package bap-std

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The Binary Analysis Platform Standard Library

Install 

dune-project
 Dependency

github.com Edit opam file Versions (5)

Authors

  1. B
    BAP Team

Maintainers

  1. I
    Ivan Gotovchits <ivg@ieee.org>

Sources

v2.4.0.tar.gz
sha256=63ada71fa4f602bd679174dc6bf780d54aeded40ad4ec20d256df15886e3d2d5
md5=b8b1aff8c6846f2213eafc54de07b304

doc/bap/Bap/Std/Bili/Make/argument-1-M/index.html

Parameter Make.M

include Monads.Std.Monad.Trans.S1
type ('a, 'e) t
type 'a m
type ('a, 'e) e
val lift : 'a m -> ('a, 'e) t

lifts inner monad into the resulting monad

val run : ('a, 'e) t -> ('a, 'e) e

runs the computation

include Monads.Std.Monad.Monad2 with type ('a, 's) t := ('a, 's) t
val void : ('a, 'e) t -> (unit, 'e) t

void m computes m and discrards the result.

val sequence : (unit, 'e) t list -> (unit, 'e) t

sequence xs computes a sequence of computations xs in the left to right order.

val forever : ('a, 'e) t -> ('b, 'e) t

forever xs creates a computationt that never returns.

module Fn : sig ... end

Various function combinators lifted into the Kleisli category.

module Pair : sig ... end

The pair interface lifted into the monad.

module Triple : sig ... end

The triple interface lifted into a monad.

module Lift : sig ... end

Lifts functions into the monad.

module Exn : sig ... end

Interacting between monads and language exceptions

module Collection : sig ... end

Lifts collection interface into the monad.

module List : Collection.S with type 'a t := 'a list

The Monad.Collection.S2 interface for lists

module Seq : Collection.S with type 'a t := 'a Core_kernel.Sequence.t

The Monad.Collection.S2 interface for sequences

include Monads.Std.Monad.Syntax.S2 with type ('a, 'e) t := ('a, 'e) t
val (>=>) : ('a -> ('b, 'e) t) -> ('b -> ('c, 'e) t) -> 'a -> ('c, 'e) t

f >=> g is fun x -> f x >>= g

val (!!) : 'a -> ('a, 'e) t

!!x is return x

val (!$) : ('a -> 'b) -> ('a, 'e) t -> ('b, 'e) t

!$f is Lift.unary f

val (!$$) : ('a -> 'b -> 'c) -> ('a, 'e) t -> ('b, 'e) t -> ('c, 'e) t

!$$f is Lift.binary f

val (!$$$) : ('a -> 'b -> 'c -> 'd) -> ('a, 'e) t -> ('b, 'e) t -> ('c, 'e) t -> ('d, 'e) t

!$$$f is Lift.ternary f

val (!$$$$) : ('a -> 'b -> 'c -> 'd -> 'e) -> ('a, 's) t -> ('b, 's) t -> ('c, 's) t -> ('d, 's) t -> ('e, 's) t

!$$$$f is Lift.quaternary f

val (!$$$$$) : ('a -> 'b -> 'c -> 'd -> 'e -> 'f) -> ('a, 's) t -> ('b, 's) t -> ('c, 's) t -> ('d, 's) t -> ('e, 's) t -> ('f, 's) t

!$$$$$f is Lift.quinary f

include Monads.Std.Monad.Syntax.Let.S2 with type ('a, 'e) t := ('a, 'e) t
val (let*) : ('a, 'e) t -> ('a -> ('b, 'e) t) -> ('b, 'e) t

let* r = f x in b is f x >>= fun r -> b

val (and*) : ('a, 'e) t -> ('b, 'e) t -> ('a * 'b, 'e) t

monoidal product

val (let+) : ('a, 'e) t -> ('a -> 'b) -> ('b, 'e) t

let+ r = f x in b is f x >>| fun r -> b

val (and+) : ('a, 'e) t -> ('b, 'e) t -> ('a * 'b, 'e) t

monoidal product

include Core_kernel.Monad.S2 with type ('a, 'e) t := ('a, 'e) t
val (>>=) : ('a, 'e) t -> ('a -> ('b, 'e) t) -> ('b, 'e) t
val (>>|) : ('a, 'e) t -> ('a -> 'b) -> ('b, 'e) t
module Let_syntax : sig ... end
module Monad_infix : sig ... end
val bind : ('a, 'e) t -> f:('a -> ('b, 'e) t) -> ('b, 'e) t
val return : 'a -> ('a, 'b) t
val map : ('a, 'e) t -> f:('a -> 'b) -> ('b, 'e) t
val join : (('a, 'e) t, 'e) t -> ('a, 'e) t
val ignore_m : ('a, 'e) t -> (unit, 'e) t
val all : ('a, 'e) t list -> ('a list, 'e) t
val all_unit : (unit, 'e) t list -> (unit, 'e) t
module Let : Monads.Std.Monad.Syntax.Let.S2 with type ('a, 'e) t := ('a, 'e) t

Monadic Binding Operators.

module Syntax : Monads.Std.Monad.Syntax.S2 with type ('a, 'e) t := ('a, 'e) t

Monadic operators, see Monad.Syntax.S2 for more.

val put : 's -> (unit, 's) t

put s changes the current state to s

val get : unit -> ('s, 's) t

get s gets the current state

val gets : ('s -> 'r) -> ('r, 's) t

gets p projects the current state with the function p

val update : ('s -> 's) -> (unit, 's) t

update f updates the current state with the function f