/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "mozilla/Assertions.h" #include "mozilla/mozalloc.h" #include "nsAutoPtr.h" #include "nsCOMPtr.h" #include "nsDebug.h" #include "nsError.h" #include "nsISupportsBase.h" #include "nsISupportsUtils.h" #include "nsITransaction.h" #include "nsITransactionList.h" #include "nsITransactionListener.h" #include "nsIWeakReference.h" #include "nsTransactionItem.h" #include "nsTransactionList.h" #include "nsTransactionManager.h" #include "nsTransactionStack.h" nsTransactionManager::nsTransactionManager(PRInt32 aMaxTransactionCount) : mMaxTransactionCount(aMaxTransactionCount) , mDoStack(nsTransactionStack::FOR_UNDO) , mUndoStack(nsTransactionStack::FOR_UNDO) , mRedoStack(nsTransactionStack::FOR_REDO) { } nsTransactionManager::~nsTransactionManager() { } NS_IMPL_CYCLE_COLLECTION_CLASS(nsTransactionManager) NS_IMPL_CYCLE_COLLECTION_UNLINK_BEGIN(nsTransactionManager) NS_IMPL_CYCLE_COLLECTION_UNLINK_NSCOMARRAY(mListeners) tmp->mDoStack.DoUnlink(); tmp->mUndoStack.DoUnlink(); tmp->mRedoStack.DoUnlink(); NS_IMPL_CYCLE_COLLECTION_UNLINK_END NS_IMPL_CYCLE_COLLECTION_TRAVERSE_BEGIN(nsTransactionManager) NS_IMPL_CYCLE_COLLECTION_TRAVERSE_NSCOMARRAY(mListeners) tmp->mDoStack.DoTraverse(cb); tmp->mUndoStack.DoTraverse(cb); tmp->mRedoStack.DoTraverse(cb); NS_IMPL_CYCLE_COLLECTION_TRAVERSE_END NS_INTERFACE_MAP_BEGIN_CYCLE_COLLECTION(nsTransactionManager) NS_INTERFACE_MAP_ENTRY(nsITransactionManager) NS_INTERFACE_MAP_ENTRY(nsISupportsWeakReference) NS_INTERFACE_MAP_ENTRY_AMBIGUOUS(nsISupports, nsITransactionManager) NS_INTERFACE_MAP_END NS_IMPL_CYCLE_COLLECTING_ADDREF(nsTransactionManager) NS_IMPL_CYCLE_COLLECTING_RELEASE(nsTransactionManager) NS_IMETHODIMP nsTransactionManager::DoTransaction(nsITransaction *aTransaction) { nsresult result; NS_ENSURE_TRUE(aTransaction, NS_ERROR_NULL_POINTER); bool doInterrupt = false; result = WillDoNotify(aTransaction, &doInterrupt); if (NS_FAILED(result)) { return result; } if (doInterrupt) { return NS_OK; } result = BeginTransaction(aTransaction); if (NS_FAILED(result)) { DidDoNotify(aTransaction, result); return result; } result = EndTransaction(); nsresult result2 = DidDoNotify(aTransaction, result); if (NS_SUCCEEDED(result)) result = result2; return result; } NS_IMETHODIMP nsTransactionManager::UndoTransaction() { nsresult result = NS_OK; // It is illegal to call UndoTransaction() while the transaction manager is // executing a transaction's DoTransaction() method! If this happens, // the UndoTransaction() request is ignored, and we return NS_ERROR_FAILURE. nsRefPtr tx = mDoStack.Peek(); if (tx) { return NS_ERROR_FAILURE; } // Peek at the top of the undo stack. Don't remove the transaction // until it has successfully completed. tx = mUndoStack.Peek(); // Bail if there's nothing on the stack. if (!tx) { return NS_OK; } nsCOMPtr t = tx->GetTransaction(); bool doInterrupt = false; result = WillUndoNotify(t, &doInterrupt); if (NS_FAILED(result)) { return result; } if (doInterrupt) { return NS_OK; } result = tx->UndoTransaction(this); if (NS_SUCCEEDED(result)) { tx = mUndoStack.Pop(); mRedoStack.Push(tx); } nsresult result2 = DidUndoNotify(t, result); if (NS_SUCCEEDED(result)) result = result2; return result; } NS_IMETHODIMP nsTransactionManager::RedoTransaction() { nsresult result = NS_OK; // It is illegal to call RedoTransaction() while the transaction manager is // executing a transaction's DoTransaction() method! If this happens, // the RedoTransaction() request is ignored, and we return NS_ERROR_FAILURE. nsRefPtr tx = mDoStack.Peek(); if (tx) { return NS_ERROR_FAILURE; } // Peek at the top of the redo stack. Don't remove the transaction // until it has successfully completed. tx = mRedoStack.Peek(); // Bail if there's nothing on the stack. if (!tx) { return NS_OK; } nsCOMPtr t = tx->GetTransaction(); bool doInterrupt = false; result = WillRedoNotify(t, &doInterrupt); if (NS_FAILED(result)) { return result; } if (doInterrupt) { return NS_OK; } result = tx->RedoTransaction(this); if (NS_SUCCEEDED(result)) { tx = mRedoStack.Pop(); mUndoStack.Push(tx); } nsresult result2 = DidRedoNotify(t, result); if (NS_SUCCEEDED(result)) result = result2; return result; } NS_IMETHODIMP nsTransactionManager::Clear() { nsresult result; result = ClearRedoStack(); if (NS_FAILED(result)) { return result; } result = ClearUndoStack(); return result; } NS_IMETHODIMP nsTransactionManager::BeginBatch() { nsresult result; // We can batch independent transactions together by simply pushing // a dummy transaction item on the do stack. This dummy transaction item // will be popped off the do stack, and then pushed on the undo stack // in EndBatch(). bool doInterrupt = false; result = WillBeginBatchNotify(&doInterrupt); if (NS_FAILED(result)) { return result; } if (doInterrupt) { return NS_OK; } result = BeginTransaction(0); nsresult result2 = DidBeginBatchNotify(result); if (NS_SUCCEEDED(result)) result = result2; return result; } NS_IMETHODIMP nsTransactionManager::EndBatch() { nsCOMPtr ti; nsresult result; // XXX: Need to add some mechanism to detect the case where the transaction // at the top of the do stack isn't the dummy transaction, so we can // throw an error!! This can happen if someone calls EndBatch() within // the DoTransaction() method of a transaction. // // For now, we can detect this case by checking the value of the // dummy transaction's mTransaction field. If it is our dummy // transaction, it should be NULL. This may not be true in the // future when we allow users to execute a transaction when beginning // a batch!!!! nsRefPtr tx = mDoStack.Peek(); if (tx) { ti = tx->GetTransaction(); } if (!tx || ti) { return NS_ERROR_FAILURE; } bool doInterrupt = false; result = WillEndBatchNotify(&doInterrupt); if (NS_FAILED(result)) { return result; } if (doInterrupt) { return NS_OK; } result = EndTransaction(); nsresult result2 = DidEndBatchNotify(result); if (NS_SUCCEEDED(result)) result = result2; return result; } NS_IMETHODIMP nsTransactionManager::GetNumberOfUndoItems(PRInt32 *aNumItems) { *aNumItems = mUndoStack.GetSize(); return NS_OK; } NS_IMETHODIMP nsTransactionManager::GetNumberOfRedoItems(PRInt32 *aNumItems) { *aNumItems = mRedoStack.GetSize(); return NS_OK; } NS_IMETHODIMP nsTransactionManager::GetMaxTransactionCount(PRInt32 *aMaxCount) { NS_ENSURE_TRUE(aMaxCount, NS_ERROR_NULL_POINTER); *aMaxCount = mMaxTransactionCount; return NS_OK; } NS_IMETHODIMP nsTransactionManager::SetMaxTransactionCount(PRInt32 aMaxCount) { PRInt32 numUndoItems = 0, numRedoItems = 0, total = 0; // It is illegal to call SetMaxTransactionCount() while the transaction // manager is executing a transaction's DoTransaction() method because // the undo and redo stacks might get pruned! If this happens, the // SetMaxTransactionCount() request is ignored, and we return // NS_ERROR_FAILURE. nsRefPtr tx = mDoStack.Peek(); if (tx) { return NS_ERROR_FAILURE; } // If aMaxCount is less than zero, the user wants unlimited // levels of undo! No need to prune the undo or redo stacks! if (aMaxCount < 0) { mMaxTransactionCount = -1; return NS_OK; } numUndoItems = mUndoStack.GetSize(); numRedoItems = mRedoStack.GetSize(); total = numUndoItems + numRedoItems; // If aMaxCount is greater than the number of transactions that currently // exist on the undo and redo stack, there is no need to prune the // undo or redo stacks! if (aMaxCount > total ) { mMaxTransactionCount = aMaxCount; return NS_OK; } // Try getting rid of some transactions on the undo stack! Start at // the bottom of the stack and pop towards the top. while (numUndoItems > 0 && (numRedoItems + numUndoItems) > aMaxCount) { tx = mUndoStack.PopBottom(); if (!tx) { return NS_ERROR_FAILURE; } --numUndoItems; } // If necessary, get rid of some transactions on the redo stack! Start at // the bottom of the stack and pop towards the top. while (numRedoItems > 0 && (numRedoItems + numUndoItems) > aMaxCount) { tx = mRedoStack.PopBottom(); if (!tx) { return NS_ERROR_FAILURE; } --numRedoItems; } mMaxTransactionCount = aMaxCount; return NS_OK; } NS_IMETHODIMP nsTransactionManager::PeekUndoStack(nsITransaction **aTransaction) { MOZ_ASSERT(aTransaction); *aTransaction = PeekUndoStack().get(); return NS_OK; } already_AddRefed nsTransactionManager::PeekUndoStack() { nsRefPtr tx = mUndoStack.Peek(); if (!tx) { return nullptr; } return tx->GetTransaction(); } NS_IMETHODIMP nsTransactionManager::PeekRedoStack(nsITransaction** aTransaction) { MOZ_ASSERT(aTransaction); *aTransaction = PeekRedoStack().get(); return NS_OK; } already_AddRefed nsTransactionManager::PeekRedoStack() { nsRefPtr tx = mRedoStack.Peek(); if (!tx) { return nullptr; } return tx->GetTransaction(); } NS_IMETHODIMP nsTransactionManager::GetUndoList(nsITransactionList **aTransactionList) { NS_ENSURE_TRUE(aTransactionList, NS_ERROR_NULL_POINTER); *aTransactionList = (nsITransactionList *)new nsTransactionList(this, &mUndoStack); NS_IF_ADDREF(*aTransactionList); return (! *aTransactionList) ? NS_ERROR_OUT_OF_MEMORY : NS_OK; } NS_IMETHODIMP nsTransactionManager::GetRedoList(nsITransactionList **aTransactionList) { NS_ENSURE_TRUE(aTransactionList, NS_ERROR_NULL_POINTER); *aTransactionList = (nsITransactionList *)new nsTransactionList(this, &mRedoStack); NS_IF_ADDREF(*aTransactionList); return (! *aTransactionList) ? NS_ERROR_OUT_OF_MEMORY : NS_OK; } NS_IMETHODIMP nsTransactionManager::AddListener(nsITransactionListener *aListener) { NS_ENSURE_TRUE(aListener, NS_ERROR_NULL_POINTER); return mListeners.AppendObject(aListener) ? NS_OK : NS_ERROR_FAILURE; } NS_IMETHODIMP nsTransactionManager::RemoveListener(nsITransactionListener *aListener) { NS_ENSURE_TRUE(aListener, NS_ERROR_NULL_POINTER); return mListeners.RemoveObject(aListener) ? NS_OK : NS_ERROR_FAILURE; } nsresult nsTransactionManager::ClearUndoStack() { mUndoStack.Clear(); return NS_OK; } nsresult nsTransactionManager::ClearRedoStack() { mRedoStack.Clear(); return NS_OK; } nsresult nsTransactionManager::WillDoNotify(nsITransaction *aTransaction, bool *aInterrupt) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->WillDo(this, aTransaction, aInterrupt); if (NS_FAILED(result) || *aInterrupt) break; } return result; } nsresult nsTransactionManager::DidDoNotify(nsITransaction *aTransaction, nsresult aDoResult) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->DidDo(this, aTransaction, aDoResult); if (NS_FAILED(result)) break; } return result; } nsresult nsTransactionManager::WillUndoNotify(nsITransaction *aTransaction, bool *aInterrupt) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->WillUndo(this, aTransaction, aInterrupt); if (NS_FAILED(result) || *aInterrupt) break; } return result; } nsresult nsTransactionManager::DidUndoNotify(nsITransaction *aTransaction, nsresult aUndoResult) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->DidUndo(this, aTransaction, aUndoResult); if (NS_FAILED(result)) break; } return result; } nsresult nsTransactionManager::WillRedoNotify(nsITransaction *aTransaction, bool *aInterrupt) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->WillRedo(this, aTransaction, aInterrupt); if (NS_FAILED(result) || *aInterrupt) break; } return result; } nsresult nsTransactionManager::DidRedoNotify(nsITransaction *aTransaction, nsresult aRedoResult) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->DidRedo(this, aTransaction, aRedoResult); if (NS_FAILED(result)) break; } return result; } nsresult nsTransactionManager::WillBeginBatchNotify(bool *aInterrupt) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->WillBeginBatch(this, aInterrupt); if (NS_FAILED(result) || *aInterrupt) break; } return result; } nsresult nsTransactionManager::DidBeginBatchNotify(nsresult aResult) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->DidBeginBatch(this, aResult); if (NS_FAILED(result)) break; } return result; } nsresult nsTransactionManager::WillEndBatchNotify(bool *aInterrupt) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->WillEndBatch(this, aInterrupt); if (NS_FAILED(result) || *aInterrupt) break; } return result; } nsresult nsTransactionManager::DidEndBatchNotify(nsresult aResult) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->DidEndBatch(this, aResult); if (NS_FAILED(result)) break; } return result; } nsresult nsTransactionManager::WillMergeNotify(nsITransaction *aTop, nsITransaction *aTransaction, bool *aInterrupt) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->WillMerge(this, aTop, aTransaction, aInterrupt); if (NS_FAILED(result) || *aInterrupt) break; } return result; } nsresult nsTransactionManager::DidMergeNotify(nsITransaction *aTop, nsITransaction *aTransaction, bool aDidMerge, nsresult aMergeResult) { nsresult result = NS_OK; for (PRInt32 i = 0, lcount = mListeners.Count(); i < lcount; i++) { nsITransactionListener *listener = mListeners[i]; NS_ENSURE_TRUE(listener, NS_ERROR_FAILURE); result = listener->DidMerge(this, aTop, aTransaction, aDidMerge, aMergeResult); if (NS_FAILED(result)) break; } return result; } nsresult nsTransactionManager::BeginTransaction(nsITransaction *aTransaction) { nsresult result = NS_OK; // XXX: POSSIBLE OPTIMIZATION // We could use a factory that pre-allocates/recycles transaction items. nsRefPtr tx = new nsTransactionItem(aTransaction); if (!tx) { return NS_ERROR_OUT_OF_MEMORY; } mDoStack.Push(tx); result = tx->DoTransaction(); if (NS_FAILED(result)) { tx = mDoStack.Pop(); return result; } return NS_OK; } nsresult nsTransactionManager::EndTransaction() { nsresult result = NS_OK; nsRefPtr tx = mDoStack.Pop(); if (!tx) return NS_ERROR_FAILURE; nsCOMPtr tint = tx->GetTransaction(); if (!tint) { PRInt32 nc = 0; // If we get here, the transaction must be a dummy batch transaction // created by BeginBatch(). If it contains no children, get rid of it! tx->GetNumberOfChildren(&nc); if (!nc) { return result; } } // Check if the transaction is transient. If it is, there's nothing // more to do, just return. bool isTransient = false; if (tint) result = tint->GetIsTransient(&isTransient); if (NS_FAILED(result) || isTransient || !mMaxTransactionCount) { // XXX: Should we be clearing the redo stack if the transaction // is transient and there is nothing on the do stack? return result; } // Check if there is a transaction on the do stack. If there is, // the current transaction is a "sub" transaction, and should // be added to the transaction at the top of the do stack. nsRefPtr top = mDoStack.Peek(); if (top) { result = top->AddChild(tx); // XXX: What do we do if this fails? return result; } // The transaction succeeded, so clear the redo stack. result = ClearRedoStack(); if (NS_FAILED(result)) { // XXX: What do we do if this fails? } // Check if we can coalesce this transaction with the one at the top // of the undo stack. top = mUndoStack.Peek(); if (tint && top) { bool didMerge = false; nsCOMPtr topTransaction = top->GetTransaction(); if (topTransaction) { bool doInterrupt = false; result = WillMergeNotify(topTransaction, tint, &doInterrupt); NS_ENSURE_SUCCESS(result, result); if (!doInterrupt) { result = topTransaction->Merge(tint, &didMerge); nsresult result2 = DidMergeNotify(topTransaction, tint, didMerge, result); if (NS_SUCCEEDED(result)) result = result2; if (NS_FAILED(result)) { // XXX: What do we do if this fails? } if (didMerge) { return result; } } } } // Check to see if we've hit the max level of undo. If so, // pop the bottom transaction off the undo stack and release it! PRInt32 sz = mUndoStack.GetSize(); if (mMaxTransactionCount > 0 && sz >= mMaxTransactionCount) { nsRefPtr overflow = mUndoStack.PopBottom(); } // Push the transaction on the undo stack: mUndoStack.Push(tx); return NS_OK; }