/*
* Copyright (C) 2013 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.content;
import android.os.Parcel;
import android.os.Parcelable;
import android.os.ParcelableParcel;
import android.text.TextUtils;
import android.util.ArrayMap;
import java.util.ArrayList;
/**
* Top-level class for managing and interacting with the global undo state for
* a document or application. This class supports both undo and redo and has
* helpers for merging undoable operations together as they are performed.
*
*
A single undoable operation is represented by {@link UndoOperation} which
* apps implement to define their undo/redo behavior. The UndoManager keeps
* a stack of undo states; each state can have one or more undo operations
* inside of it.
*
* Updates to the stack must be done inside of a {@link #beginUpdate}/{@link #endUpdate()}
* pair. During this time you can add new operations to the stack with
* {@link #addOperation}, retrieve and modify existing operations with
* {@link #getLastOperation}, control the label shown to the user for this operation
* with {@link #setUndoLabel} and {@link #suggestUndoLabel}, etc.
*
* Every {link UndoOperation} is associated with an {@link UndoOwner}, which identifies
* the data it belongs to. The owner is used to indicate how operations are dependent
* on each other -- operations with the same owner are dependent on others with the
* same owner. For example, you may have a document with multiple embedded objects. If the
* document itself and each embedded object use different owners, then you
* can provide undo semantics appropriate to the user's context: while within
* an embedded object, only edits to that object are seen and the user can
* undo/redo them without needing to impact edits in other objects; while
* within the larger document, all edits can be seen and the user must
* undo/redo them as a single stream.
*
* @hide
*/
public class UndoManager {
// The common case is a single undo owner (e.g. for a TextView), so default to that capacity.
private final ArrayMap mOwners =
new ArrayMap(1 /* capacity */);
private final ArrayList mUndos = new ArrayList();
private final ArrayList mRedos = new ArrayList();
private int mUpdateCount;
private int mHistorySize = 20;
private UndoState mWorking;
private int mCommitId = 1;
private boolean mInUndo;
private boolean mMerged;
private int mStateSeq;
private int mNextSavedIdx;
private UndoOwner[] mStateOwners;
/**
* Never merge with the last undo state.
*/
public static final int MERGE_MODE_NONE = 0;
/**
* Allow merge with the last undo state only if it contains
* operations with the caller's owner.
*/
public static final int MERGE_MODE_UNIQUE = 1;
/**
* Always allow merge with the last undo state, if possible.
*/
public static final int MERGE_MODE_ANY = 2;
public UndoOwner getOwner(String tag, Object data) {
if (tag == null) {
throw new NullPointerException("tag can't be null");
}
if (data == null) {
throw new NullPointerException("data can't be null");
}
UndoOwner owner = mOwners.get(tag);
if (owner != null) {
if (owner.mData != data) {
if (owner.mData != null) {
throw new IllegalStateException("Owner " + owner + " already exists with data "
+ owner.mData + " but giving different data " + data);
}
owner.mData = data;
}
return owner;
}
owner = new UndoOwner(tag, this);
owner.mData = data;
mOwners.put(tag, owner);
return owner;
}
void removeOwner(UndoOwner owner) {
// XXX need to figure out how to prune.
if (false) {
mOwners.remove(owner.mTag);
}
}
/**
* Flatten the current undo state into a Parcel object, which can later be restored
* with {@link #restoreInstanceState(android.os.Parcel, java.lang.ClassLoader)}.
*/
public void saveInstanceState(Parcel p) {
if (mUpdateCount > 0) {
throw new IllegalStateException("Can't save state while updating");
}
mStateSeq++;
if (mStateSeq <= 0) {
mStateSeq = 0;
}
mNextSavedIdx = 0;
p.writeInt(mHistorySize);
p.writeInt(mOwners.size());
// XXX eventually we need to be smart here about limiting the
// number of undo states we write to not exceed X bytes.
int i = mUndos.size();
while (i > 0) {
p.writeInt(1);
i--;
mUndos.get(i).writeToParcel(p);
}
i = mRedos.size();
p.writeInt(i);
while (i > 0) {
p.writeInt(2);
i--;
mRedos.get(i).writeToParcel(p);
}
p.writeInt(0);
}
void saveOwner(UndoOwner owner, Parcel out) {
if (owner.mStateSeq == mStateSeq) {
out.writeInt(owner.mSavedIdx);
} else {
owner.mStateSeq = mStateSeq;
owner.mSavedIdx = mNextSavedIdx;
out.writeInt(owner.mSavedIdx);
out.writeString(owner.mTag);
out.writeInt(owner.mOpCount);
mNextSavedIdx++;
}
}
/**
* Restore an undo state previously created with {@link #saveInstanceState(Parcel)}. This
* will restore the UndoManager's state to almost exactly what it was at the point it had
* been previously saved; the only information not restored is the data object
* associated with each {@link UndoOwner}, which requires separate calls to
* {@link #getOwner(String, Object)} to re-associate the owner with its data.
*/
public void restoreInstanceState(Parcel p, ClassLoader loader) {
if (mUpdateCount > 0) {
throw new IllegalStateException("Can't save state while updating");
}
forgetUndos(null, -1);
forgetRedos(null, -1);
mHistorySize = p.readInt();
mStateOwners = new UndoOwner[p.readInt()];
int stype;
while ((stype=p.readInt()) != 0) {
UndoState ustate = new UndoState(this, p, loader);
if (stype == 1) {
mUndos.add(0, ustate);
} else {
mRedos.add(0, ustate);
}
}
}
UndoOwner restoreOwner(Parcel in) {
int idx = in.readInt();
UndoOwner owner = mStateOwners[idx];
if (owner == null) {
String tag = in.readString();
int opCount = in.readInt();
owner = new UndoOwner(tag, this);
owner.mOpCount = opCount;
mStateOwners[idx] = owner;
mOwners.put(tag, owner);
}
return owner;
}
/**
* Set the maximum number of undo states that will be retained.
*/
public void setHistorySize(int size) {
mHistorySize = size;
if (mHistorySize >= 0 && countUndos(null) > mHistorySize) {
forgetUndos(null, countUndos(null) - mHistorySize);
}
}
/**
* Return the current maximum number of undo states.
*/
public int getHistorySize() {
return mHistorySize;
}
/**
* Perform undo of last/top count undo states. The states impacted
* by this can be limited through owners.
* @param owners Optional set of owners that should be impacted. If null, all
* undo states will be visible and available for undo. If non-null, only those
* states that contain one of the owners specified here will be visible.
* @param count Number of undo states to pop.
* @return Returns the number of undo states that were actually popped.
*/
public int undo(UndoOwner[] owners, int count) {
if (mWorking != null) {
throw new IllegalStateException("Can't be called during an update");
}
int num = 0;
int i = -1;
mInUndo = true;
UndoState us = getTopUndo(null);
if (us != null) {
us.makeExecuted();
}
while (count > 0 && (i=findPrevState(mUndos, owners, i)) >= 0) {
UndoState state = mUndos.remove(i);
state.undo();
mRedos.add(state);
count--;
num++;
}
mInUndo = false;
return num;
}
/**
* Perform redo of last/top count undo states in the transient redo stack.
* The states impacted by this can be limited through owners.
* @param owners Optional set of owners that should be impacted. If null, all
* undo states will be visible and available for undo. If non-null, only those
* states that contain one of the owners specified here will be visible.
* @param count Number of undo states to pop.
* @return Returns the number of undo states that were actually redone.
*/
public int redo(UndoOwner[] owners, int count) {
if (mWorking != null) {
throw new IllegalStateException("Can't be called during an update");
}
int num = 0;
int i = -1;
mInUndo = true;
while (count > 0 && (i=findPrevState(mRedos, owners, i)) >= 0) {
UndoState state = mRedos.remove(i);
state.redo();
mUndos.add(state);
count--;
num++;
}
mInUndo = false;
return num;
}
/**
* Returns true if we are currently inside of an undo/redo operation. This is
* useful for editors to know whether they should be generating new undo state
* when they see edit operations happening.
*/
public boolean isInUndo() {
return mInUndo;
}
public int forgetUndos(UndoOwner[] owners, int count) {
if (count < 0) {
count = mUndos.size();
}
int removed = 0;
int i = 0;
while (i < mUndos.size() && removed < count) {
UndoState state = mUndos.get(i);
if (count > 0 && matchOwners(state, owners)) {
state.destroy();
mUndos.remove(i);
removed++;
} else {
i++;
}
}
return removed;
}
public int forgetRedos(UndoOwner[] owners, int count) {
if (count < 0) {
count = mRedos.size();
}
int removed = 0;
int i = 0;
while (i < mRedos.size() && removed < count) {
UndoState state = mRedos.get(i);
if (count > 0 && matchOwners(state, owners)) {
state.destroy();
mRedos.remove(i);
removed++;
} else {
i++;
}
}
return removed;
}
/**
* Return the number of undo states on the undo stack.
* @param owners If non-null, only those states containing an operation with one of
* the owners supplied here will be counted.
*/
public int countUndos(UndoOwner[] owners) {
if (owners == null) {
return mUndos.size();
}
int count=0;
int i=0;
while ((i=findNextState(mUndos, owners, i)) >= 0) {
count++;
i++;
}
return count;
}
/**
* Return the number of redo states on the undo stack.
* @param owners If non-null, only those states containing an operation with one of
* the owners supplied here will be counted.
*/
public int countRedos(UndoOwner[] owners) {
if (owners == null) {
return mRedos.size();
}
int count=0;
int i=0;
while ((i=findNextState(mRedos, owners, i)) >= 0) {
count++;
i++;
}
return count;
}
/**
* Return the user-visible label for the top undo state on the stack.
* @param owners If non-null, will select the top-most undo state containing an
* operation with one of the owners supplied here.
*/
public CharSequence getUndoLabel(UndoOwner[] owners) {
UndoState state = getTopUndo(owners);
return state != null ? state.getLabel() : null;
}
/**
* Return the user-visible label for the top redo state on the stack.
* @param owners If non-null, will select the top-most undo state containing an
* operation with one of the owners supplied here.
*/
public CharSequence getRedoLabel(UndoOwner[] owners) {
UndoState state = getTopRedo(owners);
return state != null ? state.getLabel() : null;
}
/**
* Start creating a new undo state. Multiple calls to this function will nest until
* they are all matched by a later call to {@link #endUpdate}.
* @param label Optional user-visible label for this new undo state.
*/
public void beginUpdate(CharSequence label) {
if (mInUndo) {
throw new IllegalStateException("Can't being update while performing undo/redo");
}
if (mUpdateCount <= 0) {
createWorkingState();
mMerged = false;
mUpdateCount = 0;
}
mWorking.updateLabel(label);
mUpdateCount++;
}
private void createWorkingState() {
mWorking = new UndoState(this, mCommitId++);
if (mCommitId < 0) {
mCommitId = 1;
}
}
/**
* Returns true if currently inside of a {@link #beginUpdate}.
*/
public boolean isInUpdate() {
return mUpdateCount > 0;
}
/**
* Forcibly set a new for the new undo state being built within a {@link #beginUpdate}.
* Any existing label will be replaced with this one.
*/
public void setUndoLabel(CharSequence label) {
if (mWorking == null) {
throw new IllegalStateException("Must be called during an update");
}
mWorking.setLabel(label);
}
/**
* Set a new for the new undo state being built within a {@link #beginUpdate}, but
* only if there is not a label currently set for it.
*/
public void suggestUndoLabel(CharSequence label) {
if (mWorking == null) {
throw new IllegalStateException("Must be called during an update");
}
mWorking.updateLabel(label);
}
/**
* Return the number of times {@link #beginUpdate} has been called without a matching
* {@link #endUpdate} call.
*/
public int getUpdateNestingLevel() {
return mUpdateCount;
}
/**
* Check whether there is an {@link UndoOperation} in the current {@link #beginUpdate}
* undo state.
* @param owner Optional owner of the operation to look for. If null, will succeed
* if there is any operation; if non-null, will only succeed if there is an operation
* with the given owner.
* @return Returns true if there is a matching operation in the current undo state.
*/
public boolean hasOperation(UndoOwner owner) {
if (mWorking == null) {
throw new IllegalStateException("Must be called during an update");
}
return mWorking.hasOperation(owner);
}
/**
* Return the most recent {@link UndoOperation} that was added to the update.
* @param mergeMode May be either {@link #MERGE_MODE_NONE} or {@link #MERGE_MODE_ANY}.
*/
public UndoOperation> getLastOperation(int mergeMode) {
return getLastOperation(null, null, mergeMode);
}
/**
* Return the most recent {@link UndoOperation} that was added to the update and
* has the given owner.
* @param owner Optional owner of last operation to retrieve. If null, the last
* operation regardless of owner will be retrieved; if non-null, the last operation
* matching the given owner will be retrieved.
* @param mergeMode May be either {@link #MERGE_MODE_NONE}, {@link #MERGE_MODE_UNIQUE},
* or {@link #MERGE_MODE_ANY}.
*/
public UndoOperation> getLastOperation(UndoOwner owner, int mergeMode) {
return getLastOperation(null, owner, mergeMode);
}
/**
* Return the most recent {@link UndoOperation} that was added to the update and
* has the given owner.
* @param clazz Optional class of the last operation to retrieve. If null, the
* last operation regardless of class will be retrieved; if non-null, the last
* operation whose class is the same as the given class will be retrieved.
* @param owner Optional owner of last operation to retrieve. If null, the last
* operation regardless of owner will be retrieved; if non-null, the last operation
* matching the given owner will be retrieved.
* @param mergeMode May be either {@link #MERGE_MODE_NONE}, {@link #MERGE_MODE_UNIQUE},
* or {@link #MERGE_MODE_ANY}.
*/
public T getLastOperation(Class clazz, UndoOwner owner,
int mergeMode) {
if (mWorking == null) {
throw new IllegalStateException("Must be called during an update");
}
if (mergeMode != MERGE_MODE_NONE && !mMerged && !mWorking.hasData()) {
UndoState state = getTopUndo(null);
UndoOperation> last;
if (state != null && (mergeMode == MERGE_MODE_ANY || !state.hasMultipleOwners())
&& state.canMerge() && (last=state.getLastOperation(clazz, owner)) != null) {
if (last.allowMerge()) {
mWorking.destroy();
mWorking = state;
mUndos.remove(state);
mMerged = true;
return (T)last;
}
}
}
return mWorking.getLastOperation(clazz, owner);
}
/**
* Add a new UndoOperation to the current update.
* @param op The new operation to add.
* @param mergeMode May be either {@link #MERGE_MODE_NONE}, {@link #MERGE_MODE_UNIQUE},
* or {@link #MERGE_MODE_ANY}.
*/
public void addOperation(UndoOperation> op, int mergeMode) {
if (mWorking == null) {
throw new IllegalStateException("Must be called during an update");
}
UndoOwner owner = op.getOwner();
if (owner.mManager != this) {
throw new IllegalArgumentException(
"Given operation's owner is not in this undo manager.");
}
if (mergeMode != MERGE_MODE_NONE && !mMerged && !mWorking.hasData()) {
UndoState state = getTopUndo(null);
if (state != null && (mergeMode == MERGE_MODE_ANY || !state.hasMultipleOwners())
&& state.canMerge() && state.hasOperation(op.getOwner())) {
mWorking.destroy();
mWorking = state;
mUndos.remove(state);
mMerged = true;
}
}
mWorking.addOperation(op);
}
/**
* Finish the creation of an undo state, matching a previous call to
* {@link #beginUpdate}.
*/
public void endUpdate() {
if (mWorking == null) {
throw new IllegalStateException("Must be called during an update");
}
mUpdateCount--;
if (mUpdateCount == 0) {
pushWorkingState();
}
}
private void pushWorkingState() {
int N = mUndos.size() + 1;
if (mWorking.hasData()) {
mUndos.add(mWorking);
forgetRedos(null, -1);
mWorking.commit();
if (N >= 2) {
// The state before this one can no longer be merged, ever.
// The only way to get back to it is for the user to perform
// an undo.
mUndos.get(N-2).makeExecuted();
}
} else {
mWorking.destroy();
}
mWorking = null;
if (mHistorySize >= 0 && N > mHistorySize) {
forgetUndos(null, N - mHistorySize);
}
}
/**
* Commit the last finished undo state. This undo state can no longer be
* modified with further {@link #MERGE_MODE_UNIQUE} or
* {@link #MERGE_MODE_ANY} merge modes. If called while inside of an update,
* this will push any changes in the current update on to the undo stack
* and result with a fresh undo state, behaving as if {@link #endUpdate()}
* had been called enough to unwind the current update, then the last state
* committed, and {@link #beginUpdate} called to restore the update nesting.
* @param owner The optional owner to determine whether to perform the commit.
* If this is non-null, the commit will only execute if the current top undo
* state contains an operation with the given owner.
* @return Returns an integer identifier for the committed undo state, which
* can later be used to try to uncommit the state to perform further edits on it.
*/
public int commitState(UndoOwner owner) {
if (mWorking != null && mWorking.hasData()) {
if (owner == null || mWorking.hasOperation(owner)) {
mWorking.setCanMerge(false);
int commitId = mWorking.getCommitId();
pushWorkingState();
createWorkingState();
mMerged = true;
return commitId;
}
} else {
UndoState state = getTopUndo(null);
if (state != null && (owner == null || state.hasOperation(owner))) {
state.setCanMerge(false);
return state.getCommitId();
}
}
return -1;
}
/**
* Attempt to undo a previous call to {@link #commitState}. This will work
* if the undo state at the top of the stack has the given id, and has not been
* involved in an undo operation. Otherwise false is returned.
* @param commitId The identifier for the state to be uncommitted, as returned
* by {@link #commitState}.
* @param owner Optional owner that must appear in the committed state.
* @return Returns true if the uncommit is successful, else false.
*/
public boolean uncommitState(int commitId, UndoOwner owner) {
if (mWorking != null && mWorking.getCommitId() == commitId) {
if (owner == null || mWorking.hasOperation(owner)) {
return mWorking.setCanMerge(true);
}
} else {
UndoState state = getTopUndo(null);
if (state != null && (owner == null || state.hasOperation(owner))) {
if (state.getCommitId() == commitId) {
return state.setCanMerge(true);
}
}
}
return false;
}
UndoState getTopUndo(UndoOwner[] owners) {
if (mUndos.size() <= 0) {
return null;
}
int i = findPrevState(mUndos, owners, -1);
return i >= 0 ? mUndos.get(i) : null;
}
UndoState getTopRedo(UndoOwner[] owners) {
if (mRedos.size() <= 0) {
return null;
}
int i = findPrevState(mRedos, owners, -1);
return i >= 0 ? mRedos.get(i) : null;
}
boolean matchOwners(UndoState state, UndoOwner[] owners) {
if (owners == null) {
return true;
}
for (int i=0; i states, UndoOwner[] owners, int from) {
final int N = states.size();
if (from == -1) {
from = N-1;
}
if (from >= N) {
return -1;
}
if (owners == null) {
return from;
}
while (from >= 0) {
UndoState state = states.get(from);
if (matchOwners(state, owners)) {
return from;
}
from--;
}
return -1;
}
int findNextState(ArrayList states, UndoOwner[] owners, int from) {
final int N = states.size();
if (from < 0) {
from = 0;
}
if (from >= N) {
return -1;
}
if (owners == null) {
return from;
}
while (from < N) {
UndoState state = states.get(from);
if (matchOwners(state, owners)) {
return from;
}
from++;
}
return -1;
}
final static class UndoState {
private final UndoManager mManager;
private final int mCommitId;
private final ArrayList> mOperations = new ArrayList>();
private ArrayList> mRecent;
private CharSequence mLabel;
private boolean mCanMerge = true;
private boolean mExecuted;
UndoState(UndoManager manager, int commitId) {
mManager = manager;
mCommitId = commitId;
}
UndoState(UndoManager manager, Parcel p, ClassLoader loader) {
mManager = manager;
mCommitId = p.readInt();
mCanMerge = p.readInt() != 0;
mExecuted = p.readInt() != 0;
mLabel = TextUtils.CHAR_SEQUENCE_CREATOR.createFromParcel(p);
final int N = p.readInt();
for (int i=0; i op) {
if (mOperations.contains(op)) {
throw new IllegalStateException("Already holds " + op);
}
mOperations.add(op);
if (mRecent == null) {
mRecent = new ArrayList>();
mRecent.add(op);
}
op.mOwner.mOpCount++;
}
T getLastOperation(Class clazz, UndoOwner owner) {
final int N = mOperations.size();
if (clazz == null && owner == null) {
return N > 0 ? (T)mOperations.get(N-1) : null;
}
// First look for the top-most operation with the same owner.
for (int i=N-1; i>=0; i--) {
UndoOperation> op = mOperations.get(i);
if (owner != null && op.getOwner() != owner) {
continue;
}
// Return this operation if it has the same class that the caller wants.
// Note that we don't search deeper for the class, because we don't want
// to end up with a different order of operations for the same owner.
if (clazz != null && op.getClass() != clazz) {
return null;
}
return (T)op;
}
return null;
}
boolean matchOwner(UndoOwner owner) {
for (int i=mOperations.size()-1; i>=0; i--) {
if (mOperations.get(i).matchOwner(owner)) {
return true;
}
}
return false;
}
boolean hasData() {
for (int i=mOperations.size()-1; i>=0; i--) {
if (mOperations.get(i).hasData()) {
return true;
}
}
return false;
}
void commit() {
final int N = mRecent != null ? mRecent.size() : 0;
for (int i=0; i=0; i--) {
mOperations.get(i).undo();
}
}
void redo() {
final int N = mOperations.size();
for (int i=0; i=0; i--) {
UndoOwner owner = mOperations.get(i).mOwner;
owner.mOpCount--;
if (owner.mOpCount <= 0) {
if (owner.mOpCount < 0) {
throw new IllegalStateException("Underflow of op count on owner " + owner
+ " in op " + mOperations.get(i));
}
mManager.removeOwner(owner);
}
}
}
}
}