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import Lean
namespace Primitives
--------------------
-- ASSERT COMMAND --Std.
--------------------
open Lean Elab Command Term Meta
syntax (name := assert) "#assert" term: command
@[command_elab assert]
unsafe
def assertImpl : CommandElab := fun (_stx: Syntax) => do
runTermElabM (fun _ => do
let r ← evalTerm Bool (mkConst ``Bool) _stx[1]
if not r then
logInfo ("Assertion failed for:\n" ++ _stx[1])
throwError ("Expression reduced to false:\n" ++ _stx[1])
pure ())
#eval 2 == 2
#assert (2 == 2)
-------------
-- PRELUDE --
-------------
-- Results & monadic combinators
inductive Error where
| assertionFailure: Error
| integerOverflow: Error
| divisionByZero: Error
| arrayOutOfBounds: Error
| maximumSizeExceeded: Error
| panic: Error
deriving Repr, BEq
open Error
inductive Result (α : Type u) where
| ret (v: α): Result α
| fail (e: Error): Result α
| div
deriving Repr, BEq
open Result
instance Result_Inhabited (α : Type u) : Inhabited (Result α) :=
Inhabited.mk (fail panic)
instance Result_Nonempty (α : Type u) : Nonempty (Result α) :=
Nonempty.intro div
/- HELPERS -/
def ret? {α: Type u} (r: Result α): Bool :=
match r with
| ret _ => true
| fail _ | div => false
def div? {α: Type u} (r: Result α): Bool :=
match r with
| div => true
| ret _ | fail _ => false
def massert (b:Bool) : Result Unit :=
if b then ret () else fail assertionFailure
def eval_global {α: Type u} (x: Result α) (_: ret? x): α :=
match x with
| fail _ | div => by contradiction
| ret x => x
/- DO-DSL SUPPORT -/
def bind {α : Type u} {β : Type v} (x: Result α) (f: α → Result β) : Result β :=
match x with
| ret v => f v
| fail v => fail v
| div => div
-- Allows using Result in do-blocks
instance : Bind Result where
bind := bind
-- Allows using return x in do-blocks
instance : Pure Result where
pure := fun x => ret x
@[simp] theorem bind_ret (x : α) (f : α → Result β) : bind (.ret x) f = f x := by simp [bind]
@[simp] theorem bind_fail (x : Error) (f : α → Result β) : bind (.fail x) f = .fail x := by simp [bind]
@[simp] theorem bind_div (f : α → Result β) : bind .div f = .div := by simp [bind]
/- CUSTOM-DSL SUPPORT -/
-- Let-binding the Result of a monadic operation is oftentimes not sufficient,
-- because we may need a hypothesis for equational reasoning in the scope. We
-- rely on subtype, and a custom let-binding operator, in effect recreating our
-- own variant of the do-dsl
def Result.attach {α: Type} (o : Result α): Result { x : α // o = ret x } :=
match o with
| ret x => ret ⟨x, rfl⟩
| fail e => fail e
| div => div
@[simp] theorem bind_tc_ret (x : α) (f : α → Result β) :
(do let y ← .ret x; f y) = f x := by simp [Bind.bind, bind]
@[simp] theorem bind_tc_fail (x : Error) (f : α → Result β) :
(do let y ← fail x; f y) = fail x := by simp [Bind.bind, bind]
@[simp] theorem bind_tc_div (f : α → Result β) :
(do let y ← div; f y) = div := by simp [Bind.bind, bind]
----------
-- MISC --
----------
@[simp] def core.mem.replace (a : Type) (x : a) (_ : a) : a × (a → a) := (x, λ x => x)
/-- Aeneas-translated function -- useful to reduce non-recursive definitions.
Use with `simp [ aeneas ]` -/
register_simp_attr aeneas
-- We don't really use raw pointers for now
structure MutRawPtr (T : Type) where
v : T
structure ConstRawPtr (T : Type) where
v : T
end Primitives
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