/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* 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/. */ #ifndef nsTreeRows_h__ #define nsTreeRows_h__ #include "nsCOMPtr.h" #include "nsTArray.h" #include "PLDHashTable.h" #include "nsIXULTemplateResult.h" #include "nsTemplateMatch.h" #include "nsIRDFResource.h" /** * This class maintains the state of the XUL tree builder's * rows. It maps a row number to the nsTemplateMatch object that * populates the row. */ class nsTreeRows { public: class iterator; friend class iterator; enum Direction { eDirection_Forwards = +1, eDirection_Backwards = -1 }; enum ContainerType { eContainerType_Unknown = 0, eContainerType_Noncontainer = 1, eContainerType_Container = 2 }; enum ContainerState { eContainerState_Unknown = 0, eContainerState_Open = 1, eContainerState_Closed = 2 }; enum ContainerFill { eContainerFill_Unknown = 0, eContainerFill_Empty = 1, eContainerFill_Nonempty = 2 }; class Subtree; /** * A row in the tree. Contains the match that the row * corresponds to, and a pointer to the row's subtree, if there * are any. */ struct Row { nsTemplateMatch* mMatch; ContainerType mContainerType : 4; ContainerState mContainerState : 4; ContainerFill mContainerFill : 4; Subtree* mSubtree; // XXX eventually move to hashtable }; /** * A subtree in the tree. A subtree contains rows, which may * contain other subtrees. */ class Subtree { protected: friend class nsTreeRows; // so that it can access members, for now /** * The parent subtree; null if we're the root */ Subtree* mParent; /** * The number of immediate children in this subtree */ int32_t mCount; /** * The capacity of the subtree */ int32_t mCapacity; /** * The total number of rows in this subtree, recursively * including child subtrees. */ int32_t mSubtreeSize; /** * The array of rows in the subtree */ Row* mRows; public: /** * Creates a subtree with the specified parent. */ explicit Subtree(Subtree* aParent) : mParent(aParent), mCount(0), mCapacity(0), mSubtreeSize(0), mRows(nullptr) {} ~Subtree(); /** * Return the number of immediate child rows in the subtree */ int32_t Count() const { return mCount; } /** * Return the number of rows in this subtree, as well as all * the subtrees it contains. */ int32_t GetSubtreeSize() const { return mSubtreeSize; } /** * Retrieve the immediate child row at the specified index. */ const Row& operator[](int32_t aIndex) const { NS_PRECONDITION(aIndex >= 0 && aIndex < mCount, "bad index"); return mRows[aIndex]; } /** * Retrieve the immediate row at the specified index. */ Row& operator[](int32_t aIndex) { NS_PRECONDITION(aIndex >= 0 && aIndex < mCount, "bad index"); return mRows[aIndex]; } /** * Remove all rows from the subtree. */ void Clear(); protected: /** * Insert an immediate child row at the specified index. */ iterator InsertRowAt(nsTemplateMatch* aMatch, int32_t aIndex); /** * Remove an immediate child row from the specified index. */ void RemoveRowAt(int32_t aChildIndex); }; friend class Subtree; protected: /** * A link in the path through the view's tree. */ struct Link { Subtree* mParent; int32_t mChildIndex; Link& operator=(const Link& aLink) { mParent = aLink.mParent; mChildIndex = aLink.mChildIndex; return *this; } bool operator==(const Link& aLink) const { return (mParent == aLink.mParent) && (mChildIndex == aLink.mChildIndex); } Subtree* GetParent() { return mParent; } const Subtree* GetParent() const { return mParent; } int32_t GetChildIndex() const { return mChildIndex; } Row& GetRow() { return (*mParent)[mChildIndex]; } const Row& GetRow() const { return (*mParent)[mChildIndex]; } }; public: /** * An iterator that can be used to traverse the tree view. */ class iterator { protected: int32_t mRowIndex; AutoTArray mLink; void Next(); void Prev(); friend class Subtree; // so InsertRowAt can initialize us friend class nsTreeRows; // so nsTreeRows can initialize us /** * Used by operator[]() to initialize an iterator. */ void Append(Subtree* aParent, int32_t aChildIndex); /** * Used by InsertRowAt() to initialize an iterator. */ void Push(Subtree *aParent, int32_t aChildIndex); /** * Used by operator[]() and InsertRowAt() to initialize an iterator. */ void SetRowIndex(int32_t aRowIndex) { mRowIndex = aRowIndex; } /** * Handy accessors to the top element. */ Link& GetTop() { return mLink[mLink.Length() - 1]; } const Link& GetTop() const { return mLink[mLink.Length() - 1]; } public: iterator() : mRowIndex(-1) {} iterator(const iterator& aIterator); iterator& operator=(const iterator& aIterator); bool operator==(const iterator& aIterator) const; bool operator!=(const iterator& aIterator) const { return !aIterator.operator==(*this); } const Row& operator*() const { return GetTop().GetRow(); } Row& operator*() { return GetTop().GetRow(); } const Row* operator->() const { return &(GetTop().GetRow()); } Row* operator->() { return &(GetTop().GetRow()); } iterator& operator++() { Next(); return *this; } iterator operator++(int) { iterator temp(*this); Next(); return temp; } iterator& operator--() { Prev(); return *this; } iterator operator--(int) { iterator temp(*this); Prev(); return temp; } /** * Return the current parent link */ Subtree* GetParent() { return GetTop().GetParent(); } const Subtree* GetParent() const { return GetTop().GetParent(); } /** * Return the current child index */ int32_t GetChildIndex() const { return GetTop().GetChildIndex(); } /** * Return the depth of the path the iterator is maintaining * into the tree. */ int32_t GetDepth() const { return mLink.Length(); } /** * Return the current row index of the iterator */ int32_t GetRowIndex() const { return mRowIndex; } /** * Pop the iterator up a level. */ iterator& Pop() { mLink.SetLength(GetDepth() - 1); return *this; } }; /** * Retrieve the first element in the view */ iterator First(); /** * Retrieve (one past) the last element in the view */ iterator Last(); /** * Find the row that contains the given resource */ iterator FindByResource(nsIRDFResource* aResource); /** * Find the row that contains the result */ iterator Find(nsIXULTemplateResult* aResult); /** * Retrieve the ith element in the view */ iterator operator[](int32_t aIndex); nsTreeRows() : mRoot(nullptr) {} ~nsTreeRows() {} /** * Ensure that a child subtree exists within the specified parent * at the specified child index within the parent. (In other * words, create a subtree if one doesn't already exist.) */ Subtree* EnsureSubtreeFor(Subtree* aParent, int32_t aChildIndex); /** * Ensure that a child subtree exists at the iterator's position. */ Subtree* EnsureSubtreeFor(iterator& aIterator) { return EnsureSubtreeFor(aIterator.GetParent(), aIterator.GetChildIndex()); } /** * Get the child subtree for the specified parent at the specified * child index. Optionally return the child subtree's size. Will * return `null' if no subtree exists. */ Subtree* GetSubtreeFor(const Subtree* aParent, int32_t aChildIndex, int32_t* aSubtreeSize = nullptr); /** * Retrieve the size of the subtree within the specified parent. */ int32_t GetSubtreeSizeFor(const Subtree* aParent, int32_t aChildIndex) { int32_t size; GetSubtreeFor(aParent, aChildIndex, &size); return size; } /** * Retrieve the size of the subtree within the specified parent. */ int32_t GetSubtreeSizeFor(const iterator& aIterator) { int32_t size; GetSubtreeFor(aIterator.GetParent(), aIterator.GetChildIndex(), &size); return size; } /** * Remove the specified subtree for a row, leaving the row itself * intact. */ void RemoveSubtreeFor(Subtree* aParent, int32_t aChildIndex); /** * Remove the specified subtree for a row, leaving the row itself * intact. */ void RemoveSubtreeFor(iterator& aIterator) { RemoveSubtreeFor(aIterator.GetParent(), aIterator.GetChildIndex()); } /** * Remove the specified row from the view */ int32_t RemoveRowAt(iterator& aIterator) { iterator temp = aIterator--; Subtree* parent = temp.GetParent(); parent->RemoveRowAt(temp.GetChildIndex()); InvalidateCachedRow(); return parent->Count(); } /** * Insert a new match into the view */ iterator InsertRowAt(nsTemplateMatch* aMatch, Subtree* aSubtree, int32_t aChildIndex) { InvalidateCachedRow(); return aSubtree->InsertRowAt(aMatch, aChildIndex); } /** * Raw access to the rows; e.g., for sorting. */ Row* GetRowsFor(Subtree* aSubtree) { return aSubtree->mRows; } /** * Remove all of the rows */ void Clear(); /** * Return the total number of rows in the tree view. */ int32_t Count() const { return mRoot.GetSubtreeSize(); } /** * Retrieve the root subtree */ Subtree* GetRoot() { return &mRoot; } /** * Set the root resource for the view */ void SetRootResource(nsIRDFResource* aResource) { mRootResource = aResource; } /** * Retrieve the root resource for the view */ nsIRDFResource* GetRootResource() { return mRootResource.get(); } /** * Invalidate the cached row; e.g., because the view has changed * in a way that would corrupt the iterator. */ void InvalidateCachedRow() { mLastRow = iterator(); } protected: /** * The root subtree. */ Subtree mRoot; /** * The root resource for the view */ nsCOMPtr mRootResource; /** * The last row that was asked for by operator[]. By remembering * this, we can usually avoid the O(n) search through the row * array to find the row at the specified index. */ iterator mLastRow; }; #endif // nsTreeRows_h__