/**
 * @author fenris
 */
type int = number;
/**
 * @author fenris
 */
type float = number;
/**
 * @author fenris
 */
type type_time = {
    hours: int;
    minutes: int;
    seconds: int;
};
declare var process: any;
declare var require: any;
declare class Buffer {
    constructor(x: string, modifier?: string);
    toString(modifier?: string): string;
}
declare namespace lib_plankton.base {
    /**
     * @author fenris
     */
    function environment(): string;
}
/**
 * @author fenris
 */
type type_pseudopointer<type_value> = {
    value: type_value;
};
/**
 * @author fenris
 */
declare function pseudopointer_null<type_value>(): type_pseudopointer<type_value>;
/**
 * @author fenris
 */
declare function pseudopointer_make<type_value>(value: type_value): type_pseudopointer<type_value>;
/**
 * @author fenris
 */
declare function pseudopointer_isset<type_value>(pseudopointer: type_pseudopointer<type_value>): boolean;
/**
 * @author fenris
 */
declare function pseudopointer_read<type_value>(pseudopointer: type_pseudopointer<type_value>): type_value;
/**
 * @author fenris
 */
declare function pseudopointer_write<type_value>(pseudopointer: type_pseudopointer<type_value>, value: type_value): void;
/**
 * @author fenris
 */
declare var instance_verbosity: int;
/**
 * @desc the ability to check for equality with another element of the same domain
 * @author fenris
 */
interface interface_collatable<type_value> {
    /**
     * @author fenris
     */
    _collate(value: type_value): boolean;
}
/**
 * @author fenris
 */
declare function instance_collate<type_value>(value1: (type_value & {
    _collate?: ((value: type_value) => boolean);
}), value2: type_value): boolean;
/**
 * @desc the ability to compare with another element of the same domain for determining if the first is "smaller than or equal to" the latter
 * @author fenris
 */
interface interface_comparable<type_value> {
    /**
     * @author fenris
     */
    _compare(value: type_value): boolean;
}
/**
 * @author fenris
 */
declare function instance_compare<type_value>(value1: (type_value & {
    _compare: ((value: type_value) => boolean);
}), value2: type_value): boolean;
/**
 * @desc the ability to create an exact copy
 * @author fenris
 */
interface interface_cloneable<type_value> {
    /**
     * @author fenris
     */
    _clone(): type_value;
}
/**
 * @author fenris
 */
declare function instance_clone<type_value>(value: (type_value & {
    _clone?: (() => type_value);
})): type_value;
/**
 * @author fenris
 */
interface interface_hashable {
    /**
     * @author fenris
     */
    _hash(): string;
}
/**
 * @desc the ability to generate a string out of the element, which identifies it to a high degree
 * @author fenris
 */
declare function instance_hash<type_value>(value: (type_value & {
    _hash?: (() => string);
})): string;
/**
 * @author fenris
 */
interface interface_showable {
    /**
     * @author fenris
     */
    _show(): string;
}
/**
 * @desc the ability to map the element to a textual representation (most likely not injective)
 * @author fenris
 */
declare function instance_show<type_value>(value: (type_value & {
    _show?: (() => string);
})): string;
/**
 * @author frac
 */
interface interface_decorator<type_core> {
    /**
     * @author frac
     */
    core: type_core;
}
/**
 * @author frac
 */
declare class class_observer {
    /**
     * @author frac
     */
    protected counter: int;
    /**
     * @author frac
     */
    protected actions: {
        [id: string]: (information: Object) => void;
    };
    /**
     * @author frac
     */
    protected buffer: Array<Object>;
    /**
     * @author frac
     */
    constructor();
    /**
     * @author frac
     */
    empty(): boolean;
    /**
     * @author frac
     */
    flush(): void;
    /**
     * @author frac
     */
    set(id: string, action: (information: Object) => void): void;
    /**
     * @author frac
     */
    del(id: string): void;
    /**
     * @author frac
     */
    add(action: (information: Object) => void): void;
    /**
     * @author frac
     */
    notify(information?: Object, delayed?: boolean): void;
    /**
     * @author frac
     */
    rollout(): void;
}
/**
 * @author frac
 */
/**
 * @author frac
 */
/**
 * @author frac
 */
declare class class_error extends Error {
    /**
     * @author frac
     */
    protected suberrors: Array<Error>;
    /**
     * @author frac
     */
    protected mess: string;
    /**
     * @author frac
     */
    constructor(message: string, suberrors?: Array<Error>);
    /**
     * @override
     * @author frac
     */
    toString(): string;
}
declare namespace lib_plankton.base {
    /**
     * returns the current UNIX timestamp
     *
     * @author fenris
     */
    function get_current_timestamp(rounded?: boolean): int;
    /**
     */
    function object_merge(core: Record<string, any>, mantle: Record<string, any>): Record<string, any>;
}
declare namespace lib_plankton.pod {
    /**
     * @author fenris
     */
    type type_pod<type_value> = {
        kind: ("empty" | "filled");
        value?: type_value;
    };
    /**
     * @author fenris
     */
    function make_empty<type_value>(): type_pod<type_value>;
    /**
     * @author fenris
     */
    function make_filled<type_value>(value: type_value): type_pod<type_value>;
    /**
     * whether the pod is filled
     *
     * @author fenris
     */
    function is_filled<type_value>(pod: type_pod<type_value>): boolean;
    /**
     * return the value, stored in the pod-wrapper
     *
     * @author fenris
     */
    function cull<type_value>(pod: type_pod<type_value>): type_value;
    /**
     * to pass on a empty-pod or to use a filled-pod
     *
     * @author fenris
     */
    function propagate<type_value, type_value_>(pod: type_pod<type_value>, function_: ((value: type_value) => type_value_)): type_pod<type_value_>;
    /**
     * @author fenris
     */
    function distinguish<type_value, type_result>(pod: type_pod<type_value>, function_empty: (() => type_result), function_filled: ((value: type_value) => type_result)): type_result;
    /**
     */
    function show<type_value>(pod: type_pod<type_value>, options?: {
        show_value?: ((value: type_value) => string);
    }): string;
}
declare namespace lib_plankton.pod {
    /**
     */
    class class_pod<type_value> {
        private subject;
        private constructor();
        is_empty(): boolean;
        is_filled(): boolean;
        cull(): type_value;
        show(show_value?: any): string;
        toString(): string;
        propagate<type_value_>(function_: ((value: type_value) => type_value_)): class_pod<type_value_>;
        distinguish<type_result>(function_empty: (() => type_result), function_filled: ((value: type_value) => type_result)): type_result;
    }
}
declare namespace lib_plankton.call {
    /**
     * @author fenris
     */
    type type_executor<type_result, type_reason> = ((resolve: (result?: type_result) => any, reject?: (reason?: type_reason) => void) => void);
    /**
     * @author fenris
     */
    function executor_resolve<type_result, type_reason>(result: type_result): type_executor<type_result, type_reason>;
    /**
     * @author fenris
     */
    function executor_reject<type_result, type_reason>(reason: type_reason): type_executor<type_result, type_reason>;
    /**
     * @author fenris
     */
    function executor_transform<type_result_from, type_error_from, type_result_to, type_error_to>(executor: type_executor<type_result_from, type_error_from>, transform_result: (result_from: type_result_from) => type_result_to, transform_reason: (error_from: type_error_from) => type_error_to): type_executor<type_result_to, type_error_to>;
    /**
     * @author fenris
     */
    function executor_transform_default<type_result_from, type_result_to>(executor: type_executor<type_result_from, Error>, transform_result: (result_from: type_result_from) => type_result_to, wrap_string?: string): type_executor<type_result_to, Error>;
    /**
     * @author fenris
     */
    function executor_compose_sequential<type_result_first, type_result_second, type_reason>(first: type_executor<type_result_first, type_reason>, second: (result: type_result_first) => type_executor<type_result_second, type_reason>): type_executor<type_result_second, type_reason>;
    /**
     * @author fenris
     */
    function executor_chain<type_state, type_error>(state: type_state, executors: Array<(state: type_state) => type_executor<type_state, type_error>>): type_executor<type_state, type_error>;
    /**
     * @author fenris
     */
    function executor_first<type_result, type_reason>(executors: Array<type_executor<type_result, type_reason>>): type_executor<type_result, Array<type_reason>>;
    /**
     * @author fenris
     */
    function executor_condense<type_element>(executors: Array<type_executor<type_element, Error>>): type_executor<Array<type_element>, Error>;
    /**
     * @author fenris
     * @deprecated use condense
     */
    function executor_filter<type_element>(executors: Array<type_executor<type_element, Error>>, predicate: (element: type_element) => boolean): type_executor<Array<type_element>, Error>;
    /**
     * @author fenris
     * @deprecated use condense
     */
    function executor_map<type_element1, type_element2>(executors: Array<type_executor<type_element1, Error>>, transformator: (element1: type_element1) => type_element2): type_executor<Array<type_element2>, Error>;
    /**
     * @author fenris
     * @deprecated use condense
     */
    function executor_reduce<type_element, type_result>(executors: Array<type_executor<type_element, Error>>, initial: type_result, accumulator: (result: type_result, element: type_element) => type_result): type_executor<type_result, Error>;
}
declare namespace lib_plankton.call {
    /**
     * @author fenris
     */
    type type_promise<type_result, type_reason> = Promise<type_result>;
    /**
     * @author fenris
     */
    function promise_reject<type_result, type_reason>(reason: type_reason): type_promise<type_result, type_reason>;
    /**
     * @author fenris
     */
    function promise_resolve<type_result, type_reason>(result: type_result): type_promise<type_result, type_reason>;
    /**
     * @author fenris
     */
    function promise_make<type_result, type_reason>(executor: (resolve: (result?: type_result) => void, reject: (reason?: type_reason) => void) => void): type_promise<type_result, type_reason>;
    /**
     * @author fenris
     */
    function promise_then_close<type_result, type_reason>(promise: type_promise<type_result, type_reason>, resolver: (result: type_result) => void, rejector: (reason: type_reason) => void): void;
    /**
     * @author fenris
     */
    function promise_then_append<type_result, type_reason, type_result_>(promise: type_promise<type_result, type_reason>, resolver: (result: type_result) => type_promise<type_result_, type_reason>, rejector?: (reason: type_reason) => type_promise<type_result_, type_reason>): type_promise<type_result_, type_result>;
    /**
     * @author fenris
     */
    function promise_all<type_result, type_reason>(promises: Array<type_promise<type_result, type_reason>>): type_promise<Array<type_result>, type_reason>;
    /**
     * @author fenris
     */
    function promise_chain<type_result, type_reason>(promises: Array<(input: type_result) => type_promise<type_result, type_reason>>, start?: type_result): type_promise<type_result, type_reason>;
    /**
     * @author fenris
     */
    function promise_condense<type_element, type_reason>(promises: Array<() => type_promise<type_element, type_reason>>): type_promise<Array<type_element>, type_reason>;
    /**
     * @author fenris
     */
    function promise_group<type_reason>(promises: {
        [name: string]: () => type_promise<any, type_reason>;
    }, serial?: boolean): type_promise<{
        [name: string]: any;
    }, type_reason>;
    /**
     * @author fenris
     */
    function promise_wrap<type_result_inner, type_result_outer, type_reason>(promise: type_promise<type_result_inner, type_reason>, transformator_result: (reason: type_result_inner) => type_result_outer, transformator_reason?: (reason: type_reason) => type_reason): type_promise<type_result_outer, type_reason>;
    /**
     * @author fenris
     */
    /**
     * @author fenris
     */
    /**
     * @author fenris
     */
    function promise_attach<type_reason>(state: {
        [name: string]: any;
    }, promise: type_promise<any, type_reason>, name: string): type_promise<{
        [name: string]: any;
    }, type_reason>;
    /**
     * @author fenris
     */
    function promise_delay<type_result, type_reason>(promise: type_promise<type_result, type_reason>, delay: int): type_promise<type_result, type_reason>;
    /**
     * @author fenris
     */
    function promise_to_executor<type_result, type_reason>(promise: type_promise<type_result, type_reason>): type_executor<type_result, type_reason>;
}
declare namespace lib_plankton.call {
    /**
     */
    class CancellablePromise<type_result> extends Promise<type_result> {
        /**
         */
        private cancelled;
        /**
         */
        private interval;
        /**
         */
        private subject;
        /**
         */
        constructor(executor: ((resolve: any, reject: any) => void));
        /**
         */
        private clear;
        /**
         */
        then<type_next_resolved, type_next_rejected>(onfulfilled?: ((value: type_result) => (type_next_resolved | PromiseLike<type_next_resolved>)), onrejected?: ((reason: any) => (type_next_rejected | PromiseLike<type_next_rejected>))): Promise<type_next_resolved | type_next_rejected>;
        /**
         */
        catch(x: any): Promise<type_result>;
        /**
         */
        cancel(): void;
    }
}
declare namespace lib_plankton.call {
    /**
     * @author fenris
     */
    enum enum_initializer_state {
        initial = 0,
        waiting = 1,
        successful = 2,
        failed = 3
    }
    /**
     * @author fenris
     */
    type type_initializer<type_result, type_reason> = {
        fetcher: (() => type_promise<type_result, type_reason>);
        state?: enum_initializer_state;
        queue: Array<{
            resolve: ((result?: type_result) => void);
            reject: ((reason?: type_reason) => void);
        }>;
        result?: type_result;
        reason?: type_reason;
    };
    /**
     * @author fenris
     */
    function initializer_make<type_result, type_reason>(fetcher: (() => type_promise<type_result, type_reason>)): type_initializer<type_result, type_reason>;
    /**
     * @author fenris
     */
    function initializer_reset<type_result, type_reason>(subject: type_initializer<type_result, type_reason>): void;
    /**
     * @author fenris
     */
    function initializer_state<type_result, type_reason>(subject: type_initializer<type_result, type_reason>): enum_initializer_state;
    /**
     * @author fenris
     */
    function initializer_get<type_result, type_reason>(subject: type_initializer<type_result, type_reason>): type_promise<type_result, type_reason>;
}
declare namespace lib_plankton.call {
    /**
     * @author fenris
     */
    type type_deferral<type_input, type_output> = {
        representation: (input: type_input) => Promise<type_output>;
    };
    /**
     * @author fenris
     * @desc activates the deferral and handles its output according to a given procedure
     * @param {(value : type_value)=>void} procedure a function which receives the output of the deferral as argument
     */
    function deferral_use<type_input, type_output>(deferral: type_deferral<type_input, type_output>, input: type_input, procedure: (output: type_output) => void): void;
    /**
     * @author fenris
     * @desc creates a deferral-subject (similar to "new Promise", where "convey" reflects "resolve"/"reject")
     */
    function deferral_make<type_input, type_output>(handler: (input: type_input, convey: (output: type_output) => void) => void): type_deferral<type_input, type_output>;
    /**
     * @author fenris
     * @desc wraps a simple function into a deferral (similar to "Promise.resolve"/"Promise.reject")
     */
    function deferral_wrap<type_input, type_output>(function_: (input: type_input) => type_output): type_deferral<type_input, type_output>;
    /**
     * @author fenris
     */
    function deferral_id<type_value>(): type_deferral<type_value, type_value>;
    /**
     * @author fenris
     */
    function deferral_const<type_value>(value: type_value): type_deferral<type_value, type_value>;
    /**
     * @author fenris
     */
    function deferral_delay<type_output>(output: type_output, delay: int): type_deferral<any, type_output>;
    /**
     * @author fenris
     * @desc connects two deferrals to form a new one; the output of the first is taken as input for the second
     *     (similar to "Promise.then" when passing a function which returns a new promise)
     * @param {type_deferral<type_value1>} first a simple deferral
     * @param {(value1 : type_value1)=>type_deferral<type_value2>} second a function depending from a value returning a deferral
     */
    function deferral_compose_serial<type_input, type_between, type_output>(first: type_deferral<type_input, type_between>, second: type_deferral<type_between, type_output>): type_deferral<type_input, type_output>;
    /**
     * @author fenris
     */
    function deferral_compose_parallel<type_input, type_output_left, type_output_right>({ "left": deferral_left, "right": deferral_right, }: {
        left: type_deferral<type_input, type_output_left>;
        right: type_deferral<type_input, type_output_right>;
    }): type_deferral<type_input, {
        left: type_output_left;
        right: type_output_right;
    }>;
    /**
     * @author fenris
     * @desc repeatedly applied serial composition
     */
    function deferral_chain<type_value>(members: Array<type_deferral<type_value, type_value>>): type_deferral<type_value, type_value>;
    /**
     * @author fenris
     */
}
declare namespace lib_plankton.call {
    /**
     * @author fenris
     */
    class class_deferral<type_input, type_output> {
        /**
         * @author fenris
         */
        private subject;
        /**
         * @author fenris
         */
        private constructor();
        /**
         * @author fenris
         */
        private static _cram;
        /**
         * @author fenris
         */
        private static _tear;
        /**
         * @author fenris
         */
        static make<type_input, type_output>(handler: (input: type_input, convey: (value: type_output) => void) => void): class_deferral<type_input, type_output>;
        /**
         * @author fenris
         */
        use(input: type_input, procedure: (value: type_output) => void): void;
        /**
         * @author fenris
         */
        compose_serial<type_output_>(second: class_deferral<type_output, type_output_>): class_deferral<type_input, type_output_>;
        /**
         * @author fenris
         */
        static chain<type_value>(members: Array<class_deferral<type_value, type_value>>): class_deferral<type_value, type_value>;
        /**
         * @author fenris
         */
        static wrap<type_input, type_output>(function_: (input: type_input) => type_output): class_deferral<type_input, type_output>;
        /**
         * @author fenris
         */
        static const_<type_value>(value: type_value): class_deferral<type_value, type_value>;
        /**
         * @author fenris
         */
        static delay<type_output>(output: type_output, delay: int): class_deferral<any, type_output>;
    }
}
declare namespace lib_plankton.call {
    /**
     * converts the "arguments"-map into an array
     *
     * @param {Object} args
     * @author fenris
     */
    function args2list(args: any): Array<any>;
    /**
     * just the empty function; useful for some callbacks etc.
     *
     * @author fenris
     */
    function nothing(): void;
    /**
     * just the identity; useful for some callbacks etc.; defined as function instead of const for using type parameters
     *
     * @author fenris
     */
    function id<type_value>(x: type_value): type_value;
    /**
     * just the identity; useful for some callbacks etc.
     *
     * @author fenris
     */
    function const_<type_value>(x: type_value): ((y: any) => type_value);
    /**
     * composes two functions (i.e. returns a function that return the result of the successive execution of both input-functions)
     *
     * @param {function} function_f
     * @param {function} function_g
     * @author fenris
     */
    function compose<type_x, type_y, type_z>(function_f: ((type_x: any) => type_y), function_g: ((type_y: any) => type_z)): ((value: type_x) => type_z);
    /**
     * transforms a function with sequential input into a function with leveled input; example: add(2,3) = curryfy(add)(2)(3)
     *
     * @param {function} f
     * @return {function} the currified version of the in put function
     * @author fenris
     */
    function curryfy(f: Function): Function;
    /**
     * @author fenris
     */
    function convey(value: any, functions: Array<Function>): any;
    /**
     * @author fenris
     */
    function timeout(procedure: (() => void), delay: int): int;
    /**
     * a definition for a value being "defined"
     *
     * @author neuc
     */
    function is_def<type_value>(obj: type_value, options?: {
        null_is_valid?: boolean;
    }): boolean;
    /**
     * returns the value if set and, when a type is specified, if the type is correct, if not return default_value
     *
     * @author neuc
     */
    function def_val(value: any, default_value: any, options?: {
        type?: (null | string);
        null_is_valid?: boolean;
    }): any;
    /**
     * provides the call for an attribute of a class as a regular function; useful for processing lists of objects
     *
     * @param {string} name the name of the attribute
     * @return {function}
     * @author fenris
     */
    function attribute<type_object, type_attribute>(name: string): ((object: type_object) => type_attribute);
    /**
     * provides a method of a class as a regular function; useful for processing lists of objects
     *
     * @param {string} name the name of the method
     * @return {function}
     * @author fenris
     */
    function method<type_object, type_output>(name: string): ((object: type_object) => type_output);
    /**
     * @author fenris
     */
    type type_coproduct = {
        kind: string;
        data?: any;
    };
    /**
     * @author fenris
     */
    function distinguish<type_output>(coproduct: type_coproduct, handlers: Record<string, ((data?: any) => type_output)>, options?: {
        fallback?: (null | ((coproduct?: type_coproduct) => type_output));
    }): type_output;
    /**
     * Promise version of "setTimeout"
     *
     * @author fenris
     */
    function defer<type_result>(seconds: float, action: (() => type_result)): Promise<type_result>;
    /**
     * for rate_limit_check
     *
     * @author fenris
     */
    type type_mana_snapshot = {
        timestamp: float;
        value: float;
    };
    /**
     * rate limiting algorithm, based on the idea of mana (magic power) in video games:
     * - an actor has a fixed mana capacity, i.e. the maximum amount of available power
     * - an actor has a fixed rate of mana regeneration, i.e. how fast the power is filled up (linear growth)
     * - an action has a defined mana heft, i.e. how much power is required and deducted in order to execute it
     * - mana states are represented by snapshots, i.e. the amount of power at a certain point in time
     *
     * @author fenris
     */
    function rate_limit_check(setup: {
        capacity: float;
        regeneration_rate: float;
        get_snapshot: (() => Promise<(null | type_mana_snapshot)>);
        set_snapshot: ((snapshot: type_mana_snapshot) => Promise<void>);
        update_snapshot: ((timestamp: float, value_increment: float) => Promise<void>);
    }, heft: float): Promise<{
        granted: boolean;
        seconds: (null | float);
    }>;
}