Shader-based dynamic video manipulation

Abstract

Real-time video manipulation techniques include performing shader-based graphical operations on user interface elements based on the state of an interactive video and the properties associated with the user interface elements at the state. The user interface elements are rendered into frames of the interactive video, and transparent interactive elements are layered over the user interface elements. In another technique, video frames in an interactive video include viewable and non-viewable regions. While the video is playing, the viewable regions are modified based on information in the non-viewable regions, thereby generating modified versions of the video frames.

Description

FIELD OF THE INVENTION

The present disclosure relates generally to digital video and, more particularly, to systems and methods for manipulating video in real-time using shaders.

BACKGROUND

Providing streaming video poses numerous technical challenges, which are multiplied when there is a need to modify or add to the video in real-time as it is being presented to a viewer. In the case of web-based video, elements can be layered on the video using HyperText Markup Language (HTML) or Cascading Style Sheets (CSS); however, this inevitably leads to a degradation in performance. This negative effect on performance is especially true for elements having features that requiring complex rendering, such as opacity, animation, color changes and textures. Weaker or older mobile devices are especially susceptible to degradation in animation frame count, which can lead to a poor user experience and increased battery use. Existing solutions that layer and filter videos together either cannot do so in real-time during presentation of the video or are adapted for special use cases (e.g., providing a virtual background for a live camera stream).

SUMMARY

In one aspect, a computer-implemented method for real-time video manipulation includes the steps of identifying a state of an interactive video; determining properties associated with a user interface (UI) element at the state; receiving a next frame of the interactive video; rendering the UI element into the next frame of the interactive video, wherein the rendering comprises using a shader to perform a graphical operation on the UI element based on the properties; and when the next frame of the interactive video is displayed, layering a transparent interactive element over the UI element rendered into the next frame. Other aspects of the foregoing include corresponding systems and computer programs on non-transitory storage media.

Other implementations of the foregoing aspects can include one or more of the following features. The state of the interactive video can comprise information associated with a user's traversal of a path within the interactive video. The state of the interactive video can comprise information associated with one or more UI elements displayed during presentation of the interactive video. Determining the properties associated with the UI element at the state can comprise determining properties of the UI element that changed from a previous state. The rendering can comprise using a web-based graphics framework to render the next frame over an HTML-based canvas element. The method can further comprise performing each of the identifying, determining, receiving, rendering and layering steps for a plurality of frames of the interactive video. The UI element can comprise a video or animation, and the rendering can comprise using a shader to render each frame of the video or animation into a corresponding frame of the interactive video. The method can further comprise using a shader to render an additional graphical element in the next frame. The UI element can have a first depth level and the additional graphical element can have a second depth level, and the UI element and the additional graphical element can be rendered in the next frame in an order based on their respective depth levels. The method can further comprise, during playback of the interactive video, dynamically modifying the depth level of the UI element and/or the additional graphical element based on changes in the state of the interactive video.

In another aspect, a computer-implemented method for real-time video manipulation comprises the steps of receiving a video comprising a plurality of frames, wherein the frames each comprise a viewable region and a non-viewable region; and for each frame of the plurality of frames, in real time while the video is playing: modifying at least part of the viewable region of the frame based on information in the non-viewable region of the frame, thereby generating a modified version of the frame; and displaying the modified version of the frame within the video Other aspects of the foregoing include corresponding systems and computer programs on non-transitory storage media.

Other implementations of the foregoing aspects can include one or more of the following features. The non-viewable region of the frame can comprise a mask. Modifying the at least part of the viewable region of the frame can comprises using the mask to identify one or more areas in the viewable region of the frame; and performing a graphical operation on the one or more areas. The graphical operation can comprise a shader operation. Performing the graphical operation on the one or more areas can comprise providing, as input to an algorithm, a color associated with a pixel within the one or more areas; receiving, as output from the algorithm, a replacement color; and modifying the pixel to have the replacement color. The mask can be rotated relative to the viewable region of the frame. The mask can be the same in each frame of the plurality of frames. The mask can differ between at least two frames of the plurality of frames. The viewable region of the frame can be larger than the non-viewable region of the frame. The viewable region of the frame can comprise a first viewable region, and the frame can further comprise a second viewable region, and the first viewable region and the second viewable region can be manipulated with respect to each other based on the information in the non-viewable region of the frame.

Further aspects and advantages of the invention will become apparent from the following drawings, detailed description, and claims, all of which illustrate the principles of the invention, by way of example only.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete appreciation of the invention and many attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings. In the drawings, like reference characters generally refer to the same parts throughout the different views. Further, the drawings are not necessarily to scale, with emphasis instead generally being placed upon illustrating the principles of the invention.

FIG. 1 depicts a high-level architecture of a system for providing interactive video content, according to an implementation.

FIG. 2 depicts server-side and client-side components of an application for providing interactive video content, according to an implementation.

FIG. 3 depicts an example method for rendering user interface elements in interactive video using shaders.

FIG. 4 depicts an example of rendering animation or video into an interactive video using shaders.

FIG. 5 depicts non-shader-based and shader-based approaches to providing interactive video.

FIG. 6 depicts an example process for shader-based rendering of layers with varying depths in real-time.

FIGS. 7A-7D depict an example use of a filter framework to change wall color in a video.

FIG. 8 depicts an implementation of a filter graph within a filter framework.

FIG. 9 depicts an example video frame with multiple video regions.

DETAILED DESCRIPTION

Described herein are various implementations of methods and supporting systems for using shaders to manipulate and edit a video in real-time, while it is playing. In the case of web-based video (e.g., video embedded on a webpage and viewed through a web browser or native mobile app), relying on HTML-based or CSS-based mechanisms to manipulate video, overlay graphics, or perform other layouting or styling operations can use significant central processing unit (CPU) resources. This results in a reduction in parallel operations and, ultimately, poorer video playback performance. The present disclosure overcomes this issue through the use of shader code that can directly communicate with a graphics processing unit (GPU). By using shaders, the video can be manipulated (e.g., user interface (UI) elements can be drawn on the video, colors can be changes, effects can be added) in real-time without the need to use HTML tags and CSS properties. The benefit of the GPU's enhanced ability to perform graphical operations, compared to a CPU, is realized.

Improving the performance of real-time video manipulation is particularly useful in the case of interactive video, where it may be desirable to manipulate portions of a particular video rather than have a separate video for every possible choice. For example, shader code can be used to change the color of car appearing in a single video, which uses less bandwidth and storage than providing a separate video for each possible color choice.

Interactive Media System

FIG. 1 depicts an example high-level architecture of such a system for providing interactive video content. Application 112 executes on a user device 110 and receives a media presentation, which can include multiple video and/or audio streams. The media presentation can be presented to a user on user device 110, with application 112 capable of playing and/or editing the content. The user device 110 can be, for example, a smartphone, tablet, laptop, desktop, palmtop, television, gaming device, virtual reality headset, smart glasses, smart watch, music player, mobile telephone, workstation, or other computing device configured to execute the functionality described herein. The user device 110 can have output functionality (e.g., display monitor, touchscreen, image projector, etc.) and input functionality (e.g., touchscreen, keyboard, mouse, physical buttons, motion detection, remote control, etc.).

Media content can be provided to the user device 110 by content server 102, which can be a web server, media server, a node in a content delivery network, or other content source. In some implementations, the application 112 (or a portion thereof) is provided by application server 106. For example, some or all of the described functionality of the application 112 can be implemented in software downloaded to or existing on the user device 110 and, in some instances, some or all of the functionality exists remotely. For example, certain video encoding and processing functions can be performed on one or more remote servers, such as application server 106. In some implementations, the user device 110 serves only to provide output and input functionality, with the remainder of the processes being performed remotely.

The user device 110, content server 102, application server 106, and/or other devices and servers can communicate with each other through communications network 114. The communication can take place via any media such as wireless links (802.11, Bluetooth, GSM, CDMA, etc.), standard telephone lines, LAN or WAN links, broadband connections, and so on. The network 114 can carry TCP/IP protocol communications and HTTP/HTTPS requests made by a web browser, and the connection between clients and servers can be communicated over such TCP/IP networks. The type of network is not a limitation, however, and any suitable network can be used.

More generally, the techniques described herein can be implemented in any suitable hardware or software. If implemented as software, the processes can execute on a system capable of running one or more custom operating systems or commercial operating systems such as the Microsoft Windows® operating systems, the Apple OS X® operating systems, the Apple iOS® platform, the Google Android™ platform, the Linux® operating system and other variants of UNIX® operating systems, and the like. The software can be implemented on a computer including a processing unit, a system memory, and a system bus that couples various system components including the system memory to the processing unit.

The system can include a plurality of software modules stored in a memory and executed on one or more processors. The modules can be in the form of a suitable programming language, which is converted to machine language or object code to allow the processor or processors to read the instructions. The software can be in the form of a standalone application, implemented in any suitable programming language or framework.

Method steps of the techniques described herein can be performed by one or more programmable processors executing a computer program to perform functions of the invention by operating on input data and generating output. Method steps can also be performed by, and apparatus of the invention can be implemented as, special purpose logic circuitry, e.g., an FPGA (field programmable gate array) or an ASIC (application-specific integrated circuit). Modules can refer to portions of the computer program and/or the processor/special circuitry that implements that functionality.

Processors suitable for the execution of a computer program include, by way of example, both general and special purpose microprocessors, and any one or more processors of any kind of digital computer. Generally, a processor will receive instructions and data from a read-only memory or a random access memory or both. The essential elements of a computer are a processor for executing instructions and one or more memory devices for storing instructions and data. Information carriers suitable for embodying computer program instructions and data include all forms of non-volatile memory, including by way of example semiconductor memory devices, e.g., EPROM, EEPROM, and flash memory devices; magnetic disks, e.g., internal hard disks or removable disks; magneto-optical disks; and CD-ROM and DVD-ROM disks. One or more memories can store media assets (e.g., audio, video, graphics, interface elements, and/or other media files), configuration files, and/or instructions that, when executed by a processor, form the modules, engines, and other components described herein and perform the functionality associated with the components. The processor and the memory can be supplemented by, or incorporated in special purpose logic circuitry.

It should also be noted that the present implementations can be provided as one or more computer-readable programs embodied on or in one or more articles of manufacture. The article of manufacture can be any suitable hardware apparatus, such as, for example, a floppy disk, a hard disk, a solid state drive, a CD-ROM, a CD-RW, a CD-R, a DVD-ROM, a DVD-RW, a DVD-R, a flash memory card, a PROM, a RAM, a ROM, or a magnetic tape. In general, the computer-readable programs can be implemented in any programming language. The software programs can be further translated into machine language or virtual machine instructions and stored in a program file in that form. The program file can then be stored on or in one or more of the articles of manufacture.

Interactive Media Presentations

The media presentations referred to herein can be structured in various forms. For example, a particular media presentation can be an online streaming video having multiple tracks or streams that a user can interactively switch among in real-time or near real-time. For example, a media presentation can be structured using parallel audio and/or video tracks as described in U.S. Patent Application Pub, No. 2016/0105724, published on Apr. 14, 2016, and entitled “Systems and Methods for Parallel Track Transitions,” the entirety of which is incorporated by reference herein. More specifically, a playing video file or stream can have one or more parallel tracks that can be switched among in real-time automatically and/or based on user interactions. In some implementations, such switches are made seamlessly and substantially instantaneously (within milliseconds), such that the audio and/or video of the playing content can continue without any perceptible delays, gaps, or buffering. In further implementations, switches among tracks maintain temporal continuity; that is, the tracks can be synchronized to a common timeline so that there is continuity in audio and/or video content when switching from one track to another (e.g., the same song is played using different instruments on different audio tracks; same storyline performed by different characters on different video tracks, and the like).

Such media presentations can also include interactive video structured in a video tree, hierarchy, or other form or structure. A video tree can be formed by nodes that are connected in a branching, hierarchical, or other linked form. Nodes can each have an associated video segment, audio segment, graphical user interface (GUI) elements, and/or other associated media. Users (e.g., viewers) can watch a video that begins from a starting node in the tree and proceeds along connected nodes in a branch or path. Upon reaching a point during playback of the video where multiple video segments (child nodes) branch off from a segment (parent node), the user can interactively select the branch or path to traverse and, thus, the next video segment to watch.

As referred to herein, a particular branch or path in an interactive media structure, such as a video tree, can refer to a set of consecutively linked nodes between a starting node and ending node, inclusively, or can refer to some or all possible linked nodes that are connected subsequent to (e.g., sub-branches) or that include a particular node. Branched video can include seamlessly assembled and selectably presentable multimedia content such as that described in U.S. Patent Application Pub. No. 2011/0200116, published on Aug. 18, 2011, and entitled “System and Method for Seamless Multimedia Assembly”, and U.S. Patent Application Pub. No. 2015/0067723, published on Mar. 5, 2015, and entitled “Methods and Systems for Unfolding Video Pre-Roll,” the entireties of which are hereby incorporated by reference.

The prerecorded video segments in a video tree or other structure can be selectably presentable multimedia content; that is, some or all of the video segments in the video tree can be individually or collectively played for a user based upon the user's selection of a particular video segment, an interaction with a previous or playing video segment, or other interaction that results in a particular video segment or segments being played. The video segments can include, for example, one or more predefined, separate multimedia content segments that can be combined in various manners to create a continuous, seamless presentation such that there are no noticeable gaps, jumps, freezes, delays, or other visual or audible interruptions to video or audio playback between segments. In addition to the foregoing, “seamless” can refer to a continuous playback of content that gives the user the appearance of watching a single, linear multimedia presentation, as well as a continuous playback of multiple content segments that have smooth audio and/or video transitions (e.g., fadeout/fade-in, linking segments) between two or more of the segments.

In some implementations, different nodes in a video tree can have the same video segment, audio segment, UI elements, or other properties. For example, multiple nodes can use the same base video segment but have different audio playing or different UI elements depicted depending on which node in the tree the viewer has reached. As another example, shaders can be used to manipulate the base video segment based on user choices, with each different manipulation (user choice) resulting in a different path being traversed in the video tree and a different node being reached.

In some instances, the user is permitted to make choices or otherwise interact in real-time at decision points or during decision periods interspersed throughout the multimedia content. Decision points and/or decision periods can occur at any time and in any number during a multimedia segment, including at or near the beginning and/or the end of the segment. In some implementations, a decision period can extend over multiple multimedia segments. Decision points and/or periods can be predefined, occurring at fixed points or during fixed periods in the multimedia content segments. Based at least in part on the user's choices made before or during playback of content, one or more subsequent multimedia segment(s) associated with the choices can be presented to the user. In some implementations, the subsequent segment is played immediately and automatically following the conclusion of the current segment, whereas in other implementations, the subsequent segment is played immediately upon the user's interaction with the video, without waiting for the end of the decision period or the end of the segment itself.

If a user does not make a selection at a decision point or during a decision period, a default, previously identified selection, or random selection can be made by the system. In some instances, the user is not provided with options; rather, the system automatically selects the segments that will be shown based on information that is associated with the user, other users, or other factors, such as the current date. For example, the system can automatically select subsequent segments based on the user's IP address, location, time zone, the weather in the user's location, social networking ID, saved selections, stored user profiles (as further described below), preferred products or services, and so on. The system can also automatically select segments based on previous selections made by other users, such as the most popular suggestion or shared selections. The information can also be displayed to the user in the video, e.g., to show the user why an automatic selection is made. As one example, video segments can be automatically selected for presentation based on the geographical location of three different users: a user in Canada will see a twenty-second beer commercial segment followed by an interview segment with a Canadian citizen; a user in the US will see the same beer commercial segment followed by an interview segment with a US citizen; and a user in France is shown only the beer commercial segment.

Multimedia segment(s) selected automatically or by a user can be presented immediately following a currently playing segment, or can be shown after other segments are played. Further, the selected multimedia segment(s) can be presented to the user immediately after selection, after a fixed or random delay, at the end of a decision period, and/or at the end of the currently playing segment. Two or more combined segments can form a seamless multimedia content path or branch, and users can take multiple paths over multiple play-throughs, and experience different complete, start-to-finish, seamless presentations. Further, one or more multimedia segments can be shared among intertwining paths while still ensuring a seamless transition from a previous segment and to the next segment. The content paths can be predefined, with fixed sets of possible transitions in order to ensure seamless transitions among segments. The content paths can also be partially or wholly undefined, such that, in some or all instances, the user can switch to any known video segment without limitation. There can be any number of predefined paths, each having any number of predefined multimedia segments. Some or all of the segments can have the same or different playback lengths, including segments branching from a single source segment.

Traversal of the nodes along a content path in a tree can be performed by selecting among options that appear on and/or around the video while the video is playing. In some implementations, these options are presented to users at a decision point and/or during a decision period in a content segment. Some or all of the displayed options can hover and then disappear when the decision period ends or when an option has been selected. Further, a timer, countdown or other visual, aural, or other sensory indicator can be presented during playback of content segment to inform the user of the point by which he should (or, in some cases, must) make his selection. For example, the countdown can indicate when the decision period will end, which can be at a different time than when the currently playing segment will end. If a decision period ends before the end of a particular segment, the remaining portion of the segment can serve as a non-interactive seamless transition to one or more other segments. Further, during this non-interactive end portion, the next multimedia content segment (and other potential next segments) can be downloaded and buffered in the background for later playback (or potential playback).

A segment that is played after (immediately after or otherwise) a currently playing segment can be determined based on an option selected or other interaction with the video. Each available option can result in a different video and audio segment being played. As previously mentioned, the transition to the next segment can occur immediately upon selection, at the end of the current segment, or at some other predefined or random point. Notably, the transition between content segments can be seamless. In other words, the audio and video continue playing regardless of whether a segment selection is made, and no noticeable gaps appear in audio or video playback between any connecting segments. In some instances, the video continues on to another segment after a certain amount of time if none is chosen, or can continue playing in a loop.

In one example, the multimedia content is a music video in which the user selects options upon reaching segment decision points to determine subsequent content to be played. First, a video introduction segment is played for the user. Prior to the end of the segment, a decision point is reached at which the user can select the next segment to be played from a listing of choices. In this case, the user is presented with a choice as to who will sing the first verse of the song: a tall, female performer, or a short, male performer. The user is given an amount of time to make a selection (i.e., a decision period), after which, if no selection is made, a default segment will be automatically selected. The default can be a predefined or random selection. Of note, the media content continues to play during the time the user is presented with the choices. Once a choice is selected (or the decision period ends), a seamless transition occurs to the next segment, meaning that the audio and video continue on to the next segment as if there were no break between the two segments and the user cannot visually or audibly detect the transition. As the music video continues, the user is presented with other choices at other decisions points, depending on which path of choices is followed. Ultimately, the user arrives at a final segment, having traversed a complete multimedia content path.

Interactive Media System Detailed Architecture

FIG. 2 depicts one implementation of a detailed architecture of components in application 112 on user device 110, including inputs received from remote sources, such as content server 102 and application server 106. Client side components include Profile Manager 212, Interactive State Manager 216, Inputs Collector 244, User Experience (UX) Manager 254, Loading Manager 262, Video Appender 270, Properties Extractor 236, and Frames Render 274. Profile Manager 212 receives user profile information from User Profile 210, which can exist locally on the client (user device 110) or, as depicted, be obtained externally from a remote server (e.g., content server 102 or application server 106). Profile Manager 212 can also provide information characterizing a user for storing back in User Profile 210. A different User Profile 210 can exist for each identifiable viewer of a media presentation, with each user identified by a unique ID and/or identification technique (e.g., a cookie stored locally on the user's device). Default user profile information can be provided when a viewer is anonymous or cannot otherwise be identified.

User Profile 210 can include information collected through a user's interaction with an interactive video and an interactive media player, as well as information obtained from other sources (e.g., detected location of user's device, information made available through a user's social media account, information provided by the user when creating an account with a provider of the interactive media player, and so on). Profile Manager 212 can use the information in User Profile 210 to cause the presentation of an interactive video to be dynamically modified, e.g., by adapting choices and content presented to the user to the user's previous or current behavior, or otherwise changing the presentation of the interactive video from its default state. For example, based on information in User Profile 210, Profile Manager 212 can direct Interactive State Manager 216 to select only a subset of choices (e.g., 2 of 3 choices) to provide to a viewer approaching a decision point, where Interactive State Manager 216 would otherwise provide a full set of choices (e.g., 3 of 3 choices) by default during presentation of the interactive video. Profile Manager 212 can also receive information from Inputs Collector 244 (this information can include, e.g., user interactions) and Interactive State Manager 216 (this information can include, e.g., a currently selected path in a video tree), which can be used to update User Profile 210. In some implementations, information in User Profile 210 can be used to modify the state of the interactive media player itself.

Inputs Collector 244 receives user inputs 240 from input components such as a device display screen 272, keyboard, mouse, microphone, virtual reality headset, and the like. Such inputs 240 can include, for example, mouse clicks, keyboard presses, touchpad presses, eye movement, head movement, voice input, etc. Inputs Collector 244 provides input information based on the inputs 240 to Profile Manager 212 and Interactive State Manager 216, the latter of which also receives information from Profile Manager 212 as well as a Project Configuration File 230 to determine which video segment should be currently played and which video segments may be played or presented as options to be played at a later time (e.g., influenced by information from the User Profile 210). Interactive State Manager 216 determines the interactive state of the presentation based on the Project Configuration File 230, inputs 240, start and end nodes, and other events in the system. Interactive State Manager 216 notifies Video Appender 270 of the current interactive state, and Video Appender 270 selects the video segment to be currently played based on the interactive state and seamlessly connects that video segment to the video stream being played in real time, via Frames Render 274, which renders the video frame-by-frame, as images. Interactive State Manager 216 notifies Loading Manager 262 of the current interactive state so that Loading Manager 262 (based on the interactive state and Project Configuration File 230) can retrieve video segments that may be played or presented as options to be played at a later time.

Project Configuration File 230 can include information defining the media presentation, which can include the video tree or other structure, video files, how video segments can be linked together in various manners to form one or more paths, external assets, and other project specific data. Project Configuration File 230 can further specify which audio, video, and/or other media files correspond to each segment (e.g., node in a video tree), that is, which audio, video, and/or other media should be retrieved when application 112 determines that a particular segment should be played. Additionally, Project Configuration File 230 can indicate interface elements that should be displayed or otherwise presented to users, as well as when the elements should be displayed, such that the audio, video, and interactive elements of the media presentation are synchronized. Project Configuration File 230 can be stored on user device 110 or can be remotely accessed by Interactive State Manager 216.

In some implementations, Project Configuration File 230 is also used in determining which media files should be loaded or buffered prior to being played (or potentially played). Because decision points can occur near the end of a segment, it may be necessary to begin transferring one or more of the potential next segments to viewers prior to a selection being made. For example, if a viewer is approaching a decision point with three possible branches, all three potential next segments can be preloaded partially or fully to ensure a smooth transition upon conclusion of the current segment. Intelligent buffering and progressive downloading of the video, audio, and/or other media content can be performed as described in U.S. Patent Application Pub. No. 2013/0259442, published Oct. 3, 2013, and entitled “Systems and Methods for Loading More Than One Video Content at a Time,” the entirety of which is incorporated by reference herein.

Using information in Project Configuration File 230, Interactive State Manager 216 can inform UX Manager 254 which external assets 228 should be retrieved (e.g., buttons, pictures, animation, text, and other interface elements to be overlaid or incorporated into a video and displayed to viewers on screen 272). Properties Extractor 236 extracts properties relating to the external assets (e.g., dimensions, position, rotation, color, opacity, animation, etc.) 228 from the UX Manager 254 and sends the properties to UX—Frame Render 250. UX—Frame Render 250 communicates, directly or indirectly, with a device GPU to incorporate graphical changes into the individual frames rendered by Frames Render 274, prior to display on screen 272. The graphical changes can be based on information provided by Properties Extractor 236. UX—Frame Render 250 can use shaders to accomplish the foregoing.

In some implementations, UX—Frame Render 250 uses a framework or engine that provides graphics rendering operations. For example, Web Graphics Library (WebGL) frameworks, used for general purpose two-dimensional (2D) and three-dimensional (3D) graphics rendering over HTML5 canvas elements, can be used to animate image frames and, thereby, render video. Shader support allows such frameworks to be used to render UI elements and perform other graphical operations within image frames. Available frameworks include: (1) Three s (made available at threejs.org), a cross-browser JavaScript Application Programming Interface (API) used to create and display animated 3D computer graphics in a web browser; (2) Babylon.js (made available at babylonjs.com), a real-time 3D engine using a JavaScript library for displaying 3D graphics in a web browser; (3) Verge3D (made available at soft8soft.com), a real-time renderer and a toolkit used for creating interactive 3D experiences running on websites; and (4) Pixi.js (made available at pixijs.com), a 2D rendering library over WebGL. In addition, certain cross-platform game engines support WebGL over HTML5 canvas, and so can be used to render video and perform shader operations on the video. Examples include: (1) Unity (available at unity.com), a cross-platform game engine that supports rendering via WebGL/WebGL2; (2) Unreal Engine (available at unrealengine.com), an engine that supports WebGL-based rendering through WebAssembly; and (3) Godot Engine (available at godotengine.org), which supports rendering via WebGL2.

Project Configuration File 230 can further indicate the specific timings for which actions can be taken with respect to the interface elements (e.g., when a particular element is active and can be interacted with). The interface elements can include, for example, playback controls (pause, stop, play, seek, etc.), segment option selectors (e.g., buttons, images, text, animations, video thumbnails, and the like, that a viewer can interact with during decision periods, the selection of which results in a particular multimedia segment being seamlessly played following the conclusion of the current segment), timers (e.g., a clock or other graphical or textual countdown indicating the amount of time remaining to select an option or next segment, which, in some cases, can be the amount of time remaining until the current segment will transition to the next segment), links, popups, an index (e.g., for browsing and/or selecting other multimedia content to view or listen to), and/or a dynamic progress bar such as that described in U.S. Patent Application Pub. No. 2014/0082666, published Mar. 20, 2014, and entitled “Progress Bar for Branched Videos,” the entirety of which is incorporated by reference herein. In addition to visual elements, sounds or other sensory elements can be presented. For example, a timer can have a “ticking” sound synchronized with the movement of a clock hand. The interactive interface elements can be shared among multimedia segments or can be unique to one or more of the segments.

In addition to reading information from Project Configuration File 230, Interactive State Manager 216 is notified of user interactions (e.g., mouse clicks, keyboard presses, touchpad presses, eye movements, etc.) from Inputs Collector 244, which interactions can be translated into actions associated with the playback of a media presentation (e.g., segment selections, playback controls, etc.). Based thereon, Interactive State Manager 216 notifies Loading Manager 262, which can process the actions as further described below. Interactive State Manager 216 can also interface with Loading Manager 262 and Video Appender 270. For example, Interactive State Manager 216 can listen for user interaction information from Inputs Collector 244 and notify Loading Manager 262 when an interaction by the viewer (e.g., a selection of an option displayed during the video) has occurred. In some implementations, based on its analysis of received events, Interactive State Manager 216 causes the presentation of various forms of sensory output, such as visual, aural, tactile, olfactory, and the like.

As earlier noted, Interactive State Manager 216 can also notify Loading Manager 262 of the current interactive state, which can indicate which video segments may be played at a later time, and Loading Manger 262 can retrieve the corresponding videos 225 (whether stored locally or on, e.g., content server 102) to have them prepared for potential playback through Video Appender 270 and Frames Render 274. Interactive State Manager 216 and Loading Manager 262 can function to manage the downloading of hosted streaming media according to a loading logic. In one implementation, Interactive State Manager 216 receives information defining the media presentation structure from Project Configuration File 230 and, using information from Inputs Collector 244 and Profile Manager 212, determines which media segments to download and/or buffer (e.g., if the segments are remotely stored). For example, if Interactive State Manager 216 informs Loading Manager 262 that, based on the current interactive state, a particular segment A will or is likely to be played at an upcoming point in the presentation timeline, Loading Manager 262 can intelligently request the segment for download, as well as additional media segments X, Y and Z that can be played following segment A, in advance of playback or notification of potential playback thereof. The downloading can occur even if fewer than all of X, Y, Z will be played (e.g., if X, Y and Z are potential segment choices branching off segment A and only one will be selected for playback).

In some implementations, Loading Manager 262 ceases or cancels downloading of content segments or other media if it determines that it is no longer possible for a particular media content segment (or other content) to be presented on a currently traversed media path. Referring to the above example, a user interacts with the video presentation such that segment Y is determined to be the next segment that will be played. The interaction can be received by Interactive State Manager 216 and, based on its knowledge of the path structure of the video presentation, Loading Manager 262 is notified to stop active downloads or dequeue pending downloads of content segments no longer reachable now that segment Y has been selected.

Video Appender 270 receives media content from Loading Manager 262 and instructions from Interactive State Manager 216 on which media segments to include in a media presentation. Video Appender 270 can analyze and/or modify raw video or other media content, for example, to concatenate two separate media streams into a single timeline. Video Appender 270 can also insert cue points and other event markers, such as junction events, into media streams. Further, Video Appender 270 can form one or more streams of bytes from multiple video, audio or other media streams, and feed the formed streams to Frames Render 274 such that there is seamless playback of the combined media content on display screen 272 (as well as through speakers for audio, for example).

In some implementations, application 112 tracks information regarding user interactions, users, and/or player devices, and stores the information in a database. Collected analytics can include, but are not limited to: (1) device information, such as number, type, brand, model, device location, operating system, installed software, browser, browser parameters, user agent string, screen size, bandwidth, and network connection parameters; (2) user tracking and demographic data, such as login information, name, address, age, sex, referrer, uniform resource locator (URL), urchin tracking module (UTM) parameters; (3) user or automated action information, such as button/touchpad presses, mouse clicks, mouse/touchpad movements, action timings, media player controls (play, pause, volume up/down, mute, full screen, minimize, seek forward, seek backward, etc.), link outs, shares, rates, comments; (4) information associated with interactions with interactive media content, such as decisions made by users or made automatically (e.g., content segment user choices or default selections), starting a node, ending a node, and content paths followed in the presentation content structure; and (5) information associated with media playback events and timing, such as loading events, buffering events, play and pause events. The analytics can include those described in U.S. Patent Application Pub. No. 2011/0202562, entitled “System and Method for Data Mining within Interactive Multimedia,” and published Aug. 18, 2011, the entirety of which is incorporated by reference herein. In one instance, some or all of these analytics are included in or used to inform attributes in User Profile 210.

As earlier described, the transition between multimedia segments in an interactive media presentation can be seamless such that there is no noticeable gap or change in audio, video, and/or context between the segments. For example, with respect to audio, a seamless transition can include voices, music, or other sounds continuing uninterrupted from one segment to the next, or otherwise not having noticeable breaks or interruptions between segments. With respect to video, a seamless transition can include video content continuing uninterrupted from one segment to the next, visually (e.g., the segments, when joined together, appear to be one continuous video) and/or contextually (e.g., the segments depict different scenes in a continuous storyline). Normally, to effect a seamless transition between two segments, the end of one segment (or the end of a decision period) has to join seamlessly to the next segment. When the transition occurs at the end of a decision period, the user experiences a delay between making a decision and seeing the effect of the decision.

Various techniques can be used to address the issue of transition delay and create seamless transitions that feel immediate to the user (e.g., occurring in less than 1 second after the user's decision, or other reasonably imperceptible delay). In one implementation, to create a seamless audio transition between two segments in a media presentation, audio content is muted or faded out during the decision period in the first segment. Once a decision is made during the decision period, the presentation immediately transitions to a different segment corresponding with the decision and audio is resumed (e.g., unmuted or increased in volume). In another implementation, some of the audio in the first segment replaces audio in the next segment. For example, if a user makes a decision with two seconds left in the decision period of the first segment, the presentation can immediately transition to the next segment, but the audio associated with the two seconds remaining in the decision period is then played instead of the two seconds of audio that would normally be played at the beginning of the next segment. It should be appreciated, however, that a shorter period of audio than that remaining in the decision period can be substituted at the beginning of the next segment. To ensure a fully seamless transition, the audio associated with the next segment can be formed to allow for such substitutions without resulting in a noticeable skip or gap in audio.

Shaders in Interactive Media Presentations

One of skill in the art will appreciate the numerous ways in which the videos described herein can be manipulated using shaders. For example, shaders can be used in interactive video to apply real-time graphical effects, such as altering the color of objects or scenery in the video in response to viewer interactions. As another example, interface elements, such as those described above, can be graphically incorporated into video using shader code, rather than overlaying the elements on top of the video using HTML, for example.

FIG. 3 depicts an example method for rendering UI elements in interactive video using shaders. During presentation of an interactive video, a new interactive state is identified (Step 302) (see Interactive State Manager 216, described above). The interactive state can include various properties associated with the current state of the video, including the current node of the viewer within the video tree, node start, node end, paths in the tree taken by the viewer, choices selected, other interactions that affect the interactive state, and so on. The interactive state can also include properties associated with UI elements 352 displayed to a viewer during presentation of the interactive video. For example, the interactive state can include one or more of the following: (1) UI element appears, (2) UI element disappears, (3) UI element hovered, (4) UI element no longer hovered, (5) UI element selected, (6) UI element de-selected, (7) UI element animation start, and (8) UI element animation stop. In FIG. 3, an interactive button 332 is used as the UI element for purposes of illustration; however, it is to be appreciated that nearly any UI element (e.g., slider, switch, index, timer, etc.) can be rendered in a similar manner.

In Step 304, the current properties of UI elements in the new interactive state are determined by Properties Extractor 236, including any properties of the elements that changed with the new interactive state. In this example, the static appearance of the button (i.e., a non-interactive button 334) as it exists in the new interactive state is extracted. Properties of UI elements can include, but are not limited to, dimensions (e.g., width and height), position (e.g., x, y, and z coordinates), rotation, color, opacity, animation (e.g., current or next frame of animation), video asset (e.g., current or next frame of video), item type, character, video bitmap change, and so on. If the UI element is interactive (e.g., tappable, clickable, etc.), a transparent element with the same or similar position and dimensions as the UI element is created (Step 306), and the transparent element is configured to be interactive. As shown in FIG. 3, a transparent, clickable button 336 having the same dimensions and position as button 332 is created.

In Step 308, the next video frame 338 from the video 354 is identified (e.g., by Frames Render 274). In one implementation, WebGL is used to render the video 354 frame-by-frame on an HTML, canvas element as a sequence of images. Proceeding into Step 310, the non-interactive UI element (here, non-interactive button 334) is rendered into video frame 338. For example, UX—Frame Render 250 can use shaders to instruct a GPU to draw non-interactive button 334 into video frame 338 to create a non-interactive composite video frame 340. To make the UI element rendered into the frame interactive, a transparent interactive UI element is layered on the non-interactive UI element (Step 310). As shown in FIG. 3, the clickable transparent button 336 is layered on the non-interactive button element in the non-interactive composite video frame 340, resulting in an interactive composite video frame 342 with a clickable button.

The technique described with respect to FIG. 3 can be used to dynamically incorporate UI elements and other graphical assets and features into video. Such other graphical features can include manipulation of opacity, coloring, texture and animation in real-time using shaders. For example, in a character selection screen in an interactive video, all unselected characters can be blurred using shader effects. In addition, complex effects can be added to video through shaders such as animations with easing functions and varying opacity, real-time color changes, complex texturing, and pixel-based effects. When the assets being incorporated into a video are animations or other videos, shader-based operations can include: (1) rendering video in the foreground over UI elements while one or more videos are playing in the background, (2) rendering multiple videos on the same canvas element, (3) blending video streams, and (4) transitioning from one video stream to another, including through graphical transition effects. Incorporated video and animation properties can also change based on the content of the video or animation. For example, if the incorporated animation is a moving bus, the rendering location for the animation within the video frame can change over time as the animation shows the bus driving in a particular direction, thereby corresponding with the movement of the bus.

FIG. 4 depicts an example of rendering animation or video into an interactive video using shaders. Video frame 402 has a defined area 422 into which animation or video can be rendered. However, specific areas within the frames need not be defined, and an animation or video element can be rendered into a video frame based on properties associated with the element, such as x and y coordinates and dimensions. Video frame 402 is one of multiple frames in a sequence of frames forming a video of a landscape. Video frame 404 includes an image of a sign. Video frame 404 is one of multiple frames in a sequence of frames forming a video of an animated sign 424. A shader operation is used to render the sign 424 in frame 404 into defined area 422 of the landscape video frame 402, thereby forming a non-interactive composite video frame 406 depicting the landscape and sign 424 in combination. Similar to the process depicted in FIG. 3, to make the non-interactive compositive video frame 406 interactive, a transparent layer 408 with an interactive element 428 (e.g., a clickable button) is added on top, resulting in interactive video frame 410. The process can continue on a frame-by-frame basis, using shader operations to render each frame of the animated sign 424 into corresponding frames of the landscape.

In some implementations, the resulting video after shader operations have been performed has elements that are incorporated into the video frame using shaders, as well as elements that are layered on top of the video (e.g., using HTML5) without being “baked in” with shaders. In some implementations, the resulting video has one or more transparent areas such that a background area is visible through the transparent areas of the resulting video when it is played. In some implementations, multiple videos and UI/UX elements are used to form a single interactive video. When the interactive video is played over a network using a player application, the player application can download multiple different videos from one or more sources to include in the interactive video. In another implementation, the player application can access multiple different videos existing within a single video (e.g., each video frame is split into different videos). Examples of the foregoing are described in U.S. Patent Application Pub. No. 2015/0104155, published Apr. 16, 2015, and entitled “Systems and Methods for Real-Time Pixel Switching,” the entirety of which is incorporated by reference herein. Ultimately, an interactive presentation is formed that is seamless across audio and/or video.

In some implementations, shader operations are used for more complex layering and compositing operations. The top portion of FIG. 5 depicts a typical non-shader based approach to form an interactive video 515 by adding a UX layer 511 to a video layer 510. This approach can be accomplished by, for example, layering the UX elements on top of an HTML5 canvas over the video 510. However, this technique is limited in that all of the UX components are in the foreground with respect to the video (i.e., layered over all of the video). The bottom portion of FIG. 5 depicts a shader-based approach where multiple graphical elements (video and UX layers 520-523) can be composited to form an interactive video 525 in which UX elements can be disposed in front of and behind video elements. As shown, the duck video 520 is rendered first as the background, and shader operations are used to render the first UX element 521, then the frog video 522, and, finally, the second UX element 523. As a result, the interactive video 525 appears to have the first UX element 521 in front of the duck video 520, but behind the frog video 522. The second UX element 523 is in the foreground, in front of everything else. Different layers can be assigned different depth (z-index) values, and the depth values are used to determine the order in which the layers are rendered with respect to one another. In FIG. 5, the duck video 520 can have depth value=0, the first UX element 521 can have depth value=1, the frog video 522 can have depth value=2, and the second UX element 523 can have depth value=3. Some layers can have the same depth value and can be rendered at the same level.

In some implementations, the depth value for a particular layer is fixed. In other implementations, the depth value for a particular layer dynamically varies based on the interactive state of an interactive video presentation, properties associated with the device being used to view the presentation, or other factors. FIG. 6 depicts an example process for shader-based rendering of layers with varying depths in real-time. In Step 605, the interactive state is obtained. Step 605 can be performed continuously on a video frame-by-frame basis, every N frames (e.g., 2 frames, 5 frames, 15 frames, etc.), every N seconds (e.g., 0.1 seconds, 0.5 seconds, 1 second, 2 second, etc.), or other interval. In Step 610, the frames of each video layer 650 to be rendered into the interactive video are obtained. In one example, at time T=30.5 seconds in the interactive video, the interactive state at that time (T=30.5 s) and the frame of each of the video layers 650 to be displayed at that time (T=30.5 s) are obtained. In Step 615, the UI elements 640 and the obtained frames of video layers 650 are rendered as a frame of the interactive video by their depth (Z) values. As shown in FIG. 6, the UI elements include elements to be rendered at depth levels 1, 3, and 4, and the video layers 650 include video to be rendered at depths 2, 5, and 6. The process can be repeated for each rendered frame of the interactive video. In some implementations, rendering is performed in advance of the rendered frames being displayed, thereby buffering video for later presentation in the interactive video.

As one example of dynamically varying rendering depths, if a viewer of an interactive video hovers over an interactive user interface element that is rendered in or toward the background, the depth value associated with that element can be changed to render it in or closer to the foreground in further frames of the interactive video. As another example, if a viewer of an interactive video selects an option to drive a bus instead of a car, video associated with the bus can be moved toward the foreground and/or video of the car can be moved toward the background, in each case by adjusting the depth value of the applicable video layer. As a result, both the bus and car videos can continue to be displayed simultaneously in the interactive video, but the car video will appear behind the bus video (and behind any other video, UX or other layers having a depth level closer to the foreground than the car video). As another example, video and UI elements can be rendered at different depths depending on whether the viewer is watching an interactive video on an iPhone versus other mobile phone brands.

Filter Framework

The filter framework that will now be described allows for the manipulation and editing of a video in real-time, while it is playing (e.g., changing the colors of the walls of a room, blurring a background, etc.). The filter framework can use a mask encoded into the video that is then decoded during playback and used to perform graphical operations on the video. Advantageously, because the mask is part of the video, it can change from frame-to-frame, for example, to correspond to changes in the viewable video.

In one implementation, metadata is encoded into individual frames of a video (e.g., every frame, every other frame, every X frames, etc.). The metadata can be encoded via red-green-blue (RGB) values, for example. The video frames that include metadata can have one or more regions of the frame allocated to video and one or more regions of the frame allocated to metadata. When the video is played, some or all of the metadata regions in a particular frame are combined with some or all of the video regions in that frame. Based on the metadata in the metadata regions, graphical operations are performed on the corresponding video regions that the metadata regions are combined with. In one example, a frame of a video includes a video region making up 75% of the area of the frame, with a metadata region in the form of a pixel mask making up the remaining 25%. While the video is played, the metadata region is collapsed into the video region so that the video has the dimensions of the video region. The metadata region can remain the same size and overlap with a portion of the video region, or the metadata region can be resized (e.g., stretched to cover a larger portion of or the entire video region). The RGB values of the pixels in the mask of the metadata region can be used to determine the particular operations to perform. For example, individual bits of a pixel in particular combinations can specify a graphical add operation, subtract operation, multiply operation, mask operation, and so on. The existing pixel color in the video region can be used as input to a shader that performs the desired operation and outputs the resulting pixel color. Other inputs can be provided to the shader (e.g., a different pixel color that the existing pixel color should be blended with). Multiple shaders can be chained together to produce a final effect.

FIGS. 7A-7D depict an example of a use of the foregoing technique where the intent is to change wall color of a room in a video in real-time while the video is playing. User interface elements can be provided that allow the viewer to select different colors and see the color of the walls in the video change in real-time substantially immediately following the color selection. Referring to FIG. 7A, the video frame 700 includes a viewable region 710 comprising video and a comparatively smaller non-viewable region comprising a mask 720. In this example, the mask 720 fills the entire non-viewable region; however, this is not a requirement. The mask 720 is rotated in one direction ninety degrees with respect to the video in the viewable region 710 to utilize the full dimensions of the video frame 700. It should be noted, however, that the numbers, dimensions, and respective placements of the viewable and non-viewable regions in the video frame 700 are illustrative, and variations are contemplated For example, there can be multiple viewable regions and multiple non-viewable regions. As another example, a viewable region and non-viewable region can have the same dimensions, the same width, the same height, or entirely different dimensions. As another example, the non-viewable region need not be rotated with respect to the viewable region.

Now referring to FIG. 7B-7C, while a video containing the frame is being played for a viewer, prior to the frame being displayed, the mask 720 is separated from the original frame, rotated ninety degrees in the opposite direction, superimposed onto the viewable region 710, and then aligned to fit back in the original frame size. In this example, the viewable region 710 is square and the mask 720 has the same width as the viewable region 710, but has a smaller height than the viewable region 710. As such, when rotated and aligned with the top of the viewable region 710, the mask 720 does not fully cover the viewable region 710. Because the mask 720 defines where graphical operations are performed in the viewable region 710, it has no effect on the lower portion 740 of the viewable region 710 not covered by the mask 720. The mask 720 is used to designate where graphical operations should be performed. No operations are performed on pixels covered by the black-colored area of the mask 720, while the white-colored areas of the mask 720 designate the areas where operations are performed. For example, each pixel covered by a white-colored area in the mask 720 can be altered based on a color replacement algorithm. The color replacement algorithm can be a graphical operation performed by a GPU.

FIG. 7D depicts the video frame 750 resulting from the graphical operations, in which the walls of the room have changed color. The viewable region 760 in the resulting video frame 750 has smaller dimensions than the initial video frame 700 (here, the viewable region 760 is square-shaped and has the same height as the initial video frame 700 but a smaller width). As such, the viewable region 760 is centered in the resulting video frame 750 with black bars on either side 755. In some implementations, the video player that plays the video recognizes a designated viewable area for the video and crops or resizes the video so only the designated viewable area is seen. For example, some or all of viewable region 760 can be made visible to a viewer of the video whereas the black bars 755 (and potentially some of the viewable region 760) can be hidden. The above operations can be repeated for multiple consecutive frames in a video to graphically manipulate the video in real-time.

In one implementation, the filter framework is built on HTML5 canvas and WebGL technologies and allows filters (e.g., WebGL shaders) to be composed and connected together to perform multiple shader-based operations. The framework can provide built-in filters (e.g., mask, blur, color replace, video replace, crop, resize, rts, etc.) which have customizable parameters (e.g., blur amount, crop frame, etc.). The framework can provide a mechanism that allows a user to define a filter graph or how filters connect to each other. In one implementation, the mechanism is a JavaScript Object Notation (JSON) language. For example, if the user specifies [mask, blur] as the filter graph, the original video would be masked out and then blurred, resulting in a blurry mask.

Referring back to the example depicted in FIGS. 7A-7D, a filter graph can be defined that includes three filters: VideoResize (isolates the square viewable region 710), MaskResize (isolates and rotates the mask 720 in the non-viewable region), and ColorReplace (changes the color of the masked out areas in the viewable region 710). In one implementation, the filter graph is defined using JSON, as follows:

let filters = {
ColorReplace: {
type: ‘colorreplace’,
options: {
replacementColor: ‘rgb(255, 255, 255)’,
mainColor: “rgb(196,182,174)”,
edgeTolerance: 0.98,
enableSpill: false
}
},
MaskResize: {
type: ‘resize’,
options: {
rotate: -90,
newframe: {
x: 0.0,
y: 0,
width: 0.5625,
height: 1.0
},
originalFrame: {
x: 0.564,
y: 0.0,
width: 0.436,
height: 1.0,
},
fitToFrame: true
}
},
VideoResize: {
type: ‘resize’,
options: {
rotate: 0,
newframe: {
x: 0.0,
y: 0,
width: 0.564,
height: 1.0
},
fitToFrame: false
}
},
Chroma: {
type: ‘composite’,
options: {
graph: [
{
type: ‘VideoResize’,
inputs: [‘video’],
outputs: [‘videoOutput’]
},
{
type: ‘MaskResize’,
inputs: [‘video']
},
{
type: ‘ColorReplace’,
inputs: [‘videoOutput’,‘previous’]
}
]
}
},
};
let app = new VideoFilterApplication(player, filters);
app.applyGraph(‘Chroma’);

FIG. 8 depicts an implementation of the above-described filter graph within the filter framework. The framework uses shaders, textures, and framebuffers in order to composite multiple effects. Here, a filter is a shader that manipulates the pixels of some input, such as a texture. The output, which can also be a texture, is stored in a temporary framebuffer or a saved framebuffer. If the output is in a saved framebuffer, the output can be accessed at any point during the rendering process. If the output is in a temporary framebuffer, the output can only be accessed by the next shader in the rendering pipeline. From the original video 802, a texture is extracted 804 (e.g., video frame 700 in FIG. 7A). Resize shader 806 (e.g., the VideoResize filter) isolates the viewable video region (e.g., viewable region 710) and places the isolated region output texture into resize framebuffer 808. Resize shader 810 (e.g., the MaskResize filter) isolates and rotates the non-viewable region (e.g., mask 720) and places the isolated, rotated output texture into temporary framebuffer 812. ColorReplace shader 814 (e.g., the ColorReplace filter) uses the output stored in each framebuffer 808 and 812 to change the color of the masked-out region in the viewable video region, and stores the resulting texture in temporary framebuffer 816. Final shader 818 can optionally perform additional shader operations on the texture in temporary framebuffer 816 prior to rendering on canvas 820.

Other uses cases for the metadata encoded in pixels are contemplated. For example, in implementations where each pixel includes four channels (red, green, blue and alpha), with values ranging from 0 to 1, a value of {0, 0, 0, 0} can be used to specify that a portion of the video should be visible, whereas a value of {1, 1, 1, 1} can be used to specify that a portion of the video should be hidden. Other combinations of values can be used to provide more complex masks. Referring to FIG. 9, video frame 900 includes two separate video regions: video region 910 and video region 920. Video frame 900 also includes mask region 930. Video region 910 is the visible region when the video including video frame 900 is playing. In real-time, while the video is playing, mask 930 is rotated and aligned over video region 910. The metadata pixel values in the mask 930 are then used to determine whether the corresponding portion of video region 910 or the corresponding portion of video region 920 is shown. In this manner, shader operations can in real-time form a video that simultaneously displays a combination of portions of different videos. In another implementation, the metadata pixel values are used to determine whether to combine video region 910 and video region 920 together. In another implementation, the metadata pixel values are used to identify a type of color correction operation or graphical stylistic effect to be applied to the video. It should be noted that FIG. 9 is exemplary, and a video frame can include one or more video regions (e.g., one, two, three or more) and one or more metadata or mask regions (e.g., one, two, three or more). Different video frames can have different numbers of video regions and metadata regions, and different video or mask data within the regions.

Although the systems and methods described herein relate primarily to audio and video playback, the invention is equally applicable to various streaming and non-streaming media, including animation, video games, interactive media, and other forms of content usable in conjunction with the present systems and methods. Further, there can be more than one audio, video, and/or other media content stream played in synchronization with other streams. Streaming media can include, for example, multimedia content that is continuously presented to a user while it is received from a content delivery source, such as a remote video server. If a source media file is in a format that cannot be streamed and/or does not allow for seamless connections between segments, the media file can be transcoded or converted into a format supporting streaming and/or seamless transitions. Alternatively or in addition, audio, video and other media can be stored as files in individual or combined form, and can be stored locally on a user's device or remotely on a server that transmits or streams the files to the user device.

While various implementations of the present invention have been described herein, it should be understood that they have been presented by example only. For example, one of skill in the art will appreciate that the techniques for creating seamless audio segments can be applied to creating seamless video segments and other forms of seamless media as well. Where methods and steps described above indicate certain events occurring in certain order, those of ordinary skill in the art having the benefit of this disclosure would recognize that the ordering of certain steps can be modified and that such modifications are in accordance with the given variations. For example, although various implementations have been described as having particular features and/or combinations of components, other implementations are possible having any combination or sub-combination of any features and/or components from any of the implementations described herein.

Claims

1. A computer-implemented method for real-time video manipulation, the method comprising: identifying a state of an interactive video;receiving a first frame of the interactive video, the first frame including a video layer;determining properties associated with a composite user interface (UI) element at the state of the interactive video, wherein the properties include a real-time interactive state of the composite UI element based on a user interaction with the composite UI element in a prior frame, the composite UI element including a non-interactive UI element and a selectively-rendered transparent interactive element;rendering the non-interactive UI element into the first frame of the interactive video based on a static appearance of the composite UI element in the real-time interactive state, wherein the rendering comprises using a shader to draw the non-interactive UI element into the video layer of the first frame;determining, based on the real-time interactive state of the composite UI element, whether the composite UI element is interactive-enabled during the first frame of the interactive video;in response to a determination that the composite UI element is interactive-enabled, layering the transparent interactive element over the non-interactive UI element rendered into the video layer of the first frame;receiving a user interaction with the transparent interactive element;updating the real-time interactive state of the composite UI element based on the user interaction with the transparent interactive element;receiving a second frame of the interactive video; andrendering the non-interactive UI element into the second frame of the interactive video based on a static appearance of the composite UI element in the updated real-time interactive state.

2. The method of claim 1, wherein the state of the interactive video comprises information associated with a user's traversal of a path within the interactive video.

3. The method of claim 1, wherein the state of the interactive video comprises information associated with one or more UI elements displayed during presentation of the interactive video.

4. The method of claim 1, wherein determining the properties associated with the composite UI element at the state comprises determining properties of the composite UI element that changed from a previous state.

5. The method of claim 1, wherein the rendering comprises using a web-based graphics framework to render the next frame over an HTML-based canvas element.

6. The method of claim 1, further comprising performing each of the identifying, determining, receiving, rendering and layering steps for a plurality of frames of the interactive video.

7. The method of claim 6, wherein the non-interactive UI element comprises a video or animation, and wherein the rendering comprises using a shader to render each frame of the video or animation into a corresponding frame of the interactive video.

8. The method of claim 1, further comprising using a shader to render an additional graphical element in at least one of the first frame and the second frame.

9. The method of claim 8, wherein the non-interactive UI element has a first depth level and wherein the additional graphical element has a second depth level, and wherein the non-interactive UI element and the additional graphical element are rendered in an order based on their respective depth levels.

10. The method of claim 9, further comprising, during playback of the interactive video, dynamically modifying the depth level of the non-interactive UI element and/or the additional graphical element based on changes in the state of the interactive video.

11. A system for real-time video manipulation, the system comprising: at least one memory for storing computer-executable instructions; andat least one processor for executing the instructions stored on the memory, wherein execution of the instructions programs the at least one processor to perform operations comprising: identifying a state of an interactive video;receiving a first frame of the interactive video, the first frame including a video layer;determining properties associated with a composite user interface (UI) element at the state of the interactive video, wherein the properties include a real-time interactive state of the composite UI element based on a user interaction with the composite UI element in a prior frame, the composite UI element including a non-interactive UI element and a selectively-rendered transparent interactive element;rendering the non-interactive UI element into the first frame of the interactive video based on a static appearance of the composite UI element in the real-time interactive state, wherein the rendering comprises using a shader to draw the non-interactive UI element into the video layer of the first frame;determining, based on the real-time interactive state of the composite UI element, whether the composite UI element is interactive-enabled during the first frame of the interactive video;in response to a determination that the composite UI element is interactive-enabled, layering the transparent interactive element over the non-interactive UI element rendered into the video layer of the first frame;receiving a user interaction with the transparent interactive element;updating the real-time interactive state of the composite UI element based on the user interaction with the transparent interactive element;receiving a second frame of the interactive video; andrendering the non-interactive UI element into the second frame of the interactive video based on a static appearance of the composite UI element in the updated real-time interactive state.

12. The system of claim 11, wherein the state of the interactive video comprises information associated with a user's traversal of a path within the interactive video.

13. The system of claim 11, wherein the state of the interactive video comprises information associated with one or more UI elements displayed during presentation of the interactive video.

14. The system of claim 11, wherein determining the properties associated with the composite UI element at the state comprises determining properties of the composite UI element that changed from a previous state.

15. The system of claim 11, wherein the rendering comprises using a web-based graphics framework to render the next frame over an HTML-based canvas element.

16. The system of claim 11, wherein the operations further comprise performing each of the identifying, determining, receiving, rendering and layering steps for a plurality of frames of the interactive video.

17. The system of claim 16, wherein the non-interactive UI element comprises a video or animation, and wherein the rendering comprises using a shader to render each frame of the video or animation into a corresponding frame of the interactive video.

18. The system of claim 11, wherein the operations further comprise using a shader to render an additional graphical element in at least one of the first frame and the second frame.

19. The system of claim 18, wherein the non-interactive UI element has a first depth level and wherein the additional graphical element has a second depth level, and wherein the non-interactive UI element and the additional graphical element are rendered in an order based on their respective depth levels.

20. The system of claim 19, wherein the operations further comprise, during playback of the interactive video, dynamically modifying the depth level of the non-interactive UI element and/or the additional graphical element based on changes in the state of the interactive video.