* Implement registry.
* Refactor code to use a trait `Class` as the builder of `Visualization`s.

Original commit: 48b8d88dc3
This commit is contained in:
Michael Mauderer 2020-05-21 12:56:39 +02:00 committed by GitHub
parent 2b5353b594
commit de148f16b8
12 changed files with 543 additions and 200 deletions

View File

@ -1,29 +1,36 @@
//! This module defines the visualization widgets and related functionality.
//!
//! The overall architecture of visualizations consists of three parts:
//! The overall architecture of visualizations consists of four parts:
//!
//! 1. The `DataRenderer` trait provides the functionality to render the actual visualization view
//! that implements `display::Object`. It is provided with data and itself provides frp streams
//! of its output if there is some, for example, if it acts as a widget.
//!
//! 2. The `Visualization` is a struct that wraps the `DataRenderer` and implements the generic
//! tasks that are the same for all visualisations. That is, interfacing with the other UI
//! tasks that are the same for all visualizations. That is, interfacing with the other UI
//! elements, the visualization registry, as well as propagating frp messages.
//!
//! 3. The `Container` wraps the `Visualisation` and provides the UI elements that facilitate
//! user interactions. For example, selecting a visualisation or connecting it to nodes in the
//! 3. The `Class` is a struct that can instantiate multiple `Visualization` structs and provides
//! data about the visualization even before they are instantiated like input datatype and name.
//!
//! 4. The `Container` wraps the `Visualization` and provides the UI elements that facilitate
//! user interactions. For example, selecting a visualization or connecting it to nodes in the
//! graph editor scene.
//!
//! In addition this module also contains a `Data` struct that provides a dynamically typed way to
//! handle data for visualisations. This allows the `Visualisation` struct to be without type
//! handle data for visualizations. This allows the `Visualization` struct to be without type
//! parameters and simplifies the FRP communication and complexity of the node system.
pub mod class;
pub mod container;
pub mod renderer;
pub mod data;
pub mod js;
pub mod registry;
pub mod renderer;
pub use class::*;
pub use data::*;
pub use container::*;
pub use data::*;
pub use js::*;
pub use registry::*;
pub use renderer::*;

View File

@ -5,8 +5,9 @@ use crate::prelude::*;
use crate::frp;
use crate::visualization::*;
use ensogl::display::Scene;
use ensogl::display;
use std::error::Error;
// ====================
@ -20,11 +21,31 @@ pub struct EnsoCode {
}
/// Type alias for a string representing an enso type.
#[derive(Clone,CloneRef,Debug)]
#[derive(Clone,CloneRef,Debug,PartialEq,Eq,Hash)]
pub struct EnsoType {
content: Rc<String>
}
impl From<String> for EnsoType {
fn from(source:String) -> Self {
EnsoType { content:Rc::new(source) }
}
}
impl From<&str> for EnsoType {
fn from(source:&str) -> Self {
EnsoType { content:Rc::new(source.to_string()) }
}
}
/// Contains general information about a visualization.
#[derive(Clone,Debug)]
#[allow(missing_docs)]
pub struct Signature {
pub name : String,
pub input_types : Vec<EnsoType>,
}
// =========================
@ -145,7 +166,6 @@ impl Visualization {
frp.preprocess_change.emit(data.as_ref().map(|code|code.clone_ref()))
}));
}
self
}
@ -154,3 +174,138 @@ impl Visualization {
self.state.renderer.set_size(size)
}
}
// ===========================
// === Visualization Class ===
// ===========================
/// Indicates that instantiating a `Visualisation` from a `Class` has failed.
#[derive(Debug,Display)]
#[allow(missing_docs)]
pub enum InstantiationError {
/// Indicates a problem with instantiating a class object.
InvalidClass { inner:Box<dyn Error> },
/// Indicates a problem with instantiating a visualisation from a valid class object.
InvalidVisualisation { inner:Box<dyn Error> },
}
/// Result of the attempt to instantiate a `Visualization` from a `Class`.
pub type InstantiationResult = Result<Visualization,InstantiationError>;
/// Specifies a trait that allows the instantiation of `Visualizations`.
///
/// The `Class` provides a way to implement structs that allow the instantiation of specific
/// visualizations, while already providing general information that doesn't require an
/// instantiated visualization, for example, the name or input type of the visualization.
///
/// There are two example implementations: The `JsSourceClass`, which is based on a JS snippet to
/// instantiate `JsRenderer`, and the fairly generic `NativeConstructorClass`, that only requires
/// a function that can create a InstantiationResult. The later can be used as a thin wrapper around
/// the constructor methods of native visualizations.
///
/// Example
/// --------
/// ```no_run
/// use graph_editor::component::visualization;
/// use graph_editor::component::visualization::Visualization;
/// use graph_editor::component::visualization::renderer::example::native::BubbleChart;
/// use ensogl::display::Scene;
/// use std::rc::Rc;
///
/// // Create a `visualization::Class` from a JS source code snippet.
/// let js_source_class = visualization::JsSourceClass::from_js_source_raw(r#"
///
/// class BubbleVisualization {
/// static inputTypes = ["[[Float,Float,Float]]"]
/// onDataReceived(root, data) {}
/// setSize(root, size) {}
/// }
///
/// return BubbleVisualization;
///
/// "#.into());
///
/// // Create a `visualization::Class` that instantiates a `BubbleChart`.
/// let native_bubble_vis_class = visualization::NativeConstructorClass::new(
/// visualization::Signature {
/// name : "Bubble Visualization (native)".to_string(),
/// input_types : vec!["[[Float,Float,Float]]".into()],
/// },
/// |scene:&Scene| Ok(Visualization::new(BubbleChart::new(scene)))
/// );
/// ```
pub trait Class: Debug {
/// Provides additional information about the `Class`, for example, which `DataType`s can be
/// rendered by the instantiated visualization.
fn signature(&self) -> &Signature;
/// Create new visualization, that is initialised for the given scene. This can fail if the
/// `visualization::Class` contains invalid data, for example, JS code that fails to execute,
/// or if the scene is in an invalid state.
// TODO consider not providing the scene here, but hooking the the shapes/dom elements into the
// scene externally.
fn instantiate(&self, scene:&Scene) -> InstantiationResult;
}
/// Wrapper for `Class` objects, so they can be passed through the FRP system.
#[derive(Clone,Debug,Default)]
#[allow(missing_docs)]
pub struct Handle {
class : Option<Rc<dyn Class>>
}
impl Handle {
/// Constructor.
pub fn new<T:Class+'static>(class:T) -> Handle {
let class = Rc::new(class);
Handle {class:Some(class)}
}
/// Return the inner class.
pub fn class(&self) -> Option<Rc<dyn Class>> {
self.class.clone()
}
}
impl CloneRef for Handle {}
// ================================
// === Native Constructor Class ===
// ================================
/// Type alias for a function that can create a `Visualization`.
pub trait VisualizationConstructor = Fn(&Scene) -> InstantiationResult;
/// Constructor that instantiates visualisations from a given `VisualizationConstructor`. Can be
/// used to wrap the constructor of visualizations defined in Rust.
#[derive(CloneRef,Clone,Derivative)]
#[derivative(Debug)]
#[allow(missing_docs)]
pub struct NativeConstructorClass {
info : Rc<Signature>,
#[derivative(Debug="ignore")]
constructor : Rc<dyn VisualizationConstructor>,
}
impl NativeConstructorClass {
/// Create a visualization source from a closure that returns a `Visualization`.
pub fn new<T>(info:Signature, constructor:T) -> Self
where T: VisualizationConstructor + 'static {
let info = Rc::new(info);
let constructor = Rc::new(constructor);
NativeConstructorClass{info,constructor}
}
}
impl Class for NativeConstructorClass {
fn signature(&self) -> &Signature {
&self.info
}
fn instantiate(&self, scene:&Scene) -> InstantiationResult {
self.constructor.call((scene,))
}
}

View File

@ -46,7 +46,7 @@ impl Default for ContainerFrp {
/// Container that wraps a `Visualization` for rendering and interaction in the GUI.
///
/// The API to interact with the visualisation is exposed through the `ContainerFrp`.
/// The API to interact with the visualization is exposed through the `ContainerFrp`.
#[derive(Clone,CloneRef,Debug,Shrinkwrap)]
#[allow(missing_docs)]
pub struct Container {
@ -72,7 +72,7 @@ pub struct ContainerData {
}
impl ContainerData {
/// Set whether the visualisation should be visible or not.
/// Set whether the visualization should be visible or not.
pub fn set_visibility(&self, is_visible:bool) {
if let Some(vis) = self.visualization.borrow().as_ref() {
if is_visible {
@ -83,7 +83,7 @@ impl ContainerData {
}
}
/// Indicates whether the visualisation is visible.
/// Indicates whether the visualization is visible.
fn is_visible(&self) -> bool {
if let Some(vis) = self.visualization.borrow().as_ref() {
vis.has_parent()
@ -99,8 +99,8 @@ impl ContainerData {
/// Update the content properties with the values from the `ContainerData`.
///
/// Needs to called when a visualisation has been set.
fn init_visualisation_properties(&self) {
/// Needs to called when a visualization has been set.
fn init_visualization_properties(&self) {
let size = self.size.get();
if let Some(vis) = self.visualization.borrow().as_ref() {
vis.set_size(size);
@ -109,10 +109,10 @@ impl ContainerData {
}
/// Set the visualization shown in this container..
fn set_visualisation(&self, visualization:Visualization) {
fn set_visualization(&self, visualization:Visualization) {
self.add_child(&visualization);
self.visualization.replace(Some(visualization));
self.init_visualisation_properties();
self.init_visualization_properties();
}
}
@ -152,9 +152,9 @@ impl Container {
container_data.toggle_visibility()
}));
def _f_set_vis = frp.set_visualization.map(f!([container_data](visualisation) {
if let Some(visualisation) = visualisation.as_ref() {
container_data.set_visualisation(visualisation.clone());
def _f_set_vis = frp.set_visualization.map(f!([container_data](visualization) {
if let Some(visualization) = visualization.as_ref() {
container_data.set_visualization(visualization.clone());
}
}));

View File

@ -9,13 +9,13 @@ use serde::Deserialize;
// ======================================
// === Wrapper for Visualisation Data ===
// === Wrapper for Visualization Data ===
// =======================================
/// Type indicator
pub type DataType = EnsoType;
/// Wrapper for data that can be consumed by a visualisation.
/// Wrapper for data that can be consumed by a visualization.
/// TODO[mm] consider static versus dynamic typing for visualizations and data!
#[derive(Clone,CloneRef,Debug)]
#[allow(missing_docs)]
@ -70,7 +70,7 @@ impl Data {
pub enum DataError {
/// Indicates that that the provided data type does not match the expected data type.
InvalidDataType,
/// The data caused an error in the computation of the visualisation.
/// The data caused an error in the computation of the visualization.
InternalComputationError,
}

View File

@ -0,0 +1,133 @@
//! This module contains functionality to create a `Class` object from a JS source strings.
use crate::prelude::*;
use crate::component::visualization::JsVisualizationError;
use crate::component::visualization::InstantiationError;
use crate::component::visualization::JsRenderer;
use crate::component::visualization::JsResult;
use crate::component::visualization::InstantiationResult;
use crate::component::visualization::Class;
use crate::component::visualization::Visualization;
use crate::component::visualization::Signature;
use crate::component::visualization::EnsoType;
use ensogl::display::Scene;
use ensogl::system::web::JsValue;
use js_sys;
// ===================================
// === Visualization Class Wrapper ===
// ===================================
/// Internal wrapper for the a JS class that implements our visualization specification. Provides
/// convenience functions for accessing JS methods and signature.
#[derive(Clone,Debug)]
#[allow(missing_docs)]
struct VisualizationClassWrapper {
class: JsValue,
}
impl VisualizationClassWrapper {
fn instantiate_class(source:&str) -> JsResult<VisualizationClassWrapper> {
let context = JsValue::NULL;
let constructor = js_sys::Function::new_no_args(source);
let class = constructor.call0(&context)?;
Ok(VisualizationClassWrapper{class})
}
fn signature(&self) -> JsResult<Signature> {
let input_types = self.input_types().unwrap_or_default();
let name = self.name()?;
Ok(Signature {name,input_types})
}
fn constructor(&self) -> JsResult<js_sys::Function> {
Ok(js_sys::Reflect::get(&self.prototype()?,&"constructor".into())?.into())
}
fn prototype(&self) -> JsResult<JsValue> {
Ok(js_sys::Reflect::get(&self.class,&"prototype".into())?)
}
fn input_types(&self) -> JsResult<Vec<EnsoType>> {
let input_types = js_sys::Reflect::get(&self.class, &"inputTypes".into())?;
let input_types = js_sys::Array::from(&input_types);
let js_string_to_enso_type = |value:JsValue| {Some(EnsoType::from(value.as_string()?))};
Ok(input_types.iter().filter_map(js_string_to_enso_type).collect())
}
fn name(&self) -> JsResult<String> {
let constructor = self.constructor()?;
let name = js_sys::Reflect::get(&constructor,&"name".into())?;
Ok(name.as_string().unwrap_or_default())
}
fn instantiate(&self) -> JsResult<JsValue> {
let fn_wrapper = js_sys::Function::new_with_args("cls", "return new cls()");
let context = JsValue::NULL;
Ok(fn_wrapper.call1(&context, &self.class)?)
}
}
// ========================
// === Js Source Class ===
// ========================
/// Implements the `visualization::Class` for a JS source string.
///
/// Example
/// -------
/// ```no_run
///
/// # use graph_editor::component::visualization::JsSourceClass;
///
/// JsSourceClass::from_js_source_raw(r#"
/// class Visualization {
/// static inputTypes = ["[[Float,Float,Float]]"]
/// onDataReceived(root, data) {}
/// setSize(root, size) {}
/// }
/// return Visualizations;
/// "#.into()).unwrap();
/// ```
#[derive(CloneRef,Clone,Debug)]
#[allow(missing_docs)]
pub struct JsSourceClass {
js_class : Rc<VisualizationClassWrapper>,
signature: Rc<Signature>,
}
impl JsSourceClass {
/// Create a visualization source from piece of JS source code. Signature needs to be inferred.
pub fn from_js_source_raw(source:&str) -> Result<Self,JsVisualizationError> {
let js_class = VisualizationClassWrapper::instantiate_class(&source)?;
let signature = js_class.signature()?;
let js_class = Rc::new(js_class);
let signature = Rc::new(signature);
Ok(JsSourceClass{js_class,signature})
}
}
impl Class for JsSourceClass {
fn signature(&self) -> &Signature {
&self.signature
}
fn instantiate(&self, scene:&Scene) -> InstantiationResult {
let obj = match self.js_class.instantiate() {
Ok(obj) => obj,
Err(err) => return Err(InstantiationError::InvalidClass {inner:err.into()}),
};
let renderer = match JsRenderer::from_object(obj) {
Ok(renderer) => renderer,
Err(err) => return Err(InstantiationError::InvalidClass {inner:err.into()}),
};
renderer.set_dom_layer(&scene.dom.layers.front);
Ok(Visualization::new(renderer))
}
}

View File

@ -0,0 +1,102 @@
//! The `Registry` provides a mechanism to store `visualization::Class`es for all available visualizations. It
//! provides functionality to register new factories, as well as get suitable factories for
//! a specific data type.
//!
//! Example
//! --------
//! ```no_run
//! use graph_editor::component::visualization::Registry;
//! use graph_editor::component::visualization::EnsoType;
//! use graph_editor::component::visualization::JsSourceClass;
//!
//! // Instantiate a pre-populated registry.
//! let registry = Registry::with_default_visualizations();
//! // Add a new class that creates visualizations defined in JS.
//! registry.register_class(JsSourceClass::from_js_source_raw(r#"
//! class BubbleVisualization {
//! static inputTypes = ["[[Float,Float,Float]]"]
//! onDataReceived(root, data) {}
//! setSize(root, size) {}
//! }
//! return BubbleVisualization;
//! "#.into()).unwrap());
//!
//! // Get all factories that can render visualization for the type `[[Float,Float,Float]]`.
//! let target_type:EnsoType = "[[Float,Float,Float]]".to_string().into();
//! assert!(registry.valid_sources(&target_type).len() > 0);
//! ```
use crate::prelude::*;
use crate::component::visualization::*;
use crate::component::visualization::renderer::example::js::get_bubble_vis_class;
use crate::component::visualization::renderer::example::native::BubbleChart;
use ensogl::display::scene::Scene;
// ==============================
// === Visualization Registry ===
// ==============================
/// HashMap that contains the mapping from `EnsoType`s to a `Vec` of `Factories. This is meant to
/// map a `EnsoType` to all `visualization::Class`es that support visualising that type.
type RegistryTypeMap = HashMap<EnsoType, Vec<Rc<dyn Class>>>;
/// The registry struct. For more information see the module description.
#[derive(Clone,CloneRef,Default,Debug)]
#[allow(missing_docs)]
pub struct Registry {
entries : Rc<RefCell<RegistryTypeMap>>,
}
impl Registry {
/// Return an empty `Registry`.
pub fn new() -> Self {
Self::default()
}
/// Return a `Registry` prepopulated with default visualizations.
pub fn with_default_visualizations() -> Self {
let registry = Self::new();
// FIXME use proper enso types here.
registry.register_class(NativeConstructorClass::new(
Signature {
name : "Bubble Visualization (native)".to_string(),
input_types : vec!["[[Float,Float,Float]]".to_string().into()],
},
|scene:&Scene| Ok(Visualization::new(BubbleChart::new(scene)))
));
registry.register_class(get_bubble_vis_class());
registry
}
/// Register a new visualization class with the registry.
pub fn register_class<T:Class+'static>(&self, class:T) {
self.register_class_rc(Rc::new(class));
}
/// Register a new visualization class that's pre-wrapped in an `Rc` with the registry.
pub fn register_class_from_handle(&self, handle:&Handle) {
if let Some(class) = handle.class() {
self.register_class_rc(class);
}
}
fn register_class_rc(&self, class:Rc<dyn Class>) {
let spec = class.signature();
for dtype in &spec.input_types {
let mut entries = self.entries.borrow_mut();
let entry_vec = entries.entry(dtype.clone()).or_insert_with(default);
entry_vec.push(Rc::clone(&class));
}
}
/// Return all `visualization::Class`es that can create a visualization for the given datatype.
pub fn valid_sources(&self, dtype:&EnsoType) -> Vec<Rc<dyn Class>>{
let entries = self.entries.borrow();
entries.get(dtype).cloned().unwrap_or_else(default)
}
}

View File

@ -19,7 +19,7 @@ use ensogl::display;
pub struct DataRendererFrp {
pub network : frp::Network,
/// This is emitted if the state of the renderer has been changed by UI interaction.
/// It contains the output data of this visualisation if there is some.
/// It contains the output data of this visualization if there is some.
pub on_change : frp::Stream<Option<EnsoCode>>,
/// Will be emitted if the visualization changes it's preprocessor. Transmits the new
/// preprocessor code.
@ -53,7 +53,7 @@ impl Default for DataRendererFrp {
/// producing a `display::Object` that will be shown in the scene. It will create FRP events to
/// indicate updates to its output data (e.g., through user interaction).
///
/// A DataRenderer can indicate what kind of data it can use to create a visualisation through the
/// A DataRenderer can indicate what kind of data it can use to create a visualization through the
/// `valid_input_types` method. This serves as a hint, it will also reject invalid input in the
/// `set_data` method with a `DataError`. The owner of the `DataRenderer` is in charge of producing
/// UI feedback to indicate a problem with the data.
@ -67,7 +67,7 @@ pub trait DataRenderer: display::Object + Debug {
/// processed by this `DataRenderer`, if the data is of an invalid data type, it violates other
/// assumptions of this `DataRenderer`, a `DataError` is returned.
fn receive_data(&self, data:Data) -> Result<(), DataError>;
/// Set the size of viewport of the visualization. The visualisation must not render outside of
/// Set the size of viewport of the visualization. The visualization must not render outside of
/// this viewport.
fn set_size(&self, size:Vector2<f32>);

View File

@ -1,4 +1,4 @@
//! The `example` modules contains some examples of visualisations.
//! The `example` modules contains some examples of visualizations.
//! TODO further describe the examples, how they work and how to extend them.
pub mod native;

View File

@ -1,104 +1,15 @@
//! Example of the visualisation JS wrapper API usage
//! Example of the visualization JS wrapper API usage
// TODO remove once we have proper visualizations or replace with a nice d3 example.
// These implementations are neither efficient nor pretty, but get the idea across.
use crate::component::visualization::JsRenderer;
use crate::component::visualization::JsSourceClass;
/// Returns a simple bubble chart implemented in vanilla JS. uses single functions to implement the
/// visualization.
pub fn function_sample_js_bubble_chart() -> JsRenderer {
let fn_set_data = r#"{
const xmlns = "http://www.w3.org/2000/svg";
const root = arguments[0];
while (root.firstChild) {
root.removeChild(root.lastChild);
}
const svgElem = document.createElementNS(xmlns, "svg");
svgElem.setAttributeNS(null, "id" , "vis-svg");
svgElem.setAttributeNS(null, "viewBox", "0 0 " + 100 + " " + 100);
svgElem.setAttributeNS(null, "width" , 100);
svgElem.setAttributeNS(null, "height" , 100);
root.appendChild(svgElem);
const data = arguments[1];
data.forEach(data => {
const bubble = document.createElementNS(xmlns,"circle");
bubble.setAttributeNS(null,"stroke", "black");
bubble.setAttributeNS(null,"fill" , "red");
bubble.setAttributeNS(null,"r" , data[2]);
bubble.setAttributeNS(null,"cx" , data[0]);
bubble.setAttributeNS(null,"cy" , data[1]);
svgElem.appendChild(bubble);
});
}
"#;
let fn_set_size = r#"{
const root = arguments[0];
const width = arguments[1][0];
const height = arguments[1][1];
const svgElem = root.firstChild;
svgElem.setAttributeNS(null, "viewBox", "0 0 " + width + " " + height);
svgElem.setAttributeNS(null, "width" , width);
svgElem.setAttributeNS(null, "height" , height);
}"#;
JsRenderer::from_functions(fn_set_data, fn_set_size)
}
/// Returns a simple bubble chart implemented in vanilla JS. Uses an object to implement the
/// visualization logic.
pub fn object_sample_js_bubble_chart() -> JsRenderer {
let fn_prototype = r#"
(() => {
class BubbleVisualisation {
onDataReceived(root, data) {
const xmlns = "http://www.w3.org/2000/svg";
while (root.firstChild) {
root.removeChild(root.lastChild);
}
const svgElem = document.createElementNS(xmlns, "svg");
svgElem.setAttributeNS(null, "id" , "vis-svg");
svgElem.setAttributeNS(null, "viewBox", "0 0 " + 100 + " " + 100);
svgElem.setAttributeNS(null, "width" , 100);
svgElem.setAttributeNS(null, "height" , 100);
root.appendChild(svgElem);
data.forEach(data => {
const bubble = document.createElementNS(xmlns,"circle");
bubble.setAttributeNS(null,"stroke", "black");
bubble.setAttributeNS(null,"fill" , "red");
bubble.setAttributeNS(null,"r" , data[2]);
bubble.setAttributeNS(null,"cx" , data[0]);
bubble.setAttributeNS(null,"cy" , data[1]);
svgElem.appendChild(bubble);
});
}
setSize(root, size) {
const width = size[0];
const height = size[1];
const svgElem = root.firstChild;
svgElem.setAttributeNS(null, "viewBox", "0 0 " + width + " " + height);
svgElem.setAttributeNS(null, "width" , width);
svgElem.setAttributeNS(null, "height" , height);
}
}
return new BubbleVisualisation();
})()
"#;
JsRenderer::from_object(fn_prototype).unwrap()
}
/// Returns a simple bubble chart implemented in vanilla JS. uses single functions to implement the
/// visualization.
pub fn constructor_sample_js_bubble_chart() -> JsRenderer {
/// Return an `JsSourceClass` that creates example Bubble Visualizations implemented in JS.
pub fn get_bubble_vis_class() -> JsSourceClass {
let fn_constructor = r#"
class BubbleVisualisation {
class BubbleVisualization {
static inputTypes = ["[[Float,Float,Float]]"]
onDataReceived(root, data) {
const xmlns = "http://www.w3.org/2000/svg";
while (root.firstChild) {
@ -133,7 +44,8 @@ pub fn constructor_sample_js_bubble_chart() -> JsRenderer {
}
}
return new BubbleVisualisation();
return BubbleVisualization;
"#;
JsRenderer::from_constructor(fn_constructor).unwrap()
JsSourceClass::from_js_source_raw(fn_constructor).unwrap()
}

View File

@ -1,4 +1,4 @@
//! Examples of defining visualisation in Rust using web_sys or ensogl.
//! Examples of defining visualization in Rust using web_sys or ensogl.
use crate::prelude::*;

View File

@ -1,7 +1,7 @@
//! This module contains functionality that allows the usage of JavaScript to define visualizations.
//!
//! The `JsRenderer` defines a generic way to wrap JS function calls and allow interaction with
//! JS code and the visualisation system.
//! JS code and the visualization system.
//!
//! There are at the moment three way to generate a `JsRenderer`:
//! 1. `JsRenderer::from_functions` where the bodies of the required functions are provided as
@ -11,12 +11,15 @@
//! 3. `JsRenderer::from_constructor`where the body of a constructor function needs to be
//! provided. The returned object needs to fulfill the same specification as in (2).
//!
//! Right now the only functions required on the wrapped object are
//! * `onDataReceived(root, data)`, which receives the html element that the visualisation should be
//! Right now the only functions supported on the wrapped object are
//! * `onDataReceived(root, data)`, which receives the html element that the visualization should be
//! appended on, as well as the data that should be rendered.
//! * `setSize(root, size)`, which receives the node that the visualisation should be appended on,
//! * `setSize(root, size)`, which receives the node that the visualization should be appended on,
//! as well as the intended size.
//!
//! All functions on the class are optional, and methods that are not present, will be handled as
//! no-op by the `JsRenderer`.
//!
//! TODO: refine spec and add functions as needed, e.g., init, callback hooks or type indicators.
use crate::prelude::*;
@ -32,6 +35,7 @@ use ensogl::display;
use ensogl::system::web::JsValue;
use ensogl::system::web;
use js_sys;
use std::fmt::Formatter;
@ -42,27 +46,49 @@ use js_sys;
/// Errors that can occur when transforming JS source to a visualization.
#[derive(Clone,Debug)]
#[allow(missing_docs)]
pub enum JsVisualisationError {
pub enum JsVisualizationError {
NotAnObject { inner:JsValue },
NotAFunction { inner:JsValue },
/// An unknown error occurred on the JS side. Inspect the content for more information. .
/// An unknown error occurred on the JS side. Inspect the content for more information.
Unknown { inner:JsValue }
}
impl From<JsValue> for JsVisualisationError {
fn from(value:JsValue) -> Self {
// TODO add differentiation if we encounter specific errors and return new variants.
JsVisualisationError::Unknown {inner:value}
impl Display for JsVisualizationError {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
// TODO find a nice way to circumvent the fact that `JsValue` does not implement `Display`.
match self {
JsVisualizationError::NotAnObject { inner } => {
f.write_fmt(format_args!("Not an object: {:?}",inner))
},
JsVisualizationError::NotAFunction { inner } => {
f.write_fmt(format_args!("Not a function: {:?}",inner))
},
JsVisualizationError::Unknown { inner } => {
f.write_fmt(format_args!("Unknown: {:?}",inner))
},
}
}
}
impl std::error::Error for JsVisualizationError {}
impl From<JsValue> for JsVisualizationError {
fn from(value:JsValue) -> Self {
// TODO add differentiation if we encounter specific errors and return new variants.
JsVisualizationError::Unknown {inner:value}
}
}
/// Internal helper type to propagate results that can fail due to `JsVisualizationError`s.
pub(crate) type JsResult<T> = Result<T, JsVisualizationError>;
// ==================
// === JsRenderer ===
// ==================
/// `JsVisualizationGeneric` allows the use of arbitrary javascript to create visualisations. It
/// `JsVisualizationGeneric` allows the use of arbitrary javascript to create visualizations. It
/// takes function definitions as strings and proved those functions with data.
#[derive(Clone,Debug)]
#[allow(missing_docs)]
@ -81,11 +107,11 @@ impl JsRenderer {
/// code will be executed as the function body of the respective functions.
///
/// `fn_set_data` will be called with two arguments: the first argument (`root) )will be the
/// root node that the visualisation should use to build its output, the second argument
/// root node that the visualization should use to build its output, the second argument
/// (`data`)will be the data that it should visualise.
///
/// `fn_set_size` will be called with a tuple of floating point values indicating the desired
/// width and height. This can be used by the visualisation to ensure proper scaling.
/// width and height. This can be used by the visualization to ensure proper scaling.
///
/// For a full example see
/// `crate::component::visualization::renderer::example::function_sample_js_bubble_chart`
@ -103,14 +129,14 @@ impl JsRenderer {
}
/// Internal helper that tries to convert a JS object into a `JsRenderer`.
fn from_object_js(object:js_sys::Object) -> Result<JsRenderer,JsVisualisationError> {
fn from_object_js(object:js_sys::Object) -> Result<JsRenderer,JsVisualizationError> {
let set_data = js_sys::Reflect::get(&object,&"onDataReceived".into())?;
let set_size = js_sys::Reflect::get(&object,&"setSize".into())?;
if !set_data.is_function() {
return Err(JsVisualisationError::NotAFunction { inner:set_data })
return Err(JsVisualizationError::NotAFunction { inner:set_data })
}
if !set_size.is_function() {
return Err(JsVisualisationError::NotAFunction { inner:set_size })
return Err(JsVisualizationError::NotAFunction { inner:set_size })
}
let set_data:js_sys::Function = set_data.into();
let set_size:js_sys::Function = set_size.into();
@ -132,22 +158,30 @@ impl JsRenderer {
/// ```no_run
/// use graph_editor::component::visualization::JsRenderer;
///
/// let renderer = JsRenderer::from_object("function() {
/// let renderer = JsRenderer::from_object_source(r#"function() {
/// class Visualization {
/// static inputTypes = ["[[Float,Float,Float]]"]
/// onDataReceived(root, data) {};
/// setSize(root, size) {};
/// }
/// return new Visualisation();
/// }()").unwrap();
/// return Visualization;
/// }()"#).unwrap();
///
/// ```
///
/// For a full example see
/// `crate::component::visualization::renderer::example::object_sample_js_bubble_chart`
pub fn from_object(source: &str) -> Result<JsRenderer,JsVisualisationError> {
pub fn from_object_source(source: &str) -> Result<JsRenderer,JsVisualizationError> {
let object = js_sys::eval(source)?;
if !object.is_object() {
return Err(JsVisualisationError::NotAnObject { inner:object } )
return Err(JsVisualizationError::NotAnObject { inner:object } )
}
Self::from_object_js(object.into())
}
pub(crate) fn from_object(object:JsValue) -> Result<JsRenderer,JsVisualizationError> {
if !object.is_object() {
return Err(JsVisualizationError::NotAnObject { inner:object } )
}
Self::from_object_js(object.into())
}
@ -165,26 +199,25 @@ impl JsRenderer {
/// onDataReceived(root, data) {};
/// setSize(root, size) {};
/// }
/// return new Visualisation();
/// return Visualization;
/// ").unwrap();
///
/// ```
/// For a full example see
/// `crate::component::visualization::renderer::example::constructor_sample_js_bubble_chart`
pub fn from_constructor(source:&str) -> Result<JsRenderer,JsVisualisationError> {
pub fn from_constructor(source:&str) -> Result<JsRenderer,JsVisualizationError> {
let context = JsValue::NULL;
let constructor = js_sys::Function::new_no_args(source);
let object = constructor.call0(&context)?;
if !object.is_object() {
return Err(JsVisualisationError::NotAnObject { inner:object } )
return Err(JsVisualizationError::NotAnObject { inner:object } )
}
Self::from_object_js(object.into())
}
/// Hooks the root node into the given scene.
///
/// MUST be called to make this visualisation visible.
// TODO[mm] find a better mechanism to ensure this. Probably through the registry later on.
/// MUST be called to make this visualization visible.
pub fn set_dom_layer(&self, scene:&DomScene) {
scene.manage(&self.root_node);
}

View File

@ -56,9 +56,7 @@ use nalgebra::Vector2;
use ensogl::display::Scene;
use crate::component::visualization::Visualization;
use crate::component::visualization;
use crate::component::visualization::example::js::constructor_sample_js_bubble_chart;
use crate::component::visualization::MockDataGenerator3D;
use crate::component::visualization::example::native;
@ -247,7 +245,7 @@ ensogl::def_command_api! { Commands
remove_selected_nodes,
/// Remove all nodes from the graph.
remove_all_nodes,
/// Toggle the visibility of the selected visualisations
/// Toggle the visibility of the selected visualizations
toggle_visualization_visibility,
@ -288,7 +286,7 @@ ensogl::def_command_api! { Commands
debug_set_data_for_selected_node,
/// Cycle the visualization for the selected nodes. TODO only has dummy functionality at the moment.
debug_cycle_visualisation_for_selected_node,
debug_cycle_visualization_for_selected_node,
}
impl Commands {
@ -318,7 +316,7 @@ impl Commands {
def toggle_node_inverse_select = source();
def debug_set_data_for_selected_node = source();
def debug_cycle_visualisation_for_selected_node = source();
def debug_cycle_visualization_for_selected_node = source();
}
Self {add_node,add_node_at_cursor,remove_selected_nodes,remove_all_nodes
@ -327,7 +325,7 @@ impl Commands {
,enable_node_merge_select,disable_node_merge_select,toggle_node_merge_select
,enable_node_subtract_select,disable_node_subtract_select,toggle_node_subtract_select
,enable_node_inverse_select,disable_node_inverse_select,toggle_node_inverse_select
,debug_set_data_for_selected_node,debug_cycle_visualisation_for_selected_node}
,debug_set_data_for_selected_node,debug_cycle_visualization_for_selected_node}
}
}
@ -358,6 +356,7 @@ pub struct FrpInputs {
pub translate_selected_nodes : frp::Source<Position>,
pub cycle_visualization : frp::Source<NodeId>,
pub set_visualization : frp::Source<(NodeId,Option<Visualization>)>,
pub register_visualization_class : frp::Source<Option<Rc<visualization::Handle>>>,
}
impl FrpInputs {
@ -380,13 +379,16 @@ impl FrpInputs {
def translate_selected_nodes = source();
def cycle_visualization = source();
def set_visualization = source();
def register_visualization_class = source();
}
let commands = Commands::new(&network);
Self {commands,remove_edge,press_node_input,remove_all_node_edges
,remove_all_node_input_edges,remove_all_node_output_edges,set_visualization_data
,connect_detached_edges_to_node,connect_edge_source,connect_edge_target
,set_node_position,select_node,translate_selected_nodes,set_node_expression
,connect_nodes,deselect_all_nodes,cycle_visualization,set_visualization}
,connect_nodes,deselect_all_nodes,cycle_visualization,set_visualization
,register_visualization_class
}
}
}
@ -789,17 +791,8 @@ impl GraphEditorModelWithNetwork {
));
}
let chart = constructor_sample_js_bubble_chart();
let dom_layer = model.scene.dom.layers.front.clone_ref();
chart.set_dom_layer(&dom_layer);
let vis = Visualization::new(chart);
node.view.frp.set_visualization.emit(Some(vis));
self.nodes.insert(node_id,node);
node_id
}
@ -1132,7 +1125,7 @@ impl application::shortcut::DefaultShortcutProvider for GraphEditor {
, Self::self_shortcut(shortcut::Action::press (&[Key::Shift,Key::Alt]) , "toggle_node_inverse_select")
, Self::self_shortcut(shortcut::Action::release (&[Key::Shift,Key::Alt]) , "toggle_node_inverse_select")
, Self::self_shortcut(shortcut::Action::press (&[Key::Character("d".into())]) , "debug_set_data_for_selected_node")
, Self::self_shortcut(shortcut::Action::press (&[Key::Character("f".into())]) , "debug_cycle_visualisation_for_selected_node")
, Self::self_shortcut(shortcut::Action::press (&[Key::Character("f".into())]) , "debug_cycle_visualization_for_selected_node")
]
}
}
@ -1208,6 +1201,9 @@ fn new_graph_editor(world:&World) -> GraphEditor {
let inputs = &model.frp;
let mouse = &scene.mouse.frp;
let touch = &model.touch_state;
let visualization_registry = visualization::Registry::with_default_visualizations();
let logger = &model.logger;
let outputs = UnsealedFrpOutputs::new();
let sealed_outputs = outputs.seal(); // Done here to keep right eval order.
@ -1414,12 +1410,8 @@ fn new_graph_editor(world:&World) -> GraphEditor {
})
}));
// === Vis Cycling ===
def _cycle_vis= inputs.debug_cycle_visualisation_for_selected_node.map(f!([inputs,nodes](_) {
def _cycle_vis = inputs.debug_cycle_visualization_for_selected_node.map(f!([inputs,nodes](_) {
nodes.selected.for_each(|node| inputs.cycle_visualization.emit(node));
}));
@ -1432,8 +1424,9 @@ fn new_graph_editor(world:&World) -> GraphEditor {
}
}));
// === Vis Update Data ===
// TODO remove this once real data is available.
let dummy_switch = Rc::new(Cell::new(false));
let sample_data_generator = MockDataGenerator3D::default();
def _set_dumy_data = inputs.debug_set_data_for_selected_node.map(f!([nodes](_) {
nodes.selected.for_each(|node_id| {
@ -1446,21 +1439,21 @@ fn new_graph_editor(world:&World) -> GraphEditor {
})
}));
def _set_dumy_data = inputs.cycle_visualization.map(f!([scene,nodes](node_id) {
// TODO remove dummy cycling once we have the visualization registry.
let dc = dummy_switch.get();
dummy_switch.set(!dc);
let vis = if dc {
Visualization::new(native::BubbleChart::new(&scene))
} else {
let chart = constructor_sample_js_bubble_chart();
let dom_layer = scene.dom.layers.front.clone_ref();
chart.set_dom_layer(&dom_layer);
Visualization::new(chart)
};
if let Some(node) = nodes.get_cloned_ref(node_id) {
let cycle_count = Rc::new(Cell::new(0));
def _cycle_visualization = inputs.cycle_visualization.map(f!([scene,nodes,visualization_registry,logger](node_id) {
let visualizations = visualization_registry.valid_sources(&"[[Float,Float,Float]]".into());
cycle_count.set(cycle_count.get() % visualizations.len());
let vis = &visualizations[cycle_count.get()];
let vis = vis.instantiate(&scene);
let node = nodes.get_cloned_ref(node_id);
match (vis, node) {
(Ok(vis), Some(node)) => {
node.view.visualization_container.frp.set_visualization.emit(Some(vis));
}
},
(Err(e), _) => logger.warning(|| format!("Failed to cycle visualization: {}", e)),
_ => {}
};
cycle_count.set(cycle_count.get() + 1);
}));
def _toggle_selected = inputs.toggle_visualization_visibility.map(f!([nodes](_) {
@ -1469,8 +1462,16 @@ fn new_graph_editor(world:&World) -> GraphEditor {
node.view.visualization_container.frp.toggle_visibility.emit(());
}
});
}));
// === Register Visualization ===
def _register_visualization = inputs.register_visualization_class.map(f!([visualization_registry](handle) {
if let Some(handle) = handle {
visualization_registry.register_class_from_handle(&handle);
}
}));
// === OUTPUTS REBIND ===