slsDetectorPackage/slsDetectorCalibration/eigerHalfModuleData.h

#ifndef EIGERMODULEDATA_H
#define  EIGERMODULEDATA_H
#include "slsReceiverData.h"



class eigerHalfModuleData : public slsReceiverData<uint32_t> {
public:




	/**
     Implements the slsReceiverData structure for the eiger prototype read out by a half module i.e. using the slsReceiver
     (256*256 pixels, 512 packets for 16 bit mode, 256 for 8, 128 for 4, 1024 for 32, 1040  etc.)
     \param d dynamic range
     \param c crosstalk parameter for the output buffer

	 */


	eigerHalfModuleData(int dr, int np, int bsize, int dsize, bool top, double c=0): slsReceiverData<uint32_t>(xpixels, ypixels, np, bsize),
	xtalk(c), bufferSize(bsize), actualDataSize(dsize), dynamicRange(dr), numberOfPackets(np), top(top){


		int **dMap;
		uint32_t **dMask;

		dMap=new int*[ypixels];
		dMask=new uint32_t*[ypixels];


		for (int i = 0; i < ypixels; i++) {
			dMap[i] = new int[xpixels];
			dMask[i] = new uint32_t[xpixels];
		}

		//Map
		int totalNumberOfBytes = 1040 * dynamicRange * 16 *2; //for both 1g and 10g
		int iPacket1 = 8;
		int iPacket2 = (totalNumberOfBytes/2) + 8;
		int iData1 = 0, iData2 = 0;
		int increment = (dynamicRange/8);
		int ic_increment = 1;
		if (dynamicRange == 4) {
			increment = 1;
			ic_increment = 2;
		}
		int iPort;


		if(top){
			for (int ir=0; ir<ypixels; ir++) {
				for (int ic=0; ic<xpixels; ic = ic + ic_increment) {
					iPort = ic / (xpixels/2);
					if(!iPort){
						dMap[ir][ic]  = iPacket1;
						iPacket1 += increment;
						iData1 += increment;
						//increment header
						if(iData1 >= actualDataSize){
							iPacket1 += 16;
							iData1 = 0;
						}
					}else{
						dMap[ir][ic]  = iPacket2;
						iPacket2 += increment;
						iData2 += increment;
						//increment header
						if(iData2 >= actualDataSize){
							iPacket2 += 16;
							iData2 = 0;
						}
					}
				}
			}
		}


		//bottom
		else{
			iData1 = 0; iData2 = 0;
			int numbytesperlineperport = 1024;
			if (dynamicRange == 8)
				numbytesperlineperport = 512;
			else if (dynamicRange == 4)
				numbytesperlineperport = 256;
			else if (dynamicRange == 32)
				numbytesperlineperport = 2048;



			iPacket1 = (totalNumberOfBytes/2) - numbytesperlineperport - 8;
			iPacket2 = totalNumberOfBytes - numbytesperlineperport - 8;
			if (dynamicRange == 32){
				iPacket1 -= 16;
				iPacket2 -= 16;
			}

			for (int ir=0; ir<ypixels; ir++) {
				for (int ic=0; ic<xpixels; ic = ic + ic_increment) {
					iPort = ic / (xpixels/2);
					if(!iPort){
						dMap[ir][ic]  = iPacket1;
						iPacket1 += increment;
						iData1 += increment;
						if(dynamicRange == 32){
							if(iData1 == numbytesperlineperport){
								iPacket1 -= (numbytesperlineperport*2 + 16*3);
								iData1 = 0;
							}
							if(iData1 == actualDataSize){
								iPacket1 += 16;
							}
						}else if((iData1 % numbytesperlineperport) == 0){
							iPacket1 -= (numbytesperlineperport*2);
							if(iData1 == actualDataSize){
								iPacket1 -= 16;
								iData1 = 0;
							}

						}
					}
					//other port
					else{
						dMap[ir][ic]  = iPacket2;
						iPacket2 += increment;
						iData2 += increment;
						if(dynamicRange == 32){
							if(iData2 == numbytesperlineperport){
								iPacket2 -= (numbytesperlineperport*2 + 16*3);
								iData2 = 0;
							}
							if(iData2 == actualDataSize){
								iPacket2 += 16;
							}
						}else if((iData2 % numbytesperlineperport) == 0){
							iPacket2 -= (numbytesperlineperport*2);
							if(iData2 == actualDataSize){
								iPacket2 -= 16;
								iData2 = 0;
							}
						}
					}
				}
			}
		}




		//Mask
		for(int ir=0; ir<ypixels; ++ir)
			for(int ic=0; ic<xpixels; ++ic)
				dMask[ir][ic] = 0x0;

		setDataMap(dMap);
		setDataMask(dMask);




	};






	/** Returns the frame number for the given dataset.
	     \param buff pointer to the dataset
	     \returns frame number
	 */
	int getFrameNumber(char *buff){
		return(*(unsigned int*)(((eiger_packet_header *)((char*)buff))->num1));
	};








	/** gets the packets number
     	 \param buff pointer to the memory
     	 \returns packet number
	 */
	int getPacketNumber(char *buff){
#ifdef VERY_DEBUG
		cprintf(RED, "\n0x%x - %d - %d",
				(*(uint8_t*)(((eiger_packet_header *)((char*)(buff)))->num3)),//port and dr
				(*(uint8_t*)(((eiger_packet_header *)((char*)(buff)))->num4)),//non 32 bit packet#
				(*(uint16_t*)(((eiger_packet_header *)((char*)(buff)))->num2)));//32 bit packet#
#endif

		//both ports have same packet numbers, so reconstruct
		//16 bit packet number written in num2 for 32 bit mode

		if(dynamicRange == 32){
			if((*(uint8_t*)(((eiger_packet_header *)((char*)buff))->num3)) & 0x1)
				return ((*(uint16_t*)(((eiger_packet_header *)((char*)buff))->num2))+(numberOfPackets/2) +1);
			else
				return ((*(uint16_t*)(((eiger_packet_header *)((char*)buff))->num2))+1);
		}
		else{
			if((*(uint8_t*)(((eiger_packet_header *)((char*)buff))->num3)) &0x1)
				return ((*(uint8_t*)(((eiger_packet_header *)((char*)buff))->num4))+(numberOfPackets/2) +1);
			else
				return ((*(uint8_t*)(((eiger_packet_header *)((char*)buff))->num4))+1);
		}
	};



	/** gets the dynamic range for offline processing
     	 \param buff pointer to the memory
     	 \returns dynamic range
	 */
	static int getDynamicRange(char *buff){
#ifdef VERY_DEBUG
		cprintf(RED, "\n0x%x",
				(*(uint8_t*)(((eiger_packet_header *)((char*)(buff)))->num3)));
#endif
		return (*(uint8_t*)(((eiger_packet_header *)((char*)buff))->num3))  >> 2;
	};



	/**
    returns the pixel value as double correcting for the output buffer crosstalk
     \param data pointer to the memory
     \param ix coordinate in the x direction
     \param iy coordinate in the y direction
     \returns channel value as double

	 */
	double getValue(char *data, int ix, int iy=0) {
		//  cout << "##" << (void*)data << " " << ix << " " <<iy << endl;
		if (xtalk==0)
			return getChannel(data, ix, iy, dynamicRange);
		else
			return getChannel(data, ix, iy,dynamicRange)-xtalk * getChannel(data, ix-1, iy,dynamicRange);
	};


	/**

	     Returns the value of the selected channel for the given dataset. Virtual function, can be overloaded.
	     \param data pointer to the dataset (including headers etc)
	     \param ix pixel number in the x direction
	     \param iy pixel number in the y direction
	     \param dr dynamic range
	     \returns data for the selected channel, with inversion if required

	 */

	virtual int getChannel(char *data, int ix, int iy, int dr) {
		uint32_t m=0, n = 0;
		uint64_t t;
		int numBytes,divFactor,pixelval;

		//cout <<"ix:"<<ix<<" nx:"<<nx<<" iy:"<<iy<<" ny:"<<ny<<" datamap[iy][ix]:"<< dataMap[iy][ix] <<" datasize:"<< dataSize <<endl;
		if (ix>=0 && ix<nx && iy>=0 && iy<ny && dataMap[iy][ix]>=0 && dataMap[iy][ix]<dataSize) {
			m=dataMask[iy][ix];

			numBytes = (nx * iy + ix);
			divFactor=2;
			if(dr == 4) divFactor = 16;
			else if (dr == 8) divFactor = 8;
			else if (dr == 16) divFactor = 4;

			pixelval = numBytes % divFactor;
			/*//big endian
			 newix = ix - pixelval;
			 */

		}else
			cprintf(RED,"outside limits\n");

		/*//big endian
		t = ((uint64_t)(*((uint64_t*)(((char*)data)+(dataMap[iy][newix])))));
		if(dr == 4)			return ((t >> (pixelval*4)) & 0xf)^m;
		else if(dr == 8)	return ((t >> (pixelval*8)) & 0xff)^m;
		else if(dr == 16)	return ((t >> (pixelval*16)) & 0xffff)^m;
		else				return ((t >> (pixelval*32)) & 0xffffffff)^m;
		 */

		//little endian
		n = ((uint32_t)(*((uint32_t*)(((char*)data)+(dataMap[iy][ix])))));
		if(dr == 4)			return (n & 0xf)^m;
		else if(dr == 8)	return (n & 0xff)^m;
		else if(dr == 16)	return (n & 0xffff)^m;
		else				return (n & 0xffffffff)^m;


	};


	/** sets the output buffer crosstalk correction parameter
      \param c output buffer crosstalk correction parameter to be set
      \returns current value for the output buffer crosstalk correction parameter

	 */
	double setXTalk(double c) {xtalk=c; return xtalk;}


	/** gets the output buffer crosstalk parameter
      \returns current value for the output buffer crosstalk correction parameter
	 */
	double getXTalk() {return xtalk;}







private:

	double xtalk; /**<output buffer crosstalk correction parameter */

	const static int xpixels = 1024;
	const static int ypixels = 256;
	const int bufferSize;
	const int actualDataSize;
	const int dynamicRange;
	const int numberOfPackets;
	bool top;


	/** structure of an eiger image header*/
	typedef struct
	{
		unsigned char num1[4];
		unsigned char num2[2];
		unsigned char num3[1];
		unsigned char num4[1];
	} eiger_packet_header;

};



#endif