HepLean Documentation

Std.Sat.AIG.RelabelNat

This invariant ensures that we only insert an atom at most once and with a monotonically increasing index.

Instances For
    theorem Std.Sat.AIG.RelabelNat.State.Inv1.lt_of_get?_eq_some {α : Type} [DecidableEq α] [Hashable α] [EquivBEq α] {n : Nat} {m : Nat} (map : Std.HashMap α Nat) (x : α) (hinv : Std.Sat.AIG.RelabelNat.State.Inv1 n map) :
    map[x]? = some mm < n
    theorem Std.Sat.AIG.RelabelNat.State.Inv1.property {α : Type} [DecidableEq α] [Hashable α] [EquivBEq α] {n : Nat} {m : Nat} (x : α) (y : α) (map : Std.HashMap α Nat) (hinv : Std.Sat.AIG.RelabelNat.State.Inv1 n map) (hfound1 : map[x]? = some m) (hfound2 : map[y]? = some m) :
    x = y

    If a HashMap fulfills Inv1 it is in an injection.

    This invariant says that we have already visited and inserted all nodes up to a certain index.

    Instances For
      theorem Std.Sat.AIG.RelabelNat.State.Inv2.upper_lt_size {α : Type} [DecidableEq α] [Hashable α] {upper : Nat} {map : Std.HashMap α Nat} {decls : Array (Std.Sat.AIG.Decl α)} (hinv : Std.Sat.AIG.RelabelNat.State.Inv2 decls upper map) :
      upper decls.size
      theorem Std.Sat.AIG.RelabelNat.State.Inv2.property {α : Type} [DecidableEq α] [Hashable α] (decls : Array (Std.Sat.AIG.Decl α)) (idx : Nat) (upper : Nat) (map : Std.HashMap α Nat) (hidx : idx < upper) (a : α) (hinv : Std.Sat.AIG.RelabelNat.State.Inv2 decls upper map) (heq : decls[idx] = Std.Sat.AIG.Decl.atom a) :
      ∃ (n : Nat), map[a]? = some n

      The key property provided by Inv2, if we have Inv2 at a certain index, then all atoms below that index have been inserted into the HashMap.

      structure Std.Sat.AIG.RelabelNat.State (α : Type) [DecidableEq α] [Hashable α] (decls : Array (Std.Sat.AIG.Decl α)) (idx : Nat) :

      The invariant carrying state structure for building the HashMap that translates from arbitrary atom identifiers to Nat.

      Instances For
        theorem Std.Sat.AIG.RelabelNat.State.inv1 {α : Type} [DecidableEq α] [Hashable α] {decls : Array (Std.Sat.AIG.Decl α)} {idx : Nat} (self : Std.Sat.AIG.RelabelNat.State α decls idx) :

        Proof that we never reuse a number.

        theorem Std.Sat.AIG.RelabelNat.State.inv2 {α : Type} [DecidableEq α] [Hashable α] {decls : Array (Std.Sat.AIG.Decl α)} {idx : Nat} (self : Std.Sat.AIG.RelabelNat.State α decls idx) :

        Proof that we inserted all atoms until idx.

        The basic initial state.

        Equations
        • Std.Sat.AIG.RelabelNat.State.empty = { max := 0, map := , inv1 := , inv2 := }
        Instances For
          def Std.Sat.AIG.RelabelNat.State.addAtom {α : Type} [DecidableEq α] [Hashable α] {idx : Nat} {decls : Array (Std.Sat.AIG.Decl α)} {hidx : idx < decls.size} (state : Std.Sat.AIG.RelabelNat.State α decls idx) (a : α) (h : decls[idx] = Std.Sat.AIG.Decl.atom a) :

          Insert a Decl.atom into the State structure.

          Equations
          • One or more equations did not get rendered due to their size.
          Instances For
            def Std.Sat.AIG.RelabelNat.State.addConst {α : Type} [DecidableEq α] [Hashable α] {idx : Nat} {decls : Array (Std.Sat.AIG.Decl α)} {hidx : idx < decls.size} (state : Std.Sat.AIG.RelabelNat.State α decls idx) (b : Bool) (h : decls[idx] = Std.Sat.AIG.Decl.const b) :

            Insert a Decl.const into the State structure.

            Equations
            • state.addConst b h = { max := state.max, map := state.map, inv1 := , inv2 := }
            Instances For
              def Std.Sat.AIG.RelabelNat.State.addGate {α : Type} [DecidableEq α] [Hashable α] {idx : Nat} {decls : Array (Std.Sat.AIG.Decl α)} {hidx : idx < decls.size} (state : Std.Sat.AIG.RelabelNat.State α decls idx) (lhs : Nat) (rhs : Nat) (linv : Bool) (rinv : Bool) (h : decls[idx] = Std.Sat.AIG.Decl.gate lhs rhs linv rinv) :

              Insert a Decl.gate into the State structure.

              Equations
              • state.addGate lhs rhs linv rinv h = { max := state.max, map := state.map, inv1 := , inv2 := }
              Instances For
                def Std.Sat.AIG.RelabelNat.State.ofAIGAux {α : Type} [DecidableEq α] [Hashable α] (aig : Std.Sat.AIG α) :
                Std.Sat.AIG.RelabelNat.State α aig.decls aig.decls.size

                Build up a State that has all atoms of an AIG inserted.

                Equations
                Instances For
                  @[irreducible]
                  def Std.Sat.AIG.RelabelNat.State.ofAIGAux.go {α : Type} [DecidableEq α] [Hashable α] (decls : Array (Std.Sat.AIG.Decl α)) (idx : Nat) (state : Std.Sat.AIG.RelabelNat.State α decls idx) :
                  Std.Sat.AIG.RelabelNat.State α decls decls.size
                  Equations
                  • One or more equations did not get rendered due to their size.
                  Instances For

                    Obtain the atom mapping from α to Nat for a given AIG.

                    Equations
                    Instances For

                      The map returned by ofAIG fulfills the Inv1 property.

                      The map returned by ofAIG fulfills the Inv2 property.

                      theorem Std.Sat.AIG.RelabelNat.State.ofAIG_find_unique {α : Type} [DecidableEq α] [Hashable α] {n : Nat} {aig : Std.Sat.AIG α} (a : α) (ha : (Std.Sat.AIG.RelabelNat.State.ofAIG aig)[a]? = some n) (a' : α) :

                      Assuming that we find a Nat for an atom in the ofAIG map, that Nat is unique in the map.

                      theorem Std.Sat.AIG.RelabelNat.State.ofAIG_find_some {α : Type} [DecidableEq α] [Hashable α] {aig : Std.Sat.AIG α} (a : α) :
                      a aig∃ (n : Nat), (Std.Sat.AIG.RelabelNat.State.ofAIG aig)[a]? = some n

                      We will find a Nat for every atom in the AIG that the ofAIG map was built from.

                      Equations
                      • One or more equations did not get rendered due to their size.
                      Instances For

                        Map an AIG with arbitrary atom identifiers to one that uses Nat as atom identifiers. This is useful for preparing an AIG for CNF translation if it doesn't already use Nat identifiers.

                        Equations
                        • aig.relabelNat = aig.relabelNat'.fst
                        Instances For
                          @[simp]
                          theorem Std.Sat.AIG.relabelNat'_fst_eq_relabelNat {α : Type} [DecidableEq α] [Hashable α] {aig : Std.Sat.AIG α} :
                          aig.relabelNat'.fst = aig.relabelNat
                          @[simp]
                          theorem Std.Sat.AIG.relabelNat_size_eq_size {α : Type} [DecidableEq α] [Hashable α] {aig : Std.Sat.AIG α} :
                          aig.relabelNat.decls.size = aig.decls.size
                          theorem Std.Sat.AIG.relabelNat_unsat_iff {α : Type} [DecidableEq α] [Hashable α] {idx : Nat} [Nonempty α] {aig : Std.Sat.AIG α} {hidx1 : idx < aig.relabelNat.decls.size} {hidx2 : idx < aig.decls.size} :
                          aig.relabelNat.UnsatAt idx hidx1 aig.UnsatAt idx hidx2

                          relabelNat preserves unsatisfiablility.

                          Equations
                          • entry.relabelNat' = ({ aig := entry.aig.relabelNat'.fst, ref := let __src := entry.ref; { gate := __src.gate, hgate := } }, entry.aig.relabelNat'.snd)
                          Instances For

                            Map an Entrypoint with arbitrary atom identifiers to one that uses Nat as atom identifiers. This is useful for preparing an AIG for CNF translation if it doesn't already use Nat identifiers.

                            Equations
                            • entry.relabelNat = { aig := entry.aig.relabelNat, ref := let __src := entry.ref; { gate := __src.gate, hgate := } }
                            Instances For
                              theorem Std.Sat.AIG.Entrypoint.relabelNat_unsat_iff {α : Type} [DecidableEq α] [Hashable α] {entry : Std.Sat.AIG.Entrypoint α} [Nonempty α] :
                              entry.relabelNat.Unsat entry.Unsat

                              relabelNat preserves unsatisfiablility.