/* * Copyright (C) 2006 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 android.text; import android.annotation.Nullable; import android.graphics.BaseCanvas; import android.graphics.Paint; import android.util.Log; import com.android.internal.annotations.GuardedBy; import com.android.internal.util.ArrayUtils; import com.android.internal.util.GrowingArrayUtils; import libcore.util.EmptyArray; import java.lang.reflect.Array; import java.util.IdentityHashMap; /** * This is the class for text whose content and markup can both be changed. */ public class SpannableStringBuilder implements CharSequence, GetChars, Spannable, Editable, Appendable, GraphicsOperations { private final static String TAG = "SpannableStringBuilder"; /** * Create a new SpannableStringBuilder with empty contents */ public SpannableStringBuilder() { this(""); } /** * Create a new SpannableStringBuilder containing a copy of the * specified text, including its spans if any. */ public SpannableStringBuilder(CharSequence text) { this(text, 0, text.length()); } /** * Create a new SpannableStringBuilder containing a copy of the * specified slice of the specified text, including its spans if any. */ public SpannableStringBuilder(CharSequence text, int start, int end) { int srclen = end - start; if (srclen < 0) throw new StringIndexOutOfBoundsException(); mText = ArrayUtils.newUnpaddedCharArray(GrowingArrayUtils.growSize(srclen)); mGapStart = srclen; mGapLength = mText.length - srclen; TextUtils.getChars(text, start, end, mText, 0); mSpanCount = 0; mSpanInsertCount = 0; mSpans = EmptyArray.OBJECT; mSpanStarts = EmptyArray.INT; mSpanEnds = EmptyArray.INT; mSpanFlags = EmptyArray.INT; mSpanMax = EmptyArray.INT; mSpanOrder = EmptyArray.INT; if (text instanceof Spanned) { Spanned sp = (Spanned) text; Object[] spans = sp.getSpans(start, end, Object.class); for (int i = 0; i < spans.length; i++) { if (spans[i] instanceof NoCopySpan) { continue; } int st = sp.getSpanStart(spans[i]) - start; int en = sp.getSpanEnd(spans[i]) - start; int fl = sp.getSpanFlags(spans[i]); if (st < 0) st = 0; if (st > end - start) st = end - start; if (en < 0) en = 0; if (en > end - start) en = end - start; setSpan(false, spans[i], st, en, fl, false/*enforceParagraph*/); } restoreInvariants(); } } public static SpannableStringBuilder valueOf(CharSequence source) { if (source instanceof SpannableStringBuilder) { return (SpannableStringBuilder) source; } else { return new SpannableStringBuilder(source); } } /** * Return the char at the specified offset within the buffer. */ public char charAt(int where) { int len = length(); if (where < 0) { throw new IndexOutOfBoundsException("charAt: " + where + " < 0"); } else if (where >= len) { throw new IndexOutOfBoundsException("charAt: " + where + " >= length " + len); } if (where >= mGapStart) return mText[where + mGapLength]; else return mText[where]; } /** * Return the number of chars in the buffer. */ public int length() { return mText.length - mGapLength; } private void resizeFor(int size) { final int oldLength = mText.length; if (size + 1 <= oldLength) { return; } char[] newText = ArrayUtils.newUnpaddedCharArray(GrowingArrayUtils.growSize(size)); System.arraycopy(mText, 0, newText, 0, mGapStart); final int newLength = newText.length; final int delta = newLength - oldLength; final int after = oldLength - (mGapStart + mGapLength); System.arraycopy(mText, oldLength - after, newText, newLength - after, after); mText = newText; mGapLength += delta; if (mGapLength < 1) new Exception("mGapLength < 1").printStackTrace(); if (mSpanCount != 0) { for (int i = 0; i < mSpanCount; i++) { if (mSpanStarts[i] > mGapStart) mSpanStarts[i] += delta; if (mSpanEnds[i] > mGapStart) mSpanEnds[i] += delta; } calcMax(treeRoot()); } } private void moveGapTo(int where) { if (where == mGapStart) return; boolean atEnd = (where == length()); if (where < mGapStart) { int overlap = mGapStart - where; System.arraycopy(mText, where, mText, mGapStart + mGapLength - overlap, overlap); } else /* where > mGapStart */ { int overlap = where - mGapStart; System.arraycopy(mText, where + mGapLength - overlap, mText, mGapStart, overlap); } // TODO: be more clever (although the win really isn't that big) if (mSpanCount != 0) { for (int i = 0; i < mSpanCount; i++) { int start = mSpanStarts[i]; int end = mSpanEnds[i]; if (start > mGapStart) start -= mGapLength; if (start > where) start += mGapLength; else if (start == where) { int flag = (mSpanFlags[i] & START_MASK) >> START_SHIFT; if (flag == POINT || (atEnd && flag == PARAGRAPH)) start += mGapLength; } if (end > mGapStart) end -= mGapLength; if (end > where) end += mGapLength; else if (end == where) { int flag = (mSpanFlags[i] & END_MASK); if (flag == POINT || (atEnd && flag == PARAGRAPH)) end += mGapLength; } mSpanStarts[i] = start; mSpanEnds[i] = end; } calcMax(treeRoot()); } mGapStart = where; } // Documentation from interface public SpannableStringBuilder insert(int where, CharSequence tb, int start, int end) { return replace(where, where, tb, start, end); } // Documentation from interface public SpannableStringBuilder insert(int where, CharSequence tb) { return replace(where, where, tb, 0, tb.length()); } // Documentation from interface public SpannableStringBuilder delete(int start, int end) { SpannableStringBuilder ret = replace(start, end, "", 0, 0); if (mGapLength > 2 * length()) resizeFor(length()); return ret; // == this } // Documentation from interface public void clear() { replace(0, length(), "", 0, 0); mSpanInsertCount = 0; } // Documentation from interface public void clearSpans() { for (int i = mSpanCount - 1; i >= 0; i--) { Object what = mSpans[i]; int ostart = mSpanStarts[i]; int oend = mSpanEnds[i]; if (ostart > mGapStart) ostart -= mGapLength; if (oend > mGapStart) oend -= mGapLength; mSpanCount = i; mSpans[i] = null; sendSpanRemoved(what, ostart, oend); } if (mIndexOfSpan != null) { mIndexOfSpan.clear(); } mSpanInsertCount = 0; } // Documentation from interface public SpannableStringBuilder append(CharSequence text) { int length = length(); return replace(length, length, text, 0, text.length()); } /** * Appends the character sequence {@code text} and spans {@code what} over the appended part. * See {@link Spanned} for an explanation of what the flags mean. * @param text the character sequence to append. * @param what the object to be spanned over the appended text. * @param flags see {@link Spanned}. * @return this {@code SpannableStringBuilder}. */ public SpannableStringBuilder append(CharSequence text, Object what, int flags) { int start = length(); append(text); setSpan(what, start, length(), flags); return this; } // Documentation from interface public SpannableStringBuilder append(CharSequence text, int start, int end) { int length = length(); return replace(length, length, text, start, end); } // Documentation from interface public SpannableStringBuilder append(char text) { return append(String.valueOf(text)); } // Returns true if a node was removed (so we can restart search from root) private boolean removeSpansForChange(int start, int end, boolean textIsRemoved, int i) { if ((i & 1) != 0) { // internal tree node if (resolveGap(mSpanMax[i]) >= start && removeSpansForChange(start, end, textIsRemoved, leftChild(i))) { return true; } } if (i < mSpanCount) { if ((mSpanFlags[i] & Spanned.SPAN_EXCLUSIVE_EXCLUSIVE) == Spanned.SPAN_EXCLUSIVE_EXCLUSIVE && mSpanStarts[i] >= start && mSpanStarts[i] < mGapStart + mGapLength && mSpanEnds[i] >= start && mSpanEnds[i] < mGapStart + mGapLength && // The following condition indicates that the span would become empty (textIsRemoved || mSpanStarts[i] > start || mSpanEnds[i] < mGapStart)) { mIndexOfSpan.remove(mSpans[i]); removeSpan(i); return true; } return resolveGap(mSpanStarts[i]) <= end && (i & 1) != 0 && removeSpansForChange(start, end, textIsRemoved, rightChild(i)); } return false; } private void change(int start, int end, CharSequence cs, int csStart, int csEnd) { // Can be negative final int replacedLength = end - start; final int replacementLength = csEnd - csStart; final int nbNewChars = replacementLength - replacedLength; boolean changed = false; for (int i = mSpanCount - 1; i >= 0; i--) { int spanStart = mSpanStarts[i]; if (spanStart > mGapStart) spanStart -= mGapLength; int spanEnd = mSpanEnds[i]; if (spanEnd > mGapStart) spanEnd -= mGapLength; if ((mSpanFlags[i] & SPAN_PARAGRAPH) == SPAN_PARAGRAPH) { int ost = spanStart; int oen = spanEnd; int clen = length(); if (spanStart > start && spanStart <= end) { for (spanStart = end; spanStart < clen; spanStart++) if (spanStart > end && charAt(spanStart - 1) == '\n') break; } if (spanEnd > start && spanEnd <= end) { for (spanEnd = end; spanEnd < clen; spanEnd++) if (spanEnd > end && charAt(spanEnd - 1) == '\n') break; } if (spanStart != ost || spanEnd != oen) { setSpan(false, mSpans[i], spanStart, spanEnd, mSpanFlags[i], true/*enforceParagraph*/); changed = true; } } int flags = 0; if (spanStart == start) flags |= SPAN_START_AT_START; else if (spanStart == end + nbNewChars) flags |= SPAN_START_AT_END; if (spanEnd == start) flags |= SPAN_END_AT_START; else if (spanEnd == end + nbNewChars) flags |= SPAN_END_AT_END; mSpanFlags[i] |= flags; } if (changed) { restoreInvariants(); } moveGapTo(end); if (nbNewChars >= mGapLength) { resizeFor(mText.length + nbNewChars - mGapLength); } final boolean textIsRemoved = replacementLength == 0; // The removal pass needs to be done before the gap is updated in order to broadcast the // correct previous positions to the correct intersecting SpanWatchers if (replacedLength > 0) { // no need for span fixup on pure insertion while (mSpanCount > 0 && removeSpansForChange(start, end, textIsRemoved, treeRoot())) { // keep deleting spans as needed, and restart from root after every deletion // because deletion can invalidate an index. } } mGapStart += nbNewChars; mGapLength -= nbNewChars; if (mGapLength < 1) new Exception("mGapLength < 1").printStackTrace(); TextUtils.getChars(cs, csStart, csEnd, mText, start); if (replacedLength > 0) { // no need for span fixup on pure insertion // TODO potential optimization: only update bounds on intersecting spans final boolean atEnd = (mGapStart + mGapLength == mText.length); for (int i = 0; i < mSpanCount; i++) { final int startFlag = (mSpanFlags[i] & START_MASK) >> START_SHIFT; mSpanStarts[i] = updatedIntervalBound(mSpanStarts[i], start, nbNewChars, startFlag, atEnd, textIsRemoved); final int endFlag = (mSpanFlags[i] & END_MASK); mSpanEnds[i] = updatedIntervalBound(mSpanEnds[i], start, nbNewChars, endFlag, atEnd, textIsRemoved); } // TODO potential optimization: only fix up invariants when bounds actually changed restoreInvariants(); } if (cs instanceof Spanned) { Spanned sp = (Spanned) cs; Object[] spans = sp.getSpans(csStart, csEnd, Object.class); for (int i = 0; i < spans.length; i++) { int st = sp.getSpanStart(spans[i]); int en = sp.getSpanEnd(spans[i]); if (st < csStart) st = csStart; if (en > csEnd) en = csEnd; // Add span only if this object is not yet used as a span in this string if (getSpanStart(spans[i]) < 0) { int copySpanStart = st - csStart + start; int copySpanEnd = en - csStart + start; int copySpanFlags = sp.getSpanFlags(spans[i]) | SPAN_ADDED; setSpan(false, spans[i], copySpanStart, copySpanEnd, copySpanFlags, false/*enforceParagraph*/); } } restoreInvariants(); } } private int updatedIntervalBound(int offset, int start, int nbNewChars, int flag, boolean atEnd, boolean textIsRemoved) { if (offset >= start && offset < mGapStart + mGapLength) { if (flag == POINT) { // A POINT located inside the replaced range should be moved to the end of the // replaced text. // The exception is when the point is at the start of the range and we are doing a // text replacement (as opposed to a deletion): the point stays there. if (textIsRemoved || offset > start) { return mGapStart + mGapLength; } } else { if (flag == PARAGRAPH) { if (atEnd) { return mGapStart + mGapLength; } } else { // MARK // MARKs should be moved to the start, with the exception of a mark located at // the end of the range (which will be < mGapStart + mGapLength since mGapLength // is > 0, which should stay 'unchanged' at the end of the replaced text. if (textIsRemoved || offset < mGapStart - nbNewChars) { return start; } else { // Move to the end of replaced text (needed if nbNewChars != 0) return mGapStart; } } } } return offset; } // Note: caller is responsible for removing the mIndexOfSpan entry. private void removeSpan(int i) { Object object = mSpans[i]; int start = mSpanStarts[i]; int end = mSpanEnds[i]; if (start > mGapStart) start -= mGapLength; if (end > mGapStart) end -= mGapLength; int count = mSpanCount - (i + 1); System.arraycopy(mSpans, i + 1, mSpans, i, count); System.arraycopy(mSpanStarts, i + 1, mSpanStarts, i, count); System.arraycopy(mSpanEnds, i + 1, mSpanEnds, i, count); System.arraycopy(mSpanFlags, i + 1, mSpanFlags, i, count); System.arraycopy(mSpanOrder, i + 1, mSpanOrder, i, count); mSpanCount--; invalidateIndex(i); mSpans[mSpanCount] = null; // Invariants must be restored before sending span removed notifications. restoreInvariants(); sendSpanRemoved(object, start, end); } // Documentation from interface public SpannableStringBuilder replace(int start, int end, CharSequence tb) { return replace(start, end, tb, 0, tb.length()); } // Documentation from interface public SpannableStringBuilder replace(final int start, final int end, CharSequence tb, int tbstart, int tbend) { checkRange("replace", start, end); int filtercount = mFilters.length; for (int i = 0; i < filtercount; i++) { CharSequence repl = mFilters[i].filter(tb, tbstart, tbend, this, start, end); if (repl != null) { tb = repl; tbstart = 0; tbend = repl.length(); } } final int origLen = end - start; final int newLen = tbend - tbstart; if (origLen == 0 && newLen == 0 && !hasNonExclusiveExclusiveSpanAt(tb, tbstart)) { // This is a no-op iif there are no spans in tb that would be added (with a 0-length) // Early exit so that the text watchers do not get notified return this; } TextWatcher[] textWatchers = getSpans(start, start + origLen, TextWatcher.class); sendBeforeTextChanged(textWatchers, start, origLen, newLen); // Try to keep the cursor / selection at the same relative position during // a text replacement. If replaced or replacement text length is zero, this // is already taken care of. boolean adjustSelection = origLen != 0 && newLen != 0; int selectionStart = 0; int selectionEnd = 0; if (adjustSelection) { selectionStart = Selection.getSelectionStart(this); selectionEnd = Selection.getSelectionEnd(this); } change(start, end, tb, tbstart, tbend); if (adjustSelection) { boolean changed = false; if (selectionStart > start && selectionStart < end) { final long diff = selectionStart - start; final int offset = Math.toIntExact(diff * newLen / origLen); selectionStart = start + offset; changed = true; setSpan(false, Selection.SELECTION_START, selectionStart, selectionStart, Spanned.SPAN_POINT_POINT, true/*enforceParagraph*/); } if (selectionEnd > start && selectionEnd < end) { final long diff = selectionEnd - start; final int offset = Math.toIntExact(diff * newLen / origLen); selectionEnd = start + offset; changed = true; setSpan(false, Selection.SELECTION_END, selectionEnd, selectionEnd, Spanned.SPAN_POINT_POINT, true/*enforceParagraph*/); } if (changed) { restoreInvariants(); } } sendTextChanged(textWatchers, start, origLen, newLen); sendAfterTextChanged(textWatchers); // Span watchers need to be called after text watchers, which may update the layout sendToSpanWatchers(start, end, newLen - origLen); return this; } private static boolean hasNonExclusiveExclusiveSpanAt(CharSequence text, int offset) { if (text instanceof Spanned) { Spanned spanned = (Spanned) text; Object[] spans = spanned.getSpans(offset, offset, Object.class); final int length = spans.length; for (int i = 0; i < length; i++) { Object span = spans[i]; int flags = spanned.getSpanFlags(span); if (flags != Spanned.SPAN_EXCLUSIVE_EXCLUSIVE) return true; } } return false; } private void sendToSpanWatchers(int replaceStart, int replaceEnd, int nbNewChars) { for (int i = 0; i < mSpanCount; i++) { int spanFlags = mSpanFlags[i]; // This loop handles only modified (not added) spans. if ((spanFlags & SPAN_ADDED) != 0) continue; int spanStart = mSpanStarts[i]; int spanEnd = mSpanEnds[i]; if (spanStart > mGapStart) spanStart -= mGapLength; if (spanEnd > mGapStart) spanEnd -= mGapLength; int newReplaceEnd = replaceEnd + nbNewChars; boolean spanChanged = false; int previousSpanStart = spanStart; if (spanStart > newReplaceEnd) { if (nbNewChars != 0) { previousSpanStart -= nbNewChars; spanChanged = true; } } else if (spanStart >= replaceStart) { // No change if span start was already at replace interval boundaries before replace if ((spanStart != replaceStart || ((spanFlags & SPAN_START_AT_START) != SPAN_START_AT_START)) && (spanStart != newReplaceEnd || ((spanFlags & SPAN_START_AT_END) != SPAN_START_AT_END))) { // TODO A correct previousSpanStart cannot be computed at this point. // It would require to save all the previous spans' positions before the replace // Using an invalid -1 value to convey this would break the broacast range spanChanged = true; } } int previousSpanEnd = spanEnd; if (spanEnd > newReplaceEnd) { if (nbNewChars != 0) { previousSpanEnd -= nbNewChars; spanChanged = true; } } else if (spanEnd >= replaceStart) { // No change if span start was already at replace interval boundaries before replace if ((spanEnd != replaceStart || ((spanFlags & SPAN_END_AT_START) != SPAN_END_AT_START)) && (spanEnd != newReplaceEnd || ((spanFlags & SPAN_END_AT_END) != SPAN_END_AT_END))) { // TODO same as above for previousSpanEnd spanChanged = true; } } if (spanChanged) { sendSpanChanged(mSpans[i], previousSpanStart, previousSpanEnd, spanStart, spanEnd); } mSpanFlags[i] &= ~SPAN_START_END_MASK; } // Handle added spans for (int i = 0; i < mSpanCount; i++) { int spanFlags = mSpanFlags[i]; if ((spanFlags & SPAN_ADDED) != 0) { mSpanFlags[i] &= ~SPAN_ADDED; int spanStart = mSpanStarts[i]; int spanEnd = mSpanEnds[i]; if (spanStart > mGapStart) spanStart -= mGapLength; if (spanEnd > mGapStart) spanEnd -= mGapLength; sendSpanAdded(mSpans[i], spanStart, spanEnd); } } } /** * Mark the specified range of text with the specified object. * The flags determine how the span will behave when text is * inserted at the start or end of the span's range. */ public void setSpan(Object what, int start, int end, int flags) { setSpan(true, what, start, end, flags, true/*enforceParagraph*/); } // Note: if send is false, then it is the caller's responsibility to restore // invariants. If send is false and the span already exists, then this method // will not change the index of any spans. private void setSpan(boolean send, Object what, int start, int end, int flags, boolean enforceParagraph) { checkRange("setSpan", start, end); int flagsStart = (flags & START_MASK) >> START_SHIFT; if (isInvalidParagraph(start, flagsStart)) { if (!enforceParagraph) { // do not set the span return; } throw new RuntimeException("PARAGRAPH span must start at paragraph boundary" + " (" + start + " follows " + charAt(start - 1) + ")"); } int flagsEnd = flags & END_MASK; if (isInvalidParagraph(end, flagsEnd)) { if (!enforceParagraph) { // do not set the span return; } throw new RuntimeException("PARAGRAPH span must end at paragraph boundary" + " (" + end + " follows " + charAt(end - 1) + ")"); } // 0-length Spanned.SPAN_EXCLUSIVE_EXCLUSIVE if (flagsStart == POINT && flagsEnd == MARK && start == end) { if (send) { Log.e(TAG, "SPAN_EXCLUSIVE_EXCLUSIVE spans cannot have a zero length"); } // Silently ignore invalid spans when they are created from this class. // This avoids the duplication of the above test code before all the // calls to setSpan that are done in this class return; } int nstart = start; int nend = end; if (start > mGapStart) { start += mGapLength; } else if (start == mGapStart) { if (flagsStart == POINT || (flagsStart == PARAGRAPH && start == length())) start += mGapLength; } if (end > mGapStart) { end += mGapLength; } else if (end == mGapStart) { if (flagsEnd == POINT || (flagsEnd == PARAGRAPH && end == length())) end += mGapLength; } if (mIndexOfSpan != null) { Integer index = mIndexOfSpan.get(what); if (index != null) { int i = index; int ostart = mSpanStarts[i]; int oend = mSpanEnds[i]; if (ostart > mGapStart) ostart -= mGapLength; if (oend > mGapStart) oend -= mGapLength; mSpanStarts[i] = start; mSpanEnds[i] = end; mSpanFlags[i] = flags; if (send) { restoreInvariants(); sendSpanChanged(what, ostart, oend, nstart, nend); } return; } } mSpans = GrowingArrayUtils.append(mSpans, mSpanCount, what); mSpanStarts = GrowingArrayUtils.append(mSpanStarts, mSpanCount, start); mSpanEnds = GrowingArrayUtils.append(mSpanEnds, mSpanCount, end); mSpanFlags = GrowingArrayUtils.append(mSpanFlags, mSpanCount, flags); mSpanOrder = GrowingArrayUtils.append(mSpanOrder, mSpanCount, mSpanInsertCount); invalidateIndex(mSpanCount); mSpanCount++; mSpanInsertCount++; // Make sure there is enough room for empty interior nodes. // This magic formula computes the size of the smallest perfect binary // tree no smaller than mSpanCount. int sizeOfMax = 2 * treeRoot() + 1; if (mSpanMax.length < sizeOfMax) { mSpanMax = new int[sizeOfMax]; } if (send) { restoreInvariants(); sendSpanAdded(what, nstart, nend); } } private boolean isInvalidParagraph(int index, int flag) { return flag == PARAGRAPH && index != 0 && index != length() && charAt(index - 1) != '\n'; } /** * Remove the specified markup object from the buffer. */ public void removeSpan(Object what) { if (mIndexOfSpan == null) return; Integer i = mIndexOfSpan.remove(what); if (i != null) { removeSpan(i.intValue()); } } /** * Return externally visible offset given offset into gapped buffer. */ private int resolveGap(int i) { return i > mGapStart ? i - mGapLength : i; } /** * Return the buffer offset of the beginning of the specified * markup object, or -1 if it is not attached to this buffer. */ public int getSpanStart(Object what) { if (mIndexOfSpan == null) return -1; Integer i = mIndexOfSpan.get(what); return i == null ? -1 : resolveGap(mSpanStarts[i]); } /** * Return the buffer offset of the end of the specified * markup object, or -1 if it is not attached to this buffer. */ public int getSpanEnd(Object what) { if (mIndexOfSpan == null) return -1; Integer i = mIndexOfSpan.get(what); return i == null ? -1 : resolveGap(mSpanEnds[i]); } /** * Return the flags of the end of the specified * markup object, or 0 if it is not attached to this buffer. */ public int getSpanFlags(Object what) { if (mIndexOfSpan == null) return 0; Integer i = mIndexOfSpan.get(what); return i == null ? 0 : mSpanFlags[i]; } /** * Return an array of the spans of the specified type that overlap * the specified range of the buffer. The kind may be Object.class to get * a list of all the spans regardless of type. */ @SuppressWarnings("unchecked") public T[] getSpans(int queryStart, int queryEnd, @Nullable Class kind) { return getSpans(queryStart, queryEnd, kind, true); } /** * Return an array of the spans of the specified type that overlap * the specified range of the buffer. The kind may be Object.class to get * a list of all the spans regardless of type. * * @param queryStart Start index. * @param queryEnd End index. * @param kind Class type to search for. * @param sortByInsertionOrder If true the results are sorted by the insertion order. * @param * @return Array of the spans. Empty array if no results are found. * * @hide */ public T[] getSpans(int queryStart, int queryEnd, @Nullable Class kind, boolean sortByInsertionOrder) { if (kind == null) return (T[]) ArrayUtils.emptyArray(Object.class); if (mSpanCount == 0) return ArrayUtils.emptyArray(kind); int count = countSpans(queryStart, queryEnd, kind, treeRoot()); if (count == 0) { return ArrayUtils.emptyArray(kind); } // Safe conversion, but requires a suppressWarning T[] ret = (T[]) Array.newInstance(kind, count); final int[] prioSortBuffer = sortByInsertionOrder ? obtain(count) : EmptyArray.INT; final int[] orderSortBuffer = sortByInsertionOrder ? obtain(count) : EmptyArray.INT; getSpansRec(queryStart, queryEnd, kind, treeRoot(), ret, prioSortBuffer, orderSortBuffer, 0, sortByInsertionOrder); if (sortByInsertionOrder) { sort(ret, prioSortBuffer, orderSortBuffer); recycle(prioSortBuffer); recycle(orderSortBuffer); } return ret; } private int countSpans(int queryStart, int queryEnd, Class kind, int i) { int count = 0; if ((i & 1) != 0) { // internal tree node int left = leftChild(i); int spanMax = mSpanMax[left]; if (spanMax > mGapStart) { spanMax -= mGapLength; } if (spanMax >= queryStart) { count = countSpans(queryStart, queryEnd, kind, left); } } if (i < mSpanCount) { int spanStart = mSpanStarts[i]; if (spanStart > mGapStart) { spanStart -= mGapLength; } if (spanStart <= queryEnd) { int spanEnd = mSpanEnds[i]; if (spanEnd > mGapStart) { spanEnd -= mGapLength; } if (spanEnd >= queryStart && (spanStart == spanEnd || queryStart == queryEnd || (spanStart != queryEnd && spanEnd != queryStart)) && (Object.class == kind || kind.isInstance(mSpans[i]))) { count++; } if ((i & 1) != 0) { count += countSpans(queryStart, queryEnd, kind, rightChild(i)); } } } return count; } /** * Fills the result array with the spans found under the current interval tree node. * * @param queryStart Start index for the interval query. * @param queryEnd End index for the interval query. * @param kind Class type to search for. * @param i Index of the current tree node. * @param ret Array to be filled with results. * @param priority Buffer to keep record of the priorities of spans found. * @param insertionOrder Buffer to keep record of the insertion orders of spans found. * @param count The number of found spans. * @param sort Flag to fill the priority and insertion order buffers. If false then * the spans with priority flag will be sorted in the result array. * @param * @return The total number of spans found. */ @SuppressWarnings("unchecked") private int getSpansRec(int queryStart, int queryEnd, Class kind, int i, T[] ret, int[] priority, int[] insertionOrder, int count, boolean sort) { if ((i & 1) != 0) { // internal tree node int left = leftChild(i); int spanMax = mSpanMax[left]; if (spanMax > mGapStart) { spanMax -= mGapLength; } if (spanMax >= queryStart) { count = getSpansRec(queryStart, queryEnd, kind, left, ret, priority, insertionOrder, count, sort); } } if (i >= mSpanCount) return count; int spanStart = mSpanStarts[i]; if (spanStart > mGapStart) { spanStart -= mGapLength; } if (spanStart <= queryEnd) { int spanEnd = mSpanEnds[i]; if (spanEnd > mGapStart) { spanEnd -= mGapLength; } if (spanEnd >= queryStart && (spanStart == spanEnd || queryStart == queryEnd || (spanStart != queryEnd && spanEnd != queryStart)) && (Object.class == kind || kind.isInstance(mSpans[i]))) { int spanPriority = mSpanFlags[i] & SPAN_PRIORITY; int target = count; if (sort) { priority[target] = spanPriority; insertionOrder[target] = mSpanOrder[i]; } else if (spanPriority != 0) { //insertion sort for elements with priority int j = 0; for (; j < count; j++) { int p = getSpanFlags(ret[j]) & SPAN_PRIORITY; if (spanPriority > p) break; } System.arraycopy(ret, j, ret, j + 1, count - j); target = j; } ret[target] = (T) mSpans[i]; count++; } if (count < ret.length && (i & 1) != 0) { count = getSpansRec(queryStart, queryEnd, kind, rightChild(i), ret, priority, insertionOrder, count, sort); } } return count; } /** * Obtain a temporary sort buffer. * * @param elementCount the size of the int[] to be returned * @return an int[] with elementCount length */ private static int[] obtain(final int elementCount) { int[] result = null; synchronized (sCachedIntBuffer) { // try finding a tmp buffer with length of at least elementCount // if not get the first available one int candidateIndex = -1; for (int i = sCachedIntBuffer.length - 1; i >= 0; i--) { if (sCachedIntBuffer[i] != null) { if (sCachedIntBuffer[i].length >= elementCount) { candidateIndex = i; break; } else if (candidateIndex == -1) { candidateIndex = i; } } } if (candidateIndex != -1) { result = sCachedIntBuffer[candidateIndex]; sCachedIntBuffer[candidateIndex] = null; } } result = checkSortBuffer(result, elementCount); return result; } /** * Recycle sort buffer. * * @param buffer buffer to be recycled */ private static void recycle(int[] buffer) { synchronized (sCachedIntBuffer) { for (int i = 0; i < sCachedIntBuffer.length; i++) { if (sCachedIntBuffer[i] == null || buffer.length > sCachedIntBuffer[i].length) { sCachedIntBuffer[i] = buffer; break; } } } } /** * Check the size of the buffer and grow if required. * * @param buffer buffer to be checked. * @param size required size. * @return Same buffer instance if the current size is greater than required size. Otherwise a * new instance is created and returned. */ private static int[] checkSortBuffer(int[] buffer, int size) { if (buffer == null || size > buffer.length) { return ArrayUtils.newUnpaddedIntArray(GrowingArrayUtils.growSize(size)); } return buffer; } /** * An iterative heap sort implementation. It will sort the spans using first their priority * then insertion order. A span with higher priority will be before a span with lower * priority. If priorities are the same, the spans will be sorted with insertion order. A * span with a lower insertion order will be before a span with a higher insertion order. * * @param array Span array to be sorted. * @param priority Priorities of the spans * @param insertionOrder Insertion orders of the spans * @param Span object type. * @param */ private final void sort(T[] array, int[] priority, int[] insertionOrder) { int size = array.length; for (int i = size / 2 - 1; i >= 0; i--) { siftDown(i, array, size, priority, insertionOrder); } for (int i = size - 1; i > 0; i--) { final T tmpSpan = array[0]; array[0] = array[i]; array[i] = tmpSpan; final int tmpPriority = priority[0]; priority[0] = priority[i]; priority[i] = tmpPriority; final int tmpOrder = insertionOrder[0]; insertionOrder[0] = insertionOrder[i]; insertionOrder[i] = tmpOrder; siftDown(0, array, i, priority, insertionOrder); } } /** * Helper function for heap sort. * * @param index Index of the element to sift down. * @param array Span array to be sorted. * @param size Current heap size. * @param priority Priorities of the spans * @param insertionOrder Insertion orders of the spans * @param Span object type. */ private final void siftDown(int index, T[] array, int size, int[] priority, int[] insertionOrder) { int left = 2 * index + 1; while (left < size) { if (left < size - 1 && compareSpans(left, left + 1, priority, insertionOrder) < 0) { left++; } if (compareSpans(index, left, priority, insertionOrder) >= 0) { break; } final T tmpSpan = array[index]; array[index] = array[left]; array[left] = tmpSpan; final int tmpPriority = priority[index]; priority[index] = priority[left]; priority[left] = tmpPriority; final int tmpOrder = insertionOrder[index]; insertionOrder[index] = insertionOrder[left]; insertionOrder[left] = tmpOrder; index = left; left = 2 * index + 1; } } /** * Compare two span elements in an array. Comparison is based first on the priority flag of * the span, and then the insertion order of the span. * * @param left Index of the element to compare. * @param right Index of the other element to compare. * @param priority Priorities of the spans * @param insertionOrder Insertion orders of the spans * @return */ private final int compareSpans(int left, int right, int[] priority, int[] insertionOrder) { int priority1 = priority[left]; int priority2 = priority[right]; if (priority1 == priority2) { return Integer.compare(insertionOrder[left], insertionOrder[right]); } // since high priority has to be before a lower priority, the arguments to compare are // opposite of the insertion order check. return Integer.compare(priority2, priority1); } /** * Return the next offset after start but less than or * equal to limit where a span of the specified type * begins or ends. */ public int nextSpanTransition(int start, int limit, Class kind) { if (mSpanCount == 0) return limit; if (kind == null) { kind = Object.class; } return nextSpanTransitionRec(start, limit, kind, treeRoot()); } private int nextSpanTransitionRec(int start, int limit, Class kind, int i) { if ((i & 1) != 0) { // internal tree node int left = leftChild(i); if (resolveGap(mSpanMax[left]) > start) { limit = nextSpanTransitionRec(start, limit, kind, left); } } if (i < mSpanCount) { int st = resolveGap(mSpanStarts[i]); int en = resolveGap(mSpanEnds[i]); if (st > start && st < limit && kind.isInstance(mSpans[i])) limit = st; if (en > start && en < limit && kind.isInstance(mSpans[i])) limit = en; if (st < limit && (i & 1) != 0) { limit = nextSpanTransitionRec(start, limit, kind, rightChild(i)); } } return limit; } /** * Return a new CharSequence containing a copy of the specified * range of this buffer, including the overlapping spans. */ public CharSequence subSequence(int start, int end) { return new SpannableStringBuilder(this, start, end); } /** * Copy the specified range of chars from this buffer into the * specified array, beginning at the specified offset. */ public void getChars(int start, int end, char[] dest, int destoff) { checkRange("getChars", start, end); if (end <= mGapStart) { System.arraycopy(mText, start, dest, destoff, end - start); } else if (start >= mGapStart) { System.arraycopy(mText, start + mGapLength, dest, destoff, end - start); } else { System.arraycopy(mText, start, dest, destoff, mGapStart - start); System.arraycopy(mText, mGapStart + mGapLength, dest, destoff + (mGapStart - start), end - mGapStart); } } /** * Return a String containing a copy of the chars in this buffer. */ @Override public String toString() { int len = length(); char[] buf = new char[len]; getChars(0, len, buf, 0); return new String(buf); } /** * Return a String containing a copy of the chars in this buffer, limited to the * [start, end[ range. * @hide */ public String substring(int start, int end) { char[] buf = new char[end - start]; getChars(start, end, buf, 0); return new String(buf); } /** * Returns the depth of TextWatcher callbacks. Returns 0 when the object is not handling * TextWatchers. A return value greater than 1 implies that a TextWatcher caused a change that * recursively triggered a TextWatcher. */ public int getTextWatcherDepth() { return mTextWatcherDepth; } private void sendBeforeTextChanged(TextWatcher[] watchers, int start, int before, int after) { int n = watchers.length; mTextWatcherDepth++; for (int i = 0; i < n; i++) { watchers[i].beforeTextChanged(this, start, before, after); } mTextWatcherDepth--; } private void sendTextChanged(TextWatcher[] watchers, int start, int before, int after) { int n = watchers.length; mTextWatcherDepth++; for (int i = 0; i < n; i++) { watchers[i].onTextChanged(this, start, before, after); } mTextWatcherDepth--; } private void sendAfterTextChanged(TextWatcher[] watchers) { int n = watchers.length; mTextWatcherDepth++; for (int i = 0; i < n; i++) { watchers[i].afterTextChanged(this); } mTextWatcherDepth--; } private void sendSpanAdded(Object what, int start, int end) { SpanWatcher[] recip = getSpans(start, end, SpanWatcher.class); int n = recip.length; for (int i = 0; i < n; i++) { recip[i].onSpanAdded(this, what, start, end); } } private void sendSpanRemoved(Object what, int start, int end) { SpanWatcher[] recip = getSpans(start, end, SpanWatcher.class); int n = recip.length; for (int i = 0; i < n; i++) { recip[i].onSpanRemoved(this, what, start, end); } } private void sendSpanChanged(Object what, int oldStart, int oldEnd, int start, int end) { // The bounds of a possible SpanWatcher are guaranteed to be set before this method is // called, so that the order of the span does not affect this broadcast. SpanWatcher[] spanWatchers = getSpans(Math.min(oldStart, start), Math.min(Math.max(oldEnd, end), length()), SpanWatcher.class); int n = spanWatchers.length; for (int i = 0; i < n; i++) { spanWatchers[i].onSpanChanged(this, what, oldStart, oldEnd, start, end); } } private static String region(int start, int end) { return "(" + start + " ... " + end + ")"; } private void checkRange(final String operation, int start, int end) { if (end < start) { throw new IndexOutOfBoundsException(operation + " " + region(start, end) + " has end before start"); } int len = length(); if (start > len || end > len) { throw new IndexOutOfBoundsException(operation + " " + region(start, end) + " ends beyond length " + len); } if (start < 0 || end < 0) { throw new IndexOutOfBoundsException(operation + " " + region(start, end) + " starts before 0"); } } /* private boolean isprint(char c) { // XXX if (c >= ' ' && c <= '~') return true; else return false; } private static final int startFlag(int flag) { return (flag >> 4) & 0x0F; } private static final int endFlag(int flag) { return flag & 0x0F; } public void dump() { // XXX for (int i = 0; i < mGapStart; i++) { System.out.print('|'); System.out.print(' '); System.out.print(isprint(mText[i]) ? mText[i] : '.'); System.out.print(' '); } for (int i = mGapStart; i < mGapStart + mGapLength; i++) { System.out.print('|'); System.out.print('('); System.out.print(isprint(mText[i]) ? mText[i] : '.'); System.out.print(')'); } for (int i = mGapStart + mGapLength; i < mText.length; i++) { System.out.print('|'); System.out.print(' '); System.out.print(isprint(mText[i]) ? mText[i] : '.'); System.out.print(' '); } System.out.print('\n'); for (int i = 0; i < mText.length + 1; i++) { int found = 0; int wfound = 0; for (int j = 0; j < mSpanCount; j++) { if (mSpanStarts[j] == i) { found = 1; wfound = j; break; } if (mSpanEnds[j] == i) { found = 2; wfound = j; break; } } if (found == 1) { if (startFlag(mSpanFlags[wfound]) == MARK) System.out.print("( "); if (startFlag(mSpanFlags[wfound]) == PARAGRAPH) System.out.print("< "); else System.out.print("[ "); } else if (found == 2) { if (endFlag(mSpanFlags[wfound]) == POINT) System.out.print(") "); if (endFlag(mSpanFlags[wfound]) == PARAGRAPH) System.out.print("> "); else System.out.print("] "); } else { System.out.print(" "); } } System.out.print("\n"); } */ /** * Don't call this yourself -- exists for Canvas to use internally. * {@hide} */ @Override public void drawText(BaseCanvas c, int start, int end, float x, float y, Paint p) { checkRange("drawText", start, end); if (end <= mGapStart) { c.drawText(mText, start, end - start, x, y, p); } else if (start >= mGapStart) { c.drawText(mText, start + mGapLength, end - start, x, y, p); } else { char[] buf = TextUtils.obtain(end - start); getChars(start, end, buf, 0); c.drawText(buf, 0, end - start, x, y, p); TextUtils.recycle(buf); } } /** * Don't call this yourself -- exists for Canvas to use internally. * {@hide} */ @Override public void drawTextRun(BaseCanvas c, int start, int end, int contextStart, int contextEnd, float x, float y, boolean isRtl, Paint p) { checkRange("drawTextRun", start, end); int contextLen = contextEnd - contextStart; int len = end - start; if (contextEnd <= mGapStart) { c.drawTextRun(mText, start, len, contextStart, contextLen, x, y, isRtl, p); } else if (contextStart >= mGapStart) { c.drawTextRun(mText, start + mGapLength, len, contextStart + mGapLength, contextLen, x, y, isRtl, p); } else { char[] buf = TextUtils.obtain(contextLen); getChars(contextStart, contextEnd, buf, 0); c.drawTextRun(buf, start - contextStart, len, 0, contextLen, x, y, isRtl, p); TextUtils.recycle(buf); } } /** * Don't call this yourself -- exists for Paint to use internally. * {@hide} */ public float measureText(int start, int end, Paint p) { checkRange("measureText", start, end); float ret; if (end <= mGapStart) { ret = p.measureText(mText, start, end - start); } else if (start >= mGapStart) { ret = p.measureText(mText, start + mGapLength, end - start); } else { char[] buf = TextUtils.obtain(end - start); getChars(start, end, buf, 0); ret = p.measureText(buf, 0, end - start); TextUtils.recycle(buf); } return ret; } /** * Don't call this yourself -- exists for Paint to use internally. * {@hide} */ public int getTextWidths(int start, int end, float[] widths, Paint p) { checkRange("getTextWidths", start, end); int ret; if (end <= mGapStart) { ret = p.getTextWidths(mText, start, end - start, widths); } else if (start >= mGapStart) { ret = p.getTextWidths(mText, start + mGapLength, end - start, widths); } else { char[] buf = TextUtils.obtain(end - start); getChars(start, end, buf, 0); ret = p.getTextWidths(buf, 0, end - start, widths); TextUtils.recycle(buf); } return ret; } /** * Don't call this yourself -- exists for Paint to use internally. * {@hide} */ public float getTextRunAdvances(int start, int end, int contextStart, int contextEnd, boolean isRtl, float[] advances, int advancesPos, Paint p) { float ret; int contextLen = contextEnd - contextStart; int len = end - start; if (end <= mGapStart) { ret = p.getTextRunAdvances(mText, start, len, contextStart, contextLen, isRtl, advances, advancesPos); } else if (start >= mGapStart) { ret = p.getTextRunAdvances(mText, start + mGapLength, len, contextStart + mGapLength, contextLen, isRtl, advances, advancesPos); } else { char[] buf = TextUtils.obtain(contextLen); getChars(contextStart, contextEnd, buf, 0); ret = p.getTextRunAdvances(buf, start - contextStart, len, 0, contextLen, isRtl, advances, advancesPos); TextUtils.recycle(buf); } return ret; } /** * Returns the next cursor position in the run. This avoids placing the cursor between * surrogates, between characters that form conjuncts, between base characters and combining * marks, or within a reordering cluster. * *

The context is the shaping context for cursor movement, generally the bounds of the metric * span enclosing the cursor in the direction of movement. * contextStart, contextEnd and offset are relative to * the start of the string.

* *

If cursorOpt is CURSOR_AT and the offset is not a valid cursor position, * this returns -1. Otherwise this will never return a value before contextStart or after * contextEnd.

* * @param contextStart the start index of the context * @param contextEnd the (non-inclusive) end index of the context * @param dir either DIRECTION_RTL or DIRECTION_LTR * @param offset the cursor position to move from * @param cursorOpt how to move the cursor, one of CURSOR_AFTER, * CURSOR_AT_OR_AFTER, CURSOR_BEFORE, * CURSOR_AT_OR_BEFORE, or CURSOR_AT * @param p the Paint object that is requesting this information * @return the offset of the next position, or -1 * @deprecated This is an internal method, refrain from using it in your code */ @Deprecated public int getTextRunCursor(int contextStart, int contextEnd, int dir, int offset, int cursorOpt, Paint p) { int ret; int contextLen = contextEnd - contextStart; if (contextEnd <= mGapStart) { ret = p.getTextRunCursor(mText, contextStart, contextLen, dir, offset, cursorOpt); } else if (contextStart >= mGapStart) { ret = p.getTextRunCursor(mText, contextStart + mGapLength, contextLen, dir, offset + mGapLength, cursorOpt) - mGapLength; } else { char[] buf = TextUtils.obtain(contextLen); getChars(contextStart, contextEnd, buf, 0); ret = p.getTextRunCursor(buf, 0, contextLen, dir, offset - contextStart, cursorOpt) + contextStart; TextUtils.recycle(buf); } return ret; } // Documentation from interface public void setFilters(InputFilter[] filters) { if (filters == null) { throw new IllegalArgumentException(); } mFilters = filters; } // Documentation from interface public InputFilter[] getFilters() { return mFilters; } // Same as SpannableStringInternal @Override public boolean equals(Object o) { if (o instanceof Spanned && toString().equals(o.toString())) { Spanned other = (Spanned) o; // Check span data Object[] otherSpans = other.getSpans(0, other.length(), Object.class); if (mSpanCount == otherSpans.length) { for (int i = 0; i < mSpanCount; ++i) { Object thisSpan = mSpans[i]; Object otherSpan = otherSpans[i]; if (thisSpan == this) { if (other != otherSpan || getSpanStart(thisSpan) != other.getSpanStart(otherSpan) || getSpanEnd(thisSpan) != other.getSpanEnd(otherSpan) || getSpanFlags(thisSpan) != other.getSpanFlags(otherSpan)) { return false; } } else if (!thisSpan.equals(otherSpan) || getSpanStart(thisSpan) != other.getSpanStart(otherSpan) || getSpanEnd(thisSpan) != other.getSpanEnd(otherSpan) || getSpanFlags(thisSpan) != other.getSpanFlags(otherSpan)) { return false; } } return true; } } return false; } // Same as SpannableStringInternal @Override public int hashCode() { int hash = toString().hashCode(); hash = hash * 31 + mSpanCount; for (int i = 0; i < mSpanCount; ++i) { Object span = mSpans[i]; if (span != this) { hash = hash * 31 + span.hashCode(); } hash = hash * 31 + getSpanStart(span); hash = hash * 31 + getSpanEnd(span); hash = hash * 31 + getSpanFlags(span); } return hash; } // Primitives for treating span list as binary tree // The spans (along with start and end offsets and flags) are stored in linear arrays sorted // by start offset. For fast searching, there is a binary search structure imposed over these // arrays. This structure is inorder traversal of a perfect binary tree, a slightly unusual // but advantageous approach. // The value-containing nodes are indexed 0 <= i < n (where n = mSpanCount), thus preserving // logic that accesses the values as a contiguous array. Other balanced binary tree approaches // (such as a complete binary tree) would require some shuffling of node indices. // Basic properties of this structure: For a perfect binary tree of height m: // The tree has 2^(m+1) - 1 total nodes. // The root of the tree has index 2^m - 1. // All leaf nodes have even index, all interior nodes odd. // The height of a node of index i is the number of trailing ones in i's binary representation. // The left child of a node i of height h is i - 2^(h - 1). // The right child of a node i of height h is i + 2^(h - 1). // Note that for arbitrary n, interior nodes of this tree may be >= n. Thus, the general // structure of a recursive traversal of node i is: // * traverse left child if i is an interior node // * process i if i < n // * traverse right child if i is an interior node and i < n private int treeRoot() { return Integer.highestOneBit(mSpanCount) - 1; } // (i+1) & ~i is equal to 2^(the number of trailing ones in i) private static int leftChild(int i) { return i - (((i + 1) & ~i) >> 1); } private static int rightChild(int i) { return i + (((i + 1) & ~i) >> 1); } // The span arrays are also augmented by an mSpanMax[] array that represents an interval tree // over the binary tree structure described above. For each node, the mSpanMax[] array contains // the maximum value of mSpanEnds of that node and its descendants. Thus, traversals can // easily reject subtrees that contain no spans overlapping the area of interest. // Note that mSpanMax[] also has a valid valuefor interior nodes of index >= n, but which have // descendants of index < n. In these cases, it simply represents the maximum span end of its // descendants. This is a consequence of the perfect binary tree structure. private int calcMax(int i) { int max = 0; if ((i & 1) != 0) { // internal tree node max = calcMax(leftChild(i)); } if (i < mSpanCount) { max = Math.max(max, mSpanEnds[i]); if ((i & 1) != 0) { max = Math.max(max, calcMax(rightChild(i))); } } mSpanMax[i] = max; return max; } // restores binary interval tree invariants after any mutation of span structure private void restoreInvariants() { if (mSpanCount == 0) return; // invariant 1: span starts are nondecreasing // This is a simple insertion sort because we expect it to be mostly sorted. for (int i = 1; i < mSpanCount; i++) { if (mSpanStarts[i] < mSpanStarts[i - 1]) { Object span = mSpans[i]; int start = mSpanStarts[i]; int end = mSpanEnds[i]; int flags = mSpanFlags[i]; int insertionOrder = mSpanOrder[i]; int j = i; do { mSpans[j] = mSpans[j - 1]; mSpanStarts[j] = mSpanStarts[j - 1]; mSpanEnds[j] = mSpanEnds[j - 1]; mSpanFlags[j] = mSpanFlags[j - 1]; mSpanOrder[j] = mSpanOrder[j - 1]; j--; } while (j > 0 && start < mSpanStarts[j - 1]); mSpans[j] = span; mSpanStarts[j] = start; mSpanEnds[j] = end; mSpanFlags[j] = flags; mSpanOrder[j] = insertionOrder; invalidateIndex(j); } } // invariant 2: max is max span end for each node and its descendants calcMax(treeRoot()); // invariant 3: mIndexOfSpan maps spans back to indices if (mIndexOfSpan == null) { mIndexOfSpan = new IdentityHashMap(); } for (int i = mLowWaterMark; i < mSpanCount; i++) { Integer existing = mIndexOfSpan.get(mSpans[i]); if (existing == null || existing != i) { mIndexOfSpan.put(mSpans[i], i); } } mLowWaterMark = Integer.MAX_VALUE; } // Call this on any update to mSpans[], so that mIndexOfSpan can be updated private void invalidateIndex(int i) { mLowWaterMark = Math.min(i, mLowWaterMark); } private static final InputFilter[] NO_FILTERS = new InputFilter[0]; @GuardedBy("sCachedIntBuffer") private static final int[][] sCachedIntBuffer = new int[6][0]; private InputFilter[] mFilters = NO_FILTERS; private char[] mText; private int mGapStart; private int mGapLength; private Object[] mSpans; private int[] mSpanStarts; private int[] mSpanEnds; private int[] mSpanMax; // see calcMax() for an explanation of what this array stores private int[] mSpanFlags; private int[] mSpanOrder; // store the order of span insertion private int mSpanInsertCount; // counter for the span insertion private int mSpanCount; private IdentityHashMap mIndexOfSpan; private int mLowWaterMark; // indices below this have not been touched // TextWatcher callbacks may trigger changes that trigger more callbacks. This keeps track of // how deep the callbacks go. private int mTextWatcherDepth; // TODO These value are tightly related to the public SPAN_MARK/POINT values in {@link Spanned} private static final int MARK = 1; private static final int POINT = 2; private static final int PARAGRAPH = 3; private static final int START_MASK = 0xF0; private static final int END_MASK = 0x0F; private static final int START_SHIFT = 4; // These bits are not (currently) used by SPANNED flags private static final int SPAN_ADDED = 0x800; private static final int SPAN_START_AT_START = 0x1000; private static final int SPAN_START_AT_END = 0x2000; private static final int SPAN_END_AT_START = 0x4000; private static final int SPAN_END_AT_END = 0x8000; private static final int SPAN_START_END_MASK = 0xF000; }