type nonrec t('a)
= Relude_IO.t('a, ERR.t)
;
let map: ('a => 'b) => Functor.t('a) => Functor.t('b);
let mapError: ('a => 'b) => Relude_IO.Bifunctor.t('c, 'a) => Relude_IO.Bifunctor.t('c, 'b);
let flipMap: Functor.t('a) => ('a => 'b) => Functor.t('b);
let void: Functor.t('a) => Functor.t(unit);
let voidRight: 'a => Functor.t('b) => Functor.t('a);
let voidLeft: Functor.t('a) => 'b => Functor.t('b);
let flap: Functor.t(('a => 'b)) => 'a => Functor.t('b);
let alt: Relude_IO.t('a, 'b) => Relude_IO.t('a, 'b) => Relude_IO.t('a, 'b);
let orElse: fallback:Alt.t('a) => Alt.t('a) => Alt.t('a);
let apply: Apply.t(('a => 'b)) => Apply.t('a) => Apply.t('b);
let applyFirst: Apply.t('a) => Apply.t('b) => Apply.t('a);
let applySecond: Apply.t('a) => Apply.t('b) => Apply.t('b);
let map2: ('a => 'b => 'c) => Apply.t('a) => Apply.t('b) => Apply.t('c);
let map3: ('a => 'b => 'c => 'd) => Apply.t('a) => Apply.t('b) => Apply.t('c) => Apply.t('d);
let map4: ('a => 'b => 'c => 'd => 'e) => Apply.t('a) => Apply.t('b) => Apply.t('c) => Apply.t('d) => Apply.t('e);
let map5: ('a => 'b => 'c => 'd => 'e => 'f) => Apply.t('a) => Apply.t('b) => Apply.t('c) => Apply.t('d) => Apply.t('e) => Apply.t('f);
let tuple2: Apply.t('a) => Apply.t('b) => Apply.t(('a, 'b));
let tuple3: Apply.t('a) => Apply.t('b) => Apply.t('c) => Apply.t(('a, 'b, 'c));
let tuple4: Apply.t('a) => Apply.t('b) => Apply.t('c) => Apply.t('d) => Apply.t(('a, 'b, 'c, 'd));
let tuple5: Apply.t('a) => Apply.t('b) => Apply.t('c) => Apply.t('d) => Apply.t('e) => Apply.t(('a, 'b, 'c, 'd, 'e));
let mapTuple2: ('a => 'b => 'c) => (Apply.t('a), Apply.t('b)) => Apply.t('c);
let mapTuple3: ('a => 'b => 'c => 'd) => (Apply.t('a), Apply.t('b), Apply.t('c)) => Apply.t('d);
let mapTuple4: ('a => 'b => 'c => 'd => 'e) => (Apply.t('a), Apply.t('b), Apply.t('c), Apply.t('d)) => Apply.t('e);
let mapTuple5: ('a => 'b => 'c => 'd => 'e => 'f) => (Apply.t('a), Apply.t('b), Apply.t('c), Apply.t('d), Apply.t('e)) => Apply.t('f);
let pure: 'a => Applicative.t('a);
let liftA1: ('a => 'b) => Applicative.t('a) => Applicative.t('b);
let all: list(Applicative.t('a)) => Applicative.t(list('a));
let bind: Monad.t('a) => ('a => Monad.t('b)) => Monad.t('b);
let flatMap: ('a => Monad.t('b)) => Monad.t('a) => Monad.t('b);
let flatten: Monad.t(Monad.t('a)) => Monad.t('a);
let composeKleisli: ('a => Monad.t('b)) => ('b => Monad.t('c)) => 'a => Monad.t('c);
let flipComposeKleisli: ('b => Monad.t('c)) => ('a => Monad.t('b)) => 'a => Monad.t('c);
let liftM1: ('a => 'b) => Monad.t('a) => Monad.t('b);
let when_: Monad.t(bool) => Monad.t(unit) => Monad.t(unit);
let unless: Monad.t(bool) => Monad.t(unit) => Monad.t(unit);
let throwError: MonadThrow.e => MonadThrow.t('a);
let catchError: (MonadError.e => MonadError.t('a)) => MonadError.t('a) => MonadError.t('a);
let andThen: Semigroupoid.t('a, 'b) => Semigroupoid.t('b, 'c) => Semigroupoid.t('a, 'c);