codebase / stimlib

  #ifndef STIM_BIL_H
  #define STIM_BIL_H
  

  #include "../envi/envi_header.h"

  #include "../envi/binary.h"
  #include <cstring>
  #include <utility>
  

  namespace stim{

  /**
  	The BIL class represents a 3-dimensional binary file stored using band interleaved by line (BIL) image encoding. The binary file is stored
  	such that X-Z "frames" are stored sequentially to form an image stack along the y-axis. When accessing the data sequentially on disk,
  	the dimensions read, from fastest to slowest, are X, Z, Y.
  
  	This class is optimized for data streaming, and therefore supports extremely large (terabyte-scale) files. Data is loaded from disk
  	on request. Functions used to access data are written to support efficient reading.
  */
  

  template <typename T>
  
  class bil: public binary<T> {
  
  protected:
  	

  	std::vector<double> w;		//band wavelength

  
  public:
  
  	using binary<T>::open;
  	using binary<T>::file;

  	using binary<T>::R;

  	/// Open a data file for reading using the class interface.
  
  	/// @param filename is the name of the binary file on disk
  	/// @param X is the number of samples along dimension 1
  	/// @param Y is the number of samples (lines) along dimension 2
  	/// @param B is the number of samples (bands) along dimension 3
  	/// @param header_offset is the number of bytes (if any) in the binary header
  	/// @param wavelengths is an optional STL vector of size B specifying a numerical label for each band

  	bool open(std::string filename, unsigned int X, unsigned int Y, unsigned int B, unsigned int header_offset, std::vector<double> wavelengths){

  		w = wavelengths;

  		return open(filename, vec<unsigned int>(X, Y, B), header_offset);
  

  	}
  

  	/// Retrieve a single band (based on index) and stores it in pre-allocated memory.
  
  	/// @param p is a pointer to an allocated region of memory at least X * Y * sizeof(T) in size.
  	/// @param page <= B is the integer number of the band to be copied.

  	bool band_index( T * p, unsigned int page){
  

  		unsigned int L = R[0] * sizeof(T);		//caculate the number of bytes in a sample line
  		unsigned int jump = R[0] * (R[2] - 1) * sizeof(T);

  		if (page >= R[2]){										//make sure the bank number is right

  			std::cout<<"ERROR: page out of range"<<std::endl;
  			return false;
  		}
  

  		file.seekg(R[0] * page * sizeof(T), std::ios::beg);
  		for (unsigned i = 0; i < R[1]; i++)

  		{

  			file.read((char *)(p + i * R[0]), L);

  			file.seekg( jump, std::ios::cur);
  		}
  
  		return true;
  	}
  

  	/// Retrieve a single band (by numerical label) and stores it in pre-allocated memory.
  
  	/// @param p is a pointer to an allocated region of memory at least X * Y * sizeof(T) in size.
  	/// @param wavelength is a floating point value (usually a wavelength in spectral data) used as a label for the band to be copied.

  	bool band( T * p, double wavelength){

  		//if there are no wavelengths in the BSQ file
  		if(w.size() == 0)
  			return band_index(p, (unsigned int)wavelength);
  

  		unsigned int XY = R[0] * R[1];	//calculate the number of pixels in a band

  		unsigned int S = XY * sizeof(T);		//calculate the number of bytes of a band
  
  		unsigned page=0;                      //bands around the wavelength

  
  		//get the bands numbers around the wavelength
  
  		//if wavelength is smaller than the first one in header file

  		if ( w[page] > wavelength ){

  			band_index(p, page);
  			return true;
  		}
  

  		while( w[page] < wavelength )

  		{
  			page++;
  			//if wavelength is larger than the last wavelength in header file

  			if (page == R[2]) {
  				band_index(p, R[2]-1);

  				return true;
  			}
  		}

  		if ( wavelength < w[page] )

  		{

  			T * p1;
  			T * p2;

  			p1=(T*)malloc(S);                     //memory allocation
  			p2=(T*)malloc(S);
  			band_index(p1, page - 1);
  			band_index(p2, page );
  			for(unsigned i=0; i < XY; i++){

  				double r = (double) (wavelength - w[page-1]) / (double) (w[page] - w[page-1]);

  				p[i] = (p2[i] - p1[i]) * r + p1[i];
  			}

  			free(p1);
  			free(p2);

  		}
  		else                           //if the wavelength is equal to a wavelength in header file
  		{
  			band_index(p, page);
  		}
  
  		return true;
  	}
  
  	//get YZ line from the a Y slice, Y slice data should be already IN the MEMORY
  	bool getYZ(T* p, T* c, double wavelength)
  	{

  		unsigned int X = R[0];	//calculate the number of pixels in a sample
  		unsigned int B = R[2];

  		unsigned int L = X * sizeof(T);
  
  		unsigned page=0;                      //samples around the wavelength
  		T * p1;
  		T * p2;
  
  		//get the bands numbers around the wavelength
  
  		//if wavelength is smaller than the first one in header file

  		if ( w[page] > wavelength ){

  			memcpy(p, c, L);	
  			return true;
  		}
  

  		while( w[page] < wavelength )

  		{
  			page++;
  			//if wavelength is larger than the last wavelength in header file
  			if (page == B) {
  				memcpy(p, c + (B - 1) * X, L);
  				return true;
  			}
  		}

  		if ( wavelength < w[page] )

  		{
  			p1=(T*)malloc( L );                     //memory allocation
  			p2=(T*)malloc( L );
  
  			memcpy(p1, c + (page - 1) * X, L);
  			memcpy(p2, c + page * X, L);
  			
  			for(unsigned i=0; i < X; i++){

  				double r = (double) (wavelength - w[page-1]) / (double) (w[page] - w[page-1]);

  				p[i] = (p2[i] - p1[i]) * r + p1[i];
  			}
  		}
  		else                           //if the wavelength is equal to a wavelength in header file		
  			memcpy(p, c + page * X, L);
  		
  		return true;		
  	}
  

  	/// Retrieve a single spectrum (B-axis line) at a given (x, y) location and stores it in pre-allocated memory.
  
  	/// @param p is a pointer to pre-allocated memory at least B * sizeof(T) in size.
  	/// @param x is the x-coordinate (dimension 1) of the spectrum.
  	/// @param y is the y-coordinate (dimension 2) of the spectrum.

  	bool spectrum(T * p, unsigned x, unsigned y){

  		if ( x >= R[0] || y >= R[1]){							//make sure the sample and line number is right

  			std::cout<<"ERROR: sample or line out of range"<<std::endl;
  			exit(1);
  		}
  

  		unsigned jump = (R[0] - 1) * sizeof(T);

  		file.seekg((y * R[0] * R[2] + x) * sizeof(T), std::ios::beg);

  		for(unsigned i = 0; i < R[2]; i++)

  		{       
  			//point to the certain sample and line		

  			file.read((char *)(p + i), sizeof(T));
  			file.seekg(jump, std::ios::cur);  
  		}	
  
  		return true;	
  	}

  	/// Retrieve a single pixel and stores it in pre-allocated memory.
  
  	/// @param p is a pointer to pre-allocated memory at least sizeof(T) in size.
  	/// @param n is an integer index to the pixel using linear array indexing.

  	bool pixel(T * p, unsigned n){
  
  		//calculate the corresponding x, y
  		unsigned int x = n % R[0];
  		unsigned int y = n / R[0];
  
  		//get the pixel
  		return spectrum(p, x, y);
  	}

  	
  	//given a Y ,return a XZ slice
  	bool getY(T * p, unsigned y)
  	{

  		if ( y >= R[1]){							//make sure the line number is right

  			std::cout<<"ERROR: line out of range"<<std::endl;
  			exit(1);
  		}	
  		

  		file.seekg(y * R[2] * R[0] * sizeof(T), std::ios::beg);
  		file.read((char *)p, sizeof(T) * R[2] * R[0]);

  		
  		return true;
  		
  	}
  		

  	/// Perform baseline correction given a list of baseline points and stores the result in a new BSQ file.
  
  	/// @param outname is the name of the output file used to store the resulting baseline-corrected data.
  	/// @param wls is the list of baseline points based on band labels.

  	bool baseline(std::string outname, std::vector<double> wls){
  	
  		unsigned N = wls.size();			//get the number of baseline points
  		
  		std::ofstream target(outname.c_str(), std::ios::binary);	//open the target binary file
  		std::string headername = outname + ".hdr";              //the header file name		
  		
  		//simplify image resolution

  		unsigned int ZX = R[2] * R[0];		//calculate the number of points in a Y slice

  		unsigned int L = ZX * sizeof(T);			//calculate the number of bytes of a Y slice

  		unsigned int B = R[2];
  		unsigned int X = R[0];

  		
  		T* c;			//pointer to the current Y slice
  		c = (T*)malloc(L);  //memory allocation
  		
  		T* a;			//pointer to the two YZ lines surrounding the current YZ line
  		T* b;
  		
  		a = (T*)malloc(X * sizeof(T));
  		b = (T*)malloc(X * sizeof(T));
  
  
  		double ai, bi;	//stores the two baseline points wavelength surrounding the current band
  		double ci;		//stores the current band's wavelength

  		unsigned control;

  
  		if (a == NULL || b == NULL || c == NULL){
  			std::cout<<"ERROR: error allocating memory";
  			exit(1);
  		}
  	//	loop start	correct every y slice
  		

  		for (unsigned k =0; k < R[1]; k++)

  		{
  			//get the current y slice
  			getY(c, k);
  		
  			//initialize lownum, highnum, low, high		

  			ai = w[0];

  			control=0;

  			//if no baseline point is specified at band 0,
  			//set the baseline point at band 0 to 0

  			if(wls[0] != w[0]){

  				bi = wls[control];			
  				memset(a, (char)0, X * sizeof(T) );
  			}
  			//else get the low band
  			else{
  				control++;
  				getYZ(a, c, ai);
  				bi = wls[control];
  			}
  			//get the high band
  			getYZ(b, c, bi);
  		
  			//correct every YZ line
  			
  			for(unsigned cii = 0; cii < B; cii++){
  
  				//update baseline points, if necessary

  				if( w[cii] >= bi && cii != B - 1) {

  					//if the high band is now on the last BL point
  					if (control != N-1) {
  	
  						control++;		//increment the index
  	
  						std::swap(a, b);	//swap the baseline band pointers
  	
  						ai = bi;
  						bi = wls[control];
  						getYZ(b, c, bi);
  	
  					}
  					//if the last BL point on the last band of the file?

  					else if ( wls[control] < w[B - 1]) {

  	
  						std::swap(a, b);	//swap the baseline band pointers
  	
  						memset(b, (char)0, X * sizeof(T) );	//clear the high band
  	
  						ai = bi;

  						bi = w[B - 1];

  					}
  				}

  				ci = w[cii];

  				
  				unsigned jump = cii * X;
  				//perform the baseline correction
  				for(unsigned i=0; i < X; i++)
  				{
  					double r = (double) (ci - ai) / (double) (bi - ai);

  					c[i + jump] =(T) ( c[i + jump] - (b[i] - a[i]) * r - a[i] );

  				}
  				
  			}//loop for YZ line end  

  			target.write(reinterpret_cast<const char*>(c), L);   //write the corrected data into destination	

  		}//loop for Y slice end		

  		
  		free(a);
  		free(b);
  		free(c);
  		target.close();
  		return true;	
  		
  	}
  		

  	/// Normalize all spectra based on the value of a single band, storing the result in a new BSQ file.
  
  	/// @param outname is the name of the output file used to store the resulting baseline-corrected data.
  	///	@param w is the label specifying the band that the hyperspectral image will be normalized to.
  	///	@param t is a threshold specified such that a spectrum with a value at w less than t is set to zero. Setting this threshold allows the user to limit division by extremely small numbers.

  	bool normalize(std::string outname, double w, double t = 0.0)

  	{

  		unsigned int B = R[2];		//calculate the number of bands
  		unsigned int Y = R[1];
  		unsigned int X = R[0];
  		unsigned int ZX = R[2] * R[0];
  		unsigned int XY = R[0] * R[1];	//calculate the number of pixels in a band

  		unsigned int S = XY * sizeof(T);		//calculate the number of bytes in a band		
  		unsigned int L = ZX * sizeof(T);
  
  		std::ofstream target(outname.c_str(), std::ios::binary);	//open the target binary file
  		std::string headername = outname + ".hdr";              //the header file name
  
  		T * c;				//pointer to the current ZX slice
  		T * b;				//pointer to the standard band
  
  		b = (T*)malloc( S );     //memory allocation
  		c = (T*)malloc( L ); 
  

  		band(b, w);             //get the certain band into memory

  
  		for(unsigned j = 0; j < Y; j++)
  		{
  			getY(c, j);

  			for(unsigned i = 0; i < B; i++)

  			{

  				for(unsigned m = 0; m < X; m++)

  				{

  					if( b[m + j * X] < t )
  						c[m + i * X] = (T)0.0;
  					else
  						c[m + i * X] = c[m + i * X] / b[m + j * X];

  				}								
  			}
  			target.write(reinterpret_cast<const char*>(c), L);   //write normalized data into destination
  		}

  		
  		free(b);
  		free(c);
  		target.close();
  		return true;
  	}
  	

  	/// Convert the current BIL file to a BSQ file with the specified file name.
  
  	/// @param outname is the name of the output BSQ file to be saved to disk.

  	bool bsq(std::string outname)
  	{

  		unsigned int S = R[0] * R[1] * sizeof(T);		//calculate the number of bytes in a band

  		
  		std::ofstream target(outname.c_str(), std::ios::binary);
  		std::string headername = outname + ".hdr";
  		
  		T * p;			//pointer to the current band
  		p = (T*)malloc(S);
  		

  		for ( unsigned i = 0; i < R[2]; i++)

  		{			
  				band_index(p, i);
  				target.write(reinterpret_cast<const char*>(p), S);   //write a band data into target file	
  		}

  		free(p);
  		target.close();
  		return true;
  	}
  

  	/// Convert the current BIL file to a BIP file with the specified file name.
  
  	/// @param outname is the name of the output BIP file to be saved to disk.

  	bool bip(std::string outname)
  	{

  		unsigned int S = R[0] * R[2] * sizeof(T);		//calculate the number of bytes in a ZX slice

  		
  		std::ofstream target(outname.c_str(), std::ios::binary);
  		std::string headername = outname + ".hdr";
  		
  		T * p;			//pointer to the current XZ slice for bil file
  		p = (T*)malloc(S);
  		T * q;			//pointer to the current ZX slice for bip file
  		q = (T*)malloc(S);
  		

  		for ( unsigned i = 0; i < R[1]; i++)

  		{			
  			getY(p, i);

  			for ( unsigned k = 0; k < R[2]; k++)

  			{

  				unsigned ks = k * R[0];
  				for ( unsigned j = 0; j < R[0]; j++)
  					q[k + j * R[2]] = p[ks + j];

  			}
  			
  			target.write(reinterpret_cast<const char*>(q), S);   //write a band data into target file	
  		}
  

  		free(p);
  		free(q);
  		target.close();
  		return true;
  	}
  

  	/// Return a baseline corrected band given two adjacent baseline points and their bands. The result is stored in a pre-allocated array.
  
  	/// @param lb is the label value for the left baseline point
  	/// @param rb is the label value for the right baseline point
  	/// @param lp is a pointer to an array holding the band image for the left baseline point
  	/// @param rp is a pointer to an array holding the band image for the right baseline point
  	/// @param wavelength is the label value for the requested baseline-corrected band
  	/// @param result is a pointer to a pre-allocated array at least X * Y * sizeof(T) in size.

  	bool baseline_band(double lb, double rb, T* lp, T* rp, double wavelength, T* result){
  
  		unsigned XY = R[0] * R[1];
  		band(result, wavelength);		//get band
  
  		//perform the baseline correction
  		double r = (double) (wavelength - lb) / (double) (rb - lb);
  		for(unsigned i=0; i < XY; i++){
  			result[i] =(T) (result[i] - (rp[i] - lp[i]) * r - lp[i] );
  		}
  		return true;
  	}

  
  	/// Return a baseline corrected band given two adjacent baseline points. The result is stored in a pre-allocated array.
  
  	/// @param lb is the label value for the left baseline point
  	/// @param rb is the label value for the right baseline point
  	/// @param bandwavelength is the label value for the desired baseline-corrected band
  	/// @param result is a pointer to a pre-allocated array at least X * Y * sizeof(T) in size.

  	bool height(double lb, double rb, double bandwavelength, T* result){

  
  		T* lp;
  		T* rp;

  		unsigned XY = R[0] * R[1];
  		unsigned S = XY * sizeof(T);
  		lp = (T*) malloc(S);			//memory allocation
  		rp = (T*) malloc(S);

  		band(lp, lb);

  		band(rp, rb);		
  
  		baseline_band(lb, rb, lp, rp, bandwavelength, result);
  

  		free(lp);
  		free(rp);

  		return true;
  	}
  

  
  	/// Calculate the area under the spectrum between two specified points and stores the result in a pre-allocated array.
  
  	/// @param lb is the label value for the left baseline point
  	/// @param rb is the label value for the right baseline point
  	/// @param lab is the label value for the left bound (start of the integration)
  	/// @param rab is the label value for the right bound (end of the integration)
  	/// @param result is a pointer to a pre-allocated array at least X * Y * sizeof(T) in size

  	bool area(double lb, double rb, double lab, double rab, T* result){

  
  		T* lp;	//left band pointer
  		T* rp;	//right band pointer
  		T* cur;		//current band 1
  		T* cur2;	//current band 2

  
  		unsigned XY = R[0] * R[1];
  		unsigned S = XY * sizeof(T);
  
  		lp = (T*) malloc(S);			//memory allocation
  		rp = (T*) malloc(S);
  		cur = (T*) malloc(S);
  		cur2 = (T*) malloc(S);

  
  		memset(result, (char)0, S);
  
  		//find the wavelenght position in the whole band
  		unsigned int n = w.size();
  		unsigned int ai = 0;		//left bound position
  		unsigned int bi = n - 1;		//right bound position
  
  
  
  		//to make sure the left and the right bound are in the bandwidth
  		if (lb < w[0] || rb < w[0] || lb > w[n-1] || rb >w[n-1]){
  			std::cout<<"ERROR: left bound or right bound out of bandwidth"<<std::endl;
  			exit(1);
  		}
  		//to make sure rigth bound is bigger than left bound
  		else if(lb > rb){
  			std::cout<<"ERROR: right bound should be bigger than left bound"<<std::endl;
  			exit(1);
  		}
  
  		//get the position of lb and rb

  		while (lab >= w[ai]){

  			ai++;
  		}

  		while (rab <= w[bi]){

  			bi--;
  		}
  
  		band(lp, lb);
  		band(rp, rb);
  
  		//calculate the beginning and the ending part

  		baseline_band(lb, rb, lp, rp, rab, cur2);		//ending part
  		baseline_band(lb, rb, lp, rp, w[bi], cur);

  		for(unsigned j = 0; j < XY; j++){

  			result[j] += (rab - w[bi]) * (cur[j] + cur2[j]) / 2.0;

  		}

  		baseline_band(lb, rb, lp, rp, lab, cur2);		//beginnning part
  		baseline_band(lb, rb, lp, rp, w[ai], cur);

  		for(unsigned j = 0; j < XY; j++){	

  			result[j] += (w[ai] - lab) * (cur[j] + cur2[j]) / 2.0;

  		}

  		//calculate the area
  		ai++;
  		for(unsigned i = ai; i <= bi ;i++)
  		{
  			baseline_band(lb, rb, lp, rp, w[ai], cur2);
  			for(unsigned j = 0; j < XY; j++)
  			{
  				result[j] += (w[ai] - w[ai-1]) * (cur[j] + cur2[j]) / 2.0; 
  			}
  			std::swap(cur,cur2);		//swap the band pointers
  		}

  		free(lp);
  		free(rp);
  		free(cur);
  		free(cur2);

  		return true;
  	}
  

  	/// Compute the ratio of two baseline-corrected peaks. The result is stored in a pre-allocated array.
  
  	/// @param lb1 is the label value for the left baseline point for the first peak (numerator)
  	/// @param rb1 is the label value for the right baseline point for the first peak (numerator)
  	/// @param pos1 is the label value for the first peak (numerator) position
  	/// @param lb2 is the label value for the left baseline point for the second peak (denominator)
  	/// @param rb2 is the label value for the right baseline point for the second peak (denominator)
  	/// @param pos2 is the label value for the second peak (denominator) position
  	/// @param result is a pointer to a pre-allocated array at least X * Y * sizeof(T) in size

  	bool ph_to_ph(double lb1, double rb1, double pos1, double lb2, double rb2, double pos2, T * result){
  
  		T* p1 = (T*)malloc(R[0] * R[1] * sizeof(T));	
  		T* p2 = (T*)malloc(R[0] * R[1] * sizeof(T));	
  		
  		//get the two peak band
  		height(lb1, rb1, pos1, p1);
  		height(lb2, rb2, pos2, p2);
  		//calculate the ratio in result
  		for(unsigned i = 0; i < R[0] * R[1]; i++){
  			if(p1[i] == 0 && p2[i] ==0)
  				result[i] = 1;
  			else
  				result[i] = p1[i] / p2[i];
  		}

  
  		free(p1);
  		free(p2);

  		return true;	
  	}
  	

  	/// Compute the ratio between a peak area and peak height.
  
  	/// @param lb1 is the label value for the left baseline point for the first peak (numerator)
  	/// @param rb1 is the label value for the right baseline point for the first peak (numerator)
  	/// @param pos1 is the label value for the first peak (numerator) position
  	/// @param lb2 is the label value for the left baseline point for the second peak (denominator)
  	/// @param rb2 is the label value for the right baseline point for the second peak (denominator)
  	/// @param pos2 is the label value for the second peak (denominator) position
  	/// @param result is a pointer to a pre-allocated array at least X * Y * sizeof(T) in size