/* * Copyright (C) 2008 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. */ package com.android.inputmethod.latin; import com.android.inputmethod.event.CombinerChain; import com.android.inputmethod.event.Event; import com.android.inputmethod.latin.SuggestedWords.SuggestedWordInfo; import com.android.inputmethod.latin.common.ComposedData; import com.android.inputmethod.latin.common.Constants; import com.android.inputmethod.latin.common.CoordinateUtils; import com.android.inputmethod.latin.common.InputPointers; import com.android.inputmethod.latin.common.StringUtils; import com.android.inputmethod.latin.define.DebugFlags; import java.util.ArrayList; import java.util.Collections; import javax.annotation.Nonnull; /** * A place to store the currently composing word with information such as adjacent key codes as well */ public final class WordComposer { private static final int MAX_WORD_LENGTH = Constants.DICTIONARY_MAX_WORD_LENGTH; private static final boolean DBG = DebugFlags.DEBUG_ENABLED; public static final int CAPS_MODE_OFF = 0; // 1 is shift bit, 2 is caps bit, 4 is auto bit but this is just a convention as these bits // aren't used anywhere in the code public static final int CAPS_MODE_MANUAL_SHIFTED = 0x1; public static final int CAPS_MODE_MANUAL_SHIFT_LOCKED = 0x3; public static final int CAPS_MODE_AUTO_SHIFTED = 0x5; public static final int CAPS_MODE_AUTO_SHIFT_LOCKED = 0x7; private CombinerChain mCombinerChain; private String mCombiningSpec; // Memory so that we don't uselessly recreate the combiner chain // The list of events that served to compose this string. private final ArrayList mEvents; private final InputPointers mInputPointers = new InputPointers(MAX_WORD_LENGTH); private SuggestedWordInfo mAutoCorrection; private boolean mIsResumed; private boolean mIsBatchMode; // A memory of the last rejected batch mode suggestion, if any. This goes like this: the user // gestures a word, is displeased with the results and hits backspace, then gestures again. // At the very least we should avoid re-suggesting the same thing, and to do that we memorize // the rejected suggestion in this variable. // TODO: this should be done in a comprehensive way by the User History feature instead of // as an ad-hockery here. private String mRejectedBatchModeSuggestion; // Cache these values for performance private CharSequence mTypedWordCache; private int mCapsCount; private int mDigitsCount; private int mCapitalizedMode; // This is the number of code points entered so far. This is not limited to MAX_WORD_LENGTH. // In general, this contains the size of mPrimaryKeyCodes, except when this is greater than // MAX_WORD_LENGTH in which case mPrimaryKeyCodes only contain the first MAX_WORD_LENGTH // code points. private int mCodePointSize; private int mCursorPositionWithinWord; /** * Whether the composing word has the only first char capitalized. */ private boolean mIsOnlyFirstCharCapitalized; public WordComposer() { mCombinerChain = new CombinerChain(""); mEvents = new ArrayList<>(); mAutoCorrection = null; mIsResumed = false; mIsBatchMode = false; mCursorPositionWithinWord = 0; mRejectedBatchModeSuggestion = null; refreshTypedWordCache(); } public ComposedData getComposedDataSnapshot() { return new ComposedData(getInputPointers(), isBatchMode(), mTypedWordCache.toString()); } /** * Restart the combiners, possibly with a new spec. * @param combiningSpec The spec string for combining. This is found in the extra value. */ public void restartCombining(final String combiningSpec) { final String nonNullCombiningSpec = null == combiningSpec ? "" : combiningSpec; if (!nonNullCombiningSpec.equals(mCombiningSpec)) { mCombinerChain = new CombinerChain( mCombinerChain.getComposingWordWithCombiningFeedback().toString(), CombinerChain.createCombiners(nonNullCombiningSpec)); mCombiningSpec = nonNullCombiningSpec; } } /** * Clear out the keys registered so far. */ public void reset() { mCombinerChain.reset(); mEvents.clear(); mAutoCorrection = null; mCapsCount = 0; mDigitsCount = 0; mIsOnlyFirstCharCapitalized = false; mIsResumed = false; mIsBatchMode = false; mCursorPositionWithinWord = 0; mRejectedBatchModeSuggestion = null; refreshTypedWordCache(); } private final void refreshTypedWordCache() { mTypedWordCache = mCombinerChain.getComposingWordWithCombiningFeedback(); mCodePointSize = Character.codePointCount(mTypedWordCache, 0, mTypedWordCache.length()); } /** * Number of keystrokes in the composing word. * @return the number of keystrokes */ public int size() { return mCodePointSize; } public boolean isSingleLetter() { return size() == 1; } public final boolean isComposingWord() { return size() > 0; } public InputPointers getInputPointers() { return mInputPointers; } /** * Process an event and return an event, and return a processed event to apply. * @param event the unprocessed event. * @return the processed event. Never null, but may be marked as consumed. */ @Nonnull public Event processEvent(@Nonnull final Event event) { final Event processedEvent = mCombinerChain.processEvent(mEvents, event); // The retained state of the combiner chain may have changed while processing the event, // so we need to update our cache. refreshTypedWordCache(); mEvents.add(event); return processedEvent; } /** * Apply a processed input event. * * All input events should be supported, including software/hardware events, characters as well * as deletions, multiple inputs and gestures. * * @param event the event to apply. Must not be null. */ public void applyProcessedEvent(final Event event) { mCombinerChain.applyProcessedEvent(event); final int primaryCode = event.mCodePoint; final int keyX = event.mX; final int keyY = event.mY; final int newIndex = size(); refreshTypedWordCache(); mCursorPositionWithinWord = mCodePointSize; // We may have deleted the last one. if (0 == mCodePointSize) { mIsOnlyFirstCharCapitalized = false; } if (Constants.CODE_DELETE != event.mKeyCode) { if (newIndex < MAX_WORD_LENGTH) { // In the batch input mode, the {@code mInputPointers} holds batch input points and // shouldn't be overridden by the "typed key" coordinates // (See {@link #setBatchInputWord}). if (!mIsBatchMode) { // TODO: Set correct pointer id and time mInputPointers.addPointerAt(newIndex, keyX, keyY, 0, 0); } } if (0 == newIndex) { mIsOnlyFirstCharCapitalized = Character.isUpperCase(primaryCode); } else { mIsOnlyFirstCharCapitalized = mIsOnlyFirstCharCapitalized && !Character.isUpperCase(primaryCode); } if (Character.isUpperCase(primaryCode)) mCapsCount++; if (Character.isDigit(primaryCode)) mDigitsCount++; } mAutoCorrection = null; } public void setCursorPositionWithinWord(final int posWithinWord) { mCursorPositionWithinWord = posWithinWord; // TODO: compute where that puts us inside the events } public boolean isCursorFrontOrMiddleOfComposingWord() { if (DBG && mCursorPositionWithinWord > mCodePointSize) { throw new RuntimeException("Wrong cursor position : " + mCursorPositionWithinWord + "in a word of size " + mCodePointSize); } return mCursorPositionWithinWord != mCodePointSize; } /** * When the cursor is moved by the user, we need to update its position. * If it falls inside the currently composing word, we don't reset the composition, and * only update the cursor position. * * @param expectedMoveAmount How many java chars to move the cursor. Negative values move * the cursor backward, positive values move the cursor forward. * @return true if the cursor is still inside the composing word, false otherwise. */ public boolean moveCursorByAndReturnIfInsideComposingWord(final int expectedMoveAmount) { // TODO: should uncommit the composing feedback mCombinerChain.reset(); int actualMoveAmountWithinWord = 0; int cursorPos = mCursorPositionWithinWord; // TODO: Don't make that copy. We can do this directly from mTypedWordCache. final int[] codePoints = StringUtils.toCodePointArray(mTypedWordCache); if (expectedMoveAmount >= 0) { // Moving the cursor forward for the expected amount or until the end of the word has // been reached, whichever comes first. while (actualMoveAmountWithinWord < expectedMoveAmount && cursorPos < mCodePointSize) { actualMoveAmountWithinWord += Character.charCount(codePoints[cursorPos]); ++cursorPos; } } else { // Moving the cursor backward for the expected amount or until the start of the word // has been reached, whichever comes first. while (actualMoveAmountWithinWord > expectedMoveAmount && cursorPos > 0) { --cursorPos; actualMoveAmountWithinWord -= Character.charCount(codePoints[cursorPos]); } } // If the actual and expected amounts differ, we crossed the start or the end of the word // so the result would not be inside the composing word. if (actualMoveAmountWithinWord != expectedMoveAmount) return false; mCursorPositionWithinWord = cursorPos; return true; } public void setBatchInputPointers(final InputPointers batchPointers) { mInputPointers.set(batchPointers); mIsBatchMode = true; } public void setBatchInputWord(final String word) { reset(); mIsBatchMode = true; final int length = word.length(); for (int i = 0; i < length; i = Character.offsetByCodePoints(word, i, 1)) { final int codePoint = Character.codePointAt(word, i); // We don't want to override the batch input points that are held in mInputPointers // (See {@link #add(int,int,int)}). final Event processedEvent = processEvent(Event.createEventForCodePointFromUnknownSource(codePoint)); applyProcessedEvent(processedEvent); } } /** * Set the currently composing word to the one passed as an argument. * This will register NOT_A_COORDINATE for X and Ys, and use the passed keyboard for proximity. * @param codePoints the code points to set as the composing word. * @param coordinates the x, y coordinates of the key in the CoordinateUtils format */ public void setComposingWord(final int[] codePoints, final int[] coordinates) { reset(); final int length = codePoints.length; for (int i = 0; i < length; ++i) { final Event processedEvent = processEvent(Event.createEventForCodePointFromAlreadyTypedText(codePoints[i], CoordinateUtils.xFromArray(coordinates, i), CoordinateUtils.yFromArray(coordinates, i))); applyProcessedEvent(processedEvent); } mIsResumed = true; } /** * Returns the word as it was typed, without any correction applied. * @return the word that was typed so far. Never returns null. */ public String getTypedWord() { return mTypedWordCache.toString(); } /** * Whether this composer is composing or about to compose a word in which only the first letter * is a capital. * * If we do have a composing word, we just return whether the word has indeed only its first * character capitalized. If we don't, then we return a value based on the capitalized mode, * which tell us what is likely to happen for the next composing word. * * @return capitalization preference */ public boolean isOrWillBeOnlyFirstCharCapitalized() { return isComposingWord() ? mIsOnlyFirstCharCapitalized : (CAPS_MODE_OFF != mCapitalizedMode); } /** * Whether or not all of the user typed chars are upper case * @return true if all user typed chars are upper case, false otherwise */ public boolean isAllUpperCase() { if (size() <= 1) { return mCapitalizedMode == CAPS_MODE_AUTO_SHIFT_LOCKED || mCapitalizedMode == CAPS_MODE_MANUAL_SHIFT_LOCKED; } return mCapsCount == size(); } public boolean wasShiftedNoLock() { return mCapitalizedMode == CAPS_MODE_AUTO_SHIFTED || mCapitalizedMode == CAPS_MODE_MANUAL_SHIFTED; } /** * Returns true if more than one character is upper case, otherwise returns false. */ public boolean isMostlyCaps() { return mCapsCount > 1; } /** * Returns true if we have digits in the composing word. */ public boolean hasDigits() { return mDigitsCount > 0; } /** * Saves the caps mode at the start of composing. * * WordComposer needs to know about the caps mode for several reasons. The first is, we need * to know after the fact what the reason was, to register the correct form into the user * history dictionary: if the word was automatically capitalized, we should insert it in * all-lower case but if it's a manual pressing of shift, then it should be inserted as is. * Also, batch input needs to know about the current caps mode to display correctly * capitalized suggestions. * @param mode the mode at the time of start */ public void setCapitalizedModeAtStartComposingTime(final int mode) { mCapitalizedMode = mode; } /** * Before fetching suggestions, we don't necessarily know about the capitalized mode yet. * * If we don't have a composing word yet, we take a note of this mode so that we can then * supply this information to the suggestion process. If we have a composing word, then * the previous mode has priority over this. * @param mode the mode just before fetching suggestions */ public void adviseCapitalizedModeBeforeFetchingSuggestions(final int mode) { if (!isComposingWord()) { mCapitalizedMode = mode; } } /** * Returns whether the word was automatically capitalized. * @return whether the word was automatically capitalized */ public boolean wasAutoCapitalized() { return mCapitalizedMode == CAPS_MODE_AUTO_SHIFT_LOCKED || mCapitalizedMode == CAPS_MODE_AUTO_SHIFTED; } /** * Sets the auto-correction for this word. */ public void setAutoCorrection(final SuggestedWordInfo autoCorrection) { mAutoCorrection = autoCorrection; } /** * @return the auto-correction for this word, or null if none. */ public SuggestedWordInfo getAutoCorrectionOrNull() { return mAutoCorrection; } /** * @return whether we started composing this word by resuming suggestion on an existing string */ public boolean isResumed() { return mIsResumed; } // `type' should be one of the LastComposedWord.COMMIT_TYPE_* constants above. // committedWord should contain suggestion spans if applicable. public LastComposedWord commitWord(final int type, final CharSequence committedWord, final String separatorString, final NgramContext ngramContext) { // Note: currently, we come here whenever we commit a word. If it's a MANUAL_PICK // or a DECIDED_WORD we may cancel the commit later; otherwise, we should deactivate // the last composed word to ensure this does not happen. final LastComposedWord lastComposedWord = new LastComposedWord(mEvents, mInputPointers, mTypedWordCache.toString(), committedWord, separatorString, ngramContext, mCapitalizedMode); mInputPointers.reset(); if (type != LastComposedWord.COMMIT_TYPE_DECIDED_WORD && type != LastComposedWord.COMMIT_TYPE_MANUAL_PICK) { lastComposedWord.deactivate(); } mCapsCount = 0; mDigitsCount = 0; mIsBatchMode = false; mCombinerChain.reset(); mEvents.clear(); mCodePointSize = 0; mIsOnlyFirstCharCapitalized = false; mCapitalizedMode = CAPS_MODE_OFF; refreshTypedWordCache(); mAutoCorrection = null; mCursorPositionWithinWord = 0; mIsResumed = false; mRejectedBatchModeSuggestion = null; return lastComposedWord; } public void resumeSuggestionOnLastComposedWord(final LastComposedWord lastComposedWord) { mEvents.clear(); Collections.copy(mEvents, lastComposedWord.mEvents); mInputPointers.set(lastComposedWord.mInputPointers); mCombinerChain.reset(); refreshTypedWordCache(); mCapitalizedMode = lastComposedWord.mCapitalizedMode; mAutoCorrection = null; // This will be filled by the next call to updateSuggestion. mCursorPositionWithinWord = mCodePointSize; mRejectedBatchModeSuggestion = null; mIsResumed = true; } public boolean isBatchMode() { return mIsBatchMode; } public void setRejectedBatchModeSuggestion(final String rejectedSuggestion) { mRejectedBatchModeSuggestion = rejectedSuggestion; } public String getRejectedBatchModeSuggestion() { return mRejectedBatchModeSuggestion; } }