tesseract/wordrec/seam.cpp

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/* -*-C-*-
********************************************************************************
*
* File: seam.c (Formerly seam.c)
* Description:
* Author: Mark Seaman, OCR Technology
* Created: Fri Oct 16 14:37:00 1987
* Modified: Fri May 17 16:30:13 1991 (Mark Seaman) marks@hpgrlt
* Language: C
* Package: N/A
* Status: Reusable Software Component
*
* (c) Copyright 1987, Hewlett-Packard Company.
** 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.
*
*********************************************************************************/
/*----------------------------------------------------------------------
I n c l u d e s
----------------------------------------------------------------------*/
#include "seam.h"
#include "callcpp.h"
#include "structures.h"
#include "makechop.h"
#ifdef __UNIX__
#include <assert.h>
#endif
/*----------------------------------------------------------------------
V a r i a b l e s
----------------------------------------------------------------------*/
#define NUM_STARTING_SEAMS 20
#define SEAMBLOCK 100 /* Cells per block */
makestructure (newseam, free_seam, printseam, SEAM,
freeseam, SEAMBLOCK, "SEAM", seamcount);
/*----------------------------------------------------------------------
Public Function Code
----------------------------------------------------------------------*/
/**********************************************************************
* point_in_split
*
* Check to see if either of these points are present in the current
* split. Return TRUE if one of them is.
**********************************************************************/
bool point_in_split(SPLIT *split, EDGEPT *point1, EDGEPT *point2) {
return ((split) ?
((exact_point (split->point1, point1) ||
exact_point (split->point1, point2) ||
exact_point (split->point2, point1) ||
exact_point (split->point2, point2)) ? TRUE : FALSE) : FALSE);
}
/**********************************************************************
* point_in_seam
*
* Check to see if either of these points are present in the current
* seam. Return TRUE if one of them is.
**********************************************************************/
bool point_in_seam(SEAM *seam, SPLIT *split) {
return (point_in_split (seam->split1, split->point1, split->point2) ||
point_in_split (seam->split2, split->point1, split->point2) ||
point_in_split (seam->split3, split->point1, split->point2));
}
/**********************************************************************
* add_seam
*
* Add another seam to a collection of seams.
**********************************************************************/
SEAMS add_seam(SEAMS seam_list, SEAM *seam) {
return (array_push (seam_list, seam));
}
/**********************************************************************
* combine_seam
*
* Combine two seam records into a single seam. Move the split
* references from the second seam to the first one. The argument
* convention is patterned after strcpy.
**********************************************************************/
void combine_seams(SEAM *dest_seam, SEAM *source_seam) {
dest_seam->priority += source_seam->priority;
dest_seam->location += source_seam->location;
dest_seam->location /= 2;
if (source_seam->split1) {
if (!dest_seam->split1)
dest_seam->split1 = source_seam->split1;
else if (!dest_seam->split2)
dest_seam->split2 = source_seam->split1;
else if (!dest_seam->split3)
dest_seam->split3 = source_seam->split1;
else
cprintf ("combine_seam: Seam is too crowded, can't be combined !\n");
}
if (source_seam->split2) {
if (!dest_seam->split2)
dest_seam->split2 = source_seam->split2;
else if (!dest_seam->split3)
dest_seam->split3 = source_seam->split2;
else
cprintf ("combine_seam: Seam is too crowded, can't be combined !\n");
}
if (source_seam->split3) {
if (!dest_seam->split3)
dest_seam->split3 = source_seam->split3;
else
cprintf ("combine_seam: Seam is too crowded, can't be combined !\n");
}
free_seam(source_seam);
}
/**********************************************************************
* delete_seam
*
* Free this seam record and the splits that are attached to it.
**********************************************************************/
void delete_seam(void *arg) { //SEAM *seam)
SEAM *seam = (SEAM *) arg;
if (seam) {
if (seam->split1)
delete_split (seam->split1);
if (seam->split2)
delete_split (seam->split2);
if (seam->split3)
delete_split (seam->split3);
free_seam(seam);
}
}
/**********************************************************************
* free_seam_list
*
* Free all the seams that have been allocated in this list. Reclaim
* the memory for each of the splits as well.
**********************************************************************/
void free_seam_list(SEAMS seam_list) {
int x;
array_loop (seam_list, x) delete_seam (array_value (seam_list, x));
array_free(seam_list);
}
/**********************************************************************
* test_insert_seam
*
* Return true if insert_seam will succeed.
**********************************************************************/
bool test_insert_seam(SEAMS seam_list,
int index,
TBLOB *left_blob,
TBLOB *first_blob) {
SEAM *test_seam;
TBLOB *blob;
int test_index;
int list_length;
list_length = array_count (seam_list);
for (test_index = 0, blob = first_blob->next;
test_index < index; test_index++, blob = blob->next) {
test_seam = (SEAM *) array_value (seam_list, test_index);
if (test_index + test_seam->widthp < index &&
test_seam->widthp + test_index == index - 1 &&
account_splits_right(test_seam, blob) < 0)
return false;
}
for (test_index = index, blob = left_blob->next;
test_index < list_length; test_index++, blob = blob->next) {
test_seam = (SEAM *) array_value (seam_list, test_index);
if (test_index - test_seam->widthn >= index &&
test_index - test_seam->widthn == index &&
account_splits_left(test_seam, first_blob, blob) < 0)
return false;
}
return true;
}
/**********************************************************************
* insert_seam
*
* Add another seam to a collection of seams at a particular location
* in the seam array.
**********************************************************************/
SEAMS insert_seam(SEAMS seam_list,
int index,
SEAM *seam,
TBLOB *left_blob,
TBLOB *first_blob) {
SEAM *test_seam;
TBLOB *blob;
int test_index;
int list_length;
list_length = array_count (seam_list);
for (test_index = 0, blob = first_blob->next;
test_index < index; test_index++, blob = blob->next) {
test_seam = (SEAM *) array_value (seam_list, test_index);
if (test_index + test_seam->widthp >= index) {
test_seam->widthp++; /*got in the way */
}
else if (test_seam->widthp + test_index == index - 1) {
test_seam->widthp = account_splits_right(test_seam, blob);
if (test_seam->widthp < 0) {
cprintf ("Failed to find any right blob for a split!\n");
print_seam("New dud seam", seam);
print_seam("Failed seam", test_seam);
}
}
}
for (test_index = index, blob = left_blob->next;
test_index < list_length; test_index++, blob = blob->next) {
test_seam = (SEAM *) array_value (seam_list, test_index);
if (test_index - test_seam->widthn < index) {
test_seam->widthn++; /*got in the way */
}
else if (test_index - test_seam->widthn == index) {
test_seam->widthn = account_splits_left(test_seam, first_blob, blob);
if (test_seam->widthn < 0) {
cprintf ("Failed to find any left blob for a split!\n");
print_seam("New dud seam", seam);
print_seam("Failed seam", test_seam);
}
}
}
return (array_insert (seam_list, index, seam));
}
/**********************************************************************
* account_splits_right
*
* Account for all the splits by looking to the right.
* in the blob list.
**********************************************************************/
int account_splits_right(SEAM *seam, TBLOB *blob) {
INT8 found_em[3];
INT8 width;
found_em[0] = seam->split1 == NULL;
found_em[1] = seam->split2 == NULL;
found_em[2] = seam->split3 == NULL;
if (found_em[0] && found_em[1] && found_em[2])
return 0;
width = 0;
do {
if (!found_em[0])
found_em[0] = find_split_in_blob (seam->split1, blob);
if (!found_em[1])
found_em[1] = find_split_in_blob (seam->split2, blob);
if (!found_em[2])
found_em[2] = find_split_in_blob (seam->split3, blob);
if (found_em[0] && found_em[1] && found_em[2]) {
return width;
}
width++;
blob = blob->next;
}
while (blob != NULL);
return -1;
}
/**********************************************************************
* account_splits_left
*
* Account for all the splits by looking to the left.
* in the blob list.
**********************************************************************/
int account_splits_left(SEAM *seam, TBLOB *blob, TBLOB *end_blob) {
static INT32 depth = 0;
static INT8 width;
static INT8 found_em[3];
if (blob != end_blob) {
depth++;
account_splits_left (seam, blob->next, end_blob);
depth--;
}
else {
found_em[0] = seam->split1 == NULL;
found_em[1] = seam->split2 == NULL;
found_em[2] = seam->split3 == NULL;
width = 0;
}
if (!found_em[0])
found_em[0] = find_split_in_blob (seam->split1, blob);
if (!found_em[1])
found_em[1] = find_split_in_blob (seam->split2, blob);
if (!found_em[2])
found_em[2] = find_split_in_blob (seam->split3, blob);
if (!found_em[0] || !found_em[1] || !found_em[2]) {
width++;
if (depth == 0) {
width = -1;
}
}
return width;
}
/**********************************************************************
* find_split_in_blob
*
* Return TRUE if the split is somewhere in this blob.
**********************************************************************/
bool find_split_in_blob(SPLIT *split, TBLOB *blob) {
TESSLINE *outline;
#if 0
for (outline = blob->outlines; outline != NULL; outline = outline->next)
if (is_split_outline (outline, split))
return TRUE;
return FALSE;
#endif
for (outline = blob->outlines; outline != NULL; outline = outline->next)
if (point_in_outline(split->point1, outline))
break;
if (outline == NULL)
return FALSE;
for (outline = blob->outlines; outline != NULL; outline = outline->next)
if (point_in_outline(split->point2, outline))
return TRUE;
return FALSE;
}
/**********************************************************************
* join_two_seams
*
* Merge these two seams into a new seam. Duplicate the split records
* in both of the input seams. Return the resultant seam.
**********************************************************************/
SEAM *join_two_seams(SEAM *seam1, SEAM *seam2) {
SEAM *result = NULL;
SEAM *temp;
assert(seam1 &&seam2);
if (((seam1->split3 == NULL && seam2->split2 == NULL) ||
(seam1->split2 == NULL && seam2->split3 == NULL) ||
seam1->split1 == NULL ||
seam2->split1 == NULL) && (!shared_split_points (seam1, seam2))) {
clone_seam(result, seam1);
clone_seam(temp, seam2);
combine_seams(result, temp);
}
return (result);
}
/**********************************************************************
* new_seam
*
* Create a structure for a "seam" between two blobs. This data
* structure may actually hold up to three different splits.
* Initailization of this record is done by this routine.
**********************************************************************/
SEAM *new_seam(PRIORITY priority,
int x_location,
SPLIT *split1,
SPLIT *split2,
SPLIT *split3) {
SEAM *seam;
seam = newseam ();
seam->priority = priority;
seam->location = x_location;
seam->widthp = 0;
seam->widthn = 0;
seam->split1 = split1;
seam->split2 = split2;
seam->split3 = split3;
return (seam);
}
/**********************************************************************
* new_seam_list
*
* Create a collection of seam records in an array.
**********************************************************************/
SEAMS new_seam_list() {
return (array_new (NUM_STARTING_SEAMS));
}
/**********************************************************************
* print_seam
*
* Print a list of splits. Show the coordinates of both points in
* each split.
**********************************************************************/
void print_seam(const char *label, SEAM *seam) {
if (seam) {
cprintf(label);
cprintf (" %6.2f @ %5d, p=%d, n=%d ",
seam->priority, seam->location, seam->widthp, seam->widthn);
print_split (seam->split1);
if (seam->split2) {
cprintf (", ");
print_split (seam->split2);
if (seam->split3) {
cprintf (", ");
print_split (seam->split3);
}
}
cprintf ("\n");
}
}
/**********************************************************************
* print_seams
*
* Print a list of splits. Show the coordinates of both points in
* each split.
**********************************************************************/
void print_seams(const char *label, SEAMS seams) {
int x;
char number[CHARS_PER_LINE];
if (seams) {
cprintf ("%s\n", label);
array_loop(seams, x) {
sprintf (number, "%2d: ", x);
print_seam (number, (SEAM *) array_value (seams, x));
}
cprintf ("\n");
}
}
/**********************************************************************
* shared_split_points
*
* Check these two seams to make sure that neither of them have two
* points in common. Return TRUE if any of the same points are present
* in any of the splits of both seams.
**********************************************************************/
int shared_split_points(SEAM *seam1, SEAM *seam2) {
if (seam1 == NULL || seam2 == NULL)
return (FALSE);
if (seam2->split1 == NULL)
return (FALSE);
if (point_in_seam (seam1, seam2->split1))
return (TRUE);
if (seam2->split2 == NULL)
return (FALSE);
if (point_in_seam (seam1, seam2->split2))
return (TRUE);
if (seam2->split3 == NULL)
return (FALSE);
if (point_in_seam (seam1, seam2->split3))
return (TRUE);
return (FALSE);
}