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/** * The `Effect<A, E, R>` type is polymorphic in values of type `E` and we can * work with any error type that we want. However, there is a lot of information * that is not inside an arbitrary `E` value. So as a result, an `Effect` needs * somewhere to store things like unexpected errors or defects, stack and * execution traces, causes of fiber interruptions, and so forth. * * Effect-TS is very strict about preserving the full information related to a * failure. It captures all type of errors into the `Cause` data type. `Effect` * uses the `Cause<E>` data type to store the full story of failure. So its * error model is lossless. It doesn't throw information related to the failure * result. So we can figure out exactly what happened during the operation of * our effects. * * It is important to note that `Cause` is an underlying data type representing * errors occuring within an `Effect` workflow. Thus, we don't usually deal with * `Cause`s directly. Even though it is not a data type that we deal with very * often, the `Cause` of a failing `Effect` workflow can be accessed at any * time, which gives us total access to all parallel and sequential errors in * occurring within our codebase. * * @since 2.0.0 */ import type * as Channel from "./Channel.js"; import type * as Chunk from "./Chunk.js"; import type * as Effect from "./Effect.js"; import type * as Either from "./Either.js"; import type * as Equal from "./Equal.js"; import type * as FiberId from "./FiberId.js"; import type * as HashSet from "./HashSet.js"; import type { Inspectable } from "./Inspectable.js"; import type * as Option from "./Option.js"; import type { Pipeable } from "./Pipeable.js"; import type { Predicate, Refinement } from "./Predicate.js"; import type * as Sink from "./Sink.js"; import type * as Stream from "./Stream.js"; import type { Span } from "./Tracer.js"; import type { Covariant, NoInfer } from "./Types.js"; /** * A unique symbol identifying the `Cause` type. * * **Details** * * This provides a symbol that helps identify instances of the `Cause` data * type. This can be used for advanced operations such as refining types or * building internal utilities that check whether an unknown value is a `Cause`. * * @see {@link isCause} Check if a value is a `Cause` * * @since 2.0.0 * @category Symbols */ export declare const CauseTypeId: unique symbol; /** * @since 2.0.0 * @category Symbols */ export type CauseTypeId = typeof CauseTypeId; /** * A unique symbol identifying the `RuntimeException` type. * * **Details** * * This provides a symbol that identifies a `RuntimeException`. This is * typically used internally by the library to recognize checked exceptions that * occur during runtime. * * @see {@link RuntimeException} Create or work with a `RuntimeException` * * @since 2.0.0 * @category Symbols */ export declare const RuntimeExceptionTypeId: unique symbol; /** * @since 2.0.0 * @category Symbols */ export type RuntimeExceptionTypeId = typeof RuntimeExceptionTypeId; /** * A unique symbol identifying the `InterruptedException` type. * * **Details** * * This provides a symbol that identifies an `InterruptedException`. This is * typically used internally to recognize when a fiber has been interrupted, * helping the framework handle interruption logic correctly. * * @see {@link InterruptedException} Create or work with an `InterruptedException` * * @since 2.0.0 * @category Symbols */ export declare const InterruptedExceptionTypeId: unique symbol; /** * @since 2.0.0 * @category Symbols */ export type InterruptedExceptionTypeId = typeof InterruptedExceptionTypeId; /** * A unique symbol identifying the `IllegalArgumentException` type. * * **Details** * * This provides a symbol that identifies an `IllegalArgumentException`. This is * often used in scenarios where invalid arguments are supplied to methods that * expect specific input. * * @see {@link IllegalArgumentException} Create or work with an `IllegalArgumentException` * * @since 2.0.0 * @category Symbols */ export declare const IllegalArgumentExceptionTypeId: unique symbol; /** * @since 2.0.0 * @category Symbols */ export type IllegalArgumentExceptionTypeId = typeof IllegalArgumentExceptionTypeId; /** * A unique symbol identifying the `NoSuchElementException` type. * * **Details** * * This provides a symbol that identifies a `NoSuchElementException`. It helps * differentiate cases where a required element is missing within a data * structure. * * @see {@link NoSuchElementException} Create or work with a `NoSuchElementException` * * @since 2.0.0 * @category Symbols */ export declare const NoSuchElementExceptionTypeId: unique symbol; /** * @since 2.0.0 * @category Symbols */ export type NoSuchElementExceptionTypeId = typeof NoSuchElementExceptionTypeId; /** * A unique symbol identifying the `InvalidPubSubCapacityException` type. * * **Details** * * This provides a symbol that identifies an `InvalidPubSubCapacityException`. * It indicates an error related to an invalid capacity passed to a `PubSub` * structure. * * @see {@link InvalidPubSubCapacityException} Create or work with an `InvalidPubSubCapacityException` * * @since 2.0.0 * @category Symbols */ export declare const InvalidPubSubCapacityExceptionTypeId: unique symbol; /** * @since 2.0.0 * @category Symbols */ export type InvalidPubSubCapacityExceptionTypeId = typeof InvalidPubSubCapacityExceptionTypeId; /** * A unique symbol identifying the `ExceededCapacityException` type. * * **Details** * * This provides a symbol that identifies an `ExceededCapacityException`. It * denotes situations where a resource has exceeded its configured capacity * limit. * * @see {@link ExceededCapacityException} Create or work with an `ExceededCapacityException` * * @since 3.5.0 * @category Symbols */ export declare const ExceededCapacityExceptionTypeId: unique symbol; /** * @since 3.5.0 * @category Symbols */ export type ExceededCapacityExceptionTypeId = typeof ExceededCapacityExceptionTypeId; /** * A unique symbol identifying the `TimeoutException` type. * * **Details** * * This provides a symbol that identifies a `TimeoutException`. It helps the * framework recognize errors related to operations that fail to complete within * a given timeframe. * * @see {@link TimeoutException} Create or work with a `TimeoutException` * * @since 2.0.0 * @category Symbols */ export declare const TimeoutExceptionTypeId: unique symbol; /** * @since 2.0.0 * @category Symbols */ export type TimeoutExceptionTypeId = typeof TimeoutExceptionTypeId; /** * A unique symbol identifying the `UnknownException` type. * * **Details** * * This provides a symbol that identifies an `UnknownException`. It is typically * used for generic or unexpected errors that do not fit other specific * exception categories. * * @see {@link UnknownException} Create or work with an `UnknownException` * * @since 2.0.0 * @category Symbols */ export declare const UnknownExceptionTypeId: unique symbol; /** * @since 2.0.0 * @category Symbols */ export type UnknownExceptionTypeId = typeof UnknownExceptionTypeId; /** * Represents the full history of a failure within an `Effect`. * * **Details** * * This type is a data structure that captures all information about why and how * an effect has failed, including parallel errors, sequential errors, defects, * and interruptions. It enables a "lossless" error model: no error-related * information is discarded, which helps in debugging and understanding the root * cause of failures. * * @since 2.0.0 * @category Models */ export type Cause<E> = Empty | Fail<E> | Die | Interrupt | Sequential<E> | Parallel<E>; /** * @since 2.0.0 */ export declare namespace Cause { /** * This interface is used internally to manage the type variance of `Cause`. * * @since 2.0.0 * @category Models */ interface Variance<out E> { readonly [CauseTypeId]: { readonly _E: Covariant<E>; }; } } /** * Describes methods for reducing a `Cause<E>` into a value of type `Z` with * access to contextual information. * * **Details** * * This interface is meant for advanced transformations of `Cause`. By * implementing each method, you can define how different parts of the `Cause` * structure (like `Fail`, `Die`, or `Interrupt`) should be transformed into a * final type `Z`. The `context` parameter carries additional data needed during * this reduction. * * @see {@link reduceWithContext} Apply a `CauseReducer` to transform a `Cause` * * @since 2.0.0 * @category Models */ export interface CauseReducer<in C, in E, in out Z> { emptyCase(context: C): Z; failCase(context: C, error: E): Z; dieCase(context: C, defect: unknown): Z; interruptCase(context: C, fiberId: FiberId.FiberId): Z; sequentialCase(context: C, left: Z, right: Z): Z; parallelCase(context: C, left: Z, right: Z): Z; } /** * Represents an error object that can be yielded in `Effect.gen`. * * @since 2.0.0 * @category Models */ export interface YieldableError extends Pipeable, Inspectable, Error { readonly [Effect.EffectTypeId]: Effect.Effect.VarianceStruct<never, this, never>; readonly [Stream.StreamTypeId]: Stream.Stream.VarianceStruct<never, this, never>; readonly [Sink.SinkTypeId]: Sink.Sink.VarianceStruct<never, unknown, never, this, never>; readonly [Channel.ChannelTypeId]: Channel.Channel.VarianceStruct<never, unknown, this, unknown, never, unknown, never>; [Symbol.iterator](): Effect.EffectGenerator<Effect.Effect<never, this, never>>; } /** * Creates an error that occurs at runtime, extendable for other exception * types. * * @since 2.0.0 * @category Errors */ export declare const YieldableError: new (message?: string | undefined) => YieldableError; /** * An error representing a runtime error. * * **Details** * * This interface is used for errors that occur at runtime but are still * considered recoverable or typed. * * @since 2.0.0 * @category Models */ export interface RuntimeException extends YieldableError { readonly _tag: "RuntimeException"; readonly [RuntimeExceptionTypeId]: RuntimeExceptionTypeId; } /** * An error representing fiber interruption. * * **Details** * * This interface represents errors that occur when a fiber is forcefully * interrupted. Interruption can happen for various reasons, including * cancellations or system directives to halt operations. Code that deals with * concurrency might need to catch or handle these to ensure proper cleanup. * * @since 2.0.0 * @category Models */ export interface InterruptedException extends YieldableError { readonly _tag: "InterruptedException"; readonly [InterruptedExceptionTypeId]: InterruptedExceptionTypeId; } /** * An error representing an invalid argument passed to a method. * * **Details** * * This interface is used for signaling that a function or method received an * argument that does not meet its preconditions. * * @since 2.0.0 * @category Models */ export interface IllegalArgumentException extends YieldableError { readonly _tag: "IllegalArgumentException"; readonly [IllegalArgumentExceptionTypeId]: IllegalArgumentExceptionTypeId; } /** * An error that occurs when an expected element is missing. * * **Details** * * This interface indicates scenarios like looking up an item in a collection * or searching for data that should be present but isn't. It helps your code * signal a more specific issue rather than a general error. * * @since 2.0.0 * @category Models */ export interface NoSuchElementException extends YieldableError { readonly _tag: "NoSuchElementException"; readonly [NoSuchElementExceptionTypeId]: NoSuchElementExceptionTypeId; } /** * An error indicating invalid capacity for a `PubSub`. * * @since 2.0.0 * @category Models */ export interface InvalidPubSubCapacityException extends YieldableError { readonly _tag: "InvalidPubSubCapacityException"; readonly [InvalidPubSubCapacityExceptionTypeId]: InvalidPubSubCapacityExceptionTypeId; } /** * An error that occurs when resource capacity is exceeded. * * @since 3.5.0 * @category Models */ export interface ExceededCapacityException extends YieldableError { readonly _tag: "ExceededCapacityException"; readonly [ExceededCapacityExceptionTypeId]: ExceededCapacityExceptionTypeId; } /** * An error representing a computation that timed out. * * @since 2.0.0 * @category Models */ export interface TimeoutException extends YieldableError { readonly _tag: "TimeoutException"; readonly [TimeoutExceptionTypeId]: TimeoutExceptionTypeId; } /** * A checked exception for handling unknown or unexpected errors. * * **Details** * * This interface captures errors that don't fall under known categories. It is * especially helpful for wrapping low-level or third-party library errors that * might provide little or no context, such as from a rejected promise. * * @since 2.0.0 * @category Models */ export interface UnknownException extends YieldableError { readonly _tag: "UnknownException"; readonly [UnknownExceptionTypeId]: UnknownExceptionTypeId; readonly error: unknown; } /** * Represents a lack of errors within a `Cause`. * * @see {@link empty} Construct a new `Empty` cause * @see {@link isEmptyType} Check if a `Cause` is an `Empty` type * * @since 2.0.0 * @category Models */ export interface Empty extends Cause.Variance<never>, Equal.Equal, Pipeable, Inspectable { readonly _tag: "Empty"; } /** * Represents an expected error within a `Cause`. * * **Details** * * This interface models a `Cause` that carries an expected or known error of * type `E`. For example, if you validate user input and find it invalid, you * might store that error within a `Fail`. * * @see {@link fail} Construct a `Fail` cause * @see {@link isFailType} Check if a `Cause` is a `Fail` * * @since 2.0.0 * @category Models */ export interface Fail<out E> extends Cause.Variance<E>, Equal.Equal, Pipeable, Inspectable { readonly _tag: "Fail"; readonly error: E; } /** * Represents an unexpected defect within a `Cause`. * * **Details** * * This interface models a `Cause` for errors that are typically unrecoverable or * unanticipated—like runtime exceptions or bugs. When code "dies," it indicates a * severe failure that wasn't accounted for. * * @see {@link die} Construct a `Die` cause * @see {@link isDieType} Check if a `Cause` is a `Die` * * @since 2.0.0 * @category Models */ export interface Die extends Cause.Variance<never>, Equal.Equal, Pipeable, Inspectable { readonly _tag: "Die"; readonly defect: unknown; } /** * Represents fiber interruption within a `Cause`. * * **Details** * * This interface models a scenario where an effect was halted by an external * signal, carrying a `FiberId` that identifies which fiber was interrupted. * Interruption is a normal part of concurrency, used for cancellation or * resource cleanup. * * @see {@link interrupt} Construct an `Interrupt` cause * @see {@link isInterruptType} Check if a `Cause` is an `Interrupt` * * @since 2.0.0 * @category Models */ export interface Interrupt extends Cause.Variance<never>, Equal.Equal, Pipeable, Inspectable { readonly _tag: "Interrupt"; readonly fiberId: FiberId.FiberId; } /** * Represents parallel composition of two `Cause`s. * * **Details** * * This interface captures failures that happen simultaneously. In scenarios * with concurrency, more than one operation can fail in parallel. Instead of * losing information, this structure stores both errors together. * * @see {@link parallel} Combine two `Cause`s in parallel * @see {@link isParallelType} Check if a `Cause` is a `Parallel` * * @since 2.0.0 * @category Models */ export interface Parallel<out E> extends Cause.Variance<E>, Equal.Equal, Pipeable, Inspectable { readonly _tag: "Parallel"; readonly left: Cause<E>; readonly right: Cause<E>; } /** * Represents sequential composition of two `Cause`s. * * **Details** * * This interface models the scenario where one error follows another in * sequence, such as when a main effect fails and then a finalizer also fails. * It ensures both errors are retained in the final `Cause`. * * @see {@link sequential} Combine two `Cause`s sequentially * @see {@link isSequentialType} Check if a `Cause` is a `Sequential` * * @since 2.0.0 * @category Models */ export interface Sequential<out E> extends Cause.Variance<E>, Equal.Equal, Pipeable, Inspectable { readonly _tag: "Sequential"; readonly left: Cause<E>; readonly right: Cause<E>; } /** * Creates an `Empty` cause. * * **Details** * * This function returns a cause that signifies "no error." It's commonly used * to represent an absence of failure conditions. * * @see {@link isEmpty} Check if a `Cause` is empty * * @since 2.0.0 * @category Constructors */ export declare const empty: Cause<never>; /** * Creates a `Fail` cause from an expected error. * * **Details** * * This function constructs a `Cause` carrying an error of type `E`. It's used * when you want to represent a known or anticipated failure in your effectful * computations. * * @see {@link isFailure} Check if a `Cause` contains a failure * * @since 2.0.0 * @category Constructors */ export declare const fail: <E>(error: E) => Cause<E>; /** * Creates a `Die` cause from an unexpected error. * * **Details** * * This function wraps an unhandled or unknown defect (like a runtime crash) * into a `Cause`. It's useful for capturing unforeseen issues in a structured * way. * * @see {@link isDie} Check if a `Cause` contains a defect * * @since 2.0.0 * @category Constructors */ export declare const die: (defect: unknown) => Cause<never>; /** * Creates an `Interrupt` cause from a `FiberId`. * * **Details** * * This function represents a fiber that has been interrupted. It stores the * identifier of the interrupted fiber, enabling precise tracking of concurrent * cancellations. * * @see {@link isInterrupted} Check if a `Cause` contains an interruption * * @since 2.0.0 * @category Constructors */ export declare const interrupt: (fiberId: FiberId.FiberId) => Cause<never>; /** * Combines two `Cause`s in parallel. * * **Details** * * This function merges two errors that occurred simultaneously. Instead of * discarding one error, both are retained, allowing for richer error reporting * and debugging. * * @see {@link isParallelType} Check if a `Cause` is a `Parallel` * * @since 2.0.0 * @category Constructors */ export declare const parallel: <E, E2>(left: Cause<E>, right: Cause<E2>) => Cause<E | E2>; /** * Combines two `Cause`s sequentially. * * **Details** * * This function merges two errors that occurred in sequence, such as a main * error followed by a finalization error. It preserves both errors for complete * failure information. * * @see {@link isSequentialType} Check if a `Cause` is a `Sequential` * * @since 2.0.0 * @category Constructors */ export declare const sequential: <E, E2>(left: Cause<E>, right: Cause<E2>) => Cause<E | E2>; /** * Checks if a value is a `Cause`. * * @since 2.0.0 * @category Guards */ export declare const isCause: (u: unknown) => u is Cause<unknown>; /** * Checks if a `Cause` is an `Empty` type. * * @see {@link empty} Create a new `Empty` cause * * @since 2.0.0 * @category Guards */ export declare const isEmptyType: <E>(self: Cause<E>) => self is Empty; /** * Checks if a `Cause` is a `Fail` type. * * @see {@link fail} Create a new `Fail` cause * * @since 2.0.0 * @category Guards */ export declare const isFailType: <E>(self: Cause<E>) => self is Fail<E>; /** * Checks if a `Cause` is a `Die` type. * * @see {@link die} Create a new `Die` cause * * @since 2.0.0 * @category Guards */ export declare const isDieType: <E>(self: Cause<E>) => self is Die; /** * Checks if a `Cause` is an `Interrupt` type. * * @see {@link interrupt} Create an `Interrupt` cause * * @since 2.0.0 * @category Guards */ export declare const isInterruptType: <E>(self: Cause<E>) => self is Interrupt; /** * Checks if a `Cause` is a `Sequential` type. * * @see {@link sequential} Combine two `Cause`s sequentially * * @since 2.0.0 * @category Guards */ export declare const isSequentialType: <E>(self: Cause<E>) => self is Sequential<E>; /** * Checks if a `Cause` is a `Parallel` type. * * @see {@link parallel} Combine two `Cause`s in parallel * * @since 2.0.0 * @category Guards */ export declare const isParallelType: <E>(self: Cause<E>) => self is Parallel<E>; /** * Calculates the size of a `Cause`. * * **Details** * * This function returns the total number of `Cause` nodes in the semiring * structure, reflecting how many individual error elements are recorded. * * @since 2.0.0 * @category Getters */ export declare const size: <E>(self: Cause<E>) => number; /** * Checks if a `Cause` is entirely empty. * * **Details** * * This function returns `true` if the `Cause` contains no errors, defects, or * interruptions. It's helpful for verifying if a computation truly had no * failures. * * @since 2.0.0 * @category Getters */ export declare const isEmpty: <E>(self: Cause<E>) => boolean; /** * Checks if a `Cause` contains a failure. * * **Details** * * This function returns `true` if the `Cause` includes any `Fail` error. It's * commonly used to confirm whether a workflow encountered an anticipated error * versus just defects or interruptions. * * @since 2.0.0 * @category Getters */ export declare const isFailure: <E>(self: Cause<E>) => boolean; /** * Checks if a `Cause` contains a defect. * * **Details** * * This function returns `true` if the `Cause` includes any unexpected or * unhandled errors (`Die`). It's useful for differentiating known failures from * unexpected ones. * * @since 2.0.0 * @category Getters */ export declare const isDie: <E>(self: Cause<E>) => boolean; /** * Checks if a `Cause` contains an interruption. * * **Details** * * This function returns `true` if the `Cause` includes any fiber interruptions. * * @since 2.0.0 * @category Getters */ export declare const isInterrupted: <E>(self: Cause<E>) => boolean; /** * Checks if a `Cause` contains only interruptions. * * **Details** * * This function returns `true` if the `Cause` has been interrupted but does not * contain any other failures, such as `Fail` or `Die`. It's helpful for * verifying purely "cancellation" scenarios. * * @since 2.0.0 * @category Getters */ export declare const isInterruptedOnly: <E>(self: Cause<E>) => boolean; /** * Extracts all recoverable errors of type `E` from a `Cause`. * * **Details** * * This function returns a chunk of errors, providing a list of all `Fail` * values found in the cause. It's useful for collecting all known failures for * logging or combined error handling. * * @since 2.0.0 * @category Getters */ export declare const failures: <E>(self: Cause<E>) => Chunk.Chunk<E>; /** * Extracts all unrecoverable defects from a `Cause`. * * **Details** * * This function returns a chunk of values representing unexpected errors * (`Die`). It's handy for capturing or logging unanticipated failures that * might need special handling, such as bug reports. * * @since 2.0.0 * @category Getters */ export declare const defects: <E>(self: Cause<E>) => Chunk.Chunk<unknown>; /** * Collects all `FiberId`s responsible for interrupting a fiber. * * **Details** * * This function returns a set of IDs indicating which fibers caused * interruptions within this `Cause`. It's useful for debugging concurrency * issues or tracing cancellations. * * @since 2.0.0 * @category Getters */ export declare const interruptors: <E>(self: Cause<E>) => HashSet.HashSet<FiberId.FiberId>; /** * Retrieves the first `Fail` error in a `Cause`, if present. * * **Details** * * This function returns an `Option` containing the first recoverable error * (`E`) from the cause. It's often used to quickly check if there's a primary * error to handle or display. * * @since 2.0.0 * @category Getters */ export declare const failureOption: <E>(self: Cause<E>) => Option.Option<E>; /** * Splits a `Cause` into either its first `Fail` error or the rest of the cause * (which might only contain `Die` or `Interrupt`). * * **Details** * * This function either returns the checked error (`E`) or the remaining * `Cause<never>` with defects/interruptions. It helps you decide if there's a * recoverable path or if only unhandled issues remain. * * @since 2.0.0 * @category Getters */ export declare const failureOrCause: <E>(self: Cause<E>) => Either.Either<Cause<never>, E>; /** * Strips out failures with an error of `None` from a `Cause<Option<E>>`. * * **Details** * * This function turns a `Cause<Option<E>>` into an `Option<Cause<E>>`. If the * cause only contains failures of `None`, it becomes `None`; otherwise, it * returns a `Cause` of the remaining errors. It's helpful when working with * optional errors and filtering out certain error paths. * * @since 2.0.0 * @category Getters */ export declare const flipCauseOption: <E>(self: Cause<Option.Option<E>>) => Option.Option<Cause<E>>; /** * Retrieves the first `Die` defect in a `Cause`, if present. * * **Details** * * This function returns an `Option` containing the first unexpected failure * (`Die`) discovered. It's helpful for diagnosing the primary defect in a chain * of errors. * * @since 2.0.0 * @category Getters */ export declare const dieOption: <E>(self: Cause<E>) => Option.Option<unknown>; /** * Retrieves the first `Interrupt` in a `Cause`, if present. * * **Details** * * This function returns an `Option` with the first fiber interruption * discovered. This is particularly useful for concurrency analysis or debugging * cancellations. * * @since 2.0.0 * @category Getters */ export declare const interruptOption: <E>(self: Cause<E>) => Option.Option<FiberId.FiberId>; /** * Removes all `Fail` and `Interrupt` nodes, keeping only defects (`Die`) in a * `Cause`. * * **Details** * * This function strips a cause of recoverable errors and interruptions, leaving * only unexpected failures. If no defects remain, it returns `None`. It's * valuable for focusing only on unanticipated problems when both known errors * and defects could occur. * * @since 2.0.0 * @category Getters */ export declare const keepDefects: <E>(self: Cause<E>) => Option.Option<Cause<never>>; /** * Linearizes a `Cause` into a set of parallel causes, each containing a * sequential chain of failures. * * **Details** * * This function reorganizes the cause structure so that you can analyze each * parallel branch separately, even if they have multiple sequential errors. * * @since 2.0.0 * @category Getters */ export declare const linearize: <E>(self: Cause<E>) => HashSet.HashSet<Cause<E>>; /** * Removes `Fail` and `Interrupt` nodes from a `Cause`, keeping only defects * (`Die`). * * **Details** * * This function is similar to `keepDefects` but returns a `Cause<never>` * directly, which can still store `Die` or finalizer-related defects. It's * helpful for analyzing only the irrecoverable portion of the error. * * @since 2.0.0 * @category Getters */ export declare const stripFailures: <E>(self: Cause<E>) => Cause<never>; /** * Removes matching defects from a `Cause` using a partial function, returning * the remainder. * * **Details** * * This function applies a user-defined extraction function to each defect * (`Die`). If the function matches the defect, that defect is removed. If all * defects match, the result is `None`. Otherwise, you get a `Cause` with the * unmatched defects. * * @since 2.0.0 * @category Getters */ export declare const stripSomeDefects: { /** * Removes matching defects from a `Cause` using a partial function, returning * the remainder. * * **Details** * * This function applies a user-defined extraction function to each defect * (`Die`). If the function matches the defect, that defect is removed. If all * defects match, the result is `None`. Otherwise, you get a `Cause` with the * unmatched defects. * * @since 2.0.0 * @category Getters */ (pf: (defect: unknown) => Option.Option<unknown>): <E>(self: Cause<E>) => Option.Option<Cause<E>>; /** * Removes matching defects from a `Cause` using a partial function, returning * the remainder. * * **Details** * * This function applies a user-defined extraction function to each defect * (`Die`). If the function matches the defect, that defect is removed. If all * defects match, the result is `None`. Otherwise, you get a `Cause` with the * unmatched defects. * * @since 2.0.0 * @category Getters */ <E>(self: Cause<E>, pf: (defect: unknown) => Option.Option<unknown>): Option.Option<Cause<E>>; }; /** * Replaces any errors in a `Cause` with a provided constant error. * * **Details** * * This function transforms all `Fail` errors into the specified error value, * preserving the structure of the `Cause`. It's useful when you no longer need * the original error details but still want to keep the cause shape. * * @see {@link map} Apply a custom transformation to `Fail` errors * * @since 2.0.0 * @category Mapping */ export declare const as: { /** * Replaces any errors in a `Cause` with a provided constant error. * * **Details** * * This function transforms all `Fail` errors into the specified error value, * preserving the structure of the `Cause`. It's useful when you no longer need * the original error details but still want to keep the cause shape. * * @see {@link map} Apply a custom transformation to `Fail` errors * * @since 2.0.0 * @category Mapping */ <E2>(error: E2): <E>(self: Cause<E>) => Cause<E2>; /** * Replaces any errors in a `Cause` with a provided constant error. * * **Details** * * This function transforms all `Fail` errors into the specified error value, * preserving the structure of the `Cause`. It's useful when you no longer need * the original error details but still want to keep the cause shape. * * @see {@link map} Apply a custom transformation to `Fail` errors * * @since 2.0.0 * @category Mapping */ <E, E2>(self: Cause<E>, error: E2): Cause<E2>; }; /** * Transforms the errors in a `Cause` using a user-provided function. * * **Details** * * This function applies `f` to each `Fail` error while leaving defects (`Die`) * and interruptions untouched. It's useful for changing or simplifying error * types in your effectful workflows. * * @see {@link as} Replace errors with a single constant * * @since 2.0.0 * @category Mapping */ export declare const map: { /** * Transforms the errors in a `Cause` using a user-provided function. * * **Details** * * This function applies `f` to each `Fail` error while leaving defects (`Die`) * and interruptions untouched. It's useful for changing or simplifying error * types in your effectful workflows. * * @see {@link as} Replace errors with a single constant * * @since 2.0.0 * @category Mapping */ <E, E2>(f: (e: E) => E2): (self: Cause<E>) => Cause<E2>; /** * Transforms the errors in a `Cause` using a user-provided function. * * **Details** * * This function applies `f` to each `Fail` error while leaving defects (`Die`) * and interruptions untouched. It's useful for changing or simplifying error * types in your effectful workflows. * * @see {@link as} Replace errors with a single constant * * @since 2.0.0 * @category Mapping */ <E, E2>(self: Cause<E>, f: (e: E) => E2): Cause<E2>; }; /** * Transforms errors in a `Cause` into new causes. * * **Details** * * This function applies a function `f` to each `Fail` error, converting it into * a new `Cause`. This is especially powerful for merging or restructuring error * types while preserving or combining cause information. * * @see {@link map} Apply a simpler transformation to errors * * @since 2.0.0 * @category Sequencing */ export declare const flatMap: { /** * Transforms errors in a `Cause` into new causes. * * **Details** * * This function applies a function `f` to each `Fail` error, converting it into * a new `Cause`. This is especially powerful for merging or restructuring error * types while preserving or combining cause information. * * @see {@link map} Apply a simpler transformation to errors * * @since 2.0.0 * @category Sequencing */ <E, E2>(f: (e: E) => Cause<E2>): (self: Cause<E>) => Cause<E2>; /** * Transforms errors in a `Cause` into new causes. * * **Details** * * This function applies a function `f` to each `Fail` error, converting it into * a new `Cause`. This is especially powerful for merging or restructuring error * types while preserving or combining cause information. * * @see {@link map} Apply a simpler transformation to errors * * @since 2.0.0 * @category Sequencing */ <E, E2>(self: Cause<E>, f: (e: E) => Cause<E2>): Cause<E2>; }; /** * Sequences two `Cause`s. The second `Cause` can be dependent on the result of * the first `Cause`. * * @since 2.0.0 * @category Sequencing */ export declare const andThen: { /** * Sequences two `Cause`s. The second `Cause` can be dependent on the result of * the first `Cause`. * * @since 2.0.0 * @category Sequencing */ <E, E2>(f: (e: E) => Cause<E2>): (self: Cause<E>) => Cause<E2>; /** * Sequences two `Cause`s. The second `Cause` can be dependent on the result of * the first `Cause`. * * @since 2.0.0 * @category Sequencing */ <E2>(f: Cause<E2>): <E>(self: Cause<E>) => Cause<E2>; /** * Sequences two `Cause`s. The second `Cause` can be dependent on the result of * the first `Cause`. * * @since 2.0.0 * @category Sequencing */ <E, E2>(self: Cause<E>, f: (e: E) => Cause<E2>): Cause<E2>; /** * Sequences two `Cause`s. The second `Cause` can be dependent on the result of * the first `Cause`. * * @since 2.0.0 * @category Sequencing */ <E, E2>(self: Cause<E>, f: Cause<E2>): Cause<E2>; }; /** * Flattens a nested `Cause` structure. * * **Details** * * This function takes a `Cause<Cause<E>>` and merges the layers into a single * `Cause<E>`. It's useful for eliminating additional nesting created by * repeated transformations or compositions. * * @see {@link flatMap} Compose nested causes * * @since 2.0.0 * @category Sequencing */ export declare const flatten: <E>(self: Cause<Cause<E>>) => Cause<E>; /** * Checks if the current `Cause` contains or is equal to another `Cause`. * * **Details** * * This function returns `true` if `that` cause is part of or the same as * the current `Cause`. It's useful when you need to check for specific * error patterns or deduplicate repeated failures. * * @since 2.0.0 * @category Elements */ export declare const contains: { /** * Checks if the current `Cause` contains or is equal to another `Cause`. * * **Details** * * This function returns `true` if `that` cause is part of or the same as * the current `Cause`. It's useful when you need to check for specific * error patterns or deduplicate repeated failures. * * @since 2.0.0 * @category Elements */ <E2>(that: Cause<E2>): <E>(self: Cause<E>) => boolean; /** * Checks if the current `Cause` contains or is equal to another `Cause`. * * **Details** * * This function returns `true` if `that` cause is part of or the same as * the current `Cause`. It's useful when you need to check for specific * error patterns or deduplicate repeated failures. * * @since 2.0.0 * @category Elements */ <E, E2>(self: Cause<E>, that: Cause<E2>): boolean; }; /** * Extracts the most "important" defect from a `Cause`. * * **Details** * * This function reduces a `Cause` to a single, prioritized defect. It evaluates * the `Cause` in the following order of priority: * * 1. If the `Cause` contains a failure (e.g., from `Effect.fail`), it returns * the raw error value. * 2. If there is no failure, it looks for the first defect (e.g., from * `Effect.die`). * 3. If neither of the above is present, and the `Cause` stems from an * interruption, it creates and returns an `InterruptedException`. * * This function ensures you can always extract a meaningful representation of * the primary issue from a potentially complex `Cause` structure. * * **When to Use** * * Use this function when you need to extract the most relevant error or defect * from a `Cause`, especially in scenarios where multiple errors or defects may * be present. It's particularly useful for simplifying error reporting or * logging. * * @see {@link squashWith} Allows transforming failures into defects when squashing. * * @since 2.0.0 * @category Destructors */ export declare const squash: <E>(self: Cause<E>) => unknown; /** * Extracts the most "important" defect from a `Cause`, transforming failures * into defects using a provided function. * * **Details** * * This function reduces a `Cause` to a single, prioritized defect, while * allowing you to transform recoverable failures into defects through a custom * function. It processes the `Cause` in the following order: * * 1. If the `Cause` contains a failure (e.g., from `Effect.fail`), it applies * the provided function `f` to the error to transform it into a defect. * 2. If there is no failure, it looks for the first defect (e.g., from * `Effect.die`) and returns it. * 3. If neither is present and the `Cause` stems from an interruption, it * returns an `InterruptedException`. * * This function is particularly useful when you need custom handling or * transformation of errors while processing a `Cause`. * * @see {@link squash} Extracts the most "important" defect without transforming failures. * * @since 2.0.0 * @category Destructors */ export declare const squashWith: { /** * Extracts the most "important" defect from a `Cause`, transforming failures * into defects using a provided function. * * **Details** * * This function reduces a `Cause` to a single, prioritized defect, while * allowing you to transform recoverable failures into defects through a custom * function. It processes the `Cause` in the following order: * * 1. If the `Cause` contains a failure (e.g., from `Effect.fail`), it applies * the provided function `f` to the error to transform it into a defect. * 2. If there is no failure, it looks for the first defect (e.g., from * `Effect.die`) and returns it. * 3. If neither is present and the `Cause` stems from an interruption, it * returns an `InterruptedException`. * * This function is particularly useful when you need custom handling or * transformation of errors while processing a `Cause`. * * @see {@link squash} Extracts the most "important" defect without transforming failures. * * @since 2.0.0 * @category Destructors */ <E>(f: (error: E) => unknown): (self: Cause<E>) => unknown; /** * Extracts the most "important" defect from a `Cause`, transforming failures * into defects using a provided function. * * **Details** * * This function reduces a `Cause` to a single, prioritized defect, while * allowing you to transform recoverable failures into defects through a custom * function. It processes the `Cause` in the following order: * * 1. If the `Cause` contains a failure (e.g., from `Effect.fail`), it applies * the provided function `f` to the error to transform it into a defect. * 2. If there is no failure, it looks for the first defect (e.g., from * `Effect.die`) and returns it. * 3. If neither is present and the `Cause` stems from an interruption, it * returns an `InterruptedException`. * * This function is particularly useful when you need custom handling or * transformation of errors while processing a `Cause`. * * @see {@link squash} Extracts the most "important" defect without transforming failures. * * @since 2.0.0 * @category Destructors */ <E>(self: Cause<E>, f: (error: E) => unknown): unknown; }; /** * Searches a `Cause` using a partial function to extract information. * * **Details** * * This function allows you to search through a `Cause` using a custom partial * function. The partial function is applied to the `Cause`, and if it matches, * the result is returned wrapped in a `Some`. If no match is found, the result * is `None`. * * This is particularly useful when you are only interested in specific types of * errors, defects, or interruption causes within a potentially complex `Cause` * structure. By leveraging a partial function, you can focus on extracting only * the relevant information you care about. * * The partial function should return an `Option` indicating whether it matched * and the value it extracted. * * @since 2.0.0 * @category Elements */ export declare const find: { /** * Searches a `Cause` using a partial function to extract information. * * **Details** * * This function allows you to search through a `Cause` using a custom partial * function. The partial function is applied to the `Cause`, and if it matches, * the result is returned wrapped in a `Some`. If no match is found, the result * is `None`. * * This is particularly useful when you are only interested in specific types of * errors, defects, or interruption causes within a potentially complex `Cause` * structure. By leveraging a partial function, you can focus on extracting only * the relevant information you care about. * * The partial function should return an `Option` indicating whether it matched * and the value it extracted. * * @since 2.0.0 * @category Elements */ <E, Z>(pf: (cause: Cause<E>) => Option.Option<Z>): (self: Cause<E>) => Option.Option<Z>; /** * Searches a `Cause` using a partial function to extract information. * * **Details** * * This function allows you to search through a `Cause` using a custom partial * function. The partial function is applied to the `Cause`, and if it matches, * the result is returned wrapped in a `Some`. If no match is found, the result * is `None`. * * This is particularly useful when you are only interested in specific types of * errors, defects, or interruption causes within a potentially complex `Cause` * structure. By leveraging a partial function, you can focus on extracting only * the relevant information you care about. * * The partial function should return an `Option` indicating whether it matched * and the value it extracted. * * @since 2.0.0 * @category Elements */ <E, Z>(self: Cause<E>, pf: (cause: Cause<E>) => Option.Option<Z>): Option.Option<Z>; }; /** * Preserves parts of a `Cause` that match a given predicate. * * **Details** * * This function allows you to retain only the parts of a `Cause` structure that * match a specified predicate or refinement. Any parts of the `Cause` that do * not match the provided condition are excluded from the result. * * You can use this function in two ways: * - With a `Predicate`: A function that evaluates whether a `Cause` should be * retained based on its value. * - With a `Refinement`: A more specific predicate that can refine the type of * the `Cause`. * * This is useful when you need to extract specific types of errors, defects, or * interruptions from a `Cause` while discarding unrelated parts. * * @since 2.0.0 * @category Filtering */ export declare const filter: { /** * Preserves parts of a `Cause` that match a given predicate. * * **Details** * * This function allows you to retain only the parts of a `Cause` structure that * match a specified predicate or refinement. Any parts of the `Cause` that do * not match the provided condition are excluded from the result. * * You can use this function in two ways: * - With a `Predicate`: A function that evaluates whether a `Cause` should be * retained based on its value. * - With a `Refinement`: A more specific predicate that can refine the type of * the `Cause`. * * This is useful when you need to extract specific types of errors, defects, or * interruptions from a `Cause` while discarding unrelated parts. * * @since 2.0.0 * @category Filtering */ <E, EB extends E>(refinement: Refinement<Cause<NoInfer<E>>, Cause<EB>>): (self: Cause<E>) => Cause<EB>; /** * Preserves parts of a `Cause` that match a given predicate. * * **Details** * * This function allows you to retain only the parts of a `Cause` structure that * match a specified predicate or refinement. Any parts of the `Cause` that do * not match the provided condition are excluded from the result. * * You can use this function in two ways: * - With a `Predicate`: A function that evaluates whether a `Cause` should be * retained based on its value. * - With a `Refinement`: A more specific predicate that can refine the type of * the `Cause`. * * This is useful when you need to extract specific types of errors, defects, or * interruptions from a `Cause` while discarding unrelated parts. * * @since 2.0.0 * @category Filtering */ <E>(predicate: Predicate<Cause<NoInfer<E>>>): (self: Cause<E>) => Cause<E>; /** * Preserves parts of a `Cause` that match a given predicate. * * **Details** * * This function allows you to retain only the parts of a `Cause` structure that * match a specified predicate or refinement. Any parts of the `Cause` that do * not match the provided condition are excluded from the result. * * You can use this function in two ways: * - With a `Predicate`: A function that evaluates whether a `Cause` should be * retained based on its value. * - With a `Refinement`: A more specific predicate that can refine the type of * the `Cause`. * * This is useful when you need to extract specific types of errors, defects, or * interruptions from a `Cause` while discarding unrelated parts. * * @since 2.0.0 * @category Filtering */ <E, EB extends E>(self: Cause<E>, refinement: Refinement<Cause<E>, Cause<EB>>): Cause<EB>; /** * Preserves parts of a `Cause` that match a given predicate. * * **Details** * * This function allows you to retain only the parts of a `Cause` structure that * match a specified predicate or refinement. Any parts of the `Cause` that do * not match the provided condition are excluded from the result. * * You can use this function in two ways: * - With a `Predicate`: A function that evaluates whether a `Cause` should be * retained based on its value. * - With a `Refinement`: A more specific predicate that can refine the type of * the `Cause`. * * This is useful when you need to extract specific types of errors, defects, or * interruptions from a `Cause` while discarding unrelated parts. * * @since 2.0.0 * @category Filtering */ <E>(self: Cause<E>, predicate: Predicate<Cause<E>>): Cause<E>; }; /** * Transforms a `Cause` into a single value using custom handlers for each * possible case. * * **Details** * * This function processes a `Cause` by applying a set of custom handlers to * each possible type of cause: `Empty`, `Fail`, `Die`, `Interrupt`, * `Sequential`, and `Parallel`. The result of this function is a single value * of type `Z`. This function allows you to define exactly how to handle each * part of a `Cause`, whether it's a failure, defect, interruption, or a * combination of these. * * The options parameter provides handlers for: * - `onEmpty`: Handles the case where the cause is `Empty`, meaning no errors * occurred. * - `onFail`: Processes a failure with an error of type `E`. * - `onDie`: Processes a defect (unexpected error). * - `onInterrupt`: Handles a fiber interruption, providing the `FiberId` of the * interruption. * - `onSequential`: Combines two sequential causes into a single value of type * `Z`. * - `onParallel`: Combines two parallel causes into a single value of type `Z`. * * @since 2.0.0 * @category Matching */ export declare const match: { /** * Transforms a `Cause` into a single value using custom handlers for each * possible case. * * **Details** * * This function processes a `Cause` by applying a set of custom handlers to * each possible type of cause: `Empty`, `Fail`, `Die`, `Interrupt`, * `Sequential`, and `Parallel`. The result of this function is a single value * of type `Z`. This function allows you to define exactly how to handle each * part of a `Cause`, whether it's a failure, defect, interruption, or a * combination of these. * * The options parameter provides handlers for: * - `onEmpty`: Handles the case where the cause is `Empty`, meaning no errors * occurred. * - `onFail`: Processes a failure with an error of type `E`. * - `onDie`: Processes a defect (unexpected error). * - `onInterrupt`: Handles a fiber interruption, providing the `FiberId` of the * interruption. * - `onSequential`: Combines two sequential causes into a single value of type * `Z`. * - `onParallel`: Combines two parallel causes into a single value of type `Z`. * * @since 2.0.0 * @category Matching */ <Z, E>(options: { readonly onEmpty: Z; readonly onFail: (error: E) => Z; readonly onDie: (defect: unknown) => Z; readonly onInterrupt: (fiberId: FiberId.FiberId) => Z; readonly onSequential: (left: Z, right: Z) => Z; readonly onParallel: (left: Z, right: Z) => Z; }): (self: Cause<E>) => Z; /** * Transforms a `Cause` into a single value using custom handlers for each * possible case. * * **Details** * * This function processes a `Cause` by applying a set of custom handlers to * each possible type of cause: `Empty`, `Fail`, `Die`, `Interrupt`, * `Sequential`, and `Parallel`. The result of this function is a single value * of type `Z`. This function allows you to define exactly how to handle each * part of a `Cause`, whether it's a failure, defect, interruption, or a * combination of these. * * The options parameter provides handlers for: * - `onEmpty`: Handles the case where the cause is `Empty`, meaning no errors * occurred. * - `onFail`: Processes a failure with an error of type `E`. * - `onDie`: Processes a defect (unexpected error). * - `onInterrupt`: Handles a fiber interruption, providing the `FiberId` of the * interruption. * - `onSequential`: Combines two sequential causes into a single value of type * `Z`. * - `onParallel`: Combines two parallel causes into a single value of type `Z`. * * @since 2.0.0 * @category Matching */ <Z, E>(self: Cause<E>, options: { readonly onEmpty: Z; readonly onFail: (error: E) => Z; readonly onDie: (defect: unknown) => Z; readonly onInterrupt: (fiberId: FiberId.FiberId) => Z; readonly onSequential: (left: Z, right: Z) => Z; readonly onParallel: (left: Z, right: Z) => Z; }): Z; }; /** * Combines all parts of a `Cause` into a single value by starting with an * initial value. * * **Details** * * This function processes a `Cause` by starting with an initial value (`zero`) * and applying a custom function (`pf`) to combine all elements of the `Cause` * into a single result of type `Z`. The custom function determines how each * part of the `Cause` contributes to the final result. The function can return * an `Option` to either continue combining values or skip specific parts of the * `Cause`. * * This function is useful for tasks such as: * - Aggregating error messages from a `Cause` into a single string. * - Summarizing the structure of a `Cause` into a simplified result. * - Filtering or processing only specific parts of a `Cause`. * * The reduction proceeds in a top-down manner, visiting all nodes in the * `Cause` structure. This gives you complete control over how each part of the * `Cause` contributes to the final result. * * @since 2.0.0 * @category Reducing */ export declare const reduce: { /** * Combines all parts of a `Cause` into a single value by starting with an * initial value. * * **Details** * * This function processes a `Cause` by starting with an initial value (`zero`) * and applying a custom function (`pf`) to combine all elements of the `Cause` * into a single result of type `Z`. The custom function determines how each * part of the `Cause` contributes to the final result. The function can return * an `Option` to either continue combining values or skip specific parts of the * `Cause`. * * This function is useful for tasks such as: * - Aggregating error messages from a `Cause` into a single string. * - Summarizing the structure of a `Cause` into a simplified result. * - Filtering or processing only specific parts of a `Cause`. * * The reduction proceeds in a top-down manner, visiting all nodes in the * `Cause` structure. This gives you complete control over how each part of the * `Cause` contributes to the final result. * * @since 2.0.0 * @category Reducing */ <Z, E>(zero: Z, pf: (accumulator: Z, cause: Cause<E>) => Option.Option<Z>): (self: Cause<E>) => Z; /** * Combines all parts of a `Cause` into a single value by starting with an * initial value. * * **Details** * * This function processes a `Cause` by starting with an initial value (`zero`) * and applying a custom function (`pf`) to combine all elements of the `Cause` * into a single result of type `Z`. The custom function determines how each * part of the `Cause` contributes to the final result. The function can return * an `Option` to either continue combining values or skip specific parts of the * `Cause`. * * This function is useful for tasks such as: * - Aggregating error messages from a `Cause` into a single string. * - Summarizing the structure of a `Cause` into a simplified result. * - Filtering or processing only specific parts of a `Cause`. * * The reduction proceeds in a top-down manner, visiting all nodes in the * `Cause` structure. This gives you complete control over how each part of the * `Cause` contributes to the final result. * * @since 2.0.0 * @category Reducing */ <Z, E>(self: Cause<E>, zero: Z, pf: (accumulator: Z, cause: Cause<E>) => Option.Option<Z>): Z; }; /** * Combines all parts of a `Cause` into a single value using a custom reducer * and a context. * * **Details** * * This function allows you to reduce a `Cause` into a single value of type `Z` * using a custom `CauseReducer`. A `CauseReducer` provides methods to handle * specific parts of the `Cause`, such as failures, defects, or interruptions. * Additionally, this function provides access to a `context` value, which can * be used to carry information or maintain state during the reduction process. * * This is particularly useful when the reduction process needs additional * context or configuration, such as: * - Aggregating error details with dynamic formatting. * - Collecting logs or statistics about the `Cause`. * - Performing stateful transformations based on the `context`. * * @see {@link reduce} To reduce a `Cause` without additional context. * * @since 2.0.0 * @category Reducing */ export declare const reduceWithContext: { /** * Combines all parts of a `Cause` into a single value using a custom reducer * and a context. * * **Details** * * This function allows you to reduce a `Cause` into a single value of type `Z` * using a custom `CauseReducer`. A `CauseReducer` provides methods to handle * specific parts of the `Cause`, such as failures, defects, or interruptions. * Additionally, this function provides access to a `context` value, which can * be used to carry information or maintain state during the reduction process. * * This is particularly useful when the reduction process needs additional * context or configuration, such as: * - Aggregating error details with dynamic formatting. * - Collecting logs or statistics about the `Cause`. * - Performing stateful transformations based on the `context`. * * @see {@link reduce} To reduce a `Cause` without additional context. * * @since 2.0.0 * @category Reducing */ <C, E, Z>(context: C, reducer: CauseReducer<C, E, Z>): (self: Cause<E>) => Z; /** * Combines all parts of a `Cause` into a single value using a custom reducer * and a context. * * **Details** * * This function allows you to reduce a `Cause` into a single value of type `Z` * using a custom `CauseReducer`. A `CauseReducer` provides methods to handle * specific parts of the `Cause`, such as failures, defects, or interruptions. * Additionally, this function provides access to a `context` value, which can * be used to carry information or maintain state during the reduction process. * * This is particularly useful when the reduction process needs additional * context or configuration, such as: * - Aggregating error details with dynamic formatting. * - Collecting logs or statistics about the `Cause`. * - Performing stateful transformations based on the `context`. * * @see {@link reduce} To reduce a `Cause` without additional context. * * @since 2.0.0 * @category Reducing */ <C, E, Z>(self: Cause<E>, context: C, reducer: CauseReducer<C, E, Z>): Z; }; /** * Creates an error that indicates a `Fiber` was interrupted. * * **Details** * * This function constructs an `InterruptedException` recognized by the Effect * runtime. It is usually thrown or returned when a fiber's execution is * interrupted by external events or by another fiber. This is particularly * helpful in concurrent programs where fibers may halt each other before * completion. * * @since 2.0.0 * @category Errors */ export declare const InterruptedException: new (message?: string | undefined) => InterruptedException; /** * Checks if a given unknown value is an `InterruptedException`. * * @since 2.0.0 * @category Guards */ export declare const isInterruptedException: (u: unknown) => u is InterruptedException; /** * Creates an error indicating an invalid method argument. * * **Details** * * This function constructs an `IllegalArgumentException`. It is typically * thrown or returned when an operation receives improper inputs, such as * out-of-range values or invalid object states. * * @since 2.0.0 * @category Errors */ export declare const IllegalArgumentException: new (message?: string | undefined) => IllegalArgumentException; /** * Checks if a given unknown value is an `IllegalArgumentException`. * * @since 2.0.0 * @category Guards */ export declare const isIllegalArgumentException: (u: unknown) => u is IllegalArgumentException; /** * Creates an error indicating a missing element. * * **Details** * * This function constructs a `NoSuchElementException`. It helps you clearly * communicate that a required element is unavailable. * * @since 2.0.0 * @category Errors */ export declare const NoSuchElementException: new (message?: string | undefined) => NoSuchElementException; /** * Checks if a given unknown value is a `NoSuchElementException`. * * @since 2.0.0 * @category Guards */ export declare const isNoSuchElementException: (u: unknown) => u is NoSuchElementException; /** * Creates an error for general runtime errors. * * **Details** * * This function constructs a `RuntimeException`, for errors that occur at * runtime but are not specifically typed or categorized as interruptions, * missing elements, or invalid arguments. It helps unify a wide range of * unexpected conditions under a single, recognizable error type. * * @since 2.0.0 * @category Errors */ export declare const RuntimeException: new (message?: string | undefined) => RuntimeException; /** * Checks if a given unknown value is a `RuntimeException`. * * @since 2.0.0 * @category Guards */ export declare const isRuntimeException: (u: unknown) => u is RuntimeException; /** * Creates an error for operations that exceed their expected time. * * **Details** * * This function constructs a `TimeoutException`. It is typically used to signal * that an operation or fiber did not complete within a designated time limit, * allowing you to handle slow or hanging processes. * * @since 2.0.0 * @category Errors */ export declare const TimeoutException: new (message?: string | undefined) => TimeoutException; /** * Checks if a given unknown value is a `TimeoutException`. * * @since 3.15.0 * @category Guards */ export declare const isTimeoutException: (u: unknown) => u is TimeoutException; /** * Creates an instance of `UnknownException`, an error object used to handle * unknown errors such as those from rejected promises. * * **Details** * * This function constructs an `UnknownException` with flexible behavior for * managing the error message and cause. * * The required `error` argument is passed as the `cause` to the global `Error` * constructor, ensuring that the original cause is preserved in the error chain * for debugging purposes. This ensures that the origin stack trace is * preserved. * * The `error` argument is always stored in the `error` property of the * `UnknownException` instance for reference, regardless of its type. * * Additionally, if you provide a `message` argument, it is used as the error * message. If no `message` is provided, the error message defaults to `"An * unknown error occurred"`. * * **When to Use** * * Use this function when you need to handle unexpected or unknown errors in * your application, particularly when the source of the error might not provide * a clear message. This is useful for wrapping generic errors thrown from * promises or external APIs. * * @since 2.0.0 * @category Errors */ export declare const UnknownException: new (error: unknown, message?: string | undefined) => UnknownException; /** * Checks if a given unknown value is an `UnknownException`. * * @since 2.0.0 * @category Guards */ export declare const isUnknownException: (u: unknown) => u is UnknownException; /** * Creates an error indicating resource capacity has been exceeded. * * **Details** * * This function constructs an `ExceededCapacityException`, signifying that an * operation or resource usage surpassed established limits. This can be * essential for concurrency or resource management situations, ensuring your * application doesn't go beyond acceptable thresholds. * * @since 3.5.0 * @category Errors */ export declare const ExceededCapacityException: new (message?: string | undefined) => ExceededCapacityException; /** * Checks if a given unknown value is an `ExceededCapacityException`. * * @since 3.5.0 * @category Guards */ export declare const isExceededCapacityException: (u: unknown) => u is ExceededCapacityException; /** * Converts a `Cause` into a human-readable string. * * **Details** * * This function pretty-prints the entire `Cause`, including any failures, * defects, and interruptions. It can be especially helpful for logging, * debugging, or displaying structured errors to users. * * You can optionally pass `options` to configure how the error cause is * rendered. By default, it includes essential details of all errors in the * `Cause`. * * @see {@link prettyErrors} Get a list of `PrettyError` objects instead of a single string. * * @since 2.0.0 * @category Formatting */ export declare const pretty: <E>(cause: Cause<E>, options?: { readonly renderErrorCause?: boolean | undefined; }) => string; /** * A shape for prettified errors, optionally including a source span. * * @since 3.2.0 * @category Models */ export interface PrettyError extends Error { readonly span: Span | undefined; } /** * Returns a list of prettified errors (`PrettyError`) from a `Cause`. * * **Details** * * This function inspects the entire `Cause` and produces an array of * `PrettyError` objects. Each object may include additional metadata, such as a * `Span`, to provide deeper insights into where and how the error occurred. * * @since 3.2.0 * @category Formatting */ export declare const prettyErrors: <E>(cause: Cause<E>) => Array<PrettyError>; /** * Retrieves the original, unproxied error instance from an error object. * * **Details** * * This function returns the underlying error object without any * library-specific wrapping or proxying that might occur during error handling. * This can be essential if you need direct access to the error's native * properties, such as stack traces or custom data fields, for detailed * debugging or integration with external systems. * * @since 2.0.0 * @category Errors */ export declare const originalError: <E>(obj: E) => E; //# sourceMappingURL=Cause.d.ts.map