gcc/analyzer/call-string.h - gcc - Git at Google

 /* Call stacks at program points.
    Copyright (C) 2019-2023 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_CALL_STRING_H
 #define GCC_ANALYZER_CALL_STRING_H

 namespace ana {

 class supergraph;
 class supernode;
 class call_superedge;
 class return_superedge;


 /* A string of return_superedge pointers, representing a call stack
    at a program point.

    This is used to ensure that we generate interprocedurally valid paths
    i.e. that we return to the same callsite that called us.

    The class stores returning calls ( which may be represented by a
    returning superedge ). We do so because this is what we need to compare
    against.

    Instances of call_string are consolidated by the region_model_manager,
    which effectively owns them: it owns the root/empty call_string, and each
    call_string instance tracks its children, lazily creating them on demand,
    so that the call_string instances form a tree-like hierarchy in memory.  */

 class call_string
 {
 public:
   /* A struct representing an element in the call_string.

    Each element represents a path from m_callee to m_caller which represents
    returning from function.  */

   struct element_t
   {
     element_t (const supernode *caller, const supernode *callee)
     :  m_caller (caller), m_callee (callee)
     {
     }

     bool operator== (const element_t &other) const;
     bool operator!= (const element_t &other) const;

     /* Accessors */
     function *get_caller_function () const;
     function *get_callee_function () const;

     const supernode *m_caller;
     const supernode *m_callee;
   };

   void print (pretty_printer *pp) const;

   json::value *to_json () const;

   bool empty_p () const { return m_elements.is_empty (); }

   const call_string *push_call (const supergraph &sg,
 				const call_superedge *sedge) const;

   const call_string *push_call (const supernode *src,
 				const supernode *dest) const;
   const call_string *get_parent () const { return m_parent; }

   int calc_recursion_depth () const;

   static int cmp (const call_string &a,
 		  const call_string &b);

   static int cmp_ptr_ptr (const void *, const void *);

   /* Accessors */

   const supernode *get_callee_node () const;
   const supernode *get_caller_node () const;
   unsigned length () const { return m_elements.length (); }
   element_t operator[] (unsigned idx) const
   {
     return m_elements[idx];
   }
   const element_t &get_top_of_stack () const
   {
     gcc_assert (m_elements.length () > 0);
     return m_elements[m_elements.length () - 1];
   }

   int count_occurrences_of_function (function *) const;

   void validate () const;

 private:
   struct hashmap_traits_t
   {
     typedef element_t key_type;
     typedef const call_string *value_type;

     static const bool maybe_mx = false;
     static inline hashval_t hash (const key_type &k)
     {
       inchash::hash hstate;
       hstate.add_ptr (k.m_caller);
       hstate.add_ptr (k.m_callee);
       return hstate.end ();
     }
     static inline bool equal_keys (const key_type &k1, const key_type &k2)
     {
       return k1 == k2;
     }
     template <typename T> static inline void remove (T &entry)
     {
       entry.m_key = element_t (NULL, NULL);
     }
     static const bool empty_zero_p = true;
     template <typename T> static inline bool is_empty (const T &entry)
     {
       return entry.m_key.m_caller == NULL;
     }
     template <typename T> static inline bool is_deleted (const T &entry)
     {
       return entry.m_key.m_caller == reinterpret_cast<const supernode *> (1);
     }
     template <typename T> static inline void mark_empty (T &entry)
     {
       entry.m_key = element_t (NULL, NULL);
       entry.m_value = NULL;
     }
     template <typename T> static inline void mark_deleted (T &entry)
     {
       entry.m_key.m_caller = reinterpret_cast<const supernode *> (1);
     }
   };

   friend class region_model_manager;

   DISABLE_COPY_AND_ASSIGN (call_string);

   call_string ();
   call_string (const call_string &parent, const element_t &to_push);
   ~call_string ();

   void recursive_log (logger *logger) const;

   const call_string *m_parent;
   auto_vec<element_t> m_elements;
   mutable hash_map<element_t, const call_string *, hashmap_traits_t> m_children;
 };

 } // namespace ana

 #endif /* GCC_ANALYZER_CALL_STRING_H */
	/* Call stacks at program points.
	Copyright (C) 2019-2023 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_CALL_STRING_H
	#define GCC_ANALYZER_CALL_STRING_H

	namespace ana {

	class supergraph;
	class supernode;
	class call_superedge;
	class return_superedge;


	/* A string of return_superedge pointers, representing a call stack
	at a program point.

	This is used to ensure that we generate interprocedurally valid paths
	i.e. that we return to the same callsite that called us.

	The class stores returning calls ( which may be represented by a
	returning superedge ). We do so because this is what we need to compare
	against.

	Instances of call_string are consolidated by the region_model_manager,
	which effectively owns them: it owns the root/empty call_string, and each
	call_string instance tracks its children, lazily creating them on demand,
	so that the call_string instances form a tree-like hierarchy in memory. */

	class call_string
	{
	public:
	/* A struct representing an element in the call_string.

	Each element represents a path from m_callee to m_caller which represents
	returning from function. */

	struct element_t
	{
	element_t (const supernode caller, const supernode callee)
	: m_caller (caller), m_callee (callee)
	{
	}

	bool operator== (const element_t &other) const;
	bool operator!= (const element_t &other) const;

	/* Accessors */
	function *get_caller_function () const;
	function *get_callee_function () const;

	const supernode *m_caller;
	const supernode *m_callee;
	};

	void print (pretty_printer *pp) const;

	json::value *to_json () const;

	bool empty_p () const { return m_elements.is_empty (); }

	const call_string *push_call (const supergraph &sg,
	const call_superedge *sedge) const;

	const call_string push_call (const supernode src,
	const supernode *dest) const;
	const call_string *get_parent () const { return m_parent; }

	int calc_recursion_depth () const;

	static int cmp (const call_string &a,
	const call_string &b);

	static int cmp_ptr_ptr (const void , const void );

	/* Accessors */

	const supernode *get_callee_node () const;
	const supernode *get_caller_node () const;
	unsigned length () const { return m_elements.length (); }
	element_t operator[] (unsigned idx) const
	{
	return m_elements[idx];
	}
	const element_t &get_top_of_stack () const
	{
	gcc_assert (m_elements.length () > 0);
	return m_elements[m_elements.length () - 1];
	}

	int count_occurrences_of_function (function *) const;

	void validate () const;

	private:
	struct hashmap_traits_t
	{
	typedef element_t key_type;
	typedef const call_string *value_type;

	static const bool maybe_mx = false;
	static inline hashval_t hash (const key_type &k)
	{
	inchash::hash hstate;
	hstate.add_ptr (k.m_caller);
	hstate.add_ptr (k.m_callee);
	return hstate.end ();
	}
	static inline bool equal_keys (const key_type &k1, const key_type &k2)
	{
	return k1 == k2;
	}
	template <typename T> static inline void remove (T &entry)
	{
	entry.m_key = element_t (NULL, NULL);
	}
	static const bool empty_zero_p = true;
	template <typename T> static inline bool is_empty (const T &entry)
	{
	return entry.m_key.m_caller == NULL;
	}
	template <typename T> static inline bool is_deleted (const T &entry)
	{
	return entry.m_key.m_caller == reinterpret_cast<const supernode *> (1);
	}
	template <typename T> static inline void mark_empty (T &entry)
	{
	entry.m_key = element_t (NULL, NULL);
	entry.m_value = NULL;
	}
	template <typename T> static inline void mark_deleted (T &entry)
	{
	entry.m_key.m_caller = reinterpret_cast<const supernode *> (1);
	}
	};

	friend class region_model_manager;

	DISABLE_COPY_AND_ASSIGN (call_string);

	call_string ();
	call_string (const call_string &parent, const element_t &to_push);
	~call_string ();

	void recursive_log (logger *logger) const;

	const call_string *m_parent;
	auto_vec<element_t> m_elements;
	mutable hash_map<element_t, const call_string *, hashmap_traits_t> m_children;
	};

	} // namespace ana

	#endif /* GCC_ANALYZER_CALL_STRING_H */