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gerrit.omnirom.org / android_packages_inputmethods_LatinIME / 2df3060883c7535029c7dfbbb4f7b05935d796ae / . / native / src / unigram_dictionary.cpp
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/*
**
** Copyright 2010, The Android Open Source Project
**
** Licensed under the Apache License, Version 2.0 (the "License");
** you may not use this file except in compliance with the License.
** You may obtain a copy of the License at
**
** http://www.apache.org/licenses/LICENSE-2.0
**
** Unless required by applicable law or agreed to in writing, software
** distributed under the License is distributed on an "AS IS" BASIS,
** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
** See the License for the specific language governing permissions and
** limitations under the License.
*/
#include <assert.h>
#include <string.h>
#define LOG_TAG "LatinIME: unigram_dictionary.cpp"
#include "char_utils.h"
#include "dictionary.h"
#include "unigram_dictionary.h"
#ifdef NEW_DICTIONARY_FORMAT
#include "binary_format.h"
#endif // NEW_DICTIONARY_FORMAT
namespace latinime {
const UnigramDictionary::digraph_t UnigramDictionary::GERMAN_UMLAUT_DIGRAPHS[] =
{ { 'a', 'e' },
{ 'o', 'e' },
{ 'u', 'e' } };
// TODO: check the header
UnigramDictionary::UnigramDictionary(const uint8_t* const streamStart, int typedLetterMultiplier,
int fullWordMultiplier, int maxWordLength, int maxWords, int maxProximityChars,
const bool isLatestDictVersion)
#ifndef NEW_DICTIONARY_FORMAT
: DICT_ROOT(streamStart),
#else // NEW_DICTIONARY_FORMAT
: DICT_ROOT(streamStart + NEW_DICTIONARY_HEADER_SIZE),
#endif // NEW_DICTIONARY_FORMAT
MAX_WORD_LENGTH(maxWordLength), MAX_WORDS(maxWords),
MAX_PROXIMITY_CHARS(maxProximityChars), IS_LATEST_DICT_VERSION(isLatestDictVersion),
TYPED_LETTER_MULTIPLIER(typedLetterMultiplier), FULL_WORD_MULTIPLIER(fullWordMultiplier),
#ifndef NEW_DICTIONARY_FORMAT
ROOT_POS(isLatestDictVersion ? DICTIONARY_HEADER_SIZE : 0),
#else // NEW_DICTIONARY_FORMAT
// TODO : remove this variable.
ROOT_POS(0),
#endif // NEW_DICTIONARY_FORMAT
BYTES_IN_ONE_CHAR(MAX_PROXIMITY_CHARS * sizeof(int)),
MAX_UMLAUT_SEARCH_DEPTH(DEFAULT_MAX_UMLAUT_SEARCH_DEPTH) {
if (DEBUG_DICT) {
LOGI("UnigramDictionary - constructor");
}
mCorrectionState = new CorrectionState();
}
UnigramDictionary::~UnigramDictionary() {
delete mCorrectionState;
}
static inline unsigned int getCodesBufferSize(const int* codes, const int codesSize,
const int MAX_PROXIMITY_CHARS) {
return sizeof(*codes) * MAX_PROXIMITY_CHARS * codesSize;
}
bool UnigramDictionary::isDigraph(const int* codes, const int i, const int codesSize) const {
// There can't be a digraph if we don't have at least 2 characters to examine
if (i + 2 > codesSize) return false;
// Search for the first char of some digraph
int lastDigraphIndex = -1;
const int thisChar = codes[i * MAX_PROXIMITY_CHARS];
for (lastDigraphIndex = sizeof(GERMAN_UMLAUT_DIGRAPHS) / sizeof(GERMAN_UMLAUT_DIGRAPHS[0]) - 1;
lastDigraphIndex >= 0; --lastDigraphIndex) {
if (thisChar == GERMAN_UMLAUT_DIGRAPHS[lastDigraphIndex].first) break;
}
// No match: return early
if (lastDigraphIndex < 0) return false;
// It's an interesting digraph if the second char matches too.
return GERMAN_UMLAUT_DIGRAPHS[lastDigraphIndex].second == codes[(i + 1) * MAX_PROXIMITY_CHARS];
}
// Mostly the same arguments as the non-recursive version, except:
// codes is the original value. It points to the start of the work buffer, and gets passed as is.
// codesSize is the size of the user input (thus, it is the size of codesSrc).
// codesDest is the current point in the work buffer.
// codesSrc is the current point in the user-input, original, content-unmodified buffer.
// codesRemain is the remaining size in codesSrc.
void UnigramDictionary::getWordWithDigraphSuggestionsRec(ProximityInfo *proximityInfo,
const int *xcoordinates, const int* ycoordinates, const int *codesBuffer,
const int codesBufferSize, const int flags, const int* codesSrc, const int codesRemain,
const int currentDepth, int* codesDest, unsigned short* outWords, int* frequencies) {
if (currentDepth < MAX_UMLAUT_SEARCH_DEPTH) {
for (int i = 0; i < codesRemain; ++i) {
if (isDigraph(codesSrc, i, codesRemain)) {
// Found a digraph. We will try both spellings. eg. the word is "pruefen"
// Copy the word up to the first char of the digraph, then continue processing
// on the remaining part of the word, skipping the second char of the digraph.
// In our example, copy "pru" and continue running on "fen"
// Make i the index of the second char of the digraph for simplicity. Forgetting
// to do that results in an infinite recursion so take care!
++i;
memcpy(codesDest, codesSrc, i * BYTES_IN_ONE_CHAR);
getWordWithDigraphSuggestionsRec(proximityInfo, xcoordinates, ycoordinates,
codesBuffer, codesBufferSize, flags,
codesSrc + (i + 1) * MAX_PROXIMITY_CHARS, codesRemain - i - 1,
currentDepth + 1, codesDest + i * MAX_PROXIMITY_CHARS, outWords,
frequencies);
// Copy the second char of the digraph in place, then continue processing on
// the remaining part of the word.
// In our example, after "pru" in the buffer copy the "e", and continue on "fen"
memcpy(codesDest + i * MAX_PROXIMITY_CHARS, codesSrc + i * MAX_PROXIMITY_CHARS,
BYTES_IN_ONE_CHAR);
getWordWithDigraphSuggestionsRec(proximityInfo, xcoordinates, ycoordinates,
codesBuffer, codesBufferSize, flags, codesSrc + i * MAX_PROXIMITY_CHARS,
codesRemain - i, currentDepth + 1, codesDest + i * MAX_PROXIMITY_CHARS,
outWords, frequencies);
return;
}
}
}
// If we come here, we hit the end of the word: let's check it against the dictionary.
// In our example, we'll come here once for "prufen" and then once for "pruefen".
// If the word contains several digraphs, we'll come it for the product of them.
// eg. if the word is "ueberpruefen" we'll test, in order, against
// "uberprufen", "uberpruefen", "ueberprufen", "ueberpruefen".
const unsigned int remainingBytes = BYTES_IN_ONE_CHAR * codesRemain;
if (0 != remainingBytes)
memcpy(codesDest, codesSrc, remainingBytes);
getWordSuggestions(proximityInfo, xcoordinates, ycoordinates, codesBuffer,
(codesDest - codesBuffer) / MAX_PROXIMITY_CHARS + codesRemain, outWords, frequencies);
}
int UnigramDictionary::getSuggestions(ProximityInfo *proximityInfo, const int *xcoordinates,
const int *ycoordinates, const int *codes, const int codesSize, const int flags,
unsigned short *outWords, int *frequencies) {
if (REQUIRES_GERMAN_UMLAUT_PROCESSING & flags)
{ // Incrementally tune the word and try all possibilities
int codesBuffer[getCodesBufferSize(codes, codesSize, MAX_PROXIMITY_CHARS)];
getWordWithDigraphSuggestionsRec(proximityInfo, xcoordinates, ycoordinates, codesBuffer,
codesSize, flags, codes, codesSize, 0, codesBuffer, outWords, frequencies);
} else { // Normal processing
getWordSuggestions(proximityInfo, xcoordinates, ycoordinates, codes, codesSize,
outWords, frequencies);
}
PROF_START(20);
// Get the word count
int suggestedWordsCount = 0;
while (suggestedWordsCount < MAX_WORDS && mFrequencies[suggestedWordsCount] > 0) {
suggestedWordsCount++;
}
if (DEBUG_DICT) {
LOGI("Returning %d words", suggestedWordsCount);
/// Print the returned words
for (int j = 0; j < suggestedWordsCount; ++j) {
#ifdef FLAG_DBG
short unsigned int* w = mOutputChars + j * MAX_WORD_LENGTH;
char s[MAX_WORD_LENGTH];
for (int i = 0; i <= MAX_WORD_LENGTH; i++) s[i] = w[i];
LOGI("%s %i", s, mFrequencies[j]);
#endif
}
LOGI("Next letters: ");
for (int k = 0; k < NEXT_LETTERS_SIZE; k++) {
if (mNextLettersFrequency[k] > 0) {
LOGI("%c = %d,", k, mNextLettersFrequency[k]);
}
}
}
PROF_END(20);
PROF_CLOSE;
return suggestedWordsCount;
}
void UnigramDictionary::getWordSuggestions(ProximityInfo *proximityInfo,
const int *xcoordinates, const int *ycoordinates, const int *codes, const int codesSize,
unsigned short *outWords, int *frequencies) {
PROF_OPEN;
PROF_START(0);
initSuggestions(
proximityInfo, xcoordinates, ycoordinates, codes, codesSize, outWords, frequencies);
if (DEBUG_DICT) assert(codesSize == mInputLength);
const int MAX_DEPTH = min(mInputLength * MAX_DEPTH_MULTIPLIER, MAX_WORD_LENGTH);
PROF_END(0);
PROF_START(1);
getSuggestionCandidates(-1, -1, -1, mNextLettersFrequency, NEXT_LETTERS_SIZE, MAX_DEPTH);
PROF_END(1);
PROF_START(2);
// Suggestion with missing character
if (SUGGEST_WORDS_WITH_MISSING_CHARACTER) {
for (int i = 0; i < codesSize; ++i) {
if (DEBUG_DICT) {
LOGI("--- Suggest missing characters %d", i);
}
getSuggestionCandidates(i, -1, -1, NULL, 0, MAX_DEPTH);
}
}
PROF_END(2);
PROF_START(3);
// Suggestion with excessive character
if (SUGGEST_WORDS_WITH_EXCESSIVE_CHARACTER
&& mInputLength >= MIN_USER_TYPED_LENGTH_FOR_EXCESSIVE_CHARACTER_SUGGESTION) {
for (int i = 0; i < codesSize; ++i) {
if (DEBUG_DICT) {
LOGI("--- Suggest excessive characters %d", i);
}
getSuggestionCandidates(-1, i, -1, NULL, 0, MAX_DEPTH);
}
}
PROF_END(3);
PROF_START(4);
// Suggestion with transposed characters
// Only suggest words that length is mInputLength
if (SUGGEST_WORDS_WITH_TRANSPOSED_CHARACTERS) {
for (int i = 0; i < codesSize; ++i) {
if (DEBUG_DICT) {
LOGI("--- Suggest transposed characters %d", i);
}
getSuggestionCandidates(-1, -1, i, NULL, 0, mInputLength - 1);
}
}
PROF_END(4);
PROF_START(5);
// Suggestions with missing space
if (SUGGEST_WORDS_WITH_MISSING_SPACE_CHARACTER
&& mInputLength >= MIN_USER_TYPED_LENGTH_FOR_MISSING_SPACE_SUGGESTION) {
for (int i = 1; i < codesSize; ++i) {
if (DEBUG_DICT) {
LOGI("--- Suggest missing space characters %d", i);
}
getMissingSpaceWords(mInputLength, i);
}
}
PROF_END(5);
PROF_START(6);
if (SUGGEST_WORDS_WITH_SPACE_PROXIMITY && proximityInfo) {
// The first and last "mistyped spaces" are taken care of by excessive character handling
for (int i = 1; i < codesSize - 1; ++i) {
if (DEBUG_DICT) {
LOGI("--- Suggest words with proximity space %d", i);
}
const int x = xcoordinates[i];
const int y = ycoordinates[i];
if (DEBUG_PROXIMITY_INFO) {
LOGI("Input[%d] x = %d, y = %d, has space proximity = %d",
i, x, y, proximityInfo->hasSpaceProximity(x, y));
}
if (proximityInfo->hasSpaceProximity(x, y)) {
getMistypedSpaceWords(mInputLength, i);
}
}
}
PROF_END(6);
}
void UnigramDictionary::initSuggestions(ProximityInfo *proximityInfo, const int *xcoordinates,
const int *ycoordinates, const int *codes, const int codesSize,
unsigned short *outWords, int *frequencies) {
if (DEBUG_DICT) {
LOGI("initSuggest");
}
mFrequencies = frequencies;
mOutputChars = outWords;
mInputLength = codesSize;
mMaxEditDistance = mInputLength < 5 ? 2 : mInputLength / 2;
proximityInfo->setInputParams(codes, codesSize);
mProximityInfo = proximityInfo;
}
static inline void registerNextLetter(unsigned short c, int *nextLetters, int nextLettersSize) {
if (c < nextLettersSize) {
nextLetters[c]++;
}
}
// TODO: We need to optimize addWord by using STL or something
// TODO: This needs to take an const unsigned short* and not tinker with its contents
bool UnigramDictionary::addWord(unsigned short *word, int length, int frequency) {
word[length] = 0;
if (DEBUG_DICT && DEBUG_SHOW_FOUND_WORD) {
#ifdef FLAG_DBG
char s[length + 1];
for (int i = 0; i <= length; i++) s[i] = word[i];
LOGI("Found word = %s, freq = %d", s, frequency);
#endif
}
if (length > MAX_WORD_LENGTH) {
if (DEBUG_DICT) {
LOGI("Exceeded max word length.");
}
return false;
}
// Find the right insertion point
int insertAt = 0;
while (insertAt < MAX_WORDS) {
// TODO: How should we sort words with the same frequency?
if (frequency > mFrequencies[insertAt]) {
break;
}
insertAt++;
}
if (insertAt < MAX_WORDS) {
if (DEBUG_DICT) {
#ifdef FLAG_DBG
char s[length + 1];
for (int i = 0; i <= length; i++) s[i] = word[i];
LOGI("Added word = %s, freq = %d, %d", s, frequency, S_INT_MAX);
#endif
}
memmove((char*) mFrequencies + (insertAt + 1) * sizeof(mFrequencies[0]),
(char*) mFrequencies + insertAt * sizeof(mFrequencies[0]),
(MAX_WORDS - insertAt - 1) * sizeof(mFrequencies[0]));
mFrequencies[insertAt] = frequency;
memmove((char*) mOutputChars + (insertAt + 1) * MAX_WORD_LENGTH * sizeof(short),
(char*) mOutputChars + insertAt * MAX_WORD_LENGTH * sizeof(short),
(MAX_WORDS - insertAt - 1) * sizeof(short) * MAX_WORD_LENGTH);
unsigned short *dest = mOutputChars + insertAt * MAX_WORD_LENGTH;
while (length--) {
*dest++ = *word++;
}
*dest = 0; // NULL terminate
if (DEBUG_DICT) {
LOGI("Added word at %d", insertAt);
}
return true;
}
return false;
}
static const char QUOTE = '\'';
static const char SPACE = ' ';
void UnigramDictionary::getSuggestionCandidates(const int skipPos,
const int excessivePos, const int transposedPos, int *nextLetters,
const int nextLettersSize, const int maxDepth) {
if (DEBUG_DICT) {
LOGI("getSuggestionCandidates %d", maxDepth);
assert(transposedPos + 1 < mInputLength);
assert(excessivePos < mInputLength);
assert(missingPos < mInputLength);
}
mCorrectionState->setCorrectionParams(mProximityInfo, mInputLength, skipPos, excessivePos,
transposedPos);
int rootPosition = ROOT_POS;
// Get the number of children of root, then increment the position
int childCount = Dictionary::getCount(DICT_ROOT, &rootPosition);
int depth = 0;
mStackChildCount[0] = childCount;
mStackTraverseAll[0] = (mInputLength <= 0);
mStackNodeFreq[0] = 1;
mStackInputIndex[0] = 0;
mStackDiffs[0] = 0;
mStackSiblingPos[0] = rootPosition;
mStackOutputIndex[0] = 0;
// Depth first search
while (depth >= 0) {
if (mStackChildCount[depth] > 0) {
--mStackChildCount[depth];
bool traverseAllNodes = mStackTraverseAll[depth];
int matchWeight = mStackNodeFreq[depth];
int inputIndex = mStackInputIndex[depth];
int diffs = mStackDiffs[depth];
int siblingPos = mStackSiblingPos[depth];
int outputIndex = mStackOutputIndex[depth];
int firstChildPos;
// depth will never be greater than maxDepth because in that case,
// needsToTraverseChildrenNodes should be false
const bool needsToTraverseChildrenNodes = processCurrentNode(siblingPos, outputIndex,
maxDepth, traverseAllNodes, matchWeight, inputIndex, diffs,
nextLetters, nextLettersSize, mCorrectionState, &childCount,
&firstChildPos, &traverseAllNodes, &matchWeight, &inputIndex, &diffs,
&siblingPos, &outputIndex);
// Update next sibling pos
mStackSiblingPos[depth] = siblingPos;
if (needsToTraverseChildrenNodes) {
// Goes to child node
++depth;
mStackChildCount[depth] = childCount;
mStackTraverseAll[depth] = traverseAllNodes;
mStackNodeFreq[depth] = matchWeight;
mStackInputIndex[depth] = inputIndex;
mStackDiffs[depth] = diffs;
mStackSiblingPos[depth] = firstChildPos;
mStackOutputIndex[depth] = outputIndex;
}
} else {
// Goes to parent sibling node
--depth;
}
}
}
static const int TWO_31ST_DIV_255 = S_INT_MAX / 255;
static inline int capped255MultForFullMatchAccentsOrCapitalizationDifference(const int num) {
return (num < TWO_31ST_DIV_255 ? 255 * num : S_INT_MAX);
}
static const int TWO_31ST_DIV_2 = S_INT_MAX / 2;
inline static void multiplyIntCapped(const int multiplier, int *base) {
const int temp = *base;
if (temp != S_INT_MAX) {
// Branch if multiplier == 2 for the optimization
if (multiplier == 2) {
*base = TWO_31ST_DIV_2 >= temp ? temp << 1 : S_INT_MAX;
} else {
const int tempRetval = temp * multiplier;
*base = tempRetval >= temp ? tempRetval : S_INT_MAX;
}
}
}
inline static int powerIntCapped(const int base, const int n) {
if (base == 2) {
return n < 31 ? 1 << n : S_INT_MAX;
} else {
int ret = base;
for (int i = 1; i < n; ++i) multiplyIntCapped(base, &ret);
return ret;
}
}
inline static void multiplyRate(const int rate, int *freq) {
if (*freq != S_INT_MAX) {
if (*freq > 1000000) {
*freq /= 100;
multiplyIntCapped(rate, freq);
} else {
multiplyIntCapped(rate, freq);
*freq /= 100;
}
}
}
inline static int calcFreqForSplitTwoWords(
const int typedLetterMultiplier, const int firstWordLength, const int secondWordLength,
const int firstFreq, const int secondFreq, const bool isSpaceProximity) {
if (firstWordLength == 0 || secondWordLength == 0) {
return 0;
}
const int firstDemotionRate = 100 - 100 / (firstWordLength + 1);
int tempFirstFreq = firstFreq;
multiplyRate(firstDemotionRate, &tempFirstFreq);
const int secondDemotionRate = 100 - 100 / (secondWordLength + 1);
int tempSecondFreq = secondFreq;
multiplyRate(secondDemotionRate, &tempSecondFreq);
const int totalLength = firstWordLength + secondWordLength;
// Promote pairFreq with multiplying by 2, because the word length is the same as the typed
// length.
int totalFreq = tempFirstFreq + tempSecondFreq;
// This is a workaround to try offsetting the not-enough-demotion which will be done in
// calcNormalizedScore in Utils.java.
// In calcNormalizedScore the score will be demoted by (1 - 1 / length)
// but we demoted only (1 - 1 / (length + 1)) so we will additionally adjust freq by
// (1 - 1 / length) / (1 - 1 / (length + 1)) = (1 - 1 / (length * length))
const int normalizedScoreNotEnoughDemotionAdjustment = 100 - 100 / (totalLength * totalLength);
multiplyRate(normalizedScoreNotEnoughDemotionAdjustment, &totalFreq);
// At this moment, totalFreq is calculated by the following formula:
// (firstFreq * (1 - 1 / (firstWordLength + 1)) + secondFreq * (1 - 1 / (secondWordLength + 1)))
// * (1 - 1 / totalLength) / (1 - 1 / (totalLength + 1))
multiplyIntCapped(powerIntCapped(typedLetterMultiplier, totalLength), &totalFreq);
// This is another workaround to offset the demotion which will be done in
// calcNormalizedScore in Utils.java.
// In calcNormalizedScore the score will be demoted by (1 - 1 / length) so we have to promote
// the same amount because we already have adjusted the synthetic freq of this "missing or
// mistyped space" suggestion candidate above in this method.
const int normalizedScoreDemotionRateOffset = (100 + 100 / totalLength);
multiplyRate(normalizedScoreDemotionRateOffset, &totalFreq);
if (isSpaceProximity) {
// A word pair with one space proximity correction
if (DEBUG_DICT) {
LOGI("Found a word pair with space proximity correction.");
}
multiplyIntCapped(typedLetterMultiplier, &totalFreq);
multiplyRate(WORDS_WITH_PROXIMITY_CHARACTER_DEMOTION_RATE, &totalFreq);
}
multiplyRate(WORDS_WITH_MISSING_SPACE_CHARACTER_DEMOTION_RATE, &totalFreq);
return totalFreq;
}
bool UnigramDictionary::getMissingSpaceWords(const int inputLength, const int missingSpacePos) {
return getSplitTwoWordsSuggestion(
inputLength, 0, missingSpacePos, missingSpacePos, inputLength - missingSpacePos, false);
}
bool UnigramDictionary::getMistypedSpaceWords(const int inputLength, const int spaceProximityPos) {
return getSplitTwoWordsSuggestion(
inputLength, 0, spaceProximityPos, spaceProximityPos + 1,
inputLength - spaceProximityPos - 1, true);
}
inline int UnigramDictionary::calculateFinalFreq(const int inputIndex, const int depth,
const int matchWeight, const int freq, const bool sameLength,
CorrectionState *correctionState) const {
const int skipPos = correctionState->getSkipPos();
const int excessivePos = correctionState->getExcessivePos();
const int transposedPos = correctionState->getTransposedPos();
// TODO: Demote by edit distance
int finalFreq = freq * matchWeight;
if (skipPos >= 0) {
if (mInputLength >= 2) {
const int demotionRate = WORDS_WITH_MISSING_CHARACTER_DEMOTION_RATE
* (10 * mInputLength - WORDS_WITH_MISSING_CHARACTER_DEMOTION_START_POS_10X)
/ (10 * mInputLength
- WORDS_WITH_MISSING_CHARACTER_DEMOTION_START_POS_10X + 10);
if (DEBUG_DICT_FULL) {
LOGI("Demotion rate for missing character is %d.", demotionRate);
}
multiplyRate(demotionRate, &finalFreq);
} else {
finalFreq = 0;
}
}
if (transposedPos >= 0) multiplyRate(
WORDS_WITH_TRANSPOSED_CHARACTERS_DEMOTION_RATE, &finalFreq);
if (excessivePos >= 0) {
multiplyRate(WORDS_WITH_EXCESSIVE_CHARACTER_DEMOTION_RATE, &finalFreq);
if (!mProximityInfo->existsAdjacentProximityChars(inputIndex)) {
// If an excessive character is not adjacent to the left char or the right char,
// we will demote this word.
multiplyRate(WORDS_WITH_EXCESSIVE_CHARACTER_OUT_OF_PROXIMITY_DEMOTION_RATE, &finalFreq);
}
}
int lengthFreq = TYPED_LETTER_MULTIPLIER;
multiplyIntCapped(powerIntCapped(TYPED_LETTER_MULTIPLIER, depth), &lengthFreq);
if (lengthFreq == matchWeight) {
// Full exact match
if (depth > 1) {
if (DEBUG_DICT) {
LOGI("Found full matched word.");
}
multiplyRate(FULL_MATCHED_WORDS_PROMOTION_RATE, &finalFreq);
}
if (sameLength && transposedPos < 0 && skipPos < 0 && excessivePos < 0) {
finalFreq = capped255MultForFullMatchAccentsOrCapitalizationDifference(finalFreq);
}
} else if (sameLength && transposedPos < 0 && skipPos < 0 && excessivePos < 0 && depth > 0) {
// A word with proximity corrections
if (DEBUG_DICT) {
LOGI("Found one proximity correction.");
}
multiplyIntCapped(TYPED_LETTER_MULTIPLIER, &finalFreq);
multiplyRate(WORDS_WITH_PROXIMITY_CHARACTER_DEMOTION_RATE, &finalFreq);
}
if (DEBUG_DICT) {
LOGI("calc: %d, %d", depth, sameLength);
}
if (sameLength) multiplyIntCapped(FULL_WORD_MULTIPLIER, &finalFreq);
return finalFreq;
}
inline bool UnigramDictionary::needsToSkipCurrentNode(const unsigned short c,
const int inputIndex, const int skipPos, const int depth) {
const unsigned short userTypedChar = mProximityInfo->getPrimaryCharAt(inputIndex);
// Skip the ' or other letter and continue deeper
return (c == QUOTE && userTypedChar != QUOTE) || skipPos == depth;
}
inline void UnigramDictionary::onTerminal(unsigned short int* word, const int depth,
const uint8_t* const root, const uint8_t flags, const int pos,
const int inputIndex, const int matchWeight, const int freq, const bool sameLength,
int* nextLetters, const int nextLettersSize, CorrectionState *correctionState) {
const int skipPos = correctionState->getSkipPos();
const bool isSameAsTyped = sameLength ? mProximityInfo->sameAsTyped(word, depth + 1) : false;
if (isSameAsTyped) return;
if (depth >= MIN_SUGGEST_DEPTH) {
const int finalFreq = calculateFinalFreq(inputIndex, depth, matchWeight,
freq, sameLength, correctionState);
if (!isSameAsTyped)
addWord(word, depth + 1, finalFreq);
}
if (sameLength && depth >= mInputLength && skipPos < 0) {
registerNextLetter(word[mInputLength], nextLetters, nextLettersSize);
}
}
bool UnigramDictionary::getSplitTwoWordsSuggestion(const int inputLength,
const int firstWordStartPos, const int firstWordLength, const int secondWordStartPos,
const int secondWordLength, const bool isSpaceProximity) {
if (inputLength >= MAX_WORD_LENGTH) return false;
if (0 >= firstWordLength || 0 >= secondWordLength || firstWordStartPos >= secondWordStartPos
|| firstWordStartPos < 0 || secondWordStartPos + secondWordLength > inputLength)
return false;
const int newWordLength = firstWordLength + secondWordLength + 1;
// Allocating variable length array on stack
unsigned short word[newWordLength];
const int firstFreq = getMostFrequentWordLike(firstWordStartPos, firstWordLength, mWord);
if (DEBUG_DICT) {
LOGI("First freq: %d", firstFreq);
}
if (firstFreq <= 0) return false;
for (int i = 0; i < firstWordLength; ++i) {
word[i] = mWord[i];
}
const int secondFreq = getMostFrequentWordLike(secondWordStartPos, secondWordLength, mWord);
if (DEBUG_DICT) {
LOGI("Second freq: %d", secondFreq);
}
if (secondFreq <= 0) return false;
word[firstWordLength] = SPACE;
for (int i = (firstWordLength + 1); i < newWordLength; ++i) {
word[i] = mWord[i - firstWordLength - 1];
}
int pairFreq = calcFreqForSplitTwoWords(TYPED_LETTER_MULTIPLIER, firstWordLength,
secondWordLength, firstFreq, secondFreq, isSpaceProximity);
if (DEBUG_DICT) {
LOGI("Split two words: %d, %d, %d, %d, %d", firstFreq, secondFreq, pairFreq, inputLength,
TYPED_LETTER_MULTIPLIER);
}
addWord(word, newWordLength, pairFreq);
return true;
}
#ifndef NEW_DICTIONARY_FORMAT
inline int UnigramDictionary::getMostFrequentWordLike(const int startInputIndex,
const int inputLength, unsigned short *word) {
int pos = ROOT_POS;
int count = Dictionary::getCount(DICT_ROOT, &pos);
int maxFreq = 0;
int depth = 0;
unsigned short newWord[MAX_WORD_LENGTH_INTERNAL];
bool terminal = false;
mStackChildCount[0] = count;
mStackSiblingPos[0] = pos;
while (depth >= 0) {
if (mStackChildCount[depth] > 0) {
--mStackChildCount[depth];
int firstChildPos;
int newFreq;
int siblingPos = mStackSiblingPos[depth];
const bool needsToTraverseChildrenNodes = processCurrentNodeForExactMatch(siblingPos,
startInputIndex, depth, newWord, &firstChildPos, &count, &terminal, &newFreq,
&siblingPos);
mStackSiblingPos[depth] = siblingPos;
if (depth == (inputLength - 1)) {
// Traverse sibling node
if (terminal) {
if (newFreq > maxFreq) {
for (int i = 0; i < inputLength; ++i) word[i] = newWord[i];
if (DEBUG_DICT && DEBUG_NODE) {
#ifdef FLAG_DBG
char s[inputLength + 1];
for (int i = 0; i < inputLength; ++i) s[i] = word[i];
s[inputLength] = 0;
LOGI("New missing space word found: %d > %d (%s), %d, %d",
newFreq, maxFreq, s, inputLength, depth);
#endif
}
maxFreq = newFreq;
}
}
} else if (needsToTraverseChildrenNodes) {
// Traverse children nodes
++depth;
mStackChildCount[depth] = count;
mStackSiblingPos[depth] = firstChildPos;
}
} else {
// Traverse parent node
--depth;
}
}
word[inputLength] = 0;
return maxFreq;
}
inline bool UnigramDictionary::processCurrentNodeForExactMatch(const int firstChildPos,
const int startInputIndex, const int depth, unsigned short *word, int *newChildPosition,
int *newCount, bool *newTerminal, int *newFreq, int *siblingPos) {
const int inputIndex = startInputIndex + depth;
unsigned short c;
*siblingPos = Dictionary::setDictionaryValues(DICT_ROOT, IS_LATEST_DICT_VERSION, firstChildPos,
&c, newChildPosition, newTerminal, newFreq);
const unsigned int inputC = mProximityInfo->getPrimaryCharAt(inputIndex);
if (DEBUG_DICT) {
assert(inputC <= U_SHORT_MAX);
}
const unsigned short baseLowerC = Dictionary::toBaseLowerCase(c);
const bool matched = (inputC == baseLowerC || inputC == c);
const bool hasChild = *newChildPosition != 0;
if (matched) {
word[depth] = c;
if (DEBUG_DICT && DEBUG_NODE) {
LOGI("Node(%c, %c)<%d>, %d, %d", inputC, c, matched, hasChild, *newFreq);
if (*newTerminal) {
LOGI("Terminal %d", *newFreq);
}
}
if (hasChild) {
*newCount = Dictionary::getCount(DICT_ROOT, newChildPosition);
return true;
} else {
return false;
}
} else {
// If this node is not user typed character, this method treats this word as unmatched.
// Thus newTerminal shouldn't be true.
*newTerminal = false;
return false;
}
}
// TODO: use uint32_t instead of unsigned short
bool UnigramDictionary::isValidWord(unsigned short *word, int length) {
if (IS_LATEST_DICT_VERSION) {
return (getBigramPosition(DICTIONARY_HEADER_SIZE, word, 0, length) != NOT_VALID_WORD);
} else {
return (getBigramPosition(0, word, 0, length) != NOT_VALID_WORD);
}
}
// Require strict exact match.
int UnigramDictionary::getBigramPosition(int pos, unsigned short *word, int offset,
int length) const {
// returns address of bigram data of that word
// return -99 if not found
int count = Dictionary::getCount(DICT_ROOT, &pos);
unsigned short currentChar = (unsigned short) word[offset];
for (int j = 0; j < count; j++) {
unsigned short c = Dictionary::getChar(DICT_ROOT, &pos);
int terminal = Dictionary::getTerminal(DICT_ROOT, &pos);
int childPos = Dictionary::getAddress(DICT_ROOT, &pos);
if (c == currentChar) {
if (offset == length - 1) {
if (terminal) {
return (pos+1);
}
} else {
if (childPos != 0) {
int t = getBigramPosition(childPos, word, offset + 1, length);
if (t > 0) {
return t;
}
}
}
}
if (terminal) {
Dictionary::getFreq(DICT_ROOT, IS_LATEST_DICT_VERSION, &pos);
}
// There could be two instances of each alphabet - upper and lower case. So continue
// looking ...
}
return NOT_VALID_WORD;
}
// The following functions will be modified.
inline bool UnigramDictionary::processCurrentNode(const int initialPos, const int initialDepth,
const int maxDepth, const bool initialTraverseAllNodes, int matchWeight, int inputIndex,
const int initialDiffs, int *nextLetters, const int nextLettersSize,
CorrectionState *correctionState, int *newCount, int *newChildPosition,
bool *newTraverseAllNodes, int *newMatchRate, int *newInputIndex, int *newDiffs,
int *nextSiblingPosition, int *nextOutputIndex) {
const int skipPos = correctionState->getSkipPos();
const int excessivePos = correctionState->getExcessivePos();
const int transposedPos = correctionState->getTransposedPos();
if (DEBUG_DICT) {
int inputCount = 0;
if (skipPos >= 0) ++inputCount;
if (excessivePos >= 0) ++inputCount;
if (transposedPos >= 0) ++inputCount;
assert(inputCount <= 1);
}
unsigned short c;
int childPosition;
bool terminal;
int freq;
bool isSameAsUserTypedLength = false;
const int pos = initialPos;
const int depth = initialDepth;
const int traverseAllNodes = initialTraverseAllNodes;
const int diffs = initialDiffs;
const uint8_t flags = 0; // No flags for now
if (excessivePos == depth && inputIndex < mInputLength - 1) ++inputIndex;
*nextSiblingPosition = Dictionary::setDictionaryValues(DICT_ROOT, IS_LATEST_DICT_VERSION, pos,
&c, &childPosition, &terminal, &freq);
*nextOutputIndex = depth + 1;
const bool needsToTraverseChildrenNodes = childPosition != 0;
// If we are only doing traverseAllNodes, no need to look at the typed characters.
if (traverseAllNodes || needsToSkipCurrentNode(c, inputIndex, skipPos, depth)) {
mWord[depth] = c;
if (traverseAllNodes && terminal) {
onTerminal(mWord, depth, DICT_ROOT, flags, pos, inputIndex, matchWeight,
freq, false, nextLetters, nextLettersSize, mCorrectionState);
}
if (!needsToTraverseChildrenNodes) return false;
*newTraverseAllNodes = traverseAllNodes;
*newMatchRate = matchWeight;
*newDiffs = diffs;
*newInputIndex = inputIndex;
} else {
int inputIndexForProximity = inputIndex;
if (transposedPos >= 0) {
if (inputIndex == transposedPos) ++inputIndexForProximity;
if (inputIndex == (transposedPos + 1)) --inputIndexForProximity;
}
ProximityInfo::ProximityType matchedProximityCharId = mProximityInfo->getMatchedProximityId(
inputIndexForProximity, c, mCorrectionState);
if (ProximityInfo::UNRELATED_CHAR == matchedProximityCharId) return false;
mWord[depth] = c;
// If inputIndex is greater than mInputLength, that means there is no
// proximity chars. So, we don't need to check proximity.
if (ProximityInfo::SAME_OR_ACCENTED_OR_CAPITALIZED_CHAR == matchedProximityCharId) {
multiplyIntCapped(TYPED_LETTER_MULTIPLIER, &matchWeight);
}
bool isSameAsUserTypedLength = mInputLength == inputIndex + 1
|| (excessivePos == mInputLength - 1 && inputIndex == mInputLength - 2);
if (isSameAsUserTypedLength && terminal) {
onTerminal(mWord, depth, DICT_ROOT, flags, pos, inputIndex, matchWeight,
freq, true, nextLetters, nextLettersSize, mCorrectionState);
}
if (!needsToTraverseChildrenNodes) return false;
// Start traversing all nodes after the index exceeds the user typed length
*newTraverseAllNodes = isSameAsUserTypedLength;
*newMatchRate = matchWeight;
*newDiffs = diffs
+ ((ProximityInfo::NEAR_PROXIMITY_CHAR == matchedProximityCharId) ? 1 : 0);
*newInputIndex = inputIndex + 1;
}
// Optimization: Prune out words that are too long compared to how much was typed.
if (depth >= maxDepth || *newDiffs > mMaxEditDistance) {
return false;
}
// If inputIndex is greater than mInputLength, that means there are no proximity chars.
// TODO: Check if this can be isSameAsUserTypedLength only.
if (isSameAsUserTypedLength || mInputLength <= *newInputIndex) {
*newTraverseAllNodes = true;
}
// get the count of nodes and increment childAddress.
*newCount = Dictionary::getCount(DICT_ROOT, &childPosition);
*newChildPosition = childPosition;
if (DEBUG_DICT) assert(needsToTraverseChildrenNodes);
return needsToTraverseChildrenNodes;
}
#else // NEW_DICTIONARY_FORMAT
// Wrapper for getMostFrequentWordLikeInner, which matches it to the previous
// interface.
inline int UnigramDictionary::getMostFrequentWordLike(const int startInputIndex,
const int inputLength, unsigned short *word) {
uint16_t inWord[inputLength];
for (int i = 0; i < inputLength; ++i) {
inWord[i] = (uint16_t)mProximityInfo->getPrimaryCharAt(startInputIndex + i);
}
return getMostFrequentWordLikeInner(inWord, inputLength, word);
}
// This function will take the position of a character array within a CharGroup,
// and check it actually like-matches the word in inWord starting at startInputIndex,
// that is, it matches it with case and accents squashed.
// The function returns true if there was a full match, false otherwise.
// The function will copy on-the-fly the characters in the CharGroup to outNewWord.
// It will also place the end position of the array in outPos; in outInputIndex,
// it will place the index of the first char AFTER the match if there was a match,
// and the initial position if there was not. It makes sense because if there was
// a match we want to continue searching, but if there was not, we want to go to
// the next CharGroup.
// In and out parameters may point to the same location. This function takes care
// not to use any input parameters after it wrote into its outputs.
static inline bool testCharGroupForContinuedLikeness(const uint8_t flags,
const uint8_t* const root, const int startPos,
const uint16_t* const inWord, const int startInputIndex,
int32_t* outNewWord, int* outInputIndex, int* outPos) {
const bool hasMultipleChars = (0 != (UnigramDictionary::FLAG_HAS_MULTIPLE_CHARS & flags));
int pos = startPos;
int32_t character = BinaryFormat::getCharCodeAndForwardPointer(root, &pos);
int32_t baseChar = Dictionary::toBaseLowerCase(character);
const uint16_t wChar = Dictionary::toBaseLowerCase(inWord[startInputIndex]);
if (baseChar != wChar) {
*outPos = hasMultipleChars ? BinaryFormat::skipOtherCharacters(root, pos) : pos;
*outInputIndex = startInputIndex;
return false;
}
int inputIndex = startInputIndex;
outNewWord[inputIndex] = character;
if (hasMultipleChars) {
character = BinaryFormat::getCharCodeAndForwardPointer(root, &pos);
while (NOT_A_CHARACTER != character) {
baseChar = Dictionary::toBaseLowerCase(character);
if (Dictionary::toBaseLowerCase(inWord[++inputIndex]) != baseChar) {
*outPos = BinaryFormat::skipOtherCharacters(root, pos);
*outInputIndex = startInputIndex;
return false;
}
outNewWord[inputIndex] = character;
character = BinaryFormat::getCharCodeAndForwardPointer(root, &pos);
}
}
*outInputIndex = inputIndex + 1;
*outPos = pos;
return true;
}
// This function is invoked when a word like the word searched for is found.
// It will compare the frequency to the max frequency, and if greater, will
// copy the word into the output buffer. In output value maxFreq, it will
// write the new maximum frequency if it changed.
static inline void onTerminalWordLike(const int freq, int32_t* newWord, const int length,
short unsigned int* outWord, int* maxFreq) {
if (freq > *maxFreq) {
for (int q = 0; q < length; ++q)
outWord[q] = newWord[q];
outWord[length] = 0;
*maxFreq = freq;
}
}
// Will find the highest frequency of the words like the one passed as an argument,
// that is, everything that only differs by case/accents.
int UnigramDictionary::getMostFrequentWordLikeInner(const uint16_t * const inWord,
const int length, short unsigned int* outWord) {
int32_t newWord[MAX_WORD_LENGTH_INTERNAL];
int depth = 0;
int maxFreq = -1;
const uint8_t* const root = DICT_ROOT;
mStackChildCount[0] = root[0];
mStackInputIndex[0] = 0;
mStackSiblingPos[0] = 1;
while (depth >= 0) {
const int charGroupCount = mStackChildCount[depth];
int pos = mStackSiblingPos[depth];
for (int charGroupIndex = charGroupCount - 1; charGroupIndex >= 0; --charGroupIndex) {
int inputIndex = mStackInputIndex[depth];
const uint8_t flags = BinaryFormat::getFlagsAndForwardPointer(root, &pos);
// Test whether all chars in this group match with the word we are searching for. If so,
// we want to traverse its children (or if the length match, evaluate its frequency).
// Note that this function will output the position regardless, but will only write
// into inputIndex if there is a match.
const bool isAlike = testCharGroupForContinuedLikeness(flags, root, pos, inWord,
inputIndex, newWord, &inputIndex, &pos);
if (isAlike && (FLAG_IS_TERMINAL & flags) && (inputIndex == length)) {
const int frequency = BinaryFormat::readFrequencyWithoutMovingPointer(root, pos);
onTerminalWordLike(frequency, newWord, inputIndex, outWord, &maxFreq);
}
pos = BinaryFormat::skipFrequency(flags, pos);
const int siblingPos = BinaryFormat::skipChildrenPosAndAttributes(root, flags, pos);
const int childrenNodePos = BinaryFormat::readChildrenPosition(root, flags, pos);
// If we had a match and the word has children, we want to traverse them. We don't have
// to traverse words longer than the one we are searching for, since they will not match
// anyway, so don't traverse unless inputIndex < length.
if (isAlike && (-1 != childrenNodePos) && (inputIndex < length)) {
// Save position for this depth, to get back to this once children are done
mStackChildCount[depth] = charGroupIndex;
mStackSiblingPos[depth] = siblingPos;
// Prepare stack values for next depth
++depth;
int childrenPos = childrenNodePos;
mStackChildCount[depth] =
BinaryFormat::getGroupCountAndForwardPointer(root, &childrenPos);
mStackSiblingPos[depth] = childrenPos;
mStackInputIndex[depth] = inputIndex;
pos = childrenPos;
// Go to the next depth level.
++depth;
break;
} else {
// No match, or no children, or word too long to ever match: go the next sibling.
pos = siblingPos;
}
}
--depth;
}
return maxFreq;
}
bool UnigramDictionary::isValidWord(const uint16_t* const inWord, const int length) const {
return NOT_VALID_WORD != BinaryFormat::getTerminalPosition(DICT_ROOT, inWord, length);
}
// TODO: remove this function.
int UnigramDictionary::getBigramPosition(int pos, unsigned short *word, int offset,
int length) const {
return -1;
}
// ProcessCurrentNode returns a boolean telling whether to traverse children nodes or not.
// If the return value is false, then the caller should read in the output "nextSiblingPosition"
// to find out the address of the next sibling node and pass it to a new call of processCurrentNode.
// It is worthy to note that when false is returned, the output values other than
// nextSiblingPosition are undefined.
// If the return value is true, then the caller must proceed to traverse the children of this
// node. processCurrentNode will output the information about the children: their count in
// newCount, their position in newChildrenPosition, the traverseAllNodes flag in
// newTraverseAllNodes, the match weight into newMatchRate, the input index into newInputIndex, the
// diffs into newDiffs, the sibling position in nextSiblingPosition, and the output index into
// newOutputIndex. Please also note the following caveat: processCurrentNode does not know when
// there aren't any more nodes at this level, it merely returns the address of the first byte after
// the current node in nextSiblingPosition. Thus, the caller must keep count of the nodes at any
// given level, as output into newCount when traversing this level's parent.
inline bool UnigramDictionary::processCurrentNode(const int initialPos, const int initialDepth,
const int maxDepth, const bool initialTraverseAllNodes, int matchWeight, int inputIndex,
const int initialDiffs, int *nextLetters, const int nextLettersSize,
CorrectionState *correctionState, int *newCount, int *newChildrenPosition,
bool *newTraverseAllNodes, int *newMatchRate, int *newInputIndex, int *newDiffs,
int *nextSiblingPosition, int *newOutputIndex) {
const int skipPos = correctionState->getSkipPos();
const int excessivePos = correctionState->getExcessivePos();
const int transposedPos = correctionState->getTransposedPos();
if (DEBUG_DICT) {
correctionState->checkState();
}
int pos = initialPos;
int depth = initialDepth;
int traverseAllNodes = initialTraverseAllNodes;
int diffs = initialDiffs;
// Flags contain the following information:
// - Address type (MASK_GROUP_ADDRESS_TYPE) on two bits:
// - FLAG_GROUP_ADDRESS_TYPE_{ONE,TWO,THREE}_BYTES means there are children and their address
// is on the specified number of bytes.
// - FLAG_GROUP_ADDRESS_TYPE_NOADDRESS means there are no children, and therefore no address.
// - FLAG_HAS_MULTIPLE_CHARS: whether this node has multiple char or not.
// - FLAG_IS_TERMINAL: whether this node is a terminal or not (it may still have children)
// - FLAG_HAS_BIGRAMS: whether this node has bigrams or not
const uint8_t flags = BinaryFormat::getFlagsAndForwardPointer(DICT_ROOT, &pos);
const bool hasMultipleChars = (0 != (FLAG_HAS_MULTIPLE_CHARS & flags));
// This gets only ONE character from the stream. Next there will be:
// if FLAG_HAS_MULTIPLE CHARS: the other characters of the same node
// else if FLAG_IS_TERMINAL: the frequency
// else if MASK_GROUP_ADDRESS_TYPE is not NONE: the children address
// Note that you can't have a node that both is not a terminal and has no children.
int32_t c = BinaryFormat::getCharCodeAndForwardPointer(DICT_ROOT, &pos);
assert(NOT_A_CHARACTER != c);
// We are going to loop through each character and make it look like it's a different
// node each time. To do that, we will process characters in this node in order until
// we find the character terminator. This is signalled by getCharCode* returning
// NOT_A_CHARACTER.
// As a special case, if there is only one character in this node, we must not read the
// next bytes so we will simulate the NOT_A_CHARACTER return by testing the flags.
// This way, each loop run will look like a "virtual node".
do {
// We prefetch the next char. If 'c' is the last char of this node, we will have
// NOT_A_CHARACTER in the next char. From this we can decide whether this virtual node
// should behave as a terminal or not and whether we have children.
const int32_t nextc = hasMultipleChars
? BinaryFormat::getCharCodeAndForwardPointer(DICT_ROOT, &pos) : NOT_A_CHARACTER;
const bool isLastChar = (NOT_A_CHARACTER == nextc);
// If there are more chars in this nodes, then this virtual node is not a terminal.
// If we are on the last char, this virtual node is a terminal if this node is.
const bool isTerminal = isLastChar && (0 != (FLAG_IS_TERMINAL & flags));
// If there are more chars in this node, then this virtual node has children.
// If we are on the last char, this virtual node has children if this node has.
const bool hasChildren = (!isLastChar) || BinaryFormat::hasChildrenInFlags(flags);
// This has to be done for each virtual char (this forwards the "inputIndex" which
// is the index in the user-inputted chars, as read by proximity chars.
if (excessivePos == depth && inputIndex < mInputLength - 1) ++inputIndex;
if (traverseAllNodes || needsToSkipCurrentNode(c, inputIndex, skipPos, depth)) {
mWord[depth] = c;
if (traverseAllNodes && isTerminal) {
// The frequency should be here, because we come here only if this is actually
// a terminal node, and we are on its last char.
const int freq = BinaryFormat::readFrequencyWithoutMovingPointer(DICT_ROOT, pos);
onTerminal(mWord, depth, DICT_ROOT, flags, pos, inputIndex, matchWeight,
freq, false, nextLetters, nextLettersSize, mCorrectionState);
}
if (!hasChildren) {
// If we don't have children here, that means we finished processing all
// characters of this node (we are on the last virtual node), AND we are in
// traverseAllNodes mode, which means we are searching for *completions*. We
// should skip the frequency if we have a terminal, and report the position
// of the next sibling. We don't have to return other values because we are
// returning false, as in "don't traverse children".
if (isTerminal) pos = BinaryFormat::skipFrequency(flags, pos);
*nextSiblingPosition =
BinaryFormat::skipChildrenPosAndAttributes(DICT_ROOT, flags, pos);
return false;
}
} else {
int inputIndexForProximity = inputIndex;
if (transposedPos >= 0) {
if (inputIndex == transposedPos) ++inputIndexForProximity;
if (inputIndex == (transposedPos + 1)) --inputIndexForProximity;
}
int matchedProximityCharId = mProximityInfo->getMatchedProximityId(
inputIndexForProximity, c, mCorrectionState);
if (ProximityInfo::UNRELATED_CHAR == matchedProximityCharId) {
// We found that this is an unrelated character, so we should give up traversing
// this node and its children entirely.
// However we may not be on the last virtual node yet so we skip the remaining
// characters in this node, the frequency if it's there, read the next sibling
// position to output it, then return false.
// We don't have to output other values because we return false, as in
// "don't traverse children".
if (!isLastChar) {
pos = BinaryFormat::skipOtherCharacters(DICT_ROOT, pos);
}
pos = BinaryFormat::skipFrequency(flags, pos);
*nextSiblingPosition =
BinaryFormat::skipChildrenPosAndAttributes(DICT_ROOT, flags, pos);
return false;
}
mWord[depth] = c;
// If inputIndex is greater than mInputLength, that means there is no
// proximity chars. So, we don't need to check proximity.
if (ProximityInfo::SAME_OR_ACCENTED_OR_CAPITALIZED_CHAR == matchedProximityCharId) {
multiplyIntCapped(TYPED_LETTER_MULTIPLIER, &matchWeight);
}
const bool isSameAsUserTypedLength = mInputLength == inputIndex + 1
|| (excessivePos == mInputLength - 1 && inputIndex == mInputLength - 2);
if (isSameAsUserTypedLength && isTerminal) {
const int freq = BinaryFormat::readFrequencyWithoutMovingPointer(DICT_ROOT, pos);
onTerminal(mWord, depth, DICT_ROOT, flags, pos, inputIndex, matchWeight,
freq, true, nextLetters, nextLettersSize, mCorrectionState);
}
// This character matched the typed character (enough to traverse the node at least)
// so we just evaluated it. Now we should evaluate this virtual node's children - that
// is, if it has any. If it has no children, we're done here - so we skip the end of
// the node, output the siblings position, and return false "don't traverse children".
// Note that !hasChildren implies isLastChar, so we know we don't have to skip any
// remaining char in this group for there can't be any.
if (!hasChildren) {
pos = BinaryFormat::skipFrequency(flags, pos);
*nextSiblingPosition =
BinaryFormat::skipChildrenPosAndAttributes(DICT_ROOT, flags, pos);
return false;
}
// Start traversing all nodes after the index exceeds the user typed length
traverseAllNodes = isSameAsUserTypedLength;
diffs = diffs
+ ((ProximityInfo::NEAR_PROXIMITY_CHAR == matchedProximityCharId) ? 1 : 0);
// Finally, we are ready to go to the next character, the next "virtual node".
// We should advance the input index.
// We do this in this branch of the 'if traverseAllNodes' because we are still matching
// characters to input; the other branch is not matching them but searching for
// completions, this is why it does not have to do it.
++inputIndex;
}
// Optimization: Prune out words that are too long compared to how much was typed.
if (depth >= maxDepth || diffs > mMaxEditDistance) {
// We are giving up parsing this node and its children. Skip the rest of the node,
// output the sibling position, and return that we don't want to traverse children.
if (!isLastChar) {
pos = BinaryFormat::skipOtherCharacters(DICT_ROOT, pos);
}
pos = BinaryFormat::skipFrequency(flags, pos);
*nextSiblingPosition =
BinaryFormat::skipChildrenPosAndAttributes(DICT_ROOT, flags, pos);
return false;
}
// Prepare for the next character. Promote the prefetched char to current char - the loop
// will take care of prefetching the next. If we finally found our last char, nextc will
// contain NOT_A_CHARACTER.
c = nextc;
// Also, the next char is one "virtual node" depth more than this char.
++depth;
} while (NOT_A_CHARACTER != c);
// If inputIndex is greater than mInputLength, that means there are no proximity chars.
// Here, that's all we are interested in so we don't need to check for isSameAsUserTypedLength.
if (mInputLength <= *newInputIndex) {
traverseAllNodes = true;
}
// All the output values that are purely computation by this function are held in local
// variables. Output them to the caller.
*newTraverseAllNodes = traverseAllNodes;
*newMatchRate = matchWeight;
*newDiffs = diffs;
*newInputIndex = inputIndex;
*newOutputIndex = depth;
// Now we finished processing this node, and we want to traverse children. If there are no
// children, we can't come here.
assert(BinaryFormat::hasChildrenInFlags(flags));
// If this node was a terminal it still has the frequency under the pointer (it may have been
// read, but not skipped - see readFrequencyWithoutMovingPointer).
// Next come the children position, then possibly attributes (attributes are bigrams only for
// now, maybe something related to shortcuts in the future).
// Once this is read, we still need to output the number of nodes in the immediate children of
// this node, so we read and output it before returning true, as in "please traverse children".
pos = BinaryFormat::skipFrequency(flags, pos);
int childrenPos = BinaryFormat::readChildrenPosition(DICT_ROOT, flags, pos);
*nextSiblingPosition = BinaryFormat::skipChildrenPosAndAttributes(DICT_ROOT, flags, pos);
*newCount = BinaryFormat::getGroupCountAndForwardPointer(DICT_ROOT, &childrenPos);
*newChildrenPosition = childrenPos;
return true;
}
#endif // NEW_DICTIONARY_FORMAT
} // namespace latinime