(* Title: HOL/Library/State_Monad.thy
Author: Florian Haftmann, TU Muenchen
*)
header {* Combinator syntax for generic, open state monads (single threaded monads) *}
theory State_Monad
imports Main Monad_Syntax
begin
subsection {* Motivation *}
text {*
The logic HOL has no notion of constructor classes, so
it is not possible to model monads the Haskell way
in full genericity in Isabelle/HOL.
However, this theory provides substantial support for
a very common class of monads: \emph{state monads}
(or \emph{single-threaded monads}, since a state
is transformed single-threaded).
To enter from the Haskell world,
\url{http://www.engr.mun.ca/~theo/Misc/haskell_and_monads.htm}
makes a good motivating start. Here we just sketch briefly
how those monads enter the game of Isabelle/HOL.
*}
subsection {* State transformations and combinators *}
text {*
We classify functions operating on states into two categories:
\begin{description}
\item[transformations]
with type signature @{text "\<sigma> \<Rightarrow> \<sigma>'"},
transforming a state.
\item[``yielding'' transformations]
with type signature @{text "\<sigma> \<Rightarrow> \<alpha> \<times> \<sigma>'"},
``yielding'' a side result while transforming a state.
\item[queries]
with type signature @{text "\<sigma> \<Rightarrow> \<alpha>"},
computing a result dependent on a state.
\end{description}
By convention we write @{text "\<sigma>"} for types representing states
and @{text "\<alpha>"}, @{text "\<beta>"}, @{text "\<gamma>"}, @{text "\<dots>"}
for types representing side results. Type changes due
to transformations are not excluded in our scenario.
We aim to assert that values of any state type @{text "\<sigma>"}
are used in a single-threaded way: after application
of a transformation on a value of type @{text "\<sigma>"}, the
former value should not be used again. To achieve this,
we use a set of monad combinators:
*}
notation fcomp (infixl "\<circ>>" 60)
notation scomp (infixl "\<circ>\<rightarrow>" 60)
abbreviation (input)
"return \<equiv> Pair"
text {*
Given two transformations @{term f} and @{term g}, they
may be directly composed using the @{term "op \<circ>>"} combinator,
forming a forward composition: @{prop "(f \<circ>> g) s = f (g s)"}.
After any yielding transformation, we bind the side result
immediately using a lambda abstraction. This
is the purpose of the @{term "op \<circ>\<rightarrow>"} combinator:
@{prop "(f \<circ>\<rightarrow> (\<lambda>x. g)) s = (let (x, s') = f s in g s')"}.
For queries, the existing @{term "Let"} is appropriate.
Naturally, a computation may yield a side result by pairing
it to the state from the left; we introduce the
suggestive abbreviation @{term return} for this purpose.
The most crucial distinction to Haskell is that we do
not need to introduce distinguished type constructors
for different kinds of state. This has two consequences:
\begin{itemize}
\item The monad model does not state anything about
the kind of state; the model for the state is
completely orthogonal and may be
specified completely independently.
\item There is no distinguished type constructor
encapsulating away the state transformation, i.e.~transformations
may be applied directly without using any lifting
or providing and dropping units (``open monad'').
\item The type of states may change due to a transformation.
\end{itemize}
*}
subsection {* Monad laws *}
text {*
The common monadic laws hold and may also be used
as normalization rules for monadic expressions:
*}
lemmas monad_simp = Pair_scomp scomp_Pair id_fcomp fcomp_id
scomp_scomp scomp_fcomp fcomp_scomp fcomp_assoc
text {*
Evaluation of monadic expressions by force:
*}
lemmas monad_collapse = monad_simp fcomp_apply scomp_apply split_beta
subsection {* Do-syntax *}
nonterminals
sdo_binds sdo_bind
syntax
"_sdo_block" :: "sdo_binds \<Rightarrow> 'a" ("exec {//(2 _)//}" [12] 62)
"_sdo_bind" :: "[pttrn, 'a] \<Rightarrow> sdo_bind" ("(_ <-/ _)" 13)
"_sdo_let" :: "[pttrn, 'a] \<Rightarrow> sdo_bind" ("(2let _ =/ _)" [1000, 13] 13)
"_sdo_then" :: "'a \<Rightarrow> sdo_bind" ("_" [14] 13)
"_sdo_final" :: "'a \<Rightarrow> sdo_binds" ("_")
"_sdo_cons" :: "[sdo_bind, sdo_binds] \<Rightarrow> sdo_binds" ("_;//_" [13, 12] 12)
syntax (xsymbols)
"_sdo_bind" :: "[pttrn, 'a] \<Rightarrow> sdo_bind" ("(_ \<leftarrow>/ _)" 13)
translations
"_sdo_block (_sdo_cons (_sdo_bind p t) (_sdo_final e))"
== "CONST scomp t (\<lambda>p. e)"
"_sdo_block (_sdo_cons (_sdo_then t) (_sdo_final e))"
=> "CONST fcomp t e"
"_sdo_final (_sdo_block (_sdo_cons (_sdo_then t) (_sdo_final e)))"
<= "_sdo_final (CONST fcomp t e)"
"_sdo_block (_sdo_cons (_sdo_then t) e)"
<= "CONST fcomp t (_sdo_block e)"
"_sdo_block (_sdo_cons (_sdo_let p t) bs)"
== "let p = t in _sdo_block bs"
"_sdo_block (_sdo_cons b (_sdo_cons c cs))"
== "_sdo_block (_sdo_cons b (_sdo_final (_sdo_block (_sdo_cons c cs))))"
"_sdo_cons (_sdo_let p t) (_sdo_final s)"
== "_sdo_final (let p = t in s)"
"_sdo_block (_sdo_final e)" => "e"
text {*
For an example, see HOL/Extraction/Higman.thy.
*}
end