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compare: mirrors:async-docs
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1 Commits
eager-clon ... async-docs

Author SHA1 Message Date
Greg Johnston
5e84c2a769 docs: add create_resource, <Suspense/>, and <Transition/> 2023-02-20 17:38:55 -05:00
808 changed files with 14622 additions and 60742 deletions
Expand all files Collapse all files

39
.github/ISSUE_TEMPLATE/bug_report.md vendored
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@@ -1,39 +0,0 @@
---
name: Bug report
about: Create a report to help us improve
title: ''
labels: ''
assignees: ''
---
**Describe the bug**
A clear and concise description of what the bug is.
**Leptos Dependencies**
Please copy and paste the Leptos dependencies and features from your `Cargo.toml`.
For example:
```toml
leptos = { version = "0.3", features = ["serde"] }
leptos_axum = { version = "0.3", optional = true }
leptos_meta = { version = "0.3"}
leptos_router = { version = "0.3"}
```
**To Reproduce**
Steps to reproduce the behavior:
1. Go to '...'
2. Click on '....'
3. Scroll down to '....'
4. See error
**Expected behavior**
A clear and concise description of what you expected to happen.
**Screenshots**
If applicable, add screenshots to help explain your problem.
**Additional context**
Add any other context about the problem here.

7
.github/ISSUE_TEMPLATE/config.yml vendored
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@@ -1,7 +0,0 @@
contact_links:
- name: Support or Question
url: https://github.com/leptos-rs/leptos/discussions/new?category=q-a
about: Do you need help figuring out how to do something, or want some help troubleshooting a bug? You can ask in our Discussions section.
- name: Discord Discussions
url: https://discord.gg/YdRAhS7eQB
about: For more informal, real-time conversation and support, you can join our Discord server.

20
.github/ISSUE_TEMPLATE/feature_request.md vendored
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@@ -1,20 +0,0 @@
---
name: Feature request
about: Suggest an idea for this project
title: ''
labels: ''
assignees: ''
---
**Is your feature request related to a problem? Please describe.**
A clear and concise description of what the problem is. Ex. I'm always frustrated when [...]
**Describe the solution you'd like**
A clear and concise description of what you want to happen.
**Describe alternatives you've considered**
A clear and concise description of any alternative solutions or features you've considered.
**Additional context**
Add any other context or screenshots about the feature request here.

32
.github/workflows/ci-changed-examples.yml vendored
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@@ -1,32 +0,0 @@
name: CI Changed Examples
on:
push:
branches:
- main
pull_request:
branches:
- main
jobs:
get-example-changed:
uses: ./.github/workflows/get-example-changed.yml
get-matrix:
needs: [get-example-changed]
uses: ./.github/workflows/get-changed-examples-matrix.yml
with:
example_changed: ${{ fromJSON(needs.get-example-changed.outputs.example_changed) }}
test:
name: CI
needs: [get-example-changed, get-matrix]
if: needs.get-example-changed.outputs.example_changed == 'true'
strategy:
matrix: ${{ fromJSON(needs.get-matrix.outputs.matrix) }}
fail-fast: false
uses: ./.github/workflows/run-cargo-make-task.yml
with:
directory: ${{ matrix.directory }}
cargo_make_task: "ci"
toolchain: nightly

27
.github/workflows/ci-examples.yml vendored
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@@ -1,27 +0,0 @@
name: CI Examples
on:
push:
branches:
- main
pull_request:
branches:
- main
jobs:
get-leptos-changed:
uses: ./.github/workflows/get-leptos-changed.yml
get-examples-matrix:
uses: ./.github/workflows/get-examples-matrix.yml
test:
name: CI
needs: [get-leptos-changed, get-examples-matrix]
if: needs.get-leptos-changed.outputs.leptos_changed == 'true'
strategy:
matrix: ${{ fromJSON(needs.get-examples-matrix.outputs.matrix) }}
fail-fast: false
uses: ./.github/workflows/run-cargo-make-task.yml
with:
directory: ${{ matrix.directory }}
cargo_make_task: "ci"
toolchain: nightly

26
.github/workflows/ci-stable-examples.yml vendored
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@@ -1,26 +0,0 @@
name: CI Stable Examples
on:
push:
branches:
- main
pull_request:
branches:
- main
jobs:
get-leptos-changed:
uses: ./.github/workflows/get-leptos-changed.yml
test:
name: CI
needs: [get-leptos-changed]
if: needs.get-leptos-changed.outputs.leptos_changed == 'true'
strategy:
matrix:
directory: [examples/counters_stable, examples/counter_without_macros]
uses: ./.github/workflows/run-cargo-make-task.yml
with:
directory: ${{ matrix.directory }}
cargo_make_task: "ci"
toolchain: stable

44
.github/workflows/ci.yml vendored
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@@ -1,44 +0,0 @@
name: CI
on:
push:
branches:
- main
pull_request:
branches:
- main
jobs:
get-leptos-changed:
uses: ./.github/workflows/get-leptos-changed.yml
test:
name: CI
needs: [get-leptos-changed]
if: needs.get-leptos-changed.outputs.leptos_changed == 'true'
strategy:
matrix:
directory:
[
integrations/actix,
integrations/axum,
integrations/viz,
integrations/utils,
leptos,
leptos_config,
leptos_dom,
leptos_hot_reload,
leptos_macro,
leptos_reactive,
leptos_server,
meta,
router,
server_fn,
server_fn/server_fn_macro_default,
server_fn_macro,
]
uses: ./.github/workflows/run-cargo-make-task.yml
with:
directory: ${{ matrix.directory }}
cargo_make_task: "ci"
toolchain: nightly

55
.github/workflows/get-changed-examples-matrix.yml vendored
View File

@@ -1,55 +0,0 @@
name: Changed Examples Matrix Call
on:
workflow_call:
inputs:
example_changed:
description: "Example Changed"
required: true
type: boolean
outputs:
matrix:
description: "Matrix"
value: ${{ jobs.get-example-changed.outputs.matrix }}
jobs:
get-example-changed:
name: Get Changed Example Matrix
runs-on: ubuntu-latest
outputs:
matrix: ${{ steps.set-matrix.outputs.matrix }}
steps:
- name: Checkout
uses: actions/checkout@v4
with:
fetch-depth: 0
- name: Get example project directories that changed
id: changed-dirs
uses: tj-actions/changed-files@v39
with:
dir_names: true
dir_names_max_depth: "2"
files: |
examples
!examples/cargo-make
!examples/gtk
!examples/hackernews_js_fetch
!examples/Makefile.toml
!examples/*.md
json: true
quotepath: false
- name: List example project directories that changed
run: echo '${{ steps.changed-dirs.outputs.all_changed_files }}'
- name: Set Matrix
id: set-matrix
run: |
if [ ${{ inputs.example_changed }} == 'true' ]; then
# Create matrix with changed directories
echo "matrix={\"directory\":${{ steps.changed-dirs.outputs.all_changed_files }}}" >> "$GITHUB_OUTPUT"
else
# Create matrix with one item to prevent an empty vector error
echo "matrix={\"directory\":[\"NO_CHANGE\"]}" >> "$GITHUB_OUTPUT"
fi

39
.github/workflows/get-example-changed.yml vendored
View File

@@ -1,39 +0,0 @@
name: Examples Changed Call
on:
workflow_call:
outputs:
example_changed:
description: "Example Changed"
value: ${{ jobs.get-example-changed.outputs.example_changed }}
jobs:
get-example-changed:
name: Get Example Changed
runs-on: ubuntu-latest
outputs:
example_changed: ${{ steps.set-example-changed.outputs.example_changed }}
steps:
- name: Checkout
uses: actions/checkout@v4
with:
fetch-depth: 0
- name: Get example files that changed
id: changed-files
uses: tj-actions/changed-files@v39
with:
files: |
examples
!examples/cargo-make
!examples/gtk
!examples/Makefile.toml
!examples/*.md
- name: List example files that changed
run: echo '${{ steps.changed-files.outputs.all_changed_files }}'
- name: Set example_changed
id: set-example-changed
run: |
echo "example_changed=${{ steps.changed-files.outputs.any_changed }}" >> "$GITHUB_OUTPUT"

40
.github/workflows/get-examples-matrix.yml vendored
View File

@@ -1,40 +0,0 @@
name: Get Examples Matrix Call
on:
workflow_call:
outputs:
matrix:
description: "Matrix"
value: ${{ jobs.create.outputs.matrix }}
jobs:
create:
name: Create Examples Matrix
runs-on: ubuntu-latest
outputs:
matrix: ${{ steps.set-matrix.outputs.matrix }}
steps:
- name: Checkout
uses: actions/checkout@v4
- name: Install JQ Tool
uses: mbround18/install-jq@v1
- name: Set Matrix
id: set-matrix
run: |
examples=$(ls examples |
awk '{print "examples/" $0}' |
grep -v .md |
grep -v examples/Makefile.toml |
grep -v examples/cargo-make |
grep -v examples/gtk |
jq -R -s -c 'split("\n")[:-1]')
echo "Example Directories: $examples"
echo "matrix={\"directory\":$examples}" >> "$GITHUB_OUTPUT"
- name: Print Location Info
run: |
echo "Workspace: ${{ github.workspace }}"
pwd
ls | sort -u

44
.github/workflows/get-leptos-changed.yml vendored
View File

@@ -1,44 +0,0 @@
name: Get Leptos Changed Call
on:
workflow_call:
outputs:
leptos_changed:
description: "Leptos Changed"
value: ${{ jobs.create.outputs.leptos_changed }}
jobs:
create:
name: Detect Source Change
runs-on: ubuntu-latest
outputs:
leptos_changed: ${{ steps.set-source-changed.outputs.leptos_changed }}
steps:
- name: Checkout
uses: actions/checkout@v4
- name: Get source files that changed
id: changed-source
uses: tj-actions/changed-files@v39
with:
files: |
integrations
leptos
leptos_config
leptos_dom
leptos_hot_reload
leptos_macro
leptos_reactive
leptos_server
meta
router
server_fn
server_fn_macro
- name: List source files that changed
run: echo '${{ steps.changed-source.outputs.all_changed_files }}'
- name: Set leptos_changed
id: set-source-changed
run: |
echo "leptos_changed=${{ steps.changed-source.outputs.any_changed }}" >> "$GITHUB_OUTPUT"

37
.github/workflows/publish-book.yml vendored
View File

@@ -1,37 +0,0 @@
name: Deploy book
on:
push:
paths: ["docs/book/**"]
branches:
- main
jobs:
deploy:
runs-on: ubuntu-latest
permissions:
contents: write # To push a branch
pull-requests: write # To create a PR from that branch
steps:
- uses: actions/checkout@v4
with:
fetch-depth: 0
- name: Install mdbook
run: |
mkdir mdbook
curl -sSL https://github.com/rust-lang/mdBook/releases/download/v0.4.27/mdbook-v0.4.27-x86_64-unknown-linux-gnu.tar.gz | tar -xz --directory=./mdbook
echo `pwd`/mdbook >> $GITHUB_PATH
- name: Deploy GitHub Pages
run: |
cd docs/book
mdbook build
git worktree add gh-pages
git config user.name "Deploy book from CI"
git config user.email ""
cd gh-pages
# Delete the ref to avoid keeping history.
git update-ref -d refs/heads/gh-pages
rm -rf *
mv ../book/* .
git add .
git commit -m "Deploy book $GITHUB_SHA to gh-pages"
git push --force --set-upstream origin gh-pages

114
.github/workflows/run-cargo-make-task.yml vendored
View File

@@ -1,114 +0,0 @@
name: Run Task
on:
workflow_call:
inputs:
directory:
required: true
type: string
cargo_make_task:
required: true
type: string
toolchain:
required: true
type: string
env:
CARGO_TERM_COLOR: always
CARGO_REGISTRIES_CRATES_IO_PROTOCOL: sparse
jobs:
test:
name: Run ${{ inputs.cargo_make_task }} (${{ inputs.toolchain }})
runs-on: ubuntu-latest
steps:
# Setup environment
- uses: actions/checkout@v4
- name: Setup Rust
uses: actions-rs/toolchain@v1
with:
toolchain: ${{ inputs.toolchain }}
override: true
components: rustfmt
- name: Add wasm32-unknown-unknown
run: rustup target add wasm32-unknown-unknown
- name: Setup cargo-make
uses: davidB/rust-cargo-make@v1
- name: Cargo generate-lockfile
run: cargo generate-lockfile
- uses: Swatinem/rust-cache@v2
- name: Install Trunk
uses: jetli/trunk-action@v0.4.0
with:
version: "latest"
- name: Print Trunk Version
run: trunk --version
- name: Install Node.js
uses: actions/setup-node@v4
with:
node-version: 18
- uses: pnpm/action-setup@v2
name: Install pnpm
id: pnpm-install
with:
version: 8
run_install: false
- name: Get pnpm store directory
id: pnpm-cache
run: |
echo "STORE_PATH=$(pnpm store path)" >> $GITHUB_OUTPUT
- uses: actions/cache@v3
name: Setup pnpm cache
with:
path: ${{ steps.pnpm-cache.outputs.STORE_PATH }}
key: ${{ runner.os }}-pnpm-store-${{ hashFiles('**/pnpm-lock.yaml') }}
restore-keys: |
${{ runner.os }}-pnpm-store-
- name: Maybe install chromedriver
run: |
project_makefile=${{inputs.directory}}/Makefile.toml
webdriver_count=$(cat $project_makefile | grep "cargo-make/webdriver.toml" | wc -l)
if [ $webdriver_count -eq 1 ]; then
if ! command -v chromedriver &>/dev/null; then
echo chromedriver required
sudo apt-get update
sudo apt-get install chromium-chromedriver
else
echo chromedriver is already installed
fi
else
echo chromedriver is not required
fi
- name: Maybe install playwright browser dependencies
run: |
for pw_path in $(find ${{inputs.directory}} -name playwright.config.ts)
do
pw_dir=$(dirname $pw_path)
if [ ! -v $pw_dir ]; then
echo "Playwright required in $pw_dir"
cd $pw_dir
pnpm dlx playwright install --with-deps
else
echo Playwright is not required
fi
done
# Run Cargo Make Task
- name: ${{ inputs.cargo_make_task }}
run: |
cd ${{ inputs.directory }}
cargo make --profile=github-actions ${{ inputs.cargo_make_task }}

48
.github/workflows/test.yml vendored Normal file
View File

@@ -0,0 +1,48 @@
name: Test
on:
push:
branches: [main]
pull_request:
branches: [main]
env:
CARGO_TERM_COLOR: always
jobs:
test:
name: Test on ${{ matrix.os }} (using rustc ${{ matrix.rust }})
runs-on: ${{ matrix.os }}
strategy:
matrix:
rust:
- nightly
os:
- ubuntu-latest
steps:
- uses: actions/checkout@v3
- name: Setup Rust
uses: actions-rs/toolchain@v1
with:
toolchain: ${{ matrix.rust }}
override: true
components: rustfmt
- name: Add wasm32-unknown-unknown
run: rustup target add wasm32-unknown-unknown
- name: Setup cargo-make
uses: davidB/rust-cargo-make@v1
- name: Cargo generate-lockfile
run: cargo generate-lockfile
- name: Run Rustfmt
run: cargo fmt -- --check
- uses: Swatinem/rust-cache@v2
- name: Run tests with all features
run: cargo make ci

4
.gitignore vendored
View File

@@ -7,7 +7,3 @@ Cargo.lock
**/*.rs.bk
.DS_Store
.idea
.direnv
.envrc
.vscode

231
ARCHITECTURE.md
View File

@@ -1,231 +0,0 @@
# Architecture
The goal of this document is to make it easier for contributors (and anyone
whos interested!) to understand the architecture of the framework.
The whole Leptos framework is built from a series of layers. Each of these layers
depends on the one below it, but each can be used independently from the ones
built on top of it. While running a command like `cargo leptos new --git
leptos-rs/start` pulls in the whole framework, its important to remember that
none of this is magic: each layer of that onion can be stripped away and
reimplemented, configured, or adapted as needed, incrementally.
> Everything that follows will assume you have a good working understanding
> of the framework. There will be explanations of how some parts of it work
> or fit together, but these are not docs. They assume you know what Im
> talking about.
## The Reactive System: `leptos_reactive`
The reactive system allows you to define dynamic values (signals),
the relationships between them (derived signals and memos), and the side effects
that run in response to them (effects).
These concepts are completely independent of the DOM and can be used to drive
any kind of reactive updates. The reactive system is based on the assumption
that data is relatively cheap, and side effects are relatively expensive. Its
goal is to minimize those side effects (like updating the DOM or making a network
requests) as infrequently as possible.
The reactive system is implemented as a single data structure that exists at
runtime. In exchange for giving ownership over a value to the reactive system
(by creating a signal), you receive a `Copy + 'static` identifier for its
location in the reactive system. This enables most of the ergonomics of storing
and sharing state, the use of callback closures without lifetime issues, etc.
This is implemented by storing signals in a slotmap arena. The signal, memo,
and scope types that are exposed to users simply carry around an index into that
slotmap.
> Items owned by the reactive system are dropped when the corresponding reactive
> scope is dropped, i.e., when the component or section of the UI theyre
> created in is removed. In a sense, Leptos implements a “garbage collector”
> in which the lifetime of data is tied to the lifetime of the UI, not Rusts
> lexical scopes.
## The DOM Renderer: `leptos_dom`
The reactive system can be used to drive any kinds of side effects. One very
common side effect is calling an imperative method, for example to update the
DOM.
The entire DOM renderer is built on top of the reactive system. It provides
a builder pattern that can be used to create DOM elements dynamically.
The renderer assumes, as a convention, that dynamic attributes, classes,
styles, and children are defined by being passed a `Fn() -> T`, where their
static equivalents just receive `T`. Theres nothing about this that is
divinely ordained, but its a useful convention because it allows us to use
zero-overhead derived signals as one of several ways to indicate dynamic
content.
`leptos_dom` also contains code for server-side rendering of the same
UI views to HTML, either for out-of-order streaming (`src/ssr.rs`) or
in-order streaming/async rendering (`src/ssr_in_order.rs`).
## The Macros: `leptos_macro`
Its entirely possible to write Leptos code with no macros at all. The
`view` and `component` macros, the most common, can be replaced by
the builder syntax and simple functions (see the `counter_without_macros`
example). But the macros enable a JSX-like syntax for describing views.
This package also contains the `Params` derive macro used for typed
queries and route params in the router.
### Macro-based Optimizations
Leptos 0.0.x was built much more heavily on macros. Taking its cues
from SolidJS, the `view` macro emitted different code for CSR, SSR, and
hydration, optimizing each. The CSR/hydrate versions worked by compiling
the view to an HTML template string, cloning that `<template>`, and
traversing the DOM to set up reactivity. The SSR version worked similarly
by compiling the static parts of the view to strings at compile time,
reducing the amount of work that needed to be done on each request.
Proc macros are hard, and this system was brittle. 0.1 introduced a
more robust renderer, including the builder syntax, and rebuilt the `view`
macro to use that builder syntax instead. It moved the optimized-but-buggy
CSR version of the macro to a more-limited `template` macro.
The `view` macro now separately optimizes SSR to use the same static-string
optimizations, which (by our benchmarks) makes Leptos about 3-4x faster
than similar Rust frontend frameworks in its HTML rendering.
> The optimization is pretty straightforward. Consider the following view:
>
> ```rust
> view! { cx,
> <main class="text-center">
> <div class="flex-col">
> <button>"Click me."</button>
> <p class="italic">"Text."</p>
> </div>
> </main>
> }
> ```
>
> Internally, with the builder this is something like
>
> ```rust
> Element {
> tag: "main",
> attrs: vec![("class", "text-center")],
> children: vec![
> Element {
> tag: "div",
> attrs: vec![("class", "flex-col")],
> children: vec![
> Element {
> tag: "button",
> attrs: vec![],
> children: vec!["Click me"]
> },
> Element {
> tag: "p",
> attrs: vec![("class", "italic")],
> children: vec!["Text"]
> }
> ]
> }
> ]
> }
> ```
>
> This is a _bunch_ of small allocations and separate strings,
> and in early 0.1 versions we used a `SmallVec` for children and
> attributes and actually caused some stack overflows.
>
> But if you look at the view itself you can see that none of this
> will _ever_ change. So we can actually optimize it at compile
> time to a single `&'static str`:
>
> ```rust
> r#"<main class="text-center">
> <div class="flex-col">
> <button>"Click me."</button>
> <p class="italic">"Text."</p>
> </div>
> </main>"#
> ```
## Server Functions (`leptos_server`, `server_fn`, and `server_fn_macro`)
Server functions are a framework-agnostic shorthand for converting
a function, whose body can only be run on the server, into an ad hoc
REST API endpoint, and then generating code on the client to call that
endpoint when you call the function.
These are inspired by Solid/Blings `server$` functions, and theres
similar work being done in a number of other JavaScript frameworks.
RPC is not a new idea, but these kinds of server functions may be.
Specifically, by using web standards (defaulting to `POST`/`GET` requests
with URL-encoded form data) they allow easy graceful degradation and the
use of the `<form>` element.
This function is split across three packages so that `server_fn` and
`server_fn_macro` can be used by other frameworks. `leptos_server`
includes some Leptos-specific reactive functionality (like actions).
## `leptos`
This package is built on and reexports most of the layers already
mentioned, and implements a number of control-flow components (`<Show/>`,
`<ErrorBoundary/>`, `<For/>`, `<Suspense/>`, `<Transition/>`) that use
public APIs of the other packages.
This is the main entrypoint for users, but is relatively light itself.
## `leptos_meta`
This package exists to allow you to work with tags normally found in
the `<head>`, from within your components.
It is implemented as a distinct package, rather than part of
`leptos_dom`, on the principle that “what can be implemented in userland,
should be.” The framework can be used without it, so its not in core.
## `leptos_router`
The router originates as a direct port of `solid-router`, which is the
origin of most of its terminology, architecture, and route-matching logic.
Subsequent developments (like animated routing, and managing route transitions
given the lack of `useTransition` in Leptos) have caused it to diverge
slightly from Solids exact code, but it is still very closely related.
The core principle here is “nested routing,” dividing a single page
into independently-rendered parts. This is described in some detail in the docs.
Like `leptos_meta`, it is implemented as a distinct package, because it
can be replaced with another router or with none. The framework can be used
without it, so its not in core.
## Server Integrations
The server integrations are the most “frameworky” layer of the whole framework.
These **do** assume the use of `leptos`, `leptos_router`, and `leptos_meta`.
They specifically draw routing data from `leptos_router`, and inject the
metadata from `leptos_meta` into the `<head>` appropriately.
But of course, if you one day create `leptos-helmet` and `leptos-better-router`,
you can create new server integrations that plug them into the SSR rendering
methods from `leptos_dom` instead. Everything involved is quite modular.
These packages essentially provide helpers that save the templates and user apps
from including a huge amount of boilerplate to connect the various other packages
correctly. Again, early versions of the framework examples are illustrative here
for reference: they include large amounts of manual SSR route handling, etc.
## `cargo-leptos` helpers
`leptos_config` and `leptos_hot_reload` exist to support two different features
of `cargo-leptos`, namely its configuration and its view-patching/hot-reloading
features.
Its important to say that the main feature `cargo-leptos` remains its ability
to conveniently tie together different build tooling, compiling your app to
WASM for the browser, building the server version, pulling in SASS and
Tailwind, etc. It is an extremely good build tool, not a magic formula. Each
of the examples includes instructions for how to run the examples without
`cargo-leptos`.

2
CODE_OF_CONDUCT.md
View File

@@ -2,7 +2,7 @@
_This Code of Conduct is based on the [Rust Code of Conduct](https://www.rust-lang.org/policies/code-of-conduct)
and the [Bevy Code of Conduct](https://raw.githubusercontent.com/bevyengine/bevy/main/CODE_OF_CONDUCT.md),
which are adapted from the [Node.js Policy on Trolling](http://blog.izs.me/post/30036893703/policy-on-trolling)
which are adapted from the [Node.js Policy on Trolling](http://blog.izs.me/post/30036893703/policy-on-trolling)
and the [Contributor Covenant](https://www.contributor-covenant.org)._
## Our Pledge

94
CONTRIBUTING.md
View File

@@ -1,94 +0,0 @@
# Contributing to Leptos
Thanks for your interesting in contributing to Leptos! This is a truly
community-driven framework, and while we have a central maintainer (@gbj)
large parts of the renderer, reactive system, and server integrations have
all been written by other contributors. Contributions are always welcome.
Participation in this community is governed by a [Code of Conduct](./CODE_OF_CONDUCT.md).
Some of the most active conversations around development take place on our
[Discord server](https://discord.gg/YdRAhS7eQB).
This guide seeks to
- describe some of the frameworks values (in a technical, not an ethical, sense)
- provide a high-level overview of how the pieces of the framework fit together
- orient you to the organization of this repository
## Values
Leptos, as a framework, reflects certain technical values:
- **Expose primitives rather than imposing patterns.** Provide building blocks
that users can combine together to build up more complex behavior, rather than
requiring users follow certain templates, file formats, etc. e.g., components
are defined as functions, rather than a bespoke single-file component format.
The reactive system feeds into the rendering system, rather than being defined
by it.
- **Bottom-up over top-down.** If you envision a users application as a tree
(like an HTML document), push meaning toward the leaves of the tree. e.g., If data
needs to be loaded, load it in a granular primitive (resources) rather than a
route- or page-level data structure.
- **Performance by default.** When possible, users should only pay for what they
use. e.g., we dont make all component props reactive by default. This is
because doing so would force the overhead of a reactive prop onto props that dont
need to be reactive.
- **Full-stack performance.** Performance cant be limited to a single metric,
whether thats a DOM rendering benchmark, WASM binary size, or server response
time. Use methods like HTTP streaming and progressive enhancement to enable
applications to load, become interactive, and respond as quickly as possible.
- **Use safe Rust.** Theres no need for `unsafe` Rust in the framework, and
avoiding it at all costs reduces the maintenance and testing burden significantly.
- **Embrace Rust semantics.** Especially in things like UI templating, use Rust
semantics or extend them in a predictable way with control-flow components
rather than overloading the meaning of Rust terms like `if` or `for` in a
framework-specific way.
- **Enhance ergonomics without obfuscating whats happening.** This is by far
the hardest to achieve. Its often the case that adding additional layers to
improve DX (like a custom build tool and starter templates) comes across as
“too magic” to some people who havent had to build the same things manually.
When possible, make it easier to see how the pieces fit together, without
sacrificing the improved DX.
## Processes
We do not have PR templates or formal processes for approving PRs. But there
are a few guidelines that will make it a better experience for everyone:
- Run `cargo fmt` before submitting your code.
- Keep PRs limited to addressing one feature or one issue, in general. In some
cases (e.g., “reduce allocations in the reactive system”) this may touch a number
of different areas, but is still conceptually one thing.
- If its an unsolicited PR not linked to an open issue, please include a
specific explanation for what its trying to achieve. For example: “When I
was trying to deploy my app under _circumstances X_, I found that the way
_function Y_ was implemented caused _issue Z_. This PR should fix that by
_solution._
- Our CI tests every PR against all the existing examples, sometimes requiring
compilation for both server and client side, etc. Its thorough but slow. If
you want to run CI locally to reduce frustration, you can do that by installing
`cargo-make` and using `cargo make check && cargo make test && cargo make
check-examples`.
## Before Submitting a PR
We have a fairly extensive CI setup that runs both lints (like `rustfmt` and `clippy`)
and tests on PRs. You can run most of these locally if you have `cargo-make` installed.
If you added an example, make sure to add it to the list in `examples/Makefile.toml`.
From the root directory of the repo, run
- `cargo +nightly fmt`
- `cargo +nightly make check`
- `cargo +nightly make test`
- `cargo +nightly make check-examples`
- `cargo +nightly make --profile=github-actions ci`
If you modified an example:
- `cd examples/your_example`
- `cargo +nightly fmt -- --config-path ../..`
- `cargo +nightly make --profile=github-actions verify-flow`
## Architecture
See [ARCHITECTURE.md](./ARCHITECTURE.md).

30
Cargo.toml
View File

@@ -1,22 +1,16 @@
[workspace]
resolver = "2"
members = [
# core
"leptos",
"leptos_dom",
"leptos_config",
"leptos_hot_reload",
"leptos_macro",
"leptos_reactive",
"leptos_server",
"server_fn",
"server_fn_macro",
"server_fn/server_fn_macro_default",
# integrations
"integrations/actix",
"integrations/axum",
"integrations/viz",
"integrations/utils",
# libraries
@@ -26,22 +20,18 @@ members = [
exclude = ["benchmarks", "examples"]
[workspace.package]
version = "0.5.4"
version = "0.2.0-beta"
[workspace.dependencies]
leptos = { path = "./leptos", version = "0.5.4" }
leptos_dom = { path = "./leptos_dom", version = "0.5.4" }
leptos_hot_reload = { path = "./leptos_hot_reload", version = "0.5.4" }
leptos_macro = { path = "./leptos_macro", version = "0.5.4" }
leptos_reactive = { path = "./leptos_reactive", version = "0.5.4" }
leptos_server = { path = "./leptos_server", version = "0.5.4" }
server_fn = { path = "./server_fn", version = "0.5.4" }
server_fn_macro = { path = "./server_fn_macro", version = "0.5.4" }
server_fn_macro_default = { path = "./server_fn/server_fn_macro_default", version = "0.5.4" }
leptos_config = { path = "./leptos_config", version = "0.5.4" }
leptos_router = { path = "./router", version = "0.5.4" }
leptos_meta = { path = "./meta", version = "0.5.4" }
leptos_integration_utils = { path = "./integrations/utils", version = "0.5.4" }
leptos = { path = "./leptos", default-features = false, version = "0.2.0-beta" }
leptos_dom = { path = "./leptos_dom", default-features = false, version = "0.2.0-beta" }
leptos_macro = { path = "./leptos_macro", default-features = false, version = "0.2.0-beta" }
leptos_reactive = { path = "./leptos_reactive", default-features = false, version = "0.2.0-beta" }
leptos_server = { path = "./leptos_server", default-features = false, version = "0.2.0-beta" }
leptos_config = { path = "./leptos_config", default-features = false, version = "0.2.0-beta" }
leptos_router = { path = "./router", version = "0.2.0-beta" }
leptos_meta = { path = "./meta", default-feature = false, version = "0.2.0-beta" }
leptos_integration_utils = { path = "./integrations/utils", version = "0.2.0-beta" }
[profile.release]
codegen-units = 1

64
Makefile.toml
View File

@@ -3,37 +3,51 @@
# cargo install --force cargo-make
############
[env]
CARGO_MAKE_EXTEND_WORKSPACE_MAKEFILE = true
[config]
# make tasks run at the workspace root
default_to_workspace = false
[tasks.check-stable]
workspace = false
[tasks.ci]
dependencies = ["build", "check-examples", "test"]
[tasks.build]
clear = true
dependencies = [
{ name = "check", path = "examples/counter_without_macros" },
{ name = "check", path = "examples/counters_stable" },
]
dependencies = ["build-all", "build-wasm"]
[tasks.ci-examples]
workspace = false
cwd = "examples"
[tasks.build-all]
command = "cargo"
args = ["make", "ci-clean"]
args = ["+nightly", "build-all-features"]
install_crate = "cargo-all-features"
[tasks.build-wasm]
clear = true
dependencies = [{ name = "build-wasm", path = "leptos" }]
[tasks.check-examples]
workspace = false
cwd = "examples"
command = "cargo"
args = ["make", "check-clean"]
clear = true
dependencies = [
{ name = "check", path = "examples/counter" },
{ name = "check", path = "examples/counter_isomorphic" },
{ name = "check", path = "examples/counter_without_macros" },
{ name = "check", path = "examples/counters" },
{ name = "check", path = "examples/counters_stable" },
{ name = "check", path = "examples/errors_axum" },
{ name = "check", path = "examples/fetch" },
{ name = "check", path = "examples/hackernews" },
{ name = "check", path = "examples/hackernews_axum" },
{ name = "check", path = "examples/parent_child" },
{ name = "check", path = "examples/router" },
{ name = "check", path = "examples/tailwind" },
{ name = "check", path = "examples/todo_app_sqlite" },
{ name = "check", path = "examples/todo_app_sqlite_axum" },
{ name = "check", path = "examples/todomvc" },
]
[tasks.build-examples]
workspace = false
cwd = "examples"
command = "cargo"
args = ["make", "build-clean"]
[tasks.test]
clear = true
dependencies = ["test-all"]
[tasks.clean-examples]
workspace = false
cwd = "examples"
[tasks.test-all]
command = "cargo"
args = ["make", "clean"]
args = ["+nightly", "test-all-features"]
install_crate = "cargo-all-features"

72
README.md
View File

@@ -6,11 +6,6 @@
[![crates.io](https://img.shields.io/crates/v/leptos.svg)](https://crates.io/crates/leptos)
[![docs.rs](https://docs.rs/leptos/badge.svg)](https://docs.rs/leptos)
[![Discord](https://img.shields.io/discord/1031524867910148188?color=%237289DA&label=discord)](https://discord.gg/YdRAhS7eQB)
[![Matrix](https://img.shields.io/badge/Matrix-leptos-grey?logo=matrix&labelColor=white&logoColor=black)](https://matrix.to/#/#leptos:matrix.org)
[Website](https://leptos.dev) | [Book](https://leptos-rs.github.io/leptos/) | [Docs.rs](https://docs.rs/leptos/latest/leptos/) | [Playground](https://codesandbox.io/p/sandbox/leptos-rtfggt?file=%2Fsrc%2Fmain.rs%3A1%2C1) | [Discord](https://discord.gg/YdRAhS7eQB)
You can find a list of useful libraries and example projects at [`awesome-leptos`](https://github.com/leptos-rs/awesome-leptos).
# Leptos
@@ -18,9 +13,9 @@ You can find a list of useful libraries and example projects at [`awesome-leptos
use leptos::*;
#[component]
pub fn SimpleCounter(initial_value: i32) -> impl IntoView {
pub fn SimpleCounter(cx: Scope, initial_value: i32) -> impl IntoView {
// create a reactive signal with the initial value
let (value, set_value) = create_signal(initial_value);
let (value, set_value) = create_signal(cx, initial_value);
// create event handlers for our buttons
// note that `value` and `set_value` are `Copy`, so it's super easy to move them into closures
@@ -30,22 +25,21 @@ pub fn SimpleCounter(initial_value: i32) -> impl IntoView {
// create user interfaces with the declarative `view!` macro
view! {
cx,
<div>
<button on:click=clear>Clear</button>
<button on:click=decrement>-1</button>
// text nodes can be quoted or unquoted
<button on:click=clear>"Clear"</button>
<button on:click=decrement>"-1"</button>
<span>"Value: " {value} "!"</span>
<button on:click=increment>+1</button>
<button on:click=increment>"+1"</button>
</div>
}
}
// Easy to use with Trunk (trunkrs.dev) or with a simple wasm-bindgen setup
pub fn main() {
mount_to_body(|| view! {
<SimpleCounter initial_value=3 />
})
mount_to_body(|cx| view! { cx, <SimpleCounter initial_value=3 /> })
}
```
## About the Framework
@@ -54,27 +48,27 @@ Leptos is a full-stack, isomorphic Rust web framework leveraging fine-grained re
## What does that mean?
- **Full-stack**: Leptos can be used to build apps that run in the browser (client-side rendering), on the server (server-side rendering), or by rendering HTML on the server and then adding interactivity in the browser (server-side rendering with hydration). This includes support for HTTP streaming of both data ([`Resource`s](https://docs.rs/leptos/latest/leptos/struct.Resource.html)) and HTML (out-of-order or in-order streaming of [`<Suspense/>`](https://docs.rs/leptos/latest/leptos/fn.Suspense.html) components.)
- **Isomorphic**: Leptos provides primitives to write isomorphic [server functions](https://docs.rs/leptos_server/0.2.5/leptos_server/index.html), i.e., functions that can be called with the “same shape” on the client or server, but only run on the server. This means you can write your server-only logic (database requests, authentication etc.) alongside the client-side components that will consume it, and call server functions as if they were running in the browser, without needing to create and maintain a separate REST or other API.
- **Web**: Leptos is built on the Web platform and Web standards. The [router](https://docs.rs/leptos_router/latest/leptos_router/) is designed to use Web fundamentals (like links and forms) and build on top of them rather than trying to replace them.
- **Full-stack**: Leptos can be used to build apps that run in the browser (_client-side rendering_), on the server (_server-side rendering_), or by rendering HTML on the server and then adding interactivity in the browser (_hydration_). This includes support for _HTTP streaming_ of both data (`Resource`s) and HTML (out-of-order streaming of `<Suspense/>` components.)
- **Isomorphic**: Leptos provides primitives to write isomorphic server functions, i.e., functions that can be called with the “same shape” on the client or server, but only run on the server. This means you can write your server-only logic (database requests, authentication etc.) alongside the client-side components that will consume it, and call server functions as if they were running in the browser.
- **Web**: Leptos is built on the Web platform and Web standards. The router is designed to use Web fundamentals (like links and forms) and build on top of them rather than trying to replace them.
- **Framework**: Leptos provides most of what you need to build a modern web app: a reactive system, templating library, and a router that works on both the server and client side.
- **Fine-grained reactivity**: The entire framework is built from reactive primitives. This allows for extremely performant code with minimal overhead: when a reactive signals value changes, it can update a single text node, toggle a single class, or remove an element from the DOM without any other code running. (So, no virtual DOM overhead!)
- **Fine-grained reactivity**: The entire framework is built from reactive primitives. This allows for extremely performant code with minimal overhead: when a reactive signals value changes, it can update a single text node, toggle a single class, or remove an element from the DOM without any other code running. (_So, no virtual DOM!_)
- **Declarative**: Tell Leptos how you want the page to look, and let the framework tell the browser how to do it.
## Learn more
Here are some resources for learning more about Leptos:
- [Book](https://leptos-rs.github.io/leptos/) (work in progress)
- [Examples](https://github.com/leptos-rs/leptos/tree/main/examples)
- [API Documentation](https://docs.rs/leptos/latest/leptos/)
- [Common Bugs](https://github.com/leptos-rs/leptos/tree/main/docs/COMMON_BUGS.md) (and how to fix them!)
- Leptos Guide (in progress)
## `nightly` Note
Most of the examples assume youre using `nightly` version of Rust and the `nightly` feature of Leptos. To use `nightly` Rust, you can either set your toolchain globally or on per-project basis.
Most of the examples assume youre using `nightly` Rust.
To set `nightly` as a default toolchain for all projects (and add the ability to compile Rust to WebAssembly, if you havent already):
To set up your Rust toolchain using `nightly` (and add the ability to compile Rust to WebAssembly, if you havent already)
```
rustup toolchain install nightly
@@ -82,19 +76,17 @@ rustup default nightly
rustup target add wasm32-unknown-unknown
```
If you'd like to use `nightly` only in your Leptos project however, add [`rust-toolchain.toml`](https://rust-lang.github.io/rustup/overrides.html#the-toolchain-file) file with the following content:
If youre on `stable`, note the following:
```toml
[toolchain]
channel = "nightly"
targets = ["wasm32-unknown-unknown"]
```
The `nightly` feature enables the function call syntax for accessing and setting signals, as opposed to `.get()` and `.set()`. This leads to a consistent mental model in which accessing a reactive value of any kind (a signal, memo, or derived signal) is always represented as a function call. This is only possible with nightly Rust and the `nightly` feature.
1. You need to enable the `"stable"` flag in `Cargo.toml`: `leptos = { version = "0.1.0", features = ["stable"] }`
2. `nightly` enables the function call syntax for accessing and setting signals. If youre using `stable`,
youll just call `.get()`, `.set()`, or `.update()` manually. Check out the
[`counters_stable` example](https://github.com/leptos-rs/leptos/blob/main/examples/counters_stable/src/main.rs)
for examples of the correct API.
## `cargo-leptos`
[`cargo-leptos`](https://github.com/leptos-rs/cargo-leptos) is a build tool that's designed to make it easy to build apps that run on both the client and the server, with seamless integration. The best way to get started with a real Leptos project right now is to use `cargo-leptos` and our starter templates for [Actix](https://github.com/leptos-rs/start) or [Axum](https://github.com/leptos-rs/start-axum).
[`cargo-leptos`](https://github.com/leptos-rs/cargo-leptos) is a build tool that's designed to make it easy to build apps that run on both the client and the server, with seamless integration. The best way to get started with a real Leptos project right now is to use `cargo-leptos` and our [starter template](https://github.com/leptos-rs/start).
```bash
cargo install cargo-leptos
@@ -103,13 +95,13 @@ cd [your project name]
cargo leptos watch
```
Open browser to [http://localhost:3000/](http://localhost:3000/).
Open browser on [http://localhost:3000/](http://localhost:3000/)
## FAQs
### Whats up with the name?
_Leptos_ (λεπτός) is an ancient Greek word meaning “thin, light, refined, fine-grained.” To me, a classicist and not a dog owner, it evokes the lightweight reactive system that powers the framework. I've since learned the same word is at the root of the medical term “leptospirosis,” a blood infection that affects humans and animals... My bad. No dogs were harmed in the creation of this framework.
*Leptos* (λεπτός) is an ancient Greek word meaning “thin, light, refine, fine-grained.” To me, a classicist and not a dog owner, it evokes the lightweight reactive system that powers the framework. I've since learned the same word is at the root of the medical term “leptospirosis,” a blood infection that affects humans and animals... My bad. No dogs were harmed in the creation of this framework.
### Is it production ready?
@@ -117,7 +109,7 @@ People usually mean one of three things by this question.
1. **Are the APIs stable?** i.e., will I have to rewrite my whole app from Leptos 0.1 to 0.2 to 0.3 to 0.4, or can I write it now and benefit from new features and updates as new versions come?
The APIs are basically settled. Were adding new features, but were very happy with where the type system and patterns have landed. I would not expect major breaking changes to your code to adapt to future releases, in terms of architecture.
With 0.1 the APIs are basically settled. Were adding new features, but were very happy with where the type system and patterns have landed. I would not expect major breaking changes to your code to adapt to, for example, a 0.2.0 release.
2. **Are there bugs?**
@@ -127,7 +119,7 @@ Yes, Im sure there are. You can see from the state of our issue tracker over
This may be the big one: “production ready” implies a certain orientation to a library: that you can basically use it, without any special knowledge of its internals or ability to contribute. Everyone has this at some level in their stack: for example I (@gbj) dont have the capacity or knowledge to contribute to something like `wasm-bindgen` at this point: I simply rely on it to work.
There are several people in the community using Leptos right now for internal apps at work, who have also become significant contributors. I think this is the right level of production use for now. There may be missing features that you need, and you may end up building them! But for internal apps, if youre willing to build and contribute missing pieces along the way, the framework is definitely usable right now.
There are several people in this community using Leptos right now for internal apps at work, who have also become significant contributors. I think this is the right level of production use for now. There may be missing features that you need, and you may end up building them! But for internal apps, if youre willing to build and contribute missing pieces along the way, the framework is definitely usable right now.
### Can I use this for native GUI?
@@ -145,8 +137,8 @@ I've put together a [very simple GTK example](https://github.com/leptos-rs/lepto
On the surface level, these libraries may seem similar. Yew is, of course, the most mature Rust library for web UI development and has a huge ecosystem. Dioxus is similar in many ways, being heavily inspired by React. Here are some conceptual differences between Leptos and these frameworks:
- **VDOM vs. fine-grained:** Yew is built on the virtual DOM (VDOM) model: state changes cause components to re-render, generating a new virtual DOM tree. Yew diffs this against the previous VDOM, and applies those patches to the actual DOM. Component functions rerun whenever state changes. Leptos takes an entirely different approach. Components run once, creating (and returning) actual DOM nodes and setting up a reactive system to update those DOM nodes.
- **Performance:** This has huge performance implications: Leptos is simply much faster at both creating and updating the UI than Yew is. (Dioxus has made huge advances in performance with its recent 0.3 release, and is now roughly on par with Leptos.)
- **Mental model:** Adopting fine-grained reactivity also tends to simplify the mental model. There are no surprising component re-renders because there are no re-renders. You can call functions, create timeouts, etc. within the body of your component functions because they wont be re-run. You dont need to think about manual dependency tracking for effects; fine-grained reactivity tracks dependencies automatically.
- **Performance:** This has huge performance implications: Leptos is simply _much_ faster at both creating and updating the UI than Yew is.
- **Mental model:** Adopting fine-grained reactivity also tends to simplify the mental model. There are no surprising component re-renders because there are no re-renders. Your app can be divided into components based on what makes sense for your app, because they have no performance implications.
### How is this different from Sycamore?
@@ -154,15 +146,15 @@ Conceptually, these two frameworks are very similar: because both are built on f
There are some practical differences that make a significant difference:
- **Maturity:** Sycamore is obviously a much more mature and stable library with a larger ecosystem.
- **Templating:** Leptos uses a JSX-like template format (built on [syn-rsx](https://github.com/stoically/syn-rsx)) for its `view` macro. Sycamore offers the choice of its own templating DSL or a builder syntax.
- **Server integration:** Leptos provides primitives that encourage HTML streaming and allow for easy async integration and RPC calls, even without WASM enabled, making it easy to opt into integrations between your frontend and backend code without pushing you toward any particular metaframework patterns.
- **Read-write segregation:** Leptos, like Solid, encourages read-write segregation between signal getters and setters, so you end up accessing signals with tuples like `let (count, set_count) = create_signal(0);` _(If you prefer or if it's more convenient for your API, you can use [`create_rw_signal`](https://docs.rs/leptos/latest/leptos/fn.create_rw_signal.html) to give a unified read/write signal.)_
- **Read-write segregation:** Leptos, like Solid, encourages read-write segregation between signal getters and setters, so you end up accessing signals with tuples like `let (count, set_count) = create_signal(cx, 0);` _(If you prefer or if it's more convenient for your API, you can use `create_rw_signal` to give a unified read/write signal.)_
- **Signals are functions:** In Leptos, you can call a signal to access it rather than calling a specific method (so, `count()` instead of `count.get()`) This creates a more consistent mental model: accessing a reactive value is always a matter of calling a function. For example:
```rust
let (count, set_count) = create_signal(0); // a signal
let (count, set_count) = create_signal(cx, 0); // a signal
let double_count = move || count() * 2; // a derived signal
let memoized_count = create_memo(move |_| count() * 3); // a memo
let memoized_count = create_memo(cx, move |_| count() * 3); // a memo
// all are accessed by calling them
assert_eq!(count(), 0);
assert_eq!(double_count(), 0);

13
SECURITY.md
View File

@@ -1,13 +0,0 @@
# Security Policy
## Reporting a Vulnerability
To report a suspected security issue, please contact security@leptos.dev rather than opening
a public issue.
## Supported Versions
The most-recently-released version of the library is supported with security updates.
For example, if a security issue is discovered that affects 0.3.2 and all later releases,
a 0.4.x patch will be released but a new 0.3.x patch release will not be made. You should
plan to update to the latest version to receive any new features or bugfixes of any kind.

23
benchmarks/Cargo.toml
View File

@@ -4,19 +4,9 @@ version = "0.1.0"
edition = "2021"
[dependencies]
l0410 = { package = "leptos", version = "0.4.10", features = [
"nightly",
"ssr",
] }
leptos = { path = "../leptos", features = ["ssr", "nightly"] }
leptos_reactive = { path = "../leptos_reactive", features = ["ssr", "nightly"] }
tachydom = { git = "https://github.com/gbj/tachys", features = [
"nightly",
"leptos",
] }
tachy_maccy = { git = "https://github.com/gbj/tachys", features = ["nightly"] }
leptos = { path = "../leptos", default-features = false, features = ["ssr"] }
sycamore = { version = "0.8", features = ["ssr"] }
yew = { version = "0.20", features = ["ssr"] }
yew = { git = "https://github.com/yewstack/yew", features = ["ssr"] }
tokio-test = "0.4"
miniserde = "0.1"
gloo = "0.8"
@@ -26,10 +16,15 @@ lazy_static = "1"
log = "0.4"
strum = "0.24"
strum_macros = "0.24"
serde = { version = "1", features = ["derive", "rc"] }
serde = { version = "1", features = ["derive", "rc"]}
serde_json = "1"
tera = "1"
[dependencies.web-sys]
version = "0.3"
features = ["Window", "Document", "HtmlElement", "HtmlInputElement"]
features = [
"Window",
"Document",
"HtmlElement",
"HtmlInputElement"
]

2
benchmarks/src/lib.rs
View File

@@ -2,6 +2,6 @@
extern crate test;
mod reactive;
//mod reactive;
mod ssr;
mod todomvc;

311
benchmarks/src/reactive.rs
View File

@@ -1,227 +1,40 @@
use std::{cell::Cell, rc::Rc};
use test::Bencher;
#[bench]
fn leptos_deep_creation(b: &mut Bencher) {
use leptos::*;
let runtime = create_runtime();
b.iter(|| {
let signal = create_rw_signal(0);
let mut memos = Vec::<Memo<usize>>::new();
for _ in 0..1000usize {
let prev = memos.last().copied();
if let Some(prev) = prev {
memos.push(create_memo(move |_| prev.get() + 1));
} else {
memos.push(create_memo(move |_| signal.get() + 1));
}
}
});
runtime.dispose();
}
use std::{cell::Cell, rc::Rc};
#[bench]
fn leptos_deep_update(b: &mut Bencher) {
use leptos::*;
let runtime = create_runtime();
fn leptos_create_1000_signals(b: &mut Bencher) {
use leptos::{create_isomorphic_effect, create_memo, create_scope, create_signal};
b.iter(|| {
let signal = create_rw_signal(0);
let mut memos = Vec::<Memo<usize>>::new();
for _ in 0..1000usize {
if let Some(prev) = memos.last().copied() {
memos.push(create_memo(move |_| prev.get() + 1));
} else {
memos.push(create_memo(move |_| signal.get() + 1));
}
}
signal.set(1);
assert_eq!(memos[999].get(), 1001);
});
runtime.dispose();
}
#[bench]
fn leptos_narrowing_down(b: &mut Bencher) {
use leptos::*;
let runtime = create_runtime();
b.iter(|| {
let sigs = (0..1000).map(|n| create_signal(n)).collect::<Vec<_>>();
let reads = sigs.iter().map(|(r, _)| *r).collect::<Vec<_>>();
let writes = sigs.iter().map(|(_, w)| *w).collect::<Vec<_>>();
let memo =
create_memo(move |_| reads.iter().map(|r| r.get()).sum::<i32>());
assert_eq!(memo(), 499500);
});
runtime.dispose();
}
#[bench]
fn leptos_fanning_out(b: &mut Bencher) {
use leptos::*;
let runtime = create_runtime();
b.iter(|| {
let sig = create_rw_signal(0);
let memos = (0..1000)
.map(|_| create_memo(move |_| sig.get()))
.collect::<Vec<_>>();
assert_eq!(memos.iter().map(|m| m.get()).sum::<i32>(), 0);
sig.set(1);
assert_eq!(memos.iter().map(|m| m.get()).sum::<i32>(), 1000);
});
runtime.dispose();
}
#[bench]
fn leptos_narrowing_update(b: &mut Bencher) {
use leptos::*;
let runtime = create_runtime();
b.iter(|| {
let acc = Rc::new(Cell::new(0));
let sigs = (0..1000).map(|n| create_signal(n)).collect::<Vec<_>>();
let reads = sigs.iter().map(|(r, _)| *r).collect::<Vec<_>>();
let writes = sigs.iter().map(|(_, w)| *w).collect::<Vec<_>>();
let memo =
create_memo(move |_| reads.iter().map(|r| r.get()).sum::<i32>());
assert_eq!(memo(), 499500);
create_isomorphic_effect({
let acc = Rc::clone(&acc);
move |_| {
acc.set(memo());
}
});
assert_eq!(acc.get(), 499500);
writes[1].update(|n| *n += 1);
writes[10].update(|n| *n += 1);
writes[100].update(|n| *n += 1);
assert_eq!(acc.get(), 499503);
assert_eq!(memo(), 499503);
});
runtime.dispose();
}
#[bench]
fn l0410_deep_creation(b: &mut Bencher) {
use l0410::*;
let runtime = create_runtime();
b.iter(|| {
create_scope(runtime, |cx| {
let signal = create_rw_signal(cx, 0);
let mut memos = Vec::<Memo<usize>>::new();
for _ in 0..1000usize {
if let Some(prev) = memos.last().copied() {
memos.push(create_memo(cx, move |_| prev.get() + 1));
} else {
memos.push(create_memo(cx, move |_| signal.get() + 1));
}
}
})
.dispose()
});
runtime.dispose();
}
#[bench]
fn l0410_deep_update(b: &mut Bencher) {
use l0410::*;
let runtime = create_runtime();
b.iter(|| {
create_scope(runtime, |cx| {
let signal = create_rw_signal(cx, 0);
let mut memos = Vec::<Memo<usize>>::new();
for _ in 0..1000usize {
if let Some(prev) = memos.last().copied() {
memos.push(create_memo(cx, move |_| prev.get() + 1));
} else {
memos.push(create_memo(cx, move |_| signal.get() + 1));
}
}
signal.set(1);
assert_eq!(memos[999].get(), 1001);
})
.dispose()
});
runtime.dispose();
}
#[bench]
fn l0410_narrowing_down(b: &mut Bencher) {
use l0410::*;
let runtime = create_runtime();
b.iter(|| {
create_scope(runtime, |cx| {
create_scope(|cx| {
let acc = Rc::new(Cell::new(0));
let sigs =
(0..1000).map(|n| create_signal(cx, n)).collect::<Vec<_>>();
let sigs = (0..1000).map(|n| create_signal(cx, n)).collect::<Vec<_>>();
let reads = sigs.iter().map(|(r, _)| *r).collect::<Vec<_>>();
let writes = sigs.iter().map(|(_, w)| *w).collect::<Vec<_>>();
let memo = create_memo(cx, move |_| {
reads.iter().map(|r| r.get()).sum::<i32>()
});
let memo = create_memo(cx, move |_| reads.iter().map(|r| r.get()).sum::<i32>());
assert_eq!(memo(), 499500);
})
.dispose()
});
runtime.dispose();
}
#[bench]
fn l0410_fanning_out(b: &mut Bencher) {
use l0410::*;
let runtime = create_runtime();
fn leptos_create_and_update_1000_signals(b: &mut Bencher) {
use leptos::{create_isomorphic_effect, create_memo, create_scope, create_signal};
b.iter(|| {
create_scope(runtime, |cx| {
let sig = create_rw_signal(cx, 0);
let memos = (0..1000)
.map(|_| create_memo(cx, move |_| sig.get()))
.collect::<Vec<_>>();
assert_eq!(memos.iter().map(|m| m.get()).sum::<i32>(), 0);
sig.set(1);
assert_eq!(memos.iter().map(|m| m.get()).sum::<i32>(), 1000);
})
.dispose()
});
runtime.dispose();
}
#[bench]
fn l0410_narrowing_update(b: &mut Bencher) {
use l0410::*;
let runtime = create_runtime();
b.iter(|| {
create_scope(runtime, |cx| {
create_scope(|cx| {
let acc = Rc::new(Cell::new(0));
let sigs =
(0..1000).map(|n| create_signal(cx, n)).collect::<Vec<_>>();
let sigs = (0..1000).map(|n| create_signal(cx, n)).collect::<Vec<_>>();
let reads = sigs.iter().map(|(r, _)| *r).collect::<Vec<_>>();
let writes = sigs.iter().map(|(_, w)| *w).collect::<Vec<_>>();
let memo = create_memo(cx, move |_| {
reads.iter().map(|r| r.get()).sum::<i32>()
});
assert_eq!(memo.get(), 499500);
let memo = create_memo(cx, move |_| reads.iter().map(|r| r.get()).sum::<i32>());
assert_eq!(memo(), 499500);
create_isomorphic_effect(cx, {
let acc = Rc::clone(&acc);
move |_| {
acc.set(memo.get());
acc.set(memo());
}
});
assert_eq!(acc.get(), 499500);
@@ -231,30 +44,27 @@ fn l0410_narrowing_update(b: &mut Bencher) {
writes[100].update(|n| *n += 1);
assert_eq!(acc.get(), 499503);
assert_eq!(memo.get(), 499503);
assert_eq!(memo(), 499503);
})
.dispose()
});
runtime.dispose();
}
#[bench]
fn l0410_scope_creation_and_disposal(b: &mut Bencher) {
use l0410::*;
let runtime = create_runtime();
fn leptos_create_and_dispose_1000_scopes(b: &mut Bencher) {
use leptos::{create_isomorphic_effect, create_scope, create_signal};
b.iter(|| {
let acc = Rc::new(Cell::new(0));
let disposers = (0..1000)
.map(|_| {
create_scope(runtime, {
create_scope({
let acc = Rc::clone(&acc);
move |cx| {
let (r, w) = create_signal(cx, 0);
create_isomorphic_effect(cx, {
move |_| {
acc.set(r.get());
acc.set(r());
}
});
w.update(|n| *n += 1);
@@ -266,22 +76,16 @@ fn l0410_scope_creation_and_disposal(b: &mut Bencher) {
disposer.dispose();
}
});
runtime.dispose();
}
#[bench]
fn sycamore_narrowing_down(b: &mut Bencher) {
use sycamore::reactive::{
create_effect, create_memo, create_scope, create_signal,
};
fn sycamore_create_1000_signals(b: &mut Bencher) {
use sycamore::reactive::{create_effect, create_memo, create_scope, create_signal};
b.iter(|| {
let d = create_scope(|cx| {
let acc = Rc::new(Cell::new(0));
let sigs = Rc::new(
(0..1000).map(|n| create_signal(cx, n)).collect::<Vec<_>>(),
);
let sigs = Rc::new((0..1000).map(|n| create_signal(cx, n)).collect::<Vec<_>>());
let memo = create_memo(cx, {
let sigs = Rc::clone(&sigs);
move || sigs.iter().map(|r| *r.get()).sum::<i32>()
@@ -293,78 +97,13 @@ fn sycamore_narrowing_down(b: &mut Bencher) {
}
#[bench]
fn sycamore_fanning_out(b: &mut Bencher) {
use sycamore::reactive::{
create_effect, create_memo, create_scope, create_signal,
};
b.iter(|| {
let d = create_scope(|cx| {
let sig = create_signal(cx, 0);
let memos = (0..1000)
.map(|_| create_memo(cx, move || sig.get()))
.collect::<Vec<_>>();
assert_eq!(memos.iter().map(|m| *(*m.get())).sum::<i32>(), 0);
sig.set(1);
assert_eq!(memos.iter().map(|m| *(*m.get())).sum::<i32>(), 1000);
});
unsafe { d.dispose() };
});
}
#[bench]
fn sycamore_deep_creation(b: &mut Bencher) {
use sycamore::reactive::*;
b.iter(|| {
let d = create_scope(|cx| {
let signal = create_signal(cx, 0);
let mut memos = Vec::<&ReadSignal<usize>>::new();
for _ in 0..1000usize {
if let Some(prev) = memos.last().copied() {
memos.push(create_memo(cx, move || *prev.get() + 1));
} else {
memos.push(create_memo(cx, move || *signal.get() + 1));
}
}
});
unsafe { d.dispose() };
});
}
#[bench]
fn sycamore_deep_update(b: &mut Bencher) {
use sycamore::reactive::*;
b.iter(|| {
let d = create_scope(|cx| {
let signal = create_signal(cx, 0);
let mut memos = Vec::<&ReadSignal<usize>>::new();
for _ in 0..1000usize {
if let Some(prev) = memos.last().copied() {
memos.push(create_memo(cx, move || *prev.get() + 1));
} else {
memos.push(create_memo(cx, move || *signal.get() + 1));
}
}
signal.set(1);
assert_eq!(*memos[999].get(), 1001);
});
unsafe { d.dispose() };
});
}
#[bench]
fn sycamore_narrowing_update(b: &mut Bencher) {
use sycamore::reactive::{
create_effect, create_memo, create_scope, create_signal,
};
fn sycamore_create_and_update_1000_signals(b: &mut Bencher) {
use sycamore::reactive::{create_effect, create_memo, create_scope, create_signal};
b.iter(|| {
let d = create_scope(|cx| {
let acc = Rc::new(Cell::new(0));
let sigs = Rc::new(
(0..1000).map(|n| create_signal(cx, n)).collect::<Vec<_>>(),
);
let sigs = Rc::new((0..1000).map(|n| create_signal(cx, n)).collect::<Vec<_>>());
let memo = create_memo(cx, {
let sigs = Rc::clone(&sigs);
move || sigs.iter().map(|r| *r.get()).sum::<i32>()
@@ -390,7 +129,7 @@ fn sycamore_narrowing_update(b: &mut Bencher) {
}
#[bench]
fn sycamore_scope_creation_and_disposal(b: &mut Bencher) {
fn sycamore_create_and_dispose_1000_scopes(b: &mut Bencher) {
use sycamore::reactive::{create_effect, create_scope, create_signal};
b.iter(|| {

58
benchmarks/src/ssr.rs
View File

@@ -2,14 +2,15 @@ use test::Bencher;
#[bench]
fn leptos_ssr_bench(b: &mut Bencher) {
use leptos::*;
let r = create_runtime();
b.iter(|| {
leptos::leptos_dom::HydrationCtx::reset_id();
use leptos::*;
HydrationCtx::reset_id();
_ = create_scope(create_runtime(), |cx| {
#[component]
fn Counter(initial: i32) -> impl IntoView {
let (value, set_value) = create_signal(initial);
fn Counter(cx: Scope, initial: i32) -> impl IntoView {
let (value, set_value) = create_signal(cx, initial);
view! {
cx,
<div>
<button on:click=move |_| set_value.update(|value| *value -= 1)>"-1"</button>
<span>"Value: " {move || value().to_string()} "!"</span>
@@ -19,6 +20,7 @@ fn leptos_ssr_bench(b: &mut Bencher) {
}
let rendered = view! {
cx,
<main>
<h1>"Welcome to our benchmark page."</h1>
<p>"Here's some introductory text."</p>
@@ -26,53 +28,13 @@ fn leptos_ssr_bench(b: &mut Bencher) {
<Counter initial=2/>
<Counter initial=3/>
</main>
}.into_view().render_to_string();
}.into_view(cx).render_to_string(cx);
assert_eq!(
rendered,
"<main data-hk=\"0-0-0-1\"><h1 data-hk=\"0-0-0-2\">Welcome to our benchmark page.</h1><p data-hk=\"0-0-0-3\">Here&#x27;s some introductory text.</p><div data-hk=\"0-0-0-5\"><button data-hk=\"0-0-0-6\">-1</button><span data-hk=\"0-0-0-7\">Value: <!>1<!--hk=0-0-0-8-->!</span><button data-hk=\"0-0-0-9\">+1</button></div><!--hk=0-0-0-4--><div data-hk=\"0-0-0-11\"><button data-hk=\"0-0-0-12\">-1</button><span data-hk=\"0-0-0-13\">Value: <!>2<!--hk=0-0-0-14-->!</span><button data-hk=\"0-0-0-15\">+1</button></div><!--hk=0-0-0-10--><div data-hk=\"0-0-0-17\"><button data-hk=\"0-0-0-18\">-1</button><span data-hk=\"0-0-0-19\">Value: <!>3<!--hk=0-0-0-20-->!</span><button data-hk=\"0-0-0-21\">+1</button></div><!--hk=0-0-0-16--></main>" );
"<main id=\"_0-1\"><h1 id=\"_0-2\">Welcome to our benchmark page.</h1><p id=\"_0-3\">Here's some introductory text.</p><div id=\"_0-3-1\"><button id=\"_0-3-2\">-1</button><span id=\"_0-3-3\">Value: <!>1<!--hk=_0-3-4-->!</span><button id=\"_0-3-5\">+1</button></div><!--hk=_0-3-0--><div id=\"_0-3-5-1\"><button id=\"_0-3-5-2\">-1</button><span id=\"_0-3-5-3\">Value: <!>2<!--hk=_0-3-5-4-->!</span><button id=\"_0-3-5-5\">+1</button></div><!--hk=_0-3-5-0--><div id=\"_0-3-5-5-1\"><button id=\"_0-3-5-5-2\">-1</button><span id=\"_0-3-5-5-3\">Value: <!>3<!--hk=_0-3-5-5-4-->!</span><button id=\"_0-3-5-5-5\">+1</button></div><!--hk=_0-3-5-5-0--></main>" );
});
});
r.dispose();
}
#[bench]
fn tachys_ssr_bench(b: &mut Bencher) {
use leptos::{create_runtime, create_signal, SignalGet, SignalUpdate};
use tachy_maccy::view;
use tachydom::view::{Render, RenderHtml};
use tachydom::html::element::ElementChild;
use tachydom::html::attribute::global::ClassAttribute;
use tachydom::html::attribute::global::GlobalAttributes;
use tachydom::html::attribute::global::OnAttribute;
use tachydom::renderer::dom::Dom;
let rt = create_runtime();
b.iter(|| {
fn counter(initial: i32) -> impl Render<Dom> + RenderHtml<Dom> {
let (value, set_value) = create_signal(initial);
view! {
<div>
<button on:click=move |_| set_value.update(|value| *value -= 1)>"-1"</button>
<span>"Value: " {move || value().to_string()} "!"</span>
<button on:click=move |_| set_value.update(|value| *value += 1)>"+1"</button>
</div>
}
}
let rendered = view! {
<main>
<h1>"Welcome to our benchmark page."</h1>
<p>"Here's some introductory text."</p>
{counter(1)}
{counter(2)}
{counter(3)}
</main>
}.to_html();
assert_eq!(
rendered,
"<main><h1>Welcome to our benchmark page.</h1><p>Here's some introductory text.</p><div><button>-1</button><span>Value: <!>1<!>!</span><button>+1</button></div><div><button>-1</button><span>Value: <!>2<!>!</span><button>+1</button></div><div><button>-1</button><span>Value: <!>3<!>!</span><button>+1</button></div></main>"
);
});
rt.dispose();
}
#[bench]

238
benchmarks/src/todomvc/leptos.rs
View File

@@ -1,6 +1,5 @@
pub use leptos::*;
use miniserde::*;
use wasm_bindgen::JsCast;
use web_sys::HtmlInputElement;
#[derive(Debug, Clone, PartialEq, Eq)]
@@ -9,13 +8,13 @@ pub struct Todos(pub Vec<Todo>);
const STORAGE_KEY: &str = "todos-leptos";
impl Todos {
pub fn new() -> Self {
pub fn new(cx: Scope) -> Self {
Self(vec![])
}
pub fn new_with_1000() -> Self {
pub fn new_with_1000(cx: Scope) -> Self {
let todos = (0..1000)
.map(|id| Todo::new(id, format!("Todo #{id}")))
.map(|id| Todo::new(cx, id, format!("Todo #{id}")))
.collect();
Self(todos)
}
@@ -72,17 +71,13 @@ pub struct Todo {
}
impl Todo {
pub fn new(id: usize, title: String) -> Self {
Self::new_with_completed(id, title, false)
pub fn new(cx: Scope, id: usize, title: String) -> Self {
Self::new_with_completed(cx, id, title, false)
}
pub fn new_with_completed(
id: usize,
title: String,
completed: bool,
) -> Self {
let (title, set_title) = create_signal(title);
let (completed, set_completed) = create_signal(completed);
pub fn new_with_completed(cx: Scope, id: usize, title: String, completed: bool) -> Self {
let (title, set_title) = create_signal(cx, title);
let (completed, set_completed) = create_signal(cx, completed);
Self {
id,
title,
@@ -102,7 +97,7 @@ const ESCAPE_KEY: u32 = 27;
const ENTER_KEY: u32 = 13;
#[component]
pub fn TodoMVC(todos: Todos) -> impl IntoView {
pub fn TodoMVC(cx: Scope, todos: Todos) -> impl IntoView {
let mut next_id = todos
.0
.iter()
@@ -111,10 +106,14 @@ pub fn TodoMVC(todos: Todos) -> impl IntoView {
.map(|last| last + 1)
.unwrap_or(0);
let (todos, set_todos) = create_signal(todos);
provide_context(set_todos);
let (todos, set_todos) = create_signal(cx, todos);
provide_context(cx, set_todos);
let (mode, set_mode) = create_signal(Mode::All);
let (mode, set_mode) = create_signal(cx, Mode::All);
window_event_listener("hashchange", move |_| {
let new_mode = location_hash().map(|hash| route(&hash)).unwrap_or_default();
set_mode(new_mode);
});
let add_todo = move |ev: web_sys::KeyboardEvent| {
let target = event_target::<HtmlInputElement>(&ev);
@@ -124,7 +123,7 @@ pub fn TodoMVC(todos: Todos) -> impl IntoView {
let title = event_target_value(&ev);
let title = title.trim();
if !title.is_empty() {
let new = Todo::new(next_id, title.to_string());
let new = Todo::new(cx, next_id, title.to_string());
set_todos.update(|t| t.add(new));
next_id += 1;
target.set_value("");
@@ -132,7 +131,7 @@ pub fn TodoMVC(todos: Todos) -> impl IntoView {
}
};
let filtered_todos = create_memo::<Vec<Todo>>(move |_| {
let filtered_todos = create_memo::<Vec<Todo>>(cx, move |_| {
todos.with(|todos| match mode.get() {
Mode::All => todos.0.to_vec(),
Mode::Active => todos
@@ -152,7 +151,7 @@ pub fn TodoMVC(todos: Todos) -> impl IntoView {
// effect to serialize to JSON
// this does reactive reads, so it will automatically serialize on any relevant change
create_effect(move |_| {
create_effect(cx, move |_| {
if let Ok(Some(storage)) = window().local_storage() {
let objs = todos
.get()
@@ -167,87 +166,65 @@ pub fn TodoMVC(todos: Todos) -> impl IntoView {
}
});
view! {
<main>
<section class="todoapp">
<header class="header">
<h1>"todos"</h1>
<input
class="new-todo"
placeholder="What needs to be done?"
autofocus=""
on:keydown=add_todo
/>
</header>
<section class="main" class:hidden=move || todos.with(|t| t.is_empty())>
<input
id="toggle-all"
class="toggle-all"
type="checkbox"
prop:checked=move || todos.with(|t| t.remaining() > 0)
on:input=move |_| set_todos.update(|t| t.toggle_all())
/>
<label for="toggle-all">"Mark all as complete"</label>
<ul class="todo-list">
<For
each=filtered_todos
key=|todo| todo.id
children=move |todo: Todo| {
view! { <Todo todo=todo.clone()/> }
}
/>
</ul>
</section>
<footer class="footer" class:hidden=move || todos.with(|t| t.is_empty())>
<span class="todo-count">
<strong>{move || todos.with(|t| t.remaining().to_string())}</strong>
{move || if todos.with(|t| t.remaining()) == 1 { " item" } else { " items" }}
" left"
</span>
<ul class="filters">
<li>
<a
href="#/"
class="selected"
class:selected=move || mode() == Mode::All
>
"All"
</a>
</li>
<li>
<a href="#/active" class:selected=move || mode() == Mode::Active>
"Active"
</a>
</li>
<li>
<a href="#/completed" class:selected=move || mode() == Mode::Completed>
"Completed"
</a>
</li>
</ul>
<button
class="clear-completed hidden"
class:hidden=move || todos.with(|t| t.completed() == 0)
on:click=move |_| set_todos.update(|t| t.clear_completed())
>
"Clear completed"
</button>
</footer>
</section>
<footer class="info">
<p>"Double-click to edit a todo"</p>
<p>"Created by " <a href="http://todomvc.com">"Greg Johnston"</a></p>
<p>"Part of " <a href="http://todomvc.com">"TodoMVC"</a></p>
</footer>
</main>
}.into_view()
view! { cx,
<main>
<section class="todoapp">
<header class="header">
<h1>"todos"</h1>
<input class="new-todo" placeholder="What needs to be done?" autofocus="" on:keydown=add_todo />
</header>
<section class="main" class:hidden={move || todos.with(|t| t.is_empty())}>
<input id="toggle-all" class="toggle-all" type="checkbox"
prop:checked={move || todos.with(|t| t.remaining() > 0)}
on:input=move |_| set_todos.update(|t| t.toggle_all())
/>
<label for="toggle-all">"Mark all as complete"</label>
<ul class="todo-list">
<For
each=filtered_todos
key=|todo| todo.id
view=move |todo: Todo| view! { cx, <Todo todo=todo.clone() /> }
/>
</ul>
</section>
<footer class="footer" class:hidden={move || todos.with(|t| t.is_empty())}>
<span class="todo-count">
<strong>{move || todos.with(|t| t.remaining().to_string())}</strong>
{move || if todos.with(|t| t.remaining()) == 1 {
" item"
} else {
" items"
}}
" left"
</span>
<ul class="filters">
<li><a href="#/" class="selected" class:selected={move || mode() == Mode::All}>"All"</a></li>
<li><a href="#/active" class:selected={move || mode() == Mode::Active}>"Active"</a></li>
<li><a href="#/completed" class:selected={move || mode() == Mode::Completed}>"Completed"</a></li>
</ul>
<button
class="clear-completed hidden"
class:hidden={move || todos.with(|t| t.completed() == 0)}
on:click=move |_| set_todos.update(|t| t.clear_completed())
>
"Clear completed"
</button>
</footer>
</section>
<footer class="info">
<p>"Double-click to edit a todo"</p>
<p>"Created by "<a href="http://todomvc.com">"Greg Johnston"</a></p>
<p>"Part of "<a href="http://todomvc.com">"TodoMVC"</a></p>
</footer>
</main>
}.into_view(cx)
}
#[component]
pub fn Todo(todo: Todo) -> impl IntoView {
let (editing, set_editing) = create_signal(false);
let set_todos = use_context::<WriteSignal<Todos>>().unwrap();
//let input = NodeRef::new();
pub fn Todo(cx: Scope, todo: Todo) -> impl IntoView {
let (editing, set_editing) = create_signal(cx, false);
let set_todos = use_context::<WriteSignal<Todos>>(cx).unwrap();
//let input = NodeRef::new(cx);
let save = move |value: &str| {
let value = value.trim();
@@ -259,37 +236,42 @@ pub fn Todo(todo: Todo) -> impl IntoView {
set_editing(false);
};
view! {
<li class="todo" class:editing=editing class:completed=move || (todo.completed)()>
view! { cx,
<li
class="todo"
class:editing={editing}
class:completed={move || (todo.completed)()}
//_ref=input
>
<div class="view">
<input class="toggle" type="checkbox" prop:checked=move || (todo.completed)()/>
<label on:dblclick=move |_| set_editing(true)>{move || todo.title.get()}</label>
<button
class="destroy"
on:click=move |_| set_todos.update(|t| t.remove(todo.id))
></button>
<input
class="toggle"
type="checkbox"
prop:checked={move || (todo.completed)()}
/>
<label on:dblclick=move |_| set_editing(true)>
{move || todo.title.get()}
</label>
<button class="destroy" on:click=move |_| set_todos.update(|t| t.remove(todo.id))/>
</div>
{move || {
editing()
.then(|| {
view! {
<input
class="edit"
class:hidden=move || !(editing)()
prop:value=move || todo.title.get()
on:focusout=move |ev| save(&event_target_value(&ev))
on:keyup=move |ev| {
let key_code = ev.unchecked_ref::<web_sys::KeyboardEvent>().key_code();
if key_code == ENTER_KEY {
save(&event_target_value(&ev));
} else if key_code == ESCAPE_KEY {
set_editing(false);
}
}
/>
{move || editing().then(|| view! { cx,
<input
class="edit"
class:hidden={move || !(editing)()}
prop:value={move || todo.title.get()}
on:focusout=move |ev| save(&event_target_value(&ev))
on:keyup={move |ev| {
let key_code = ev.unchecked_ref::<web_sys::KeyboardEvent>().key_code();
if key_code == ENTER_KEY {
save(&event_target_value(&ev));
} else if key_code == ESCAPE_KEY {
set_editing(false);
}
})
}}
}}
/>
})
}
</li>
}
}
@@ -323,8 +305,8 @@ pub struct TodoSerialized {
}
impl TodoSerialized {
pub fn into_todo(self, ) -> Todo {
Todo::new_with_completed(self.id, self.title, self.completed)
pub fn into_todo(self, cx: Scope) -> Todo {
Todo::new_with_completed(cx, self.id, self.title, self.completed)
}
}

88
benchmarks/src/todomvc/mod.rs
View File

@@ -2,45 +2,32 @@ use test::Bencher;
mod leptos;
mod sycamore;
mod tachys;
mod tera;
mod yew;
#[bench]
fn leptos_todomvc_ssr(b: &mut Bencher) {
use ::leptos::*;
let runtime = create_runtime();
b.iter(|| {
use crate::todomvc::leptos::*;
let html = ::leptos::ssr::render_to_string(|| {
view! { <TodoMVC todos=Todos::new()/> }
_ = create_scope(create_runtime(), |cx| {
let rendered = view! {
cx,
<TodoMVC todos=Todos::new(cx)/>
}
.into_view(cx)
.render_to_string(cx);
assert!(rendered.len() > 1);
});
assert!(html.len() > 1);
});
runtime.dispose();
}
#[bench]
fn tachys_todomvc_ssr(b: &mut Bencher) {
use ::leptos::*;
let runtime = create_runtime();
b.iter(|| {
use crate::todomvc::tachys::*;
use tachydom::view::{Render, RenderHtml};
let rendered = TodoMVC(Todos::new()).to_html();
assert_eq!(
rendered,
"<main><section class=\"todoapp\"><header class=\"header\"><h1>todos</h1><input placeholder=\"What needs to be done?\" autofocus class=\"new-todo\"></header><section class=\"main hidden\"><input id=\"toggle-all\" type=\"checkbox\" class=\"toggle-all\"><label for=\"toggle-all\">Mark all as complete</label><ul class=\"todo-list\"></ul></section><footer class=\"footer hidden\"><span class=\"todo-count\"><strong>0</strong><!> items<!> left</span><ul class=\"filters\"><li><a href=\"#/\" class=\"selected selected\">All</a></li><li><a href=\"#/active\" class=\"\">Active</a></li><li><a href=\"#/completed\" class=\"\">Completed</a></li></ul><button class=\"clear-completed hidden hidden\">Clear completed</button></footer></section><footer class=\"info\"><p>Double-click to edit a todo</p><p>Created by <a href=\"http://todomvc.com\">Greg Johnston</a></p><p>Part of <a href=\"http://todomvc.com\">TodoMVC</a></p></footer></main>" );
});
runtime.dispose();
}
#[bench]
fn sycamore_todomvc_ssr(b: &mut Bencher) {
use self::sycamore::*;
use ::sycamore::{prelude::*, *};
use ::sycamore::prelude::*;
use ::sycamore::*;
b.iter(|| {
_ = create_scope(|cx| {
@@ -59,7 +46,8 @@ fn sycamore_todomvc_ssr(b: &mut Bencher) {
#[bench]
fn yew_todomvc_ssr(b: &mut Bencher) {
use self::yew::*;
use ::yew::{prelude::*, ServerRenderer};
use ::yew::prelude::*;
use ::yew::ServerRenderer;
b.iter(|| {
tokio_test::block_on(async {
@@ -69,40 +57,29 @@ fn yew_todomvc_ssr(b: &mut Bencher) {
});
});
}
/*
#[bench]
fn leptos_todomvc_ssr_with_1000(b: &mut Bencher) {
b.iter(|| {
use self::leptos::*;
use ::leptos::*;
let html = ::leptos::ssr::render_to_string(|| {
view! {
<TodoMVC todos=Todos::new_with_1000()/>
}
_ = create_scope(create_runtime(), |cx| {
let rendered = view! {
cx,
<TodoMVC todos=Todos::new_with_1000(cx)/>
}.into_view(cx).render_to_string(cx);
assert!(rendered.len() > 1);
});
assert!(html.len() > 1);
});
}
#[bench]
fn tachys_todomvc_ssr_with_1000(b: &mut Bencher) {
use ::leptos::*;
let runtime = create_runtime();
b.iter(|| {
use crate::todomvc::tachys::*;
use tachydom::view::{Render, RenderHtml};
let rendered = TodoMVC(Todos::new_with_1000()).to_html();
assert!(rendered.len() > 20_000)
});
runtime.dispose();
}
#[bench]
fn sycamore_todomvc_ssr_with_1000(b: &mut Bencher) {
use self::sycamore::*;
use ::sycamore::{prelude::*, *};
use ::sycamore::prelude::*;
use ::sycamore::*;
b.iter(|| {
_ = create_scope(|cx| {
@@ -121,7 +98,8 @@ fn sycamore_todomvc_ssr_with_1000(b: &mut Bencher) {
#[bench]
fn yew_todomvc_ssr_with_1000(b: &mut Bencher) {
use self::yew::*;
use ::yew::{prelude::*, ServerRenderer};
use ::yew::prelude::*;
use ::yew::ServerRenderer;
b.iter(|| {
tokio_test::block_on(async {
@@ -131,18 +109,4 @@ fn yew_todomvc_ssr_with_1000(b: &mut Bencher) {
});
});
}
#[bench]
fn tera_todomvc_ssr(b: &mut Bencher) {
use ::leptos::*;
let runtime = create_runtime();
b.iter(|| {
use crate::todomvc::leptos::*;
let html = ::leptos::ssr::render_to_string(|| {
view! { <TodoMVC todos=Todos::new()/> }
});
assert!(html.len() > 1);
});
runtime.dispose();
}
*/

333
benchmarks/src/todomvc/tachys.rs
View File

@@ -1,333 +0,0 @@
pub use leptos_reactive::*;
use miniserde::*;
use tachy_maccy::view;
use tachydom::{
html::{
attribute::global::{ClassAttribute, GlobalAttributes, OnAttribute},
element::ElementChild,
},
renderer::dom::Dom,
view::{keyed::keyed, Render, RenderHtml},
};
use wasm_bindgen::JsCast;
use web_sys::HtmlInputElement;
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct Todos(pub Vec<Todo>);
const STORAGE_KEY: &str = "todos-leptos";
impl Todos {
pub fn new() -> Self {
Self(vec![])
}
pub fn new_with_1000() -> Self {
let todos = (0..1000)
.map(|id| Todo::new(id, format!("Todo #{id}")))
.collect();
Self(todos)
}
pub fn is_empty(&self) -> bool {
self.0.is_empty()
}
pub fn add(&mut self, todo: Todo) {
self.0.push(todo);
}
pub fn remove(&mut self, id: usize) {
self.0.retain(|todo| todo.id != id);
}
pub fn remaining(&self) -> usize {
self.0.iter().filter(|todo| !(todo.completed)()).count()
}
pub fn completed(&self) -> usize {
self.0.iter().filter(|todo| (todo.completed)()).count()
}
pub fn toggle_all(&self) {
// if all are complete, mark them all active instead
if self.remaining() == 0 {
for todo in &self.0 {
if todo.completed.get() {
(todo.set_completed)(false);
}
}
}
// otherwise, mark them all complete
else {
for todo in &self.0 {
(todo.set_completed)(true);
}
}
}
fn clear_completed(&mut self) {
self.0.retain(|todo| !todo.completed.get());
}
}
#[derive(Debug, PartialEq, Eq, Clone)]
pub struct Todo {
pub id: usize,
pub title: ReadSignal<String>,
pub set_title: WriteSignal<String>,
pub completed: ReadSignal<bool>,
pub set_completed: WriteSignal<bool>,
}
impl Todo {
pub fn new(id: usize, title: String) -> Self {
Self::new_with_completed(id, title, false)
}
pub fn new_with_completed(
id: usize,
title: String,
completed: bool,
) -> Self {
let (title, set_title) = create_signal(title);
let (completed, set_completed) = create_signal(completed);
Self {
id,
title,
set_title,
completed,
set_completed,
}
}
pub fn toggle(&self) {
self.set_completed
.update(|completed| *completed = !*completed);
}
}
const ESCAPE_KEY: u32 = 27;
const ENTER_KEY: u32 = 13;
pub fn TodoMVC(todos: Todos) -> impl Render<Dom> + RenderHtml<Dom> {
let mut next_id = todos
.0
.iter()
.map(|todo| todo.id)
.max()
.map(|last| last + 1)
.unwrap_or(0);
let (todos, set_todos) = create_signal(todos);
provide_context(set_todos);
let (mode, set_mode) = create_signal(Mode::All);
let add_todo = move |ev: web_sys::KeyboardEvent| {
todo!()
/* let target = event_target::<HtmlInputElement>(&ev);
ev.stop_propagation();
let key_code = ev.unchecked_ref::<web_sys::KeyboardEvent>().key_code();
if key_code == ENTER_KEY {
let title = event_target_value(&ev);
let title = title.trim();
if !title.is_empty() {
let new = Todo::new(next_id, title.to_string());
set_todos.update(|t| t.add(new));
next_id += 1;
target.set_value("");
}
} */
};
let filtered_todos = create_memo::<Vec<Todo>>(move |_| {
todos.with(|todos| match mode.get() {
Mode::All => todos.0.to_vec(),
Mode::Active => todos
.0
.iter()
.filter(|todo| !todo.completed.get())
.cloned()
.collect(),
Mode::Completed => todos
.0
.iter()
.filter(|todo| todo.completed.get())
.cloned()
.collect(),
})
});
// effect to serialize to JSON
// this does reactive reads, so it will automatically serialize on any relevant change
create_effect(move |_| {
()
/* if let Ok(Some(storage)) = window().local_storage() {
let objs = todos
.get()
.0
.iter()
.map(TodoSerialized::from)
.collect::<Vec<_>>();
let json = json::to_string(&objs);
if storage.set_item(STORAGE_KEY, &json).is_err() {
log::error!("error while trying to set item in localStorage");
}
} */
});
view! {
<main>
<section class="todoapp">
<header class="header">
<h1>"todos"</h1>
<input
class="new-todo"
placeholder="What needs to be done?"
autofocus
/>
</header>
<section class="main" class:hidden=move || todos.with(|t| t.is_empty())>
<input
id="toggle-all"
class="toggle-all"
r#type="checkbox"
//prop:checked=move || todos.with(|t| t.remaining() > 0)
on:input=move |_| set_todos.update(|t| t.toggle_all())
/>
<label r#for="toggle-all">"Mark all as complete"</label>
<ul class="todo-list">
{move || {
keyed(filtered_todos.get(), |todo| todo.id, Todo)
}}
</ul>
</section>
<footer class="footer" class:hidden=move || todos.with(|t| t.is_empty())>
<span class="todo-count">
<strong>{move || todos.with(|t| t.remaining().to_string())}</strong>
{move || if todos.with(|t| t.remaining()) == 1 { " item" } else { " items" }}
" left"
</span>
<ul class="filters">
<li>
<a
href="#/"
class="selected"
class:selected=move || mode() == Mode::All
>
"All"
</a>
</li>
<li>
<a href="#/active" class:selected=move || mode() == Mode::Active>
"Active"
</a>
</li>
<li>
<a href="#/completed" class:selected=move || mode() == Mode::Completed>
"Completed"
</a>
</li>
</ul>
<button
class="clear-completed hidden"
class:hidden=move || todos.with(|t| t.completed() == 0)
on:click=move |_| set_todos.update(|t| t.clear_completed())
>
"Clear completed"
</button>
</footer>
</section>
<footer class="info">
<p>"Double-click to edit a todo"</p>
<p>"Created by " <a href="http://todomvc.com">"Greg Johnston"</a></p>
<p>"Part of " <a href="http://todomvc.com">"TodoMVC"</a></p>
</footer>
</main>
}
}
pub fn Todo(todo: Todo) -> impl Render<Dom> + RenderHtml<Dom> {
let (editing, set_editing) = create_signal(false);
let set_todos = use_context::<WriteSignal<Todos>>().unwrap();
//let input = NodeRef::new();
let save = move |value: &str| {
let value = value.trim();
if value.is_empty() {
set_todos.update(|t| t.remove(todo.id));
} else {
(todo.set_title)(value.to_string());
}
set_editing(false);
};
view! {
<li class="todo" class:editing=editing class:completed=move || (todo.completed)()>
/* <div class="view">
<input class="toggle" r#type="checkbox"/>
<label on:dblclick=move |_| set_editing(true)>{move || todo.title.get()}</label>
<button
class="destroy"
on:click=move |_| set_todos.update(|t| t.remove(todo.id))
></button>
</div>
{move || {
editing()
.then(|| {
view! {
<input
class="edit"
class:hidden=move || !(editing)()
/>
}
})
}} */
</li>
}
}
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
pub enum Mode {
Active,
Completed,
All,
}
impl Default for Mode {
fn default() -> Self {
Mode::All
}
}
pub fn route(hash: &str) -> Mode {
match hash {
"/active" => Mode::Active,
"/completed" => Mode::Completed,
_ => Mode::All,
}
}
#[derive(Serialize, Deserialize)]
pub struct TodoSerialized {
pub id: usize,
pub title: String,
pub completed: bool,
}
impl TodoSerialized {
pub fn into_todo(self) -> Todo {
Todo::new_with_completed(self.id, self.title, self.completed)
}
}
impl From<&Todo> for TodoSerialized {
fn from(todo: &Todo) -> Self {
Self {
id: todo.id,
title: todo.title.get(),
completed: (todo.completed)(),
}
}
}

4
benchmarks/src/todomvc/tera.rs
View File

@@ -87,7 +87,7 @@ static TEMPLATE: &str = r#"<main>
</main>"#;
#[bench]
fn tera_todomvc_ssr(b: &mut Bencher) {
fn tera_todomvc(b: &mut Bencher) {
use serde::{Deserialize, Serialize};
use tera::*;
@@ -127,7 +127,7 @@ fn tera_todomvc_ssr(b: &mut Bencher) {
}
#[bench]
fn tera_todomvc_ssr_1000(b: &mut Bencher) {
fn tera_todomvc_1000(b: &mut Bencher) {
use serde::{Deserialize, Serialize};
use tera::*;

7
cargo-make/check.toml
View File

@@ -1,7 +0,0 @@
[tasks.check]
alias = "check-all"
[tasks.check-all]
command = "cargo"
args = ["+nightly", "check-all-features"]
install_crate = "cargo-all-features"

11
cargo-make/lint.toml
View File

@@ -1,11 +0,0 @@
[tasks.lint]
dependencies = ["check-format-flow", "clippy-each-feature"]
[tasks.check-format]
env = { LEPTOS_PROJECT_DIRECTORY = "../" }
args = ["fmt", "--", "--check", "--config-path", "${LEPTOS_PROJECT_DIRECTORY}"]
[tasks.clippy-each-feature]
dependencies = ["install-clippy"]
command = "cargo"
args = ["hack", "clippy", "--all", "--each-feature", "--no-dev-deps"]

15
cargo-make/main.toml
View File

@@ -1,15 +0,0 @@
extend = [
{ path = "./check.toml" },
{ path = "./lint.toml" },
{ path = "./test.toml" },
]
[env]
RUSTFLAGS = ""
LEPTOS_OUTPUT_NAME = "ci" # allows examples to check/build without cargo-leptos
[env.github-actions]
RUSTFLAGS = "-D warnings"
[tasks.ci]
dependencies = ["lint", "test"]

7
cargo-make/test.toml
View File

@@ -1,7 +0,0 @@
[tasks.test]
alias = "test-all"
[tasks.test-all]
command = "cargo"
args = ["+nightly", "test-all-features"]
install_crate = "cargo-all-features"

78
docs/COMMON_BUGS.md
View File

@@ -9,10 +9,10 @@ This document is intended as a running list of common issues, with example code
**Issue**: Sometimes you want to update a reactive signal in a way that depends on another signal.
```rust
let (a, set_a) = create_signal(0);
let (b, set_b) = create_signal(false);
let (a, set_a) = create_signal(cx, 0);
let (b, set_b) = create_signal(cx, false);
create_effect(move |_| {
create_effect(cx, move |_| {
if a() > 5 {
set_b(true);
}
@@ -24,56 +24,10 @@ This creates an inefficient chain of updates, and can easily lead to infinite lo
**Solution**: Follow the rule, _What can be derived, should be derived._ In this case, this has the benefit of massively reducing the code size, too!
```rust
let (a, set_a) = create_signal(0);
let (a, set_a) = create_signal(cx, 0);
let b = move || a () > 5;
```
### Nested signal updates/reads triggering panic
Sometimes you have nested signals: for example, hash-map that can change over time, each of whose values can also change over time:
```rust
#[component]
pub fn App() -> impl IntoView {
let resources = create_rw_signal(HashMap::new());
let update = move |id: usize| {
resources.update(|resources| {
resources
.entry(id)
.or_insert_with(|| create_rw_signal(0))
.update(|amount| *amount += 1)
})
};
view! {
<div>
<pre>{move || format!("{:#?}", resources.get().into_iter().map(|(id, resource)| (id, resource.get())).collect::<Vec<_>>())}</pre>
<button on:click=move |_| update(1)>"+"</button>
</div>
}
}
```
Clicking the button twice will cause a panic, because of the nested signal _read_. Calling the `update` function on `resources` immediately takes out a mutable borrow on `resources`, then updates the `resource` signal—which re-runs the effect that reads from the signals, which tries to immutably access `resources` and panics. It's the nested update here which causes a problem, because the inner update triggers and effect that tries to read both signals while the outer is still updating.
You can fix this fairly easily by using the [`batch()`](https://docs.rs/leptos/latest/leptos/fn.batch.html) method:
```rust
let update = move |id: usize| {
batch(move || {
resources.update(|resources| {
resources
.entry(id)
.or_insert_with(|| create_rw_signal(0))
.update(|amount| *amount += 1)
})
});
};
```
This delays running any effects until after both updates are made, preventing the conflict entirely without requiring any other restructuring.
## Templates and the DOM
### `<input value=...>` doesn't update or stops updating
@@ -83,11 +37,11 @@ Many DOM attributes can be updated either by setting an attribute on the DOM nod
This means that in practice, attributes like `value` or `checked` on an `<input/>` element only update the _default_ value for the `<input/>`. If you want to reactively update the value, you should use `prop:value` instead to set the `value` property.
```rust
let (a, set_a) = create_signal("Starting value".to_string());
let (a, set_a) = create_signal(cx, "Starting value".to_string());
let on_input = move |ev| set_a(event_target_value(&ev));
view! {
cx,
// ❌ reactivity doesn't work as expected: typing only updates the default
// of each input, so if you start typing in the second input, it won't
// update the first one
@@ -97,29 +51,13 @@ view! {
```
```rust
let (a, set_a) = create_signal("Starting value".to_string());
let (a, set_a) = create_signal(cx, "Starting value".to_string());
let on_input = move |ev| set_a(event_target_value(&ev));
view! {
cx,
// ✅ works as intended by setting the value *property*
<input prop:value=a on:input=on_input />
<input prop:value=a on:input=on_input />
}
```
## Build configuration
### Cargo feature resolution in workspaces
A new [version](https://doc.rust-lang.org/cargo/reference/resolver.html#resolver-versions) of Cargo's feature resolver was introduced for the 2021 edition of Rust.
For single crate projects it will select a resolver version based on the Rust edition in `Cargo.toml`. As there is no Rust edition present for `Cargo.toml` in a workspace, Cargo will default to the pre 2021 edition resolver.
This can cause issues resulting in non WASM compatible code being built for a WASM target. Seeing `mio` failing to build is often a sign that none WASM compatible code is being included in the build.
The resolver version can be set in the workspace `Cargo.toml` to remedy this issue.
```toml
[workspace]
members = ["member1", "member2"]
resolver = "2"
```

15
docs/book/README.md
View File

@@ -1,3 +1,14 @@
The Leptos book is now available at [https://book.leptos.dev](https://book.leptos.dev).
This project contains the core of a new introductory guide to Leptos.
The source code for the book has moved to [https://github.com/leptos-rs/book](https://github.com/leptos-rs/book). Please open issues or make PRs in that repository.
It is built using `mdbook`. You can view a local copy by installing `mdbook`
```bash
cargo install mdbook
```
and run the book with
```
mdbook serve
```
It should be available at `http://localhost:3000`.

10
docs/book/book.toml
View File

@@ -1,10 +0,0 @@
[output.html]
additional-css = ["./mdbook-admonish.css"]
[output.html.playground]
runnable = false
[preprocessor]
[preprocessor.admonish]
command = "mdbook-admonish"
assets_version = "3.0.1" # do not edit: managed by `mdbook-admonish install`

345
docs/book/mdbook-admonish.css
View File

@@ -1,345 +0,0 @@
@charset "UTF-8";
:root {
--md-admonition-icon--admonish-note: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M20.71 7.04c.39-.39.39-1.04 0-1.41l-2.34-2.34c-.37-.39-1.02-.39-1.41 0l-1.84 1.83 3.75 3.75M3 17.25V21h3.75L17.81 9.93l-3.75-3.75L3 17.25z'/></svg>");
--md-admonition-icon--admonish-abstract: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M17 9H7V7h10m0 6H7v-2h10m-3 6H7v-2h7M12 3a1 1 0 0 1 1 1 1 1 0 0 1-1 1 1 1 0 0 1-1-1 1 1 0 0 1 1-1m7 0h-4.18C14.4 1.84 13.3 1 12 1c-1.3 0-2.4.84-2.82 2H5a2 2 0 0 0-2 2v14a2 2 0 0 0 2 2h14a2 2 0 0 0 2-2V5a2 2 0 0 0-2-2z'/></svg>");
--md-admonition-icon--admonish-info: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M13 9h-2V7h2m0 10h-2v-6h2m-1-9A10 10 0 0 0 2 12a10 10 0 0 0 10 10 10 10 0 0 0 10-10A10 10 0 0 0 12 2z'/></svg>");
--md-admonition-icon--admonish-tip: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M17.66 11.2c-.23-.3-.51-.56-.77-.82-.67-.6-1.43-1.03-2.07-1.66C13.33 7.26 13 4.85 13.95 3c-.95.23-1.78.75-2.49 1.32-2.59 2.08-3.61 5.75-2.39 8.9.04.1.08.2.08.33 0 .22-.15.42-.35.5-.23.1-.47.04-.66-.12a.58.58 0 0 1-.14-.17c-1.13-1.43-1.31-3.48-.55-5.12C5.78 10 4.87 12.3 5 14.47c.06.5.12 1 .29 1.5.14.6.41 1.2.71 1.73 1.08 1.73 2.95 2.97 4.96 3.22 2.14.27 4.43-.12 6.07-1.6 1.83-1.66 2.47-4.32 1.53-6.6l-.13-.26c-.21-.46-.77-1.26-.77-1.26m-3.16 6.3c-.28.24-.74.5-1.1.6-1.12.4-2.24-.16-2.9-.82 1.19-.28 1.9-1.16 2.11-2.05.17-.8-.15-1.46-.28-2.23-.12-.74-.1-1.37.17-2.06.19.38.39.76.63 1.06.77 1 1.98 1.44 2.24 2.8.04.14.06.28.06.43.03.82-.33 1.72-.93 2.27z'/></svg>");
--md-admonition-icon--admonish-success: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='m9 20.42-6.21-6.21 2.83-2.83L9 14.77l9.88-9.89 2.83 2.83L9 20.42z'/></svg>");
--md-admonition-icon--admonish-question: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='m15.07 11.25-.9.92C13.45 12.89 13 13.5 13 15h-2v-.5c0-1.11.45-2.11 1.17-2.83l1.24-1.26c.37-.36.59-.86.59-1.41a2 2 0 0 0-2-2 2 2 0 0 0-2 2H8a4 4 0 0 1 4-4 4 4 0 0 1 4 4 3.2 3.2 0 0 1-.93 2.25M13 19h-2v-2h2M12 2A10 10 0 0 0 2 12a10 10 0 0 0 10 10 10 10 0 0 0 10-10c0-5.53-4.5-10-10-10z'/></svg>");
--md-admonition-icon--admonish-warning: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M13 14h-2V9h2m0 9h-2v-2h2M1 21h22L12 2 1 21z'/></svg>");
--md-admonition-icon--admonish-failure: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M20 6.91 17.09 4 12 9.09 6.91 4 4 6.91 9.09 12 4 17.09 6.91 20 12 14.91 17.09 20 20 17.09 14.91 12 20 6.91z'/></svg>");
--md-admonition-icon--admonish-danger: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M11 15H6l7-14v8h5l-7 14v-8z'/></svg>");
--md-admonition-icon--admonish-bug: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M14 12h-4v-2h4m0 6h-4v-2h4m6-6h-2.81a5.985 5.985 0 0 0-1.82-1.96L17 4.41 15.59 3l-2.17 2.17a6.002 6.002 0 0 0-2.83 0L8.41 3 7 4.41l1.62 1.63C7.88 6.55 7.26 7.22 6.81 8H4v2h2.09c-.05.33-.09.66-.09 1v1H4v2h2v1c0 .34.04.67.09 1H4v2h2.81c1.04 1.79 2.97 3 5.19 3s4.15-1.21 5.19-3H20v-2h-2.09c.05-.33.09-.66.09-1v-1h2v-2h-2v-1c0-.34-.04-.67-.09-1H20V8z'/></svg>");
--md-admonition-icon--admonish-example: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M7 13v-2h14v2H7m0 6v-2h14v2H7M7 7V5h14v2H7M3 8V5H2V4h2v4H3m-1 9v-1h3v4H2v-1h2v-.5H3v-1h1V17H2m2.25-7a.75.75 0 0 1 .75.75c0 .2-.08.39-.21.52L3.12 13H5v1H2v-.92L4 11H2v-1h2.25z'/></svg>");
--md-admonition-icon--admonish-quote: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M14 17h3l2-4V7h-6v6h3M6 17h3l2-4V7H5v6h3l-2 4z'/></svg>");
--md-details-icon: url("data:image/svg+xml;charset=utf-8,<svg xmlns='http://www.w3.org/2000/svg' viewBox='0 0 24 24'><path d='M8.59 16.58 13.17 12 8.59 7.41 10 6l6 6-6 6-1.41-1.42Z'/></svg>");
}
:is(.admonition) {
display: flow-root;
margin: 1.5625em 0;
padding: 0 1.2rem;
color: var(--fg);
page-break-inside: avoid;
background-color: var(--bg);
border: 0 solid black;
border-inline-start-width: 0.4rem;
border-radius: 0.2rem;
box-shadow: 0 0.2rem 1rem rgba(0, 0, 0, 0.05), 0 0 0.1rem rgba(0, 0, 0, 0.1);
}
@media print {
:is(.admonition) {
box-shadow: none;
}
}
:is(.admonition) > * {
box-sizing: border-box;
}
:is(.admonition) :is(.admonition) {
margin-top: 1em;
margin-bottom: 1em;
}
:is(.admonition) > .tabbed-set:only-child {
margin-top: 0;
}
html :is(.admonition) > :last-child {
margin-bottom: 1.2rem;
}
a.admonition-anchor-link {
display: none;
position: absolute;
left: -1.2rem;
padding-right: 1rem;
}
a.admonition-anchor-link:link, a.admonition-anchor-link:visited {
color: var(--fg);
}
a.admonition-anchor-link:link:hover, a.admonition-anchor-link:visited:hover {
text-decoration: none;
}
a.admonition-anchor-link::before {
content: "§";
}
:is(.admonition-title, summary.admonition-title) {
position: relative;
min-height: 4rem;
margin-block: 0;
margin-inline: -1.6rem -1.2rem;
padding-block: 0.8rem;
padding-inline: 4.4rem 1.2rem;
font-weight: 700;
background-color: rgba(68, 138, 255, 0.1);
print-color-adjust: exact;
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<link rel="canonical" href="https://book.leptos.dev/">
# Introduction
This book is intended as an introduction to the [Leptos](https://github.com/leptos-rs/leptos) Web framework.
It will walk through the fundamental concepts you need to build applications,
beginning with a simple application rendered in the browser, and building toward a
full-stack application with server-side rendering and hydration.
The guide doesnt assume you know anything about fine-grained reactivity or the
details of modern Web frameworks. It does assume you are familiar with the Rust
programming language, HTML, CSS, and the DOM and basic Web APIs.
Leptos is most similar to frameworks like [Solid](https://www.solidjs.com) (JavaScript)
and [Sycamore](https://sycamore-rs.netlify.app/) (Rust). There are some similarities
to other frameworks like React (JavaScript), Svelte (JavaScript), Yew (Rust), and
Dioxus (Rust), so knowledge of one of those frameworks may also make it easier to
understand Leptos.
You can find more detailed docs for each part of the API at [Docs.rs](https://docs.rs/leptos/latest/leptos/).
**The guide is a work in progress.**

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# Getting Started
There are two basic paths to getting started with Leptos:
1. Client-side rendering with [Trunk](https://trunkrs.dev/)
2. Full-stack rendering with [`cargo-leptos`](https://github.com/leptos-rs/cargo-leptos)
For the early examples, it will be easiest to begin with Trunk. Well introduce
`cargo-leptos` a little later in this series.
If you dont already have it installed, you can install Trunk by running
```bash
cargo install trunk
```
Create a basic Rust binary project
```bash
cargo init leptos-tutorial
```
`cd` into your new `leptos-tutorial` project and add `leptos` as a dependency
```bash
cargo add leptos
```
Create a simple `index.html` in the root of the `leptos-tutorial` directory
```html
<!DOCTYPE html>
<html>
<head></head>
<body></body>
</html>
```
And add a simple “Hello, world!” to your `main.rs`
```rust
use leptos::*;
fn main() {
mount_to_body(|_cx| view! { cx, <p>"Hello, world!"</p> })
}
```
Now run `trunk serve --open`. Trunk should automatically compile your app and
open it in your default browser. If you make edits to `main.rs`, Trunk will
recompile your source code and live-reload the page.

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# Summary
- [Introduction](./01_introduction.md)
- [Getting Started](./getting_started/README.md)
- [Leptos DX](./getting_started/leptos_dx.md)
- [The Leptos Community and leptos-* Crates](./getting_started/community_crates.md)
- [Part 1: Building User Interfaces](./view/README.md)
- [Getting Started](./02_getting_started.md)
- [Building User Interfaces](./view/README.md)
- [A Basic Component](./view/01_basic_component.md)
- [Dynamic Attributes](./view/02_dynamic_attributes.md)
- [Components and Props](./view/03_components.md)
- [Iteration](./view/04_iteration.md)
- [Iterating over More Complex Data](./view/04b_iteration.md)
- [Forms and Inputs](./view/05_forms.md)
- [Control Flow](./view/06_control_flow.md)
- [Error Handling](./view/07_errors.md)
- [Parent-Child Communication](./view/08_parent_child.md)
- [Passing Children to Components](./view/09_component_children.md)
- [No Macros: The View Builder Syntax](./view/builder.md)
- [Reactivity](./reactivity/README.md)
- [Working with Signals](./reactivity/working_with_signals.md)
- [Responding to Changes with `create_effect`](./reactivity/14_create_effect.md)
- [Interlude: Reactivity and Functions](./reactivity/interlude_functions.md)
- [Interlude: Reactivity and Functions](./interlude_functions.md)
- [Testing](./testing.md)
- [Async](./async/README.md)
- [Loading Data with Resources](./async/10_resources.md)
- [Suspense](./async/11_suspense.md)
- [Transition](./async/12_transition.md)
- [Actions](./async/13_actions.md)
- [Interlude: Projecting Children](./interlude_projecting_children.md)
- [Global State Management](./15_global_state.md)
- [Router](./router/README.md)
- [Defining `<Routes/>`](./router/16_routes.md)
- [Nested Routing](./router/17_nested_routing.md)
- [Params and Queries](./router/18_params_and_queries.md)
- [`<A/>`](./router/19_a.md)
- [`<Form/>`](./router/20_form.md)
- [Interlude: Styling](./interlude_styling.md)
- [Metadata](./metadata.md)
- [Client-Side Rendering: Wrapping Up](./csr_wrapping_up.md)
- [Part 2: Server Side Rendering](./ssr/README.md)
- [`cargo-leptos`](./ssr/21_cargo_leptos.md)
- [The Life of a Page Load](./ssr/22_life_cycle.md)
- [Async Rendering and SSR “Modes”](./ssr/23_ssr_modes.md)
- [Hydration Bugs](./ssr/24_hydration_bugs.md)
- [Working with the Server](./server/README.md)
- [Server Functions](./server/25_server_functions.md)
- [Extractors](./server/26_extractors.md)
- [Responses and Redirects](./server/27_response.md)
- [Progressive Enhancement and Graceful Degradation](./progressive_enhancement/README.md)
- [`<ActionForm/>`s](./progressive_enhancement/action_form.md)
- [Deployment](./deployment/README.md)
- [Optimizing WASM Binary Size](./deployment/binary_size.md)
- [Guide: Islands](./islands.md)
- [Appendix: How Does the Reactive System Work?](./appendix_reactive_graph.md)
- [Transition]()
- [Interlude: Styling — CSS, Tailwind, Style.rs, and more]()
- [State Management]()
- [Interlude: Advanced Reactivity]()
- [Router]()
- [Fundamentals]()
- [defining `<Routes/>`]()
- [`<A/>`]()
- [`<Form/>`]()
- [Metadata]()
- [SSR]()
- [Models of SSR]()
- [`cargo-leptos`]()
- [Hydration Footguns]()
- [Request/Response]()
- [Headers]()
- [Cookies]()
- [Server Functions]()
- [Actions]()
- [Forms]()
- [`<ActionForm/>`s]()
- [Turning off WebAssembly]()

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# Loading Data with Resources
A [Resource](https://docs.rs/leptos/latest/leptos/struct.Resource.html) is a reactive data structure that reflects the current state of an asynchronous task, allowing you to integrate asynchronous `Future`s into the synchronous reactive system. Rather than waiting for its data to load with `.await`, you transform the `Future` into a signal that returns `Some(T)` if it has resolved, and `None` if its still pending.
You do this by using the [`create_resource`](https://docs.rs/leptos/latest/leptos/fn.create_resource.html) function. This takes two arguments (other than the ubiquitous `cx`):
1. a source signal, which will generate a new `Future` whenever it changes
2. a fetcher function, which takes the data from that signal and returns a `Future`
Heres an example
```rust
// our source signal: some synchronous, local state
let (count, set_count) = create_signal(cx, 0);
// our resource
let async_data = create_resource(cx,
count,
// every time `count` changes, this will run
|value| async move {
log!("loading data from API");
load_data(value).await
},
);
```
To create a resource that simply runs once, you can pass a non-reactive, empty source signal:
```rust
let once = create_resource(cx, || (), |_| async move { load_data().await });
```
To access the value you can use `.read(cx)` or `.with(cx, |data| /* */)`. These work just like `.get()` and `.with()` on a signal—`read` clones the value and returns it, `with` applies a closure to it—but with two differences
1. For any `Resource<_, T>`, they always return `Option<T>`, not `T`: because its always possible that your resource is still loading.
2. They take a `Scope` argument. Youll see why in the next chapter, on `<Suspense/>`.
So, you can show the current state of a resource in your view:
```rust
let once = create_resource(cx, || (), |_| async move { load_data().await });
view! { cx,
<h1>"My Data"</h1>
{move || match once.read(cx) {
None => view! { cx, <p>"Loading..."</p> }.into_view(cx),
Some(data) => view! { cx, <ShowData data/> }.into_view(cx)
}}
}
```
Resources also provide a `refetch()` method that allow you to manually reload the data (for example, in response to a button click) and a `loading()` method that returns a `ReadSignal<bool>` indicating whether the resource is currently loading or not.
<iframe src="https://codesandbox.io/p/sandbox/10-async-resources-4z0qt3?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A1%2C%22endLineNumber%22%3A3%2C%22startColumn%22%3A1%2C%22startLineNumber%22%3A3%7D%5D" width="100%" height="1000px"></iframe>

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# `<Suspense/>`
In the previous chapter, we showed how you can create a simple loading screen to show some fallback while a resource is loading.
```rust
let (count, set_count) = create_signal(cx, 0);
let a = create_resource(cx, count, |count| async move { load_a(count).await });
view! { cx,
<h1>"My Data"</h1>
{move || match once.read(cx) {
None => view! { cx, <p>"Loading..."</p> }.into_view(cx),
Some(data) => view! { cx, <ShowData data/> }.into_view(cx)
}}
}
```
But what if we have two resources, and want to wait for both of them?
```rust
let (count, set_count) = create_signal(cx, 0);
let (count2, set_count2) = create_signal(cx, 0);
let a = create_resource(cx, count, |count| async move { load_a(count).await });
let b = create_resource(cx, count2, |count| async move { load_b(count).await });
view! { cx,
<h1>"My Data"</h1>
{move || match (a.read(cx), b.read(cx)) {
_ => view! { cx, <p>"Loading..."</p> }.into_view(cx),
(Some(a), Some(b)) => view! { cx,
<ShowA a/>
<ShowA b/>
}.into_view(cx)
}}
}
```
Thats not _so_ bad, but its kind of annoying. What if we could invert the flow of control?
The [`<Suspense/>`](https://docs.rs/leptos/latest/leptos/fn.Suspense.html) component lets us do exactly that. You give it a `fallback` prop and children, one or more of which usually involves reading from a resource. Reading from a resource “under” a `<Suspense/>` (i.e., in one of its children) registers that resource with the `<Suspense/>`. If its still waiting for resources to load, it shows the `fallback`. When theyve all loaded, it shows the children.
```rust
let (count, set_count) = create_signal(cx, 0);
let (count2, set_count2) = create_signal(cx, 0);
let a = create_resource(cx, count, |count| async move { load_a(count).await });
let b = create_resource(cx, count2, |count| async move { load_b(count).await });
view! { cx,
<h1>"My Data"</h1>
<Suspense
fallback=move || view! { cx, <p>"Loading..."</p> }
>
<h2>"My Data"</h2>
<h3>"A"</h3>
{move || {
a.read(cx)
.map(|a| view! { cx, <ShowA a/> })
}}
<h3>"B"</h3>
{move || {
b.read(cx)
.map(|b| view! { cx, <ShowB b/> })
}}
</Suspense>
}
```
Every time one of the resources is reloading, the `"Loading..."` fallback will show again.
This inversion of the flow of control makes it easier to add or remove individual resources, as you dont need to handle the matching yourself. It also unlocks some massive performance improvements during server-side rendering, which well talk about during a later chapter.
<iframe src="https://codesandbox.io/p/sandbox/10-async-resources-4z0qt3?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A1%2C%22endLineNumber%22%3A3%2C%22startColumn%22%3A1%2C%22startLineNumber%22%3A3%7D%5D" width="100%" height="1000px"></iframe>

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# `<Transition/>`
Youll notice in the `<Suspense/>` example that if you keep reloading the data, it keeps flickering back to `"Loading..."`. Sometimes this is fine. For other times, theres [`<Transition/>`](https://docs.rs/leptos/latest/leptos/fn.Suspense.html).
`<Transition/>` behaves exactly the same as `<Suspense/>`, but instead of falling back every time, it only shows the fallback the first time. On all subsequent loads, it continues showing the old data until the new data are ready. This can be really handy to prevent the flickering effect, and to allow users to continue interacting with your application.
This example shows how you can create a simple tabbed contact list with `<Transition/>`. When you select a new tab, it continues showing the current contact until the new data laods. This can be a much better user experience than constantly falling back to a loading message.
<iframe src="https://codesandbox.io/p/sandbox/12-transition-sn38sd?selection=%5B%7B%22endColumn%22%3A15%2C%22endLineNumber%22%3A2%2C%22startColumn%22%3A15%2C%22startLineNumber%22%3A2%7D%5D&file=%2Fsrc%2Fmain.rs" width="100%" height="1000px"></iframe>

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# Working with `async`
So far weve only been working with synchronous users interfaces: You provide some input,
the app immediately process it and updates the interface. This is great, but is a tiny
subset of what web applications do. In particular, most web apps have to deal with some kind
of asynchronous data loading, usually loading something from an API.
Asynchronous data is notoriously hard to integrate with the synchronous parts of your code.
In this chapter, well see how Leptos helps smooth out that process for you.

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# Interlude: Reactivity and Functions
One of our core contributors said to me recently: “I never used closures this often
until I started using Leptos.” And its true. Closures are at the heart of any Leptos
application. It sometimes looks a little silly:
```rust
// a signal holds a value, and can be updated
let (count, set_count) = create_signal(cx, 0);
// a derived signal is a function that accesses other signals
let double_count = move || count() * 2;
let count_is_odd = move || count() & 1 == 1;
let text = move || if count_is_odd() {
"odd"
} else {
"even"
};
// an effect automatically tracks the signals it depends on
// and re-runs when they change
create_effect(cx, move |_| {
log!("text = {}", text());
});
view! { cx,
<p>{move || text().to_uppercase()}</p>
}
```
Closures, closures everywhere!
But why?
## Functions and UI Frameworks
Functions are at the heart of every UI framework. And this makes perfect sense. Creating a user interface is basically divided into two phases:
1. initial rendering
2. updates
In a web framework, the framework does some kind of initial rendering. Then it hands control back over to the browser. When certain events fire (like a mouse click) or asynchronous tasks finish (like an HTTP request finishing), the browser wakes the framework back up to update something. The framework runs some kind of code to update your user interface, and goes back asleep until the browser wakes it up again.
The key phrase here is “runs some kind of code.” The natural way to “run some kind of code” at an arbitrary point in time—in Rust or in any other programming language—is to call a function. And in fact every UI framework is based on rerunning some kind of function over and over:
1. virtual DOM (VDOM) frameworks like React, Yew, or Dioxus rerun a component or render function over and over, to generate a virtual DOM tree that can be reconciled with the previous result to patch the DOM
2. compiled frameworks like Angular and Svelte divide your component templates into “create” and “update” functions, rerunning the update function when they detect a change to the components state
3. in fine-grained reactive frameworks like SolidJS, Sycamore, or Leptos, _you_ define the functions that re-run
Thats what all our components are doing.
Take our typical `<SimpleCounter/>` example in its simplest form:
```rust
#[component]
pub fn SimpleCounter(cx: Scope) -> impl IntoView {
let (value, set_value) = create_signal(cx, 0);
let increment = move |_| set_value.update(|value| *value += 1);
view! { cx,
<button on:click=increment>
{value}
</button>
}
}
```
The `SimpleCounter` function itself runs once. The `value` signal is created once. The framework hands off the `increment` function to the browser as an event listener. When you click the button, the browser calls `increment`, which updates `value` via `set_value`. And that updates the single text node represented in our view by `{value}`.
Closures are key to reactivity. They provide the framework with the ability to re-run the smallest possible unit of your application in responsive to a change.
So remember two things:
1. Your component function is a setup function, not a render function: it only runs once.
2. For values in your view template to be reactive, they must be functions: either signals (which implement the `Fn` traits) or closures.

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# Testing Your Components
Testing user interfaces can be relatively tricky, but really important. This article
will discuss a couple principles and approaches for testing a Leptos app.
## 1. Test business logic with ordinary Rust tests
In many cases, it makes sense to pull the logic out of your components and test
it separately. For some simple components, theres no particular logic to test, but
for many its worth using a testable wrapping type and implementing the logic in
ordinary Rust `impl` blocks.
For example, instead of embedding logic in a component directly like this:
```rust
#[component]
pub fn TodoApp(cx: Scope) -> impl IntoView {
let (todos, set_todos) = create_signal(cx, vec![Todo { /* ... */ }]);
// ⚠️ this is hard to test because it's embedded in the component
let maximum = move || todos.with(|todos| {
todos.iter().filter(|todo| todo.completed).sum()
});
}
```
You could pull that logic out into a separate data structure and test it:
```rust
pub struct Todos(Vec<Todo>);
impl Todos {
pub fn remaining(&self) -> usize {
todos.iter().filter(|todo| todo.completed).sum()
}
}
#[cfg(test)]
mod tests {
#[test]
fn test_remaining {
// ...
}
}
#[component]
pub fn TodoApp(cx: Scope) -> impl IntoView {
let (todos, set_todos) = create_signal(cx, Todos(vec![Todo { /* ... */ }]));
// ✅ this has a test associated with it
let maximum = move || todos.with(Todos::remaining);
}
```
In general, the less of your logic is wrapped into your components themselves, the
more idiomatic your code will feel and the easier it will be to test.
## 2. Test components with `wasm-bindgen-test`
[`wasm-bindgen-test`](https://crates.io/crates/wasm-bindgen-test) is a great utility
for integrating or end-to-end testing WebAssembly apps in a headless browser.
To use this testing utility, you need to add `wasm-bindgen-test` to your `Cargo.toml`:
```toml
[dev-dependencies]
wasm-bindgen-test = "0.3.0"
```
You should create tests in a separate `tests` directory. You can then run your tests in the browser of your choice:
```bash
wasm-pack test --firefox
```
> To see the full setup, check out the tests for the [`counter`](https://github.com/leptos-rs/leptos/tree/main/examples/counter) example.
### Writing Your Tests
Most tests will involve some combination of vanilla DOM manipulation and comparison to a `view`. For example, heres a test [for the
`counter` example](https://github.com/leptos-rs/leptos/blob/main/examples/counter/tests/mod.rs).
First, we set up the testing environment.
```rust
use wasm_bindgen_test::*;
use counter::*;
use leptos::*;
use web_sys::HtmlElement;
// tell the test runner to run tests in the browser
wasm_bindgen_test_configure!(run_in_browser);
```
Im going to create a simpler wrapper for each test case, and mount it there.
This makes it easy to encapsulate the test results.
```rust
// like marking a regular test with #[test]
#[wasm_bindgen_test]
fn clear() {
let document = leptos::document();
let test_wrapper = document.create_element("section").unwrap();
document.body().unwrap().append_child(&test_wrapper);
// start by rendering our counter and mounting it to the DOM
// note that we start at the initial value of 10
mount_to(
test_wrapper.clone().unchecked_into(),
|cx| view! { cx, <SimpleCounter initial_value=10 step=1/> },
);
```
Well use some manual DOM operations to grab the `<div>` that wraps
the whole component, as well as the `clear` button.
```rust
// now we extract the buttons by iterating over the DOM
// this would be easier if they had IDs
let div = test_wrapper.query_selector("div").unwrap().unwrap();
let clear = test_wrapper
.query_selector("button")
.unwrap()
.unwrap()
.unchecked_into::<web_sys::HtmlElement>();
```
Now we can use ordinary DOM APIs to simulate user interaction.
```rust
// now let's click the `clear` button
clear.click();
```
You can test individual DOM element attributes or text node values. Sometimes
I like to test the whole view at once. We can do this by testing the elements
`outerHTML` against our expectations.
```rust
assert_eq!(
div.outer_html(),
// here we spawn a mini reactive system to render the test case
run_scope(create_runtime(), |cx| {
// it's as if we're creating it with a value of 0, right?
let (value, set_value) = create_signal(cx, 0);
// we can remove the event listeners because they're not rendered to HTML
view! { cx,
<div>
<button>"Clear"</button>
<button>"-1"</button>
<span>"Value: " {value} "!"</span>
<button>"+1"</button>
</div>
}
// the view returned an HtmlElement<Div>, which is a smart pointer for
// a DOM element. So we can still just call .outer_html()
.outer_html()
})
);
```
That test involved us manually replicating the `view` thats inside the component.
There's actually an easier way to do this... We can just test against a `<SimpleCounter/>`
with the initial value `0`. This is where our wrapping element comes in: Ill just test
the wrappers `innerHTML` against another comparison case.
```rust
assert_eq!(test_wrapper.inner_html(), {
let comparison_wrapper = document.create_element("section").unwrap();
leptos::mount_to(
comparison_wrapper.clone().unchecked_into(),
|cx| view! { cx, <SimpleCounter initial_value=0 step=1/>},
);
comparison_wrapper.inner_html()
});
}
```
This is only a very limited introduction to testing. But I hope its useful as you begin to build applications.
> For more, see [the testing section of the `wasm-bindgen` guide](https://rustwasm.github.io/wasm-bindgen/wasm-bindgen-test/index.html#testing-on-wasm32-unknown-unknown-with-wasm-bindgen-test).

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# A Basic Component
That “Hello, world!” was a *very* simple example. Lets move on to something a
little more like an ordinary app.
First, lets edit the `main` function so that, instead of rendering the whole
app, it just renders an `<App/>` component. Components are the basic unit of
composition and design in most web frameworks, and Leptos is no exception.
Conceptually, they are similar to HTML elements: they represent a section of the
DOM, with self-contained, defined behavior. Unlike HTML elements, they are in
`PascalCase`, so most Leptos applications will start with something like an
`<App/>` component.
```rust
fn main() {
leptos::mount_to_body(|cx| view! { cx, <App/> })
}
```
Now lets define our `<App/>` component itself. Because its relatively simple,
Ill give you the whole thing up front, then walk through it line by line.
```rust
#[component]
fn App(cx: Scope) -> impl IntoView {
let (count, set_count) = create_signal(cx, 0);
view! { cx,
<button
on:click=move |_| {
set_count.update(|n| *n += 1);
}
>
"Click me"
{move || count.get()}
</button>
}
}
```
## The Component Signature
```rust
#[component]
```
Like all component definitions, this begins with the [`#[component]`](https://docs.rs/leptos/latest/leptos/attr.component.html) macro. `#[component]` annotates a function so it can be
used as a component in your Leptos application. Well see some of the other features of
this macro in a couple chapters.
```rust
fn App(cx: Scope) -> impl IntoView
```
Every component is a function with the following characteristics
1. It takes a reactive [`Scope`](https://docs.rs/leptos/latest/leptos/struct.Scope.html)
as its first argument. This `Scope` is our entrypoint into the reactive system.
By convention, its usually named `cx`.
2. You can include other arguments, which will be available as component “props.”
3. Component functions return `impl IntoView`, which is an opaque type that includes
anything you could return from a Leptos `view`.
## The Component Body
The body of the component function is a set-up function that runs once, not a
render function that re-runs multiple times. Youll typically use it to create a
few reactive variables, define any side effects that run in response to those values
changing, and describe the user interface.
```rust
let (count, set_count) = create_signal(cx, 0);
```
[`create_signal`](https://docs.rs/leptos/latest/leptos/fn.create_signal.html)
creates a signal, the basic unit of reactive change and state management in Leptos.
This returns a `(getter, setter)` tuple. To access the current value, youll
use `count.get()` (or, on `nightly` Rust, the shorthand `count()`). To set the
current value, youll call `set_count.set(...)` (or `set_count(...)`).
> `.get()` clones the value and `.set()` overwrites it. In many cases, its more
efficient to use `.with()` or `.update()`; check out the docs for [`ReadSignal`](https://docs.rs/leptos/latest/leptos/struct.ReadSignal.html) and [`WriteSignal`](https://docs.rs/leptos/latest/leptos/struct.WriteSignal.html) if youd like to learn more about those trade-offs at this point.
## The View
Leptos defines user interfaces using a JSX-like format via the [`view`](https://docs.rs/leptos/latest/leptos/macro.view.html) macro.
```rust
view! { cx,
<button
// define an event listener with on:
on:click=move |_| {
set_count.update(|n| *n += 1);
}
>
// text nodes are wrapped in quotation marks
"Click me: "
// blocks can include Rust code
{move || count.get()}
</button>
}
```
This should mostly be easy to understand: it looks like HTML, with a special
`on:click` to define a `click` event listener, a text node thats formatted like
a Rust string, and then...
```rust
{move || count.get()}
```
whatever that is.
People sometimes joke that they use more closures in their first Leptos application
than theyve ever used in their lives. And fair enough. Basically, passing a function
into the view tells the framework: “Hey, this is something that might change.”
When we click the button and call `set_count`, the `count` signal is updated. This
`move || count.get()` closure, whose value depends on the value of `count`, re-runs,
and the framework makes a targeted update to that one specific text node, touching
nothing else in your application. This is what allows for extremely efficient updates
to the DOM.
Now, if you have Clippy on—or if you have a particularly sharp eye—you might notice
that this closure is redundant, at least if youre in `nightly` Rust. If youre using
Leptos with `nightly` Rust, signals are already functions, so the closure is unnecessary.
As a result, you can write a simpler view:
```rust
view! { cx,
<button /* ... */>
"Click me: "
// identical to {move || count.get()}
{count}
</button>
}
```
Remember—and this is *very important*—only functions are reactive. This means that
`{count}` and `{count()}` do very different things in your view. `{count}` passes
in a function, telling the framework to update the view every time `count` changes.
`{count()}` access the value of `count` once, and passes an `i32` into the view,
rendering it once, unreactively. You can see the difference in the CodeSandbox below!
> Throughout this tutorial, well use CodeSandbox to show interactive examples. To
show the browser in the sandbox, you may need to click `Add DevTools >
Other Previews > 8080.` Hover over any of the variables to show Rust-Analyzer details
and docs for whats going on. Feel free to fork the examples to play with them yourself!
<iframe src="https://codesandbox.io/p/sandbox/1-basic-component-3d74p3?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A31%2C%22endLineNumber%22%3A19%2C%22startColumn%22%3A31%2C%22startLineNumber%22%3A19%7D%5D" width="100%" height="1000px"></iframe>

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# `view`: Dynamic Attributes and Classes
So far weve seen how to use the `view` macro to create event listeners and to
create dynamic text by passing a function (such as a signal) into the view.
But of course there are other things you might want to update in your user interface.
In this section, well look at how to update attributes and classes dynamically,
and well introduce the concept of a **derived signal**.
Lets start with a simple component that should be familiar: click a button to
increment a counter.
```rust
#[component]
fn App(cx: Scope) -> impl IntoView {
let (count, set_count) = create_signal(cx, 0);
view! { cx,
<button
on:click=move |_| {
set_count.update(|n| *n += 1);
}
```
So far, this is just the example from the last chapter.
## Dynamic Classes
Now lets say Id like to update the list of CSS classes on this element dynamically.
For example, lets say I want to add the class `red` when the count is odd. I can
do this using the `class:` syntax.
```rust
class:red=move || count() & 1 == 1
```
`class:` attributes take
1. the class name, following the colon (`red`)
2. a value, which can be a `bool` or a function that returns a `bool`
When the value is `true`, the class is added. When the value is `false`, the class
is removed. And if the value is a function that accesses a signal, the class will
reactively update when the signal changes.
Now every time I click the button, the text should toggle between red and black as
the number switches between even and odd.
## Dynamic Attributes
The same applies to plain attributes. Passing a plain string or primitive value to
an attribute gives it a static value. Passing a function (including a signal) to
an attribute causes it to update its value reactively. Lets add another element
to our view:
```rust
<progress
max="50"
// signals are functions, so this <=> `move || count.get()`
value=count
/>
```
Now every time we set the count, not only will the `class` of the `<button>` be
toggled, but the `value` of the `<progress>` bar will increase, which means that
our progress bar will move forward.
## Derived Signals
Lets go one layer deeper, just for fun.
You already know that we create reactive interfaces just by passing functions into
the `view`. This means that we can easily change our progress bar. For example,
suppose we want it to move twice as fast:
```rust
<progress
max="50"
value=move || count() * 2
/>
```
But imagine we want to reuse that calculation in more than one place. You can do this
using a **derived signal**: a closure that accesses a signal.
```rust
let double_count = move || count() * 2;
/* insert the rest of the view */
<progress
max="50"
// we use it once here
value=double_count
/>
<p>
"Double Count: "
// and again here
{double_count}
</p>
```
Derived signals let you create reactive computed values that can be used in multiple
places in your application with minimal overhead.
> Note: Using a derived signal like this means that the calculation runs once per
signal change per place we access `double_count`; in other words, twice. This is a
very cheap calculation, so thats fine. Well look at memos in a later chapter, which
are designed to solve this problem for expensive calculations.
<iframe src="https://codesandbox.io/p/sandbox/2-dynamic-attribute-pqyvzl?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A1%2C%22endLineNumber%22%3A2%2C%22startColumn%22%3A1%2C%22startLineNumber%22%3A2%7D%5D" width="100%" height="1000px"></iframe>

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# Components and Props
So far, weve been building our whole application in a single component. This
is fine for really tiny examples, but in any real application youll need to
break the user interface out into multiple components, so you can break your
interface down into smaller, reusable, composable chunks.
Lets take our progress bar example. Imagine that you want two progress bars
instead of one: one that advances one tick per click, one that advances two ticks
per click.
You _could_ do this by just creating two `<progress>` elements:
```rust
let (count, set_count) = create_signal(cx, 0);
let double_count = move || count() * 2;
view! {
<progress
max="50"
value=progress
/>
<progress
max="50"
value=double_count
/>
```
But of course, this doesnt scale very well. If you want to add a third progress
bar, you need to add this code another time. And if you want to edit anything
about it, you need to edit it in triplicate.
Instead, lets create a `<ProgressBar/>` component.
```rust
#[component]
fn ProgressBar(
cx: Scope
) -> impl IntoView {
view! { cx,
<progress
max="50"
// hmm... where will we get this from?
value=progress
/>
}
}
```
Theres just one problem: `progress` is not defined. Where should it come from?
When we were defining everything manually, we just used the local variable names.
Now we need some way to pass an argument into the component.
## Component Props
We do this using component properties, or “props.” If youve used another frontend
framework, this is probably a familiar idea. Basically, properties are to components
as attributes are to HTML elements: they let you pass additional information into
the component.
In Leptos, you define props by giving additional arguments to the component function.
```rust
#[component]
fn ProgressBar(
cx: Scope,
progress: ReadSignal<i32>
) -> impl IntoView {
view! { cx,
<progress
max="50"
// now this works
value=progress
/>
}
}
```
Now we can use our component in the main `<App/>` components view.
```rust
#[component]
fn App(cx: Scope) -> impl IntoView {
let (count, set_count) = create_signal(cx, 0);
view! { cx,
<button on:click=move |_| { set_count.update(|n| *n += 1); }>
"Click me"
</button>
// now we use our component!
<ProgressBar progress=count/>
}
}
```
Using a component in the view looks a lot like using an HTML element. Youll
notice that you can easily tell the difference between an element and a component
because components always have `PascalCase` names. You pass the `progress` prop
in as if it were an HTML element attribute. Simple.
> ### Important Note
> For every `Component`, Leptos generates a corresponding `ComponentProps` type. This
is what allows us to have named props, when Rust does not have named function parameters.
If youre defining a component in one module and importing it into another, make
sure you include this `ComponentProps` type:
>
> `use progress_bar::{ProgressBar, ProgressBarProps};`
### Reactive and Static Props
Youll notice that throughout this example, `progress` takes a reactive
`ReadSignal<i32>`, and not a plain `i32`. This is **very important**.
Component props have no special meaning attached to them. A component is simply
a function that runs once to set up the user interface. The only way to tell the
interface to respond to changing is to pass it a signal type. So if you have a
component property that will change over time, like our `progress`, it should
be a signal.
### `optional` Props
Right now the `max` setting is hard-coded. Lets take that as a prop too. But
lets add a catch: lets make this prop optional by annotating the particular
argument to the component function with `#[prop(optional)]`.
```rust
#[component]
fn ProgressBar(
cx: Scope,
// mark this prop optional
// you can specify it or not when you use <ProgressBar/>
#[prop(optional)]
max: u16,
progress: ReadSignal<i32>
) -> impl IntoView {
view! { cx,
<progress
max=max
value=progress
/>
}
}
```
Now, we can use `<ProgressBar max=50 value=count/>`, or we can omit `max`
to use the default value (i.e., `<ProgressBar value=count/>`). The default value
on an `optional` is its `Default::default()` value, which for a `u16` is going to
be `0`. In the case of a progress bar, a max value of `0` is not very useful.
So lets give it a particular default value instead.
### `default` props
You can specify a default value other than `Default::default()` pretty simply
with `#[prop(default = ...)`.
```rust
#[component]
fn ProgressBar(
cx: Scope,
#[prop(default = 100)]
max: u16,
progress: ReadSignal<i32>
) -> impl IntoView {
view! { cx,
<progress
max=max
value=progress
/>
}
}
```
### Generic Props
This is great. But we began with two counters, one driven by `count`, and one by
the derived signal `double_count`. Lets recreate that by using `double_count`
as the `progress` prop on another `<ProgressBar/>`.
```rust
#[component]
fn App(cx: Scope) -> impl IntoView {
let (count, set_count) = create_signal(cx, 0);
let double_count = move || count() * 2;
view! { cx,
<button on:click=move |_| { set_count.update(|n| *n += 1); }>
"Click me"
</button>
<ProgressBar progress=count/>
// add a second progress bar
<ProgressBar progress=double_count/>
}
}
```
Hm... this wont compile. It should be pretty easy to understand why: weve declared
that the `progress` prop takes `ReadSignal<i32>`, and `double_count` is not
`ReadSignal<i32>`. As rust-analyzer will tell you, its type is `|| -> i32`, i.e.,
its a closure that returns an `i32`.
There are a couple ways to handle this. One would be to say: “Well, I know that
a `ReadSignal` is a function, and I know that a closure is a function; maybe I
could just take any function?” If youre savvy, you may know that both these
implement the trait `Fn() -> i32`. So you could use a generic component:
```rust
#[component]
fn ProgressBar<F>(
cx: Scope,
#[prop(default = 100)]
max: u16,
progress: F
) -> impl IntoView
where
F: Fn() -> i32
{
view! { cx,
<progress
max=max
value=progress
/>
}
}
```
This is a perfectly reasonable way to write this component: `progress` now takes
any value that implements this `Fn()` trait.
> Note that generic component props _cannot_ be specified inline (as `<F: Fn() -> i32>`)
or as `progress: impl Fn() -> i32`, in part because theyre actually used to generate
a `struct ProgressBarProps`, and struct fields cannot be `impl` types.
### `into` Props
Theres one more way we could implement this, and it would be to use `#[prop(into)]`.
This attribute automatically calls `.into()` on the values you pass as proprs,
which allows you to pass props of different values easily.
In this case, its helpful to know about the
[`Signal`](https://docs.rs/leptos/latest/leptos/struct.Signal.html) type. `Signal`
is a enumerated type that represents any kind of readable reactive signal. It can
be useful when defining APIs for components youll want to reuse while passing
different sorts of signals. The [`MaybeSignal`](https://docs.rs/leptos/latest/leptos/enum.MaybeSignal.html) type is useful when you want to be able to take either a static or
reactive value.
```rust
#[component]
fn ProgressBar(
cx: Scope,
#[prop(default = 100)]
max: u16,
#[prop(into)]
progress: Signal<i32>
) -> impl IntoView
{
view! { cx,
<progress
max=max
value=progress
/>
}
}
#[component]
fn App(cx: Scope) -> impl IntoView {
let (count, set_count) = create_signal(cx, 0);
let double_count = move || count() * 2;
view! { cx,
<button on:click=move |_| { set_count.update(|n| *n += 1); }>
"Click me"
</button>
// .into() converts `ReadSignal` to `Signal`
<ProgressBar progress=count/>
// use `Signal::derive()` to wrap a derived signal
<ProgressBar progress=Signal::derive(cx, double_count)/>
}
}
```
## Documenting Components
This is one of the least essential but most important sections of this book.
Its not strictly necessary to document your components and their props. It may
be very important, depending on the size of your team and your app. But its very
easy, and bears immediate fruit.
To document a component and its props, you can simply add doc comments on the
component function, and each one of the props:
```rust
/// Shows progress toward a goal.
#[component]
fn ProgressBar(
cx: Scope,
/// The maximum value of the progress bar.
#[prop(default = 100)]
max: u16,
/// How much progress should be displayed.
#[prop(into)]
progress: Signal<i32>,
) -> impl IntoView {
/* ... */
}
```
Thats all you need to do. These behave like ordinary Rust doc comments, except
that you can document individual component props, which cant be done with Rust
function arguments.
This will automatically generate documentation for your component, its `Props`
type, and each of the fields used to add props. It can be a little hard to
understand how powerful this is until you hover over the component name or props
and see the power of the `#[component]` macro combined with rust-analyzer here.
<iframe src="https://codesandbox.io/p/sandbox/3-components-50t2e7?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A1%2C%22endLineNumber%22%3A7%2C%22startColumn%22%3A1%2C%22startLineNumber%22%3A7%7D%5D" width="100%" height="1000px"></iframe>

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# Iteration
Whether youre listing todos, displaying a table, or showing product images,
iterating over a list of items is a common task in web applications. Reconciling
the differences between changing sets of items can also be one of the trickiest
tasks for a framework to handle well.
Leptos supports to two different patterns for iterating over items:
1. For static views: `Vec<_>`
2. For dynamic lists: `<For/>`
## Static Views with `Vec<_>`
Sometimes you need to show an item repeatedly, but the list youre drawing from
does not often change. In this case, its important to know that you can insert
any `Vec<IV> where IV: IntoView` into your view. In other views, if you can render
`T`, you can render `Vec<T>`.
```rust
let values = vec![0, 1, 2];
view! { cx,
// this will just render "012"
<p>{values.clone()}</p>
// or we can wrap them in <li>
<ul>
{values.into_iter()
.map(|n| view! { cx, <li>{n}</li>})
.collect::<Vec<_>>()}
</ul>
}
```
The fact that the _list_ is static doesnt mean the interface needs to be static.
You can render dynamic items as part of a static list.
```rust
// create a list of N signals
let counters = (1..=length).map(|idx| create_signal(cx, idx));
// each item manages a reactive view
// but the list itself will never change
let counter_buttons = counters
.map(|(count, set_count)| {
view! { cx,
<li>
<button
on:click=move |_| set_count.update(|n| *n += 1)
>
{count}
</button>
</li>
}
})
.collect::<Vec<_>>();
view! { cx,
<ul>{counter_buttons}</ul>
}
```
You _can_ render a `Fn() -> Vec<_>` reactively as well. But note that every time
it changes, this will rerender every item in the list. This is quite inefficient!
Fortunately, theres a better way.
## Dynamic Rendering with the `<For/>` Component
The [`<For/>`](https://docs.rs/leptos/latest/leptos/fn.For.html) component is a
keyed dynamic list. It takes three props:
- `each`: a function (such as a signal) that returns the items `T` to be iterated over
- `key`: a key function that takes `&T` and returns a stable, unique key or ID
- `view`: renders each `T` into a view
`key` is, well, the key. You can add, remove, and move items within the list. As
long as each items key is stable over time, the framework does not need to rerender
any of the items, unless they are new additions, and it can very efficiently add,
remove, and move items as they change. This allows for extremely efficient updates
to the list as it changes, with minimal additional work.
Creating a good `key` can be a little tricky. You generally do _not_ want to use
an index for this purpose, as it is not stable—if you remove or move items, their
indices change.
But its a great idea to do something like generating a unique ID for each row as
it is generated, and using that as an ID for the key function.
Check out the `<DynamicList/>` component below for an example.
<iframe src="https://codesandbox.io/p/sandbox/4-iteration-sglt1o?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A6%2C%22endLineNumber%22%3A55%2C%22startColumn%22%3A5%2C%22startLineNumber%22%3A31%7D%5D" width="100%" height="100px"></iframe>

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# Forms and Inputs
Forms and form inputs are an important part of interactive apps. There are two
basic patterns for interacting with inputs in Leptos, which you may recognize
if youre familiar with React, SolidJS, or a similar framework: using **controlled**
or **uncontrolled** inputs.
## Controlled Inputs
In a "controlled input," the framework controls the state of the input
element. On every `input` event, it updates a local signal that holds the current
state, which in turn updates the `value` prop of the input.
There are two important things to remember:
1. The `input` event fires on (almost) every change to the element, while the
`change` event fires (more or less) when you unfocus the input. You probably
want `on:input`, but we give you the freedom to choose.
2. The `value` *attribute* only sets the initial value of the input, i.e., it
only updates the input up to the point that you begin typing. The `value`
*property* continues updating the input after that. You usually want to set
`prop:value` for this reason.
```rust
let (name, set_name) = create_signal(cx, "Controlled".to_string());
view! { cx,
<input type="text"
on:input=move |ev| {
// event_target_value is a Leptos helper function
// it functions the same way as event.target.value
// in JavaScript, but smooths out some of the typecasting
// necessary to make this work in Rust
set_name(event_target_value(&ev));
}
// the `prop:` syntax lets you update a DOM property,
// rather than an attribute.
prop:value=name
/>
<p>"Name is: " {name}</p>
}
```
## Uncontrolled Inputs
In an "uncontrolled input," the browser controls the state of the input element.
Rather than continuously updating a signal to hold its value, we use a
[`NodeRef`](https://docs.rs/leptos/latest/leptos/struct.NodeRef.html) to access
the input once when we want to get its value.
In this example, we only notify the framework when the `<form>` fires a `submit`
event.
```rust
let (name, set_name) = create_signal(cx, "Uncontrolled".to_string());
let input_element: NodeRef<HtmlElement<Input>> = NodeRef::new(cx);
```
`NodeRef` is a kind of reactive smart pointer: we can use it to access the
underlying DOM node. Its value will be set when the element is rendered.
```rust
let on_submit = move |ev: SubmitEvent| {
// stop the page from reloading!
ev.prevent_default();
// here, we'll extract the value from the input
let value = input_element()
// event handlers can only fire after the view
// is mounted to the DOM, so the `NodeRef` will be `Some`
.expect("<input> to exist")
// `NodeRef` implements `Deref` for the DOM element type
// this means we can call`HtmlInputElement::value()`
// to get the current value of the input
.value();
set_name(value);
};
```
Our `on_submit` handler will access the inputs value and use it to call `set_name`.
To access the DOM node stored in the `NodeRef`, we can simply call it as a function
(or using `.get()`). This will return `Option<web_sys::HtmlInputElement>`, but we
know it will already have been filled when we rendered the view, so its safe to
unwrap here.
We can then call `.value()` to get the value out of the input, because `NodeRef`
gives us access to a correctly-typed HTML element.
```rust
view! { cx,
<form on:submit=on_submit>
<input type="text"
value=name
node_ref=input_element
/>
<input type="submit" value="Submit"/>
</form>
<p>"Name is: " {name}</p>
}
```
The view should be pretty self-explanatory by now. Note two things:
1. Unlike in the controlled input example, we use `value` (not `prop:value`).
This is because were just setting the initial value of the input, and letting
the browser control its state. (We could use `prop:value` instead.)
2. We use `node_ref` to fill the `NodeRef`. (Older examples sometimes use `_ref`.
They are the same thing, but `node_ref` has better rust-analyzer support.)
<iframe src="https://codesandbox.io/p/sandbox/5-form-inputs-ih9m62?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A1%2C%22endLineNumber%22%3A12%2C%22startColumn%22%3A1%2C%22startLineNumber%22%3A12%7D%5D" width="100%" height="1000px"></iframe>

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# Control Flow
In most applications, you sometimes need to make a decision: Should I render this
part of the view, or not? Should I render `<ButtonA/>` or `<WidgetB/>`? This is
**control flow**.
## A Few Tips
When thinking about how to do this with Leptos, its important to remember a few
things:
1. Rust is an expression-oriented language: control-flow expressions like
`if x() { y } else { z }` and `match x() { ... }` return their values. This
makes them very useful for declarative user interfaces.
2. For any `T` that implements `IntoView`—in other words, for any type that Leptos
knows how to render—`Option<T>` and `Result<T, impl Error>` _also_ implement
`IntoView`. And just as `Fn() -> T` renders a reactive `T`, `Fn() -> Option<T>`
and `Fn() -> Result<T, impl Error>` are reactive.
3. Rust has lots of handy helpers like [Option::map](https://doc.rust-lang.org/std/option/enum.Option.html#method.map),
[Option::and_then](https://doc.rust-lang.org/std/option/enum.Option.html#method.and_then),
[Option::ok_or](https://doc.rust-lang.org/std/option/enum.Option.html#method.ok_or),
[Result::map](https://doc.rust-lang.org/std/result/enum.Result.html#method.map),
[Result::ok](https://doc.rust-lang.org/std/result/enum.Result.html#method.ok), and
[bool::then](https://doc.rust-lang.org/std/primitive.bool.html#method.then) that
allow you to convert, in a declarative way, between a few different standard types,
all of which can be rendered. Spending time in the `Option` and `Result` docs in particular
is one of the best ways to level up your Rust game.
4. And always remember: to be reactive, values must be functions. Youll see me constantly
wrap things in a `move ||` closure, below. This is to ensure that they actually re-run
when the signal they depend on changes, keeping the UI reactive.
## So What?
To connect the dots a little: this means that you can actually implement most of
your control flow with native Rust code, without any control-flow components or
special knowledge.
For example, lets start with a simple signal and derived signal:
```rust
let (value, set_value) = create_signal(cx, 0);
let is_odd = move || value() & 1 == 1;
```
> If you dont recognize whats going on with `is_odd`, dont worry about it
> too much. Its just a simple way to test whether an integer is odd by doing a
> bitwise `AND` with `1`.
We can use these signals and ordinary Rust to build most control flow.
### `if` statements
Lets say I want to render some text if the number is odd, and some other text
if its even. Well, how about this?
```rust
view! { cx,
<p>
{move || if is_odd() {
"Odd"
} else {
"Even"
}}
</p>
}
```
An `if` expression returns its value, and a `&str` implements `IntoView`, so a
`Fn() -> &str` implements `IntoView`, so this... just works!
### `Option<T>`
Lets say we want to render some text if its odd, and nothing if its even.
```rust
let message = move || {
if is_odd() {
Some("Ding ding ding!")
} else {
None
}
};
view! { cx,
<p>{message}</p>
}
```
This works fine. We can make it a little shorter if wed like, using `bool::then()`.
```rust
let message = move || is_odd().then(|| "Ding ding ding!");
view! { cx,
<p>{message}</p>
}
```
You could even inline this if youd like, although personally I sometimes like the
better `cargo fmt` and `rust-analyzer` support I get by pulling things out of the `view`.
### `match` statements
Were still just writing ordinary Rust code, right? So you have all the power of Rusts
pattern matching at your disposal.
```rust
let message = move || {
match value() {
0 => "Zero",
1 => "One",
n if is_odd() => "Odd",
_ => "Even"
}
};
view! { cx,
<p>{message}</p>
}
```
And why not? YOLO, right?
## Preventing Over-Rendering
Not so YOLO.
Everything weve just done is basically fine. But theres one thing you should remember
and try to be careful with. Each one of the control-flow functions weve created so far
is basically a derived signal: it will rerun every time the value changes. In the examples
above, where the value switches from even to odd on every change, this is fine.
But consider the following example:
```rust
let (value, set_value) = create_signal(cx, 0);
let message = move || if value() > 5 {
"Big"
} else {
"Small"
};
view! { cx,
<p>{message}</p>
}
```
This _works_, for sure. But if you added a log, you might be surprised
```rust
let message = move || if value() > 5 {
log!("{}: rendering Big", value());
"Big"
} else {
log!("{}: rendering Small", value());
"Small"
};
```
As a user clicks a button, youd see something like this:
```
1: rendering Small
2: rendering Small
3: rendering Small
4: rendering Small
5: rendering Small
6: rendering Big
7: rendering Big
8: rendering Big
... ad infinitum
```
Every time `value` changes, it reruns the `if` statement. This makes sense, with
how reactivity works. But it has a downside. For a simple text node, rerunning
the `if` statement and rerendering isnt a big deal. But imagine it were
like this:
```rust
let message = move || if value() > 5 {
<Big/>
} else {
<Small/>
};
```
This rerenders `<Small/>` five times, then `<Big/>` infinitely. If theyre
loading resources, creating signals, or even just creating DOM nodes, this is
unnecessary work.
### `<Show/>`
The [`<Show/>`](https://docs.rs/leptos/latest/leptos/fn.Show.html) component is
the answer. You pass it a `when` condition function, a `fallback` to be shown if
the `when` function returns `false`, and children to be rendered if `when` is `true`.
```rust
let (value, set_value) = create_signal(cx, 0);
view! { cx,
<Show
when=move || value() > 5
fallback=|cx| view! { cx, <Small/> }
>
<Big/>
</Show>
}
```
`<Show/>` memoizes the `when` condition, so it only renders its `<Small/>` once,
continuing to show the same component until `value` is greater than five;
then it renders `<Big/>` once, continuing to show it indefinitely.
This is a helpful tool to avoid rerendering when using dynamic `if` expressions.
As always, there's some overhead: for a very simple node (like updating a single
text node, or updating a class or attribute), a `move || if ...` will be more
efficient. But if its at all expensive to render either branch, reach for
`<Show/>`.
## Note: Type Conversions
Theres one final thing its important to say in this section.
The `view` macro doesnt return the most-generic wrapping type
[`View`](https://docs.rs/leptos/latest/leptos/enum.View.html).
Instead, it returns things with types like `Fragment` or `HtmlElement<Input>`. This
can be a little annoying if youre returning different HTML elements from
different branches of a conditional:
```rust,compile_error
view! { cx,
<main>
{move || match is_odd() {
true if value() == 1 => {
// returns HtmlElement<Pre>
view! { cx, <pre>"One"</pre> }
},
false if value() == 2 => {
// returns HtmlElement<P>
view! { cx, <p>"Two"</p> }
}
// returns HtmlElement<Textarea>
_ => view! { cx, <textarea>{value()}</textarea> }
}}
</main>
}
```
This strong typing is actually very powerful, because
[`HtmlElement`](https://docs.rs/leptos/0.1.3/leptos/struct.HtmlElement.html) is,
among other things, a smart pointer: each `HtmlElement<T>` type implements
`Deref` for the appropriate underlying `web_sys` type. In other words, in the browser
your `view` returns real DOM elements, and you can access native DOM methods on
them.
But it can be a little annoying in conditional logic like this, because you cant
return different types from different branches of a condition in Rust. There are two ways
to get yourself out of this situation:
1. If you have multiple `HtmlElement` types, convert them to `HtmlElement<AnyElement>`
with [`.into_any()`](https://docs.rs/leptos/latest/leptos/struct.HtmlElement.html#method.into_any)
2. If you have a variety of view types that are not all `HtmlElement`, convert them to
`View`s with [`.into_view(cx)`](https://docs.rs/leptos/latest/leptos/trait.IntoView.html#tymethod.into_view).
Heres the same example, with the conversion added:
```rust,compile_error
view! { cx,
<main>
{move || match is_odd() {
true if value() == 1 => {
// returns HtmlElement<Pre>
view! { cx, <pre>"One"</pre> }.into_any()
},
false if value() == 2 => {
// returns HtmlElement<P>
view! { cx, <p>"Two"</p> }.into_any()
}
// returns HtmlElement<Textarea>
_ => view! { cx, <textarea>{value()}</textarea> }.into_any()
}}
</main>
}
```
<iframe src="https://codesandbox.io/p/sandbox/6-control-flow-in-view-zttwfx?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A1%2C%22endLineNumber%22%3A2%2C%22startColumn%22%3A1%2C%22startLineNumber%22%3A2%7D%5D" width="100%" height="1000px"></iframe>

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<link rel="canonical" href="https://book.leptos.dev/view/07_errors.html">
# Error Handling
[In the last chapter](./06_control_flow.md), we saw that you can render `Option<T>`:
in the `None` case, it will render nothing, and in the `T` case, it will render `T`
(that is, if `T` implements `IntoView`). You can actually do something very similar
with a `Result<T, E>`. In the `Err(_)` case, it will render nothing. In the `Ok(T)`
case, it will render the `T`.
Lets start with a simple component to capture a number input.
```rust
#[component]
fn NumericInput(cx: Scope) -> impl IntoView {
let (value, set_value) = create_signal(cx, Ok(0));
// when input changes, try to parse a number from the input
let on_input = move |ev| set_value(event_target_value(&ev).parse::<i32>());
view! { cx,
<label>
"Type a number (or not!)"
<input type="number" on:input=on_input/>
<p>
"You entered "
<strong>{value}</strong>
</p>
</label>
}
}
```
Every time you change the input, `on_input` will attempt to parse its value into a 32-bit
integer (`i32`), and store it in our `value` signal, which is a `Result<i32, _>`. If you
type the number `42`, the UI will display
```
You entered 42
```
But if you type the string`foo`, it will display
```
You entered
```
This is not great. It saves us using `.unwrap_or_default()` or something, but it would be
much nicer if we could catch the error and do something with it.
You can do that, with the [`<ErrorBoundary/>`](https://docs.rs/leptos/latest/leptos/fn.ErrorBoundary.html)
component.
## `<ErrorBoundary/>`
An `<ErrorBoundary/>` is a little like the `<Show/>` component we saw in the last chapter.
If everythings okay—which is to say, if everything is `Ok(_)`—it renders its children.
But if theres an `Err(_)` rendered among those children, it will trigger the
`<ErrorBoundary/>`s `fallback`.
Lets add an `<ErrorBoundary/>` to this example.
```rust
#[component]
fn NumericInput(cx: Scope) -> impl IntoView {
let (value, set_value) = create_signal(cx, Ok(0));
let on_input = move |ev| set_value(event_target_value(&ev).parse::<i32>());
view! { cx,
<h1>"Error Handling"</h1>
<label>
"Type a number (or something that's not a number!)"
<input type="number" on:input=on_input/>
<ErrorBoundary
// the fallback receives a signal containing current errors
fallback=|cx, errors| view! { cx,
<div class="error">
<p>"Not a number! Errors: "</p>
// we can render a list of errors as strings, if we'd like
<ul>
{move || errors.unwrap()
.get()
.0
.into_iter()
.map(|(_, e)| view! { cx, <li>{e.to_string()}</li>})
.collect::<Vec<_>>()
}
</ul>
</div>
}
>
<p>"You entered " <strong>{value}</strong></p>
</ErrorBoundary>
</label>
}
}
```
Now, if you type `42`, `value` is `Ok(42)` and youll see
```
You entered 42
```
If you type `foo`, value is `Err(_)` and the `fallback` will render. Weve chosen to render
the list of errors as a `String`, so youll see something like
```
Not a number! Errors:
- cannot parse integer from empty string
```
If you fix the error, the error message will disappear and the content youre wrapping in
an `<ErrorBoundary/>` will appear again.
<iframe src="https://codesandbox.io/p/sandbox/7-error-handling-and-error-boundaries-sroncx?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A1%2C%22endLineNumber%22%3A2%2C%22startColumn%22%3A1%2C%22startLineNumber%22%3A2%7D%5D" width="100%" height="1000px"></iframe>

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<meta http-equiv="refresh" content="0; URL=https://book.leptos.dev/view/08_parent_child.html">
<link rel="canonical" href="https://book.leptos.dev/view/08_parent_child.html">
# Parent-Child Communication
You can think of your application as a nested tree of components. Each component
handles its own local state and manages a section of the user interface, so
components tend to be relatively self-contained.
Sometimes, though, youll want to communicate between a parent component and its
child. For example, imagine youve defined a `<FancyButton/>` component that adds
some styling, logging, or something else to a `<button/>`. You want to use a
`<FancyButton/>` in your `<App/>` component. But how can you communicate between
the two?
Its easy to communicate state from a parent component to a child component. We
covered some of this in the material on [components and props](./03_components.md).
Basically if you want the parent to communicate to the child, you can pass a
[`ReadSignal`](https://docs.rs/leptos/latest/leptos/struct.ReadSignal.html), a
[`Signal`](https://docs.rs/leptos/latest/leptos/struct.Signal.html), or even a
[`MaybeSignal`](https://docs.rs/leptos/latest/leptos/struct.MaybeSignal.html) as a prop.
But what about the other direction? How can a child send notifications about events
or state changes back up to the parent?
There are four basic patterns of parent-child communication in Leptos.
## 1. Pass a [`WriteSignal`](https://docs.rs/leptos/latest/leptos/struct.WriteSignal.html)
One approach is simply to pass a `WriteSignal` from the parent down to the child, and update
it in the child. This lets you manipulate the state of the parent from the child.
```rust
#[component]
pub fn App(cx: Scope) -> impl IntoView {
let (toggled, set_toggled) = create_signal(cx, false);
view! { cx,
<p>"Toggled? " {toggled}</p>
<ButtonA setter=set_toggled/>
}
}
#[component]
pub fn ButtonA(cx: Scope, setter: WriteSignal<bool>) -> impl IntoView {
view! { cx,
<button
on:click=move |_| setter.update(|value| *value = !*value)
>
"Toggle"
</button>
}
}
```
This pattern is simple, but you should be careful with it: passing around a `WriteSignal`
can make it hard to reason about your code. In this example, its pretty clear when you
read `<App/>` that you are handing off the ability to mutate `toggled`, but its not at
all clear when or how it will change. In this small, local example its easy to understand,
but if you find yourself passing around `WriteSignal`s like this throughout your code,
you should really consider whether this is making it too easy to write spaghetti code.
## 2. Use a Callback
Another approach would be to pass a callback to the child: say, `on_click`.
```rust
#[component]
pub fn App(cx: Scope) -> impl IntoView {
let (toggled, set_toggled) = create_signal(cx, false);
view! { cx,
<p>"Toggled? " {toggled}</p>
<ButtonB on_click=move |_| set_toggled.update(|value| *value = !*value)/>
}
}
#[component]
pub fn ButtonB<F>(
cx: Scope,
on_click: F,
) -> impl IntoView
where
F: Fn(MouseEvent) + 'static,
{
view! { cx,
<button on:click=on_click>
"Toggle"
</button>
}
}
```
Youll notice that whereas `<ButtonA/>` was given a `WriteSignal` and decided how to mutate it,
`<ButtonB/>` simply fires an event: the mutation happens back in `<App/>`. This has the advantage
of keeping local state local, preventing the problem of spaghetti mutation. But it also means
the logic to mutate that signal needs to exist up in `<App/>`, not down in `<ButtonB/>`. These
are real trade-offs, not a simple right-or-wrong choice.
> Note the way we declare the generic type `F` here for the callback. If youre
> confused, look back at the [generic props](./03_components.html#generic-props) section
> of the chapter on components.
## 3. Use an Event Listener
You can actually write Option 2 in a slightly different way. If the callback maps directly onto
a native DOM event, you can add an `on:` listener directly to the place you use the component
in your `view` macro in `<App/>`.
```rust
#[component]
pub fn App(cx: Scope) -> impl IntoView {
let (toggled, set_toggled) = create_signal(cx, false);
view! { cx,
<p>"Toggled? " {toggled}</p>
// note the on:click instead of on_click
// this is the same syntax as an HTML element event listener
<ButtonC on:click=move |_| set_toggled.update(|value| *value = !*value)/>
}
}
#[component]
pub fn ButtonC<F>(cx: Scope) -> impl IntoView {
view! { cx,
<button>"Toggle"</button>
}
}
```
This lets you write way less code in `<ButtonC/>` than you did for `<ButtonB/>`,
and still gives a correctly-typed event to the listener. This works by adding an
`on:` event listener to each element that `<ButtonC/>` returns: in this case, just
the one `<button>`.
Of course, this only works for actual DOM events that youre passing directly through
to the elements youre rendering in the component. For more complex logic that
doesnt map directly onto an element (say you create `<ValidatedForm/>` and want an
`on_valid_form_submit` callback) you should use Option 2.
## 4. Providing a Context
This version is actually a variant on Option 1. Say you have a deeply-nested component
tree:
```rust
#[component]
pub fn App(cx: Scope) -> impl IntoView {
let (toggled, set_toggled) = create_signal(cx, false);
view! { cx,
<p>"Toggled? " {toggled}</p>
<Layout/>
}
}
#[component]
pub fn Layout(cx: Scope) -> impl IntoView {
view! { cx,
<header>
<h1>"My Page"</h1>
<main>
<Content/>
</main>
}
}
#[component]
pub fn Content(cx: Scope) -> impl IntoView {
view! { cx,
<div class="content">
<ButtonD/>
</div>
}
}
#[component]
pub fn ButtonD<F>(cx: Scope) -> impl IntoView {
todo!()
}
```
Now `<ButtonD/>` is no longer a direct child of `<App/>`, so you cant simply
pass your `WriteSignal` to its props. You could do whats sometimes called
“prop drilling,” adding a prop to each layer between the two:
```rust
#[component]
pub fn App(cx: Scope) -> impl IntoView {
let (toggled, set_toggled) = create_signal(cx, false);
view! { cx,
<p>"Toggled? " {toggled}</p>
<Layout set_toggled/>
}
}
#[component]
pub fn Layout(cx: Scope, set_toggled: WriteSignal<bool>) -> impl IntoView {
view! { cx,
<header>
<h1>"My Page"</h1>
<main>
<Content set_toggled/>
</main>
}
}
#[component]
pub fn Content(cx: Scope, set_toggled: WriteSignal<bool>) -> impl IntoView {
view! { cx,
<div class="content">
<ButtonD set_toggled/>
</div>
}
}
#[component]
pub fn ButtonD<F>(cx: Scope, set_toggled: WriteSignal<bool>) -> impl IntoView {
todo!()
}
```
This is a mess. `<Layout/>` and `<Content/>` dont need `set_toggled`; they just
pass it through to `<ButtonD/>`. But I need to declare the prop in triplicate.
This is not only annoying but hard to maintain: imagine we add a “half-toggled”
option and the type of `set_toggled` needs to change to an `enum`. We have to change
it in three places!
Isnt there some way to skip levels?
There is!
### The Context API
You can provide data that skips levels by using [`provide_context`](https://docs.rs/leptos/latest/leptos/fn.provide_context.html)
and [`use_context`](https://docs.rs/leptos/latest/leptos/fn.use_context.html). Contexts are identified
by the type of the data you provide (in this example, `WriteSignal<bool>`), and they exist in a top-down
tree that follows the contours of your UI tree. In this example, we can use context to skip the
unnecessary prop drilling.
```rust
#[component]
pub fn App(cx: Scope) -> impl IntoView {
let (toggled, set_toggled) = create_signal(cx, false);
// share `set_toggled` with all children of this component
provide_context(cx, set_toggled);
view! { cx,
<p>"Toggled? " {toggled}</p>
<Layout/>
}
}
// <Layout/> and <Content/> omitted
#[component]
pub fn ButtonD(cx: Scope) -> impl IntoView {
// use_context searches up the context tree, hoping to
// find a `WriteSignal<bool>`
// in this case, I .expect() because I know I provided it
let setter = use_context::<WriteSignal<bool>>(cx)
.expect("to have found the setter provided");
view! { cx,
<button
on:click=move |_| setter.update(|value| *value = !*value)
>
"Toggle"
</button>
}
}
```
The same caveats apply to this as to `<ButtonA/>`: passing a `WriteSignal`
around should be done with caution, as it allows you to mutate state from
arbitrary parts of your code. But when done carefully, this can be one of
the most effective techniques for global state management in Leptos: simply
provide the state at the highest level youll need it, and use it wherever
you need it lower down.
Note that there are no performance downsides to this approach. Because you
are passing a fine-grained reactive signal, _nothing happens_ in the intervening
components (`<Layout/>` and `<Content/>`) when you update it. You are communicating
directly between `<ButtonD/>` and `<App/>`. In fact—and this is the power of
fine-grained reactivity—you are communicating directly between a button click
in `<ButtonD/>` and a single text node in `<App/>`. Its as if the components
themselves dont exist at all. And, well... at runtime, they dont. Its just
signals and effects, all the way down.
<iframe src="https://codesandbox.io/p/sandbox/8-parent-child-communication-84we8m?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A1%2C%22endLineNumber%22%3A3%2C%22startColumn%22%3A1%2C%22startLineNumber%22%3A3%7D%5D" width="100%" height="1000px"></iframe>

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<meta http-equiv="refresh" content="0; URL=https://book.leptos.dev/view/09_component_children.html">
<link rel="canonical" href="https://book.leptos.dev/view/09_component_children.html">
# Component Children
Its pretty common to want to pass children into a component, just as you can pass
children into an HTML element. For example, imagine I have a `<FancyForm/>` component
that enhances an HTML `<form>`. I need some way to pass all its inputs.
```rust
view! { cx,
<Form>
<fieldset>
<label>
"Some Input"
<input type="text" name="something"/>
</label>
</fieldset>
<button>"Submit"</button>
</Form>
}
```
How can you do this in Leptos? There are basically two ways to pass components to
other components:
1. **render props**: properties that are functions that return a view
2. the **`children`** prop: a special component property that includes anything
you pass as a child to the component.
In fact, youve already seen these both in action in the [`<Show/>`](/view/06_control_flow.html#show) component:
```rust
view! { cx,
<Show
// `when` is a normal prop
when=move || value() > 5
// `fallback` is a "render prop": a function that returns a view
fallback=|cx| view! { cx, <Small/> }
>
// `<Big/>` (and anything else here)
// will be given to the `children` prop
<Big/>
</Show>
}
```
Lets define a component that takes some children and a render prop.
```rust
#[component]
pub fn TakesChildren<F, IV>(
cx: Scope,
/// Takes a function (type F) that returns anything that can be
/// converted into a View (type IV)
render_prop: F,
/// `children` takes the `Children` type
children: Children,
) -> impl IntoView
where
F: Fn() -> IV,
IV: IntoView,
{
view! { cx,
<h2>"Render Prop"</h2>
{render_prop()}
<h2>"Children"</h2>
{children(cx)}
}
}
```
`render_prop` and `children` are both functions, so we can call them to generate
the appropriate views. `children`, in particular, is an alias for
`Box<dyn FnOnce(Scope) -> Fragment>`. (Aren't you glad we named it `Children` instead?)
> If you need a `Fn` or `FnMut` here because you need to call `children` more than once,
> we also provide `ChildrenFn` and `ChildrenMut` aliases.
We can use the component like this:
```rust
view! { cx,
<TakesChildren render_prop=|| view! { cx, <p>"Hi, there!"</p> }>
// these get passed to `children`
"Some text"
<span>"A span"</span>
</TakesChildren>
}
```
## Manipulating Children
The [`Fragment`](https://docs.rs/leptos/latest/leptos/struct.Fragment.html) type is
basically a way of wrapping a `Vec<View>`. You can insert it anywhere into your view.
But you can also access those inner views directly to manipulate them. For example, heres
a component that takes its children and turns them into an unordered list.
```rust
#[component]
pub fn WrapsChildren(cx: Scope, children: Children) -> impl IntoView {
// Fragment has `nodes` field that contains a Vec<View>
let children = children(cx)
.nodes
.into_iter()
.map(|child| view! { cx, <li>{child}</li> })
.collect::<Vec<_>>();
view! { cx,
<ul>{children}</ul>
}
}
```
Calling it like this will create a list:
```rust
view! { cx,
<WrappedChildren>
"A"
"B"
"C"
</WrappedChildren>
}
```
<iframe src="https://codesandbox.io/p/sandbox/9-component-children-2wrdfd?file=%2Fsrc%2Fmain.rs&selection=%5B%7B%22endColumn%22%3A12%2C%22endLineNumber%22%3A19%2C%22startColumn%22%3A12%2C%22startLineNumber%22%3A19%7D%5D" width="100%" height="1000px"></iframe>

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<link rel="canonical" href="https://book.leptos.dev/view/index.html">
# Building User Interfaces
This first section will introduce you to the basic tools you need to build a reactive
user interface using Leptos. By the end of this section, you should be able to
build a simple, synchronous application that is rendered in the browser.

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extend = [{ path = "./cargo-make/main.toml" }]
[env]
CARGO_MAKE_EXTEND_WORKSPACE_MAKEFILE = true
CARGO_MAKE_CARGO_BUILD_TEST_FLAGS = ""
CARGO_MAKE_WORKSPACE_EMULATION = true
CARGO_MAKE_CRATE_WORKSPACE_MEMBERS = [
"animated_show",
"counter",
"counter_isomorphic",
"counters",
"counters_stable",
"counter_url_query",
"counter_without_macros",
"error_boundary",
"errors_axum",
"fetch",
"hackernews",
"hackernews_axum",
"js-framework-benchmark",
"login_with_token_csr_only",
"parent_child",
"router",
"session_auth_axum",
"slots",
"ssr_modes",
"ssr_modes_axum",
"suspense_tests",
"tailwind_actix",
"tailwind_csr",
"tailwind_axum",
"timer",
"todo_app_sqlite",
"todo_app_sqlite_axum",
"todo_app_sqlite_viz",
"todomvc",
]
[tasks.gen-members]
workspace = false
description = "Generate the list of workspace members"
script = '''
examples=$(ls |
grep -v .md |
grep -v Makefile.toml |
grep -v cargo-make |
grep -v gtk |
jq -R -s -c 'split("\n")[:-1]')
echo "CARGO_MAKE_CRATE_WORKSPACE_MEMBERS = $examples"
'''
[tasks.test-report]
workspace = false
description = "report web testing technology used by examples - OPTION: [all]"
script = '''
set -emu
BOLD="\e[1m"
GREEN="\e[0;32m"
ITALIC="\e[3m"
YELLOW="\e[0;33m"
RESET="\e[0m"
echo
echo "${YELLOW}Web Test Technology${RESET}"
echo
makefile_paths=$(find . -name Makefile.toml -not -path '*/target/*' -not -path '*/node_modules/*' |
sed 's%./%%' |
sed 's%/Makefile.toml%%' |
grep -v Makefile.toml |
sort -u)
start_path=$(pwd)
for path in $makefile_paths; do
cd $path
crate_symbols=
pw_count=$(find . -name playwright.config.ts | wc -l)
while read -r line; do
case $line in
*"cucumber"*)
crate_symbols=$crate_symbols"C"
;;
*"fantoccini"*)
crate_symbols=$crate_symbols"D"
;;
esac
done <"./Cargo.toml"
while read -r line; do
case $line in
*"cargo-make/wasm-test.toml"*)
crate_symbols=$crate_symbols"W"
;;
*"cargo-make/playwright-test.toml"*)
crate_symbols=$crate_symbols"P"
crate_symbols=$crate_symbols"N"
;;
*"cargo-make/playwright-trunk-test.toml"*)
crate_symbols=$crate_symbols"P"
crate_symbols=$crate_symbols"T"
;;
*"cargo-make/trunk_server.toml"*)
crate_symbols=$crate_symbols"T"
;;
*"cargo-make/cargo-leptos-webdriver-test.toml"*)
crate_symbols=$crate_symbols"L"
;;
*"cargo-make/cargo-leptos-test.toml"*)
crate_symbols=$crate_symbols"L"
if [ $pw_count -gt 0 ]; then
crate_symbols=$crate_symbols"P"
fi
;;
esac
done <"./Makefile.toml"
# Sort list of tools
sorted_crate_symbols=$(echo ${crate_symbols} | grep -o . | sort | tr -d "\n")
formatted_crate_symbols="${BOLD}${YELLOW}${sorted_crate_symbols}${RESET}"
crate_line=$path
if [ ! -z ${1+x} ]; then
# Show all examples
if [ ! -z $crate_symbols ]; then
crate_line=$crate_line$formatted_crate_symbols
fi
echo $crate_line
elif [ ! -z $crate_symbols ]; then
# Filter out examples that do not run tests in `ci`
crate_line=$crate_line$formatted_crate_symbols
echo $crate_line
fi
cd ${start_path}
done
c="${BOLD}${YELLOW}C${RESET} = Cucumber"
d="${BOLD}${YELLOW}D${RESET} = WebDriver"
l="${BOLD}${YELLOW}L${RESET} = Cargo Leptos"
n="${BOLD}${YELLOW}N${RESET} = Node"
p="${BOLD}${YELLOW}P${RESET} = Playwright"
t="${BOLD}${YELLOW}T${RESET} = Trunk"
w="${BOLD}${YELLOW}W${RESET} = WASM"
echo
echo "${ITALIC}Keys:${RESET} $c, $d, $l, $n, $p, $t, $w"
echo
'''

47
examples/README.md
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@@ -1,47 +0,0 @@
# Examples README
## Main Branch
The examples in this directory are all built and tested against the current `main` branch.
To the extent that new features have been released or breaking changes have been made since the previous release, the examples are compatible with the `main` branch but not the current release.
To see the examples as they were at the time of the `0.5.0` release, [click here](https://github.com/leptos-rs/leptos/tree/v0.5.0/examples).
## Cargo Make
[Cargo Make](https://sagiegurari.github.io/cargo-make/) is used to build, test, and run examples.
Here are the highlights.
- Extendable custom task files are located in the [cargo-make](./cargo-make/) directory
- Running a task will automatically install `cargo` dependencies
- Each `Makefile.toml` file must extend the [cargo-make/main.toml](./cargo-make/main.toml) file
- [cargo-make](./cargo-make/) files that end in `*-test.toml` configure web testing strategies
- Run `cargo make test-report` to learn which examples have web tests
## Getting Started
Follow these steps to get any example up and running.
1. `cd` to the example root directory
2. Run `cargo make ci` to setup and test the example
3. Run `cargo make start` to run the example
4. Open the client URL in the console output (<http://127.0.0.1:8080> or <http://127.0.0.1:3000> by default)
## Prerequisites
Example projects depend on the following tools. Please install them as needed.
- [Rust](https://www.rust-lang.org/)
- Nightly Rust
- Run `rustup toolchain install nightly`
- Run `rustup target add wasm32-unknown-unknown`
- [Cargo Make](https://sagiegurari.github.io/cargo-make/)
- Run `cargo install --force cargo-make`
- Setup a command alias like `alias cm='cargo make'` to reduce typing (**_Optional_**)
- [Trunk](https://github.com/thedodd/trunk)
- Run `cargo install trunk`
- [Node Version Manager](https://github.com/nvm-sh/nvm/) (**_Optional_**)
- [Node.js](https://nodejs.org/)
- [pnpm](https://pnpm.io/) (**_Optional_**)

68
examples/SSR_NOTES.md
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@@ -1,68 +0,0 @@
# Server Side Rendering
## Cargo Leptos
cargo-leptos is now the easiest and most featureful way to build server side rendered apps with hydration. It provides automatic recompilation of client and server code, wasm optimisation, CSS minification, and more! Check out more about it [here](https://github.com/akesson/cargo-leptos)
1. Install cargo-leptos
```bash
cargo install --locked cargo-leptos
```
2. Build the site in watch mode, recompiling on file changes
```bash
cargo leptos watch
```
Open browser on [http://localhost:3000/](http://localhost:3000/)
3. When ready to deploy, run
```bash
cargo leptos build --release
```
## WASM Pack
To run it as a server side app with hydration, you'll need to have wasm-pack installed.
0. Edit the `[package.metadata.leptos]` section and set `site-root` to `"."`. For examples with CSS you also want to change the path of the `<StyleSheet / >` component in the root component to point towards the CSS file in the root. This tells leptos that the WASM/JS files generated by wasm-pack are available at `./pkg` and that the CSS files are no longer processed by cargo-leptos. Building to alternative folders is not supported at this time. You'll also want to edit the call to `get_configuration()` to pass in `Some(Cargo.toml)`, so that Leptos will read the settings instead of cargo-leptos. If you do so, your file/folder names cannot include dashes.
1. Install wasm-pack
```bash
cargo install wasm-pack
```
2. Build the Webassembly used to hydrate the HTML from the server
```bash
wasm-pack build --target=web --debug --no-default-features --features=hydrate
```
3. Run the server to serve the Webassembly, JS, and HTML
```bash
cargo run --no-default-features --features=ssr
```
### Server Side Rendering With Hydration
To run it as a server side app with hydration, first you should run
```bash
wasm-pack build --target=web --debug --no-default-features --features=hydrate
```
to generate the WebAssembly to hydrate the HTML delivered from the server.
Then run the server with `cargo run` to serve the server side rendered HTML and the WASM bundle for hydration.
```bash
cargo run --no-default-features --features=ssr
```
> Note that if your hydration code changes, you will have to rerun the wasm-pack command above before running
> `cargo run`

14
examples/animated_show/Cargo.toml
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@@ -1,14 +0,0 @@
[package]
name = "animated-show"
version = "0.1.0"
edition = "2021"
[profile.release]
codegen-units = 1
lto = true
[dependencies]
leptos = { path = "../../leptos", features = ["csr"] }
console_log = "1"
log = "0.4"
console_error_panic_hook = "0.1.7"

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