My Site Title

``` Meanwhile, any given HTML page can reference a list of stylesheets which can define a bunch of styles, where each style is tied to a selector (a rule which _selects_ what elements those styles apply to). A concrete example of a very short stylesheet can help here: ```css body { background-color: black; color: magenta } #title { color: yellow } ``` And you could use that stylesheet to style the following document: ```html

Yellow on black

Magenta on black ``` > [!NOTE] > When conflicting styles are present both in a stylesheet and as an inline declaration, the inline styles take > precedence. There's no hard and fast rule, but in general, when writing HTML / CSS by hand, stylesheets are often preferred over inline styles as it better maintains a separation of concerns. That is, the HTML should represent the content of your site, while the CSS controls the look and feel. However! We're not writing HTML / CSS by hand. We're using Compose HTML! Should we even care about this in Kotlin? As it turns out, there are times when you have to use stylesheets, because without them, you can't define styles for advanced behaviors (particularly [pseudo-classes](https://developer.mozilla.org/en-US/docs/Web/CSS/Pseudo-classes), [pseudo-elements](https://developer.mozilla.org/en-US/docs/Web/CSS/Pseudo-elements), and [media queries](https://developer.mozilla.org/en-US/docs/Web/CSS/Media_Queries/Using_media_queries)). For example, you can't override the color of visited links without using a stylesheet approach. So it's worth realizing there are fundamental differences. Finally, it can also be much easier debugging your page with browser tools when you lean on stylesheets over inline styles, as it makes your DOM tree easier to read when your elements are simple (e.g. `

` vs. `

`). --- We'll be introducing and discussing modifiers and CSS style blocks in more detail shortly. But in general, when you pass modifiers directly into a composable widget in Silk, those will result in inline styles, whereas if you use a CSS style block to define your styles, those will get embedded into the site's stylesheet: ```kotlin // Uses inline styles Box(Modifier.color(Colors.Red)) { /* ... */ } // Uses a stylesheet val BoxStyle = CssStyle { base { Modifier.Color(Colors.Red) } } Box(BoxStyle.toModifier()) { /* ... */ } ``` As a beginner, or even as an advanced user when prototyping, feel free to use inline modifiers as much as you can, pivoting to CSS style blocks if you find yourself needing to use pseudo-classes, pseudo-elements, or media queries. It is fairly easy to migrate inline styles over to stylesheets in Kobweb. In my own projects, I tend to use inline styles for really simple layout elements (e.g. `Row(Modifier.fillMaxWidth())`) and CSS style blocks for complex and/or re-usable widgets. It actually becomes a nice organizational convention to have all your styles grouped together in one place above the widget itself. ### Modifier Kobweb introduces the `Modifier` class, in order to provide an experience similar to what you find in Jetpack Compose. (You can read [more about them here](https://developer.android.com/jetpack/compose/modifiers) if you're unfamiliar with the concept). In the world of Compose HTML, you can think of a `Modifier` as a wrapper on top of CSS styles and attributes. > [!IMPORTANT] > Please refer to official documentation if you are not familiar with > HTML [attributes](https://developer.mozilla.org/en-US/docs/Web/HTML/Attributes) > and/or [styles](https://developer.mozilla.org/en-US/docs/Web/HTML/Element/style). So this: ```kotlin Modifier.backgroundColor(Colors.Red).color(Colors.Green).padding(200.px) ``` when passed into a widget provided by Kobweb, like `Box`: ```kotlin Box(Modifier.backgroundColor(Colors.Red).color(Colors.Green).padding(200.px)) { /* ... */ } ``` would generate an HTML tag with a style property like: `

` #### attrsModifier and styleModifier There are a bunch of modifier extensions (and they're growing) provided by Kobweb, like `background`, `color`, and `padding` above. But there are also two escape hatches anytime you run into a modifier that's missing: `attrsModifier` and `styleModifier`. At this point, you are interacting with Compose HTML, one layer underneath Kobweb. Using them looks like this: ```kotlin // Modify attributes of an element tag // e.g. the "a", "b", and "c" in Modifier.attrsModifier { id("example") } // Modify styles of an element tag // e.g. the "x", "y", and "z" in ` Modifier.styleModifier { width(100.percent) height(50.percent) } // Note: Because "style" itself is an attribute, you can define styles in an attrsModifier: Modifier.attrsModifier { id("example") style { width(100.percent) height(50.percent) } } // ... but in the above case, you should use a styleModifier for simplicity ``` In the occasional (and hopefully rare!) case where Kobweb doesn't provide a modifier and Compose HTML doesn't provide the attribute or style support you need, you can use `attrsModifier` plus the `attr` method or `styleModifier` plus the `property` method. This escape hatch within an escape hatch allows you to provide any custom value you need. The above cases can be rewritten as: ```kotlin Modifier.attrsModifier { attr("id", "example") } Modifier.styleModifier { property("width", 100.percent) // Or even raw CSS: // property("width", "100%") property("height", 50.percent) } ``` If you end up needing to use `attr` or `property` in your own codebase, consider [filing an issue](https://github.com/varabyte/kobweb/issues/new?assignees=&labels=enhancement&projects=&template=feature_request.md&title=) with us so that we can add the missing modifier to the library. ## Silk Silk is a UI layer included with Kobweb and built upon Compose HTML. While Compose HTML requires you to understand underlying HTML / CSS concepts, Silk attempts to abstract some of that away, providing an API more akin to what you might experience developing a Compose app on Android or Desktop. Less "div, span, flexbox, attrs, styles, classes" and more "Rows, Columns, Boxes, and Modifiers". We consider Silk a pretty important part of the Kobweb experience, but it's worth pointing out that it's designed as an optional component. You can absolutely use Kobweb without Silk. (You can also use Silk without Kobweb!). You can also interleave Silk and Compose HTML components easily (as Silk is just composing them itself). ### `@InitSilk` methods Before going further, we want to quickly mention you can annotate a method with `@InitSilk`, which will be called when your site starts up. This method must take a single `InitSilkContext` parameter. A context contains various properties that allow adjusting Silk defaults, which will be demonstrated in more detail in sections below. ```kotlin @InitSilk fun initSilk(ctx: InitSilkContext) { // `ctx` has a handful of properties which allow you to adjust Silk's default behavior. } ``` > [!TIP] > The names of your `@InitSilk` methods don't matter, as long as they're public, take a single `InitSilkContext` > parameter, and don't collide with another method of the same name. You are encouraged to choose a name for readability > purposes. > > You can define as many `@InitSilk` methods as you want, so feel free to break them up into relevant, clearly named > pieces, instead of declaring a single, monolithic, generically named `fun initSilk(ctx)` method that does everything. ### CssStyle With Silk, you can define a style like so, using the `CssStyle` function and the `base` block: ```kotlin val CustomStyle = CssStyle { base { Modifier.background(Colors.Red) } } ``` and convert it to a modifier by using `CustomStyle.toModifier()`. At this point, you can pass it into any composable which takes a `Modifier` parameter: ```kotlin // Approach #1 (uses inline styles) Box(Modifier.backgroundColor(Colors.Red)) { /* ... */ } // Approach #2 (uses stylesheets) Box(CustomStyle.toModifier()) { /* ... */ } ``` > [!IMPORTANT] > When you declare a `CssStyle`, it must be public. This is because code gets generated inside a `main.kt` file by > the Kobweb Gradle plugin, and that code needs to be able to access your style in order to register it. > > In general, it's a good idea to think of styles as global anyway, since technically they all live in a globally > applied stylesheet, and you have to make sure that the style name is unique across your whole application. > > You can technically make a style private if you add a bit of boilerplate to handle the registration yourself: > > ```kotlin > @Suppress("PRIVATE_COMPONENT_STYLE") > private val ExampleCustomStyle = CssStyle { /* ... */ } > // Or use a leading underscore to automatically suppress the warning > private val _ExampleOtherCustomStyle = CssStyle { /* ... */ } > > @InitSilk > fun registerPrivateStyle(ctx: InitSilkContext) { > // Kobweb will not be able to detect the property name, so a name must be provided manually > ctx.theme.registerStyle("example-custom", ExampleCustomStyle) > ctx.theme.registerStyle("example-other-custom", _ExampleOtherCustomStyle) > } > ``` > > However, you are encouraged to keep your styles public and let the Kobweb Gradle plugin handle everything for you. #### `CssStyle.base` You can simplify the syntax of basic style blocks a bit further with the `CssStyle.base` declaration: ```kotlin val CustomStyle = CssStyle.base { Modifier.background(Colors.Red) } ``` Just be aware you may have to break this out again if you find yourself needing to support [additional selectors▼](#additional-selectors). #### CssStyle name The Kobweb Gradle plugin automatically detects your `CssStyle` properties and generates a name for it for you, derived from the property name itself but using [Kebab Case](https://www.freecodecamp.org/news/snake-case-vs-camel-case-vs-pascal-case-vs-kebab-case-whats-the-difference/#kebab-case). For example, if you write `val TitleTextStyle = CssStyle { ... }`, its name will be "title-text". You usually won't need to care about this name, but there are niche cases where it can be useful to understand that is what's going on. If you need to set a name manually, you can use the `CssName` annotation to override the default name: ```kotlin @CssName("my-custom-name") val CustomStyle = CssStyle { base { Modifier.background(Colors.Red) } } ``` #### Additional selectors So, what's up with the `base` block? True, it looks a bit verbose on its own. However, you can define additional selector blocks that take effect conditionally. The base style will always apply first, but then any additional styles will be applied based on the specific selector's rules. > [!CAUTION] > Order matters when defining additional selectors, particularly if more than one of them modify the same CSS property > at the same time. Here, we create a style which is red by default but green when the mouse hovers over it: ```kotlin val CustomStyle = CssStyle { base { Modifier.color(Colors.Red) } hover { Modifier.color(Colors.Green) } } ``` Kobweb provides a bunch of standard selectors for you for convenience, but for those who are CSS-savvy, you can always define the CSS rule directly to enable more complex combinations or selectors that Kobweb hasn't added yet. For example, this is identical to the above style definition: ```kotlin val CustomStyle = CssStyle { base { Modifier.color(Colors.Red) } cssRule(":hover") { Modifier.color(Colors.Green) } } ``` #### Breakpoints There's a feature in the world of responsive HTML / CSS design called breakpoints, which confusingly have nothing to do with debugging breakpoints. Rather, they specify size boundaries for your site when styles change. This is how sites present content differently on mobile vs. tablet vs. desktop. Kobweb provides four breakpoint sizes you can use for your project, which, including using no breakpoint size at all, gives you five buckets you can work with when designing your site: * no breakpoint - mobile (and larger) * sm - tablets (and larger) * md - desktops (and larger) * lg - widescreen (and larger) * xl - ultra widescreen (and larger) You can change the default values of breakpoints for your site by adding an `@InitSilk` method to your code and setting `ctx.theme.breakpoints`: ```kotlin @InitSilk fun initializeBreakpoints(ctx: InitSilkContext) { ctx.theme.breakpoints = BreakpointSizes( sm = 30.cssRem, md = 48.cssRem, lg = 62.cssRem, xl = 80.cssRem, ) } ``` To reference a breakpoint in a `CssStyle`, just invoke it: ```kotlin val CustomStyle = CssStyle { base { Modifier.fontSize(24.px) } Breakpoint.MD { Modifier.fontSize(32.px) } } ``` > [!TIP] > When testing your breakpoint-conditional styles, you should be aware that browser dev tools let you simulate window > dimensions to see how your site looks at different sizes. For example, on Chrome, you can follow these instructions: > https://developer.chrome.com/docs/devtools/device-mode #### Color-mode aware When you define a `CssStyle`, a field called `colorMode` is available for you to use: ```kotlin val CustomStyle = CssStyle.base { Modifier.color(if (colorMode.isLight) Colors.Red else Colors.Pink) } ``` Silk defines a bunch of light and dark colors for all of its widgets, and if you'd like to re-use any of them in your own widget, you can query them using `colorMode.toPalette()`: ```kotlin val CustomStyle = CssStyle.base { Modifier.color(colorMode.toPalette().link.default) } ``` `SilkTheme` contains very simple (e.g. black and white) defaults, but you can override them in an `@InitSilk` method, perhaps to something that is more brand-aware: ```kotlin // Assume a bunch of color constants (e.g. BRAND_LIGHT_COLOR) are defined somewhere @InitSilk fun overrideSilkTheme(ctx: InitSilkContext) { ctx.theme.palettes.light.background = BRAND_LIGHT_BACKGROUND ctx.theme.palettes.light.color = BRAND_LIGHT_COLOR ctx.theme.palettes.dark.background = BRAND_DARK_BACKGROUND ctx.theme.palettes.dark.color = BRAND_DARK_COLOR } ``` #### Extending CSS styles You may find yourself occasionally wanting to define a style that should only be applied along with / after another style. The easiest way to accomplish this is by extending the base CSS style block, using the `extendedBy` method: ```kotlin val GeneralTextStyle = CssStyle { base { Modifier.fontSize(16.px).fontFamily("...") } } val EmphasizedTextStyle = GenerateTextStyle.extendedBy { base { Modifier.fontWeight(FontWeight.Bold) } } // Or, using the `base` methods: // val GeneralTextStyle = CssStyle.base { // Modifier.fontSize(16.px).fontFamily("...") // } // val EmphasizedTextStyle = GenerateTextStyle.extendedByBase { // Modifier.fontWeight(FontWeight.Bold) // } ``` Once extended, you only need to call `toModifier` on the extended style to include both styles automatically: ```kotlin SpanText("WARNING", EmphasizedTextStyle.toModifier()) // You do NOT need to reference the base style, i.e. // GeneralTextStyle.toModifier().then(EmphasizedTextStyle.toModifier()) ``` #### Component styles So far, we've discussed CSS style blocks as defining a general assortment of CSS style properties. However, there is a way to define typed CSS style blocks, which let you generate typed variants associated with, and only compatible with, a specific base style. The base style in this case is called a *component style* because the pattern is effective when defining widget components. In fact, it is the standard pattern that Silk uses for every single one of its widgets. We'll discuss this full pattern around building widgets using component styles later, but to start we'll demonstrate how to declare one. You create a marker interface that implements `ComponentKind` and then pass that into your `CssStyle` declaration block. For example, if you were creating your own `Button` widget: ```kotlin sealed interface ButtonKind : ComponentKind val ButtonStyle = CssStyle { /* ... */ } ``` Notice two points about our interface declaration: 1. It is marked `sealed`. This is technically not necessary to do, but we recommend it as a way to express your intention that no one else is going to subclass it further. 2. The interface is empty. It is just a marker interface, useful only in enforcing typing for variants. This is discussed more in the next section. Like normal `CssStyle` declarations, the associated name is derived from its property name. You can use a `@CssName` annotation to override this behavior. #### Component variants The power of component styles is they can generate *component variants*, using the `addVariant` method: ```kotlin val OutlinedButtonVariant: CssStyleVariant = ButtonStyle.addVariant { /* ... */ } ``` > [!NOTE] > The recommended naming convention for variants is to take their associated style and use its name as a suffix plus the > word "Variant", e.g. "ButtonStyle" -> "OutlinedButtonVariant" and "TextStyle" -> "EmphasizedTextVariant". > [!IMPORTANT] > Like a `CssStyle`, your `CssStyleVariant` must be public. This is for the same reason: because code gets generated > inside a `main.kt` file by the Kobweb Gradle plugin, and that code needs to be able to access your variant in order to > register it. > > You can technically make a variant private if you add a bit of boilerplate to handle the registration yourself: > > ```kotlin > @Suppress("PRIVATE_COMPONENT_VARIANT") > private val ExampleCustomVariant = ButtonStyle.addVariant { > /* ... */ > } > // Or, `private val _ExampleCustomVariant` > > @InitSilk > fun registerPrivateVariant(ctx: InitSilkContext) { > // When registering variants, using a leading dash will automatically prepend the bast style name. > // This example here will generate the final name "button-example". > ctx.theme.registerVariant("-example", ExampleCustomVariant) > } > ``` > > However, you are encouraged to keep your variants public and let the Kobweb Gradle plugin handle everything for you. The idea behind component variants is that they give the widget author power to define a base style along with one or more common tweaks that users might want to apply on top of it. (And even if a widget author doesn't provide any variants for the style, any user can always define their own in their own codebase.) Let's revisit the button style example, bringing everything together. ```kotlin sealed interface ButtonKind : ComponentKind val ButtonStyle = CssStyle { /* ... */ } // Note: Creates a CSS style called "button-outlined" val OutlinedButtonVariant = ButtonStyle.addVariant { /* ... */ } // Note: Creates a CSS style called "button-inverted" val InvertedButtonVariant = ButtonStyle.addVariant { /* ... */ } ``` When used with a component style, the `toModifier()` method optionally takes a variant parameter. When a variant is passed in, both styles will be applied -- the base style followed by the variant style. For example, `ButtonStyle.toModifier(OutlinedButtonVariant)` applies the main button style first layered on top with some additional outline styling. You can annotate style variants with the `@CssName` annotation, exactly like you can with `CssStyle`. Using a leading dash will automatically prepend the base style name. For example: ```kotlin @CssName("custom-name") val OutlinedButtonVariant = ButtonStyle.addVariant { /* ... */ } // Creates a CSS style called "custom-name" @CssName("-custom-name") val InvertedButtonVariant = ButtonStyle.addVariant { /* ... */ } // Creates a CSS style called "button-custom-name" ``` ##### `addVariantBase` Like `CssStyle.base`, variants that don't need to support additional selectors can use `addVariantBase` instead to slightly simplify their declaration: ```kotlin val HighlightedCustomVariant by CustomStyle.addVariantBase { Modifier.backgroundColor(Colors.Green) } // Short for // val HighlightedCustomVariant by CustomStyle.addVariant { // base { Modifier.backgroundColor(Colors.Green) } // } ``` #### Structuring code around component styles Silk uses component styles when defining its widgets, and you can too! The full pattern looks like this: ```kotlin sealed interface CustomWidgetKind : ComponentKind val CustomWidgetStyle = CssStyle { /* ... */ } @Composable fun CustomWidget( modifier: Modifier = Modifier, variant: CssStyleVariant? = null, @Composable content: () -> Unit ) { val finalModifier = CustomWidgetStyle.toModifier(variant).then(modifier) /* ... */ } ``` In other words: * you define a composable widget method * it should take in a `modifier` as its first optional parameter. * it should take in an optional `CssStyleVariant` parameter (typed to your unique `ComponentKind` implementation) * inside your widget, you should apply the modifiers in order of: base style, then variant, then user modifier. * it should end with a `@Composable` context lambda parameter (unless this widget doesn't support custom content) A caller might call your widget one of several ways: ```kotlin // Approach #1: Use default styling CustomWidget { /* ... */ } // Approach #2: Tweak default styling with a variant CustomWidget(variant = TransparentWidgetVariant) { /* ... */ } // Approach #3: Tweak default styling with inline overrides CustomWidget(Modifier.backgroundColor(Colors.Blue)) { /* ... */ } // Approach #4: Tweak default styling with both a variant and inline overrides CustomWidget(Modifier.backgroundColor(Colors.Blue), variant = TransparentWidgetVariant) { /* ... */ } ``` ### Animations In CSS, animations work by letting you define keyframes in a stylesheet which you then reference, by name, in an animation style. You can read more about them [on Mozilla's documentation site](https://developer.mozilla.org/en-US/docs/Web/CSS/CSS_Animations/Using_CSS_animations). For example, here's the CSS for an animation of a sliding rectangle ([from this tutorial](https://www.w3schools.com/cssref/tryit.php?filename=trycss3_animation)): ```css div { width: 100px; height: 100px; background: red; position: relative; animation: mymove 5s infinite; } @keyframes shift-right { from {left: 0px;} to {left: 200px;} } ``` Kobweb lets you define your keyframes in code by using a `Keyframes` block: ```kotlin val ShiftRightKeyframes = Keyframes { from { Modifier.left(0.px) } to { Modifier.left(200.px) } } // Later Div( Modifier .size(100.px).backgroundColor(Colors.Red).position(Position.Relative) .animation(ShiftRightKeyframes.toAnimation( duration = 5.s, iterationCount = AnimationIterationCount.Infinite )) .toAttrs() ) ``` The name of the keyframes block is automatically derived from the property name (here, `ShiftRightKeyframes` is converted into `"shift-right"`). You can then use the `toAnimation` method to convert your collection of keyframes into an animation that uses them, which you can pass into the `Modifier.animation` modifier. > [!IMPORTANT] > When you declare a `Keyframes` animation, it must be public. This is because code gets generated inside a `main.kt` > file by the Kobweb Gradle plugin, and that code needs to be able to access your variant in order to register it. > > In general, it's a good idea to think of animations as global anyway, since technically they all live in a globally > applied stylesheet, and you have to make sure that the animation name is unique across your whole application. > > You can technically make an animation private if you add a bit of boilerplate to handle the registration yourself: > > ```kotlin > @Suppress("PRIVATE_KEYFRAMES") > private val ExampleKeyframes = Keyframes { /* ... */ } > // Or, `private val _ExampleKeyframes` > > @InitSilk > fun registerPrivateAnim(ctx: InitSilkContext) { > ctx.stylesheet.registerKeyframes("example", ExampleKeyframes) > } > ``` > > However, you are encouraged to keep your keyframes public and let the Kobweb Gradle plugin handle everything for you. ### ElementRefScope and raw HTML elements Occasionally, you may need access to the raw element backing the Silk widget you've just created. All Silk widgets provide an optional `ref` parameter which takes a listener that provides this information. ```kotlin Box( ref = /* ... */ ) { /* ... */ } ``` All `ref` callbacks (discussed more below) will receive an `org.w3c.dom.Element` subclass. You can check out the [Element](https://kotlinlang.org/api/latest/jvm/stdlib/org.w3c.dom/-element/) class (and its often more relevant [HTMLElement](https://kotlinlang.org/api/latest/jvm/stdlib/org.w3c.dom/-h-t-m-l-element/) inheritor) to see the methods and properties that are available on it. Raw HTML elements expose a lot of functionality not available through the higher-level Compose HTML APIs. #### `ref` For a trivial but common example, we can use the raw element to capture focus: ```kotlin Box( ref = ref { element -> // Triggered when this Box is first added into the DOM element.focus() } ) ``` The `ref { ... }` method can actually take one or more optional keys of any value. If any of these keys change on a subsequent recomposition, the callback will be rerun: ```kotlin val colorMode by ColorMode.currentState Box( // Callback will get triggered each time the color mode changes ref = ref(colorMode) { element -> /* ... */ } ) ``` #### `disposableRef` If you need to know both when the element enters AND exits the DOM, you can use `disposableRef` instead. With `disposableRef`, the very last line in your block must be a call to `onDispose`: ```kotlin val activeElements: MutableSet = /* ... */ /* ... later ... */ Box( ref = disposableRef { element -> activeElements.put(element) onDispose { activeElements.remove(element) } } ) ``` The `disposableRef` method can also take keys that rerun the listener if any of them change. The `onDispose` callback will also be triggered in that case, as the old effect gets discarded. #### `refScope` And, finally, you may want to have multiple listeners that are recreated independently of one another based on different keys. You can use `refScope` as a way to combine two or more `ref` and/or `disposableRef` calls in any combination: ```kotlin val isFeature1Enabled: Boolean = /* ... */ val isFeature2Enabled: Boolean = /* ... */ Box( ref = refScope { ref(isFeature1Enabled) { element -> /* ... */ } disposableRef(isFeature2Enabled) { element -> /* ... */; onDispose { /* ... */ } } } ) ``` #### Compose HTML refs You may occasionally want the backing element of a normal Compose HTML widget, such as a `Div` or `Span`. However, these widgets don't have a `ref` callback, as that's a convenience feature provided by Silk. You still have a few options in this case. The official way to retrieve a reference is by using a `ref` block inside an `attrs` block. This version of `ref` is actually more similar to Silk's `disposableRef` concept than its `ref` one, as it requires an `onDispose` block: ```kotlin Div(attrs = { ref { element -> /* ... */; onDispose { /* ... */ } } }) ``` *The above snippet was adapted from [the official tutorials](https://github.com/JetBrains/compose-multiplatform/tree/master/tutorials/HTML/Using_Effects#ref-in-attrsbuilder).* You could put that exact same logic inside the `Modifier.toAttrs` block if you're terminating some modifier chain: ```kotlin Div(attrs = Modifier.toAttrs { ref { element -> /* ... */; onDispose { /* ... */ } } }) ``` Unlike Silk's version of `ref`, Compose HTML's version does not accept keys. If you need this behavior and if the Compose HTML widget accepts a content block (many of them do), you can call Silk's `registerRefScope` method directly within it: ```kotlin Div { registerRefScope( disposableRef { element -> /* ... */; onDispose { /* ... */ } } // or ref { element -> /* ... */ } ) } ``` ### Style Variables Kobweb supports CSS variables (also called CSS custom properties), which is a feature where you can store and retrieve property values from variables declared within your CSS styles. It does this through a class called `StyleVariable`. > [!NOTE] > You can find [official documentation for CSS custom properties here](https://developer.mozilla.org/en-US/docs/Web/CSS/Using_CSS_custom_properties). Using style variables is fairly simple. You first declare one without a value (but lock it down to a type) and later you can initialize it within a style using `Modifier.setVariable(...)`: ```kotlin val dialogWidth by StyleVariable() // This style will be applied to a div that lives at the root, so that // this variable value will be made available to all children. val RootStyle = CssStyle.base { Modifier.setVariable(dialogWidth, 600.px) } ``` > [!TIP] > Compose HTML provides a `CSSLengthValue`, which represents concrete values like `10.px` or `5.cssRem`. However, Kobweb > provides a `CSSLengthNumericValue` type which represents the concept more generally, e.g. as the result of > intermediate calculations. There are `CSS*NumericValue` types provided for all relevant units, and it is recommended > to use them when declaring style variables as they more naturally support being used in calculations. > > We discuss [CSSNumericValue types▼](#cssnumeric) in more detail later in this document. You can later query variables using the `value()` method to extract their current value: ```kotlin val DialogStyle = CssStyle.base { Modifier.width(dialogWidth.value()) } ``` You can also provide a fallback value, which, if present, would be used in the case that a variable hadn't already been set previously: ```kotlin val DialogStyle = CssStyle.base { // Will be the value of the dialogWidth variable if it was set, otherwise 500px Modifier.width(dialogWidth.value(500.px)) } ``` Additionally, you can also provide a default fallback value when declaring the variable: ```kotlin // Note the default fallback: 100px val dialogWidth by StyleVariable(100.px) val DialogStyle100 = CssStyle.base { // Uses default fallback. width = 100px Modifier.width(dialogWidth.value()) } val DialogStyle200 = CssStyle.base { // Uses specific fallback. width = 200px Modifier.width(dialogWidth.value(200.px)) } val DialogStyle300 = CssStyle.base { // Fallback (400px) ignored because variable is set explicitly. width = 300px Modifier.setVariable(dialogWidth, 300.px).width(dialogWidth.value(400.px)) } ``` > [!CAUTION] > In the above example in the `DialogStyle300` style, we set a variable and query it in the same line, which we did > purely for demonstration purposes. In practice, you would probably never do this -- the variable would have been set > separately elsewhere, e.g. in an inline style or on a parent container. To demonstrate these concepts all together, below we declare a background color variable, create a root container scope which sets it, a child style that uses it, and, finally, a child style variant that overrides it: ```kotlin // Default to a debug color, so if we see it, it indicates we forgot to set it later val bgColor by StyleVariable(Colors.Magenta) val ContainerStyle = CssStyle.base { Modifier.setVariable(bgColor, Colors.Blue) } val SquareStyle = CssStyle.base { Modifier.size(100.px).backgroundColor(bgColor.value()) } val RedSquareStyle = SquareStyle.extendedByBase { Modifier.setVariable(bgColor, Colors.Red) } ``` The following code brings the above styles together (and in some cases uses inline styles to override the background color further): ```kotlin @Composable fun ColoredSquares() { Box(ContainerStyle.toModifier()) { Column { Row { // 1: Read color from ContainerStyle Box(SquareStyle.toModifier()) // 2: Override color via RedSquareStyle Box(RedSquareStyle.toModifier()) } Row { // 3: Override color via inline styles Box(SquareStyle.toModifier().setVariable(bgColor, Colors.Green)) Span(Modifier.setVariable(bgColor, Colors.Yellow).toAttrs()) { // 4: Read color from parent's inline style Box(SquareStyle.toModifier()) } } } } } ``` The above renders the following output: ![Kobweb CSS Variables, Squares example](https://github.com/varabyte/media/raw/main/kobweb/images/kobweb-variable-squares-example.png) --- You can also set CSS variables directly from code if you have access to the backing HTML element. Below, we use the `ref` callback to get the backing element for a fullscreen `Box` and then use a `Button` to set it to a random color from the colors of the rainbow: ```kotlin // We specify the initial color of the rainbow here, since the variable // won't otherwise be set until the user clicks a button. val bgColor by StyleVariable(Colors.Red) val ScreenStyle = CssStyle.base { Modifier.fillMaxSize().backgroundColor(bgColor.value()) } @Page @Composable fun RainbowBackground() { val roygbiv = listOf(Colors.Red, /*...*/ Colors.Violet) var screenElement: HTMLElement? by remember { mutableStateOf(null) } Box(ScreenStyle.toModifier(), ref = ref { screenElement = it }) { Button(onClick = { // You can call `setVariable` on the backing HTML element to set the variable value directly screenElement!!.setVariable(bgColor, roygbiv.random()) }) { Text("Click me") } } } ``` The above results in the following UI: ![Kobweb CSS Variables, Rainbow example](https://github.com/varabyte/media/raw/main/kobweb/screencasts/kobweb-variable-roygbiv-example.gif) #### In many cases, don't use CSS Variables Most of the time, you can actually get away with not using CSS Variables! Your Kotlin code is often a more natural place to describe dynamic behavior than HTML / CSS is. Let's revisit the "colored squares" example from above. Note it's much easier to read if we don't try to use variables at all. ```kotlin val SquareStyle = CssStyle.base { Modifier.size(100.px) } @Composable fun ColoredSquares() { Column { Row { Box(SquareStyle.toModifier().backgroundColor(Colors.Blue)) Box(SquareStyle.toModifier().backgroundColor(Colors.Red)) } Row { Box(SquareStyle.toModifier().backgroundColor(Colors.Green)) Box(SquareStyle.toModifier().backgroundColor(Colors.Yellow)) } } } ``` And the "rainbow background" example is similarly easier to read by using Kotlin variables (i.e. `var someValue by remember { mutableStateOf(...) }`) instead of CSS variables: ```kotlin val ScreenStyle = CssStyle.base { Modifier.fillMaxSize() } @Page @Composable fun RainbowBackground() { val roygbiv = listOf(Colors.Red, /*...*/ Colors.Violet) var currColor by remember { mutableStateOf(Colors.Red) } Box(ScreenStyle.toModifier().backgroundColor(currColor)) { Button(onClick = { currColor = roygbiv.random() }) { Text("Click me") } } } ``` Even though you should rarely need CSS variables, there may be occasions where they can be a useful tool in your toolbox. The above examples were artificial scenarios used as a way to show off CSS variables in relatively isolated environments. But here are some situations that might benefit from CSS variables: * You have a site which allows users to choose from a list of several themes (e.g. primary and secondary colors). It would be trivial enough to add CSS variables for `themePrimary` and `themeSecondary` (applied at the site's root) which you can then reference throughout your styles. * You need more control for colors in your theming than can be provided for by the simple light / dark color mode. For example, Wordle has light / dark + normal / contrast modes. * You want to create a widget which dynamically changes its behavior based on the context it is added within. For example, maybe your site has a dark area and a light area, and the widget should use white outlines in the dark area and black outlines in the light. This can be accomplished by exposing an outline color variable, which each area of your site is responsible for setting. * You want to allow the user to tweak values within a pseudo-class selector (e.g. hover, focus, active) for some widget (e.g. color or border size), which is much easier to do using variables than listening to events and setting inline styles. * You have a widget that you ended up creating a bunch of variants for, but instead you realize you could replace them all with one or two CSS variables. When in doubt, lean on Kotlin for handling dynamic behavior, and occasionally consider using style variables if you feel doing so would clean up the code. ### Font Awesome Kobweb provides the `silk-icons-fa` artifact which you can use in your project if you want access to all the free Font Awesome (v6) icons. Using it is easy! Search the [Font Awesome gallery](https://fontawesome.com/search?o=r&m=free), choose an icon, and then call it using the associated Font Awesome icon composable. For example, if I wanted to add the Kobweb-themed [spider icon](https://fontawesome.com/icons/spider?s=solid&f=classic), I could call this in my Kobweb code: ```kotlin FaSpider() ``` That's it! Some icons have a choice between solid and outline versions, such as "Square" ([outline](https://fontawesome.com/icons/square?s=solid&f=classic) and [filled](https://fontawesome.com/icons/square?s=regular&f=classic)). In that case, the default choice will be an outline mode, but you can pass in a style enum to control this: ```kotlin FaSquare(style = IconStyle.FILLED) ``` All Font Awesome composables accept a modifier parameter, so you can tweak it further: ```kotlin FaSpider(Modifier.color(Colors.Red)) ``` > [!NOTE] > When you create a project using our `app` template, Font Awesome icons are included. ### Material Design Icons Kobweb provides the `silk-icons-mdi` artifact which you can use in your project if you want access to all the free Material Design icons. Using it is easy! Search the [Material Icons gallery](https://fonts.google.com/icons?icon.set=Material+Icons), choose an icon, and then call it using the associated Material Design Icon composable. For example, let's say after a search I found and wanted to use their [bug report icon](https://fonts.google.com/icons?icon.set=Material+Icons&icon.query=bug+report), I could call this in my Kobweb code by converting the name to camel case: ```kotlin MdiBugReport() ``` That's it! Most material design icons support multiple styles: outlined, filled, rounded, sharp, and two-tone. Check the gallery search link above to verify what styles are supported by your icon. You can identify the one you want to use by passing it into the method's `style` parameter: ```kotlin MdiLightMode(style = IconStyle.TWO_TONED) ``` All Material Design Icon composables accept a modifier parameter, so you can tweak it further: ```kotlin MdiError(Modifier.color(Colors.Red)) ``` ## Layouts, Sections, and Widgets Outside of pages, it is common to create reusable, composable parts. While Kobweb doesn't enforce any particular rule here, we recommend a convention that, if followed, may make it easier to allow new readers of your codebase to get around. First, as a sibling to pages, create a folder called **components**. Within it, add: * **layouts** - High-level composables that provide entire page layouts. Most (all?) of your `@Page` pages will start by calling a page layout function first. It's possible that you will only need a single layout for your entire site. * **sections** - Medium-level composables that represent compound areas inside your pages, organizing a collection of many children composables. If you have multiple layouts, it's likely sections would be shared across them. For example, nav headers and footers are great candidates for this subfolder. * **widgets** - Low-level composables. Focused UI pieces that you may want to reuse all around your site. For example, a stylized visitor counter would be a good candidate for this subfolder. ## Markdown If you create a markdown file under the `jsMain/resources/markdown` folder, a corresponding page will be created for you at build time, using the filename as its path. For example, if I create the following file: ```markdown // jsMain/resources/markdown/docs/tutorial/Kobweb.md # Kobweb Tutorial ... ``` this will create a page that I can then visit by going to `mysite.com/docs/tutorial/kobweb` ### Front Matter Front Matter is metadata that you can specify at the beginning of your document, like so: ```markdown --- title: Tutorial author: bitspittle --- ... ``` In a following section, we'll discuss how to embed code in your markdown, but for now, know that these key / value pairs can be queried in code using the page's context: ```kotlin @Composable fun AuthorWidget() { val ctx = rememberPageContext() // Note: You can use `markdown!!` only if you're sure that // this composable is called while inside a page generated // from Markdown. val author = ctx.markdown!!.frontMatter.getValue("author").single() Text("Article by $author") } ``` > [!IMPORTANT] > If you're not seeing `ctx.markdown` autocomplete, you need to make sure you depend on the > `com.varabyte.kobwebx:kobwebx-markdown` artifact in your project's `build.gradle`. #### Root Within your front matter, there's a special value which, if set, will be used to render a root `@Composable` that adds the rest of your markdown code as its content. This is useful for specifying a layout for example: ```markdown --- root: .components.layout.DocsLayout --- # Kobweb Tutorial ``` The above will generate code like the following: ```kotlin import com.mysite.components.layout.DocsLayout @Composable @Page fun KobwebPage() { DocsLayout { H1 { Text("Kobweb Tutorial") } } } ``` If you have a default root that you'd like to use in most / all of your markdown files, you can specify it in the markdown block in your build script: ```kotlin // site/build.gradle.kts kobweb { markdown { defaultRoot.set(".components.layout.MarkdownLayout") } } ``` #### Route Override Kobweb Markdown front matter supports a `routeOverride` key. If present, its value will be passed into the generated `@Page` annotation (see the [Route Override section▲](#route-override) for valid values here). This allows you to give your URL a name that normal Kotlin filename rules don't allow for, such as a hyphen: `# AStarDemo.md` ```markdown --- routeOverride: a*-demo --- ``` The above will generate code like the following: ```kotlin @Composable @Page("a*-demo") fun AStarDemoPage() { /* ... */ } ``` ### Kobweb Call The power of Kotlin + Compose HTML is interactive components, not static text! Therefore, Kobweb Markdown support enables special syntax that can be used to insert Kotlin code. #### Block syntax Usually, you will define widgets that belong in their own section. Just use three triple-curly braces to insert a function that lives in its own block: ```markdown # Kobweb Tutorial ... {{{ .components.widgets.VisitorCounter }}} ``` which will generate code for you like the following: ```kotlin @Composable @Page fun KobwebPage() { /* ... */ com.mysite.components.widgets.VisitorCounter() } ``` You may have noticed that the code path in the markdown file is prefixed with a `.`. When you do that, the final path will automatically be prepended with your site's full package. #### Inline syntax Occasionally, you may want to insert a smaller widget into the flow of a single sentence. For this case, use the `${...}` inline syntax: ```markdown Press ${.components.widgets.ColorButton} to toggle the site's current color. ``` > [!CAUTION] > Spaces are not allowed within the curly braces! If you have them there, Markdown skips over the whole thing and leaves > it as text. ### Imports You may wish to add imports to the code generated from your markdown. Kobweb Markdown supports registering both *global* imports (imports that will be added to every generated file) and *local* imports (those that will only apply to a single target file). #### Global Imports To register a global import, you configure the `markdown` block in your build script: ```kotlin // site/build.gradle.kts kobweb { markdown { imports.add(".components.widgets.*") } } ``` Notice that you can begin your path with a "." to tell the Kobweb Markdown plugin to prepend your site's package to it. The above would ensure that every markdown file generated would have the following import: ```kotlin import com.mysite.components.widgets.* ``` Imports can help you simplify your Kobweb calls. Revisiting an example from just above: ```markdown # Without imports Press ${.components.widgets.ColorButton} to toggle the site's current color. # With imports Press ${ColorButton} to toggle the site's current color. ``` #### Local Imports Local imports are specified in your markdown's front matter (and can even affect its root declaration!): ```markdown --- root: DocsLayout imports: - .components.sections.DocsLayout - .components.widgets.VisitorCounter --- ... {{{ VisitorCounter }}} ``` ### Iterating over all markdown files It can be really useful to process all markdown files during your site's build. A common example is to collect all markdown articles and generate a listing page from them. You can actually do this using pure Gradle code, but it's common enough that Kobweb provides a convenience API, via the `markdown` block's `process` callback. You can register a callback that will be triggered at build time with a list of all markdown files in your project. ```kotlin kobweb { markdown { process.set { markdownEntries -> // `markdownEntries` is type `List`, where an entry includes the file's path, the route it will // be served at, and any parsed front matter. println("Processing markdown files:") markdownEntries.forEach { entry -> println("\t* ${entry.filePath} -> ${entry.route}") } } } } ``` Inside the callback, you can also call `generateKotlin` and `generateMarkdown` utility methods. Here is a very rough example of creating a listing page for all blog posts in a site (found under the `resources/markdown/blog` folder): ```kotlin kobweb { markdown { process.set { markdownEntries -> generateMarkdown("blog/index.md", buildString { appendLine("# Blog Index") markdownEntries.forEach { entry -> if (entry.filePath.startsWith("blog/")) { val title = entry.frontMatter["title"] ?: "Untitled" appendLine("* [$title](${entry.route})") } } }) } } } ``` Refer to the build script of [my open source blog site](https://github.com/bitspittle/bitspittle.dev/blob/main/site/build.gradle.kts) and search for "process.set" to see this feature in action in a production environment. ## Learning CSS through Kobweb Many developers new to web development have heard horror stories about CSS, and they might hope that Kobweb, by leveraging Kotlin and a Jetpack Compose-inspired API, means they won't have to learn it. It's worth dispelling that illusion! CSS is inevitable. That said, CSS's reputation is probably worse than it deserves to be. Many of its features are actually fairly straightforward and some are quite powerful. For example, you can efficiently declare that your element should be wrapped with a thin border, with round corners, casting a drop shadow beneath it to give it a feeling of depth, painted with a gradient effect for its background, and animated with an oscillating, tilting effect. It's hoped that, once you've learned a bit of CSS through Kobweb, you'll find yourself actually enjoying it (sometimes)! ### Ways Kobweb helps with CSS Kobweb offers enough of a layer of abstraction that you can learn CSS in a more incremental way. First and most importantly, Kobweb gives you a Kotlin-idiomatic type-safe API to CSS properties. This is a major improvement over writing CSS in text files which fail silently at runtime. Next, layout widgets like `Box`, `Column`, and `Row` can get you up and running quickly with rich, complex layouts before ever having to understand what a "flex layout" is. Meanwhile, using `CssStyle` can help you break your CSS up into smaller, more manageable pieces that live close to the code that actually uses them, allowing your project to avoid a giant, monolithic CSS file. (Such giant CSS files are one of the reasons CSS has an intimidating reputation). For example, a CSS file that could easily look like this: ```css /* Dozens of rules... */ .important { background-color: red; font-weight: bold; } .important:hover { background-color: pink; } /* Dozens of other rules... */ .post-title { font-size: 24px; } /* A dozen more more rules... */ ``` can migrate to this in Kobweb: ```kotlin //------------------ CriticalInformation.kt val ImportantStyle = CssStyle { base { Modifier.backgroundColor(Colors.Red).fontWeight(FontWeight.Bold) } hover { Modifier.backgroundColor(Colors.Pink) } } //------------------ Post.kt val PostTitleStyle = CssStyle.base { Modifier.fontSize(24.px) } ``` Next, Silk provides a `deferRender` method which lets you declare code that won't get rendered until the rest of the DOM finishes first, meaning it will appear on top of everything else. This is a clean way to avoid setting CSS z-index values (another aspect of CSS that has a bad reputation). And finally, Silk aims to provide widgets with default styles that look good for many sites. This means you should be able to rapidly develop common UIs without running into some of the more complex aspects of CSS. ### A concrete example Let's walk through an example of layering CSS effects on top of a basic element. > [!TIP] > Two of the best learning resources for CSS properties are `https://developer.mozilla.org` > and `https://www.w3schools.com`. Keep an eye out for these when you do a web search. We'll create the bordered, floating, oscillating element we discussed earlier. Rereading it now, here are the concepts we need to figure out how to do: * Create a border * Round out the corners * Add a drop shadow * Add a gradient background * Add a wobble animation Let's say we want to create an attention grabbing "welcome" widget on our site. You can always start with an empty box, which we'll put some text in: ```kotlin Box(Modifier.padding(topBottom = 5.px, leftRight = 30.px)) { Text("WELCOME!!") } ``` ![Learning CSS in Kobweb, Step 1 (base)](https://github.com/varabyte/media/raw/main/kobweb/images/css/css-example-step-1.png) **Create a border** Next, search the internet for "CSS border". One of the top links should be: https://developer.mozilla.org/en-US/docs/Web/CSS/border Skim the docs and play around with the interactive examples. With an understanding of the border property now, let's use code completion to discover the Kobweb version of the API: ```kotlin Box( Modifier .padding(topBottom = 5.px, leftRight = 30.px) .border(1.px, LineStyle.Solid, Colors.Black) ) { Text("WELCOME!!") } ``` ![Learning CSS in Kobweb, Step 2 (border added)](https://github.com/varabyte/media/raw/main/kobweb/images/css/css-example-step-2.png) **Round out the corners** Search for "CSS rounded corners". It turns out the CSS property in this case is called a "border radius": https://developer.mozilla.org/en-US/docs/Web/CSS/border-radius ```kotlin Box( Modifier .padding(topBottom = 5.px, leftRight = 30.px) .border(1.px, LineStyle.Solid, Colors.Black) .borderRadius(5.px) ) { Text("WELCOME!!") } ``` ![Learning CSS in Kobweb, Step 3 (corners rounded)](https://github.com/varabyte/media/raw/main/kobweb/images/css/css-example-step-3.png) **Add a drop shadow** Search for "CSS shadow". There are a few types of CSS shadow features, but after some quick reading, we realize we want to use box shadows: https://developer.mozilla.org/en-US/docs/Web/CSS/box-shadow After playing around with blur and spread values, we get something that looks decent: ```kotlin Box( Modifier .padding(topBottom = 5.px, leftRight = 30.px) .border(1.px, LineStyle.Solid, Colors.Black) .borderRadius(5.px) .boxShadow(blurRadius = 5.px, spreadRadius = 3.px, color = Colors.DarkGray) ) { Text("WELCOME!!") } ``` ![Learning CSS in Kobweb, Step 4 (box shadow added)](https://github.com/varabyte/media/raw/main/kobweb/images/css/css-example-step-4.png) **Add a gradient background** Search for "CSS gradient background". This isn't a straightforward CSS property like the previous cases, so we instead get a more general documentation page explaining the feature: https://developer.mozilla.org/en-US/docs/Web/CSS/CSS_images/Using_CSS_gradients This case turns out to be a little trickier to ultimately find the Kotlin, type-safe equivalent, but if you dig a bit more into the CSS docs, you'll learn that a linear gradient is a type of background image. ```kotlin Box( Modifier .padding(topBottom = 5.px, leftRight = 30.px) .border(1.px, LineStyle.Solid, Colors.Black) .borderRadius(5.px) .boxShadow(blurRadius = 5.px, spreadRadius = 3.px, color = Colors.DarkGray) .backgroundImage(linearGradient(LinearGradient.Direction.ToRight, Colors.LightBlue, Colors.LightGreen)) ) { Text("WELCOME!!") } ``` ![Learning CSS in Kobweb, Step 5 (gradient background added)](https://github.com/varabyte/media/raw/main/kobweb/images/css/css-example-step-5.png) **Add a wobble animation** And finally, search for "CSS animations": https://developer.mozilla.org/en-US/docs/Web/CSS/CSS_animations/Using_CSS_animations You can review the [Animations▲](#animations) section above for a refresher on how Kobweb supports this feature, which requires declaring a top-level `Keyframes` block which then gets referenced inside an animation modifier: ```kotlin // Top level property val WobbleKeyframes = Keyframes { from { Modifier.rotate((-5).deg) } to { Modifier.rotate(5.deg) } } // Inside your @Page composable Box( Modifier .padding(topBottom = 5.px, leftRight = 30.px) .border(1.px, LineStyle.Solid, Colors.Black) .borderRadius(5.px) .boxShadow(blurRadius = 5.px, spreadRadius = 3.px, color = Colors.DarkGray) .backgroundImage(linearGradient(LinearGradient.Direction.ToRight, Colors.LightBlue, Colors.LightGreen)) .animation( WobbleKeyframes.toAnimation( duration = 1.s, iterationCount = AnimationIterationCount.Infinite, timingFunction = AnimationTimingFunction.EaseInOut, direction = AnimationDirection.Alternate, ) ) ) { Text("WELCOME!!") } ``` ![Learning CSS in Kobweb, Step 6 (wobble animation added)](https://github.com/varabyte/media/raw/main/kobweb/screencasts/css/css-example-step-6.gif) **And we're done!** The above element isn't going to win any style awards, but I hope this demonstrates how much power CSS can give you in just a few declarative lines of code. And thanks to the nature of CSS, combined with Kobweb's live reloading experience, we were able to experiment with our idea incrementally. ### CSS 2 Kobweb One of our main project contributors created a site called [CSS 2 Kobweb](https://opletter.github.io/css2kobweb/) which aims to simplify the process of converting CSS examples to equivalent Kobweb `CssStyle` and/or `Modifier` declarations. ![CSS 2 Kobweb example](https://github.com/varabyte/media/raw/main/kobweb/images/css/css2kobweb.png) > [!TIP] > [CSS 2 Kobweb](https://opletter.github.io/css2kobweb/) also supports specifying class name selectors and keyframes. > For example, see what happens when you paste in the following CSS code: > ```css > .site-banner { > position: relative; > padding-left: 10px; > padding-top: 5%; > animation: slide-in 3s linear 1s infinite; > background-position: bottom 10px right; > background-image: linear-gradient(to bottom, #eeeeee, white 25px); > } > .site-banner:hover { > color: rgb(40, 40, 40); > } > @keyframes slide-in { > from { > transform: translateX(-2rem) scale(0.5); > } > to { > transform: translateX(0); > opacity: 1; > } > } > ``` The web is full of examples of interesting CSS effects. Almost any CSS-related search will result in tons of StackOverflow answers, interactive playgrounds featuring WYSIWYG editors, and blog posts. Many of these introduce some really novel CSS examples. This is a great way to learn more about web development! However, as the previous section demonstrated, it can sometimes be a pain to go from a CSS example to the equivalent Kobweb code. We hope that *CSS 2 Kobweb* can help with that. This project is already very useful, but it's still early days. If you find cases of *CSS 2 Kobweb* that are incorrect, please consider [filing an issue](https://github.com/opLetter/css2kobweb/issues) in their repository. ### Still stuck? Hopefully this section gave you insight into how you can explore CSS APIs on your own, but if you're stuck on getting an effect working, remember you can reach out to one of the options in the [connecting with us▼](#connecting-with-us) section, and someone in the community can probably help! ## Exporting your site One of Kobweb's major additions on top of Compose HTML is the export process. This feature elevates the framework from one that produces a single-page application to one that produces a whole, navigable site. The export process takes snapshots of every page, resulting in better SEO support and a quicker initial render. A normal development workflow will have you using `kobweb run` to build up your site, and then when you're ready to publish it, you'll `kobweb export` a production version. ### A concrete export example Let's take a moment to walk through this process in more detail, in order to demystify it. The `index.html` file of a normal Compose HTML site looks like this: ```html My Site Title

``` > [!NOTE] > For example, you can find this exact structure > recommended [in the official Getting Started instructions](https://github.com/JetBrains/compose-multiplatform/tree/master/tutorials/HTML/Getting_Started#6-add-the-indexhtml-file-to-the-resources). What this does is declare a root element whose contents will get filled out dynamically at runtime. You can think of the `mysite.js` script at the end of the file as the seed that grows into your website. This is very powerful, but when you build a website with this approach, you run into two major issues: 1. As your codebase grows larger, `mysite.js` gets bigger and bigger, meaning a larger download is required before the site gets rendered. 2. Search engines have a harder time indexing your site, because they can't see the content until the JavaScript executes. Any web crawler that doesn't execute JavaScript will see a blank page. OK, so let's add Kobweb into the mix. Here, we build a very minimal page and export our site (using `kobweb export`) to see what happens. ```kotlin @Page @Composable fun ExampleKobwebPage() { Text("This is a minimal example to demonstrate exporting.") } ``` Exporting generates the following HTML under your `kobweb/.site` folder, which I've reproduced here with a bunch of styles elided: ```html My Site Title

This is a minimal example to demonstrate exporting.

``` As you can see, Kobweb has filled out a bunch of extra information, although the site script it still linked to at the bottom of the file. This is important since, as mentioned earlier in this section, it contains all information necessary not just to render this page but the whole site. In other words, you can download just this page and then continue to navigate around the site without needing to download any more files. In short, the export process will discover all `@Page`-annotated methods in your codebase and generate a snapshot of each one. You can think of each snapshot as an SEO-friendly starting point from which you can access the rest of your site. ### Exporting requires a browser In order for Kobweb exporting to be able to take a snapshot of your site, it needs to spin up a browser in headless mode. This browser is responsible for loading the simple Compose HTML version of an `index.html` page and running its JavaScript to fill out the page. The browser will then get queried for the final html which Kobweb saves to disk. Kobweb delegates much of this task to Microsoft's excellent [Playwright framework](https://playwright.dev/). Hopefully this will be invisible to almost all users, but for advanced cases, it can be useful to know the technology that's running under the hood. For custom CI/CD setups, you will at the very least need to be aware that the Kobweb export process requires a browser. For users who would like more information about this, we discuss one example in more detail later, in the [GitHub Workflow for exports▼](#exporting-your-site-in-a-github-workflow) section. ### Static layout vs. Full stack sites There are two flavors of Kobweb sites: *static* and *full stack*. #### Static layout sites A *static* site (or, more completely, a *static layout* site) is one where you export a bunch of frontend files (e.g. `html`, `js`, and public resources) into a single, organized folder that gets served directly by a [static website hosting provider](https://en.wikipedia.org/wiki/Web_hosting_service#Static_page_hosting). In other words, you don't write a single line of server code. The server is provided for you in this case and uses a fairly straightforward algorithm - it hosts all the content you upload to it as raw, static assets. The name *static* does not refer to the behavior of your site but rather that of your hosting provider solution. If someone makes a request for a page, the same response bytes get served every time (even if that page is full of custom code that allows it to behave in very interactive ways). #### Full stack sites A *full stack* site is one where you write both the logic that runs on the frontend (i.e. on the user's machine) and the logic that runs on the backend (i.e. on a server somewhere). This custom server must at least serve requested files (exactly the same job that a static web hosting service does) plus it likely also defines endpoints providing custom functionality tailored to your site's needs. For example, maybe you define an endpoint which, given a user ID and an authentication token, returns that user's profile information. #### Choosing the right site layout for your project When Kobweb was first written, it only provided the full stack solution, as being able to write your own server logic enabled a maximum amount of power and flexibility. The mental model for using Kobweb during this early time was simple and clear. However, in practice, most projects don't need the power afforded by a full stack setup. A website can give users a very clean, dynamic experience simply by writing responsive frontend logic to make it look good, e.g. with animations and delightful user interactions. Additionally, many "*Feature* as a Service" solutions have popped up over the years, which can provide a ton of convenient functionality that used to require a custom server. These days, you can easily integrate auth, database, and analytics solutions all without writing a single line of backend code. The process for exporting a bunch of files in a way that can be consumed by a static web hosting provider tends to be *much* faster *and* cheaper than using a full stack solution. Therefore, you should prefer a static site layout unless you have a specific need for a full stack approach. Some possible reasons to use a custom server (and, therefore, a full stack approach) are: * needing to communicate with other, private backend services in your company. * intercepting requests as an intermediary for some third-party service where you own a very sensitive API key that you don't want to leak (such as a service that delegates to ChatGPT). * acting as a hub to connect multiple clients together (such as a chat server). If you aren't sure which category you fall into, then you should probably be creating a static layout site. It's much easier to migrate from a static layout site to a full stack site later than the other way around. ### Exporting and running Both site flavors require an export. To export your site with a static layout, use the `kobweb export --layout static` command, while for full stack the command is `kobweb export --layout fullstack` (or just `kobweb export` since `fullstack` is the default layout as it originally was the only way). Once exported, you can test your site by running it locally before uploading. You run a static site with `kobweb run --env prod --layout static` and a full stack site with `kobweb run --env prod --layout fullstack` (or just `kobweb run --env prod`). ### Dynamic routes and exporting Dynamic routes are skipped over by the export process. After all, it's not possible to know all the possible values that could be passed into a dynamic route. However, if you have a specific instance of a dynamic route that you'd like to export, you can configure your site's build script as follows: ```kotlin kobweb { app { export { // "/users/{user}/posts/{post}" has special handling for the "default" / "0" case addExtraRoute("/users/default/posts/0", "users/index.html") } } } ``` ### Deploying A static site gets exported into `.kobweb/site` by default (you can configure this location in your `.kobweb/conf.yaml` file if you'd like). You can then upload the contents of that folder to the static web hosting provider of your choice. Deploying a full stack site is a bit more complex, as different providers have wildly varying setups, and some users may even decide to run their own web server themselves. However, when you export your Kobweb site, scripts are generated for running your server, both for *nix platforms (`.kobweb/server/start.sh`) and the Windows platform (`.kobweb/server/start.bat`). If the provider you are using speaks Dockerfile, you can set `ENTRYPOINT` to either of these scripts (depending on the server's platform). Going in more detail than this is outside the scope of this README. However, you can read my blog posts for a lot more information and some clear, concrete examples: * [Static site generation and deployment with Kobweb](https://bitspittle.dev/blog/2022/static-deploy) * [Deploying Kobweb into the cloud](https://bitspittle.dev/blog/2023/cloud-deploy) # Intermediate topics ## Specifying your application root By default, Kobweb will automatically root every page to the [`KobwebApp` composable](https://github.com/varabyte/kobweb/blob/main/frontend/kobweb-core/src/jsMain/kotlin/com/varabyte/kobweb/core/App.kt) (or, if using Silk, to a [`SilkApp` composable](https://github.com/varabyte/kobweb/blob/main/frontend/kobweb-silk/src/jsMain/kotlin/com/varabyte/kobweb/silk/SilkApp.kt)). These perform some minimal common work (e.g. applying CSS styles) that should be present across your whole site. This means if you register a page: ```kotlin // jsMain/kotlin/com/mysite/pages/Index.kt @Page @Composable fun HomePage() { /* ... */ } ``` then the final result that actually runs on your site will be: ```kotlin // In a generated main.kt somewhere... KobwebApp { HomePage() } ``` It is likely you'll want to configure this further for your own application. Perhaps you have some initialization logic that you'd like to run before any page gets run (like logic for updating saved settings into local storage). And for many apps it's a great place to specify a full screen Silk `Surface` as that makes all children beneath it transition between light and dark colors smoothly. In this case, you can create your own root composable and annotate it with `@App`. If present, Kobweb will use that instead of its own default. You should, of course, delegate to `KobwebApp` (or `SilkApp` if using Silk), as the initialization logic from those methods should still be run. Here's an example application composable override that I use in many of my own projects: ```kotlin @App @Composable fun MyApp(content: @Composable () -> Unit) { SilkApp { val colorMode = ColorMode.current LaunchedEffect(colorMode) { // Relaunched every time the color mode changes localStorage.setItem("color-mode", colorMode.name) } // A full screen Silk surface. Sets the background based on Silk's palette and animates color changes. Surface(SmoothColorStyle.toModifier().minHeight(100.vh)) { content() } } } ``` You can define *at most* a single `@App` on your site, or else the Kobweb Application plugin will complain at build time. ## Updating default HTML styles with Silk The default styles picked by browsers for many HTML elements rarely fit most site designs, and it's likely you'll want to tweak at least some of them. A very common example of this is the default web font, which if left as is will make your site look a bit archaic. Most traditional sites overwrite styles by creating a CSS stylesheet and then linking to it in their HTML. However, if you are using Silk in your Kobweb application, you can use an approach very similar to `CssStyle` discussed above but for general HTML elements. To do this, create an `@InitSilk` method. The context parameter includes a `stylesheet` property that represents the CSS stylesheet for your site, providing a Silk-idiomatic API for adding CSS rules to it. Below is a simple example that sets the whole site to more aesthetically pleasing fonts than the browser defaults, one for regular text and one for code: ```kotlin @InitSilk fun initSilk(ctx: InitSilkContext) { ctx.stylesheet.registerStyleBase("body") { Modifier.fontFamily("Ubuntu", "Roboto", "Arial", "Helvetica", "sans-serif") .fontSize(18.px) .lineHeight(1.5) } ctx.stylesheet.registerStyleBase("code") { Modifier.fontFamily("Ubuntu Mono", "Roboto Mono", "Lucida Console", "Courier New", "monospace") } } ``` > [!TIP] > The `registerStyleBase` method is commonly used for registering styles with minimal code, but you can also use > `registerStyle`, especially if you want to add some support for one or more pseudo-classes ( > e.g. `hover`, `focus`, `active`): > > ```kotlin > ctx.stylesheet.registerStyle("code") { > base { > Modifier > .fontFamily("Ubuntu Mono", "Roboto Mono", "Lucida Console", "Courier New", "monospace") > .userSelect(UserSelect.None) // No copying code allowed! > } > hover { > Modifier.cursor(Cursor.NotAllowed) > } > } > ``` ## Setting application globals Occasionally you might find yourself with a value at build time that you want your site to know at runtime. For example, maybe you want to specify a version based on the current UTC timestamp. Or maybe you want to read a system environment variable's value and pass that into your Kobweb site as a way to configure its behavior. This is supported via Kobweb's `AppGlobals` singleton, which is like a `Map` whose values you can set from your project's build script using the `kobweb.app.globals` property. Let's demonstrate this with the UTC version example. In your application's `build.gradle.kts`, add the following code: ```kotlin import java.time.LocalDateTime import java.time.ZoneId import java.time.format.DateTimeFormatter plugins { /* ... */ alias(libs.plugins.kobweb.application) } kobweb { app { globals.put( "version", LocalDateTime .now(ZoneId.of("UTC")) .format(DateTimeFormatter.ofPattern("yyyyMMdd.kkmm")) ) } } ``` You can then access them via the `AppGlobals.get` or `AppGlobals.getValue` methods: ```kotlin val version = AppGlobals.getValue("version") ``` In your Kotlin project somewhere, it is recommended that you either add some type-safe extension methods, or you can create your own wrapper object (based on your preference): ```kotlin // SiteGlobals.kt import com.varabyte.kobweb.core.AppGlobals // Extension method approach --------------------- val AppGlobals.version: String get() = getValue("version") // Wrapper object approach ----------------------- object SiteGlobals { val version: String = AppGlobals.getValue("version") } ``` At this point, you can access this value in your site's code, say for a tiny label that would look good in a footer perhaps: ```kotlin // components/widgets/SiteVersion.kt val VersionTextStyle = CssStyle.base { Modifier.fontSize(0.6.cssRem) } @Composable fun SiteVersion(modifier: Modifier = Modifier) { SpanText("v" + SiteGlobals.version, VersionTextStyle.toModifier().then(modifier)) } ``` ## Globally replacing Silk widget styles As mentioned earlier, Silk widgets all use [component styles▲](#component-styles) to power their look and feel. Normally, if you want to tweak a style in select locations within your site, you just create a variant from that style: ```kotlin val TweakedButtonVariant = ButtonStyle.addVariantBase { /* ... */ } // Later... Button(variant = TweakedButtonVariant) { /* ... */ } ``` But what if you want to globally change the look and feel of a widget across your entire site? You could of course create your own composable which wraps some underlying composable with its own new style, e.g. `MyButton` which defines its own `MyButtonStyle` that internally delegates to `Button`. However, you'd have to be careful to make sure all new developers who add code to your site know to use `MyButton` instead of `Button` directly. Silk provides another way, allowing you to modify any of its declared styles and/or variants in place. You can do this via an `@InitSilk` method, which takes an `InitSilkContext` parameter. This context provides the `theme` property, which provides the following family of methods for rewriting styles and variants: ```kotlin @InitSilk fun replaceStylesAndOrVariants(ctx: InitSilkContext) { ctx.theme.replaceStyle(SomeStyle) { /* ... */ } ctx.theme.replaceVariant(SomeVariant) { /* ... */ } ctx.theme.modifyStyle(SomeStyle) { /* ... */ } ctx.theme.modifyVariant(SomeVariant) { /* ... */ } } ``` > [!NOTE] > Technically, you can use these methods with your own site's declared styles and variants as well, but there should be > no reason to do so since you can just go to the source and change those values directly. However, this can still be > useful if you're using a third-party Kobweb library that provides its own styles and/or variants. Use the `replace` versions if you want to define a whole new set of CSS rules from scratch, or use the `modify` versions to layer additional changes on top of what's already there. > [!CAUTION] > Using `replace` on some of the more complex Silk styles can be tricky, and you may want to familiarize yourself with > the details of how those widgets are implemented before attempting to do so. Additionally, once you replace a style > in your site, you will be opting-out of any future improvements to that style that may be made in future versions of > Silk. Here's an example of replacing `ImageStyle` on a site that wants to force all images to have rounded corners and automatically scale down to fit their container: ```kotlin @InitSilk fun replaceSilkImageStyle(ctx: InitSilkContext) { ctx.theme.replaceStyleBase(ImageStyle) { Modifier .clip(Rect(cornerRadius = 8.px)) .fillMaxWidth() .objectFit(ObjectFit.ScaleDown) } } ``` and here's an example for a site that always wants its horizontal dividers to fill max width: ```kotlin @InitSilk fun makeHorizontalDividersFillWidth(ctx: InitSilkContext) { ctx.theme.modifyStyleBase(HorizontalDividerStyle) { Modifier.fillMaxWidth() } } ``` ## Communicating with the server Let's say you've decided on creating a full stack website using Kobweb. This section walks you through setting it up as well as introducing the various APIs for communicating to the backend from the frontend. ### Declare a full stack project A Kobweb project will always at least have a JavaScript component, but if you declare a JVM target, that will be used to define custom server logic that can then be used by your Kobweb site. It's easiest to let Kobweb do it for you. In your site's build script, make sure you've declared `configAsKobwebApplication(includeServer = true)`: ```kotlin // site/build.gradle.kts import com.varabyte.kobweb.gradle.application.util.configAsKobwebApplication plugins { alias(libs.plugins.kotlin.multiplatform) alias(libs.plugins.jetbrains.compose) alias(libs.plugins.kobweb.application) } /* ... */ kotlin { configAsKobwebApplication(includeServer = true) /* ... */ } ``` > [!IMPORTANT] > `configAsKobwebApplication(includeServer = true)` declares and sets up both `js()` and `jvm()` > [Kotlin Multiplatform targets](https://kotlinlang.org/docs/multiplatform-set-up-targets.html) for you. If you don't > set `includeServer = true` explicitly, only the JS target will be declared. The easy way to check if everything is set up correctly is to open your project inside IntelliJ IDEA, wait for it to finish indexing, and check that the `jvmMain` folder is detected as a module (if so, it will be given a special icon and look the same as the `jsMain` folder): ![Kobweb JVM main set up correctly](https://github.com/varabyte/media/raw/main/kobweb/images/kobweb-jvm-main.png) ### Define API routes You can define and annotate methods which will generate server endpoints you can interact with. To add one: 1. Define your method (optionally `suspend`able) in a file somewhere under the `api` package in your `jvmMain` source directory. 1. The method should take exactly one argument, an `ApiContext`. 1. Annotate it with `@Api` For example, here's a simple method that echoes back an argument passed into it: ```kotlin // jvmMain/kotlin/com/mysite/api/Echo.kt @Api suspend fun echo(ctx: ApiContext) { // ctx.req is for the incoming request, ctx.res for responding back to the client // Params are parsed from the URL, e.g. here "/api/echo?message=..." val msg = ctx.req.params["message"] ?: "" ctx.res.setBodyText(msg) } ``` After running your project, you can test the endpoint by visiting `mysite.com/api/echo?message=hello` You can also trigger the endpoint in your frontend code by using the extension `api` property added to the `kotlinx.browser.window` class: ```kotlin @Page @Composable fun ApiDemoPage() { val coroutineScope = rememberCoroutineScope() Button(onClick = { coroutineScope.launch { println("Echoed: " + window.api.get("echo?message=hello").decodeToString()) } }) { Text("Click me") } } ``` All the HTTP methods are supported (`post`, `put`, etc.). These methods will throw an exception if the request fails for any reason. Note that for every HTTP method, there's a corresponding "try" version that will return null instead (`tryPost`, `tryPut`, etc.). If you know what you're doing, you can of course always use [`window.fetch(...)`](https://developer.mozilla.org/en-US/docs/Web/API/fetch) directly. ### Responding to an API request When you define an API route, you are expected to set a status code for the response, or otherwise it will default to status code `404`. In other words, the following API route stub will return a 404: ```kotlin @Api suspend fun error404(ctx: ApiContext) { } ``` In contrast, this minimal API route returns an OK status code: ```kotlin @Api suspend fun noActionButOk(ctx: ApiContext) { ctx.res.status = 200 } ``` This design was chosen to allow you to conditionally handle API routes based on input conditions. A very common case is creating an API route that only handles POST requests: ```kotlin @Api suspend fun updateUser(ctx: ApiContext) { if (ctx.req.method != HttpMethod.POST) return // ... ctx.res.status = 200 } ``` Finally, note that you can add headers to your response. A common endpoint that some servers provide is a redirect (302) with an updated URL location. This would look like: ```kotlin @Api suspend fun redirect(ctx: ApiContext) { if (ctx.req.method != HttpMethod.GET) return ctx.res.headers["Location"] = "..." ctx.res.status = 302 } ``` Simple! > [!NOTE] > The `ctx.res.setBodyText` method sets the status code to 200 automatically for you, which is why code in the previous > section worked without setting the status directly. Of course, if you wanted to return a different status code value > after setting the body text, you could update it explicitly yourself after the `setBodyText` call. ### `@InitApi` methods and initializing services Kobweb also supports declaring methods that should be run when your server starts up, which is particularly useful for initializing services that your `@Api` methods can then use. These methods must be annotated with `@InitApi` and must take a single `InitApiContext` parameter. > [!IMPORTANT] > If you are running a development server and change any of your backend code, causing a live reloading event, the > init methods will be run again. The `InitApiContext` class exposes a mutable set property (called `data`) which you can put anything into. Meanwhile, `@Api` methods expose an immutable version of `data`. This allows you to initialize a service in an `@InitApi` method and then access it in your `@Api` methods. Let's demonstrate a concrete example, imagining we had an interface called `Database` with a mutable subclass `MutableDatabase` that implements it and provides additional APIs for mutating the database. The skeleton for registering and later querying such a database instance might look like this: ```kotlin @InitApi fun initDatabase(ctx: InitApiContext) { val db = MutableDatabase() db.createTable("users", listOf("id", "name")).apply { addRow(listOf("1", "Alice")) addRow(listOf("2", "Bob")) } db.loadResource("products.csv") ctx.data.add(db) } @Api fun getUsers(ctx: ApiContext) { if (ctx.req.method != HttpMethod.GET) return val db = ctx.data.get() ctx.res.setBodyText(db.query("SELECT * FROM users").toString()) } ``` ### Define API streams Kobweb servers also support persistent connections via streams. Streams are essentially named channels that maintain continuous contact between the client and the server, allowing either to send messages to the other at any time. This is especially useful if you want your server to be able to communicate updates to your client without needing to poll. Additionally, multiple clients can connect to the same stream. In this case, the server can choose to not only send a message back to your client, but also to broadcast messages to all users (or a filtered subset of users) on the same stream. You could use this, for example, to implement a chat server with rooms. #### Example API stream Like API routes, API streams must be defined under the `api` package in your `jvmMain` source directory. By default, the name of the stream will be derived from the file name and path that it's declared in (e.g. "api/lobby/Chat.kt" will create a channel named "lobby/chat"). Unlike API routes, API streams are defined as properties, not methods. This is because API streams need to be a bit more flexible than routes, since streams consist of multiple distinct events: client connection, client messages, and client disconnection. Also unlike API routes, streams do not have to be annotated. The Kobweb Application plugin can automatically detect them. For example, here's a simple stream, declared on the backend, that echoes back any argument it receives: ```kotlin // jvmMain/kotlin/com/mysite/api/Echo.kt val echo = object : ApiStream { override suspend fun onClientConnected(ctx: ClientConnectedContext) { // Optional: ctx.stream.broadcast a message to all other clients that ctx.clientId connected // Optional: Update ctx.data here, initializing data associated with ctx.clientId } override suspend fun onTextReceived(ctx: TextReceivedContext) { ctx.stream.send(ctx.text) } override suspend fun onClientDisconnected(ctx: ClientDisconnectedContext) { // Optional: ctx.stream.broadcast a message to all other clients that ctx.clientId disconnected // Optional: Update ctx.data here, removing data associated with ctx.clientId } } ``` To communicate with an API stream from your site, you need to create a stream connection on the client: ```kotlin @Page @Composable fun ApiStreamDemoPage() { val echoStream = rememberApiStream("echo", object : ApiStreamListener { override fun onConnected(ctx: ConnectedContext) {} override fun onTextReceived(ctx: TextReceivedContext) { console.log("Echoed: ${ctx.text}") } override fun onDisconnected(ctx: DisconnectedContext) {} }) Button(onClick = { echoStream.send("hello!") }) { Text("Click me") } } ``` After running your project, you can click on the button and check the console logs. If everything is working properly, you should see "Echoed: hello!" for each time you press the button. > [!TIP] > The `examples/chat` template project uses API streams to implement a very simple chat application, so you can > reference that project for a more realistic example. #### API stream conveniences The above example was intentionally verbose, to showcase the broader functionality around API streams. However, depending on your use-case, you can elide a fair bit of boilerplate. First of all, the connect and disconnect handlers are optional, so you can omit them if you don't need them. Let's simplify the echo example: ```kotlin // Backend val echo = object : ApiStream { override suspend fun onTextReceived(ctx: TextReceivedContext) { ctx.stream.send(ctx.text) } } // Frontend val echoStream = rememberApiStream("echo", object : ApiStreamListener { override fun onTextReceived(ctx: TextReceivedContext) { console.log("Echoed: ${ctx.text}") } }) ``` Additionally, if you only care about the text event, there are convenience methods for that: ```kotlin // Backend val echo = ApiStream { ctx -> ctx.stream.send(ctx.text) } // Frontend val echoStream = rememberApiStream("echo") { ctx -> console.log("Echoed: ${ctx.text}") } ``` In practice, your API streams will probably be a bit more involved than the echo example above, but it's nice to know that you can handle some cases only needing a one-liner on the server and another on the client to create a persistent client-server connection! > [!NOTE] > If you need to create an API stream with stricter control around when it actually connects to the server, you can > create the `ApiStream` object directly instead of using `rememberApiStream`: > ```kotlin > val echoStream = remember { ApiStream("echo") } > val scope = rememberCoroutineScope() > > // Later, perhaps after a button is clicked... > scope.launch { > echoStream.connect(object : ApiStreamListener { /* ... */ }) > } > ``` ### API routes vs. API streams When faced with a choice, use API routes as often as you can. They are conceptually simpler, and you can query API endpoints with a CLI program like curl and sometimes even visit the URL directly in your browser. They are great for handling queries of or updates to server resources in response to user-driven actions (like visiting a page or clicking on a button). Every operation you perform returns a clear response code in addition to some payload information. Meanwhile, API streams are very flexible and can be a natural choice to handle high-frequency communication. But they are also more complex. Unlike a simple request / response pattern, you are instead opting in to manage a potentially long lifetime during which you can receive any number of events. You may have to concern yourself about interactions between all the clients on the stream as well. API streams are fundamentally stateful. You often need to make a lot of decisions when using API streams. What should you do if a client or server disconnects earlier than expected? How do you want to communicate to the client that their last action succeeded or failed (and you need to be clear about exactly which action because they might have sent another one in the meantime)? What structure do you want to enforce, if any, between a client and server connection where both sides can send messages to each other at any time? Most importantly, API streams may not horizontally scale as well as API routes. At some point, you may find yourself in a situation where a new web server is spun up to handle some intense load. If you're using API routes, you're already probably delegating to a database service as your data backend, so this may just work seamlessly. But for API streams, you many naturally find yourself writing a bunch of broadcasting code. However, this only works to communicate between all clients that are connected to the same server. Two clients connected to the same stream on different servers are effectively in different, disconnected worlds. The above situation is often handled by using a pubsub service (like Redis). This feels somewhat equivalent to using a database as a service in the API route situation, but this code might not be as straightforward to migrate. API routes and API streams are not a you-must-use-one-or-the-other situation. Your project can use both! In general, try to imagine the case where a new server might get spun up, and design your code to handle that situation gracefully. API routes are generally safe to use, so use them often. However, if you have a situation where you need to communicate events in real-time, especially situations where you want your client to be continuously directed what to do by the server via events, API streams are a great choice. > [!NOTE] > You can also search online about REST vs WebSockets, as these are the technologies that API routes and API streams are > implemented with. Any discussions about them should apply here as well. ## Splitting Kobweb code across multiple modules For simplicity, new projects can choose to put all their pages and widgets inside a single application module, e.g. `site/`. However, you can define components and/or pages in separate modules and apply the `com.varabyte.kobweb.library` plugin on them (in contrast to your main module which applies the `com.varabyte.kobweb.application` plugin.) In other words, you can split up and organize your project like this: ``` my-project ├── sitelib │ ├── build.gradle.kts # apply "com.varabyte.kobweb.library" │ └── src/jsMain │ └── kotlin.org.example.myproject.sitelib │ ├── components │ └── pages └── site ├── build.gradle.kts # apply "com.varabyte.kobweb.application" ├── .kobweb/conf.yaml └── src/jsMain └── kotlin.org.example.myproject.site ├── components └── pages ``` If you'd like to explore a multimodule project example, you can do so by running: ```bash $ kobweb create examples/chat ``` which demonstrates a chat application with its auth and chat functionality each managed in their own separate modules. ## Creating a Kobweb Worker ### Background: What are web workers? [Web workers](https://developer.mozilla.org/en-US/docs/Web/API/Web_Workers_API) are a standard web technology that allow you to run JavaScript code in a separate thread from your main application. Although JavaScript is famously single-threaded, web workers offer a way for you to run potentially expensive code in parallel to your main site without slowing it down. A web worker script is entirely isolated from your main site and has no access to the DOM. The only way to communicate between them is via message passing. > [!NOTE] > Astute readers may recognize the [actor model](https://en.wikipedia.org/wiki/Actor_model) here, which is an effective > way to allow concurrency without worrying about common synchronization issues that plague common lock-based > approaches. A somewhat forced but easy-to-understand example of a web worker is one that computes the first N prime numbers. While the worker is crunching away on intensive calculations, your site still works as normal, fully responsive. When the worker is finished, it posts a message to the application, which handles it by updating relevant UI elements. ### Web workers wrapped in Kobweb Kobweb aims to make using web workers as easy as possible. Here's everything you have to do (we'll show examples of these steps shortly): * Create a new module and apply the Kobweb Worker Gradle plugin on it. * Tag the `kotlin { ... }` block in your build script with a `configAsKobwebWorker()` call. * (Optional but recommended) Specify a name for your worker. Otherwise, the generic name "worker" (with a short random suffix) will be used, which is functional but may make it harder to debug if something goes wrong. * Declare a dependency on `"com.varabyte.kobweb:kobweb-worker"`. * Implement the `WorkerFactory` interface, providing a `WorkerStrategy` that represents the core logic of your worker. ### Example Worker module build file ```kotlin import com.varabyte.kobweb.gradle.worker.util.configAsKobwebWorker plugins { alias(libs.plugins.kotlin.multiplatform) alias(libs.plugins.kobweb.worker) // or id("com.varabyte.kobweb.worker") } group = "example.worker" version = "1.0-SNAPSHOT" kotlin { configAsKobwebWorker("example-worker") sourceSets { jsMain.dependencies { implementation(libs.kobweb.worker) // or "com.varabyte.kobweb:kobweb-worker" } } } ``` ### Worker factory The `WorkerFactory` interface is minimal: ```kotlin interface WorkerFactory { fun createStrategy(postOutput: OutputDispatcher): WorkerStrategy fun createIOSerializer(): IOSerializer } ``` This concise interface still captures a lot of information. It declares: * What types your worker accepts as input and output messages. * How it serializes those input and output messages. * The strategy for handling input messages from the application. * A `postOutput` object that can be used to send output messages back to the application. The `WorkerStrategy` class represents the core logic your worker does after receiving input from the application, as well as exposes a [`self`](https://developer.mozilla.org/en-US/docs/Web/API/WorkerGlobalScope/self) parameter that provides useful worker functionality. ```kotlin abstract class WorkerStrategy { protected val self: DedicatedWorkerGlobalScope abstract fun onInput(inputMessage: InputMessage) } ``` The `OutputDispatcher` is a simple class which allows you to send output messages back to the application. ```kotlin class OutputDispatcher { operator fun invoke(output: O, transferables: Transferables = Transferables.Empty) } // `postOutput: OutputDispatcher` can be called like a normal method, e.g. `postOutput("hello!")` ``` > [!NOTE] > Do not worry about the `Transferables` parameter for now. Transferable objects are a somewhat niche, > performance-related feature, and they will be discussed later. It is not expected that a majority of workers will > require them. Finally, `IOSerializer` is responsible for marshalling objects between the worker and the application. ```kotlin interface IOSerializer { fun serializeInput(input: I): String fun deserializeInput(input: String): I fun serializeOutput(output: O): String fun deserializeOutput(output: String): O } ``` This class allows you to use the serialization library of your choice. However, as you'll see later, this can be a one-liner for developers using Kotlinx Serialization. ### Worker Once the Kobweb Worker Gradle plugin finds your worker factory implementation, it will generate a simple `Worker` class that wraps it. ```kotlin // Generated code! class Worker(val onOutput: WorkerContext.(O) -> Unit) { fun postInput(input: I, transferables: Transferables = Transferables.Empty) fun terminate() } ``` Applications will interact with this `Worker` and not the `WorkerStrategy` directly. In fact, you should make your worker factory implementation `internal` to prevent applications from seeing anything but the worker. You should think of the `WorkerStrategy` as representing implementation details while the `Worker` class represents a public API. In other words, the `WorkerStrategy` receives inputs, processes data, and posts outputs, while the `Worker` allows users to post inputs and get notified when outputs are ready. An application module (i.e. one that applies the Kobweb Application Gradle plugin) will automatically discover any Kobweb worker dependencies, extracting its worker script and putting it under the `public/` folder of your final site. ### WorkerFactory examples The following sections introduce concrete worker factories, which should help solidify the abstract concepts introduced above. #### EchoWorkerFactory The simplest worker strategy possible is one that blindly repeats back whatever input it receives. This is never a worker strategy that you'd actually create -- there wouldn't be a need for it -- but it's a good starting point for seeing a worker factory in action. When you have a worker strategy that works with raw strings like this one does, you can use a one-line helper method to implement the `createIOSerializer` method, called `createPassThroughSerializer` (since it just passes the raw strings unmodified). ```kotlin // Worker module internal class EchoWorkerFactory : WorkerFactory { override fun createStrategy(postOutput: OutputDispatcher) = WorkerStrategy { input -> postOutput(input) } override fun createIOSerializer() = createPassThroughSerializer() } ``` Based on that implementation, a worker called `EchoWorker` will be auto-generated at compile time. Using it in your application looks like this: ```kotlin // Application module val worker = rememberWorker { EchoWorker { message -> println("Echoed: $message") } } // Later worker.postInput("hello!") // After a round trip: "Echoed: hello!" ``` That's it! > [!IMPORTANT] > Note the use of the `rememberWorker` method. This internally calls a `remember` but also sets up disposal logic that > terminates the worker when the composable is exited. If you just use a normal `remember` block, the worker may keep > running longer than you expect, even if you navigate to another part of your site. > > You can also stop a worker yourself by calling `worker.terminate()` directly. #### CountDownWorkerFactory This next worker strategy will take in an `Int` value from the user. This number represents how many seconds to count down, firing a message for each second that passes. This is another strategy that you'd never need in practice -- you'd just use the `window.setInterval` method yourself in your site script -- but we'll show this anyway to demonstrate two additional concepts on top of the echo worker: * How to define a custom message serializer. * The fact that you can call `postOutput` as often as you want. ```kotlin // Worker module internal class CountDownWorkerFactory : WorkerFactory { override fun createStrategy(postOutput: OutputDispatcher) = WorkerStrategy { input -> var nextCount = input var intervalId: Int = 0 intervalId = self.setInterval({ // A postOutput(nextCount) // B if (nextCount > 0) { --nextCount } else { self.clearInterval(intervalId) } }, 1000) } override fun createIOSerializer() = object : IOSerializer { // C override fun serializeInput(input: Int) = input.toString() override fun deserializeInput(input: String) = input.toInt() override fun serializeOutput(output: Int) = output.toString() override fun deserializeOutput(output: String) = output.toInt() } } ``` Notice the three comment tags above. * **A:** We use `self.setInterval` (and `self.clearInterval` later) instead of the `window` object to do this. This is because the `window` object is only available in the main script and using it here will throw an exception. * **B:** You can use `postOutput` any time following an input message, not just in direct response to one. * **C:** This is how you define a custom message serializer. You shouldn't worry about receiving improperly formatted strings in your `deserialize` calls, because you control them! In other words, the only way you'd get a bad string is if you generated it yourself in either of the `serialize` methods. If a message serializer ever does throw an exception, then the Kobweb worker will simply ignore it as a bad message. Using the worker in your application looks like this: ```kotlin // Application module val worker = rememberWorker { CountDownWorker { if (it > 0) { console.log(it + "...") } else { console.log("HAPPY NEW YEAR!!!") } } } // Later worker.postInput(10) // 10... 9... 8... etc. ``` > [!TIP] > If you need really accurate, consistent interval timers, creating a worker like this may actually be beneficial. > According to [this article](https://hackwild.com/article/web-worker-timers/), web worker timers are slightly more > accurate than timers run in the main thread, as they don't have to compete with the rest of the site's > responsibilities. Also, it seems that web workers timers stay consistent even if the site tab loses focus. #### FindPrimesWorkerFactory Finally, we get to the worker idea we introduced in the very first section -- finding the first N primes. This kind of worker likely looks like one that would actually get used in a real codebase, that being a worker which performs a potentially expensive, UI-agnostic calculation. We'll also use this example to demonstrate how to use Kotlinx Serialization to easily declare rich input and output message types. First, add `kotlinx-serialization` and `kobwebx-serialization-kotlinx` to your dependencies: ```kotlin // build.gradle.kts kotlin { configAsKobwebWorker() jsMain.dependencies { implementation(libs.kotlinx.serialization.json) // or "org.jetbrains.kotlinx:kotlinx-serialization-json" implementation(libs.kobwebx.worker.kotlinx.serialization) // or "com.varabyte.kobwebx:kobwebx-serialization-kotlinx" } } ``` Then, define the worker factory: ```kotlin @Serializable data class FindPrimesInput(val max: Int) @Serializable data class FindPrimesOutput(val max: Int, val primes: List) private fun findPrimes(max: Int): List { // Loop through all numbers, taking out multiples of each prime // e.g. 2 will take out 4, 6, 8, 10, etc. // then 3 will take out 9, 15, 21, etc. (6, 12, and 18 were already removed) val primes = (1..max).toMutableList() var primeIndex = 1 // Skip index 0, which is 1. while (primeIndex < primes.lastIndex) { val prime = primes[primeIndex] var maybePrimeIndex = primeIndex + 1 while (maybePrimeIndex <= primes.lastIndex) { if (primes[maybePrimeIndex] % prime == 0) { primes.removeAt(maybePrimeIndex) } else { ++maybePrimeIndex } } primeIndex++ } return primes } internal class FindPrimesWorkerFactory: WorkerFactory { override fun createStrategy(postOutput: OutputDispatcher) = object : WorkerStrategy() { override fun onInput(inputMessage: InputMessage) { val input = inputMessage.input postOutput(FindPrimesOutput(input.max, findPrimes(input.max))) } } override fun createIOSerializer() = Json.createIOSerializer() } ``` Most of the complexity above is the `findPrimes` algorithm itself! The `onInput` handler is about as easy as it gets. Notice that we pass the input `max` value back into the output, so that the receiving application can easily correlate the output with the input. And finally, note the use of the `Json.createIOSerializer` method call. This utility method comes from the `kobwebx-serialization-kotlinx` dependency, allowing you to use a one-liner to implement all the serialization methods for you. > [!TIP] > It's fairly trivial to write the message serializer yourself if you don't want to pull in the extra dependency (or if > you are using a different serialization library): > > ```kotlin > object : IOSerializer { > override fun serializeInput(input: FindPrimesInput): String = Json.encodeToString(input) > override fun deserializeInput(input: String): FindPrimesInput = Json.decodeFromString(input) > override fun serializeOutput(output: FindPrimesOutput): String = Json.encodeToString(output) > override fun deserializeOutput(output: String): FindPrimesOutput = Json.decodeFromString(output) > } > ``` Using the worker in your application looks like this: ```kotlin // Application module val worker = rememberWorker { FindPrimesWorker { println("Primes for ${it.max}: ${it.primes}") } } // Later worker.postInput(FindPrimesInput(1000)) // Primes for 1000: [1, 2, 3, 5, 7, 11, ..., 977, 983, 991, 997] ``` The richly-typed input and output messages allow for a very explicit API here, and in the future, more parameters could be added (with default values) to either input or output classes, extending the functionality of your workers without breaking existing code. We don't show it here, but you could also create sealed classes for your input and output messages, allowing you to define multiple types of messages that your worker can receive and respond to. ### Transferables Occasionally, you may find yourself with a very large blob of data in your main application that you want to pass to a worker (or vice versa!). For example, maybe your worker will be responsible for processing a potentially large, multi-megabyte image. Serializing a large amount of data can be expensive! In fact, you may find that even though your worker can run efficiently on a background thread, sending a large amount of data to it can cause your site to experience a significant pause during the copy. This can easily be seconds if the data is large enough! This isn't just an issue with Kobweb. This was originally a problem with standard web APIs. To support this use-case, web workers introduced the concept of [transferable objects](https://developer.mozilla.org/en-US/docs/Web/API/Web_Workers_API/Transferable_objects). Instead of an object being copied over, its ownership is transferred over from one thread to another. Attempts to use the object in the original thread after that point will throw an exception. Kobweb workers support transferable objects in a type-safe, Kotlin-idiomatic way, via the `Transferables` class. Using it, you can register named objects in one thread and then retrieve them by that name in another. Here's an example where we send a very large array over to a worker. ```kotlin // In your site: val largeArray = Uint8Array(1024 * 1024 * 8).apply { /* initialize it */ } worker.postInput(WorkerInput(), Transferables { add("largeArray", largeArray) }) // In the worker: val largeArray = transferables.getUint8Array("largeArray")!! ``` And, of course, workers can send transferable objects back to the main application as well. ```kotlin // In the worker: val largeArray = Uint8Array(1024 * 1024 * 8).apply { /* initialize it */ } postOutput(WorkerOutput(), Transferables { add("largeArray", largeArray) }) // In your site: val worker = rememberWorker { ExampleWorker { val largeArray = transferables.getUint8Array("largeArray")!! // ... } } ``` Finally, it's worth noting that not every object can be transferred. In fact, very few can! You can refer to the official docs for a [full list of supported transferable objects](https://developer.mozilla.org/en-US/docs/Web/API/Web_Workers_API/Transferable_objects#supported_objects). When building a `Transferables` object, the `add` method is type-safe, meaning you cannot add an object that cannot then be transferred over. > [!CAUTION] > Kotlin/JS does not support a majority of the classes listed here, so neither does Kobweb as a result. If you find > yourself needing one of these missing classes, consider > [filing an issue](https://github.com/varabyte/kobweb/issues/new?assignees=&labels=enhancement&projects=&template=feature_request.md&title=) > and we might wrap the JavaScript class into Kobweb directly and update the Transferables API. Despite official limitations, Kobweb actually offers support for a few additional types, as a convenience. If it is possible to extract transferable content from an object, transfer *that*, and then build the original object back up on the other end, we are happy to do that for you. Typed arrays, such as `Int8Array`, are a great example. They are actually not transferable! Only their internal `ArrayBuffer` is. However, when you ask Kobweb to transfer a typed array, it will instead transfer its contents for you and regenerate the outer array seamlessly on the other end. This is just boilerplate code that you would have had to write yourself anyway. > [!TIP] > The `examples/imageprocessor` template demonstrates workers leveraging `Transferables` to pass image data from the > main thread to a worker and back, so you can reference that project for a complete, working example. ### Final notes about worker factories #### Single worker factory Due to the fundamental design of web workers, you can only define a single worker per module. If you need multiple workers, you must create multiple modules, each providing their own separate worker strategy. The Kobweb Worker Gradle plugin will complain if it finds more than one worker factory implemented in a module. #### Worker factory name constraint By default, the Kobweb Worker Gradle plugin requires your worker factory class to be suffixed with `WorkerFactory` so it has guidance on how to name the final worker (for example, `MyExampleWorkerFactory` would generate a worker called `MyExampleWorker`, placing it in the same package as the factory class). ```kotlin // ❌ The Kobweb Worker Gradle plugin will complain about this name! internal class MyWorkerInfoProvider : WorkerFactory { /* ... */ } ``` If you don't like this constraint, you can override the `kobweb.worker.fqcn` property in your build script to provide a worker name explicitly: ```kotlin // build.gradle.kts kobweb { worker { fqcn.set("com.mysite.MyWorker") } } ``` at which point, you are free to name your worker factory whatever you like. If you want to just change the name of your worker, you can omit the package: ```kotlin // build.gradle.kts kobweb { worker { fqcn.set(".MyWorker") // Uses the same package as the worker factory } } ``` ### When to use Kobweb Workers In practice, almost every site can get away without ever using a worker, especially in Kotlin/JS where you can leverage coroutines as a way to mimic concurrency in your single-threaded site. That said, if you know your site is going to run some logic that is not concerned with the web DOM at all, and which might additionally take a long time to run, separating that out into its own worker can be a sensible approach. By isolating your logic into a separate worker, you not only keep it from potentially freezing your UI, but you also guarantee that it will be strongly decoupled from the rest of your site, preventing future developers from introducing potential spaghetti code issues in the future. Another interesting use-case for a worker is isolating some sort of complex state management, where encapsulating that complexity keeps the rest of your site easier to reason about. For example, maybe you're making a web game, and you decide to create a worker to manage all the game logic. You could of course create a Kobweb library for the same effect, but using a worker has a stronger guarantee that the logic will never interact directly with your site's UI. > [!CAUTION] > You should be aware that, since a web worker is a whole separate standalone script, it needs to include its own copy > of the Kotlin/JS runtime, even though your main site already has its own copy. > > Even after running a dead-code elimination pass, I found that the trivial echo worker's final output was about 200K > (which compressed down to 60K before being sent over the wire). > > For most practical use-cases, a 60K download is not a deal-breaker, especially as most images are many multiples > larger than that. But developers should be aware of this, and if this is indeed a concern, you may need to avoid using > Kobweb workers on your site. # Advanced topics ## Setting your site's route prefix Typically, sites live at the top level. This means if you have a root file `index.html` and your site is hosted at the domain `https://mysite.com` then that HTML file can be accessed by visiting `https://mysite.com/index.html`. However, in some cases your site may be hosted under a subfolder, such as `https://example.com/products/myproduct/`, in which case your site's root `index.html` file would live at `https://example.com/products/myproduct/index.html`. Kobweb needs to know about this subfolder structure so that it takes them into account in its routing logic. This can be specified in your project's `.kobweb/conf.yaml` file with the `routePrefix` value under the `site` section: ```yaml site: title: "..." routePrefix: "..." ``` where the value of `routePrefix` is the part between the origin part of the URL and your site's root. For example, if your site is rooted at `https://example.com/products/myproduct/`, then the value of `routePrefix` would be `products/myproduct`. > [!NOTE] > If you are planning to host your site on GitHub Pages using the default `github.io` domain, you will need to set an > appropriate `routePrefix` value. For a concrete example of setting `routePrefix` for GitHub Pages, > [check out this relevant section](https://bitspittle.dev/blog/2022/static-deploy#github-pages) from my blog post about > exporting static layout sites. Outside of setting your `routePrefix` in the `conf.yaml` file, you can design your site without explicitly mentioning it, as Kobweb's composables handle it for you. For example, `Link("docs/manuals/v123.pdf")` (or `Anchor` if you're not using Silk) will automatically resolve to `https://example.com/products/myproduct/docs/manuals/v123.pdf`. If you do need to access the route prefix in your own code, you can do so by referencing the `RoutePrefix.value` companion property or by utilizing the `RoutePrefix.prepend(...)` companion method. This should rarely be required in practice, however. > [!NOTE] > This note is included for anyone who wants to better understand the reason for this feature's design in Kobweb. > > Normally, websites are flexible enough to be hosted under any subfolder because they can use relative paths. > For example, if you are on page `a/b/c` and you need to get to `e/f/g`, you would set your link to `../../../e/f/g` > and not `/e/f/g`. In this setup, if you referenced an icon in your top-level `index.html` file, you would use > `favicon.ico` (a relative path to a sibling file) and not `/favicon.ico`. > > However, Kobweb is built on top of a reactive framework (Compose HTML) normally meant for SPAs (Single Page > Applications). In this setup, the same code is used to handle any URL in your site, at which point it intercepts the > URL value and renders the associated content using some giant switch case in its routing logic. > > This means that Kobweb has a single, global `index.html` which is used for all pages on the site. (If you look at it, > you'll mainly see a minimal DOM skeleton that acts as a container for your dynamically generated pages, plus a script > link to the code of your site.) > > Now, imagine if this `index.html` linked to `favicon.ico`, as in the relative path case. If you were to > visit `https://example.com/products/myproduct/a/b/c`, you would ultimately get served the global `index.html` > file that would then look for the icon file at `https://example.com/products/myproduct/a/b/c/favicon.ico`, where > it doesn't exist. In other words, Kobweb needs help to know that the icon file it is looking for is always at > `https://example.com/products/myproduct/favicon.ico`, so that the `index.html` file link is valid in whatever > context it is served. > > If you were creating your site the traditional way, you might have one hand-crafted HTML file per page, where each one > would have its own unique link to `favicon.ico`. Perhaps the rooted `index.html` file would use `favicon.ico` and the > one located under `a/b/c` would use `../../../favicon.ico`. > > But, in Kobweb, since we're using the same `index.html` file for every page, we use the absolute path `/favicon.ico`, > or, in the case of a route prefix being set, `/${routePrefix}/favicon.ico`. ## Redirects Over the lifetime of a site, you may find yourself needing to change its structure. Perhaps you need to move a handful of pages under a new folder, or you need to rename a page, etc. However, if your site has been live for a while, you may have a ton of internal links to those pages. Worse, the rest of the web (say, Google search results, or blogs and articles) may be full of links to those old locations, so even if you can find and fix up everything on your end, you can't control what others have done. The web has long supported the concept of redirects to handle this. By advertising what links you've changed publicly, search indices can be updated and even if someone visits your page at the old location, your server can automatically tell your browser where they should have gone instead. In Kobweb, you can define redirects in your project's `.kobweb/conf.yaml` file. You simplify define a series of `from` and `to` values in the `server.redirects` block. ```yaml server: redirects: - from: "/old-page" to: "/new-page" ``` Kobweb servers will pick up these redirect values from the `conf.yaml` file and will intercept any matching incoming route requests, sending back a [301 status code](https://developer.mozilla.org/en-US/docs/Web/HTTP/Status/301) to the client. So, in the above example, if a user tries to visit `https://example.com/old-page`, they will be redirected to `https://example.com/new-page` automatically. Any internal links on your site that reference the old page will also be handled -- trying to navigate to the old location will automatically end up at the new one. The Kobweb redirect feature also supports using regexes in the `from` value, which can then be referenced in the `to` section using `$1`, `$2`, etc. variables which will be substituted with text matches in parentheses. Group matching can be really useful if you want to redirect a whole section of your site to a new location. For example, the following redirect rule can help if you've moved all pages from an old parent folder into a new one: ```yaml server: redirects: - from: "/socials/facebook/([^/]+)" to: "/socials/meta/$1" ``` The last thing to note is that if you have multiple redirects, they will be processed in order and all applied. This should rarely matter in most cases, but you can use it if you need to combine both changing a folder name AND a page name: ```yaml server: redirects: - from: "/socials/facebook/([^/]+)" to: "/socials/meta/$1" - from: "(/socials/meta)/about-facebook" to: "$1/about-meta" ``` > [!IMPORTANT] > If you are using a third-party static hosting provider to host your site, they will be unaware of the Kobweb > `conf.yaml` file, so you will need to read their documentation to learn how to configure your redirects with them. > > In this case, you may be able to skip defining redirects in your own Kobweb configuration file, since it may be > redundant at that point. However, it may still be useful to do for documentation purposes and to ensure you won't 404 > due to an old, internal link that you forgot to update. ## CSS Layers [CSS Layers](https://developer.mozilla.org/en-US/docs/Web/CSS/@layer) are a very powerful but also relatively new CSS feature, which allow wrapping CSS style rules inside named layers as a way to control their priorities. In short, CSS layers are arbitrary names that you specify the order of. This can be an especially useful tool when dealing with CSS style rules that are fighting with each other. Compose HTML does *not* support CSS layers, but Silk does! Even if you never use layers directly in your own project, Silk uses them, so users can still benefit from the feature. ### Default layers By default, Silk defines six layers (from lowest to highest ordering priority): 1. reset 2. base 3. component-styles 4. component-variants 5. restricted-styles 6. general-styles The *reset* layer is useful for defining CSS rules that exist to compensate for browser defaults that are inconsistent with each other or to override values that exist for legacy reasons that modern web design has moved away from. The *base* layer is actually not used by Silk (this may change someday), but it is provided so users can home general CSS styles in there if they want to. It is a useful place to define global styles that should get easily overridden by any other CSS rule defined elsewhere in your project, such as inside a `CssStyle`. The next four styles are associated with the various flavors of `CssStyle` definitions: ```kotlin interface SomeKind : ComponentKind val SomeStyle = CssStyle { /* ... */ } // "component-styles" val SomeVariant = SomeStyle.addVariant { /* ... */ } // "component-variants" class ButtonSize(/*...*/) : CssStyle.Base(/*...*/) // "restricted-styles" val GeneralStyle = CssSTyle { /* ... */ } // "general-styles" ``` We chose this order to ensure that CSS styles are layered in ways that match intuition; for example, a style's variant will always layer on top of the base style itself; meanwhile, a user's declared style will always layer over a component style defined by Silk. ### Registering layers You can register your own custom layers inside an `@InitSilk` method, using the `cssLayers` property: ```kotlin @InitSilk fun initSilk(ctx: InitSilkContext) { ctx.stylesheet.cssLayers.add("theme", "layout", "utilities") } ``` When declaring new layers, you can anchor them relative to existing layers. This is useful, for example, if you want to insert layers between Silk's *base* layer and its `CssStyle` layers: ```kotlin @InitSilk fun initSilk(ctx: InitSilkContext) { ctx.stylesheet.cssLayers.add("third-party", after = SilkLayer.BASE) } ``` ### `@CssLayer` annotation If you need to affect the layer for a `CssStyle` block, you can tag it with the `@CssLayer` annotation: ```kotlin @CssLayer("important") val ImportantStyle = CssStyle { /* ... */ } ``` > [!NOTE] > You should always explicitly register your layers. So, for the code above, you should also declare: > ```kotlin > @InitSilk > fun initSilk(ctx: InitSilkContext) { > ctx.stylesheet.cssLayers.add("important") > } > ``` > If you don't do this, the browser will append add any unknown layer to the end of the CSS layer list (i.e. the highest > priority spot). In many cases this will be fine, but being explicit both expresses your intention clearly and reduces > the chance of your site breaking in subtle ways when a future developer adds a new layer in the future. > > Silk will print out a warning to the console if it detects any unregistered layers. ### `layer` blocks `@InitSilk` blocks let you register general CSS styles. You can wrap them insides layers using `layer` blocks: ```kotlin @InitSilk fun initSilk(ctx: InitSilkContext) { ctx.stylesheet.apply { cssLayers.add("headers") layer("headers") { registerStyle("h1") { /* ... */ } registerStyle("h2") { /* ... */ } } } } ``` Of course, you can associate styles with existing layers, such as the *base* layer we mentioned a few sections above: ```kotlin @InitSilk fun initSilk(ctx: InitSilkContext) { ctx.stylesheet.apply { layer(SilkLayer.BASE) { registerStyle("div") { /* ... */ } registerStyle("span") { /* ... */ } } } } ``` ### Importing third party styles into layers Finally, if you are working with third party CSS stylesheets, it can be a very useful trick to wrap them in their own layer. For example, let's say you are fighting with a third party library whose styles are a bit too aggressive and are interfering with your own styles. First, inside your build script, import the stylesheet using an [`@import` directive](https://developer.mozilla.org/en-US/docs/Web/CSS/@import): ```kotlin // BEFORE kobweb.app.index.head.add { link { rel = "stylesheet" href = "/highlight.js/styles/dracula.css" } } // AFTER kobweb.app.index.head.add { style { unsafe { raw("@import url(\"/highlight.js/styles/dracula.css\") layer(highlightjs);") } } } ``` Then, register your new layer in an `@InitSilk` block. ```kotlin @InitSilk fun initSilk(ctx: InitSilkContext) { // Layer(s) referenced in build.gradle.kts ctx.stylesheet.cssLayers.add("highlightjs", after = SilkLayer.BASE) } ``` You've just tamed some wild CSS styles, congratulations! ## Legacy Routes > [!NOTE] > If you... > > * created your site after Kobweb v0.16.0 *OR* > * only have single word page names, e.g. "About.kt" and "Login.kt", as well as packages that are all lowercased... > > then congratulations, you don't have to worry at all about the concerns presented in this section. You should ensure > that your build script's `kobweb.app.legacyRouteRedirectStrategy` is set to `DISALLOW`. When Kobweb was first released, it used very simple logic for generating routes from code in your Kotlin project: - filenames for pages would be lowercased and turned into a slug - packages were converted into route parts as is `pages/home/About.kt` would become `https://example.com/home/about`, in other words. This is fine for most sites! Especially since route overrides were possible through Kobweb's `@Page` and `@PackageMapping` annotations. However, this choice becomes a problem when you start considering parts of a URL that represent multiple words. It is a common practice to use hyphens for this case, e.g. `state-of-art`, but Kobweb was not generating them, resulting in slugs that could sometimes be hard to read, e.g. `stateofart`. Because of this, some users had to create a lot of overrides in their site. This is fragile, as it means it can be easy to refactor a site later without realizing that stale names remain embedded in the code. As a result, in v0.16.0, we made the choice to change the route generating algorithms to split words up with hyphens. As a concrete example, for the page `pages/silkWidgets/SimpleGrid.kt`, Kobweb *used* to generate `https://example.com/silkWidgets/simplegrid`, whereas now it generates `https://example.com/silk-widgets/simple-grid`. If we just changed the route generation logic from one version to the next, that would totally break existing sites! Perhaps a user has a Kobweb site that search engines have already indexed. Or maybe there are many internal links in their site referencing route paths that are now no longer there. So of course, we didn't. Instead, we introduced the idea of legacy route redirects. ### Legacy route redirect strategy Kobweb now defaults to supporting users visiting both the old *and* new route paths. Using the "simple-grid" link example above, if a user ran their site with latest, *either* path would work. However, this is not an ideal state of affairs. It is much better for a site to have a single, canonical URL for each route in your site. This is not only better for SEO, but it also makes it easier to reason about your site's structure. Therefore, Kobweb allows you to disable this feature. In fact, disabling these redirects are encouraged. New sites should disable them from the start (the `kobweb create app` templates started doing this with the introduction of this feature). Older sites should consider auditing their codebase with an eye towards disabling redirects in the near future. It is easy to set the route redirect strategy in your project's build script: ```kotlin kobweb { app { legacyRouteRedirectStrategy.set(LegacyRouteRedirectStrategy.DISALLOW) } } ``` There are actually three strategies available: `ALLOW`, `WARN`, and `DISALLOW`. If nothing is set explicitly, the strategy will default to `WARN` in development and `ALLOW` in production. `ALLOW` and `WARN` are functionally the same, except `WARN` will log a warning to the dev console when a redirect happens. It will also be chattier about things that are happening during export time. ### Redirects and static exports Even though a Kobweb site, once loaded locally, can handle redirects just fine, many users will be hosting their site on a static hosting provider that doesn't know anything about Kobweb. So what happens if a regular visitor bookmarked `https://example.com/someroute` which has since migrated to `https://example.com/some-route`? They would get a 404, and Kobweb wouldn't even get a chance to run its redirect logic. To prevent this from happening, Kobweb checks at export time if legacy route redirects are enabled, and if so, it will generate a copy of each route that has hyphens in it with alternate versions matching the old legacy way. So in the above static hosting site example, Kobweb will actually generate a snapshot for `https://example.com/some-route` and then a copy of the snapshot for `https://example.com/someroute` This works in a pinch. However, you should review how your static hosting provider prefers to be communicated about redirects. It is preferable to disable legacy route redirects in Kobweb and leverage your static hosting provider for this instead, as they will likely do it in a way that communicates the situation better to search engine crawlers. ### Symbolic links By default, Kobweb creates a "copy" of an export snapshot using symbolic links instead of directly copying the file. This is a much more efficient solution, especially if pages are very large. However, if this fails for any reason (Windows famously require admin privileges for users to create them), this will fall back to a direct copy. Although I didn't notice any issue with my own testing, there may be static hosting providers out there that don't handle symbolic links well. In that case, you can force copying to happen instead: ```kotlin kobweb { app { export { forceCopyingForRedirects.set(true) } } } ``` ### Disabling legacy route redirects If you have a pre-0.16.0 site, there are three steps you need to do, after which you can consider disabling legacy route redirects. 1. In your site directory, run `../gradlew kobwebListRoutes` and look for any routes that have hyphens in them. 2. Search through your codebase to see if there are any versions of those links but with hyphens removed. If so, update them. 3. Consider updating the `redirects` section of the `conf.yaml` file to explicitly redirect from the old route to the new one. See the [Redirects▲](#redirects) section for more information. 4. If you are using a third-party service or hosting provider for serving your site, check their documentation to learn how to notify them of these redirects. > [!CAUTION] > Although leaving legacy route redirects on will work for a while, it should be considered deprecated and is slated for > eventual removal. > [!TIP] > This [target commit](https://github.com/bitspittle/bitspittle.dev/commit/08b508ffcbb8503d1b3a7242213c8183aa9f15f3) > demonstrates how I upgraded my blog site (which uses Firebase) to move away from Kobweb legacy route redirecting. It's > way better to let Firebase handle it, because it will communicate necessary information to search engine crawlers so > they too can update their own indexes. ## Generating site code at compile time Occasionally, you might find yourself wanting code for your site that is better generated programmatically than written by hand. The recommended best practice is to create a Gradle task that is associated with its own unique output directory, use the task to write some code to disk under that directory, and then add that task as a source directory for your project. > [!NOTE] > The reason to encourage tasks with their own unique output directory is because this approach is very friendly with > Gradle caching. You may [read more here](https://docs.gradle.org/current/userguide/build_cache_concepts.html#concepts_overlapping_outputs) > to learn about this in more detail. > > Adding your task as a source directory ensures it will get triggered automatically before the Kobweb tasks responsible > for processing your project are themselves run. You want to do this even if you only plan to generate a single file. This is because associating your task with an output directory is what enables it to be used in place of a source directory. The structure for this approach generally looks like this: ```kotlin // e.g. site/build.gradle.kts val generateCodeTask = tasks.register("generateCode") { group = "myproject" // You may not need an input file or dir for your task, and if so, you can exclude the next line. If you do need one, // I'm assuming it is a data file or files in your resources somewhere. val resInputDir = layout.projectDirectory.dir("src/jsMain/resources") // $name here to create a unique output directory just for this task val genOutputDir = layout.buildDirectory.dir("generated/$group/$name/src/jsMain/kotlin") inputs.dir(resInputDir).withPathSensitivity(PathSensitivity.RELATIVE) outputs.dir(genOutputDir) doLast { genOutputDir.get().file("org/example/pages/SomeCode.kt").asFile.apply { parentFile.mkdirs() // find and parse file out of resInputDir and write generated code here: writeText(/* ... */) println("Generated $absolutePath") } } } kotlin { configAsKobwebApplication() commonMain.dependencies { /* ... */ } jsMain { kotlin.srcDir(generateCodeTask) // <----- Set your task here dependencies { /* ... */ } } } ``` ### Generating resources In case you want to generate *resources* that end up in your final site as files (e.g. `mysite.com/rss.xml`) and not code, the main change you need to make is migrating the line `kotlin.srcDir` to `resources.srcDir`: ```kotlin // e.g. site/build.gradle.kts val generateResourceTask = tasks.register("generateResource") { group = "myproject" // $name here to create a unique output directory just for this task val genOutputDir = layout.buildDirectory.dir("generated/$group/$name/src/jsMain/resources") outputs.dir(genOutputDir) doLast { // NOTE: Use "public/" here so the export pass will find it and put it into the final site genOutputDir.get().file("public/rss.xml").asFile.apply { parentFile.mkdirs() writeText(/* ... */) println("Generated $absolutePath") } } } kotlin { configAsKobwebApplication() commonMain.dependencies { /* ... */ } jsMain { resources.srcDir(generateResourceTask) // <----- Set your task here dependencies { /* ... */ } } } ``` ## Adding Kobweb to an existing project Currently, Kobweb is still under active development, and due to our limited resources, we are focusing on improving the path to creating a new project from scratch. However, some users have shown interest in Kobweb but already have an existing project and aren't sure how to add Kobweb into it. As long as you understand that this path isn't officially supported yet, we'll provide steps below to take which may help people accomplish this manually for now. Honestly, the hardest part is creating a correct `.kobweb/conf.yaml`, which the following steps help you work around: 1. Be sure to check the Kobweb compatibility matrix [(see: COMPATIBILITY.md)](https://github.com/varabyte/kobweb/blob/main/COMPATIBILITY.md) to make sure you can match the versions it expects. 2. Create a dummy app project somewhere. Pay attention to the questions it asks you, as you may want to choose a package name that matches your project. ```bash # In some tmp directory somewhere kobweb create app # or `kobweb create app/empty`, if you are already # experienced with Kobweb and know what you're doing ``` 3. When finished, copy the `site` subfolder out into your own project. (Once done, you can delete the dummy project, as it has served its usefulness.) ```bash cp -r app/site /path/to/your/project # delete app ``` 4. In your own project's root `settings.gradle.kts` file, include the new module *and* add our custom artifact repository link so your project can find the Kobweb Gradle plugins. ```kotlin // settings.gradle.kts pluginManagement { repositories { // ... other repositories you already declared ... maven("https://us-central1-maven.pkg.dev/varabyte-repos/public") } } // ... other includes you already declared include(":site") ``` 5. In your project's root `build.gradle.kts` file, add our custom artifact repository there as well (so your project can find Kobweb libraries) ```kotlin // build.gradle.kts subprojects { repositories { // ... other repositories you already declared ... maven("https://us-central1-maven.pkg.dev/varabyte-repos/public") } } // If you prefer, you can just declare this directly inside the // repositories block in site's `build.gradle.kts` file, but I // like declaring my maven repositories globally. ``` 6. Kobweb uses version catalogs for its dependencies. Add or update your version catalog under `gradle/libs.versions.toml` ```toml [versions] jetbrains-compose = "..." # replace with actual version, see COMPATIBILITY.md! kobweb = "..." # replace with actual version kotlin = "..." # replace with actual version [libraries] kobweb-api = { module = "com.varabyte.kobweb:kobweb-api", version.ref = "kobweb" } kobweb-core = { module = "com.varabyte.kobweb:kobweb-core ", version.ref = "kobweb" } kobweb-silk = { module = "com.varabyte.kobweb:kobweb-silk", version.ref = "kobweb" } kobwebx-markdown = { module = "com.varabyte.kobwebx:kobwebx-markdown", version.ref = "kobweb" } silk-icons-fa = { module = "com.varabyte.kobwebx:silk-icons-fa", version.ref = "kobweb" } [plugins] jetbrains-compose = { id = "org.jetbrains.compose", version.ref = "jetbrains-compose" } kobweb-application = { id = "com.varabyte.kobweb.application", version.ref = "kobweb" } kobwebx-markdown = { id = "com.varabyte.kobwebx.markdown", version.ref = "kobweb" } kotlin-multiplatform = { id = "org.jetbrains.kotlin.multiplatform", version.ref = "kotlin" } ``` If everything is working as expected, you should be able to run Kobweb within your project now: ```bash # In /path/to/your/project cd site kobweb run ``` If you're still having issues, you may want to [connect with us▼](#connecting-with-us) for support (but understand that getting Kobweb added to complex existing projects may not be something we can currently prioritize). ## Exporting your site in a GitHub workflow While you can always export your site manually on your machine, you may want to automate this process. A common solution for this is a [GitHub workflow](https://docs.github.com/en/actions/using-workflows). For your convenience, we include a sample workflow below that exports your site and then uploads the results (which can be downloaded from a link shown in the workflow summary page): ```yaml # .github/workflows/export-site.yml name: Export Kobweb site on: workflow_dispatch: jobs: export_and_upload: runs-on: ubuntu-latest defaults: run: shell: bash env: KOBWEB_CLI_VERSION: 0.9.15 steps: - uses: actions/checkout@v4 - uses: actions/setup-java@v4 with: distribution: temurin java-version: 11 # When projects are created on Windows, the executable bit is sometimes lost. So set it back just in case. - name: Ensure Gradle is executable run: chmod +x gradlew - name: Setup Gradle uses: gradle/actions/setup-gradle@v3 - name: Query Browser Cache ID id: browser-cache-id run: echo "value=$(./gradlew -q :site:kobwebBrowserCacheId)" >> $GITHUB_OUTPUT - name: Cache Browser Dependencies uses: actions/cache@v4 id: playwright-cache with: path: ~/.cache/ms-playwright key: ${{ runner.os }}-playwright-${{ steps.browser-cache-id.outputs.value }} - name: Fetch kobweb uses: robinraju/release-downloader@v1.9 with: repository: "varabyte/kobweb-cli" tag: "v${{ env.KOBWEB_CLI_VERSION }}" fileName: "kobweb-${{ env.KOBWEB_CLI_VERSION }}.zip" tarBall: false zipBall: false - name: Unzip kobweb run: unzip kobweb-${{ env.KOBWEB_CLI_VERSION }}.zip - name: Run export run: | cd site ../kobweb-${{ env.KOBWEB_CLI_VERSION }}/bin/kobweb export --notty --layout static - name: Upload site uses: actions/upload-artifact@v4 with: name: site path: site/.kobweb/site/ if-no-files-found: error retention-days: 1 ``` You can copy this workflow (or parts of it) into your own GitHub project and then modify it to your needs. Some notes... * ***workflow_dispatch***: This means that you can manually trigger this workflow from the GitHub UI, which I suggested here to prevent running an expensive export operation more than you need to. Of course, you can also configure your workflow to run on a schedule, or on push to a branch, etc. * ***Setup Gradle***: This action is optional but I recommend it because it configures a bunch of caching for you. * ***Caching the browser***: `kobweb export` needs to download a browser the first time it is run. This workflow sets up a cache that saves it across runs. The cache is tagged with a unique ID so that future Kobweb releases, which may change the version of the browser downloaded, will use a new cache bucket (allowing GitHub to eventually clean up the old one). * ***Upload site***: This action uploads the exported site as an artifact. You can then download the artifact from the workflow summary page. Your own workflow will likely delete this action and do something else here, like upload to a web server (or some location accessible by your web server) or copy files over into a `gh_pages` repository. I've included this here (and set the retention days very low) just so you can verify that the workflow is working for your project. For a simple site, the above workflow should take about 2 minutes to run. ## Arithmetic for `StyleVariable`s using `calc` `StyleVariable`s work in a subtle way that is usually fine until it isn't -- which is often when you try to interact with their values instead of just passing them around. Specifically, this would compile but be a problem at runtime: ```kotlin val MyOpacityVar by StyleVariable() // later... // Border opacity should be more opaque than the rest of the widget val borderOpacity = max(1.0, MyOpacityVar.value().toDouble() * 2) ``` To see what the problem is, let's first take a step back. The following code: ```kotlin val MyOpacityVar by StyleVariable() // later... Modifier.opacity(MyOpacityVar.value()) ``` generates the following CSS: ```css opacity: var(--my-opacity); ``` However, `MyOpacityVar` acts like a `Number` in our code! How does something that effectively has a type of `Number` generate text output like `var(--my-opacity)`? This is accomplished through the use of Kotlin/JS's `unsafeCast`, where you can tell the compiler to treat a value as a different type than it actually is. In this case, `MyOpacityVar.value()` returns some object which the Kotlin compiler *treats* like a `Number` for compilation purposes, but it is really some class instance whose `toString()` evaluates to `var(--my-opacity)`. Therefore, `Modifier.opacity(MyOpacityVar.value())` works seemingly like magic! However, if you try to do some arithmetic, like `MyOpacityVar.value().toDouble() * 0.5`, the compiler might be happy, but things will break silently at runtime, when the JS engine is asked to do math on something that's not really a number. In CSS, doing math with variables is accomplished by using `calc` blocks, so Kobweb offers its own `calc` method to mirror this. When dealing with raw numerical values, you must wrap them in `num` so we can escape the raw type system which was causing runtime confusion above: ```kotlin calc { num(MyOpacityVar.value()) * num(0.5) } // Output: "calc(var(--my-opacity, 1) * 0.5)" ``` At this point, you can write code like this: ```kotlin Modifier.opacity(calc { num(MyOpacityVar.value()) * num(0.5) }) ``` It's a little hard to remember to wrap raw values in `num`, but you will get compile errors if you do it wrong. Working with variables representing length values don't require calc blocks because Compose HTML supports mathematical operations on such numeric unit types: ```kotlin val MyFontSizeVar by StyleVariable() MyFontSizeVar.value() + 1.cssRem // Output: "calc(var(--my-font-size) + 1rem)" ``` However, a calc block could still be useful if you were starting with a raw number that you wanted to convert to a size: ```kotlin val MyFontSizeScaleFactorVar by StyleVariable() calc { MyFontSizeScaleFactorVar.value() * 16.px } // Output: calc(var(--my-font-size-scale-factor) * 16px) ``` ## Kobweb Server Plugins Many users who create a full stack application generally expect to completely own both the client- and server-side code. However, being an opinionated framework, Kobweb provides a custom Ktor server in order to deliver some of its features. For example, it implements the logic for handling [server API routes▲](#define-api-routes) as well as some live reloading functionality. It would not be trivial to refactor this behavior into some library that users could import into their own backend server. As a compromise, some server configuration is exposed by the `.kobweb/conf.yaml` file, and this has been the main way users could affect the server's behavior. That said, there will always be some use cases that Kobweb won't anticipate. So as an escape hatch, Kobweb allows users who know what they're doing to write their own plugins to extend the server. > [!NOTE] > The Kobweb Server plugin feature is still fairly new. If you use it, please consider > [filing issues](https://github.com/varabyte/kobweb/issues/new?assignees=&labels=enhancement&projects=&template=feature_request.md&title=) > for any missing features and [connecting with us▼](#connecting-with-us) to share any feedback you have about your > experience. Creating a Kobweb server plugin is relatively straightforward. You'll need to: * Create a new module in your project that produces a JAR file that bundles an implementation of the `KobwebServerPlugin` interface. * Add that module as a `kobwebServerPlugin` dependency in your site's build script. * This ensures a copy of that jar is put under your project's `.kobweb/server/plugins` directory. ### Create a Kobweb Server Plugin The following steps will walk you through creating your first Kobweb Server Plugin. > [!TIP] > You can > download [this project](https://github.com/varabyte/data/raw/main/kobweb/projects/serverplugin.zip) to see the > completed result from applying the instructions in this section to the `kobweb create app` site. * Create a new module in your project. * For example, name it "demo-server-plugin". * Be sure to update your `settings.gradle.kts` file to include the new project. * Add new entries for the `kobweb-server-project` library and kotlin JVM plugin in `.gradle/libs.versions.toml`: ```toml [libraries] kobweb-server-plugin = { module = "com.varabyte.kobweb:kobweb-server-plugin", version.ref = "kobweb" } [plugins] kotlin-jvm = { id = "org.jetbrains.kotlin.jvm", version.ref = "kotlin" } ``` * **For all remaining steps, create all files / directories under your new module's directory (e.g. `demo-server-plugin/`).** * Create `build.gradle.kts`: ```kotlin plugins { alias(libs.plugins.kotlin.jvm) } group = "org.example.app" // update to your own project's group version = "1.0-SNAPSHOT" dependencies { compileOnly(libs.kobweb.server.plugin) } ``` * Create `src/main/kotlin/DemoKobwebServerPlugin.kt`: ```kotlin import com.varabyte.kobweb.server.plugin.KobwebServerPlugin import io.ktor.server.application.Application import io.ktor.server.application.log class DemoKobwebServerPlugin : KobwebServerPlugin { override fun configure(application: Application) { application.log.info("REPLACE ME WITH REAL CONFIGURATION") } } ``` > [!TIP] > As the Kobweb server is written in Ktor, you should familiarize yourself with [Ktor's documentation](https://ktor.io/docs/plugins.html). * Create `src/main/resources/META-INF/services/com.varabyte.kobweb.server.plugin.KobwebServerPlugin`, setting its content to the fully-qualified class name of your plugin. For example: ```text org.example.app.DemoKobwebServerPlugin ``` > [!NOTE] > If you aren't familiar with `META-INF/services`, you can > read [this helpful article](https://www.baeldung.com/java-spi) to learn more about service implementations, a very > useful Java feature. ### Register your server plugin jar The Kobweb Gradle Application plugin provides a way to notify it about your JAR project. Set it up, and Gradle will build and copy your plugin jar over for you automatically. In your Kobweb project's build script, include the following `kobwebServerPlugin` line in a top-level dependencies block: ```kotlin // site/build.gradle.kts dependencies { kobwebServerPlugin(project(":demo-server-plugin")) } kotlin { /* ... */ } ``` > [!IMPORTANT] > You need to put the `kobwebServerPlugin` declaration inside a top-level `dependencies` block, not in one of the > ones nested under the `kotlin` block (such as `kotlin.jvmMain.dependencies`). Once this is set up, upon the next Kobweb server run (e.g. via `kobweb run`), if you check the logs, you should see something like this: ```text [main] INFO ktor.application - Autoreload is disabled because the development mode is off. [main] INFO ktor.application - REPLACE ME WITH REAL CONFIGURATION [main] INFO ktor.application - Application started in 0.112 seconds. [main] INFO ktor.application - Responding at http://0.0.0.0:8080 ``` ### Hooking into Ktor routing events Despite the simplicity of the `KobwebServerPlugin` interface, the `application` parameter passed into `KobwebServerPlugin.configure` is quite powerful. While I know it may sound kind of meta, you can create and install a Ktor Application Plugin inside a Kobweb Server Plugin. Once you've done that, you have access to all stages of a network call, as well as some other hooks like ones for receiving Application lifecycle events. > [!TIP] > Please read the [Extending Ktor documentation](https://ktor.io/docs/custom-plugins.html) to learn more. Doing so looks like this: ```kotlin import com.varabyte.kobweb.server.plugin.KobwebServerPlugin import io.ktor.server.application.Application import io.ktor.server.application.createApplicationPlugin import io.ktor.server.application.install class DemoKobwebServerPlugin : KobwebServerPlugin { override fun configure(application: Application) { val demo = createApplicationPlugin("DemoKobwebServerPlugin") { onCall { call -> /* ... */ } // Request comes in onCallRespond { call -> /* ... */ } // Response goes out } application.install(demo) } } ``` ### Changing a Kobweb Server Plugin requires a server restart It's important to note that, unlike other parts of Kobweb, Kobweb Server Plugins do NOT support live reloading. We only start up and configure a Kobweb server once in its lifetime. If you make a change to a Kobweb Server Plugin, you must quit and restart the server for it to take effect. ## Using your own backend with Kobweb You may already have an existing and complex backend, perhaps written with Ktor or Spring Boot, and, if so, are wondering if you can integrate Kobweb with it. The recommended solution for now is to export your site using a static layout ([read more about static layout sites here▲](#static-layout-vs-full-stack-sites)) and then add code to your backend to serve the files yourself, as it is fairly trivial. When you export a site statically, it will generate all files into your `.kobweb/site` folder. Then, if using Ktor, for example, serving these files is a one-liner: ```kotlin routing { staticFiles("/", File(".kobweb/site")) } ``` If using Ktor, you should also install the [`IgnoreTrailingSlash` plugin](https://api.ktor.io/ktor-server/ktor-server-core/io.ktor.server.routing/-ignore-trailing-slash.html) so that your web server will serve `index.html` when a user visits a directory (e.g. `/docs/`) instead of returning a 404: ```kotlin embeddedServer(...) { // `this` is `Application` in this scope this.install(IgnoreTrailingSlash) // Remaining configuration } ``` If you need to access HTTP endpoints exposed by your backend, you can use [`window.fetch(...)`](https://developer.mozilla.org/en-US/docs/Web/API/fetch) directly, or you can use the convenience `http` property that Kobweb adds to the `window` object which exposes all the HTTP methods (`get`, `post`, `put`, etc.): ```kotlin @Page @Composable fun CustomBackendDemoPage() { LaunchedEffect(Unit) { val endpointResponse = window.http.get("/my/endpoint?id=123").decodeToString() /* ... */ } } ``` Unfortunately, using your own backend does mean you're opting out of using Kobweb's full stack solution, which means you won't have access to Kobweb's API routes, API streams, or live reloading support. This is a situation we'd like to improve someday ([link to tracking issue](https://github.com/varabyte/kobweb/issues/22)), but we don't have enough resources to be able to prioritize resolving this for a 1.0 release. ## `CSSNumericValue` type-aliases Kobweb introduces a handful of type-aliases for CSS unit values, basing them off of the `CSSNumericValue` class and extending the set defined by Compose HTML: ```kotlin typealias CSSAngleNumericValue = CSSNumericValue typealias CSSLengthOrPercentageNumericValue = CSSNumericValue typealias CSSLengthNumericValue = CSSNumericValue typealias CSSPercentageNumericValue = CSSNumericValue typealias CSSFlexNumericValue = CSSNumericValue typealias CSSTimeNumericValue = CSSNumericValue ``` This section explains why they were added and why you should almost always prefer using them. ### Background #### CSSSizeValue When you write CSS values like `10.px`, `5.cssRem`, `45.deg`, or even `30.s` into your code, you normally don't have to think too much about their types. You just create them and pass them into the appropriate Kobweb / Compose HTML APIs. Let's discuss what is actually happening when you do this. Compose HTML provides a `CSSSizeValue` class which represents a number value and its unit. ```kotlin val lengthValue = 10.px // CSSSizeValue (value = 10 and unit = px) val angleValue = 45.deg // CSSSizeValue (value = 45 and unit = deg) ``` This is a pretty elegant approach, but the types are verbose. This can be troublesome when writing code that needs to work with them: ```kotlin val lengths: List> fun drawArc(arc: CSSSizeValue) ``` Note also that the above cases are overly restrictive, only supporting a single length and angle type, respectively. We usually want to support all relevant types (e.g. `px`, `em`, `cssRem`, etc. for lengths; `deg`, `rad`, `grad`, and `turn` for angles). We can do this with the following `out` syntax: ```kotlin val lengths: List> fun drawArc(arc: CSSSizeValue) ``` What a mouthful! As a result, the Compose HTML team added type-aliases for all these unit types, such as `CSSLengthValue` and `CSSAngleValue`. Now, you can write the above code like: ```kotlin val lengths: List fun drawArc(arc: CSSAngleValue) ``` Much better! Seems great. No problems, right? *Right?!* #### CSSNumericValue You can probably tell by my tone: Yes problems. To explain, we first need to talk about `CSSNumericValue`. It is common to transform values in CSS using many of its various mathematical functions. Perhaps you want to take the sum of two different units (`10.px + 5.cssRem`) or call some other math function (`clamp(1.cssRem, 3.vw)`). These operations return intermediate values that cannot be directly queried like a `CSSSizeValue` can. This is handled by the `CSSNumericValue` class, also defined by Compose HTML (and which is actually a base class of `CSSSizeValue`). ```kotlin val lengthSum = 10.px + 2.cssRem // CSSNumericValue val angleSum = 45.deg + 1.turn // CSSNumericValue ``` These numeric operations are of course useful to the browser, which can resolve them into absolute screen values, but for us in user space, they are opaque calculations. In practice, however, that's fine! The limited view of these values does not matter because we rarely need to query them in our code. In almost all cases, we just take some numeric value, optionally tweak it by doing some more math on it, and then pass it onto the browser. Because it is opaque, `CSSNumericValue` is far more flexible and widely applicable than `CSSSizeValue` is. If you are writing a function that takes a parameter, or declaring a `StyleVariable` tied to some length or time, you almost always want to use `CSSNumericValue` and not `CSSSizeValue`. ### Prefer using Kobweb's `CSSNumericValue` type-aliases As mentioned above, the Compose HTML team created their unit-related type-aliases against the `CSSSizeValue` class. This decision makes it really easy to write code that works well when you test it with concrete size values but is actually more restrictive than you expected. Kobweb ensures its APIs all reference its `CSSNumericValue` type-aliases: ```kotlin // Legacy Kobweb fun Modifier.lineHeight(value: CSSLengthOrPercentageValue): Modifier = styleModifier { lineHeight(value) } // Modern Kobweb fun Modifier.lineHeight(value: CSSLengthOrPercentageNumericValue): Modifier = styleModifier { lineHeight(value) } ``` If you are using style variables in your code, or writing your own functions that take CSS units as arguments, you might be referencing the Compose HTML types. Your code will still work fine, but you are strongly encouraged to migrate them to Kobweb's newer set, in order to make your code more flexible about what it can accept: ```kotlin // Not recommended val MyFontSize by StyleVariable fun drawArc(arc: CSSAngleValue) // Recommended val MyFontSize by StyleVariable fun drawArc(arc: CSSAngleNumericValue) ``` > [!NOTE] > Perhaps in the future, the Compose HTML team might consider updating their type-aliases to use the `CSSNumericValue` > type and not the `CSSSizeValue` type. If that happens, we can revert our changes and delete this section. But until > then, it's worth understanding why Kobweb introduces its own type-aliases and why you are encouraged to use them > instead of the Compose HTML versions. # Miscellaneous topics ## Debugging your site A Kobweb project always has a frontend and, if configured as a full stack site, a backend as well. Both require different steps to debug them. ### Debugging the frontend At the moment, attaching a debugger to Kotlin/JS code requires IntelliJ Ultimate. If you have it, you can [follow these steps](https://kotlinlang.org/docs/js-debugging.html#debug-in-the-ide) in the official docs. > [!IMPORTANT] > Be sure the port in your URL matches the port you specified in your `.kobweb/conf.yaml` file. By default, this > is 8080. If you do not have access to IntelliJ Ultimate, then you'll have to rely on `println` debugging. While this is far from great, live reloading plus Kotlin's type system generally help you incrementally build your site up without too many issues. > [!TIP] > If you're a student, you can apply for a free IntelliJ Ultimate > license [here](https://www.jetbrains.com/community/education/#students). If you maintain an open source project, you > can apply [here](https://www.jetbrains.com/community/opensource/#support). ### Debugging the backend Debugging the backend first requires configuring the Kobweb server to support remote debugging. This is easy to do by modifying the `kobweb` block in your build script to enable remote debugging: ```kotlin kobweb { app { server { remoteDebugging { enabled.set(true) port.set(5005) } } } } ``` > [!NOTE] > Specifying the port is optional. Otherwise, it is 5005, a common remote debugging default. If you ever need to debug > multiple Kobweb servers at the same time, however, it can be useful to change it. Once you've enabled remote debugging support, you can then [follow the official documentation](https://www.jetbrains.com/help/idea/attaching-to-local-process.html#attach-to-remote) to add a *remote JVM debug* configuration to your IDE. > [!IMPORTANT] > For remote debugging to work: > * The *Debugger Mode* should be set to *Attach to remote JVM*. > * You need to correctly specify the *Use module classpath* value. In general, use the `jvmMain` classpath associated > with your Kobweb application, e.g. `app.site.jvmMain`. If you've refactored your backend code out to another module, > you should be able to use that instead. At this point, start up your Kobweb server using `kobweb run`. > [!CAUTION] > Remote debugging is only supported in dev mode. It will not be enabled for a server started with > `kobweb run --env prod`. With your Kobweb server running and your "remote debug" run configuration selected, press the debug button. If everything is set up correctly, you should see a message in the IDE debugger console like: `Connected to the target VM, address: 'localhost:5005', transport: 'socket'` If instead, you see a red popup with a message like `Unable to open debugger port (localhost:5005): java.net.ConnectException "Connection refused"`, please double-check the values in your `conf.yaml` file, restart the server, and try again. ## Using a custom font ### Font hosting service The easiest way to use a custom font is if it is already hosted for you. For example, Google Fonts provides a CDN that you can use to load fonts directly. > [!CAUTION] > While this is the easiest approach, be sure you won't run into compliance issues! If you use Google Fonts on your > site, you may technically be in violation of the GDPR in Europe, because an EU citizen's IP address is communicated to > Google and logged. You may wish to find a Europe-safe host instead, or self-host, which you can read about > in [the next section▼](#self-hosted-fonts). The font service should give you HTML to add to your site's `` tag. For example, Google Fonts suggests the following when I select Roboto Regular 400: ```html ``` This code should be converted into Kotlin and added to the `kobweb` block of your site's `build.gradle.kts` script: ```kotlin kobweb { app { index { head.add { link(rel = "preconnect", href = "https://fonts.googleapis.com") link(rel = "preconnect", href = "https://fonts.gstatic.com") { attributes["crossorigin"] = "" } link( href = "https://fonts.googleapis.com/css2?family=Roboto&display=swap", rel = "stylesheet" ) } } } } ``` Once done, you can now reference this new font: ```kotlin Column(Modifier.fontFamily("Roboto")) { Text("Hello world!") } ``` ### Self-hosted fonts Users can flexibly declare a custom font by using CSS's [`@font-face` rule](https://developer.mozilla.org/en-US/docs/Web/CSS/@font-face). In Kobweb, you can normally declare CSS properties in Kotlin (within an `@InitSilk` block), but unfortunately, Firefox doesn't allow you to define or modify `@font-face` entries in code ([relevant Bugzilla issue](https://bugzilla.mozilla.org/show_bug.cgi?id=443978)). Therefore, for guaranteed cross-platform compatibility, you should create a CSS file and reference it from your build script. To keep the example concrete, let's say you've downloaded the open source font [Lobster](https://fonts.google.com/specimen/Lobster) from Google Fonts (and its license as well, of course). You need to put the font file inside your public resources directory, so it can be found by the user visiting your site. I recommend the following file organization: ``` jsMain └── resources └── public └── fonts ├── faces.css └── lobster ├── OFL.txt └── Lobster-Regular.ttf ``` where `faces.css` contains all your `@font-face` rule definitions (we just have a single one for now): ```css @font-face { font-family: 'Lobster'; src: url('/fonts/lobster/Lobster-Regular.ttf'); } ``` > [!NOTE] > The above layout may be slightly overkill if you are sure you'll only ever have a single font, but it's flexible > enough to support additional fonts if you decide to add more in the future, which is why we recommend it as a general > advice here. Now, you need to reference this CSS file from your `build.gradle.kts` script: ```kotlin kobweb { app { index { head.add { link(rel = "stylesheet", href = "/fonts/faces.css") } } } } ``` Finally, you can reference the font in your code: ```kotlin Column(Modifier.fontFamily("Lobster")) { Text("Hello world!") } ``` ## Kobweb server logs When you run `kobweb run`, the spun-up web server will, by default, log to the `.kobweb/server/logs` directory. > [!NOTE] > You can generate logs using the `ctx.logger` property inside [`@Api` calls▲](#define-api-routes). You can configure logging behavior by editing the `.kobweb/conf.yaml` file. Below we show setting all parameters to their default values: ```yaml server: logging: level: DEBUG # ALL, TRACE, DEBUG, INFO, WARN, ERROR, OFF logRoot: ".kobweb/server/logs" clearLogsOnStart: true # Warning - if true, wipes ALL files in logRoot, so don't put other files in there! logFileBaseName: "kobweb-server" # e.g. "kobweb-server.log", "kobweb-server.2023-04-13.log" maxFileCount: null # null = unbound. One log file is created per day, so 30 = 1 month of logs totalSizeCap: 10MiB # null = unbound. Accepted units: B, K, M, G, KB, MB, GB, KiB, MiB, GiB compressHistory: true # If true, old log files are compressed with gzip ``` The above defaults were chosen to be reasonable for most users running their projects on their local machines in developer mode. However, for production servers, you may want to set `clearLogsOnStart` to false, bump up the `totalSizeCap` after reviewing the disk limitations of your web server host, and maybe set `maxFileCount` to a reasonable limit. Note that most config files assume "10MB" is 10 * 1024 * 1024 bytes, but here it will actually result in 10 * 1000 * 1000 bytes. You probably want to use "KiB", "MiB", or "GiB" when you configure this value. ## Configuring CORS [CORS](https://developer.mozilla.org/en-US/docs/Web/HTTP/CORS), or *Cross-Origin Resource Sharing*, is a security feature built on the idea that a web page should not be able to make requests for resources from a server that is not the same as the one that served the page *unless* it was served from a trusted domain. To configure CORS for a Kobweb backend, Kobweb's `.kobweb/conf.yaml` file allows you to declare such trusted domains using a `cors` block: ```yaml server: cors: hosts: - name: "example.com" schemes: - "https" ``` > [!NOTE] > Specifying the schemes is optional. If you don't specify them, Kobweb defaults to "http" and "https". > [!NOTE] > You can also specify subdomains, e.g. > ```yaml > - name: "example.com" > subdomains: > - "en" > - "de" > - "es" > ``` > which would add CORS support for `en.example.com`, `de.example.com`, and `es.example.com`, as well as `example.com` > itself. Once configured, your Kobweb server will be able to respond to data requests from any of the specified hosts. > [!TIP] > If you find that your full-stack site, which was working locally during development, rejects requests in the > production version, check your browser's console logs. If you see errors in there about a violated CORS policy, that > means you didn't configure CORS correctly. ## Generating export traces The Kobweb export feature is built on top of [Microsoft Playwright](https://playwright.dev/), a solution for making it easy to download and run browsers programmatically. One of the features provided by Playwright is the ability to generate traces, which are essentially detailed reports you can use to understand what is happening as your site loads. Kobweb exposes this feature through the `export` block in your Kobweb application's build script. Enabling traces is easy: ```kotlin // build.gradle.kts plugins { // ... other plugins ... alias(libs.plugins.kobweb.application) } kobweb { app { export { enableTraces() } } } ``` You can pass in parameters to configure the `enableTraces` method, but by default, it will generate trace files into your `.kobweb/export-traces/` directory. Once enabled, you can run `kobweb export`, then once exported, open any of the generated `*.trace.zip` files by navigating to them using your OS's file explorer and drag-and-dropping them into the [Playwright Trace Viewer](https://trace.playwright.dev/). > [!TIP] > You can learn more about how to use the Trace > Viewer [using the official documentation](https://playwright.dev/docs/trace-viewer). It's not expected many users will need to debug their site exports, but it's a great tool to have (especially combined with the [server logs feature](#kobweb-server-logs)) to diagnose if one of your pages is taking longer to export than expected. ## General purpose improvements on top of Compose HTML and Kotlin/JS In the beginning, Kobweb was only intended to be a thin layer on top of Compose HTML, but the more we worked on it, the more we ran into features that were simply not yet implemented in Compose HTML. In other cases, we found ourselves reaching for utilities that we wished existed in Kotlin/JS browser APIs. As we began adding these features, we realized it would have been a shame to bury them deep inside our framework. As a result, we created two modules: * [`compose-html-ext`](frontend/compose-html-ext/README.md), where we put code that we would be more than happy for the Compose HTML team to fork and migrate over to Compose HTML someday. * [`browser-ext`](frontend/browser-ext/README.md), a collection of general purpose utilities that we think could be useful to any Kotlin/JS project targeting the browser. The features across these modules include (not comprehensive): * a *ton* of missing type-safe wrappers around many, many CSS properties * type-safe wrappers around CSS functions, like gradients, filters, `calc` (especially useful when working with CSS variables), etc. * rich SVG support * utility methods around saving files to / loading files from the disk * utility methods and classes built on top of [`window.fetch`](https://kotlinlang.org/api/latest/jvm/stdlib/org.w3c.dom/-window-or-worker-global-scope/fetch.html) (for example, making it easier to use the most common HTTP verbs like GET, POST, etc., as well as providing `suspend fun` versions of fetch) * additions for the missing [transition events](https://developer.mozilla.org/en-US/docs/Web/API/TransitionEvent) * implementations of resize and intersection observers * utility methods for getting a sequence of descendant/ancestor HTML elements, useful for walking the DOM tree in a Kotlin-idiomatic way * a utility composable, `GenericTag`, which is an easy-to-use API wrapping Compose HTML's `TagElement` composable, with additional namespacing support if needed (for example, required when implementing SVG elements) * a utility class for working with CSS variables, `StyleVariable`, allows specifying a default value, provides first-class number/string variable support, and fixes [a bug in Compose HTML's `CSSStyleVariable`class](https://github.com/JetBrains/compose-multiplatform/issues/2763) where it can accept invalid values. * `setTimeout` and `setInterval` methods that are more Kotlin-idiomatic (e.g. the lambdas are the last parameter) > [!NOTE] > Some users have mentioned we should have opened PRs for the Compose HTML team instead of maintaining a separate > codebase. However, after observing that JetBrains was focusing more and more of its energy on Compose Multiplatform > for Web, we decided to implement the features we needed in our own project. This way, we could maintain our velocity > while allowing their team to pick and choose what they agreed with at some point in the future at their leisure. > There's so much code here, especially around CSS APIs, that getting mired down in PR discussions would have ground our > progress to a halt. If you want to use Compose HTML but *not* Kobweb, or Kotlin/JS but *not* Compose HTML, you can still use and benefit from `compose-html-ext` or `browser-ext` in your own project. An example build script could look like this (here, for a non-Kobweb Compose HTML project): ```kotlin // build.gradle.kts plugins { kotlin("multiplatform") version "..." } repositories { mavenCentral() maven("https://maven.pkg.jetbrains.space/public/p/compose/dev") google() maven("https://us-central1-maven.pkg.dev/varabyte-repos/public") // IMPORTANT!!! } kotlin { js().browser() sourceSets { jsMain.dependencies { implementation(compose.html.core) implementation(compose.runtime) implementation("com.varabyte.kobweb:compose-html-ext:...") // IMPORTANT!!! } } } ``` > [!NOTE] > The `compose-html-ext` dependency automatically exposes the `browser-ext` dependency. ## What about Compose Multiplatform for Web? Jetbrains is working on the "Compose Multiplatform UI Framework", which allows developers to use the same codebase across Android, iOS, Desktop, and the Web. And it may seem like the Kobweb + Silk approach is obsoleted by it. It's first worth understanding the core difference between the two approaches. With Compose Multiplatform, the framework owns its own rendering pipeline, drawing to a buffer. In contrast, Compose HTML modifies an HTML / CSS DOM tree and leaves it up to the browser to do the final rendering. This has major implications on how similar the two APIs can get. For example, in Compose Multiplatform, the order you apply modifiers matters. However, in Compose HTML, this action simply sets html style properties under the hood, where order does not matter. Due to its reputation, ditching HTML / CSS entirely at first can seem like a total win, but this approach has several limitations: * robots would lose the ability to crawl and index your site, hurting SEO. * your initial render may take longer (as nothing will be rendered until your site's logic is downloaded and run for one frame). * your site will need to allocate a large canvas buffer, which could be *very* expensive on high-res, wide-screen desktops. * your UI will be opaque to the powerful suite of devtools that come bundled with browsers. * you won't have the ability to style unvisited vs visited links differently (this information is hidden from you by the browser for security reasons and can only be set through HTML / CSS). * you won't have the ability to turn elements on / off when printing the page. * accessibility tools for browsers might not work. * the download size of the rendering components is not insignificant and apparently not very compressible, often resulting in a site's basic footprint being 4-6x larger total (e.g. 200-400K vs. 2-3MB for small sites). It would also prevent a developer from making use of the rich ecosystem of Javascript libraries out there. Finally, Kobweb is more than just Kotlin-ifying HTML / CSS. It also provides rich integration with powerful web technologies like [web workers▲](#worker) and [websockets▲](#api-stream). For now, I am making a bet that there will always be value in embracing the web, providing a framework that sticks to HTML / CSS but offers a growing suite of UI widgets, layouts, and other features that make it a more comfortable experience for the Kotlin developer. For example, [the flexbox layout](https://css-tricks.com/snippets/css/a-guide-to-flexbox/) is a very powerful concept, but it can be very tricky to use. In most cases, you'll find it's much easier to compose `Row`s and `Column`s together than trying to remember if you should be justifying your items or aligning your content, even if `Row`s and `Column`s are just configuring the correct HTML / CSS for you behind the scenes. Ultimately, I believe there is room for both Compose Multiplatform *and* Kobweb. If you want to make an app experience that feels the same on Android, iOS, Desktop, and Web, then Compose Multiplatform could be the right choice for you. However, if you just want to make a traditional website but want to use Kotlin instead of TypeScript, Kobweb can provide an excellent development experience for that case. # Can We Kobweb Yet Current state: **Foundations are in place! You may encounter API gaps.** You may wish to refer to our [Kobweb 1.0 roadmap document](https://docs.google.com/document/d/1n2Jd02yzuxaatpT7gOhEuijzfaSu9UIaQTV2t4EPcPk/preview). Kobweb is becoming quite functional. We are already using it to build https://kobweb.varabyte.com and https://bitspittle.dev. Several users have created working portfolio sites already, and I'm aware of at least two cases where Kobweb was used in a project for a client. At this point: * It is easy to set up a new project and get things running quickly. * The live reloading flow is pretty nice, and you'll miss it when you switch to projects that don't have it. * It supports generating pages from Markdown that can reference your Composable code. * While it's not quite a server-side rendering, you can export static pages which will get hydrated on load. * A huge range of CSS properties are supported, along with support for style variables and animations. * You can use the `Modifier` builder for a significant number of CSS properties. * Silk components are color-mode aware and support responsive behavior. * There are quite a few widgets available, and it's easy to create your own. However, there's always more to do. * I'm trying to add support for every stabilized CSS property, but some are still missing, especially less common ones. (You can use a fallback for such cases in the meantime). * There are still a handful of widgets planned to be added. * A lot of detailed documentation is planned to go into the Kobweb site (linked just above) but it isn't done yet. I think there's enough there now to let you do almost anything you'd want to do, as either Kobweb supports it or you can escape hatch to underlying Compose HTML / Kotlin/JS approaches, but there might be some areas where it's still a bit DIY. It would be great to get real-world experience to hear what issues users are actually running into. So, should you use Kobweb at this point? If you are... * playing around with Compose HTML for the first time and want to get up and running quickly on a toy project: * **YES!!!** Please see the [connecting with us▼](#connecting-with-us) section below, we'd definitely love to hear from you. It's still a good time if you want to have a voice in the direction of this project. * a Kotlin developer who wants to write a small web app or create a new blog from scratch: * **Probably!** I hope if you evaluate Kobweb at this point, you'll find a lot to like. You can get in touch with us at our Discord if you try it and have questions or run into missing features. * someone who already has an existing project in progress and wants to integrate Kobweb into it: * **Maybe not?** Depending on how much work you've done, it may not be a trivial refactor. You can review [this earlier section▲](#adding-kobweb-to-an-existing-project) if you want to try anyway. * a company: * **Probably not?** I'm assuming most companies are so risk-averse they would not even use Compose HTML, which Kobweb is built on top of. If you *were* considering Compose HTML, however, Kobweb is worth a look. On the fence but not sure? Connect with us, and I'd be happy to help you assess your situation. ## Testimonials I'm pleased to mention that Kobweb has received feedback from some satisfied users. Here are a few: * "This is a pretty bloody amazing technology you've created here. I have been dreading upgrading [my] website for ages because I didn't want to go back to html and css 🫤 now I can stay with Kotlin 😀" * "Kobweb looks fantastic and I've been [trying] to use Kotlin in all parts of [my] hobby stuff and work, so I got real excited when I saw Kobweb, [even though] I hadn't been satisfied with a web framework in a long time. Incredible work." * "I started using Kobweb last week and I have to say this [...] reinvented web development for me. [...] I used to hate html css. After getting my hands on kobweb I’m in love with it." * "Finally got paid -- all thanks to kobweb 🎉💥" * "I didn't wanna learn any JS framework so when I first learned about kobweb it felt like a no-brainer; having built 2 Android apps with compose already and a backend with ktor. One could argue Android developers are the best target audience since the additional knowledge needed to move an app to the web with Kobweb is minimal. I love it! 🤩" # Connecting with us * [Join my Discord!](https://discord.gg/5NZ2GKV5Cs) * [GitHub Discussions](https://github.com/varabyte/kobweb/discussions) for this project * The [Kobweb channel](https://kotlinlang.slack.com/archives/C04RTD72RQ8) on the Kotlin Slack * You can send direct queries to [my email](mailto:bitspittle@gmail.com) If you're comfortable with it, using Discord is recommended, because there's a growing community of users in there who can offer help even when I'm not around. # Filing issues and leaving feedback It is still early days, and while we believe we've proven the feasibility of this approach at this point, there's still plenty of work to do to get to a 1.0 launch! We are hungry for the community's feedback, so please don't hesitate to: * [Open an issue](https://github.com/varabyte/kobweb/issues/new/choose) * Contact us (using any of the ways mentioned above) telling us what features you want * Ask us for guidance, especially as there are no tutorials yet (your questions can help us know what to write first!) Thank you for your support and interest in Kobweb!