binary.h
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//make sure that this header file is only loaded once
#ifndef RTS_BINARY_H
#define RTS_BINARY_H
#include "../envi/envi_header.h"
#include "../math/vector.h"
#include <fstream>
#include <sys/stat.h>
namespace stim{
/** This class manages the streaming of large multidimensional binary files.
* Generally these are hyperspectral files with 2 spatial and 1 spectral dimension. However, this class supports
* other dimensions via the template parameter D.
*
* @param T is the data type used to store data to disk (generally float or double)
* @param D is the dimension of the data (default 3)
*/
template< typename T, unsigned int D = 3 >
class binary{
protected:
std::fstream file; //file stream used for reading and writing
std::string name; //file name
unsigned long long R[D]; //resolution
unsigned long long header; //header size (in bytes)
unsigned char* mask; //pointer to a character array: 0 = background, 1 = foreground (or valid data)
double progress; //stores the progress on the current operation (accessible using a thread)
/// Private initialization function used to set default parameters in the data structure.
void init(){
memset(R, 0, sizeof(unsigned long long) * D); //initialize the resolution to zero
header = 0; //initialize the header size to zero
mask = NULL;
progress = 0;
}
/// Private helper function that returns the size of the file on disk using system functions.
long long int get_file_size(){
#ifdef _WIN32
struct _stat64 results;
if(_stat64(name.c_str(), &results) == 0)
return results.st_size;
#else
struct stat results;
if(stat(name.c_str(), &results) == 0)
return results.st_size;
#endif
else return 0;
}
/// Private helper function that tests to make sure that the calculated data size specified by the structure is the same as the data size on disk.
bool test_file_size(){
long long int npts = 1; //initialize the number of data points to 1
for(unsigned int i = 0; i<D; i++) //iterate over each dimension
npts *= R[i]; //compute the total number of data points in the file
long long int datasize = npts * sizeof(T);//multiply the sum by the size of the template parameter
if(datasize + header == get_file_size()) return true; //if the byte size matches the file size, we're golden
else return false; //otherwise return an error
}
/// Private helper function that resets the file pointer to the beginning of the data
void reset(){
file.seekg(header, std::ios_base::beg);
}
/// Private helper file that opens a specified binary file.
/// @param filename is the name of the binary file to stream
bool open_file(std::string filename){
//open the file as binary for reading and writing
file.open(filename.c_str(), std::ios::in | std::ios::out | std::ios::binary);
//if the file isn't open, the user may only have read access
if(!file.is_open()){
std::cout<<"class STIM::BINARY - failed to open file, trying for read only"<<std::endl;
file.open(filename.c_str(), std::ios::in | std::ios::binary);
if(!file.is_open()){
std::cout<<" still unable to load the file"<<std::endl;
return false;
}
}
//if the file is successful
if(file){
name = filename; //set the name
if(test_file_size()) //test the file size
return true;
}
return false;
}
public:
double get_progress(){
return progress;
}
void reset_progress(){
progress = 0;
}
/// Open a binary file for streaming.
/// @param filename is the name of the binary file
/// @param r is a STIM vector specifying the size of the binary file along each dimension
/// @param h is the length (in bytes) of any header file (default zero)
bool open(std::string filename, vec<unsigned long long> r, unsigned long long h = 0){
for(unsigned long long i = 0; i < D; i++) //set the dimensions of the binary file object
R[i] = r[i];
header = h; //save the header size
if(!open_file(filename)) return false; //open the binary file
//reset();
return test_file_size();
}
/// Creates a new binary file for streaming
/// @param filename is the name of the binary file to be created
/// @param r is a STIM vector specifying the size of the file along each dimension
/// @offset specifies how many bytes to offset the file (used to leave room for a header)
bool create(std::string filename, vec<unsigned long long> r, unsigned long long offset = 0){
std::ofstream target(filename.c_str(), std::ios::binary);
//initialize binary file
T p = 0;
for(unsigned long long i =0; i < r[0] * r[1] * r[2]; i++){
target.write((char*)(&p), sizeof(T));
}
for(unsigned long long i = 0; i < D; i++) //set the dimensions of the binary file object
R[i] = r[i];
header = offset; //save the header size
if(!open_file(filename)) return false; //open the binary file
return test_file_size();
}
/// Writes a single page of data to disk. A page consists of a sequence of data of size R[0] * R[1] * ... * R[D-1].
/// @param p is a pointer to the data to be written
/// @param page is the page number (index of the highest-numbered dimension)
bool write_page( T * p, unsigned long long page){
if(p == NULL){
std::cout<<"ERROR: unable to write into file, empty pointer"<<std::endl;
exit(1);
}
file.seekg(R[1] * R[0] * page * sizeof(T) + header, std::ios::beg); //seek to the desired location on disk
file.write((char *)p, R[0] * R[1] * sizeof(T)); //write binary data
return true;
}
/// Reads a page from disk. A page consists of a sequence of data of size R[0] * R[1] * ... * R[D-1].
/// @param p is a pointer to pre-allocated memory equal to the page size
/// @param page is the index of the page
bool read_page( T * p, unsigned long long page, bool PROGRESS = false){
if(PROGRESS) progress = 0;
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[1] * R[0] * page * sizeof(T) + header, std::ios::beg); //write into memory from the binary file
file.read((char *)p, R[0] * R[1] * sizeof(T));
if(PROGRESS) progress = 100;
return true;
}
///Reads a line Z (slowest dimension) for a given XY value
/// @param p is a pointer to pre-allocated memory equal to the line size R[2]
/// @param x is the x coordinate
/// @param y is the y coordinate
bool read_line_2( T * p, unsigned long long x, unsigned long long y, bool PROGRESS = false){
unsigned long long i;
if(PROGRESS) progress = 0;
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;
return false;
}
file.seekg((x + y * R[0]) * sizeof(T), std::ios::beg); //point to the certain sample and line
for (i = 0; i < R[2]; i++)
{
file.read((char *)(p + i), sizeof(T));
file.seekg((R[1] * R[0] - 1) * sizeof(T), std::ios::cur); //go to the next band
if(PROGRESS) progress = (double)i / (double)R[2] * 100;
}
if(PROGRESS) progress = 100;
return true;
}
///Reads a line X (fastest dimension) for a given YZ value
/// @param p is a pointer to pre-allocated memory equal to the line size R[2]
/// @param x is the y coordinate
/// @param y is the z coordinate
bool read_line_0(T * p, unsigned long long y, unsigned long long z, bool PROGRESS = false){
//test to make sure the specified value is within range
if( y >= R[1] || z >= R[2] ){
std::cout<<"ERROR: sample or line out of range"<<std::endl;
return false;
}
file.seekg((z * R[0] * R[1] + y * R[0]) * sizeof(T), std::ios::beg); //seek to the start of the line
file.read((char *)p, sizeof(T) * R[0]); //read the line
if(PROGRESS) progress = 100;
return true;
}
///Reads a line Y (second fastest dimension) for a given XZ value
/// @param p is a pointer to pre-allocated memory equal to the line size R[2]
/// @param x is the y coordinate
/// @param z is the z coordinate
bool read_line_1(T * p, unsigned long long x, unsigned long long z, bool PROGRESS = false){
if(PROGRESS) progress = 0;
//test to make sure the specified value is within range
if( x >= R[0] || z >= R[2] ){
std::cout<<"ERROR: sample or line out of range"<<std::endl;
return false;
}
file.seekg((z * R[0] * R[1] + x) * sizeof(T), std::ios::beg); //seek to the start of the line
for (unsigned long long i = 0; i < R[1]; i++){ //for each pixel in the line
file.read((char *)(p + i), sizeof(T)); //read the pixel
file.seekg((R[0] - 1) * sizeof(T), std::ios::cur); //seek to the next pixel in the line
if(PROGRESS) progress = (double)i / (double)R[1] * 100;
}
if(PROGRESS) progress = 100;
return true;
}
/// Reads a plane given a coordinate along the 0-axis (YZ plane)
/// @param p is a pointer to pre-allocated memory of size R[1] * R[2] * sizeof(T)
/// @param n is the 0-axis coordinate used to retrieve the plane
bool read_plane_0(T* p, unsigned long long n, bool PROGRESS = false){
if(PROGRESS) progress = 0;
if (n >= R[0]){ //make sure the number is within the possible range
std::cout<<"ERROR read_plane_0: page out of range"<<std::endl;
return false;
}
unsigned long long jump = (R[0] - 1) * sizeof(T); //number of bytes to skip between samples
//seek to the start of the plane
file.seekg(n * sizeof(T), std::ios::beg);
unsigned long long N = R[1] * R[2];
for(unsigned long long i = 0; i<N; i++){
file.read((char*)(p+i), sizeof(T));
file.seekg(jump, std::ios::cur);
if(PROGRESS) progress = (double)(i+1) / N * 100;
}
if(PROGRESS) progress = 100;
return true;
}
/// Reads a plane given a coordinate along the 1-axis (XZ plane)
/// @param p is a pointer to pre-allocated memory of size R[0] * R[2] * sizeof(T)
/// @param n is the 1-axis coordinate used to retrieve the plane
bool read_plane_1(T* p, unsigned long long n, bool PROGRESS = false){
if(PROGRESS) progress = 0;
unsigned long long L = R[0] * sizeof(T); //caculate the number of bytes in a sample line
unsigned long long jump = R[0] * (R[1] - 1) * sizeof(T);
if (n >= R[1]){ //make sure the bank number is right
std::cout<<"ERROR read_plane_1: page out of range"<<std::endl;
return false;
}
file.seekg(R[0] * n * sizeof(T), std::ios::beg);
for (unsigned long long i = 0; i < R[2]; i++){
if(PROGRESS) progress = (double)i / R[2] * 100;
file.read((char *)(p + i * R[0]), L);
file.seekg( jump, std::ios::cur);
std::cout<<i<<" ";
}
if(PROGRESS) progress = 100;
return true;
}
/// Reads a plane given a coordinate along the 2-axis (XY plane)
/// @param p is a pointer to pre-allocated memory of size R[0] * R[1] * sizeof(T)
/// @param n is the 2-axis coordinate used to retrieve the plane
bool read_plane_2(T* p, unsigned long long n, bool PROGRESS = false){
return read_page(p, n, PROGRESS);
}
/// Reads a single pixel, treating the entire data set as a linear array
/// @param p is a pointer to pre-allocated memory of size sizeof(T)
/// @param i is the index to the pixel using linear indexing
bool read_pixel(T* p, unsigned long long i){
if(i >= R[0] * R[1] * R[2]){
std::cout<<"ERROR read_pixel: n is out of range"<<std::endl;
return false;
}
file.seekg(i * sizeof(T), std::ios::cur);
file.read((char*)p, sizeof(T));
}
/// Reads a single pixel, given an x, y, z coordinate
/// @param p is a pointer to pre-allocated memory of size sizeof(T)
/// @param x is the x (0) axis coordinate
/// @param y is the y (1) axis coordinate
/// @param z is the z (2) axis coordinate
bool read_pixel(T* p, unsigned long long x, unsigned long long y, unsigned long long z){
if(x < 0 || x >= R[0] || y < 0 || y >= R[1] || z < 0 || z > R[2]){
std::cout<<"ERROR read_pixel: (x,y,z) is out of range"<<std::endl;
return false;
}
unsigned long long i = z * R[0] * R[1] + y * R[0] + z;
return read_pixel(p, i);
}
};
}
#endif