tesseract/ccmain/tfacepp.cpp

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/**********************************************************************
* File: tfacepp.cpp (Formerly tface++.c)
* Description: C++ side of the C/C++ Tess/Editor interface.
* Author: Ray Smith
* Created: Thu Apr 23 15:39:23 BST 1992
*
* (C) Copyright 1992, 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.
*
**********************************************************************/
#ifdef _MSC_VER
#pragma warning(disable:4244) // Conversion warnings
#pragma warning(disable:4305) // int/float warnings
#pragma warning(disable:4800) // int/bool warnings
#endif
#include <math.h>
#ifdef __UNIX__
#include <assert.h>
#endif
#include "errcode.h"
#include "ratngs.h"
#include "reject.h"
#include "werd.h"
#include "tfacep.h"
#include "tfacepp.h"
#include "tessvars.h"
#include "globals.h"
#include "reject.h"
#include "tesseractclass.h"
#define MAX_UNDIVIDED_LENGTH 24
/**********************************************************************
* recog_word
*
* Convert the word to tess form and pass it to the tess segmenter.
* Convert the output back to editor form.
**********************************************************************/
namespace tesseract {
void Tesseract::recog_word(WERD_RES *word,
BLOB_CHOICE_LIST_CLIST *blob_choices) {
ASSERT_HOST(word->chopped_word->blobs != NULL);
recog_word_recursive(word, blob_choices);
word->SetupBoxWord();
if ((word->best_choice->length() != word->box_word->length()) ||
(word->best_choice->length() != blob_choices->length())) {
tprintf("recog_word ASSERT FAIL String:\"%s\"; "
"Strlen=%d; #Blobs=%d; #Choices=%d\n",
word->best_choice->debug_string().string(),
word->best_choice->length(), word->box_word->length(),
blob_choices->length());
}
ASSERT_HOST(word->best_choice->length() == word->box_word->length());
ASSERT_HOST(word->best_choice->length() == blob_choices->length());
if (tessedit_override_permuter) {
/* Override the permuter type if a straight dictionary check disagrees. */
uinT8 perm_type = word->best_choice->permuter();
if ((perm_type != SYSTEM_DAWG_PERM) &&
(perm_type != FREQ_DAWG_PERM) && (perm_type != USER_DAWG_PERM)) {
uinT8 real_dict_perm_type = dict_word(*word->best_choice);
if (((real_dict_perm_type == SYSTEM_DAWG_PERM) ||
(real_dict_perm_type == FREQ_DAWG_PERM) ||
(real_dict_perm_type == USER_DAWG_PERM)) &&
(alpha_count(word->best_choice->unichar_string().string(),
word->best_choice->unichar_lengths().string()) > 0)) {
word->best_choice->set_permuter(real_dict_perm_type); // use dict perm
}
}
if (tessedit_rejection_debug &&
perm_type != word->best_choice->permuter()) {
tprintf("Permuter Type Flipped from %d to %d\n",
perm_type, word->best_choice->permuter());
}
}
// Factored out from control.cpp
ASSERT_HOST((word->best_choice == NULL) == (word->raw_choice == NULL));
if (word->best_choice == NULL || word->best_choice->length() == 0 ||
strspn(word->best_choice->unichar_string().string(), " ") ==
word->best_choice->length()) {
word->tess_failed = true;
word->reject_map.initialise(word->box_word->length());
word->reject_map.rej_word_tess_failure();
} else {
word->tess_failed = false;
}
}
/**********************************************************************
* recog_word_recursive
*
* Convert the word to tess form and pass it to the tess segmenter.
* Convert the output back to editor form.
**********************************************************************/
void Tesseract::recog_word_recursive(WERD_RES *word,
BLOB_CHOICE_LIST_CLIST *blob_choices) {
int word_length = word->chopped_word->NumBlobs(); // no of blobs
if (word_length > MAX_UNDIVIDED_LENGTH) {
return split_and_recog_word(word, blob_choices);
}
int initial_blob_choice_len = blob_choices->length();
BLOB_CHOICE_LIST_VECTOR* tess_ratings = cc_recog(word);
// Put BLOB_CHOICE_LISTs from tess_ratings into blob_choices.
BLOB_CHOICE_LIST_C_IT blob_choices_it(blob_choices);
for (int i = 0; i < tess_ratings->length(); ++i) {
blob_choices_it.add_to_end(tess_ratings->get(i));
}
delete tess_ratings;
word_length = word->rebuild_word->NumBlobs(); // No of blobs in output.
// Pad raw_choice with spaces if needed.
if (word->raw_choice->length() < word_length) {
UNICHAR_ID space_id = unicharset.unichar_to_id(" ");
while (word->raw_choice->length() < word_length) {
word->raw_choice->append_unichar_id(space_id, 1, 0.0,
word->raw_choice->certainty());
}
}
// Do sanity checks and minor fixes on best_choice.
if (word->best_choice->length() > word_length) {
word->best_choice->make_bad(); // should never happen
tprintf("recog_word: Discarded long string \"%s\""
" (%d characters vs %d blobs)\n",
word->best_choice->unichar_string().string(),
word->best_choice->length(), word_length);
tprintf("Word is at:");
word->word->bounding_box().print();
}
if (blob_choices->length() - initial_blob_choice_len != word_length) {
word->best_choice->make_bad(); // force rejection
tprintf("recog_word: Choices list len:%d; blob lists len:%d\n",
blob_choices->length(), word_length);
blob_choices_it.set_to_list(blob_choices); // list of lists
while (blob_choices->length() - initial_blob_choice_len < word_length) {
blob_choices_it.add_to_end(new BLOB_CHOICE_LIST()); // add a fake one
tprintf("recog_word: Added dummy choice list\n");
}
while (blob_choices->length() - initial_blob_choice_len > word_length) {
blob_choices_it.move_to_last(); // should never happen
delete blob_choices_it.extract();
tprintf("recog_word: Deleted choice list\n");
}
}
if (word->best_choice->length() < word_length) {
UNICHAR_ID space_id = unicharset.unichar_to_id(" ");
while (word->best_choice->length() < word_length) {
word->best_choice->append_unichar_id(space_id, 1, 0.0,
word->best_choice->certainty());
}
}
}
/**********************************************************************
* split_and_recog_word
*
* Split the word into 2 smaller pieces at the largest gap.
* Recognize the pieces and stick the results back together.
**********************************************************************/
void Tesseract::split_and_recog_word(WERD_RES *word,
BLOB_CHOICE_LIST_CLIST *blob_choices) {
// Find the biggest blob gap in the chopped_word.
int bestgap = -MAX_INT32;
TPOINT best_split_pt;
TBLOB* best_end = NULL;
TBLOB* prev_blob = NULL;
for (TBLOB* blob = word->chopped_word->blobs; blob != NULL;
blob = blob->next) {
if (prev_blob != NULL) {
TBOX prev_box = prev_blob->bounding_box();
TBOX blob_box = blob->bounding_box();
int gap = blob_box.left() - prev_box.right();
if (gap > bestgap) {
bestgap = gap;
best_end = prev_blob;
best_split_pt.x = (prev_box.right() + blob_box.left()) / 2;
best_split_pt.y = (prev_box.top() + prev_box.bottom() +
blob_box.top() + blob_box.bottom()) / 4;
}
}
prev_blob = blob;
}
ASSERT_HOST(best_end != NULL);
ASSERT_HOST(best_end->next != NULL);
// Make a copy of the word to put the 2nd half in.
WERD_RES* word2 = new WERD_RES(*word);
// Blow away the copied chopped_word, as we want to work with the blobs
// from the input chopped_word so the seam_arrays can be merged.
delete word2->chopped_word;
word2->chopped_word = new TWERD;
word2->chopped_word->blobs = best_end->next;
best_end->next = NULL;
// Make a new seamarray on both words.
free_seam_list(word->seam_array);
word->seam_array = start_seam_list(word->chopped_word->blobs);
word2->seam_array = start_seam_list(word2->chopped_word->blobs);
BlamerBundle *orig_bb = word->blamer_bundle;
STRING blamer_debug;
// Try to adjust truth information.
if (orig_bb != NULL) {
// Find truth boxes that correspond to the split in the blobs.
int b;
int begin2_truth_index = -1;
if (orig_bb->incorrect_result_reason != IRR_NO_TRUTH &&
orig_bb->truth_has_char_boxes) {
int end1_x = best_end->bounding_box().right();
int begin2_x = word2->chopped_word->blobs->bounding_box().left();
blamer_debug = "Looking for truth split at";
blamer_debug.add_str_int(" end1_x ", end1_x);
blamer_debug.add_str_int(" begin2_x ", begin2_x);
blamer_debug += "\nnorm_truth_word boxes:\n";
if (orig_bb->norm_truth_word.length() > 1) {
orig_bb->norm_truth_word.BlobBox(0).append_debug(&blamer_debug);
for (b = 1; b < orig_bb->norm_truth_word.length(); ++b) {
orig_bb->norm_truth_word.BlobBox(b).append_debug(&blamer_debug);
if ((abs(end1_x - orig_bb->norm_truth_word.BlobBox(b-1).right()) <
orig_bb->norm_box_tolerance) &&
(abs(begin2_x - orig_bb->norm_truth_word.BlobBox(b).left()) <
orig_bb->norm_box_tolerance)) {
begin2_truth_index = b;
blamer_debug += "Split found\n";
break;
}
}
}
}
// Populate truth information in word and word2 with the first and second
// part of the original truth.
word->blamer_bundle = new BlamerBundle();
word2->blamer_bundle = new BlamerBundle();
if (begin2_truth_index > 0) {
word->blamer_bundle->truth_has_char_boxes = true;
word->blamer_bundle->norm_box_tolerance = orig_bb->norm_box_tolerance;
word2->blamer_bundle->truth_has_char_boxes = true;
word2->blamer_bundle->norm_box_tolerance = orig_bb->norm_box_tolerance;
BlamerBundle *curr_bb = word->blamer_bundle;
for (b = 0; b < orig_bb->norm_truth_word.length(); ++b) {
if (b == begin2_truth_index) curr_bb = word2->blamer_bundle;
curr_bb->norm_truth_word.InsertBox(
b, orig_bb->norm_truth_word.BlobBox(b));
curr_bb->truth_word.InsertBox(b, orig_bb->truth_word.BlobBox(b));
curr_bb->truth_text.push_back(orig_bb->truth_text[b]);
}
} else if (orig_bb->incorrect_result_reason == IRR_NO_TRUTH) {
word->blamer_bundle->incorrect_result_reason = IRR_NO_TRUTH;
word2->blamer_bundle->incorrect_result_reason = IRR_NO_TRUTH;
} else {
blamer_debug += "Truth split not found";
blamer_debug += orig_bb->truth_has_char_boxes ?
"\n" : " (no truth char boxes)\n";
word->blamer_bundle->SetBlame(IRR_NO_TRUTH_SPLIT, blamer_debug,
NULL, wordrec_debug_blamer);
word2->blamer_bundle->SetBlame(IRR_NO_TRUTH_SPLIT, blamer_debug,
NULL, wordrec_debug_blamer);
}
}
// Recognize the first part of the word.
recog_word_recursive(word, blob_choices);
// Recognize the second part of the word.
recog_word_recursive(word2, blob_choices);
// Tack the word2 outputs onto the end of the word outputs.
// New blobs might have appeared on the end of word1.
for (best_end = word->chopped_word->blobs; best_end->next != NULL;
best_end = best_end->next);
best_end->next = word2->chopped_word->blobs;
TBLOB* blob;
for (blob = word->rebuild_word->blobs; blob->next != NULL; blob = blob->next);
blob->next = word2->rebuild_word->blobs;
word2->chopped_word->blobs = NULL;
word2->rebuild_word->blobs = NULL;
// Copy the seams onto the end of the word1 seam_array.
// Since the seam list is one element short, an empty seam marking the
// end of the last blob in the first word is needed first.
word->seam_array = add_seam(word->seam_array,
new_seam(0.0, best_split_pt, NULL, NULL, NULL));
for (int i = 0; i < array_count(word2->seam_array); ++i) {
SEAM* seam = reinterpret_cast<SEAM*>(array_value(word2->seam_array, i));
array_value(word2->seam_array, i) = NULL;
word->seam_array = add_seam(word->seam_array, seam);
}
word->best_state += word2->best_state;
// Append the word choices.
*word->best_choice += *word2->best_choice;
*word->raw_choice += *word2->raw_choice;
// How many alt choices from each should we try to get?
const int kAltsPerPiece = 2;
// When do we start throwing away extra alt choices?
const int kTooManyAltChoices = 100;
if (word->alt_choices.size() > 0 && word2->alt_choices.size() > 0) {
// Construct the cartesian product of the alt choices of word(1) and word2.
int num_first_alt_choices = word->alt_choices.size();
// Nota Bene: For the main loop here, we leave in place word1-only
// alt_choices in
// word->alt_choices[0] .. word_alt_choices[num_first_alt_choices - 1]
// These will get fused with the best choices for word2 below.
for (int j = 1; j < word2->alt_choices.size() &&
(j <= kAltsPerPiece || word->alt_choices.size() < kTooManyAltChoices);
j++) {
for (int i = 0; i < num_first_alt_choices &&
(i <= kAltsPerPiece ||
word->alt_choices.size() < kTooManyAltChoices);
i++) {
WERD_CHOICE *wc = new WERD_CHOICE(*word->alt_choices[i]);
*wc += *word2->alt_choices[j];
word->alt_choices.push_back(wc);
word->alt_states.push_back(GenericVector<int>());
GenericVector<int> &alt_state = word->alt_states.back();
alt_state += word->alt_states[i];
alt_state += word2->alt_states[j];
}
}
// Now that we've filled in as many alternates as we want, paste the best
// choice for word2 onto the original word alt_choices.
for (int i = 0; i < num_first_alt_choices; i++) {
*word->alt_choices[i] += *word2->alt_choices[0];
word->alt_states[i] += word2->alt_states[0];
}
}
// Restore the pointer to original blamer bundle and combine blamer
// information recorded in the splits.
if (orig_bb != NULL) {
IncorrectResultReason irr = orig_bb->incorrect_result_reason;
if (irr != IRR_NO_TRUTH_SPLIT) blamer_debug = "";
if (word->blamer_bundle->incorrect_result_reason != IRR_CORRECT &&
word->blamer_bundle->incorrect_result_reason != IRR_NO_TRUTH &&
word->blamer_bundle->incorrect_result_reason != IRR_NO_TRUTH_SPLIT) {
blamer_debug += "Blame from part 1: ";
blamer_debug += word->blamer_bundle->debug;
irr = word->blamer_bundle->incorrect_result_reason;
}
if (word2->blamer_bundle->incorrect_result_reason != IRR_CORRECT &&
word2->blamer_bundle->incorrect_result_reason != IRR_NO_TRUTH &&
word2->blamer_bundle->incorrect_result_reason != IRR_NO_TRUTH_SPLIT) {
blamer_debug += "Blame from part 2: ";
blamer_debug += word2->blamer_bundle->debug;
if (irr == IRR_CORRECT) {
irr = word2->blamer_bundle->incorrect_result_reason;
} else if (irr != word2->blamer_bundle->incorrect_result_reason) {
irr = IRR_UNKNOWN;
}
}
delete word->blamer_bundle;
word->blamer_bundle = orig_bb;
word->blamer_bundle->incorrect_result_reason = irr;
if (irr != IRR_CORRECT && irr != IRR_NO_TRUTH) {
word->blamer_bundle->SetBlame(irr, blamer_debug, NULL,
wordrec_debug_blamer);
}
}
delete word2;
}
} // namespace tesseract