gcc/rtl-ssa/functions.h - gcc - Git at Google

 // Function-related RTL SSA classes                                 -*- C++ -*-
 // Copyright (C) 2020-2021 Free Software Foundation, Inc.
 //
 // 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/>.

 namespace rtl_ssa {

 // SSA-related information about a function.  It contains three levels
 // of information, each in reverse postorder:
 //
 // - a list of extended basic blocks
 // - a list of basic blocks
 // - a list of instructions
 //
 // It also maintains a list of definitions of memory, and a list of
 // definitions of each register.
 //
 // See doc/rtl.texi for more details about the way this information
 // is organized and how changes to it are made.
 class function_info
 {
   // The default obstack alignment takes long double into account.
   // Since we have no use for that here, and since we allocate many
   // relatively small objects, it's better to specify an alignment
   // explicitly.  The allocation routines assert that the alignment
   // is enough for the objects being allocated.
   //
   // Because various structures use pointer_mux, we need at least 2 bytes
   // of alignment.
   static const size_t obstack_alignment = sizeof (void *);

 public:
   // Construct SSA form for function FN.
   function_info (function *fn);
   ~function_info ();

   // Return a list of all the extended basic blocks in the function, in reverse
   // postorder.  The list includes the entry and exit blocks.
   iterator_range<ebb_iterator> ebbs () const;

   // Like ebbs (), but in the reverse order.
   iterator_range<reverse_ebb_iterator> reverse_ebbs () const;

   // Return a list of all the basic blocks in the function, in reverse
   // postorder.  The list includes the entry and exit blocks.
   iterator_range<bb_iterator> bbs () const;

   // Like bbs (), but in the reverse order.
   iterator_range<reverse_bb_iterator> reverse_bbs () const;

   // Return the SSA information for the basic block with index INDEX.
   bb_info *bb (unsigned int index) const { return m_bbs[index]; }

   // Return the SSA information for CFG_BB.
   bb_info *bb (basic_block cfg_bb) const { return m_bbs[cfg_bb->index]; }

   // Return a list of all the instructions in the function, in reverse
   // postorder.  The list includes both real and artificial instructions.
   //
   // Iterations over the list will pick up any new instructions that are
   // inserted after the iterator's current instruction.
   iterator_range<any_insn_iterator> all_insns () const;

   // Like all_insns (), but in the reverse order.
   //
   // Iterations over the list will pick up any new instructions that are
   // inserted before the iterator's current instruction.
   iterator_range<reverse_any_insn_iterator> reverse_all_insns () const;

   // Like all_insns (), but without the debug instructions.
   iterator_range<nondebug_insn_iterator> nondebug_insns () const;

   // Like reverse_all_insns (), but without the debug instructions.
   iterator_range<reverse_nondebug_insn_iterator>
     reverse_nondebug_insns () const;

   // Return the first and last instructions in insns ().
   insn_info *first_insn () const { return m_first_insn; }
   insn_info *last_insn () const { return m_last_insn; }

   // Return a list of all definitions of memory, in reverse postorder.
   // This includes both real stores by instructions and artificial
   // definitions by things like phi nodes.
   iterator_range<def_iterator> mem_defs () const;

   // Return a list of all definitions of register REGNO, in reverse postorder.
   // This includes both real stores by instructions and artificial
   // definitions by things like phi nodes.
   iterator_range<def_iterator> reg_defs (unsigned int regno) const;

   // Check if all uses of register REGNO are either unconditionally undefined
   // or use the same single dominating definition.  Return the definition
   // if so, otherwise return null.
   set_info *single_dominating_def (unsigned int regno) const;

   // Look for a definition of RESOURCE at INSN.  Return the result of the
   // search as a def_lookup; see the comments there for more details.
   def_lookup find_def (resource_info resource, insn_info *insn);

   // Return an RAII object that owns all temporary RTL SSA memory
   // allocated during a change attempt.  The object should remain in
   // scope until the change has been aborted or successfully completed.
   obstack_watermark new_change_attempt () { return &m_temp_obstack; }

   // Make a best attempt to check whether the values used by USES are
   // available on entry to BB, without solving a full dataflow problem.
   // If all the values are already live on entry to BB or can be made
   // available there, return a use_array that describes the uses as
   // if they occured at the start of BB.  These uses are purely temporary,
   // and will not become permanent unless applied using change_insns.
   //
   // If the operation fails, return an invalid use_array.
   //
   // WATERMARK is a watermark returned by new_change_attempt ().
   // WILL_BE_DEBUG_USES is true if the returned use_array will be
   // used only for debug instructions.
   use_array make_uses_available (obstack_watermark &watermark,
 				 use_array uses, bb_info *bb,
 				 bool will_be_debug_uses);

   // If CHANGE doesn't already clobber REGNO, try to add such a clobber,
   // limiting the movement range in order to make the clobber valid.
   // When determining whether REGNO is live, ignore accesses made by an
   // instruction I if IGNORE (I) is true.  The caller then assumes the
   // responsibility of ensuring that CHANGE and I are placed in a valid order.
   //
   // Return true on success.  Leave CHANGE unmodified when returning false.
   //
   // WATERMARK is a watermark returned by new_change_attempt ().
   template<typename IgnorePredicate>
   bool add_regno_clobber (obstack_watermark &watermark, insn_change &change,
 			  unsigned int regno, IgnorePredicate ignore);

   // Return true if change_insns will be able to perform the changes
   // described by CHANGES.
   bool verify_insn_changes (array_slice<insn_change *const> changes);

   // Perform all the changes in CHANGES, keeping the instructions in the
   // order specified by the CHANGES array.  On return, the SSA information
   // remains up-to-date.  The same is true for instruction-level DF
   // information, although the block-level DF information might be
   // marked dirty.
   void change_insns (array_slice<insn_change *> changes);

   // Like change_insns, but for a single change CHANGE.
   void change_insn (insn_change &change);

   // If the changes that have been made to instructions require updates
   // to the CFG, perform those updates now.  Return true if something changed.
   // If it did:
   //
   // - The SSA information is now invalid and needs to be recomputed.
   //
   // - Dominance information is no longer available (in either direction).
   //
   // - The caller will need to call cleanup_cfg at some point.
   //
   // ??? We could probably update the SSA information for simple updates,
   // but currently nothing would benefit.  These late CFG changes are
   // relatively rare anyway, since gimple optimisers should remove most
   // unnecessary control flow.
   bool perform_pending_updates ();

   // Print the contents of the function to PP.
   void print (pretty_printer *pp) const;

 private:
   class bb_phi_info;
   class build_info;
   class bb_walker;

   // Return an RAII object that owns all objects allocated by
   // allocate_temp during its lifetime.
   obstack_watermark temp_watermark () { return &m_temp_obstack; }

   template<typename T, typename... Ts>
   T *allocate (Ts... args);

   template<typename T, typename... Ts>
   T *allocate_temp (Ts... args);

   access_array temp_access_array (access_array accesses);

   clobber_group *need_clobber_group (clobber_info *);
   def_node *need_def_node (def_info *);
   def_splay_tree need_def_splay_tree (def_info *);

   use_info *make_use_available (use_info *, bb_info *, bool);
   def_array insert_temp_clobber (obstack_watermark &, insn_info *,
 				 unsigned int, def_array);

   void insert_def_before (def_info *, def_info *);
   void insert_def_after (def_info *, def_info *);
   void remove_def_from_list (def_info *);

   void add_clobber (clobber_info *, clobber_group *);
   void remove_clobber (clobber_info *, clobber_group *);
   void prepend_clobber_to_group (clobber_info *, clobber_group *);
   void append_clobber_to_group (clobber_info *, clobber_group *);
   void merge_clobber_groups (clobber_info *, clobber_info *,
 			     def_info *);
   clobber_info *split_clobber_group (clobber_group *, insn_info *);

   void append_def (def_info *);
   void add_def (def_info *);
   void remove_def (def_info *);

   void need_use_splay_tree (set_info *);

   static void insert_use_before (use_info *, use_info *);
   static void insert_use_after (use_info *, use_info *);

   void add_use (use_info *);
   void remove_use (use_info *);

   insn_info::order_node *need_order_node (insn_info *);

   void add_insn_after (insn_info *, insn_info *);
   void append_insn (insn_info *);
   void remove_insn (insn_info *);

   insn_info *append_artificial_insn (bb_info *, rtx_insn * = nullptr);

   void start_insn_accesses ();
   void finish_insn_accesses (insn_info *);

   use_info *create_reg_use (build_info &, insn_info *, resource_info);
   void record_use (build_info &, insn_info *, rtx_obj_reference);
   void record_call_clobbers (build_info &, insn_info *, rtx_call_insn *);
   void record_def (build_info &, insn_info *, rtx_obj_reference);
   void add_insn_to_block (build_info &, rtx_insn *);

   void add_reg_unused_notes (insn_info *);

   void add_live_out_use (bb_info *, set_info *);
   set_info *live_out_value (bb_info *, set_info *);

   void append_phi (ebb_info *, phi_info *);
   void remove_phi (phi_info *);
   void delete_phi (phi_info *);
   void replace_phi (phi_info *, set_info *);
   phi_info *create_phi (ebb_info *, resource_info, access_info **,
 			unsigned int);
   phi_info *create_degenerate_phi (ebb_info *, set_info *);

   bb_info *create_bb_info (basic_block);
   void append_bb (bb_info *);

   insn_info *add_placeholder_after (insn_info *);
   void possibly_queue_changes (insn_change &);
   void finalize_new_accesses (insn_change &);
   void apply_changes_to_insn (insn_change &);

   void init_function_data ();
   void calculate_potential_phi_regs (build_info &);
   void place_phis (build_info &);
   void create_ebbs (build_info &);
   void add_entry_block_defs (build_info &);
   void calculate_ebb_live_in_for_debug (build_info &);
   void add_phi_nodes (build_info &);
   void add_artificial_accesses (build_info &, df_ref_flags);
   void add_block_contents (build_info &);
   void record_block_live_out (build_info &);
   void start_block (build_info &, bb_info *);
   void end_block (build_info &, bb_info *);
   void populate_phi_inputs (build_info &);
   void process_all_blocks ();

   void simplify_phi_setup (phi_info *, set_info **, bitmap);
   void simplify_phi_propagate (phi_info *, set_info **, bitmap, bitmap);
   void simplify_phis ();

   // The function that this object describes.
   function *m_fn;

   // The lowest (negative) in-use artificial insn uid minus one.
   int m_next_artificial_uid;

   // The highest in-use phi uid plus one.
   unsigned int m_next_phi_uid;

   // The highest in-use register number plus one.
   unsigned int m_num_regs;

   // M_DEFS[R] is the first definition of register R - 1 in a reverse
   // postorder traversal of the function, or null if the function has
   // no definition of R.  Applying last () gives the last definition of R.
   //
   // M_DEFS[0] is for memory; MEM_REGNO + 1 == 0.
   auto_vec<def_info *> m_defs;

   // M_BBS[BI] gives the SSA information about the block with index BI.
   auto_vec<bb_info *> m_bbs;

   // An obstack used to allocate the main RTL SSA information.
   obstack m_obstack;

   // An obstack used for temporary work, such as while building up a list
   // of possible instruction changes.
   obstack m_temp_obstack;

   // The start of each obstack, so that all memory in them can be freed.
   char *m_obstack_start;
   char *m_temp_obstack_start;

   // The entry and exit blocks.
   bb_info *m_first_bb;
   bb_info *m_last_bb;

   // The first and last instructions in a reverse postorder traversal
   // of the function.
   insn_info *m_first_insn;
   insn_info *m_last_insn;

   // The last nondebug instruction in the list of instructions.
   // This is only different from m_last_insn when building the initial
   // SSA information; after that, the last instruction is always a
   // BB end instruction.
   insn_info *m_last_nondebug_insn;

   // Temporary working state when building up lists of definitions and uses.
   // Keeping them around should reduce the number of unnecessary reallocations.
   auto_vec<access_info *> m_temp_defs;
   auto_vec<access_info *> m_temp_uses;

   // A list of phis that are no longer in use.  Their uids are still unique
   // and so can be recycled.
   phi_info *m_free_phis;

   // A list of instructions that have been changed in ways that need
   // further processing later, such as removing dead instructions or
   // altering the CFG.
   auto_vec<insn_info *> m_queued_insn_updates;

   // The INSN_UIDs of all instructions in M_QUEUED_INSN_UPDATES.
   auto_bitmap m_queued_insn_update_uids;

   // A basic_block is in this bitmap if we need to call purge_dead_edges
   // on it.  As with M_QUEUED_INSN_UPDATES, these updates are queued until
   // a convenient point.
   auto_bitmap m_need_to_purge_dead_edges;
 };

 void pp_function (pretty_printer *, const function_info *);
 }

 void dump (FILE *, const rtl_ssa::function_info *);

 void DEBUG_FUNCTION debug (const rtl_ssa::function_info *);
	// Function-related RTL SSA classes -- C++ --
	// Copyright (C) 2020-2021 Free Software Foundation, Inc.
	//
	// 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/>.

	namespace rtl_ssa {

	// SSA-related information about a function. It contains three levels
	// of information, each in reverse postorder:
	//
	// - a list of extended basic blocks
	// - a list of basic blocks
	// - a list of instructions
	//
	// It also maintains a list of definitions of memory, and a list of
	// definitions of each register.
	//
	// See doc/rtl.texi for more details about the way this information
	// is organized and how changes to it are made.
	class function_info
	{
	// The default obstack alignment takes long double into account.
	// Since we have no use for that here, and since we allocate many
	// relatively small objects, it's better to specify an alignment
	// explicitly. The allocation routines assert that the alignment
	// is enough for the objects being allocated.
	//
	// Because various structures use pointer_mux, we need at least 2 bytes
	// of alignment.
	static const size_t obstack_alignment = sizeof (void *);

	public:
	// Construct SSA form for function FN.
	function_info (function *fn);
	~function_info ();

	// Return a list of all the extended basic blocks in the function, in reverse
	// postorder. The list includes the entry and exit blocks.
	iterator_range<ebb_iterator> ebbs () const;

	// Like ebbs (), but in the reverse order.
	iterator_range<reverse_ebb_iterator> reverse_ebbs () const;

	// Return a list of all the basic blocks in the function, in reverse
	// postorder. The list includes the entry and exit blocks.
	iterator_range<bb_iterator> bbs () const;

	// Like bbs (), but in the reverse order.
	iterator_range<reverse_bb_iterator> reverse_bbs () const;

	// Return the SSA information for the basic block with index INDEX.
	bb_info *bb (unsigned int index) const { return m_bbs[index]; }

	// Return the SSA information for CFG_BB.
	bb_info *bb (basic_block cfg_bb) const { return m_bbs[cfg_bb->index]; }

	// Return a list of all the instructions in the function, in reverse
	// postorder. The list includes both real and artificial instructions.
	//
	// Iterations over the list will pick up any new instructions that are
	// inserted after the iterator's current instruction.
	iterator_range<any_insn_iterator> all_insns () const;

	// Like all_insns (), but in the reverse order.
	//
	// Iterations over the list will pick up any new instructions that are
	// inserted before the iterator's current instruction.
	iterator_range<reverse_any_insn_iterator> reverse_all_insns () const;

	// Like all_insns (), but without the debug instructions.
	iterator_range<nondebug_insn_iterator> nondebug_insns () const;

	// Like reverse_all_insns (), but without the debug instructions.
	iterator_range<reverse_nondebug_insn_iterator>
	reverse_nondebug_insns () const;

	// Return the first and last instructions in insns ().
	insn_info *first_insn () const { return m_first_insn; }
	insn_info *last_insn () const { return m_last_insn; }

	// Return a list of all definitions of memory, in reverse postorder.
	// This includes both real stores by instructions and artificial
	// definitions by things like phi nodes.
	iterator_range<def_iterator> mem_defs () const;

	// Return a list of all definitions of register REGNO, in reverse postorder.
	// This includes both real stores by instructions and artificial
	// definitions by things like phi nodes.
	iterator_range<def_iterator> reg_defs (unsigned int regno) const;

	// Check if all uses of register REGNO are either unconditionally undefined
	// or use the same single dominating definition. Return the definition
	// if so, otherwise return null.
	set_info *single_dominating_def (unsigned int regno) const;

	// Look for a definition of RESOURCE at INSN. Return the result of the
	// search as a def_lookup; see the comments there for more details.
	def_lookup find_def (resource_info resource, insn_info *insn);

	// Return an RAII object that owns all temporary RTL SSA memory
	// allocated during a change attempt. The object should remain in
	// scope until the change has been aborted or successfully completed.
	obstack_watermark new_change_attempt () { return &m_temp_obstack; }

	// Make a best attempt to check whether the values used by USES are
	// available on entry to BB, without solving a full dataflow problem.
	// If all the values are already live on entry to BB or can be made
	// available there, return a use_array that describes the uses as
	// if they occured at the start of BB. These uses are purely temporary,
	// and will not become permanent unless applied using change_insns.
	//
	// If the operation fails, return an invalid use_array.
	//
	// WATERMARK is a watermark returned by new_change_attempt ().
	// WILL_BE_DEBUG_USES is true if the returned use_array will be
	// used only for debug instructions.
	use_array make_uses_available (obstack_watermark &watermark,
	use_array uses, bb_info *bb,
	bool will_be_debug_uses);

	// If CHANGE doesn't already clobber REGNO, try to add such a clobber,
	// limiting the movement range in order to make the clobber valid.
	// When determining whether REGNO is live, ignore accesses made by an
	// instruction I if IGNORE (I) is true. The caller then assumes the
	// responsibility of ensuring that CHANGE and I are placed in a valid order.
	//
	// Return true on success. Leave CHANGE unmodified when returning false.
	//
	// WATERMARK is a watermark returned by new_change_attempt ().
	template<typename IgnorePredicate>
	bool add_regno_clobber (obstack_watermark &watermark, insn_change &change,
	unsigned int regno, IgnorePredicate ignore);

	// Return true if change_insns will be able to perform the changes
	// described by CHANGES.
	bool verify_insn_changes (array_slice<insn_change *const> changes);

	// Perform all the changes in CHANGES, keeping the instructions in the
	// order specified by the CHANGES array. On return, the SSA information
	// remains up-to-date. The same is true for instruction-level DF
	// information, although the block-level DF information might be
	// marked dirty.
	void change_insns (array_slice<insn_change *> changes);

	// Like change_insns, but for a single change CHANGE.
	void change_insn (insn_change &change);

	// If the changes that have been made to instructions require updates
	// to the CFG, perform those updates now. Return true if something changed.
	// If it did:
	//
	// - The SSA information is now invalid and needs to be recomputed.
	//
	// - Dominance information is no longer available (in either direction).
	//
	// - The caller will need to call cleanup_cfg at some point.
	//
	// ??? We could probably update the SSA information for simple updates,
	// but currently nothing would benefit. These late CFG changes are
	// relatively rare anyway, since gimple optimisers should remove most
	// unnecessary control flow.
	bool perform_pending_updates ();

	// Print the contents of the function to PP.
	void print (pretty_printer *pp) const;

	private:
	class bb_phi_info;
	class build_info;
	class bb_walker;

	// Return an RAII object that owns all objects allocated by
	// allocate_temp during its lifetime.
	obstack_watermark temp_watermark () { return &m_temp_obstack; }

	template<typename T, typename... Ts>
	T *allocate (Ts... args);

	template<typename T, typename... Ts>
	T *allocate_temp (Ts... args);

	access_array temp_access_array (access_array accesses);

	clobber_group need_clobber_group (clobber_info );
	def_node need_def_node (def_info );
	def_splay_tree need_def_splay_tree (def_info *);

	use_info make_use_available (use_info , bb_info *, bool);
	def_array insert_temp_clobber (obstack_watermark &, insn_info *,
	unsigned int, def_array);

	void insert_def_before (def_info , def_info );
	void insert_def_after (def_info , def_info );
	void remove_def_from_list (def_info *);

	void add_clobber (clobber_info , clobber_group );
	void remove_clobber (clobber_info , clobber_group );
	void prepend_clobber_to_group (clobber_info , clobber_group );
	void append_clobber_to_group (clobber_info , clobber_group );
	void merge_clobber_groups (clobber_info , clobber_info ,
	def_info *);
	clobber_info split_clobber_group (clobber_group , insn_info *);

	void append_def (def_info *);
	void add_def (def_info *);
	void remove_def (def_info *);

	void need_use_splay_tree (set_info *);

	static void insert_use_before (use_info , use_info );
	static void insert_use_after (use_info , use_info );

	void add_use (use_info *);
	void remove_use (use_info *);

	insn_info::order_node need_order_node (insn_info );

	void add_insn_after (insn_info , insn_info );
	void append_insn (insn_info *);
	void remove_insn (insn_info *);

	insn_info append_artificial_insn (bb_info , rtx_insn * = nullptr);

	void start_insn_accesses ();
	void finish_insn_accesses (insn_info *);

	use_info create_reg_use (build_info &, insn_info , resource_info);
	void record_use (build_info &, insn_info *, rtx_obj_reference);
	void record_call_clobbers (build_info &, insn_info , rtx_call_insn );
	void record_def (build_info &, insn_info *, rtx_obj_reference);
	void add_insn_to_block (build_info &, rtx_insn *);

	void add_reg_unused_notes (insn_info *);

	void add_live_out_use (bb_info , set_info );
	set_info live_out_value (bb_info , set_info *);

	void append_phi (ebb_info , phi_info );
	void remove_phi (phi_info *);
	void delete_phi (phi_info *);
	void replace_phi (phi_info , set_info );
	phi_info create_phi (ebb_info , resource_info, access_info **,
	unsigned int);
	phi_info create_degenerate_phi (ebb_info , set_info *);

	bb_info *create_bb_info (basic_block);
	void append_bb (bb_info *);

	insn_info add_placeholder_after (insn_info );
	void possibly_queue_changes (insn_change &);
	void finalize_new_accesses (insn_change &);
	void apply_changes_to_insn (insn_change &);

	void init_function_data ();
	void calculate_potential_phi_regs (build_info &);
	void place_phis (build_info &);
	void create_ebbs (build_info &);
	void add_entry_block_defs (build_info &);
	void calculate_ebb_live_in_for_debug (build_info &);
	void add_phi_nodes (build_info &);
	void add_artificial_accesses (build_info &, df_ref_flags);
	void add_block_contents (build_info &);
	void record_block_live_out (build_info &);
	void start_block (build_info &, bb_info *);
	void end_block (build_info &, bb_info *);
	void populate_phi_inputs (build_info &);
	void process_all_blocks ();

	void simplify_phi_setup (phi_info , set_info *, bitmap);
	void simplify_phi_propagate (phi_info , set_info *, bitmap, bitmap);
	void simplify_phis ();

	// The function that this object describes.
	function *m_fn;

	// The lowest (negative) in-use artificial insn uid minus one.
	int m_next_artificial_uid;

	// The highest in-use phi uid plus one.
	unsigned int m_next_phi_uid;

	// The highest in-use register number plus one.
	unsigned int m_num_regs;

	// M_DEFS[R] is the first definition of register R - 1 in a reverse
	// postorder traversal of the function, or null if the function has
	// no definition of R. Applying last () gives the last definition of R.
	//
	// M_DEFS[0] is for memory; MEM_REGNO + 1 == 0.
	auto_vec<def_info *> m_defs;

	// M_BBS[BI] gives the SSA information about the block with index BI.
	auto_vec<bb_info *> m_bbs;

	// An obstack used to allocate the main RTL SSA information.
	obstack m_obstack;

	// An obstack used for temporary work, such as while building up a list
	// of possible instruction changes.
	obstack m_temp_obstack;

	// The start of each obstack, so that all memory in them can be freed.
	char *m_obstack_start;
	char *m_temp_obstack_start;

	// The entry and exit blocks.
	bb_info *m_first_bb;
	bb_info *m_last_bb;

	// The first and last instructions in a reverse postorder traversal
	// of the function.
	insn_info *m_first_insn;
	insn_info *m_last_insn;

	// The last nondebug instruction in the list of instructions.
	// This is only different from m_last_insn when building the initial
	// SSA information; after that, the last instruction is always a
	// BB end instruction.
	insn_info *m_last_nondebug_insn;

	// Temporary working state when building up lists of definitions and uses.
	// Keeping them around should reduce the number of unnecessary reallocations.
	auto_vec<access_info *> m_temp_defs;
	auto_vec<access_info *> m_temp_uses;

	// A list of phis that are no longer in use. Their uids are still unique
	// and so can be recycled.
	phi_info *m_free_phis;

	// A list of instructions that have been changed in ways that need
	// further processing later, such as removing dead instructions or
	// altering the CFG.
	auto_vec<insn_info *> m_queued_insn_updates;

	// The INSN_UIDs of all instructions in M_QUEUED_INSN_UPDATES.
	auto_bitmap m_queued_insn_update_uids;

	// A basic_block is in this bitmap if we need to call purge_dead_edges
	// on it. As with M_QUEUED_INSN_UPDATES, these updates are queued until
	// a convenient point.
	auto_bitmap m_need_to_purge_dead_edges;
	};

	void pp_function (pretty_printer , const function_info );
	}

	void dump (FILE , const rtl_ssa::function_info );

	void DEBUG_FUNCTION debug (const rtl_ssa::function_info *);