delay too small (Press [ENTER] to continue)\r\n"); cstcState = gCsTcStateTransmissionControlEndTest_c; SelfNotificationEvent(); break; } FlaggedDelay_ms(miliSecDelay - totalTimeMs); } else { uart.printf("\r\n\r\nFinished transmitting "); uart.printf("%d", (uint32_t)u16TotalPackets); uart.printf(" packets!\r\n\r\n"); uart.printf("\r\n -Press [ENTER] to end Transmission Control Test"); cstcState = gCsTcStateTransmissionControlEndTest_c; } } if(timePassed) { timePassed = FALSE; startTime = GetTimestampUS(); (void)MLMEScanRequest(testChannel); } if(evDataFromUART && gu8UartData == ' ') { uart.printf("\r\n\r\n-Test interrupted by user. Press [ENTER] to continue\r\n\r\n"); cstcState = gCsTcStateTransmissionControlEndTest_c; } break; case gCsTcStateTransmissionControlEndTest_c: if(evDataFromUART && gu8UartData == '\r') { cstcState = gCsTcStateInit_c; SelfNotificationEvent(); } evDataFromUART = FALSE; break; } } /************************************************************************************ * * Handler for Carrier Sense Test * ************************************************************************************/ void CarrierSenseHandler(void) { int8_t fillIndex = 0; uint8_t* smacPduPtr; switch(cstcState) { case gCsTcStateCarrierSenseStart_c: #if CT_Feature_Calibration if( gMode1Bitrate_c == crtBitrate ) { (void)MLMESetAdditionalRFOffset(gOffsetIncrement + 30); } else { (void)MLMESetAdditionalRFOffset(gOffsetIncrement + 60); } #endif (void)MLMESetChannelRequest(testChannel); uart.printf( "\r\n\r\n Press [SPACE] to begin/interrupt test"); uart.printf( "\r\n Press [p] to return to previous menu"); // PrintTestParameters(FALSE); shortCutsEnabled = FALSE; uart.printf("\r\n"); fillIndex = testPayloadLen / gPrbs9BufferLength_c; while(fillIndex > 0) { fillIndex--; smacPduPtr = gAppTxPacket->smacPdu.smacPdu + fillIndex * gPrbs9BufferLength_c; FLib_MemCpy(smacPduPtr, u8Prbs9Buffer, gPrbs9BufferLength_c); } smacPduPtr = gAppTxPacket->smacPdu.smacPdu + ((testPayloadLen / gPrbs9BufferLength_c)*gPrbs9BufferLength_c); FLib_MemCpy(smacPduPtr, u8Prbs9Buffer, (testPayloadLen % gPrbs9BufferLength_c)); gAppTxPacket->u8DataLength = testPayloadLen; cstcState = gCsTcStateCarrierSenseSelectType_c; break; case gCsTcStateCarrierSenseSelectType_c: if(evDataFromUART) { if(' ' == gu8UartData) { cstcState = gCsTcStateCarrierSensePerformingTest_c; (void)MLMEScanRequest(testChannel); } else if ('p' == gu8UartData) { #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMESetChannelRequest(testChannel); cstcState = gCsTcStateInit_c; SelfNotificationEvent(); } evDataFromUART = FALSE; } break; case gCsTcStateCarrierSensePerformingTest_c: if(bScanDone) { bScanDone = FALSE; uart.printf( "\r\n\tSampling done. RSSI value: -"); uart.printf("%d", (uint32_t) au8ScanResults[testChannel]); uart.printf( "dBm"); if(au8ScanResults[testChannel] > ccaThresh) { (void)MCPSDataRequest(gAppTxPacket); } else { (void)MLMEScanRequest(testChannel); } } if(bTxDone) { bTxDone = FALSE; uart.printf("\r\n Transmission Performed\r\n"); uart.printf("\r\n -Press [ENTER] to end Carrier Sense Test"); cstcState = gCsTcStateCarrierSenseEndTest_c; } if(evDataFromUART && gu8UartData == ' ') { uart.printf("\r\n\r\n-Test interrupted by user. Press [ENTER] to continue\r\n\r\n"); cstcState = gCsTcStateCarrierSenseEndTest_c; } break; case gCsTcStateCarrierSenseEndTest_c: if(evDataFromUART && gu8UartData == '\r') { #if CT_Feature_Calibration (void)MLMESetAdditionalRFOffset(gOffsetIncrement); #endif (void)MLMESetChannelRequest(testChannel); cstcState = gCsTcStateInit_c; SelfNotificationEvent(); } evDataFromUART = FALSE; break; } } /************************************************************************************ * * Auxiliary Functions * ************************************************************************************/ /**************************************************************************************/ void SetRadioRxOnNoTimeOut(void) { bRxDone = FALSE; gAppRxPacket->u8MaxDataLength = gMaxSmacSDULength_c; (void)MLMERXEnableRequest(gAppRxPacket, 0); } /**************************************************************************************/ void PrintPerRxFinalLine(uint16_t u16Received, uint16_t u16Total) { uart.printf("Received "); uart.printf("%d",(uint32_t)u16Received); uart.printf(" of "); uart.printf("%d",(uint32_t)u16Total); uart.printf(" packets transmitted \r\n"); uart.printf("\r\n Press [enter] to go back to the Per Rx test menu"); } /************************************************************************************ * * * By employing this function, users can execute a test of the radio. Test mode * implements the following: * -PRBS9 Mode, * -Force_idle, * -Continuos TX without modulation, * -Continuos TX with modulation.(0's,1's and PN patterns) * ************************************************************************************/ smacErrors_t TestMode ( smacTestMode_t mode /*IN: The test mode to start.*/ ) { aspTestRequestMsg.msgType = aspMsgTypeTelecTest_c; #if(TRUE == smacParametersValidation_d) if(gMaxTestMode_c <= mode) { return gErrorOutOfRange_c; } #endif if(gTestModeForceIdle_c == mode) { aspTestRequestMsg.msgData.aspTelecTest.mode = gTestForceIdle_c; } else if(gTestModeContinuousTxModulated_c == mode) { /*if(contTxModBitValue==gContTxModSelectOnes_c) { aspTestRequestMsg.msgData.aspTelecTest.mode = gTestContinuousTxModOne_c; } else if(contTxModBitValue == gContTxModSelectZeros_c) { aspTestRequestMsg.msgData.aspTelecTest.mode = gTestContinuousTxModZero_c; } else */if(contTxModBitValue == gContTxModSelectPN9_c) { #ifdef gPHY_802_15_4g_d aspTestRequestMsg.msgData.aspTelecTest.mode = gTestContinuousTxContPN9_c; #else aspTestRequestMsg.msgData.aspTelecTest.mode = gTestPulseTxPrbs9_c; #endif } } else if(gTestModeContinuousTxUnmodulated_c == mode) { aspTestRequestMsg.msgData.aspTelecTest.mode = gTestContinuousTxNoMod_c; } else if(gTestModeContinuousRxBER_c == mode) { aspTestRequestMsg.msgData.aspTelecTest.mode = gTestContinuousRx_c; } else if(gTestModePRBS9_c == mode) { /*Set Data Mode*/ gAppTxPacket->u8DataLength = gPrbs9BufferLength_c; FLib_MemCpy(gAppTxPacket->smacPdu.smacPdu, u8Prbs9Buffer, gPrbs9BufferLength_c); PacketHandler_Prbs9(); } if(gTestModePRBS9_c != mode) (void)APP_ASP_SapHandler(&aspTestRequestMsg, 0); return gErrorNoError_c; } /************************************************************************************ * PacketHandler_Prbs9 * * This function sends OTA the content of a PRBS9 polynomial of 65 bytes of payload. * * ************************************************************************************/ void PacketHandler_Prbs9(void) { smacErrors_t err; /*@CMA, Need to set Smac to Idle in order to get PRBS9 to work after a second try on the Conn Test menu*/ (void)MLMERXDisableRequest(); (void)MLMETXDisableRequest(); err = MCPSDataRequest(gAppTxPacket); if(err != gErrorNoError_c) { failedPRBS9 = TRUE; SelfNotificationEvent(); //in case data isn't sent, no confirm event will fire. //this way we need to make sure the application will not freeze. } } /***************************************************************************** * UartRxCallBack function * * Interface assumptions: * This callback is triggered when a new byte is received over the UART * * Return Value: * None *****************************************************************************/ void UartRxCallBack(void) { gu8UartData = uart.getc(); gTaskEventFlags |= gUART_RX_EVENT_c; mainTask->signal_set(gEventsAny_c); } /*@CMA, Conn Test. Range Test CallBack*/ void RangeTest_Timer_CallBack () { gTaskEventFlags |= gRangeTest_EVENT_c; mainTask->signal_set(gEventsAny_c); } /************************************************************************************ * * Increments channel on the ED Confirm event and fires a new ED measurement request * ************************************************************************************/ void IncrementChannelOnEdEvent() { bScanDone = FALSE; smacErrors_t err; if (ChannelToScan <= gMaxChannel_c) { err = MLMEScanRequest((channels_t)ChannelToScan); if(err == gErrorNoError_c) ChannelToScan++; //Increment channel to scan } else { bScanDone = TRUE; //PRINT ALL CHANNEL RESULTS FlaggedDelay_ms(300); //Add delay between channel scanning series. } } /*********************************************************************** *********************Utilities Software******************************** ************************************************************************/ bool_t stringComp(uint8_t * au8leftString, uint8_t * au8RightString, uint8_t bytesToCompare) { do { }while((*au8leftString++ == *au8RightString++) && --bytesToCompare); return(0 == bytesToCompare); } uint32_t HexString2Dec(uint8_t* au8String) { uint8_t u8LocIndex=0; uint8_t u8LocIndex2=0; uint32_t u32DecValue = 0; while(au8String[u8LocIndex]){ u8LocIndex++; } while(u8LocIndex--){ if((au8String[u8LocIndex] >= '0') && (au8String[u8LocIndex] <= '9')) u32DecValue |= ((uint32_t)(au8String[u8LocIndex] - '0'))<<(u8LocIndex2*4); else if((au8String[u8LocIndex] >= 'A') && (au8String[u8LocIndex] <= 'F')){ u32DecValue |= ((uint32_t)(au8String[u8LocIndex] - 'A' + 0x0A))<<(u8LocIndex2*4); }else{ u32DecValue |= ((uint32_t)(au8String[u8LocIndex] - 'a' + 0x0A))<<(u8LocIndex2*4); } u8LocIndex2++; } return u32DecValue; } static void DelayTimeElapsed() { timePassed = TRUE; gTaskEventFlags |= gTimePassed_EVENT_c; mainTask->signal_set(gEventsAny_c); } /*********************************************************************************** * * PrintMenu * ************************************************************************************/ void PrintMenu(char * const pu8Menu[], uint8_t port) { uint8_t u8Index = 0; (void)port; while(pu8Menu[u8Index]){ uart.printf(pu8Menu[u8Index]); u8Index++; } } /*********************************************************************** ************************************************************************/ /************************************************************************************ * * PrintTestParameters * ************************************************************************************/ void PrintTestParameters(bool_t bEraseLine) { uint8_t u8lineLen = 63; uint8_t u8Index; if(bEraseLine) { for(u8Index = 0;u8Index<u8lineLen;u8Index++) { uart.printf("\b"); } } uart.printf("Mode "); if(mTxOperation_c == testOpMode) { uart.printf("Tx"); } else { uart.printf("Rx"); } uart.printf(", Channel "); uart.printf("%d", (uint32_t)testChannel); uart.printf(", Power "); uart.printf("%d",(uint32_t)testPower); uart.printf(", Payload "); uart.printf("%d", (uint32_t)testPayloadLen); uart.printf(", CCA Thresh "); if(ccaThresh != 0) { uart.printf("-"); } uart.printf("%d", (uint32_t)ccaThresh); uart.printf("dBm"); uart.printf(" >"); } /*****************************************************************************/ int main() { mainTask = new Thread(main_task); while(1) { } return 0; }