#include #include #include #include #include #include const char * input_file; const char * output_file; const char * filter; double times; const char * axis; const char * direction; /* 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; for (y = 0; y < height; y++) { JSAMPROW row = row_pointers[y]; for (x = 0; x < width; x++) { JSAMPROW ptr = &(row[x * 3]); printf("Pixel at position [ %d - %d ] \ has the following RGB values: \ %d - %d - %d\n", x, y, ptr[0], ptr[1], ptr[2]); ptr[0] = 0; ptr[1] = ptr[2]; } } } void flip_x(){ int y; 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 flip_y(){ int x, y, c; for (y= 0 ; y < height; y++) { JSAMPROW row = row_pointers[y]; for (x = 0; x < width / 2; x++) { for (c = 0; c < num_components; c++) { JSAMPLE tmp = row[x * num_components + c]; row[x * num_components+c] = row[(width - 1 - x) * num_components+c]; row[(width - 1 - x) * num_components + c] = tmp; } } } } void rotate_right(){ int x, y, c; JDIMENSION new_width = height; JDIMENSION new_height = width; size_t new_rowbytes = new_width * num_components; JSAMPARRAY new_rows = (JSAMPARRAY) malloc(sizeof(j_common_ptr) * new_height); for (y = 0; y < new_height; y++){ new_rows[y] = (JSAMPROW) malloc(new_rowbytes); } for (y = 0; y < height; y++) { for (x = 0; x < width; x++) { for (c = 0; c < num_components; c++) { new_rows[x][(height - 1 -y)*num_components + c] = row_pointers[y][x * num_components + c]; } } } for (y = 0; y < height; y++){ free(row_pointers[y]); } free(row_pointers); row_pointers = new_rows; width = new_width; height = new_height; } void rotate_left(){ int x, y, c; JDIMENSION new_width = height; JDIMENSION new_height = width; size_t new_rowbytes = new_width * num_components; JSAMPARRAY new_rows = (JSAMPARRAY) malloc(sizeof(j_common_ptr) * new_height); for (y = 0; y < new_height; y++){ new_rows[y] = (JSAMPROW) malloc(new_rowbytes); } for (y = 0; y < height; y++) { for (x = 0; x < width; x++) { for (c = 0; c < num_components; c++) { new_rows[width - 1 - x][y * num_components + c] = row_pointers[y][x * num_components + c]; } } } 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 ){ if(strcmp(axis, "x") == 0){ flip_x(); } else if(strcmp(axis, "y") == 0){ flip_y(); } } else if(strcmp(filter, "rotate") == 0){ if(strcmp(direction, "left") == 0){ rotate_left(); } else if(strcmp(direction, "right") == 0){ rotate_right(); } } } 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 JPEG File"); struct arg_file *output_file_arg = arg_file1("o", "out-file" , "", "Output JPEG File"); struct arg_str *filter_arg = arg_str1("f", "filter" , "", "Filter"); struct arg_dbl *times_arg = arg_dbl0("t", "times" , "", "Multiplyer"); struct arg_str *axis_arg = arg_str0("a", "axis" , "", "Axis"); struct arg_str *direction_arg = arg_str0("d", "direction" , "", "Direction"); 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, times_arg, axis_arg, direction_arg, help, end}; if (arg_nullcheck(argtable) != 0) printf("error: insufficient memory\n"); times_arg->dval[0] = 1; 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]; times = times_arg->dval[0]; if (axis_arg->count > 0){ axis = axis_arg->sval[0]; } if (direction_arg->count > 0){ direction = direction_arg->sval[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; }