views/view.h

// Copyright (c) 2006-2008 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.

#ifndef VIEWS_VIEW_H_
#define VIEWS_VIEW_H_

#include "build/build_config.h"

#include <algorithm>
#include <map>
#include <set>
#include <string>
#include <vector>

#include "app/gfx/native_widget_types.h"
#include "app/os_exchange_data.h"
#include "base/gfx/rect.h"
#include "base/scoped_ptr.h"
#include "views/accelerator.h"
#include "views/accessibility/accessibility_types.h"
#include "views/background.h"
#include "views/border.h"

namespace gfx {
class Canvas;
class Insets;
class Path;
}

class ViewAccessibilityWrapper;
class ThemeProvider;

namespace views {

class Background;
class Border;
class FocusManager;
class FocusTraversable;
class LayoutManager;
class RestoreFocusTask;
class RootView;
class ScrollView;
class Widget;
class Window;

// ContextMenuController is responsible for showing the context menu for a
// View. To use a ContextMenuController invoke SetContextMenuController on a
// View. When the appropriate user gesture occurs ShowContextMenu is invoked
// on the ContextMenuController.
//
// Setting a ContextMenuController on a view makes the view process mouse
// events.
//
// It is up to subclasses that do their own mouse processing to invoke
// the appropriate ContextMenuController method, typically by invoking super's
// implementation for mouse processing.
//
class ContextMenuController {
 public:
  // Invoked to show the context menu for the source view. If is_mouse_gesture
  // is true, the x/y coordinate are the location of the mouse. If
  // is_mouse_gesture is false, this method was not invoked by a mouse gesture
  // and x/y is the recommended location to show the menu at.
  //
  // x/y is in screen coordinates.
  virtual void ShowContextMenu(View* source,
                               int x,
                               int y,
                               bool is_mouse_gesture) = 0;
};

// DragController is responsible for writing drag data for a view, as well as
// supplying the supported drag operations. Use DragController if you don't
// want to subclass.

class DragController {
 public:
  // Writes the data for the drag.
  virtual void WriteDragData(View* sender,
                             int press_x,
                             int press_y,
                             OSExchangeData* data) = 0;

  // Returns the supported drag operations (see DragDropTypes for possible
  // values). A drag is only started if this returns a non-zero value.
  virtual int GetDragOperations(View* sender, int x, int y) = 0;

  // Returns true if a drag operation can be started.
  // |press_x| and |press_y| represent coordinates where mouse was initially
  // pressed down. |x| and |y| are the current mouse coordinates.
  virtual bool CanStartDrag(View* sender,
                            int press_x,
                            int press_y,
                            int x,
                            int y) = 0;
};

/////////////////////////////////////////////////////////////////////////////
//
// View class
//
//   A View is a rectangle within the views View hierarchy. It is the base
//   class for all Views.
//
//   A View is a container of other Views (there is no such thing as a Leaf
//   View - makes code simpler, reduces type conversion headaches, design
//   mistakes etc)
//
//   The View contains basic properties for sizing (bounds), layout (flex,
//   orientation, etc), painting of children and event dispatch.
//
//   The View also uses a simple Box Layout Manager similar to XUL's
//   SprocketLayout system. Alternative Layout Managers implementing the
//   LayoutManager interface can be used to lay out children if required.
//
//   It is up to the subclass to implement Painting and storage of subclass -
//   specific properties and functionality.
//
/////////////////////////////////////////////////////////////////////////////
class View : public AcceleratorTarget {
 public:
  // Used in the versions of GetBounds() and x() that take a transformation
  // parameter in order to determine whether or not to take into account the
  // mirroring setting of the View when returning bounds positions.
  enum PositionMirroringSettings {
    IGNORE_MIRRORING_TRANSFORMATION = 0,
    APPLY_MIRRORING_TRANSFORMATION
  };

  // The view class name.
  static char kViewClassName[];

  View();
  virtual ~View();

  // Returns the amount of time between double clicks, in milliseconds.
  static int GetDoubleClickTimeMS();

  // Sizing functions

  // Get the bounds of the View, relative to the parent. Essentially, this
  // function returns the bounds_ rectangle.
  //
  // This is the function subclasses should use whenever they need to obtain
  // the bounds of one of their child views (for example, when implementing
  // View::Layout()).
  const gfx::Rect& bounds() const { return bounds_; }

  // Get the size of the View.
  const gfx::Size& size() const { return bounds_.size(); }

  // Return the bounds of the View, relative to the parent. If
  // |settings| is IGNORE_MIRRORING_TRANSFORMATION, the function returns the
  // bounds_ rectangle. If |settings| is APPLY_MIRRORING_TRANSFORMATION AND the
  // parent View is using a right-to-left UI layout, then the function returns
  // a shifted version of the bounds_ rectangle that represents the mirrored
  // View bounds.
  //
  // NOTE: in the vast majority of the cases, the mirroring implementation is
  //       transparent to the View subclasses and therefore you should use the
  //       version of GetBounds() which does not take a transformation settings
  //       parameter.
  gfx::Rect GetBounds(PositionMirroringSettings settings) const;

  // Set the bounds in the parent's coordinate system.
  void SetBounds(const gfx::Rect& bounds);
  void SetBounds(int x, int y, int width, int height) {
    SetBounds(gfx::Rect(x, y, std::max(0, width), std::max(0, height)));
  }
  void SetX(int x) { SetBounds(x, y(), width(), height()); }
  void SetY(int y) { SetBounds(x(), y, width(), height()); }

  // Returns the left coordinate of the View, relative to the parent View,
  // which is the value of bounds_.x().
  //
  // This is the function subclasses should use whenever they need to obtain
  // the left position of one of their child views (for example, when
  // implementing View::Layout()).
  // This is equivalent to GetX(IGNORE_MIRRORING_TRANSFORMATION), but
  // inlinable.
  int x() const { return bounds_.x(); }
  int y() const { return bounds_.y(); }
  int width() const { return bounds_.width(); }
  int height() const { return bounds_.height(); }

  // Return the left coordinate of the View, relative to the parent. If
  // |settings| is IGNORE_MIRRORING_SETTINGS, the function returns the value of
  // bounds_.x(). If |settings| is APPLY_MIRRORING_SETTINGS AND the parent
  // View is using a right-to-left UI layout, then the function returns the
  // mirrored value of bounds_.x().
  //
  // NOTE: in the vast majority of the cases, the mirroring implementation is
  //       transparent to the View subclasses and therefore you should use the
  //       paremeterless version of x() when you need to get the X
  //       coordinate of a child View.
  int GetX(PositionMirroringSettings settings) const;

  // Return this control local bounds. If include_border is true, local bounds
  // is the rectangle {0, 0, width(), height()}, otherwise, it does not
  // include the area where the border (if any) is painted.
  gfx::Rect GetLocalBounds(bool include_border) const;

  // Get the position of the View, relative to the parent.
  //
  // Note that if the parent uses right-to-left UI layout, then the mirrored
  // position of this View is returned. Use x()/y() if you want to ignore
  // mirroring.
  gfx::Point GetPosition() const;

  // Get the size the View would like to be, if enough space were available.
  virtual gfx::Size GetPreferredSize();

  // Returns the baseline of this view, or -1 if this view has no baseline. The
  // return value is relative to the preferred height.
  virtual int GetBaseline();

  // Convenience method that sizes this view to its preferred size.
  void SizeToPreferredSize();

  // Gets the minimum size of the view. View's implementation invokes
  // GetPreferredSize.
  virtual gfx::Size GetMinimumSize();

  // Return the height necessary to display this view with the provided width.
  // View's implementation returns the value from getPreferredSize.cy.
  // Override if your View's preferred height depends upon the width (such
  // as with Labels).
  virtual int GetHeightForWidth(int w);

  // This method is invoked when this object size or position changes.
  // The default implementation does nothing.
  virtual void DidChangeBounds(const gfx::Rect& previous,
                               const gfx::Rect& current);

  // Set whether the receiving view is visible. Painting is scheduled as needed
  virtual void SetVisible(bool flag);

  // Return whether a view is visible
  virtual bool IsVisible() const { return is_visible_; }

  // Return whether a view and its ancestors are visible. Returns true if the
  // path from this view to the root view is visible.
  virtual bool IsVisibleInRootView() const;

  // Set whether this view is enabled. A disabled view does not receive keyboard
  // or mouse inputs. If flag differs from the current value, SchedulePaint is
  // invoked.
  virtual void SetEnabled(bool flag);

  // Returns whether the view is enabled.
  virtual bool IsEnabled() const;

  // Set whether this view is hottracked. A disabled view cannot be hottracked.
  // If flag differs from the current value, SchedulePaint is invoked.
  virtual void SetHotTracked(bool flag);

  // Returns whether the view is hot-tracked.
  virtual bool IsHotTracked() const { return false; }

  // Returns whether the view is pushed.
  virtual bool IsPushed() const { return false; }

  // Scrolls the specified region, in this View's coordinate system, to be
  // visible. View's implementation passes the call onto the parent View (after
  // adjusting the coordinates). It is up to views that only show a portion of
  // the child view, such as Viewport, to override appropriately.
  virtual void ScrollRectToVisible(int x, int y, int width, int height);

  // Layout functions

  // Lay out the child Views (set their bounds based on sizing heuristics
  // specific to the current Layout Manager)
  virtual void Layout();

  // Gets/Sets the Layout Manager used by this view to size and place its
  // children.
  // The LayoutManager is owned by the View and is deleted when the view is
  // deleted, or when a new LayoutManager is installed.
  LayoutManager* GetLayoutManager() const;
  void SetLayoutManager(LayoutManager* layout);

  // Right-to-left UI layout functions

  // Indicates whether the UI layout for this view is right-to-left. The view
  // has an RTL UI layout if RTL hasn't been disabled for the view and if the
  // locale's language is an RTL language.
  bool UILayoutIsRightToLeft() const;

  // Enables or disables the right-to-left layout for the view. If |enable| is
  // true, the layout will become right-to-left only if the locale's language
  // is right-to-left.
  //
  // By default, right-to-left UI layout is enabled for the view and therefore
  // this function must be called (with false as the |enable| parameter) in
  // order to disable the right-to-left layout property for a specific instance
  // of the view. Disabling the right-to-left UI layout is necessary in case a
  // UI element will not appear correctly when mirrored.
  void EnableUIMirroringForRTLLanguages(bool enable) {
    ui_mirroring_is_enabled_for_rtl_languages_ = enable;
  }

  // This method determines whether the gfx::Canvas object passed to
  // View::Paint() needs to be transformed such that anything drawn on the
  // canvas object during View::Paint() is flipped horizontally.
  //
  // By default, this function returns false (which is the initial value of
  // |flip_canvas_on_paint_for_rtl_ui_|). View subclasses that need to paint on
  // a flipped gfx::Canvas when the UI layout is right-to-left need to call
  // EnableCanvasFlippingForRTLUI().
  bool FlipCanvasOnPaintForRTLUI() const {
    return flip_canvas_on_paint_for_rtl_ui_ ? UILayoutIsRightToLeft() : false;
  }

  // Enables or disables flipping of the gfx::Canvas during View::Paint().
  // Note that if canvas flipping is enabled, the canvas will be flipped only
  // if the UI layout is right-to-left; that is, the canvas will be flipped
  // only if UILayoutIsRightToLeft() returns true.
  //
  // Enabling canvas flipping is useful for leaf views that draw a bitmap that
  // needs to be flipped horizontally when the UI layout is right-to-left
  // (views::Button, for example). This method is helpful for such classes
  // because their drawing logic stays the same and they can become agnostic to
  // the UI directionality.
  void EnableCanvasFlippingForRTLUI(bool enable) {
    flip_canvas_on_paint_for_rtl_ui_ = enable;
  }

  // Returns the mirrored X position for the view, relative to the parent. If
  // the parent view is not mirrored, this function returns bound_.left.
  //
  // UI mirroring is transparent to most View subclasses and therefore there is
  // no need to call this routine from anywhere within your subclass
  // implementation.
  int MirroredX() const;

  // Given a rectangle specified in this View's coordinate system, the function
  // computes the 'left' value for the mirrored rectangle within this View. If
  // the View's UI layout is not right-to-left, then bounds.x() is returned.
  //
  // UI mirroring is transparent to most View subclasses and therefore there is
  // no need to call this routine from anywhere within your subclass
  // implementation.
  int MirroredLeftPointForRect(const gfx::Rect& rect) const;

  // Given the X coordinate of a point inside the View, this function returns
  // the mirrored X coordinate of the point if the View's UI layout is
  // right-to-left. If the layout is left-to-right, the same X coordinate is
  // returned.
  //
  // Following are a few examples of the values returned by this function for
  // a View with the bounds {0, 0, 100, 100} and a right-to-left layout:
  //
  // MirroredXCoordinateInsideView(0) -> 100
  // MirroredXCoordinateInsideView(20) -> 80
  // MirroredXCoordinateInsideView(99) -> 1
  int MirroredXCoordinateInsideView(int x) const {
    return UILayoutIsRightToLeft() ? width() - x : x;
  }

  // Given a X coordinate and a width inside the View, this function returns
  // the mirrored X coordinate if the View's UI layout is right-to-left. If the
  // layout is left-to-right, the same X coordinate is returned.
  //
  // Following are a few examples of the values returned by this function for
  // a View with the bounds {0, 0, 100, 100} and a right-to-left layout:
  //
  // MirroredXCoordinateInsideView(0, 10) -> 90
  // MirroredXCoordinateInsideView(20, 20) -> 60
  int MirroredXWithWidthInsideView(int x, int w) const {
    return UILayoutIsRightToLeft() ? width() - x - w : x;
  }

  // Painting functions

  // Mark the specified rectangle as dirty (needing repaint). If |urgent| is
  // true, the view will be repainted when the current event processing is
  // done. Otherwise, painting will take place as soon as possible.
  virtual void SchedulePaint(const gfx::Rect& r, bool urgent);

  // Mark the entire View's bounds as dirty. Painting will occur as soon as
  // possible.
  virtual void SchedulePaint();

  // Convenience to schedule a paint given some ints. Painting will occur as
  // soon as possible.
  virtual void SchedulePaint(int x, int y, int w, int h);

  // Paint the receiving view. g is prepared such as it is in
  // receiver's coordinate system. g's state is restored after this
  // call so your implementation can change the graphics configuration
  //
  // Default implementation paints the background if it is defined
  //
  // Override this method when implementing a new control.
  virtual void Paint(gfx::Canvas* canvas);

  // Paint the background if any. This method is called by Paint() and
  // should rarely be invoked directly.
  virtual void PaintBackground(gfx::Canvas* canvas);

  // Paint the border if any. This method is called by Paint() and
  // should rarely be invoked directly.
  virtual void PaintBorder(gfx::Canvas* canvas);

  // Paints the focus border (only if the view has the focus).
  // This method is called by Paint() and should rarely be invoked directly.
  // The default implementation paints a gray border around the view. Override
  // it for custom focus effects.
  virtual void PaintFocusBorder(gfx::Canvas* canvas);

  // Paint this View immediately.
  virtual void PaintNow();

  // Tree functions

  // Add a child View.
  void AddChildView(View* v);

  // Adds a child View at the specified position.
  void AddChildView(int index, View* v);

  // Get the child View at the specified index.
  View* GetChildViewAt(int index) const;

  // Remove a child view from this view. v's parent will change to NULL
  void RemoveChildView(View *v);

  // Remove all child view from this view.  If |delete_views| is true, the views
  // are deleted, unless marked as not parent owned.
  void RemoveAllChildViews(bool delete_views);

  // Get the number of child Views.
  int GetChildViewCount() const;

  // Returns the deepest descendant that contains the specified point.
  virtual View* GetViewForPoint(const gfx::Point& point);

  // Get the Widget that hosts this View, if any.
  virtual Widget* GetWidget() const;

  // Gets the Widget that most closely contains this View, if any.
  // NOTE: almost all views displayed on screen have a Widget, but not
  // necessarily a Window. This is due to widgets being able to create top
  // level windows (as is done for popups, bubbles and menus).
  virtual Window* GetWindow() const;

  // Get the containing RootView
  virtual RootView* GetRootView();

  // Get the parent View
  View* GetParent() const { return parent_; }

  // Returns the index of the specified |view| in this view's children, or -1
  // if the specified view is not a child of this view.
  int GetChildIndex(View* v) const;

  // Returns true if the specified view is a direct or indirect child of this
  // view.
  bool IsParentOf(View* v) const;

  // Recursively descends the view tree starting at this view, and returns
  // the first child that it encounters that has the given ID.
  // Returns NULL if no matching child view is found.
  virtual View* GetViewByID(int id) const;

  // Sets and gets the ID for this view.  ID should be unique within the subtree
  // that you intend to search for it.  0 is the default ID for views.
  void SetID(int id);
  int GetID() const;

  // A group id is used to tag views which are part of the same logical group.
  // Focus can be moved between views with the same group using the arrow keys.
  // Groups are currently used to implement radio button mutual exclusion.
  // The group id is immutable once it's set.
  void SetGroup(int gid);
  // Returns the group id of the view, or -1 if the id is not set yet.
  int GetGroup() const;

  // If this returns true, the views from the same group can each be focused
  // when moving focus with the Tab/Shift-Tab key.  If this returns false,
  // only the selected view from the group (obtained with
  // GetSelectedViewForGroup()) is focused.
  virtual bool IsGroupFocusTraversable() const { return true; }

  // Fills the provided vector with all the available views which belong to the
  // provided group.
  void GetViewsWithGroup(int group_id, std::vector<View*>* out);

  // Return the View that is currently selected in the specified group.
  // The default implementation simply returns the first View found for that
  // group.
  virtual View* GetSelectedViewForGroup(int group_id);

  // Focus support
  //
  // Returns the view that should be selected next when pressing Tab.
  View* GetNextFocusableView();

  // Returns the view that should be selected next when pressing Shift-Tab.
  View* GetPreviousFocusableView();

  // Sets the component that should be selected next when pressing Tab, and
  // makes the current view the precedent view of the specified one.
  // Note that by default views are linked in the order they have been added to
  // their container. Use this method if you want to modify the order.
  // IMPORTANT NOTE: loops in the focus hierarchy are not supported.
  void SetNextFocusableView(View* view);

  // Return whether this view can accept the focus.
  virtual bool IsFocusable() const;

  // Sets whether this view can accept the focus.
  // Note that this is false by default so that a view used as a container does
  // not get the focus.
  virtual void SetFocusable(bool focusable);

  // Convenience method to retrieve the FocusManager associated with the
  // Widget that contains this view.  This can return NULL if this view is not
  // part of a view hierarchy with a Widget.
  virtual FocusManager* GetFocusManager();

  // Sets a keyboard accelerator for that view. When the user presses the
  // accelerator key combination, the AcceleratorPressed method is invoked.
  // Note that you can set multiple accelerators for a view by invoking this
  // method several times.
  virtual void AddAccelerator(const Accelerator& accelerator);

  // Removes the specified accelerator for this view.
  virtual void RemoveAccelerator(const Accelerator& accelerator);

  // Removes all the keyboard accelerators for this view.
  virtual void ResetAccelerators();

  // Called when a keyboard accelerator is pressed.
  // Derived classes should implement desired behavior and return true if they
  // handled the accelerator.
  virtual bool AcceleratorPressed(const Accelerator& accelerator) {
    return false;
  }

  // Returns whether this view currently has the focus.
  virtual bool HasFocus();

  // Accessibility support
  // TODO(klink): Move all this out to a AccessibleInfo wrapper class.
  //
  // Returns the MSAA default action of the current view. The string returned
  // describes the default action that will occur when executing
  // IAccessible::DoDefaultAction. For instance, default action of a button is
  // 'Press'. Sets the input string appropriately, and returns true if
  // successful.
  virtual bool GetAccessibleDefaultAction(std::wstring* action) {
    return false;
  }

  // Returns a string containing the mnemonic, or the keyboard shortcut, for a
  // given control. Sets the input string appropriately, and returns true if
  // successful.
  virtual bool GetAccessibleKeyboardShortcut(std::wstring* shortcut) {
    return false;
  }

  // Returns a brief, identifying string, containing a unique, readable name of
  // a given control. Sets the input string appropriately, and returns true if
  // successful.
  virtual bool GetAccessibleName(std::wstring* name) { return false; }

  // Returns the accessibility role of the current view. The role is what
  // assistive technologies (ATs) use to determine what behavior to expect from
  // a given control. Sets the input Role appropriately, and returns true if
  // successful.
  virtual bool GetAccessibleRole(AccessibilityTypes::Role* role) {
    return false;
  }

  // Returns the accessibility state of the current view. Sets the input State
  // appropriately, and returns true if successful.
  virtual bool GetAccessibleState(AccessibilityTypes::State* state) {
    return false;
  }

  // Assigns a keyboard shortcut string description to the given control. Needed
  // as a View does not know which shortcut will be associated with it until it
  // is created to be a certain type.
  virtual void SetAccessibleKeyboardShortcut(const std::wstring& shortcut) {}

  // Assigns a string name to the given control. Needed as a View does not know
  // which name will be associated with it until it is created to be a
  // certain type.
  virtual void SetAccessibleName(const std::wstring& name) {}

  // Returns an instance of a wrapper class implementing the (platform-specific)
  // accessibility interface for a given View. If one exists, it will be
  // re-used, otherwise a new instance will be created.
  ViewAccessibilityWrapper* GetViewAccessibilityWrapper();

  // Accessor used to determine if a child view (leaf) has accessibility focus.
  // Returns NULL if there are no children, or if none of the children has
  // accessibility focus.
  virtual View* GetAccFocusedChildView() { return NULL; }

  // Utility functions

  // Note that the utility coordinate conversions functions always operate on
  // the mirrored position of the child Views if the parent View uses a
  // right-to-left UI layout.

  // Convert a point from source coordinate system to dst coordinate system.
  //
  // source is a parent or a child of dst, directly or transitively.
  // If source and dst are not in the same View hierarchy, the result is
  // undefined.
  // Source can be NULL in which case it means the screen coordinate system
  static void ConvertPointToView(const View* src,
                                 const View* dst,
                                 gfx::Point* point);

  // Convert a point from the coordinate system of a View to that of the
  // Widget. This is useful for example when sizing HWND children of the
  // Widget that don't know about the View hierarchy and need to be placed
  // relative to the Widget that is their parent.
  static void ConvertPointToWidget(const View* src, gfx::Point* point);

  // Convert a point from a view Widget to a View dest
  static void ConvertPointFromWidget(const View* dest, gfx::Point* p);

  // Convert a point from the coordinate system of a View to that of the
  // screen. This is useful for example when placing popup windows.
  static void ConvertPointToScreen(const View* src, gfx::Point* point);

  // Event Handlers

  // This method is invoked when the user clicks on this view.
  // The provided event is in the receiver's coordinate system.
  //
  // Return true if you processed the event and want to receive subsequent
  // MouseDraggged and MouseReleased events.  This also stops the event from
  // bubbling.  If you return false, the event will bubble through parent
  // views.
  //
  // If you remove yourself from the tree while processing this, event bubbling
  // stops as if you returned true, but you will not receive future events.
  // The return value is ignored in this case.
  //
  // Default implementation returns true if a ContextMenuController has been
  // set, false otherwise. Override as needed.
  //
  virtual bool OnMousePressed(const MouseEvent& event);

  // This method is invoked when the user clicked on this control.
  // and is still moving the mouse with a button pressed.
  // The provided event is in the receiver's coordinate system.
  //
  // Return true if you processed the event and want to receive
  // subsequent MouseDragged and MouseReleased events.
  //
  // Default implementation returns true if a ContextMenuController has been
  // set, false otherwise. Override as needed.
  //
  virtual bool OnMouseDragged(const MouseEvent& event);

  // This method is invoked when the user releases the mouse
  // button. The event is in the receiver's coordinate system.
  //
  // If canceled is true it indicates the mouse press/drag was canceled by a
  // system/user gesture.
  //
  // Default implementation notifies the ContextMenuController is appropriate.
  // Subclasses that wish to honor the ContextMenuController should invoke
  // super.
  virtual void OnMouseReleased(const MouseEvent& event, bool canceled);

  // This method is invoked when the mouse is above this control
  // The event is in the receiver's coordinate system.
  //
  // Default implementation does nothing. Override as needed.
  virtual void OnMouseMoved(const MouseEvent& e);

  // This method is invoked when the mouse enters this control.
  //
  // Default implementation does nothing. Override as needed.
  virtual void OnMouseEntered(const MouseEvent& event);

  // This method is invoked when the mouse exits this control
  // The provided event location is always (0, 0)
  // Default implementation does nothing. Override as needed.
  virtual void OnMouseExited(const MouseEvent& event);

  // Set the MouseHandler for a drag session.
  //
  // A drag session is a stream of mouse events starting
  // with a MousePressed event, followed by several MouseDragged
  // events and finishing with a MouseReleased event.
  //
  // This method should be only invoked while processing a
  // MouseDragged or MouseReleased event.
  //
  // All further mouse dragged and mouse up events will be sent
  // the MouseHandler, even if it is reparented to another window.
  //
  // The MouseHandler is automatically cleared when the control
  // comes back from processing the MouseReleased event.
  //
  // Note: if the mouse handler is no longer connected to a
  // view hierarchy, events won't be sent.
  //
  virtual void SetMouseHandler(View* new_mouse_handler);

  // Request the keyboard focus. The receiving view will become the
  // focused view.
  virtual void RequestFocus();

  // Invoked when a view is about to gain focus
  virtual void WillGainFocus();

  // Invoked when a view just gained focus.
  virtual void DidGainFocus();

  // Invoked when a view is about lose focus
  virtual void WillLoseFocus();

  // Invoked when a view is about to be requested for focus due to the focus
  // traversal. Reverse is this request was generated going backward
  // (Shift-Tab).
  virtual void AboutToRequestFocusFromTabTraversal(bool reverse) { }

  // Invoked when a key is pressed before the key event is processed (and
  // potentially eaten) by the focus manager for tab traversal, accelerators and
  // other focus related actions.
  // The default implementation returns false, ensuring that tab traversal and
  // accelerators processing is performed.
  // Subclasses should return true if they want to process the key event and not
  // have it processed as an accelerator (if any) or as a tab traversal (if the
  // key event is for the TAB key).  In that case, OnKeyPressed will
  // subsequently be invoked for that event.
  virtual bool SkipDefaultKeyEventProcessing(const KeyEvent& e) {
    return false;
  }

  // Invoked when a key is pressed or released.
  // Subclasser should return true if the event has been processed and false
  // otherwise. If the event has not been processed, the parent will be given a
  // chance.
  virtual bool OnKeyPressed(const KeyEvent& e);
  virtual bool OnKeyReleased(const KeyEvent& e);

  // Invoked when the user uses the mousewheel. Implementors should return true
  // if the event has been processed and false otherwise. This message is sent
  // if the view is focused. If the event has not been processed, the parent
  // will be given a chance.
  virtual bool OnMouseWheel(const MouseWheelEvent& e);

  // Drag and drop functions.

  // Set/get the DragController. See description of DragController for more
  // information.
  void SetDragController(DragController* drag_controller);
  DragController* GetDragController();

  // During a drag and drop session when the mouse moves the view under the
  // mouse is queried for the drop types it supports by way of the
  // GetDropFormats methods. If the view returns true and the drag site can
  // provide data in one of the formats, the view is asked if the drop data
  // is required before any other drop events are sent. Once the
  // data is available the view is asked if it supports the drop (by way of
  // the CanDrop method). If a view returns true from CanDrop,
  // OnDragEntered is sent to the view when the mouse first enters the view,
  // as the mouse moves around within the view OnDragUpdated is invoked.
  // If the user releases the mouse over the view and OnDragUpdated returns a
  // valid drop, then OnPerformDrop is invoked. If the mouse moves outside the
  // view or over another view that wants the drag, OnDragExited is invoked.
  //
  // Similar to mouse events, the deepest view under the mouse is first checked
  // if it supports the drop (Drop). If the deepest view under
  // the mouse does not support the drop, the ancestors are walked until one
  // is found that supports the drop.

  // Override and return the set of formats that can be dropped on this view.
  // |formats| is a bitmask of the formats defined bye OSExchangeData::Format.
  // The default implementation returns false, which means the view doesn't
  // support dropping.
  virtual bool GetDropFormats(
      int* formats,
      std::set<OSExchangeData::CustomFormat>* custom_formats);

  // Override and return true if the data must be available before any drop
  // methods should be invoked. The default is false.
  virtual bool AreDropTypesRequired();

  // A view that supports drag and drop must override this and return true if
  // data contains a type that may be dropped on this view.
  virtual bool CanDrop(const OSExchangeData& data);

  // OnDragEntered is invoked when the mouse enters this view during a drag and
  // drop session and CanDrop returns true. This is immediately
  // followed by an invocation of OnDragUpdated, and eventually one of
  // OnDragExited or OnPerformDrop.
  virtual void OnDragEntered(const DropTargetEvent& event);

  // Invoked during a drag and drop session while the mouse is over the view.
  // This should return a bitmask of the DragDropTypes::DragOperation supported
  // based on the location of the event. Return 0 to indicate the drop should
  // not be accepted.
  virtual int OnDragUpdated(const DropTargetEvent& event);

  // Invoked during a drag and drop session when the mouse exits the views, or
  // when the drag session was canceled and the mouse was over the view.
  virtual void OnDragExited();

  // Invoked during a drag and drop session when OnDragUpdated returns a valid
  // operation and the user release the mouse.
  virtual int OnPerformDrop(const DropTargetEvent& event);

  // Returns true if the mouse was dragged enough to start a drag operation.
  // delta_x and y are the distance the mouse was dragged.
  static bool ExceededDragThreshold(int delta_x, int delta_y);

  // This method is the main entry point to process paint for this
  // view and its children. This method is called by the painting
  // system. You should call this only if you want to draw a sub tree
  // inside a custom graphics.
  // To customize painting override either the Paint or PaintChildren method,
  // not this one.
  virtual void ProcessPaint(gfx::Canvas* canvas);

  // Paint the View's child Views, in reverse order.
  virtual void PaintChildren(gfx::Canvas* canvas);

  // Sets the ContextMenuController. Setting this to non-null makes the View
  // process mouse events.
  void SetContextMenuController(ContextMenuController* menu_controller);
  ContextMenuController* GetContextMenuController() {
    return context_menu_controller_;
  }

  // Provides default implementation for context menu handling. The default
  // implementation calls the ShowContextMenu of the current
  // ContextMenuController (if it is not NULL). Overridden in subclassed views
  // to provide right-click menu display triggerd by the keyboard (i.e. for the
  // Chrome toolbar Back and Forward buttons). No source needs to be specified,
  // as it is always equal to the current View.
  virtual void ShowContextMenu(int x,
                               int y,
                               bool is_mouse_gesture);

  // The background object is owned by this object and may be NULL.
  void set_background(Background* b) { background_.reset(b); }
  const Background* background() const { return background_.get(); }

  // The border object is owned by this object and may be NULL.
  void set_border(Border* b) { border_.reset(b); }
  const Border* border() const { return border_.get(); }

  // Returns the insets of the current border. If there is no border an empty
  // insets is returned.
  virtual gfx::Insets GetInsets() const;

  // Return the cursor that should be used for this view or NULL if
  // the default cursor should be used. The provided point is in the
  // receiver's coordinate system. The caller is responsible for managing the
  // lifetime of the returned object, though that lifetime may vary from
  // platform to platform. On Windows, the cursor is a shared resource but in
  // Gtk, the framework destroys the returned cursor after setting it.
  virtual gfx::NativeCursor GetCursorForPoint(Event::EventType event_type,
                                              int x,
                                              int y);

  // Convenience to test whether a point is within this view's bounds
  virtual bool HitTest(const gfx::Point& l) const;

  // Gets the tooltip for this View. If the View does not have a tooltip,
  // return false. If the View does have a tooltip, copy the tooltip into
  // the supplied string and return true.
  // Any time the tooltip text that a View is displaying changes, it must
  // invoke TooltipTextChanged.
  // The x/y provide the coordinates of the mouse (relative to this view).
  virtual bool GetTooltipText(int x, int y, std::wstring* tooltip);

  // Returns the location (relative to this View) for the text on the tooltip
  // to display. If false is returned (the default), the tooltip is placed at
  // a default position.
  virtual bool GetTooltipTextOrigin(int x, int y, gfx::Point* loc);

  // Set whether this view is owned by its parent. A view that is owned by its
  // parent is automatically deleted when the parent is deleted. The default is
  // true. Set to false if the view is owned by another object and should not
  // be deleted by its parent.
  void set_parent_owned(bool is_parent_owned) {
    is_parent_owned_ = is_parent_owned;
  }

  // Return whether a view is owned by its parent.
  bool IsParentOwned() const { return is_parent_owned_; }

  // Return the receiving view's class name. A view class is a string which
  // uniquely identifies the view class. It is intended to be used as a way to
  // find out during run time if a view can be safely casted to a specific view
  // subclass. The default implementation returns kViewClassName.
  virtual std::string GetClassName() const;

  // Returns the first ancestor, starting at this, whose class name is |name|.
  // Returns null if no ancestor has the class name |name|.
  View* GetAncestorWithClassName(const std::string& name);

  // Returns the visible bounds of the receiver in the receivers coordinate
  // system.
  //
  // When traversing the View hierarchy in order to compute the bounds, the
  // function takes into account the mirroring setting for each View and
  // therefore it will return the mirrored version of the visible bounds if
  // need be.
  gfx::Rect GetVisibleBounds();

  // Subclasses that contain traversable children that are not directly
  // accessible through the children hierarchy should return the associated
  // FocusTraversable for the focus traversal to work properly.
  virtual FocusTraversable* GetFocusTraversable() { return NULL; }

#ifndef NDEBUG
  // Debug method that logs the view hierarchy to the output.
  void PrintViewHierarchy();

  // Debug method that logs the focus traversal hierarchy to the output.
  void PrintFocusHierarchy();
#endif

  // The following methods are used by ScrollView to determine the amount
  // to scroll relative to the visible bounds of the view. For example, a
  // return value of 10 indicates the scrollview should scroll 10 pixels in
  // the appropriate direction.
  //
  // Each method takes the following parameters:
  //
  // is_horizontal: if true, scrolling is along the horizontal axis, otherwise
  //                the vertical axis.
  // is_positive: if true, scrolling is by a positive amount. Along the
  //              vertical axis scrolling by a positive amount equates to
  //              scrolling down.
  //
  // The return value should always be positive and gives the number of pixels
  // to scroll. ScrollView interprets a return value of 0 (or negative)
  // to scroll by a default amount.
  //
  // See VariableRowHeightScrollHelper and FixedRowHeightScrollHelper for
  // implementations of common cases.
  virtual int GetPageScrollIncrement(ScrollView* scroll_view,
                                     bool is_horizontal, bool is_positive);
  virtual int GetLineScrollIncrement(ScrollView* scroll_view,
                                     bool is_horizontal, bool is_positive);

  // Get the theme provider from the parent widget.
  ThemeProvider* GetThemeProvider() const;

 protected:
  // The id of this View. Used to find this View.
  int id_;

  // The group of this view. Some view subclasses use this id to find other
  // views of the same group. For example radio button uses this information
  // to find other radio buttons.
  int group_;

  // Called when the UI theme has changed, overriding allows individual Views to
  // do special cleanup and processing (such as dropping resource caches).
  // Subclasses that override this method must call the base class
  // implementation to ensure child views are processed.
  // Can only be called by subclasses. To dispatch a theme changed notification,
  // call this method on the RootView.
  virtual void ThemeChanged();

#ifndef NDEBUG
  // Returns true if the View is currently processing a paint.
  virtual bool IsProcessingPaint() const;
#endif

  // Returns the location, in screen coordinates, to show the context menu at
  // when the context menu is shown from the keyboard. This implementation
  // returns the middle of the visible region of this view.
  //
  // This method is invoked when the context menu is shown by way of the
  // keyboard.
  virtual gfx::Point GetKeyboardContextMenuLocation();

  // Called by HitTest to see if this View has a custom hit test mask. If the
  // return value is true, GetHitTestMask will be called to obtain the mask.
  // Default value is false, in which case the View will hit-test against its
  // bounds.
  virtual bool HasHitTestMask() const;

  // Called by HitTest to retrieve a mask for hit-testing against. Subclasses
  // override to provide custom shaped hit test regions.
  virtual void GetHitTestMask(gfx::Path* mask) const;

  // This method is invoked when the tree changes.
  //
  // When a view is removed, it is invoked for all children and grand
  // children. For each of these views, a notification is sent to the
  // view and all parents.
  //
  // When a view is added, a notification is sent to the view, all its
  // parents, and all its children (and grand children)
  //
  // Default implementation does nothing. Override to perform operations
  // required when a view is added or removed from a view hierarchy
  //
  // parent is the new or old parent. Child is the view being added or
  // removed.
  //
  virtual void ViewHierarchyChanged(bool is_add, View* parent, View* child);

  // When SetVisible() changes the visibility of a view, this method is
  // invoked for that view as well as all the children recursively.
  virtual void VisibilityChanged(View* starting_from, bool is_visible);

  // Called when the preferred size of a child view changed.  This gives the
  // parent an opportunity to do a fresh layout if that makes sense.
  virtual void ChildPreferredSizeChanged(View* child) {}

  // Simply calls ChildPreferredSizeChanged on the parent if there is one.
  virtual void PreferredSizeChanged();

  // Views must invoke this when the tooltip text they are to display changes.
  void TooltipTextChanged();

  // Sets whether this view wants notification when its visible bounds relative
  // to the root view changes. If true, this view is notified any time the
  // origin of one its ancestors changes, or the portion of the bounds not
  // obscured by ancestors changes. The default is false.
  void SetNotifyWhenVisibleBoundsInRootChanges(bool value);
  bool GetNotifyWhenVisibleBoundsInRootChanges();

  // Notification that this views visible bounds, relative to the RootView
  // has changed. The visible bounds corresponds to the region of the
  // view not obscured by other ancestors.
  virtual void VisibleBoundsInRootChanged() {}

  // Sets the keyboard focus to this View. The correct way to set the focus is
  // to call RequestFocus() on the view. This method is called when the focus is
  // set and gives an opportunity to subclasses to perform any extra focus steps
  // (for example native component set the native focus on their native
  // component). The default behavior is to set the native focus on the root
  // Widget, which is what is appropriate for views that have no native window
  // associated with them (so the root view gets the keyboard messages).
  virtual void Focus();

  // These are cover methods that invoke the method of the same name on
  // the DragController. Subclasses may wish to override rather than install
  // a DragController.
  // See DragController for a description of these methods.
  virtual int GetDragOperations(int press_x, int press_y);
  virtual void WriteDragData(int press_x, int press_y, OSExchangeData* data);

  // Invoked from DoDrag after the drag completes. This implementation does
  // nothing, and is intended for subclasses to do cleanup.
  virtual void OnDragDone();

  // Returns whether we're in the middle of a drag session that was initiated
  // by us.
  bool InDrag();

  // Returns how much the mouse needs to move in one direction to start a
  // drag. These methods cache in a platform-appropriate way. These values are
  // used by the public static method ExceededDragThreshold().
  static int GetHorizontalDragThreshold();
  static int GetVerticalDragThreshold();

  // Whether this view is enabled.
  bool enabled_;

  // Whether the view can be focused.
  bool focusable_;

 private:
  friend class RootView;
  friend class FocusManager;
  friend class ViewStorage;

  // Used to track a drag. RootView passes this into
  // ProcessMousePressed/Dragged.
  struct DragInfo {
    // Sets possible_drag to false and start_x/y to 0. This is invoked by
    // RootView prior to invoke ProcessMousePressed.
    void Reset();

    // Sets possible_drag to true and start_x/y to the specified coordinates.
    // This is invoked by the target view if it detects the press may generate
    // a drag.
    void PossibleDrag(int x, int y);

    // Whether the press may generate a drag.
    bool possible_drag;

    // Coordinates of the mouse press.
    int start_x;
    int start_y;
  };

  // RootView invokes these. These in turn invoke the appropriate OnMouseXXX
  // method. If a drag is detected, DoDrag is invoked.
  bool ProcessMousePressed(const MouseEvent& e, DragInfo* drop_info);
  bool ProcessMouseDragged(const MouseEvent& e, DragInfo* drop_info);
  void ProcessMouseReleased(const MouseEvent& e, bool canceled);

  // Starts a drag and drop operation originating from this view. This invokes
  // WriteDragData to write the data and GetDragOperations to determine the
  // supported drag operations. When done, OnDragDone is invoked.
  void DoDrag(const MouseEvent& e, int press_x, int press_y);

  // Removes |view| from the hierarchy tree.  If |update_focus_cycle| is true,
  // the next and previous focusable views of views pointing to this view are
  // updated.  If |update_tool_tip| is true, the tooltip is updated.  If
  // |delete_removed_view| is true, the view is also deleted (if it is parent
  // owned).
  void DoRemoveChildView(View* view,
                         bool update_focus_cycle,
                         bool update_tool_tip,
                         bool delete_removed_view);

  // Sets the parent View. This is called automatically by AddChild and is
  // thus private.
  void SetParent(View* parent);

  // Call ViewHierarchyChanged for all child views on all parents
  void PropagateRemoveNotifications(View* parent);

  // Call ViewHierarchyChanged for all children
  void PropagateAddNotifications(View* parent, View* child);

  // Call VisibilityChanged() recursively for all children.
  void PropagateVisibilityNotifications(View* from, bool is_visible);

  // Takes care of registering/unregistering accelerators if
  // |register_accelerators| true and calls ViewHierarchyChanged().
  void ViewHierarchyChangedImpl(bool register_accelerators,
                                bool is_add,
                                View* parent,
                                View* child);

  // This is the actual implementation for ConvertPointToView()
  // Attempts a parent -> child conversion and then a
  // child -> parent conversion if try_other_direction is true
  static void ConvertPointToView(const View* src,
                                 const View* dst,
                                 gfx::Point* point,
                                 bool try_other_direction);

  // Propagates UpdateTooltip() to the TooltipManager for the Widget.
  // This must be invoked any time the View hierarchy changes in such a way
  // the view under the mouse differs. For example, if the bounds of a View is
  // changed, this is invoked. Similarly, as Views are added/removed, this
  // is invoked.
  void UpdateTooltip();

  // Recursively descends through all descendant views,
  // registering/unregistering all views that want visible bounds in root
  // view notification.
  static void RegisterChildrenForVisibleBoundsNotification(RootView* root,
                                                           View* view);
  static void UnregisterChildrenForVisibleBoundsNotification(RootView* root,
                                                             View* view);

  // Adds/removes view to the list of descendants that are notified any time
  // this views location and possibly size are changed.
  void AddDescendantToNotify(View* view);
  void RemoveDescendantToNotify(View* view);

  // Initialize the previous/next focusable views of the specified view relative
  // to the view at the specified index.
  void InitFocusSiblings(View* view, int index);

  // Actual implementation of PrintFocusHierarchy.
  void PrintViewHierarchyImp(int indent);
  void PrintFocusHierarchyImp(int indent);

  // Registers this view's keyboard accelerators that are not registered to
  // FocusManager yet, if possible.
  void RegisterPendingAccelerators();

  // Unregisters all the keyboard accelerators associated with this view.
  void UnregisterAccelerators();

  // This View's bounds in the parent coordinate system.
  gfx::Rect bounds_;

  // This view's parent
  View* parent_;

  // This view's children.
  typedef std::vector<View*> ViewList;
  ViewList child_views_;

  // The View's LayoutManager defines the sizing heuristics applied to child
  // Views. The default is absolute positioning according to bounds_.
  scoped_ptr<LayoutManager> layout_manager_;

  // Visible state
  bool is_visible_;

  // Background
  scoped_ptr<Background> background_;

  // Border.
  scoped_ptr<Border> border_;

  // Whether this view is owned by its parent.
  bool is_parent_owned_;

  // See SetNotifyWhenVisibleBoundsInRootChanges.
  bool notify_when_visible_bounds_in_root_changes_;

  // Whether or not RegisterViewForVisibleBoundsNotification on the RootView
  // has been invoked.
  bool registered_for_visible_bounds_notification_;

  // List of descendants wanting notification when their visible bounds change.
  scoped_ptr<ViewList> descendants_to_notify_;

  // Next view to be focused when the Tab key is pressed.
  View* next_focusable_view_;

  // Next view to be focused when the Shift-Tab key combination is pressed.
  View* previous_focusable_view_;

  // The list of accelerators. List elements in the range
  // [0, registered_accelerator_count_) are already registered to FocusManager,
  // and the rest are not yet.
  scoped_ptr<std::vector<Accelerator> > accelerators_;
  size_t registered_accelerator_count_;

  // The menu controller.
  ContextMenuController* context_menu_controller_;

#if defined(OS_WIN)
  // The accessibility implementation for this View.
  scoped_ptr<ViewAccessibilityWrapper> accessibility_;
#endif

  DragController* drag_controller_;

  // Indicates whether or not the view is going to be mirrored (that is, use a
  // right-to-left UI layout) if the locale's language is a right-to-left
  // language like Arabic or Hebrew.
  bool ui_mirroring_is_enabled_for_rtl_languages_;

  // Indicates whether or not the gfx::Canvas object passed to View::Paint()
  // is going to be flipped horizontally (using the appropriate transform) on
  // right-to-left locales for this View.
  bool flip_canvas_on_paint_for_rtl_ui_;

  DISALLOW_COPY_AND_ASSIGN(View);
};

}  // namespace views

#endif  // VIEWS_VIEW_H_