tesseract/ccstruct/coutln.cpp

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/**********************************************************************
* File: coutln.c (Formerly coutline.c)
* Description: Code for the C_OUTLINE class.
* Author: Ray Smith
* Created: Mon Oct 07 16:01:57 BST 1991
*
* (C) Copyright 1991, 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 "mfcpch.h"
#include <string.h>
#ifdef __UNIX__
#include <assert.h>
#endif
#include "coutln.h"
ELISTIZE_S (C_OUTLINE)
ICOORD C_OUTLINE::step_coords[4] = {
ICOORD (-1, 0), ICOORD (0, -1), ICOORD (1, 0), ICOORD (0, 1)
};
/**********************************************************************
* C_OUTLINE::C_OUTLINE
*
* Constructor to build a C_OUTLINE from a CRACKEDGE LOOP.
**********************************************************************/
C_OUTLINE::C_OUTLINE (
//constructor
CRACKEDGE * startpt, //outline to convert
ICOORD bot_left, //bounding box
ICOORD top_right, INT16 length //length of loop
):box (bot_left, top_right), start (startpt->pos) {
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
*
* Constructor to build a C_OUTLINE from a C_OUTLINE_FRAG.
**********************************************************************/
C_OUTLINE::C_OUTLINE (
//constructor
//steps to copy
ICOORD startpt, DIR128 * new_steps,
INT16 length //length of loop
):start (startpt) {
INT8 dirdiff; //direction difference
DIR128 prevdir; //previous direction
DIR128 dir; //current direction
DIR128 lastdir; //dir of last step
BOX new_box; //easy bounding
INT16 stepindex; //index to step
INT16 srcindex; //source steps
ICOORD pos; //current position
pos = startpt;
stepcount = length; //no of steps
//get memory
steps = (UINT8 *) alloc_mem (step_mem());
memset(steps, 0, step_mem());
lastdir = new_steps[length - 1];
prevdir = lastdir;
for (stepindex = 0, srcindex = 0; srcindex < length;
stepindex++, srcindex++) {
new_box = BOX (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
*
* Constructor to build a C_OUTLINE from a rotation of a C_OUTLINE.
**********************************************************************/
C_OUTLINE::C_OUTLINE( //constructor
C_OUTLINE *srcline, //outline to
FCOORD rotation //rotate
) {
BOX 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;
//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 = BOX (start, start);
destindex = 0;
for (stepindex = 0; stepindex < srcline->stepcount; stepindex++) {
pos += srcline->step (stepindex);
destpos = pos;
destpos.rotate (rotation);
if (destpos.x () != prevpos.x () || destpos.y () != prevpos.y ()) {
dir = DIR128 (FCOORD (destpos - prevpos));
dir += 64; //turn to step style
new_step = dir.get_dir ();
if (new_step & 31) {
set_step(destindex++, dir + round1);
if (destindex < 2
|| ((dirdiff =
step_dir (destindex - 1) - step_dir (destindex - 2)) !=
-64 && dirdiff != 64))
set_step(destindex++, dir + round2);
else {
set_step(destindex - 1, dir + round2);
set_step(destindex++, dir + round1);
}
}
else {
set_step(destindex++, dir);
if (destindex >= 2
&&
((dirdiff =
step_dir (destindex - 1) - step_dir (destindex - 2)) ==
-64 || dirdiff == 64))
destindex -= 2; // Forget u turn
}
prevpos = destpos;
new_box = BOX (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;
}
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::area
*
* Compute the area of the outline.
**********************************************************************/
INT32 C_OUTLINE::area() { //winding number
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
C_OUTLINE_IT it = child ();
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;
}
/**********************************************************************
* C_OUTLINE::outer_area
*
* Compute the area of the outline.
**********************************************************************/
INT32 C_OUTLINE::outer_area() { //winding number
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;
}
/**********************************************************************
* C_OUTLINE::count_transitions
*
* Compute the number of x and y maxes and mins in the outline.
**********************************************************************/
INT32 C_OUTLINE::count_transitions( //winding number
INT32 threshold //on size
) {
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;
}
/**********************************************************************
* C_OUTLINE::operator<
*
* Return TRUE if the left operand is inside the right one.
**********************************************************************/
BOOL8
C_OUTLINE::operator< ( //winding number
const C_OUTLINE & other //other outline
) const
{
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::winding_number
*
* Return the winding number of the outline around the given point.
**********************************************************************/
INT16 C_OUTLINE::winding_number( //winding number
ICOORD point //point to wind around
) const {
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
}
/**********************************************************************
* C_OUTLINE::turn_direction
*
* Return the sum direction delta of the outline.
**********************************************************************/
INT16 C_OUTLINE::turn_direction() const { //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
}
/**********************************************************************
* C_OUTLINE::reverse
*
* Reverse the direction of an outline.
**********************************************************************/
void C_OUTLINE::reverse() { //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);
}
}
/**********************************************************************
* C_OUTLINE::move
*
* Move C_OUTLINE by vector
**********************************************************************/
void C_OUTLINE::move( // reposition OUTLINE
const ICOORD vec // by vector
) {
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
}
/**********************************************************************
* C_OUTLINE::plot
*
* Draw the outline in the given colour.
**********************************************************************/
#ifndef GRAPHICS_DISABLED
void C_OUTLINE::plot( //draw it
ScrollView* window, //window to draw in
ScrollView::Color colour //colour to draw in
) const {
INT16 stepindex; //index to cstep
ICOORD pos; //current position
DIR128 stepdir; //direction of step
DIR128 oldstepdir; //previous stepdir
pos = start; //current position
window->Pen(colour);
window->SetCursor(pos.x(), pos.y());
stepindex = 0;
stepdir = step_dir (0); //get direction
while (stepindex < stepcount) {
do {
pos += step (stepindex); //step to next
stepindex++; //count steps
oldstepdir = stepdir;
//new direction
stepdir = step_dir (stepindex);
}
while (stepindex < stepcount
&& oldstepdir.get_dir () == stepdir.get_dir ());
//merge straight lines
window->DrawTo(pos.x(), pos.y());
}
}
#endif
/**********************************************************************
* C_OUTLINE::operator=
*
* Assignment - deep copy data
**********************************************************************/
//assignment
C_OUTLINE & C_OUTLINE::operator= (
const C_OUTLINE & source //from this
) {
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);
return *this;
}