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Volume Number: | 10 | |||
Issue Number: | 9 | |||
Column Tag: | Apple Technology First Look |
Writing An Application In Dylan
Looking ahead to a richer programming experience
By Larisa Matejic, Brown University
Note: Source code files accompanying article are located on MacTech CD-ROM or source code disks.
Conceived and developed in Cambridge, Massachusetts, Dylan holds the promise of a new breed of development environment - dynamic, interactive, object oriented, and aimed at the professional application developer. As of this writing, the Dylan team continues to prepare Dylan for release. We’re pleased to be able to bring you this first look at developing an application in Dylan. Our author has worked with Dylan over the past year or so as an intern with Apple’s Cambridge group, and walks us through using Dylan to construct a QuickTime movie player. While we’ll bring you more articles on things like language specifics and the highly-interactive nature of the development environment later, this article should help you get a feel for putting together an application with Dylan - Ed stb
Dylan is one of the most versatile languages I have encountered. Apple Dylan has a number of features that make it easy and natural to use. Apple Dylan includes a development environment which greatly simplifies programming and debugging. Dylan’s expressive, yet simple syntax lends itself to efficient application development.
In this article, we’ll look at the process of writing a movie player application to explore Dylan’s unique features. We’ll focus on different properties of the Dylan language, as well as Apple Dylan’s cross-language calling mechanism.
The movie player application we’ll build mimics the QuickTime Movie Player application provided in the QuickTime developer’s kit.
QuickTime API
To use QuickTime, we’ll need to import QuickTime function and type definitions into Dylan. In fact, we’ll need to do the same for any Toolbox function or type we use in writing our application.
Dylan makes it easy to interface with C code - simply specify the .h file name and list the names of the functions and types you want to use. Dylan takes care of the rest. Here’s an example of how to import Toolbox function headers and types:
/* 1 */ define interface #include "Quickdraw.h", import: {"Picture", "PicHandle", "DrawPicture", "KillPicture", "CGrafPort", "UnionRect", "GDHandle", "GWorldPtr" } end interface;
We can call any of the C functions we import in the scope of our application as if they were written in Dylan.
Dylan Framework API
Dylan Framework provides useful class definitions for writing applications; it consists mainly of Dylan derivatives of Toolbox functionality. Among other things, it handles events, pick correlation (a fancy buzzword), view, and window operations. It originated with MacApp, but is cleaner and written entirely in Dylan.
The next thing is to get QuickTime and the Framework together. For that, we’ll define classes to deal with QuickTime movies. First, a bit about how classes work in Dylan.
Class Definitions
As in other object-oriented languages, each instance of a Dylan class stores information about its state in slots. A slot, equivalent to a data-member or field in other object-oriented languages, is a place to keep data, and each instance gets its own storage (i.e. set of slots). In addition to having its own slots, a class inherits all the slots of its superclasses.
Slots in Dylan are accessed by invoking methods using a simple syntax. For instance, to get the value stored in slot v of some object point, we write: point.v.
We’ll define a class called <movie-view>, which will provide a view onto the QuickTime movie. Note: it’s a convention in Dylan to surround class names by angle brackets.
Our class <movie-view> inherits from the Framework’s <view>. Among other things, it handles mouse events in the view. In other words, <movie-view> is a subclass of <view>, and we’ll add the data and methods we need to work with a QuickTime movie. We include slots particular to <movie-view> in the class definition; it inherits other slots from <view>.
/* 2 */ define class <movie-view> (<view>) slot movie :: <Movie>, init-value: as(<Movie>, 0), init-keyword: movie:; slot show-mc?, init-value: #t, init-keyword: show-mc?:; slot enable-editing?, init-value: #t, init-keyword: enable-editing?:; slot is-playing?, init-value: #f; slot loop?, init-value: #f; slot mc :: <MovieController>, init-value: as(<MovieController>, 0); end class;
From the class definition above, we see that the slot movie is of type <Movie>, imported from QuickTime through the define interface. Its initial value is a null pointer, or, more accurately, it is the integer 0 coerced into type <Movie> by the as operator. To specify which movie to associate with a particular <movie-view>, we’ll use the init-keyword at instantiation time. In this case, the init-keyword is movie:.
The next slot in <movie-view> is a boolean called show-mc?, whose value indicates whether to show QuickTime’s movie controller in the <movie-view>. Similarly, the boolean slot enable-editing? indicates whether the movie is read-only.
The next two slots can’t be initialized by use of a keyword by the creator of an instance of <movie-view>. That’s because we chose to not include an init-keyword in their slot definitions. Rather, their values are determined in the initialize routine of the instance of <movie-view>.
The slot is-playing? is used to keep track of when the movie is playing when the movie controller is not present to do that for us.
The slot mc is of the type <MovieController>, a type also imported from QuickTime. This is where we store a pointer to the movie controller object. The movie controller provides an interface to the movie, making it possible to play, stop and edit the movie.
With the QuickTime Movie Player, a movie is associated with a window that contains it, that window’s controls, and the file the movie is stored in. We need to define a class that will provide that window and the file. The Dylan Framework class <document> provides a mechanism for exactly that. We’ll define a subclass of <document> called <movie-document> in the following way:
/* 3 */ define class <movie-document> (<document>) slot movie :: <Movie>, init-value: as(<Movie>, 0); slot movie-view :: <movie-view>; end class;
In addition to inheriting all the slots of <document>, <movie-document> has a slot for storing an instance of <movie-view> and a slot for storing a pointer to the movie. The slot movie stores a copy of the pointer to the QuickTime movie already stored in <movie-view>. Having the slot movie present in <movie-document> is a matter of convenience and can be omitted if desired.
Now that we have defined our main classes, we can address how to define methods for these classes to provide the functionality want in this application.
Our app’s File and Edit menus will be standard. We’ll also have a Movie menu with items like Set Movie Poster, Show Movie Poster and Loop. We’ll focus our discussion on implementing the functionality of the items in the File menu, mainly Opening and Closing a movie. The code at the end of the article shows how we implemented the functionality of the rest of the menu items.
We aren’t going to show how to create and add menu items to a menu here. What we will discuss is the functionality needed for the menu callbacks, i.e. the functions that are called as a result of a menu item being selected.
Methods in Dylan
Dylan methods are grouped by name into collections called generic functions. Dylan supports polymorphism through generic functions and method dispatch. When you call a generic function, Dylan determines which method to invoke based on the type of arguments passed to it. This process is called method dispatch.
A method is said to be specialized when it is defined to operate on instances of a specific class. That is, a method is specialized on the type of its parameters. In addition to providing type information to the compiler, specializers make code easier for humans to understand. During method dispatch, a generic function compares all specializers with the arguments it receives to determine which method to invoke. The method whose parameters most closely match the argument types gets invoked.
You don’t need to modify class definitions to modify an object’s behavior. Method definitions in Dylan are separate from the classes they use for specialization. This makes for more flexible code organization. Given that you may not even be able to get to the code where a class is defined, the most effective approach then seems to be adding a method specialized on a specific class. For instance, Dylan lets you add a method on the class <integer> without changing the class itself or affecting other applications.
Next we’ll discuss some of the functions of our movie player app, and Dylan’s modularity will become more apparent. We’ll also show how simple it is to use pre-defined classes and augment them to get the behavior you want.
Opening a Movie File
When the user selects Open from the File menu and chooses a QuickTime movie, we’ll make an instance of <movie-document>, and store the file pointer in the main-file slot.
Since <movie-document> is a subclass of <document>, we can specialize the methods for <document> to incorporate our movie specific functionality.
The initialize method for <document> calls the method open-files, which opens a QuickTime movie file:
/* 4 */ define method open-files (document :: <movie-document>) open-movie-file(document.main-file); end method; define method open-movie-file (file :: <file>) with-stack-structure (spec(<FSSpec>), begin set-fs-spec(file, spec); let (err, ref-num) = OpenMovieFile(spec, file.data-permission); fail-os-error(err); file.data-ref-num := ref-num; end); end method;
To get the movie data out of the file, we specialize read-from-file, a method of <document>, that is eventually called by initialize.
/* 5 */ define method read-from-file (document :: <movie-document>, file :: <file>) let (err, new-movie,resId) = NewMovieFromFile( file.data-ref-num, "", 0); ignore(resId); fail-os-error(err); document.movie := new-movie; close-files(document); end method;
Next, in instantiating <document>, initialize calls the method make-windows to open the document in a window on screen.
/* 6 */ define method make-windows (document :: <movie-document>) let movie-bounds = with-stack-structure(box(<qd-rect>), begin GetMovieBox(document.movie,box); get-rect(box); end); let movie-size = point(movie-bounds.width, movie-bounds.height); document.movie-view := make(<movie-view>, location: $zero-point, size: movie-size); let window = make(<window>, location: point(100, 100), size: movie-size, next-handler: document, target-view: document.movie-view, has-go-away: #t); add-sub-view(window.root-view, document.movie-view); open(window); set-movie-to-view(document.movie-view, document.movie); make-document-title(document); end method;
In make-windows we get the movie’s size by calling the QuickTime function GetMovieBox. The Dylan wrapper surrounding the function call itself sets up a temporary local instance of <qd-rect> (a Dylan derivative of a QuickDraw rectangle), fills it with the values returned by GetMovieBox, and removes it from the stack. Then we create an instance of <movie-view> of the same size, followed by an instance of <window> with the same dimensions, and we designate our instance of <movie-view> to be the target view of the window. Then we add our <movie-view> instance to the window’s list of subviews. After opening the window, we call the method set-movie-to-view.
/* 7 */ define method set-movie-to-view (view :: <movie-view>, new-movie :: <Movie>) unless (new-movie = view.movie) unless (nil?(view.movie)) unless(nil?(view.mc)) DisposeMovieController(view.mc); end unless; DisposeMovie(view.movie); end unless; view.movie := new-movie; with-stack-structure (view-rect(<qd-rect>), begin set-rect(view-rect, view.local-bounds); let movie-window = get-window(view); let movie-port= as(<CGrafPort>, movie-window.window-ptr); SetMovieGWorld(view.movie, movie-port, as(<GDHandle>,0)); SetMovieBox(view.movie, view-rect); if (view.show-mc?) view.mc := as(<MovieController>, NewMovieController(view.movie, view-rect, $mcTopLeftMovie)); unless (nil?(view.mc)) MCSetControllerBoundsRect(view.mc, view-rect); MCSetControllerPort(view.mc, movie-port); draw(view, view.local-bounds); *controller-list* := add!(*controller-list*, view.mc); if (view.enable-editing?) MCEnableEditing(view.mc, #t); end if; end unless; end if; end); end unless; end method;
In set-movie-to-view, we use the QuickTime function SetMovieGWorld using the GWorld of the movie’s window (we instantiated it in make-windows). We also call SetMovieBox to let QuickTime know how big a window the movie needs to be displayed in.
The second half of the set-movie-to-view method instantiates a movie controller if the show-mc? slot of view (our instance of <movie-view>) is true. Then we call MCSetControllerBoundsRect with the size of our movie. We next set the GrafPort of the controller to match that of the movie and the window. The draw method draws the current frame (in this case, the first frame) of the movie and the controller on the screen. The variable *controller-list* is global and stores pointers to all movie controllers that are visible at a given time.
In Dylan, it is a convention to begin and end global variable names with asterisks.
In order to include controller events in our event loop, we need to keep a global list of controller pointers. Finally, if editing is enabled, we invoke the MCEnableEditing function.
Closing a Movie File
close-files is a generic function defined on <document>, which we specialize in the following way:
/* 8 */ define method close-files (document :: <movie-document>) close-movie-file(document.main-file); end method; define method close-movie-file (file :: <file>) unless (~(file.data-ref-num)) CloseMovieFile(file.data-ref-num); file.data-ref-num := 0; end unless; end method;
Playing a movie
There are two ways for the user to invoke movie playback. If the movie controller is visible, then it handles all the playback functionality. Otherwise, a double-click in the movie region on screen starts playback, a single click pauses it. This is one of the reasons why we subclassed <view> when we defined <movie-view>. <view> is equipped with methods to handle mouse events, which can easily be specialized to add the behavior we want (see the code listing for these).
Now we’ll discuss how to get the movie controller to take care of the playback functionality. We already mentioned that we keep a global list, *controller-list*, of all visible movie controllers that we update as each controller is created or disposed. A movie can have at most one controller, but we can have a number of movies open at once, so we can have more than a single item in *controller-list*.
Next, we create an event filter so a movie controller can be aware of user events. It will filter out events relevant to the movie controller and act upon them.
/* 9 */ define method controller-event-hook (event-rec :: <EventRecord>) block(exit) for (mc in *controller-list*) if (MCIsPlayerEvent(mc, event-rec) ~= 0) exit(#t); end if; end for; #f; end block; end method;
The method defined here is called from the event loop each time an event occurs and before it is handled. What our event-hook does is call MCIsPlayer on each movie controller in the list. It informs the event handler that the event was handled if a controller responds with something other than 0. Otherwise the event record is passed back to the event loop to be handled somewhere else. MCIsPlayerEvent is a QuickTime function which examines the event record and handles the event if it determines that the event should be handled by the movie controller. MCIsPlayerEvent returns a 0 if it didn’t handle the event.
Summary
Dylan has a number of features which make it a great language and environment:
• straightforward syntax
• easy access to functions coded in other languages
• design modularity through specialization, inheritance, etc
• a good framework to build on
Although this look at building Dylan applications leaves a lot of territory unexplored, reading the following code may help build your understanding further. There’ll be much more to come in the months ahead.
The Dylan environment lends itself to interactive browsing of code, so it’s unusual to see Dylan code flattened like this, but we’ve got to do something to get it into the magazine.
/* 10 */ // Source container: toolbox-interface.dylan // Interface to C files // Files.h define interface #include "Files.h", import: {"fsWrPerm"}; end interface; // Quickdraw.h define interface #include "Quickdraw.h", import: { "CGrafPort", "GDHandle"}, type: {"CQDProcsPtr" => <machine-pointer>}; end interface; // Movies.h define interface // import everything from Movies.h, and just a few necessary types from other files. #include "TextEdit.h", define: {"SystemSevenOrLater" => 1}, import: {"ScrpSTElement"}; #include "Components.h", define: {"SystemSevenOrLater" => 1}, import: {"Component", "ComponentInstance"}; #include "ImageCompression.h", import: {"MatrixRecord"}; #include "Movies.h", define: {"SystemSevenOrLater" => 1}; function "PreflightMovie", output-argument: outFlags; function "GetMovieGWorld", output-argument: port, output-argument: gdh; function "GetMoviePreviewTime", output-argument: previewTime, output-argument: previewDuration; function "GetMovieSelection", output-argument: selectionTime, output-argument: selectionDuration; function "GetMovieActiveSegment", output-argument: startTime, output-argument: duration; function "GetTrackDimensions", output-argument: width, output-argument: height; function "GetMediaHandlerDescription", output-argument: mediaType, output-argument: creatorManufacturer; function "SampleNumToMediaTime", output-argument: sampleTime, output-argument: sampleDuration; function "MediaTimeToSampleNum", output-argument: sampleNum, output-argument: sampleTime, output-argument: sampleDuration; function "AddMediaSample", output-argument: sampleTime; function "AddMediaSampleReference", output-argument: sampleTime; function "GetMediaSample", output-argument: size, output-argument: sampleTime, output-argument: durationPerSample, output-argument: sampleDescriptionIndex, output-argument: numberOfSamples, output-argument: sampleFlags; function "GetMediaSampleReference", output-argument: dataOffset, output-argument: size, output-argument: sampleTime, output-argument: durationPerSample, output-argument: sampleDescriptionIndex, output-argument: numberOfSamples, output-argument: sampleFlags; function "GetMediaShadowSync", output-argument: syncSampleNum; function "ConvertFileToMovieFile", output-argument: resID; function "ConvertMovieToFile", output-argument: resID; function "GetTrackDimensions", output-argument: height; function "GetMediaHandlerDescription", output-argument: mediaType, output-argument: creatorManufacturer; function "GetMediaDataHandlerDescription", output-argument: dhType, output-argument: creatorManufacturer; function "SampleNumToMediaTime", output-argument: sampleTime, output-argument: sampleDuration; function "MediaTimeToSampleNum", output-argument: *sampleNum, output-argument: sampleTime, output-argument: sampleDuration; function "AddMediaSample", output-argument: sampleTime; function "AddMediaSampleReference", output-argument: sampleTime; function "GetMediaSample", output-argument: size, output-argument: sampleTime, output-argument: durationPerSample, output-argument: sampleDescriptionIndex, output-argument: numberOfSamples, output-argument: sampleFlags; function "GetMediaSampleReference", output-argument: dataOffset, output-argument: size, output-argument: sampleTime, output-argument: durationPerSample, output-argument: sampleDescriptionIndex, output-argument: numberOfSamples, output-argument: sampleFlags; function "GetMediaShadowSync", output-argument: syncSampleNum; function "ConvertFileToMovieFile", output-argument: resID; function "ConvertMovieToFile", output-argument: resID; function "GetMediaNextInterestingTime", output-argument: interestingTime, output-argument: interestingDuration; function "GetTrackNextInterestingTime", output-argument: interestingTime, output-argument: interestingDuration; function "GetMovieNextInterestingTime", output-argument: whichMediaTypes, output-argument: interestingTime, output-argument: interestingDuration; function "CreateMovieFile", output-argument: resRefNum, output-argument: newmovie; function "OpenMovieFile", output-argument: resRefNum; function "NewMovieFromFile", output-argument: theMovie, output-argument: resId, output-argument: dataRefWasChanged; function "NewMovieFromHandle", output-argument: theMovie, output-argument: dataRefWasChanged; function "NewMovieFromDataFork", output-argument: theMovie, output-argument: dataRefWasChanged; function "AddMovieResource", output-argument: resId; function "GetMovieDefaultDataRef", output-argument: dataRef, output-argument: dataRefType; function "FlattenMovie", output-argument: resId; function "GetVideoMediaGraphicsMode", output-argument: graphicsMode; function "GetSoundMediaBalance", output-argument: balance; function "AddTextSample", output-argument: sampleTime; function "AddTESample", output-argument: sampleTime; function "AddHiliteSample", output-argument: sampleTime; function "FindNextText", output-argument: foundTime, output-argument: foundDuration, output-argument: offset; function "GetMovieCoverProcs", output-argument: uncoverProc, output-argument: coverProc, output-argument: refcon; function "GetMovieStatus", output-argument: firstProblemTrack; function "GetMediaDataRef", output-argument: dataRef, output-argument: dataRefType, output-argument: dataRefAttributes; function "AddMediaDataRef", output-argument: index; function "GetMediaDataRefCount", output-argument: count; function "MCGetCurrentTime", output-argument: scale; function "MCGetControllerInfo", output-argument: someFlags; function "MCGetClip", output-argument: theClip, output-argument: movieClip; function "MCDrawBadge", output-argument: badgeRgn; end interface; Events.h define interface #include "Events.h", import: {"GetMouse", "TickCount"}; end interface;
Menus.h
/* 11 */ define interface #include "Menus.h", import: {"MenuHandle"}; end interface; // source container: movie-utils.dylan define variable *controller-list* = #(); define variable *edit-menu* = #(); // this is the event hook called from the event loop to filter out movie controller events define constant controller-event-hook = method (event-rec :: <EventRecord>) block(exit) for (mc in *controller-list*) if(MCIsPlayerEvent(mc, event-rec) ~= 0) exit(#t); end if; end for; #f; end block; end method; // this must be called to initialize QuickTime define constant init-quicktime = method () fail-os-error(EnterMovies()); *controller-list* := #(); *event-hooks* := add(*event-hooks*, controller-event-hook); end method; // recommended to call this upon exiting QuickTime define constant exit-quicktime = method() ExitMovies(); end method; // opens a movie file define method open-movie-file (file :: <file>) with-stack-structure(spec(<FSSpec>), begin set-fs-spec(file, spec); let (err, ref-num) = OpenMovieFile(spec, file.data-permission); fail-os-error(err); file.data-ref-num := ref-num; end); end method; // closes a movie file define method close-movie-file (file :: <file>) unless (~(file.data-ref-num)) CloseMovieFile(file.data-ref-num); file.data-ref-num := 0; end unless; end method; // source container: movie-view.dylan define class <movie-view> (<view>) slot movie :: <Movie>, init-value: as(<Movie>, 0), init-keyword: movie:; slot show-mc?, init-value: #t, init-keyword: show-mc?:; slot enable-editing?, init-value: #t, init-keyword: enable-editing?:; slot is-playing?, init-value: #f; slot loop?, init-value: #f; slot mc :: <MovieController>, init-value: as(<MovieController>, 0); end class; // called as each instance of <movie-view> is instantiated define method initialize (view :: <movie-view>, #key) next-method(); unless (nil?(view.movie)) set-movie-to-view(view, view.movie); end unless; end method; // when a movie is closed, we need to clean up the relevant structures define method dispose (view :: <movie-view>) stop-playing(view); unless (nil?(view.movie)) unless(nil?(view.mc)) *controller-list* := remove!(*controller-list*,view.mc); DisposeMovieController(as(<ComponentInstance>,view.mc)); view.mc := as(<MovieController>, 0); end unless; DisposeMovie(view.movie); view.movie := as(<Movie>, 0); end unless; next-method(); end method; // this informs the movie about the size of the window it will play inside // of on screen and intializes the GWorld of the movie to be the current one define method size-setter(view :: <movie-view>, new-size :: <point>) next-method(); unless (nil?(view.movie)) with-stack-structure(r(<qd-rect>), begin focus(view); // Set the movie to play in our view set-rect(r, view.local-bounds); SetMovieBox(view.movie, r); SetMovieGWorld(view.movie,as(<CGrafPort>, 0), as(<GDHandle>,0)); end); end unless; end method; define method start-playing (view :: <movie-view>) unless (nil?(view.movie)) if (view.is-playing?) stop-playing(view); end if; GoToBeginningOfMovie(view.movie); // Start the movie playing StartMovie(view.movie); // Mark that we are playing view.is-playing? := #t; end unless; end method; define method stop-playing (view :: <movie-view>) unless (nil?(view.movie) | ~ view.is-playing?) StopMovie(view.movie); view.is-playing? := #f; end unless; end method; // this is called in response to an update event (the engine that calls it is // embedded within the Framework define method draw (view :: <movie-view>, draw-rect :: <rect>) ignore(draw-rect); unless (nil?(view.movie)) SetMovieActive(view.movie, #t); UpdateMovie(view.movie); MoviesTask(view.movie, $doTheRightThing); end unless; unless (~view.show-mc? | nil?(view.mc)) MCDraw(view.mc, get-window(view).window-ptr); end unless; end method; //sets up a view onto the movie in the window that is to contain the movie define method set-movie-to-view (view :: <movie-view>, new-movie :: <Movie>) unless (new-movie = view.movie) unless (nil?(view.movie)) unless(nil?(view.mc)) DisposeMovieController(view.mc); end unless; DisposeMovie(view.movie); end unless; view.movie := new-movie; with-stack-structure(view-rect(<qd-rect>), begin set-rect(view-rect, view.local-bounds); let movie-window = get-window(view); let movie-port = as(<CGrafPort>, movie-window.window-ptr); SetMovieGWorld(view.movie, movie-port, as(<GDHandle>,0)); SetMovieBox(view.movie, view-rect); if (view.show-mc?) view.mc := as(<MovieController>, NewMovieController(view.movie, view-rect, $mcTopLeftMovie)); unless (nil?(view.mc)) MCSetControllerBoundsRect(view.mc, view-rect); MCSetControllerPort(view.mc, movie-port); draw(view, view.local-bounds); *controller-list* := add!(*controller-list*, view.mc); if (view.enable-editing?) MCEnableEditing(view.mc, #t); end if; end unless; end if; end); end unless; end method; // called while waiting for the events to occur (during idle time) define method do-idle (view :: <movie-view>) if (view.mc & view.show-mc) // hack to have null events sent to the event loop during idle time // next version of the Framework will take care of this with-stack-structure(event-record(<EventRecord>), begin event-record.EventRecord$what := 0; GetMouse(event-record.EventRecord$where); event-record.EventRecord$when := TickCount(); event-record.EventRecord$message := 0; event-record.EventRecord$modifiers := #x80; MCIsPlayerEvent(view.mc, event-record); end); else if (view.is-playing?) MoviesTask(view.movie, $doTheRightThing); if (IsMovieDone(view.movie)) stop-playing(view); end if; end if; end if; end method; // The following methods are menu callbacks that suport editing // functionality of the movie controller define method do-event (view :: <movie-view>, event :: <menu-event>, id == #"clear") ignore(event, id); unless(nil?(view.mc)) MCClear(view.mc); end unless; end method; define method do-event (view :: <movie-view>, event :: <menu-event>, id == #"undo") ignore(event, id); unless(nil?(view.mc)) MCUndo(view.mc); end unless; end method; define method do-event (view :: <movie-view>, event :: <menu-event>, id == #"copy") ignore(event, id); unless(nil?(view.mc)) let selection = MCCopy(view.mc); unless(nil?(selection)) PutMovieOnScrap(selection, $movieScrapOnlyPutMovie); DisposeMovie(selection); end unless; end unless; end method; define method do-event (view :: <movie-view>, event :: <menu-event>, id == #"cut") ignore(event, id); unless(nil?(view.mc)) let selection = MCCut(view.mc); unless(nil?(selection)) PutMovieOnScrap(selection, $movieScrapOnlyPutMovie); DisposeMovie(selection); end unless; end unless; end method; define method do-event (view :: <movie-view>, event :: <menu-event>, id == #"paste") ignore(event, id); unless(nil?(view.mc) | ~IsScrapMovie(as(<Track>,0))) MCPaste(view.mc, as(<Movie>,0)); end unless; end method; // this method highlights the menus correctly define method do-setup-menus (view :: <movie-view>) next-method(); unless(nil?(view.mc) | ~view.enable-editing? | ~view.show-mc | nil?(view.movie)) enable-item(#"copy"); MCSetUpEditMenu(view.mc, $doTheRightThing, as(<MenuHandle>,*edit-menu*.toolbox-menu)); end unless; end method; define method do-event (view :: <movie-view>, event :: <generic-mouse-down-event>, id :: <keyword>) // when controller not present: double-click to play, single-click to stop ignore(id); if (~view.show-mc | nil?(view.mc)) if (double-click? (event)) if (IsMovieDone(view.movie)) GoToBeginningOfMovie(view.movie); end if; start-playing(view); else stop-playing(view); next-method(); end if; else next-method(); end if; end method; // source container: movie-document.dylan define class <movie-document> (<document>) slot movie :: <Movie>, init-value: as(<Movie>, 0); slot movie-view :: <movie-view>; end class; define method main-file-type (document :: <movie-document>) ignore(document); $MovieFileType; end method; //opens up a window containing a view onto the movie define method make-windows (document :: <movie-document>) let movie-bounds = with-stack-structure(box(<qd-rect>), begin GetMovieBox(document.movie, box); get-rect(box); end); let movie-size = point(movie-bounds.width, movie-bounds.height); document.movie-view := make(<movie-view>, location: $zero-point, size: movie-size); let window = make(<window>, location: point(100, 100), size: movie-size, next-handler: document, target-view: document.movie-view, has-go-away: #t); add-sub-view(window.root-view, document.movie-view); open(window); set-movie-to-view(document.movie-view, document.movie); make-document-title(document); end method; define method open-files (document :: <movie-document>) open-movie-file(document.main-file); end method; define method close-files (document :: <movie-document>) close-movie-file(document.main-file); end method; // gets the movie data in correctly from a file define method read-from-file (document :: <movie-document>, file :: <file>) let (err, new-movie,resId) = NewMovieFromFile( file.data-ref-num, "", 0); ignore(resId); fail-os-error(err); document.movie := new-movie; close-files(document); end method; // highlights the menu items in the Movie menu define method do-setup-menus (document :: <movie-document>) next-method(); enable-item(#"show-poster"); enable-item(#"set-poster"); end method; // menu callback for Show Poster menu item - goes to the poster frame define method do-event (document :: <movie-document>, event :: <menu-event>, id == #"show-poster") ignore(event, id); unless (nil?(document.movie)) let movie = document.movie; let poster-time = GetMoviePosterTime(movie); let movie-time = GetMovieTime(movie, as(<TimeRecord>, 0)); unless (poster-time = movie-time) StopMovie(movie); SetMovieTimeValue(movie, poster-time); end unless; end unless; end method; // menu callback for Set Poster menu item - sets movie poster to be the current frame define method do-event (document :: <movie-document>, event :: <menu-event>, id == #"set-poster") ignore(event, id); unless (nil?(document.movie)) let movie = document.movie; let new-poster-time = GetMovieTime(movie, as(<TimeRecord>, 0)); SetMoviePosterTime(movie, new-poster-time); end unless; end method; // Source container: movie-player.dylan define class <movie-player-behavior> (<behavior>) end class; define method behavior-setup-menus (behavior :: <movie-player-behavior>, next :: <list>, main-handler :: <main-handler>) ignore(behavior, next, main-handler); next-method(); end method; // callback for Quit menu item define method behavior-event (behavior :: <movie-player-behavior>, next :: <list>, main-handler :: <main-handler>, event :: <menu-event>, id == #"quit") ignore(behavior, next, main-handler, event, id); exit-quicktime(); next-method(); end method; define method init-movie () // initializes the Framework and QuickTime init-framework(); init-quicktime(); // Set up the menus. make(<menu>, title: "File", install: #t, items: list(make(<menu-item>, title: "New", identifier: #"new", command-key: 'N'), make(<menu-item>, title: "Open ", identifier: #"open", command-key: 'O'), make(<separator-item>), make(<menu-item>, title: "Save", identifier: #"save", command-key: 'S'), make(<menu-item>, title: "Save As ", identifier: #"save-as"), make(<separator-item>), make(<menu-item>, title: "Close", identifier: #"close", command-key: 'W'), make(<separator-item>), make(<menu-item>, title: "Quit", identifier: #"quit", command-key: 'Q'))); *edit-menu* := make-edit-menu(install: #t); make(<menu>, title: "Movie", install: #t, items: list( make(<menu-item>, title: "Go To Poster Frame", identifier: #"show-poster"), make(<menu-item>, title: "Set Poster Frame", identifier: #"set-poster") )); add-behavior(*main-handler*, make(<movie-player-behavior>)); add-document-type(*main-handler*, $MovieFileType, <movie-document>); #t; end method; // this method is called to actually run the application define method run-movie () init-movie(); run(); end method;
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