gcc/analyzer/constraint-manager.h - gcc - Git at Google

 /* Tracking equivalence classes and constraints at a point on an execution path.
    Copyright (C) 2019-2020 Free Software Foundation, Inc.
    Contributed by David Malcolm <dmalcolm@redhat.com>.

 This file is part of GCC.

 GCC is free software; you can redistribute it and/or modify it
 under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 3, or (at your option)
 any later version.

 GCC is distributed in the hope that it will be useful, but
 WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 General Public License for more details.

 You should have received a copy of the GNU General Public License
 along with GCC; see the file COPYING3.  If not see
 <http://www.gnu.org/licenses/>.  */

 #ifndef GCC_ANALYZER_CONSTRAINT_MANAGER_H
 #define GCC_ANALYZER_CONSTRAINT_MANAGER_H

 namespace ana {

 class constraint_manager;

 /* Abstract base class for specifying how state should be purged.  */

 class purge_criteria
 {
 public:
   virtual ~purge_criteria () {}
   virtual bool should_purge_p (svalue_id sid) const = 0;
 };

 /* An equivalence class within a constraint manager: a set of
    svalue_ids that are known to all be equal to each other,
    together with an optional tree constant that they are equal to.  */

 class equiv_class
 {
 public:
   equiv_class ();
   equiv_class (const equiv_class &other);

   hashval_t hash () const;
   bool operator== (const equiv_class &other);

   void add (svalue_id sid, const constraint_manager &cm);
   bool del (svalue_id sid);

   tree get_any_constant () const { return m_constant; }

   svalue_id get_representative () const;

   void remap_svalue_ids (const svalue_id_map &map);

   void canonicalize ();

   void print (pretty_printer *pp) const;

   /* An equivalence class can contain multiple constants (e.g. multiple
      different zeroes, for different types); these are just for the last
      constant added.  */
   tree m_constant;
   svalue_id m_cst_sid;

   // TODO: should this be a set rather than a vec?
   auto_vec<svalue_id> m_vars;
 };

 /* The various kinds of constraint.  */

 enum constraint_op
 {
   CONSTRAINT_NE,
   CONSTRAINT_LT,
   CONSTRAINT_LE
 };

 const char *constraint_op_code (enum constraint_op c_op);

 /* An ID for an equiv_class within a constraint_manager.  Internally, this
    is an index into a vector of equiv_class * within the constraint_manager.  */

 class equiv_class_id
 {
 public:
   static equiv_class_id null () { return equiv_class_id (-1); }

   equiv_class_id (unsigned idx) : m_idx (idx) {}
   const equiv_class &get_obj (const constraint_manager &cm) const;
   equiv_class &get_obj (constraint_manager &cm) const;

   bool operator== (const equiv_class_id &other) const
   {
     return m_idx == other.m_idx;
   }
   bool operator!= (const equiv_class_id &other) const
   {
     return m_idx != other.m_idx;
   }

   bool null_p () const { return m_idx == -1; }

   static equiv_class_id from_int (int idx) { return equiv_class_id (idx); }
   int as_int () const { return m_idx; }

   void print (pretty_printer *pp) const;

   void update_for_removal (equiv_class_id other)
   {
     if (m_idx > other.m_idx)
       m_idx--;
   }

   int m_idx;
 };

 /* A relationship between two equivalence classes in a constraint_manager.  */

 class constraint
 {
  public:
   constraint (equiv_class_id lhs, enum constraint_op c_op, equiv_class_id rhs)
   : m_lhs (lhs), m_op (c_op), m_rhs (rhs)
   {
     gcc_assert (!lhs.null_p ());
     gcc_assert (!rhs.null_p ());
   }

   void print (pretty_printer *pp, const constraint_manager &cm) const;

   hashval_t hash () const;
   bool operator== (const constraint &other) const;

   /* Is this an ordering, rather than a "!=".  */
   bool is_ordering_p () const
   {
     return m_op != CONSTRAINT_NE;
   }

   equiv_class_id m_lhs;
   enum constraint_op m_op;
   equiv_class_id m_rhs;
 };

 /* An abstract base class for use with constraint_manager::for_each_fact.  */

 class fact_visitor
 {
  public:
   virtual ~fact_visitor () {}
   virtual void on_fact (svalue_id lhs, enum tree_code, svalue_id rhs) = 0;
 };

 /* A collection of equivalence classes and constraints on them.

    Given N svalues, this can be thought of as representing a subset of
    N-dimensional space.  When we call add_constraint,
    we are effectively taking an intersection with that constraint.  */

 class constraint_manager
 {
 public:
   constraint_manager () {}
   constraint_manager (const constraint_manager &other);
   virtual ~constraint_manager () {}

   virtual constraint_manager *clone (region_model *) const = 0;
   virtual tree maybe_get_constant (svalue_id sid) const = 0;
   virtual svalue_id get_sid_for_constant (tree cst) const = 0;
   virtual int get_num_svalues () const = 0;

   constraint_manager& operator= (const constraint_manager &other);

   hashval_t hash () const;
   bool operator== (const constraint_manager &other) const;
   bool operator!= (const constraint_manager &other) const
   {
     return !(*this == other);
   }

   void print (pretty_printer *pp) const;
   void dump_to_pp (pretty_printer *pp) const;
   void dump (FILE *fp) const;
   void dump () const;

   const equiv_class &get_equiv_class_by_index (unsigned idx) const
   {
     return *m_equiv_classes[idx];
   }
   equiv_class &get_equiv_class_by_index (unsigned idx)
   {
     return *m_equiv_classes[idx];
   }

   equiv_class &get_equiv_class (svalue_id sid)
   {
     equiv_class_id ec_id = get_or_add_equiv_class (sid);
     return ec_id.get_obj (*this);
   }

   bool add_constraint (svalue_id lhs, enum tree_code op, svalue_id rhs);

   bool add_constraint (equiv_class_id lhs_ec_id,
 		       enum tree_code op,
 		       equiv_class_id rhs_ec_id);

   bool get_equiv_class_by_sid (svalue_id sid, equiv_class_id *out) const;
   equiv_class_id get_or_add_equiv_class (svalue_id sid);
   tristate eval_condition (equiv_class_id lhs,
 			   enum tree_code op,
 			   equiv_class_id rhs);
   tristate eval_condition (svalue_id lhs,
 			   enum tree_code op,
 			   svalue_id rhs);

   void purge (const purge_criteria &p, purge_stats *stats);

   void remap_svalue_ids (const svalue_id_map &map);

   void canonicalize (unsigned num_svalue_ids);

   static void merge (const constraint_manager &cm_a,
 		     const constraint_manager &cm_b,
 		     constraint_manager *out,
 		     const model_merger &merger);

   void for_each_fact (fact_visitor *) const;

   void validate () const;

   auto_delete_vec<equiv_class> m_equiv_classes;
   auto_vec<constraint> m_constraints;

  private:
   static void clean_merger_input (const constraint_manager &cm_in,
 				  const one_way_svalue_id_map &map_sid_to_m,
 				  constraint_manager *out);

   void add_constraint_internal (equiv_class_id lhs_id,
 				enum constraint_op c_op,
 				equiv_class_id rhs_id);
 };

 } // namespace ana

 #endif /* GCC_ANALYZER_CONSTRAINT_MANAGER_H */
	/* Tracking equivalence classes and constraints at a point on an execution path.
	Copyright (C) 2019-2020 Free Software Foundation, Inc.
	Contributed by David Malcolm <dmalcolm@redhat.com>.

	This file is part of GCC.

	GCC is free software; you can redistribute it and/or modify it
	under the terms of the GNU General Public License as published by
	the Free Software Foundation; either version 3, or (at your option)
	any later version.

	GCC is distributed in the hope that it will be useful, but
	WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with GCC; see the file COPYING3. If not see
	<http://www.gnu.org/licenses/>. */

	#ifndef GCC_ANALYZER_CONSTRAINT_MANAGER_H
	#define GCC_ANALYZER_CONSTRAINT_MANAGER_H

	namespace ana {

	class constraint_manager;

	/* Abstract base class for specifying how state should be purged. */

	class purge_criteria
	{
	public:
	virtual ~purge_criteria () {}
	virtual bool should_purge_p (svalue_id sid) const = 0;
	};

	/* An equivalence class within a constraint manager: a set of
	svalue_ids that are known to all be equal to each other,
	together with an optional tree constant that they are equal to. */

	class equiv_class
	{
	public:
	equiv_class ();
	equiv_class (const equiv_class &other);

	hashval_t hash () const;
	bool operator== (const equiv_class &other);

	void add (svalue_id sid, const constraint_manager &cm);
	bool del (svalue_id sid);

	tree get_any_constant () const { return m_constant; }

	svalue_id get_representative () const;

	void remap_svalue_ids (const svalue_id_map &map);

	void canonicalize ();

	void print (pretty_printer *pp) const;

	/* An equivalence class can contain multiple constants (e.g. multiple
	different zeroes, for different types); these are just for the last
	constant added. */
	tree m_constant;
	svalue_id m_cst_sid;

	// TODO: should this be a set rather than a vec?
	auto_vec<svalue_id> m_vars;
	};

	/* The various kinds of constraint. */

	enum constraint_op
	{
	CONSTRAINT_NE,
	CONSTRAINT_LT,
	CONSTRAINT_LE
	};

	const char *constraint_op_code (enum constraint_op c_op);

	/* An ID for an equiv_class within a constraint_manager. Internally, this
	is an index into a vector of equiv_class * within the constraint_manager. */

	class equiv_class_id
	{
	public:
	static equiv_class_id null () { return equiv_class_id (-1); }

	equiv_class_id (unsigned idx) : m_idx (idx) {}
	const equiv_class &get_obj (const constraint_manager &cm) const;
	equiv_class &get_obj (constraint_manager &cm) const;

	bool operator== (const equiv_class_id &other) const
	{
	return m_idx == other.m_idx;
	}
	bool operator!= (const equiv_class_id &other) const
	{
	return m_idx != other.m_idx;
	}

	bool null_p () const { return m_idx == -1; }

	static equiv_class_id from_int (int idx) { return equiv_class_id (idx); }
	int as_int () const { return m_idx; }

	void print (pretty_printer *pp) const;

	void update_for_removal (equiv_class_id other)
	{
	if (m_idx > other.m_idx)
	m_idx--;
	}

	int m_idx;
	};

	/* A relationship between two equivalence classes in a constraint_manager. */

	class constraint
	{
	public:
	constraint (equiv_class_id lhs, enum constraint_op c_op, equiv_class_id rhs)
	: m_lhs (lhs), m_op (c_op), m_rhs (rhs)
	{
	gcc_assert (!lhs.null_p ());
	gcc_assert (!rhs.null_p ());
	}

	void print (pretty_printer *pp, const constraint_manager &cm) const;

	hashval_t hash () const;
	bool operator== (const constraint &other) const;

	/* Is this an ordering, rather than a "!=". */
	bool is_ordering_p () const
	{
	return m_op != CONSTRAINT_NE;
	}

	equiv_class_id m_lhs;
	enum constraint_op m_op;
	equiv_class_id m_rhs;
	};

	/* An abstract base class for use with constraint_manager::for_each_fact. */

	class fact_visitor
	{
	public:
	virtual ~fact_visitor () {}
	virtual void on_fact (svalue_id lhs, enum tree_code, svalue_id rhs) = 0;
	};

	/* A collection of equivalence classes and constraints on them.

	Given N svalues, this can be thought of as representing a subset of
	N-dimensional space. When we call add_constraint,
	we are effectively taking an intersection with that constraint. */

	class constraint_manager
	{
	public:
	constraint_manager () {}
	constraint_manager (const constraint_manager &other);
	virtual ~constraint_manager () {}

	virtual constraint_manager clone (region_model ) const = 0;
	virtual tree maybe_get_constant (svalue_id sid) const = 0;
	virtual svalue_id get_sid_for_constant (tree cst) const = 0;
	virtual int get_num_svalues () const = 0;

	constraint_manager& operator= (const constraint_manager &other);

	hashval_t hash () const;
	bool operator== (const constraint_manager &other) const;
	bool operator!= (const constraint_manager &other) const
	{
	return !(*this == other);
	}

	void print (pretty_printer *pp) const;
	void dump_to_pp (pretty_printer *pp) const;
	void dump (FILE *fp) const;
	void dump () const;

	const equiv_class &get_equiv_class_by_index (unsigned idx) const
	{
	return *m_equiv_classes[idx];
	}
	equiv_class &get_equiv_class_by_index (unsigned idx)
	{
	return *m_equiv_classes[idx];
	}

	equiv_class &get_equiv_class (svalue_id sid)
	{
	equiv_class_id ec_id = get_or_add_equiv_class (sid);
	return ec_id.get_obj (*this);
	}

	bool add_constraint (svalue_id lhs, enum tree_code op, svalue_id rhs);

	bool add_constraint (equiv_class_id lhs_ec_id,
	enum tree_code op,
	equiv_class_id rhs_ec_id);

	bool get_equiv_class_by_sid (svalue_id sid, equiv_class_id *out) const;
	equiv_class_id get_or_add_equiv_class (svalue_id sid);
	tristate eval_condition (equiv_class_id lhs,
	enum tree_code op,
	equiv_class_id rhs);
	tristate eval_condition (svalue_id lhs,
	enum tree_code op,
	svalue_id rhs);

	void purge (const purge_criteria &p, purge_stats *stats);

	void remap_svalue_ids (const svalue_id_map &map);

	void canonicalize (unsigned num_svalue_ids);

	static void merge (const constraint_manager &cm_a,
	const constraint_manager &cm_b,
	constraint_manager *out,
	const model_merger &merger);

	void for_each_fact (fact_visitor *) const;

	void validate () const;

	auto_delete_vec<equiv_class> m_equiv_classes;
	auto_vec<constraint> m_constraints;

	private:
	static void clean_merger_input (const constraint_manager &cm_in,
	const one_way_svalue_id_map &map_sid_to_m,
	constraint_manager *out);

	void add_constraint_internal (equiv_class_id lhs_id,
	enum constraint_op c_op,
	equiv_class_id rhs_id);
	};

	} // namespace ana

	#endif /* GCC_ANALYZER_CONSTRAINT_MANAGER_H */