Danom 1.0.0-alpha2

This is a prerelease version of Danom.
There is a newer version of this package available.
See the version list below for details.
dotnet add package Danom --version 1.0.0-alpha2                
NuGet\Install-Package Danom -Version 1.0.0-alpha2                
This command is intended to be used within the Package Manager Console in Visual Studio, as it uses the NuGet module's version of Install-Package.
<PackageReference Include="Danom" Version="1.0.0-alpha2" />                
For projects that support PackageReference, copy this XML node into the project file to reference the package.
paket add Danom --version 1.0.0-alpha2                
#r "nuget: Danom, 1.0.0-alpha2"                
#r directive can be used in F# Interactive and Polyglot Notebooks. Copy this into the interactive tool or source code of the script to reference the package.
// Install Danom as a Cake Addin
#addin nuget:?package=Danom&version=1.0.0-alpha2&prerelease

// Install Danom as a Cake Tool
#tool nuget:?package=Danom&version=1.0.0-alpha2&prerelease                

Danom

NuGet Version build

Danom is a C# library that provides monadic structures to simplify functional programming patterns in C#, that enforces exhaustive matching by preventing direct value access (this is good).

Key Features

  • Implementation of common monads like Option, Result, and ResultOption.
  • Fluent API for chaining operations.
  • Error handling with monads.
  • Integration with async/await for asynchronous operations.

Design Goals

  • Simplicity: Easy to use API for common monadic operations.
  • Performance: Efficient implementation to minimize overhead.
  • Interoperability: Seamless integration with existing C# code and libraries.
  • Durability: Prevent direct use of internal value, enforcing exhaustive matching.

Getting Started

Install the Danom NuGet package:

PM>  Install-Package Danom

Or using the dotnet CLI

dotnet add package Danom

Quick Start

using Danom;

// Create an Option
var option = Option<int>.Some(5);

option.Match(
    some: x => Console.WriteLine("Value: {0}", x),
    none: () => Console.WriteLine("No value"));

// Create a Result
public Result<int, string> TryDivide(int numerator, int denominator) =>
    denominator == 0
        ? Result<int, string>.Error("Cannot divide by zero")
        : Result<int, string>.Ok(numerator / denominator);

TryDivide(10, 2)
    .Match(
        ok: x => Console.WriteLine("Result: {0}", x),
        error: e => Console.WriteLine("Error: {0}", e));

Option

Represents when an actual value might not exist for a value or named variable. An option has an underlying type and can hold a value of that type, or it might not have a value. Options are a fantastic means of reducing primitive congestion in your code, and they are a much safer way to handle null values and virutally eliminate null reference exceptions.

Creating Options

var option = Option<int>.Some(5);

// or, with no value
var optionNone = Option<int>.None();

// also returns none
var optionNull = Option<object>.Some(default!);

Using Option

Options are commonly used when a operation might not return a value. For example:

public Option<int> TryFind(IEnumerable<int> numbers, Func<int, bool> predicate) =>
    numbers.FirstOrDefault(predicate).ToOption();

With this method defined we can begin performing operations against the Option result:

IEnumerable<int> nums = [1,2,3];

// Exhasutive matching
TryFind(nums, x => x == 1)
    .Match(
        some: x => Console.WriteLine("Found: {0}", x),
        none: () => Console.WriteLine("Did not find number"));

// Mapping the value
Option<int> optionSum =
    TryFind(nums, x => x == 1)
        .Map(x => x + 1);

// Binding the option
Option<int> optionBindSum =
    TryFind(nums, x => x == 1)
        .Bind(num1 =>
            TryFind(nums, x => x == 2)
                .Map(num2 => num1 + num2));

// Handling "None"
Option<int> optionDefault =
    TryFind(nums, x => x == 4)
        .DefaultValue(99);

Option<int> optionDefaultWith =
    TryFind(nums, x => x == 4)
        .DefaultWith(() => 99); // useful if creating the value is expensive

Option<int> optionOrElse =
    TryFind(nums, x => x == 4)
        .OrElse(Option<int>.Some(99));

Option<int> optionOrElseWith =
    TryFind(nums, x => x == 4)
        .OrElseWith(() => Option<int>.Some(99)); // useful if creating the value is expensive

Result

Represents the result of an operation that can either succeed or fail. These results can be chained together allowing you to form error-tolerant pipelines. This lets you break up functionality like this into small pieces which are as composable as you need them to be. Also benefiting from the exhaustive matching.

Creating Results

var result = Result<int, string>.Ok(5);
// or, with an error
var resultError = Result<int, string>.Error("An error occurred");
// or, using the built-in Error type
var resultErrors = Result<int>.Ok(5);
var resultErrorsError = Result<int>.Error("An error occurred");
var resultErrorsMultiError = Result<int>.Error(["An error occurred", "Another error occurred"]);
var resultErrorsTyped = Result<int>.Error(new ResultErrors("error-key", "An error occurred"));

Using Results

Results are commonly used when an operation might not succeed, and you want to manage the expected errors. For example:

public Result<int, string> TryDivide(int numerator, int denominator) =>
    denominator == 0
        ? Result<int, string>.Error("Cannot divide by zero")
        : Result<int, string>.Ok(numerator / denominator);

With this method defined we can begin performing operations against the Result result:

// Exhasutive matching
TryDivide(10, 2)
    .Match(
        ok: x => Console.WriteLine("Result: {0}", x),
        error: e => Console.WriteLine("Error: {0}", e));

// Mapping the value
Result<int, string> resultSum =
    TryDivide(10, 2)
        .Map(x => x + 1);

// Binding the result (i.e., when a nested operation also returns a Result)
Result<int, string> resultBindSum =
    TryDivide(10, 2)
        .Bind(num1 =>
            TryDivide(20, 2)
                .Map(num2 =>
                    num1 + num2));

// Handling errors
Result<int, string> resultDefault =
    TryDivide(10, 0)
        .DefaultValue(99);

Result<int, string> resultDefaultWith =
    TryDivide(10, 0)
        .DefaultWith(() => 99); // useful if creating the value is expensive

Result<int, string> resultOrElse =
    TryDivide(10, 0)
        .OrElse(Result<int, string>.Ok(99));

Result<int, string> resultOrElseWith =
    TryDivide(10, 0)
        .OrElseWith(() =>
            Result<int, string>.Ok(99)); // useful if creating the value is expensive

Since error messages are frequently represented as string collections, often with keys (e.g., for validation), the ResultErrors type is provided to simplify Result creation. The flexible constructor allows errors to be initialized with a single string, a collection of strings, or a key-value pair.

Result<int, ResultErrors> resultErrors = Result<int>.Ok(5);
Result<int, ResultErrors> resultErrorsError = Result<int>.Error("An error occurred");
Result<int, ResultErrors> resultErrorsMultiError = Result<int>.Error(["An error occurred", "Another error occurred"]);
Result<int, ResultErrors> resultErrorsTyped = Result<int>.Error(new ResultErrors("error-key", "An error occurred"));

ResultOption

Represents a combination of the Result and Option monads. This is useful when you want to handle both the success and failure of an operation, but also want to handle the case where a value might not exist. It simplifies the inspection by eliminating the redundant nested Match calls.

Creating ResultOptions

var resultOption = ResultOption<int, string>.Ok(5);
// or, with an error
var resultOptionError = ResultOption<int, string>.Error("An error occurred");
// or, with no value
var resultOptionNone = ResultOption<int, string>.None();

Using ResultOptions

ResultOptions are commonly used when an operation might not succeed, but also where a value might not exist. For example:

public Option<int> LookupUserId(string username) => // ...

public ResultOption<int, string> GetUserId(string username)
{
    if(username == "admin")
    {
        return ResultOption<int,string>.Error("Invalid username");
    }

    return LookupUserId(username).Match(
        some: id => ResultOption<int, string>.Ok(1) :
        none: ResultOption<int, string>.None);

    // or, using the extension method
    // return LookupUserId(username).ToResultOption();
}

Contribute

Thank you for considering contributing to Danom, and to those who have already contributed! We appreciate (and actively resolve) PRs of all shapes and sizes.

We kindly ask that before submitting a pull request, you first submit an issue or open a discussion.

If functionality is added to the API, or changed, please kindly update the relevant document. Unit tests must also be added and/or updated before a pull request can be successfully merged.

Only pull requests which pass all build checks and comply with the general coding guidelines can be approved.

If you have any further questions, submit an issue or open a discussion.

Find a bug?

There's an issue for that.

License

Built with ♥ by Pim Brouwers in Toronto, ON. Licensed under Apache License 2.0.

Product Compatible and additional computed target framework versions.
.NET net8.0 is compatible.  net8.0-android was computed.  net8.0-browser was computed.  net8.0-ios was computed.  net8.0-maccatalyst was computed.  net8.0-macos was computed.  net8.0-tvos was computed.  net8.0-windows was computed. 
Compatible target framework(s)
Included target framework(s) (in package)
Learn more about Target Frameworks and .NET Standard.
  • net8.0

    • No dependencies.

NuGet packages (2)

Showing the top 2 NuGet packages that depend on Danom:

Package Downloads
Danom.Mvc

ASP.NET Core MVC helpers for Danom.

Danom.Validation

Validators and validation helpers for Danom based on FluentValidation.

GitHub repositories

This package is not used by any popular GitHub repositories.

Version Downloads Last updated
1.0.0 75 11/18/2024
1.0.0-beta1 98 10/11/2024
1.0.0-alpha3 90 8/31/2024
1.0.0-alpha2 90 8/30/2024
1.0.0-alpha1 75 8/28/2024