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authoryoni206 <yoni206@users.noreply.github.com>2020-02-24 19:58:01 -0800
committerGitHub <noreply@github.com>2020-02-24 19:58:01 -0800
commit6e17dd6d5e3ec043e5edd097ac6a736f6a41c753 (patch)
tree5faac828524e121bcba8cd2d4f1c09bb46cadcfe /src/preprocessing/passes/bv_to_int.cpp
parenta3b9a99404ee00bde5db42aab63ab08df3712ba3 (diff)
bv_to_int preprocessing pass
Introduces a preprocessing pass that translates bv problems to integer problems.
Diffstat (limited to 'src/preprocessing/passes/bv_to_int.cpp')
-rw-r--r--src/preprocessing/passes/bv_to_int.cpp977
1 files changed, 977 insertions, 0 deletions
diff --git a/src/preprocessing/passes/bv_to_int.cpp b/src/preprocessing/passes/bv_to_int.cpp
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+++ b/src/preprocessing/passes/bv_to_int.cpp
@@ -0,0 +1,977 @@
+/********************* */
+/*! \file bv_to_int.cpp
+ ** \verbatim
+ ** Top contributors (to current version):
+ ** Yoni Zohar and Ahmed Irfan
+ ** This file is part of the CVC4 project.
+ ** Copyright (c) 2009-2019 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 BVToInt preprocessing pass
+ **
+ ** Converts bit-vector operations into integer operations.
+ **
+ **/
+
+#include "preprocessing/passes/bv_to_int.h"
+
+#include <cmath>
+#include <string>
+#include <unordered_map>
+#include <vector>
+
+#include "expr/node.h"
+#include "theory/bv/theory_bv_rewrite_rules_operator_elimination.h"
+#include "theory/bv/theory_bv_rewrite_rules_simplification.h"
+#include "theory/rewriter.h"
+
+namespace CVC4 {
+namespace preprocessing {
+namespace passes {
+
+using namespace CVC4::theory;
+using namespace CVC4::theory::bv;
+
+namespace {
+
+Rational intpow2(uint64_t b)
+{
+ return Rational(Integer(2).pow(b), Integer(1));
+}
+
+/**
+ * Helper functions for createBitwiseNode
+ */
+bool oneBitAnd(bool a, bool b) { return (a && b); }
+
+bool oneBitOr(bool a, bool b) { return (a || b); }
+
+bool oneBitXor(bool a, bool b) { return a != b; }
+
+bool oneBitXnor(bool a, bool b) { return a == b; }
+
+bool oneBitNand(bool a, bool b) { return !(a && b); }
+
+bool oneBitNor(bool a, bool b) { return !(a || b); }
+
+} //end empty namespace
+
+Node BVToInt::mkRangeConstraint(Node newVar, uint64_t k)
+{
+ Node lower = d_nm->mkNode(kind::LEQ, d_zero, newVar);
+ Node upper = d_nm->mkNode(kind::LT, newVar, pow2(k));
+ Node result = d_nm->mkNode(kind::AND, lower, upper);
+ return Rewriter::rewrite(result);
+}
+
+Node BVToInt::maxInt(uint64_t k)
+{
+ Assert(k > 0);
+ Rational max_value = intpow2(k) - 1;
+ return d_nm->mkConst<Rational>(max_value);
+}
+
+Node BVToInt::pow2(uint64_t k)
+{
+ Assert(k >= 0);
+ return d_nm->mkConst<Rational>(intpow2(k));
+}
+
+Node BVToInt::modpow2(Node n, uint64_t exponent)
+{
+ Node p2 = d_nm->mkConst<Rational>(intpow2(exponent));
+ return d_nm->mkNode(kind::INTS_MODULUS_TOTAL, n, p2);
+}
+
+/**
+ * Binarizing n via post-order traversal.
+ */
+Node BVToInt::makeBinary(Node n)
+{
+ vector<Node> toVisit;
+ toVisit.push_back(n);
+ while (!toVisit.empty())
+ {
+ Node current = toVisit.back();
+ uint64_t numChildren = current.getNumChildren();
+ if (d_binarizeCache.find(current) == d_binarizeCache.end())
+ {
+ /**
+ * We still haven't visited the sub-dag rooted at the current node.
+ * In this case, we:
+ * mark that we have visited this node by assigning a null node to it in
+ * the cache, and add its children to toVisit.
+ */
+ d_binarizeCache[current] = Node();
+ toVisit.insert(toVisit.end(), current.begin(), current.end());
+ }
+ else if (d_binarizeCache[current].isNull())
+ {
+ /*
+ * We already visited the sub-dag rooted at the current node,
+ * and binarized all its children.
+ * Now we binarize the current node itself.
+ */
+ toVisit.pop_back();
+ kind::Kind_t k = current.getKind();
+ if ((numChildren > 2)
+ && (k == kind::BITVECTOR_PLUS || k == kind::BITVECTOR_MULT
+ || k == kind::BITVECTOR_AND || k == kind::BITVECTOR_OR
+ || k == kind::BITVECTOR_XOR || k == kind::BITVECTOR_CONCAT))
+ {
+ // We only binarize bvadd, bvmul, bvand, bvor, bvxor, bvconcat
+ Assert(d_binarizeCache.find(current[0]) != d_binarizeCache.end());
+ Node result = d_binarizeCache[current[0]];
+ for (uint64_t i = 1; i < numChildren; i++)
+ {
+ Assert(d_binarizeCache.find(current[i]) != d_binarizeCache.end());
+ Node child = d_binarizeCache[current[i]];
+ result = d_nm->mkNode(current.getKind(), result, child);
+ }
+ d_binarizeCache[current] = result;
+ }
+ else if (numChildren > 0)
+ {
+ // current has children, but we do not binarize it
+ NodeBuilder<> builder(k);
+ if (current.getKind() == kind::BITVECTOR_EXTRACT
+ || current.getKind() == kind::APPLY_UF)
+ {
+ builder << current.getOperator();
+ }
+ for (Node child : current)
+ {
+ builder << d_binarizeCache[child];
+ }
+ d_binarizeCache[current] = builder.constructNode();
+ }
+ else
+ {
+ // current has no children
+ d_binarizeCache[current] = current;
+ }
+ }
+ else
+ {
+ // We already binarized current and it is in the cache.
+ toVisit.pop_back();
+ }
+ }
+ return d_binarizeCache[n];
+}
+
+/**
+ * We traverse n and perform rewrites both on the way down and on the way up.
+ * On the way down we rewrite the node but not it's children.
+ * On the way up, we update the node's children to the rewritten ones.
+ * For each sub-node, we perform rewrites to eliminate operators.
+ * Then, the original children are added to toVisit stack so that we rewrite
+ * them as well.
+ */
+Node BVToInt::eliminationPass(Node n)
+{
+ std::vector<Node> toVisit;
+ toVisit.push_back(n);
+ Node current;
+ while (!toVisit.empty())
+ {
+ current = toVisit.back();
+ toVisit.pop_back();
+ bool inEliminationCache =
+ (d_eliminationCache.find(current) != d_eliminationCache.end());
+ bool inRebuildCache =
+ (d_rebuildCache.find(current) != d_rebuildCache.end());
+ if (!inRebuildCache)
+ {
+ // current is not the elimination of any previously-visited node
+ if (!inEliminationCache)
+ {
+ // current hasn't been eliminated yet.
+ // eliminate operators from it
+ Node currentEliminated =
+ FixpointRewriteStrategy<RewriteRule<UdivZero>,
+ RewriteRule<SdivEliminate>,
+ RewriteRule<SremEliminate>,
+ RewriteRule<SmodEliminate>,
+ RewriteRule<RepeatEliminate>,
+ RewriteRule<ZeroExtendEliminate>,
+ RewriteRule<SignExtendEliminate>,
+ RewriteRule<RotateRightEliminate>,
+ RewriteRule<RotateLeftEliminate>,
+ RewriteRule<CompEliminate>,
+ RewriteRule<SleEliminate>,
+ RewriteRule<SltEliminate>,
+ RewriteRule<SgtEliminate>,
+ RewriteRule<SgeEliminate>,
+ RewriteRule<ShlByConst>,
+ RewriteRule<LshrByConst> >::apply(current);
+ // save in the cache
+ d_eliminationCache[current] = currentEliminated;
+ // put the eliminated node in the rebuild cache, but mark that it hasn't
+ // yet been rebuilt by assigning null.
+ d_rebuildCache[currentEliminated] = Node();
+ // Push the eliminated node to the stack
+ toVisit.push_back(currentEliminated);
+ // Add the children to the stack for future processing.
+ toVisit.insert(
+ toVisit.end(), currentEliminated.begin(), currentEliminated.end());
+ }
+ }
+ else
+ {
+ // current was already added to the rebuild cache.
+ if (d_rebuildCache[current].isNull())
+ {
+ // current wasn't rebuilt yet.
+ uint64_t numChildren = current.getNumChildren();
+ if (numChildren == 0)
+ {
+ // We only eliminate operators that are not nullary.
+ d_rebuildCache[current] = current;
+ }
+ else
+ {
+ // The main operator is replaced, and the children
+ // are replaced with their eliminated counterparts.
+ NodeBuilder<> builder(current.getKind());
+ if (current.getKind() == kind::BITVECTOR_EXTRACT
+ || current.getKind() == kind::APPLY_UF)
+ {
+ builder << current.getOperator();
+ }
+ for (Node child : current)
+ {
+ Assert(d_eliminationCache.find(child) != d_eliminationCache.end());
+ Node eliminatedChild = d_eliminationCache[child];
+ Assert(d_rebuildCache.find(eliminatedChild) != d_eliminationCache.end());
+ Assert(!d_rebuildCache[eliminatedChild].isNull());
+ builder << d_rebuildCache[eliminatedChild];
+ }
+ d_rebuildCache[current] = builder.constructNode();
+ }
+ }
+ }
+ }
+ Assert(d_eliminationCache.find(n) != d_eliminationCache.end());
+ Node eliminated = d_eliminationCache[n];
+ Assert(d_rebuildCache.find(eliminated) != d_rebuildCache.end());
+ Assert(!d_rebuildCache[eliminated].isNull());
+ return d_rebuildCache[eliminated];
+}
+
+/**
+ * Translate n to Integers via post-order traversal.
+ */
+Node BVToInt::bvToInt(Node n)
+{
+ n = eliminationPass(n);
+ n = makeBinary(n);
+ vector<Node> toVisit;
+ toVisit.push_back(n);
+ uint64_t granularity = options::solveBVAsInt();
+
+ while (!toVisit.empty())
+ {
+ Node current = toVisit.back();
+ uint64_t currentNumChildren = current.getNumChildren();
+ if (d_bvToIntCache.find(current) == d_bvToIntCache.end())
+ {
+ // This is the first time we visit this node and it is not in the cache.
+ d_bvToIntCache[current] = Node();
+ toVisit.insert(toVisit.end(), current.begin(), current.end());
+ }
+ else
+ {
+ // We already visited this node
+ if (!d_bvToIntCache[current].isNull())
+ {
+ // We are done computing the translation for current
+ toVisit.pop_back();
+ }
+ else
+ {
+ // We are now visiting current on the way back up.
+ // This is when we do the actual translation.
+ if (currentNumChildren == 0)
+ {
+ Assert(current.isVar() || current.isConst());
+ if (current.isVar())
+ {
+ if (current.getType().isBitVector())
+ {
+ // For bit-vector variables, we create integer variables and add a
+ // range constraint.
+ Node newVar = d_nm->mkSkolem("__bvToInt_var",
+ d_nm->integerType(),
+ "Variable introduced in bvToInt "
+ "pass instead of original variable "
+ + current.toString());
+
+ d_bvToIntCache[current] = newVar;
+ d_rangeAssertions.insert(mkRangeConstraint(
+ newVar, current.getType().getBitVectorSize()));
+ }
+ else
+ {
+ // Boolean variables are left unchanged.
+ AlwaysAssert(current.getType() == d_nm->booleanType()
+ || current.getType().isSort());
+ d_bvToIntCache[current] = current;
+ }
+ }
+ else
+ {
+ // current is a const
+ if (current.getKind() == kind::CONST_BITVECTOR)
+ {
+ // Bit-vector constants are transformed into their integer value.
+ BitVector constant(current.getConst<BitVector>());
+ Integer c = constant.toInteger();
+ d_bvToIntCache[current] = d_nm->mkConst<Rational>(c);
+ }
+ else
+ {
+ // Other constants stay the same.
+ d_bvToIntCache[current] = current;
+ }
+ }
+ }
+ else
+ {
+ /**
+ * The current node has children.
+ * Since we are on the way back up,
+ * these children were already translated.
+ * We save their translation for future use.
+ */
+ vector<Node> translated_children;
+ for (uint64_t i = 0; i < currentNumChildren; i++)
+ {
+ translated_children.push_back(d_bvToIntCache[current[i]]);
+ }
+ // The translation of the current node is determined by the kind of
+ // the node.
+ kind::Kind_t oldKind = current.getKind();
+ //ultbv and sltbv were supposed to be eliminated before this point.
+ Assert(oldKind != kind::BITVECTOR_ULTBV);
+ Assert(oldKind != kind::BITVECTOR_SLTBV);
+ switch (oldKind)
+ {
+ case kind::BITVECTOR_PLUS:
+ {
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ /**
+ * we avoid modular arithmetics by the addition of an
+ * indicator variable sigma.
+ * Tr(a+b) is Tr(a)+Tr(b)-(sigma*2^k),
+ * with k being the bit width,
+ * and sigma being either 0 or 1.
+ */
+ Node sigma = d_nm->mkSkolem(
+ "__bvToInt_sigma_var",
+ d_nm->integerType(),
+ "Variable introduced in bvToInt pass to avoid integer mod");
+ Node plus = d_nm->mkNode(kind::PLUS, translated_children);
+ Node multSig = d_nm->mkNode(kind::MULT, sigma, pow2(bvsize));
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::MINUS, plus, multSig);
+ d_rangeAssertions.insert(d_nm->mkNode(kind::LEQ, d_zero, sigma));
+ d_rangeAssertions.insert(d_nm->mkNode(kind::LEQ, sigma, d_one));
+ d_rangeAssertions.insert(
+ mkRangeConstraint(d_bvToIntCache[current], bvsize));
+ break;
+ }
+ case kind::BITVECTOR_MULT:
+ {
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ /**
+ * we use a similar trick to the one used for addition.
+ * Tr(a*b) is Tr(a)*Tr(b)-(sigma*2^k),
+ * with k being the bit width,
+ * and sigma is between [0, 2^k - 1).
+ */
+ Node sigma = d_nm->mkSkolem(
+ "__bvToInt_sigma_var",
+ d_nm->integerType(),
+ "Variable introduced in bvToInt pass to avoid integer mod");
+ Node mult = d_nm->mkNode(kind::MULT, translated_children);
+ Node multSig = d_nm->mkNode(kind::MULT, sigma, pow2(bvsize));
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::MINUS, mult, multSig);
+ d_rangeAssertions.insert(
+ mkRangeConstraint(d_bvToIntCache[current], bvsize));
+ d_rangeAssertions.insert(mkRangeConstraint(sigma, bvsize));
+ break;
+ }
+ case kind::BITVECTOR_UDIV_TOTAL:
+ {
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ // we use an ITE for the case where the second operand is 0.
+ Node pow2BvSize = pow2(bvsize);
+ Node divNode =
+ d_nm->mkNode(kind::INTS_DIVISION_TOTAL, translated_children);
+ Node ite = d_nm->mkNode(
+ kind::ITE,
+ d_nm->mkNode(kind::EQUAL, translated_children[1], d_zero),
+ d_nm->mkNode(kind::MINUS, pow2BvSize, d_one),
+ divNode);
+ d_bvToIntCache[current] = ite;
+ break;
+ }
+ case kind::BITVECTOR_UREM_TOTAL:
+ {
+ // we use an ITE for the case where the second operand is 0.
+ Node modNode =
+ d_nm->mkNode(kind::INTS_MODULUS_TOTAL, translated_children);
+ Node ite = d_nm->mkNode(
+ kind::ITE,
+ d_nm->mkNode(kind::EQUAL, translated_children[1], d_zero),
+ translated_children[0],
+ modNode);
+ d_bvToIntCache[current] = ite;
+ break;
+ }
+ case kind::BITVECTOR_NEG:
+ {
+ // (bvneg x) is 2^k-x, unless x is 0,
+ // in which case the result should be 0.
+ // This can be expressed by (2^k-x) mod 2^k
+ // However, since mod is an expensive arithmetic operation,
+ // we represent `bvneg` using an ITE.
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ Node pow2BvSize = pow2(bvsize);
+ Node neg =
+ d_nm->mkNode(kind::MINUS, pow2BvSize, translated_children[0]);
+ Node isZero =
+ d_nm->mkNode(kind::EQUAL, translated_children[0], d_zero);
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::ITE, isZero, d_zero, neg);
+ break;
+ }
+ case kind::BITVECTOR_NOT:
+ {
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ // we use a specified function to generate the node.
+ d_bvToIntCache[current] =
+ createBVNotNode(translated_children[0], bvsize);
+ break;
+ }
+ case kind::BITVECTOR_TO_NAT:
+ {
+ // In this case, we already translated the child to integer.
+ // So the result is the translated child.
+ d_bvToIntCache[current] = translated_children[0];
+ break;
+ }
+ case kind::BITVECTOR_AND:
+ {
+ // Construct an ite, based on granularity.
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ Assert(translated_children.size() == 2);
+ Node newNode = createBitwiseNode(translated_children[0],
+ translated_children[1],
+ bvsize,
+ granularity,
+ &oneBitAnd);
+ d_bvToIntCache[current] = newNode;
+ break;
+ }
+ case kind::BITVECTOR_OR:
+ {
+ // Construct an ite, based on granularity.
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ Node newNode = createBitwiseNode(translated_children[0],
+ translated_children[1],
+ bvsize,
+ granularity,
+ &oneBitOr);
+ d_bvToIntCache[current] = newNode;
+ break;
+ }
+ case kind::BITVECTOR_XOR:
+ {
+ // Construct an ite, based on granularity.
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ Node newNode = createBitwiseNode(translated_children[0],
+ translated_children[1],
+ bvsize,
+ granularity,
+ &oneBitXor);
+ d_bvToIntCache[current] = newNode;
+ break;
+ }
+ case kind::BITVECTOR_XNOR:
+ {
+ // Construct an ite, based on granularity.
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ Node newNode = createBitwiseNode(translated_children[0],
+ translated_children[1],
+ bvsize,
+ granularity,
+ &oneBitXnor);
+ d_bvToIntCache[current] = newNode;
+ break;
+ }
+ case kind::BITVECTOR_NAND:
+ {
+ // Construct an ite, based on granularity.
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ Node newNode = createBitwiseNode(translated_children[0],
+ translated_children[1],
+ bvsize,
+ granularity,
+ &oneBitNand);
+ d_bvToIntCache[current] = newNode;
+ break;
+ }
+ case kind::BITVECTOR_NOR:
+ {
+ // Construct an ite, based on granularity.
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ Node newNode = createBitwiseNode(translated_children[0],
+ translated_children[1],
+ bvsize,
+ granularity,
+ &oneBitNor);
+ d_bvToIntCache[current] = newNode;
+ break;
+ }
+ case kind::BITVECTOR_SHL:
+ {
+ /**
+ * a << b is a*2^b.
+ * The exponentiation is simulated by an ite.
+ * Only cases where b <= bit width are considered.
+ * Otherwise, the result is 0.
+ */
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ Node newNode = createShiftNode(translated_children, bvsize, true);
+ d_bvToIntCache[current] = newNode;
+ break;
+ }
+ case kind::BITVECTOR_LSHR:
+ {
+ /**
+ * a >> b is a div 2^b.
+ * The exponentiation is simulated by an ite.
+ * Only cases where b <= bit width are considered.
+ * Otherwise, the result is 0.
+ */
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ Node newNode = createShiftNode(translated_children, bvsize, false);
+ d_bvToIntCache[current] = newNode;
+ break;
+ }
+ case kind::BITVECTOR_ASHR:
+ {
+ /* From SMT-LIB2:
+ * (bvashr s t) abbreviates
+ * (ite (= ((_ extract |m-1| |m-1|) s) #b0)
+ * (bvlshr s t)
+ * (bvnot (bvlshr (bvnot s) t)))
+ *
+ * Equivalently:
+ * (bvashr s t) abbreviates
+ * (ite (bvult s 100000...)
+ * (bvlshr s t)
+ * (bvnot (bvlshr (bvnot s) t)))
+ *
+ */
+ uint64_t bvsize = current[0].getType().getBitVectorSize();
+ // signed_min is 100000...
+ Node signed_min = pow2(bvsize - 1);
+ Node condition =
+ d_nm->mkNode(kind::LT, translated_children[0], signed_min);
+ Node thenNode = createShiftNode(translated_children, bvsize, false);
+ vector<Node> children = {
+ createBVNotNode(translated_children[0], bvsize),
+ translated_children[1]};
+ Node elseNode = createBVNotNode(
+ createShiftNode(children, bvsize, false), bvsize);
+ Node ite = d_nm->mkNode(kind::ITE, condition, thenNode, elseNode);
+ d_bvToIntCache[current] = ite;
+ break;
+ }
+ case kind::BITVECTOR_ITE:
+ {
+ // Lifted to a boolean ite.
+ Node cond = d_nm->mkNode(kind::EQUAL, translated_children[0], d_one);
+ Node ite = d_nm->mkNode(
+ kind::ITE, cond, translated_children[1], translated_children[2]);
+ d_bvToIntCache[current] = ite;
+ break;
+ }
+ case kind::BITVECTOR_CONCAT:
+ {
+ // (concat a b) translates to a*2^k+b, k being the bitwidth of b.
+ uint64_t bvsizeRight = current[1].getType().getBitVectorSize();
+ Node pow2BvSizeRight = pow2(bvsizeRight);
+ Node a = d_nm->mkNode(
+ kind::MULT, translated_children[0], pow2BvSizeRight);
+ Node b = translated_children[1];
+ Node sum = d_nm->mkNode(kind::PLUS, a, b);
+ d_bvToIntCache[current] = sum;
+ break;
+ }
+ case kind::BITVECTOR_EXTRACT:
+ {
+ // ((_ extract i j) a) is a / 2^j mod 2^{i-j+1}
+ // current = a[i:j]
+ Node a = current[0];
+ uint64_t i = bv::utils::getExtractHigh(current);
+ uint64_t j = bv::utils::getExtractLow(current);
+ Assert(d_bvToIntCache.find(a) != d_bvToIntCache.end());
+ Assert(i >= j);
+ Node div = d_nm->mkNode(
+ kind::INTS_DIVISION_TOTAL, d_bvToIntCache[a], pow2(j));
+ d_bvToIntCache[current] = modpow2(div, i - j + 1);
+ break;
+ }
+ case kind::EQUAL:
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::EQUAL, translated_children);
+ break;
+ }
+ case kind::BITVECTOR_ULT:
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::LT, translated_children);
+ break;
+ }
+ case kind::BITVECTOR_ULE:
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::LEQ, translated_children);
+ break;
+ }
+ case kind::BITVECTOR_UGT:
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::GT, translated_children);
+ break;
+ }
+ case kind::BITVECTOR_UGE:
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::GEQ, translated_children);
+ break;
+ }
+ case kind::LT:
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::LT, translated_children);
+ break;
+ }
+ case kind::LEQ:
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::LEQ, translated_children);
+ break;
+ }
+ case kind::GT:
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::GT, translated_children);
+ break;
+ }
+ case kind::GEQ:
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::GEQ, translated_children);
+ break;
+ }
+ case kind::ITE:
+ {
+ d_bvToIntCache[current] = d_nm->mkNode(oldKind, translated_children);
+ break;
+ }
+ case kind::APPLY_UF:
+ {
+ /*
+ * We replace all BV-sorts of the domain with INT
+ * If the range is a BV sort, we replace it with INT
+ * We cache both the term itself (e.g., f(a)) and the function
+ * symbol f.
+ */
+ Node bvUF = current.getOperator();
+ Node intUF;
+ TypeNode tn = current.getOperator().getType();
+ TypeNode bvRange = tn.getRangeType();
+ if (d_bvToIntCache.find(bvUF) != d_bvToIntCache.end())
+ {
+ intUF = d_bvToIntCache[bvUF];
+ }
+ else
+ {
+ vector<TypeNode> bvDomain = tn.getArgTypes();
+ vector<TypeNode> intDomain;
+ /**
+ * if the original range is a bit-vector sort,
+ * the new range should be an integer sort.
+ * Otherwise, we keep the original range.
+ */
+ TypeNode intRange =
+ bvRange.isBitVector() ? d_nm->integerType() : bvRange;
+ for (TypeNode d : bvDomain)
+ {
+ intDomain.push_back(d.isBitVector() ? d_nm->integerType()
+ : d);
+ }
+ ostringstream os;
+ os << "__bvToInt_fun_" << bvUF << "_int";
+ intUF =
+ d_nm->mkSkolem(os.str(),
+ d_nm->mkFunctionType(intDomain, intRange),
+ "bv2int function");
+ // Insert the function symbol itself to the cache
+ d_bvToIntCache[bvUF] = intUF;
+ }
+ translated_children.insert(translated_children.begin(), intUF);
+ // Insert the term to the cache
+ d_bvToIntCache[current] =
+ d_nm->mkNode(kind::APPLY_UF, translated_children);
+ /**
+ * Add range constraints if necessary.
+ * If the original range was a BV sort, the current application of
+ * the fucntion Must be within the range determined by the
+ * bitwidth.
+ */
+ if (bvRange.isBitVector())
+ {
+ d_rangeAssertions.insert(
+ mkRangeConstraint(d_bvToIntCache[current],
+ current.getType().getBitVectorSize()));
+ }
+ break;
+ }
+ default:
+ {
+ if (Theory::theoryOf(current) == THEORY_BOOL)
+ {
+ d_bvToIntCache[current] =
+ d_nm->mkNode(oldKind, translated_children);
+ break;
+ }
+ else
+ {
+ // Currently, only QF_UFBV formulas are handled.
+ // In the future, more theories should be supported, e.g., arrays.
+ Unimplemented();
+ }
+ }
+ }
+ }
+ toVisit.pop_back();
+ }
+ }
+ }
+ return d_bvToIntCache[n];
+}
+
+BVToInt::BVToInt(PreprocessingPassContext* preprocContext)
+ : PreprocessingPass(preprocContext, "bv-to-int"),
+ d_binarizeCache(),
+ d_eliminationCache(),
+ d_bvToIntCache(),
+ d_rangeAssertions()
+{
+ d_nm = NodeManager::currentNM();
+ d_zero = d_nm->mkConst<Rational>(0);
+ d_one = d_nm->mkConst<Rational>(1);
+};
+
+PreprocessingPassResult BVToInt::applyInternal(
+ AssertionPipeline* assertionsToPreprocess)
+{
+ AlwaysAssert(!options::incrementalSolving());
+ for (uint64_t i = 0; i < assertionsToPreprocess->size(); ++i)
+ {
+ Node bvNode = (*assertionsToPreprocess)[i];
+ Node intNode = bvToInt(bvNode);
+ Node rwNode = Rewriter::rewrite(intNode);
+ Trace("bv-to-int-debug") << "bv node: " << bvNode << std::endl;
+ Trace("bv-to-int-debug") << "int node: " << intNode << std::endl;
+ Trace("bv-to-int-debug") << "rw node: " << rwNode << std::endl;
+ assertionsToPreprocess->replace(i, rwNode);
+ }
+ addFinalizeRangeAssertions(assertionsToPreprocess);
+ return PreprocessingPassResult::NO_CONFLICT;
+}
+
+void BVToInt::addFinalizeRangeAssertions(
+ AssertionPipeline* assertionsToPreprocess)
+{
+ vector<Node> vec_range;
+ vec_range.assign(d_rangeAssertions.begin(), d_rangeAssertions.end());
+ if (vec_range.size() == 1)
+ {
+ assertionsToPreprocess->push_back(vec_range[0]);
+ Trace("bv-to-int-debug")
+ << "range constraints: " << vec_range[0].toString() << std::endl;
+ }
+ else if (vec_range.size() >= 2)
+ {
+ Node rangeAssertions =
+ Rewriter::rewrite(d_nm->mkNode(kind::AND, vec_range));
+ assertionsToPreprocess->push_back(rangeAssertions);
+ Trace("bv-to-int-debug")
+ << "range constraints: " << rangeAssertions.toString() << std::endl;
+ }
+}
+
+Node BVToInt::createShiftNode(vector<Node> children,
+ uint64_t bvsize,
+ bool isLeftShift)
+{
+ Node x = children[0];
+ Node y = children[1];
+ Assert(!y.isConst());
+ // ite represents 2^x for every integer x from 0 to bvsize-1.
+ Node ite = pow2(0);
+ for (uint64_t i = 1; i < bvsize; i++)
+ {
+ ite = d_nm->mkNode(kind::ITE,
+ d_nm->mkNode(kind::EQUAL, y, d_nm->mkConst<Rational>(i)),
+ pow2(i),
+ ite);
+ }
+ /**
+ * from SMT-LIB:
+ * [[(bvshl s t)]] := nat2bv[m](bv2nat([[s]]) * 2^(bv2nat([[t]])))
+ * [[(bvlshr s t)]] := nat2bv[m](bv2nat([[s]]) div 2^(bv2nat([[t]])))
+ * Since we don't have exponentiation, we use the ite declared above.
+ */
+ kind::Kind_t then_kind = isLeftShift ? kind::MULT : kind::INTS_DIVISION_TOTAL;
+ return d_nm->mkNode(kind::ITE,
+ d_nm->mkNode(kind::LT, y, d_nm->mkConst<Rational>(bvsize)),
+ d_nm->mkNode(kind::INTS_MODULUS_TOTAL,
+ d_nm->mkNode(then_kind, x, ite),
+ pow2(bvsize)),
+ d_zero);
+}
+
+Node BVToInt::createITEFromTable(
+ Node x,
+ Node y,
+ uint64_t granularity,
+ std::map<std::pair<uint64_t, uint64_t>, uint64_t> table)
+{
+ Assert(granularity <= 8);
+ uint64_t max_value = ((uint64_t)pow(2, granularity));
+ // The table represents a function from pairs of integers to integers, where
+ // all integers are between 0 (inclusive) and max_value (exclusive).
+ Assert(table.size() == max_value * max_value);
+ Node ite = d_nm->mkConst<Rational>(table[std::make_pair(0, 0)]);
+ for (uint64_t i = 0; i < max_value; i++)
+ {
+ for (uint64_t j = 0; j < max_value; j++)
+ {
+ if ((i == 0) && (j == 0))
+ {
+ continue;
+ }
+ ite = d_nm->mkNode(
+ kind::ITE,
+ d_nm->mkNode(
+ kind::AND,
+ d_nm->mkNode(kind::EQUAL, x, d_nm->mkConst<Rational>(i)),
+ d_nm->mkNode(kind::EQUAL, y, d_nm->mkConst<Rational>(j))),
+ d_nm->mkConst<Rational>(table[std::make_pair(i, j)]),
+ ite);
+ }
+ }
+ return ite;
+}
+
+Node BVToInt::createBitwiseNode(Node x,
+ Node y,
+ uint64_t bvsize,
+ uint64_t granularity,
+ bool (*f)(bool, bool))
+{
+ /**
+ * Standardize granularity.
+ * If it is greater than bvsize, it is set to bvsize.
+ * Otherwise, it is set to the closest (going down) divider of bvsize.
+ */
+ Assert(granularity > 0);
+ if (granularity > bvsize)
+ {
+ granularity = bvsize;
+ }
+ else
+ {
+ while (bvsize % granularity != 0)
+ {
+ granularity = granularity - 1;
+ }
+ }
+ // transform f into a table
+ // f is defined over 1 bit, while the table is defined over `granularity` bits
+ std::map<std::pair<uint64_t, uint64_t>, uint64_t> table;
+ uint64_t max_value = ((uint64_t)pow(2, granularity));
+ for (uint64_t i = 0; i < max_value; i++)
+ {
+ for (uint64_t j = 0; j < max_value; j++)
+ {
+ uint64_t sum = 0;
+ for (uint64_t n = 0; n < granularity; n++)
+ {
+ // b is the result of f on the current bit
+ bool b = f((((i >> n) & 1) == 1), (((j >> n) & 1) == 1));
+ // add the corresponding power of 2 only if the result is 1
+ if (b)
+ {
+ sum += 1 << n;
+ }
+ }
+ table[std::make_pair(i, j)] = sum;
+ }
+ }
+ Assert(table.size() == max_value * max_value);
+
+ /*
+ * Create the sum.
+ * For granularity 1, the sum has bvsize elements.
+ * In contrast, if bvsize = granularity, sum has one element.
+ * Each element in the sum is an ite that corresponds to the generated table,
+ * multiplied by the appropriate power of two.
+ * More details are in bv_to_int.h .
+ */
+ uint64_t sumSize = bvsize / granularity;
+ Node sumNode = d_zero;
+ /**
+ * extract definition in integers is:
+ * (define-fun intextract ((k Int) (i Int) (j Int) (a Int)) Int
+ * (mod (div a (two_to_the j)) (two_to_the (+ (- i j) 1))))
+ */
+ for (uint64_t i = 0; i < sumSize; i++)
+ {
+ Node xExtract = d_nm->mkNode(
+ kind::INTS_MODULUS_TOTAL,
+ d_nm->mkNode(kind::INTS_DIVISION_TOTAL, x, pow2(i * granularity)),
+ pow2(granularity));
+ Node yExtract = d_nm->mkNode(
+ kind::INTS_MODULUS_TOTAL,
+ d_nm->mkNode(kind::INTS_DIVISION_TOTAL, y, pow2(i * granularity)),
+ pow2(granularity));
+ Node ite = createITEFromTable(xExtract, yExtract, granularity, table);
+ sumNode =
+ d_nm->mkNode(kind::PLUS,
+ sumNode,
+ d_nm->mkNode(kind::MULT, pow2(i * granularity), ite));
+ }
+ return sumNode;
+}
+
+Node BVToInt::createBVNotNode(Node n, uint64_t bvsize)
+{
+ return d_nm->mkNode(kind::MINUS, maxInt(bvsize), n);
+}
+
+} // namespace passes
+} // namespace preprocessing
+} // namespace CVC4
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