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https://github.com/tesseract-ocr/tesseract.git
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cd8de9157c
git-svn-id: https://tesseract-ocr.googlecode.com/svn/trunk@716 d0cd1f9f-072b-0410-8dd7-cf729c803f20
668 lines
23 KiB
C++
668 lines
23 KiB
C++
///////////////////////////////////////////////////////////////////////
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// File: resultiterator.cpp
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// Description: Iterator for tesseract results that is capable of
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// iterating in proper reading order over Bi Directional
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// (e.g. mixed Hebrew and English) text.
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// Author: David Eger
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// Created: Fri May 27 13:58:06 PST 2011
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//
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// (C) Copyright 2011, Google Inc.
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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// http://www.apache.org/licenses/LICENSE-2.0
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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//
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///////////////////////////////////////////////////////////////////////
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#include "resultiterator.h"
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#include "allheaders.h"
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#include "pageres.h"
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#include "strngs.h"
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#include "tesseractclass.h"
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#include "unicharset.h"
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#include "unicodes.h"
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namespace tesseract {
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ResultIterator::ResultIterator(const LTRResultIterator &resit)
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: LTRResultIterator(resit) {
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in_minor_direction_ = false;
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at_beginning_of_minor_run_ = false;
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current_paragraph_is_ltr_ = CurrentParagraphIsLtr();
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MoveToLogicalStartOfTextline();
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}
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ResultIterator *ResultIterator::StartOfParagraph(
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const LTRResultIterator &resit) {
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return new ResultIterator(resit);
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}
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bool ResultIterator::ParagraphIsLtr() const {
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return current_paragraph_is_ltr_;
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}
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bool ResultIterator::CurrentParagraphIsLtr() const {
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if (!it_->word())
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return true; // doesn't matter.
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LTRResultIterator it(*this);
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it.RestartParagraph();
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// Try to figure out the ltr-ness of the paragraph. The rules below
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// make more sense in the context of a difficult paragraph example.
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// Here we denote {ltr characters, RTL CHARACTERS}:
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//
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// "don't go in there!" DAIS EH
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// EHT OTNI DEPMUJ FELSMIH NEHT DNA
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// .GNIDLIUB GNINRUB
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//
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// On the first line, the left-most word is LTR and the rightmost word
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// is RTL. Thus, we are better off taking the majority direction for
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// the whole paragraph contents. So instead of "the leftmost word is LTR"
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// indicating an LTR paragraph, we use a heuristic about what RTL paragraphs
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// would not do: Typically an RTL paragraph would *not* start with an LTR
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// word. So our heuristics are as follows:
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//
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// (1) If the first text line has an RTL word in the left-most position
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// it is RTL.
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// (2) If the first text line has an LTR word in the right-most position
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// it is LTR.
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// (3) If neither of the above is true, take the majority count for the
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// paragraph -- if there are more rtl words, it is RTL. If there
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// are more LTR words, it's LTR.
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bool leftmost_rtl = it.WordDirection() == DIR_RIGHT_TO_LEFT;
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bool rightmost_ltr = it.WordDirection() == DIR_LEFT_TO_RIGHT;
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int num_ltr, num_rtl;
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num_rtl = leftmost_rtl ? 1 : 0;
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num_ltr = (it.WordDirection() == DIR_LEFT_TO_RIGHT) ? 1 : 0;
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for (it.Next(RIL_WORD);
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!it.Empty(RIL_WORD) && !it.IsAtBeginningOf(RIL_TEXTLINE);
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it.Next(RIL_WORD)) {
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StrongScriptDirection dir = it.WordDirection();
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rightmost_ltr = (dir == DIR_LEFT_TO_RIGHT);
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num_rtl += (dir == DIR_RIGHT_TO_LEFT) ? 1 : 0;
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num_ltr += rightmost_ltr ? 1 : 0;
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}
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if (leftmost_rtl)
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return false;
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if (rightmost_ltr)
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return true;
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// First line is ambiguous. Take statistics on the whole paragraph.
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if (!it.Empty(RIL_WORD) && !it.IsAtBeginningOf(RIL_PARA)) do {
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StrongScriptDirection dir = it.WordDirection();
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num_rtl += (dir == DIR_RIGHT_TO_LEFT) ? 1 : 0;
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num_ltr += (dir == DIR_LEFT_TO_RIGHT) ? 1 : 0;
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} while (it.Next(RIL_WORD) && !it.IsAtBeginningOf(RIL_PARA));
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return num_ltr >= num_rtl;
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}
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const int ResultIterator::kMinorRunStart = -1;
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const int ResultIterator::kMinorRunEnd = -2;
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const int ResultIterator::kComplexWord = -3;
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void ResultIterator::CalculateBlobOrder(
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GenericVector<int> *blob_indices) const {
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bool context_is_ltr = current_paragraph_is_ltr_ ^ in_minor_direction_;
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blob_indices->clear();
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if (Empty(RIL_WORD)) return;
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if (context_is_ltr || it_->word()->UnicharsInReadingOrder()) {
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// Easy! just return the blobs in order;
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for (int i = 0; i < word_length_; i++)
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blob_indices->push_back(i);
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return;
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}
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// The blobs are in left-to-right order, but the current reading context
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// is right-to-left.
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const int U_LTR = UNICHARSET::U_LEFT_TO_RIGHT;
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const int U_RTL = UNICHARSET::U_RIGHT_TO_LEFT;
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const int U_EURO_NUM = UNICHARSET::U_EUROPEAN_NUMBER;
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const int U_EURO_NUM_SEP = UNICHARSET::U_EUROPEAN_NUMBER_SEPARATOR;
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const int U_EURO_NUM_TERM = UNICHARSET::U_EUROPEAN_NUMBER_TERMINATOR;
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const int U_COMMON_NUM_SEP = UNICHARSET::U_COMMON_NUMBER_SEPARATOR;
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const int U_OTHER_NEUTRAL = UNICHARSET::U_OTHER_NEUTRAL;
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// Step 1: Scan for and mark European Number sequences
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// [:ET:]*[:EN:]+(([:ES:]|[:CS:])?[:EN:]+)*[:ET:]*
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GenericVector<int> letter_types;
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for (int i = 0; i < word_length_; i++) {
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letter_types.push_back(it_->word()->SymbolDirection(i));
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}
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// Convert a single separtor sandwiched between two EN's into an EN.
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for (int i = 0; i + 2 < word_length_; i++) {
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if (letter_types[i] == U_EURO_NUM && letter_types[i + 2] == U_EURO_NUM &&
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(letter_types[i + 1] == U_EURO_NUM_SEP ||
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letter_types[i + 1] == U_COMMON_NUM_SEP)) {
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letter_types[i + 1] = U_EURO_NUM;
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}
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}
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// Scan for sequences of European Number Terminators around ENs and convert
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// them to ENs.
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for (int i = 0; i < word_length_; i++) {
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if (letter_types[i] == U_EURO_NUM_TERM) {
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int j = i + 1;
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while (j < word_length_ && letter_types[j] == U_EURO_NUM_TERM) { j++; }
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if (j < word_length_ && letter_types[j] == U_EURO_NUM) {
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// The sequence [i..j] should be converted to all European Numbers.
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for (int k = i; k < j; k++) letter_types[k] = U_EURO_NUM;
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}
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j = i - 1;
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while (j > -1 && letter_types[j] == U_EURO_NUM_TERM) { j--; }
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if (j > -1 && letter_types[j] == U_EURO_NUM) {
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// The sequence [j..i] should be converted to all European Numbers.
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for (int k = j; k <= i; k++) letter_types[k] = U_EURO_NUM;
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}
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}
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}
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// Step 2: Convert all remaining types to either L or R.
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// Sequences ([:L:]|[:EN:])+ (([:CS:]|[:ON:])+ ([:L:]|[:EN:])+)* -> L.
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// All other are R.
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for (int i = 0; i < word_length_;) {
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int ti = letter_types[i];
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if (ti == U_LTR || ti == U_EURO_NUM) {
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// Left to right sequence; scan to the end of it.
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int last_good = i;
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for (int j = i + 1; j < word_length_; j++) {
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int tj = letter_types[j];
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if (tj == U_LTR || tj == U_EURO_NUM) {
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last_good = j;
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} else if (tj == U_COMMON_NUM_SEP || tj == U_OTHER_NEUTRAL) {
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// do nothing.
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} else {
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break;
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}
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}
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// [i..last_good] is the L sequence
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for (int k = i; k <= last_good; k++) letter_types[k] = U_LTR;
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i = last_good + 1;
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} else {
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letter_types[i] = U_RTL;
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i++;
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}
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}
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// At this point, letter_types is entirely U_LTR or U_RTL.
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for (int i = word_length_ - 1; i >= 0;) {
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if (letter_types[i] == U_RTL) {
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blob_indices->push_back(i);
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i--;
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} else {
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// left to right sequence. scan to the beginning.
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int j = i - 1;
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for (; j >= 0 && letter_types[j] != U_RTL; j--) { } // pass
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// Now (j, i] is LTR
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for (int k = j + 1; k <= i; k++) blob_indices->push_back(k);
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i = j;
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}
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}
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ASSERT_HOST(blob_indices->size() == word_length_);
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}
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static void PrintScriptDirs(const GenericVector<StrongScriptDirection> &dirs) {
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for (int i = 0; i < dirs.size(); i++) {
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switch (dirs[i]) {
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case DIR_NEUTRAL: tprintf ("N "); break;
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case DIR_LEFT_TO_RIGHT: tprintf("L "); break;
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case DIR_RIGHT_TO_LEFT: tprintf("R "); break;
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case DIR_MIX: tprintf("Z "); break;
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default: tprintf("? "); break;
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}
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}
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tprintf("\n");
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}
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void ResultIterator::CalculateTextlineOrder(
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bool paragraph_is_ltr,
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const LTRResultIterator &resit,
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GenericVectorEqEq<int> *word_indices) const {
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GenericVector<StrongScriptDirection> directions;
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CalculateTextlineOrder(paragraph_is_ltr, resit, &directions, word_indices);
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}
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void ResultIterator::CalculateTextlineOrder(
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bool paragraph_is_ltr,
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const LTRResultIterator &resit,
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GenericVector<StrongScriptDirection> *dirs_arg,
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GenericVectorEqEq<int> *word_indices) const {
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GenericVector<StrongScriptDirection> dirs;
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GenericVector<StrongScriptDirection> *directions;
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directions = (dirs_arg != NULL) ? dirs_arg : &dirs;
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directions->truncate(0);
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// A LTRResultIterator goes strictly left-to-right word order.
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LTRResultIterator ltr_it(resit);
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ltr_it.RestartRow();
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if (ltr_it.Empty(RIL_WORD)) return;
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do {
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directions->push_back(ltr_it.WordDirection());
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} while (ltr_it.Next(RIL_WORD) && !ltr_it.IsAtBeginningOf(RIL_TEXTLINE));
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word_indices->truncate(0);
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CalculateTextlineOrder(paragraph_is_ltr, *directions, word_indices);
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}
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void ResultIterator::CalculateTextlineOrder(
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bool paragraph_is_ltr,
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const GenericVector<StrongScriptDirection> &word_dirs,
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GenericVectorEqEq<int> *reading_order) {
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reading_order->truncate(0);
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if (word_dirs.size() == 0) return;
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// Take all of the runs of minor direction words and insert them
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// in reverse order.
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int minor_direction, major_direction, major_step, start, end;
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if (paragraph_is_ltr) {
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start = 0;
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end = word_dirs.size();
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major_step = 1;
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major_direction = DIR_LEFT_TO_RIGHT;
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minor_direction = DIR_RIGHT_TO_LEFT;
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} else {
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start = word_dirs.size() - 1;
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end = -1;
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major_step = -1;
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major_direction = DIR_RIGHT_TO_LEFT;
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minor_direction = DIR_LEFT_TO_RIGHT;
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// Special rule: if there are neutral words at the right most side
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// of a line adjacent to a left-to-right word in the middle of the
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// line, we interpret the end of the line as a single LTR sequence.
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if (word_dirs[start] == DIR_NEUTRAL) {
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int neutral_end = start;
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while (neutral_end > 0 && word_dirs[neutral_end] == DIR_NEUTRAL) {
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neutral_end--;
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}
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if (neutral_end >= 0 && word_dirs[neutral_end] == DIR_LEFT_TO_RIGHT) {
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// LTR followed by neutrals.
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// Scan for the beginning of the minor left-to-right run.
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int left = neutral_end;
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for (int i = left; i >= 0 && word_dirs[i] != DIR_RIGHT_TO_LEFT; i--) {
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if (word_dirs[i] == DIR_LEFT_TO_RIGHT) left = i;
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}
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reading_order->push_back(kMinorRunStart);
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for (int i = left; i < word_dirs.size(); i++) {
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reading_order->push_back(i);
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if (word_dirs[i] == DIR_MIX) reading_order->push_back(kComplexWord);
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}
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reading_order->push_back(kMinorRunEnd);
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start = left - 1;
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}
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}
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}
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for (int i = start; i != end;) {
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if (word_dirs[i] == minor_direction) {
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int j = i;
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while (j != end && word_dirs[j] != major_direction)
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j += major_step;
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if (j == end) j -= major_step;
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while (j != i && word_dirs[j] != minor_direction)
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j -= major_step;
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// [j..i] is a minor direction run.
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reading_order->push_back(kMinorRunStart);
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for (int k = j; k != i; k -= major_step) {
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reading_order->push_back(k);
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}
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reading_order->push_back(i);
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reading_order->push_back(kMinorRunEnd);
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i = j + major_step;
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} else {
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reading_order->push_back(i);
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if (word_dirs[i] == DIR_MIX) reading_order->push_back(kComplexWord);
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i += major_step;
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}
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}
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}
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int ResultIterator::LTRWordIndex() const {
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int this_word_index = 0;
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LTRResultIterator textline(*this);
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textline.RestartRow();
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while (!textline.PositionedAtSameWord(it_)) {
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this_word_index++;
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textline.Next(RIL_WORD);
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}
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return this_word_index;
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}
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void ResultIterator::MoveToLogicalStartOfWord() {
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if (word_length_ == 0) {
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BeginWord(0);
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return;
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}
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GenericVector<int> blob_order;
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CalculateBlobOrder(&blob_order);
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if (blob_order.size() == 0 || blob_order[0] == 0) return;
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BeginWord(blob_order[0]);
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}
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bool ResultIterator::IsAtFinalSymbolOfWord() const {
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if (!it_->word()) return true;
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GenericVector<int> blob_order;
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CalculateBlobOrder(&blob_order);
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return blob_order.size() == 0 || blob_order.back() == blob_index_;
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}
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bool ResultIterator::IsAtFirstSymbolOfWord() const {
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if (!it_->word()) return true;
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GenericVector<int> blob_order;
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CalculateBlobOrder(&blob_order);
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return blob_order.size() == 0 || blob_order[0] == blob_index_;
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}
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void ResultIterator::AppendSuffixMarks(STRING *text) const {
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if (!it_->word()) return;
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bool reading_direction_is_ltr =
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current_paragraph_is_ltr_ ^ in_minor_direction_;
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// scan forward to see what meta-information the word ordering algorithm
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// left us.
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// If this word is at the *end* of a minor run, insert the other
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// direction's mark; else if this was a complex word, insert the
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// current reading order's mark.
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GenericVectorEqEq<int> textline_order;
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CalculateTextlineOrder(current_paragraph_is_ltr_,
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*this, &textline_order);
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int this_word_index = LTRWordIndex();
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int i = textline_order.get_index(this_word_index);
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if (i < 0) return;
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int last_non_word_mark = 0;
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for (i++; i < textline_order.size() && textline_order[i] < 0; i++) {
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last_non_word_mark = textline_order[i];
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}
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if (last_non_word_mark == kComplexWord) {
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*text += reading_direction_is_ltr ? kLRM : kRLM;
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} else if (last_non_word_mark == kMinorRunEnd) {
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if (current_paragraph_is_ltr_) {
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*text += kRLM;
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*text += kLRM;
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} else {
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*text += kRLM;
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*text += kLRM;
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}
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}
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}
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void ResultIterator::MoveToLogicalStartOfTextline() {
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GenericVectorEqEq<int> word_indices;
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RestartRow();
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CalculateTextlineOrder(current_paragraph_is_ltr_,
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dynamic_cast<const LTRResultIterator&>(*this),
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&word_indices);
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int i = 0;
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for (; i < word_indices.size() && word_indices[i] < 0; i++) {
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if (word_indices[i] == kMinorRunStart) in_minor_direction_ = true;
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else if (word_indices[i] == kMinorRunEnd) in_minor_direction_ = false;
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}
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if (in_minor_direction_) at_beginning_of_minor_run_ = true;
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if (i >= word_indices.size()) return;
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int first_word_index = word_indices[i];
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for (int j = 0; j < first_word_index; j++) {
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PageIterator::Next(RIL_WORD);
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}
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MoveToLogicalStartOfWord();
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}
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void ResultIterator::Begin() {
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LTRResultIterator::Begin();
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current_paragraph_is_ltr_ = CurrentParagraphIsLtr();
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in_minor_direction_ = false;
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at_beginning_of_minor_run_ = false;
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MoveToLogicalStartOfTextline();
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}
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bool ResultIterator::Next(PageIteratorLevel level) {
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if (it_->block() == NULL) return false; // already at end!
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switch (level) {
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case RIL_BLOCK: // explicit fall-through
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case RIL_PARA: // explicit fall-through
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case RIL_TEXTLINE:
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if (!PageIterator::Next(level)) return false;
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if (IsWithinFirstTextlineOfParagraph()) {
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// if we've advanced to a new paragraph,
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// recalculate current_paragraph_is_ltr_
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current_paragraph_is_ltr_ = CurrentParagraphIsLtr();
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}
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in_minor_direction_ = false;
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MoveToLogicalStartOfTextline();
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return it_->block() != NULL;
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case RIL_SYMBOL:
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{
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GenericVector<int> blob_order;
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CalculateBlobOrder(&blob_order);
|
|
int next_blob = 0;
|
|
while (next_blob < blob_order.size() &&
|
|
blob_index_ != blob_order[next_blob])
|
|
next_blob++;
|
|
next_blob++;
|
|
if (next_blob < blob_order.size()) {
|
|
// we're in the same word; simply advance one blob.
|
|
BeginWord(blob_order[next_blob]);
|
|
at_beginning_of_minor_run_ = false;
|
|
return true;
|
|
}
|
|
level = RIL_WORD; // we've fallen through to the next word.
|
|
}
|
|
case RIL_WORD: // explicit fall-through.
|
|
{
|
|
if (it_->word() == NULL) return Next(RIL_BLOCK);
|
|
GenericVectorEqEq<int> word_indices;
|
|
int this_word_index = LTRWordIndex();
|
|
CalculateTextlineOrder(current_paragraph_is_ltr_,
|
|
*this,
|
|
&word_indices);
|
|
int final_real_index = word_indices.size() - 1;
|
|
while (final_real_index > 0 && word_indices[final_real_index] < 0)
|
|
final_real_index--;
|
|
for (int i = 0; i < final_real_index; i++) {
|
|
if (word_indices[i] == this_word_index) {
|
|
int j = i + 1;
|
|
for (; j < final_real_index && word_indices[j] < 0; j++) {
|
|
if (word_indices[j] == kMinorRunStart) in_minor_direction_ = true;
|
|
if (word_indices[j] == kMinorRunEnd) in_minor_direction_ = false;
|
|
}
|
|
at_beginning_of_minor_run_ = (word_indices[j - 1] == kMinorRunStart);
|
|
// awesome, we move to word_indices[j]
|
|
if (BidiDebug(3)) {
|
|
tprintf("Next(RIL_WORD): %d -> %d\n",
|
|
this_word_index, word_indices[j]);
|
|
}
|
|
PageIterator::RestartRow();
|
|
for (int k = 0; k < word_indices[j]; k++) {
|
|
PageIterator::Next(RIL_WORD);
|
|
}
|
|
MoveToLogicalStartOfWord();
|
|
return true;
|
|
}
|
|
}
|
|
if (BidiDebug(3)) {
|
|
tprintf("Next(RIL_WORD): %d -> EOL\n", this_word_index);
|
|
}
|
|
// we're going off the end of the text line.
|
|
return Next(RIL_TEXTLINE);
|
|
}
|
|
}
|
|
ASSERT_HOST(false); // shouldn't happen.
|
|
return false;
|
|
}
|
|
|
|
bool ResultIterator::IsAtBeginningOf(PageIteratorLevel level) const {
|
|
if (it_->block() == NULL) return false; // Already at the end!
|
|
if (it_->word() == NULL) return true; // In an image block.
|
|
if (level == RIL_SYMBOL) return true; // Always at beginning of a symbol.
|
|
|
|
bool at_word_start = IsAtFirstSymbolOfWord();
|
|
if (level == RIL_WORD) return at_word_start;
|
|
|
|
ResultIterator line_start(*this);
|
|
// move to the first word in the line...
|
|
line_start.MoveToLogicalStartOfTextline();
|
|
|
|
bool at_textline_start = at_word_start && *line_start.it_ == *it_;
|
|
if (level == RIL_TEXTLINE) return at_textline_start;
|
|
|
|
// now we move to the left-most word...
|
|
line_start.RestartRow();
|
|
bool at_block_start = at_textline_start &&
|
|
line_start.it_->block() != line_start.it_->prev_block();
|
|
if (level == RIL_BLOCK) return at_block_start;
|
|
|
|
bool at_para_start = at_block_start ||
|
|
(at_textline_start &&
|
|
line_start.it_->row()->row->para() !=
|
|
line_start.it_->prev_row()->row->para());
|
|
if (level == RIL_PARA) return at_para_start;
|
|
|
|
ASSERT_HOST(false); // shouldn't happen.
|
|
return false;
|
|
}
|
|
|
|
/**
|
|
* NOTE! This is an exact copy of PageIterator::IsAtFinalElement with the
|
|
* change that the variable next is now a ResultIterator instead of a
|
|
* PageIterator.
|
|
*/
|
|
bool ResultIterator::IsAtFinalElement(PageIteratorLevel level,
|
|
PageIteratorLevel element) const {
|
|
if (Empty(element)) return true; // Already at the end!
|
|
// The result is true if we step forward by element and find we are
|
|
// at the the end of the page or at beginning of *all* levels in:
|
|
// [level, element).
|
|
// When there is more than one level difference between element and level,
|
|
// we could for instance move forward one symbol and still be at the first
|
|
// word on a line, so we also have to be at the first symbol in a word.
|
|
ResultIterator next(*this);
|
|
next.Next(element);
|
|
if (next.Empty(element)) return true; // Reached the end of the page.
|
|
while (element > level) {
|
|
element = static_cast<PageIteratorLevel>(element - 1);
|
|
if (!next.IsAtBeginningOf(element))
|
|
return false;
|
|
}
|
|
return true;
|
|
}
|
|
|
|
/**
|
|
* Returns the null terminated UTF-8 encoded text string for the current
|
|
* object at the given level. Use delete [] to free after use.
|
|
*/
|
|
char* ResultIterator::GetUTF8Text(PageIteratorLevel level) const {
|
|
if (it_->word() == NULL) return NULL; // Already at the end!
|
|
STRING text;
|
|
switch (level) {
|
|
case RIL_BLOCK:
|
|
{
|
|
ResultIterator pp(*this);
|
|
do {
|
|
pp.AppendUTF8ParagraphText(&text);
|
|
} while (pp.Next(RIL_PARA) && pp.it_->block() == it_->block());
|
|
}
|
|
break;
|
|
case RIL_PARA:
|
|
AppendUTF8ParagraphText(&text);
|
|
break;
|
|
case RIL_TEXTLINE:
|
|
{
|
|
ResultIterator it(*this);
|
|
it.MoveToLogicalStartOfTextline();
|
|
it.IterateAndAppendUTF8TextlineText(&text);
|
|
}
|
|
break;
|
|
case RIL_WORD:
|
|
AppendUTF8WordText(&text);
|
|
break;
|
|
case RIL_SYMBOL:
|
|
{
|
|
bool reading_direction_is_ltr =
|
|
current_paragraph_is_ltr_ ^ in_minor_direction_;
|
|
if (at_beginning_of_minor_run_) {
|
|
text += reading_direction_is_ltr ? kLRM : kRLM;
|
|
}
|
|
text = it_->word()->BestUTF8(blob_index_, !reading_direction_is_ltr);
|
|
if (IsAtFinalSymbolOfWord()) AppendSuffixMarks(&text);
|
|
}
|
|
break;
|
|
}
|
|
int length = text.length() + 1;
|
|
char* result = new char[length];
|
|
strncpy(result, text.string(), length);
|
|
return result;
|
|
}
|
|
|
|
void ResultIterator::AppendUTF8WordText(STRING *text) const {
|
|
if (!it_->word()) return;
|
|
ASSERT_HOST(it_->word()->best_choice != NULL);
|
|
bool reading_direction_is_ltr =
|
|
current_paragraph_is_ltr_ ^ in_minor_direction_;
|
|
if (at_beginning_of_minor_run_) {
|
|
*text += reading_direction_is_ltr ? kLRM : kRLM;
|
|
}
|
|
|
|
GenericVector<int> blob_order;
|
|
CalculateBlobOrder(&blob_order);
|
|
for (int i = 0; i < blob_order.size(); i++) {
|
|
*text += it_->word()->BestUTF8(blob_order[i], !reading_direction_is_ltr);
|
|
}
|
|
AppendSuffixMarks(text);
|
|
}
|
|
|
|
void ResultIterator::IterateAndAppendUTF8TextlineText(STRING *text) {
|
|
if (Empty(RIL_WORD)) {
|
|
Next(RIL_WORD);
|
|
return;
|
|
}
|
|
if (BidiDebug(1)) {
|
|
GenericVectorEqEq<int> textline_order;
|
|
GenericVector<StrongScriptDirection> dirs;
|
|
CalculateTextlineOrder(current_paragraph_is_ltr_,
|
|
*this, &dirs, &textline_order);
|
|
tprintf("Strong Script dirs [%p/P=%s]: ", it_->row(),
|
|
current_paragraph_is_ltr_ ? "ltr" : "rtl");
|
|
PrintScriptDirs(dirs);
|
|
tprintf("Logical textline order [%p/P=%s]: ", it_->row(),
|
|
current_paragraph_is_ltr_ ? "ltr" : "rtl");
|
|
for (int i = 0; i < textline_order.size(); i++) {
|
|
tprintf("%d ", textline_order[i]);
|
|
}
|
|
tprintf("\n");
|
|
}
|
|
|
|
int words_appended = 0;
|
|
do {
|
|
AppendUTF8WordText(text);
|
|
words_appended++;
|
|
*text += " ";
|
|
} while (Next(RIL_WORD) && !IsAtBeginningOf(RIL_TEXTLINE));
|
|
if (BidiDebug(1)) {
|
|
tprintf("%d words printed\n", words_appended);
|
|
}
|
|
text->truncate_at(text->length() - 1);
|
|
*text += line_separator_;
|
|
// If we just finished a paragraph, add an extra newline.
|
|
if (it_->block() == NULL || IsAtBeginningOf(RIL_PARA))
|
|
*text += paragraph_separator_;
|
|
}
|
|
|
|
void ResultIterator::AppendUTF8ParagraphText(STRING *text) const {
|
|
ResultIterator it(*this);
|
|
it.RestartParagraph();
|
|
it.MoveToLogicalStartOfTextline();
|
|
if (it.Empty(RIL_WORD)) return;
|
|
do {
|
|
it.IterateAndAppendUTF8TextlineText(text);
|
|
} while (it.it_->block() != NULL && !it.IsAtBeginningOf(RIL_PARA));
|
|
}
|
|
|
|
bool ResultIterator::BidiDebug(int min_level) const {
|
|
int debug_level = 1;
|
|
IntParam *p = ParamUtils::FindParam<IntParam>(
|
|
"bidi_debug", GlobalParams()->int_params,
|
|
tesseract_->params()->int_params);
|
|
if (p != NULL) debug_level = (inT32)(*p);
|
|
return debug_level >= min_level;
|
|
}
|
|
|
|
} // namespace tesseract.
|