Documentation

Lean.Meta.Tactic.Grind.AC.Types

def Lean.Meta.Grind.AC.instHashableSeq_lean.hash :

Grind.AC.Seq → UInt64

Equations

Lean.Meta.Grind.AC.instHashableSeq_lean.hash (Lean.Grind.AC.Seq.var a) = mixHash 0 (hash a)
Lean.Meta.Grind.AC.instHashableSeq_lean.hash (Lean.Grind.AC.Seq.cons a a_1) = mixHash (mixHash 1 (hash a)) (Lean.Meta.Grind.AC.instHashableSeq_lean.hash a_1)

Instances For

instance Lean.Meta.Grind.AC.instHashableSeq_lean :

Hashable Grind.AC.Seq

Equations

Lean.Meta.Grind.AC.instHashableSeq_lean = { hash := Lean.Meta.Grind.AC.instHashableSeq_lean.hash }

instance Lean.Meta.Grind.AC.instHashableExpr_lean :

Hashable Grind.AC.Expr

Equations

Lean.Meta.Grind.AC.instHashableExpr_lean = { hash := Lean.Meta.Grind.AC.instHashableExpr_lean.hash }

def Lean.Meta.Grind.AC.instHashableExpr_lean.hash :

Grind.AC.Expr → UInt64

Equations

Lean.Meta.Grind.AC.instHashableExpr_lean.hash (Lean.Grind.AC.Expr.var a) = mixHash 0 (hash a)
Lean.Meta.Grind.AC.instHashableExpr_lean.hash (a.op a_1) = mixHash (mixHash 1 (Lean.Meta.Grind.AC.instHashableExpr_lean.hash a)) (Lean.Meta.Grind.AC.instHashableExpr_lean.hash a_1)

Instances For

structure Lean.Meta.Grind.AC.EqCnstr :

Instances For

inductive Lean.Meta.Grind.AC.EqCnstrProof :

core (a b : Expr) (ea eb : Grind.AC.Expr) : EqCnstrProof
erase_dup (c : EqCnstr) : EqCnstrProof
erase0 (c : EqCnstr) : EqCnstrProof
swap (c : EqCnstr) : EqCnstrProof
simp_exact (lhs : Bool) (c₁ c₂ : EqCnstr) : EqCnstrProof
simp_ac (lhs : Bool) (s : Grind.AC.Seq) (c₁ c₂ : EqCnstr) : EqCnstrProof
simp_suffix (lhs : Bool) (s : Grind.AC.Seq) (c₁ c₂ : EqCnstr) : EqCnstrProof
simp_prefix (lhs : Bool) (s : Grind.AC.Seq) (c₁ c₂ : EqCnstr) : EqCnstrProof
simp_middle (lhs : Bool) (s₁ s₂ : Grind.AC.Seq) (c₁ c₂ : EqCnstr) : EqCnstrProof
superpose_ac (r₁ c r₂ : Grind.AC.Seq) (c₁ c₂ : EqCnstr) : EqCnstrProof
superpose (p s c : Grind.AC.Seq) (c₁ c₂ : EqCnstr) : EqCnstrProof
superpose_ac_idempotent (x : Grind.AC.Var) (c₁ : EqCnstr) : EqCnstrProof
superpose_head_idempotent (x : Grind.AC.Var) (c₁ : EqCnstr) : EqCnstrProof
superpose_tail_idempotent (x : Grind.AC.Var) (c₁ : EqCnstr) : EqCnstrProof
refl (s : Grind.AC.Seq) : EqCnstrProof
erase_dup_rhs (c : EqCnstr) : EqCnstrProof
erase0_rhs (c : EqCnstr) : EqCnstrProof

Instances For

instance Lean.Meta.Grind.AC.instInhabitedEqCnstrProof :

Inhabited EqCnstrProof

Equations

Lean.Meta.Grind.AC.instInhabitedEqCnstrProof = { default := Lean.Meta.Grind.AC.EqCnstrProof.core default default default default }

instance Lean.Meta.Grind.AC.instInhabitedEqCnstr :

Inhabited EqCnstr

Equations

Lean.Meta.Grind.AC.instInhabitedEqCnstr = { default := { lhs := default, rhs := default, h := default, id := 0 } }

def Lean.Meta.Grind.AC.EqCnstr.compare (c₁ c₂ : EqCnstr) :

Equations

c₁.compare c₂ = (compare c₁.lhs.length c₂.lhs.length).then (compare c₁.id c₂.id)

Instances For

@[reducible, inline]

abbrev Lean.Meta.Grind.AC.Queue :

Equations

Lean.Meta.Grind.AC.Queue = Std.TreeSet Lean.Meta.Grind.AC.EqCnstr Lean.Meta.Grind.AC.EqCnstr.compare

Instances For

structure Lean.Meta.Grind.AC.DiseqCnstr :

Instances For

inductive Lean.Meta.Grind.AC.DiseqCnstrProof :

core (a b : Expr) (ea eb : Grind.AC.Expr) : DiseqCnstrProof
erase_dup (c : DiseqCnstr) : DiseqCnstrProof
erase0 (c : DiseqCnstr) : DiseqCnstrProof
simp_exact (lhs : Bool) (c₁ : EqCnstr) (c₂ : DiseqCnstr) : DiseqCnstrProof
simp_ac (lhs : Bool) (s : Grind.AC.Seq) (c₁ : EqCnstr) (c₂ : DiseqCnstr) : DiseqCnstrProof
simp_suffix (lhs : Bool) (s : Grind.AC.Seq) (c₁ : EqCnstr) (c₂ : DiseqCnstr) : DiseqCnstrProof
simp_prefix (lhs : Bool) (s : Grind.AC.Seq) (c₁ : EqCnstr) (c₂ : DiseqCnstr) : DiseqCnstrProof
simp_middle (lhs : Bool) (s₁ s₂ : Grind.AC.Seq) (c₁ : EqCnstr) (c₂ : DiseqCnstr) : DiseqCnstrProof

Instances For

structure Lean.Meta.Grind.AC.Struct :

id : Nat
type : Expr
u : Level
Cached getLevel type
op : Expr
neutral? : Option Expr
assocInst : Expr
idempotentInst? : Option Expr
commInst? : Option Expr
neutralInst? : Option Expr
nextId : Nat
Next unique id for EqCnstrs.
vars : PArray Expr
Mapping from variables to their denotations. Remark each variable can be in only one ring.
varMap : PHashMap ExprPtr Grind.AC.Var
Mapping from Expr to a variable representing it.
denote : PHashMap ExprPtr Grind.AC.Expr
Mapping from Lean expressions to their representations as AC.Expr
denoteEntries : PArray (Expr × Grind.AC.Expr)
denoteEntries is denote as a PArray for deterministic traversal.
queue : Queue
Equations to process.
basis : List EqCnstr
Processed equations.
diseqs : PArray DiseqCnstr
Disequalities.
recheck : Bool
If recheck is true, then new equalities have been added to the basis since we checked disequalities and implied equalities.

Instances For

def Lean.Meta.Grind.AC.instInhabitedStruct.default :

Equations

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

Instances For

instance Lean.Meta.Grind.AC.instInhabitedStruct :

Inhabited Struct

Equations

Lean.Meta.Grind.AC.instInhabitedStruct = { default := Lean.Meta.Grind.AC.instInhabitedStruct.default }

structure Lean.Meta.Grind.AC.State :

State for all associative operators detected by grind.

structs : Array Struct
Structures/operators detected. We expect to find a small number of associative operators in a given goal. Thus, using Array is fine here.
opIdOf : PHashMap ExprPtr (Option Nat)
Mapping from operators to its "operator id". We cache failures using none. opIdOf[op] is some id, then id < structs.size.
exprToOpIds : PHashMap ExprPtr (List Nat)
Mapping from expressions/terms to their structure ids. Recall that term may be the argument of different operators.
steps : Nat

Instances For

def Lean.Meta.Grind.AC.instInhabitedState.default :

Equations

Lean.Meta.Grind.AC.instInhabitedState.default = { structs := default, opIdOf := default, exprToOpIds := default, steps := default }

Instances For

instance Lean.Meta.Grind.AC.instInhabitedState :

Inhabited State

Equations

Lean.Meta.Grind.AC.instInhabitedState = { default := Lean.Meta.Grind.AC.instInhabitedState.default }

opaque Lean.Meta.Grind.AC.acExt :

SolverExtension State