#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>

#include <jpeglib.h>
#include <argtable2.h>
#include <string.h>

const char * input_file;
const char * output_file;
const char * filter;
const char * axis;
const char * direction;
double times;



/* we will be using this uninitialized pointer later to store raw, uncompressd image */
JSAMPARRAY row_pointers = NULL;


/* dimensions of the image we want to write */
JDIMENSION width;
JDIMENSION height;
int num_components;
int quality = 75;
J_COLOR_SPACE color_space;

void flip(){
  int x, y;
  if (color_space != JCS_RGB)  return;
  
  if (strcmp(axis,"y") == 0){

	  for (y=0; y<height; y++) {
		JSAMPROW row = row_pointers[y];
		for (x=0; x<width/2; x++) {
		  JSAMPROW ptr1 = &(row[x*3]);
		  JSAMPROW ptr2 = &(row[(width-1-x)*3]);
		  
		  JSAMPLE tmp;
		  tmp = ptr1[0];ptr1[0] = ptr2[0]; ptr2[0] = tmp;
		  tmp = ptr1[1];ptr1[1] = ptr2[1]; ptr2[1] = tmp;
		  tmp = ptr1[2];ptr1[2] = ptr2[2]; ptr2[2] = tmp;
		  
		  
		}
	  }
  }
  else if(strcmp(axis, "x") == 0){

      for(y=0; y<height/2; y++){

          JSAMPROW tmp = row_pointers[y];

          row_pointers[y] = row_pointers[height-1-y];

          row_pointers[height-1-y] = tmp;
      }
  }
} 
void rotate(){

    int x, y;

    if (color_space != JCS_RGB) return;

    JDIMENSION new_width = height;
    JDIMENSION new_height = width;

    JSAMPARRAY new_rows;

    new_rows = (JSAMPARRAY) malloc(sizeof(JSAMPROW) * new_height);

    for(y=0; y<new_height; y++){
        new_rows[y] = (JSAMPROW) malloc(new_width * 3);
    }

    // obrót w prawo
    if(strcmp(direction, "right") == 0){

        for(y=0; y<height; y++){

            for(x=0; x<width; x++){

                JSAMPROW src = row_pointers[y];
                JSAMPROW dst = new_rows[x];

                int new_x = height - 1 - y;

                dst[new_x*3 + 0] = src[x*3 + 0];
                dst[new_x*3 + 1] = src[x*3 + 1];
                dst[new_x*3 + 2] = src[x*3 + 2];
            }
        }
    }

    // obrót w lewo
    else if(strcmp(direction, "left") == 0){

        for(y=0; y<height; y++){

            for(x=0; x<width; x++){

                JSAMPROW src = row_pointers[y];

                int new_y = width - 1 - x;

                JSAMPROW dst = new_rows[new_y];

                dst[y*3 + 0] = src[x*3 + 0];
                dst[y*3 + 1] = src[x*3 + 1];
                dst[y*3 + 2] = src[x*3 + 2];
            }
        }
    }

    for(y=0; y<height; y++){
        free(row_pointers[y]);
    }

    free(row_pointers);

    row_pointers = new_rows;

    width = new_width;
    height = new_height;
}   


void process_file(){

    if(strcmp(filter, "flip") == 0){
        flip();
    }

    else if(strcmp(filter, "rotate") == 0){
        rotate();
    }
}




void abort_(const char * s, ...)
{
	va_list args;
	va_start(args, s);
	vfprintf(stderr, s, args);
	fprintf(stderr, "\n");
	va_end(args);
	abort();
}


/**
 * read_jpeg_file Reads from a jpeg file on disk specified by filename and saves into the 
 * raw_image buffer in an uncompressed format.
 * 
 * \returns positive integer if successful, -1 otherwise
 * \param *filename char string specifying the file name to read from
 *
 */

void read_jpeg_file( const char *filename )
{
	/* these are standard libjpeg structures for reading(decompression) */
	struct jpeg_decompress_struct cinfo;
	struct jpeg_error_mgr jerr;
	/* libjpeg data structure for storing one row, that is, scanline of an image */
	int y;
	
	FILE *infile = fopen( filename, "rb" );
	
	if ( !infile )
	{
		abort_("Error opening input jpeg file %s!\n", filename);
	}
	/* here we set up the standard libjpeg error handler */
	cinfo.err = jpeg_std_error( &jerr );
	jpeg_create_decompress( &cinfo );
	/* this makes the library read from infile */
	jpeg_stdio_src( &cinfo, infile );
	/* reading the image header which contains image information */
	jpeg_read_header( &cinfo, TRUE );


	/* Start decompression jpeg here */
	jpeg_start_decompress( &cinfo );
	width = cinfo.output_width;
	height = cinfo.output_height;
	num_components = cinfo.out_color_components;
	color_space = cinfo.out_color_space;
	
	/* allocate memory to hold the uncompressed image */
	size_t rowbytes = width * num_components;
	row_pointers = (JSAMPARRAY) malloc(sizeof(j_common_ptr) * height);
	for (y=0; y<height; y++){
		row_pointers[y] = (JSAMPROW) malloc(rowbytes);
	}

	
	/* read one scan line at a time */
	y=0;
	JSAMPARRAY tmp = row_pointers;
	while( cinfo.output_scanline < cinfo.image_height )
	{
		y = jpeg_read_scanlines( &cinfo, tmp, 1 );
		tmp +=y;
	}
	/* wrap up decompression, destroy objects, free pointers and close open files */
	jpeg_finish_decompress( &cinfo );
	jpeg_destroy_decompress( &cinfo );
// 	free( row_pointer[0] );
	fclose( infile );
	/* yup, we succeeded! */
}




/**
 * write_jpeg_file Writes the raw image data stored in the raw_image buffer
 * to a jpeg image with default compression and smoothing options in the file
 * specified by *filename.
 *
 * \returns positive integer if successful, -1 otherwise
 * \param *filename char string specifying the file name to save to
 *
 */
void write_jpeg_file( const char *filename )
{
	struct jpeg_compress_struct cinfo;
	struct jpeg_error_mgr jerr;
	int y;
	JSAMPARRAY tmp;

	
	/* this is a pointer to one row of image data */
	FILE *outfile = fopen( filename, "wb" );
	
	if ( !outfile )	{
		abort_("Error opening output jpeg file %s!\n", filename );
	}
	cinfo.err = jpeg_std_error( &jerr );
	jpeg_create_compress(&cinfo);
	jpeg_stdio_dest(&cinfo, outfile);

	/* Setting the parameters of the output file here */
	cinfo.image_width = width;	
	cinfo.image_height = height;
	cinfo.input_components = num_components;
	cinfo.in_color_space = color_space;
    /* default compression parameters, we shouldn't be worried about these */
	jpeg_set_defaults( &cinfo );
	jpeg_set_quality (&cinfo, quality, TRUE);
	/* Now do the compression .. */
	jpeg_start_compress( &cinfo, TRUE );
	/* like reading a file, this time write one row at a time */
	tmp = row_pointers;
	while( cinfo.next_scanline < cinfo.image_height )
	{
		y = jpeg_write_scanlines( &cinfo, tmp, 1 );
		tmp +=y;
	}
	/* similar to read file, clean up after we're done compressing */
	jpeg_finish_compress( &cinfo );
	jpeg_destroy_compress( &cinfo );
	fclose( outfile );
	
        /* cleanup heap allocation */
	for (y=0; y<height; y++){
		free(row_pointers[y]);
	}
	free(row_pointers);
}




int main(int argc, char **argv){   
  // Options
  struct arg_file *input_file_arg = arg_file1("i", "in-file", "<input>", "Input JPEG File");
  struct arg_file *output_file_arg = arg_file1("o", "out-file" , "<output>", "Output JPEG File");
  struct arg_str *filter_arg = arg_str1("f", "filter" , "<filter>", "Filter");
  struct arg_str *axis_arg = arg_str0("a", "axis" , "<axis>", "Flip axis");
  struct arg_str *direction_arg = arg_str0("d", "direction" , "<direction>", "Rotate direction");
  struct arg_dbl *times_arg = arg_dbl0("t", "times" , "<times>", "Multiplyer");
  struct arg_lit *help = arg_lit0("h","help", "print this help and exit");
  struct arg_end *end = arg_end(10); // maksymalna liczba błędów 10
  
  int nerrors;
  
  void *argtable[] = {
    input_file_arg,
    output_file_arg,
    filter_arg,
    axis_arg,
    direction_arg,
    times_arg,
    help,
    end
};
  
  if (arg_nullcheck(argtable) != 0) printf("error: insufficient memory\n");
  
  times_arg->dval[0] = 1;
  axis_arg->sval[0] = "y";
  direction_arg->sval[0] = "right";
  
  nerrors = arg_parse(argc, argv, argtable);
  
  if (help->count > 0){
     printf("Usage: geometry");
     arg_print_syntax(stdout, argtable,"\n");
     arg_print_glossary(stdout, argtable,"  %-25s %s\n");
     arg_freetable(argtable, sizeof(argtable)/sizeof(argtable[0]));
     return 0;
  }

  if (nerrors==0){
     input_file = input_file_arg->filename[0];
     output_file = output_file_arg->filename[0];
     filter = filter_arg->sval[0];
     axis = axis_arg->sval[0];
	 direction = direction_arg->sval[0];
     times = times_arg->dval[0];
  }
  else{
     arg_print_errors(stderr, end, "point");
     arg_print_glossary(stderr, argtable, " %-25s %s\n");
     arg_freetable(argtable, sizeof(argtable)/sizeof(argtable[0]));
     return 1;
  }

   read_jpeg_file(input_file);
   process_file();
   write_jpeg_file(output_file);
   arg_freetable(argtable, sizeof(argtable)/sizeof(argtable[0]));
   return 0;
}