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/********************* */
/*! \file node_algorithm_black.cpp
** \verbatim
** Top contributors (to current version):
** Aina Niemetz, Yoni Zohar, Abdalrhman Mohamed
** This file is part of the CVC4 project.
** Copyright (c) 2009-2021 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 Black box testing of utility functions in node_algorithm.{h,cpp}
**
** Black box testing of node_algorithm.{h,cpp}
**/
#include <string>
#include <vector>
#include "base/output.h"
#include "expr/node_algorithm.h"
#include "expr/node_manager.h"
#include "test_node.h"
#include "theory/bv/theory_bv_utils.h"
#include "util/integer.h"
#include "util/rational.h"
namespace cvc5 {
using namespace expr;
using namespace kind;
namespace test {
class TestNodeBlackNodeAlgorithm : public TestNode
{
};
TEST_F(TestNodeBlackNodeAlgorithm, get_symbols1)
{
// The only symbol in ~x (x is a boolean varible) should be x
Node x = d_nodeManager->mkSkolem("x", d_nodeManager->booleanType());
Node n = d_nodeManager->mkNode(NOT, x);
std::unordered_set<Node, NodeHashFunction> syms;
getSymbols(n, syms);
ASSERT_EQ(syms.size(), 1);
ASSERT_NE(syms.find(x), syms.end());
}
TEST_F(TestNodeBlackNodeAlgorithm, get_symbols2)
{
// the only symbols in x=y ^ (exists var. var+var = x) are x and y, because
// "var" is bound.
// left conjunct
Node x = d_nodeManager->mkSkolem("x", d_nodeManager->integerType());
Node y = d_nodeManager->mkSkolem("y", d_nodeManager->integerType());
Node left = d_nodeManager->mkNode(EQUAL, x, y);
// right conjunct
Node var = d_nodeManager->mkBoundVar(*d_intTypeNode);
std::vector<Node> vars;
vars.push_back(var);
Node sum = d_nodeManager->mkNode(PLUS, var, var);
Node qeq = d_nodeManager->mkNode(EQUAL, x, sum);
Node bvl = d_nodeManager->mkNode(BOUND_VAR_LIST, vars);
Node right = d_nodeManager->mkNode(EXISTS, bvl, qeq);
// conjunction
Node res = d_nodeManager->mkNode(AND, left, right);
// symbols
std::unordered_set<Node, NodeHashFunction> syms;
getSymbols(res, syms);
// assertions
ASSERT_EQ(syms.size(), 2);
ASSERT_NE(syms.find(x), syms.end());
ASSERT_NE(syms.find(y), syms.end());
ASSERT_EQ(syms.find(var), syms.end());
}
TEST_F(TestNodeBlackNodeAlgorithm, get_operators_map)
{
// map to store result
std::map<TypeNode, std::unordered_set<Node, NodeHashFunction> > result =
std::map<TypeNode, std::unordered_set<Node, NodeHashFunction> >();
// create test formula
Node x = d_nodeManager->mkSkolem("x", d_nodeManager->integerType());
Node plus = d_nodeManager->mkNode(PLUS, x, x);
Node mul = d_nodeManager->mkNode(MULT, x, x);
Node eq1 = d_nodeManager->mkNode(EQUAL, plus, mul);
Node y = d_nodeManager->mkSkolem("y", d_nodeManager->mkBitVectorType(4));
Node ext1 = theory::bv::utils::mkExtract(y, 1, 0);
Node ext2 = theory::bv::utils::mkExtract(y, 3, 2);
Node eq2 = d_nodeManager->mkNode(EQUAL, ext1, ext2);
Node formula = d_nodeManager->mkNode(AND, eq1, eq2);
// call function
expr::getOperatorsMap(formula, result);
// Verify result
// We should have only integer, bv and boolean as types
ASSERT_EQ(result.size(), 3);
ASSERT_NE(result.find(*d_intTypeNode), result.end());
ASSERT_NE(result.find(*d_boolTypeNode), result.end());
ASSERT_NE(result.find(*d_bvTypeNode), result.end());
// in integers, we should only have plus and mult as operators
ASSERT_EQ(result[*d_intTypeNode].size(), 2);
ASSERT_NE(result[*d_intTypeNode].find(d_nodeManager->operatorOf(PLUS)),
result[*d_intTypeNode].end());
ASSERT_NE(result[*d_intTypeNode].find(d_nodeManager->operatorOf(MULT)),
result[*d_intTypeNode].end());
// in booleans, we should only have "=" and "and" as an operator.
ASSERT_EQ(result[*d_boolTypeNode].size(), 2);
ASSERT_NE(result[*d_boolTypeNode].find(d_nodeManager->operatorOf(EQUAL)),
result[*d_boolTypeNode].end());
ASSERT_NE(result[*d_boolTypeNode].find(d_nodeManager->operatorOf(AND)),
result[*d_boolTypeNode].end());
// in bv, we should only have "extract" as an operator.
ASSERT_EQ(result[*d_boolTypeNode].size(), 2);
Node extractOp1 =
d_nodeManager->mkConst<BitVectorExtract>(BitVectorExtract(1, 0));
Node extractOp2 =
d_nodeManager->mkConst<BitVectorExtract>(BitVectorExtract(3, 2));
ASSERT_NE(result[*d_bvTypeNode].find(extractOp1),
result[*d_bvTypeNode].end());
ASSERT_NE(result[*d_bvTypeNode].find(extractOp2),
result[*d_bvTypeNode].end());
}
TEST_F(TestNodeBlackNodeAlgorithm, match)
{
TypeNode integer = d_nodeManager->integerType();
Node one = d_nodeManager->mkConst(Rational(1));
Node two = d_nodeManager->mkConst(Rational(2));
Node x = d_nodeManager->mkBoundVar(integer);
Node a = d_nodeManager->mkSkolem("a", integer);
Node n1 = d_nodeManager->mkNode(MULT, two, x);
std::unordered_map<Node, Node, NodeHashFunction> subs;
// check reflexivity
ASSERT_TRUE(match(n1, n1, subs));
ASSERT_EQ(subs.size(), 0);
Node n2 = d_nodeManager->mkNode(MULT, two, a);
subs.clear();
// check instance
ASSERT_TRUE(match(n1, n2, subs));
ASSERT_EQ(subs.size(), 1);
ASSERT_EQ(subs[x], a);
// should return false for flipped arguments (match is not symmetric)
ASSERT_FALSE(match(n2, n1, subs));
n2 = d_nodeManager->mkNode(MULT, one, a);
// should return false since n2 is not an instance of n1
ASSERT_FALSE(match(n1, n2, subs));
n2 = d_nodeManager->mkNode(NONLINEAR_MULT, two, a);
// should return false for similar operators
ASSERT_FALSE(match(n1, n2, subs));
n2 = d_nodeManager->mkNode(MULT, two, a, one);
// should return false for different number of arguments
ASSERT_FALSE(match(n1, n2, subs));
n1 = x;
n2 = d_nodeManager->mkConst(true);
// should return false for different types
ASSERT_FALSE(match(n1, n2, subs));
n1 = d_nodeManager->mkNode(MULT, x, x);
n2 = d_nodeManager->mkNode(MULT, two, a);
// should return false for contradictory substitutions
ASSERT_FALSE(match(n1, n2, subs));
n2 = d_nodeManager->mkNode(MULT, a, a);
subs.clear();
// implementation: check if the cache works correctly
ASSERT_TRUE(match(n1, n2, subs));
ASSERT_EQ(subs.size(), 1);
ASSERT_EQ(subs[x], a);
}
} // namespace test
} // namespace cvc5
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