/* * Copyright (C) 2011 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 #include #include #define LOG_TAG "LatinIME: proximity_info.cpp" #include "additional_proximity_chars.h" #include "defines.h" #include "dictionary.h" #include "proximity_info.h" #include "proximity_info_state.h" namespace latinime { inline void copyOrFillZero(void *to, const void *from, size_t size) { if (from) { memcpy(to, from, size); } else { memset(to, 0, size); } } ProximityInfo::ProximityInfo(const std::string localeStr, const int maxProximityCharsSize, const int keyboardWidth, const int keyboardHeight, const int gridWidth, const int gridHeight, const int mostCommonKeyWidth, const int32_t *proximityCharsArray, const int keyCount, const int32_t *keyXCoordinates, const int32_t *keyYCoordinates, const int32_t *keyWidths, const int32_t *keyHeights, const int32_t *keyCharCodes, const float *sweetSpotCenterXs, const float *sweetSpotCenterYs, const float *sweetSpotRadii) : MAX_PROXIMITY_CHARS_SIZE(maxProximityCharsSize), KEYBOARD_WIDTH(keyboardWidth), KEYBOARD_HEIGHT(keyboardHeight), GRID_WIDTH(gridWidth), GRID_HEIGHT(gridHeight), MOST_COMMON_KEY_WIDTH_SQUARE(mostCommonKeyWidth * mostCommonKeyWidth), CELL_WIDTH((keyboardWidth + gridWidth - 1) / gridWidth), CELL_HEIGHT((keyboardHeight + gridHeight - 1) / gridHeight), KEY_COUNT(min(keyCount, MAX_KEY_COUNT_IN_A_KEYBOARD)), HAS_TOUCH_POSITION_CORRECTION_DATA(keyCount > 0 && keyXCoordinates && keyYCoordinates && keyWidths && keyHeights && keyCharCodes && sweetSpotCenterXs && sweetSpotCenterYs && sweetSpotRadii), mLocaleStr(localeStr) { const int proximityGridLength = GRID_WIDTH * GRID_HEIGHT * MAX_PROXIMITY_CHARS_SIZE; if (DEBUG_PROXIMITY_INFO) { AKLOGI("Create proximity info array %d", proximityGridLength); } mProximityCharsArray = new int32_t[proximityGridLength]; memcpy(mProximityCharsArray, proximityCharsArray, proximityGridLength * sizeof(mProximityCharsArray[0])); copyOrFillZero(mKeyXCoordinates, keyXCoordinates, KEY_COUNT * sizeof(mKeyXCoordinates[0])); copyOrFillZero(mKeyYCoordinates, keyYCoordinates, KEY_COUNT * sizeof(mKeyYCoordinates[0])); copyOrFillZero(mKeyWidths, keyWidths, KEY_COUNT * sizeof(mKeyWidths[0])); copyOrFillZero(mKeyHeights, keyHeights, KEY_COUNT * sizeof(mKeyHeights[0])); copyOrFillZero(mKeyCharCodes, keyCharCodes, KEY_COUNT * sizeof(mKeyCharCodes[0])); copyOrFillZero(mSweetSpotCenterXs, sweetSpotCenterXs, KEY_COUNT * sizeof(mSweetSpotCenterXs[0])); copyOrFillZero(mSweetSpotCenterYs, sweetSpotCenterYs, KEY_COUNT * sizeof(mSweetSpotCenterYs[0])); copyOrFillZero(mSweetSpotRadii, sweetSpotRadii, KEY_COUNT * sizeof(mSweetSpotRadii[0])); initializeCodeToKeyIndex(); } // Build the reversed look up table from the char code to the index in mKeyXCoordinates, // mKeyYCoordinates, mKeyWidths, mKeyHeights, mKeyCharCodes. void ProximityInfo::initializeCodeToKeyIndex() { memset(mCodeToKeyIndex, -1, (MAX_CHAR_CODE + 1) * sizeof(mCodeToKeyIndex[0])); for (int i = 0; i < KEY_COUNT; ++i) { const int code = mKeyCharCodes[i]; if (0 <= code && code <= MAX_CHAR_CODE) { mCodeToKeyIndex[code] = i; } } } ProximityInfo::~ProximityInfo() { delete[] mProximityCharsArray; } inline int ProximityInfo::getStartIndexFromCoordinates(const int x, const int y) const { return ((y / CELL_HEIGHT) * GRID_WIDTH + (x / CELL_WIDTH)) * MAX_PROXIMITY_CHARS_SIZE; } bool ProximityInfo::hasSpaceProximity(const int x, const int y) const { if (x < 0 || y < 0) { if (DEBUG_DICT) { AKLOGI("HasSpaceProximity: Illegal coordinates (%d, %d)", x, y); assert(false); } return false; } const int startIndex = getStartIndexFromCoordinates(x, y); if (DEBUG_PROXIMITY_INFO) { AKLOGI("hasSpaceProximity: index %d, %d, %d", startIndex, x, y); } int32_t* proximityCharsArray = mProximityCharsArray; for (int i = 0; i < MAX_PROXIMITY_CHARS_SIZE; ++i) { if (DEBUG_PROXIMITY_INFO) { AKLOGI("Index: %d", mProximityCharsArray[startIndex + i]); } if (proximityCharsArray[startIndex + i] == KEYCODE_SPACE) { return true; } } return false; } int ProximityInfo::squaredDistanceToEdge(const int keyId, const int x, const int y) const { if (keyId < 0) return true; // NOT_A_ID is -1, but return whenever < 0 just in case const int left = mKeyXCoordinates[keyId]; const int top = mKeyYCoordinates[keyId]; const int right = left + mKeyWidths[keyId]; const int bottom = top + mKeyHeights[keyId]; const int edgeX = x < left ? left : (x > right ? right : x); const int edgeY = y < top ? top : (y > bottom ? bottom : y); const int dx = x - edgeX; const int dy = y - edgeY; return dx * dx + dy * dy; } void ProximityInfo::calculateNearbyKeyCodes( const int x, const int y, const int32_t primaryKey, int *inputCodes) const { int32_t *proximityCharsArray = mProximityCharsArray; int insertPos = 0; inputCodes[insertPos++] = primaryKey; const int startIndex = getStartIndexFromCoordinates(x, y); if (startIndex >= 0) { for (int i = 0; i < MAX_PROXIMITY_CHARS_SIZE; ++i) { const int32_t c = proximityCharsArray[startIndex + i]; if (c < KEYCODE_SPACE || c == primaryKey) { continue; } const int keyIndex = getKeyIndex(c); const bool onKey = isOnKey(keyIndex, x, y); const int distance = squaredDistanceToEdge(keyIndex, x, y); if (onKey || distance < MOST_COMMON_KEY_WIDTH_SQUARE) { inputCodes[insertPos++] = c; if (insertPos >= MAX_PROXIMITY_CHARS_SIZE) { if (DEBUG_DICT) { assert(false); } return; } } } const int additionalProximitySize = AdditionalProximityChars::getAdditionalCharsSize(&mLocaleStr, primaryKey); if (additionalProximitySize > 0) { inputCodes[insertPos++] = ADDITIONAL_PROXIMITY_CHAR_DELIMITER_CODE; if (insertPos >= MAX_PROXIMITY_CHARS_SIZE) { if (DEBUG_DICT) { assert(false); } return; } const int32_t* additionalProximityChars = AdditionalProximityChars::getAdditionalChars(&mLocaleStr, primaryKey); for (int j = 0; j < additionalProximitySize; ++j) { const int32_t ac = additionalProximityChars[j]; int k = 0; for (; k < insertPos; ++k) { if ((int)ac == inputCodes[k]) { break; } } if (k < insertPos) { continue; } inputCodes[insertPos++] = ac; if (insertPos >= MAX_PROXIMITY_CHARS_SIZE) { if (DEBUG_DICT) { assert(false); } return; } } } } // Add a delimiter for the proximity characters for (int i = insertPos; i < MAX_PROXIMITY_CHARS_SIZE; ++i) { inputCodes[i] = NOT_A_CODE; } } int ProximityInfo::getKeyIndex(const int c) const { if (KEY_COUNT == 0) { // We do not have the coordinate data return NOT_AN_INDEX; } const unsigned short baseLowerC = toBaseLowerCase(c); if (baseLowerC > MAX_CHAR_CODE) { return NOT_AN_INDEX; } return mCodeToKeyIndex[baseLowerC]; } } // namespace latinime