define('DISALLOW_FILE_EDIT', true);
[js]
if (window.devicePixelRatio) {
// grab the width and height from canvas
var height = canvas.getAttribute(‘height’);
var width = canvas.getAttribute(‘width’);
// reset the canvas width and height with window.devicePixelRatio applied
canvas.setAttribute(‘width’, Math.round(width * window.devicePixelRatio));
canvas.setAttribute(‘height’, Math.round( height * window.devicePixelRatio));
// force the canvas back to the original size using css
canvas.style.width = width+"px";
canvas.style.height = height+"px";
// set CreateJS to render scaled
stage.scaleX = stage.scaleY = window.devicePixelRatio;
}
[/js]
IE 10 doesn’t support devicePixelRatio, but you can get a resonable devicePixelRatio with this (include it before your CreateJS script, and call window.getDevicePixelRatio() instead of using the standard property):
[js]
/*! GetDevicePixelRatio | Author: Tyson Matanich, 2012 | License: MIT */
(function (window) {
window.getDevicePixelRatio = function () {
var ratio = 1;
// To account for zoom, change to use deviceXDPI instead of systemXDPI
if (window.screen.systemXDPI !== undefined && window.screen.logicalXDPI !== undefined && window.screen.systemXDPI > window.screen.logicalXDPI) {
// Only allow for values > 1
ratio = window.screen.systemXDPI / window.screen.logicalXDPI;
}
else if (window.devicePixelRatio !== undefined) {
ratio = window.devicePixelRatio;
}
return ratio;
};
})(this);
[/js]
If you like to load your CreateJS based animation in an iframe (I do) and the canvas content is the only content, you may also want to add some styles to avoid scrollbars and extra padding:
[css]
body {
margin:0;
padding:0;
}
canvas {
display: block;
}
[/css]
Before making these edits, I recommend copying the main html page, so that you don’t have to worry about the publisher wiping out your changes when you publish again (if certain things change, you may need to reintegrate your changes).
Some Notes:
Relevant info for devicePixelRatio and supporting HiDPI / Retina displays
]]>Currently, Backstage2D’s code base is mostly a playground for proof of concept of some API ideas. Some stuff in this post may not match the git repo (for example, I’m still using “layer” instead of “surface”). There’s a bunch left to do, but it is working enough to run a modified version of MoleHill_BunnMark that some folks from Adobe put together (I actually lifted most of my GPU code from that example code, heh). The BunnyMark example was adapted from Iain Lobb’s BunnyMark, with some additions from Phillipe Elsass. You can view the Backstage2D version of BunnyMark here (and check out the original BunnyMark MoleHill here).
The rest of this post describes the thought process that went into Backstage2D.
The Flash AS3 display list API is not the best way to utilize the massively parallel capabilities of a GPU, and deal with the other limitations of a CPU/GPU architecture. The display list’s deeply nestable DisplayObject metaphor, and all the fun filters and blend modes just doesn’t translate well to very parallel, flat GPU hardware renderer. All of this is especially true on mobile like iPhones, iPads and Android devices, and that’s the primary target for Backstage2D.
With an API like the traditional flash display list, it’s easy to create situations that can’t easily be batched due to branching operations and other things which change the GPU state, and break parallel processing – slowing everything down. You see this in Adobe AIR’s GPU render mode, where seemingly random things can have a huge negative impact on performance. Behind the scenes AIR attempts to break the content into batches to speed things up. The use of certain features, or normal features in certain ways can drop you out of a batch. When performance degradation happens, it’s not always clear why. Because of that, to get great performance you must target just a subset of the normal features, and apply a lot of discipline to make sure everything keeps working smoothly.
I wanted do something different. I wanted to play with an API that is intentionally unlike the Flash display list – one designed to help the implementor (Flash developer or designer) understand how to arrange their content, so that it renders very quickly, even on mobile devices – and still get the benefits of all the glorious Flash stuff we are all used to.
Here are some of the primary principles I came up with, which impact the API:
Of these, batching is the starting point, since it is the most necessary for advanced performance, and effects how data must be organized the most. You can draw each Quad (think Flash DisplayObject, or Sprite) individually by setting up the vertex, program, texture, etc. data for each quad, and calling drawTriangle for each and every Sprite. But the GPU can’t optimize to run in parallel if you do that – most of its processing cores end up underutilized in that model.
Batching let’s more than one quad be draw simultaneously, but there are limitations – Every item in a batch must use the same vector data (a giant array of x,y,other data), single texture and other state information, like blend modes. Additionally, the entire batch must be drawn without interruption, which means you can’t insert items from other batches (with other state settings like a different blend mode) in the middle of the batch.
So batches resemble layers, or surfaces. The model for Backstage2D will be a series of stacked surfaces, instead of a deeply nested tree structure starting at the root.
In this paradigm, the surface gets batched, and the children it contains get rendered in parallel – perfect for GPUs. To eliminate batch breaking APIs, certain “state changing” operations can be applied to only an entire layer, not to each element – operations like blend mode settings – or adding and removing elements from a surface. The limitations of surface API should help the implementor understand the impact of doing certain things. If you need to have 100 elements, and every other element has a blend mode of Multiply, while the one below it has a blend mode of Normal – in the traditional Flash API, this is fine, and can actually run pretty well. On the GPU, all 100 elements must be rendered individually in 100 distinct surfaces. Having that many surfaces feels heavy because it is heavy.
Texture changes are one of the things that break batching – a Shader can deal with only one texture (well, actually up to 8 – but that makes the pixel shader more expensive to run), so a set of elements in a batch must be combined into a sprite sheet or texture atlas. If you’ve tried to use a texture atlas in another 2D rendering engine, you may have noticed these are a pain to deal with – and usually it requires setting them up manually before compilation. This is one thing that Backstage2D handles for you – at runtime – in an automagic kind of way.
This feature was actually done for a bunch of reasons. I’d like to add is a resolution (screen DPI) independent measurement mode, where assets get generated on each device an app runs on, from high quality vector art, for exactly the necessary DPI the system is running at, and scaled to real life sizes. Type specified at 12-point, should truly measure at 12-point.
Additionally, Flash vector art looks great (especially with the new 16X16 quality modes), but they look their best when rendered to match the screen exactly. Resizing prerendered vector art can ruin the beautiful anti-aliasing in vector art. Proper sizing can also help performance with older hardware like an iPhone 3GS, which is actually pretty capable, but doesn’t cope well with iPhone 4 retina screen sized material (4x more pixels than will be displayed).
Setting all this up is expensive – especially generating the sprite sheet. But just setting up vector data and loading even predigested textures is already expensive enough that you wouldn’t want to do those tasks while your app is running some smooth animation – it will cause missed frames, and your users will notice. So Backstage2d’s API should guid the user to avoid doing expensive things while an app or animation is running. It exposes a build, load, and/or upload commands per layer. That way, the implementer always knows that what they are doing is computationally expensive (down the road, the plan would be to move much of that into concurrency – more on that another time).
The characteristics of this are very different from normal Flash, which is to load only the minimum of whats needed, when it’s needed, and try to keep as much as you can off the display list. In the Backstage2D model (in the standard surface type anyway), an entire surface, and all it’s children (called “Actors” to avoid colliding with AS3’s “Sprite”, etc.) gets rendered up front to a big TextureAtlas, and stored in memory or on disk. How to optimize and organize your assets to avoid running out of memory becomes an entirely different matter from the way to optimize for the CPU. A surface will have an associated sprite sheet bitmapData asset though, which can be measured.
With these restrictions in mind, the idea would be to create a variety of surface types to suit differing kinds of content. For classic content, a standard static Quads surface (done!), still frame animations (sprite sheet animations – generated at runtime), tweened animations (inverse kinematics – the bone tool), and streaming animations (dynamic MovieClips, large MovieClips, or video) – maybe even some surfaces useful for standard UI, like scroll panes. For more advanced 2D assets, a variety of different mesh layer types could be added (that’s where GPU stage3D programming gets fun!).
I’d love to flesh this out with more features, including an animation subsystem that would include a couple of different Animation display types. Alas, free time is short, and I’ll probably never get to it. But I already spent a lot of time on this (I broke my foot, and was couch bound for a while) so thought I’d share where I got to.
]]>Some quick numbers from the performance-test with 1,000,000 iterations on a Core 2 Duo 2.6GHz (in milliseconds):
Func call time: 15
Runnable call time: 5
Event (1 listener) time: 863
Signal (1 listener) time: 260
SignalLite (1 listener) time: 232
RunnableSignal (1 listener) time: 56
Func call (10 listeners) time: 190
Runnable call (10 listeners) time: 399
Event (10 listeners) time: 2757
Signal (10 listeners) time: 741
SignalLite (10 listeners) time: 725
RunnableSignal (10 listeners) time: 221
The bold line is a vanilla SignalLite, and the line above Robert Penner’s AS3 Signals. They are pretty close, but SignalsLite takes a modest edge. But let’s look at the same test on iOS (iPhone 4S) with 100,000 iterations:
Func call time: 171
Runnable call time: 26
Event (1 listener) time: 3723
Signal (1 listener) time: 789
SignalLite (1 listener) time: 481
RunnableSignal (1 listener) time: 117
Func call (10 listeners) time: 2004
Runnable call (10 listeners) time: 1892
Event (10 listeners) time: 9217
Signal (10 listeners) time: 4030
SignalLite (10 listeners) time: 2074
RunnableSignal (10 listeners) time: 498
On iPhone you can see that SignalLite is almost twice as fast as AS3 Signals – a more substantial difference than on desktop. I’m not sure why that is, maybe the AOT compiler can optimize something about SignalLite better – IDK, but it sure is fast!
Then there’s that last line in each group – RunnableSignal. Now your talking speed. That one also solves a particular problem with function callback systems that they all seem to have – there is no compile time function signature checking. You have to wait until the thing runs, and then find out you are taking the wrong number of arguments, or the wrong type, etc. But, solving one problem (compile time type checking), solves the other (speed), and that brings us to SignalTyped which RunnableSignal in the test above extends (I’ll probably rename at some point).
SignalTyped is beginnings of a fast executing type safe implementation of AS3 Signals. The idea is, you extend 2 classes – SignalTyped and SlotLite. SignalTyped is effectively an abstract class – you must extend it and implement the dispatch method, and the constructor (at least for now, I’m looking for better ways to handle this). It takes a bit of boilerplate to implement this in a class that would expose signals. This example is based on the performance test from Jackson Dunstan’s CallbackTest which I borrowed (I hope that’s ok!):
[sourcecode language=”actionscript3″]
// Interface for your class that might have listeners for the SignalTyped.
// Make one of these per listener type.
interface IRunnable {
function run(): void;
}
// Custom Slot has a specific property for the Runnable class.
class RunnableSlot extends SlotLite
{
public function RunnableSlot( runnable:IRunnable ) {
this.runnable = runnable;
}
public var runnable:IRunnable = new EmptyRunnable;
}
// An empty IRunnable class for first node.
class EmptyRunnable implements IRunnable {
public function run():void {};
}
// You need one of these per dispatch type.
class RunnableSignal extends SignalTyped
{
// last and first must be set to the typed Slot.
public function RunnableSignal() {
last = first = new RunnableSlot;
}
// implement the dispatch method to call the runnable prop directly
// It’s easy to have it take and dispatch any type you want – with compile time type checking!
public function dispatchRunnable():void
{
var node:RunnableSlot = first as RunnableSlot;
while ( node = (node.next as RunnableSlot) ) {
node.runnable.run(); // FAST!
}
}
}
[/sourcecode]
That’s all necessary for the implementation requirements – a lot of boilerplate, I admit. Then you expose that in a class that might use it all:
[sourcecode language=”actionscript3″]
class MyDisplayObject
{
// could probably make this a getter..
public var signaled:RunnableSignal = new RunnableSignal;
}
[/sourcecode]
Now for the consumer to use this, it’s just a bit more boilerplate than a normal signal:
[sourcecode language=”actionscript3″]
class MyConsumerOfSignalLite implements IRunnable // boilerplate point 1
{
public function MyConsumerOfSignalLite()
{
var dspObj:MyDisplayObject = new MyDisplayObject();
// add the signal (boilerplate point 2 – normal)
dspObj.signaled.addSlot( this );
}
// boilerplate 3 – normal, but more strict – naming is specific – FAST!
public function run(): void {
// do whatever when signals
}
}
// boilerplates 2 and 3 are normal for any signal, except the strictness of #3
[/sourcecode]
What’s cool about this is you get compile time type checking for your method signature, and the performance improvement that comes with skipping those checks at runtime.
I’m also thinking about a slightly different signal API that would be more like the Robot Legs’ contract system – think signals by contract – I’m working on it. Since we would be implementing a defined interface per signal type, we could boil the add methods and signal nodes down to one method to add all the listeners of a single object – one add method per dispatching class, instead of one per signal on the dispatching class. This could lead to a reduction in boilerplate. We’d filter by interface type instead of using multiple signal.add nodes and methods. So – improved runtime performance, reduction in (usage) boilerplate (if not implementation) and compile time type checking. I love it!
Note – I tested none of the example in this post, and the code in github is all very early stage stuff. The performance-test class works though – give it a try!
Oh, here’s the github repo:
https://github.com/CaptainN/SignalsLite
I published an old post with my thoughts on the “Flash is Dead” thing that pops up routinely in media circles after anything happens to shake things up (like an Apple ban on Flash, or Adobe dropping a supported platform, etc.) yesterday. I optimistically highlighted in that piece the promise that AIR technology represents – itās even in the title “Flash and AIR, Nothing But Opportunity“. I really believe the technology represents, and could fulfill all the promise those of us down in the weeds perceive. I also believe that Adobeās Flash Platform engineers and evangelists also see that promise, and would like to see it fulfilled.
Yesterday Adobe unceremoniously dropped support for an entire class of platforms. No more Flash Player in mobile browsers. Itās not a terrible technical decision – working in AIR and native app land offers a ton more flexibility. It even makes business sense. Browser makers are increasingly hostile to Flash – Apple has never let it in the door on iOS (and never will), and Microsoft announced plans to kill off plugins even on the desktop in Windows 8 Metro interface. Browsers have become hostile territory for Flash, so it makes sense to move emphasis in the two directions the industry is headed – app store apps with AIR (which no one knows about) and HTML5 for browsers. In an important way, this does mean Flash is dead – itās not going to be in the browser going forward. It really is out of Adobeās control.
But thereās a problem. The longer Adobeās bumbles the messaging, the harder it is to say for sure whether there is a lack of commitment to their platform (including AIR), or if it is truly just a PR problem. This kind of announcement had an easy to predict effect on Flashās brand, yet there was no attempt to get out in front of that narrative that would show they are committed to the larger “Flash Platform” of which AIR is an important part going forward. In the non-technical parts of the industry – the media, managers, and creative side of production teams – they all heard Adobe Flash is out of mobile – use HTML5. Itās even worse in client land, where the term “HTML5 app” is used regularly along with “app store” – this news was so harmful to them, that clients with existing Flash content, which can be ported to the app space easily with AIR, are really freaking out. I can tell them about AIR all I want, but itās hard for me to counteract all the media buzz (repetition is reality – brain science).
But what if they got the right message. This kind of move could represent a real intent on the part of Adobeās leadership to get out of the Flash Platform altogether, and maybe out of the platform space entirely, and focus instead only on tooling to produce for the platform commons that HTML5 represents. Look at the kinds of decisions theyāve made recently. Adobe has essentially dropped internal support for their “Flash Platform” on every system platform they can, by either straight up dumping it (Linux, mobile flash, TV), or by farming out porting and support to partners like RIM.
On the other hand, Adobe and Flash evangelists and engineers seem committed to the “Flash Platform” which in an un-articulated narrative (narrative – itās how we think – more brain science), really means AIR in app stores (mobile and desktop), but Iām not sure Iām getting the same message from the real decision makers at Adobe. I donāt know if itās intent, or just plain old bad PR judgement, but it feels like Iām standing on the greasy platform, and itās getting pretty tough to hold my balance. Some folks are already sliding off.
I think they are in it for the long haul, and they’ve even built some of their own apps on the little known Flash based mobile app technology that is AIR. But guessing someoneās intent is problematic – that only makes the PR problem clearer. I shouldnāt have to guess.
It boils down to this. I know technology, and I know the Flash Platform. I know it has merit and potential. But if people canāt tell if the decision makers at Adobe are serious about supporting it into the future, it’s going to be a tough haul to convince anyone to build anything on that platform. I already know a few platforms, including HTML, learning a new one isnāt scary, but I really prefer Flash and AIR because of itās potential and even itās legacy, which has value (despite the tar Steve Jobs dumped on it). If Adobe canāt or wonāt make it clear that they are committed to AIR and the Flash Platform, Iāll have to find an alternative – and the decision wonāt be mine. At this point, we need a clear unambiguous statement of intent from Adobe – are you committed to the Flash Platform and AIR, or not? A public roadmap wouldnāt hurt either.
]]>In the technology business, if you aren’t looking ahead, you are being left behind. There is fundamental shift occurring in the content technology space, where Flash and HTML live their happy lives. This shift has mostly been explained using old terms, like “apps” and “HTML5 vs. Flash” – these explanations miss the point. They all describe how things were yesterday and are today, but miss how they will be tomorrow. The browser has been and is today, the primary means of application and content delivery. A new set of opportunities for delivering content are changing all that. The Split puts the traditional desktop browser market on one side, and app stores on new platforms, with new hardware, and new interface paradigms on the other.
App stores should be more broadly called content stores, because the line between apps and other kinds of content is pretty thin. Market specific content stores have been around for a while already on the desktop. Game shops like Steam and Direct2Drive already make up the lion’s share of the PC games market, and iTunes was already a form of an app store, before apps where apps.
The companies behind every platform are adopting apps stores, including all major operating systems on traditional PCs, including OSX, and soon Windows. Open source trail blazers like Ubuntu have actually had something like app stores for a long while now. Additionally, more and more types of content are being pulled into them, from apps, to music and movies, to Magazines and local newspapers. The models for monetization are so much clearer, and the tools to take advantage of the various models are already built, and for the consumer, very convenient. App stores are the new reality.
To really understand why this is happening, and what it means for those of us who make a living in the weeds, we need to understand where we are, and how we got here.
The PC Era
In the early days of personal computing, “applications” (or “programs”) were the hot action. You needed something to do with your new beige personal computer (PC), so you bought (or borrowed) software or other types of content on diskettes, and later CD-ROM (oh the magic) and installed that software to run on your PC or Mac. It was an offline process, but it was the only realistic way to go. Even if you had access to the internet, you weren’t going to download megabytes of data over your cutting edge 14.4KB fax/modem connection. Traditional forms of acquisition ruled in those days. You had to take yourself to the store, and buy a box or a publication or whatever else, to obtain content – probably paying with cash.
When the internet hit mainstream in the 90s, and data speeds increased, the transition from “applications” delivered through boxed diskettes, to continuously updated “websites” began.Ā The internet had some advantages over boxed content. The biggest was that accessing a web site through the internet was exceedingly convenient for consumers. Far more convenient than traveling to the store and buying a box with a CD of clip art on it. For content producers there is also a sense of limitless shelf space compared with traditional retail outlets, so they were quick to try to carve out advantage there. Search engines and content indexing services like Google and Yahoo! made a killing on both ends by providing a way for content producers to get their content in front of users.
Broadband completed the transition. At the dawn of the new millennium and “the internet,” became the primary means of content and application delivery (aside from a few important smaller markets like games and productivity apps). The browser was the primary means of application and content delivery, and for good reason. The content is easy to access from multiple platforms, and is super convenient. All you need is an internet connection, and a browser.
A Flash of brilliance
At around the same time, Microsoft mostly won “the browser wars” with Internet Explorer 6, and basically stopped forward movement in their browser, and for many years, the internet – the commerce in the browser era’s “website” based economy was able to mature. The stagnant development of the dominant browser platform created a challenging environment, one in which it’s easy to see why Flash was able to thrive.
Flash brought many improvements over the browser, through constant performance and scriptability advancements, as well as significant additional features the browsers in the aggregate simply couldn’t match – video being an important notable feature. Additionally, Flash provided consistency across browsers and operating systems, and comparably great performance, when measured against HTML and JavaScript. A browser-based app simply couldn’t (still can’t) match it. Flash in the browser became the go to platform for serious interactive work on the internet. You just couldn’t get similar levels of awesome out of IE6 and the rest of the browsers of the time.
All good things
The split started to happen in 2006. On the PC, which really means in the PC browser, Adobe was getting more serious about the application space in the browser by releasing the first version of Flash with AVM2 (and s 3.0), a much more stable foundation than Actionscript 2.0 had been, along with an update to its application framework, Flex that took advantage of the improvements to Actionscript 3.0. This helped move trends in Flash’s direction, as seemingly every great site was build using the plugin technology. IE7 had come out that same year, but it only added to developers’ pain in the short-term, and it still wasn’t the robust interoperable platform that browser ecosystem needed to compete in the applications space. So in that space, movement continued toward Flash.
This could be considered the golden age for Flash. Flash ruled the content space during that time, in everything from banner ads, to browser-based games, to anything dealing with charts, and data (so-called RIAs), to just about all the video delivery on the internet.
Browsers didn’t come without problems. They have been slow to innovate, incompatible with one another – universally slow, buggy and crashy – and often full of horrible security holes (especially IE – the dominant player). They were mired in standards battles, forks, company and social politics (open source/EU fines) – but mostly, the leader – Microsoft with IE6, just held everything up. On top of all that, it was difficult for content producers, like traditional newspapers, to find revenue sources other than ad systems. The market was set for change.
That’s about when Apple fired the first warning shots across the bows of the PC browser fleet, by releasing the first iPhone, which could browse the internet, but didn’t run Flash. A brand new platform – software and hardware, with a brand new interface paradigm – touch, instead of mouse and keyboard. This would be a platform built from the lessons of the browser era, and it provided a wide open space for Apple to do what it does best. They rapidly iterated on their ecosystem, and came up with the overwhelmingly successful App Store, a system that seemingly everyone wanted in to. This was a system that came with multiple obvious revenue systems built right in – app sales, technology cross-licensing, advertising, etc. – all things that could be done in the browser space, but the app store made exceedingly convenient, to both producers and consumers. Apple catered to that demand masterfully, and over time expanded opportunities to include, in-app purchases, magazine publishing platforms, and subscriptions services, among others.
In the same way the internet – the modern PC era – had provided enough advantages over the previous content delivery systems to overshadow any of its shortcomings, the App Store model would provide enough promise to overshadow its possible shortcomings measured against its predecessor. App stores proved so compelling, and so big a threat to the existing browser-based models, it almost immediately ended a cozy relationship between Apple and Google, who ruled the browser era, as the gatekeeper to content, and the owner of essentially all advertising on the web. Google moved quickly to duplicate the app systemĀ for Android, and the other platform makers – WebOS, and Microsoft Windows Phone 7 Series – have been playing catch-up ever since. Eventually, Apple brought the app store system to the desktop in OSX Lion, and even Microsoft is picking it up in their Windows 8 Metro interface for full app store coverage in the traditional PC markets.
The rapidly evolving iPhone (later iOS) platform created new ways to think about a lot things. The most important new things were app and content delivery, and revenue sources through new monetization strategies. The Apple App Store changed everything.
The end of an era
When Apple released the iPad in April, 2010, Steve Jobs announced the “end of the PC era.” With the release of the iPad Apple did nothing less than complete and publish the rule book rewrite they began with the iPhone. More than anyone else, the folks at Apple seemed to understand that there is a divide between the “PC era” – which is really the “PC browser era” – and the new app store era. They understood that these two are on two different trajectories, and the app store era will supersede the browser. From now on, for better or for worse, applications would exist in App Stores, and websites would just be websites.
In the same month Apple announced the iPad, Steve Jobs followed up with a special letter in his open letter titled “Thoughts on Flash”, which highlighted some of the negatives of the browser-based “PC era,” where Flash was settling in as the dominant platform. The letter also exploited a division between the Flash crowd and the standards and open source crowds. And he directly addressed the āfull web,ā – Adobe’s tone-deaf name for “the PC era”. In that direct critique Jobs highlighted the disadvantages of the new app store model, by putting the “full web” flash apps in the “free” – or unprofitable box, and painting the technology with the old brush. Even the main part of the label “PC” is an old term, from a time that came before the modern browser era.
That letter was truly a brilliant piece of market positioning magic, but it was ultimately unnecessary, and Apple has since backed off. The app store model provides a marvelous promise without the need to degenerate the old browser based economy. Content makers, all of whom struggled to find revenue from websites, now have multiple new revenue streams to explore, through app sales, and licensing, and other kinds of content transactions within apps.
During the PC Era, browsers dominated users’ mind share, and time on the PC, native applications were still the clear leaders in performance, access to hardware, and close integration with the underlying OS platform. Despite that advantage, native apps were hamstrung by seemingly insurmountable inconvenience – the boxed distribution model – an inconvenience that most online distribution stores of the time simply duplicated (download, unzip setup, run setup, store setup file somewhere in case you lose your hard drive, etc.).
App stores solve these native application distribution problems by providing a central hub for content, simple e-commerce (no more credit card into the random unverified website), and can be integrated with the legacy system – the website.
My head hurts.
So what does this all mean for us, the front line Flash developers? It means opportunity. There are now three platforms to develop for!
Yeah, that’s right – three.
The transition to app stores on the desktop will take a while to roll out, and old habbits die hard, and Flash will stick around in that space for .. well, as long as that space exists. There are still a chunk of 98%+ of the user out there on the internet, still accessing the web through their existing PCs. That won’t change overnight. Even initiatives like Microsoft’s plugin blockade with Windows 8 and Metro mode take effect, they will come hand in hand with app stores, so there’s a workaround.
But let’s get real for a second, the Flash Player – in the browser – sits at the core of entire new lucrative markets on the PC, in the browser. Take browser era social gaming andĀ Zynga – a game company, with a quirky social media, micro-transaction game library, integrated with Facebook’s social platform, is more profitable than top traditional PC game companies like E.A. Flash in the browser is having a grand time. Stage3d was just released, Unreal Engine was shown running on it at MAX. Flash is still tops for the best kinds of awesome on the internet.
Second, you have all the HTML5 opportunity – not directly relevant for Flash devs (yet), but for those of us that have had their hands in both worlds this whole time, this is exciting! HTML, JavaScript and CSS are finally getting to the point where you can build really awesome stuff with it. And, for app store monetization to work, discovery is key. Searchable HTML (and HTML5) will dominate for that. App stores are easy to search and easy to link into – from a website. Websites aren’t going anywhere – in every way, the app store model can’t work without the browser based internet.
And finally, the new kid on the block, the app store. For Flash devs, that means AIR – which is essentially Flash for app stores. If you have Flash (or even HTML) skills to burn, you can almost, just recompile your Flash app for AIR. Adobe has built this amazing tool – the best kept secret they didn’t mean to keep (don’t get me started on their PR). The sky is the start with AIR for Mobile, never mind the limit (Apollo indeed). The best part is, once you build for one app store with AIR, you can build for basically all of them, with very little additional effort.
Have a look at Machinarium. A traditionally packaged standalone desktop app, made with Flash, and distributed in a box through traditional outlets (and the specialty PC app stores, like Steam) with an online demo that runs in the desktop browser in Flash Player. Now republished for the Apple App Store with AIR and some optimizations, to run on iPad as a native app.
So where are we? Flash is alive and kicking – thriving even – despite the clueless ramblings of know-nothing media pundits and their bandwagon seeking behavior. You don’t need to listen to them, just get out there, and make cool apps/websites/games/whatever else with the same technology you’ve always used. These are exciting times.
]]>
Some caveats – this only tests instances of flash.display.Bitmap on the display list, at the size they are, moving the way they move. It’s on my list to add Blitting (I have some initial work on that done, thanks to Iain, but I need to add the rotation, and alpha settings to it), and I’d like to add a vector test, and maybe some extra sized Bitmaps (I’ve heard that makes a difference).
Enough! Here are some results – quality had no effect on GPU mode, so I included only one line:
Note: some are reporting they see a difference in GPU mode, but I still don’t. Update: It appears some users are confusing “Mobile Performance Tester” with BunnyMark, which explains the discrepancy. BunnyMark is not currently in any App Store, which is one key distinguishing feature.
BunnyMark Results – 500 Bunnies | |||||||||
---|---|---|---|---|---|---|---|---|---|
Alpha | ā | ā | ā | ||||||
Rotation | ā | ā | ā | ā | |||||
CaB | ā | ā | ā | ā | ā | ||||
CaBM | ā | ā | |||||||
iPhone 3GS – GPU | |||||||||
FPS | 24 | 18 | 17 | 22 | 13 | 13 | 19 | 1 | 19 |
iPhone 3GS – CPU | |||||||||
FPS-L | 28 | 21 | 19 | 9 | 19 | 5 | 7 | 5 | 5 |
FPS-M | 28 | 21 | 19 | 4 | 18 | 3 | 7 | 5 | 3 |
FPS-H | 28 | 21 | 19 | 3 | 18 | 2 | 7 | 5 | 2 |
FPS-B | 28 | 21 | 19 | 3 | 18 | 2 | 7 | 5 | 2 |
iPhone 4 (Retina) – GPU | |||||||||
FPS | 25 | 21 | 20 | 25 | 13 | 13 | 16 | 0.5 | 16 |
iPhone 4 (Retina) – CPU | |||||||||
FPS-L | 32 | 23 | 20 | 10 | 21 | 6 | 8 | 6 | 7 |
FPS-M | 32 | 23 | 20 | 5 | 20 | 3 | 8 | 6 | 3 |
FPS-H | 32 | 23 | 19 | 4 | 20 | 2 | 8 | 6 | 2 |
FPS-B | 32 | 23 | 19 | 4 | 20 | 2 | 8 | 6 | 2 |
Notes about the Benchmark:
It’d be nice to have more benchmarks for more devices, but I only have the above devices available. This should run just fine on Android, Blackberry Playbook, and iPads. If anyone wants to contribute a set of benchmarks, hit the comments. Here is the source. One of these days I’ll make another post, and try to draw some conclusions, maybe wrap the bullet points into a narrative, and edit some of this, but the tables are there, and the source code, and that’s the important stuff.
In the midst of playing with this benchmark, I found (or was pointed at) some great resources. Here are some of them:
Here is the Benchmark to see it in action:
Download unBrix Alpha and let me know what you think! I’d provide a link, but I don’t know how.
Update: I Nerfed the framerate a bit to get it to run a little smoother. I think the problem will be solved better by setting NO_SCALE, but I’ll have to do that another time (probably when I get to iPad port!). I also fixed the red line, and the icon too (I don’t know that didn’t show up last time). There is a report of the paddle jumping to one side when some users remove their finger from the screen. I haven’t been able to reproduce, but please let me know if this happens to you! Here is a link to unBrix Alpha on appbrain (it isn’t showing the update yet).
Update 2: I switched to CPU rendering, because it seems as though GPU rendering is just slower on Android devices than CPU rendering – at least in this kind of game. Anyway, this solved a lot of problems, including missing text and missing affects. I also had to set a fullScreenRect to match the original intended size of the game (iPhone 3Gs size). Doing these two things cleaned up most of the performance issues and graphics glitches. I’ll work on getting the remainder of the basics in place, like proper shutdowns – so this doesn’t run in the background like it does now (didn’t have to worry about that for iOS!).
]]>This won’t run at 60FPS on Android Flash Player plugin in the browser (or Firefox on Mac!) – this post is about the iPhone build – but here’s the web version to look at anyway.
Here is a blurry video of the thing running as a native iPhone app on a 3GS (I smoothed out the choppy splash transition in a later build by setting the BG element with cacheAsBitmapMatrix):
The most important thing was to make sure GPU acceleration was working, and to learn what things will impact performance in that area.
It turns out, there are some important differences with how GPU accelerated Flash woks compared with the traditional software renderer. In the software Flash renderer keeping your display list shallow, and sparse (using addChild/removeChild a lot) or avoiding the display list completely (by writing to BitmapData – as the Flixel game engine does) is a key optimization for performance. This is how the exploding bunny video demo is done, and why it’s so fast.
My current theory is that on GPU accelerated content (even on desktop) the reverse is true. You want to avoid CPU/system RAM to GPU/video RAM updates as much as possible – which means avoiding BitmapData updates which cause the player to upload a new texture to the GPU VRAM with every update. Because I don’t have access to the internals of the Flash Player architecture, I can’t be sure, but I think the bottle neck comes from clogging up the lanes between the CPU and GPU, and all stressing all three areas of the rendering pipeline (CPU, GPU and the bus) as they juggle around objects in memory. The key observation this conclusion is based on is the large performance impact addChild and removeChild has on the framerate. So I relentlessly avoid that in my iPhone Flash development – I precache everything, and don’t mess with the display list. This is also one reason why filters (which operate on a BitmapData representation of the DisplayObject you apply them to) are not recommended on mobile content.
Anyway, hopefully I can turn this into a full app for iPhone in a reasonable timeframe.
]]>Steve Jobs is full of crap. I could actually understand and respect a straightforward admission that the Flash Platform is a threat to Apple’s iOS business model – which is the real reason Jobs won’t let Flash on the iPhone and iPad. That’s not even a very good reason – the App Store has many compelling features on it’s own, even if Flash is in the browser, not the least of which is the easy to understand path to monitization. Performance is another issue – Flash is fast enough, faster than JS/Canvas by quite a bit, but it’s still not as fast as a native app and all it’s OpenGL goodness (among all the other great Apple APIs). Keeping Flash off iPhone (and especially CS5 iPhone apps) has nothing to do with performance, or compatibility. That’s just bunk! And nobody likes a liar.
/rant
Here are some screenshots to show how well many sites I’ve been involved with work in Flash on the iPhone (3GS using jailbreak and Frash).
A quit note on the technology: this is using Frash, which is a hack (a wrapper or compatibility layer) to get the Android version of Flash Player 10.1 running inside of iOS – it has not been optimized (or even completed at this point) to run well on iOS yet, and probably will never run as well as it can on Android. A recent test app I’ve been playing with runs 50% faster on a Droid Eris, vs. the iPhone 3GS – the Eris is slower hardware, running Android 2.1. It’s also crashy, and is missing features like streaming movie support (it does work with videos embedded in a swf) – and touch events are not quite as streamlined as they are on a real Android device (hover works better on Android for example, and hot spots are easier to hit). It’s also got all the quirks of the Wii and desktop Flash Player’s “noscale” feature (on Android there is a workaround that solves this, not implemented in Frash yet).
I just like to point that out, because some users are judging the viability of Flash on iOS/iPhone/iPad based on this hack (which is current at version 0.02), which is beyond silly.
For anyone interested, I followed these instructions to install it on my iPhone. Note: this uses SSH and dpkg to install. If you don’t know how to reverse that, you may want to find an apt repo and use Cydia to grab this, so you can uninstall Frash when you are done playing, as it can be quite unstable.
]]>I wanted to see how far I could push that exploding Actionscript 3.0 code – see if Flash could handle updating each animating pixel every frame, while playing a video, then blurring it. Sure enough, it can! It did take further optimization from the version I posted the other day – including swapping copyPixels with getPixel/setPixel, and removing an anonymous function call (wow that was expensive!). Here it is:
Note: This WILL run like slush on the debug player. I don’t know why. If anyone knows why, please let me know!
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