Source file alternative.ml
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module Core_via_pure_map_and_product
(Req : Preface_specs.Alternative.WITH_PURE_MAP_AND_PRODUCT) =
struct
include Applicative.Core_via_pure_map_and_product (Req)
let combine = Req.combine
let neutral = Req.neutral
end
module Core_via_pure_and_apply
(Req : Preface_specs.Alternative.WITH_PURE_AND_APPLY) =
struct
include Applicative.Core_via_pure_and_apply (Req)
let combine = Req.combine
let neutral = Req.neutral
end
module Core_via_pure_and_lift2
(Req : Preface_specs.Alternative.WITH_PURE_AND_LIFT2) =
struct
include Applicative.Core_via_pure_and_lift2 (Req)
let combine = Req.combine
let neutral = Req.neutral
end
let reduce' combine neutral list = List.fold_left combine neutral list
module Operation (Core : Preface_specs.Alternative.CORE) = struct
include Applicative.Operation (Core)
include Alt.Operation (Core)
let times n x = Preface_core.Monoid.times Core.combine Core.neutral n x
let reduce list = reduce' Core.combine Core.neutral list
end
module Syntax (Core : Preface_specs.Alternative.CORE) = Applicative.Syntax (Core)
module Infix
(Core : Preface_specs.Alternative.CORE)
(Operation : Preface_specs.Alternative.OPERATION with type 'a t = 'a Core.t) =
struct
include Applicative.Infix (Core) (Operation)
include Alt.Infix (Core) (Operation)
end
module Via
(Core : Preface_specs.Alternative.CORE)
(Operation : Preface_specs.Alternative.OPERATION)
(Infix : Preface_specs.Alternative.INFIX)
(Syntax : Preface_specs.Alternative.SYNTAX) =
struct
include Core
include Operation
include Syntax
include Infix
module Infix = Infix
module Syntax = Syntax
end
module Via_pure_map_and_product
(Req : Preface_specs.Alternative.WITH_PURE_MAP_AND_PRODUCT) =
struct
module Core = Core_via_pure_map_and_product (Req)
module Operation = Operation (Core)
module Syntax = Syntax (Core)
module Infix = Infix (Core) (Operation)
include Core
include Operation
include Syntax
include Infix
end
module Via_pure_and_apply (Req : Preface_specs.Alternative.WITH_PURE_AND_APPLY) =
struct
module Core = Core_via_pure_and_apply (Req)
module Operation = Operation (Core)
module Syntax = Syntax (Core)
module Infix = Infix (Core) (Operation)
include Core
include Operation
include Syntax
include Infix
end
module Via_pure_and_lift2 (Req : Preface_specs.Alternative.WITH_PURE_AND_LIFT2) =
struct
module Core = Core_via_pure_and_lift2 (Req)
module Operation = Operation (Core)
module Syntax = Syntax (Core)
module Infix = Infix (Core) (Operation)
include Core
include Operation
include Syntax
include Infix
end
module Over_applicative
(Applicative : Preface_specs.APPLICATIVE)
(Req : Preface_specs.Alternative.WITH_NEUTRAL_AND_COMBINE
with type 'a t = 'a Applicative.t) =
Via
(struct
include Applicative
let combine = Req.combine
let neutral = Req.neutral
end)
(struct
include Alt.Operation (struct
include Applicative
include Req
end)
include Applicative
let times n x = Preface_core.Monoid.times Req.combine Req.neutral n x
let reduce list = reduce' Req.combine Req.neutral list
end)
(struct
include Applicative.Infix
let ( <|> ) = Req.combine
end)
(Applicative.Syntax)
module Composition
(F : Preface_specs.ALTERNATIVE)
(G : Preface_specs.APPLICATIVE) =
Over_applicative
(Applicative.Composition (F) (G))
(struct
type 'a t = 'a G.t F.t
let neutral = F.neutral
let combine = F.combine
end)
module From_arrow_plus (A : Preface_specs.ARROW_PLUS) =
Over_applicative
(Applicative.From_arrow
(A))
(struct
type 'a t = (unit, 'a) A.t
let neutral = A.neutral
let combine x y = A.(x <|> y)
end)
module Product (F : Preface_specs.ALTERNATIVE) (G : Preface_specs.ALTERNATIVE) =
Over_applicative
(Applicative.Product (F) (G))
(struct
type 'a t = 'a F.t * 'a G.t
let neutral = (F.neutral, G.neutral)
let combine (x1, y1) (x2, y2) = (F.combine x1 x2, G.combine y1 y2)
end)