Reversing the slider
Following is a very brief explanation of how the script works, including a suggestion for getting it to reverse the direction and 'unswipe' cards. The reverse direction method was inspired by Rocky's excellent answer - he deserves full credit for the idea.
Once the document is loaded the script gets a list of all available cards. In your example the cards are hard coded elements in the DOM, and the list of cards,
listElNodesObj, is a list of those elements. This is important to remember: the cards are not an abstraction, they are fundamentally elements within the page. When you add media and data to your cards you will have to do so by attaching it to elements in the DOM (e.g. with data attributes).
The script gets the current card index called
currentPosition; to begin with this is the top card. It then displays the current card and the two cards behind it (
currentPosition + 1 and
currentPosition + 2).
On an input the card is appropriately animated to fly off the left, right or top. The current card index is incremented by one, advancing by one into the stack. The new current card and the two cards behind it are displayed.
At the moment all actions - swipe left, right and top - all advance into the stack. To reverse the direction you need to listen for a new action (or repurpose a current one such as swipe top), and on that action the current card index is decremented by 1. Add a check for less than zero.
currentPosition = Math.max( 0, currentPosition - 1 );
Rocky has answered with an excellent solution that implements this.
Now this implementation begins with all cards already present in the DOM. You appear to want to update your stack of cards from a backend API. To do this you need a way of popping the card off one end and adding a new one on the other end when swiping. As stated above your list of cards is tied very closely to the DOM so you will need to abstract it a little to achieve this. Create a list of elements that you fill from your API and populate your initial document with it (instead of the other way around). When you swipe, whether forwards or back, pop an element off the receding end and add a new element, populated from your API, to the advancing end. Interestingly both your list size and your current position will always stay the same.
If your current position is always one back from the top-most card, and the last card in the stack is one more than the last visible card, you will always have a card ready to animate into view.
A slight clarification of terms here: Altering something like
opacity causes a repaint, removing an element from the DOM, whether soft or hard removal, causes a reflow. Repaints are expensive because the browser must check the visibility of every element in the DOM; reflows are even more expensive because the layout must be recalculated. See What's the difference between reflow and repaint?
There are two ways you could limit the number of cards in the DOM. You could set
display: none which leaves it in memory and the DOM, but prevents the browser from considering it when reflowing or repainting. Or you could use
parent.appendChild(child) to add a card and
opacity: 0 will remain fully in the DOM for reflowing and repainting.
As to what gives the best performance: changing the opacity or removing from memory, that really depends on your implementation. I can give you a few relevant pointers though.
Memory constraints "Is there a limit as to how many cards should be in DOM?" Absolutely, but this depends on your data. If you have a very small total amount of cards you could indeed load them all at the beginning and hide swiped ones with
opacity: 0 or
display: none. The animation fluidity might even be improved (see point on animation blocking computations below). The performance difference purely from higher memory use will almost certainly be unnoticeable as modern browsers have oodles of memory and will stop your script well before it needs pagefile or swap. If you really will have such a huge DOM in memory that performance would noticeably degrade, your content download time would be a much bigger issue.
However, much more to the point, you rightly ask if removing or adding elements is the whole point of a virtual list. Why keep an element in memory if you will never access it again, or why load an element that is so far down the list it may never be reached. Indeed you state that you will be accessing content from an API which strongly implies you'll be accessing the card content one at a time. Waiting till you have all the content from your API may take a very noticeable length of time; as you already seem to be aware it would provide a better experience to only access the cards that you need to fill a fixed size list. (If you intend to reverse the direction of the slider then you should keep at least one swiped card in memory so that when swiping back you aren't ruining the animation by pausing or sending an empty card as you wait to download the content)
Animation Blocking Computations Download times aside, the real performance advantage of
display: none and
opacity: 0 for cards that are swiped or are too far back in the list is that their content is already present in the DOM. (And as stated above,
opacity: 0 has one further advantage: it does not trigger a reflow). By comparison physically adding and removing elements from the DOM requires an extra computation, namely inserting or removing the card node and all its children in the DOM tree. If this is done synchronously then you will have an animation blocking computation, whereby the swipe animation cannot take place until the DOM tree update is completed.
Finally, every DOM manipulation is a new render update so you want to do as few manipulations as possible. You would therefore create the elements against each other in memory and only at the very end insert the highest element into the DOM. See Fastest DOM insertion . If you can contain all card data within that card then each swipe would require just two DOM manipulations. It depends on what media the cards contain, but it's conceivable that, at worst, adding and removing cards to the stack will take only tens of milliseconds in combined time.
GPU Most rendering engines have access to a GPU which can achieve far better efficiency than the CPU in drawing and compositing operations that involve large numbers of pixels. Render layers are not rendered with the GPU by default. The page GPU Accelerated Compositing in Chrome states,
While in theory every single RenderLayer could paint itself into a separate backing surface [i.e. a GPU accessible compositing layer], in practice this could be quite wasteful in terms of memory (VRAM especially).
In summary, the performance increase due to dynamically adding and removing elements from the virtual list, while potentially marginally higher than having the entire list fully loaded, is likely to be only a extra few milliseconds per swipe. With an asynchronous implementation, the frame rate during the animation should not change. This should normally be an easy concession for the likely large savings in initial download time, but must be considered in conjunction with other details of your particular implementation.