tesseract/textord/gap_map.cpp

174 lines
5.8 KiB
C++
Raw Normal View History

#include "statistc.h"
#include "gap_map.h"
#define EXTERN
EXTERN BOOL_VAR (gapmap_debug, FALSE, "Say which blocks have tables");
EXTERN BOOL_VAR (gapmap_use_ends, FALSE,
"Use large space at start and end of rows");
EXTERN BOOL_VAR (gapmap_no_isolated_quanta, FALSE,
"Ensure gaps not less than 2quanta wide");
EXTERN double_VAR (gapmap_big_gaps, 1.75, "xht multiplier");
/*************************************************************************
* A block gap map is a quantised histogram of whitespace regions in the
* block. It is a vertical projection of wide gaps WITHIN lines
*
* The map is held as an array of counts of rows which have a wide gap
* covering that region of the row. Each bucket in the map represents a width
* of about half an xheight - (The median of the xhts in the rows is used.)
*
* The block is considered RECTANGULAR - delimited by the left and right
* extremes of the rows in the block. However, ONLY wide gaps WITHIN a row are
* counted.
*
*************************************************************************/
GAPMAP::GAPMAP( //Constructor
TO_BLOCK *block //block
) {
TO_ROW_IT row_it; //row iterator
TO_ROW *row; //current row
BLOBNBOX_IT blob_it; //iterator
TBOX blob_box;
TBOX prev_blob_box;
inT16 gap_width;
inT16 start_of_row;
inT16 end_of_row;
STATS xht_stats (0, 128);
inT16 min_quantum;
inT16 max_quantum;
inT16 i;
row_it.set_to_list (block->get_rows ());
/*
Find left and right extremes and bucket size
*/
map = NULL;
min_left = MAX_INT16;
max_right = -MAX_INT16;
total_rows = 0;
any_tabs = FALSE;
for (row_it.mark_cycle_pt (); !row_it.cycled_list (); row_it.forward ()) {
row = row_it.data ();
if (!row->blob_list ()->empty ()) {
total_rows++;
xht_stats.add ((inT16) floor (row->xheight + 0.5), 1);
blob_it.set_to_list (row->blob_list ());
start_of_row = blob_it.data ()->bounding_box ().left ();
end_of_row = blob_it.data_relative (-1)->bounding_box ().right ();
if (min_left > start_of_row)
min_left = start_of_row;
if (max_right < end_of_row)
max_right = end_of_row;
}
}
if ((total_rows < 3) || (min_left >= max_right)) {
total_rows = 0;
min_left = max_right = 0;
return;
}
bucket_size = (inT16) floor (xht_stats.median () + 0.5) / 2;
map_max = (max_right - min_left) / bucket_size;
map = (inT16 *) alloc_mem ((map_max + 1) * sizeof (inT16));
for (i = 0; i <= map_max; i++)
map[i] = 0;
for (row_it.mark_cycle_pt (); !row_it.cycled_list (); row_it.forward ()) {
row = row_it.data ();
if (!row->blob_list ()->empty ()) {
blob_it.set_to_list (row->blob_list ());
blob_it.mark_cycle_pt ();
blob_box = box_next (&blob_it);
prev_blob_box = blob_box;
if (gapmap_use_ends) {
/* Leading space */
gap_width = blob_box.left () - min_left;
if ((gap_width > gapmap_big_gaps * row->xheight)
&& gap_width > 2) {
max_quantum = (blob_box.left () - min_left) / bucket_size;
if (max_quantum > map_max) max_quantum = map_max;
for (i = 0; i <= max_quantum; i++)
map[i]++;
}
}
while (!blob_it.cycled_list ()) {
blob_box = box_next (&blob_it);
gap_width = blob_box.left () - prev_blob_box.right ();
if ((gap_width > gapmap_big_gaps * row->xheight)
&& gap_width > 2) {
min_quantum =
(prev_blob_box.right () - min_left) / bucket_size;
max_quantum = (blob_box.left () - min_left) / bucket_size;
if (max_quantum > map_max) max_quantum = map_max;
for (i = min_quantum; i <= max_quantum; i++)
map[i]++;
}
prev_blob_box = blob_box;
}
if (gapmap_use_ends) {
/* Trailing space */
gap_width = max_right - prev_blob_box.right ();
if ((gap_width > gapmap_big_gaps * row->xheight)
&& gap_width > 2) {
min_quantum =
(prev_blob_box.right () - min_left) / bucket_size;
if (min_quantum < 0) min_quantum = 0;
for (i = min_quantum; i <= map_max; i++)
map[i]++;
}
}
}
}
for (i = 0; i <= map_max; i++) {
if (map[i] > total_rows / 2) {
if (gapmap_no_isolated_quanta &&
(((i == 0) &&
(map[i + 1] <= total_rows / 2)) ||
((i == map_max) &&
(map[i - 1] <= total_rows / 2)) ||
((i > 0) &&
(i < map_max) &&
(map[i - 1] <= total_rows / 2) &&
(map[i + 1] <= total_rows / 2)))) {
map[i] = 0; //prevent isolated quantum
}
else
any_tabs = TRUE;
}
}
if (gapmap_debug && any_tabs)
tprintf ("Table found\n");
}
/*************************************************************************
* GAPMAP::table_gap()
* Is there a bucket in the specified range where more than half the rows in the
* block have a wide gap?
*************************************************************************/
BOOL8 GAPMAP::table_gap( //Is gap a table?
inT16 left, //From here
inT16 right //To here
) {
inT16 min_quantum;
inT16 max_quantum;
inT16 i;
BOOL8 tab_found = FALSE;
if (!any_tabs)
return FALSE;
min_quantum = (left - min_left) / bucket_size;
max_quantum = (right - min_left) / bucket_size;
// Clip to the bounds of the array. In some circumstances (big blob followed
// by small blob) max_quantum can exceed the map_max bounds, but we clip
// here instead, as it provides better long-term safety.
if (min_quantum < 0) min_quantum = 0;
if (max_quantum > map_max) max_quantum = map_max;
for (i = min_quantum; (!tab_found && (i <= max_quantum)); i++)
if (map[i] > total_rows / 2)
tab_found = TRUE;
return tab_found;
}