585 lines
21 KiB
Text
585 lines
21 KiB
Text
//----------------------------------------------------------------------
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// File: ann2fig.cpp
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// Programmer: David Mount
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// Last modified: 05/03/05
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// Description: convert ann dump file to fig file
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//----------------------------------------------------------------------
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// Copyright (c) 1997-2005 University of Maryland and Sunil Arya and
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// David Mount. All Rights Reserved.
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//
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// This software and related documentation is part of the Approximate
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// Nearest Neighbor Library (ANN). This software is provided under
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// the provisions of the Lesser GNU Public License (LGPL). See the
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// file ../ReadMe.txt for further information.
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//
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// The University of Maryland (U.M.) and the authors make no
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// representations about the suitability or fitness of this software for
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// any purpose. It is provided "as is" without express or implied
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// warranty.
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//----------------------------------------------------------------------
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// History:
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// Revision 0.1 03/04/98
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// Initial release
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// Revision 1.0 04/01/05
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// Changed dump file suffix from .ann to .dmp.
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// Revision 1.1 05/03/05
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// Fixed usage output string.
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//----------------------------------------------------------------------
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// This program inputs an ann dump file of a search structure
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// perhaps along with point coordinates, and outputs a fig (Ver 3.1)
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// file (see fig2dev (1)) displaying the tree. The fig file may
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// then be displayed using xfig, or converted to any of a number of
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// other formats using fig2dev.
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//
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// If the dimension is 2 then the entire tree is display. If the
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// dimension is larger than 2 then the user has the option of
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// selecting which two dimensions will be displayed, and the slice
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// value for each of the remaining dimensions. All leaf cells
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// intersecting the slice are shown along with the points in these
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// cells. See the procedure getArgs() below for the command-line
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// arguments.
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//----------------------------------------------------------------------
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#include <cstdio> // C standard I/O
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#include <fstream> // file I/O
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#include <string> // string manipulation
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#include <ANN/ANNx.h> // all ANN includes
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using namespace std; // make std:: accessible
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//----------------------------------------------------------------------
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// Globals and their defaults
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//----------------------------------------------------------------------
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const int STRING_LEN = 500; // string lengths
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const int MAX_DIM = 1000; // maximum dimension
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const double DEF_SLICE_VAL = 0; // default slice value
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const char FIG_HEAD[] = {"#FIG 3.1"}; // fig file header
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const char DUMP_SUFFIX[] = {".dmp"}; // suffix for dump file
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const char FIG_SUFFIX[] = {".fig"}; // suffix for fig file
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char file_name[STRING_LEN]; // (root) file name (say xxx)
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char infile_name[STRING_LEN];// input file name (xxx.dmp)
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char outfile_name[STRING_LEN];// output file name (xxx.fig)
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char caption[STRING_LEN]; // caption line (= command line)
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ofstream ofile; // output file stream
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ifstream ifile; // input file stream
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int dim_x = 0; // horizontal dimension
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int dim_y = 1; // vertical dimension
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double slice_val[MAX_DIM]; // array of slice values
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double u_per_in = 1200; // fig units per inch (version 3.1)
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double in_size = 5; // size of figure (in inches)
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double in_low_x = 1; // fig upper left corner (in inches)
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double in_low_y = 1; // fig upper left corner (in inches)
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double u_size = 6000; // size of figure (in units)
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double u_low_x = 1200; // fig upper left corner (in units)
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double u_low_y = 1200; // fig upper left corner (in units)
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int pt_size = 10; // point size (in fig units)
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int dim; // dimension
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int n_pts; // number of points
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ANNpointArray pts = NULL; // point array
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double scale; // scale factor for transformation
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double offset_x; // offsets for transformation
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double offset_y;
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// transformations
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#define TRANS_X(p) (offset_x + scale*(p[dim_x]))
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#define TRANS_Y(p) (offset_y - scale*(p[dim_y]))
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//----------------------------------------------------------------------
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// Error handler
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//----------------------------------------------------------------------
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void Error(char *msg, ANNerr level)
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{
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if (level == ANNabort) {
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cerr << "ann2fig: ERROR------->" << msg << "<-------------ERROR\n";
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exit(1);
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}
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else {
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cerr << "ann2fig: WARNING----->" << msg << "<-------------WARNING\n";
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}
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}
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//----------------------------------------------------------------------
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// set_slice_val - set all slice values to given value
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//----------------------------------------------------------------------
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void set_slice_val(double val)
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{
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for (int i = 0; i < MAX_DIM; i++) {
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slice_val[i] = val;
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}
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}
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//----------------------------------------------------------------------
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// getArgs - get input arguments
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//
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// Syntax:
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// ann2fig [-upi scale] [-x low_x] [-y low_y]
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// [-sz size] [-dx dim_x] [-dy dim_y] [-sl dim value]*
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// [-ps pointsize]
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// file
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//
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// where:
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// -upi scale fig units per inch (default = 1200)
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// -x low_x x and y offset of upper left corner (inches)
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// -y low_y ...(default = 1)
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// -sz size maximum side length of figure (in inches)
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// ...(default = 5)
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// -dx dim_x horizontal dimension (default = 0)
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// -dy dim_y vertical dimension (default = 1)
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// -sv value default slice value (default = 0)
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// -sl dim value each such pair defines the value along the
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// ...given dimension at which to slice. This
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// ...may be supplied for all dimensions except
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// ...dim_x and dim_y.
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// -ps pointsize size of points in fig units (def = 10)
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// file file (input=file.dmp, output=file.fig)
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//
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//----------------------------------------------------------------------
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void getArgs(int argc, char **argv)
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{
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int i;
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int sl_dim; // temp slice dimension
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double sl_val; // temp slice value
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set_slice_val(DEF_SLICE_VAL); // set initial slice-values
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if (argc <= 1) {
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cerr << "Syntax:\n\
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ann2fig [-upi scale] [-x low_x] [-y low_y]\n\
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[-sz size] [-dx dim_x] [-dy dim_y] [-sl dim value]*\n\
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file\n\
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\n\
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where:\n\
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-upi scale fig units per inch (default = 1200)\n\
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-x low_x x and y offset of upper left corner (inches)\n\
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-y low_y ...(default = 1)\n\
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-sz size maximum side length of figure (in inches)\n\
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...(default = 5)\n\
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-dx dim_x horizontal dimension (default = 0)\n\
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-dy dim_y vertical dimension (default = 1)\n\
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-sv value default slice value (default = 0)\n\
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-sl dim value each such pair defines the value along the\n\
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...given dimension at which to slice. This\n\
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...may be supplied for each dimension except\n\
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...dim_x and dim_y.\n\
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-ps pointsize size of points in fig units (def = 10)\n\
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file file (input=file.dmp, output=file.fig)\n";
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exit(0);
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}
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ANNbool fileSeen = ANNfalse; // file argument seen?
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for (i = 1; i < argc; i++) {
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if (!strcmp(argv[i], "-upi")) { // process -upi option
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sscanf(argv[++i], "%lf", &u_per_in);
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}
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else if (!strcmp(argv[i], "-x")) { // process -x option
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sscanf(argv[++i], "%lf", &in_low_x);
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}
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else if (!strcmp(argv[i], "-y")) { // process -y option
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sscanf(argv[++i], "%lf", &in_low_y);
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}
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else if (!strcmp(argv[i], "-sz")) { // process -sz option
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sscanf(argv[++i], "%lf", &in_size);
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}
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else if (!strcmp(argv[i], "-dx")) { // process -dx option
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sscanf(argv[++i], "%d", &dim_x);
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}
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else if (!strcmp(argv[i], "-dy")) { // process -dy option
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sscanf(argv[++i], "%d", &dim_y);
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}
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else if (!strcmp(argv[i], "-sv")) { // process -sv option
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sscanf(argv[++i], "%lf", &sl_val);
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set_slice_val(sl_val); // set slice values
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}
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else if (!strcmp(argv[i], "-sl")) { // process -sl option
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sscanf(argv[++i], "%d", &sl_dim);
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if (sl_dim < 0 || sl_dim >= MAX_DIM) {
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Error("Slice dimension out of bounds", ANNabort);
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}
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sscanf(argv[++i], "%lf", &slice_val[sl_dim]);
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}
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if (!strcmp(argv[i], "-ps")) { // process -ps option
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sscanf(argv[++i], "%i", &pt_size);
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}
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else { // must be file name
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fileSeen = ANNtrue;
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sscanf(argv[i], "%s", file_name);
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strcpy(infile_name, file_name); // copy to input file name
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strcat(infile_name, DUMP_SUFFIX);
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strcpy(outfile_name, file_name); // copy to output file name
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strcat(outfile_name, FIG_SUFFIX);
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}
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}
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if (!fileSeen) { // no file seen
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Error("File argument is required", ANNabort);
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}
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ifile.open(infile_name, ios::in); // open for reading
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if (!ifile) {
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Error("Cannot open input file", ANNabort);
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}
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ofile.open(outfile_name, ios::out); // open for writing
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if (!ofile) {
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Error("Cannot open output file", ANNabort);
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}
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u_low_x = u_per_in * in_low_x; // convert inches to fig units
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u_low_y = u_per_in * in_low_y;
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u_size = u_per_in * in_size;
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strcpy(caption, argv[0]); // copy command line to caption
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for (i = 1; i < argc; i++) {
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strcat(caption, " ");
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strcat(caption, argv[i]);
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}
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}
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//----------------------------------------------------------------------
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// Graphics utilities for fig output
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//
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// writeHeader write header for fig file
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// writePoint write a point
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// writeBox write a box
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// writeLine write a line
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//----------------------------------------------------------------------
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void writeHeader()
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{
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ofile << FIG_HEAD << "\n" // fig file header
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<< "Portrait\n"
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<< "Center\n"
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<< "Inches\n"
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<< (int) u_per_in << " 2\n";
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}
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void writePoint(ANNpoint p) // write a single point
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{
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// filled black point object
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ofile << "1 3 0 1 -1 7 0 0 0 0.000 1 0.0000 ";
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int cent_x = (int) TRANS_X(p); // transform center coords
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int cent_y = (int) TRANS_Y(p);
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ofile << cent_x << " " << cent_y << " " // write center, radius, bounds
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<< pt_size << " " << pt_size << " "
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<< cent_x << " " << cent_y << " "
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<< cent_x + pt_size << " " << cent_y + pt_size << "\n";
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}
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void writeBox(const ANNorthRect &r) // write box
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{
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// unfilled box object
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ofile << "2 2 0 1 -1 7 0 0 -1 0.000 0 0 -1 0 0 5\n";
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int p0_x = (int) TRANS_X(r.lo); // transform endpoints
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int p0_y = (int) TRANS_Y(r.lo);
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int p1_x = (int) TRANS_X(r.hi);
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int p1_y = (int) TRANS_Y(r.hi);
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ofile << "\t"
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<< p0_x << " " << p0_y << " " // write vertices
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<< p1_x << " " << p0_y << " "
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<< p1_x << " " << p1_y << " "
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<< p0_x << " " << p1_y << " "
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<< p0_x << " " << p0_y << "\n";
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}
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void writeLine(ANNpoint p0, ANNpoint p1) // write line
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{
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// unfilled line object
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ofile << "2 1 0 1 -1 7 0 0 -1 0.000 0 0 -1 0 0 2\n";
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int p0_x = (int) TRANS_X(p0); // transform endpoints
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int p0_y = (int) TRANS_Y(p0);
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int p1_x = (int) TRANS_X(p1);
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int p1_y = (int) TRANS_Y(p1);
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ofile << "\t"
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<< p0_x << " " << p0_y << " " // write vertices
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<< p1_x << " " << p1_y << "\n";
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}
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void writeCaption( // write caption text
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const ANNorthRect &bnd_box, // bounding box
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char *caption) // caption
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{
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if (!strcmp(caption, "\0")) return; // null string?
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int px = (int) TRANS_X(bnd_box.lo); // put .5 in. lower left
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int py = (int) (TRANS_Y(bnd_box.lo) + 0.50 * u_per_in);
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ofile << "4 0 -1 0 0 0 20 0.0000 4 255 2000 ";
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ofile << px << " " << py << " " << caption << "\\001\n";
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}
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//----------------------------------------------------------------------
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// overlap - test whether a box overlap slicing region
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//
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// The slicing region is a 2-dimensional plane in space
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// which contains points (x1, x2, ..., xn) satisfying the
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// n-2 linear equalities:
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//
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// xi == slice_val[i] for i != dim_x, dim_y
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//
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// This procedure returns true of the box defined by
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// corner points box.lo and box.hi overlap this plane.
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//----------------------------------------------------------------------
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ANNbool overlap(const ANNorthRect &box)
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{
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for (int i = 0; i < dim; i++) {
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if (i != dim_x && i != dim_y &&
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(box.lo[i] > slice_val[i] || box.hi[i] < slice_val[i]))
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return ANNfalse;
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}
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return ANNtrue;
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}
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//----------------------------------------------------------------------
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// readTree, recReadTree - inputs tree and outputs figure
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//
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// readTree procedure initializes things and then calls recReadTree
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// which does all the work.
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//
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// recReadTree reads in a node of the tree, makes any recursive
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// calls as needed to input the children of this node (if internal)
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// and maintains the bounding box. Note that the bounding box
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// is modified within this procedure, but it is the responsibility
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// of the procedure that it be restored to its original value
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// on return.
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//
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// Recall that these are the formats. The tree is given in
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// preorder.
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//
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// Leaf node:
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// leaf <n_pts> <bkt[0]> <bkt[1]> ... <bkt[n-1]>
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// Splitting nodes:
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// split <cut_dim> <cut_val> <lo_bound> <hi_bound>
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// Shrinking nodes:
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// shrink <n_bnds>
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// <cut_dim> <cut_val> <side>
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// <cut_dim> <cut_val> <side>
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// ... (repeated n_bnds times)
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//
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// On reading a leaf we determine whether we should output the
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// cell's points (if dimension = 2 or this cell overlaps the
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// slicing region). For splitting nodes we check whether the
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// current cell overlaps the slicing plane and whether the
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// cutting dimension coincides with either the x or y drawing
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// dimensions. If so, we output the corresponding splitting
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// segment.
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//----------------------------------------------------------------------
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void recReadTree(ANNorthRect &box)
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{
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char tag[STRING_LEN]; // tag (leaf, split, shrink)
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int n_pts; // number of points in leaf
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int idx; // point index
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int cd; // cut dimension
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ANNcoord cv; // cut value
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ANNcoord lb; // low bound
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ANNcoord hb; // high bound
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int n_bnds; // number of bounding sides
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int sd; // which side
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ifile >> tag; // input node tag
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if (strcmp(tag, "leaf") == 0) { // leaf node
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ifile >> n_pts; // input number of points
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// check for overlap
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if (dim == 2 || overlap(box)) {
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for (int i = 0; i < n_pts; i++) { // yes, write the points
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ifile >> idx;
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writePoint(pts[idx]);
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}
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}
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else { // input but ignore points
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for (int i = 0; i < n_pts; i++) {
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ifile >> idx;
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}
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}
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}
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else if (strcmp(tag, "split") == 0) { // splitting node
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ifile >> cd >> cv >> lb >> hb;
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if (lb != box.lo[cd] || hb != box.hi[cd]) {
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Error("Bounding box coordinates are fishy", ANNwarn);
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}
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ANNcoord lv = box.lo[cd]; // save bounds for cutting dim
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ANNcoord hv = box.hi[cd];
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//--------------------------------------------------------------
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// The following code is rather fragile so modify at your
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// own risk. We first decrease the high-end of the bounding
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// box down to the cutting plane and then read the left subtree.
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// Then we increase the low-end of the bounding box up to the
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// cutting plane (thus collapsing the bounding box to a d-1
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// dimensional hyperrectangle). Then we draw the projection of
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// its diagonal if it crosses the slicing plane. This will have
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// the effect of drawing its intersection on the slicing plane.
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// Then we restore the high-end of the bounding box and read
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// the right subtree. Finally we restore the low-end of the
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// bounding box, before returning.
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//--------------------------------------------------------------
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box.hi[cd] = cv; // decrease high bounds
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recReadTree(box); // read left subtree
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// check for overlap
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box.lo[cd] = cv; // increase low bounds
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if (dim == 2 || overlap(box)) { // check for overlap
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if (cd == dim_x || cd == dim_y) { // cut through slice plane
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writeLine(box.lo, box.hi); // draw cutting line
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}
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}
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box.hi[cd] = hv; // restore high bounds
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recReadTree(box); // read right subtree
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box.lo[cd] = lv; // restore low bounds
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}
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else if (strcmp(tag, "shrink") == 0) { // splitting node
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ANNorthRect inner(dim, box); // copy bounding box
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ifile >> n_bnds; // number of bounding sides
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for (int i = 0; i < n_bnds; i++) {
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ifile >> cd >> cv >> sd; // input bounding halfspace
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ANNorthHalfSpace hs(cd, cv, sd); // create orthogonal halfspace
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hs.project(inner.lo); // intersect by projecting
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hs.project(inner.hi);
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}
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if (dim == 2 || overlap(inner)) {
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writeBox(inner); // draw inner rectangle
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}
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recReadTree(inner); // read inner subtree
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recReadTree(box); // read outer subtree
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}
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else {
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Error("Illegal node type in dump file", ANNabort);
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}
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}
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void readTree(ANNorthRect &bnd_box)
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{
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writeHeader(); // output header
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writeBox(bnd_box); // draw bounding box
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writeCaption(bnd_box, caption); // write caption
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recReadTree(bnd_box); // do it
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}
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//----------------------------------------------------------------------
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// readANN - read the ANN dump file
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//
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// This procedure reads in the dump file. See the format below.
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// It first reads the header line with version number. If the
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// points section is present it reads them (otherwise just leaves
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// points = NULL), and then it reads the tree section. It inputs
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// the bounding box and determines the parameters for transforming
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// the image to figure units. It then invokes the procedure
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// readTree to do all the real work.
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//
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// Dump File Format: <xxx> = coordinate value (ANNcoord)
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|
//
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|
// #ANN <version number> <comments> [END_OF_LINE]
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|
// points <dim> <n_pts> (point coordinates: this is optional)
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// 0 <xxx> <xxx> ... <xxx> (point indices and coordinates)
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// 1 <xxx> <xxx> ... <xxx>
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// ...
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|
// tree <dim> <n_pts> <bkt_size>
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|
// <xxx> <xxx> ... <xxx> (lower end of bounding box)
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|
// <xxx> <xxx> ... <xxx> (upper end of bounding box)
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|
// If the tree is null, then a single line "null" is
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|
// output. Otherwise the nodes of the tree are printed
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|
// one per line in preorder. Leaves and splitting nodes
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|
// have the following formats:
|
|
// Leaf node:
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|
// leaf <n_pts> <bkt[0]> <bkt[1]> ... <bkt[n-1]>
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|
// Splitting nodes:
|
|
// split <cut_dim> <cut_val> <lo_bound> <hi_bound>
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|
// Shrinking nodes:
|
|
// shrink <n_bnds>
|
|
// <cut_dim> <cut_val> <side>
|
|
// <cut_dim> <cut_val> <side>
|
|
// ... (repeated n_bnds times)
|
|
//
|
|
// Note: Infinite lo_ and hi_bounds are printed as the special
|
|
// values "-INF" and "+INF", respectively. We do not
|
|
// check for this, because the current version of ANN
|
|
// starts with a finite bounding box if the tree is
|
|
// nonempty.
|
|
//----------------------------------------------------------------------
|
|
|
|
void readANN()
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|
{
|
|
int j;
|
|
char str[STRING_LEN]; // storage for string
|
|
char version[STRING_LEN]; // storage for version
|
|
int bkt_size; // bucket size
|
|
|
|
ifile >> str; // input header
|
|
if (strcmp(str, "#ANN") != 0) { // incorrect header
|
|
Error("Incorrect header for dump file", ANNabort);
|
|
}
|
|
ifile.getline(version, STRING_LEN); // get version (ignore)
|
|
ifile >> str; // get major heading
|
|
if (strcmp(str, "points") == 0) { // points section
|
|
ifile >> dim; // read dimension
|
|
ifile >> n_pts; // number of points
|
|
pts = annAllocPts(n_pts, dim); // allocate points
|
|
for (int i = 0; i < n_pts; i++) { // input point coordinates
|
|
int idx; // point index
|
|
ifile >> idx; // input point index
|
|
if (idx < 0 || idx >= n_pts) {
|
|
Error("Point index is out of range", ANNabort);
|
|
}
|
|
for (j = 0; j < dim; j++) {
|
|
ifile >> pts[idx][j]; // read point coordinates
|
|
}
|
|
}
|
|
ifile >> str; // get next major heading
|
|
}
|
|
if (strcmp(str, "tree") == 0) { // tree section
|
|
ifile >> dim; // read dimension
|
|
if (dim_x > dim || dim_y > dim) {
|
|
Error("Dimensions out of bounds", ANNabort);
|
|
}
|
|
ifile >> n_pts; // number of points
|
|
ifile >> bkt_size; // bucket size (ignored)
|
|
// read bounding box
|
|
ANNorthRect bnd_box(dim); // create bounding box
|
|
for (j = 0; j < dim; j++) {
|
|
ifile >> bnd_box.lo[j]; // read box low coordinates
|
|
}
|
|
for (j = 0; j < dim; j++) {
|
|
ifile >> bnd_box.hi[j]; // read box high coordinates
|
|
}
|
|
// compute scaling factors
|
|
double box_len_x = bnd_box.hi[dim_x] - bnd_box.lo[dim_x];
|
|
double box_len_y = bnd_box.hi[dim_y] - bnd_box.lo[dim_y];
|
|
// longer side determines scale
|
|
if (box_len_x > box_len_y) scale = u_size/box_len_x;
|
|
else scale = u_size/box_len_y;
|
|
// compute offsets
|
|
offset_x = u_low_x - scale*bnd_box.lo[dim_x];
|
|
offset_y = u_low_y + scale*bnd_box.hi[dim_y];
|
|
readTree(bnd_box); // read the tree and process
|
|
}
|
|
else if (strcmp(str, "null") == 0) return; // empty tree
|
|
else {
|
|
cerr << "Input string: " << str << "\n";
|
|
Error("Illegal ann format. Expecting section heading", ANNabort);
|
|
}
|
|
}
|
|
|
|
//----------------------------------------------------------------------
|
|
// Main program
|
|
//
|
|
// Gets the command-line arguments and invokes the main scanning
|
|
// procedure.
|
|
//----------------------------------------------------------------------
|
|
|
|
main(int argc, char **argv)
|
|
{
|
|
getArgs(argc, argv); // get input arguments
|
|
readANN(); // read the dump file
|
|
}
|