/** * The `effect/match` module provides a type-safe pattern matching system for * TypeScript. Inspired by functional programming, it simplifies conditional * logic by replacing verbose if/else or switch statements with a structured and * expressive API. * * This module supports matching against types, values, and discriminated unions * while enforcing exhaustiveness checking to ensure all cases are handled. * * Although pattern matching is not yet a native JavaScript feature, * `effect/match` offers a reliable implementation that is available today. * * **How Pattern Matching Works** * * Pattern matching follows a structured process: * * - **Creating a matcher**: Define a `Matcher` that operates on either a * specific `Match.type` or `Match.value`. * * - **Defining patterns**: Use combinators such as `Match.when`, `Match.not`, * and `Match.tag` to specify matching conditions. * * - **Completing the match**: Apply a finalizer such as `Match.exhaustive`, * `Match.orElse`, or `Match.option` to determine how unmatched cases should * be handled. * * @since 4.0.0 */ import * as internal from "./internal/matcher.ts" import type * as Option from "./Option.ts" import type { Pipeable } from "./Pipeable.ts" import * as Predicate from "./Predicate.ts" import type * as Result from "./Result.ts" import type * as T from "./Types.ts" import type { Unify } from "./Unify.ts" const TypeId = internal.TypeId /** * Pattern matching follows a structured process: * * - **Creating a matcher**: Define a `Matcher` that operates on either a * specific `Match.type` or `Match.value`. * * - **Defining patterns**: Use combinators such as `Match.when`, `Match.not`, * and `Match.tag` to specify matching conditions. * * - **Completing the match**: Apply a finalizer such as `Match.exhaustive`, * `Match.orElse`, or `Match.option` to determine how unmatched cases should * be handled. * * @example * ```ts * import { Match } from "effect" * * // Simulated dynamic input that can be a string or a number * const input: string | number = "some input" * * // ┌─── string * // ▼ * const result = Match.value(input).pipe( * // Match if the value is a number * Match.when(Match.number, (n) => `number: ${n}`), * // Match if the value is a string * Match.when(Match.string, (s) => `string: ${s}`), * // Ensure all possible cases are covered * Match.exhaustive * ) * * console.log(result) * // Output: "string: some input" * ``` * * @category Model * @since 4.0.0 */ export type Matcher = | TypeMatcher | ValueMatcher /** * Represents a pattern matcher that operates on types rather than specific values. * * A `TypeMatcher` is created when using `Match.type()` and allows you to define * patterns that will be applied to values of the specified type. It maintains * type-level information about the input type, applied filters, remaining cases, * and expected results. * * @example * ```ts * import { Match } from "effect" * * // Create a TypeMatcher for string | number * const matcher = Match.type().pipe( * Match.when(Match.string, (s) => `String: ${s}`), * Match.when(Match.number, (n) => `Number: ${n}`), * Match.exhaustive * ) * * console.log(matcher("hello")) // "String: hello" * console.log(matcher(42)) // "Number: 42" * ``` * * @category models * @since 4.0.0 */ export interface TypeMatcher extends Pipeable { readonly _tag: "TypeMatcher" readonly [TypeId]: { readonly _input: T.Contravariant readonly _filters: T.Covariant readonly _remaining: T.Covariant readonly _result: T.Covariant readonly _return: T.Covariant } readonly cases: ReadonlyArray add(_case: Case): TypeMatcher } /** * Represents a pattern matcher that operates on a specific provided value. * * A `ValueMatcher` is created when using `Match.value(someValue)` and contains * the actual value to be matched against. It tracks both the provided value * and the result of applying patterns to determine matches. * * @example * ```ts * import { Match } from "effect" * * const input = { type: "user", name: "Alice", age: 30 } * * // Create a ValueMatcher for the specific input * const result = Match.value(input).pipe( * Match.when({ type: "user" }, (user) => `User: ${user.name}`), * Match.when({ type: "admin" }, (admin) => `Admin: ${admin.name}`), * Match.orElse(() => "Unknown type") * ) * * console.log(result) // "User: Alice" * ``` * * @category models * @since 4.0.0 */ export interface ValueMatcher extends Pipeable { readonly _tag: "ValueMatcher" readonly [TypeId]: { readonly _input: T.Contravariant readonly _filters: T.Covariant readonly _result: T.Covariant readonly _return: T.Covariant } readonly provided: Provided readonly value: Result.Result add(_case: Case): ValueMatcher } /** * Represents a single pattern matching case. * * A `Case` can be either a positive match (`When`) or a negative match (`Not`). * Cases are the building blocks of pattern matching logic and determine * how values are tested and transformed. * * @example * ```ts * import type { Match } from "effect" * * // Case is a union type representing pattern matching cases * // It combines When (positive) and Not (negative) matching logic * * // When you write this: * // Match.when(pattern, handler) // Creates a When case * // Match.not(pattern, handler) // Creates a Not case * * // The Match module internally uses Case = When | Not * type MyCaseType = Match.Case // When | Not * ``` * * @category models * @since 4.0.0 */ export type Case = When | Not /** * Represents a positive pattern matching case. * * A `When` case contains the logic to test if a value matches a specific pattern * and the function to evaluate when the pattern matches. It's the primary * building block for pattern matching conditions. * * @example * ```ts * import { Match } from "effect" * * // When creates cases that match specific patterns * const stringMatcher = Match.type().pipe( * Match.when(Match.string, (s: string) => `Got string: ${s}`), * Match.when(Match.number, (n: number) => `Got number: ${n}`), * Match.exhaustive * ) * * console.log(stringMatcher("hello")) // "Got string: hello" * console.log(stringMatcher(42)) // "Got number: 42" * ``` * * @category models * @since 4.0.0 */ export interface When { readonly _tag: "When" guard(u: unknown): boolean evaluate(input: unknown): any } /** * Represents a negative pattern matching case. * * A `Not` case contains the logic to test if a value does NOT match a specific * pattern and the function to evaluate when the pattern doesn't match. It's used * for exclusion-based pattern matching. * * @example * ```ts * import { Match } from "effect" * * // Not creates cases that exclude specific patterns * const matcher = Match.type().pipe( * // Match any string except "forbidden" * Match.not("forbidden", (s) => `Allowed: ${s}`), * Match.orElse(() => "This string is forbidden") * ) * * console.log(matcher("hello")) // "Allowed: hello" * console.log(matcher("forbidden")) // "This string is forbidden" * ``` * * @category models * @since 4.0.0 */ export interface Not { readonly _tag: "Not" guard(u: unknown): boolean evaluate(input: unknown): any } /** * Creates a matcher for a specific type. * * **Details** * * This function defines a `Matcher` that operates on a given type, allowing you * to specify conditions for handling different cases. Once the matcher is * created, you can use pattern-matching functions like {@link when} to define * how different values should be processed. * * @example (Matching Numbers and Strings) * * ```ts * import { Match } from "effect" * * // Create a matcher for values that are either strings or numbers * // * // ┌─── (u: string | number) => string * // ▼ * const match = Match.type().pipe( * // Match when the value is a number * Match.when(Match.number, (n) => `number: ${n}`), * // Match when the value is a string * Match.when(Match.string, (s) => `string: ${s}`), * // Ensure all possible cases are handled * Match.exhaustive * ) * * console.log(match(0)) * // Output: "number: 0" * * console.log(match("hello")) * // Output: "string: hello" * ``` * * @see {@link value} for creating a matcher from a specific value. * * @category Creating a matcher * @since 4.0.0 */ export const type: () => Matcher, I, never, never> = internal.type /** * Creates a matcher from a specific value. * * **Details** * * This function allows you to define a `Matcher` directly from a given value, * rather than from a type. This is useful when working with known values, * enabling structured pattern matching on objects, primitives, or any data * structure. * * Once the matcher is created, you can use pattern-matching functions like * {@link when} to define how different cases should be handled. * * @example (Matching an Object by Property) * * ```ts * import { Match } from "effect" * * const input = { name: "John", age: 30 } * * // Create a matcher for the specific object * const result = Match.value(input).pipe( * // Match when the 'name' property is "John" * Match.when( * { name: "John" }, * (user) => `${user.name} is ${user.age} years old` * ), * // Provide a fallback if no match is found * Match.orElse(() => "Oh, not John") * ) * * console.log(result) * // Output: "John is 30 years old" * ``` * * @see {@link type} for creating a matcher from a specific type. * * @category Creating a matcher * @since 4.0.0 */ export const value: ( i: I ) => Matcher, I, never, I> = internal.value /** * Creates a match function for a specific value with discriminated union handling. * * This function provides a convenient way to pattern match on discriminated unions * by providing an object that maps each `_tag` value to its corresponding handler. * It's similar to a switch statement but with better type safety and exhaustiveness checking. * * @example * ```ts * import { Match } from "effect" * * type Status = { readonly _tag: "Success"; readonly data: string } * * const success: Status = { _tag: "Success", data: "Hello" } * * // Simple valueTags usage * const message = Match.valueTags(success, { * Success: (result) => `Success: ${result.data}` * }) * * console.log(message) // "Success: Hello" * ``` * * @category Creating a matcher * @since 4.0.0 */ export const valueTags: { /** * Creates a match function for a specific value with discriminated union handling. * * This function provides a convenient way to pattern match on discriminated unions * by providing an object that maps each `_tag` value to its corresponding handler. * It's similar to a switch statement but with better type safety and exhaustiveness checking. * * @example * ```ts * import { Match } from "effect" * * type Status = { readonly _tag: "Success"; readonly data: string } * * const success: Status = { _tag: "Success", data: "Hello" } * * // Simple valueTags usage * const message = Match.valueTags(success, { * Success: (result) => `Success: ${result.data}` * }) * * console.log(message) // "Success: Hello" * ``` * * @category Creating a matcher * @since 4.0.0 */ < const I, P extends & { readonly [Tag in Types.Tags<"_tag", I> & string]: (_: Extract) => any } & { readonly [Tag in Exclude>]: never } >(fields: P): (input: I) => Unify> /** * Creates a match function for a specific value with discriminated union handling. * * This function provides a convenient way to pattern match on discriminated unions * by providing an object that maps each `_tag` value to its corresponding handler. * It's similar to a switch statement but with better type safety and exhaustiveness checking. * * @example * ```ts * import { Match } from "effect" * * type Status = { readonly _tag: "Success"; readonly data: string } * * const success: Status = { _tag: "Success", data: "Hello" } * * // Simple valueTags usage * const message = Match.valueTags(success, { * Success: (result) => `Success: ${result.data}` * }) * * console.log(message) // "Success: Hello" * ``` * * @category Creating a matcher * @since 4.0.0 */ < const I, P extends & { readonly [Tag in Types.Tags<"_tag", I> & string]: (_: Extract) => any } & { readonly [Tag in Exclude>]: never } >(input: I, fields: P): Unify> } = internal.valueTags /** * Creates a type-safe match function for discriminated unions based on `_tag` field. * * This function allows you to define exhaustive pattern matching for discriminated unions * by providing handlers for each possible `_tag` value. It ensures type safety and * can optionally enforce a specific return type across all branches. * * @example * ```ts * import { Match } from "effect" * * type Result = * | { readonly _tag: "Success"; readonly data: string } * | { readonly _tag: "Error"; readonly message: string } * | { readonly _tag: "Loading" } * * // Create a matcher with specific return type * const formatResult = Match.typeTags()({ * Success: (result) => `Data: ${result.data}`, * Error: (result) => `Error: ${result.message}`, * Loading: () => "Loading..." * }) * * console.log(formatResult({ _tag: "Success", data: "Hello World" })) * // Output: "Data: Hello World" * * console.log(formatResult({ _tag: "Error", message: "Network failed" })) * // Output: "Error: Network failed" * * // Create a matcher with inferred return type * const processResult = Match.typeTags()({ * Success: (result) => ({ type: "ok", value: result.data }), * Error: (result) => ({ type: "error", error: result.message }), * Loading: () => ({ type: "pending" }) * }) * * console.log(processResult({ _tag: "Loading" })) * // Output: { type: "pending" } * ``` * * @category Creating a matcher * @since 4.0.0 */ export const typeTags: { /** * Creates a type-safe match function for discriminated unions based on `_tag` field. * * This function allows you to define exhaustive pattern matching for discriminated unions * by providing handlers for each possible `_tag` value. It ensures type safety and * can optionally enforce a specific return type across all branches. * * @example * ```ts * import { Match } from "effect" * * type Result = * | { readonly _tag: "Success"; readonly data: string } * | { readonly _tag: "Error"; readonly message: string } * | { readonly _tag: "Loading" } * * // Create a matcher with specific return type * const formatResult = Match.typeTags()({ * Success: (result) => `Data: ${result.data}`, * Error: (result) => `Error: ${result.message}`, * Loading: () => "Loading..." * }) * * console.log(formatResult({ _tag: "Success", data: "Hello World" })) * // Output: "Data: Hello World" * * console.log(formatResult({ _tag: "Error", message: "Network failed" })) * // Output: "Error: Network failed" * * // Create a matcher with inferred return type * const processResult = Match.typeTags()({ * Success: (result) => ({ type: "ok", value: result.data }), * Error: (result) => ({ type: "error", error: result.message }), * Loading: () => ({ type: "pending" }) * }) * * console.log(processResult({ _tag: "Loading" })) * // Output: { type: "pending" } * ``` * * @category Creating a matcher * @since 4.0.0 */ (): < P extends & { readonly [Tag in Types.Tags<"_tag", I> & string]: ( _: Extract ) => Ret } & { readonly [Tag in Exclude>]: never } >(fields: P) => (input: I) => Ret /** * Creates a type-safe match function for discriminated unions based on `_tag` field. * * This function allows you to define exhaustive pattern matching for discriminated unions * by providing handlers for each possible `_tag` value. It ensures type safety and * can optionally enforce a specific return type across all branches. * * @example * ```ts * import { Match } from "effect" * * type Result = * | { readonly _tag: "Success"; readonly data: string } * | { readonly _tag: "Error"; readonly message: string } * | { readonly _tag: "Loading" } * * // Create a matcher with specific return type * const formatResult = Match.typeTags()({ * Success: (result) => `Data: ${result.data}`, * Error: (result) => `Error: ${result.message}`, * Loading: () => "Loading..." * }) * * console.log(formatResult({ _tag: "Success", data: "Hello World" })) * // Output: "Data: Hello World" * * console.log(formatResult({ _tag: "Error", message: "Network failed" })) * // Output: "Error: Network failed" * * // Create a matcher with inferred return type * const processResult = Match.typeTags()({ * Success: (result) => ({ type: "ok", value: result.data }), * Error: (result) => ({ type: "error", error: result.message }), * Loading: () => ({ type: "pending" }) * }) * * console.log(processResult({ _tag: "Loading" })) * // Output: { type: "pending" } * ``` * * @category Creating a matcher * @since 4.0.0 */ (): < P extends & { readonly [Tag in Types.Tags<"_tag", I> & string]: ( _: Extract ) => any } & { readonly [Tag in Exclude>]: never } >(fields: P) => (input: I) => Unify> } = internal.typeTags /** * Ensures that all branches of a matcher return a specific type. * * **Details** * * This function enforces a consistent return type across all pattern-matching * branches. By specifying a return type, TypeScript will check that every * matching condition produces a value of the expected type. * * **Important:** This function must be the first step in the matcher pipeline. * If used later, TypeScript will not enforce type consistency correctly. * * @example (Validating Return Type Consistency) * * ```ts * import { Match } from "effect" * * const match = Match.type<{ a: number } | { b: string }>().pipe( * // Ensure all branches return a string * Match.withReturnType(), * // ❌ Type error: 'number' is not assignable to type 'string' * // @ts-expect-error * Match.when({ a: Match.number }, (_) => _.a), * // ✅ Correct: returns a string * Match.when({ b: Match.string }, (_) => _.b), * Match.exhaustive * ) * ``` * * @category utils * @since 4.0.0 */ export const withReturnType: () => ( self: Matcher ) => [Ret] extends [[A] extends [never] ? any : A] ? Matcher : "withReturnType constraint does not extend Result type" = internal.withReturnType /** * Defines a condition for matching values. * * **Details** * * This function enables pattern matching by checking whether a given value * satisfies a condition. It supports both direct value comparisons and * predicate functions. If the condition is met, the associated function is * executed. * * This function is useful when defining matchers that need to check for * specific values or apply logical conditions to determine a match. It works * well with structured objects and primitive types. * * @example (Matching with Values and Predicates) * * ```ts * import { Match } from "effect" * * // Create a matcher for objects with an "age" property * const match = Match.type<{ age: number }>().pipe( * // Match when age is greater than 18 * Match.when( * { age: (age: number) => age > 18 }, * (user: { age: number }) => `Age: ${user.age}` * ), * // Match when age is exactly 18 * Match.when({ age: 18 }, () => "You can vote"), * // Fallback case for all other ages * Match.orElse((user: { age: number }) => `${user.age} is too young`) * ) * * console.log(match({ age: 20 })) * // Output: "Age: 20" * * console.log(match({ age: 18 })) * // Output: "You can vote" * * console.log(match({ age: 4 })) * // Output: "4 is too young" * ``` * * @see {@link whenOr} Use this when multiple patterns should match in a single * condition. * @see {@link whenAnd} Use this when a value must match all provided patterns. * @see {@link orElse} Provides a fallback when no patterns match. * * @category Defining patterns * @since 4.0.0 */ export const when: < R, const P extends Types.PatternPrimitive | Types.PatternBase, Ret, Fn extends (_: Types.WhenMatch) => Ret >( pattern: P, f: Fn ) => ( self: Matcher ) => Matcher< I, Types.AddWithout>, Types.ApplyFilters>>, A | ReturnType, Pr, Ret > = internal.when /** * Matches one of multiple patterns in a single condition. * * **Details** * * This function allows defining a condition where a value matches any of the * provided patterns. If a match is found, the associated function is executed. * It simplifies cases where multiple patterns share the same handling logic. * * Unlike {@link when}, which requires separate conditions for each pattern, * this function enables combining them into a single statement, making the * matcher more concise. * * @example * ```ts * import { Match } from "effect" * * type ErrorType = * | { readonly _tag: "NetworkError"; readonly message: string } * | { readonly _tag: "TimeoutError"; readonly duration: number } * | { readonly _tag: "ValidationError"; readonly field: string } * * const handleError = Match.type().pipe( * Match.whenOr( * { _tag: "NetworkError" }, * { _tag: "TimeoutError" }, * () => "Retry the request" * ), * Match.when({ _tag: "ValidationError" }, (_) => `Invalid field: ${_.field}`), * Match.exhaustive * ) * * console.log(handleError({ _tag: "NetworkError", message: "No connection" })) * // Output: "Retry the request" * * console.log(handleError({ _tag: "ValidationError", field: "email" })) * // Output: "Invalid field: email" * ``` * * @category Defining patterns * @since 4.0.0 */ export const whenOr: < R, const P extends ReadonlyArray | Types.PatternBase>, Ret, Fn extends (_: Types.WhenMatch) => Ret >( ...args: [...patterns: P, f: Fn] ) => ( self: Matcher ) => Matcher< I, Types.AddWithout>, Types.ApplyFilters>>, A | ReturnType, Pr, Ret > = internal.whenOr /** * Matches a value that satisfies all provided patterns. * * **Details** * * This function allows defining a condition where a value must match all the * given patterns simultaneously. If the value satisfies every pattern, the * associated function is executed. * * Unlike {@link when}, which matches a single pattern at a time, this function * ensures that multiple conditions are met before executing the callback. It is * useful when checking for values that need to fulfill multiple criteria at * once. * * @example * ```ts * import { Match } from "effect" * * type User = { readonly age: number; readonly role: "admin" | "user" } * * const checkUser = Match.type().pipe( * Match.whenAnd( * { age: (n) => n >= 18 }, * { role: "admin" }, * () => "Admin access granted" * ), * Match.orElse(() => "Access denied") * ) * * console.log(checkUser({ age: 20, role: "admin" })) * // Output: "Admin access granted" * * console.log(checkUser({ age: 20, role: "user" })) * // Output: "Access denied" * ``` * * @category Defining patterns * @since 4.0.0 */ export const whenAnd: < R, const P extends ReadonlyArray | Types.PatternBase>, Ret, Fn extends (_: Types.WhenMatch>) => Ret >( ...args: [...patterns: P, f: Fn] ) => ( self: Matcher ) => Matcher< I, Types.AddWithout>>, Types.ApplyFilters>>>, A | ReturnType, Pr > = internal.whenAnd /** * Matches values based on a specified discriminant field. * * **Details** * * This function is used to define pattern matching on objects that follow a * **discriminated union** structure, where a specific field (e.g., `type`, * `kind`, `_tag`) determines the variant of the object. It allows matching * multiple values of the discriminant and provides a function to handle the * matched cases. * * @example * ```ts * import { Match, pipe } from "effect" * * const match = pipe( * Match.type< * { type: "A"; a: string } | { type: "B"; b: number } | { * type: "C" * c: boolean * } * >(), * Match.discriminator("type")("A", "B", (_) => `A or B: ${_.type}`), * Match.discriminator("type")("C", (_) => `C(${_.c})`), * Match.exhaustive * ) * ``` * * @category Defining patterns * @since 4.0.0 */ export const discriminator: ( field: D ) => & string, Ret, Fn extends (_: Extract>) => Ret>( ...pattern: [first: P, ...values: Array
, f: Fn] ) => ( self: Matcher ) => Matcher< I, Types.AddWithout>>, Types.ApplyFilters>>>, A | ReturnType, Pr, Ret > = internal.discriminator /** * Matches values where a specified field starts with a given prefix. * * **Details** * * This function is useful for working with discriminated unions where the * discriminant field follows a hierarchical or namespaced structure. It allows * you to match values based on whether the specified field starts with a given * prefix, making it easier to handle grouped cases. * * Instead of checking for exact matches, this function lets you match values * that share a common prefix. For example, if your discriminant field contains * hierarchical names like `"A"`, `"A.A"`, and `"B"`, you can match all values * starting with `"A"` using a single rule. * * @example * ```ts * import { Match, pipe } from "effect" * * const match = pipe( * Match.type<{ type: "A" } | { type: "B" } | { type: "A.A" } | {}>(), * Match.discriminatorStartsWith("type")("A", (_) => 1 as const), * Match.discriminatorStartsWith("type")("B", (_) => 2 as const), * Match.orElse((_) => 3 as const) * ) * * console.log(match({ type: "A" })) // 1 * console.log(match({ type: "B" })) // 2 * console.log(match({ type: "A.A" })) // 1 * ``` * * @category Defining patterns * @since 4.0.0 */ export const discriminatorStartsWith: ( field: D ) => >) => Ret>( pattern: P, f: Fn ) => ( self: Matcher ) => Matcher< I, Types.AddWithout>>, Types.ApplyFilters>>>, A | ReturnType, Pr, Ret > = internal.discriminatorStartsWith /** * Matches values based on a field that serves as a discriminator, mapping each * possible value to a corresponding handler. * * **Details** * * This function simplifies working with discriminated unions by letting you * define a set of handlers for each possible value of a given field. Instead of * chaining multiple calls to {@link discriminator}, this function allows * defining all possible cases at once using an object where the keys are the * possible values of the field, and the values are the corresponding handler * functions. * * @example * ```ts * import { Match, pipe } from "effect" * * const match = pipe( * Match.type< * { type: "A"; a: string } | { type: "B"; b: number } | { * type: "C" * c: boolean * } * >(), * Match.discriminators("type")({ * A: (a) => a.a, * B: (b) => b.b, * C: (c) => c.c * }), * Match.exhaustive * ) * ``` * * @category Defining patterns * @since 4.0.0 */ export const discriminators: ( field: D ) => < R, Ret, P extends & { readonly [Tag in Types.Tags & string]?: ((_: Extract>) => Ret) | undefined } & { readonly [Tag in Exclude>]: never } >( fields: P ) => ( self: Matcher ) => Matcher< I, Types.AddWithout>>, Types.ApplyFilters>>>, A | ReturnType, Pr, Ret > = internal.discriminators /** * Matches values based on a discriminator field and **ensures all cases are * handled**. * * **Details*+ * * This function is similar to {@link discriminators}, but **requires that all * possible cases** are explicitly handled. It is useful when working with * discriminated unions, where a specific field (e.g., `"type"`) determines the * shape of an object. Each possible value of the field must have a * corresponding handler, ensuring **exhaustiveness checking** at compile time. * * This function **does not require** `Match.exhaustive` at the end of the * pipeline because it enforces exhaustiveness by design. * * @example * ```ts * import { Match, pipe } from "effect" * * const match = pipe( * Match.type< * { type: "A"; a: string } | { type: "B"; b: number } | { * type: "C" * c: boolean * } * >(), * Match.discriminatorsExhaustive("type")({ * A: (a) => a.a, * B: (b) => b.b, * C: (c) => c.c * }) * ) * ``` * * @category Defining patterns * @since 4.0.0 */ export const discriminatorsExhaustive: ( field: D ) => < R, Ret, P extends & { readonly [Tag in Types.Tags & string]: (_: Extract>) => Ret } & { readonly [Tag in Exclude>]: never } >( fields: P ) => ( self: Matcher ) => [Pr] extends [never] ? (u: I) => Unify> : Unify > = internal.discriminatorsExhaustive /** * The `Match.tag` function allows pattern matching based on the `_tag` field in * a [Discriminated Union](https://www.typescriptlang.org/docs/handbook/typescript-in-5-minutes-func.html#discriminated-unions). * You can specify multiple tags to match within a single pattern. * * **Note** * * The `Match.tag` function relies on the convention within the Effect ecosystem * of naming the tag field as `"_tag"`. Ensure that your discriminated unions * follow this naming convention for proper functionality. * * @example (Matching a Discriminated Union by Tag) * * ```ts * import { Match } from "effect" * * type Event = * | { readonly _tag: "fetch" } * | { readonly _tag: "success"; readonly data: string } * | { readonly _tag: "error"; readonly error: Error } * | { readonly _tag: "cancel" } * * const match = Match.type().pipe( * // Match either "fetch" or "success" * Match.tag("fetch", "success", () => `Ok!`), * // Match "error" and extract the error message * Match.tag("error", (event) => `Error: ${event.error.message}`), * // Match "cancel" * Match.tag("cancel", () => "Cancelled"), * Match.exhaustive * ) * * console.log(match({ _tag: "success", data: "Hello" })) * // Output: "Ok!" * * console.log(match({ _tag: "error", error: new Error("Oops!") })) * // Output: "Error: Oops!" * ``` * * @category Defining patterns * @since 4.0.0 */ export const tag: < R, P extends Types.Tags<"_tag", R> & string, Ret, Fn extends (_: Extract>) => Ret >( ...pattern: [first: P, ...values: Array
, f: Fn] ) => ( self: Matcher ) => Matcher< I, Types.AddWithout>>, Types.ApplyFilters>>>, ReturnType | A, Pr, Ret > = internal.tag /** * Matches values where the `_tag` field starts with a given prefix. * * **Details** * * This function allows you to match on values in a **discriminated union** * based on whether the `_tag` field starts with a specified prefix. It is * useful for handling hierarchical or namespaced tags, where multiple related * cases share a common prefix. * * @example ```ts * import { pipe } from "effect" * import { Match } from "effect" * * const match = pipe( * Match.type<{ _tag: "A" } | { _tag: "B" } | { _tag: "A.A" } | {}>(), * Match.tagStartsWith("A", (_) => 1 as const), * Match.tagStartsWith("B", (_) => 2 as const), * Match.orElse((_) => 3 as const) * ) * * console.log(match({ _tag: "A" })) // 1 * console.log(match({ _tag: "B" })) // 2 * console.log(match({ _tag: "A.A" })) // 1 * ``` * * @category Defining patterns * @since 4.0.0 */ export const tagStartsWith: < R, P extends string, Ret, Fn extends (_: Extract>) => Ret >( pattern: P, f: Fn ) => ( self: Matcher ) => Matcher< I, Types.AddWithout>>, Types.ApplyFilters>>>, ReturnType | A, Pr, Ret > = internal.tagStartsWith /** * Matches values based on their `_tag` field, mapping each tag to a * corresponding handler. * * **Details** * * This function provides a way to handle discriminated unions by mapping `_tag` * values to specific functions. Each handler receives the matched value and * returns a transformed result. If all possible tags are handled, you can * enforce exhaustiveness using `Match.exhaustive` to ensure no case is missed. * * @example * ```ts * import { Match, pipe } from "effect" * * const match = pipe( * Match.type< * { _tag: "A"; a: string } | { _tag: "B"; b: number } | { * _tag: "C" * c: boolean * } * >(), * Match.tags({ * A: (a) => a.a, * B: (b) => b.b, * C: (c) => c.c * }), * Match.exhaustive * ) * ``` * * @category Defining patterns * @since 4.0.0 */ export const tags: < R, Ret, P extends & { readonly [Tag in Types.Tags<"_tag", R> & string]?: ((_: Extract>) => Ret) | undefined } & { readonly [Tag in Exclude>]: never } >( fields: P ) => ( self: Matcher ) => Matcher< I, Types.AddWithout>>, Types.ApplyFilters>>>, A | ReturnType, Pr, Ret > = internal.tags /** * Matches values based on their `_tag` field and requires handling of all * possible cases. * * **Details** * * This function is designed for **discriminated unions** where every possible * `_tag` value must have a corresponding handler. Unlike {@link tags}, this * function ensures **exhaustiveness**, meaning all cases must be explicitly * handled. If a `_tag` value is missing from the mapping, TypeScript will * report an error. * * @example * ```ts * import { Match, pipe } from "effect" * * const match = pipe( * Match.type< * { _tag: "A"; a: string } | { _tag: "B"; b: number } | { * _tag: "C" * c: boolean * } * >(), * Match.tagsExhaustive({ * A: (a) => a.a, * B: (b) => b.b, * C: (c) => c.c * }) * ) * ``` * * @category Defining patterns * @since 4.0.0 */ export const tagsExhaustive: < R, Ret, P extends & { readonly [Tag in Types.Tags<"_tag", R> & string]: (_: Extract>) => Ret } & { readonly [Tag in Exclude>]: never } >( fields: P ) => ( self: Matcher ) => [Pr] extends [never] ? (u: I) => Unify > : Unify > = internal.tagsExhaustive /** * Excludes a specific value from matching while allowing all others. * * **Details** * * This function is useful when you need to **handle all values except one or * more specific cases**. Instead of listing all possible matches manually, this * function simplifies the logic by allowing you to specify values to exclude. * Any excluded value will bypass the provided function and continue matching * through other cases. * * @example (Ignoring a Specific Value) * * ```ts * import { Match } from "effect" * * // Create a matcher for string or number values * const match = Match.type().pipe( * // Match any value except "hi", returning "ok" * Match.not("hi", () => "ok"), * // Fallback case for when the value is "hi" * Match.orElse(() => "fallback") * ) * * console.log(match("hello")) * // Output: "ok" * * console.log(match("hi")) * // Output: "fallback" * ``` * * @category Defining patterns * @since 4.0.0 */ export const not: < R, const P extends Types.PatternPrimitive | Types.PatternBase, Ret, Fn extends (_: Types.NotMatch) => Ret >( pattern: P, f: Fn ) => ( self: Matcher ) => Matcher< I, Types.AddOnly>, Types.ApplyFilters>>, A | ReturnType, Pr, Ret > = internal.not /** * Matches non-empty strings. * * This predicate matches any string that contains at least one character, * effectively filtering out empty strings (""). * * @example * ```ts * import { Match } from "effect" * * const processInput = Match.type() * .pipe( * Match.when(Match.nonEmptyString, (str) => `Valid input: ${str}`), * Match.orElse(() => "Input cannot be empty") * ) * * console.log(processInput("hello")) * // Output: "Valid input: hello" * * console.log(processInput("")) * // Output: "Input cannot be empty" * * console.log(processInput(" ")) * // Output: "Valid input: " (whitespace-only strings are considered non-empty) * ``` * * @category Predicates * @since 4.0.0 */ export const nonEmptyString: SafeRefinement = internal.nonEmptyString /** * Matches a specific set of literal values (e.g., `Match.is("a", 42, true)`). * * This function creates a predicate that matches any of the provided literal values. * It's useful for matching against multiple specific values in a single pattern. * * @example * ```ts * import { Match } from "effect" * * const handleStatus = Match.type() * .pipe( * Match.when(Match.is("success", "ok", 200), () => "Operation successful"), * Match.when(Match.is("error", "failed", 500), () => "Operation failed"), * Match.when(Match.is(0, false, null), () => "Falsy value"), * Match.orElse((value) => `Unknown status: ${value}`) * ) * * console.log(handleStatus("success")) * // Output: "Operation successful" * * console.log(handleStatus(200)) * // Output: "Operation successful" * * console.log(handleStatus("failed")) * // Output: "Operation failed" * * console.log(handleStatus(0)) * // Output: "Falsy value" * * console.log(handleStatus("pending")) * // Output: "Unknown status: pending" * ``` * * @category Predicates * @since 4.0.0 */ export const is: < Literals extends ReadonlyArray >(...literals: Literals) => SafeRefinement = internal.is /** * Matches values of type `string`. * * This predicate refines unknown values to strings, allowing pattern matching * on string types. It's commonly used in type-based matchers to handle string cases. * * @example * ```ts * import { Match } from "effect" * * const processValue = Match.type().pipe( * Match.when(Match.string, (str) => `String: ${str.toUpperCase()}`), * Match.when(Match.number, (num) => `Number: ${num * 2}`), * Match.when(Match.boolean, (bool) => `Boolean: ${bool ? "yes" : "no"}`), * Match.exhaustive * ) * * console.log(processValue("hello")) // "String: HELLO" * console.log(processValue(42)) // "Number: 84" * console.log(processValue(true)) // "Boolean: yes" * ``` * * @category predicates * @since 4.0.0 */ export const string: Predicate.Refinement = Predicate.isString /** * Matches values of type `number`. * * This predicate refines unknown values to numbers, allowing pattern matching * on numeric types. It matches all number values including integers, floats, * `Infinity`, `-Infinity`, and `NaN`. * * @example * ```ts * import { Match } from "effect" * * const categorizeNumber = Match.type().pipe( * Match.when(Match.number, (num) => { * if (Number.isNaN(num)) return "Not a number" * if (!Number.isFinite(num)) return "Infinite" * if (Number.isInteger(num)) return `Integer: ${num}` * return `Float: ${num.toFixed(2)}` * }), * Match.orElse(() => "Not a number type") * ) * * console.log(categorizeNumber(42)) // "Integer: 42" * console.log(categorizeNumber(3.14)) // "Float: 3.14" * console.log(categorizeNumber(NaN)) // "Not a number" * console.log(categorizeNumber("hello")) // "Not a number type" * ``` * * @category predicates * @since 4.0.0 */ export const number: Predicate.Refinement = Predicate.isNumber /** * Matches any value without restrictions. * * This predicate matches absolutely any value, including `undefined`, `null`, * objects, primitives, functions, etc. It's useful as a catch-all pattern * or when you need to match any remaining cases. * * @example * ```ts * import { Match } from "effect" * * const describeValue = Match.type() * .pipe( * Match.when(Match.string, (str) => `String: ${str}`), * Match.when(Match.number, (num) => `Number: ${num}`), * Match.when(Match.boolean, (bool) => `Boolean: ${bool}`), * Match.when(Match.any, (value) => `Other: ${typeof value}`), * Match.exhaustive * ) * * console.log(describeValue("hello")) * // Output: "String: hello" * * console.log(describeValue(42)) * // Output: "Number: 42" * * console.log(describeValue([1, 2, 3])) * // Output: "Other: object" * * console.log(describeValue(null)) * // Output: "Other: object" * ``` * * @category Predicates * @since 4.0.0 */ export const any: SafeRefinement = internal.any /** * Matches any defined (non-null and non-undefined) value. * * This predicate matches values that are neither `null` nor `undefined`, * effectively filtering out nullish values while preserving all other types. * * @example * ```ts * import { Match } from "effect" * * const processValue = Match.type() * .pipe( * Match.when(Match.defined, (value) => `Defined value: ${value}`), * Match.orElse(() => "Value is null or undefined") * ) * * console.log(processValue("hello")) * // Output: "Defined value: hello" * * console.log(processValue(42)) * // Output: "Defined value: 42" * * console.log(processValue(0)) * // Output: "Defined value: 0" * * console.log(processValue("")) * // Output: "Defined value: " * * console.log(processValue(null)) * // Output: "Value is null or undefined" * * console.log(processValue(undefined)) * // Output: "Value is null or undefined" * ``` * * @category Predicates * @since 4.0.0 */ export const defined: (u: A) => u is A & {} = internal.defined /** * Matches values of type `boolean`. * * This predicate refines unknown values to booleans, allowing pattern matching * on boolean types. It only matches the primitive boolean values `true` and `false`. * * @example * ```ts * import { Match } from "effect" * * const describeTruthiness = Match.type().pipe( * Match.when( * Match.boolean, * (bool) => bool ? "Definitely true" : "Definitely false" * ), * Match.when(0, () => "Falsy number"), * Match.when("", () => "Empty string"), * Match.when(Match.null, () => "Null value"), * Match.orElse(() => "Some other truthy value") * ) * * console.log(describeTruthiness(true)) // "Definitely true" * console.log(describeTruthiness(false)) // "Definitely false" * console.log(describeTruthiness(0)) // "Falsy number" * console.log(describeTruthiness(1)) // "Some other truthy value" * ``` * * @category predicates * @since 4.0.0 */ export const boolean: Predicate.Refinement = Predicate.isBoolean const _undefined: Predicate.Refinement = Predicate.isUndefined export { /** * Matches the value `undefined`. * * @category Predicates * @since 4.0.0 */ _undefined as undefined } const _null: Predicate.Refinement = Predicate.isNull export { /** * Matches the value `null`. * * @category Predicates * @since 4.0.0 */ _null as null } /** * Matches values of type `bigint`. * * This predicate refines unknown values to bigints, allowing pattern matching * on bigint types. BigInts are used for representing integers with arbitrary precision. * * @example * ```ts * import { Match } from "effect" * * const processLargeNumber = Match.type().pipe( * Match.when(Match.bigint, (big) => { * if (big > 9007199254740991n) { * return `Large integer: ${big.toString()}` * } * return `BigInt: ${big.toString()}` * }), * Match.when(Match.number, (num) => `Regular number: ${num}`), * Match.orElse(() => "Not a numeric type") * ) * * console.log(processLargeNumber(123n)) // "BigInt: 123" * console.log(processLargeNumber(9007199254740992n)) // "Large integer: 9007199254740992" * console.log(processLargeNumber(123)) // "Regular number: 123" * console.log(processLargeNumber("123")) // "Not a numeric type" * ``` * * @category predicates * @since 4.0.0 */ export const bigint: Predicate.Refinement = Predicate.isBigInt /** * Matches values of type `symbol`. * * This predicate refines unknown values to symbols, allowing pattern matching * on symbol types. Symbols are unique identifiers that are often used as * object keys or for creating private properties. * * @example * ```ts * import { Match } from "effect" * * const mySymbol = Symbol("my-symbol") * const globalSymbol = Symbol.for("global-symbol") * * const handleSymbol = Match.type().pipe( * Match.when(Match.symbol, (sym) => { * const description = sym.description * if (description) { * return `Symbol with description: ${description}` * } * return "Symbol without description" * }), * Match.orElse(() => "Not a symbol") * ) * * console.log(handleSymbol(mySymbol)) // "Symbol with description: my-symbol" * console.log(handleSymbol(Symbol())) // "Symbol without description" * console.log(handleSymbol("string")) // "Not a symbol" * ``` * * @category predicates * @since 4.0.0 */ export const symbol: Predicate.Refinement = Predicate.isSymbol /** * Matches values that are instances of `Date`. * * This predicate refines unknown values to Date instances, allowing pattern * matching on Date objects. It only matches actual Date instances, not * date strings or timestamps. * * @example * ```ts * import { Match } from "effect" * * const processDateValue = Match.type().pipe( * Match.when(Match.date, (date) => { * if (isNaN(date.getTime())) { * return "Invalid date" * } * return `Date: ${date.toISOString().split("T")[0]}` * }), * Match.when(Match.string, (str) => `Date string: ${str}`), * Match.when( * Match.number, * (num) => `Timestamp: ${new Date(num).toISOString()}` * ), * Match.orElse(() => "Not a date-related value") * ) * * console.log(processDateValue(new Date("2024-01-01"))) // "Date: 2024-01-01" * console.log(processDateValue(new Date("invalid"))) // "Invalid date" * console.log(processDateValue("2024-01-01")) // "Date string: 2024-01-01" * console.log(processDateValue(1704067200000)) // "Timestamp: 2024-01-01T00:00:00.000Z" * ``` * * @category predicates * @since 4.0.0 */ export const date: Predicate.Refinement = Predicate.isDate /** * Matches objects where keys are `string` or `symbol` and values are `unknown`. * * This predicate refines unknown values to record objects, allowing pattern * matching on plain objects. It excludes arrays, functions, dates, and other * special object types, matching only plain objects and object literals. * * @example * ```ts * import { Match } from "effect" * * const analyzeValue = Match.type().pipe( * Match.when(Match.record, (obj) => { * const keys = Object.keys(obj) * const valueCount = keys.length * return `Object with ${valueCount} properties: [${keys.join(", ")}]` * }), * Match.when( * Match.instanceOf(Array), * (arr) => `Array with ${arr.length} items` * ), * Match.when(Match.date, () => "Date object"), * Match.orElse(() => "Not an object") * ) * * console.log(analyzeValue({ name: "Alice", age: 30 })) * // "Object with 2 properties: [name, age]" * console.log(analyzeValue([1, 2, 3])) * // "Array with 3 items" * console.log(analyzeValue(new Date())) * // "Date object" * console.log(analyzeValue("hello")) * // "Not an object" * ``` * * @category predicates * @since 4.0.0 */ export const record: Predicate.Refinement = Predicate.isObject /** * Matches instances of a given class. * * This predicate checks if a value is an instance of the specified constructor, * providing type-safe matching for class instances and built-in objects. * * @example * ```ts * import { Match } from "effect" * * class CustomError extends Error { * constructor(message: string, public code: number) { * super(message) * } * } * * const handleValue = Match.type() * .pipe( * Match.when( * Match.instanceOf(CustomError), * (err) => `Custom error: ${err.message} (code: ${err.code})` * ), * Match.when( * Match.instanceOf(Error), * (err) => `Standard error: ${err.message}` * ), * Match.when(Match.instanceOf(Date), (date) => `Date: ${date.toISOString()}`), * Match.when( * Match.instanceOf(Array), * (arr) => `Array with ${arr.length} items` * ), * Match.orElse((value) => `Other: ${typeof value}`) * ) * * console.log(handleValue(new CustomError("Failed", 404))) * // Output: "Custom error: Failed (code: 404)" * * console.log(handleValue(new Error("Generic error"))) * // Output: "Standard error: Generic error" * * console.log(handleValue(new Date())) * // Output: "Date: 2024-01-01T00:00:00.000Z" * * console.log(handleValue([1, 2, 3])) * // Output: "Array with 3 items" * ``` * * @category Predicates * @since 4.0.0 */ export const instanceOf: any>( constructor: A ) => SafeRefinement, never> = internal.instanceOf /** * Unsafe variant of `instanceOf` that allows matching without type narrowing. * * This predicate checks if a value is an instance of the specified constructor * but doesn't provide the same type safety guarantees as the regular `instanceOf`. * Use this when you need more flexibility but understand the type safety implications. * * @example * ```ts * import { Match } from "effect" * * class CustomError extends Error { * constructor(message: string, public code: number) { * super(message) * } * } * * // When you need to match instances but handle type narrowing manually * const handleError = Match.type().pipe( * Match.when(Match.instanceOfUnsafe(CustomError), (err: any) => { * // Manual type assertion needed * const customErr = err as CustomError * return `Custom error ${customErr.code}: ${customErr.message}` * }), * Match.orElse(() => "Not a CustomError") * ) * ``` * * @category predicates * @since 4.0.0 */ export const instanceOfUnsafe: any>( constructor: A ) => SafeRefinement, InstanceType > = internal.instanceOf /** * Provides a fallback value when no patterns match. * * **Details** * * This function ensures that a matcher always returns a valid result, even if * no defined patterns match. It acts as a default case, similar to the * `default` clause in a `switch` statement or the final `else` in an `if-else` * chain. * * @example (Providing a Default Value When No Patterns Match) * * ```ts * import { Match } from "effect" * * // Create a matcher for string or number values * const match = Match.type().pipe( * // Match when the value is "a" * Match.when("a", () => "ok"), * // Fallback when no patterns match * Match.orElse(() => "fallback") * ) * * console.log(match("a")) * // Output: "ok" * * console.log(match("b")) * // Output: "fallback" * ``` * * @category Completion * @since 4.0.0 */ export const orElse: Ret>( f: F ) => ( self: Matcher ) => [Pr] extends [never] ? (input: I) => Unify | A> : Unify | A> = internal.orElse // TODO(4.0): Rename to "orThrow"? Like Result.getOrThrow /** * Throws an error if no pattern matches. * * **Details** * * This function finalizes a matcher by ensuring that if no patterns match, an * error is thrown. It is useful when all cases should be covered, and any * unexpected input should trigger an error instead of returning a default * value. * * When used, this function removes the need for an explicit fallback case and * ensures that an unmatched value is never silently ignored. * * @example * ```ts * import { Match } from "effect" * * const strictMatcher = Match.type<"a" | "b">().pipe( * Match.when("a", () => "Found A"), * Match.when("b", () => "Found B"), * // Will throw if input is neither "a" nor "b" * Match.orElseAbsurd * ) * * console.log(strictMatcher("a")) // "Found A" * console.log(strictMatcher("b")) // "Found B" * * // This would throw an error at runtime: * // strictMatcher("c" as any) // throws * ``` * * @category completion * @since 4.0.0 */ export const orElseAbsurd: ( self: Matcher ) => [Pr] extends [never] ? (input: I) => Unify : Unify = internal.orElseAbsurd /** * Wraps the match result in a `Result`, distinguishing matched and unmatched * cases. * * **Details** * * This function ensures that the result of a matcher is always wrapped in an * `Result`, allowing clear differentiation between successful matches * (`Ok(value)`) and cases where no pattern matched (`Err(unmatched * value)`). * * This approach is particularly useful when handling optional values or when an * unmatched case should be explicitly handled rather than returning a default * value or throwing an error. * * @example (Extracting a User Role with `Match.result`) * * ```ts * import { Match } from "effect" * * type User = { readonly role: "admin" | "editor" | "viewer" } * * // Create a matcher to extract user roles * const getRole = Match.type().pipe( * Match.when({ role: "admin" }, () => "Has full access"), * Match.when({ role: "editor" }, () => "Can edit content"), * Match.result // Wrap the result in an Result * ) * * console.log(getRole({ role: "admin" })) * // Output: { _id: 'Result', _tag: 'Ok', ok: 'Has full access' } * * console.log(getRole({ role: "viewer" })) * // Output: { _id: 'Result', _tag: 'Err', err: { role: 'viewer' } } * ``` * * @category Completion * @since 4.0.0 */ export const result: ( self: Matcher ) => [Pr] extends [never] ? (input: I) => Result.Result, R> : Result.Result, R> = internal.result /** * Wraps the match result in an `Option`, representing an optional match. * * **Details** * * This function ensures that the result of a matcher is wrapped in an `Option`, * making it easy to handle cases where no pattern matches. If a match is found, * it returns `Some(value)`, otherwise, it returns `None`. * * This is useful in cases where a missing match is expected and should be * handled explicitly rather than throwing an error or returning a default * value. * * @example (Extracting a User Role with `Match.option`) * * ```ts * import { Match } from "effect" * * type User = { readonly role: "admin" | "editor" | "viewer" } * * // Create a matcher to extract user roles * const getRole = Match.type().pipe( * Match.when({ role: "admin" }, () => "Has full access"), * Match.when({ role: "editor" }, () => "Can edit content"), * Match.option // Wrap the result in an Option * ) * * console.log(getRole({ role: "admin" })) * // Output: { _id: 'Option', _tag: 'Some', value: 'Has full access' } * * console.log(getRole({ role: "viewer" })) * // Output: { _id: 'Option', _tag: 'None' } * ``` * * @category Completion * @since 4.0.0 */ export const option: ( self: Matcher ) => [Pr] extends [never] ? (input: I) => Option.Option> : Option.Option> = internal.option /** * The `Match.exhaustive` method finalizes the pattern matching process by * ensuring that all possible cases are accounted for. If any case is missing, * TypeScript will produce a type error. This is particularly useful when * working with unions, as it helps prevent unintended gaps in pattern matching. * * @example (Ensuring All Cases Are Covered) * * ```ts * import { Match } from "effect" * * // Create a matcher for string or number values * const match = Match.type().pipe( * // Match when the value is a number * Match.when(Match.number, (n) => `number: ${n}`), * // Mark the match as exhaustive, ensuring all cases are handled * // TypeScript will throw an error if any case is missing * // @ts-expect-error Type 'string' is not assignable to type 'never' * Match.exhaustive * ) * ``` * * @category Completion * @since 4.0.0 */ export const exhaustive: ( self: Matcher ) => [Pr] extends [never] ? (u: I) => Unify : Unify = internal.exhaustive const SafeRefinementId = "~effect/match/Match/SafeRefinement" /** * A safe refinement that narrows types without runtime errors. * * `SafeRefinement` provides a way to refine types in pattern matching while * maintaining type safety. Unlike regular predicates, safe refinements can * transform the matched value's type without throwing runtime errors. * * @example * ```ts * import { Match } from "effect" * * // Built-in safe refinements * const processValue = Match.type().pipe( * Match.when(Match.string, (s) => s.toUpperCase()), * Match.when(Match.number, (n) => n * 2), * Match.when(Match.defined, (value) => `Defined: ${value}`), * Match.orElse(() => "Undefined or null") * ) * * console.log(processValue("hello")) // "HELLO" * console.log(processValue(21)) // 42 * console.log(processValue(true)) // "Defined: true" * console.log(processValue(null)) // "Undefined or null" * ``` * * @category models * @since 4.0.0 */ export interface SafeRefinement { readonly [SafeRefinementId]: (a: A) => R } const Fail = Symbol.for("effect/Fail") type Fail = typeof Fail /** * A namespace containing utility types for Match operations. * * This namespace provides advanced type-level utilities used internally by the * Match module to perform complex pattern matching, type narrowing, and filter * application. These types enable the sophisticated type inference that makes * pattern matching both type-safe and ergonomic. * * @example * ```ts * import { Match } from "effect" * * // Most users won't need to use Types directly, but it powers the type system: * type MyPattern = Match.Types.PatternBase<{ name: string; age: number }> * type MyWhenMatch = Match.Types.WhenMatch * * // These types are used internally to provide accurate type inference * const matcher = Match.type().pipe( * Match.when(Match.string, (s) => s.length), // s is correctly typed as string * Match.when(Match.number, (n) => n * 2), // n is correctly typed as number * Match.exhaustive * ) * ``` * * @category types * @since 4.0.0 */ export declare namespace Types { /** * Computes the matched type when a pattern P is applied to type R. * * This utility type determines what type a value will have after successfully * matching against a pattern. It handles refinements, predicates, and complex * object patterns to provide accurate type narrowing. * * @example * ```ts * import type { Match } from "effect" * * // WhenMatch computes the narrowed type after pattern matching * type StringMatch = Match.Types.WhenMatch * // Result: string * * type ObjectMatch = Match.Types.WhenMatch< * { type: "user"; name: string } | { * type: "admin" * permissions: Array * }, * { type: "user" } * > * // Result: { type: "user"; name: string } * ``` * * @category types * @since 4.0.0 */ export type WhenMatch = // check for any [0] extends [1 & R] ? ResolvePred
: P extends SafeRefinement ? SP : P extends Predicate.Refinement // try to narrow refinement ? [Extract] extends [infer X] ? [X] extends [never] // fallback to original refinement ? RP : X : never : P extends PredicateA ? PP : ExtractMatch /** * Computes the remaining type when a pattern P is excluded from type R. * * This utility type determines what type remains after a `Match.not` pattern * excludes certain values. It's the complement of `WhenMatch`, calculating * what's left after removing the matched portion. * * @example * ```ts * import type { Match } from "effect" * * // NotMatch computes what remains after exclusion * type NotString = Match.Types.NotMatch< * string | number | boolean, * typeof Match.string * > * // Result: number | boolean * * type NotSpecificValue = Match.Types.NotMatch<"a" | "b" | "c", "a"> * // Result: "b" | "c" * ``` * * @category types * @since 4.0.0 */ export type NotMatch = Exclude>> type PForNotMatch
= [ToInvertedRefinement
] extends [infer X] ? X : never /** * Resolves a pattern to its matched type for use in type computations. * * This utility type processes patterns (predicates, refinements, objects) * and resolves them to their corresponding matched types. It's used internally * to compute type transformations during pattern matching. * * @example * ```ts * import type { Match } from "effect" * * // PForMatch resolves patterns to their matched types * type StringPattern = Match.Types.PForMatch * // Result: string * * type ObjectPattern = Match.Types.PForMatch<{ name: string }> * // Result: { name: string } * ``` * * @category types * @since 4.0.0 */ export type PForMatch
= [ResolvePred
] extends [infer X] ? X : never /** * Computes the excluded type when a pattern P is used for exclusion. * * This utility type determines what should be excluded from a union type * when a pattern is used in filtering operations. It transforms patterns * into their exclusion-safe representations. * * @example * ```ts * import type { Match } from "effect" * * // PForExclude computes what to exclude from type operations * type ExcludeString = Match.Types.PForExclude * // Used internally to filter out string types * * type ExcludeObject = Match.Types.PForExclude<{ type: "admin" }> * // Used internally to filter out admin objects * ``` * * @category types * @since 4.0.0 */ export type PForExclude
= [SafeRefinementR>] extends [infer X] ? X : never // utilities type PredicateA = Predicate.Predicate | Predicate.Refinement type SafeRefinementR = A extends never ? never : A extends SafeRefinement ? R : A extends Function ? A : A extends Record ? { [K in keyof A]: SafeRefinementR } : A type ResolvePred = A extends never ? never : A extends SafeRefinement ? _A : A extends Predicate.Refinement ? P : A extends Predicate.Predicate ? P : A extends Record ? { [K in keyof A]: ResolvePred } : A type ToSafeRefinement = A extends never ? never : A extends Predicate.Refinement ? SafeRefinement : A extends Predicate.Predicate ? SafeRefinement : A extends SafeRefinement ? A : A extends Record ? { [K in keyof A]: ToSafeRefinement } : NonLiteralsTo type ToInvertedRefinement = A extends never ? never : A extends Predicate.Refinement ? SafeRefinement
: A extends Predicate.Predicate ? SafeRefinement : A extends SafeRefinement ? SafeRefinement<_R> : A extends Record ? { [K in keyof A]: ToInvertedRefinement } : NonLiteralsTo type NonLiteralsTo = [A] extends [string | number | boolean | bigint] ? [string] extends [A] ? T : [number] extends [A] ? T : [boolean] extends [A] ? T : [bigint] extends [A] ? T : A : A /** * Defines the structure for complex object and array patterns. * * This type represents patterns that can match against complex data structures * like objects and arrays. It supports nested pattern matching and partial * object matching, enabling sophisticated pattern compositions. * * @example * ```ts * import { Match } from "effect" * * // PatternBase enables complex object patterns * type UserPattern = Match.Types.PatternBase<{ * name: string * age: number * role: "admin" | "user" * }> * // Allows: { name?: string | Predicate, age?: number | Predicate, ... } * * // Example usage: * Match.value({ name: "Alice", age: 30, role: "admin" as const }).pipe( * Match.when( * { age: (n: number) => n >= 18, role: "admin" }, * (user: { name: string; age: number; role: "admin" }) => * `Admin: ${user.name}` * ), * Match.orElse(() => "Not an adult admin") * ) * ``` * * @category types * @since 4.0.0 */ export type PatternBase = A extends ReadonlyArray ? ReadonlyArray | PatternPrimitive : A extends Record ? Partial< { [K in keyof A]: PatternPrimitive | PatternBase } > : never /** * Defines primitive patterns that can match simple values. * * This type represents the building blocks of pattern matching: predicates, * literal values, and safe refinements. These are the atomic patterns that * can be composed into more complex matching logic. * * @example * ```ts * import { Match } from "effect" * * // PatternPrimitive includes various pattern types: * * // Literal values * Match.when("exact", () => "matched exact") * Match.when(42, () => "matched number") * * // Predicates * Match.when(Match.string, (s) => `string: ${s}`) * Match.when((x: number) => x > 10, (n: number) => `large number: ${n}`) * * // Custom refinements * Match.when(Match.defined, (value) => `defined: ${value}`) * ``` * * @category types * @since 4.0.0 */ export type PatternPrimitive = PredicateA | A | SafeRefinement /** * Represents a filter that excludes specific types from a union. * * `Without` is used internally to track which types should be excluded * from consideration during pattern matching. It helps implement the * type-level logic for `Match.not` and other exclusion operations. * * @example * ```ts * import { Match } from "effect" * * // Without is used internally when you write: * Match.type().pipe( * Match.not(Match.string, (value) => `not string: ${value}`), * // At this point, type system uses Without to track exclusion * Match.orElse(() => "was a string") * ) * ``` * * @category types * @since 4.0.0 */ export interface Without { readonly _tag: "Without" readonly _X: X } /** * Represents a filter that includes only specific types from a union. * * `Only` is used internally to track which types should be exclusively * considered during pattern matching. It helps implement the type-level * logic for positive matches and type narrowing. * * @example * ```ts * import { Match } from "effect" * * // Only is used internally when you write: * Match.type().pipe( * Match.when(Match.string, (s) => `string: ${s}`), * // At this point, type system uses Only for the match * Match.orElse((value) => `not string: ${value}`) * ) * ``` * * @category types * @since 4.0.0 */ export interface Only { readonly _tag: "Only" readonly _X: X } /** * Adds a type to the exclusion filter, expanding what should be filtered out. * * This utility type manages the accumulation of excluded types during * pattern matching. When multiple exclusions are applied, it combines * them into a single filter representation. * * @example * ```ts * import { Match } from "effect" * * // AddWithout is used when combining multiple exclusions: * Match.type().pipe( * Match.not(Match.string, () => "not string"), * Match.not(Match.number, () => "not number"), * // Type system uses AddWithout to combine exclusions * Match.orElse(() => "was string or number") * ) * ``` * * @category types * @since 4.0.0 */ export type AddWithout = [A] extends [Without] ? Without : [A] extends [Only] ? Only> : never /** * Adds a type to the inclusion filter, refining what should be included. * * This utility type manages the refinement of included types during * pattern matching. It ensures that only the most specific type * constraints are maintained when multiple positive matches are applied. * * @example * ```ts * import { Match } from "effect" * * // AddOnly is used when refining positive matches: * Match.type<{ type: "user" | "admin"; name: string }>().pipe( * Match.when({ type: "admin" }, (admin) => admin.name), * // Type system uses AddOnly to refine the constraint * Match.orElse(() => "not admin") * ) * ``` * * @category types * @since 4.0.0 */ export type AddOnly = [A] extends [Without] ? [X] extends [WX] ? never : Only : [A] extends [Only] ? [X] extends [OX] ? Only : never : never /** * Applies accumulated filters to an input type, producing the final narrowed type. * * This utility type takes the collected inclusion/exclusion filters and * applies them to the input type to compute the final narrowed result. * It's the culmination of the type-level filtering process. * * @example * ```ts * import type { Match } from "effect" * * // ApplyFilters computes the final narrowed type: * type Result = Match.Types.ApplyFilters< * string | number | boolean, * Match.Types.Only * > * // Result: string * * type ExclusionResult = Match.Types.ApplyFilters< * string | number | boolean, * Match.Types.Without * > * // Result: number | boolean * ``` * * @category types * @since 4.0.0 */ export type ApplyFilters = A extends Only ? X : A extends Without ? Exclude : never /** * Extracts tag values from a discriminated union based on a discriminant field. * * This utility type extracts the possible values of a discriminant field * from a union type. It's used internally to implement tag-based pattern * matching for discriminated unions. * * @example * ```ts * import type { Match } from "effect" * * type Events = * | { _tag: "click"; x: number; y: number } * | { _tag: "keypress"; key: string } * | { _tag: "scroll"; delta: number } * * type EventTags = Match.Types.Tags<"_tag", Events> * // Result: "click" | "keypress" | "scroll" * * type CustomTags = Match.Types.Tags< * "type", * | { type: "user"; name: string } * | { type: "admin"; permissions: Array } * > * // Result: "user" | "admin" * ``` * * @category types * @since 4.0.0 */ export type Tags = P extends Record ? X : never /** * Converts an array type to an intersection of its element types. * * This utility type takes an array of types and converts them into a single * intersection type. It's used internally when multiple patterns need to * be satisfied simultaneously (like in `Match.whenAnd`). * * @example * ```ts * import type { Match } from "effect" * * type Combined = Match.Types.ArrayToIntersection<[ * { name: string }, * { age: number }, * { active: boolean } * ]> * // Result: { name: string } & { age: number } & { active: boolean } * // = { name: string; age: number; active: boolean } * * // This type utility enables complex type intersections * // Complex type operations are handled by this utility type * // for advanced pattern matching scenarios * ``` * * @category types * @since 4.0.0 */ export type ArrayToIntersection > = T.UnionToIntersection< A[number] > /** * Extracts and narrows the matched type from an input type given a pattern. * * This is the core type utility that performs the actual type extraction * and narrowing logic. It handles the complex type-level computation that * determines what type results from applying a pattern to an input type. * * @example * ```ts * import { Match } from "effect" * * type StringExtract = Match.Types.ExtractMatch< * string | number | boolean, * typeof Match.string * > * // Result: string * * type ObjectExtract = Match.Types.ExtractMatch< * { type: "user"; name: string } | { type: "admin"; role: string }, * { type: "user" } * > * // Result: { type: "user"; name: string } * * // This powers the type narrowing in: * Match.when(Match.string, (s) => s.toUpperCase()) * // ^^^ s is correctly typed as string * ``` * * @category types * @since 4.0.0 */ export type ExtractMatch = [ExtractAndNarrow] extends [infer EI] ? EI : never type Replace = A extends Function ? A : A extends Record ? { [K in keyof A]: K extends keyof B ? Replace : A[K] } : [B] extends [A] ? B : A type MaybeReplace = [P] extends [I] ? P : [I] extends [P] ? Replace : Fail type BuiltInObjects = | Function | Date | RegExp | Generator | { readonly [Symbol.toStringTag]: string } type IsPlainObject = T extends BuiltInObjects ? false : T extends Record ? true : false type Simplify = { [K in keyof A]: A[K] } & {} type ExtractAndNarrow = P extends Predicate.Refinement ? _Out extends Input ? Extract<_Out, Input> : Extract : P extends SafeRefinement ? [0] extends [1 & _R] ? Input : _In extends Input ? Extract<_In, Input> : Extract : P extends Predicate.Predicate ? Extract : Input extends infer I ? Exclude< I extends ReadonlyArray ? P extends ReadonlyArray ? { readonly [K in keyof I]: K extends keyof P ? ExtractAndNarrow : I[K] } extends infer R ? Fail extends R[keyof R] ? never : R : never : never : IsPlainObject extends true ? string extends keyof I ? I extends P ? I : never : symbol extends keyof I ? I extends P ? I : never : Simplify< & { [RK in Extract]-?: ExtractAndNarrow } & Omit > extends infer R ? keyof P extends NonFailKeys ? R : never : never : MaybeReplace extends infer R ? [I] extends [R] ? I : R : never, Fail > : never type NonFailKeys = keyof A & {} extends infer K ? K extends keyof A ? A[K] extends Fail ? never : K : never : never }