tesseract  3.03
C_OUTLINE Class Reference

#include <coutln.h>

Inheritance diagram for C_OUTLINE:
ELIST_LINK

List of all members.

Public Member Functions

 C_OUTLINE ()
 C_OUTLINE (CRACKEDGE *startpt, ICOORD bot_left, ICOORD top_right, inT16 length)
 C_OUTLINE (ICOORD startpt, DIR128 *new_steps, inT16 length)
 C_OUTLINE (C_OUTLINE *srcline, FCOORD rotation)
 ~C_OUTLINE ()
BOOL8 flag (C_OUTLINE_FLAGS mask) const
void set_flag (C_OUTLINE_FLAGS mask, BOOL8 value)
C_OUTLINE_LIST * child ()
const TBOXbounding_box () const
void set_step (inT16 stepindex, inT8 stepdir)
void set_step (inT16 stepindex, DIR128 stepdir)
inT32 pathlength () const
DIR128 step_dir (int index) const
ICOORD step (int index) const
const ICOORDstart_pos () const
ICOORD position_at_index (int index) const
FCOORD sub_pixel_pos_at_index (const ICOORD &pos, int index) const
int direction_at_index (int index) const
int edge_strength_at_index (int index) const
int chain_code (int index) const
inT32 area () const
inT32 perimeter () const
inT32 outer_area () const
inT32 count_transitions (inT32 threshold)
BOOL8 operator< (const C_OUTLINE &other) const
BOOL8 operator> (C_OUTLINE &other) const
inT16 winding_number (ICOORD testpt) const
inT16 turn_direction () const
void reverse ()
void move (const ICOORD vec)
bool IsLegallyNested () const
void RemoveSmallRecursive (int min_size, C_OUTLINE_IT *it)
void ComputeEdgeOffsets (int threshold, Pix *pix)
void ComputeBinaryOffsets ()
void render (int left, int top, Pix *pix) const
void render_outline (int left, int top, Pix *pix) const
void plot (ScrollView *window, ScrollView::Color colour) const
void plot_normed (const DENORM &denorm, ScrollView::Color colour, ScrollView *window) const
C_OUTLINEoperator= (const C_OUTLINE &source)

Static Public Member Functions

static void FakeOutline (const TBOX &box, C_OUTLINE_LIST *outlines)
static C_OUTLINEdeep_copy (const C_OUTLINE *src)
static ICOORD chain_step (int chaindir)

Static Public Attributes

static const int kMaxOutlineLength = 16000

Detailed Description

Definition at line 69 of file coutln.h.


Constructor & Destructor Documentation

C_OUTLINE::C_OUTLINE ( ) [inline]

Definition at line 71 of file coutln.h.

              {  //empty constructor
      steps = NULL;
      offsets = NULL;
    }
C_OUTLINE::C_OUTLINE ( CRACKEDGE startpt,
ICOORD  bot_left,
ICOORD  top_right,
inT16  length 
)

Definition at line 47 of file coutln.cpp.

 :box (bot_left, top_right), start (startpt->pos), offsets(NULL) {
  inT16 stepindex;               //index to step
  CRACKEDGE *edgept;             //current point

  stepcount = length;            //no of steps
  if (length == 0) {
    steps = NULL;
    return;
  }
                                 //get memory
  steps = (uinT8 *) alloc_mem (step_mem());
  memset(steps, 0, step_mem());
  edgept = startpt;

  for (stepindex = 0; stepindex < length; stepindex++) {
                                 //set compact step
    set_step (stepindex, edgept->stepdir);
    edgept = edgept->next;
  }
}
C_OUTLINE::C_OUTLINE ( ICOORD  startpt,
DIR128 new_steps,
inT16  length 
)

Definition at line 79 of file coutln.cpp.

 :start (startpt), offsets(NULL) {
  inT8 dirdiff;                  //direction difference
  DIR128 prevdir;                //previous direction
  DIR128 dir;                    //current direction
  DIR128 lastdir;                //dir of last step
  TBOX new_box;                   //easy bounding
  inT16 stepindex;               //index to step
  inT16 srcindex;                //source steps
  ICOORD pos;                    //current position

  pos = startpt;
  stepcount = length;            // No. of steps.
  ASSERT_HOST(length >= 0);
  steps = reinterpret_cast<uinT8*>(alloc_mem(step_mem()));  // Get memory.
  memset(steps, 0, step_mem());

  lastdir = new_steps[length - 1];
  prevdir = lastdir;
  for (stepindex = 0, srcindex = 0; srcindex < length;
  stepindex++, srcindex++) {
    new_box = TBOX (pos, pos);
    box += new_box;
                                 //copy steps
    dir = new_steps[srcindex];
    set_step(stepindex, dir);
    dirdiff = dir - prevdir;
    pos += step (stepindex);
    if ((dirdiff == 64 || dirdiff == -64) && stepindex > 0) {
      stepindex -= 2;            //cancel there-and-back
      prevdir = stepindex >= 0 ? step_dir (stepindex) : lastdir;
    }
    else
      prevdir = dir;
  }
  ASSERT_HOST (pos.x () == startpt.x () && pos.y () == startpt.y ());
  do {
    dirdiff = step_dir (stepindex - 1) - step_dir (0);
    if (dirdiff == 64 || dirdiff == -64) {
      start += step (0);
      stepindex -= 2;            //cancel there-and-back
      for (int i = 0; i < stepindex; ++i)
        set_step(i, step_dir(i + 1));
    }
  }
  while (stepindex > 1 && (dirdiff == 64 || dirdiff == -64));
  stepcount = stepindex;
  ASSERT_HOST (stepcount >= 4);
}
C_OUTLINE::C_OUTLINE ( C_OUTLINE srcline,
FCOORD  rotation 
)

Definition at line 139 of file coutln.cpp.

                      : offsets(NULL) {
  TBOX new_box;                   //easy bounding
  inT16 stepindex;               //index to step
  inT16 dirdiff;                 //direction change
  ICOORD pos;                    //current position
  ICOORD prevpos;                //previous dest point

  ICOORD destpos;                //destination point
  inT16 destindex;               //index to step
  DIR128 dir;                    //coded direction
  uinT8 new_step;

  stepcount = srcline->stepcount * 2;
  if (stepcount == 0) {
    steps = NULL;
    box = srcline->box;
    box.rotate(rotation);
    return;
  }
                                 //get memory
  steps = (uinT8 *) alloc_mem (step_mem());
  memset(steps, 0, step_mem());

  for (int iteration = 0; iteration < 2; ++iteration) {
    DIR128 round1 = iteration == 0 ? 32 : 0;
    DIR128 round2 = iteration != 0 ? 32 : 0;
    pos = srcline->start;
    prevpos = pos;
    prevpos.rotate (rotation);
    start = prevpos;
    box = TBOX (start, start);
    destindex = 0;
    for (stepindex = 0; stepindex < srcline->stepcount; stepindex++) {
      pos += srcline->step (stepindex);
      destpos = pos;
      destpos.rotate (rotation);
      //  tprintf("%i %i %i %i ", destpos.x(), destpos.y(), pos.x(), pos.y());
      while (destpos.x () != prevpos.x () || destpos.y () != prevpos.y ()) {
        dir = DIR128 (FCOORD (destpos - prevpos));
        dir += 64;                 //turn to step style
        new_step = dir.get_dir ();
        //  tprintf(" %i\n", new_step);
        if (new_step & 31) {
          set_step(destindex++, dir + round1);
          prevpos += step(destindex - 1);
          if (destindex < 2
            || ((dirdiff =
            step_dir (destindex - 1) - step_dir (destindex - 2)) !=
            -64 && dirdiff != 64)) {
            set_step(destindex++, dir + round2);
            prevpos += step(destindex - 1);
          } else {
            prevpos -= step(destindex - 1);
            destindex--;
            prevpos -= step(destindex - 1);
            set_step(destindex - 1, dir + round2);
            prevpos += step(destindex - 1);
          }
        }
        else {
          set_step(destindex++, dir);
          prevpos += step(destindex - 1);
        }
        while (destindex >= 2 &&
               ((dirdiff =
                 step_dir (destindex - 1) - step_dir (destindex - 2)) == -64 ||
                dirdiff == 64)) {
          prevpos -= step(destindex - 1);
          prevpos -= step(destindex - 2);
          destindex -= 2;        // Forget u turn
        }
        //ASSERT_HOST(prevpos.x() == destpos.x() && prevpos.y() == destpos.y());
        new_box = TBOX (destpos, destpos);
        box += new_box;
      }
    }
    ASSERT_HOST (destpos.x () == start.x () && destpos.y () == start.y ());
    dirdiff = step_dir (destindex - 1) - step_dir (0);
    while ((dirdiff == 64 || dirdiff == -64) && destindex > 1) {
      start += step (0);
      destindex -= 2;
      for (int i = 0; i < destindex; ++i)
        set_step(i, step_dir(i + 1));
      dirdiff = step_dir (destindex - 1) - step_dir (0);
    }
    if (destindex >= 4)
      break;
  }
  ASSERT_HOST(destindex <= stepcount);
  stepcount = destindex;
  destpos = start;
  for (stepindex = 0; stepindex < stepcount; stepindex++) {
    destpos += step (stepindex);
  }
  ASSERT_HOST (destpos.x () == start.x () && destpos.y () == start.y ());
}
C_OUTLINE::~C_OUTLINE ( ) [inline]

Definition at line 89 of file coutln.h.

                  {              //destructor
      if (steps != NULL)
        free_mem(steps);
      steps = NULL;
      delete [] offsets;
    }

Member Function Documentation

Definition at line 256 of file coutln.cpp.

                            {
  int stepindex;                 //current step
  inT32 total_steps;             //steps to do
  inT32 total;                   //total area
  ICOORD pos;                    //position of point
  ICOORD next_step;              //step to next pix
  // We aren't going to modify the list, or its contents, but there is
  // no const iterator.
  C_OUTLINE_IT it(const_cast<C_OUTLINE_LIST*>(&children));

  pos = start_pos ();
  total_steps = pathlength ();
  total = 0;
  for (stepindex = 0; stepindex < total_steps; stepindex++) {
                                 //all intersected
    next_step = step (stepindex);
    if (next_step.x () < 0)
      total += pos.y ();
    else if (next_step.x () > 0)
      total -= pos.y ();
    pos += next_step;
  }
  for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ())
    total += it.data ()->area ();//add areas of children

  return total;
}
const TBOX& C_OUTLINE::bounding_box ( ) const [inline]

Definition at line 111 of file coutln.h.

                                     {
      return box;
    }
int C_OUTLINE::chain_code ( int  index) const [inline]

Definition at line 193 of file coutln.h.

                                    {  // index of step
      return (steps[index / 4] >> (index % 4 * 2)) & STEP_MASK;
    }
ICOORD C_OUTLINE::chain_step ( int  chaindir) [static]

Definition at line 1040 of file coutln.cpp.

                                         {
  return step_coords[chaindir % 4];
}
C_OUTLINE_LIST* C_OUTLINE::child ( ) [inline]

Definition at line 106 of file coutln.h.

                            {  //get child list
      return &children;
    }

Definition at line 834 of file coutln.cpp.

                                     {
  delete [] offsets;
  offsets = new EdgeOffset[stepcount];
  // Count of the number of steps in each direction in the sliding window.
  int dir_counts[4];
  // Sum of the positions (y for a horizontal step, x for vertical) in each
  // direction in the sliding window.
  int pos_totals[4];
  memset(dir_counts, 0, sizeof(dir_counts));
  memset(pos_totals, 0, sizeof(pos_totals));
  ICOORD pos = start;
  ICOORD tail_pos = pos;
  // tail_pos is the trailing position, with the next point to be lost from
  // the window.
  tail_pos -= step(stepcount - 1);
  tail_pos -= step(stepcount - 2);
  // head_pos is the leading position, with the next point to be added to the
  // window.
  ICOORD head_pos = tail_pos;
  // Set up the initial window with 4 points in [-2, 2)
  for (int s = -2; s < 2; ++s) {
    increment_step(s, 1, &head_pos, dir_counts, pos_totals);
  }
  for (int s = 0; s < stepcount; pos += step(s++)) {
    // At step s, s in in the middle of [s-2, s+2].
    increment_step(s + 2, 1, &head_pos, dir_counts, pos_totals);
    int dir_index = chain_code(s);
    ICOORD step_vec = step(s);
    int best_diff = 0;
    int offset = 0;
    // Use only steps that have a count of >=2 OR the strong U-turn with a
    // single d and 2 at d-1 and 2 at d+1 (mod 4).
    if (dir_counts[dir_index] >= 2 || (dir_counts[dir_index] == 1 &&
        dir_counts[Modulo(dir_index - 1, 4)] == 2 &&
        dir_counts[Modulo(dir_index + 1, 4)] == 2)) {
      // Valid step direction.
      best_diff = dir_counts[dir_index];
      int edge_pos = step_vec.x() == 0 ? pos.x() : pos.y();
      // The offset proposes that the actual step should be positioned at
      // the mean position of the steps in the window of the same direction.
      // See ASCII art above.
      offset = pos_totals[dir_index] - best_diff * edge_pos;
    }
    offsets[s].offset_numerator =
        static_cast<inT8>(ClipToRange(offset, -MAX_INT8, MAX_INT8));
    offsets[s].pixel_diff = static_cast<uinT8>(ClipToRange(best_diff, 0 ,
                                                           MAX_UINT8));
    // The direction is just the vector from start to end of the window.
    FCOORD direction(head_pos.x() - tail_pos.x(), head_pos.y() - tail_pos.y());
    offsets[s].direction = direction.to_direction();
    increment_step(s - 2, -1, &tail_pos, dir_counts, pos_totals);
  }
}
void C_OUTLINE::ComputeEdgeOffsets ( int  threshold,
Pix *  pix 
)

Definition at line 722 of file coutln.cpp.

                                                          {
  if (pixGetDepth(pix) != 8) return;
  const l_uint32* data = pixGetData(pix);
  int wpl = pixGetWpl(pix);
  int width = pixGetWidth(pix);
  int height = pixGetHeight(pix);
  bool negative = flag(COUT_INVERSE);
  delete [] offsets;
  offsets = new EdgeOffset[stepcount];
  ICOORD pos = start;
  ICOORD prev_gradient;
  ComputeGradient(data, wpl, pos.x(), height - pos.y(), width, height,
                  &prev_gradient);
  for (int s = 0; s < stepcount; ++s) {
    ICOORD step_vec = step(s);
    TPOINT pt1(pos);
    pos += step_vec;
    TPOINT pt2(pos);
    ICOORD next_gradient;
    ComputeGradient(data, wpl, pos.x(), height - pos.y(), width, height,
                    &next_gradient);
    // Use the sum of the prev and next as the working gradient.
    ICOORD gradient = prev_gradient + next_gradient;
    // best_diff will be manipulated to be always positive.
    int best_diff = 0;
    // offset will be the extrapolation of the location of the greyscale
    // threshold from the edge with the largest difference, relative to the
    // location of the binary edge.
    int offset = 0;
    if (pt1.y == pt2.y && abs(gradient.y()) * 2 >= abs(gradient.x())) {
      // Horizontal step. diff_sign == 1 indicates black above.
      int diff_sign = (pt1.x > pt2.x) == negative ? 1 : -1;
      int x = MIN(pt1.x, pt2.x);
      int y = height - pt1.y;
      int best_sum = 0;
      int best_y = y;
      EvaluateVerticalDiff(data, wpl, diff_sign, x, y, height,
                           &best_diff, &best_sum, &best_y);
      // Find the strongest edge.
      int test_y = y;
      do {
        ++test_y;
      } while (EvaluateVerticalDiff(data, wpl, diff_sign, x, test_y, height,
                                    &best_diff, &best_sum, &best_y));
      test_y = y;
      do {
        --test_y;
      } while (EvaluateVerticalDiff(data, wpl, diff_sign, x, test_y, height,
                                    &best_diff, &best_sum, &best_y));
      offset = diff_sign * (best_sum / 2 - threshold) +
          (y - best_y) * best_diff;
    } else if (pt1.x == pt2.x && abs(gradient.x()) * 2 >= abs(gradient.y())) {
      // Vertical step. diff_sign == 1 indicates black on the left.
      int diff_sign = (pt1.y > pt2.y) == negative ? 1 : -1;
      int x = pt1.x;
      int y = height - MAX(pt1.y, pt2.y);
      const l_uint32* line = pixGetData(pix) + y * wpl;
      int best_sum = 0;
      int best_x = x;
      EvaluateHorizontalDiff(line, diff_sign, x, width,
                             &best_diff, &best_sum, &best_x);
      // Find the strongest edge.
      int test_x = x;
      do {
        ++test_x;
      } while (EvaluateHorizontalDiff(line, diff_sign, test_x, width,
                                      &best_diff, &best_sum, &best_x));
      test_x = x;
      do {
        --test_x;
      } while (EvaluateHorizontalDiff(line, diff_sign, test_x, width,
                                      &best_diff, &best_sum, &best_x));
      offset = diff_sign * (threshold - best_sum / 2) +
          (best_x - x) * best_diff;
    }
    offsets[s].offset_numerator =
        static_cast<inT8>(ClipToRange(offset, -MAX_INT8, MAX_INT8));
    offsets[s].pixel_diff = static_cast<uinT8>(ClipToRange(best_diff, 0 ,
                                                           MAX_UINT8));
    if (negative) gradient = -gradient;
    // Compute gradient angle quantized to 256 directions, rotated by 64 (pi/2)
    // to convert from gradient direction to edge direction.
    offsets[s].direction =
        Modulo(FCOORD::binary_angle_plus_pi(gradient.angle()) + 64, 256);
    prev_gradient = next_gradient;
  }
}

Definition at line 342 of file coutln.cpp.

                                    {
  BOOL8 first_was_max_x;         //what was first
  BOOL8 first_was_max_y;
  BOOL8 looking_for_max_x;       //what is next
  BOOL8 looking_for_min_x;
  BOOL8 looking_for_max_y;       //what is next
  BOOL8 looking_for_min_y;
  int stepindex;                 //current step
  inT32 total_steps;             //steps to do
                                 //current limits
  inT32 max_x, min_x, max_y, min_y;
  inT32 initial_x, initial_y;    //initial limits
  inT32 total;                   //total changes
  ICOORD pos;                    //position of point
  ICOORD next_step;              //step to next pix

  pos = start_pos ();
  total_steps = pathlength ();
  total = 0;
  max_x = min_x = pos.x ();
  max_y = min_y = pos.y ();
  looking_for_max_x = TRUE;
  looking_for_min_x = TRUE;
  looking_for_max_y = TRUE;
  looking_for_min_y = TRUE;
  first_was_max_x = FALSE;
  first_was_max_y = FALSE;
  initial_x = pos.x ();
  initial_y = pos.y ();          //stop uninit warning
  for (stepindex = 0; stepindex < total_steps; stepindex++) {
                                 //all intersected
    next_step = step (stepindex);
    pos += next_step;
    if (next_step.x () < 0) {
      if (looking_for_max_x && pos.x () < min_x)
        min_x = pos.x ();
      if (looking_for_min_x && max_x - pos.x () > threshold) {
        if (looking_for_max_x) {
          initial_x = max_x;
          first_was_max_x = FALSE;
        }
        total++;
        looking_for_max_x = TRUE;
        looking_for_min_x = FALSE;
        min_x = pos.x ();        //reset min
      }
    }
    else if (next_step.x () > 0) {
      if (looking_for_min_x && pos.x () > max_x)
        max_x = pos.x ();
      if (looking_for_max_x && pos.x () - min_x > threshold) {
        if (looking_for_min_x) {
          initial_x = min_x;     //remember first min
          first_was_max_x = TRUE;
        }
        total++;
        looking_for_max_x = FALSE;
        looking_for_min_x = TRUE;
        max_x = pos.x ();
      }
    }
    else if (next_step.y () < 0) {
      if (looking_for_max_y && pos.y () < min_y)
        min_y = pos.y ();
      if (looking_for_min_y && max_y - pos.y () > threshold) {
        if (looking_for_max_y) {
          initial_y = max_y;     //remember first max
          first_was_max_y = FALSE;
        }
        total++;
        looking_for_max_y = TRUE;
        looking_for_min_y = FALSE;
        min_y = pos.y ();        //reset min
      }
    }
    else {
      if (looking_for_min_y && pos.y () > max_y)
        max_y = pos.y ();
      if (looking_for_max_y && pos.y () - min_y > threshold) {
        if (looking_for_min_y) {
          initial_y = min_y;     //remember first min
          first_was_max_y = TRUE;
        }
        total++;
        looking_for_max_y = FALSE;
        looking_for_min_y = TRUE;
        max_y = pos.y ();
      }
    }

  }
  if (first_was_max_x && looking_for_min_x) {
    if (max_x - initial_x > threshold)
      total++;
    else
      total--;
  }
  else if (!first_was_max_x && looking_for_max_x) {
    if (initial_x - min_x > threshold)
      total++;
    else
      total--;
  }
  if (first_was_max_y && looking_for_min_y) {
    if (max_y - initial_y > threshold)
      total++;
    else
      total--;
  }
  else if (!first_was_max_y && looking_for_max_y) {
    if (initial_y - min_y > threshold)
      total++;
    else
      total--;
  }

  return total;
}
static C_OUTLINE* C_OUTLINE::deep_copy ( const C_OUTLINE src) [inline, static]

Definition at line 259 of file coutln.h.

                                                      {
      C_OUTLINE* outline = new C_OUTLINE;
      *outline = *src;
      return outline;
    }
int C_OUTLINE::direction_at_index ( int  index) const [inline]

Definition at line 176 of file coutln.h.

                                            {
      if (offsets != NULL && offsets[index].pixel_diff > 0)
        return offsets[index].direction;
      return -1;
    }
int C_OUTLINE::edge_strength_at_index ( int  index) const [inline]

Definition at line 185 of file coutln.h.

                                                {
      if (offsets != NULL)
        return offsets[index].pixel_diff;
      return 1;
    }
void C_OUTLINE::FakeOutline ( const TBOX box,
C_OUTLINE_LIST *  outlines 
) [static]

Definition at line 240 of file coutln.cpp.

                                                                     {
  C_OUTLINE_IT ol_it(outlines);
  // Make a C_OUTLINE from the bounds. This is a bit of a hack,
  // as there is no outline, just a bounding box, but it works nicely.
  CRACKEDGE start;
  start.pos = box.topleft();
  C_OUTLINE* outline = new C_OUTLINE(&start, box.topleft(), box.botright(), 0);
  ol_it.add_to_end(outline);
}
BOOL8 C_OUTLINE::flag ( C_OUTLINE_FLAGS  mask) const [inline]

Definition at line 96 of file coutln.h.

                                           {  //flag to test
      return flags.bit (mask);
    }

Definition at line 615 of file coutln.cpp.

                                      {
  if (stepcount == 0) return true;
  int parent_area = outer_area();
  // We aren't going to modify the list, or its contents, but there is
  // no const iterator.
  C_OUTLINE_IT child_it(const_cast<C_OUTLINE_LIST*>(&children));
  for (child_it.mark_cycle_pt(); !child_it.cycled_list(); child_it.forward()) {
    const C_OUTLINE* child = child_it.data();
    if (child->outer_area() * parent_area > 0 || !child->IsLegallyNested())
      return false;
  }
  return true;
}
void C_OUTLINE::move ( const ICOORD  vec)

Definition at line 599 of file coutln.cpp.

                      {
  C_OUTLINE_IT it(&children);  // iterator

  box.move (vec);
  start += vec;

  for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ())
    it.data ()->move (vec);      // move child outlines
}
BOOL8 C_OUTLINE::operator< ( const C_OUTLINE other) const

Definition at line 471 of file coutln.cpp.

{
  inT16 count = 0;               //winding count
  ICOORD pos;                    //position of point
  inT32 stepindex;               //index to cstep

  if (!box.overlap (other.box))
    return FALSE;                //can't be contained
  if (stepcount == 0)
    return other.box.contains(this->box);

  pos = start;
  for (stepindex = 0; stepindex < stepcount
    && (count = other.winding_number (pos)) == INTERSECTING; stepindex++)
    pos += step (stepindex);     //try all points
  if (count == INTERSECTING) {
                                 //all intersected
    pos = other.start;
    for (stepindex = 0; stepindex < other.stepcount
      && (count = winding_number (pos)) == INTERSECTING; stepindex++)
                                 //try other way round
      pos += other.step (stepindex);
    return count == INTERSECTING || count == 0;
  }
  return count != 0;
}
C_OUTLINE & C_OUTLINE::operator= ( const C_OUTLINE source)

Definition at line 1000 of file coutln.cpp.

  {
  box = source.box;
  start = source.start;
  if (steps != NULL)
    free_mem(steps);
  stepcount = source.stepcount;
  steps = (uinT8 *) alloc_mem (step_mem());
  memmove (steps, source.steps, step_mem());
  if (!children.empty ())
    children.clear ();
  children.deep_copy(&source.children, &deep_copy);
  delete [] offsets;
  if (source.offsets != NULL) {
    offsets = new EdgeOffset[stepcount];
    memcpy(offsets, source.offsets, stepcount * sizeof(*offsets));
  } else {
    offsets = NULL;
  }
  return *this;
}
BOOL8 C_OUTLINE::operator> ( C_OUTLINE other) const [inline]

Definition at line 205 of file coutln.h.

    {
      return other < *this;      //use the < to do it
    }

Definition at line 310 of file coutln.cpp.

                                  {
  int stepindex;                 //current step
  inT32 total_steps;             //steps to do
  inT32 total;                   //total area
  ICOORD pos;                    //position of point
  ICOORD next_step;              //step to next pix

  pos = start_pos ();
  total_steps = pathlength ();
  if (total_steps == 0)
    return box.area();
  total = 0;
  for (stepindex = 0; stepindex < total_steps; stepindex++) {
                                 //all intersected
    next_step = step (stepindex);
    if (next_step.x () < 0)
      total += pos.y ();
    else if (next_step.x () > 0)
      total -= pos.y ();
    pos += next_step;
  }

  return total;
}
inT32 C_OUTLINE::pathlength ( ) const [inline]

Definition at line 133 of file coutln.h.

                             {  //get path length
      return stepcount;
    }

Definition at line 290 of file coutln.cpp.

                                 {
  inT32 total_steps;             // Return value.
  // We aren't going to modify the list, or its contents, but there is
  // no const iterator.
  C_OUTLINE_IT it(const_cast<C_OUTLINE_LIST*>(&children));

  total_steps = pathlength();
  for (it.mark_cycle_pt(); !it.cycled_list(); it.forward())
    total_steps += it.data()->pathlength();  // Add perimeters of children.

  return total_steps;
}
void C_OUTLINE::plot ( ScrollView window,
ScrollView::Color  colour 
) const

Definition at line 931 of file coutln.cpp.

                            {
  inT16 stepindex;               // index to cstep
  ICOORD pos;                    // current position
  DIR128 stepdir;                // direction of step

  pos = start;                   // current position
  window->Pen(colour);
  if (stepcount == 0) {
    window->Rectangle(box.left(), box.top(), box.right(), box.bottom());
    return;
  }
  window->SetCursor(pos.x(), pos.y());

  stepindex = 0;
  while (stepindex < stepcount) {
    pos += step(stepindex);    // step to next
    stepdir = step_dir(stepindex);
    stepindex++;               // count steps
    // merge straight lines
    while (stepindex < stepcount &&
           stepdir.get_dir() == step_dir(stepindex).get_dir()) {
      pos += step(stepindex);
      stepindex++;
    }
    window->DrawTo(pos.x(), pos.y());
  }
}
void C_OUTLINE::plot_normed ( const DENORM denorm,
ScrollView::Color  colour,
ScrollView window 
) const

Definition at line 963 of file coutln.cpp.

                                                      {
  window->Pen(colour);
  if (stepcount == 0) {
    window->Rectangle(box.left(), box.top(), box.right(), box.bottom());
    return;
  }
  const DENORM* root_denorm = denorm.RootDenorm();
  ICOORD pos = start;                   // current position
  FCOORD f_pos = sub_pixel_pos_at_index(pos, 0);
  FCOORD pos_normed;
  denorm.NormTransform(root_denorm, f_pos, &pos_normed);
  window->SetCursor(IntCastRounded(pos_normed.x()),
                    IntCastRounded(pos_normed.y()));
  for (int s = 0; s < stepcount; pos += step(s++)) {
    int edge_weight = edge_strength_at_index(s);
    if (edge_weight == 0) {
      // This point has conflicting gradient and step direction, so ignore it.
      continue;
    }
    FCOORD f_pos = sub_pixel_pos_at_index(pos, s);
    FCOORD pos_normed;
    denorm.NormTransform(root_denorm, f_pos, &pos_normed);
    window->DrawTo(IntCastRounded(pos_normed.x()),
                   IntCastRounded(pos_normed.y()));
  }
}
ICOORD C_OUTLINE::position_at_index ( int  index) const [inline]

Definition at line 151 of file coutln.h.

                                              {
      ICOORD pos = start;
      for (int i = 0; i < index; ++i)
        pos += step(i);
      return pos;
    }
void C_OUTLINE::RemoveSmallRecursive ( int  min_size,
C_OUTLINE_IT *  it 
)

Definition at line 634 of file coutln.cpp.

                                                                   {
  if (box.width() < min_size || box.height() < min_size) {
    ASSERT_HOST(this == it->data());
    delete it->extract();  // Too small so get rid of it and any children.
  } else if (!children.empty()) {
    // Search the children of this, deleting any that are too small.
    C_OUTLINE_IT child_it(&children);
    for (child_it.mark_cycle_pt(); !child_it.cycled_list();
         child_it.forward()) {
      C_OUTLINE* child = child_it.data();
      child->RemoveSmallRecursive(min_size, &child_it);
    }
  }
}
void C_OUTLINE::render ( int  left,
int  top,
Pix *  pix 
) const

Definition at line 890 of file coutln.cpp.

                                                        {
  ICOORD pos = start;
  for (int stepindex = 0; stepindex < stepcount; ++stepindex) {
    ICOORD next_step = step(stepindex);
    if (next_step.y() < 0) {
      pixRasterop(pix, 0, top - pos.y(), pos.x() - left, 1,
                  PIX_NOT(PIX_DST), NULL, 0, 0);
    } else if (next_step.y() > 0) {
      pixRasterop(pix, 0, top - pos.y() - 1, pos.x() - left, 1,
                  PIX_NOT(PIX_DST), NULL, 0, 0);
    }
    pos += next_step;
  }
}
void C_OUTLINE::render_outline ( int  left,
int  top,
Pix *  pix 
) const

Definition at line 907 of file coutln.cpp.

                                                                {
  ICOORD pos = start;
  for (int stepindex = 0; stepindex < stepcount; ++stepindex) {
    ICOORD next_step = step(stepindex);
    if (next_step.y() < 0) {
      pixSetPixel(pix, pos.x() - left, top - pos.y(), 1);
    } else if (next_step.y() > 0) {
      pixSetPixel(pix, pos.x() - left - 1, top - pos.y() - 1, 1);
    } else if (next_step.x() < 0) {
      pixSetPixel(pix, pos.x() - left - 1, top - pos.y(), 1);
    } else if (next_step.x() > 0) {
      pixSetPixel(pix, pos.x() - left, top - pos.y() - 1, 1);
    }
    pos += next_step;
  }
}

Definition at line 576 of file coutln.cpp.

                        {  //reverse drection
  DIR128 halfturn = MODULUS / 2; //amount to shift
  DIR128 stepdir;                //direction of step
  inT16 stepindex;               //index to cstep
  inT16 farindex;                //index to other side
  inT16 halfsteps;               //half of stepcount

  halfsteps = (stepcount + 1) / 2;
  for (stepindex = 0; stepindex < halfsteps; stepindex++) {
    farindex = stepcount - stepindex - 1;
    stepdir = step_dir (stepindex);
    set_step (stepindex, step_dir (farindex) + halfturn);
    set_step (farindex, stepdir + halfturn);
  }
}
void C_OUTLINE::set_flag ( C_OUTLINE_FLAGS  mask,
BOOL8  value 
) [inline]

Definition at line 100 of file coutln.h.

                               {         //value to set
      flags.set_bit (mask, value);
    }
void C_OUTLINE::set_step ( inT16  stepindex,
inT8  stepdir 
) [inline]

Definition at line 114 of file coutln.h.

                                {     //chain code
      int shift = stepindex%4 * 2;
      uinT8 mask = 3 << shift;
      steps[stepindex/4] = ((stepdir << shift) & mask) |
                           (steps[stepindex/4] & ~mask);
      //squeeze 4 into byte
    }
void C_OUTLINE::set_step ( inT16  stepindex,
DIR128  stepdir 
) [inline]

Definition at line 123 of file coutln.h.

                                  {   //direction
                                 //clean it
      inT8 chaindir = stepdir.get_dir() >> (DIRBITS - 2);
                                 //difference
      set_step(stepindex, chaindir);
      //squeeze 4 into byte
    }
const ICOORD& C_OUTLINE::start_pos ( ) const [inline]

Definition at line 146 of file coutln.h.

                                    {
      return start;
    }
ICOORD C_OUTLINE::step ( int  index) const [inline]

Definition at line 142 of file coutln.h.

                                 { // index of step
      return step_coords[chain_code(index)];
    }
DIR128 C_OUTLINE::step_dir ( int  index) const [inline]

Definition at line 137 of file coutln.h.

                                     {
      return DIR128((inT16)(((steps[index/4] >> (index%4 * 2)) & STEP_MASK) <<
                      (DIRBITS - 2)));
    }
FCOORD C_OUTLINE::sub_pixel_pos_at_index ( const ICOORD pos,
int  index 
) const [inline]

Definition at line 161 of file coutln.h.

                                                                      {
      const ICOORD& step_to_next(step(index));
      FCOORD f_pos(pos.x() + step_to_next.x() / 2.0f,
                   pos.y() + step_to_next.y() / 2.0f);
      if (offsets != NULL && offsets[index].pixel_diff > 0) {
        float offset = offsets[index].offset_numerator;
        offset /= offsets[index].pixel_diff;
        if (step_to_next.x() != 0)
          f_pos.set_y(f_pos.y() + offset);
        else
          f_pos.set_x(f_pos.x() + offset);
      }
      return f_pos;
    }

Definition at line 547 of file coutln.cpp.

                                      {  //winding number
  DIR128 prevdir;                //previous direction
  DIR128 dir;                    //current direction
  inT16 stepindex;               //index to cstep
  inT8 dirdiff;                  //direction difference
  inT16 count;                   //winding count

  if (stepcount == 0)
    return 128;
  count = 0;
  prevdir = step_dir (stepcount - 1);
  for (stepindex = 0; stepindex < stepcount; stepindex++) {
    dir = step_dir (stepindex);
    dirdiff = dir - prevdir;
    ASSERT_HOST (dirdiff == 0 || dirdiff == 32 || dirdiff == -32);
    count += dirdiff;
    prevdir = dir;
  }
  ASSERT_HOST (count == 128 || count == -128);
  return count;                  //winding number
}

Definition at line 507 of file coutln.cpp.

                                       {
  inT16 stepindex;               //index to cstep
  inT16 count;                   //winding count
  ICOORD vec;                    //to current point
  ICOORD stepvec;                //step vector
  inT32 cross;                   //cross product

  vec = start - point;           //vector to it
  count = 0;
  for (stepindex = 0; stepindex < stepcount; stepindex++) {
    stepvec = step (stepindex);  //get the step
                                 //crossing the line
    if (vec.y () <= 0 && vec.y () + stepvec.y () > 0) {
      cross = vec * stepvec;     //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 () + stepvec.y () <= 0) {
      cross = vec * stepvec;
      if (cross < 0)
        count--;                 //crossing back
      else if (cross == 0)
        return INTERSECTING;     //illegal
    }
    vec += stepvec;              //sum vectors
  }
  return count;                  //winding number
}

Member Data Documentation

const int C_OUTLINE::kMaxOutlineLength = 16000 [static]

Definition at line 271 of file coutln.h.


The documentation for this class was generated from the following files:
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