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|
import Lean
import Lean.Meta.Tactic.Simp
import Init.Data.List.Basic
import Mathlib.Tactic.RunCmd
import Mathlib.Tactic.Linarith
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]
----------------------
-- MACHINE INTEGERS --
----------------------
-- We redefine our machine integers types.
-- For Isize/Usize, we reuse `getNumBits` from `USize`. You cannot reduce `getNumBits`
-- using the simplifier, meaning that proofs do not depend on the compile-time value of
-- USize.size. (Lean assumes 32 or 64-bit platforms, and Rust doesn't really support, at
-- least officially, 16-bit microcontrollers, so this seems like a fine design decision
-- for now.)
-- Note from Chris Bailey: "If there's more than one salient property of your
-- definition then the subtyping strategy might get messy, and the property part
-- of a subtype is less discoverable by the simplifier or tactics like
-- library_search." So, we will not add refinements on the return values of the
-- operations defined on Primitives, but will rather rely on custom lemmas to
-- invert on possible return values of the primitive operations.
-- Machine integer constants, done via `ofNatCore`, which requires a proof that
-- the `Nat` fits within the desired integer type. We provide a custom tactic.
open System.Platform.getNumBits
-- TODO: is there a way of only importing System.Platform.getNumBits?
--
@[simp] def size_num_bits : Nat := (System.Platform.getNumBits ()).val
-- Remark: Lean seems to use < for the comparisons with the upper bounds by convention.
-- The "structured" bounds
def Isize.smin : Int := - (HPow.hPow 2 (size_num_bits - 1))
def Isize.smax : Int := (HPow.hPow 2 (size_num_bits - 1)) - 1
def I8.smin : Int := - (HPow.hPow 2 7)
def I8.smax : Int := HPow.hPow 2 7 - 1
def I16.smin : Int := - (HPow.hPow 2 15)
def I16.smax : Int := HPow.hPow 2 15 - 1
def I32.smin : Int := -(HPow.hPow 2 31)
def I32.smax : Int := HPow.hPow 2 31 - 1
def I64.smin : Int := -(HPow.hPow 2 63)
def I64.smax : Int := HPow.hPow 2 63 - 1
def I128.smin : Int := -(HPow.hPow 2 127)
def I128.smax : Int := HPow.hPow 2 127 - 1
def Usize.smin : Int := 0
def Usize.smax : Int := HPow.hPow 2 size_num_bits - 1
def U8.smin : Int := 0
def U8.smax : Int := HPow.hPow 2 8 - 1
def U16.smin : Int := 0
def U16.smax : Int := HPow.hPow 2 16 - 1
def U32.smin : Int := 0
def U32.smax : Int := HPow.hPow 2 32 - 1
def U64.smin : Int := 0
def U64.smax : Int := HPow.hPow 2 64 - 1
def U128.smin : Int := 0
def U128.smax : Int := HPow.hPow 2 128 - 1
-- The "normalized" bounds, that we use in practice
def I8.min := -128
def I8.max := 127
def I16.min := -32768
def I16.max := 32767
def I32.min := -2147483648
def I32.max := 2147483647
def I64.min := -9223372036854775808
def I64.max := 9223372036854775807
def I128.min := -170141183460469231731687303715884105728
def I128.max := 170141183460469231731687303715884105727
@[simp] def U8.min := 0
def U8.max := 255
@[simp] def U16.min := 0
def U16.max := 65535
@[simp] def U32.min := 0
def U32.max := 4294967295
@[simp] def U64.min := 0
def U64.max := 18446744073709551615
@[simp] def U128.min := 0
def U128.max := 340282366920938463463374607431768211455
@[simp] def Usize.min := 0
def Isize.refined_min : { n:Int // n = I32.min ∨ n = I64.min } :=
⟨ Isize.smin, by
simp [Isize.smin]
cases System.Platform.numBits_eq <;>
unfold System.Platform.numBits at * <;> simp [*] ⟩
def Isize.refined_max : { n:Int // n = I32.max ∨ n = I64.max } :=
⟨ Isize.smax, by
simp [Isize.smax]
cases System.Platform.numBits_eq <;>
unfold System.Platform.numBits at * <;> simp [*] ⟩
def Usize.refined_max : { n:Int // n = U32.max ∨ n = U64.max } :=
⟨ Usize.smax, by
simp [Usize.smax]
cases System.Platform.numBits_eq <;>
unfold System.Platform.numBits at * <;> simp [*] ⟩
def Isize.min := Isize.refined_min.val
def Isize.max := Isize.refined_max.val
def Usize.max := Usize.refined_max.val
inductive ScalarTy :=
| Isize
| I8
| I16
| I32
| I64
| I128
| Usize
| U8
| U16
| U32
| U64
| U128
def Scalar.smin (ty : ScalarTy) : Int :=
match ty with
| .Isize => Isize.smin
| .I8 => I8.smin
| .I16 => I16.smin
| .I32 => I32.smin
| .I64 => I64.smin
| .I128 => I128.smin
| .Usize => Usize.smin
| .U8 => U8.smin
| .U16 => U16.smin
| .U32 => U32.smin
| .U64 => U64.smin
| .U128 => U128.smin
def Scalar.smax (ty : ScalarTy) : Int :=
match ty with
| .Isize => Isize.smax
| .I8 => I8.smax
| .I16 => I16.smax
| .I32 => I32.smax
| .I64 => I64.smax
| .I128 => I128.smax
| .Usize => Usize.smax
| .U8 => U8.smax
| .U16 => U16.smax
| .U32 => U32.smax
| .U64 => U64.smax
| .U128 => U128.smax
def Scalar.min (ty : ScalarTy) : Int :=
match ty with
| .Isize => Isize.min
| .I8 => I8.min
| .I16 => I16.min
| .I32 => I32.min
| .I64 => I64.min
| .I128 => I128.min
| .Usize => Usize.min
| .U8 => U8.min
| .U16 => U16.min
| .U32 => U32.min
| .U64 => U64.min
| .U128 => U128.min
def Scalar.max (ty : ScalarTy) : Int :=
match ty with
| .Isize => Isize.max
| .I8 => I8.max
| .I16 => I16.max
| .I32 => I32.max
| .I64 => I64.max
| .I128 => I128.max
| .Usize => Usize.max
| .U8 => U8.max
| .U16 => U16.max
| .U32 => U32.max
| .U64 => U64.max
| .U128 => U128.max
def Scalar.smin_eq (ty : ScalarTy) : Scalar.min ty = Scalar.smin ty := by
cases ty <;> rfl
def Scalar.smax_eq (ty : ScalarTy) : Scalar.max ty = Scalar.smax ty := by
cases ty <;> rfl
-- "Conservative" bounds
-- We use those because we can't compare to the isize bounds (which can't
-- reduce at compile-time). Whenever we perform an arithmetic operation like
-- addition we need to check that the result is in bounds: we first compare
-- to the conservative bounds, which reduce, then compare to the real bounds.
-- This is useful for the various #asserts that we want to reduce at
-- type-checking time.
def Scalar.cMin (ty : ScalarTy) : Int :=
match ty with
| .Isize => Scalar.min .I32
| _ => Scalar.min ty
def Scalar.cMax (ty : ScalarTy) : Int :=
match ty with
| .Isize => Scalar.max .I32
| .Usize => Scalar.max .U32
| _ => Scalar.max ty
theorem Scalar.cMin_bound ty : Scalar.min ty ≤ Scalar.cMin ty := by
cases ty <;> simp [Scalar.min, Scalar.max, Scalar.cMin, Scalar.cMax] at *
have h := Isize.refined_min.property
cases h <;> simp [*, Isize.min]
theorem Scalar.cMax_bound ty : Scalar.cMax ty ≤ Scalar.max ty := by
cases ty <;> simp [Scalar.min, Scalar.max, Scalar.cMin, Scalar.cMax] at *
. have h := Isize.refined_max.property
cases h <;> simp [*, Isize.max]
. have h := Usize.refined_max.property
cases h <;> simp [*, Usize.max]
theorem Scalar.cMin_suffices ty (h : Scalar.cMin ty ≤ x) : Scalar.min ty ≤ x := by
have := Scalar.cMin_bound ty
linarith
theorem Scalar.cMax_suffices ty (h : x ≤ Scalar.cMax ty) : x ≤ Scalar.max ty := by
have := Scalar.cMax_bound ty
linarith
structure Scalar (ty : ScalarTy) where
val : Int
hmin : Scalar.min ty ≤ val
hmax : val ≤ Scalar.max ty
deriving Repr
theorem Scalar.bound_suffices (ty : ScalarTy) (x : Int) :
Scalar.cMin ty ≤ x ∧ x ≤ Scalar.cMax ty ->
Scalar.min ty ≤ x ∧ x ≤ Scalar.max ty
:=
λ h => by
apply And.intro <;> have hmin := Scalar.cMin_bound ty <;> have hmax := Scalar.cMax_bound ty <;> linarith
def Scalar.ofIntCore {ty : ScalarTy} (x : Int)
(hmin : Scalar.min ty ≤ x) (hmax : x ≤ Scalar.max ty) : Scalar ty :=
{ val := x, hmin := hmin, hmax := hmax }
-- Tactic to prove that integers are in bounds
-- TODO: use this: https://leanprover.zulipchat.com/#narrow/stream/270676-lean4/topic/instance.20with.20tactic.20autoparam
syntax "intlit" : tactic
macro_rules
| `(tactic| intlit) => `(tactic| apply Scalar.bound_suffices; decide)
def Scalar.ofInt {ty : ScalarTy} (x : Int)
(h : Scalar.min ty ≤ x ∧ x ≤ Scalar.max ty := by intlit) : Scalar ty :=
-- Remark: we initially wrote:
-- let ⟨ hmin, hmax ⟩ := h
-- Scalar.ofIntCore x hmin hmax
-- We updated to the line below because a similar pattern in `Scalar.tryMk`
-- made reduction block. Both versions seem to work for `Scalar.ofInt`, though.
-- TODO: investigate
Scalar.ofIntCore x h.left h.right
@[simp] def Scalar.check_bounds (ty : ScalarTy) (x : Int) : Bool :=
(Scalar.cMin ty ≤ x || Scalar.min ty ≤ x) ∧ (x ≤ Scalar.cMax ty || x ≤ Scalar.max ty)
theorem Scalar.check_bounds_prop {ty : ScalarTy} {x : Int} (h: Scalar.check_bounds ty x) :
Scalar.min ty ≤ x ∧ x ≤ Scalar.max ty := by
simp at *
have ⟨ hmin, hmax ⟩ := h
have hbmin := Scalar.cMin_bound ty
have hbmax := Scalar.cMax_bound ty
cases hmin <;> cases hmax <;> apply And.intro <;> linarith
-- Further thoughts: look at what has been done here:
-- https://github.com/leanprover-community/mathlib4/blob/master/Mathlib/Data/Fin/Basic.lean
-- and
-- https://github.com/leanprover-community/mathlib4/blob/master/Mathlib/Data/UInt.lean
-- which both contain a fair amount of reasoning already!
def Scalar.tryMk (ty : ScalarTy) (x : Int) : Result (Scalar ty) :=
if h:Scalar.check_bounds ty x then
-- If we do:
-- ```
-- let ⟨ hmin, hmax ⟩ := (Scalar.check_bounds_prop h)
-- Scalar.ofIntCore x hmin hmax
-- ```
-- then normalization blocks (for instance, some proofs which use reflexivity fail).
-- However, the version below doesn't block reduction (TODO: investigate):
return Scalar.ofInt x (Scalar.check_bounds_prop h)
else fail integerOverflow
def Scalar.neg {ty : ScalarTy} (x : Scalar ty) : Result (Scalar ty) := Scalar.tryMk ty (- x.val)
def Scalar.div {ty : ScalarTy} (x : Scalar ty) (y : Scalar ty) : Result (Scalar ty) :=
if y.val != 0 then Scalar.tryMk ty (x.val / y.val) else fail divisionByZero
-- Our custom remainder operation, which satisfies the semantics of Rust
-- TODO: is there a better way?
def scalar_rem (x y : Int) : Int :=
if 0 ≤ x then |x| % |y|
else - (|x| % |y|)
-- Our custom division operation, which satisfies the semantics of Rust
-- TODO: is there a better way?
def scalar_div (x y : Int) : Int :=
if 0 ≤ x && 0 ≤ y then |x| / |y|
else if 0 ≤ x && y < 0 then - (|x| / |y|)
else if x < 0 && 0 ≤ y then - (|x| / |y|)
else |x| / |y|
-- Checking that the remainder operation is correct
#assert scalar_rem 1 2 = 1
#assert scalar_rem (-1) 2 = -1
#assert scalar_rem 1 (-2) = 1
#assert scalar_rem (-1) (-2) = -1
#assert scalar_rem 7 3 = (1:Int)
#assert scalar_rem (-7) 3 = -1
#assert scalar_rem 7 (-3) = 1
#assert scalar_rem (-7) (-3) = -1
-- Checking that the division operation is correct
#assert scalar_div 3 2 = 1
#assert scalar_div (-3) 2 = -1
#assert scalar_div 3 (-2) = -1
#assert scalar_div (-3) (-2) = 1
#assert scalar_div 7 3 = 2
#assert scalar_div (-7) 3 = -2
#assert scalar_div 7 (-3) = -2
#assert scalar_div (-7) (-3) = 2
def Scalar.rem {ty : ScalarTy} (x : Scalar ty) (y : Scalar ty) : Result (Scalar ty) :=
if y.val != 0 then Scalar.tryMk ty (x.val % y.val) else fail divisionByZero
def Scalar.add {ty : ScalarTy} (x : Scalar ty) (y : Scalar ty) : Result (Scalar ty) :=
Scalar.tryMk ty (x.val + y.val)
def Scalar.sub {ty : ScalarTy} (x : Scalar ty) (y : Scalar ty) : Result (Scalar ty) :=
Scalar.tryMk ty (x.val - y.val)
def Scalar.mul {ty : ScalarTy} (x : Scalar ty) (y : Scalar ty) : Result (Scalar ty) :=
Scalar.tryMk ty (x.val * y.val)
-- TODO: instances of +, -, * etc. for scalars
-- Cast an integer from a [src_ty] to a [tgt_ty]
-- TODO: check the semantics of casts in Rust
def Scalar.cast {src_ty : ScalarTy} (tgt_ty : ScalarTy) (x : Scalar src_ty) : Result (Scalar tgt_ty) :=
Scalar.tryMk tgt_ty x.val
-- The scalar types
-- We declare the definitions as reducible so that Lean can unfold them (useful
-- for type class resolution for instance).
@[reducible] def Isize := Scalar .Isize
@[reducible] def I8 := Scalar .I8
@[reducible] def I16 := Scalar .I16
@[reducible] def I32 := Scalar .I32
@[reducible] def I64 := Scalar .I64
@[reducible] def I128 := Scalar .I128
@[reducible] def Usize := Scalar .Usize
@[reducible] def U8 := Scalar .U8
@[reducible] def U16 := Scalar .U16
@[reducible] def U32 := Scalar .U32
@[reducible] def U64 := Scalar .U64
@[reducible] def U128 := Scalar .U128
-- TODO: below: not sure this is the best way.
-- Should we rather overload operations like +, -, etc.?
-- Also, it is possible to automate the generation of those definitions
-- with macros (but would it be a good idea? It would be less easy to
-- read the file, which is not supposed to change a lot)
-- Negation
/--
Remark: there is no heterogeneous negation in the Lean prelude: we thus introduce
one here.
The notation typeclass for heterogeneous addition.
This enables the notation `- a : β` where `a : α`.
-/
class HNeg (α : Type u) (β : outParam (Type v)) where
/-- `- a` computes the negation of `a`.
The meaning of this notation is type-dependent. -/
hNeg : α → β
prefix:75 "-" => HNeg.hNeg
instance : HNeg Isize (Result Isize) where hNeg x := Scalar.neg x
instance : HNeg I8 (Result I8) where hNeg x := Scalar.neg x
instance : HNeg I16 (Result I16) where hNeg x := Scalar.neg x
instance : HNeg I32 (Result I32) where hNeg x := Scalar.neg x
instance : HNeg I64 (Result I64) where hNeg x := Scalar.neg x
instance : HNeg I128 (Result I128) where hNeg x := Scalar.neg x
-- Addition
instance {ty} : HAdd (Scalar ty) (Scalar ty) (Result (Scalar ty)) where
hAdd x y := Scalar.add x y
-- Substraction
instance {ty} : HSub (Scalar ty) (Scalar ty) (Result (Scalar ty)) where
hSub x y := Scalar.sub x y
-- Multiplication
instance {ty} : HMul (Scalar ty) (Scalar ty) (Result (Scalar ty)) where
hMul x y := Scalar.mul x y
-- Division
instance {ty} : HDiv (Scalar ty) (Scalar ty) (Result (Scalar ty)) where
hDiv x y := Scalar.div x y
-- Remainder
instance {ty} : HMod (Scalar ty) (Scalar ty) (Result (Scalar ty)) where
hMod x y := Scalar.rem x y
-- ofIntCore
-- TODO: typeclass?
def Isize.ofIntCore := @Scalar.ofIntCore .Isize
def I8.ofIntCore := @Scalar.ofIntCore .I8
def I16.ofIntCore := @Scalar.ofIntCore .I16
def I32.ofIntCore := @Scalar.ofIntCore .I32
def I64.ofIntCore := @Scalar.ofIntCore .I64
def I128.ofIntCore := @Scalar.ofIntCore .I128
def Usize.ofIntCore := @Scalar.ofIntCore .Usize
def U8.ofIntCore := @Scalar.ofIntCore .U8
def U16.ofIntCore := @Scalar.ofIntCore .U16
def U32.ofIntCore := @Scalar.ofIntCore .U32
def U64.ofIntCore := @Scalar.ofIntCore .U64
def U128.ofIntCore := @Scalar.ofIntCore .U128
-- ofInt
-- TODO: typeclass?
def Isize.ofInt := @Scalar.ofInt .Isize
def I8.ofInt := @Scalar.ofInt .I8
def I16.ofInt := @Scalar.ofInt .I16
def I32.ofInt := @Scalar.ofInt .I32
def I64.ofInt := @Scalar.ofInt .I64
def I128.ofInt := @Scalar.ofInt .I128
def Usize.ofInt := @Scalar.ofInt .Usize
def U8.ofInt := @Scalar.ofInt .U8
def U16.ofInt := @Scalar.ofInt .U16
def U32.ofInt := @Scalar.ofInt .U32
def U64.ofInt := @Scalar.ofInt .U64
def U128.ofInt := @Scalar.ofInt .U128
-- Comparisons
instance {ty} : LT (Scalar ty) where
lt a b := LT.lt a.val b.val
instance {ty} : LE (Scalar ty) where le a b := LE.le a.val b.val
instance Scalar.decLt {ty} (a b : Scalar ty) : Decidable (LT.lt a b) := Int.decLt ..
instance Scalar.decLe {ty} (a b : Scalar ty) : Decidable (LE.le a b) := Int.decLe ..
theorem Scalar.eq_of_val_eq {ty} : ∀ {i j : Scalar ty}, Eq i.val j.val → Eq i j
| ⟨_, _, _⟩, ⟨_, _, _⟩, rfl => rfl
theorem Scalar.val_eq_of_eq {ty} {i j : Scalar ty} (h : Eq i j) : Eq i.val j.val :=
h ▸ rfl
theorem Scalar.ne_of_val_ne {ty} {i j : Scalar ty} (h : Not (Eq i.val j.val)) : Not (Eq i j) :=
fun h' => absurd (val_eq_of_eq h') h
instance (ty : ScalarTy) : DecidableEq (Scalar ty) :=
fun i j =>
match decEq i.val j.val with
| isTrue h => isTrue (Scalar.eq_of_val_eq h)
| isFalse h => isFalse (Scalar.ne_of_val_ne h)
def Scalar.toInt {ty} (n : Scalar ty) : Int := n.val
-- -- We now define a type class that subsumes the various machine integer types, so
-- -- as to write a concise definition for scalar_cast, rather than exhaustively
-- -- enumerating all of the possible pairs. We remark that Rust has sane semantics
-- -- and fails if a cast operation would involve a truncation or modulo.
-- class MachineInteger (t: Type) where
-- size: Nat
-- val: t -> Fin size
-- ofNatCore: (n:Nat) -> LT.lt n size -> t
-- set_option hygiene false in
-- run_cmd
-- for typeName in [`UInt8, `UInt16, `UInt32, `UInt64, `USize].map Lean.mkIdent do
-- Lean.Elab.Command.elabCommand (← `(
-- namespace $typeName
-- instance: MachineInteger $typeName where
-- size := size
-- val := val
-- ofNatCore := ofNatCore
-- end $typeName
-- ))
-- -- Aeneas only instantiates the destination type (`src` is implicit). We rely on
-- -- Lean to infer `src`.
-- def scalar_cast { src: Type } (dst: Type) [ MachineInteger src ] [ MachineInteger dst ] (x: src): Result dst :=
-- if h: MachineInteger.val x < MachineInteger.size dst then
-- .ret (MachineInteger.ofNatCore (MachineInteger.val x).val h)
-- else
-- .fail integerOverflow
-------------
-- VECTORS --
-------------
def Vec (α : Type u) := { l : List α // List.length l ≤ Usize.max }
def Vec.new (α : Type u): Vec α := ⟨ [], by apply Scalar.cMax_suffices .Usize; simp ⟩
def Vec.len (α : Type u) (v : Vec α) : Usize :=
let ⟨ v, l ⟩ := v
Usize.ofIntCore (List.length v) (by simp [Scalar.min, Usize.min]) l
-- This shouldn't be used
def Vec.push_fwd (α : Type u) (_ : Vec α) (_ : α) : Unit := ()
-- This is actually the backward function
def Vec.push (α : Type u) (v : Vec α) (x : α) : Result (Vec α)
:=
let nlen := List.length v.val + 1
if h : nlen ≤ U32.max || nlen ≤ Usize.max then
have h : nlen ≤ Usize.max := by
simp [Usize.max] at *
have hm := Usize.refined_max.property
cases h <;> cases hm <;> simp [U32.max, U64.max] at * <;> try linarith
return ⟨ List.concat v.val x, by simp at *; assumption ⟩
else
fail maximumSizeExceeded
-- This shouldn't be used
def Vec.insert_fwd (α : Type u) (v: Vec α) (i: Usize) (_: α): Result Unit :=
if i.val < List.length v.val then
.ret ()
else
.fail arrayOutOfBounds
-- This is actually the backward function
def Vec.insert (α : Type u) (v: Vec α) (i: Usize) (x: α): Result (Vec α) :=
if i.val < List.length v.val then
-- TODO: maybe we should redefine a list library which uses integers
-- (instead of natural numbers)
let i := i.val.toNat
.ret ⟨ List.set v.val i x, by
have h: List.length v.val ≤ Usize.max := v.property
simp [*] at *
⟩
else
.fail arrayOutOfBounds
def Vec.index_to_fin {α : Type u} {v: Vec α} {i: Usize} (h : i.val < List.length v.val) :
Fin (List.length v.val) :=
let j := i.val.toNat
let h: j < List.length v.val := by
have heq := @Int.toNat_lt (List.length v.val) i.val i.hmin
apply heq.mpr
assumption
⟨j, h⟩
def Vec.index (α : Type u) (v: Vec α) (i: Usize): Result α :=
if h: i.val < List.length v.val then
let i := Vec.index_to_fin h
.ret (List.get v.val i)
else
.fail arrayOutOfBounds
-- This shouldn't be used
def Vec.index_back (α : Type u) (v: Vec α) (i: Usize) (_: α): Result Unit :=
if i.val < List.length v.val then
.ret ()
else
.fail arrayOutOfBounds
def Vec.index_mut (α : Type u) (v: Vec α) (i: Usize): Result α :=
if h: i.val < List.length v.val then
let i := Vec.index_to_fin h
.ret (List.get v.val i)
else
.fail arrayOutOfBounds
def Vec.index_mut_back (α : Type u) (v: Vec α) (i: Usize) (x: α): Result (Vec α) :=
if h: i.val < List.length v.val then
let i := Vec.index_to_fin h
.ret ⟨ List.set v.val i x, by
have h: List.length v.val ≤ Usize.max := v.property
simp [*] at *
⟩
else
.fail arrayOutOfBounds
----------
-- MISC --
----------
@[simp] def mem.replace (a : Type) (x : a) (_ : a) : a := x
@[simp] def mem.replace_back (a : Type) (_ : a) (y : a) : a := y
/-- Aeneas-translated function -- useful to reduce non-recursive definitions.
Use with `simp [ aeneas ]` -/
register_simp_attr aeneas
end Primitives
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