This directory offers three different SAT tactics for proving goals involving BitVec
and Bool
:
bv_decide
takes the goal, hands it over to a SAT solver and verifies the generated LRAT UNSAT proof to prove the goal.bv_check file.lrat
can prove the same things asbv_decide
. However instead of dynamically handing the goal to a SAT solver to obtain an LRAT proof, the LRAT proof is read fromfile.lrat
. This allows users that do not have a SAT solver installed to verify proofs.bv_decide?
offers a code action to turn abv_decide
invocation automatically into abv_check
one.
There are also some options to influence the behavior of bv_decide
and friends:
sat.solver
: the name of the SAT solver used bybv_decide
. It goes through 3 steps to determine which solver to use:- If sat.solver is set to something != "" it will use that.
- If sat.solver is set to "" it will check if there is a cadical binary next to the executing
program. Usually that program is going to be
lean
itself and we do ship acadical
next to it. - If that does not succeed try to call
cadical
from PATH.
sat.timeout
: The timeout for waiting for the SAT solver in seconds, default 10.sat.trimProofs
: Whether to run the trimming algorithm on LRAT proofs, default true.sat.binaryProofs
: Whether to use the binary LRAT proof format, default true.trace.Meta.Tactic.bv
andtrace.Meta.Tactic.sat
for inspecting the inner workings ofbv_decide
.debug.skipKernelTC
: may be set to true to disable actually checking the LRAT proof.bv_decide
will still run bitblasting + SAT solving so this option essentially trusts the SAT solver.
Architecture #
bv_decide
roughly runs through the following steps:
- Apply
false_or_by_contra
to start a proof by contradiction. - Apply the
bv_normalize
andseval
simp set to all hypotheses. This has two effects: - Use proof by reflection to reduce the proof to showing that an SMTLIB-syntax-like value that represents the conjunction of all relevant assumptions is UNSAT.
- Use a verified bitblasting algorithm to turn that expression into an AIG.
The bitblasting algorithms are collected from various other bitblasters, including Bitwuzla and
Z3 and verified using Lean's
BitVec
theory. - Turn the AIG into a CNF.
- Run CaDiCal on the CNF to obtain an LRAT proof that the CNF is UNSAT. If CaDiCal returns SAT instead the tactic aborts here and presents a counterexample.
- Use an LRAT checker with a soundness proof in Lean to show that the LRAT proof is correct.
- Chain all the proofs so far to demonstrate that the original goal holds.
Axioms #
bv_decide
makes use of proof by reflection and ofReduceBool
, thus adding the Lean compiler to
the trusted code base.
Adding a new primitive #
bv_decide
knows two kinds of primitives:
- The ones that can be reduced to already existing ones.
- The ones that cannot.
For the first kind the steps to adding them are very simple, go to Std.Tactic.BVDecide.Normalize
and add the reduction lemma into the bv_normalize
simp set. Don't forget to add a test!
For the second kind more steps are involved:
- Add a new constructor to
BVExpr
/BVPred
- Add a bitblasting algorithm for the new constructor to
Std.Tactic.BVDecide.Bitblast.BVExpr.Circuit.Impl
. - Verify that algorithm in
Std.Tactic.BVDecide.Bitblast.BVExpr.Circuit.Lemmas
. - Integrate it with either the expression or predicate bitblaster and use the proof above to verify it.
- Add simplification lemmas for the primitive to
bv_normalize
inStd.Tactic.BVDecide.Normalize
. If there are mutliple ways to write the primitive (e.g. with TC based notation and without) you should normalize for one notation here. - Add the reflection code to
Lean.Elab.Tactic.BVDecide.Frontend.BVDecide
- Add a test!