/* * Copyright (C) 2014 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.support.v7.widget; import android.content.Context; import android.content.res.TypedArray; import android.graphics.Canvas; import android.graphics.drawable.Drawable; import android.os.Build; import android.support.annotation.IntDef; import android.support.v4.view.GravityCompat; import android.support.v4.view.ViewCompat; import android.support.v7.appcompat.R; import android.util.AttributeSet; import android.view.Gravity; import android.view.View; import android.view.ViewGroup; import android.view.accessibility.AccessibilityEvent; import android.view.accessibility.AccessibilityNodeInfo; import java.lang.annotation.Retention; import java.lang.annotation.RetentionPolicy; /** * A Layout that arranges its children in a single column or a single row. The direction of * the row can be set by calling {@link #setOrientation(int) setOrientation()}. * You can also specify gravity, which specifies the alignment of all the child elements by * calling {@link #setGravity(int) setGravity()} or specify that specific children * grow to fill up any remaining space in the layout by setting the weight member of * {@link LinearLayoutCompat.LayoutParams LinearLayoutCompat.LayoutParams}. * The default orientation is horizontal. * *
See the Linear Layout * guide.
* ** Also see {@link LinearLayoutCompat.LayoutParams} for layout attributes
*/ public class LinearLayoutCompat extends ViewGroup { /** @hide */ @IntDef({HORIZONTAL, VERTICAL}) @Retention(RetentionPolicy.SOURCE) public @interface OrientationMode {} public static final int HORIZONTAL = 0; public static final int VERTICAL = 1; /** @hide */ @IntDef(flag = true, value = { SHOW_DIVIDER_NONE, SHOW_DIVIDER_BEGINNING, SHOW_DIVIDER_MIDDLE, SHOW_DIVIDER_END }) @Retention(RetentionPolicy.SOURCE) public @interface DividerMode {} /** * Don't show any dividers. */ public static final int SHOW_DIVIDER_NONE = 0; /** * Show a divider at the beginning of the group. */ public static final int SHOW_DIVIDER_BEGINNING = 1; /** * Show dividers between each item in the group. */ public static final int SHOW_DIVIDER_MIDDLE = 2; /** * Show a divider at the end of the group. */ public static final int SHOW_DIVIDER_END = 4; /** * Whether the children of this layout are baseline aligned. Only applicable * if {@link #mOrientation} is horizontal. */ private boolean mBaselineAligned = true; /** * If this layout is part of another layout that is baseline aligned, * use the child at this index as the baseline. * * Note: this is orthogonal to {@link #mBaselineAligned}, which is concerned * with whether the children of this layout are baseline aligned. */ private int mBaselineAlignedChildIndex = -1; /** * The additional offset to the child's baseline. * We'll calculate the baseline of this layout as we measure vertically; for * horizontal linear layouts, the offset of 0 is appropriate. */ private int mBaselineChildTop = 0; private int mOrientation; private int mGravity = GravityCompat.START | Gravity.TOP; private int mTotalLength; private float mWeightSum; private boolean mUseLargestChild; private int[] mMaxAscent; private int[] mMaxDescent; private static final int VERTICAL_GRAVITY_COUNT = 4; private static final int INDEX_CENTER_VERTICAL = 0; private static final int INDEX_TOP = 1; private static final int INDEX_BOTTOM = 2; private static final int INDEX_FILL = 3; private Drawable mDivider; private int mDividerWidth; private int mDividerHeight; private int mShowDividers; private int mDividerPadding; public LinearLayoutCompat(Context context) { this(context, null); } public LinearLayoutCompat(Context context, AttributeSet attrs) { this(context, attrs, 0); } public LinearLayoutCompat(Context context, AttributeSet attrs, int defStyleAttr) { super(context, attrs, defStyleAttr); final TintTypedArray a = TintTypedArray.obtainStyledAttributes(context, attrs, R.styleable.LinearLayoutCompat, defStyleAttr, 0); int index = a.getInt(R.styleable.LinearLayoutCompat_android_orientation, -1); if (index >= 0) { setOrientation(index); } index = a.getInt(R.styleable.LinearLayoutCompat_android_gravity, -1); if (index >= 0) { setGravity(index); } boolean baselineAligned = a.getBoolean(R.styleable.LinearLayoutCompat_android_baselineAligned, true); if (!baselineAligned) { setBaselineAligned(baselineAligned); } mWeightSum = a.getFloat(R.styleable.LinearLayoutCompat_android_weightSum, -1.0f); mBaselineAlignedChildIndex = a.getInt(R.styleable.LinearLayoutCompat_android_baselineAlignedChildIndex, -1); mUseLargestChild = a.getBoolean(R.styleable.LinearLayoutCompat_measureWithLargestChild, false); setDividerDrawable(a.getDrawable(R.styleable.LinearLayoutCompat_divider)); mShowDividers = a.getInt(R.styleable.LinearLayoutCompat_showDividers, SHOW_DIVIDER_NONE); mDividerPadding = a.getDimensionPixelSize(R.styleable.LinearLayoutCompat_dividerPadding, 0); a.recycle(); } /** * Set how dividers should be shown between items in this layout * * @param showDividers One or more of {@link #SHOW_DIVIDER_BEGINNING}, * {@link #SHOW_DIVIDER_MIDDLE}, or {@link #SHOW_DIVIDER_END}, * or {@link #SHOW_DIVIDER_NONE} to show no dividers. */ public void setShowDividers(@DividerMode int showDividers) { if (showDividers != mShowDividers) { requestLayout(); } mShowDividers = showDividers; } @Override public boolean shouldDelayChildPressedState() { return false; } /** * @return A flag set indicating how dividers should be shown around items. * @see #setShowDividers(int) */ @DividerMode public int getShowDividers() { return mShowDividers; } /** * @return the divider Drawable that will divide each item. * * @see #setDividerDrawable(Drawable) */ public Drawable getDividerDrawable() { return mDivider; } /** * Set a drawable to be used as a divider between items. * * @param divider Drawable that will divide each item. * * @see #setShowDividers(int) */ public void setDividerDrawable(Drawable divider) { if (divider == mDivider) { return; } mDivider = divider; if (divider != null) { mDividerWidth = divider.getIntrinsicWidth(); mDividerHeight = divider.getIntrinsicHeight(); } else { mDividerWidth = 0; mDividerHeight = 0; } setWillNotDraw(divider == null); requestLayout(); } /** * Set padding displayed on both ends of dividers. * * @param padding Padding value in pixels that will be applied to each end * * @see #setShowDividers(int) * @see #setDividerDrawable(Drawable) * @see #getDividerPadding() */ public void setDividerPadding(int padding) { mDividerPadding = padding; } /** * Get the padding size used to inset dividers in pixels * * @see #setShowDividers(int) * @see #setDividerDrawable(Drawable) * @see #setDividerPadding(int) */ public int getDividerPadding() { return mDividerPadding; } /** * Get the width of the current divider drawable. * * @hide Used internally by framework. */ public int getDividerWidth() { return mDividerWidth; } @Override protected void onDraw(Canvas canvas) { if (mDivider == null) { return; } if (mOrientation == VERTICAL) { drawDividersVertical(canvas); } else { drawDividersHorizontal(canvas); } } void drawDividersVertical(Canvas canvas) { final int count = getVirtualChildCount(); for (int i = 0; i < count; i++) { final View child = getVirtualChildAt(i); if (child != null && child.getVisibility() != GONE) { if (hasDividerBeforeChildAt(i)) { final LayoutParams lp = (LayoutParams) child.getLayoutParams(); final int top = child.getTop() - lp.topMargin - mDividerHeight; drawHorizontalDivider(canvas, top); } } } if (hasDividerBeforeChildAt(count)) { final View child = getVirtualChildAt(count - 1); int bottom = 0; if (child == null) { bottom = getHeight() - getPaddingBottom() - mDividerHeight; } else { final LayoutParams lp = (LayoutParams) child.getLayoutParams(); bottom = child.getBottom() + lp.bottomMargin; } drawHorizontalDivider(canvas, bottom); } } void drawDividersHorizontal(Canvas canvas) { final int count = getVirtualChildCount(); final boolean isLayoutRtl = ViewUtils.isLayoutRtl(this); for (int i = 0; i < count; i++) { final View child = getVirtualChildAt(i); if (child != null && child.getVisibility() != GONE) { if (hasDividerBeforeChildAt(i)) { final LayoutParams lp = (LayoutParams) child.getLayoutParams(); final int position; if (isLayoutRtl) { position = child.getRight() + lp.rightMargin; } else { position = child.getLeft() - lp.leftMargin - mDividerWidth; } drawVerticalDivider(canvas, position); } } } if (hasDividerBeforeChildAt(count)) { final View child = getVirtualChildAt(count - 1); int position; if (child == null) { if (isLayoutRtl) { position = getPaddingLeft(); } else { position = getWidth() - getPaddingRight() - mDividerWidth; } } else { final LayoutParams lp = (LayoutParams) child.getLayoutParams(); if (isLayoutRtl) { position = child.getLeft() - lp.leftMargin - mDividerWidth; } else { position = child.getRight() + lp.rightMargin; } } drawVerticalDivider(canvas, position); } } void drawHorizontalDivider(Canvas canvas, int top) { mDivider.setBounds(getPaddingLeft() + mDividerPadding, top, getWidth() - getPaddingRight() - mDividerPadding, top + mDividerHeight); mDivider.draw(canvas); } void drawVerticalDivider(Canvas canvas, int left) { mDivider.setBounds(left, getPaddingTop() + mDividerPadding, left + mDividerWidth, getHeight() - getPaddingBottom() - mDividerPadding); mDivider.draw(canvas); } /** *Indicates whether widgets contained within this layout are aligned * on their baseline or not.
* * @return true when widgets are baseline-aligned, false otherwise */ public boolean isBaselineAligned() { return mBaselineAligned; } /** *Defines whether widgets contained in this layout are * baseline-aligned or not.
* * @param baselineAligned true to align widgets on their baseline, * false otherwise */ public void setBaselineAligned(boolean baselineAligned) { mBaselineAligned = baselineAligned; } /** * When true, all children with a weight will be considered having * the minimum size of the largest child. If false, all children are * measured normally. * * @return True to measure children with a weight using the minimum * size of the largest child, false otherwise. */ public boolean isMeasureWithLargestChildEnabled() { return mUseLargestChild; } /** * When set to true, all children with a weight will be considered having * the minimum size of the largest child. If false, all children are * measured normally. * * Disabled by default. * * @param enabled True to measure children with a weight using the * minimum size of the largest child, false otherwise. */ public void setMeasureWithLargestChildEnabled(boolean enabled) { mUseLargestChild = enabled; } @Override public int getBaseline() { if (mBaselineAlignedChildIndex < 0) { return super.getBaseline(); } if (getChildCount() <= mBaselineAlignedChildIndex) { throw new RuntimeException("mBaselineAlignedChildIndex of LinearLayout " + "set to an index that is out of bounds."); } final View child = getChildAt(mBaselineAlignedChildIndex); final int childBaseline = child.getBaseline(); if (childBaseline == -1) { if (mBaselineAlignedChildIndex == 0) { // this is just the default case, safe to return -1 return -1; } // the user picked an index that points to something that doesn't // know how to calculate its baseline. throw new RuntimeException("mBaselineAlignedChildIndex of LinearLayout " + "points to a View that doesn't know how to get its baseline."); } // TODO: This should try to take into account the virtual offsets // (See getNextLocationOffset and getLocationOffset) // We should add to childTop: // sum([getNextLocationOffset(getChildAt(i)) / i < mBaselineAlignedChildIndex]) // and also add: // getLocationOffset(child) int childTop = mBaselineChildTop; if (mOrientation == VERTICAL) { final int majorGravity = mGravity & Gravity.VERTICAL_GRAVITY_MASK; if (majorGravity != Gravity.TOP) { switch (majorGravity) { case Gravity.BOTTOM: childTop = getBottom() - getTop() - getPaddingBottom() - mTotalLength; break; case Gravity.CENTER_VERTICAL: childTop += ((getBottom() - getTop() - getPaddingTop() - getPaddingBottom()) - mTotalLength) / 2; break; } } } LinearLayoutCompat.LayoutParams lp = (LinearLayoutCompat.LayoutParams) child.getLayoutParams(); return childTop + lp.topMargin + childBaseline; } /** * @return The index of the child that will be used if this layout is * part of a larger layout that is baseline aligned, or -1 if none has * been set. */ public int getBaselineAlignedChildIndex() { return mBaselineAlignedChildIndex; } /** * @param i The index of the child that will be used if this layout is * part of a larger layout that is baseline aligned. */ public void setBaselineAlignedChildIndex(int i) { if ((i < 0) || (i >= getChildCount())) { throw new IllegalArgumentException("base aligned child index out " + "of range (0, " + getChildCount() + ")"); } mBaselineAlignedChildIndex = i; } /** *Returns the view at the specified index. This method can be overriden * to take into account virtual children. Refer to * {@link android.widget.TableLayout} and {@link android.widget.TableRow} * for an example.
* * @param index the child's index * @return the child at the specified index */ View getVirtualChildAt(int index) { return getChildAt(index); } /** *Returns the virtual number of children. This number might be different * than the actual number of children if the layout can hold virtual * children. Refer to * {@link android.widget.TableLayout} and {@link android.widget.TableRow} * for an example.
* * @return the virtual number of children */ int getVirtualChildCount() { return getChildCount(); } /** * Returns the desired weights sum. * * @return A number greater than 0.0f if the weight sum is defined, or * a number lower than or equals to 0.0f if not weight sum is * to be used. */ public float getWeightSum() { return mWeightSum; } /** * Defines the desired weights sum. If unspecified the weights sum is computed * at layout time by adding the layout_weight of each child. * * This can be used for instance to give a single child 50% of the total * available space by giving it a layout_weight of 0.5 and setting the * weightSum to 1.0. * * @param weightSum a number greater than 0.0f, or a number lower than or equals * to 0.0f if the weight sum should be computed from the children's * layout_weight */ public void setWeightSum(float weightSum) { mWeightSum = Math.max(0.0f, weightSum); } @Override protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec) { if (mOrientation == VERTICAL) { measureVertical(widthMeasureSpec, heightMeasureSpec); } else { measureHorizontal(widthMeasureSpec, heightMeasureSpec); } } /** * Determines where to position dividers between children. * * @param childIndex Index of child to check for preceding divider * @return true if there should be a divider before the child at childIndex * @hide Pending API consideration. Currently only used internally by the system. */ protected boolean hasDividerBeforeChildAt(int childIndex) { if (childIndex == 0) { return (mShowDividers & SHOW_DIVIDER_BEGINNING) != 0; } else if (childIndex == getChildCount()) { return (mShowDividers & SHOW_DIVIDER_END) != 0; } else if ((mShowDividers & SHOW_DIVIDER_MIDDLE) != 0) { boolean hasVisibleViewBefore = false; for (int i = childIndex - 1; i >= 0; i--) { if (getChildAt(i).getVisibility() != GONE) { hasVisibleViewBefore = true; break; } } return hasVisibleViewBefore; } return false; } /** * Measures the children when the orientation of this LinearLayout is set * to {@link #VERTICAL}. * * @param widthMeasureSpec Horizontal space requirements as imposed by the parent. * @param heightMeasureSpec Vertical space requirements as imposed by the parent. * * @see #getOrientation() * @see #setOrientation(int) * @see #onMeasure(int, int) */ void measureVertical(int widthMeasureSpec, int heightMeasureSpec) { mTotalLength = 0; int maxWidth = 0; int childState = 0; int alternativeMaxWidth = 0; int weightedMaxWidth = 0; boolean allFillParent = true; float totalWeight = 0; final int count = getVirtualChildCount(); final int widthMode = MeasureSpec.getMode(widthMeasureSpec); final int heightMode = MeasureSpec.getMode(heightMeasureSpec); boolean matchWidth = false; boolean skippedMeasure = false; final int baselineChildIndex = mBaselineAlignedChildIndex; final boolean useLargestChild = mUseLargestChild; int largestChildHeight = Integer.MIN_VALUE; // See how tall everyone is. Also remember max width. for (int i = 0; i < count; ++i) { final View child = getVirtualChildAt(i); if (child == null) { mTotalLength += measureNullChild(i); continue; } if (child.getVisibility() == View.GONE) { i += getChildrenSkipCount(child, i); continue; } if (hasDividerBeforeChildAt(i)) { mTotalLength += mDividerHeight; } LinearLayoutCompat.LayoutParams lp = (LinearLayoutCompat.LayoutParams) child.getLayoutParams(); totalWeight += lp.weight; if (heightMode == MeasureSpec.EXACTLY && lp.height == 0 && lp.weight > 0) { // Optimization: don't bother measuring children who are going to use // leftover space. These views will get measured again down below if // there is any leftover space. final int totalLength = mTotalLength; mTotalLength = Math.max(totalLength, totalLength + lp.topMargin + lp.bottomMargin); skippedMeasure = true; } else { int oldHeight = Integer.MIN_VALUE; if (lp.height == 0 && lp.weight > 0) { // heightMode is either UNSPECIFIED or AT_MOST, and this // child wanted to stretch to fill available space. // Translate that to WRAP_CONTENT so that it does not end up // with a height of 0 oldHeight = 0; lp.height = LayoutParams.WRAP_CONTENT; } // Determine how big this child would like to be. If this or // previous children have given a weight, then we allow it to // use all available space (and we will shrink things later // if needed). measureChildBeforeLayout( child, i, widthMeasureSpec, 0, heightMeasureSpec, totalWeight == 0 ? mTotalLength : 0); if (oldHeight != Integer.MIN_VALUE) { lp.height = oldHeight; } final int childHeight = child.getMeasuredHeight(); final int totalLength = mTotalLength; mTotalLength = Math.max(totalLength, totalLength + childHeight + lp.topMargin + lp.bottomMargin + getNextLocationOffset(child)); if (useLargestChild) { largestChildHeight = Math.max(childHeight, largestChildHeight); } } /** * If applicable, compute the additional offset to the child's baseline * we'll need later when asked {@link #getBaseline}. */ if ((baselineChildIndex >= 0) && (baselineChildIndex == i + 1)) { mBaselineChildTop = mTotalLength; } // if we are trying to use a child index for our baseline, the above // book keeping only works if there are no children above it with // weight. fail fast to aid the developer. if (i < baselineChildIndex && lp.weight > 0) { throw new RuntimeException("A child of LinearLayout with index " + "less than mBaselineAlignedChildIndex has weight > 0, which " + "won't work. Either remove the weight, or don't set " + "mBaselineAlignedChildIndex."); } boolean matchWidthLocally = false; if (widthMode != MeasureSpec.EXACTLY && lp.width == LayoutParams.MATCH_PARENT) { // The width of the linear layout will scale, and at least one // child said it wanted to match our width. Set a flag // indicating that we need to remeasure at least that view when // we know our width. matchWidth = true; matchWidthLocally = true; } final int margin = lp.leftMargin + lp.rightMargin; final int measuredWidth = child.getMeasuredWidth() + margin; maxWidth = Math.max(maxWidth, measuredWidth); childState = ViewUtils.combineMeasuredStates(childState, ViewCompat.getMeasuredState(child)); allFillParent = allFillParent && lp.width == LayoutParams.MATCH_PARENT; if (lp.weight > 0) { /* * Widths of weighted Views are bogus if we end up * remeasuring, so keep them separate. */ weightedMaxWidth = Math.max(weightedMaxWidth, matchWidthLocally ? margin : measuredWidth); } else { alternativeMaxWidth = Math.max(alternativeMaxWidth, matchWidthLocally ? margin : measuredWidth); } i += getChildrenSkipCount(child, i); } if (mTotalLength > 0 && hasDividerBeforeChildAt(count)) { mTotalLength += mDividerHeight; } if (useLargestChild && (heightMode == MeasureSpec.AT_MOST || heightMode == MeasureSpec.UNSPECIFIED)) { mTotalLength = 0; for (int i = 0; i < count; ++i) { final View child = getVirtualChildAt(i); if (child == null) { mTotalLength += measureNullChild(i); continue; } if (child.getVisibility() == GONE) { i += getChildrenSkipCount(child, i); continue; } final LinearLayoutCompat.LayoutParams lp = (LinearLayoutCompat.LayoutParams) child.getLayoutParams(); // Account for negative margins final int totalLength = mTotalLength; mTotalLength = Math.max(totalLength, totalLength + largestChildHeight + lp.topMargin + lp.bottomMargin + getNextLocationOffset(child)); } } // Add in our padding mTotalLength += getPaddingTop() + getPaddingBottom(); int heightSize = mTotalLength; // Check against our minimum height heightSize = Math.max(heightSize, getSuggestedMinimumHeight()); // Reconcile our calculated size with the heightMeasureSpec int heightSizeAndState = ViewCompat.resolveSizeAndState(heightSize, heightMeasureSpec, 0); heightSize = heightSizeAndState & ViewCompat.MEASURED_SIZE_MASK; // Either expand children with weight to take up available space or // shrink them if they extend beyond our current bounds. If we skipped // measurement on any children, we need to measure them now. int delta = heightSize - mTotalLength; if (skippedMeasure || delta != 0 && totalWeight > 0.0f) { float weightSum = mWeightSum > 0.0f ? mWeightSum : totalWeight; mTotalLength = 0; for (int i = 0; i < count; ++i) { final View child = getVirtualChildAt(i); if (child.getVisibility() == View.GONE) { continue; } LinearLayoutCompat.LayoutParams lp = (LinearLayoutCompat.LayoutParams) child.getLayoutParams(); float childExtra = lp.weight; if (childExtra > 0) { // Child said it could absorb extra space -- give him his share int share = (int) (childExtra * delta / weightSum); weightSum -= childExtra; delta -= share; final int childWidthMeasureSpec = getChildMeasureSpec(widthMeasureSpec, getPaddingLeft() + getPaddingRight() + lp.leftMargin + lp.rightMargin, lp.width); // TODO: Use a field like lp.isMeasured to figure out if this // child has been previously measured if ((lp.height != 0) || (heightMode != MeasureSpec.EXACTLY)) { // child was measured once already above... // base new measurement on stored values int childHeight = child.getMeasuredHeight() + share; if (childHeight < 0) { childHeight = 0; } child.measure(childWidthMeasureSpec, MeasureSpec.makeMeasureSpec(childHeight, MeasureSpec.EXACTLY)); } else { // child was skipped in the loop above. // Measure for this first time here child.measure(childWidthMeasureSpec, MeasureSpec.makeMeasureSpec(share > 0 ? share : 0, MeasureSpec.EXACTLY)); } // Child may now not fit in vertical dimension. childState = ViewUtils.combineMeasuredStates(childState, ViewCompat.getMeasuredState(child) & (ViewCompat.MEASURED_STATE_MASK >> ViewCompat.MEASURED_HEIGHT_STATE_SHIFT)); } final int margin = lp.leftMargin + lp.rightMargin; final int measuredWidth = child.getMeasuredWidth() + margin; maxWidth = Math.max(maxWidth, measuredWidth); boolean matchWidthLocally = widthMode != MeasureSpec.EXACTLY && lp.width == LayoutParams.MATCH_PARENT; alternativeMaxWidth = Math.max(alternativeMaxWidth, matchWidthLocally ? margin : measuredWidth); allFillParent = allFillParent && lp.width == LayoutParams.MATCH_PARENT; final int totalLength = mTotalLength; mTotalLength = Math.max(totalLength, totalLength + child.getMeasuredHeight() + lp.topMargin + lp.bottomMargin + getNextLocationOffset(child)); } // Add in our padding mTotalLength += getPaddingTop() + getPaddingBottom(); // TODO: Should we recompute the heightSpec based on the new total length? } else { alternativeMaxWidth = Math.max(alternativeMaxWidth, weightedMaxWidth); // We have no limit, so make all weighted views as tall as the largest child. // Children will have already been measured once. if (useLargestChild && heightMode != MeasureSpec.EXACTLY) { for (int i = 0; i < count; i++) { final View child = getVirtualChildAt(i); if (child == null || child.getVisibility() == View.GONE) { continue; } final LinearLayoutCompat.LayoutParams lp = (LinearLayoutCompat.LayoutParams) child.getLayoutParams(); float childExtra = lp.weight; if (childExtra > 0) { child.measure( MeasureSpec.makeMeasureSpec(child.getMeasuredWidth(), MeasureSpec.EXACTLY), MeasureSpec.makeMeasureSpec(largestChildHeight, MeasureSpec.EXACTLY)); } } } } if (!allFillParent && widthMode != MeasureSpec.EXACTLY) { maxWidth = alternativeMaxWidth; } maxWidth += getPaddingLeft() + getPaddingRight(); // Check against our minimum width maxWidth = Math.max(maxWidth, getSuggestedMinimumWidth()); setMeasuredDimension(ViewCompat.resolveSizeAndState(maxWidth, widthMeasureSpec, childState), heightSizeAndState); if (matchWidth) { forceUniformWidth(count, heightMeasureSpec); } } private void forceUniformWidth(int count, int heightMeasureSpec) { // Pretend that the linear layout has an exact size. int uniformMeasureSpec = MeasureSpec.makeMeasureSpec(getMeasuredWidth(), MeasureSpec.EXACTLY); for (int i = 0; i< count; ++i) { final View child = getVirtualChildAt(i); if (child.getVisibility() != GONE) { LinearLayoutCompat.LayoutParams lp = ((LinearLayoutCompat.LayoutParams)child.getLayoutParams()); if (lp.width == LayoutParams.MATCH_PARENT) { // Temporarily force children to reuse their old measured height // FIXME: this may not be right for something like wrapping text? int oldHeight = lp.height; lp.height = child.getMeasuredHeight(); // Remeasue with new dimensions measureChildWithMargins(child, uniformMeasureSpec, 0, heightMeasureSpec, 0); lp.height = oldHeight; } } } } /** * Measures the children when the orientation of this LinearLayout is set * to {@link #HORIZONTAL}. * * @param widthMeasureSpec Horizontal space requirements as imposed by the parent. * @param heightMeasureSpec Vertical space requirements as imposed by the parent. * * @see #getOrientation() * @see #setOrientation(int) * @see #onMeasure(int, int) */ void measureHorizontal(int widthMeasureSpec, int heightMeasureSpec) { mTotalLength = 0; int maxHeight = 0; int childState = 0; int alternativeMaxHeight = 0; int weightedMaxHeight = 0; boolean allFillParent = true; float totalWeight = 0; final int count = getVirtualChildCount(); final int widthMode = MeasureSpec.getMode(widthMeasureSpec); final int heightMode = MeasureSpec.getMode(heightMeasureSpec); boolean matchHeight = false; boolean skippedMeasure = false; if (mMaxAscent == null || mMaxDescent == null) { mMaxAscent = new int[VERTICAL_GRAVITY_COUNT]; mMaxDescent = new int[VERTICAL_GRAVITY_COUNT]; } final int[] maxAscent = mMaxAscent; final int[] maxDescent = mMaxDescent; maxAscent[0] = maxAscent[1] = maxAscent[2] = maxAscent[3] = -1; maxDescent[0] = maxDescent[1] = maxDescent[2] = maxDescent[3] = -1; final boolean baselineAligned = mBaselineAligned; final boolean useLargestChild = mUseLargestChild; final boolean isExactly = widthMode == MeasureSpec.EXACTLY; int largestChildWidth = Integer.MIN_VALUE; // See how wide everyone is. Also remember max height. for (int i = 0; i < count; ++i) { final View child = getVirtualChildAt(i); if (child == null) { mTotalLength += measureNullChild(i); continue; } if (child.getVisibility() == GONE) { i += getChildrenSkipCount(child, i); continue; } if (hasDividerBeforeChildAt(i)) { mTotalLength += mDividerWidth; } final LinearLayoutCompat.LayoutParams lp = (LinearLayoutCompat.LayoutParams) child.getLayoutParams(); totalWeight += lp.weight; if (widthMode == MeasureSpec.EXACTLY && lp.width == 0 && lp.weight > 0) { // Optimization: don't bother measuring children who are going to use // leftover space. These views will get measured again down below if // there is any leftover space. if (isExactly) { mTotalLength += lp.leftMargin + lp.rightMargin; } else { final int totalLength = mTotalLength; mTotalLength = Math.max(totalLength, totalLength + lp.leftMargin + lp.rightMargin); } // Baseline alignment requires to measure widgets to obtain the // baseline offset (in particular for TextViews). The following // defeats the optimization mentioned above. Allow the child to // use as much space as it wants because we can shrink things // later (and re-measure). if (baselineAligned) { final int freeSpec = MeasureSpec.makeMeasureSpec(0, MeasureSpec.UNSPECIFIED); child.measure(freeSpec, freeSpec); } else { skippedMeasure = true; } } else { int oldWidth = Integer.MIN_VALUE; if (lp.width == 0 && lp.weight > 0) { // widthMode is either UNSPECIFIED or AT_MOST, and this // child // wanted to stretch to fill available space. Translate that to // WRAP_CONTENT so that it does not end up with a width of 0 oldWidth = 0; lp.width = LayoutParams.WRAP_CONTENT; } // Determine how big this child would like to be. If this or // previous children have given a weight, then we allow it to // use all available space (and we will shrink things later // if needed). measureChildBeforeLayout(child, i, widthMeasureSpec, totalWeight == 0 ? mTotalLength : 0, heightMeasureSpec, 0); if (oldWidth != Integer.MIN_VALUE) { lp.width = oldWidth; } final int childWidth = child.getMeasuredWidth(); if (isExactly) { mTotalLength += childWidth + lp.leftMargin + lp.rightMargin + getNextLocationOffset(child); } else { final int totalLength = mTotalLength; mTotalLength = Math.max(totalLength, totalLength + childWidth + lp.leftMargin + lp.rightMargin + getNextLocationOffset(child)); } if (useLargestChild) { largestChildWidth = Math.max(childWidth, largestChildWidth); } } boolean matchHeightLocally = false; if (heightMode != MeasureSpec.EXACTLY && lp.height == LayoutParams.MATCH_PARENT) { // The height of the linear layout will scale, and at least one // child said it wanted to match our height. Set a flag indicating that // we need to remeasure at least that view when we know our height. matchHeight = true; matchHeightLocally = true; } final int margin = lp.topMargin + lp.bottomMargin; final int childHeight = child.getMeasuredHeight() + margin; childState = ViewUtils.combineMeasuredStates(childState, ViewCompat.getMeasuredState(child)); if (baselineAligned) { final int childBaseline = child.getBaseline(); if (childBaseline != -1) { // Translates the child's vertical gravity into an index // in the range 0..VERTICAL_GRAVITY_COUNT final int gravity = (lp.gravity < 0 ? mGravity : lp.gravity) & Gravity.VERTICAL_GRAVITY_MASK; final int index = ((gravity >> Gravity.AXIS_Y_SHIFT) & ~Gravity.AXIS_SPECIFIED) >> 1; maxAscent[index] = Math.max(maxAscent[index], childBaseline); maxDescent[index] = Math.max(maxDescent[index], childHeight - childBaseline); } } maxHeight = Math.max(maxHeight, childHeight); allFillParent = allFillParent && lp.height == LayoutParams.MATCH_PARENT; if (lp.weight > 0) { /* * Heights of weighted Views are bogus if we end up * remeasuring, so keep them separate. */ weightedMaxHeight = Math.max(weightedMaxHeight, matchHeightLocally ? margin : childHeight); } else { alternativeMaxHeight = Math.max(alternativeMaxHeight, matchHeightLocally ? margin : childHeight); } i += getChildrenSkipCount(child, i); } if (mTotalLength > 0 && hasDividerBeforeChildAt(count)) { mTotalLength += mDividerWidth; } // Check mMaxAscent[INDEX_TOP] first because it maps to Gravity.TOP, // the most common case if (maxAscent[INDEX_TOP] != -1 || maxAscent[INDEX_CENTER_VERTICAL] != -1 || maxAscent[INDEX_BOTTOM] != -1 || maxAscent[INDEX_FILL] != -1) { final int ascent = Math.max(maxAscent[INDEX_FILL], Math.max(maxAscent[INDEX_CENTER_VERTICAL], Math.max(maxAscent[INDEX_TOP], maxAscent[INDEX_BOTTOM]))); final int descent = Math.max(maxDescent[INDEX_FILL], Math.max(maxDescent[INDEX_CENTER_VERTICAL], Math.max(maxDescent[INDEX_TOP], maxDescent[INDEX_BOTTOM]))); maxHeight = Math.max(maxHeight, ascent + descent); } if (useLargestChild && (widthMode == MeasureSpec.AT_MOST || widthMode == MeasureSpec.UNSPECIFIED)) { mTotalLength = 0; for (int i = 0; i < count; ++i) { final View child = getVirtualChildAt(i); if (child == null) { mTotalLength += measureNullChild(i); continue; } if (child.getVisibility() == GONE) { i += getChildrenSkipCount(child, i); continue; } final LinearLayoutCompat.LayoutParams lp = (LinearLayoutCompat.LayoutParams) child.getLayoutParams(); if (isExactly) { mTotalLength += largestChildWidth + lp.leftMargin + lp.rightMargin + getNextLocationOffset(child); } else { final int totalLength = mTotalLength; mTotalLength = Math.max(totalLength, totalLength + largestChildWidth + lp.leftMargin + lp.rightMargin + getNextLocationOffset(child)); } } } // Add in our padding mTotalLength += getPaddingLeft() + getPaddingRight(); int widthSize = mTotalLength; // Check against our minimum width widthSize = Math.max(widthSize, getSuggestedMinimumWidth()); // Reconcile our calculated size with the widthMeasureSpec int widthSizeAndState = ViewCompat.resolveSizeAndState(widthSize, widthMeasureSpec, 0); widthSize = widthSizeAndState & ViewCompat.MEASURED_SIZE_MASK; // Either expand children with weight to take up available space or // shrink them if they extend beyond our current bounds. If we skipped // measurement on any children, we need to measure them now. int delta = widthSize - mTotalLength; if (skippedMeasure || delta != 0 && totalWeight > 0.0f) { float weightSum = mWeightSum > 0.0f ? mWeightSum : totalWeight; maxAscent[0] = maxAscent[1] = maxAscent[2] = maxAscent[3] = -1; maxDescent[0] = maxDescent[1] = maxDescent[2] = maxDescent[3] = -1; maxHeight = -1; mTotalLength = 0; for (int i = 0; i < count; ++i) { final View child = getVirtualChildAt(i); if (child == null || child.getVisibility() == View.GONE) { continue; } final LinearLayoutCompat.LayoutParams lp = (LinearLayoutCompat.LayoutParams) child.getLayoutParams(); float childExtra = lp.weight; if (childExtra > 0) { // Child said it could absorb extra space -- give him his share int share = (int) (childExtra * delta / weightSum); weightSum -= childExtra; delta -= share; final int childHeightMeasureSpec = getChildMeasureSpec( heightMeasureSpec, getPaddingTop() + getPaddingBottom() + lp.topMargin + lp.bottomMargin, lp.height); // TODO: Use a field like lp.isMeasured to figure out if this // child has been previously measured if ((lp.width != 0) || (widthMode != MeasureSpec.EXACTLY)) { // child was measured once already above ... base new measurement // on stored values int childWidth = child.getMeasuredWidth() + share; if (childWidth < 0) { childWidth = 0; } child.measure( MeasureSpec.makeMeasureSpec(childWidth, MeasureSpec.EXACTLY), childHeightMeasureSpec); } else { // child was skipped in the loop above. Measure for this first time here child.measure(MeasureSpec.makeMeasureSpec( share > 0 ? share : 0, MeasureSpec.EXACTLY), childHeightMeasureSpec); } // Child may now not fit in horizontal dimension. childState = ViewUtils.combineMeasuredStates(childState, ViewCompat.getMeasuredState(child) & ViewCompat.MEASURED_STATE_MASK); } if (isExactly) { mTotalLength += child.getMeasuredWidth() + lp.leftMargin + lp.rightMargin + getNextLocationOffset(child); } else { final int totalLength = mTotalLength; mTotalLength = Math.max(totalLength, totalLength + child.getMeasuredWidth() + lp.leftMargin + lp.rightMargin + getNextLocationOffset(child)); } boolean matchHeightLocally = heightMode != MeasureSpec.EXACTLY && lp.height == LayoutParams.MATCH_PARENT; final int margin = lp.topMargin + lp .bottomMargin; int childHeight = child.getMeasuredHeight() + margin; maxHeight = Math.max(maxHeight, childHeight); alternativeMaxHeight = Math.max(alternativeMaxHeight, matchHeightLocally ? margin : childHeight); allFillParent = allFillParent && lp.height == LayoutParams.MATCH_PARENT; if (baselineAligned) { final int childBaseline = child.getBaseline(); if (childBaseline != -1) { // Translates the child's vertical gravity into an index in the range 0..2 final int gravity = (lp.gravity < 0 ? mGravity : lp.gravity) & Gravity.VERTICAL_GRAVITY_MASK; final int index = ((gravity >> Gravity.AXIS_Y_SHIFT) & ~Gravity.AXIS_SPECIFIED) >> 1; maxAscent[index] = Math.max(maxAscent[index], childBaseline); maxDescent[index] = Math.max(maxDescent[index], childHeight - childBaseline); } } } // Add in our padding mTotalLength += getPaddingLeft() + getPaddingRight(); // TODO: Should we update widthSize with the new total length? // Check mMaxAscent[INDEX_TOP] first because it maps to Gravity.TOP, // the most common case if (maxAscent[INDEX_TOP] != -1 || maxAscent[INDEX_CENTER_VERTICAL] != -1 || maxAscent[INDEX_BOTTOM] != -1 || maxAscent[INDEX_FILL] != -1) { final int ascent = Math.max(maxAscent[INDEX_FILL], Math.max(maxAscent[INDEX_CENTER_VERTICAL], Math.max(maxAscent[INDEX_TOP], maxAscent[INDEX_BOTTOM]))); final int descent = Math.max(maxDescent[INDEX_FILL], Math.max(maxDescent[INDEX_CENTER_VERTICAL], Math.max(maxDescent[INDEX_TOP], maxDescent[INDEX_BOTTOM]))); maxHeight = Math.max(maxHeight, ascent + descent); } } else { alternativeMaxHeight = Math.max(alternativeMaxHeight, weightedMaxHeight); // We have no limit, so make all weighted views as wide as the largest child. // Children will have already been measured once. if (useLargestChild && widthMode != MeasureSpec.EXACTLY) { for (int i = 0; i < count; i++) { final View child = getVirtualChildAt(i); if (child == null || child.getVisibility() == View.GONE) { continue; } final LinearLayoutCompat.LayoutParams lp = (LinearLayoutCompat.LayoutParams) child.getLayoutParams(); float childExtra = lp.weight; if (childExtra > 0) { child.measure( MeasureSpec.makeMeasureSpec(largestChildWidth, MeasureSpec.EXACTLY), MeasureSpec.makeMeasureSpec(child.getMeasuredHeight(), MeasureSpec.EXACTLY)); } } } } if (!allFillParent && heightMode != MeasureSpec.EXACTLY) { maxHeight = alternativeMaxHeight; } maxHeight += getPaddingTop() + getPaddingBottom(); // Check against our minimum height maxHeight = Math.max(maxHeight, getSuggestedMinimumHeight()); setMeasuredDimension(widthSizeAndState | (childState&ViewCompat.MEASURED_STATE_MASK), ViewCompat.resolveSizeAndState(maxHeight, heightMeasureSpec, (childState<Returns the size (width or height) that should be occupied by a null * child.
* * @param childIndex the index of the null child * @return the width or height of the child depending on the orientation */ int measureNullChild(int childIndex) { return 0; } /** *Measure the child according to the parent's measure specs. This * method should be overriden by subclasses to force the sizing of * children. This method is called by {@link #measureVertical(int, int)} and * {@link #measureHorizontal(int, int)}.
* * @param child the child to measure * @param childIndex the index of the child in this view * @param widthMeasureSpec horizontal space requirements as imposed by the parent * @param totalWidth extra space that has been used up by the parent horizontally * @param heightMeasureSpec vertical space requirements as imposed by the parent * @param totalHeight extra space that has been used up by the parent vertically */ void measureChildBeforeLayout(View child, int childIndex, int widthMeasureSpec, int totalWidth, int heightMeasureSpec, int totalHeight) { measureChildWithMargins(child, widthMeasureSpec, totalWidth, heightMeasureSpec, totalHeight); } /** *Return the location offset of the specified child. This can be used * by subclasses to change the location of a given widget.
* * @param child the child for which to obtain the location offset * @return the location offset in pixels */ int getLocationOffset(View child) { return 0; } /** *Return the size offset of the next sibling of the specified child.
* This can be used by subclasses to change the location of the widget
* following child
.