gcc/gimple-range-gori.h - gcc - Git at Google

 /* Header file for gimple range GORI structures.
    Copyright (C) 2017-2021 Free Software Foundation, Inc.
    Contributed by Andrew MacLeod <amacleod@redhat.com>
    and Aldy Hernandez <aldyh@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_GIMPLE_RANGE_GORI_H
 #define GCC_GIMPLE_RANGE_GORI_H

 // RANGE_DEF_CHAIN is used to determine which SSA names in a block can
 // have range information calculated for them, and what the
 // dependencies on each other are.

 class range_def_chain
 {
 public:
   range_def_chain ();
   ~range_def_chain ();
   tree depend1 (tree name) const;
   tree depend2 (tree name) const;
   bool in_chain_p (tree name, tree def);
   bool chain_import_p (tree name, tree import);
   void register_dependency (tree name, tree ssa1, basic_block bb = NULL);
   void dump (FILE *f, basic_block bb, const char *prefix = NULL);
 protected:
   bool has_def_chain (tree name);
   bool def_chain_in_bitmap_p (tree name, bitmap b);
   void add_def_chain_to_bitmap (bitmap b, tree name);
   bitmap get_def_chain (tree name);
   bitmap get_imports (tree name);
   bitmap_obstack m_bitmaps;
 private:
   struct rdc {
    tree ssa1;		// First direct dependency
    tree ssa2;		// Second direct dependency
    bitmap bm;		// All dependencies
    bitmap m_import;
   };
   vec<rdc> m_def_chain;	// SSA_NAME : def chain components.
   void set_import (struct rdc &data, tree imp, bitmap b);
   int m_logical_depth;
 };

 // Return the first direct dependency for NAME, if there is one.
 // Direct dependencies are those which occur on the defintion statement.
 // Only the first 2 such names are cached.

 inline tree
 range_def_chain::depend1 (tree name) const
 {
   unsigned v = SSA_NAME_VERSION (name);
   if (v >= m_def_chain.length ())
     return NULL_TREE;
   return m_def_chain[v].ssa1;
 }

 // Return the second direct dependency for NAME, if there is one.

 inline tree
 range_def_chain::depend2 (tree name) const
 {
   unsigned v = SSA_NAME_VERSION (name);
   if (v >= m_def_chain.length ())
     return NULL_TREE;
   return m_def_chain[v].ssa2;
 }

 // GORI_MAP is used to accumulate what SSA names in a block can
 // generate range information, and provides tools for the block ranger
 // to enable it to efficiently calculate these ranges.

 class gori_map : public range_def_chain
 {
 public:
   gori_map ();
   ~gori_map ();

   bool is_export_p (tree name, basic_block bb = NULL);
   bool is_import_p (tree name, basic_block bb);
   bitmap exports (basic_block bb);
   bitmap imports (basic_block bb);
   void set_range_invariant (tree name);

   void dump (FILE *f);
   void dump (FILE *f, basic_block bb, bool verbose = true);
 private:
   vec<bitmap> m_outgoing;	// BB: Outgoing ranges calculatable on edges
   vec<bitmap> m_incoming;	// BB: Incoming ranges which can affect exports.
   bitmap m_maybe_variant;	// Names which might have outgoing ranges.
   void maybe_add_gori (tree name, basic_block bb);
   void calculate_gori (basic_block bb);
 };


 // This class is used to determine which SSA_NAMES can have ranges
 // calculated for them on outgoing edges from basic blocks.  This represents
 // ONLY the effect of the basic block edge->src on a range.
 //
 // There are 2 primary entry points:
 //
 // has_edge_range_p (tree name, edge e)
 //   returns true if the outgoing edge *may* be able to produce range
 //   information for ssa_name NAME on edge E.
 //   FALSE is returned if this edge does not affect the range of NAME.
 //   if no edge is specified, return TRUE if name may have a value calculated
 //   on *ANY* edge that has been seen.  FALSE indicates that the global value
 //   is applicable everywhere that has been processed.
 //
 // outgoing_edge_range_p (irange &range, edge e, tree name)
 //   Actually does the calculation of RANGE for name on E
 //   This represents application of whatever static range effect edge E
 //   may have on NAME, not any cumulative effect.

 // There are also some internal APIs
 //
 // ssa_range_in_bb ()  is an internal routine which is used to start any
 // calculation chain using SSA_NAMES which come from outside the block. ie
 //      a_2 = b_4 - 8
 //      if (a_2 < 30)
 // on the true edge, a_2 is known to be [0, 29]
 // b_4 can be calculated as [8, 37]
 // during this calculation, b_4 is considered an "import" and ssa_range_in_bb
 // is queried for a starting range which is used in the calculation.
 // A default value of VARYING provides the raw static info for the edge.
 //
 // If there is any known range for b_4 coming into this block, it can refine
 // the results.  This allows for cascading results to be propogated.
 // if b_4 is [100, 200] on entry to the block, feeds into the calculation
 // of a_2 = [92, 192], and finally on the true edge the range would be
 // an empty range [] because it is not possible for the true edge to be taken.
 //
 // expr_range_in_bb is simply a wrapper which calls ssa_range_in_bb for
 // SSA_NAMES and otherwise simply calculates the range of the expression.
 //
 // The constructor takes a flag value to use on edges to check for the
 // NON_EXECUTABLE_EDGE property.  The zero default means no flag is checked.
 // All value requests from NON_EXECUTABLE_EDGE edges are returned UNDEFINED.
 //
 // The remaining routines are internal use only.

 class gori_compute : public gori_map
 {
 public:
   gori_compute (int not_executable_flag = 0);
   bool outgoing_edge_range_p (irange &r, edge e, tree name, range_query &q);
   bool has_edge_range_p (tree name, edge e = NULL);
   void dump (FILE *f);
 private:
   bool may_recompute_p (tree name, edge e = NULL);
   bool compute_operand_range (irange &r, gimple *stmt, const irange &lhs,
 			      tree name, class fur_source &src);
   bool compute_operand_range_switch (irange &r, gswitch *s, const irange &lhs,
 				     tree name, fur_source &src);
   bool compute_operand1_range (irange &r, gimple *stmt, const irange &lhs,
 			       tree name, fur_source &src);
   bool compute_operand2_range (irange &r, gimple *stmt, const irange &lhs,
 			       tree name, fur_source &src);
   bool compute_operand1_and_operand2_range (irange &r, gimple *stmt,
 					    const irange &lhs, tree name,
 					    fur_source &src);
   void compute_logical_operands (irange &true_range, irange &false_range,
 				 gimple *stmt, const irange &lhs,
 				 tree name, fur_source &src, tree op,
 				 bool op_in_chain);
   bool logical_combine (irange &r, enum tree_code code, const irange &lhs,
 			const irange &op1_true, const irange &op1_false,
 			const irange &op2_true, const irange &op2_false);
   int_range<2> m_bool_zero;	// Boolean false cached.
   int_range<2> m_bool_one;	// Boolean true cached.

   gimple_outgoing_range outgoing;	// Edge values for COND_EXPR & SWITCH_EXPR.
   range_tracer tracer;
   int m_not_executable_flag;
 };

 // These routines provide a GIMPLE interface to the range-ops code.
 extern bool gimple_range_calc_op1 (irange &r, const gimple *s,
 				   const irange &lhs_range);
 extern bool gimple_range_calc_op1 (irange &r, const gimple *s,
 				   const irange &lhs_range,
 				   const irange &op2_range);
 extern bool gimple_range_calc_op2 (irange &r, const gimple *s,
 				   const irange &lhs_range,
 				   const irange &op1_range);

 // For each name that is an import into BB's exports..
 #define FOR_EACH_GORI_IMPORT_NAME(gori, bb, name)			\
   for (gori_export_iterator iter ((gori).imports ((bb)));	\
        ((name) = iter.get_name ());				\
        iter.next ())

 // For each name possibly exported from block BB.
 #define FOR_EACH_GORI_EXPORT_NAME(gori, bb, name)		\
   for (gori_export_iterator iter ((gori).exports ((bb)));	\
        ((name) = iter.get_name ());				\
        iter.next ())

 // Used to assist with iterating over the GORI export list in various ways
 class gori_export_iterator {
 public:
   gori_export_iterator (bitmap b);
   void next ();
   tree get_name ();
 protected:
   bitmap bm;
   bitmap_iterator bi;
   unsigned y;
 };

 #endif // GCC_GIMPLE_RANGE_GORI_H
	/* Header file for gimple range GORI structures.
	Copyright (C) 2017-2021 Free Software Foundation, Inc.
	Contributed by Andrew MacLeod <amacleod@redhat.com>
	and Aldy Hernandez <aldyh@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_GIMPLE_RANGE_GORI_H
	#define GCC_GIMPLE_RANGE_GORI_H

	// RANGE_DEF_CHAIN is used to determine which SSA names in a block can
	// have range information calculated for them, and what the
	// dependencies on each other are.

	class range_def_chain
	{
	public:
	range_def_chain ();
	~range_def_chain ();
	tree depend1 (tree name) const;
	tree depend2 (tree name) const;
	bool in_chain_p (tree name, tree def);
	bool chain_import_p (tree name, tree import);
	void register_dependency (tree name, tree ssa1, basic_block bb = NULL);
	void dump (FILE f, basic_block bb, const char prefix = NULL);
	protected:
	bool has_def_chain (tree name);
	bool def_chain_in_bitmap_p (tree name, bitmap b);
	void add_def_chain_to_bitmap (bitmap b, tree name);
	bitmap get_def_chain (tree name);
	bitmap get_imports (tree name);
	bitmap_obstack m_bitmaps;
	private:
	struct rdc {
	tree ssa1; // First direct dependency
	tree ssa2; // Second direct dependency
	bitmap bm; // All dependencies
	bitmap m_import;
	};
	vec<rdc> m_def_chain; // SSA_NAME : def chain components.
	void set_import (struct rdc &data, tree imp, bitmap b);
	int m_logical_depth;
	};

	// Return the first direct dependency for NAME, if there is one.
	// Direct dependencies are those which occur on the defintion statement.
	// Only the first 2 such names are cached.

	inline tree
	range_def_chain::depend1 (tree name) const
	{
	unsigned v = SSA_NAME_VERSION (name);
	if (v >= m_def_chain.length ())
	return NULL_TREE;
	return m_def_chain[v].ssa1;
	}

	// Return the second direct dependency for NAME, if there is one.

	inline tree
	range_def_chain::depend2 (tree name) const
	{
	unsigned v = SSA_NAME_VERSION (name);
	if (v >= m_def_chain.length ())
	return NULL_TREE;
	return m_def_chain[v].ssa2;
	}

	// GORI_MAP is used to accumulate what SSA names in a block can
	// generate range information, and provides tools for the block ranger
	// to enable it to efficiently calculate these ranges.

	class gori_map : public range_def_chain
	{
	public:
	gori_map ();
	~gori_map ();

	bool is_export_p (tree name, basic_block bb = NULL);
	bool is_import_p (tree name, basic_block bb);
	bitmap exports (basic_block bb);
	bitmap imports (basic_block bb);
	void set_range_invariant (tree name);

	void dump (FILE *f);
	void dump (FILE *f, basic_block bb, bool verbose = true);
	private:
	vec<bitmap> m_outgoing; // BB: Outgoing ranges calculatable on edges
	vec<bitmap> m_incoming; // BB: Incoming ranges which can affect exports.
	bitmap m_maybe_variant; // Names which might have outgoing ranges.
	void maybe_add_gori (tree name, basic_block bb);
	void calculate_gori (basic_block bb);
	};


	// This class is used to determine which SSA_NAMES can have ranges
	// calculated for them on outgoing edges from basic blocks. This represents
	// ONLY the effect of the basic block edge->src on a range.
	//
	// There are 2 primary entry points:
	//
	// has_edge_range_p (tree name, edge e)
	// returns true if the outgoing edge may be able to produce range
	// information for ssa_name NAME on edge E.
	// FALSE is returned if this edge does not affect the range of NAME.
	// if no edge is specified, return TRUE if name may have a value calculated
	// on ANY edge that has been seen. FALSE indicates that the global value
	// is applicable everywhere that has been processed.
	//
	// outgoing_edge_range_p (irange &range, edge e, tree name)
	// Actually does the calculation of RANGE for name on E
	// This represents application of whatever static range effect edge E
	// may have on NAME, not any cumulative effect.

	// There are also some internal APIs
	//
	// ssa_range_in_bb () is an internal routine which is used to start any
	// calculation chain using SSA_NAMES which come from outside the block. ie
	// a_2 = b_4 - 8
	// if (a_2 < 30)
	// on the true edge, a_2 is known to be [0, 29]
	// b_4 can be calculated as [8, 37]
	// during this calculation, b_4 is considered an "import" and ssa_range_in_bb
	// is queried for a starting range which is used in the calculation.
	// A default value of VARYING provides the raw static info for the edge.
	//
	// If there is any known range for b_4 coming into this block, it can refine
	// the results. This allows for cascading results to be propogated.
	// if b_4 is [100, 200] on entry to the block, feeds into the calculation
	// of a_2 = [92, 192], and finally on the true edge the range would be
	// an empty range [] because it is not possible for the true edge to be taken.
	//
	// expr_range_in_bb is simply a wrapper which calls ssa_range_in_bb for
	// SSA_NAMES and otherwise simply calculates the range of the expression.
	//
	// The constructor takes a flag value to use on edges to check for the
	// NON_EXECUTABLE_EDGE property. The zero default means no flag is checked.
	// All value requests from NON_EXECUTABLE_EDGE edges are returned UNDEFINED.
	//
	// The remaining routines are internal use only.

	class gori_compute : public gori_map
	{
	public:
	gori_compute (int not_executable_flag = 0);
	bool outgoing_edge_range_p (irange &r, edge e, tree name, range_query &q);
	bool has_edge_range_p (tree name, edge e = NULL);
	void dump (FILE *f);
	private:
	bool may_recompute_p (tree name, edge e = NULL);
	bool compute_operand_range (irange &r, gimple *stmt, const irange &lhs,
	tree name, class fur_source &src);
	bool compute_operand_range_switch (irange &r, gswitch *s, const irange &lhs,
	tree name, fur_source &src);
	bool compute_operand1_range (irange &r, gimple *stmt, const irange &lhs,
	tree name, fur_source &src);
	bool compute_operand2_range (irange &r, gimple *stmt, const irange &lhs,
	tree name, fur_source &src);
	bool compute_operand1_and_operand2_range (irange &r, gimple *stmt,
	const irange &lhs, tree name,
	fur_source &src);
	void compute_logical_operands (irange &true_range, irange &false_range,
	gimple *stmt, const irange &lhs,
	tree name, fur_source &src, tree op,
	bool op_in_chain);
	bool logical_combine (irange &r, enum tree_code code, const irange &lhs,
	const irange &op1_true, const irange &op1_false,
	const irange &op2_true, const irange &op2_false);
	int_range<2> m_bool_zero; // Boolean false cached.
	int_range<2> m_bool_one; // Boolean true cached.

	gimple_outgoing_range outgoing; // Edge values for COND_EXPR & SWITCH_EXPR.
	range_tracer tracer;
	int m_not_executable_flag;
	};

	// These routines provide a GIMPLE interface to the range-ops code.
	extern bool gimple_range_calc_op1 (irange &r, const gimple *s,
	const irange &lhs_range);
	extern bool gimple_range_calc_op1 (irange &r, const gimple *s,
	const irange &lhs_range,
	const irange &op2_range);
	extern bool gimple_range_calc_op2 (irange &r, const gimple *s,
	const irange &lhs_range,
	const irange &op1_range);

	// For each name that is an import into BB's exports..
	#define FOR_EACH_GORI_IMPORT_NAME(gori, bb, name) \
	for (gori_export_iterator iter ((gori).imports ((bb))); \
	((name) = iter.get_name ()); \
	iter.next ())

	// For each name possibly exported from block BB.
	#define FOR_EACH_GORI_EXPORT_NAME(gori, bb, name) \
	for (gori_export_iterator iter ((gori).exports ((bb))); \
	((name) = iter.get_name ()); \
	iter.next ())

	// Used to assist with iterating over the GORI export list in various ways
	class gori_export_iterator {
	public:
	gori_export_iterator (bitmap b);
	void next ();
	tree get_name ();
	protected:
	bitmap bm;
	bitmap_iterator bi;
	unsigned y;
	};

	#endif // GCC_GIMPLE_RANGE_GORI_H