twain3.0/3rdparty/hgOCR/include/ccstruct/polyblk.cpp

/**********************************************************************
 * File:        polyblk.c  (Formerly poly_block.c)
 * Description: Polygonal blocks
 * Author:          Sheelagh Lloyd?
 * Created:
 *
 * (C) Copyright 1993, Hewlett-Packard Ltd.
 ** Licensed under the Apache License, Version 2.0 (the "License");
 ** you may not use this file except in compliance with the License.
 ** You may obtain a copy of the License at
 ** http://www.apache.org/licenses/LICENSE-2.0
 ** Unless required by applicable law or agreed to in writing, software
 ** distributed under the License is distributed on an "AS IS" BASIS,
 ** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 ** See the License for the specific language governing permissions and
 ** limitations under the License.
 *
 **********************************************************************/

#include <ctype.h>
#include <math.h>
#include <stdio.h>
#include "elst.h"
#include "polyblk.h"

// Include automatically generated configuration file if running autoconf.
#ifdef HAVE_CONFIG_H
#include "config_auto.h"
#endif

#define PBLOCK_LABEL_SIZE 150
#define INTERSECTING MAX_INT16

int lessthan(const void *first, const void *second);

POLY_BLOCK::POLY_BLOCK(ICOORDELT_LIST *points, PolyBlockType t) {
  ICOORDELT_IT v = &vertices;

  vertices.clear();
  v.move_to_first();
  v.add_list_before(points);
  compute_bb();
  type = t;
}

// Initialize from box coordinates.
POLY_BLOCK::POLY_BLOCK(const TBOX& box, PolyBlockType t) {
  vertices.clear();
  ICOORDELT_IT v = &vertices;
  v.move_to_first();
  v.add_to_end(new ICOORDELT(box.left(), box.top()));
  v.add_to_end(new ICOORDELT(box.left(), box.bottom()));
  v.add_to_end(new ICOORDELT(box.right(), box.bottom()));
  v.add_to_end(new ICOORDELT(box.right(), box.top()));
  compute_bb();
  type = t;
}

/**
 * @name POLY_BLOCK::compute_bb
 *
 * Compute the bounding box from the outline points.
 */

void POLY_BLOCK::compute_bb() {  //constructor
  ICOORD ibl, itr;               //integer bb
  ICOORD botleft;                //bounding box
  ICOORD topright;
  ICOORD pos;                    //current pos;
  ICOORDELT_IT pts = &vertices;  //iterator

  botleft = *pts.data ();
  topright = botleft;
  do {
    pos = *pts.data ();
    if (pos.x () < botleft.x ())
                                 //get bounding box
      botleft = ICOORD (pos.x (), botleft.y ());
    if (pos.y () < botleft.y ())
      botleft = ICOORD (botleft.x (), pos.y ());
    if (pos.x () > topright.x ())
      topright = ICOORD (pos.x (), topright.y ());
    if (pos.y () > topright.y ())
      topright = ICOORD (topright.x (), pos.y ());
    pts.forward ();
  }
  while (!pts.at_first ());
  ibl = ICOORD (botleft.x (), botleft.y ());
  itr = ICOORD (topright.x (), topright.y ());
  box = TBOX (ibl, itr);
}


/**
 * @name POLY_BLOCK::winding_number
 *
 * Return the winding number of the outline around the given point.
 * @param point point to wind around
 */

inT16 POLY_BLOCK::winding_number(const ICOORD &point) {
  inT16 count;                   //winding count
  ICOORD pt;                     //current point
  ICOORD vec;                    //point to current point
  ICOORD vvec;                   //current point to next point
  inT32 cross;                   //cross product
  ICOORDELT_IT it = &vertices;   //iterator

  count = 0;
  do {
    pt = *it.data ();
    vec = pt - point;
    vvec = *it.data_relative (1) - pt;
                                 //crossing the line
    if (vec.y () <= 0 && vec.y () + vvec.y () > 0) {
      cross = vec * vvec;        //cross product
      if (cross > 0)
        count++;                 //crossing right half
      else if (cross == 0)
        return INTERSECTING;     //going through point
    }
    else if (vec.y () > 0 && vec.y () + vvec.y () <= 0) {
      cross = vec * vvec;
      if (cross < 0)
        count--;                 //crossing back
      else if (cross == 0)
        return INTERSECTING;     //illegal
    }
    else if (vec.y () == 0 && vec.x () == 0)
      return INTERSECTING;
    it.forward ();
  }
  while (!it.at_first ());
  return count;                  //winding number
}


/// @return true if other is inside this.
bool POLY_BLOCK::contains(POLY_BLOCK *other) {
  inT16 count;                   // winding count
  ICOORDELT_IT it = &vertices;   // iterator
  ICOORD vertex;

  if (!box.overlap (*(other->bounding_box ())))
    return false;                // can't be contained

  /* check that no vertex of this is inside other */

  do {
    vertex = *it.data ();
                                 // get winding number
    count = other->winding_number (vertex);
    if (count != INTERSECTING)
      if (count != 0)
        return false;
    it.forward ();
  }
  while (!it.at_first ());

  /* check that all vertices of other are inside this */

                                 //switch lists
  it.set_to_list (other->points ());
  do {
    vertex = *it.data ();
                                 //try other way round
    count = winding_number (vertex);
    if (count != INTERSECTING)
      if (count == 0)
        return false;
    it.forward ();
  }
  while (!it.at_first ());
  return true;
}


/**
 * @name POLY_BLOCK::rotate
 *
 * Rotate the POLY_BLOCK.
 * @param rotation cos, sin of angle
 */

void POLY_BLOCK::rotate(FCOORD rotation) {
  FCOORD pos;                    //current pos;
  ICOORDELT *pt;                 //current point
  ICOORDELT_IT pts = &vertices;  //iterator

  do {
    pt = pts.data ();
    pos.set_x (pt->x ());
    pos.set_y (pt->y ());
    pos.rotate (rotation);
    pt->set_x ((inT16) (floor (pos.x () + 0.5)));
    pt->set_y ((inT16) (floor (pos.y () + 0.5)));
    pts.forward ();
  }
  while (!pts.at_first ());
  compute_bb();
}

/**
 * @name POLY_BLOCK::reflect_in_y_axis
 *
 * Reflect the coords of the polygon in the y-axis. (Flip the sign of x.)
 */

void POLY_BLOCK::reflect_in_y_axis() {
  ICOORDELT *pt;                 // current point
  ICOORDELT_IT pts = &vertices;  // Iterator.

  do {
    pt = pts.data();
    pt->set_x(-pt->x());
    pts.forward();
  }
  while (!pts.at_first());
  compute_bb();
}


/**
 * POLY_BLOCK::move
 *
 * Move the POLY_BLOCK.
 * @param shift x,y translation vector
 */

void POLY_BLOCK::move(ICOORD shift) {
  ICOORDELT *pt;                 //current point
  ICOORDELT_IT pts = &vertices;  //iterator

  do {
    pt = pts.data ();
    *pt += shift;
    pts.forward ();
  }
  while (!pts.at_first ());
  compute_bb();
}


#ifndef GRAPHICS_DISABLED
void POLY_BLOCK::plot(ScrollView* window, inT32 num) {
  ICOORDELT_IT v = &vertices;

  window->Pen(ColorForPolyBlockType(type));

  v.move_to_first ();

  if (num > 0) {
    window->TextAttributes("Times", 80, false, false, false);
    char temp_buff[34];
    #if defined(__UNIX__) || defined(MINGW)
    sprintf(temp_buff, INT32FORMAT, num);
    #else
    ltoa (num, temp_buff, 10);
    #endif
    window->Text(v.data ()->x (), v.data ()->y (), temp_buff);
  }

  window->SetCursor(v.data ()->x (), v.data ()->y ());
  for (v.mark_cycle_pt (); !v.cycled_list (); v.forward ()) {
    window->DrawTo(v.data ()->x (), v.data ()->y ());
   }
  v.move_to_first ();
   window->DrawTo(v.data ()->x (), v.data ()->y ());
}


void POLY_BLOCK::fill(ScrollView* window, ScrollView::Color colour) {
  inT16 y;
  inT16 width;
  PB_LINE_IT *lines;
  ICOORDELT_LIST *segments;
  ICOORDELT_IT s_it;

  lines = new PB_LINE_IT (this);
  window->Pen(colour);

  for (y = this->bounding_box ()->bottom ();
  y <= this->bounding_box ()->top (); y++) {
    segments = lines->get_line (y);
    if (!segments->empty ()) {
      s_it.set_to_list (segments);
      for (s_it.mark_cycle_pt (); !s_it.cycled_list (); s_it.forward ()) {
        // Note different use of ICOORDELT, x coord is x coord of pixel
        // at the start of line segment, y coord is length of line segment
        // Last pixel is start pixel + length.
        width = s_it.data ()->y ();
        window->SetCursor(s_it.data ()->x (), y);
        window->DrawTo(s_it.data ()->x () + (float) width, y);
      }
    }
  }

  delete lines;
}
#endif


/// @return true if the polygons of other and this overlap.
bool POLY_BLOCK::overlap(POLY_BLOCK *other) {
  inT16 count;                   // winding count
  ICOORDELT_IT it = &vertices;   // iterator
  ICOORD vertex;

  if (!box.overlap(*(other->bounding_box())))
    return false;                // can't be any overlap.

  /* see if a vertex of this is inside other */

  do {
    vertex = *it.data ();
                                 // get winding number
    count = other->winding_number (vertex);
    if (count != INTERSECTING)
      if (count != 0)
        return true;
    it.forward ();
  }
  while (!it.at_first ());

  /* see if a vertex of other is inside this */

                                 // switch lists
  it.set_to_list (other->points ());
  do {
    vertex = *it.data();
                                 // try other way round
    count = winding_number (vertex);
    if (count != INTERSECTING)
      if (count != 0)
        return true;
    it.forward ();
  }
  while (!it.at_first ());
  return false;
}


ICOORDELT_LIST *PB_LINE_IT::get_line(inT16 y) {
  ICOORDELT_IT v, r;
  ICOORDELT_LIST *result;
  ICOORDELT *x, *current, *previous;
  float fy, fx;

  fy = (float) (y + 0.5);
  result = new ICOORDELT_LIST ();
  r.set_to_list (result);
  v.set_to_list (block->points ());

  for (v.mark_cycle_pt (); !v.cycled_list (); v.forward ()) {
    if (((v.data_relative (-1)->y () > y) && (v.data ()->y () <= y))
    || ((v.data_relative (-1)->y () <= y) && (v.data ()->y () > y))) {
      previous = v.data_relative (-1);
      current = v.data ();
      fx = (float) (0.5 + previous->x () +
        (current->x () - previous->x ()) * (fy -
        previous->y ()) /
        (current->y () - previous->y ()));
      x = new ICOORDELT ((inT16) fx, 0);
      r.add_to_end (x);
    }
  }

  if (!r.empty ()) {
    r.sort (lessthan);
    for (r.mark_cycle_pt (); !r.cycled_list (); r.forward ())
      x = r.data ();
    for (r.mark_cycle_pt (); !r.cycled_list (); r.forward ()) {
      r.data ()->set_y (r.data_relative (1)->x () - r.data ()->x ());
      r.forward ();
      delete (r.extract ());
    }
  }

  return result;
}


int lessthan(const void *first, const void *second) {
  ICOORDELT *p1 = (*(ICOORDELT **) first);
  ICOORDELT *p2 = (*(ICOORDELT **) second);

  if (p1->x () < p2->x ())
    return (-1);
  else if (p1->x () > p2->x ())
    return (1);
  else
    return (0);
}

#ifndef GRAPHICS_DISABLED
/// Returns a color to draw the given type.
ScrollView::Color POLY_BLOCK::ColorForPolyBlockType(PolyBlockType type) {
  // Keep kPBColors in sync with PolyBlockType.
  const ScrollView::Color kPBColors[PT_COUNT] = {
    ScrollView::WHITE,        // Type is not yet known. Keep as the 1st element.
    ScrollView::BLUE,         // Text that lives inside a column.
    ScrollView::CYAN,         // Text that spans more than one column.
    ScrollView::MEDIUM_BLUE,  // Text that is in a cross-column pull-out region.
    ScrollView::AQUAMARINE,   // Partition belonging to an equation region.
    ScrollView::SKY_BLUE,   // Partition belonging to an inline equation region.
    ScrollView::MAGENTA,      // Partition belonging to a table region.
    ScrollView::GREEN,        // Text-line runs vertically.
    ScrollView::LIGHT_BLUE,   // Text that belongs to an image.
    ScrollView::RED,          // Image that lives inside a column.
    ScrollView::YELLOW,       // Image that spans more than one column.
    ScrollView::ORANGE,       // Image in a cross-column pull-out region.
    ScrollView::BROWN,        // Horizontal Line.
    ScrollView::DARK_GREEN,   // Vertical Line.
    ScrollView::GREY          // Lies outside of any column.
  };
  if (type >= 0 && type < PT_COUNT) {
    return kPBColors[type];
  }
  return ScrollView::WHITE;
}
#endif  // GRAPHICS_DISABLED
合并ocr更改 2021-11-20 06:24:33 +00:00			`/**********************************************************************`
			`* File: polyblk.c (Formerly poly_block.c)`
			`* Description: Polygonal blocks`
			`* Author: Sheelagh Lloyd?`
			`* Created:`
			`*`
			`* (C) Copyright 1993, Hewlett-Packard Ltd.`
			`** Licensed under the Apache License, Version 2.0 (the "License");`
			`** you may not use this file except in compliance with the License.`
			`** You may obtain a copy of the License at`
			`** http://www.apache.org/licenses/LICENSE-2.0`
			`** Unless required by applicable law or agreed to in writing, software`
			`** distributed under the License is distributed on an "AS IS" BASIS,`
			`** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.`
			`** See the License for the specific language governing permissions and`
			`** limitations under the License.`
			`*`
			`**********************************************************************/`

			`#include <ctype.h>`
			`#include <math.h>`
			`#include <stdio.h>`
			`#include "elst.h"`
			`#include "polyblk.h"`

			`// Include automatically generated configuration file if running autoconf.`
			`#ifdef HAVE_CONFIG_H`
			`#include "config_auto.h"`
			`#endif`

			`#define PBLOCK_LABEL_SIZE 150`
			`#define INTERSECTING MAX_INT16`

			`int lessthan(const void first, const void second);`

			`POLY_BLOCK::POLY_BLOCK(ICOORDELT_LIST *points, PolyBlockType t) {`
			`ICOORDELT_IT v = &vertices;`

			`vertices.clear();`
			`v.move_to_first();`
			`v.add_list_before(points);`
			`compute_bb();`
			`type = t;`
			`}`

			`// Initialize from box coordinates.`
			`POLY_BLOCK::POLY_BLOCK(const TBOX& box, PolyBlockType t) {`
			`vertices.clear();`
			`ICOORDELT_IT v = &vertices;`
			`v.move_to_first();`
			`v.add_to_end(new ICOORDELT(box.left(), box.top()));`
			`v.add_to_end(new ICOORDELT(box.left(), box.bottom()));`
			`v.add_to_end(new ICOORDELT(box.right(), box.bottom()));`
			`v.add_to_end(new ICOORDELT(box.right(), box.top()));`
			`compute_bb();`
			`type = t;`
			`}`

			`/**`
			`* @name POLY_BLOCK::compute_bb`
			`*`
			`* Compute the bounding box from the outline points.`
			`*/`

			`void POLY_BLOCK::compute_bb() { //constructor`
			`ICOORD ibl, itr; //integer bb`
			`ICOORD botleft; //bounding box`
			`ICOORD topright;`
			`ICOORD pos; //current pos;`
			`ICOORDELT_IT pts = &vertices; //iterator`

			`botleft = *pts.data ();`
			`topright = botleft;`
			`do {`
			`pos = *pts.data ();`
			`if (pos.x () < botleft.x ())`
			`//get bounding box`
			`botleft = ICOORD (pos.x (), botleft.y ());`
			`if (pos.y () < botleft.y ())`
			`botleft = ICOORD (botleft.x (), pos.y ());`
			`if (pos.x () > topright.x ())`
			`topright = ICOORD (pos.x (), topright.y ());`
			`if (pos.y () > topright.y ())`
			`topright = ICOORD (topright.x (), pos.y ());`
			`pts.forward ();`
			`}`
			`while (!pts.at_first ());`
			`ibl = ICOORD (botleft.x (), botleft.y ());`
			`itr = ICOORD (topright.x (), topright.y ());`
			`box = TBOX (ibl, itr);`
			`}`


			`/**`
			`* @name POLY_BLOCK::winding_number`
			`*`
			`* Return the winding number of the outline around the given point.`
			`* @param point point to wind around`
			`*/`

			`inT16 POLY_BLOCK::winding_number(const ICOORD &point) {`
			`inT16 count; //winding count`
			`ICOORD pt; //current point`
			`ICOORD vec; //point to current point`
			`ICOORD vvec; //current point to next point`
			`inT32 cross; //cross product`
			`ICOORDELT_IT it = &vertices; //iterator`

			`count = 0;`
			`do {`
			`pt = *it.data ();`
			`vec = pt - point;`
			`vvec = *it.data_relative (1) - pt;`
			`//crossing the line`
			`if (vec.y () <= 0 && vec.y () + vvec.y () > 0) {`
			`cross = vec * vvec; //cross product`
			`if (cross > 0)`
			`count++; //crossing right half`
			`else if (cross == 0)`
			`return INTERSECTING; //going through point`
			`}`
			`else if (vec.y () > 0 && vec.y () + vvec.y () <= 0) {`
			`cross = vec * vvec;`
			`if (cross < 0)`
			`count--; //crossing back`
			`else if (cross == 0)`
			`return INTERSECTING; //illegal`
			`}`
			`else if (vec.y () == 0 && vec.x () == 0)`
			`return INTERSECTING;`
			`it.forward ();`
			`}`
			`while (!it.at_first ());`
			`return count; //winding number`
			`}`


			`/// @return true if other is inside this.`
			`bool POLY_BLOCK::contains(POLY_BLOCK *other) {`
			`inT16 count; // winding count`
			`ICOORDELT_IT it = &vertices; // iterator`
			`ICOORD vertex;`

			`if (!box.overlap (*(other->bounding_box ())))`
			`return false; // can't be contained`

			`/* check that no vertex of this is inside other */`

			`do {`
			`vertex = *it.data ();`
			`// get winding number`
			`count = other->winding_number (vertex);`
			`if (count != INTERSECTING)`
			`if (count != 0)`
			`return false;`
			`it.forward ();`
			`}`
			`while (!it.at_first ());`

			`/* check that all vertices of other are inside this */`

			`//switch lists`
			`it.set_to_list (other->points ());`
			`do {`
			`vertex = *it.data ();`
			`//try other way round`
			`count = winding_number (vertex);`
			`if (count != INTERSECTING)`
			`if (count == 0)`
			`return false;`
			`it.forward ();`
			`}`
			`while (!it.at_first ());`
			`return true;`
			`}`


			`/**`
			`* @name POLY_BLOCK::rotate`
			`*`
			`* Rotate the POLY_BLOCK.`
			`* @param rotation cos, sin of angle`
			`*/`

			`void POLY_BLOCK::rotate(FCOORD rotation) {`
			`FCOORD pos; //current pos;`
			`ICOORDELT *pt; //current point`
			`ICOORDELT_IT pts = &vertices; //iterator`

			`do {`
			`pt = pts.data ();`
			`pos.set_x (pt->x ());`
			`pos.set_y (pt->y ());`
			`pos.rotate (rotation);`
			`pt->set_x ((inT16) (floor (pos.x () + 0.5)));`
			`pt->set_y ((inT16) (floor (pos.y () + 0.5)));`
			`pts.forward ();`
			`}`
			`while (!pts.at_first ());`
			`compute_bb();`
			`}`

			`/**`
			`* @name POLY_BLOCK::reflect_in_y_axis`
			`*`
			`* Reflect the coords of the polygon in the y-axis. (Flip the sign of x.)`
			`*/`

			`void POLY_BLOCK::reflect_in_y_axis() {`
			`ICOORDELT *pt; // current point`
			`ICOORDELT_IT pts = &vertices; // Iterator.`

			`do {`
			`pt = pts.data();`
			`pt->set_x(-pt->x());`
			`pts.forward();`
			`}`
			`while (!pts.at_first());`
			`compute_bb();`
			`}`


			`/**`
			`* POLY_BLOCK::move`
			`*`
			`* Move the POLY_BLOCK.`
			`* @param shift x,y translation vector`
			`*/`

			`void POLY_BLOCK::move(ICOORD shift) {`
			`ICOORDELT *pt; //current point`
			`ICOORDELT_IT pts = &vertices; //iterator`

			`do {`
			`pt = pts.data ();`
			`*pt += shift;`
			`pts.forward ();`
			`}`
			`while (!pts.at_first ());`
			`compute_bb();`
			`}`


			`#ifndef GRAPHICS_DISABLED`
			`void POLY_BLOCK::plot(ScrollView* window, inT32 num) {`
			`ICOORDELT_IT v = &vertices;`

			`window->Pen(ColorForPolyBlockType(type));`

			`v.move_to_first ();`

			`if (num > 0) {`
			`window->TextAttributes("Times", 80, false, false, false);`
			`char temp_buff[34];`
			`#if defined(__UNIX__) \|\| defined(MINGW)`
			`sprintf(temp_buff, INT32FORMAT, num);`
			`#else`
			`ltoa (num, temp_buff, 10);`
			`#endif`
			`window->Text(v.data ()->x (), v.data ()->y (), temp_buff);`
			`}`

			`window->SetCursor(v.data ()->x (), v.data ()->y ());`
			`for (v.mark_cycle_pt (); !v.cycled_list (); v.forward ()) {`
			`window->DrawTo(v.data ()->x (), v.data ()->y ());`
			`}`
			`v.move_to_first ();`
			`window->DrawTo(v.data ()->x (), v.data ()->y ());`
			`}`


			`void POLY_BLOCK::fill(ScrollView* window, ScrollView::Color colour) {`
			`inT16 y;`
			`inT16 width;`
			`PB_LINE_IT *lines;`
			`ICOORDELT_LIST *segments;`
			`ICOORDELT_IT s_it;`

			`lines = new PB_LINE_IT (this);`
			`window->Pen(colour);`

			`for (y = this->bounding_box ()->bottom ();`
			`y <= this->bounding_box ()->top (); y++) {`
			`segments = lines->get_line (y);`
			`if (!segments->empty ()) {`
			`s_it.set_to_list (segments);`
			`for (s_it.mark_cycle_pt (); !s_it.cycled_list (); s_it.forward ()) {`
			`// Note different use of ICOORDELT, x coord is x coord of pixel`
			`// at the start of line segment, y coord is length of line segment`
			`// Last pixel is start pixel + length.`
			`width = s_it.data ()->y ();`
			`window->SetCursor(s_it.data ()->x (), y);`
			`window->DrawTo(s_it.data ()->x () + (float) width, y);`
			`}`
			`}`
			`}`

			`delete lines;`
			`}`
			`#endif`


			`/// @return true if the polygons of other and this overlap.`
			`bool POLY_BLOCK::overlap(POLY_BLOCK *other) {`
			`inT16 count; // winding count`
			`ICOORDELT_IT it = &vertices; // iterator`
			`ICOORD vertex;`

			`if (!box.overlap(*(other->bounding_box())))`
			`return false; // can't be any overlap.`

			`/* see if a vertex of this is inside other */`

			`do {`
			`vertex = *it.data ();`
			`// get winding number`
			`count = other->winding_number (vertex);`
			`if (count != INTERSECTING)`
			`if (count != 0)`
			`return true;`
			`it.forward ();`
			`}`
			`while (!it.at_first ());`

			`/* see if a vertex of other is inside this */`

			`// switch lists`
			`it.set_to_list (other->points ());`
			`do {`
			`vertex = *it.data();`
			`// try other way round`
			`count = winding_number (vertex);`
			`if (count != INTERSECTING)`
			`if (count != 0)`
			`return true;`
			`it.forward ();`
			`}`
			`while (!it.at_first ());`
			`return false;`
			`}`


			`ICOORDELT_LIST *PB_LINE_IT::get_line(inT16 y) {`
			`ICOORDELT_IT v, r;`
			`ICOORDELT_LIST *result;`
			`ICOORDELT x, current, *previous;`
			`float fy, fx;`

			`fy = (float) (y + 0.5);`
			`result = new ICOORDELT_LIST ();`
			`r.set_to_list (result);`
			`v.set_to_list (block->points ());`

			`for (v.mark_cycle_pt (); !v.cycled_list (); v.forward ()) {`
			`if (((v.data_relative (-1)->y () > y) && (v.data ()->y () <= y))`
			`\|\| ((v.data_relative (-1)->y () <= y) && (v.data ()->y () > y))) {`
			`previous = v.data_relative (-1);`
			`current = v.data ();`
			`fx = (float) (0.5 + previous->x () +`
			`(current->x () - previous->x ()) * (fy -`
			`previous->y ()) /`
			`(current->y () - previous->y ()));`
			`x = new ICOORDELT ((inT16) fx, 0);`
			`r.add_to_end (x);`
			`}`
			`}`

			`if (!r.empty ()) {`
			`r.sort (lessthan);`
			`for (r.mark_cycle_pt (); !r.cycled_list (); r.forward ())`
			`x = r.data ();`
			`for (r.mark_cycle_pt (); !r.cycled_list (); r.forward ()) {`
			`r.data ()->set_y (r.data_relative (1)->x () - r.data ()->x ());`
			`r.forward ();`
			`delete (r.extract ());`
			`}`
			`}`

			`return result;`
			`}`


			`int lessthan(const void first, const void second) {`
			`ICOORDELT p1 = ((ICOORDELT **) first);`
			`ICOORDELT p2 = ((ICOORDELT **) second);`

			`if (p1->x () < p2->x ())`
			`return (-1);`
			`else if (p1->x () > p2->x ())`
			`return (1);`
			`else`
			`return (0);`
			`}`

			`#ifndef GRAPHICS_DISABLED`
			`/// Returns a color to draw the given type.`
			`ScrollView::Color POLY_BLOCK::ColorForPolyBlockType(PolyBlockType type) {`
			`// Keep kPBColors in sync with PolyBlockType.`
			`const ScrollView::Color kPBColors[PT_COUNT] = {`
			`ScrollView::WHITE, // Type is not yet known. Keep as the 1st element.`
			`ScrollView::BLUE, // Text that lives inside a column.`
			`ScrollView::CYAN, // Text that spans more than one column.`
			`ScrollView::MEDIUM_BLUE, // Text that is in a cross-column pull-out region.`
			`ScrollView::AQUAMARINE, // Partition belonging to an equation region.`
			`ScrollView::SKY_BLUE, // Partition belonging to an inline equation region.`
			`ScrollView::MAGENTA, // Partition belonging to a table region.`
			`ScrollView::GREEN, // Text-line runs vertically.`
			`ScrollView::LIGHT_BLUE, // Text that belongs to an image.`
			`ScrollView::RED, // Image that lives inside a column.`
			`ScrollView::YELLOW, // Image that spans more than one column.`
			`ScrollView::ORANGE, // Image in a cross-column pull-out region.`
			`ScrollView::BROWN, // Horizontal Line.`
			`ScrollView::DARK_GREEN, // Vertical Line.`
			`ScrollView::GREY // Lies outside of any column.`
			`};`
			`if (type >= 0 && type < PT_COUNT) {`
			`return kPBColors[type];`
			`}`
			`return ScrollView::WHITE;`
			`}`
			`#endif // GRAPHICS_DISABLED`