tesseract/ccstruct/ratngs.cpp
Stefan Weil 068d43d3d8 Remove old code for string class (no longer needed) (#1354)
* Remove old code for string class (no longer needed)

Signed-off-by: Stefan Weil <sw@weilnetz.de>

* Add std namespace to string class

Signed-off-by: Stefan Weil <sw@weilnetz.de>
2018-03-03 14:36:28 +01:00

841 lines
28 KiB
C++

/**********************************************************************
* File: ratngs.cpp (Formerly ratings.c)
* Description: Code to manipulate the BLOB_CHOICE and WERD_CHOICE classes.
* Author: Ray Smith
* Created: Thu Apr 23 13:23:29 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 HAVE_CONFIG_H
#include "config_auto.h"
#endif
#include "ratngs.h"
#include <string>
#include "blobs.h"
#include "callcpp.h"
#include "genericvector.h"
#include "matrix.h"
#include "normalis.h" // kBlnBaselineOffset.
#include "unicharset.h"
using tesseract::ScriptPos;
ELISTIZE(BLOB_CHOICE)
ELISTIZE(WERD_CHOICE)
const float WERD_CHOICE::kBadRating = 100000.0;
// Min offset in baseline-normalized coords to make a character a subscript.
const int kMinSubscriptOffset = 20;
// Min offset in baseline-normalized coords to make a character a superscript.
const int kMinSuperscriptOffset = 20;
// Max y of bottom of a drop-cap blob.
const int kMaxDropCapBottom = -128;
// Max fraction of x-height to use as denominator in measuring x-height overlap.
const double kMaxOverlapDenominator = 0.125;
// Min fraction of x-height range that should be in agreement for matching
// x-heights.
const double kMinXHeightMatch = 0.5;
// Max tolerance on baseline position as a fraction of x-height for matching
// baselines.
const double kMaxBaselineDrift = 0.0625;
static const char kPermuterTypeNoPerm[] = "None";
static const char kPermuterTypePuncPerm[] = "Punctuation";
static const char kPermuterTypeTopPerm[] = "Top Choice";
static const char kPermuterTypeLowerPerm[] = "Top Lower Case";
static const char kPermuterTypeUpperPerm[] = "Top Upper Case";
static const char kPermuterTypeNgramPerm[] = "Ngram";
static const char kPermuterTypeNumberPerm[] = "Number";
static const char kPermuterTypeUserPatPerm[] = "User Pattern";
static const char kPermuterTypeSysDawgPerm[] = "System Dictionary";
static const char kPermuterTypeDocDawgPerm[] = "Document Dictionary";
static const char kPermuterTypeUserDawgPerm[] = "User Dictionary";
static const char kPermuterTypeFreqDawgPerm[] = "Frequent Words Dictionary";
static const char kPermuterTypeCompoundPerm[] = "Compound";
static const char * const kPermuterTypeNames[] = {
kPermuterTypeNoPerm, // 0
kPermuterTypePuncPerm, // 1
kPermuterTypeTopPerm, // 2
kPermuterTypeLowerPerm, // 3
kPermuterTypeUpperPerm, // 4
kPermuterTypeNgramPerm, // 5
kPermuterTypeNumberPerm, // 6
kPermuterTypeUserPatPerm, // 7
kPermuterTypeSysDawgPerm, // 8
kPermuterTypeDocDawgPerm, // 9
kPermuterTypeUserDawgPerm, // 10
kPermuterTypeFreqDawgPerm, // 11
kPermuterTypeCompoundPerm // 12
};
/**
* BLOB_CHOICE::BLOB_CHOICE
*
* Constructor to build a BLOB_CHOICE from a char, rating and certainty.
*/
BLOB_CHOICE::BLOB_CHOICE(UNICHAR_ID src_unichar_id, // character id
float src_rating, // rating
float src_cert, // certainty
int src_script_id, // script
float min_xheight, // min xheight allowed
float max_xheight, // max xheight by this char
float yshift, // yshift out of position
BlobChoiceClassifier c) { // adapted match or other
unichar_id_ = src_unichar_id;
rating_ = src_rating;
certainty_ = src_cert;
fontinfo_id_ = -1;
fontinfo_id2_ = -1;
script_id_ = src_script_id;
min_xheight_ = min_xheight;
max_xheight_ = max_xheight;
yshift_ = yshift;
classifier_ = c;
}
/**
* BLOB_CHOICE::BLOB_CHOICE
*
* Constructor to build a BLOB_CHOICE from another BLOB_CHOICE.
*/
BLOB_CHOICE::BLOB_CHOICE(const BLOB_CHOICE &other) : ELIST_LINK(other) {
unichar_id_ = other.unichar_id();
rating_ = other.rating();
certainty_ = other.certainty();
fontinfo_id_ = other.fontinfo_id();
fontinfo_id2_ = other.fontinfo_id2();
script_id_ = other.script_id();
matrix_cell_ = other.matrix_cell_;
min_xheight_ = other.min_xheight_;
max_xheight_ = other.max_xheight_;
yshift_ = other.yshift();
classifier_ = other.classifier_;
fonts_ = other.fonts_;
}
// Returns true if *this and other agree on the baseline and x-height
// to within some tolerance based on a given estimate of the x-height.
bool BLOB_CHOICE::PosAndSizeAgree(const BLOB_CHOICE& other, float x_height,
bool debug) const {
double baseline_diff = fabs(yshift() - other.yshift());
if (baseline_diff > kMaxBaselineDrift * x_height) {
if (debug) {
tprintf("Baseline diff %g for %d v %d\n",
baseline_diff, unichar_id_, other.unichar_id_);
}
return false;
}
double this_range = max_xheight() - min_xheight();
double other_range = other.max_xheight() - other.min_xheight();
double denominator = ClipToRange(MIN(this_range, other_range),
1.0, kMaxOverlapDenominator * x_height);
double overlap = MIN(max_xheight(), other.max_xheight()) -
MAX(min_xheight(), other.min_xheight());
overlap /= denominator;
if (debug) {
tprintf("PosAndSize for %d v %d: bl diff = %g, ranges %g, %g / %g ->%g\n",
unichar_id_, other.unichar_id_, baseline_diff,
this_range, other_range, denominator, overlap);
}
return overlap >= kMinXHeightMatch;
}
// Helper to find the BLOB_CHOICE in the bc_list that matches the given
// unichar_id, or NULL if there is no match.
BLOB_CHOICE* FindMatchingChoice(UNICHAR_ID char_id,
BLOB_CHOICE_LIST* bc_list) {
// Find the corresponding best BLOB_CHOICE.
BLOB_CHOICE_IT choice_it(bc_list);
for (choice_it.mark_cycle_pt(); !choice_it.cycled_list();
choice_it.forward()) {
BLOB_CHOICE* choice = choice_it.data();
if (choice->unichar_id() == char_id) {
return choice;
}
}
return NULL;
}
const char *WERD_CHOICE::permuter_name(uinT8 permuter) {
return kPermuterTypeNames[permuter];
}
namespace tesseract {
const char *ScriptPosToString(enum ScriptPos script_pos) {
switch (script_pos) {
case SP_NORMAL: return "NORM";
case SP_SUBSCRIPT: return "SUB";
case SP_SUPERSCRIPT: return "SUPER";
case SP_DROPCAP: return "DROPC";
}
return "SP_UNKNOWN";
}
} // namespace tesseract.
/**
* WERD_CHOICE::WERD_CHOICE
*
* Constructor to build a WERD_CHOICE from the given string.
* The function assumes that src_string is not NULL.
*/
WERD_CHOICE::WERD_CHOICE(const char *src_string,
const UNICHARSET &unicharset)
: unicharset_(&unicharset){
GenericVector<UNICHAR_ID> encoding;
GenericVector<char> lengths;
std::string cleaned = unicharset.CleanupString(src_string);
if (unicharset.encode_string(cleaned.c_str(), true, &encoding, &lengths,
NULL)) {
lengths.push_back('\0');
STRING src_lengths = &lengths[0];
this->init(cleaned.c_str(), src_lengths.string(), 0.0, 0.0, NO_PERM);
} else { // There must have been an invalid unichar in the string.
this->init(8);
this->make_bad();
}
}
/**
* WERD_CHOICE::init
*
* Helper function to build a WERD_CHOICE from the given string,
* fragment lengths, rating, certainty and permuter.
*
* The function assumes that src_string is not NULL.
* src_lengths argument could be NULL, in which case the unichars
* in src_string are assumed to all be of length 1.
*/
void WERD_CHOICE::init(const char *src_string,
const char *src_lengths,
float src_rating,
float src_certainty,
uinT8 src_permuter) {
int src_string_len = strlen(src_string);
if (src_string_len == 0) {
this->init(8);
} else {
this->init(src_lengths ? strlen(src_lengths): src_string_len);
length_ = reserved_;
int offset = 0;
for (int i = 0; i < length_; ++i) {
int unichar_length = src_lengths ? src_lengths[i] : 1;
unichar_ids_[i] =
unicharset_->unichar_to_id(src_string+offset, unichar_length);
state_[i] = 1;
certainties_[i] = src_certainty;
offset += unichar_length;
}
}
adjust_factor_ = 1.0f;
rating_ = src_rating;
certainty_ = src_certainty;
permuter_ = src_permuter;
dangerous_ambig_found_ = false;
}
/**
* WERD_CHOICE::~WERD_CHOICE
*/
WERD_CHOICE::~WERD_CHOICE() {
delete[] unichar_ids_;
delete[] script_pos_;
delete[] state_;
delete[] certainties_;
}
const char *WERD_CHOICE::permuter_name() const {
return kPermuterTypeNames[permuter_];
}
// Returns the BLOB_CHOICE_LIST corresponding to the given index in the word,
// taken from the appropriate cell in the ratings MATRIX.
// Borrowed pointer, so do not delete.
BLOB_CHOICE_LIST* WERD_CHOICE::blob_choices(int index, MATRIX* ratings) const {
MATRIX_COORD coord = MatrixCoord(index);
BLOB_CHOICE_LIST* result = ratings->get(coord.col, coord.row);
if (result == NULL) {
result = new BLOB_CHOICE_LIST;
ratings->put(coord.col, coord.row, result);
}
return result;
}
// Returns the MATRIX_COORD corresponding to the location in the ratings
// MATRIX for the given index into the word.
MATRIX_COORD WERD_CHOICE::MatrixCoord(int index) const {
int col = 0;
for (int i = 0; i < index; ++i)
col += state_[i];
int row = col + state_[index] - 1;
return MATRIX_COORD(col, row);
}
// Sets the entries for the given index from the BLOB_CHOICE, assuming
// unit fragment lengths, but setting the state for this index to blob_count.
void WERD_CHOICE::set_blob_choice(int index, int blob_count,
const BLOB_CHOICE* blob_choice) {
unichar_ids_[index] = blob_choice->unichar_id();
script_pos_[index] = tesseract::SP_NORMAL;
state_[index] = blob_count;
certainties_[index] = blob_choice->certainty();
}
/**
* contains_unichar_id
*
* Returns true if unichar_ids_ contain the given unichar_id, false otherwise.
*/
bool WERD_CHOICE::contains_unichar_id(UNICHAR_ID unichar_id) const {
for (int i = 0; i < length_; ++i) {
if (unichar_ids_[i] == unichar_id) {
return true;
}
}
return false;
}
/**
* remove_unichar_ids
*
* Removes num unichar ids starting from index start from unichar_ids_
* and updates length_ and fragment_lengths_ to reflect this change.
* Note: this function does not modify rating_ and certainty_.
*/
void WERD_CHOICE::remove_unichar_ids(int start, int num) {
ASSERT_HOST(start >= 0 && start + num <= length_);
// Accumulate the states to account for the merged blobs.
for (int i = 0; i < num; ++i) {
if (start > 0)
state_[start - 1] += state_[start + i];
else if (start + num < length_)
state_[start + num] += state_[start + i];
}
for (int i = start; i + num < length_; ++i) {
unichar_ids_[i] = unichar_ids_[i + num];
script_pos_[i] = script_pos_[i + num];
state_[i] = state_[i + num];
certainties_[i] = certainties_[i + num];
}
length_ -= num;
}
/**
* reverse_and_mirror_unichar_ids
*
* Reverses and mirrors unichars in unichar_ids.
*/
void WERD_CHOICE::reverse_and_mirror_unichar_ids() {
for (int i = 0; i < length_ / 2; ++i) {
UNICHAR_ID tmp_id = unichar_ids_[i];
unichar_ids_[i] = unicharset_->get_mirror(unichar_ids_[length_-1-i]);
unichar_ids_[length_-1-i] = unicharset_->get_mirror(tmp_id);
}
if (length_ % 2 != 0) {
unichar_ids_[length_/2] = unicharset_->get_mirror(unichar_ids_[length_/2]);
}
}
/**
* punct_stripped
*
* Returns the half-open interval of unichar_id indices [start, end) which
* enclose the core portion of this word -- the part after stripping
* punctuation from the left and right.
*/
void WERD_CHOICE::punct_stripped(int *start, int *end) const {
*start = 0;
*end = length() - 1;
while (*start < length() &&
unicharset()->get_ispunctuation(unichar_id(*start))) {
(*start)++;
}
while (*end > -1 &&
unicharset()->get_ispunctuation(unichar_id(*end))) {
(*end)--;
}
(*end)++;
}
void WERD_CHOICE::GetNonSuperscriptSpan(int *pstart, int *pend) const {
int end = length();
while (end > 0 &&
unicharset_->get_isdigit(unichar_ids_[end - 1]) &&
BlobPosition(end - 1) == tesseract::SP_SUPERSCRIPT) {
end--;
}
int start = 0;
while (start < end &&
unicharset_->get_isdigit(unichar_ids_[start]) &&
BlobPosition(start) == tesseract::SP_SUPERSCRIPT) {
start++;
}
*pstart = start;
*pend = end;
}
WERD_CHOICE WERD_CHOICE::shallow_copy(int start, int end) const {
ASSERT_HOST(start >= 0 && start <= length_);
ASSERT_HOST(end >= 0 && end <= length_);
if (end < start) { end = start; }
WERD_CHOICE retval(unicharset_, end - start);
for (int i = start; i < end; i++) {
retval.append_unichar_id_space_allocated(
unichar_ids_[i], state_[i], 0.0f, certainties_[i]);
}
return retval;
}
/**
* has_rtl_unichar_id
*
* Returns true if unichar_ids contain at least one "strongly" RTL unichar.
*/
bool WERD_CHOICE::has_rtl_unichar_id() const {
int i;
for (i = 0; i < length_; ++i) {
UNICHARSET::Direction dir = unicharset_->get_direction(unichar_ids_[i]);
if (dir == UNICHARSET::U_RIGHT_TO_LEFT ||
dir == UNICHARSET::U_RIGHT_TO_LEFT_ARABIC) {
return true;
}
}
return false;
}
/**
* string_and_lengths
*
* Populates the given word_str with unichars from unichar_ids and
* and word_lengths_str with the corresponding unichar lengths.
*/
void WERD_CHOICE::string_and_lengths(STRING *word_str,
STRING *word_lengths_str) const {
*word_str = "";
if (word_lengths_str != NULL) *word_lengths_str = "";
for (int i = 0; i < length_; ++i) {
const char *ch = unicharset_->id_to_unichar_ext(unichar_ids_[i]);
*word_str += ch;
if (word_lengths_str != NULL) {
*word_lengths_str += strlen(ch);
}
}
}
/**
* append_unichar_id
*
* Make sure there is enough space in the word for the new unichar id
* and call append_unichar_id_space_allocated().
*/
void WERD_CHOICE::append_unichar_id(
UNICHAR_ID unichar_id, int blob_count,
float rating, float certainty) {
if (length_ == reserved_) {
this->double_the_size();
}
this->append_unichar_id_space_allocated(unichar_id, blob_count,
rating, certainty);
}
/**
* WERD_CHOICE::operator+=
*
* Cat a second word rating on the end of this current one.
* The ratings are added and the confidence is the min.
* If the permuters are NOT the same the permuter is set to COMPOUND_PERM
*/
WERD_CHOICE & WERD_CHOICE::operator+= (const WERD_CHOICE & second) {
ASSERT_HOST(unicharset_ == second.unicharset_);
while (reserved_ < length_ + second.length()) {
this->double_the_size();
}
const UNICHAR_ID *other_unichar_ids = second.unichar_ids();
for (int i = 0; i < second.length(); ++i) {
unichar_ids_[length_ + i] = other_unichar_ids[i];
state_[length_ + i] = second.state_[i];
certainties_[length_ + i] = second.certainties_[i];
script_pos_[length_ + i] = second.BlobPosition(i);
}
length_ += second.length();
if (second.adjust_factor_ > adjust_factor_)
adjust_factor_ = second.adjust_factor_;
rating_ += second.rating(); // add ratings
if (second.certainty() < certainty_) // take min
certainty_ = second.certainty();
if (second.dangerous_ambig_found_)
dangerous_ambig_found_ = true;
if (permuter_ == NO_PERM) {
permuter_ = second.permuter();
} else if (second.permuter() != NO_PERM &&
second.permuter() != permuter_) {
permuter_ = COMPOUND_PERM;
}
return *this;
}
/**
* WERD_CHOICE::operator=
*
* Allocate enough memory to hold a copy of source and copy over
* all the information from source to this WERD_CHOICE.
*/
WERD_CHOICE& WERD_CHOICE::operator=(const WERD_CHOICE& source) {
while (reserved_ < source.length()) {
this->double_the_size();
}
unicharset_ = source.unicharset_;
const UNICHAR_ID *other_unichar_ids = source.unichar_ids();
for (int i = 0; i < source.length(); ++i) {
unichar_ids_[i] = other_unichar_ids[i];
state_[i] = source.state_[i];
certainties_[i] = source.certainties_[i];
script_pos_[i] = source.BlobPosition(i);
}
length_ = source.length();
adjust_factor_ = source.adjust_factor_;
rating_ = source.rating();
certainty_ = source.certainty();
min_x_height_ = source.min_x_height();
max_x_height_ = source.max_x_height();
permuter_ = source.permuter();
dangerous_ambig_found_ = source.dangerous_ambig_found_;
return *this;
}
// Sets up the script_pos_ member using the blobs_list to get the bln
// bounding boxes, *this to get the unichars, and this->unicharset
// to get the target positions. If small_caps is true, sub/super are not
// considered, but dropcaps are.
// NOTE: blobs_list should be the chopped_word blobs. (Fully segemented.)
void WERD_CHOICE::SetScriptPositions(bool small_caps, TWERD* word) {
// Since WERD_CHOICE isn't supposed to depend on a Tesseract,
// we don't have easy access to the flags Tesseract stores. Therefore, debug
// for this module is hard compiled in.
int debug = 0;
// Initialize to normal.
for (int i = 0; i < length_; ++i)
script_pos_[i] = tesseract::SP_NORMAL;
if (word->blobs.empty() || word->NumBlobs() != TotalOfStates()) {
return;
}
int position_counts[4];
for (int i = 0; i < 4; i++) {
position_counts[i] = 0;
}
int chunk_index = 0;
for (int blob_index = 0; blob_index < length_; ++blob_index, ++chunk_index) {
TBLOB* tblob = word->blobs[chunk_index];
int uni_id = unichar_id(blob_index);
TBOX blob_box = tblob->bounding_box();
if (state_ != NULL) {
for (int i = 1; i < state_[blob_index]; ++i) {
++chunk_index;
tblob = word->blobs[chunk_index];
blob_box += tblob->bounding_box();
}
}
script_pos_[blob_index] = ScriptPositionOf(false, *unicharset_, blob_box,
uni_id);
if (small_caps && script_pos_[blob_index] != tesseract::SP_DROPCAP) {
script_pos_[blob_index] = tesseract::SP_NORMAL;
}
position_counts[script_pos_[blob_index]]++;
}
// If almost everything looks like a superscript or subscript,
// we most likely just got the baseline wrong.
if (position_counts[tesseract::SP_SUBSCRIPT] > 0.75 * length_ ||
position_counts[tesseract::SP_SUPERSCRIPT] > 0.75 * length_) {
if (debug >= 2) {
tprintf("Most characters of %s are subscript or superscript.\n"
"That seems wrong, so I'll assume we got the baseline wrong\n",
unichar_string().string());
}
for (int i = 0; i < length_; i++) {
ScriptPos sp = script_pos_[i];
if (sp == tesseract::SP_SUBSCRIPT || sp == tesseract::SP_SUPERSCRIPT) {
position_counts[sp]--;
position_counts[tesseract::SP_NORMAL]++;
script_pos_[i] = tesseract::SP_NORMAL;
}
}
}
if ((debug >= 1 && position_counts[tesseract::SP_NORMAL] < length_) ||
debug >= 2) {
tprintf("SetScriptPosition on %s\n", unichar_string().string());
int chunk_index = 0;
for (int blob_index = 0; blob_index < length_; ++blob_index) {
if (debug >= 2 || script_pos_[blob_index] != tesseract::SP_NORMAL) {
TBLOB* tblob = word->blobs[chunk_index];
ScriptPositionOf(true, *unicharset_, tblob->bounding_box(),
unichar_id(blob_index));
}
chunk_index += state_ != NULL ? state_[blob_index] : 1;
}
}
}
// Sets the script_pos_ member from some source positions with a given length.
void WERD_CHOICE::SetScriptPositions(const tesseract::ScriptPos* positions,
int length) {
ASSERT_HOST(length == length_);
if (positions != script_pos_) {
delete [] script_pos_;
script_pos_ = new ScriptPos[length];
memcpy(script_pos_, positions, sizeof(positions[0]) * length);
}
}
// Sets all the script_pos_ positions to the given position.
void WERD_CHOICE::SetAllScriptPositions(tesseract::ScriptPos position) {
for (int i = 0; i < length_; ++i)
script_pos_[i] = position;
}
/* static */
ScriptPos WERD_CHOICE::ScriptPositionOf(bool print_debug,
const UNICHARSET& unicharset,
const TBOX& blob_box,
UNICHAR_ID unichar_id) {
ScriptPos retval = tesseract::SP_NORMAL;
int top = blob_box.top();
int bottom = blob_box.bottom();
int min_bottom, max_bottom, min_top, max_top;
unicharset.get_top_bottom(unichar_id,
&min_bottom, &max_bottom,
&min_top, &max_top);
int sub_thresh_top = min_top - kMinSubscriptOffset;
int sub_thresh_bot = kBlnBaselineOffset - kMinSubscriptOffset;
int sup_thresh_bot = max_bottom + kMinSuperscriptOffset;
if (bottom <= kMaxDropCapBottom) {
retval = tesseract::SP_DROPCAP;
} else if (top < sub_thresh_top && bottom < sub_thresh_bot) {
retval = tesseract::SP_SUBSCRIPT;
} else if (bottom > sup_thresh_bot) {
retval = tesseract::SP_SUPERSCRIPT;
}
if (print_debug) {
const char *pos = ScriptPosToString(retval);
tprintf("%s Character %s[bot:%d top: %d] "
"bot_range[%d,%d] top_range[%d, %d] "
"sub_thresh[bot:%d top:%d] sup_thresh_bot %d\n",
pos, unicharset.id_to_unichar(unichar_id),
bottom, top,
min_bottom, max_bottom, min_top, max_top,
sub_thresh_bot, sub_thresh_top,
sup_thresh_bot);
}
return retval;
}
// Returns the script-id (eg Han) of the dominant script in the word.
int WERD_CHOICE::GetTopScriptID() const {
int max_script = unicharset_->get_script_table_size();
int *sid = new int[max_script];
int x;
for (x = 0; x < max_script; x++) sid[x] = 0;
for (x = 0; x < length_; ++x) {
int script_id = unicharset_->get_script(unichar_id(x));
sid[script_id]++;
}
if (unicharset_->han_sid() != unicharset_->null_sid()) {
// Add the Hiragana & Katakana counts to Han and zero them out.
if (unicharset_->hiragana_sid() != unicharset_->null_sid()) {
sid[unicharset_->han_sid()] += sid[unicharset_->hiragana_sid()];
sid[unicharset_->hiragana_sid()] = 0;
}
if (unicharset_->katakana_sid() != unicharset_->null_sid()) {
sid[unicharset_->han_sid()] += sid[unicharset_->katakana_sid()];
sid[unicharset_->katakana_sid()] = 0;
}
}
// Note that high script ID overrides lower one on a tie, thus biasing
// towards non-Common script (if sorted that way in unicharset file).
int max_sid = 0;
for (x = 1; x < max_script; x++)
if (sid[x] >= sid[max_sid]) max_sid = x;
if (sid[max_sid] < length_ / 2)
max_sid = unicharset_->null_sid();
delete[] sid;
return max_sid;
}
// Fixes the state_ for a chop at the given blob_posiiton.
void WERD_CHOICE::UpdateStateForSplit(int blob_position) {
int total_chunks = 0;
for (int i = 0; i < length_; ++i) {
total_chunks += state_[i];
if (total_chunks > blob_position) {
++state_[i];
return;
}
}
}
// Returns the sum of all the state elements, being the total number of blobs.
int WERD_CHOICE::TotalOfStates() const {
int total_chunks = 0;
for (int i = 0; i < length_; ++i) {
total_chunks += state_[i];
}
return total_chunks;
}
/**
* WERD_CHOICE::print
*
* Print WERD_CHOICE to stdout.
*/
void WERD_CHOICE::print(const char *msg) const {
tprintf("%s : ", msg);
for (int i = 0; i < length_; ++i) {
tprintf("%s", unicharset_->id_to_unichar(unichar_ids_[i]));
}
tprintf(" : R=%g, C=%g, F=%g, Perm=%d, xht=[%g,%g], ambig=%d\n",
rating_, certainty_, adjust_factor_, permuter_,
min_x_height_, max_x_height_, dangerous_ambig_found_);
tprintf("pos");
for (int i = 0; i < length_; ++i) {
tprintf("\t%s", ScriptPosToString(script_pos_[i]));
}
tprintf("\nstr");
for (int i = 0; i < length_; ++i) {
tprintf("\t%s", unicharset_->id_to_unichar(unichar_ids_[i]));
}
tprintf("\nstate:");
for (int i = 0; i < length_; ++i) {
tprintf("\t%d ", state_[i]);
}
tprintf("\nC");
for (int i = 0; i < length_; ++i) {
tprintf("\t%.3f", certainties_[i]);
}
tprintf("\n");
}
// Prints the segmentation state with an introductory message.
void WERD_CHOICE::print_state(const char *msg) const {
tprintf("%s", msg);
for (int i = 0; i < length_; ++i)
tprintf(" %d", state_[i]);
tprintf("\n");
}
// Displays the segmentation state of *this (if not the same as the last
// one displayed) and waits for a click in the window.
void WERD_CHOICE::DisplaySegmentation(TWERD* word) {
#ifndef GRAPHICS_DISABLED
// Number of different colors to draw with.
const int kNumColors = 6;
static ScrollView *segm_window = NULL;
// Check the state against the static prev_drawn_state.
static GenericVector<int> prev_drawn_state;
bool already_done = prev_drawn_state.size() == length_;
if (!already_done) prev_drawn_state.init_to_size(length_, 0);
for (int i = 0; i < length_; ++i) {
if (prev_drawn_state[i] != state_[i]) {
already_done = false;
}
prev_drawn_state[i] = state_[i];
}
if (already_done || word->blobs.empty()) return;
// Create the window if needed.
if (segm_window == NULL) {
segm_window = new ScrollView("Segmentation", 5, 10, 500, 256,
2000.0, 256.0, true);
} else {
segm_window->Clear();
}
TBOX bbox;
int blob_index = 0;
for (int c = 0; c < length_; ++c) {
ScrollView::Color color =
static_cast<ScrollView::Color>(c % kNumColors + 3);
for (int i = 0; i < state_[c]; ++i, ++blob_index) {
TBLOB* blob = word->blobs[blob_index];
bbox += blob->bounding_box();
blob->plot(segm_window, color, color);
}
}
segm_window->ZoomToRectangle(bbox.left(), bbox.top(),
bbox.right(), bbox.bottom());
segm_window->Update();
window_wait(segm_window);
#endif
}
bool EqualIgnoringCaseAndTerminalPunct(const WERD_CHOICE &word1,
const WERD_CHOICE &word2) {
const UNICHARSET *uchset = word1.unicharset();
if (word2.unicharset() != uchset) return false;
int w1start, w1end;
word1.punct_stripped(&w1start, &w1end);
int w2start, w2end;
word2.punct_stripped(&w2start, &w2end);
if (w1end - w1start != w2end - w2start) return false;
for (int i = 0; i < w1end - w1start; i++) {
if (uchset->to_lower(word1.unichar_id(w1start + i)) !=
uchset->to_lower(word2.unichar_id(w2start + i))) {
return false;
}
}
return true;
}
/**
* print_ratings_list
*
* Send all the ratings out to the logfile.
*
* @param msg intro message
* @param ratings list of ratings
* @param current_unicharset unicharset that can be used
* for id-to-unichar conversion
*/
void print_ratings_list(const char *msg,
BLOB_CHOICE_LIST *ratings,
const UNICHARSET &current_unicharset) {
if (ratings->length() == 0) {
tprintf("%s:<none>\n", msg);
return;
}
if (*msg != '\0') {
tprintf("%s\n", msg);
}
BLOB_CHOICE_IT c_it;
c_it.set_to_list(ratings);
for (c_it.mark_cycle_pt(); !c_it.cycled_list(); c_it.forward()) {
c_it.data()->print(&current_unicharset);
if (!c_it.at_last()) tprintf("\n");
}
tprintf("\n");
fflush(stdout);
}