From: Andrew Reynolds Date: Mon, 20 Sep 2021 18:02:59 +0000 (-0500) Subject: Add the LFSC proof post-processor (#7134) X-Git-Tag: cvc5-1.0.0~1193 X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=44832e870dcf44c4710411331f9ce21e7f0dc64f;p=cvc5.git Add the LFSC proof post-processor (#7134) Includes the necessary conversions to LFSC for the core rules of the internal calculus. --- diff --git a/src/CMakeLists.txt b/src/CMakeLists.txt index abc2d7219..d6fbfba37 100644 --- a/src/CMakeLists.txt +++ b/src/CMakeLists.txt @@ -182,6 +182,8 @@ libcvc5_add_sources( proof/lfsc/lfsc_list_sc_node_converter.h proof/lfsc/lfsc_node_converter.cpp proof/lfsc/lfsc_node_converter.h + proof/lfsc/lfsc_post_processor.cpp + proof/lfsc/lfsc_post_processor.h proof/lfsc/lfsc_print_channel.cpp proof/lfsc/lfsc_print_channel.h proof/lfsc/lfsc_util.cpp diff --git a/src/proof/lfsc/lfsc_post_processor.cpp b/src/proof/lfsc/lfsc_post_processor.cpp new file mode 100644 index 000000000..72db06060 --- /dev/null +++ b/src/proof/lfsc/lfsc_post_processor.cpp @@ -0,0 +1,406 @@ +/********************* */ +/*! \file lfsc_post_processor.cpp + ** \verbatim + ** Top contributors (to current version): + ** Andrew Reynolds + ** This file is part of the CVC4 project. + ** Copyright (c) 2009-2020 by the authors listed in the file AUTHORS + ** in the top-level source directory) and their institutional affiliations. + ** All rights reserved. See the file COPYING in the top-level source + ** directory for licensing information.\endverbatim + ** + ** \brief Implementation of the Lfsc post proccessor + **/ + +#include "proof/lfsc/lfsc_post_processor.h" + +#include "options/proof_options.h" +#include "proof/lazy_proof.h" +#include "proof/proof_checker.h" +#include "proof/proof_node_algorithm.h" +#include "proof/proof_node_manager.h" +#include "proof/proof_node_updater.h" + +using namespace cvc5::kind; + +namespace cvc5 { +namespace proof { + +LfscProofPostprocessCallback::LfscProofPostprocessCallback( + LfscNodeConverter& ltp, ProofNodeManager* pnm) + : d_pnm(pnm), d_pc(pnm->getChecker()), d_tproc(ltp), d_firstTime(false) +{ +} + +void LfscProofPostprocessCallback::initializeUpdate() { d_firstTime = true; } + +bool LfscProofPostprocessCallback::shouldUpdate(std::shared_ptr pn, + const std::vector& fa, + bool& continueUpdate) +{ + return pn->getRule() != PfRule::LFSC_RULE; +} + +bool LfscProofPostprocessCallback::update(Node res, + PfRule id, + const std::vector& children, + const std::vector& args, + CDProof* cdp, + bool& continueUpdate) +{ + Trace("lfsc-pp") << "LfscProofPostprocessCallback::update: " << id + << std::endl; + Trace("lfsc-pp-debug") << "...proves " << res << std::endl; + NodeManager* nm = NodeManager::currentNM(); + Assert(id != PfRule::LFSC_RULE); + bool isFirstTime = d_firstTime; + // On the first call to update, the proof node is the outermost scope of the + // proof. This scope should not be printed in the LFSC proof. Instead, the + // LFSC proof printer will print the proper scope around the proof, which + // e.g. involves an LFSC "check" command. + d_firstTime = false; + + switch (id) + { + case PfRule::SCOPE: + { + if (isFirstTime) + { + // Note that we do not want to modify the top-most SCOPE + return false; + } + Assert(children.size() == 1); + // (SCOPE P :args (F1 ... Fn)) + // becomes + // (scope _ _ (\ X1 ... (scope _ _ (\ Xn P)) ... )) + Node curr = children[0]; + for (size_t i = 0, nargs = args.size(); i < nargs; i++) + { + size_t ii = (nargs - 1) - i; + // Use a dummy conclusion for what LAMBDA proves, since there is no + // FOL representation for its type. + Node fconc = mkDummyPredicate(); + addLfscRule(cdp, fconc, {curr}, LfscRule::LAMBDA, {args[ii]}); + // we use a chained implication (=> F1 ... (=> Fn C)) which avoids + // aliasing. + Node next = nm->mkNode(OR, args[ii].notNode(), curr); + addLfscRule(cdp, next, {fconc}, LfscRule::SCOPE, {args[ii]}); + curr = next; + } + // In LFSC, we have now proved: + // (or (not F1) (or (not F2) ... (or (not Fn) C) ... )) + // We now must convert this to one of two cases + if (res.getKind() == NOT) + { + // we have C = false, + // convert to (not (and F1 (and F2 ... (and Fn true) ... ))) + // this also handles the case where the conclusion is simply F1, + // when n=1. + addLfscRule(cdp, res, {curr}, LfscRule::NOT_AND_REV, {}); + } + else + { + // we have that C != false + // convert to (=> (and F1 (and F2 ... (and Fn true) ... )) C) + addLfscRule(cdp, res, {curr}, LfscRule::PROCESS_SCOPE, {children[0]}); + } + } + break; + case PfRule::CHAIN_RESOLUTION: + { + // turn into binary resolution + Node cur = children[0]; + for (size_t i = 1, size = children.size(); i < size; i++) + { + std::vector newChildren{cur, children[i]}; + std::vector newArgs{args[(i - 1) * 2], args[(i - 1) * 2 + 1]}; + cur = d_pc->checkDebug(PfRule::RESOLUTION, newChildren, newArgs); + cdp->addStep(cur, PfRule::RESOLUTION, newChildren, newArgs); + } + } + break; + case PfRule::SYMM: + { + if (res.getKind() != NOT) + { + // no need to convert (positive) equality symmetry + return false; + } + // must use alternate SYMM rule for disequality + addLfscRule(cdp, res, {children[0]}, LfscRule::NEG_SYMM, {}); + } + break; + case PfRule::TRANS: + { + if (children.size() <= 2) + { + // no need to change + return false; + } + // turn into binary + Node cur = children[0]; + std::unordered_set processed; + processed.insert(children.begin(), children.end()); + for (size_t i = 1, size = children.size(); i < size; i++) + { + std::vector newChildren{cur, children[i]}; + cur = d_pc->checkDebug(PfRule::TRANS, newChildren, {}); + if (processed.find(cur) != processed.end()) + { + continue; + } + processed.insert(cur); + cdp->addStep(cur, PfRule::TRANS, newChildren, {}); + } + } + break; + case PfRule::CONG: + { + Assert(res.getKind() == EQUAL); + Assert(res[0].getOperator() == res[1].getOperator()); + // different for closures + if (res[0].isClosure()) + { + if (res[0][0] != res[1][0]) + { + // cannot convert congruence with different variables currently + return false; + } + Node cop = d_tproc.getOperatorOfClosure(res[0]); + Trace("lfsc-pp-qcong") << "Operator for closure " << cop << std::endl; + // start with base case body = body' + Node curL = children[1][0]; + Node curR = children[1][1]; + Node currEq = children[1]; + Trace("lfsc-pp-qcong") << "Base congruence " << currEq << std::endl; + for (size_t i = 0, nvars = res[0][0].getNumChildren(); i < nvars; i++) + { + Trace("lfsc-pp-qcong") << "Process child " << i << std::endl; + // CONG rules for each variable + Node v = res[0][0][nvars - 1 - i]; + Node vop = d_tproc.getOperatorOfBoundVar(cop, v); + Node vopEq = vop.eqNode(vop); + cdp->addStep(vopEq, PfRule::REFL, {}, {vop}); + Node nextEq; + if (i + 1 == nvars) + { + // if we are at the end, we prove the final equality + nextEq = res; + } + else + { + curL = nm->mkNode(HO_APPLY, vop, curL); + curR = nm->mkNode(HO_APPLY, vop, curR); + nextEq = curL.eqNode(curR); + } + addLfscRule(cdp, nextEq, {vopEq, currEq}, LfscRule::CONG, {}); + currEq = nextEq; + } + return true; + } + Kind k = res[0].getKind(); + if (k == HO_APPLY) + { + // HO_APPLY congruence is a single application of LFSC congruence + addLfscRule(cdp, res, children, LfscRule::CONG, {}); + return true; + } + // We are proving f(t1, ..., tn) = f(s1, ..., sn), nested. + // First, get the operator, which will be used for printing the base + // REFL step. Notice this may be for interpreted or uninterpreted + // function symbols. + Node op = d_tproc.getOperatorOfTerm(res[0]); + Assert(!op.isNull()); + // initial base step is REFL + Node opEq = op.eqNode(op); + cdp->addStep(opEq, PfRule::REFL, {}, {op}); + size_t nchildren = children.size(); + Node nullTerm = d_tproc.getNullTerminator(k, res[0].getType()); + // Are we doing congruence of an n-ary operator? If so, notice that op + // is a binary operator and we must apply congruence in a special way. + // Note we use the first block of code if we have more than 2 children, + // or if we have a null terminator. + // special case: constructors and apply uf are not treated as n-ary; these + // symbols have function types that expect n arguments. + bool isNary = NodeManager::isNAryKind(k) && k != kind::APPLY_CONSTRUCTOR + && k != kind::APPLY_UF; + if (isNary && (nchildren > 2 || !nullTerm.isNull())) + { + // get the null terminator for the kind, which may mean we are doing + // a special kind of congruence for n-ary kinds whose base is a REFL + // step for the null terminator. + Node currEq; + if (!nullTerm.isNull()) + { + currEq = nullTerm.eqNode(nullTerm); + // if we have a null terminator, we do a final REFL step to add + // the null terminator to both sides. + cdp->addStep(currEq, PfRule::REFL, {}, {nullTerm}); + } + else + { + // Otherwise, start with the last argument. + currEq = children[nchildren - 1]; + } + for (size_t i = 0; i < nchildren; i++) + { + size_t ii = (nchildren - 1) - i; + Node argAppEq = + nm->mkNode(HO_APPLY, op, children[ii][0]) + .eqNode(nm->mkNode(HO_APPLY, op, children[ii][1])); + addLfscRule(cdp, argAppEq, {opEq, children[ii]}, LfscRule::CONG, {}); + // now, congruence to the current equality + Node nextEq; + if (ii == 0) + { + // use final conclusion + nextEq = res; + } + else + { + // otherwise continue to apply + nextEq = nm->mkNode(HO_APPLY, argAppEq[0], currEq[0]) + .eqNode(nm->mkNode(HO_APPLY, argAppEq[1], currEq[1])); + } + addLfscRule(cdp, nextEq, {argAppEq, currEq}, LfscRule::CONG, {}); + currEq = nextEq; + } + } + else + { + // non n-ary kinds do not have null terminators + Assert(nullTerm.isNull()); + Node curL = op; + Node curR = op; + Node currEq = opEq; + for (size_t i = 0; i < nchildren; i++) + { + // CONG rules for each child + Node nextEq; + if (i + 1 == nchildren) + { + // if we are at the end, we prove the final equality + nextEq = res; + } + else + { + curL = nm->mkNode(HO_APPLY, curL, children[i][0]); + curR = nm->mkNode(HO_APPLY, curR, children[i][1]); + nextEq = curL.eqNode(curR); + } + addLfscRule(cdp, nextEq, {currEq, children[i]}, LfscRule::CONG, {}); + currEq = nextEq; + } + } + } + break; + case PfRule::AND_INTRO: + { + Node cur = d_tproc.getNullTerminator(AND); + size_t nchildren = children.size(); + for (size_t j = 0; j < nchildren; j++) + { + size_t jj = (nchildren - 1) - j; + // conclude the final conclusion if we are finished + Node next = jj == 0 ? res : nm->mkNode(AND, children[jj], cur); + if (j == 0) + { + addLfscRule(cdp, next, {children[jj]}, LfscRule::AND_INTRO1, {}); + } + else + { + addLfscRule(cdp, next, {children[jj], cur}, LfscRule::AND_INTRO2, {}); + } + cur = next; + } + } + break; + case PfRule::ARITH_SUM_UB: + { + // proof of null terminator base 0 = 0 + Node zero = d_tproc.getNullTerminator(PLUS); + Node cur = zero.eqNode(zero); + cdp->addStep(cur, PfRule::REFL, {}, {zero}); + for (size_t i = 0, size = children.size(); i < size; i++) + { + size_t ii = (children.size() - 1) - i; + std::vector newChildren{children[ii], cur}; + if (ii == 0) + { + // final rule must be the real conclusion + addLfscRule(cdp, res, newChildren, LfscRule::ARITH_SUM_UB, {}); + } + else + { + // rules build an n-ary chain of + on both sides + cur = d_pc->checkDebug(PfRule::ARITH_SUM_UB, newChildren, {}); + addLfscRule(cdp, cur, newChildren, LfscRule::ARITH_SUM_UB, {}); + } + } + } + break; + default: return false; break; + } + AlwaysAssert(cdp->getProofFor(res)->getRule() != PfRule::ASSUME); + return true; +} + +void LfscProofPostprocessCallback::addLfscRule( + CDProof* cdp, + Node conc, + const std::vector& children, + LfscRule lr, + const std::vector& args) +{ + std::vector largs; + largs.push_back(mkLfscRuleNode(lr)); + largs.push_back(conc); + largs.insert(largs.end(), args.begin(), args.end()); + cdp->addStep(conc, PfRule::LFSC_RULE, children, largs); +} + +Node LfscProofPostprocessCallback::mkChain(Kind k, + const std::vector& children) +{ + Assert(!children.empty()); + NodeManager* nm = NodeManager::currentNM(); + size_t nchildren = children.size(); + size_t i = 0; + // do we have a null terminator? If so, we start with it. + Node ret = d_tproc.getNullTerminator(k, children[0].getType()); + if (ret.isNull()) + { + ret = children[nchildren - 1]; + i = 1; + } + while (i < nchildren) + { + ret = nm->mkNode(k, children[(nchildren - 1) - i], ret); + i++; + } + return ret; +} + +Node LfscProofPostprocessCallback::mkDummyPredicate() +{ + NodeManager* nm = NodeManager::currentNM(); + return nm->mkBoundVar(nm->booleanType()); +} + +LfscProofPostprocess::LfscProofPostprocess(LfscNodeConverter& ltp, + ProofNodeManager* pnm) + : d_cb(new proof::LfscProofPostprocessCallback(ltp, pnm)), d_pnm(pnm) +{ +} + +void LfscProofPostprocess::process(std::shared_ptr pf) +{ + d_cb->initializeUpdate(); + // do not automatically add symmetry steps, since this leads to + // non-termination for example on policy_variable.smt2 + ProofNodeUpdater updater(d_pnm, *(d_cb.get()), false, false); + updater.process(pf); +} + +} // namespace proof +} // namespace cvc5 diff --git a/src/proof/lfsc/lfsc_post_processor.h b/src/proof/lfsc/lfsc_post_processor.h new file mode 100644 index 000000000..3776cf75b --- /dev/null +++ b/src/proof/lfsc/lfsc_post_processor.h @@ -0,0 +1,103 @@ +/********************* */ +/*! \file lfsc_post_processor.h + ** \verbatim + ** Top contributors (to current version): + ** Andrew Reynolds + ** This file is part of the CVC4 project. + ** Copyright (c) 2009-2020 by the authors listed in the file AUTHORS + ** in the top-level source directory) and their institutional affiliations. + ** All rights reserved. See the file COPYING in the top-level source + ** directory for licensing information.\endverbatim + ** + ** \brief The module for processing proof nodes into Lfsc proof nodes + **/ + +#include "cvc5_private.h" + +#ifndef CVC4__PROOF__LFSC__LFSC_POST_PROCESSOR_H +#define CVC4__PROOF__LFSC__LFSC_POST_PROCESSOR_H + +#include +#include + +#include "proof/lfsc/lfsc_node_converter.h" +#include "proof/lfsc/lfsc_util.h" +#include "proof/proof_node_updater.h" + +namespace cvc5 { + +class ProofChecker; + +namespace proof { + +/** + * A callback class used by the Lfsc convereter for post-processing proof nodes + * by replacing internal rules by the rules in the Lfsc calculus. + */ +class LfscProofPostprocessCallback : public ProofNodeUpdaterCallback +{ + public: + LfscProofPostprocessCallback(LfscNodeConverter& ltp, ProofNodeManager* pnm); + /** + * Initialize, called once for each new ProofNode to process. This initializes + * static information to be used by successive calls to update. + */ + void initializeUpdate(); + /** Should update */ + bool shouldUpdate(std::shared_ptr pn, + const std::vector& fa, + bool& continueUpdate) override; + /** Update the proof rule application. */ + bool update(Node res, + PfRule id, + const std::vector& children, + const std::vector& args, + CDProof* cdp, + bool& continueUpdate) override; + + private: + /** The proof node manager */ + ProofNodeManager* d_pnm; + /** The proof checker of d_pnm **/ + ProofChecker* d_pc; + /** The term processor */ + LfscNodeConverter& d_tproc; + /** + * Are we in the first call to update? This is to distinguish the top-most + * SCOPE. + */ + bool d_firstTime; + /** Add LFSC rule to cdp with children, args, conc */ + void addLfscRule(CDProof* cdp, + Node conc, + const std::vector& children, + LfscRule lr, + const std::vector& args); + /** Make chained form of a term */ + Node mkChain(Kind k, const std::vector& children); + /** Make fresh dummy predicate */ + static Node mkDummyPredicate(); +}; + +/** + * The proof postprocessor module. This postprocesses a proof node into one + * using the rules from the Lfsc calculus. + */ +class LfscProofPostprocess +{ + public: + LfscProofPostprocess(LfscNodeConverter& ltp, ProofNodeManager* pnm); + /** post-process */ + void process(std::shared_ptr pf); + + private: + /** The post process callback */ + std::unique_ptr d_cb; + /** The proof node manager */ + ProofNodeManager* d_pnm; +}; + +} // namespace proof +} // namespace cvc5 + +#endif