gcc/ipa-fnsummary.h - gcc - Git at Google

 /* IPA function body analysis.
    Copyright (C) 2003-2020 Free Software Foundation, Inc.
    Contributed by Jan Hubicka

 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_IPA_SUMMARY_H
 #define GCC_IPA_SUMMARY_H

 #include "sreal.h"
 #include "ipa-predicate.h"


 /* Hints are reasons why IPA heuristics should prefer specializing given
    function.  They are represented as bitmap of the following values.  */
 enum ipa_hints_vals {
   /* When specialization turns indirect call into a direct call,
      it is good idea to do so.  */
   INLINE_HINT_indirect_call = 1,
   /* Inlining may make loop iterations or loop stride known.  It is good idea
      to do so because it enables loop optimizations.  */
   INLINE_HINT_loop_iterations = 2,
   INLINE_HINT_loop_stride = 4,
   /* Inlining within same strongly connected component of callgraph is often
      a loss due to increased stack frame usage and prologue setup costs.  */
   INLINE_HINT_same_scc = 8,
   /* Inlining functions in strongly connected component is not such a great
      win.  */
   INLINE_HINT_in_scc = 16,
   /* If function is declared inline by user, it may be good idea to inline
      it.  Set by simple_edge_hints in ipa-inline-analysis.c.  */
   INLINE_HINT_declared_inline = 32,
   /* Programs are usually still organized for non-LTO compilation and thus
      if functions are in different modules, inlining may not be so important.
      Set by simple_edge_hints in ipa-inline-analysis.c.   */
   INLINE_HINT_cross_module = 64,
   /* We know that the callee is hot by profile.  */
   INLINE_HINT_known_hot = 128
 };

 typedef int ipa_hints;

 /* Simple description of whether a memory load or a condition refers to a load
    from an aggregate and if so, how and where from in the aggregate.
    Individual fields have the same meaning like fields with the same name in
    struct condition.  */

 struct agg_position_info
 {
   HOST_WIDE_INT offset;
   bool agg_contents;
   bool by_ref;
 };

 /* Representation of function body size and time depending on the call
    context.  We keep simple array of record, every containing of predicate
    and time/size to account.  */
 class GTY(()) size_time_entry
 {
 public:
   /* Predicate for code to be executed.  */
   predicate exec_predicate;
   /* Predicate for value to be constant and optimized out in a specialized copy.
      When deciding on specialization this makes it possible to see how much
      the executed code paths will simplify.  */
   predicate nonconst_predicate;
   int size;
   sreal GTY((skip)) time;
 };

 /* Summary about function and stack frame sizes.  We keep this info
    for inline clones and also for WPA streaming. For this reason this is not
    part of ipa_fn_summary which exists only for offline functions.  */
 class ipa_size_summary
 {
 public:
   /* Estimated stack frame consumption by the function.  */
   HOST_WIDE_INT estimated_self_stack_size;
   /* Size of the function body.  */
   int self_size;
   /* Estimated size of the function after inlining.  */
   int size;

   ipa_size_summary ()
   : estimated_self_stack_size (0), self_size (0), size (0)
   {
   }
 };

 /* Function inlining information.  */
 class GTY(()) ipa_fn_summary
 {
 public:
   /* Keep all field empty so summary dumping works during its computation.
      This is useful for debugging.  */
   ipa_fn_summary ()
     : min_size (0),
       inlinable (false), single_caller (false),
       fp_expressions (false), estimated_stack_size (false),
       time (0), conds (NULL),
       size_time_table (NULL), call_size_time_table (NULL), loop_iterations (NULL),
       loop_stride (NULL), growth (0), scc_no (0)
   {
   }

   /* Copy constructor.  */
   ipa_fn_summary (const ipa_fn_summary &s)
     : min_size (s.min_size),
     inlinable (s.inlinable), single_caller (s.single_caller),
     fp_expressions (s.fp_expressions),
     estimated_stack_size (s.estimated_stack_size),
     time (s.time), conds (s.conds), size_time_table (s.size_time_table),
     call_size_time_table (NULL),
     loop_iterations (s.loop_iterations), loop_stride (s.loop_stride),
     growth (s.growth), scc_no (s.scc_no)
   {}

   /* Default constructor.  */
   ~ipa_fn_summary ();

   /* Information about the function body itself.  */

   /* Minimal size increase after inlining.  */
   int min_size;

   /* False when there something makes inlining impossible (such as va_arg).  */
   unsigned inlinable : 1;
   /* True wen there is only one caller of the function before small function
      inlining.  */
   unsigned int single_caller : 1;
   /* True if function contains any floating point expressions.  */
   unsigned int fp_expressions : 1;

   /* Information about function that will result after applying all the
      inline decisions present in the callgraph.  Generally kept up to
      date only for functions that are not inline clones. */

   /* Estimated stack frame consumption by the function.  */
   HOST_WIDE_INT estimated_stack_size;
   /* Estimated runtime of function after inlining.  */
   sreal GTY((skip)) time;

   /* Conditional size/time information.  The summaries are being
      merged during inlining.  */
   conditions conds;
   /* Normal code is accounted in size_time_table, while calls are
      accounted in call_size_time_table.  This is because calls
      are often adjusted by IPA optimizations and thus this summary
      is generated from call summary information when needed.  */
   vec<size_time_entry, va_gc> *size_time_table;
   vec<size_time_entry, va_gc> *call_size_time_table;

   /* Predicate on when some loop in the function becomes to have known
      bounds.   */
   predicate * GTY((skip)) loop_iterations;
   /* Predicate on when some loop in the function becomes to have known
      stride.   */
   predicate * GTY((skip)) loop_stride;
   /* Estimated growth for inlining all copies of the function before start
      of small functions inlining.
      This value will get out of date as the callers are duplicated, but
      using up-to-date value in the badness metric mean a lot of extra
      expenses.  */
   int growth;
   /* Number of SCC on the beginning of inlining process.  */
   int scc_no;

   /* Record time and size under given predicates.  */
   void account_size_time (int, sreal, const predicate &, const predicate &,
 		  	  bool call = false);

   /* We keep values scaled up, so fractional sizes can be accounted.  */
   static const int size_scale = 2;
   /* Maximal size of size_time_table before we start to be conservative.  */
   static const int max_size_time_table_size = 256;
 };

 class GTY((user)) ipa_fn_summary_t:
   public fast_function_summary <ipa_fn_summary *, va_gc>
 {
 public:
   ipa_fn_summary_t (symbol_table *symtab):
     fast_function_summary <ipa_fn_summary *, va_gc> (symtab) {}

   static ipa_fn_summary_t *create_ggc (symbol_table *symtab)
   {
     class ipa_fn_summary_t *summary
       = new (ggc_alloc_no_dtor<ipa_fn_summary_t> ()) ipa_fn_summary_t (symtab);
     summary->disable_insertion_hook ();
     return summary;
   }

   /* Remove ipa_fn_summary for all callees of NODE.  */
   void remove_callees (cgraph_node *node);

   virtual void insert (cgraph_node *, ipa_fn_summary *);
   virtual void remove (cgraph_node *node, ipa_fn_summary *)
   {
     remove_callees (node);
   }

   virtual void duplicate (cgraph_node *src, cgraph_node *dst,
 			  ipa_fn_summary *src_data, ipa_fn_summary *dst_data);
 };

 extern GTY(()) fast_function_summary <ipa_fn_summary *, va_gc>
   *ipa_fn_summaries;

 class ipa_size_summary_t:
   public fast_function_summary <ipa_size_summary *, va_heap>
 {
 public:
   ipa_size_summary_t (symbol_table *symtab):
     fast_function_summary <ipa_size_summary *, va_heap> (symtab)
   {
     disable_insertion_hook ();
   }

   virtual void duplicate (cgraph_node *, cgraph_node *,
 			  ipa_size_summary *src_data,
 			  ipa_size_summary *dst_data)
   {
     *dst_data = *src_data;
   }
 };
 extern fast_function_summary <ipa_size_summary *, va_heap>
   *ipa_size_summaries;

 /* Information kept about callgraph edges.  */
 class ipa_call_summary
 {
 public:
   /* Keep all field empty so summary dumping works during its computation.
      This is useful for debugging.  */
   ipa_call_summary ()
     : predicate (NULL), param (vNULL), call_stmt_size (0), call_stmt_time (0),
       loop_depth (0), is_return_callee_uncaptured (false)
     {
     }

   /* Copy constructor.  */
   ipa_call_summary (const ipa_call_summary &s):
     predicate (s.predicate), param (s.param), call_stmt_size (s.call_stmt_size),
     call_stmt_time (s.call_stmt_time), loop_depth (s.loop_depth),
     is_return_callee_uncaptured (s.is_return_callee_uncaptured)
   {
   }

   /* Default destructor.  */
   ~ipa_call_summary ();

   class predicate *predicate;
   /* Vector indexed by parameters.  */
   vec<inline_param_summary> param;
   /* Estimated size and time of the call statement.  */
   int call_stmt_size;
   int call_stmt_time;
   /* Depth of loop nest, 0 means no nesting.  */
   unsigned int loop_depth;
   /* Indicates whether the caller returns the value of it's callee.  */
   bool is_return_callee_uncaptured;
 };

 class ipa_call_summary_t: public fast_call_summary <ipa_call_summary *, va_heap>
 {
 public:
   ipa_call_summary_t (symbol_table *symtab):
     fast_call_summary <ipa_call_summary *, va_heap> (symtab) {}

   /* Hook that is called by summary when an edge is duplicated.  */
   virtual void duplicate (cgraph_edge *src, cgraph_edge *dst,
 			  ipa_call_summary *src_data,
 			  ipa_call_summary *dst_data);
 };

 /* This object describe a context of call.  That is a summary of known
    information about its parameters.  Main purpose of this context is
    to give more realistic estimations of function runtime, size and
    inline hints.  */
 class ipa_call_context
 {
 public:
   ipa_call_context (cgraph_node *node,
       		    clause_t possible_truths,
 		    clause_t nonspec_possible_truths,
 		    vec<tree> known_vals,
 		    vec<ipa_polymorphic_call_context> known_contexts,
 		    vec<ipa_agg_value_set> known_aggs,
 		    vec<inline_param_summary> m_inline_param_summary);
   ipa_call_context ()
   : m_node(NULL)
   {
   }
   void estimate_size_and_time (int *ret_size, int *ret_min_size,
 			       sreal *ret_time,
 			       sreal *ret_nonspecialized_time,
 			       ipa_hints *ret_hints);
   void duplicate_from (const ipa_call_context &ctx);
   void release (bool all = false);
   bool equal_to (const ipa_call_context &);
   bool exists_p ()
   {
     return m_node != NULL;
   }
 private:
   /* Called function.  */
   cgraph_node *m_node;
   /* Clause describing what predicate conditionals can be satisfied
      in this context if function is inlined/specialized.  */
   clause_t m_possible_truths;
   /* Clause describing what predicate conditionals can be satisfied
      in this context if function is kept offline.  */
   clause_t m_nonspec_possible_truths;
   /* Inline summary maintains info about change probabilities.  */
   vec<inline_param_summary> m_inline_param_summary;

   /* The following is used only to resolve indirect calls.  */

   /* Vector describing known values of parameters.  */
   vec<tree> m_known_vals;
   /* Vector describing known polymorphic call contexts.  */
   vec<ipa_polymorphic_call_context> m_known_contexts;
   /* Vector describing known aggregate values.  */
   vec<ipa_agg_value_set> m_known_aggs;
 };

 extern fast_call_summary <ipa_call_summary *, va_heap> *ipa_call_summaries;

 /* In ipa-fnsummary.c  */
 void ipa_debug_fn_summary (struct cgraph_node *);
 void ipa_dump_fn_summaries (FILE *f);
 void ipa_dump_fn_summary (FILE *f, struct cgraph_node *node);
 void ipa_dump_hints (FILE *f, ipa_hints);
 void ipa_free_fn_summary (void);
 void ipa_free_size_summary (void);
 void inline_analyze_function (struct cgraph_node *node);
 void estimate_ipcp_clone_size_and_time (struct cgraph_node *,
 					vec<tree>,
 					vec<ipa_polymorphic_call_context>,
 					vec<ipa_agg_value_set>,
 					int *, sreal *, sreal *,
 				        ipa_hints *);
 void ipa_merge_fn_summary_after_inlining (struct cgraph_edge *edge);
 void ipa_update_overall_fn_summary (struct cgraph_node *node, bool reset = true);
 void compute_fn_summary (struct cgraph_node *, bool);


 void evaluate_properties_for_edge (struct cgraph_edge *e,
 	       		           bool inline_p,
 				   clause_t *clause_ptr,
 				   clause_t *nonspec_clause_ptr,
 				   vec<tree> *known_vals_ptr,
 				   vec<ipa_polymorphic_call_context>
 				   *known_contexts_ptr,
 				   vec<ipa_agg_value_set> *);

 void ipa_fnsummary_c_finalize (void);
 HOST_WIDE_INT ipa_get_stack_frame_offset (struct cgraph_node *node);
 void ipa_remove_from_growth_caches (struct cgraph_edge *edge);

 /* Return true if EDGE is a cross module call.  */

 static inline bool
 cross_module_call_p (struct cgraph_edge *edge)
 {
   /* Here we do not want to walk to alias target becuase ICF may create
      cross-unit aliases.  */
   if (edge->caller->unit_id == edge->callee->unit_id)
     return false;
   /* If the call is to a (former) comdat function or s symbol with mutiple
      extern inline definitions then treat is as in-module call.  */
   if (edge->callee->merged_extern_inline || edge->callee->merged_comdat
       || DECL_COMDAT (edge->callee->decl))
     return false;
   return true;
 }

 #endif /* GCC_IPA_FNSUMMARY_H */
	/* IPA function body analysis.
	Copyright (C) 2003-2020 Free Software Foundation, Inc.
	Contributed by Jan Hubicka

	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_IPA_SUMMARY_H
	#define GCC_IPA_SUMMARY_H

	#include "sreal.h"
	#include "ipa-predicate.h"


	/* Hints are reasons why IPA heuristics should prefer specializing given
	function. They are represented as bitmap of the following values. */
	enum ipa_hints_vals {
	/* When specialization turns indirect call into a direct call,
	it is good idea to do so. */
	INLINE_HINT_indirect_call = 1,
	/* Inlining may make loop iterations or loop stride known. It is good idea
	to do so because it enables loop optimizations. */
	INLINE_HINT_loop_iterations = 2,
	INLINE_HINT_loop_stride = 4,
	/* Inlining within same strongly connected component of callgraph is often
	a loss due to increased stack frame usage and prologue setup costs. */
	INLINE_HINT_same_scc = 8,
	/* Inlining functions in strongly connected component is not such a great
	win. */
	INLINE_HINT_in_scc = 16,
	/* If function is declared inline by user, it may be good idea to inline
	it. Set by simple_edge_hints in ipa-inline-analysis.c. */
	INLINE_HINT_declared_inline = 32,
	/* Programs are usually still organized for non-LTO compilation and thus
	if functions are in different modules, inlining may not be so important.
	Set by simple_edge_hints in ipa-inline-analysis.c. */
	INLINE_HINT_cross_module = 64,
	/* We know that the callee is hot by profile. */
	INLINE_HINT_known_hot = 128
	};

	typedef int ipa_hints;

	/* Simple description of whether a memory load or a condition refers to a load
	from an aggregate and if so, how and where from in the aggregate.
	Individual fields have the same meaning like fields with the same name in
	struct condition. */

	struct agg_position_info
	{
	HOST_WIDE_INT offset;
	bool agg_contents;
	bool by_ref;
	};

	/* Representation of function body size and time depending on the call
	context. We keep simple array of record, every containing of predicate
	and time/size to account. */
	class GTY(()) size_time_entry
	{
	public:
	/* Predicate for code to be executed. */
	predicate exec_predicate;
	/* Predicate for value to be constant and optimized out in a specialized copy.
	When deciding on specialization this makes it possible to see how much
	the executed code paths will simplify. */
	predicate nonconst_predicate;
	int size;
	sreal GTY((skip)) time;
	};

	/* Summary about function and stack frame sizes. We keep this info
	for inline clones and also for WPA streaming. For this reason this is not
	part of ipa_fn_summary which exists only for offline functions. */
	class ipa_size_summary
	{
	public:
	/* Estimated stack frame consumption by the function. */
	HOST_WIDE_INT estimated_self_stack_size;
	/* Size of the function body. */
	int self_size;
	/* Estimated size of the function after inlining. */
	int size;

	ipa_size_summary ()
	: estimated_self_stack_size (0), self_size (0), size (0)
	{
	}
	};

	/* Function inlining information. */
	class GTY(()) ipa_fn_summary
	{
	public:
	/* Keep all field empty so summary dumping works during its computation.
	This is useful for debugging. */
	ipa_fn_summary ()
	: min_size (0),
	inlinable (false), single_caller (false),
	fp_expressions (false), estimated_stack_size (false),
	time (0), conds (NULL),
	size_time_table (NULL), call_size_time_table (NULL), loop_iterations (NULL),
	loop_stride (NULL), growth (0), scc_no (0)
	{
	}

	/* Copy constructor. */
	ipa_fn_summary (const ipa_fn_summary &s)
	: min_size (s.min_size),
	inlinable (s.inlinable), single_caller (s.single_caller),
	fp_expressions (s.fp_expressions),
	estimated_stack_size (s.estimated_stack_size),
	time (s.time), conds (s.conds), size_time_table (s.size_time_table),
	call_size_time_table (NULL),
	loop_iterations (s.loop_iterations), loop_stride (s.loop_stride),
	growth (s.growth), scc_no (s.scc_no)
	{}

	/* Default constructor. */
	~ipa_fn_summary ();

	/* Information about the function body itself. */

	/* Minimal size increase after inlining. */
	int min_size;

	/* False when there something makes inlining impossible (such as va_arg). */
	unsigned inlinable : 1;
	/* True wen there is only one caller of the function before small function
	inlining. */
	unsigned int single_caller : 1;
	/* True if function contains any floating point expressions. */
	unsigned int fp_expressions : 1;

	/* Information about function that will result after applying all the
	inline decisions present in the callgraph. Generally kept up to
	date only for functions that are not inline clones. */

	/* Estimated stack frame consumption by the function. */
	HOST_WIDE_INT estimated_stack_size;
	/* Estimated runtime of function after inlining. */
	sreal GTY((skip)) time;

	/* Conditional size/time information. The summaries are being
	merged during inlining. */
	conditions conds;
	/* Normal code is accounted in size_time_table, while calls are
	accounted in call_size_time_table. This is because calls
	are often adjusted by IPA optimizations and thus this summary
	is generated from call summary information when needed. */
	vec<size_time_entry, va_gc> *size_time_table;
	vec<size_time_entry, va_gc> *call_size_time_table;

	/* Predicate on when some loop in the function becomes to have known
	bounds. */
	predicate * GTY((skip)) loop_iterations;
	/* Predicate on when some loop in the function becomes to have known
	stride. */
	predicate * GTY((skip)) loop_stride;
	/* Estimated growth for inlining all copies of the function before start
	of small functions inlining.
	This value will get out of date as the callers are duplicated, but
	using up-to-date value in the badness metric mean a lot of extra
	expenses. */
	int growth;
	/* Number of SCC on the beginning of inlining process. */
	int scc_no;

	/* Record time and size under given predicates. */
	void account_size_time (int, sreal, const predicate &, const predicate &,
	bool call = false);

	/* We keep values scaled up, so fractional sizes can be accounted. */
	static const int size_scale = 2;
	/* Maximal size of size_time_table before we start to be conservative. */
	static const int max_size_time_table_size = 256;
	};

	class GTY((user)) ipa_fn_summary_t:
	public fast_function_summary <ipa_fn_summary *, va_gc>
	{
	public:
	ipa_fn_summary_t (symbol_table *symtab):
	fast_function_summary <ipa_fn_summary *, va_gc> (symtab) {}

	static ipa_fn_summary_t create_ggc (symbol_table symtab)
	{
	class ipa_fn_summary_t *summary
	= new (ggc_alloc_no_dtor<ipa_fn_summary_t> ()) ipa_fn_summary_t (symtab);
	summary->disable_insertion_hook ();
	return summary;
	}

	/* Remove ipa_fn_summary for all callees of NODE. */
	void remove_callees (cgraph_node *node);

	virtual void insert (cgraph_node , ipa_fn_summary );
	virtual void remove (cgraph_node node, ipa_fn_summary )
	{
	remove_callees (node);
	}

	virtual void duplicate (cgraph_node src, cgraph_node dst,
	ipa_fn_summary src_data, ipa_fn_summary dst_data);
	};

	extern GTY(()) fast_function_summary <ipa_fn_summary *, va_gc>
	*ipa_fn_summaries;

	class ipa_size_summary_t:
	public fast_function_summary <ipa_size_summary *, va_heap>
	{
	public:
	ipa_size_summary_t (symbol_table *symtab):
	fast_function_summary <ipa_size_summary *, va_heap> (symtab)
	{
	disable_insertion_hook ();
	}

	virtual void duplicate (cgraph_node , cgraph_node ,
	ipa_size_summary *src_data,
	ipa_size_summary *dst_data)
	{
	dst_data = src_data;
	}
	};
	extern fast_function_summary <ipa_size_summary *, va_heap>
	*ipa_size_summaries;

	/* Information kept about callgraph edges. */
	class ipa_call_summary
	{
	public:
	/* Keep all field empty so summary dumping works during its computation.
	This is useful for debugging. */
	ipa_call_summary ()
	: predicate (NULL), param (vNULL), call_stmt_size (0), call_stmt_time (0),
	loop_depth (0), is_return_callee_uncaptured (false)
	{
	}

	/* Copy constructor. */
	ipa_call_summary (const ipa_call_summary &s):
	predicate (s.predicate), param (s.param), call_stmt_size (s.call_stmt_size),
	call_stmt_time (s.call_stmt_time), loop_depth (s.loop_depth),
	is_return_callee_uncaptured (s.is_return_callee_uncaptured)
	{
	}

	/* Default destructor. */
	~ipa_call_summary ();

	class predicate *predicate;
	/* Vector indexed by parameters. */
	vec<inline_param_summary> param;
	/* Estimated size and time of the call statement. */
	int call_stmt_size;
	int call_stmt_time;
	/* Depth of loop nest, 0 means no nesting. */
	unsigned int loop_depth;
	/* Indicates whether the caller returns the value of it's callee. */
	bool is_return_callee_uncaptured;
	};

	class ipa_call_summary_t: public fast_call_summary <ipa_call_summary *, va_heap>
	{
	public:
	ipa_call_summary_t (symbol_table *symtab):
	fast_call_summary <ipa_call_summary *, va_heap> (symtab) {}

	/* Hook that is called by summary when an edge is duplicated. */
	virtual void duplicate (cgraph_edge src, cgraph_edge dst,
	ipa_call_summary *src_data,
	ipa_call_summary *dst_data);
	};

	/* This object describe a context of call. That is a summary of known
	information about its parameters. Main purpose of this context is
	to give more realistic estimations of function runtime, size and
	inline hints. */
	class ipa_call_context
	{
	public:
	ipa_call_context (cgraph_node *node,
	clause_t possible_truths,
	clause_t nonspec_possible_truths,
	vec<tree> known_vals,
	vec<ipa_polymorphic_call_context> known_contexts,
	vec<ipa_agg_value_set> known_aggs,
	vec<inline_param_summary> m_inline_param_summary);
	ipa_call_context ()
	: m_node(NULL)
	{
	}
	void estimate_size_and_time (int ret_size, int ret_min_size,
	sreal *ret_time,
	sreal *ret_nonspecialized_time,
	ipa_hints *ret_hints);
	void duplicate_from (const ipa_call_context &ctx);
	void release (bool all = false);
	bool equal_to (const ipa_call_context &);
	bool exists_p ()
	{
	return m_node != NULL;
	}
	private:
	/* Called function. */
	cgraph_node *m_node;
	/* Clause describing what predicate conditionals can be satisfied
	in this context if function is inlined/specialized. */
	clause_t m_possible_truths;
	/* Clause describing what predicate conditionals can be satisfied
	in this context if function is kept offline. */
	clause_t m_nonspec_possible_truths;
	/* Inline summary maintains info about change probabilities. */
	vec<inline_param_summary> m_inline_param_summary;

	/* The following is used only to resolve indirect calls. */

	/* Vector describing known values of parameters. */
	vec<tree> m_known_vals;
	/* Vector describing known polymorphic call contexts. */
	vec<ipa_polymorphic_call_context> m_known_contexts;
	/* Vector describing known aggregate values. */
	vec<ipa_agg_value_set> m_known_aggs;
	};

	extern fast_call_summary <ipa_call_summary , va_heap> ipa_call_summaries;

	/* In ipa-fnsummary.c */
	void ipa_debug_fn_summary (struct cgraph_node *);
	void ipa_dump_fn_summaries (FILE *f);
	void ipa_dump_fn_summary (FILE f, struct cgraph_node node);
	void ipa_dump_hints (FILE *f, ipa_hints);
	void ipa_free_fn_summary (void);
	void ipa_free_size_summary (void);
	void inline_analyze_function (struct cgraph_node *node);
	void estimate_ipcp_clone_size_and_time (struct cgraph_node *,
	vec<tree>,
	vec<ipa_polymorphic_call_context>,
	vec<ipa_agg_value_set>,
	int , sreal , sreal *,
	ipa_hints *);
	void ipa_merge_fn_summary_after_inlining (struct cgraph_edge *edge);
	void ipa_update_overall_fn_summary (struct cgraph_node *node, bool reset = true);
	void compute_fn_summary (struct cgraph_node *, bool);


	void evaluate_properties_for_edge (struct cgraph_edge *e,
	bool inline_p,
	clause_t *clause_ptr,
	clause_t *nonspec_clause_ptr,
	vec<tree> *known_vals_ptr,
	vec<ipa_polymorphic_call_context>
	*known_contexts_ptr,
	vec<ipa_agg_value_set> *);

	void ipa_fnsummary_c_finalize (void);
	HOST_WIDE_INT ipa_get_stack_frame_offset (struct cgraph_node *node);
	void ipa_remove_from_growth_caches (struct cgraph_edge *edge);

	/* Return true if EDGE is a cross module call. */

	static inline bool
	cross_module_call_p (struct cgraph_edge *edge)
	{
	/* Here we do not want to walk to alias target becuase ICF may create
	cross-unit aliases. */
	if (edge->caller->unit_id == edge->callee->unit_id)
	return false;
	/* If the call is to a (former) comdat function or s symbol with mutiple
	extern inline definitions then treat is as in-module call. */
	if (edge->callee->merged_extern_inline \|\| edge->callee->merged_comdat
	\|\| DECL_COMDAT (edge->callee->decl))
	return false;
	return true;
	}

	#endif /* GCC_IPA_FNSUMMARY_H */