The contenteditiable attribute allows for the editing of content within any valid HTML5 element. By default, elements implicitly inherit edibility from their parent element unless explicitly defined.
The contenteditiable attribute is an enumerated attribute with three states which map to the four keywords:
The true state indicates that the element is editable; it is specified by the ("" Empty String) or true keywords.
The false state indicates that the element is editable; it is specified by the false keyword.
The inherit state indicates that the element is editable if it’s immediate parent element is editable.
The following examples provide basic “live” demonstrations and source implementations of the contenteditiable attribute. (Note: These examples assume an HTML5 compatible Browser which support this attribute.)
As you can see, enabling and disabling an editable element in HTML5 is quite simple with the addition of the contenteditiable attribute. This allows for some very interesting possibilities when implemented in conjunction with many of the other new features in HTML5; specifically, the Web Storage API and the spellcheck attribute.
The Web Timing Specification (draft) aims at providing a standard set of APIs which allow for true end-to-end instrumentation of page load times across browsers.
To quote the w3 spec: “This specification (Web Timing Specification) defines an interface for web applications to access timing information related to navigation and elements.” The API is based on the Navigation Timing and Resource Timing interfaces, respectively.
While I haven’t seen this specification mentioned as part of the HTML5 Family before, in many ways I would consider it to be a worthy candidate for membership as it provides a standards based API through which web applications can be tested for load efficiency. This is obviously something quite useful for any web application as, the ability to precisely measure page load times – and implement optimizations as needed – affords developers the opportunity to provide an improved user experience.
Historically, the ability to accurately measure page load times of web applications has been quite challenging for a number reasons. Just knowing when and where to begin is debatable and, determining the best means of doing so can be a challenge in of itself. Regardless of any current strategies being used, the result is never entirely accurate. With Web Timing developers need not be concerned with these specifics as the API provides the ability to truly measure page load times by encompassing the full scope of loading and parsing a page. This includes the time involved to request, receive and render an HTML document.
For more information, try out the examples in the current supported browsers; IE9, Chrome 6.
“If everyone is moving forward together, then success takes care of itself.” – Henry Ford
The HTML5 Family of Technologies has been receiving considerable coverage lately; and, rightfully so, as, many next generation browsers – specifically those in the Mobile space based on WebKit: Android, iPhone, iPad, Blackberry etc. are now beginning to implement it’s specification, or parts thereof. On the Desktop more HTML5 support is also being seen in the latest versions of Chrome, Firefox, Safari, IE9 and Opera.
The HTML5 Family of technologies will without question play a vital role in the future of the web; and currently, in the mobile Web space, that future is now.
A Brief Overview of the HTML5 Family
For anyone who is unfamiliar with what has been termed “The HTML5 Family“, allow me to provide succinct overview of the technologies which I feel encompass what has already become a rather overloaded term. In general, on a very high level, I would summarize the HTML5 Family simply as follows:
While the above could be considered the umbrella Technologies upon which The HTML5 Family is based, there are certainly more associated technologies which themselves further augment what could be considered the HTML5 Family, some of which are (based on current specification status at the time of this writing ):
Web Storage (localStorage, sessionStorage) APIs
Web SQL Database API
Web Workers API
Web Sockets API
First, HTML5. HTML5 is the next major revision of HTML which aims to advance the open Web through web standards and semantically rich content. HTML5 defines an emphasis on semantic structure and meaning.
In general, HTML5 provides a content model which can be broadly defined into the following categories: Metadata content, Flow content, Sectioning content, Heading content, Phrasing content, Embedded content and Interactive content as well as form-associated elements etc.. HTML5 defines new tags such as canvas, audio, video, keygen, header, footer, nav, article, aside, datalist and more.
HTML5 Microdata provides a mechanism which allows machine-readable data to be embedded in HTML documents in the form of annotations, with an unambiguous parsing model. Microdata is compatible with numerous data formats such as JSON. Micro-data is intended to provide a standard to replace other similar concepts such as RDFa, from which browsers and other applications can discover relevant content based on the context of an applications markup. Such examples include markup for contact information, calendar events and more. This markup is understood by HTML5 compatible browsers which can then automatically offer to add the relevant content to the appropriate application. At an implementation level, microdata simply consists of a group of name-value pairs; with the groups being called items, and each name-value pair is a property.
The HTML5 Geolocation API is rather straightforward; it simply provides a means by which the location of a device can be determined via a native API (as opposed to say, determining the clients IP address). The Geolocation spec is currently in last call status in the W3C.
Device APIs are client-side APIs which allow for direct interaction with native device services such as a device Camera, Calendar, Contacts etc.
Web Storage API
The Web Storage API allows for the persistence of local (permanent) and session based (browser session) data on the client. The API for Web Storage is extremely simple as it is based upon simple Key / Value pairs; with which Keys are simply Strings. Each site contains its own separate storage area.
Web SQL Database
While not a part of the actual HTML5 specification, the Web SQL Database presents some extremely interesting possibilities within Web Applications. The Web SQL Database provides a set of APIs which allow for the manipulation of client-side databases using SQL. The Web SQL Database is based upon SQLite (3.1.19) thus supporting the features as specified therein.
Web Workers API
Web Workers provide a mechanism by which web content can execute scripts in background threads. Web Workers allow for a much needed multi-threaded implementation for web based applications executing in a browser. While somewhat similar, Web Workers are different from threads in that they are primarily intended for executing long running, expensive computations and algorithms so as to facilitate non-blocking UI background processes. One specific aspect of Web Workers which has considerable positive implications for the web moving forward is that they run in native threads as opposed to Green Threads; as is the case in VM architectures. This is quite significant as it essentially means Web Workers can scale vertically. Considering the inevitable proliferation of multi-core desktop and mobile devices, this is certainly something that will prove advantageous.
Web Sockets API
If you are interested in learning more about each of these technologies I recommend the following resources:
Moving forward, I plan to go into further detail for each of these associated HTML5 Family technologies, providing working examples and detailed information as to how each can be utilized to create some very unique and interesting possibilities on the Web.