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Scintilla and SciTE
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<a href="index.html" style="color:white;text-decoration:none"><font size="5">Scintilla
Component Design</font></a>
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<h2>
Top level structure
</h2>
<p>
Scintilla consists of three major layers of C++ code
</p>
<ul>
<li>
Portability Library
</li>
<li>
Core Code
</li>
<li>
Platform Events and API
</li>
</ul>
<p>
The primary purpose of this structure is to separate the platform dependent code from the
platform independent core code. This makes it easier to port Scintilla to a new platform and
ensures that most readers of the code do not have to deal with platform details. To minimise
portability problems and avoid code bloat, a conservative subset of C++ is used in Scintilla
with no exception handling, run time type information or use of the standard C++
library and with limited use of templates.
</p>
<p>
The currently supported platforms, Windows, GTK/Linux, Cocoa, Qt, and wxWidgets are fairly similar in
many ways.
Each has windows, menus and bitmaps. These features generally work in similar ways so each
has a way to move a window or draw a red line. Sometimes one platform requires a sequence of
calls rather than a single call. At other times, the differences are more profound. Reading
the Windows clipboard occurs synchronously but reading the GTK clipboard requires a request
call that will be asynchronously answered with a message containing the clipboard data.
The wxWidgets platform is available from the <a href="http://wxwidgets.org/">wxWidgets site</a>
</p>
<br />
<h3>
Portability Library
</h3>
<p>
This is a fairly small and thin layer over the platform's native capabilities.
</p>
<p>
The portability library is defined in Geometry.h and Platform.h and is implemented once for each platform.
PlatWin.cxx defines the Windows variants of the methods and PlatGTK.cxx the GTK variants.
</p>
<p>
Several of the classes here hold platform specific object identifiers and act as proxies to
these platform objects. Most client code can thus manipulate the platform objects without
caring which is the current platform. Sometimes client code needs access to the underlying
object identifiers and this is provided by the GetID method. The underlying types of the
platform specific identifiers are typedefed to common names to allow them to be transferred
around in client code where needed.
</p>
<h4>
Point, PRectangle
</h4>
<p>
These are simple classes provided to hold the commonly used geometric primitives. A
PRectangle follows the Mac / Windows convention of not including its bottom and right sides
instead of including all its sides as is normal in GTK. It is not called Rectangle as this may be
the name of a macro on Windows.
</p>
<h4>
ColourDesired
</h4>
<p>
This is a simple class holding an expected colour. It is internally represented as a single
32 bit integer in BGR format with 8 bits per colour, but also provides a convenient API to fetch
each component separately.
As a platform might not be able to represent the exact desired colour if it doesn't have 24 bit
depth available, it might not actually represent the exact desired colour but select a best fit
that it can actually render.
</p>
<h4>
Font
</h4>
<p>
Font holds a platform specific font identifier - HFONT for Windows, PangoFontDescription* for GTK. It
does not own the identifier and so will not delete the platform font object in its
destructor. Client code should call Destroy at appropriate times.
</p>
<h4>
Surface
</h4>
<p>
Surface is an abstraction over each platform's concept of somewhere that graphical drawing
operations can be done. It may wrap an already created drawing place such as a window or be
used to create a bitmap that can be drawn into and later copied onto another surface. On
Windows it wraps a HDC and possibly a HBITMAP. On GTK it wraps a cairo_surface_t*.
Other platform specific objects are created (and correctly destroyed) whenever
required to perform drawing actions.
</p>
<p>
Drawing operations provided include drawing filled and unfilled polygons, lines, rectangles,
ellipses and text. The height and width of text as well as other details can be measured.
Operations can be clipped to a rectangle. Most of the calls are stateless with all parameters
being passed at each call. The exception to this is line drawing which is performed by
calling MoveTo and then LineTo.
</p>
<h4>
Window
</h4>
<p>
Window acts as a proxy to a platform window allowing operations such as showing, moving,
redrawing, and destroying to be performed. It contains a platform specific window identifier
- HWND for Windows, GtkWidget* for GTK.
</p>
<h4>
ListBox
</h4>
<p>
ListBox is a subclass of Window and acts as a proxy to a platform listbox adding methods for
operations such as adding, retrieving, and selecting items.
</p>
<h4>
Menu
</h4>
<p>
Menu is a small helper class for constructing popup menus. It contains the platform specific
menu identifier - HMENU for Windows, GtkMenu* for GTK. Most of the work in
constructing menus requires access to platform events and so is done in the Platform Events
and API layer.
</p>
<h4>
Platform
</h4>
<p>
The Platform class is used to access the facilities of the platform. System wide parameters
such as double click speed and chrome colour are available from Platform. Utility functions
such as DebugPrintf are also available from Platform.
</p>
<h3>
Core Code
</h3>
<p>
The bulk of Scintilla's code is platform independent. This is made up of the CellBuffer,
ContractionState, Document, Editor, Indicator, LineMarker, Style, ViewStyle, KeyMap,
ScintillaBase, CallTip,
and AutoComplete primary classes.
</p>
<h4>
CellBuffer
</h4>
<p>
A CellBuffer holds text and styling information, the undo stack, the assignment of line
markers to lines, and the fold structure.
</p>
<p>
A cell contains a character byte and its associated style byte. The current state of the
cell buffer is the sequence of cells that make up the text and a sequence of line information
containing the starting position of each line and any markers assigned to each line.
</p>
<p>
The undo stack holds a sequence of actions on the cell buffer. Each action is one of a text
insertion, a text deletion or an undo start action. The start actions are used to group
sequences of text insertions and deletions together so they can be undone together. To
perform an undo operation, each insertion or deletion is undone in reverse sequence.
Similarly, redo reapplies each action to the buffer in sequence. Whenever a character is
inserted in the buffer either directly through a call such as InsertString or through undo or
redo, its styling byte is initially set to zero. Client code is responsible for styling each
character whenever convenient. Styling information is not stored in undo actions.
</p>
<h4>
Document
</h4>
<p>
A document contains a CellBuffer and deals with some higher level abstractions such as
words, DBCS character sequences and line end character sequences. It is responsible for
managing the styling process and for notifying other objects when changes occur to the
document.
</p>
<h4>
Editor
</h4>
<p>
The Editor object is central to Scintilla. It is responsible for displaying a document and
responding to user actions and requests from the container. It uses ContractionState, Indicator,
LineMarker, Style, and ViewStyle objects to display the document and a KeyMap class to
map key presses to functions.
The visibility of each line is kept in the ContractionState which is also responsible for mapping
from display lines to documents lines and vice versa.
</p>
<p>
There may be multiple Editor objects attached to one Document object. Changes to a
document are broadcast to the editors through the DocWatcher mechanism.
</p>
<h4>
ScintillaBase
</h4>
<p>
ScintillaBase is a subclass of Editor and adds extra windowing features including display of
calltips, autocompletion lists and context menus. These features use CallTip and AutoComplete
objects. This class is optional so a lightweight implementation of Scintilla may bypass it if
the added functionality is not required.
</p>
<h3>
Platform Events and API
</h3>
<p>
Each platform uses different mechanisms for receiving events. On Windows, events are
received through messages and COM. On GTK, callback functions are used.
</p>
<p>
For each platform, a class is derived from ScintillaBase (and thus from Editor). This is
ScintillaWin on Windows and ScintillaGTK on GTK. These classes are responsible for
connecting to the platforms event mechanism and also to implement some virtual methods in
Editor and ScintillaBase which are different on the platforms. For example, this layer has to
support this difference between the synchronous Windows clipboard and the asynchronous GTK
clipboard.
</p>
<p>
The external API is defined in this layer as each platform has different preferred styles of
API - messages on Windows and function calls on GTK. This also allows multiple APIs to be
defined on a platform. The currently available API on GTK is similar to the Windows API and
does not follow platform conventions well. A second API could be implemented here that did
follow platform conventions.
</p>
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