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GCC Code Coverage Report

Directory:	.		Exec	Total	Coverage
File:	src/theory/arith/proof_checker.cpp	Lines:	122	174	70.1 %
Date:	2021-09-05	Branches:	253	857	29.5 %


/******************************************************************************
 * Top contributors (to current version):
 *   Alex Ozdemir, Gereon Kremer, Andres Noetzli
 *
 * This file is part of the cvc5 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.
 * ****************************************************************************
 *
 * Implementation of arithmetic proof checker.
 */

#include "theory/arith/proof_checker.h"

#include <iostream>
#include <set>

#include "expr/skolem_manager.h"
#include "theory/arith/arith_utilities.h"
#include "theory/arith/constraint.h"
#include "theory/arith/normal_form.h"
#include "theory/arith/operator_elim.h"

namespace cvc5 {
namespace theory {
namespace arith {

void ArithProofRuleChecker::registerTo(ProofChecker* pc)
{
  pc->registerChecker(PfRule::MACRO_ARITH_SCALE_SUM_UB, this);
  pc->registerChecker(PfRule::ARITH_SUM_UB, this);
  pc->registerChecker(PfRule::ARITH_TRICHOTOMY, this);
  pc->registerChecker(PfRule::INT_TIGHT_UB, this);
  pc->registerChecker(PfRule::INT_TIGHT_LB, this);
  pc->registerChecker(PfRule::ARITH_OP_ELIM_AXIOM, this);
  pc->registerChecker(PfRule::ARITH_MULT_POS, this);
  pc->registerChecker(PfRule::ARITH_MULT_NEG, this);
}

Node ArithProofRuleChecker::checkInternal(PfRule id,
                                          const std::vector<Node>& children,
                                          const std::vector<Node>& args)
{
  NodeManager* nm = NodeManager::currentNM();
  auto zero = nm->mkConst<Rational>(0);
  if (Debug.isOn("arith::pf::check"))
  {
    Debug("arith::pf::check") << "Arith PfRule:" << id << std::endl;
    Debug("arith::pf::check") << "  children: " << std::endl;
    for (const auto& c : children)
    {
      Debug("arith::pf::check") << "  * " << c << std::endl;
    }
    Debug("arith::pf::check") << "  args:" << std::endl;
    for (const auto& c : args)
    {
      Debug("arith::pf::check") << "  * " << c << std::endl;
    }
  }
  switch (id)
  {
    case PfRule::ARITH_MULT_POS:
    {
      Assert(children.empty());
      Assert(args.size() == 2);
      Node mult = args[0];
      Kind rel = args[1].getKind();
      Assert(rel == Kind::EQUAL || rel == Kind::DISTINCT || rel == Kind::LT
             || rel == Kind::LEQ || rel == Kind::GT || rel == Kind::GEQ);
      Node lhs = args[1][0];
      Node rhs = args[1][1];
      return nm->mkNode(Kind::IMPLIES,
                        nm->mkAnd(std::vector<Node>{
                            nm->mkNode(Kind::GT, mult, zero), args[1]}),
                        nm->mkNode(rel,
                                   nm->mkNode(Kind::MULT, mult, lhs),
                                   nm->mkNode(Kind::MULT, mult, rhs)));
    }
    case PfRule::ARITH_MULT_NEG:
    {
      Assert(children.empty());
      Assert(args.size() == 2);
      Node mult = args[0];
      Kind rel = args[1].getKind();
      Assert(rel == Kind::EQUAL || rel == Kind::DISTINCT || rel == Kind::LT
             || rel == Kind::LEQ || rel == Kind::GT || rel == Kind::GEQ);
      Kind rel_inv = (rel == Kind::DISTINCT ? rel : reverseRelationKind(rel));
      Node lhs = args[1][0];
      Node rhs = args[1][1];
      return nm->mkNode(Kind::IMPLIES,
                        nm->mkAnd(std::vector<Node>{
                            nm->mkNode(Kind::LT, mult, zero), args[1]}),
                        nm->mkNode(rel_inv,
                                   nm->mkNode(Kind::MULT, mult, lhs),
                                   nm->mkNode(Kind::MULT, mult, rhs)));
    }
    case PfRule::ARITH_SUM_UB:
    {
      if (children.size() < 2)
      {
        return Node::null();
      }

      // Whether a strict inequality is in the sum.
      bool strict = false;
      NodeBuilder leftSum(Kind::PLUS);
      NodeBuilder rightSum(Kind::PLUS);
      for (size_t i = 0; i < children.size(); ++i)
      {
        // Adjust strictness
        switch (children[i].getKind())
        {
          case Kind::LT:
          {
            strict = true;
            break;
          }
          case Kind::LEQ:
          case Kind::EQUAL:
          {
            break;
          }
          default:
          {
            Debug("arith::pf::check")
                << "Bad kind: " << children[i].getKind() << std::endl;
            return Node::null();
          }
        }
        leftSum << children[i][0];
        rightSum << children[i][1];
      }
      Node r = nm->mkNode(strict ? Kind::LT : Kind::LEQ,
                          leftSum.constructNode(),
                          rightSum.constructNode());
      return r;
    }
    case PfRule::MACRO_ARITH_SCALE_SUM_UB:
    {
      //================================================= Arithmetic rules
      // ======== Adding Inequalities
      // Note: an ArithLiteral is a term of the form (>< poly const)
      // where
      //   >< is >=, >, ==, <, <=, or not(== ...).
      //   poly is a polynomial
      //   const is a rational constant

      // Children: (P1:l1, ..., Pn:ln)
      //           where each li is an ArithLiteral
      //           not(= ...) is dis-allowed!
      //
      // Arguments: (k1, ..., kn), non-zero reals
      // ---------------------
      // Conclusion: (>< t1 t2)
      //    where >< is the fusion of the combination of the ><i, (flipping each
      //    it its ki is negative). >< is always one of <, <= NB: this implies
      //    that lower bounds must have negative ki,
      //                      and upper bounds must have positive ki.
      //    t1 is the sum of the scaled polynomials (k_1 * poly_1 + ... + k_n *
      //    poly_n) t2 is the sum of the scaled constants (k_1 * const_1 + ... +
      //    k_n * const_n)
      Assert(children.size() == args.size());
      if (children.size() < 2)
      {
        return Node::null();
      }

      // Whether a strict inequality is in the sum.
      bool strict = false;
      NodeBuilder leftSum(Kind::PLUS);
      NodeBuilder rightSum(Kind::PLUS);
      for (size_t i = 0; i < children.size(); ++i)
      {
        Rational scalar = args[i].getConst<Rational>();
        if (scalar == 0)
        {
          Debug("arith::pf::check") << "Error: zero scalar" << std::endl;
          return Node::null();
        }

        // Adjust strictness
        switch (children[i].getKind())
        {
          case Kind::GT:
          case Kind::LT:
          {
            strict = true;
            break;
          }
          case Kind::GEQ:
          case Kind::LEQ:
          case Kind::EQUAL:
          {
            break;
          }
          default:
          {
            Debug("arith::pf::check")
                << "Bad kind: " << children[i].getKind() << std::endl;
          }
        }
        // Check sign
        switch (children[i].getKind())
        {
          case Kind::GT:
          case Kind::GEQ:
          {
            if (scalar > 0)
            {
              Debug("arith::pf::check")
                  << "Positive scalar for lower bound: " << scalar << " for "
                  << children[i] << std::endl;
              return Node::null();
            }
            break;
          }
          case Kind::LEQ:
          case Kind::LT:
          {
            if (scalar < 0)
            {
              Debug("arith::pf::check")
                  << "Negative scalar for upper bound: " << scalar << " for "
                  << children[i] << std::endl;
              return Node::null();
            }
            break;
          }
          case Kind::EQUAL:
          {
            break;
          }
          default:
          {
            Debug("arith::pf::check")
                << "Bad kind: " << children[i].getKind() << std::endl;
          }
        }
        leftSum << nm->mkNode(
            Kind::MULT, nm->mkConst<Rational>(scalar), children[i][0]);
        rightSum << nm->mkNode(
            Kind::MULT, nm->mkConst<Rational>(scalar), children[i][1]);
      }
      Node r = nm->mkNode(strict ? Kind::LT : Kind::LEQ,
                          leftSum.constructNode(),
                          rightSum.constructNode());
      return r;
    }
    case PfRule::INT_TIGHT_LB:
    {
      // Children: (P:(> i c))
      //         where i has integer type.
      // Arguments: none
      // ---------------------
      // Conclusion: (>= i leastIntGreaterThan(c)})
      if (children.size() != 1
          || (children[0].getKind() != Kind::GT
              && children[0].getKind() != Kind::GEQ)
          || !children[0][0].getType().isInteger()
          || children[0][1].getKind() != Kind::CONST_RATIONAL)
      {
        Debug("arith::pf::check") << "Illformed input: " << children;
        return Node::null();
      }
      else
      {
        Rational originalBound = children[0][1].getConst<Rational>();
        Rational newBound = leastIntGreaterThan(originalBound);
        Node rational = nm->mkConst<Rational>(newBound);
        return nm->mkNode(kind::GEQ, children[0][0], rational);
      }
    }
    case PfRule::INT_TIGHT_UB:
    {
      // ======== Tightening Strict Integer Upper Bounds
      // Children: (P:(< i c))
      //         where i has integer type.
      // Arguments: none
      // ---------------------
      // Conclusion: (<= i greatestIntLessThan(c)})
      if (children.size() != 1
          || (children[0].getKind() != Kind::LT
              && children[0].getKind() != Kind::LEQ)
          || !children[0][0].getType().isInteger()
          || children[0][1].getKind() != Kind::CONST_RATIONAL)
      {
        Debug("arith::pf::check") << "Illformed input: " << children;
        return Node::null();
      }
      else
      {
        Rational originalBound = children[0][1].getConst<Rational>();
        Rational newBound = greatestIntLessThan(originalBound);
        Node rational = nm->mkConst<Rational>(newBound);
        return nm->mkNode(kind::LEQ, children[0][0], rational);
      }
    }
    case PfRule::ARITH_TRICHOTOMY:
    {
      Node a = negateProofLiteral(children[0]);
      Node b = negateProofLiteral(children[1]);
      Node c = args[0];
      if (a[0] == b[0] && b[0] == c[0] && a[1] == b[1] && b[1] == c[1])
      {
        std::set<Kind> cmps;
        cmps.insert(a.getKind());
        cmps.insert(b.getKind());
        cmps.insert(c.getKind());
        if (cmps.count(Kind::EQUAL) == 0)
        {
          Debug("arith::pf::check") << "Error: No = " << std::endl;
          return Node::null();
        }
        if (cmps.count(Kind::GT) == 0)
        {
          Debug("arith::pf::check") << "Error: No > " << std::endl;
          return Node::null();
        }
        if (cmps.count(Kind::LT) == 0)
        {
          Debug("arith::pf::check") << "Error: No < " << std::endl;
          return Node::null();
        }
        return args[0];
      }
      else
      {
        Debug("arith::pf::check")
            << "Error: Different polynomials / values" << std::endl;
        Debug("arith::pf::check") << "  a: " << a << std::endl;
        Debug("arith::pf::check") << "  b: " << b << std::endl;
        Debug("arith::pf::check") << "  c: " << c << std::endl;
        return Node::null();
      }
      // Check that all have the same constant:
    }
    case PfRule::ARITH_OP_ELIM_AXIOM:
    {
      Assert(children.empty());
      Assert(args.size() == 1);
      return OperatorElim::getAxiomFor(args[0]);
    }
    default: return Node::null();
  }
}
}  // namespace arith
}  // namespace theory
}  // namespace cvc5


Generated by: GCOVR (Version 3.2)

Line	Exec	Source
1		/******************************************************************************
2		* Top contributors (to current version):
3		* Alex Ozdemir, Gereon Kremer, Andres Noetzli
4		*
5		* This file is part of the cvc5 project.
6		*
7		* Copyright (c) 2009-2021 by the authors listed in the file AUTHORS
8		* in the top-level source directory and their institutional affiliations.
9		* All rights reserved. See the file COPYING in the top-level source
10		* directory for licensing information.
11		* ****************************************************************************
12		*
13		* Implementation of arithmetic proof checker.
14		*/
15
16		#include "theory/arith/proof_checker.h"
17
18		#include <iostream>
19		#include <set>
20
21		#include "expr/skolem_manager.h"
22		#include "theory/arith/arith_utilities.h"
23		#include "theory/arith/constraint.h"
24		#include "theory/arith/normal_form.h"
25		#include "theory/arith/operator_elim.h"
26
27		namespace cvc5 {
28		namespace theory {
29		namespace arith {
30
31	3784	void ArithProofRuleChecker::registerTo(ProofChecker* pc)
32		{
33	3784	pc->registerChecker(PfRule::MACRO_ARITH_SCALE_SUM_UB, this);
34	3784	pc->registerChecker(PfRule::ARITH_SUM_UB, this);
35	3784	pc->registerChecker(PfRule::ARITH_TRICHOTOMY, this);
36	3784	pc->registerChecker(PfRule::INT_TIGHT_UB, this);
37	3784	pc->registerChecker(PfRule::INT_TIGHT_LB, this);
38	3784	pc->registerChecker(PfRule::ARITH_OP_ELIM_AXIOM, this);
39	3784	pc->registerChecker(PfRule::ARITH_MULT_POS, this);
40	3784	pc->registerChecker(PfRule::ARITH_MULT_NEG, this);
41	3784	}
42
43	192749	Node ArithProofRuleChecker::checkInternal(PfRule id,
44		const std::vector<Node>& children,
45		const std::vector<Node>& args)
46		{
47	192749	NodeManager* nm = NodeManager::currentNM();
48	385498	auto zero = nm->mkConst<Rational>(0);
49	192749	if (Debug.isOn("arith::pf::check"))
50		{
51		Debug("arith::pf::check") << "Arith PfRule:" << id << std::endl;
52		Debug("arith::pf::check") << " children: " << std::endl;
53		for (const auto& c : children)
54		{
55		Debug("arith::pf::check") << " * " << c << std::endl;
56		}
57		Debug("arith::pf::check") << " args:" << std::endl;
58		for (const auto& c : args)
59		{
60		Debug("arith::pf::check") << " * " << c << std::endl;
61		}
62		}
63	192749	switch (id)
64		{
65	23994	case PfRule::ARITH_MULT_POS:
66		{
67	23994	Assert(children.empty());
68	23994	Assert(args.size() == 2);
69	47988	Node mult = args[0];
70	23994	Kind rel = args[1].getKind();
71	23994	Assert(rel == Kind::EQUAL \|\| rel == Kind::DISTINCT \|\| rel == Kind::LT
72		\|\| rel == Kind::LEQ \|\| rel == Kind::GT \|\| rel == Kind::GEQ);
73	47988	Node lhs = args[1][0];
74	47988	Node rhs = args[1][1];
75		return nm->mkNode(Kind::IMPLIES,
76	119970	nm->mkAnd(std::vector<Node>{
77	71982	nm->mkNode(Kind::GT, mult, zero), args[1]}),
78	95976	nm->mkNode(rel,
79	47988	nm->mkNode(Kind::MULT, mult, lhs),
80	119970	nm->mkNode(Kind::MULT, mult, rhs)));
81		}
82	27147	case PfRule::ARITH_MULT_NEG:
83		{
84	27147	Assert(children.empty());
85	27147	Assert(args.size() == 2);
86	54294	Node mult = args[0];
87	27147	Kind rel = args[1].getKind();
88	27147	Assert(rel == Kind::EQUAL \|\| rel == Kind::DISTINCT \|\| rel == Kind::LT
89		\|\| rel == Kind::LEQ \|\| rel == Kind::GT \|\| rel == Kind::GEQ);
90	27147	Kind rel_inv = (rel == Kind::DISTINCT ? rel : reverseRelationKind(rel));
91	54294	Node lhs = args[1][0];
92	54294	Node rhs = args[1][1];
93		return nm->mkNode(Kind::IMPLIES,
94	135735	nm->mkAnd(std::vector<Node>{
95	81441	nm->mkNode(Kind::LT, mult, zero), args[1]}),
96	108588	nm->mkNode(rel_inv,
97	54294	nm->mkNode(Kind::MULT, mult, lhs),
98	135735	nm->mkNode(Kind::MULT, mult, rhs)));
99		}
100	9722	case PfRule::ARITH_SUM_UB:
101		{
102	9722	if (children.size() < 2)
103		{
104		return Node::null();
105		}
106
107		// Whether a strict inequality is in the sum.
108	9722	bool strict = false;
109	19444	NodeBuilder leftSum(Kind::PLUS);
110	19444	NodeBuilder rightSum(Kind::PLUS);
111	62144	for (size_t i = 0; i < children.size(); ++i)
112		{
113		// Adjust strictness
114	52422	switch (children[i].getKind())
115		{
116	9024	case Kind::LT:
117		{
118	9024	strict = true;
119	9024	break;
120		}
121	43398	case Kind::LEQ:
122		case Kind::EQUAL:
123		{
124	43398	break;
125		}
126		default:
127		{
128		Debug("arith::pf::check")
129		<< "Bad kind: " << children[i].getKind() << std::endl;
130		return Node::null();
131		}
132		}
133	52422	leftSum << children[i][0];
134	52422	rightSum << children[i][1];
135		}
136		Node r = nm->mkNode(strict ? Kind::LT : Kind::LEQ,
137	19444	leftSum.constructNode(),
138	38888	rightSum.constructNode());
139	9722	return r;
140		}
141	85155	case PfRule::MACRO_ARITH_SCALE_SUM_UB:
142		{
143		//================================================= Arithmetic rules
144		// ======== Adding Inequalities
145		// Note: an ArithLiteral is a term of the form (>< poly const)
146		// where
147		// >< is >=, >, ==, <, <=, or not(== ...).
148		// poly is a polynomial
149		// const is a rational constant
150
151		// Children: (P1:l1, ..., Pn:ln)
152		// where each li is an ArithLiteral
153		// not(= ...) is dis-allowed!
154		//
155		// Arguments: (k1, ..., kn), non-zero reals
156		// ---------------------
157		// Conclusion: (>< t1 t2)
158		// where >< is the fusion of the combination of the ><i, (flipping each
159		// it its ki is negative). >< is always one of <, <= NB: this implies
160		// that lower bounds must have negative ki,
161		// and upper bounds must have positive ki.
162		// t1 is the sum of the scaled polynomials (k_1 * poly_1 + ... + k_n *
163		// poly_n) t2 is the sum of the scaled constants (k_1 * const_1 + ... +
164		// k_n * const_n)
165	85155	Assert(children.size() == args.size());
166	85155	if (children.size() < 2)
167		{
168		return Node::null();
169		}
170
171		// Whether a strict inequality is in the sum.
172	85155	bool strict = false;
173	170310	NodeBuilder leftSum(Kind::PLUS);
174	170310	NodeBuilder rightSum(Kind::PLUS);
175	365997	for (size_t i = 0; i < children.size(); ++i)
176		{
177	561684	Rational scalar = args[i].getConst<Rational>();
178	280842	if (scalar == 0)
179		{
180		Debug("arith::pf::check") << "Error: zero scalar" << std::endl;
181		return Node::null();
182		}
183
184		// Adjust strictness
185	280842	switch (children[i].getKind())
186		{
187	53267	case Kind::GT:
188		case Kind::LT:
189		{
190	53267	strict = true;
191	53267	break;
192		}
193	227575	case Kind::GEQ:
194		case Kind::LEQ:
195		case Kind::EQUAL:
196		{
197	227575	break;
198		}
199		default:
200		{
201		Debug("arith::pf::check")
202		<< "Bad kind: " << children[i].getKind() << std::endl;
203		}
204		}
205		// Check sign
206	280842	switch (children[i].getKind())
207		{
208	76835	case Kind::GT:
209		case Kind::GEQ:
210		{
211	76835	if (scalar > 0)
212		{
213		Debug("arith::pf::check")
214		<< "Positive scalar for lower bound: " << scalar << " for "
215		<< children[i] << std::endl;
216		return Node::null();
217		}
218	76835	break;
219		}
220	84739	case Kind::LEQ:
221		case Kind::LT:
222		{
223	84739	if (scalar < 0)
224		{
225		Debug("arith::pf::check")
226		<< "Negative scalar for upper bound: " << scalar << " for "
227		<< children[i] << std::endl;
228		return Node::null();
229		}
230	84739	break;
231		}
232	119268	case Kind::EQUAL:
233		{
234	119268	break;
235		}
236		default:
237		{
238		Debug("arith::pf::check")
239		<< "Bad kind: " << children[i].getKind() << std::endl;
240		}
241		}
242	1404210	leftSum << nm->mkNode(
243	1404210	Kind::MULT, nm->mkConst<Rational>(scalar), children[i][0]);
244	1404210	rightSum << nm->mkNode(
245	1404210	Kind::MULT, nm->mkConst<Rational>(scalar), children[i][1]);
246		}
247		Node r = nm->mkNode(strict ? Kind::LT : Kind::LEQ,
248	170310	leftSum.constructNode(),
249	340620	rightSum.constructNode());
250	85155	return r;
251		}
252	270	case PfRule::INT_TIGHT_LB:
253		{
254		// Children: (P:(> i c))
255		// where i has integer type.
256		// Arguments: none
257		// ---------------------
258		// Conclusion: (>= i leastIntGreaterThan(c)})
259	540	if (children.size() != 1
260	270	\|\| (children[0].getKind() != Kind::GT
261		&& children[0].getKind() != Kind::GEQ)
262	540	\|\| !children[0][0].getType().isInteger()
263	810	\|\| children[0][1].getKind() != Kind::CONST_RATIONAL)
264		{
265		Debug("arith::pf::check") << "Illformed input: " << children;
266		return Node::null();
267		}
268		else
269		{
270	540	Rational originalBound = children[0][1].getConst<Rational>();
271	540	Rational newBound = leastIntGreaterThan(originalBound);
272	540	Node rational = nm->mkConst<Rational>(newBound);
273	270	return nm->mkNode(kind::GEQ, children[0][0], rational);
274		}
275		}
276	4135	case PfRule::INT_TIGHT_UB:
277		{
278		// ======== Tightening Strict Integer Upper Bounds
279		// Children: (P:(< i c))
280		// where i has integer type.
281		// Arguments: none
282		// ---------------------
283		// Conclusion: (<= i greatestIntLessThan(c)})
284	8270	if (children.size() != 1
285	4135	\|\| (children[0].getKind() != Kind::LT
286		&& children[0].getKind() != Kind::LEQ)
287	8270	\|\| !children[0][0].getType().isInteger()
288	12405	\|\| children[0][1].getKind() != Kind::CONST_RATIONAL)
289		{
290		Debug("arith::pf::check") << "Illformed input: " << children;
291		return Node::null();
292		}
293		else
294		{
295	8270	Rational originalBound = children[0][1].getConst<Rational>();
296	8270	Rational newBound = greatestIntLessThan(originalBound);
297	8270	Node rational = nm->mkConst<Rational>(newBound);
298	4135	return nm->mkNode(kind::LEQ, children[0][0], rational);
299		}
300		}
301	42326	case PfRule::ARITH_TRICHOTOMY:
302		{
303	84652	Node a = negateProofLiteral(children[0]);
304	84652	Node b = negateProofLiteral(children[1]);
305	84652	Node c = args[0];
306	42326	if (a[0] == b[0] && b[0] == c[0] && a[1] == b[1] && b[1] == c[1])
307		{
308	84652	std::set<Kind> cmps;
309	42326	cmps.insert(a.getKind());
310	42326	cmps.insert(b.getKind());
311	42326	cmps.insert(c.getKind());
312	42326	if (cmps.count(Kind::EQUAL) == 0)
313		{
314		Debug("arith::pf::check") << "Error: No = " << std::endl;
315		return Node::null();
316		}
317	42326	if (cmps.count(Kind::GT) == 0)
318		{
319		Debug("arith::pf::check") << "Error: No > " << std::endl;
320		return Node::null();
321		}
322	42326	if (cmps.count(Kind::LT) == 0)
323		{
324		Debug("arith::pf::check") << "Error: No < " << std::endl;
325		return Node::null();
326		}
327	42326	return args[0];
328		}
329		else
330		{
331		Debug("arith::pf::check")
332		<< "Error: Different polynomials / values" << std::endl;
333		Debug("arith::pf::check") << " a: " << a << std::endl;
334		Debug("arith::pf::check") << " b: " << b << std::endl;
335		Debug("arith::pf::check") << " c: " << c << std::endl;
336		return Node::null();
337		}
338		// Check that all have the same constant:
339		}
340		case PfRule::ARITH_OP_ELIM_AXIOM:
341		{
342		Assert(children.empty());
343		Assert(args.size() == 1);
344		return OperatorElim::getAxiomFor(args[0]);
345		}
346		default: return Node::null();
347		}
348		}
349		} // namespace arith
350		} // namespace theory
351	29505	} // namespace cvc5