ASP.NET Core Blazor state management

Note

This isn't the latest version of this article. For the current release, see the ASP.NET Core 8.0 version of this article.

This article describes common approaches for maintaining a user's data (state) while they use an app and across browser sessions.

Note

The code examples in this article adopt nullable reference types (NRTs) and .NET compiler null-state static analysis, which are supported in ASP.NET Core in .NET 6 or later. When targeting ASP.NET Core 5.0 or earlier, remove the null type designation (?) from types in the article's examples.

Throughout this article, the terms server/server-side and client/client-side are used to distinguish locations where app code executes:

  • Server/server-side: Interactive server-side rendering (interactive SSR) of a Blazor Web App.
  • Client/client-side
    • Client-side rendering (CSR) of a Blazor Web App.
    • A Blazor WebAssembly app.

Documentation component examples usually don't configure an interactive render mode with an @rendermode directive in the component's definition file (.razor):

  • In a Blazor Web App, the component must have an interactive render mode applied, either in the component's definition file or inherited from a parent component. For more information, see ASP.NET Core Blazor render modes.

  • In a standalone Blazor WebAssembly app, the components function as shown and don't require a render mode because components always run interactively on WebAssembly in a Blazor WebAssembly app.

When using the Interactive WebAssembly or Interactive Auto render modes, component code sent to the client can be decompiled and inspected. Don't place private code, app secrets, or other sensitive information in client-rendered components.

  • Server/server-side
    • The Server project of a hosted Blazor WebAssembly app.
    • A Blazor Server app.
  • Client/client-side
    • The Client project of a hosted Blazor WebAssembly app.
    • A Blazor WebAssembly app.

For guidance on the purpose and locations of files and folders, see ASP.NET Core Blazor project structure, which also describes the location of the Blazor start script and the location of <head> and <body> content.

The best way to run the demonstration code is to download the BlazorSample_{PROJECT TYPE} sample apps from the Blazor samples GitHub repository that matches the version of .NET that you're targeting. Not all of the documentation examples are currently in the sample apps, but an effort is currently underway to move most of the .NET 8 article examples into the .NET 8 sample apps. This work will be completed in the first quarter of 2024.

Maintain user state

Server-side Blazor is a stateful app framework. Most of the time, the app maintains a connection to the server. The user's state is held in the server's memory in a circuit.

Examples of user state held in a circuit include:

  • The hierarchy of component instances and their most recent render output in the rendered UI.
  • The values of fields and properties in component instances.
  • Data held in dependency injection (DI) service instances that are scoped to the circuit.

User state might also be found in JavaScript variables in the browser's memory set via JavaScript interop calls.

If a user experiences a temporary network connection loss, Blazor attempts to reconnect the user to their original circuit with their original state. However, reconnecting a user to their original circuit in the server's memory isn't always possible:

  • The server can't retain a disconnected circuit forever. The server must release a disconnected circuit after a timeout or when the server is under memory pressure.
  • In multi-server, load-balanced deployment environments, individual servers may fail or be automatically removed when no longer required to handle the overall volume of requests. The original server processing requests for a user may become unavailable when the user attempts to reconnect.
  • The user might close and reopen their browser or reload the page, which removes any state held in the browser's memory. For example, JavaScript variable values set through JavaScript interop calls are lost.

When a user can't be reconnected to their original circuit, the user receives a new circuit with an empty state. This is equivalent to closing and reopening a desktop app.

Persist state across circuits

Generally, maintain state across circuits where users are actively creating data, not simply reading data that already exists.

To preserve state across circuits, the app must persist the data to some other storage location than the server's memory. State persistence isn't automatic. You must take steps when developing the app to implement stateful data persistence.

Data persistence is typically only required for high-value state that users expended effort to create. In the following examples, persisting state either saves time or aids in commercial activities:

  • Multi-step web forms: It's time-consuming for a user to re-enter data for several completed steps of a multi-step web form if their state is lost. A user loses state in this scenario if they navigate away from the form and return later.
  • Shopping carts: Any commercially important component of an app that represents potential revenue can be maintained. A user who loses their state, and thus their shopping cart, may purchase fewer products or services when they return to the site later.

An app can only persist app state. UIs can't be persisted, such as component instances and their render trees. Components and render trees aren't generally serializable. To persist UI state, such as the expanded nodes of a tree view control, the app must use custom code to model the behavior of the UI state as serializable app state.

Where to persist state

Common locations exist for persisting state:

Server-side storage

For permanent data persistence that spans multiple users and devices, the app can use server-side storage. Options include:

  • Blob storage
  • Key-value storage
  • Relational database
  • Table storage

After data is saved, the user's state is retained and available in any new circuit.

For more information on Azure data storage options, see the following:

URL

For transient data representing navigation state, model the data as a part of the URL. Examples of user state modeled in the URL include:

  • The ID of a viewed entity.
  • The current page number in a paged grid.

The contents of the browser's address bar are retained:

  • If the user manually reloads the page.
  • If the web server becomes unavailable, and the user is forced to reload the page in order to connect to a different server.

For information on defining URL patterns with the @page directive, see ASP.NET Core Blazor routing and navigation.

Browser storage

For transient data that the user is actively creating, a commonly used storage location is the browser's localStorage and sessionStorage collections:

  • localStorage is scoped to the browser's window. If the user reloads the page or closes and reopens the browser, the state persists. If the user opens multiple browser tabs, the state is shared across the tabs. Data persists in localStorage until explicitly cleared.
  • sessionStorage is scoped to the browser tab. If the user reloads the tab, the state persists. If the user closes the tab or the browser, the state is lost. If the user opens multiple browser tabs, each tab has its own independent version of the data.

Generally, sessionStorage is safer to use. sessionStorage avoids the risk that a user opens multiple tabs and encounters the following:

  • Bugs in state storage across tabs.
  • Confusing behavior when a tab overwrites the state of other tabs.

localStorage is the better choice if the app must persist state across closing and reopening the browser.

Caveats for using browser storage:

  • Similar to the use of a server-side database, loading and saving data are asynchronous.
  • Unlike a server-side database, storage isn't available during prerendering because the requested page doesn't exist in the browser during the prerendering stage.
  • Storage of a few kilobytes of data is reasonable to persist for server-side Blazor apps. Beyond a few kilobytes, you must consider the performance implications because the data is loaded and saved across the network.
  • Users may view or tamper with the data. ASP.NET Core Data Protection can mitigate the risk. For example, ASP.NET Core Protected Browser Storage uses ASP.NET Core Data Protection.

Third-party NuGet packages provide APIs for working with localStorage and sessionStorage. It's worth considering choosing a package that transparently uses ASP.NET Core Data Protection. Data Protection encrypts stored data and reduces the potential risk of tampering with stored data. If JSON-serialized data is stored in plain text, users can see the data using browser developer tools and also modify the stored data. Securing data isn't always a problem because the data might be trivial in nature. For example, reading or modifying the stored color of a UI element isn't a significant security risk to the user or the organization. Avoid allowing users to inspect or tamper with sensitive data.

ASP.NET Core Protected Browser Storage

ASP.NET Core Protected Browser Storage leverages ASP.NET Core Data Protection for localStorage and sessionStorage.

Note

Protected Browser Storage relies on ASP.NET Core Data Protection and is only supported for server-side Blazor apps.

Warning

Microsoft.AspNetCore.ProtectedBrowserStorage is an unsupported, experimental package that isn't intended for production use.

The package is only available for use in ASP.NET Core 3.1 apps.

Configuration

  1. Add a package reference to Microsoft.AspNetCore.ProtectedBrowserStorage.

    Note

    For guidance on adding packages to .NET apps, see the articles under Install and manage packages at Package consumption workflow (NuGet documentation). Confirm correct package versions at NuGet.org.

  2. In the _Host.cshtml file, add the following script inside the closing </body> tag:

    <script src="_content/Microsoft.AspNetCore.ProtectedBrowserStorage/protectedBrowserStorage.js"></script>
    
  3. In Startup.ConfigureServices, call AddProtectedBrowserStorage to add localStorage and sessionStorage services to the service collection:

    services.AddProtectedBrowserStorage();
    

Save and load data within a component

In any component that requires loading or saving data to browser storage, use the @inject directive to inject an instance of either of the following:

  • ProtectedLocalStorage
  • ProtectedSessionStorage

The choice depends on which browser storage location you wish to use. In the following example, sessionStorage is used:

@using Microsoft.AspNetCore.Components.Server.ProtectedBrowserStorage
@inject ProtectedSessionStorage ProtectedSessionStore
@using Microsoft.AspNetCore.ProtectedBrowserStorage
@inject ProtectedSessionStorage ProtectedSessionStore

The @using directive can be placed in the app's _Imports.razor file instead of in the component. Use of the _Imports.razor file makes the namespace available to larger segments of the app or the whole app.

To persist the currentCount value in the Counter component of an app based on the Blazor project template, modify the IncrementCount method to use ProtectedSessionStore.SetAsync:

private async Task IncrementCount()
{
    currentCount++;
    await ProtectedSessionStore.SetAsync("count", currentCount);
}

In larger, more realistic apps, storage of individual fields is an unlikely scenario. Apps are more likely to store entire model objects that include complex state. ProtectedSessionStore automatically serializes and deserializes JSON data to store complex state objects.

In the preceding code example, the currentCount data is stored as sessionStorage['count'] in the user's browser. The data isn't stored in plain text but rather is protected using ASP.NET Core Data Protection. The encrypted data can be inspected if sessionStorage['count'] is evaluated in the browser's developer console.

To recover the currentCount data if the user returns to the Counter component later, including if the user is on a new circuit, use ProtectedSessionStore.GetAsync:

protected override async Task OnInitializedAsync()
{
    var result = await ProtectedSessionStore.GetAsync<int>("count");
    currentCount = result.Success ? result.Value : 0;
}
protected override async Task OnInitializedAsync()
{
    currentCount = await ProtectedSessionStore.GetAsync<int>("count");
}

If the component's parameters include navigation state, call ProtectedSessionStore.GetAsync and assign a non-null result in OnParametersSetAsync, not OnInitializedAsync. OnInitializedAsync is only called once when the component is first instantiated. OnInitializedAsync isn't called again later if the user navigates to a different URL while remaining on the same page. For more information, see ASP.NET Core Razor component lifecycle.

Warning

The examples in this section only work if the server doesn't have prerendering enabled. With prerendering enabled, an error is generated explaining that JavaScript interop calls cannot be issued because the component is being prerendered.

Either disable prerendering or add additional code to work with prerendering. To learn more about writing code that works with prerendering, see the Handle prerendering section.

Handle the loading state

Since browser storage is accessed asynchronously over a network connection, there's always a period of time before the data is loaded and available to a component. For the best results, render a message while loading is in progress instead of displaying blank or default data.

One approach is to track whether the data is null, which means that the data is still loading. In the default Counter component, the count is held in an int. Make currentCount nullable by adding a question mark (?) to the type (int):

private int? currentCount;

Instead of unconditionally displaying the count and Increment button, display these elements only if the data is loaded by checking HasValue:

@if (currentCount.HasValue)
{
    <p>Current count: <strong>@currentCount</strong></p>
    <button @onclick="IncrementCount">Increment</button>
}
else
{
    <p>Loading...</p>
}

Handle prerendering

During prerendering:

  • An interactive connection to the user's browser doesn't exist.
  • The browser doesn't yet have a page in which it can run JavaScript code.

localStorage or sessionStorage aren't available during prerendering. If the component attempts to interact with storage, an error is generated explaining that JavaScript interop calls cannot be issued because the component is being prerendered.

One way to resolve the error is to disable prerendering. This is usually the best choice if the app makes heavy use of browser-based storage. Prerendering adds complexity and doesn't benefit the app because the app can't prerender any useful content until localStorage or sessionStorage are available.

To disable prerendering, indicate the render mode with the prerender parameter set to false at the highest-level component in the app's component hierarchy that isn't a root component.

Note

Making a root component interactive, such as the App component, isn't supported. Therefore, prerendering can't be disabled directly by the App component.

For apps based on the Blazor Web App project template, prerendering is typically disabled where the Routes component is used in the App component (Components/App.razor):

<Routes @rendermode="new InteractiveServerRenderMode(prerender: false)" />

Also, disable prerendering for the HeadOutlet component:

<HeadOutlet @rendermode="new InteractiveServerRenderMode(prerender: false)" />

For more information, see ASP.NET Core Blazor render modes.

To disable prerendering, open the _Host.cshtml file and change the render-mode attribute of the Component Tag Helper to Server:

<component type="typeof(App)" render-mode="Server" />

When prerendering is disabled, prerendering of <head> content is disabled.

Prerendering might be useful for other pages that don't use localStorage or sessionStorage. To retain prerendering, defer the loading operation until the browser is connected to the circuit. The following is an example for storing a counter value:

@using Microsoft.AspNetCore.Components.Server.ProtectedBrowserStorage
@inject ProtectedLocalStorage ProtectedLocalStore

@if (isConnected)
{
    <p>Current count: <strong>@currentCount</strong></p>
    <button @onclick="IncrementCount">Increment</button>
}
else
{
    <p>Loading...</p>
}

@code {
    private int currentCount;
    private bool isConnected;

    protected override async Task OnAfterRenderAsync(bool firstRender)
    {
        if (firstRender)
        {
            isConnected = true;
            await LoadStateAsync();
            StateHasChanged();
        }
    }

    private async Task LoadStateAsync()
    {
        var result = await ProtectedLocalStore.GetAsync<int>("count");
        currentCount = result.Success ? result.Value : 0;
    }

    private async Task IncrementCount()
    {
        currentCount++;
        await ProtectedLocalStore.SetAsync("count", currentCount);
    }
}
@using Microsoft.AspNetCore.ProtectedBrowserStorage
@inject ProtectedLocalStorage ProtectedLocalStore

@if (isConnected)
{
    <p>Current count: <strong>@currentCount</strong></p>
    <button @onclick="IncrementCount">Increment</button>
}
else
{
    <p>Loading...</p>
}

@code {
    private int currentCount = 0;
    private bool isConnected = false;

    protected override async Task OnAfterRenderAsync(bool firstRender)
    {
        if (firstRender)
        {
            isConnected = true;
            await LoadStateAsync();
            StateHasChanged();
        }
    }

    private async Task LoadStateAsync()
    {
        currentCount = await ProtectedLocalStore.GetAsync<int>("count");
    }

    private async Task IncrementCount()
    {
        currentCount++;
        await ProtectedLocalStore.SetAsync("count", currentCount);
    }
}

Factor out the state preservation to a common location

If many components rely on browser-based storage, implementing state provider code many times creates code duplication. One option for avoiding code duplication is to create a state provider parent component that encapsulates the state provider logic. Child components can work with persisted data without regard to the state persistence mechanism.

In the following example of a CounterStateProvider component, counter data is persisted to sessionStorage:

@using Microsoft.AspNetCore.Components.Server.ProtectedBrowserStorage
@inject ProtectedSessionStorage ProtectedSessionStore

@if (isLoaded)
{
    <CascadingValue Value="this">
        @ChildContent
    </CascadingValue>
}
else
{
    <p>Loading...</p>
}

@code {
    private bool isLoaded;

    [Parameter]
    public RenderFragment? ChildContent { get; set; }

    public int CurrentCount { get; set; }

    protected override async Task OnInitializedAsync()
    {
        var result = await ProtectedSessionStore.GetAsync<int>("count");
        CurrentCount = result.Success ? result.Value : 0;
        isLoaded = true;
    }

    public async Task SaveChangesAsync()
    {
        await ProtectedSessionStore.SetAsync("count", CurrentCount);
    }
}
@using Microsoft.AspNetCore.ProtectedBrowserStorage
@inject ProtectedSessionStorage ProtectedSessionStore

@if (isLoaded)
{
    <CascadingValue Value="this">
        @ChildContent
    </CascadingValue>
}
else
{
    <p>Loading...</p>
}

@code {
    private bool isLoaded;

    [Parameter]
    public RenderFragment ChildContent { get; set; }

    public int CurrentCount { get; set; }

    protected override async Task OnInitializedAsync()
    {
        CurrentCount = await ProtectedSessionStore.GetAsync<int>("count");
        isLoaded = true;
    }

    public async Task SaveChangesAsync()
    {
        await ProtectedSessionStore.SetAsync("count", CurrentCount);
    }
}

Note

For more information on RenderFragment, see ASP.NET Core Razor components.

The CounterStateProvider component handles the loading phase by not rendering its child content until state loading is complete.

To make the state accessible to all components in an app, wrap the CounterStateProvider component around the Router (<Router>...</Router>) in the Routes component with global interactive server-side rendering (interactive SSR).

In the App component (Components/App.razor):

<Routes @rendermode="InteractiveServer" />

In the Routes component (Components/Routes.razor):

To use the CounterStateProvider component, wrap an instance of the component around any other component that requires access to the counter state. To make the state accessible to all components in an app, wrap the CounterStateProvider component around the Router in the App component (App.razor):

<CounterStateProvider>
    <Router ...>
        ...
    </Router>
</CounterStateProvider>

Note

With the release of ASP.NET Core 5.0.1 and for any additional 5.x releases, the Router component includes the PreferExactMatches parameter set to @true. For more information, see Migrate from ASP.NET Core 3.1 to 5.0.

Wrapped components receive and can modify the persisted counter state. The following Counter component implements the pattern:

@page "/counter"

<p>Current count: <strong>@CounterStateProvider?.CurrentCount</strong></p>
<button @onclick="IncrementCount">Increment</button>

@code {
    [CascadingParameter]
    private CounterStateProvider? CounterStateProvider { get; set; }

    private async Task IncrementCount()
    {
        if (CounterStateProvider is not null)
        {
            CounterStateProvider.CurrentCount++;
            await CounterStateProvider.SaveChangesAsync();
        }
    }
}

The preceding component isn't required to interact with ProtectedBrowserStorage, nor does it deal with a "loading" phase.

To deal with prerendering as described earlier, CounterStateProvider can be amended so that all of the components that consume the counter data automatically work with prerendering. For more information, see the Handle prerendering section.

In general, the state provider parent component pattern is recommended:

  • To consume state across many components.
  • If there's just one top-level state object to persist.

To persist many different state objects and consume different subsets of objects in different places, it's better to avoid persisting state globally.

User state created in a Blazor WebAssembly app is held in the browser's memory.

Examples of user state held in browser memory include:

  • The hierarchy of component instances and their most recent render output in the rendered UI.
  • The values of fields and properties in component instances.
  • Data held in dependency injection (DI) service instances.
  • Values set through JavaScript interop calls.

When a user closes and reopens their browser or reloads the page, user state held in the browser's memory is lost.

Note

Protected Browser Storage (Microsoft.AspNetCore.Components.Server.ProtectedBrowserStorage namespace) relies on ASP.NET Core Data Protection and is only supported for server-side Blazor apps.

Persist state across browser sessions

Generally, maintain state across browser sessions where users are actively creating data, not simply reading data that already exists.

To preserve state across browser sessions, the app must persist the data to some other storage location than the browser's memory. State persistence isn't automatic. You must take steps when developing the app to implement stateful data persistence.

Data persistence is typically only required for high-value state that users expended effort to create. In the following examples, persisting state either saves time or aids in commercial activities:

  • Multi-step web forms: It's time-consuming for a user to re-enter data for several completed steps of a multi-step web form if their state is lost. A user loses state in this scenario if they navigate away from the form and return later.
  • Shopping carts: Any commercially important component of an app that represents potential revenue can be maintained. A user who loses their state, and thus their shopping cart, may purchase fewer products or services when they return to the site later.

An app can only persist app state. UIs can't be persisted, such as component instances and their render trees. Components and render trees aren't generally serializable. To persist UI state, such as the expanded nodes of a tree view control, the app must use custom code to model the behavior of the UI state as serializable app state.

Where to persist state

Common locations exist for persisting state:

Server-side storage

For permanent data persistence that spans multiple users and devices, the app can use independent server-side storage accessed via a web API. Options include:

  • Blob storage
  • Key-value storage
  • Relational database
  • Table storage

After data is saved, the user's state is retained and available in any new browser session.

Because Blazor WebAssembly apps run entirely in the user's browser, they require additional measures to access secure external systems, such as storage services and databases. Blazor WebAssembly apps are secured in the same manner as single-page applications (SPAs). Typically, an app authenticates a user via OAuth/OpenID Connect (OIDC) and then interacts with storage services and databases through web API calls to a server-side app. The server-side app mediates the transfer of data between the Blazor WebAssembly app and the storage service or database. The Blazor WebAssembly app maintains an ephemeral connection to the server-side app, while the server-side app has a persistent connection to storage.

For more information, see the following resources:

For more information on Azure data storage options, see the following:

URL

For transient data representing navigation state, model the data as a part of the URL. Examples of user state modeled in the URL include:

  • The ID of a viewed entity.
  • The current page number in a paged grid.

The contents of the browser's address bar are retained if the user manually reloads the page.

For information on defining URL patterns with the @page directive, see ASP.NET Core Blazor routing and navigation.

Browser storage

For transient data that the user is actively creating, a commonly used storage location is the browser's localStorage and sessionStorage collections:

  • localStorage is scoped to the browser's window. If the user reloads the page or closes and reopens the browser, the state persists. If the user opens multiple browser tabs, the state is shared across the tabs. Data persists in localStorage until explicitly cleared.
  • sessionStorage is scoped to the browser tab. If the user reloads the tab, the state persists. If the user closes the tab or the browser, the state is lost. If the user opens multiple browser tabs, each tab has its own independent version of the data.

Note

localStorage and sessionStorage can be used in Blazor WebAssembly apps but only by writing custom code or using a third-party package.

Generally, sessionStorage is safer to use. sessionStorage avoids the risk that a user opens multiple tabs and encounters the following:

  • Bugs in state storage across tabs.
  • Confusing behavior when a tab overwrites the state of other tabs.

localStorage is the better choice if the app must persist state across closing and reopening the browser.

Warning

Users may view or tamper with the data stored in localStorage and sessionStorage.

In-memory state container service

Nested components typically bind data using chained bind as described in ASP.NET Core Blazor data binding. Nested and unnested components can share access to data using a registered in-memory state container. A custom state container class can use an assignable Action to notify components in different parts of the app of state changes. In the following example:

  • A pair of components uses a state container to track a property.
  • One component in the following example is nested in the other component, but nesting isn't required for this approach to work.

Important

The example in this section demonstrates how to create an in-memory state container service, register the service, and use the service in components. The example doesn't persist data without further development. For persistent storage of data, the state container must adopt an underlying storage mechanism that survives when browser memory is cleared. This can be accomplished with localStorage/sessionStorage or some other technology.

StateContainer.cs:

public class StateContainer
{
    private string? savedString;

    public string Property
    {
        get => savedString ?? string.Empty;
        set
        {
            savedString = value;
            NotifyStateChanged();
        }
    }

    public event Action? OnChange;

    private void NotifyStateChanged() => OnChange?.Invoke();
}

Client-side apps (Program file):

builder.Services.AddSingleton<StateContainer>();

Server-side apps (Program file, ASP.NET Core in .NET 6 or later):

builder.Services.AddScoped<StateContainer>();

Server-side apps (Startup.ConfigureServices of Startup.cs, ASP.NET Core earlier than 6.0):

services.AddScoped<StateContainer>();

Shared/Nested.razor:

@implements IDisposable
@inject StateContainer StateContainer

<h2>Nested component</h2>

<p>Nested component Property: <b>@StateContainer.Property</b></p>

<p>
    <button @onclick="ChangePropertyValue">
        Change the Property from the Nested component
    </button>
</p>

@code {
    protected override void OnInitialized()
    {
        StateContainer.OnChange += StateHasChanged;
    }

    private void ChangePropertyValue()
    {
        StateContainer.Property = 
            $"New value set in the Nested component: {DateTime.Now}";
    }

    public void Dispose()
    {
        StateContainer.OnChange -= StateHasChanged;
    }
}

StateContainerExample.razor:

@page "/state-container-example"
@implements IDisposable
@inject StateContainer StateContainer

<h1>State Container Example component</h1>

<p>State Container component Property: <b>@StateContainer.Property</b></p>

<p>
    <button @onclick="ChangePropertyValue">
        Change the Property from the State Container Example component
    </button>
</p>

<Nested />

@code {
    protected override void OnInitialized()
    {
        StateContainer.OnChange += StateHasChanged;
    }

    private void ChangePropertyValue()
    {
        StateContainer.Property = "New value set in the State " +
            $"Container Example component: {DateTime.Now}";
    }

    public void Dispose()
    {
        StateContainer.OnChange -= StateHasChanged;
    }
}

The preceding components implement IDisposable, and the OnChange delegates are unsubscribed in the Dispose methods, which are called by the framework when the components are disposed. For more information, see ASP.NET Core Razor component lifecycle.

Additional approaches

When implementing custom state storage, a useful approach is to adopt cascading values and parameters:

  • To consume state across many components.
  • If there's just one top-level state object to persist.

Troubleshoot

In a custom state management service, a callback invoked outside of Blazor's synchronization context must wrap the logic of the callback in ComponentBase.InvokeAsync to move it onto the renderer's synchronization context.

When the state management service doesn't call StateHasChanged on Blazor's synchronization context, the following error is thrown:

System.InvalidOperationException: 'The current thread is not associated with the Dispatcher. Use InvokeAsync() to switch execution to the Dispatcher when triggering rendering or component state.'

For more information and an example of how to address this error, see ASP.NET Core Razor component rendering.

Additional resources