New dict format, step 5
Move functions that will be modified and enclose those that will be replaced into #ifdefs. This change does not modify any code, only move some code around. Bug: 4392433 Change-Id: Ibefbda1eb8bdc8a0c72de47ad9c67a08d0aca960main
parent
e218baa6cc
commit
bc90c72faf
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@ -518,47 +518,6 @@ inline static int calcFreqForSplitTwoWords(
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return totalFreq;
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}
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bool UnigramDictionary::getSplitTwoWordsSuggestion(const int inputLength,
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const int firstWordStartPos, const int firstWordLength, const int secondWordStartPos,
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const int secondWordLength, const bool isSpaceProximity) {
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if (inputLength >= MAX_WORD_LENGTH) return false;
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if (0 >= firstWordLength || 0 >= secondWordLength || firstWordStartPos >= secondWordStartPos
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|| firstWordStartPos < 0 || secondWordStartPos + secondWordLength > inputLength)
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return false;
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const int newWordLength = firstWordLength + secondWordLength + 1;
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// Allocating variable length array on stack
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unsigned short word[newWordLength];
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const int firstFreq = getBestWordFreq(firstWordStartPos, firstWordLength, mWord);
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if (DEBUG_DICT) {
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LOGI("First freq: %d", firstFreq);
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}
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if (firstFreq <= 0) return false;
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for (int i = 0; i < firstWordLength; ++i) {
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word[i] = mWord[i];
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}
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const int secondFreq = getBestWordFreq(secondWordStartPos, secondWordLength, mWord);
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if (DEBUG_DICT) {
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LOGI("Second freq: %d", secondFreq);
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}
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if (secondFreq <= 0) return false;
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word[firstWordLength] = SPACE;
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for (int i = (firstWordLength + 1); i < newWordLength; ++i) {
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word[i] = mWord[i - firstWordLength - 1];
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}
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int pairFreq = calcFreqForSplitTwoWords(TYPED_LETTER_MULTIPLIER, firstWordLength,
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secondWordLength, firstFreq, secondFreq, isSpaceProximity);
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if (DEBUG_DICT) {
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LOGI("Split two words: %d, %d, %d, %d, %d", firstFreq, secondFreq, pairFreq, inputLength,
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TYPED_LETTER_MULTIPLIER);
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}
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addWord(word, newWordLength, pairFreq);
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return true;
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}
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bool UnigramDictionary::getMissingSpaceWords(const int inputLength, const int missingSpacePos) {
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return getSplitTwoWordsSuggestion(
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inputLength, 0, missingSpacePos, missingSpacePos, inputLength - missingSpacePos, false);
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@ -570,48 +529,6 @@ bool UnigramDictionary::getMistypedSpaceWords(const int inputLength, const int s
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inputLength - spaceProximityPos - 1, true);
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}
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// Keep this for comparing spec to new getWords
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void UnigramDictionary::getWordsOld(const int initialPos, const int inputLength, const int skipPos,
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const int excessivePos, const int transposedPos,int *nextLetters,
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const int nextLettersSize) {
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int initialPosition = initialPos;
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const int count = Dictionary::getCount(DICT_ROOT, &initialPosition);
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getWordsRec(count, initialPosition, 0,
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min(inputLength * MAX_DEPTH_MULTIPLIER, MAX_WORD_LENGTH),
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mInputLength <= 0, 1, 0, 0, skipPos, excessivePos, transposedPos, nextLetters,
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nextLettersSize);
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}
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void UnigramDictionary::getWordsRec(const int childrenCount, const int pos, const int depth,
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const int maxDepth, const bool traverseAllNodes, const int matchWeight,
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const int inputIndex, const int diffs, const int skipPos, const int excessivePos,
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const int transposedPos, int *nextLetters, const int nextLettersSize) {
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int siblingPos = pos;
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for (int i = 0; i < childrenCount; ++i) {
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int newCount;
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int newChildPosition;
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bool newTraverseAllNodes;
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int newMatchRate;
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int newInputIndex;
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int newDiffs;
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int newSiblingPos;
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int newOutputIndex;
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const bool needsToTraverseChildrenNodes = processCurrentNode(siblingPos, depth, maxDepth,
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traverseAllNodes, matchWeight, inputIndex, diffs,
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skipPos, excessivePos, transposedPos,
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nextLetters, nextLettersSize,
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&newCount, &newChildPosition, &newTraverseAllNodes, &newMatchRate,
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&newInputIndex, &newDiffs, &newSiblingPos, &newOutputIndex);
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siblingPos = newSiblingPos;
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if (needsToTraverseChildrenNodes) {
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getWordsRec(newCount, newChildPosition, newOutputIndex, maxDepth, newTraverseAllNodes,
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newMatchRate, newInputIndex, newDiffs, skipPos, excessivePos, transposedPos,
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nextLetters, nextLettersSize);
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}
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}
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}
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inline int UnigramDictionary::calculateFinalFreq(const int inputIndex, const int depth,
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const int matchWeight, const int skipPos, const int excessivePos, const int transposedPos,
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const int freq, const bool sameLength) const {
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@ -763,92 +680,49 @@ inline void UnigramDictionary::onTerminal(unsigned short int* word, const int de
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}
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}
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inline bool UnigramDictionary::processCurrentNode(const int pos, const int depth,
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const int maxDepth, const bool traverseAllNodes, int matchWeight, int inputIndex,
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const int diffs, const int skipPos, const int excessivePos, const int transposedPos,
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int *nextLetters, const int nextLettersSize, int *newCount, int *newChildPosition,
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bool *newTraverseAllNodes, int *newMatchRate, int *newInputIndex, int *newDiffs,
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int *nextSiblingPosition, int *nextOutputIndex) {
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if (DEBUG_DICT) {
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int inputCount = 0;
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if (skipPos >= 0) ++inputCount;
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if (excessivePos >= 0) ++inputCount;
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if (transposedPos >= 0) ++inputCount;
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assert(inputCount <= 1);
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}
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unsigned short c;
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int childPosition;
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bool terminal;
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int freq;
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bool isSameAsUserTypedLength = false;
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#ifndef NEW_DICTIONARY_FORMAT
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// TODO: Don't forget to bring inline functions back to over where they are used.
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const uint8_t flags = 0; // No flags for now
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// The following functions will be entirely replaced with new implementations.
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void UnigramDictionary::getWordsOld(const int initialPos, const int inputLength, const int skipPos,
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const int excessivePos, const int transposedPos,int *nextLetters,
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const int nextLettersSize) {
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int initialPosition = initialPos;
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const int count = Dictionary::getCount(DICT_ROOT, &initialPosition);
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getWordsRec(count, initialPosition, 0,
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min(inputLength * MAX_DEPTH_MULTIPLIER, MAX_WORD_LENGTH),
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mInputLength <= 0, 1, 0, 0, skipPos, excessivePos, transposedPos, nextLetters,
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nextLettersSize);
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}
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if (excessivePos == depth && inputIndex < mInputLength - 1) ++inputIndex;
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void UnigramDictionary::getWordsRec(const int childrenCount, const int pos, const int depth,
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const int maxDepth, const bool traverseAllNodes, const int matchWeight,
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const int inputIndex, const int diffs, const int skipPos, const int excessivePos,
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const int transposedPos, int *nextLetters, const int nextLettersSize) {
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int siblingPos = pos;
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for (int i = 0; i < childrenCount; ++i) {
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int newCount;
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int newChildPosition;
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bool newTraverseAllNodes;
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int newMatchRate;
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int newInputIndex;
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int newDiffs;
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int newSiblingPos;
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int newOutputIndex;
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const bool needsToTraverseChildrenNodes = processCurrentNode(siblingPos, depth, maxDepth,
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traverseAllNodes, matchWeight, inputIndex, diffs,
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skipPos, excessivePos, transposedPos,
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nextLetters, nextLettersSize,
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&newCount, &newChildPosition, &newTraverseAllNodes, &newMatchRate,
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&newInputIndex, &newDiffs, &newSiblingPos, &newOutputIndex);
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siblingPos = newSiblingPos;
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*nextSiblingPosition = Dictionary::setDictionaryValues(DICT_ROOT, IS_LATEST_DICT_VERSION, pos,
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&c, &childPosition, &terminal, &freq);
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*nextOutputIndex = depth + 1;
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const bool needsToTraverseChildrenNodes = childPosition != 0;
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// If we are only doing traverseAllNodes, no need to look at the typed characters.
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if (traverseAllNodes || needsToSkipCurrentNode(c, inputIndex, skipPos, depth)) {
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mWord[depth] = c;
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if (traverseAllNodes && terminal) {
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onTerminal(mWord, depth, DICT_ROOT, flags, pos, inputIndex, matchWeight, skipPos,
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excessivePos, transposedPos, freq, false, nextLetters, nextLettersSize);
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if (needsToTraverseChildrenNodes) {
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getWordsRec(newCount, newChildPosition, newOutputIndex, maxDepth, newTraverseAllNodes,
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newMatchRate, newInputIndex, newDiffs, skipPos, excessivePos, transposedPos,
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nextLetters, nextLettersSize);
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}
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if (!needsToTraverseChildrenNodes) return false;
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*newTraverseAllNodes = traverseAllNodes;
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*newMatchRate = matchWeight;
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*newDiffs = diffs;
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*newInputIndex = inputIndex;
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} else {
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const int *currentChars = getInputCharsAt(inputIndex);
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if (transposedPos >= 0) {
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if (inputIndex == transposedPos) currentChars += MAX_PROXIMITY_CHARS;
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if (inputIndex == (transposedPos + 1)) currentChars -= MAX_PROXIMITY_CHARS;
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}
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int matchedProximityCharId = getMatchedProximityId(currentChars, c, skipPos, excessivePos,
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transposedPos);
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if (UNRELATED_CHAR == matchedProximityCharId) return false;
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mWord[depth] = c;
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// If inputIndex is greater than mInputLength, that means there is no
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// proximity chars. So, we don't need to check proximity.
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if (SAME_OR_ACCENTED_OR_CAPITALIZED_CHAR == matchedProximityCharId) {
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multiplyIntCapped(TYPED_LETTER_MULTIPLIER, &matchWeight);
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}
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bool isSameAsUserTypedLength = mInputLength == inputIndex + 1
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|| (excessivePos == mInputLength - 1 && inputIndex == mInputLength - 2);
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if (isSameAsUserTypedLength && terminal) {
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onTerminal(mWord, depth, DICT_ROOT, flags, pos, inputIndex, matchWeight, skipPos,
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excessivePos, transposedPos, freq, true, nextLetters, nextLettersSize);
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}
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if (!needsToTraverseChildrenNodes) return false;
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// Start traversing all nodes after the index exceeds the user typed length
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*newTraverseAllNodes = isSameAsUserTypedLength;
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*newMatchRate = matchWeight;
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*newDiffs = diffs + ((NEAR_PROXIMITY_CHAR == matchedProximityCharId) ? 1 : 0);
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*newInputIndex = inputIndex + 1;
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}
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// Optimization: Prune out words that are too long compared to how much was typed.
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if (depth >= maxDepth || *newDiffs > mMaxEditDistance) {
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return false;
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}
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// If inputIndex is greater than mInputLength, that means there are no proximity chars.
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// TODO: Check if this can be isSameAsUserTypedLength only.
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if (isSameAsUserTypedLength || mInputLength <= *newInputIndex) {
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*newTraverseAllNodes = true;
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}
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// get the count of nodes and increment childAddress.
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*newCount = Dictionary::getCount(DICT_ROOT, &childPosition);
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*newChildPosition = childPosition;
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if (DEBUG_DICT) assert(needsToTraverseChildrenNodes);
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return needsToTraverseChildrenNodes;
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}
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inline int UnigramDictionary::getBestWordFreq(const int startInputIndex, const int inputLength,
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@ -986,4 +860,138 @@ int UnigramDictionary::getBigramPosition(int pos, unsigned short *word, int offs
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return NOT_VALID_WORD;
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}
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// The following functions will be modified.
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bool UnigramDictionary::getSplitTwoWordsSuggestion(const int inputLength,
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const int firstWordStartPos, const int firstWordLength, const int secondWordStartPos,
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const int secondWordLength, const bool isSpaceProximity) {
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if (inputLength >= MAX_WORD_LENGTH) return false;
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if (0 >= firstWordLength || 0 >= secondWordLength || firstWordStartPos >= secondWordStartPos
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|| firstWordStartPos < 0 || secondWordStartPos + secondWordLength > inputLength)
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return false;
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const int newWordLength = firstWordLength + secondWordLength + 1;
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// Allocating variable length array on stack
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unsigned short word[newWordLength];
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const int firstFreq = getBestWordFreq(firstWordStartPos, firstWordLength, mWord);
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if (DEBUG_DICT) {
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LOGI("First freq: %d", firstFreq);
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}
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if (firstFreq <= 0) return false;
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for (int i = 0; i < firstWordLength; ++i) {
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word[i] = mWord[i];
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}
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const int secondFreq = getBestWordFreq(secondWordStartPos, secondWordLength, mWord);
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if (DEBUG_DICT) {
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LOGI("Second freq: %d", secondFreq);
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}
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if (secondFreq <= 0) return false;
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word[firstWordLength] = SPACE;
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for (int i = (firstWordLength + 1); i < newWordLength; ++i) {
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word[i] = mWord[i - firstWordLength - 1];
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}
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int pairFreq = calcFreqForSplitTwoWords(TYPED_LETTER_MULTIPLIER, firstWordLength,
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secondWordLength, firstFreq, secondFreq, isSpaceProximity);
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if (DEBUG_DICT) {
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LOGI("Split two words: %d, %d, %d, %d, %d", firstFreq, secondFreq, pairFreq, inputLength,
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TYPED_LETTER_MULTIPLIER);
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}
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addWord(word, newWordLength, pairFreq);
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return true;
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}
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inline bool UnigramDictionary::processCurrentNode(const int pos, const int depth,
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const int maxDepth, const bool traverseAllNodes, int matchWeight, int inputIndex,
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const int diffs, const int skipPos, const int excessivePos, const int transposedPos,
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int *nextLetters, const int nextLettersSize, int *newCount, int *newChildPosition,
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bool *newTraverseAllNodes, int *newMatchRate, int *newInputIndex, int *newDiffs,
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int *nextSiblingPosition, int *nextOutputIndex) {
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if (DEBUG_DICT) {
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int inputCount = 0;
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if (skipPos >= 0) ++inputCount;
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if (excessivePos >= 0) ++inputCount;
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if (transposedPos >= 0) ++inputCount;
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assert(inputCount <= 1);
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}
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unsigned short c;
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int childPosition;
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bool terminal;
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int freq;
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bool isSameAsUserTypedLength = false;
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const uint8_t flags = 0; // No flags for now
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if (excessivePos == depth && inputIndex < mInputLength - 1) ++inputIndex;
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*nextSiblingPosition = Dictionary::setDictionaryValues(DICT_ROOT, IS_LATEST_DICT_VERSION, pos,
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&c, &childPosition, &terminal, &freq);
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*nextOutputIndex = depth + 1;
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const bool needsToTraverseChildrenNodes = childPosition != 0;
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// If we are only doing traverseAllNodes, no need to look at the typed characters.
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if (traverseAllNodes || needsToSkipCurrentNode(c, inputIndex, skipPos, depth)) {
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mWord[depth] = c;
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if (traverseAllNodes && terminal) {
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onTerminal(mWord, depth, DICT_ROOT, flags, pos, inputIndex, matchWeight, skipPos,
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excessivePos, transposedPos, freq, false, nextLetters, nextLettersSize);
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}
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if (!needsToTraverseChildrenNodes) return false;
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*newTraverseAllNodes = traverseAllNodes;
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*newMatchRate = matchWeight;
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*newDiffs = diffs;
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*newInputIndex = inputIndex;
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} else {
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const int *currentChars = getInputCharsAt(inputIndex);
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if (transposedPos >= 0) {
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if (inputIndex == transposedPos) currentChars += MAX_PROXIMITY_CHARS;
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if (inputIndex == (transposedPos + 1)) currentChars -= MAX_PROXIMITY_CHARS;
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}
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int matchedProximityCharId = getMatchedProximityId(currentChars, c, skipPos, excessivePos,
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transposedPos);
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if (UNRELATED_CHAR == matchedProximityCharId) return false;
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mWord[depth] = c;
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// If inputIndex is greater than mInputLength, that means there is no
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// proximity chars. So, we don't need to check proximity.
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if (SAME_OR_ACCENTED_OR_CAPITALIZED_CHAR == matchedProximityCharId) {
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multiplyIntCapped(TYPED_LETTER_MULTIPLIER, &matchWeight);
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}
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bool isSameAsUserTypedLength = mInputLength == inputIndex + 1
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|| (excessivePos == mInputLength - 1 && inputIndex == mInputLength - 2);
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if (isSameAsUserTypedLength && terminal) {
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onTerminal(mWord, depth, DICT_ROOT, flags, pos, inputIndex, matchWeight, skipPos,
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excessivePos, transposedPos, freq, true, nextLetters, nextLettersSize);
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}
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if (!needsToTraverseChildrenNodes) return false;
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// Start traversing all nodes after the index exceeds the user typed length
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*newTraverseAllNodes = isSameAsUserTypedLength;
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*newMatchRate = matchWeight;
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*newDiffs = diffs + ((NEAR_PROXIMITY_CHAR == matchedProximityCharId) ? 1 : 0);
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*newInputIndex = inputIndex + 1;
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}
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// Optimization: Prune out words that are too long compared to how much was typed.
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if (depth >= maxDepth || *newDiffs > mMaxEditDistance) {
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return false;
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}
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// If inputIndex is greater than mInputLength, that means there are no proximity chars.
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// TODO: Check if this can be isSameAsUserTypedLength only.
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if (isSameAsUserTypedLength || mInputLength <= *newInputIndex) {
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*newTraverseAllNodes = true;
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}
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// get the count of nodes and increment childAddress.
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*newCount = Dictionary::getCount(DICT_ROOT, &childPosition);
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*newChildPosition = childPosition;
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if (DEBUG_DICT) assert(needsToTraverseChildrenNodes);
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return needsToTraverseChildrenNodes;
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}
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#else // NEW_DICTIONARY_FORMAT
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#endif // NEW_DICTIONARY_FORMAT
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} // namespace latinime
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