//============================================================================== int COptoTrack::DeactivateSensors( ){ int iErr; if( !IsRunning()) { CP_printf("Cannot deactivate sensors. Tracker is not active!\n"); return 1; } iErr = OptotrakDeActivateMarkers(); if( iErr ) { CP_printf("Error: OptotrakDeActivateMarkers() failed!\n"); return 1; } return 0; }
//***************************************************************** void main( int argc, unsigned char *argv[] ){ int nNumSensors, nNumOdaus, nMarkers, nSensorCode; unsigned int uFlags, uElements, uFrameCnt, uMarkerCnt, uSensorCnt, uFrameNumber, uSpoolStatus = 0; static FullRawDataType pFullRawData[ NUM_MARKERS]; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; // Load the system of transputers. if( TransputerLoadSystem( "system" ) ) { goto ERROR_EXIT; } Sleep( 1000 ); // Wait one second to let the system finish loading. // Initialize the transputer system. if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG )) { goto ERROR_EXIT; } // Set optional processing flags (this overides the settings in OPTOTRAK.INI). if( OptotrakSetProcessingFlags( OPTO_LIB_POLL_REAL_DATA | OPTO_CONVERT_ON_HOST | OPTO_RIGID_ON_HOST ) ) { goto ERROR_EXIT; } // Load the standard camera parameters. if( OptotrakLoadCameraParameters( "standard" ) ) { goto ERROR_EXIT; } // Set up a collection for the OPTOTRAK. if( OptotrakSetupCollection( NUM_MARKERS, /* Number of markers in the collection. */ (float)100.0, /* Frequency to collect data frames at. */ (float)2500.0, /* Marker frequency for marker maximum on-time. */ 30, /* Dynamic or Static Threshold value to use. */ 160, /* Minimum gain code amplification to use. */ 0, /* Stream mode for the data buffers. */ (float)0.35, /* Marker Duty Cycle to use. */ (float)7.0, /* Voltage to use when turning on markers. */ (float)1.0, /* Number of seconds of data to collect. */ (float)0.0, /* Number of seconds to pre-trigger data by. */ OPTOTRAK_BUFFER_RAW_FLAG | OPTOTRAK_GET_NEXT_FRAME_FLAG ) ) { goto ERROR_EXIT; } Sleep( 1000 ); /* // Request and receive the OPTOTRAK status. if( OptotrakGetStatus( &nNumSensors, // Number of sensors in the OPTOTRAK system. &nNumOdaus, // Number of ODAUs in the OPTOTRAK system. NULL, // Number of rigid bodies being tracked by the O/T. &nMarkers, // Number of markers in the collection. NULL, // Frequency that data frames are being collected. NULL, // Marker firing frequency. NULL, // Dynamic or Static Threshold value being used. NULL, // Minimum gain code amplification being used. NULL, // Stream mode indication for the data buffers NULL, // Marker Duty Cycle being used. NULL, // Voltage being used when turning on markers. NULL, // Number of seconds data is being collected. NULL, // Number of seconds data is being pre-triggered. NULL ) ) // Configuration flags. { goto ERROR_EXIT; } // Display elements of the status received. printf("Sensors in system :%3d\n", nNumSensors ); printf("ODAUs in system :%3d\n", nNumOdaus ); printf("Default OPTOTRAK Markers:%3d\n", nMarkers ); // Activate the markers. if( OptotrakActivateMarkers() ) { goto ERROR_EXIT; } */ // Get and display ten frames of full raw data. for( uFrameCnt = 0; uFrameCnt < 1000; ++uFrameCnt ) { // Get a frame of data. // we did set OPTOTRAK_GET_NEXT_FRAME_FLAG, so we will have // no repeating frames if( DataGetLatestRaw( &uFrameNumber, &uElements, &uFlags, pFullRawData ) ){ goto ERROR_EXIT; } printf("Frame Number: %8u\r", uFrameNumber ); /* printf("Frame Number: %8u\n", uFrameNumber ); printf("Elements : %8u\n", uElements ); printf("Flags : 0x%04x\n", uFlags ); for( uMarkerCnt = 0; uMarkerCnt < NUM_MARKERS; ++uMarkerCnt ) { printf("Marker %u\t\tCentroid Peak DRC Code\n", uMarkerCnt + 1 ); for( uSensorCnt = 0; uSensorCnt < NUM_SENSORS; ++uSensorCnt ){ printf("\tSensor %u\t", uSensorCnt + 1 ); if( pFullRawData[ uMarkerCnt].fCentroid[ uSensorCnt] < MAX_NEGATIVE ) { printf(" missing " ); } else { printf("%8.2f ", pFullRawData[ uMarkerCnt].fCentroid[ uSensorCnt] ); } nSensorCode = pFullRawData[ uMarkerCnt].SensorData[ uSensorCnt].ucCode; printf("%4d %4d %s\n", pFullRawData[ uMarkerCnt].SensorData[ uSensorCnt].ucPeak, pFullRawData[ uMarkerCnt].SensorData[ uSensorCnt].ucDRC, pSensorStatusString[ nSensorCode] ); } // for uMarkerCnt } // for uMarkerCnt */ } // for uFrameCnt // De-activate the markers. if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } // Shutdown the transputer message passing system. if( TransputerShutdownSystem() ) { goto ERROR_EXIT; } printf( "\nProgram execution complete.\n" ); return; ERROR_EXIT: if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { printf( "\n\nError!\n"); printf( szNDErrorString ); } TransputerShutdownSystem(); return; } // main
void main( int argc, unsigned char *argv[] ) { OptotrakSettings dtSettings; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1], szProperty[32]; int i, nCurDevice, nCurProperty, nCurFrame, nCurMarker, nMarkersToActivate, nDevices, nDeviceMarkers; ApplicationDeviceInformation *pdtDevices; DeviceHandle *pdtDeviceHandles; DeviceHandleInfo *pdtDeviceHandlesInfo; unsigned int uFlags, uElements, uFrameNumber; Position3d *p3dData; char *pChar, szInput[10]; /* * initialization * intialize variables */ pdtDevices = NULL; pdtDeviceHandles = NULL; pdtDeviceHandlesInfo = NULL; p3dData = NULL; nMarkersToActivate = 0; nDevices = 0; nDeviceMarkers = 0; dtSettings.nMarkers = 0; dtSettings.fFrameFrequency = SAMPLE_FRAMEFREQ; dtSettings.fMarkerFrequency = SAMPLE_MARKERFREQ; dtSettings.nThreshold = 30; dtSettings.nMinimumGain = 160; dtSettings.nStreamData = SAMPLE_STREAMDATA; dtSettings.fDutyCycle = SAMPLE_DUTYCYCLE; dtSettings.fVoltage = SAMPLE_VOLTAGE; dtSettings.fCollectionTime = 1.0; dtSettings.fPreTriggerTime = 0.0; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak Certus sample program\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Communication Initialization * Once the system processors have been loaded, the application * prepares for communication by initializing the system processors. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Determine if this sample will run with the system attached. * This sample is intended for Optotrak Certus systems. */ fprintf( stdout, "...DetermineSystem\n" ); if( uDetermineSystem( ) != OPTOTRAK_CERTUS_FLAG ) { goto PROGRAM_COMPLETE; } /* if */ EXECUTION_START: /* * Strober Initialization * Once communication has been initialized, the application must * determine the strober configuration. * The application retrieves device handles and all strober * properties from the system. */ fprintf( stdout, "...DetermineStroberConfiguration\n" ); if( DetermineStroberConfiguration( &pdtDeviceHandles, &pdtDeviceHandlesInfo, &nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Now that all the device handles have been completely set up, * the application can store all the device handle information in * an internal data structure. This will facilitate lookups when * a property setting needs to be checked. */ ApplicationStoreDeviceProperties( &pdtDevices, pdtDeviceHandlesInfo, nDevices ); /* * Change the number of markers to fire for all devices */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { nMarkersToActivate = pdtDevices[nCurDevice].b3020Capability? CERTUS_SAMPLE_3020_STROBER_MARKERSTOFIRE : CERTUS_SAMPLE_STROBER_MARKERSTOFIRE; SetMarkersToActivateForDevice( &(pdtDevices[nCurDevice]), pdtDeviceHandlesInfo[nCurDevice].pdtHandle->nID, nMarkersToActivate ); } /* if */ fprintf( stdout, "\n" ); /* * Retrieve the device properties again to verify that the changes took effect. */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { if( GetDevicePropertiesFromSystem( &(pdtDeviceHandlesInfo[nCurDevice]) ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ } /* for */ if( ApplicationStoreDeviceProperties( &pdtDevices, pdtDeviceHandlesInfo, nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Display all the property values */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { fprintf( stdout, "...Device %d properties:\n", nCurDevice ); for( nCurProperty = 0; nCurProperty < pdtDeviceHandlesInfo[nCurDevice].nProperties; nCurProperty++ ) { /* * Determine the property */ switch( pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].uPropertyID ) { case DH_PROPERTY_NAME: sprintf( szProperty, "Device Name " ); break; case DH_PROPERTY_MARKERSTOFIRE: sprintf( szProperty, "Markers To Activate " ); /* * add to the number of total markers being fired */ dtSettings.nMarkers += pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.nData; break; case DH_PROPERTY_MAXMARKERS: sprintf( szProperty, "MaxDeviceMarkers " ); break; case DH_PROPERTY_STARTMARKERPERIOD: sprintf( szProperty, "Start Marker Period " ); break; case DH_PROPERTY_SWITCHES: sprintf( szProperty, "Device Switches " ); break; case DH_PROPERTY_VLEDS: sprintf( szProperty, "Device VLEDs " ); break; case DH_PROPERTY_PORT: sprintf( szProperty, "Strober Port " ); break; case DH_PROPERTY_ORDER: sprintf( szProperty, "Strober Port Order " ); break; case DH_PROPERTY_SUBPORT: sprintf( szProperty, "Strober SubPort " ); break; case DH_PROPERTY_FIRINGSEQUENCE: sprintf( szProperty, "Activation Sequence " ); break; case DH_PROPERTY_HAS_ROM: sprintf( szProperty, "Has Rom? " ); break; case DH_PROPERTY_TOOLPORTS: sprintf( szProperty, "Num ToolPorts " ); break; case DH_PROPERTY_3020_CAPABILITY: sprintf( szProperty, "3020 Capability " ); break; case DH_PROPERTY_3020_MARKERSTOFIRE: sprintf( szProperty, "3020 MrkrsToActivate " ); /* * add to the number of total markers being fired */ dtSettings.nMarkers += pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.nData; break; case DH_PROPERTY_3020_STARTMARKERPERIOD: sprintf( szProperty, "3020 StartMarkerPrd " ); break; case DH_PROPERTY_STATUS: sprintf( szProperty, "Status " ); break; case DH_PROPERTY_UNKNOWN: default: sprintf( szProperty, "Unknown Property %d ", pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].uPropertyID ); break; } /* switch */ /* * Determine the property's data type before displaying it */ switch( pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtPropertyType ) { case DH_PROPERTY_TYPE_INT: fprintf( stdout, "......Property_%.2d - %s = %d\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.nData ); break; case DH_PROPERTY_TYPE_FLOAT: fprintf( stdout, "......Property_%.2d - %s = %f\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.fData ); break; case DH_PROPERTY_TYPE_DOUBLE: fprintf( stdout, "......Property_%.2d - %s = %f\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.dData ); break; case DH_PROPERTY_TYPE_CHAR: fprintf( stdout, "......Property_%.2d - %s = %s\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.cData ); break; case DH_PROPERTY_TYPE_STRING: if( pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].uPropertyID == DH_PROPERTY_FIRINGSEQUENCE ) { fprintf( stdout, "......Property_%.2d - %s = ", nCurProperty, szProperty ); for( pChar = pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.szData; ( pChar != '\0' ) && ( *pChar != 0 ); pChar++ ) { fprintf( stdout, "%.3d, ", *pChar ); } /* for */ fprintf( stdout, "\n" ); } else { fprintf( stdout, "......Property_%.2d - %s = %s\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.szData ); } /* if */ break; default: fprintf( stdout, "......Property_%.2d = UNKNOWN PROPERTY TYPE\n", nCurDevice ); break; } /* switch */ } /* for */ fprintf( stdout, "\n" ); } /* for */ fprintf( stdout, "Continue? or determine strober configuration Again? [c|a] : " ); gets( szInput ); if( szInput[0] == 'a' ) { goto EXECUTION_START; } /* if */ /* * Retrieve Optotrak Data */ fprintf( stdout, "\n" ); /* * check if any devices have been detected by the system */ if( nDevices == 0 ) { fprintf( stdout, ".........no devices detected.\n" ); fprintf( stdout, "Quit program? [y|n] : " ); gets( szInput ); if( szInput[0] == 'y' ) { goto PROGRAM_COMPLETE; } /* if */ fprintf( stdout, "...restarting program execution\n\n" ); goto EXECUTION_START; } /* if */ /* * Determine the collection settings based on the device properties */ ApplicationDetermineCollectionParameters( nDevices, pdtDevices, &dtSettings ); /* * Set optional processing flags (this overides the settings in Optotrak.INI). */ fprintf( stdout, "...OptotrakSetProcessingFlags\n" ); if( OptotrakSetProcessingFlags( OPTO_LIB_POLL_REAL_DATA | OPTO_CONVERT_ON_HOST | OPTO_RIGID_ON_HOST ) ) { goto ERROR_EXIT; } /* if */ /* * Load camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Ensure that we are firing some markers */ if( dtSettings.nMarkers == 0 ) { fprintf( stdout, "Error: There are no markers to be activated.\n" ); goto ERROR_EXIT; } /* if */ /* * allocate memory for 3d data */ p3dData = (Position3d*)malloc( dtSettings.nMarkers * sizeof( Position3d ) ); /* * Configure Optotrak Collection * Once the system strobers have been enabled, and all settings are * loaded, the application can set up the Optotrak collection */ fprintf( stdout, "...OptotrakSetupCollection\n" ); fprintf( stdout, ".....%d, %.2f, %.0f, %d, %d, %d, %.2f, %.2f, %.0f, %.0f\n", dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime ); if( OptotrakSetupCollection( dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime, OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_BUFFER_RAW_FLAG | OPTOTRAK_SWITCH_AND_CONFIG_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Prepare for realtime data retrieval. * Activate markers. Turn on the markers prior to data retrieval. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers( ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * Get and display five frames of 3D data. */ fprintf( stdout, "\n\nSample Program Results:\n\n" ); fprintf( stdout, "\n\n3D Data Display\n" ); for( nCurFrame = 0; nCurFrame < 5; nCurFrame++ ) { /* * Get a frame of data. */ fprintf( stdout, "\n" ); if( DataGetLatest3D( &uFrameNumber, &uElements, &uFlags, p3dData ) ) { goto ERROR_EXIT; } /* if */ /* * Print out the data. */ fprintf( stdout, "Frame Number: %8u\n", uFrameNumber ); fprintf( stdout, "Elements : %8u\n", uElements ); fprintf( stdout, "Flags : 0x%04x\n", uFlags ); for( nCurMarker = 0; nCurMarker < dtSettings.nMarkers; nCurMarker++ ) { DisplayMarker( nCurMarker + 1, p3dData[nCurMarker] ); } /* for */ } /* for */ fprintf( stdout, "\n" ); /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Stop the collection. */ fprintf( stdout, "...OptotrakStopCollection\n" ); if( OptotrakStopCollection( ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ fprintf( stdout, "Run again? [y|n] : " ); gets( szInput ); if( szInput[0] == 'y' ) { goto EXECUTION_START; } /* if */ PROGRAM_COMPLETE: /* * CLEANUP */ fprintf( stdout, "\n" ); fprintf( stdout, "...TransputerShutdownSystem\n" ); TransputerShutdownSystem( ); /* * free all memory */ if( pdtDeviceHandlesInfo ) { for( i = 0; i < nDevices; i++ ) { AllocateMemoryDeviceHandleProperties( &(pdtDeviceHandlesInfo[i].grProperties), 0 ); } /* for */ } /* if */ AllocateMemoryDeviceHandles( &pdtDeviceHandles, 0 ); AllocateMemoryDeviceHandlesInfo( &pdtDeviceHandlesInfo, pdtDeviceHandles, 0 ); free( p3dData ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); /* * free all memory */ if( pdtDeviceHandlesInfo ) { for( i = 0; i < nDevices; i++ ) { AllocateMemoryDeviceHandleProperties( &(pdtDeviceHandlesInfo[i].grProperties), 0 ); } /* for */ } /* if */ AllocateMemoryDeviceHandles( &pdtDeviceHandles, 0 ); AllocateMemoryDeviceHandlesInfo( &pdtDeviceHandlesInfo, pdtDeviceHandles, 0 ); free( p3dData ); exit( 1 ); } /* main */
void main( int argc, unsigned char *argv[] ) { OptotrakSettings dtSettings; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; int i, nVLED, nMarkersToActivate, nCurDevice, nDevices; ApplicationDeviceInformation *pdtDevices; DeviceHandle *pdtDeviceHandles; DeviceHandleInfo *pdtDeviceHandlesInfo; /* * initialization * intialize variables */ pdtDevices = NULL; pdtDeviceHandles = NULL; pdtDeviceHandlesInfo = NULL; nDevices = 0; dtSettings.nMarkers = 0; dtSettings.fFrameFrequency = SAMPLE_FRAMEFREQ; dtSettings.fMarkerFrequency = SAMPLE_MARKERFREQ; dtSettings.nThreshold = 30; dtSettings.nMinimumGain = 160; dtSettings.nStreamData = SAMPLE_STREAMDATA; dtSettings.fDutyCycle = SAMPLE_DUTYCYCLE; dtSettings.fVoltage = SAMPLE_VOLTAGE; dtSettings.fCollectionTime = 1.0; dtSettings.fPreTriggerTime = 0.0; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak Certus sample program #11\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Communication Initialization * Once the system processors have been loaded, the application * prepares for communication by initializing the system processors. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Determine if this sample will run with the system attached. * This sample is intended for Optotrak Certus systems. */ fprintf( stdout, "...DetermineSystem\n" ); if( uDetermineSystem( ) != OPTOTRAK_CERTUS_FLAG ) { goto PROGRAM_COMPLETE; } /* if */ /* * Strober Initialization * Once communication has been initialized, the application must * determine the strober configuration. * The application retrieves device handles and all strober * properties from the system. */ fprintf( stdout, "...DetermineStroberConfiguration\n" ); if( DetermineStroberConfiguration( &pdtDeviceHandles, &pdtDeviceHandlesInfo, &nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * check if any devices have been detected by the system */ if( nDevices == 0 ) { fprintf( stdout, ".........no devices detected. Quitting program...\n" ); goto PROGRAM_COMPLETE; } /* if */ /* * Now that all the device handles have been completely set up, * the application can store all the device handle information in * an internal data structure. This will facilitate lookups when * a property setting needs to be checked. */ ApplicationStoreDeviceProperties( &pdtDevices, pdtDeviceHandlesInfo, nDevices ); /* * Change the number of markers to fire for all devices */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { nMarkersToActivate = pdtDevices[nCurDevice].b3020Capability? CERTUS_SAMPLE_3020_STROBER_MARKERSTOFIRE : CERTUS_SAMPLE_STROBER_MARKERSTOFIRE; SetMarkersToActivateForDevice( &(pdtDevices[nCurDevice]), pdtDeviceHandlesInfo[nCurDevice].pdtHandle->nID, nMarkersToActivate ); } /* if */ fprintf( stdout, "\n" ); /* * Determine the collection settings based on the device properties */ ApplicationDetermineCollectionParameters( nDevices, pdtDevices, &dtSettings ); /* * Set optional processing flags (this overides the settings in Optotrak.INI). */ fprintf( stdout, "...OptotrakSetProcessingFlags\n" ); if( OptotrakSetProcessingFlags( OPTO_LIB_POLL_REAL_DATA | OPTO_CONVERT_ON_HOST | OPTO_RIGID_ON_HOST ) ) { goto ERROR_EXIT; } /* if */ /* * Load camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Configure Optotrak Collection * Once the system strobers have been enabled, and all settings are * loaded, the application can set up the Optotrak collection */ fprintf( stdout, "...OptotrakSetupCollection\n" ); fprintf( stdout, ".....%d, %.2f, %.0f, %d, %d, %d, %.2f, %.2f, %.0f, %.0f\n", dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime ); if( OptotrakSetupCollection( dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime, OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_BUFFER_RAW_FLAG | OPTOTRAK_SWITCH_AND_CONFIG_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Prepare for realtime data retrieval. * Activate markers. Turn on the markers prior to data retrieval. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers( ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); fprintf( stdout, "...waiting for 2 seconds\n" ); sleep( 2 ); /* * Look through all devices to find visible LEDs */ fprintf( stdout, "\nProgram Results:\n" ); for( i = 0; i < nDevices; i++ ) { if( pdtDevices[i].nVLEDs == 0 ) { fprintf( stdout, "...Device %d has no LEDs. skipping...\n", i + 1 ); continue; } /* if */ /* * Turn every visible LED in the device on, except for the first VLED * NOTE: The first VLED is reserved by the strober so we do not try to set it. */ if( pdtDevices[i].nVLEDs == 1 ) { fprintf( stdout, "...Device %d has only 1 LED. skipping...\n", i + 1 ); continue; } /* if */ for( nVLED = 2; nVLED <= pdtDevices[i].nVLEDs; nVLED++ ) { fprintf( stdout, "...OptotrakDeviceHandleSetVisibleLED (Device %d, LED %d)\n", i + 1, nVLED ); if( OptotrakDeviceHandleSetVisibleLED( pdtDeviceHandlesInfo[i].pdtHandle->nID, nVLED, VLEDST_ON ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ } /* for */ } /* for */ fprintf( stdout, "...waiting for 5 seconds. LEDs should be ON\n\n" ); sleep( 5 ); /* * now make all the LEDs blink */ for( i = 0; i < nDevices; i++ ) { if( pdtDevices[i].nVLEDs == 0 ) { continue; } /* if */ /* * Make every visible LED in the device blink, except for the first VLED * NOTE: The first VLED is reserved by the strober so we do not try to set it. */ if( pdtDevices[i].nVLEDs == 1 ) { continue; } /* if */ for( nVLED = 2; nVLED <= pdtDevices[i].nVLEDs; nVLED++ ) { fprintf( stdout, "...OptotrakDeviceHandleSetVisibleLED (Device %d, LED %d)\n", i + 1, nVLED ); if( OptotrakDeviceHandleSetVisibleLED( pdtDeviceHandlesInfo[i].pdtHandle->nID, nVLED, VLEDST_BLINK ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ } /* for */ } /* for */ fprintf( stdout, "...waiting for 5 seconds. LEDs should be BLINKING\n\n" ); sleep( 5 ); /* * finally, turn all LEDs off */ for( i = 0; i < nDevices; i++ ) { if( pdtDevices[i].nVLEDs == 0 ) { continue; } /* if */ /* * Turn every visible LED in the device off, except for the first VLED * NOTE: The first VLED is reserved by the strober so we do not try to set it. */ if( pdtDevices[i].nVLEDs == 1 ) { continue; } /* if */ for( nVLED = 2; nVLED <= pdtDevices[i].nVLEDs; nVLED++ ) { fprintf( stdout, "...OptotrakDeviceHandleSetVisibleLED (Device %d, LED %d)\n", i + 1, nVLED ); if( OptotrakDeviceHandleSetVisibleLED( pdtDeviceHandlesInfo[i].pdtHandle->nID, nVLED, VLEDST_OFF ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ } /* for */ } /* for */ fprintf( stdout, "...waiting for 5 seconds. LEDs should be OFF\n\n" ); sleep( 5 ); /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ PROGRAM_COMPLETE: /* * CLEANUP */ fprintf( stdout, "\n" ); fprintf( stdout, "...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); exit( 1 ); } /* main */
/***************************************************************** Name: main Input Values: int argc :Number of command line parameters. unsigned char *argv[] :Pointer array to each parameter. Output Values: None. Return Value: None. Description: Main program routine performs all steps listed in the above program description. *****************************************************************/ void main( int argc, unsigned char *argv[] ) { unsigned int uFlags, uElements, uFrameCnt, uChannelCnt, uFrameNumber; static int puRawData[ NUM_CHANNELS + 1]; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak sample program #12\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Wait one second to let the system finish loading. */ sleep( 1 ); /* * Initialize the processors system. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Load the standard camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) ) { goto ERROR_EXIT; } /* if */ /* * Set up a collection for the ODAU. */ fprintf( stdout, "...OdauSetupCollection\n" ); if( OdauSetupCollection( ODAU1, /* Id the ODAU the parameters are for. */ NUM_CHANNELS, /* Number of analog channels to collect. */ ODAU_GAIN, /* Gain to use for the analog channels.*/ ODAU_DIGITAL_INPB_INPA, /* Mode for the Digital I/O port.*/ (float)100.0, /* Frequency to collect data frames at. */ (float)90000.0, /* Frequency to scan channels at. */ 0, /* Stream mode for the data buffers. */ (float)1.0, /* Number of seconds of data to collect. */ 0.0, /* Number of seconds to pre-trigger data by. */ 0 ) ) /* Flags. */ { goto ERROR_EXIT; } /* if */ /* * Set up a collection for the Optotrak. */ fprintf( stdout, "...OptotrakSetupCollection\n" ); if( OptotrakSetupCollection( NUM_MARKERS, /* Number of markers in the collection. */ (float)100.0, /* Frequency to collect data frames at. */ (float)2500.0, /* Marker frequency for marker maximum on-time. */ 30, /* Dynamic or Static Threshold value to use. */ 160, /* Minimum gain code amplification to use. */ 0, /* Stream mode for the data buffers. */ (float)0.4, /* Marker Duty Cycle to use. */ (float)7.5, /* Voltage to use when turning on markers. */ (float)1.0, /* Number of seconds of data to collect. */ (float)0.0, /* Number of seconds to pre-trigger data by. */ OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_BUFFER_RAW_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Activate the markers. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers() ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * Get and display ten frames of ODAU data. */ fprintf( stdout, "\n\nSample Program Results:\n\n" ); fprintf( stdout, "ODAU Data Display\n" ); for( uFrameCnt = 0; uFrameCnt < 10; ++uFrameCnt ) { /* * Get a frame of ODAU raw data. */ fprintf( stdout, "\n" ); if( DataGetLatestOdauRaw( ODAU1, &uFrameNumber, &uElements, &uFlags, puRawData ) ) { goto ERROR_EXIT; } /* if */ /* * Print out the data. */ fprintf( stdout, "Frame Number: %8u\n", uFrameNumber ); fprintf( stdout, "Elements : %8u\n", uElements ); fprintf( stdout, "Flags : 0x%04x\n", uFlags ); for( uChannelCnt = 0; uChannelCnt < NUM_CHANNELS; ++uChannelCnt ) { fprintf( stdout, "Channel %u Raw 0x%08x Voltage %f\n", uChannelCnt + 1, puRawData[ uChannelCnt], (float)( (int)( puRawData[ uChannelCnt])) * 0.000305175/(float)ODAU_GAIN ); /* * if you have an ODAUI unit, instead of an ODAUII unit, * replace the above fprintf statement with: * fprintf( stdout, "Channel %u Raw 0x%08x Voltage %f\n", * uChannelCnt + 1, * puRawData[ uChannelCnt ], * (float)( (int)( puRawData[ uChannelCnt] & 0x0FFF ) - 2048) * * (10.0/2048.0)/(float)ODAU_GAIN ); */ } /* for */ fprintf( stdout, "Digital 0x%04x\n", puRawData[ NUM_CHANNELS] ); } /* for */ fprintf( stdout, "\n" ); /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Shutdown the processors message passing system. */ fprintf( stdout, "...TransputerShutdownSystem\n" ); if( TransputerShutdownSystem() ) { goto ERROR_EXIT; } /* if */ /* * Exit the program. */ fprintf( stdout, "\nProgram execution complete.\n" ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers(); TransputerShutdownSystem(); exit( 1 ); } /* main */
/***************************************************************** Name: main Input Values: int argc :Number of command line parameters. unsigned char *argv[] :Pointer array to each parameter. Output Values: None. Return Value: None. Description: Main program routine performs all steps listed in the above program description. *****************************************************************/ void main( int argc, unsigned char *argv[] ) { unsigned int uFlags, uElements, uFrameCnt, uRigidCnt, uMarkerCnt, uFrameNumber; RigidBodyDataType RigidBodyData; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; /* * Load the system of transputers. */ if( TransputerLoadSystem( "system" ) ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the system finish loading. */ sleep( 1 ); /* * Initialize the transputer system. */ if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Load the standard camera parameters. */ if( OptotrakLoadCameraParameters( "standard" ) ) { goto ERROR_EXIT; } /* if */ /* * Set up a collection for the OPTOTRAK. */ if( OptotrakSetupCollection( NUM_MARKERS, /* Number of markers in the collection. */ FRAME_RATE, /* Frequency to collect data frames at. */ (float)2500.0, /* Marker frequency for marker maximum on-time. */ 30, /* Dynamic or Static Threshold value to use. */ 160, /* Minimum gain code amplification to use. */ 1, /* Stream mode for the data buffers. */ (float)0.4, /* Marker Duty Cycle to use. */ (float)7.5, /* Voltage to use when turning on markers. */ COLLECTION_TIME, /* Number of seconds of data to collect. */ (float)0.0, /* Number of seconds to pre-trigger data by. */ OPTOTRAK_BUFFER_RAW_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Activate the markers. */ if( OptotrakActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Add rigid body 1 for tracking to the OPTOTRAK system from a .RIG file. */ if( RigidBodyAddFromFile( RIGID_BODY_1, /* ID associated with this rigid body. */ 1, /* First marker in the rigid body.*/ "plate", /* RIG file containing rigid body coordinates.*/ 0 ) ) /* flags */ { goto ERROR_EXIT; } /* if */ /* * Change the default settings for this rigid body 1. */ if( RigidBodyChangeSettings( RIGID_BODY_1, /* ID associated with this rigid body. */ 4, /* Minimum number of markers which must be seen before performing rigid body calculations.*/ 60, /* Cut off angle for marker inclusion in calcs.*/ (float)0.25, /* Maximum 3-D marker error for this rigid body. */ (float)1.0, /* Maximum raw sensor error for this rigid body. */ (float)1.0, /* Maximum 3-D RMS marker error for this rigid body. */ (float)1.0, /* Maximum raw sensor RMS error for this rigid body. */ OPTOTRAK_QUATERN_RIGID_FLAG | OPTOTRAK_RETURN_QUATERN_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Get and display ten frames of rigid body data. */ fprintf( stdout, "Rigid Body Data Display\n" ); for( uFrameCnt = 0; uFrameCnt < 10; ++uFrameCnt ) { /* * Get a frame of data. */ if( DataGetLatestTransforms( &uFrameNumber, &uElements, &uFlags, &RigidBodyData ) ) { goto ERROR_EXIT; } /* if */ /* * Print out the rigid body transformation data. */ fprintf( stdout, "\n" ); fprintf( stdout, "Rigid Body Transformation Data\n\n" ); fprintf( stdout, "Frame Number: %8u\n", uFrameNumber ); fprintf( stdout, "Transforms : %8u\n", uElements ); fprintf( stdout, "Flags : 0x%04x\n", uFlags ); for( uRigidCnt = 0; uRigidCnt < uElements; ++uRigidCnt ) { fprintf( stdout, "Rigid Body %u\n", RigidBodyData.pRigidData[ uRigidCnt].RigidId ); fprintf( stdout, "XT = %8.2f YT = %8.2f ZT = %8.2f\n", RigidBodyData.pRigidData[ uRigidCnt].transformation. quaternion.translation.x, RigidBodyData.pRigidData[ uRigidCnt].transformation. quaternion.translation.y, RigidBodyData.pRigidData[ uRigidCnt].transformation. quaternion.translation.z ); fprintf( stdout, "Q0 = %8.2f QX = %8.2f QY = %8.2f QZ = %8.2f\n", RigidBodyData.pRigidData[ uRigidCnt].transformation. quaternion.rotation.q0, RigidBodyData.pRigidData[ uRigidCnt].transformation. quaternion.rotation.qx, RigidBodyData.pRigidData[ uRigidCnt].transformation. quaternion.rotation.qy, RigidBodyData.pRigidData[ uRigidCnt].transformation. quaternion.rotation.qz ); } /* for */ /* * Print out the 3D data. */ fprintf( stdout, "\nAssociated 3D Marker Data\n\n" ); for( uMarkerCnt = 0; uMarkerCnt < NUM_MARKERS; ++uMarkerCnt ) { fprintf( stdout, "Marker %u X %f Y %f Z %f\n", uMarkerCnt + 1, RigidBodyData.p3dData[ uMarkerCnt].x, RigidBodyData.p3dData[ uMarkerCnt].y, RigidBodyData.p3dData[ uMarkerCnt].z ); } /* for */ } /* for */ /* * De-activate the markers. */ if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Shutdown the transputer message passing system. */ if( TransputerShutdownSystem() ) { goto ERROR_EXIT; } /* if */ /* * Exit the program. */ fprintf( stdout, "\nProgram execution complete.\n" ); exit( 0 ); ERROR_EXIT: if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ OptotrakDeActivateMarkers(); TransputerShutdownSystem(); exit( 1 ); } /* main */
/***************************************************************** Name: main Input Values: int argc :Number of command line parameters. unsigned char *argv[] :Pointer array to each parameter. Output Values: None. Return Value: None. Description: Main program routine performs all steps listed in the above program description. *****************************************************************/ void main( int argc, unsigned char *argv[] ) { unsigned int uFlags, uElements, uFrameCnt, uRigidCnt, uMarkerCnt, uFrameNumber; RigidBodyDataType RigidBodyData; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak sample program #11\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Wait one second to let the system finish loading. */ sleep( 1 ); /* * Initialize the processors system. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Set optional processing flags (this overides the settings in Optotrak.INI). */ fprintf( stdout, "...OptotrakSetProcessingFlags\n" ); if( OptotrakSetProcessingFlags( OPTO_LIB_POLL_REAL_DATA | OPTO_CONVERT_ON_HOST | OPTO_RIGID_ON_HOST ) ) { goto ERROR_EXIT; } /* if */ /* * Load the standard camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) ) { goto ERROR_EXIT; } /* if */ /* * Set up a collection for the Optotrak. */ fprintf( stdout, "...OptotrakSetupCollection\n" ); if( OptotrakSetupCollection( NUM_MARKERS, /* Number of markers in the collection. */ FRAME_RATE, /* Frequency to collect data frames at. */ (float)2500.0, /* Marker frequency for marker maximum on-time. */ 30, /* Dynamic or Static Threshold value to use. */ 160, /* Minimum gain code amplification to use. */ 1, /* Stream mode for the data buffers. */ (float)0.4, /* Marker Duty Cycle to use. */ (float)7.5, /* Voltage to use when turning on markers. */ COLLECTION_TIME, /* Number of seconds of data to collect. */ (float)0.0, /* Number of seconds to pre-trigger data by. */ OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_BUFFER_RAW_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Activate the markers. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers() ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * Add rigid body 2 for tracking to the Optotrak system from an array of * 3D points. */ fprintf( stdout, "...RigidBodyAdd\n" ); if( RigidBodyAdd( RIGID_BODY_2, /* ID associated with this rigid body. */ 7, /* First marker in the rigid body. */ 6, /* Number of markers in the rigid body. */ (float *)RigidBody2, /* 3D coords for each marker in the body. */ NULL, /* no normals for this rigid body. */ OPTOTRAK_QUATERN_RIGID_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Add rigid body 1 for tracking to the Optotrak system from a .RIG file. */ fprintf( stdout, "...RigidBodyAddFromFile\n" ); if( RigidBodyAddFromFile( RIGID_BODY_1, /* ID associated with this rigid body.*/ 1, /* First marker in the rigid body.*/ "plate", /* RIG file containing rigid body coordinates.*/ OPTOTRAK_QUATERN_RIGID_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Change the default frame of reference to be defined by rigid body one. */ fprintf( stdout, "...RigidBodyChangeFOR\n" ); if( RigidBodyChangeFOR( RIGID_BODY_1, OPTOTRAK_CONSTANT_RIGID_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Get and display ten frames of rigid body data. */ fprintf( stdout, "\n\nSample Program Results:\n\n" ); fprintf( stdout, "Rigid Body Data Display\n" ); for( uFrameCnt = 0; uFrameCnt < 10; ++uFrameCnt ) { /* * Get a frame of data. */ if( DataGetLatestTransforms( &uFrameNumber, &uElements, &uFlags, &RigidBodyData ) ) { goto ERROR_EXIT; } /* if */ /* * Print out the rigid body transformation data. */ fprintf( stdout, "\n" ); fprintf( stdout, "Rigid Body Transformation Data\n\n" ); fprintf( stdout, "Frame Number: %8u\n", uFrameNumber ); fprintf( stdout, "Transforms : %8u\n", uElements ); fprintf( stdout, "Flags : 0x%04x\n", uFlags ); for( uRigidCnt = 0; uRigidCnt < uElements; ++uRigidCnt ) { fprintf( stdout, "Rigid Body %u\n", RigidBodyData.pRigidData[ uRigidCnt].RigidId ); fprintf( stdout, "XT = %8.2f YT = %8.2f ZT = %8.2f\n", RigidBodyData.pRigidData[ uRigidCnt].transformation. euler.translation.x, RigidBodyData.pRigidData[ uRigidCnt].transformation. euler.translation.y, RigidBodyData.pRigidData[ uRigidCnt].transformation. euler.translation.z ); fprintf( stdout, "Y = %8.2f P = %8.2f R = %8.2f\n", RigidBodyData.pRigidData[ uRigidCnt].transformation. euler.rotation.yaw, RigidBodyData.pRigidData[ uRigidCnt].transformation. euler.rotation.pitch, RigidBodyData.pRigidData[ uRigidCnt].transformation. euler.rotation.roll ); } /* for */ /* * Print out the 3D data. */ fprintf( stdout, "\nAssociated 3D Marker Data\n\n" ); for( uMarkerCnt = 0; uMarkerCnt < NUM_MARKERS; ++uMarkerCnt ) { DisplayMarker( uMarkerCnt + 1, RigidBodyData.p3dData[uMarkerCnt] ); } /* for */ } /* for */ fprintf( stdout, "\n" ); /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Shutdown the processors message passing system. */ fprintf( stdout, "...TransputerShutdownSystem\n" ); if( TransputerShutdownSystem() ) { goto ERROR_EXIT; } /* if */ /* * Exit the program. */ fprintf( stdout, "\nProgram execution complete.\n" ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers(); TransputerShutdownSystem(); exit( 1 ); } /* main */
void main( int argc, unsigned char *argv[] ) { OptotrakSettings dtSettings; int i, nIterations, nCurDevice, nCurMarker, nDevices, nMarkersToActivate; ApplicationDeviceInformation *pdtDevices; DeviceHandle *pdtDeviceHandles; DeviceHandleInfo *pdtDeviceHandlesInfo; unsigned int uFlags, uElements, uFrameNumber; Position3d *p3dData; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; /* * initialization * intialize variables */ pdtDevices = NULL; pdtDeviceHandles = NULL; pdtDeviceHandlesInfo = NULL; p3dData = NULL; dtSettings.nMarkers = 0; dtSettings.fFrameFrequency = SAMPLE_FRAMEFREQ; dtSettings.fMarkerFrequency = SAMPLE_MARKERFREQ; dtSettings.nThreshold = 30; dtSettings.nMinimumGain = 160; dtSettings.nStreamData = SAMPLE_STREAMDATA; dtSettings.fDutyCycle = SAMPLE_DUTYCYCLE; dtSettings.fVoltage = SAMPLE_VOLTAGE; dtSettings.fCollectionTime = 1.0; dtSettings.fPreTriggerTime = 0.0; nDevices = 0; nMarkersToActivate = 0; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak Certus sample program #2\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Communication Initialization * Once the system processors have been loaded, the application * prepares for communication by initializing the system processors. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Determine if this sample will run with the system attached. * This sample is intended for Optotrak Certus systems. */ fprintf( stdout, "...DetermineSystem\n" ); if( uDetermineSystem( ) != OPTOTRAK_CERTUS_FLAG ) { goto ERROR_EXIT; } /* if */ nIterations = 2; for( i = 0; i < nIterations; i++ ) { /* * Strober Initialization * Once communication has been initialized, the application must * determine the strober configuration. * The application retrieves device handles and all strober * properties from the system. */ fprintf( stdout, "...DetermineStroberConfiguration\n" ); if( DetermineStroberConfiguration( &pdtDeviceHandles, &pdtDeviceHandlesInfo, &nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * check if any devices have been detected by the system */ if( nDevices == 0 ) { fprintf( stdout, ".........no devices detected. Quitting program...\n" ); goto PROGRAM_COMPLETE; } /* if */ /* * Now that all the device handles have been completely set up, * the application can store all the device handle information in * an internal data structure. This will facilitate lookups when * a property setting needs to be checked. */ ApplicationStoreDeviceProperties( &pdtDevices, pdtDeviceHandlesInfo, nDevices ); /* * Change the number of markers to fire for all devices */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { nMarkersToActivate = pdtDevices[nCurDevice].b3020Capability? CERTUS_SAMPLE_3020_STROBER_MARKERSTOFIRE : CERTUS_SAMPLE_STROBER_MARKERSTOFIRE; SetMarkersToActivateForDevice( &(pdtDevices[nCurDevice]), pdtDeviceHandlesInfo[nCurDevice].pdtHandle->nID, nMarkersToActivate ); } /* for */ fprintf( stdout, "\n" ); /* * If there are strobers with tool capabilities, but no tools, * then set up the strobers to fire some markers */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { if( pdtDevices[nCurDevice].nToolPorts > 0 ) { /* * set the markers to activate for this device * this will be 0 if there are tools plugged into the * device, or CERTUS_SAMPLE_STROBER_MARKERSTOFIRE if there * are no tools plugged in */ nMarkersToActivate = CERTUS_SAMPLE_STROBER_MARKERSTOFIRE; SetMarkersToActivateForToolDevice( &(pdtDevices[nCurDevice]), pdtDeviceHandlesInfo[nCurDevice].pdtHandle->nID, nMarkersToActivate, pdtDevices, nDevices ); } /* if */ } /* for */ /* * Determine the collection settings based on the device properties */ ApplicationDetermineCollectionParameters( nDevices, pdtDevices, &dtSettings ); /* * Set optional processing flags (this overides the settings in Optotrak.INI). */ fprintf( stdout, "...OptotrakSetProcessingFlags\n" ); if( OptotrakSetProcessingFlags( OPTO_LIB_POLL_REAL_DATA | OPTO_CONVERT_ON_HOST | OPTO_RIGID_ON_HOST ) ) { goto ERROR_EXIT; } /* if */ /* * Load camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Ensure that we are firing some markers */ if( dtSettings.nMarkers == 0 ) { fprintf( stdout, "Error: There are no markers to be activated.\n" ); goto ERROR_EXIT; } /* if */ /* * allocate memory for 3d data */ p3dData = (Position3d*)malloc( dtSettings.nMarkers * sizeof( Position3d ) ); /* * Configure Optotrak Collection * Once the system strobers have been enabled, and all settings are * loaded, the application can set up the Optotrak collection */ fprintf( stdout, "...OptotrakSetupCollection\n" ); fprintf( stdout, ".....%d, %.2f, %.0f, %d, %d, %d, %.2f, %.2f, %.0f, %.0f\n", dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime ); if( OptotrakSetupCollection( dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime, OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_BUFFER_RAW_FLAG | OPTOTRAK_SWITCH_AND_CONFIG_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Prepare for realtime data retrieval. * Activate markers. Turn on the markers prior to data retrieval. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers( ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * loop around until a device is plugged or unplugged */ while( 1 ) { fprintf( stdout, "\nCHANGE THE STROBER CONFIGURATION TO END THIS TEST\n\n" ); sleep( 1 ); if( DataGetLatest3D( &uFrameNumber, &uElements, &uFlags, p3dData ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * display the 3d data */ fprintf( stdout, "3D Data Display (%d Markers)\n", dtSettings.nMarkers ); /* * Print out the data. */ fprintf( stdout, "Frame Number: %8u\n", uFrameNumber ); fprintf( stdout, "Elements : %8u\n", uElements ); fprintf( stdout, "Flags : 0x%04x\n", uFlags ); for( nCurMarker = 0; nCurMarker < dtSettings.nMarkers; nCurMarker++ ) { DisplayMarker( nCurMarker + 1, p3dData[nCurMarker] ); } /* for */ /* * check if the tool configuration has changed */ if( uFlags & OPTO_TOOL_CONFIG_CHANGED_FLAG ) { fprintf( stdout, "\n\n\n...Tool Configuration Changed\n" ); sleep( 3 ); break; } /* if */ } /* while */ sleep( 1 ); /* * stop the collection since we are finished at this point */ fprintf( stdout, "...OptotrakStopCollection\n\n\n" ); if( OptotrakStopCollection( ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ } /* for */ /* * Exiting the loop above means that the tool configuration has changed */ fprintf( stdout, "...DetermineStroberConfiguration\n" ); if( DetermineStroberConfiguration( &pdtDeviceHandles, &pdtDeviceHandlesInfo, &nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ PROGRAM_COMPLETE: /* * CLEANUP */ fprintf( stdout, "\n" ); fprintf( stdout, "...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); /* * free all memory */ if( pdtDeviceHandlesInfo ) { for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { AllocateMemoryDeviceHandleProperties( &(pdtDeviceHandlesInfo[nCurDevice].grProperties), 0 ); } /* for */ } /* if */ AllocateMemoryDeviceHandles( &pdtDeviceHandles, 0 ); AllocateMemoryDeviceHandlesInfo( &pdtDeviceHandlesInfo, pdtDeviceHandles, 0 ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); /* * free all memory */ if( pdtDeviceHandlesInfo ) { for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { AllocateMemoryDeviceHandleProperties( &(pdtDeviceHandlesInfo[nCurDevice].grProperties), 0 ); } /* for */ } /* if */ AllocateMemoryDeviceHandles( &pdtDeviceHandles, 0 ); AllocateMemoryDeviceHandlesInfo( &pdtDeviceHandlesInfo, pdtDeviceHandles, 0 ); exit( 1 ); } /* main */
/***************************************************************** Name: main Input Values: int argc :Number of command line parameters. unsigned char *argv[] :Pointer array to each parameter. Output Values: None. Return Value: None. Description: Main program routine performs all steps listed in the above program description. *****************************************************************/ void main( int argc, unsigned char *argv[] ) { unsigned int uSpoolStatus = 0; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak sample program #13\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Wait one second to let the system finish loading. */ sleep( 1 ); /* * Initialize the processors system. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Load the standard camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) ) { goto ERROR_EXIT; } /* if */ /* * Set up a collection for the ODAU. */ fprintf( stdout, "...OdauSetupCollection\n" ); if( OdauSetupCollection( ODAU1, /* Id the ODAU the parameters are for. */ NUM_CHANNELS, /* Number of analog channels to collect. */ ODAU_GAIN, /* Gain to use for the analog channels.*/ ODAU_DIGITAL_INPB_INPA, /* Mode for the Digital I/O port.*/ (float)100.0, /* Frequency to collect data frames at. */ (float)90000.0, /* Frequency to scan channels at. */ 1, /* Stream mode for the data buffers. */ (float)2.0, /* Number of seconds of data to collect. */ (float)0.0, /* Number of seconds to pre-trigger data by. */ 0 ) ) /* Flags. */ { goto ERROR_EXIT; } /* if */ /* * Set up a collection for the Optotrak. */ fprintf( stdout, "...OptotrakSetupCollection\n" ); if( OptotrakSetupCollection( NUM_MARKERS, /* Number of markers in the collection. */ (float)50.0, /* Frequency to collect data frames at. */ (float)2500.0, /* Marker frequency for marker maximum on-time. */ 30, /* Dynamic or Static Threshold value to use. */ 160, /* Minimum gain code amplification to use. */ 1, /* Stream mode for the data buffers. */ (float)0.40, /* Marker Duty Cycle to use. */ (float)8.0, /* Voltage to use when turning on markers. */ (float)2.0, /* Number of seconds of data to collect. */ (float)0.0, /* Number of seconds to pre-trigger data by. */ OPTOTRAK_NO_FIRE_MARKERS_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Activate the markers. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers() ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * Initialize a file for spooling of the Optotrak 3D data. */ fprintf( stdout, "...DataBufferInitializeFile\n" ); if( DataBufferInitializeFile( OPTOTRAK, "C#001.S13" ) ) { goto ERROR_EXIT; } /* if */ /* * Initialize a file for spooling of the ODAU raw data. */ fprintf( stdout, "...DataBufferInitializeFile\n" ); if( DataBufferInitializeFile( ODAU1, "O1#001.S13" ) ) { goto ERROR_EXIT; } /* if */ /* * Spool data to the previously initialized files. */ fprintf( stdout, "\n\nSample Program Results:\n\n" ); fprintf( stdout, "Collecting data files...\n" ); if( DataBufferSpoolData( &uSpoolStatus ) ) { goto ERROR_EXIT; } /* if */ fprintf( stdout, "Spool Status: 0x%04x\n", uSpoolStatus ); fprintf( stdout, "\n" ); /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Shutdown the processors message passing system. */ fprintf( stdout, "...TransputerShutdownSystem\n" ); if( TransputerShutdownSystem() ) { goto ERROR_EXIT; } /* if */ /* * Exit the program. */ fprintf( stdout, "\nProgram execution complete.\n" ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers(); TransputerShutdownSystem(); exit( 1 ); } /* main */
/***************************************************************** Name: main Input Values: int argc :Number of command line parameters. unsigned char *argv[] :Pointer array to each parameter. Output Values: None. Return Value: None. Description: Main program routine performs all steps listed in the above program description. *****************************************************************/ void main( int argc, unsigned char *argv[] ) { float fRmsError; boolean bValid = TRUE; unsigned int uFlags, uElements, uFramesToAvg, uFrameCnt, uMarkerCnt, uFrameNumber; static Position3d grdt3dData[NUM_MARKERS], grdtAveraged3dData[NUM_MARKERS]; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; /* * Initialize the averaged marker position array to zeros. */ for( uMarkerCnt = 0; uMarkerCnt < NUM_MARKERS; uMarkerCnt++ ) { grdtAveraged3dData[uMarkerCnt].x = grdtAveraged3dData[uMarkerCnt].y = grdtAveraged3dData[uMarkerCnt].z = (float) 0.0; } /* for */ /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak sample program #18\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Wait one second to let the system finish loading. */ sleep( 1 ); /* * Initialize the processors system. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Load the standard camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) ) { goto ERROR_EXIT; } /* if */ /* * Set up a collection for the Optotrak. */ fprintf( stdout, "...OptotrakSetupCollection\n" ); if( OptotrakSetupCollection( NUM_MARKERS, /* Number of markers in the collection. */ (float)100.0, /* Frequency to collect data frames at. */ (float)2500.0, /* Marker frequency for marker maximum on-time. */ 30, /* Dynamic or Static Threshold value to use. */ 160, /* Minimum gain code amplification to use. */ 0, /* Stream mode for the data buffers. */ (float)0.35, /* Marker Duty Cycle to use. */ (float)7.0, /* Voltage to use when turning on markers. */ (float)1.0, /* Number of seconds of data to collect. */ (float)0.0, /* Number of seconds to pre-trigger data by. */ OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_BUFFER_RAW_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Activate the markers. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers() ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * Average 50 frames of 3D data to a single frame. */ uFrameCnt = 0; uFramesToAvg = 0; fprintf( stdout, "\n\nSample Program Results:\n\n" ); fprintf( stdout, "\n\nAveraging 3D data...\n" ); do { /* * Get a frame of data. */ if( DataGetLatest3D( &uFrameNumber, &uElements, &uFlags, grdt3dData ) ) { goto ERROR_EXIT; } /* if */ /* * Determine if the frame is valid; that is if each marker has a 3D * coordinate. */ bValid = TRUE; for( uMarkerCnt = 0; uMarkerCnt < NUM_MARKERS; uMarkerCnt++ ) { if( grdt3dData[uMarkerCnt].x < MAX_NEGATIVE ) { bValid = FALSE; } /* if */ } /* for */ /* * Add in each markers contribution if this frame was valid. */ if( bValid ) { for( uMarkerCnt = 0; uMarkerCnt < NUM_MARKERS; uMarkerCnt++ ) { grdtAveraged3dData[uMarkerCnt].x += grdt3dData[uMarkerCnt].x; grdtAveraged3dData[uMarkerCnt].y += grdt3dData[uMarkerCnt].y; grdtAveraged3dData[uMarkerCnt].z += grdt3dData[uMarkerCnt].z; uFramesToAvg++; } /* for */ ++uFrameCnt; } /* if */ } /* do */ while( uFrameCnt < 50 ); /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Divide sums by 50 to get the averaged marker positions. */ for( uMarkerCnt = 0; uMarkerCnt < NUM_MARKERS; uMarkerCnt++ ) { grdtAveraged3dData[uMarkerCnt].x /= uFramesToAvg; grdtAveraged3dData[uMarkerCnt].y /= uFramesToAvg; grdtAveraged3dData[uMarkerCnt].z /= uFramesToAvg; } /* for */ /* * Transform the measurement frame of reference for the Optotrak system * to the frame of reference defined by the grdtAlignedPositions array. */ if( OptotrakChangeCameraFOR( "standard", /* Camera Parameter File to load transform. */ NUM_MARKERS, /* Number of markers in 3D arrays. */ grdtAlignedPositions, /* Marker positions in current FOR. */ grdtAveraged3dData, /* Marker positions in desired FOR. */ "new", /* Name of new camera parameter file. */ grdt3dErrors, /* 3D errors of alignment transformation. */ &fRmsError ) ) /* RMS distance error of alignment transformation.*/ { goto ERROR_EXIT; } /* if */ /* * Print out the results of the alignment. */ fprintf( stdout, "RMS Fit Error : %6.3f\n", fRmsError ); fprintf( stdout, "Coordinate Fit Error Table\n" ); fprintf( stdout, "Mkr %6s %6s %6s\n","X", "Y", "Z" ); for( uMarkerCnt = 0; uMarkerCnt < NUM_MARKERS; ++uMarkerCnt ) { DisplayMarker( uMarkerCnt + 1, grdt3dErrors[uMarkerCnt] ); } /* for */ /* * Load the NEW camera parameter file to the Optotrak system. */ fprintf( stdout, "\nLoading NEW camera parameters...\n\n" ); if( OptotrakLoadCameraParameters( "NEW" ) ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Activate the markers. */ if( OptotrakActivateMarkers() ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * Get and display ten frames of 3D data. The position of which will be * in the new frame of reference. */ fprintf( stdout, "\n\n3D Data Display\n" ); for( uFrameCnt = 0; uFrameCnt < 10; ++uFrameCnt ) { /* * Get a frame of data. */ fprintf( stdout, "\n" ); if( DataGetLatest3D( &uFrameNumber, &uElements, &uFlags, grdt3dData ) ) { goto ERROR_EXIT; } /* if */ /* * Print out the data. */ fprintf( stdout, "Frame Number: %8u\n", uFrameNumber ); fprintf( stdout, "Elements : %8u\n", uElements ); fprintf( stdout, "Flags : 0x%04x\n", uFlags ); for( uMarkerCnt = 0; uMarkerCnt < NUM_MARKERS; uMarkerCnt++ ) { DisplayMarker( uMarkerCnt + 1, grdt3dData[uMarkerCnt] ); } /* for */ } /* for */ fprintf( stdout, "\n" ); /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Shutdown the processors message passing system. */ fprintf( stdout, "...TransputerShutdownSystem\n" ); if( TransputerShutdownSystem() ) { goto ERROR_EXIT; } /* if */ /* * Exit the program. */ fprintf( stdout, "\nProgram execution complete.\n" ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers(); TransputerShutdownSystem(); exit( 1 ); } /* main */
void main( int argc, unsigned char *argv[] ) { char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1], szProperty[32]; int i, nMarkersToActivate, nCurProperty, nCurDevice, nDevices; ApplicationDeviceInformation *pdtDevices; DeviceHandle *pdtDeviceHandles; DeviceHandleInfo *pdtDeviceHandlesInfo; char *pChar; /* * initialization * intialize variables */ pdtDevices = NULL; pdtDeviceHandles = NULL; pdtDeviceHandlesInfo = NULL; nDevices = 0; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak Certus sample program #4\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Communication Initialization * Once the system processors have been loaded, the application * prepares for communication by initializing the system processors. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Determine if this sample will run with the system attached. * This sample is intended for Optotrak Certus systems. */ fprintf( stdout, "...DetermineSystem\n" ); if( uDetermineSystem( ) != OPTOTRAK_CERTUS_FLAG ) { goto PROGRAM_COMPLETE; } /* if */ /* * Strober Initialization * Once communication has been initialized, the application must * determine the strober configuration. * The application retrieves device handles and all strober * properties from the system. */ fprintf( stdout, "...DetermineStroberConfiguration\n" ); if( DetermineStroberConfiguration( &pdtDeviceHandles, &pdtDeviceHandlesInfo, &nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * check if any devices have been detected by the system */ if( nDevices == 0 ) { fprintf( stdout, ".........no devices detected. Quitting program...\n" ); goto PROGRAM_COMPLETE; } /* if */ /* * Now that all the device handles have been completely set up, * the application can store all the device handle information in * an internal data structure. This will facilitate lookups when * a property setting needs to be checked. */ ApplicationStoreDeviceProperties( &pdtDevices, pdtDeviceHandlesInfo, nDevices ); /* * Display all the property values */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { fprintf( stdout, "...Device %d properties:\n", nCurDevice ); for( nCurProperty = 0; nCurProperty < pdtDeviceHandlesInfo[nCurDevice].nProperties; nCurProperty++ ) { /* * Determine the property */ switch( pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].uPropertyID ) { case DH_PROPERTY_NAME: sprintf( szProperty, "Device Name " ); break; case DH_PROPERTY_MARKERSTOFIRE: sprintf( szProperty, "Markers To Activate " ); break; case DH_PROPERTY_MAXMARKERS: sprintf( szProperty, "MaxDeviceMarkers " ); break; case DH_PROPERTY_STARTMARKERPERIOD: sprintf( szProperty, "Start Marker Period " ); break; case DH_PROPERTY_SWITCHES: sprintf( szProperty, "Device Switches " ); break; case DH_PROPERTY_VLEDS: sprintf( szProperty, "Device VLEDs " ); break; case DH_PROPERTY_PORT: sprintf( szProperty, "Strober Port " ); break; case DH_PROPERTY_ORDER: sprintf( szProperty, "Strober Port Order " ); break; case DH_PROPERTY_SUBPORT: sprintf( szProperty, "Strober SubPort " ); break; case DH_PROPERTY_FIRINGSEQUENCE: sprintf( szProperty, "Activation Sequence " ); break; case DH_PROPERTY_HAS_ROM: sprintf( szProperty, "Has Rom? " ); break; case DH_PROPERTY_TOOLPORTS: sprintf( szProperty, "Num ToolPorts " ); break; case DH_PROPERTY_3020_CAPABILITY: sprintf( szProperty, "3020 Capability " ); break; case DH_PROPERTY_3020_MARKERSTOFIRE: sprintf( szProperty, "3020 MrkrsToActivate " ); break; case DH_PROPERTY_3020_STARTMARKERPERIOD: sprintf( szProperty, "3020 StartMarkerPrd " ); break; case DH_PROPERTY_STATUS: sprintf( szProperty, "Status " ); break; case DH_PROPERTY_UNKNOWN: default: sprintf( szProperty, "Unknown Property %d ", pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].uPropertyID ); break; } /* switch */ /* * Determine the property's data type before displaying it */ switch( pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtPropertyType ) { case DH_PROPERTY_TYPE_INT: fprintf( stdout, "......Property_%.2d - %s = %d\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.nData ); break; case DH_PROPERTY_TYPE_FLOAT: fprintf( stdout, "......Property_%.2d - %s = %f\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.fData ); break; case DH_PROPERTY_TYPE_DOUBLE: fprintf( stdout, "......Property_%.2d - %s = %f\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.dData ); break; case DH_PROPERTY_TYPE_CHAR: fprintf( stdout, "......Property_%.2d - %s = %s\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.cData ); break; case DH_PROPERTY_TYPE_STRING: if( pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].uPropertyID == DH_PROPERTY_FIRINGSEQUENCE ) { fprintf( stdout, "......Property_%.2d - %s = ", nCurProperty, szProperty ); for( pChar = pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.szData; ( pChar != '\0' ) && ( *pChar != 0 ); pChar++ ) { fprintf( stdout, "%.3d, ", *pChar ); } /* for */ fprintf( stdout, "\n" ); } else { fprintf( stdout, "......Property_%.2d - %s = %s\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.szData ); } /* if */ break; default: fprintf( stdout, "......Property_%.2d = UNKNOWN PROPERTY TYPE\n", nCurDevice ); break; } /* switch */ } /* for */ fprintf( stdout, "\n" ); } /* for */ /* * Change the number of markers to fire for all devices */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { /* * skip Tools and Tool strobers */ if( ( pdtDevices[nCurDevice].bHasROM ) || ( pdtDevices[nCurDevice].nToolPorts > 0 ) ) { continue; } /* if */ nMarkersToActivate = pdtDevices[nCurDevice].b3020Capability? CERTUS_SAMPLE_3020_STROBER_MARKERSTOFIRE : CERTUS_SAMPLE_STROBER_MARKERSTOFIRE; SetMarkersToActivateForDevice( &(pdtDevices[nCurDevice]), pdtDeviceHandlesInfo[nCurDevice].pdtHandle->nID, nMarkersToActivate ); } /* if */ fprintf( stdout, "\n" ); /* * Retrieve the device properties again to verify that the changes took effect. */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { if( GetDevicePropertiesFromSystem( &(pdtDeviceHandlesInfo[nCurDevice]) ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ } /* for */ if( ApplicationStoreDeviceProperties( &pdtDevices, pdtDeviceHandlesInfo, nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Display all the property values */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { fprintf( stdout, "...Device %d properties:\n", nCurDevice ); for( nCurProperty = 0; nCurProperty < pdtDeviceHandlesInfo[nCurDevice].nProperties; nCurProperty++ ) { /* * Determine the property */ switch( pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].uPropertyID ) { case DH_PROPERTY_NAME: sprintf( szProperty, "Device Name " ); break; case DH_PROPERTY_MARKERSTOFIRE: sprintf( szProperty, "Markers To Activate " ); break; case DH_PROPERTY_STARTMARKERPERIOD: sprintf( szProperty, "Start Marker Period " ); break; case DH_PROPERTY_FIRINGSEQUENCE: sprintf( szProperty, "Activation Sequence " ); break; case DH_PROPERTY_3020_MARKERSTOFIRE: sprintf( szProperty, "3020 MrkrsToActivate " ); break; case DH_PROPERTY_3020_STARTMARKERPERIOD: sprintf( szProperty, "3020 StartMarkerPrd " ); break; case DH_PROPERTY_UNKNOWN: default: continue; break; } /* switch */ /* * Determine the property's data type before displaying it */ switch( pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtPropertyType ) { case DH_PROPERTY_TYPE_INT: fprintf( stdout, "......Property_%.2d - %s = %d\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.nData ); break; case DH_PROPERTY_TYPE_FLOAT: fprintf( stdout, "......Property_%.2d - %s = %f\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.fData ); break; case DH_PROPERTY_TYPE_DOUBLE: fprintf( stdout, "......Property_%.2d - %s = %f\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.dData ); break; case DH_PROPERTY_TYPE_CHAR: fprintf( stdout, "......Property_%.2d - %s = %s\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.cData ); break; case DH_PROPERTY_TYPE_STRING: if( pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].uPropertyID == DH_PROPERTY_FIRINGSEQUENCE ) { fprintf( stdout, "......Property_%.2d - %s = ", nCurProperty, szProperty ); for( pChar = pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.szData; ( pChar != '\0' ) && ( *pChar != 0 ); pChar++ ) { fprintf( stdout, "%.3d, ", *pChar ); } /* for */ fprintf( stdout, "\n" ); } else { fprintf( stdout, "......Property_%.2d - %s = %s\n", nCurProperty, szProperty, pdtDeviceHandlesInfo[nCurDevice].grProperties[nCurProperty].dtData.szData ); } /* if */ break; default: fprintf( stdout, "......Property_%.2d = UNKNOWN PROPERTY TYPE\n", nCurDevice ); break; } /* switch */ } /* for */ fprintf( stdout, "\n" ); } /* for */ fprintf( stdout, "...Test completed --- Pass. \n" ); PROGRAM_COMPLETE: /* * CLEANUP */ fprintf( stdout, "\n" ); fprintf( stdout, "...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); exit( 1 ); } /* main */
/***************************************************************** Name: main Input Values: int argc :Number of command line parameters. unsigned char *argv[] :Pointer array to each parameter. Output Values: None. Return Value: None. Description: Main program routine performs all steps listed in the above program description. *****************************************************************/ void main( int argc, unsigned char *argv[] ) { int nFileItems, nFileSubItems; void *pFileHeader; float fFileFrequency, *pfRawDataCur = NULL; long int lnFrameCnt, lnFileFrames; unsigned int uElements, uElementCnt, uSpoolStatus = 0; static char szFileComments[ 81]; float *pfRawData = NULL; Position3d *pdtPositionData = NULL, *pdtPositionCur = NULL; struct OptotrakRigidStruct dtRigidBodyData; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak sample program #19\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Wait one second to let the system finish loading. */ sleep( 1 ); /* * Initialize the processors system. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Set optional processing flags (this overides the settings in Optotrak.INI). */ fprintf( stdout, "...OptotrakSetProcessingFlags\n" ); if( OptotrakSetProcessingFlags( OPTO_LIB_POLL_REAL_DATA | OPTO_RIGID_ON_HOST ) ) { goto ERROR_EXIT; } /* if */ /* * Load the standard camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) ) { goto ERROR_EXIT; } /* if */ /* * Set up a collection for the Optotrak. */ fprintf( stdout, "...OptotrakSetupCollection\n" ); if( OptotrakSetupCollection( NUM_MARKERS, /* Number of markers in the collection. */ FRAME_RATE, /* Frequency to collect data frames at. */ (float)2500.0, /* Marker frequency for marker maximum on-time. */ 30, /* Dynamic or Static Threshold value to use. */ 160, /* Minimum gain code amplification to use. */ 0, /* Stream mode for the data buffers. */ (float)0.4, /* Marker Duty Cycle to use. */ (float)7.5, /* Voltage to use when turning on markers. */ COLLECTION_TIME, /* Number of seconds of data to collect. */ (float)0.0, /* Number of seconds to pre-trigger data by. */ OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_BUFFER_RAW_FLAG | OPTOTRAK_GET_NEXT_FRAME_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Add the rigid body to the Optotrak system from an array of 3D points. */ fprintf( stdout, "...RigidBodyAdd\n" ); if( RigidBodyAdd( RIGID_BODY_ID, /* ID associated with this rigid body. */ 1, /* First marker in the rigid body. */ NUM_MARKERS, /* Number of markers in the rigid body. */ (float *)dtRigidBody, /* 3D coords for each marker in the body. */ NULL, /* no normals for this rigid body. */ OPTOTRAK_QUATERN_RIGID_FLAG | OPTOTRAK_RETURN_EULER_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Activate the markers. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers() ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * Initialize a file for spooling of the Optotrak raw data. */ fprintf( stdout, "...DataBufferInitializeFile\n" ); if( DataBufferInitializeFile( OPTOTRAK, "R#001.S19" ) ) { goto ERROR_EXIT; } /* if */ /* * Spool data to the previously initialized file. */ fprintf( stdout, "\n\nSample Program Results:\n\n" ); fprintf( stdout, "Collecting data file...\n" ); if( DataBufferSpoolData( &uSpoolStatus ) ) { goto ERROR_EXIT; } /* if */ fprintf( stdout, "Spool Status: 0x%04x\n", uSpoolStatus ); fprintf( stdout, "\n" ); /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Open the raw data file we just collected as our input data file. */ fprintf( stdout, "\n\nSample Program Results:\n\n" ); fprintf( stdout, "Processing raw data file...\n" ); if( FileOpen( "R#001.S19", INPUT_FILE, OPEN_READ, &nFileItems, &nFileSubItems, &lnFileFrames, &fFileFrequency, szFileComments, &pFileHeader ) ) { goto ERROR_EXIT; } /* if */ /* * Allocate the memory required for the conversions and transformations. */ pfRawData = (float *)malloc( lnFileFrames * nFileItems * nFileSubItems * sizeof(float) ); if( pfRawData == NULL ) { fprintf( stderr, "Insufficient memory for raw data." ); goto ERROR_EXIT; } /* if */ pdtPositionData = (Position3d *)malloc( lnFileFrames * nFileItems * nFileSubItems * sizeof(Position3d) ); if( pdtPositionData == NULL ) { fprintf( stderr, "Insufficient memory for 3D position data." ); goto ERROR_EXIT; } /* if */ /* * Read the raw data from the file. */ if( FileRead( INPUT_FILE, 0L, (int)lnFileFrames, pfRawData ) ) { goto ERROR_EXIT; } /* if */ /* * Close the input file. */ FileClose( INPUT_FILE ); fprintf( stdout, "File processing complete.\n" ); /* * Convert the raw data to 3D position data and display it. */ fprintf( stdout, "\n3D position data:" ); pfRawDataCur = pfRawData; pdtPositionCur = pdtPositionData; for( lnFrameCnt = 0; lnFrameCnt < lnFileFrames; lnFrameCnt++ ) { if( OptotrakConvertRawTo3D( &uElements, pfRawDataCur, pdtPositionCur ) ) { goto ERROR_EXIT; } /* if */ for( uElementCnt = 0; uElementCnt < uElements; uElementCnt++ ) { fprintf( stdout, "\n%5ld %3u %12.5f %12.5f %12.5f", lnFrameCnt, uElementCnt, pdtPositionCur[uElementCnt].x, pdtPositionCur[uElementCnt].y, pdtPositionCur[uElementCnt].z ); } /* for */ pfRawDataCur += uElements * NUM_SENSORS; pdtPositionCur += uElements; } /* for */ /* * Transform the 3D position data to 6D and display it. */ fprintf( stdout, "\n\nRigid body data:\n" ); pdtPositionCur = pdtPositionData; for( lnFrameCnt = 0; lnFrameCnt < lnFileFrames; lnFrameCnt++ ) { if( OptotrakConvertTransforms( &uElements, &dtRigidBodyData, pdtPositionCur ) ) { goto ERROR_EXIT; } /* if */ fprintf( stdout, "Frame %04u\n", lnFrameCnt ); fprintf( stdout, "XT = %12.6f YT = %12.6f ZT = %12.6f\n", dtRigidBodyData.transformation.euler.translation.x, dtRigidBodyData.transformation.euler.translation.y, dtRigidBodyData.transformation.euler.translation.z ); fprintf( stdout, "Y = %12.6f P = %12.6f R = %12.6f\n", dtRigidBodyData.transformation.euler.rotation.yaw, dtRigidBodyData.transformation.euler.rotation.pitch, dtRigidBodyData.transformation.euler.rotation.roll ); pdtPositionCur += uElementCnt; } /* for */ fprintf( stdout, "\n" ); /* * Shutdown the processors message passing system. */ fprintf( stdout, "...TransputerShutdownSystem\n" ); if( TransputerShutdownSystem() ) { goto ERROR_EXIT; } /* if */ /* * Exit the program. */ free( pfRawData ); free( pdtPositionData ); fprintf( stdout, "\nProgram execution complete.\n" ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers(); TransputerShutdownSystem(); if( pfRawData != NULL ) { free( pfRawData ); } /* if */ if( pdtPositionData != NULL ) { free( pdtPositionData ); } /* if */ exit( 1 ); } /* main */
/***************************************************************** Name: main Input Values: int argc :Number of command line parameters. unsigned char *argv[] :Pointer array to each parameter. Output Values: None. Return Value: None. Description: Main program routine performs all steps listed in the above program description. *****************************************************************/ void main( int argc, unsigned char *argv[] ) { int nSensorCode; unsigned int uFlags, uElements, uFrameCnt, uMarkerCnt, uSensorCnt, uFrameNumber, uSpoolStatus = 0; static FullRawDataType pFullRawData[ NUM_MARKERS]; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak sample program #3\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Initialize the processors system. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Load the standard camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) ) { goto ERROR_EXIT; } /* if */ /* * Set up a collection for the Optotrak. */ fprintf( stdout, "...OptotrakSetupCollection\n" ); if( OptotrakSetupCollection( NUM_MARKERS, /* Number of markers in the collection. */ (float)50.0, /* Frequency to collect data frames at. */ (float)2500.0, /* Marker frequency for marker maximum on-time. */ 30, /* Dynamic or Static Threshold value to use. */ 160, /* Minimum gain code amplification to use. */ 1, /* Stream mode for the data buffers. */ (float)0.4, /* Marker Duty Cycle to use. */ (float)7.5, /* Voltage to use when turning on markers. */ (float)2.0, /* Number of seconds of data to collect. */ (float)0.0, /* Number of seconds to pre-trigger data by. */ OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_GET_NEXT_FRAME_FLAG ) ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Activate the markers. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers() ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * Get and display ten frames of full raw data. */ fprintf( stdout, "\n\nSample Program Results:\n\n" ); for( uFrameCnt = 0; uFrameCnt < 10; ++uFrameCnt ) { /* * Get a frame of data. */ if( DataGetLatestRaw( &uFrameNumber, &uElements, &uFlags, pFullRawData ) ) { goto ERROR_EXIT; } /* if */ /* * Print out the data. */ fprintf( stdout, "Frame Number: %8u\n", uFrameNumber ); fprintf( stdout, "Elements : %8u\n", uElements ); fprintf( stdout, "Flags : 0x%04x\n", uFlags ); for( uMarkerCnt = 0; uMarkerCnt < 6; ++uMarkerCnt ) { /* * Print out the current marker number. */ fprintf( stdout, "Marker %u\t\tCentroid Peak DRC Code\n", uMarkerCnt + 1 ); /* * Print out the information for each sensor. */ for( uSensorCnt = 0; uSensorCnt < NUM_SENSORS; ++uSensorCnt ) { /* * Print out the current sensor number. */ fprintf( stdout, "\tSensor %u\t", uSensorCnt + 1 ); /* * Print out the centroid. If is is bad print out the * string 'missing'. */ if( pFullRawData[ uMarkerCnt].fCentroid[ uSensorCnt] < MAX_NEGATIVE ) { fprintf( stdout, " missing " ); } /* if */ else { fprintf( stdout, "%8.2f ", pFullRawData[ uMarkerCnt].fCentroid[ uSensorCnt] ); } /* else */ /* * Print out the rest of this sensor's information. */ nSensorCode = pFullRawData[ uMarkerCnt].SensorData[ uSensorCnt].ucCode; fprintf( stdout, "%4d %4d %s\n", pFullRawData[ uMarkerCnt].SensorData[ uSensorCnt].ucPeak, pFullRawData[ uMarkerCnt].SensorData[ uSensorCnt].ucDRC, pSensorStatusString[ nSensorCode] ); } /* for */ } /* for */ } /* for */ fprintf( stdout, "\n" ); /* * Initialize a data file for spooling of the Optotrak data. */ fprintf( stdout, "...DataBufferInitializeFile\n" ); if( DataBufferInitializeFile( OPTOTRAK, "C#001.S03" ) ) { goto ERROR_EXIT; } /* if */ /* * Spool data to the previously initialized file. */ fprintf( stdout, "...DataBufferSpoolData\n" ); if( DataBufferSpoolData( &uSpoolStatus ) ) { goto ERROR_EXIT; } /* if */ fprintf( stdout, "\n\nSample Program Results:\n\n" ); fprintf( stdout, "Spool Status: 0x%04x\n", uSpoolStatus ); fprintf( stdout, "\n" ); /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ /* * Shutdown the processors message passing system. */ fprintf( stdout, "...TransputerShutdownSystem\n" ); if( TransputerShutdownSystem() ) { goto ERROR_EXIT; } /* if */ /* * Exit the program. */ fprintf( stdout, "\nProgram execution complete.\n" ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers(); TransputerShutdownSystem(); exit( 1 ); } /* main */
int main(){ // Function to retrieve OAPI version size_t len = LEN; size_t read; char *line = malloc(len); assert(line); // return variables char s0[1024]; int i0; int nFrameOld = -1; while ((read = getline(&line, &len, stdin)) != -1) { //fprintf(stderr, "INFO: Retrieved line of length %zu (including NULL): %s", read, line); if (cmp(line, "OAPIGetVersionString")){ i0 = OAPIGetVersionString(s0, len); printf("'%s'\n", s0); } else if (cmp(line, "OptoGetLastError")){ i0 = OptoGetLastError(s0, len); printf("'%s'\n", s0); } else if (cmp(line, "OptotrakGetErrorString")){ i0 = OptotrakGetErrorString(s0, len); printf("'%s'\n", s0); } else if (cmp(line, "OptoGetExtendedErrorCode")){ i0 = OptoGetExtendedErrorCode(); printf("%d\n", i0); } else if (cmp(line, "TransputerLoadSystem")){ strtok(line, "\""); char* s = strtok(NULL, "\""); // may be null i0 = TransputerLoadSystem(s); //i0 = TransputerLoadSystem("/opt/NDIoapi/ndigital/realtime/system.nif"); printf("%d\n", i0); } else if (cmp(line, "TransputerInitializeSystem")){ i0 = TransputerInitializeSystem(OPTO_LOG_ERRORS_FLAG); printf("%d\n", i0); } else if (cmp(line, "TransputerShutdownSystem")){ i0 = TransputerShutdownSystem(); printf("%d\n", i0); } else if (cmp(line, "TransputerDetermineSystemCfg")){ strtok(line, "\""); char* s = strtok(NULL, "\""); // may be null i0 = TransputerDetermineSystemCfg(s); printf("%d\n", i0); } else if (cmp(line, "OptotrakLoadCameraParameters")){ strtok(line, "\""); char* s = strtok(NULL, "\""); // may be null OptotrakLoadCameraParameters(s); printf("%d\n", i0); } else if (cmp(line, "OptotrakLoadAutoScale")){ strtok(line, "\""); char* s = strtok(NULL, "\""); // may be null OptotrakLoadAutoScale(s); printf("%d\n", i0); } else if (cmp(line, "OptotrakLockTemperatures")){ i0 = OptotrakLockTemperatures(); printf("%d\n", i0); } else if (cmp(line, "OptotrakSetCollectionFile")){ strtok(line, "\""); char* s = strtok(NULL, "\""); // may be null OptotrakSetCollectionFile(s); printf("%d\n", i0); } else if (cmp(line, "OptotrakSetupCollectionFromFile")){ strtok(line, "\""); char* s = strtok(NULL, "\""); // may be null OptotrakSetupCollectionFromFile(s); printf("%d\n", i0); } else if (cmp(line, "OptotrakSetupCollection")){ float fFrameFrequency, fMarkerFrequency; int nThreshold, nMinimumGain, nStreamData; float fDutyCycle, fVoltage, fCollectionTime, fPreTriggerTime; int nFlags; strtok(line, "("); char* s = strtok(NULL, ")"); int i = sscanf(s, "%d, %f, %f, %d, %d, %d, %f, %f, %f, %f, %d", &nMarkers, &fFrameFrequency, &fMarkerFrequency, &nThreshold, &nMinimumGain, &nStreamData, &fDutyCycle, &fVoltage, &fCollectionTime, &fPreTriggerTime, &nFlags); if(i==11){ i0 = OptotrakSetupCollection(nMarkers, fFrameFrequency, fMarkerFrequency, nThreshold, nMinimumGain, nStreamData, fDutyCycle, fVoltage, fCollectionTime, fPreTriggerTime, nFlags); printf("%d\n", i0); allocSpace(nMarkers); } else printf("ERROR: %d arguments read (11 expected)\n", i); } else if (cmp(line, "OptotrakActivateMarkers")){ i0 = OptotrakActivateMarkers(); printf("%d\n", i0); } else if (cmp(line, "OptotrakDeActivateMarkers")){ i0 = OptotrakDeActivateMarkers(); printf("%d\n", i0); } else if (cmp(line, "OptotrakGetStatus")){ int nNumSensors, nNumOdaus, nNumRigidBodies, nMarkers; float fFrameFrequency, fMarkerFrequency; int nThreshold, nMinimumGain, nStreamData; float fDutyCycle, fVoltage, fCollectionTime, fPreTriggerTime; int nFlags; i0 = OptotrakGetStatus(&nNumSensors, &nNumOdaus, &nNumRigidBodies, &nMarkers, &fFrameFrequency, &fMarkerFrequency, &nThreshold, &nMinimumGain, &nStreamData, &fDutyCycle, &fVoltage, &fCollectionTime, &fPreTriggerTime, &nFlags); printf("(%d, %d, %d, %d, %f, %f, %d, %d, %d, %f, %f, %f, %f, 0x%x)\n", nNumSensors, nNumOdaus, nNumRigidBodies, nMarkers, fFrameFrequency, fMarkerFrequency, nThreshold, nMinimumGain, nStreamData, fDutyCycle, fVoltage, fCollectionTime, fPreTriggerTime, nFlags); } else if (cmp(line, "OptotrakSetStroberPortTable")){ int nPort1, nPort2, nPort3, nPort4; strtok(line, "("); char* s = strtok(NULL, ")"); if(s && sscanf(s, "%d, %d, %d, %d", &nPort1, &nPort2, &nPort3, &nPort4) == 4){ i0 = OptotrakSetStroberPortTable(nPort1, nPort2, nPort3, nPort4); printf("%d\n", i0); } else printf("ERROR: reading 4 arguments\n"); } else if (cmp(line, "OptotrakSaveCollectionToFile")){ strtok(line, "\""); char* s = strtok(NULL, "\""); if (s) i0 = OptotrakSaveCollectionToFile(s); else i0 = OptotrakSaveCollectionToFile(""); printf("%d\n", i0); } else if (cmp(line, "OptotrakSetCameraParameters")){ int nMarkerType, nWaveLength, nModelType; strtok(line, "("); char* s = strtok(NULL, ")"); if(s && sscanf(s, "%d, %d, %d", &nMarkerType, &nWaveLength, &nModelType) == 3){ i0 = OptotrakSetCameraParameters(nMarkerType, nWaveLength, nModelType); printf("%d\n", i0); } else printf("ERROR: reading 3 arguments\n"); } else if (cmp(line, "OptotrakGetCameraParameterStatus")){ int curMarkerType, nCurWaveLength, nCurModelType; char szStatus[len]; i0 = OptotrakGetCameraParameterStatus(&curMarkerType, &nCurWaveLength, &nCurModelType, szStatus, len); printf("(%d, %d, %d, '%s')\n", curMarkerType, nCurWaveLength, nCurModelType, szStatus); } else if (cmp(line, "OdauSaveCollectionToFile")){ strtok(line, "\""); char* s = strtok(NULL, "\""); if (s){ i0 = OptotrakSaveCollectionToFile(s); printf("%d\n", i0); } else printf("ERROR: reading filename\n"); } else if (cmp(line, "OdauSetupCollectionFromFile")){ strtok(line, "\""); char* s = strtok(NULL, "\""); if (s){ i0 = OdauSetupCollectionFromFile(s); printf("%d\n", i0); } else printf("ERROR: reading filename\n"); } else if (cmp(line, "OdauSetTimer")){ //int OdauSetTimer( int nOdauId, unsigned uTimer, unsigned uMode, unsigned long ulVal ); int nOdauId; unsigned uTimer, uMode; unsigned long ulVal; strtok(line, "("); char* s = strtok(NULL, ")"); if(s && sscanf(s, "%d, %u, %u, %lu", &nOdauId, &uTimer, &uMode, &ulVal) == 4){ i0 = OdauSetTimer(ODAU1+nOdauId-1, uMode, uTimer, ulVal); printf("%d\n", i0); } else printf("ERROR: reading 4 arguments\n"); } else if (cmp(line, "OdauSetAnalogOutputs")){ //int OdauSetAnalogOutputs( int nOdauId, float *pfVoltage1, float *pfVoltage2, unsigned uChangeMask ); int nOdauId; // 1-4 -> ODAU1-ODAU4 float fVoltage1; float fVoltage2; unsigned uChangeMask; strtok(line, "("); char* s = strtok(NULL, ")"); if(s && sscanf(s, "%d, %f, %f, %u", &nOdauId, &fVoltage1, &fVoltage2, &uChangeMask) == 4){ i0 = OdauSetAnalogOutputs(ODAU1+nOdauId-1, &fVoltage1, &fVoltage2, uChangeMask); printf("(%f, %f)\n", fVoltage1, fVoltage1); } else printf("ERROR: reading 4 arguments\n"); } else if (cmp(line, "OdauSetDigitalOutputs")){ //int OdauSetDigitalOutputs( int nOdauId, unsigned *puDigitalOut, unsigned uUpdateMask ); int nOdauId; // 1-4 -> ODAU1-ODAU4 unsigned uDigitalOut, uUpdateMask; strtok(line, "("); char* s = strtok(NULL, ")"); if(s && sscanf(s, "%d, %u, %u", &nOdauId, &uDigitalOut, &uUpdateMask) == 4){ i0 = OdauSetDigitalOutputs(ODAU1+nOdauId-1, &uDigitalOut, uUpdateMask); printf("0x%x\n", uDigitalOut); } else printf("ERROR: reading 3 arguments\n"); } else if (cmp(line, "OdauSetupCollection")){ //OdauSetupCollection( int nOdauId, int nChannels, int nGain, int nDigitalMode, float fFrameFreq, float fScanFreq, int nStreamData, float fCollectionTime, float fPreTriggerTime, unsigned uFlags ); int nOdauId, nChannels, nGain, nDigitalMode; float fFrameFreq, fScanFreq; int nStreamData; float fCollectionTime, fPreTriggerTime; unsigned uFlags; strtok(line, "("); char* s = strtok(NULL, ")"); if(s && sscanf(s, "%d, %d, %d, %d, %f, %f, %d, %f, %f, %u", &nOdauId, &nChannels, &nGain, &nDigitalMode, &fFrameFreq, &fScanFreq, &nStreamData, &fCollectionTime, &fPreTriggerTime, &uFlags) == 10){ i0 = OdauSetupCollection(ODAU1+nOdauId-1, nChannels, nGain, nDigitalMode, fFrameFreq, fScanFreq, nStreamData, fCollectionTime, fPreTriggerTime, uFlags); printf("%d\n", i0); } else printf("ERROR: reading 10 arguments\n"); } else if (cmp(line, "OptotrakStopCollection")){ i0 = OptotrakStopCollection(); printf("%d\n", i0); } else if (cmp(line, "OdauGetStatus")){ //int OdauGetStatus( int nOdauId, int *pnChannels, int *pnGain, int *pnDigitalMode, float *pfFrameFrequency, float *pfScanFrequency, int *pnStreamData, float *pfCollectionTime, float *pfPreTriggerTime, unsigned *puCollFlags, int *pnFlags ); int nOdauId, nChannels, nGain, nDigitalMode; float fFrameFrequency, fScanFrequency; int nStreamData; float fCollectionTime, fPreTriggerTime; unsigned uCollFlags; int nFlags; strtok(line, "("); char* s = strtok(NULL, ")"); if(s && sscanf(s, "%d", &nOdauId) == 1){ i0 = OdauGetStatus(ODAU1+nOdauId-1, &nChannels, &nGain, &nDigitalMode, &fFrameFrequency, &fScanFrequency, &nStreamData, &fCollectionTime, &fPreTriggerTime, &uCollFlags, &nFlags); printf("(%d, %d, %d, %f, %f, %d, %f, %f, 0x%04x, %d)\n", nChannels, nGain, nDigitalMode, fFrameFrequency, fScanFrequency, nStreamData, fCollectionTime, fPreTriggerTime, uCollFlags, nFlags); } else printf("ERROR: reading argument\n"); } else if (cmp(line, "RigidBodyAddFromFile")){ int nRigidBodyId, nStartMarker; char szRigFile[len]; int nFlags; strtok(line, "("); char* s = strtok(NULL, ")"); if(s && sscanf(s, "%d, %d, %s, %d", &nRigidBodyId, &nStartMarker, szRigFile, &nFlags) != 4){ i0 = RigidBodyAddFromFile(nRigidBodyId, nStartMarker, szRigFile, nFlags); printf("%d\n", i0); } else printf("ERROR: reading 4 arguments\n"); } else if (cmp(line, "RigidBodyAdd")){ //int ( int nRigidBodyId, int nStartMarker, int nNumMarkers, float *pRigidCoordinates, float *pNormalCoordinates, int nFlags ); int nRigidBodyId, nStartMarker, nNumMarkers; float *rigidCoordinates, *normalCoordinates; int nFlags; char* s = strtok(line, "("); if(s && sscanf(line+strlen(s)+1, "%d, %d, %d", &nRigidBodyId, &nStartMarker, &nNumMarkers)==3){ rigidCoordinates = calloc(3*nNumMarkers, sizeof(float)); normalCoordinates = calloc(3*nNumMarkers, sizeof(float)); s = strtok(NULL, "[("); // up to first list/tuple if(!s){ printf("ERROR: reading rigid values\n"); goto end; } for(int i=0; i<3*nNumMarkers; i++){ char* s = strtok(NULL, ","); if(!s){ printf("ERROR: reading rigid value %d\n", i); goto end; } if(sscanf(s, "%f", (float*)&rigidCoordinates[i]) != 1){ printf("ERROR: parsing rigid value %d\n", i); goto end; } } s = strtok(NULL, "[("); // up to first list/tuple if(!s){ printf("ERROR: reading normal values\n"); goto end; } for(int i=0; i<3*nNumMarkers; i++){ char* s = strtok(NULL, ","); if(!s){ printf("ERROR: reading normal value %d\n", i); goto end; } if(sscanf(s, "%f", (float*)&normalCoordinates[i]) != 1){ printf("ERROR: parsing normal value %d\n", i); goto end; } } s = strtok(NULL, "],) "); //s = strtok(NULL, ")"); if(s && sscanf(s, "%d", &nFlags)==1){ i0 = RigidBodyAdd(nRigidBodyId, nStartMarker, nNumMarkers, rigidCoordinates, normalCoordinates, nFlags); printf("%d\n", i0); } else printf("ERROR: reading last argument\n"); } else printf("ERROR: reading first 3 arguments\n"); //int RigidBodyAddFromFile( int nRigidBodyId, int nStartMarker, char *pszRigFile, int nFlags ); //int RigidBodyChangeSettings( int nRigidBodyId, int nMinMarkers, int nMaxMarkersAngle, float fMax3dError, float fMaxSensorError, float fMax3dRmsError, float fMaxSensorRmsError, int nFlags ); //int RigidBodyDelete( int nRigidBodyId ); //int RigidBodyChangeFOR( int nRigidId, int nRotationMethod ); } else if (cmp(line, "RigidBodyChangeSettings")){ int nRigidBodyId, nMinMarkers, nMaxMarkersAngle; float fMax3dError, fMaxSensorError, fMax3dRmsError, fMaxSensorRmsError; int nFlags; strtok(line, "("); char* s = strtok(NULL, ")"); if(s && sscanf(s, "%d, %d, %d, %f, %f, %f, %f, %d", &nRigidBodyId, &nMinMarkers, &nMaxMarkersAngle, &fMax3dError, &fMaxSensorError, &fMax3dRmsError, &fMaxSensorRmsError, &nFlags) != 4){ i0 = RigidBodyChangeSettings(nRigidBodyId, nMinMarkers, nMaxMarkersAngle, fMax3dError, fMaxSensorError, fMax3dRmsError, fMaxSensorRmsError, nFlags); printf("%d\n", i0); } else printf("ERROR: reading 8 arguments\n"); } else if (cmp(line, "DataGetLatestRaw")){ uint uFrameNumber=999, uElements=999, uFlags=999; i0 = DataGetLatestRaw(&uFrameNumber, &uElements, &uFlags, pFullRawData); printf("Frame Number: %8u\n", uFrameNumber); printf("Elements : %8u\n", uElements); printf("Flags : 0x%04x\n", uFlags); for(uint uMarkerCnt=0; uMarkerCnt<nMarkers; uMarkerCnt++){ // Print out the current marker number. fprintf( stdout, "Marker %u, ", uMarkerCnt + 1 ); //Print out the information for each sensor. for(uint uSensorCnt = 0; uSensorCnt<NUM_SENSORS; ++uSensorCnt ){ //Print out the current sensor number. fprintf( stdout, "Sensor %u, ", uSensorCnt + 1 ); // Print out the centroid. If it is bad print out *the string 'missing'. //if( pFullRawData[uMarkerCnt].fCentroid[uSensorCnt] < MAX_NEGATIVE ) //printf("data missing, " ); //else printf("data: %8.2g, ", (float)pFullRawData[uMarkerCnt].fCentroid[uSensorCnt] ); //Print out the rest of this sensor’s information. printf("peak: %4d, DRC: %4d, sensorCode: %u\n", pFullRawData[uMarkerCnt].SensorData[uSensorCnt].ucPeak, pFullRawData[uMarkerCnt].SensorData[uSensorCnt].ucDRC, (uint)pFullRawData[uMarkerCnt].SensorData[uSensorCnt].ucCode); } /* for */ } /* for */ } else if (cmp(line, "DataGetLatest3D")){ //int DataGetLatest3D( unsigned *pnFrame, unsigned *pElems, unsigned *pFlags, void *pDataDest ); uint nFrame=999, elems=999, flags=999; //Position3d dataDest[NUM_MARKERS]; i0 = DataGetLatest3D(&nFrame, &elems, &flags, pPosition3d); printf("(%d, %u, %u, 0x%X, (", i0, nFrame, elems, flags); for(uint i=0; i<nMarkers; i++){ printf(" (%10.3g, %10.3g, %10.3g),", pPosition3d[i].x, pPosition3d[i].y, pPosition3d[i].z); } printf("))\n"); } else if (cmp(line, "RequestLatest3D")){ i0 = RequestLatest3D(); printf("%d\n", i0); } else if (cmp(line, "DataIsReady")){ i0 = DataIsReady(); printf("%d\n", i0); } else if (cmp(line, "DataReceiveLatest3D")){ // alle markers 3d uint nFrame=999, elems=999, flags=999; Position3d dataDest; i0 = DataReceiveLatest3D(&nFrame, &elems, &flags, &dataDest); printf("(%d, %u, %u, 0x%X, (", i0, nFrame, elems, flags); for(uint i=0; i<nMarkers; i++){ printf(" (%10.3g, %10.3g, %10.3g),", pPosition3d[i].x, pPosition3d[i].y, pPosition3d[i].z); } printf("))\n"); } else if (cmp(line, "DataReceiveLatestRaw")){ uint nFrame, elems, flags; void *dataDest; // todo allocate! i0 = DataReceiveLatestRaw(&nFrame, &elems, &flags, &dataDest); printf("(%d, %u, 0x%x)\n", i0, nFrame, flags); } else if (cmp(line, "DataBufferInitializeFile")){ //unsigned uDataId; char pszFileName[len]; strtok(line, "\""); char* s = strtok(NULL, "\""); if(sscanf(s, "%s", pszFileName)==1){ i0 = DataBufferInitializeFile(OPTOTRAK, s); printf("%d\n", i0); } else printf("ERROR: could not read filename\n"); } else if (cmp(line, "DataBufferSpoolData")){ int i = 999; i0 = DataBufferSpoolData(&i); printf("(%d, %d)\n", i0, i); } else if (cmp(line, "DataBufferStart")){ i0 = DataBufferStart(); printf("%d\n", i0); } else if (cmp(line, "DataBufferStop")){ i0 = DataBufferStop(); printf("%d\n", i0); } else if (cmp(line, "DataBufferWriteData")){ unsigned uRealtimeData=999, uSpoolComplete=0, uSpoolStatus=999; unsigned long ulFramesBuffered=999; i0 = DataBufferWriteData(&uRealtimeData, &uSpoolComplete, &uSpoolStatus, &ulFramesBuffered); printf("(%d, %u, %u, %u, %lu)\n", i0, uRealtimeData, uSpoolComplete, uSpoolStatus, ulFramesBuffered); } else if (cmp(line, "DataBufferAbortSpooling")){ i0 = DataBufferAbortSpooling(); printf("%d\n", i0); } else { printf("ERROR: no such command: %s\n", line); } end: fflush(stdout); } exit(EXIT_SUCCESS); }
void main( int argc, unsigned char *argv[] ) { char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; int i, nDevices; ApplicationDeviceInformation *pdtDevices; DeviceHandle *pdtDeviceHandles; DeviceHandleInfo *pdtDeviceHandlesInfo; /* * initialization * intialize variables */ pdtDevices = NULL; pdtDeviceHandles = NULL; pdtDeviceHandlesInfo = NULL; nDevices = 0; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak Certus sample program #12\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Communication Initialization * Once the system processors have been loaded, the application * prepares for communication by initializing the system processors. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Determine if this sample will run with the system attached. * This sample is intended for Optotrak Certus systems. */ fprintf( stdout, "...DetermineSystem\n" ); if( uDetermineSystem( ) != OPTOTRAK_CERTUS_FLAG ) { goto PROGRAM_COMPLETE; } /* if */ /* * Strober Initialization * Once communication has been initialized, the application must * determine the strober configuration. * The application retrieves device handles and all strober * properties from the system. */ fprintf( stdout, "...DetermineStroberConfiguration\n" ); if( DetermineStroberConfiguration( &pdtDeviceHandles, &pdtDeviceHandlesInfo, &nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * check if any devices have been detected by the system */ if( nDevices == 0 ) { fprintf( stdout, ".........no devices detected. Quitting program...\n" ); goto PROGRAM_COMPLETE; } /* if */ /* * Now that all the device handles have been completely set up, * the application can store all the device handle information in * an internal data structure. This will facilitate lookups when * a property setting needs to be checked. */ ApplicationStoreDeviceProperties( &pdtDevices, pdtDeviceHandlesInfo, nDevices ); /* * Turn the beeper ON */ for( i = 0; i < nDevices; i++ ) { fprintf( stdout, "...OptotrakDeviceHandleSetBeeper (ON)\n" ); if( OptotrakDeviceHandleSetBeeper( pdtDeviceHandlesInfo[i].pdtHandle->nID, BEEPER_STATE_ON ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Wait 1 second */ fprintf( stdout, "...beeping for one second\n" ); sleep( 1 ); /* * Turn the beeper OFF */ fprintf( stdout, "...OptotrakDeviceHandleSetBeeper (OFF)\n" ); if( OptotrakDeviceHandleSetBeeper( pdtDeviceHandlesInfo[i].pdtHandle->nID, BEEPER_STATE_OFF ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ } /* for */ PROGRAM_COMPLETE: /* * CLEANUP */ fprintf( stdout, "\n" ); fprintf( stdout, "...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); exit( 1 ); } /* main */
void main( int argc, unsigned char *argv[] ) { OptotrakSettings dtSettings; int nCurDevice, nCurMarker, nDevices, nMarkersToActivate; ApplicationDeviceInformation *pdtDevices; DeviceHandle *pdtDeviceHandles; DeviceHandleInfo *pdtDeviceHandlesInfo; unsigned int uFlags, uElements, uChannelCnt, uFrameNumber; Position3d *p3dData; static int puOdauData[ SAMPLE_NUM_CHANNELS + 1]; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; /* * initialization * intialize variables */ pdtDevices = NULL; pdtDeviceHandles = NULL; pdtDeviceHandlesInfo = NULL; p3dData = NULL; dtSettings.nMarkers = 0; dtSettings.fFrameFrequency = SAMPLE_FRAMEFREQ; dtSettings.fMarkerFrequency = SAMPLE_MARKERFREQ; dtSettings.nThreshold = 30; dtSettings.nMinimumGain = 160; dtSettings.nStreamData = SAMPLE_STREAMDATA; dtSettings.fDutyCycle = SAMPLE_DUTYCYCLE; dtSettings.fVoltage = SAMPLE_VOLTAGE; dtSettings.fCollectionTime = 1.0; dtSettings.fPreTriggerTime = 0.0; nDevices = 0; nMarkersToActivate = 0; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak Certus sample program #19\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Communication Initialization * Once the system processors have been loaded, the application * prepares for communication by initializing the system processors. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Determine if this sample will run with the system attached. * This sample is intended for Optotrak Certus systems. */ fprintf( stdout, "...DetermineSystem\n" ); if( uDetermineSystem( ) != OPTOTRAK_CERTUS_FLAG ) { goto ERROR_EXIT; } /* if */ /* * Strober Initialization * Once communication has been initialized, the application must * determine the strober configuration. * The application retrieves device handles and all strober * properties from the system. */ fprintf( stdout, "...DetermineStroberConfiguration\n" ); if( DetermineStroberConfiguration( &pdtDeviceHandles, &pdtDeviceHandlesInfo, &nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * check if any devices have been detected by the system */ if( nDevices == 0 ) { fprintf( stdout, ".........no devices detected. Quitting program...\n" ); goto PROGRAM_COMPLETE; } /* if */ /* * Now that all the device handles have been completely set up, * the application can store all the device handle information in * an internal data structure. This will facilitate lookups when * a property setting needs to be checked. */ ApplicationStoreDeviceProperties( &pdtDevices, pdtDeviceHandlesInfo, nDevices ); /* * Change the number of markers to fire for all devices */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { nMarkersToActivate = pdtDevices[nCurDevice].b3020Capability? CERTUS_SAMPLE_3020_STROBER_MARKERSTOFIRE : CERTUS_SAMPLE_STROBER_MARKERSTOFIRE; SetMarkersToActivateForDevice( &(pdtDevices[nCurDevice]), pdtDeviceHandlesInfo[nCurDevice].pdtHandle->nID, nMarkersToActivate ); } /* if */ fprintf( stdout, "\n" ); /* * Determine the collection settings based on the device properties */ ApplicationDetermineCollectionParameters( nDevices, pdtDevices, &dtSettings ); /* * Set optional processing flags (this overides the settings in Optotrak.INI). */ fprintf( stdout, "...OptotrakSetProcessingFlags\n" ); if( OptotrakSetProcessingFlags( OPTO_LIB_POLL_REAL_DATA | OPTO_CONVERT_ON_HOST | OPTO_RIGID_ON_HOST ) ) { goto ERROR_EXIT; } /* if */ /* * Load camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Ensure that we are firing some markers */ if( dtSettings.nMarkers == 0 ) { fprintf( stdout, "Error: There are no markers to be activated.\n" ); goto ERROR_EXIT; } /* if */ /* * allocate memory for 3d data */ p3dData = (Position3d*)malloc( dtSettings.nMarkers * sizeof( Position3d ) ); /* * Configure ODAU Collection. */ fprintf( stdout, "...OdauSetupCollection\n" ); if( OdauSetupCollection( ODAU1, SAMPLE_NUM_CHANNELS, /* Number of analog channels to collect. */ SAMPLE_ODAU_GAIN, /* Gain to use for the analog channels.*/ ODAU_DIGITAL_INPB_INPA, /* Mode for the Digital I/O port.*/ (float)100.0, /* Frequency to collect data frames at. */ (float)90000.0, /* Frequency to scan channels at. */ SAMPLE_STREAMDATA, /* Stream mode for the data buffers. */ (float)1.0, /* Number of seconds of data to collect. */ 0.0, /* Number of seconds to pre-trigger data by. */ 0 ) ) /* Flags. */ { goto ERROR_EXIT; } /* if */ /* * Configure Optotrak Collection * Once the system strobers have been enabled, and all settings are * loaded, the application can set up the Optotrak collection */ fprintf( stdout, "...OptotrakSetupCollection\n" ); fprintf( stdout, ".....%d, %.2f, %.0f, %d, %d, %d, %.2f, %.2f, %.0f, %.0f\n", dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime ); if( OptotrakSetupCollection( dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime, OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_BUFFER_RAW_FLAG | OPTOTRAK_SWITCH_AND_CONFIG_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Activate markers. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers( ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); /* * loop around until a device is plugged or unplugged */ while( 1 ) { fprintf( stdout, "\nCHANGE THE STROBER CONFIGURATION OR PRESS SWITCH TO END THIS TEST\n\n" ); sleep( 1 ); if( DataGetLatest3D( &uFrameNumber, &uElements, &uFlags, p3dData ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ fprintf( stdout, "\nFrame Number: %8u\n", uFrameNumber ); /* * display the 3d data */ fprintf( stdout, "3D Data Display (%d Markers)\n", dtSettings.nMarkers ); for( nCurMarker = 0; nCurMarker < dtSettings.nMarkers; nCurMarker++ ) { DisplayMarker( nCurMarker + 1, p3dData[nCurMarker] ); } /* for */ /* * check if the tool configuration has changed */ if( uFlags & OPTO_TOOL_CONFIG_CHANGED_FLAG ) { /* * exit the program loop */ fprintf( stdout, "\n\n\n...Tool Configuration Changed\n" ); break; } /* if */ if( uFlags & OPTO_SWITCH_DATA_CHANGED_FLAG ) { /* * exit the program loop */ fprintf( stdout, "\n\n\n...Switch Data Changed\n" ); break; } /* if */ /* * Get a frame of ODAU raw data. */ fprintf( stdout, "\n" ); if( DataGetLatestOdauRaw( ODAU1, &uFrameNumber, &uElements, &uFlags, puOdauData ) ) { goto ERROR_EXIT; } /* if */ /* * Print out the data. */ for( uChannelCnt = 0; uChannelCnt < SAMPLE_NUM_CHANNELS; ++uChannelCnt ) { fprintf( stdout, "Channel %u Raw 0x%08x Voltage %f\n", uChannelCnt + 1, puOdauData[ uChannelCnt], (float)( (int)( puOdauData[uChannelCnt])) * 0.000305175/(float)SAMPLE_ODAU_GAIN ); /* * if you have an ODAUI unit, instead of an ODAUII unit, * replace the above fprintf statement with: * fprintf( stdout, "Channel %u Raw 0x%08x Voltage %f\n", * uChannelCnt + 1, * puOdauData[ uChannelCnt ], * (float)( (int)( puOdauData[ uChannelCnt] & 0x0FFF ) - 2048) * * (10.0/2048.0)/(float)SAMPLE_ODAU_GAIN ); */ } /* for */ fprintf( stdout, "Digital 0x%04x\n", puOdauData[SAMPLE_NUM_CHANNELS] ); } /* while */ sleep( 1 ); PROGRAM_COMPLETE: /* * CLEANUP */ fprintf( stdout, "\n" ); fprintf( stdout, "...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); /* * free all memory */ if( pdtDeviceHandlesInfo ) { for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { AllocateMemoryDeviceHandleProperties( &(pdtDeviceHandlesInfo[nCurDevice].grProperties), 0 ); } /* for */ } /* if */ AllocateMemoryDeviceHandles( &pdtDeviceHandles, 0 ); AllocateMemoryDeviceHandlesInfo( &pdtDeviceHandlesInfo, pdtDeviceHandles, 0 ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); /* * free all memory */ if( pdtDeviceHandlesInfo ) { for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { AllocateMemoryDeviceHandleProperties( &(pdtDeviceHandlesInfo[nCurDevice].grProperties), 0 ); } /* for */ } /* if */ AllocateMemoryDeviceHandles( &pdtDeviceHandles, 0 ); AllocateMemoryDeviceHandlesInfo( &pdtDeviceHandlesInfo, pdtDeviceHandles, 0 ); exit( 1 ); } /* main */
void main( int argc, unsigned char *argv[] ) { OptotrakSettings dtSettings; char szNDErrorString[MAX_ERROR_STRING_LENGTH + 1]; int i, nCurDevice, nCurMarker, nMarkersToActivate, nDevices, nDeviceMarkers, nNumSensors, nCurSensor; ApplicationDeviceInformation *pdtDevices; DeviceHandle *pdtDeviceHandles; DeviceHandleInfo *pdtDeviceHandlesInfo; unsigned int uFlags, uElements, uFrameNumber; Position3d *p3dData; float *pfCurSensor, *pCentroidData; /* * initialization * intialize variables */ pdtDevices = NULL; pdtDeviceHandles = NULL; pdtDeviceHandlesInfo = NULL; p3dData = NULL; nMarkersToActivate = 0; nDevices = 0; nDeviceMarkers = 0; dtSettings.nMarkers = 0; dtSettings.fFrameFrequency = SAMPLE_FRAMEFREQ; dtSettings.fMarkerFrequency = SAMPLE_MARKERFREQ; dtSettings.nThreshold = 30; dtSettings.nMinimumGain = 160; dtSettings.nStreamData = SAMPLE_STREAMDATA; dtSettings.fDutyCycle = SAMPLE_DUTYCYCLE; dtSettings.fVoltage = SAMPLE_VOLTAGE; dtSettings.fCollectionTime = 1.0; dtSettings.fPreTriggerTime = 0.0; /* * Announce that the program has started */ fprintf( stdout, "\nOptotrak Certus sample program #16\n\n" ); /* * look for the -nodld parameter that indicates 'no download' */ if( ( argc < 2 ) || ( strncmp( argv[1], "-nodld", 6 ) != 0 ) ) { /* * Load the system of processors. */ fprintf( stdout, "...TransputerLoadSystem\n" ); if( TransputerLoadSystem( "system" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); } /* if */ /* * Communication Initialization * Once the system processors have been loaded, the application * prepares for communication by initializing the system processors. */ fprintf( stdout, "...TransputerInitializeSystem\n" ); if( TransputerInitializeSystem( OPTO_LOG_ERRORS_FLAG | OPTO_LOG_MESSAGES_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Determine if this sample will run with the system attached. * This sample is intended for Certus systems. */ fprintf( stdout, "...DetermineSystem\n" ); if( uDetermineSystem( ) != OPTOTRAK_CERTUS_FLAG ) { goto PROGRAM_COMPLETE; } /* if */ /* * Strober Initialization * Once communication has been initialized, the application must * determine the strober configuration. * The application retrieves device handles and all strober * properties from the system. */ fprintf( stdout, "...DetermineStroberConfiguration\n" ); if( DetermineStroberConfiguration( &pdtDeviceHandles, &pdtDeviceHandlesInfo, &nDevices ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * check if any devices have been detected by the system */ if( nDevices == 0 ) { fprintf( stdout, ".........no devices detected. Quitting program...\n" ); goto PROGRAM_COMPLETE; } /* if */ /* * Now that all the device handles have been completely set up, * the application can store all the device handle information in * an internal data structure. This will facilitate lookups when * a property setting needs to be checked. */ ApplicationStoreDeviceProperties( &pdtDevices, pdtDeviceHandlesInfo, nDevices ); /* * Change the number of markers to fire for all devices */ for( nCurDevice = 0; nCurDevice < nDevices; nCurDevice++ ) { nMarkersToActivate = pdtDevices[nCurDevice].b3020Capability? CERTUS_SAMPLE_3020_STROBER_MARKERSTOFIRE : CERTUS_SAMPLE_STROBER_MARKERSTOFIRE; SetMarkersToActivateForDevice( &(pdtDevices[nCurDevice]), pdtDeviceHandlesInfo[nCurDevice].pdtHandle->nID, nMarkersToActivate ); } /* if */ fprintf( stdout, "\n" ); /* * Determine the collection settings based on the device properties */ ApplicationDetermineCollectionParameters( nDevices, pdtDevices, &dtSettings ); /* * Set optional processing flags (this overides the settings in Optotrak.INI). */ fprintf( stdout, "...OptotrakSetProcessingFlags\n" ); if( OptotrakSetProcessingFlags( OPTO_LIB_POLL_REAL_DATA | OPTO_CONVERT_ON_HOST | OPTO_RIGID_ON_HOST ) ) { goto ERROR_EXIT; } /* if */ /* * Load camera parameters. */ fprintf( stdout, "...OptotrakLoadCameraParameters\n" ); if( OptotrakLoadCameraParameters( "standard" ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * allocate memory for all data */ if( OptotrakGetStatus( &nNumSensors, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Ensure that we are firing some markers */ if( dtSettings.nMarkers == 0 ) { fprintf( stdout, "Error: There are no markers to be activated.\n" ); goto ERROR_EXIT; } /* if */ p3dData = (Position3d*)malloc( dtSettings.nMarkers * sizeof( Position3d ) ); pCentroidData = (float*)malloc( dtSettings.nMarkers * nNumSensors * sizeof( float ) ); /* * Configure Optotrak Collection * Once the system strobers have been enabled, and all settings are * loaded, the application can set up the Optotrak collection */ fprintf( stdout, "...OptotrakSetupCollection\n" ); fprintf( stdout, ".....%d, %.2f, %.0f, %d, %d, %d, %.2f, %.2f, %.0f, %.0f\n", dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime ); if( OptotrakSetupCollection( dtSettings.nMarkers, dtSettings.fFrameFrequency, dtSettings.fMarkerFrequency, dtSettings.nThreshold, dtSettings.nMinimumGain, dtSettings.nStreamData, dtSettings.fDutyCycle, dtSettings.fVoltage, dtSettings.fCollectionTime, dtSettings.fPreTriggerTime, OPTOTRAK_NO_FIRE_MARKERS_FLAG | OPTOTRAK_BUFFER_RAW_FLAG | OPTOTRAK_SWITCH_AND_CONFIG_FLAG ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * Wait one second to let the camera adjust. */ sleep( 1 ); /* * Prepare for realtime data retrieval. * Activate markers. Turn on the markers prior to data retrieval. */ fprintf( stdout, "...OptotrakActivateMarkers\n" ); if( OptotrakActivateMarkers( ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ sleep( 1 ); fprintf( stdout, "\n\nSample Program Results:\n\n" ); /* * Retrieve a frame of Centroid data. * Use the non-block 'RequestNext'/'ReceiveLatest' call to * retrieve a frame of data. * Add the data retrieval functions return status information in * the uFlags field. * All the data retrieval functions return status information in * the uFlags field. * If the flags indicate that the system configuration has changed, * all processing should stop and the application should re-query * the system for all device information. * NOTE: The re-initialization is not done here in order to * simplify the sample program. */ if( RequestNextCentroid( ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ while( !DataIsReady( ) ); if( DataReceiveLatestCentroid( &uFrameNumber, &uElements, &uFlags, pCentroidData ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * display the Centroid data */ fprintf( stdout, "Centroid Data Display (%d Markers)\n", dtSettings.nMarkers ); /* * Print out the data. */ fprintf( stdout, "Frame Number: %8u\n", uFrameNumber ); fprintf( stdout, "Elements : %8u\n", uElements ); fprintf( stdout, "Flags : 0x%04x\n", uFlags ); for( nCurMarker = 0, pfCurSensor = pCentroidData; nCurMarker < dtSettings.nMarkers; nCurMarker++ ) { fprintf( stdout, "Marker_%.3d:\n", nCurMarker + 1 ); for( nCurSensor = 0; nCurSensor < nNumSensors; nCurSensor++, pfCurSensor++ ) { fprintf( stdout, " sensor_%.2d: %10.4f\n", nCurSensor, *pfCurSensor ); } /* for */ } /* for */ fprintf( stdout, "\n\n" ); /* * Retrieve a frame of 3D data. * Use the blocking 'GetLatest' call to retrieve a frame of data. */ if( DataGetLatest3D( &uFrameNumber, &uElements, &uFlags, p3dData ) != OPTO_NO_ERROR_CODE ) { goto ERROR_EXIT; } /* if */ /* * display the 3d data */ fprintf( stdout, "3D Data Display (%d Markers)\n", dtSettings.nMarkers ); /* * Print out the data. */ fprintf( stdout, "Frame Number: %8u\n", uFrameNumber ); fprintf( stdout, "Elements : %8u\n", uElements ); fprintf( stdout, "Flags : 0x%04x\n", uFlags ); for( nCurMarker = 0; nCurMarker < dtSettings.nMarkers; nCurMarker++ ) { DisplayMarker( nCurMarker, p3dData[nCurMarker] ); } /* for */ /* * De-activate the markers. */ fprintf( stdout, "...OptotrakDeActivateMarkers\n" ); if( OptotrakDeActivateMarkers() ) { goto ERROR_EXIT; } /* if */ PROGRAM_COMPLETE: /* * CLEANUP */ fprintf( stdout, "\n" ); fprintf( stdout, "...TransputerShutdownSystem\n" ); TransputerShutdownSystem( ); /* * free all memory */ if( pdtDeviceHandlesInfo ) { for( i = 0; i < nDevices; i++ ) { AllocateMemoryDeviceHandleProperties( &(pdtDeviceHandlesInfo[i].grProperties), 0 ); } /* for */ } /* if */ AllocateMemoryDeviceHandles( &pdtDeviceHandles, 0 ); AllocateMemoryDeviceHandlesInfo( &pdtDeviceHandlesInfo, pdtDeviceHandles, 0 ); free( p3dData ); free( pCentroidData ); exit( 0 ); ERROR_EXIT: /* * Indicate that an error has occurred */ fprintf( stdout, "\nAn error has occurred during execution of the program.\n" ); if( OptotrakGetErrorString( szNDErrorString, MAX_ERROR_STRING_LENGTH + 1 ) == 0 ) { fprintf( stdout, szNDErrorString ); } /* if */ fprintf( stdout, "\n\n...TransputerShutdownSystem\n" ); OptotrakDeActivateMarkers( ); TransputerShutdownSystem( ); /* * free all memory */ if( pdtDeviceHandlesInfo ) { for( i = 0; i < nDevices; i++ ) { AllocateMemoryDeviceHandleProperties( &(pdtDeviceHandlesInfo[i].grProperties), 0 ); } /* for */ } /* if */ AllocateMemoryDeviceHandles( &pdtDeviceHandles, 0 ); AllocateMemoryDeviceHandlesInfo( &pdtDeviceHandlesInfo, pdtDeviceHandles, 0 ); free( p3dData ); free( pCentroidData ); exit( 1 ); } /* main */