tesseract/cube/con_comp.cpp
Stefan Weil 03eec61a2f cube: Simplify new operations
It is not necessary to check for null pointers after new.

Simplify also two delete operations which were missing
in the previous commit.

Signed-off-by: Stefan Weil <sw@weilnetz.de>
2016-11-30 20:24:38 +01:00

269 lines
6.4 KiB
C++

/**********************************************************************
* File: con_comp.cpp
* Description: Implementation of a Connected Component class
* Author: Ahmad Abdulkader
* Created: 2007
*
* (C) Copyright 2008, Google Inc.
** 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 <stdlib.h>
#include <string.h>
#include "con_comp.h"
#include "cube_const.h"
namespace tesseract {
ConComp::ConComp() {
head_ = NULL;
tail_ = NULL;
left_ = 0;
top_ = 0;
right_ = 0;
bottom_ = 0;
left_most_ = false;
right_most_ = false;
id_ = -1;
pt_cnt_ = 0;
}
ConComp::~ConComp() {
if (head_ != NULL) {
ConCompPt *pt_ptr = head_;
while (pt_ptr != NULL) {
ConCompPt *pptNext = pt_ptr->Next();
delete pt_ptr;
pt_ptr = pptNext;
}
head_ = NULL;
}
}
// adds a pt to the conn comp and updates its boundaries
bool ConComp::Add(int x, int y) {
ConCompPt *pt_ptr = new ConCompPt(x, y);
if (head_ == NULL) {
left_ = x;
right_ = x;
top_ = y;
bottom_ = y;
head_ = pt_ptr;
} else {
left_ = left_ <= x ? left_ : x;
top_ = top_ <= y ? top_ : y;
right_ = right_ >= x ? right_ : x;
bottom_ = bottom_ >= y ? bottom_ : y;
}
if (tail_ != NULL) {
tail_->SetNext(pt_ptr);
}
tail_ = pt_ptr;
pt_cnt_++;
return true;
}
// merges two connected components
bool ConComp::Merge(ConComp *concomp) {
if (head_ == NULL || tail_ == NULL ||
concomp->head_ == NULL || concomp->tail_ == NULL) {
return false;
}
tail_->SetNext(concomp->head_);
tail_ = concomp->tail_;
left_ = left_ <= concomp->left_ ? left_ : concomp->left_;
top_ = top_ <= concomp->top_ ? top_ : concomp->top_;
right_ = right_ >= concomp->right_ ? right_ : concomp->right_;
bottom_ = bottom_ >= concomp->bottom_ ? bottom_ : concomp->bottom_;
pt_cnt_ += concomp->pt_cnt_;
concomp->head_ = NULL;
concomp->tail_ = NULL;
return true;
}
// Creates the x-coord density histogram after spreading
// each x-coord position by the HIST_WND_RATIO fraction of the
// height of the ConComp, but limited to max_hist_wnd
int *ConComp::CreateHistogram(int max_hist_wnd) {
int wid = right_ - left_ + 1,
hgt = bottom_ - top_ + 1,
hist_wnd = static_cast<int>(hgt * HIST_WND_RATIO);
if (hist_wnd > max_hist_wnd) {
hist_wnd = max_hist_wnd;
}
// alloc memo for histogram
int *hist_array = new int[wid];
memset(hist_array, 0, wid * sizeof(*hist_array));
// compute windowed histogram
ConCompPt *pt_ptr = head_;
while (pt_ptr != NULL) {
int x = pt_ptr->x() - left_,
xw = x - hist_wnd;
for (int xdel = -hist_wnd; xdel <= hist_wnd; xdel++, xw++) {
if (xw >= 0 && xw < wid) {
hist_array[xw]++;
}
}
pt_ptr = pt_ptr->Next();
}
return hist_array;
}
// find out the seg pts by looking for local minima in the histogram
int *ConComp::SegmentHistogram(int *hist_array, int *seg_pt_cnt) {
// init
(*seg_pt_cnt) = 0;
int wid = right_ - left_ + 1,
hgt = bottom_ - top_ + 1;
int *x_seg_pt = new int[wid];
int seg_pt_wnd = static_cast<int>(hgt * SEG_PT_WND_RATIO);
if (seg_pt_wnd > 1) {
seg_pt_wnd = 1;
}
for (int x = 2; x < (wid - 2); x++) {
if (hist_array[x] < hist_array[x - 1] &&
hist_array[x] < hist_array[x - 2] &&
hist_array[x] <= hist_array[x + 1] &&
hist_array[x] <= hist_array[x + 2]) {
x_seg_pt[(*seg_pt_cnt)++] = x;
x += seg_pt_wnd;
} else if (hist_array[x] <= hist_array[x - 1] &&
hist_array[x] <= hist_array[x - 2] &&
hist_array[x] < hist_array[x + 1] &&
hist_array[x] < hist_array[x + 2]) {
x_seg_pt[(*seg_pt_cnt)++] = x;
x += seg_pt_wnd;
}
}
// no segments, nothing to do
if ((*seg_pt_cnt) == 0) {
delete []x_seg_pt;
return NULL;
}
return x_seg_pt;
}
// segments a concomp based on pixel density histogram local minima
// if there were none found, it returns NULL
// this is more useful than creating a clone of itself
ConComp **ConComp::Segment(int max_hist_wnd, int *concomp_cnt) {
// init
(*concomp_cnt) = 0;
// No pts
if (head_ == NULL) {
return NULL;
}
int seg_pt_cnt = 0;
// create the histogram
int *hist_array = CreateHistogram(max_hist_wnd);
if (hist_array == NULL) {
return NULL;
}
int *x_seg_pt = SegmentHistogram(hist_array, &seg_pt_cnt);
// free histogram
delete []hist_array;
// no segments, nothing to do
if (seg_pt_cnt == 0) {
delete []x_seg_pt;
return NULL;
}
// create concomp array
ConComp **concomp_array = new ConComp *[seg_pt_cnt + 1];
for (int concomp = 0; concomp <= seg_pt_cnt; concomp++) {
concomp_array[concomp] = new ConComp();
// split concomps inherit the ID this concomp
concomp_array[concomp]->SetID(id_);
}
// set the left and right most attributes of the
// appropriate concomps
concomp_array[0]->left_most_ = true;
concomp_array[seg_pt_cnt]->right_most_ = true;
// assign pts to concomps
ConCompPt *pt_ptr = head_;
while (pt_ptr != NULL) {
int seg_pt;
// find the first seg-pt that exceeds the x value
// of the pt
for (seg_pt = 0; seg_pt < seg_pt_cnt; seg_pt++) {
if ((x_seg_pt[seg_pt] + left_) > pt_ptr->x()) {
break;
}
}
// add the pt to the proper concomp
if (concomp_array[seg_pt]->Add(pt_ptr->x(), pt_ptr->y()) == false) {
delete []x_seg_pt;
delete []concomp_array;
return NULL;
}
pt_ptr = pt_ptr->Next();
}
delete []x_seg_pt;
(*concomp_cnt) = (seg_pt_cnt + 1);
return concomp_array;
}
// Shifts the co-ordinates of all points by the specified x & y deltas
void ConComp::Shift(int dx, int dy) {
ConCompPt *pt_ptr = head_;
while (pt_ptr != NULL) {
pt_ptr->Shift(dx, dy);
pt_ptr = pt_ptr->Next();
}
left_ += dx;
right_ += dx;
top_ += dy;
bottom_ += dy;
}
} // namespace tesseract