Documentation

Batteries.Control.Nondet.Basic

A nondeterminism monad. #

We represent nondeterministic values in a type α as a single field structure containing an MLList m (σ × α), i.e. as a monadic lazy list of possible values, each equipped with the backtrackable state required to run further computations in the ambient monad.

We provide an Alternative Monad instance, as well as functions bind, mapM, and filterMapM, and functions singletonM, ofListM, ofOptionM, and firstM for entering and leaving the nondeterministic world.

Operations on the nondeterministic value via bind, mapM, and filterMapM run with the appropriate backtrackable state, and are responsible for updating the state themselves (typically this doesn't need to be done explicitly, but just happens as a side effect in the monad m).

structure Nondet {σ : Type} (m : Type → Type) [Lean.MonadBacktrack σ m] (α : Type) :

Nondet m α is variation on MLList m α suitable for use with backtrackable monads m.

We think of Nondet m α as a nondeterministic value in α, with the possible alternatives stored in a monadic lazy list.

Along with each a : α we store the backtrackable state, and ensure that monadic operations on alternatives run with the appropriate state.

Operations on the nondeterministic value via bind, mapM, and filterMapM run with the appropriate backtrackable state, and are responsible for updating the state themselves (typically this doesn't need to be done explicitly, but just happens as a side effect in the monad m).

toMLList : MLList m (α × σ)
Convert a non-deterministic value into a lazy list, keeping the backtrackable state. Be careful that monadic operations on the MLList will not respect this state!

Instances For

def Nondet.nil {σ : Type} {m : Type → Type} [Lean.MonadBacktrack σ m] {α : Type} :

The empty nondeterministic value.

Equations

Nondet.nil = { toMLList := MLList.nil }

Instances For

instance Nondet.instInhabited {σ : Type} {m : Type → Type} [Lean.MonadBacktrack σ m] {α : Type} :

Inhabited (Nondet m α)

Equations

Nondet.instInhabited = { default := Nondet.nil }

def Nondet.squash {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (L : Unit → m (Nondet m α)) :

Squash a monadic nondeterministic value to a nondeterministic value.

Equations

Nondet.squash L = { toMLList := MLList.squash fun (x : Unit) => do let __do_lift ← L () pure __do_lift.toMLList }

Instances For

partial def Nondet.bind {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} {β : Type} (L : Nondet m α) (f : α → Nondet m β) :

Bind a nondeterministic function over a nondeterministic value, ensuring the function is run with the relevant backtrackable state at each value.

def Nondet.singletonM {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (x : m α) :

Convert any value in the monad to the singleton nondeterministic value.

Equations

Nondet.singletonM x = { toMLList := MLList.singletonM do let a ← x let __do_lift ← Lean.saveState pure (a, __do_lift) }

Instances For

def Nondet.singleton {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (x : α) :

Convert a value to the singleton nondeterministic value.

Equations

Nondet.singleton x = Nondet.singletonM (pure x)

Instances For

instance Nondet.instMonad {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] :

Monad (Nondet m)

Nondet m is a monad.

Equations

Nondet.instMonad = Monad.mk

instance Nondet.instAlternative {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] :

Alternative (Nondet m)

Nondet m is an alternative monad.

Equations

One or more equations did not get rendered due to their size.

instance Nondet.instMonadLift {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] :

MonadLift m (Nondet m)

Equations

Nondet.instMonadLift = { monadLift := fun {α : Type} => Nondet.singletonM }

def Nondet.ofListM {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (L : List (m α)) :

Lift a list of monadic values to a nondeterministic value. We ensure that each monadic value is evaluated with the same backtrackable state.

Equations

One or more equations did not get rendered due to their size.

Instances For

def Nondet.ofList {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (L : List α) :

Lift a list of values to a nondeterministic value. (The backtrackable state in each will be identical: whatever the state was when we first read from the result.)

Equations

Nondet.ofList L = Nondet.ofListM (List.map pure L)

Instances For

def Nondet.mapM {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} {β : Type} (f : α → m β) (L : Nondet m α) :

Apply a function which returns values in the monad to every alternative of a Nondet m α.

Equations

Nondet.mapM f L = L.bind fun (a : α) => Nondet.singletonM (f a)

Instances For

def Nondet.map {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} {β : Type} (f : α → β) (L : Nondet m α) :

Apply a function to each alternative in a Nondet m α .

Equations

Nondet.map f L = Nondet.mapM (fun (a : α) => pure (f a)) L

Instances For

def Nondet.ofOptionM {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (x : m (Option α)) :

Convert a monadic optional value to a nondeterministic value.

Equations

Nondet.ofOptionM x = Nondet.squash fun (x_1 : Unit) => do let __do_lift ← x match __do_lift with | none => pure Nondet.nil | some a => pure (Nondet.singleton a)

Instances For

def Nondet.ofOption {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (x : Option α) :

Convert an optional value to a nondeterministic value.

Equations

Nondet.ofOption x = Nondet.ofOptionM (pure x)

Instances For

def Nondet.filterMapM {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} {β : Type} (f : α → m (Option β)) (L : Nondet m α) :

Filter and map a nondeterministic value using a monadic function which may return none.

Equations

Nondet.filterMapM f L = L.bind fun (a : α) => Nondet.ofOptionM (f a)

Instances For

def Nondet.filterMap {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} {β : Type} (f : α → Option β) (L : Nondet m α) :

Filter and map a nondeterministic value.

Equations

Nondet.filterMap f L = Nondet.filterMapM (fun (a : α) => pure (f a)) L

Instances For

def Nondet.filterM {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (p : α → m (ULift Bool)) (L : Nondet m α) :

Filter a nondeterministic value using a monadic predicate.

Equations

Nondet.filterM p L = Nondet.filterMapM (fun (a : α) => do let __do_lift ← p a if __do_lift.down = true then pure (some a) else pure none) L

Instances For

def Nondet.filter {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (p : α → Bool) (L : Nondet m α) :

Filter a nondeterministic value.

Equations

Nondet.filter p L = Nondet.filterM (fun (a : α) => pure { down := p a }) L

Instances For

partial def Nondet.iterate {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (f : α → Nondet m α) (a : α) :

All iterations of a non-deterministic function on an initial value.

(That is, depth first search.)

def Nondet.head {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} [Alternative m] (L : Nondet m α) :

m α

Find the first alternative in a nondeterministic value, as a monadic value.

Equations

L.head = do let __discr ← L.toMLList.head match __discr with | (x, s) => do Lean.restoreState s pure x

Instances For

def Nondet.firstM {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} {β : Type} [Alternative m] (L : Nondet m α) (f : α → m (Option β)) :

m β

Find the value of a monadic function on the first alternative in a nondeterministic value where the function succeeds.

Equations

L.firstM f = (Nondet.filterMapM f L).head

Instances For

def Nondet.toMLList' {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (L : Nondet m α) :

Convert a non-deterministic value into a lazy list, by discarding the backtrackable state.

Equations

L.toMLList' = MLList.map (fun (x : α × σ) => x.fst) L.toMLList

Instances For

def Nondet.toList {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (L : Nondet m α) :

m (List (α × σ))

Convert a non-deterministic value into a list in the monad, retaining the backtrackable state.

Equations

L.toList = L.toMLList.force

Instances For

def Nondet.toList' {σ : Type} {m : Type → Type} [Monad m] [Lean.MonadBacktrack σ m] {α : Type} (L : Nondet m α) :

m (List α)

Convert a non-deterministic value into a list in the monad, by discarding the backtrackable state.

Equations

L.toList' = (MLList.map (fun (x : α × σ) => x.fst) L.toMLList).force

Instances For

instance instMonadBacktrackUnitId_batteries :

Lean.MonadBacktrack Unit Id

The Id monad is trivially backtrackable, with state Unit.

Equations

instMonadBacktrackUnitId_batteries = { saveState := pure (), restoreState := fun (x : Unit) => pure () }