gcc/rtl-ssa/internals.inl - gcc - Git at Google

 // Implementation of private inline member functions for RTL SSA    -*- 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 {

 // Construct a new access with the given resource () and kind () values.
 inline access_info::access_info (resource_info resource, access_kind kind)
   : m_regno (resource.regno),
     m_kind (kind),
     m_is_artificial (false),
     m_is_set_with_nondebug_insn_uses (false),
     m_is_pre_post_modify (false),
     m_is_call_clobber (false),
     m_is_live_out_use (false),
     m_includes_address_uses (false),
     m_includes_read_writes (false),
     m_includes_subregs (false),
     m_includes_multiregs (false),
     m_only_occurs_in_notes (false),
     m_is_last_nondebug_insn_use (false),
     m_is_in_debug_insn_or_phi (false),
     m_has_been_superceded (false),
     m_is_temp (false),
     m_spare (0),
     m_mode (resource.mode)
 {
 }

 // Construct a use of RESOURCE in LOCATION.  The resource's value is provided
 // by DEF, or is completely undefined if DEF is null.
 inline use_info::use_info (insn_or_phi location, resource_info resource,
 			   set_info *definition)
   : access_info (resource, access_kind::USE),
     m_insn_or_phi (location),
     m_last_use_or_prev_use (nullptr),
     m_last_nondebug_insn_use_or_next_use (nullptr),
     m_def (definition)
 {
   if (m_insn_or_phi.is_second ())
     {
       m_is_in_debug_insn_or_phi = true;
       m_is_artificial = true;
     }
   else
     {
       insn_info *insn = m_insn_or_phi.known_first ();
       m_is_in_debug_insn_or_phi = insn->is_debug_insn ();
       m_is_artificial = insn->is_artificial ();
     }
 }

 // Return the correct (uncached) value of m_is_last_nondebug_insn_use.
 inline bool
 use_info::calculate_is_last_nondebug_insn_use () const
 {
   use_info *next = next_use ();
   return is_in_nondebug_insn () && (!next || next->is_in_debug_insn_or_phi ());
 }

 // Accumulate any properties about REF that are also stored in use_infos.
 // IS_FIRST is true if REF is the first access to resource () that we have
 // recorded in this way, false if we have already recorded previous
 // references.
 inline void
 use_info::record_reference (rtx_obj_reference ref, bool is_first)
 {
   if (is_first)
     {
       m_includes_address_uses = ref.in_address ();
       m_includes_read_writes = ref.is_write ();
       m_includes_subregs = ref.in_subreg ();
       m_includes_multiregs = ref.is_multireg ();
       m_only_occurs_in_notes = ref.in_note ();
     }
   else
     {
       m_includes_address_uses |= ref.in_address ();
       m_includes_read_writes |= ref.is_write ();
       m_includes_subregs |= ref.in_subreg ();
       m_includes_multiregs |= ref.is_multireg ();
       m_only_occurs_in_notes &= ref.in_note ();
     }
 }

 // Change the value of insn () to INSN.
 inline void
 use_info::set_insn (insn_info *insn)
 {
   m_insn_or_phi = insn;
   m_is_artificial = insn->is_artificial ();
 }

 // Copy the overloaded prev link from OTHER.
 inline void
 use_info::copy_prev_from (use_info *other)
 {
   m_last_use_or_prev_use = other->m_last_use_or_prev_use;
 }

 // Copy the overloaded next link from OTHER.
 inline void
 use_info::copy_next_from (use_info *other)
 {
   m_last_nondebug_insn_use_or_next_use
     = other->m_last_nondebug_insn_use_or_next_use;
   m_is_last_nondebug_insn_use = calculate_is_last_nondebug_insn_use ();
 }

 // Record that this use is the first in the list and that the last use is LAST.
 inline void
 use_info::set_last_use (use_info *last_use)
 {
   m_last_use_or_prev_use.set_first (last_use);
 }

 // Record that this use is not the first in the list and that the previous
 // use is PREV.
 inline void
 use_info::set_prev_use (use_info *prev_use)
 {
   m_last_use_or_prev_use.set_second (prev_use);
 }

 // Record that this use is the last use in the list.  If USE is nonnull,
 // record that USE is the last use in the list by a nondebug instruction,
 // otherwise record that there are no uses by nondebug instructions
 // in the list.
 inline void
 use_info::set_last_nondebug_insn_use (use_info *use)
 {
   m_last_nondebug_insn_use_or_next_use.set_first (use);
   m_is_last_nondebug_insn_use = (use == this);
 }

 // Record that this use is not the last in the list and that the next
 // use is NEXT_USE.
 inline void
 use_info::set_next_use (use_info *next_use)
 {
   m_last_nondebug_insn_use_or_next_use.set_second (next_use);
   m_is_last_nondebug_insn_use = calculate_is_last_nondebug_insn_use ();
 }

 // Clear any information relating to the position of the use in its
 // definition's list.
 inline void
 use_info::clear_use_links ()
 {
   m_last_use_or_prev_use = nullptr;
   m_last_nondebug_insn_use_or_next_use = nullptr;
   m_is_last_nondebug_insn_use = false;
 }

 // Return true if the use has any links to other uses.  This is mostly
 // for assert checking.
 inline bool
 use_info::has_use_links ()
 {
   return (m_last_use_or_prev_use
 	  || m_last_nondebug_insn_use_or_next_use
 	  || m_is_last_nondebug_insn_use);
 }

 // Construct a definition of RESOURCE in INSN, giving it kind KIND.
 inline def_info::def_info (insn_info *insn, resource_info resource,
 			   access_kind kind)
   : access_info (resource, kind),
     m_insn (insn),
     m_last_def_or_prev_def (nullptr),
     m_splay_root_or_next_def (nullptr)
 {
   m_is_artificial = insn->is_artificial ();
 }

 // Record any properties about REF that are also stored in def_infos.
 // IS_FIRST is true if REF is the first access to resource () that we have
 // recorded in this way, false if we have already recorded previous
 // references.
 inline void
 def_info::record_reference (rtx_obj_reference ref, bool is_first)
 {
   if (is_first)
     {
       m_is_pre_post_modify = ref.is_pre_post_modify ();
       m_includes_read_writes = ref.is_read ();
       m_includes_subregs = ref.in_subreg ();
       m_includes_multiregs = ref.is_multireg ();
     }
   else
     {
       m_is_pre_post_modify |= ref.is_pre_post_modify ();
       m_includes_read_writes |= ref.is_read ();
       m_includes_subregs |= ref.in_subreg ();
       m_includes_multiregs |= ref.is_multireg ();
     }
 }

 // Return the last definition in the list.  Only valid when is_first ()
 // is true.
 inline def_info *
 def_info::last_def () const
 {
   return m_last_def_or_prev_def.known_first ();
 }

 // Return the root of the splay tree of definitions of resource (),
 // or null if no splay tree has been created for this resource.
 // Only valid when is_last () is true.
 inline def_node *
 def_info::splay_root () const
 {
   return m_splay_root_or_next_def.known_first ();
 }

 // Copy the overloaded prev link from OTHER.
 inline void
 def_info::copy_prev_from (def_info *other)
 {
   m_last_def_or_prev_def
     = other->m_last_def_or_prev_def;
 }

 // Copy the overloaded next link from OTHER.
 inline void
 def_info::copy_next_from (def_info *other)
 {
   m_splay_root_or_next_def = other->m_splay_root_or_next_def;
 }

 // Record that this definition is the first in the list and that the last
 // definition is LAST.
 inline void
 def_info::set_last_def (def_info *last_def)
 {
   m_last_def_or_prev_def.set_first (last_def);
 }

 // Record that this definition is not the first in the list and that the
 // previous definition is PREV.
 inline void
 def_info::set_prev_def (def_info *prev_def)
 {
   m_last_def_or_prev_def.set_second (prev_def);
 }

 // Record that this definition is the last in the list and that the root
 // of the splay tree associated with resource () is ROOT.
 inline void
 def_info::set_splay_root (def_node *root)
 {
   m_splay_root_or_next_def = root;
 }

 // Record that this definition is not the last in the list and that the
 // next definition is NEXT.
 inline void
 def_info::set_next_def (def_info *next_def)
 {
   m_splay_root_or_next_def = next_def;
 }

 // Clear the prev and next links
 inline void
 def_info::clear_def_links ()
 {
   m_last_def_or_prev_def = nullptr;
   m_splay_root_or_next_def = nullptr;
 }

 // Return true if the definition has any links to other definitions.
 // This is mostly for assert checking.
 inline bool
 def_info::has_def_links ()
 {
   return m_last_def_or_prev_def || m_splay_root_or_next_def;
 }

 // Construct a clobber of register REGNO in insn INSN.
 inline clobber_info::clobber_info (insn_info *insn, unsigned int regno)
   : def_info (insn, { E_BLKmode, regno }, access_kind::CLOBBER),
     m_children (),
     m_parent (nullptr),
     m_group (nullptr)
 {
 }

 // Set the containing group to GROUP, if it isn't already.  The main
 // use of this function is to update the new root of GROUP's splay tree.
 inline void
 clobber_info::update_group (clobber_group *group)
 {
   if (__builtin_expect (m_group != group, 0))
     m_group = group;
 }

 // Cconstruct a set_info for a store to RESOURCE in INSN, giving it
 // kind KIND.
 inline set_info::set_info (insn_info *insn, resource_info resource,
 			   access_kind kind)
   : def_info (insn, resource, kind),
     m_first_use (nullptr)
 {
 }

 // Cconstruct a set_info for a store to RESOURCE in INSN.
 inline set_info::set_info (insn_info *insn, resource_info resource)
   : set_info (insn, resource, access_kind::SET)
 {
 }

 // Record that USE is the first use of this definition.
 inline void
 set_info::set_first_use (use_info *first_use)
 {
   m_first_use = first_use;
   m_is_set_with_nondebug_insn_uses
     = (first_use && first_use->is_in_nondebug_insn ());
 }

 // Construct a phi for RESOURCE in INSN, giving it identifier UID.
 inline phi_info::phi_info (insn_info *insn, resource_info resource,
 			   unsigned int uid)
   : set_info (insn, resource, access_kind::PHI),
     m_uid (uid),
     m_num_inputs (0),
     m_prev_phi (nullptr),
     m_next_phi (nullptr)
 {
 }

 // Turn the phi into a degenerate phi, with INPUT representing the
 // value of the resource on all incoming edges.
 inline void
 phi_info::make_degenerate (use_info *input)
 {
   m_num_inputs = 1;
   m_single_input = input;
 }

 // Set the inputs of the phi to INPUTS.
 inline void
 phi_info::set_inputs (use_array inputs)
 {
   m_num_inputs = inputs.size ();
   if (inputs.size () == 1)
     m_single_input = inputs[0];
   else
     m_inputs = access_array (inputs).begin ();
 }

 // Construct a definition splay tree node for FIRST_DEF, which is either
 // the first clobber_info in a group or a standalone set_info.
 inline def_node::def_node (clobber_or_set first_def)
   : m_clobber_or_set (first_def),
     m_children ()
 {
 }

 // Construct a new group of clobber_infos that initially contains just CLOBBER.
 inline clobber_group::clobber_group (clobber_info *clobber)
   : def_node (clobber),
     m_last_clobber (clobber),
     m_clobber_tree (clobber)
 {
   clobber->m_group = this;
 }

 // Construct a node for the instruction with uid UID.
 inline insn_info::order_node::order_node (int uid)
   : insn_note (kind),
     m_children (),
     m_parent (nullptr)
 {
   m_data32 = uid;
 }

 // Construct a note for instruction INSN, giving it abi_id () value ABI_ID.
 inline insn_call_clobbers_note::insn_call_clobbers_note (unsigned int abi_id,
 							 insn_info *insn)
   : insn_note (kind),
     m_children (),
     m_insn (insn)
 {
   m_data32 = abi_id;
 }

 // Construct an instruction with the given bb () and rtl () values.
 // If the instruction is real, COST_OR_UID is the value of cost (),
 // otherwise it is the value of uid ().
 inline insn_info::insn_info (bb_info *bb, rtx_insn *rtl, int cost_or_uid)
   : m_prev_insn_or_last_debug_insn (nullptr),
     m_next_nondebug_or_debug_insn (nullptr),
     m_bb (bb),
     m_rtl (rtl),
     m_accesses (nullptr),
     m_num_uses (0),
     m_num_defs (0),
     m_is_debug_insn (rtl && DEBUG_INSN_P (rtl)),
     m_can_be_optimized (false),
     m_is_asm (false),
     m_has_pre_post_modify (false),
     m_has_volatile_refs (false),
     m_spare (0),
     m_point (0),
     m_cost_or_uid (cost_or_uid),
     m_first_note (nullptr)
 {
 }

 // Copy any insn properties from PROPERTIES that are also stored in an
 // insn_info.
 inline void
 insn_info::set_properties (const rtx_properties &properties)
 {
   m_is_asm = properties.has_asm;
   m_has_pre_post_modify = properties.has_pre_post_modify;
   m_has_volatile_refs = properties.has_volatile_refs;
   // Not strictly related to the properties we've been given, but it's
   // a convenient location to do this.
   m_can_be_optimized = (NONDEBUG_INSN_P (m_rtl)
 			& (GET_CODE (PATTERN (m_rtl)) != USE)
 			& (GET_CODE (PATTERN (m_rtl)) != CLOBBER));
 }

 // Change the list of instruction accesses to ACCESSES, which contains
 // NUM_DEFS definitions followed by NUM_USES uses.
 inline void
 insn_info::set_accesses (access_info **accesses,
 			 unsigned int num_defs, unsigned int num_uses)
 {
   m_accesses = accesses;
   m_num_defs = num_defs;
   gcc_assert (num_defs == m_num_defs);
   m_num_uses = num_uses;
 }

 // Change defs () and uses () to DEFS and USES respectively, given that
 // the existing m_accesses array has enough room for them.
 inline void
 insn_info::copy_accesses (access_array defs, access_array uses)
 {
   gcc_assert (defs.size () + uses.size () <= m_num_defs + m_num_uses);
   memcpy (m_accesses, defs.begin (), defs.size_bytes ());
   memcpy (m_accesses + defs.size (), uses.begin (), uses.size_bytes ());
   m_num_defs = defs.size ();
   gcc_assert (m_num_defs == defs.size ());
   m_num_uses = uses.size ();
 }

 // If the instruction has an insn_info::order_node, return the node,
 // otherwise return null.
 inline insn_info::order_node *
 insn_info::get_order_node () const
 {
   // The order_node always comes first.
   if (insn_note *note = first_note ())
     return note->dyn_cast<insn_info::order_node *> ();
   return nullptr;
 }

 // Like get_order_node (), but the node is known to exist.
 inline insn_info::order_node *
 insn_info::get_known_order_node () const
 {
   // The order_node always comes first.
   return first_note ()->as_a<insn_info::order_node *> ();
 }

 // Copy the overloaded prev link from OTHER.
 inline void
 insn_info::copy_prev_from (insn_info *other)
 {
   m_prev_insn_or_last_debug_insn = other->m_prev_insn_or_last_debug_insn;
 }

 // Copy the overloaded next link from OTHER.
 inline void
 insn_info::copy_next_from (insn_info *other)
 {
   m_next_nondebug_or_debug_insn = other->m_next_nondebug_or_debug_insn;
 }

 // If this is a nondebug instruction, record that the previous nondebug
 // instruction is PREV.  (There might be intervening debug instructions.)
 //
 // If this is a debug instruction, record that the previous instruction
 // is debug instruction PREV.
 inline void
 insn_info::set_prev_sametype_insn (insn_info *prev)
 {
   m_prev_insn_or_last_debug_insn.set_first (prev);
 }

 // Only valid for debug instructions.  Record that this instruction starts
 // a subsequence of debug instructions that ends with LAST.
 inline void
 insn_info::set_last_debug_insn (insn_info *last)
 {
   m_prev_insn_or_last_debug_insn.set_second (last);
 }

 // Record that the next instruction of any kind is NEXT.
 inline void
 insn_info::set_next_any_insn (insn_info *next)
 {
   if (next && next->is_debug_insn ())
     m_next_nondebug_or_debug_insn.set_second (next);
   else
     m_next_nondebug_or_debug_insn.set_first (next);
 }

 // Clear the list links and point number for this instruction.
 inline void
 insn_info::clear_insn_links ()
 {
   m_prev_insn_or_last_debug_insn = nullptr;
   m_next_nondebug_or_debug_insn = nullptr;
   m_point = 0;
 }

 // Return true if the instruction contains any list information.
 // This is used by assert checking.
 inline bool
 insn_info::has_insn_links ()
 {
   return (m_prev_insn_or_last_debug_insn
 	  || m_next_nondebug_or_debug_insn
 	  || m_point);
 }

 // Construct a representation of basic block CFG_BB.
 inline bb_info::bb_info (basic_block cfg_bb)
   : m_prev_bb (nullptr),
     m_next_bb (nullptr),
     m_cfg_bb (cfg_bb),
     m_ebb (nullptr),
     m_head_insn (nullptr),
     m_end_insn (nullptr)
 {
 }

 // Construct a tree of call clobbers for the given ABI.
 inline ebb_call_clobbers_info::
 ebb_call_clobbers_info (const predefined_function_abi *abi)
   : m_next (nullptr),
     m_abi (abi)
 {
 }

 // Construct an EBB whose first block is FIRST_BB and whose last block
 // is LAST_BB.
 inline ebb_info::ebb_info (bb_info *first_bb, bb_info *last_bb)
   : m_first_phi (nullptr),
     m_phi_insn (nullptr),
     m_first_bb (first_bb),
     m_last_bb (last_bb),
     m_first_call_clobbers (nullptr)
 {
 }

 // Record register definition DEF in last_access, pushing a definition
 // to def_stack where appropriate.
 inline void
 function_info::build_info::record_reg_def (def_info *def)
 {
   unsigned int regno = def->regno ();
   auto *prev_dominating_def = safe_as_a<def_info *> (last_access[regno + 1]);
   if (!prev_dominating_def)
     // Indicate that DEF is the first dominating definition of REGNO.
     def_stack.safe_push (def);
   else if (prev_dominating_def->bb () != def->bb ())
     // Record that PREV_DOMINATING_DEF was the dominating definition
     // of REGNO on entry to the current block.
     def_stack.safe_push (prev_dominating_def);
   last_access[regno + 1] = def;
 }

 // Set the contents of last_access for memory to DEF.
 inline void
 function_info::build_info::record_mem_def (def_info *def)
 {
   last_access[0] = def;
 }

 // Return the current value of live register REGNO, or null if the register's
 // value is completedly undefined.
 inline set_info *
 function_info::build_info::current_reg_value (unsigned int regno) const
 {
   return safe_dyn_cast<set_info *> (last_access[regno + 1]);
 }

 // Return the current value of memory.
 inline set_info *
 function_info::build_info::current_mem_value () const
 {
   return as_a<set_info *> (last_access[0]);
 }

 // Allocate a T on the function's main obstack, passing ARGS
 // to its constructor.
 template<typename T, typename... Ts>
 inline T *
 function_info::allocate (Ts... args)
 {
   static_assert (std::is_trivially_destructible<T>::value,
 		 "destructor won't be called");
   static_assert (alignof (T) <= obstack_alignment,
 		 "too much alignment required");
   void *addr = obstack_alloc (&m_obstack, sizeof (T));
   return new (addr) T (std::forward<Ts> (args)...);
 }

 // Allocate a T on the function's temporary obstack, passing ARGS
 // to its constructor.
 template<typename T, typename... Ts>
 inline T *
 function_info::allocate_temp (Ts... args)
 {
   static_assert (std::is_trivially_destructible<T>::value,
 		 "destructor won't be called");
   static_assert (alignof (T) <= obstack_alignment,
 		 "too much alignment required");
   void *addr = obstack_alloc (&m_temp_obstack, sizeof (T));
   return new (addr) T (std::forward<Ts> (args)...);
 }

 // Add INSN to the end of the function's list of instructions.
 inline void
 function_info::append_insn (insn_info *insn)
 {
   gcc_checking_assert (!insn->has_insn_links ());
   if (insn_info *after = m_last_insn)
     add_insn_after (insn, after);
   else
     // The first instruction is for the entry block and is always a nondebug
     // insn
     m_first_insn = m_last_insn = m_last_nondebug_insn = insn;
 }

 // Start building a new list of uses and definitions for an instruction.
 inline void
 function_info::start_insn_accesses ()
 {
   gcc_checking_assert (m_temp_defs.is_empty ()
 		       && m_temp_uses.is_empty ());
 }

 // Return a mode that encapsulates two distinct references to a register,
 // one with mode MODE1 and one with mode MODE2.  Treat BLKmode as a
 // "don't know" wildcard.
 inline machine_mode
 combine_modes (machine_mode mode1, machine_mode mode2)
 {
   if (mode1 == E_BLKmode)
     return mode2;

   if (mode2 == E_BLKmode)
     return mode1;

   return wider_subreg_mode (mode1, mode2);
 }

 // PRINTER (PP, ARGS...) prints ARGS... to a pretty_printer PP.  Use it
 // to print ARGS... to FILE.
 template<typename Printer, typename... Args>
 inline void
 dump_using (FILE *file, Printer printer, Args... args)
 {
   pretty_printer pp;
   printer (&pp, args...);
   pp_newline (&pp);
   fprintf (file, "%s", pp_formatted_text (&pp));
 }

 }
	// Implementation of private inline member functions for RTL SSA -- 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 {

	// Construct a new access with the given resource () and kind () values.
	inline access_info::access_info (resource_info resource, access_kind kind)
	: m_regno (resource.regno),
	m_kind (kind),
	m_is_artificial (false),
	m_is_set_with_nondebug_insn_uses (false),
	m_is_pre_post_modify (false),
	m_is_call_clobber (false),
	m_is_live_out_use (false),
	m_includes_address_uses (false),
	m_includes_read_writes (false),
	m_includes_subregs (false),
	m_includes_multiregs (false),
	m_only_occurs_in_notes (false),
	m_is_last_nondebug_insn_use (false),
	m_is_in_debug_insn_or_phi (false),
	m_has_been_superceded (false),
	m_is_temp (false),
	m_spare (0),
	m_mode (resource.mode)
	{
	}

	// Construct a use of RESOURCE in LOCATION. The resource's value is provided
	// by DEF, or is completely undefined if DEF is null.
	inline use_info::use_info (insn_or_phi location, resource_info resource,
	set_info *definition)
	: access_info (resource, access_kind::USE),
	m_insn_or_phi (location),
	m_last_use_or_prev_use (nullptr),
	m_last_nondebug_insn_use_or_next_use (nullptr),
	m_def (definition)
	{
	if (m_insn_or_phi.is_second ())
	{
	m_is_in_debug_insn_or_phi = true;
	m_is_artificial = true;
	}
	else
	{
	insn_info *insn = m_insn_or_phi.known_first ();
	m_is_in_debug_insn_or_phi = insn->is_debug_insn ();
	m_is_artificial = insn->is_artificial ();
	}
	}

	// Return the correct (uncached) value of m_is_last_nondebug_insn_use.
	inline bool
	use_info::calculate_is_last_nondebug_insn_use () const
	{
	use_info *next = next_use ();
	return is_in_nondebug_insn () && (!next \|\| next->is_in_debug_insn_or_phi ());
	}

	// Accumulate any properties about REF that are also stored in use_infos.
	// IS_FIRST is true if REF is the first access to resource () that we have
	// recorded in this way, false if we have already recorded previous
	// references.
	inline void
	use_info::record_reference (rtx_obj_reference ref, bool is_first)
	{
	if (is_first)
	{
	m_includes_address_uses = ref.in_address ();
	m_includes_read_writes = ref.is_write ();
	m_includes_subregs = ref.in_subreg ();
	m_includes_multiregs = ref.is_multireg ();
	m_only_occurs_in_notes = ref.in_note ();
	}
	else
	{
	m_includes_address_uses \|= ref.in_address ();
	m_includes_read_writes \|= ref.is_write ();
	m_includes_subregs \|= ref.in_subreg ();
	m_includes_multiregs \|= ref.is_multireg ();
	m_only_occurs_in_notes &= ref.in_note ();
	}
	}

	// Change the value of insn () to INSN.
	inline void
	use_info::set_insn (insn_info *insn)
	{
	m_insn_or_phi = insn;
	m_is_artificial = insn->is_artificial ();
	}

	// Copy the overloaded prev link from OTHER.
	inline void
	use_info::copy_prev_from (use_info *other)
	{
	m_last_use_or_prev_use = other->m_last_use_or_prev_use;
	}

	// Copy the overloaded next link from OTHER.
	inline void
	use_info::copy_next_from (use_info *other)
	{
	m_last_nondebug_insn_use_or_next_use
	= other->m_last_nondebug_insn_use_or_next_use;
	m_is_last_nondebug_insn_use = calculate_is_last_nondebug_insn_use ();
	}

	// Record that this use is the first in the list and that the last use is LAST.
	inline void
	use_info::set_last_use (use_info *last_use)
	{
	m_last_use_or_prev_use.set_first (last_use);
	}

	// Record that this use is not the first in the list and that the previous
	// use is PREV.
	inline void
	use_info::set_prev_use (use_info *prev_use)
	{
	m_last_use_or_prev_use.set_second (prev_use);
	}

	// Record that this use is the last use in the list. If USE is nonnull,
	// record that USE is the last use in the list by a nondebug instruction,
	// otherwise record that there are no uses by nondebug instructions
	// in the list.
	inline void
	use_info::set_last_nondebug_insn_use (use_info *use)
	{
	m_last_nondebug_insn_use_or_next_use.set_first (use);
	m_is_last_nondebug_insn_use = (use == this);
	}

	// Record that this use is not the last in the list and that the next
	// use is NEXT_USE.
	inline void
	use_info::set_next_use (use_info *next_use)
	{
	m_last_nondebug_insn_use_or_next_use.set_second (next_use);
	m_is_last_nondebug_insn_use = calculate_is_last_nondebug_insn_use ();
	}

	// Clear any information relating to the position of the use in its
	// definition's list.
	inline void
	use_info::clear_use_links ()
	{
	m_last_use_or_prev_use = nullptr;
	m_last_nondebug_insn_use_or_next_use = nullptr;
	m_is_last_nondebug_insn_use = false;
	}

	// Return true if the use has any links to other uses. This is mostly
	// for assert checking.
	inline bool
	use_info::has_use_links ()
	{
	return (m_last_use_or_prev_use
	\|\| m_last_nondebug_insn_use_or_next_use
	\|\| m_is_last_nondebug_insn_use);
	}

	// Construct a definition of RESOURCE in INSN, giving it kind KIND.
	inline def_info::def_info (insn_info *insn, resource_info resource,
	access_kind kind)
	: access_info (resource, kind),
	m_insn (insn),
	m_last_def_or_prev_def (nullptr),
	m_splay_root_or_next_def (nullptr)
	{
	m_is_artificial = insn->is_artificial ();
	}

	// Record any properties about REF that are also stored in def_infos.
	// IS_FIRST is true if REF is the first access to resource () that we have
	// recorded in this way, false if we have already recorded previous
	// references.
	inline void
	def_info::record_reference (rtx_obj_reference ref, bool is_first)
	{
	if (is_first)
	{
	m_is_pre_post_modify = ref.is_pre_post_modify ();
	m_includes_read_writes = ref.is_read ();
	m_includes_subregs = ref.in_subreg ();
	m_includes_multiregs = ref.is_multireg ();
	}
	else
	{
	m_is_pre_post_modify \|= ref.is_pre_post_modify ();
	m_includes_read_writes \|= ref.is_read ();
	m_includes_subregs \|= ref.in_subreg ();
	m_includes_multiregs \|= ref.is_multireg ();
	}
	}

	// Return the last definition in the list. Only valid when is_first ()
	// is true.
	inline def_info *
	def_info::last_def () const
	{
	return m_last_def_or_prev_def.known_first ();
	}

	// Return the root of the splay tree of definitions of resource (),
	// or null if no splay tree has been created for this resource.
	// Only valid when is_last () is true.
	inline def_node *
	def_info::splay_root () const
	{
	return m_splay_root_or_next_def.known_first ();
	}

	// Copy the overloaded prev link from OTHER.
	inline void
	def_info::copy_prev_from (def_info *other)
	{
	m_last_def_or_prev_def
	= other->m_last_def_or_prev_def;
	}

	// Copy the overloaded next link from OTHER.
	inline void
	def_info::copy_next_from (def_info *other)
	{
	m_splay_root_or_next_def = other->m_splay_root_or_next_def;
	}

	// Record that this definition is the first in the list and that the last
	// definition is LAST.
	inline void
	def_info::set_last_def (def_info *last_def)
	{
	m_last_def_or_prev_def.set_first (last_def);
	}

	// Record that this definition is not the first in the list and that the
	// previous definition is PREV.
	inline void
	def_info::set_prev_def (def_info *prev_def)
	{
	m_last_def_or_prev_def.set_second (prev_def);
	}

	// Record that this definition is the last in the list and that the root
	// of the splay tree associated with resource () is ROOT.
	inline void
	def_info::set_splay_root (def_node *root)
	{
	m_splay_root_or_next_def = root;
	}

	// Record that this definition is not the last in the list and that the
	// next definition is NEXT.
	inline void
	def_info::set_next_def (def_info *next_def)
	{
	m_splay_root_or_next_def = next_def;
	}

	// Clear the prev and next links
	inline void
	def_info::clear_def_links ()
	{
	m_last_def_or_prev_def = nullptr;
	m_splay_root_or_next_def = nullptr;
	}

	// Return true if the definition has any links to other definitions.
	// This is mostly for assert checking.
	inline bool
	def_info::has_def_links ()
	{
	return m_last_def_or_prev_def \|\| m_splay_root_or_next_def;
	}

	// Construct a clobber of register REGNO in insn INSN.
	inline clobber_info::clobber_info (insn_info *insn, unsigned int regno)
	: def_info (insn, { E_BLKmode, regno }, access_kind::CLOBBER),
	m_children (),
	m_parent (nullptr),
	m_group (nullptr)
	{
	}

	// Set the containing group to GROUP, if it isn't already. The main
	// use of this function is to update the new root of GROUP's splay tree.
	inline void
	clobber_info::update_group (clobber_group *group)
	{
	if (__builtin_expect (m_group != group, 0))
	m_group = group;
	}

	// Cconstruct a set_info for a store to RESOURCE in INSN, giving it
	// kind KIND.
	inline set_info::set_info (insn_info *insn, resource_info resource,
	access_kind kind)
	: def_info (insn, resource, kind),
	m_first_use (nullptr)
	{
	}

	// Cconstruct a set_info for a store to RESOURCE in INSN.
	inline set_info::set_info (insn_info *insn, resource_info resource)
	: set_info (insn, resource, access_kind::SET)
	{
	}

	// Record that USE is the first use of this definition.
	inline void
	set_info::set_first_use (use_info *first_use)
	{
	m_first_use = first_use;
	m_is_set_with_nondebug_insn_uses
	= (first_use && first_use->is_in_nondebug_insn ());
	}

	// Construct a phi for RESOURCE in INSN, giving it identifier UID.
	inline phi_info::phi_info (insn_info *insn, resource_info resource,
	unsigned int uid)
	: set_info (insn, resource, access_kind::PHI),
	m_uid (uid),
	m_num_inputs (0),
	m_prev_phi (nullptr),
	m_next_phi (nullptr)
	{
	}

	// Turn the phi into a degenerate phi, with INPUT representing the
	// value of the resource on all incoming edges.
	inline void
	phi_info::make_degenerate (use_info *input)
	{
	m_num_inputs = 1;
	m_single_input = input;
	}

	// Set the inputs of the phi to INPUTS.
	inline void
	phi_info::set_inputs (use_array inputs)
	{
	m_num_inputs = inputs.size ();
	if (inputs.size () == 1)
	m_single_input = inputs[0];
	else
	m_inputs = access_array (inputs).begin ();
	}

	// Construct a definition splay tree node for FIRST_DEF, which is either
	// the first clobber_info in a group or a standalone set_info.
	inline def_node::def_node (clobber_or_set first_def)
	: m_clobber_or_set (first_def),
	m_children ()
	{
	}

	// Construct a new group of clobber_infos that initially contains just CLOBBER.
	inline clobber_group::clobber_group (clobber_info *clobber)
	: def_node (clobber),
	m_last_clobber (clobber),
	m_clobber_tree (clobber)
	{
	clobber->m_group = this;
	}

	// Construct a node for the instruction with uid UID.
	inline insn_info::order_node::order_node (int uid)
	: insn_note (kind),
	m_children (),
	m_parent (nullptr)
	{
	m_data32 = uid;
	}

	// Construct a note for instruction INSN, giving it abi_id () value ABI_ID.
	inline insn_call_clobbers_note::insn_call_clobbers_note (unsigned int abi_id,
	insn_info *insn)
	: insn_note (kind),
	m_children (),
	m_insn (insn)
	{
	m_data32 = abi_id;
	}

	// Construct an instruction with the given bb () and rtl () values.
	// If the instruction is real, COST_OR_UID is the value of cost (),
	// otherwise it is the value of uid ().
	inline insn_info::insn_info (bb_info bb, rtx_insn rtl, int cost_or_uid)
	: m_prev_insn_or_last_debug_insn (nullptr),
	m_next_nondebug_or_debug_insn (nullptr),
	m_bb (bb),
	m_rtl (rtl),
	m_accesses (nullptr),
	m_num_uses (0),
	m_num_defs (0),
	m_is_debug_insn (rtl && DEBUG_INSN_P (rtl)),
	m_can_be_optimized (false),
	m_is_asm (false),
	m_has_pre_post_modify (false),
	m_has_volatile_refs (false),
	m_spare (0),
	m_point (0),
	m_cost_or_uid (cost_or_uid),
	m_first_note (nullptr)
	{
	}

	// Copy any insn properties from PROPERTIES that are also stored in an
	// insn_info.
	inline void
	insn_info::set_properties (const rtx_properties &properties)
	{
	m_is_asm = properties.has_asm;
	m_has_pre_post_modify = properties.has_pre_post_modify;
	m_has_volatile_refs = properties.has_volatile_refs;
	// Not strictly related to the properties we've been given, but it's
	// a convenient location to do this.
	m_can_be_optimized = (NONDEBUG_INSN_P (m_rtl)
	& (GET_CODE (PATTERN (m_rtl)) != USE)
	& (GET_CODE (PATTERN (m_rtl)) != CLOBBER));
	}

	// Change the list of instruction accesses to ACCESSES, which contains
	// NUM_DEFS definitions followed by NUM_USES uses.
	inline void
	insn_info::set_accesses (access_info **accesses,
	unsigned int num_defs, unsigned int num_uses)
	{
	m_accesses = accesses;
	m_num_defs = num_defs;
	gcc_assert (num_defs == m_num_defs);
	m_num_uses = num_uses;
	}

	// Change defs () and uses () to DEFS and USES respectively, given that
	// the existing m_accesses array has enough room for them.
	inline void
	insn_info::copy_accesses (access_array defs, access_array uses)
	{
	gcc_assert (defs.size () + uses.size () <= m_num_defs + m_num_uses);
	memcpy (m_accesses, defs.begin (), defs.size_bytes ());
	memcpy (m_accesses + defs.size (), uses.begin (), uses.size_bytes ());
	m_num_defs = defs.size ();
	gcc_assert (m_num_defs == defs.size ());
	m_num_uses = uses.size ();
	}

	// If the instruction has an insn_info::order_node, return the node,
	// otherwise return null.
	inline insn_info::order_node *
	insn_info::get_order_node () const
	{
	// The order_node always comes first.
	if (insn_note *note = first_note ())
	return note->dyn_cast<insn_info::order_node *> ();
	return nullptr;
	}

	// Like get_order_node (), but the node is known to exist.
	inline insn_info::order_node *
	insn_info::get_known_order_node () const
	{
	// The order_node always comes first.
	return first_note ()->as_a<insn_info::order_node *> ();
	}

	// Copy the overloaded prev link from OTHER.
	inline void
	insn_info::copy_prev_from (insn_info *other)
	{
	m_prev_insn_or_last_debug_insn = other->m_prev_insn_or_last_debug_insn;
	}

	// Copy the overloaded next link from OTHER.
	inline void
	insn_info::copy_next_from (insn_info *other)
	{
	m_next_nondebug_or_debug_insn = other->m_next_nondebug_or_debug_insn;
	}

	// If this is a nondebug instruction, record that the previous nondebug
	// instruction is PREV. (There might be intervening debug instructions.)
	//
	// If this is a debug instruction, record that the previous instruction
	// is debug instruction PREV.
	inline void
	insn_info::set_prev_sametype_insn (insn_info *prev)
	{
	m_prev_insn_or_last_debug_insn.set_first (prev);
	}

	// Only valid for debug instructions. Record that this instruction starts
	// a subsequence of debug instructions that ends with LAST.
	inline void
	insn_info::set_last_debug_insn (insn_info *last)
	{
	m_prev_insn_or_last_debug_insn.set_second (last);
	}

	// Record that the next instruction of any kind is NEXT.
	inline void
	insn_info::set_next_any_insn (insn_info *next)
	{
	if (next && next->is_debug_insn ())
	m_next_nondebug_or_debug_insn.set_second (next);
	else
	m_next_nondebug_or_debug_insn.set_first (next);
	}

	// Clear the list links and point number for this instruction.
	inline void
	insn_info::clear_insn_links ()
	{
	m_prev_insn_or_last_debug_insn = nullptr;
	m_next_nondebug_or_debug_insn = nullptr;
	m_point = 0;
	}

	// Return true if the instruction contains any list information.
	// This is used by assert checking.
	inline bool
	insn_info::has_insn_links ()
	{
	return (m_prev_insn_or_last_debug_insn
	\|\| m_next_nondebug_or_debug_insn
	\|\| m_point);
	}

	// Construct a representation of basic block CFG_BB.
	inline bb_info::bb_info (basic_block cfg_bb)
	: m_prev_bb (nullptr),
	m_next_bb (nullptr),
	m_cfg_bb (cfg_bb),
	m_ebb (nullptr),
	m_head_insn (nullptr),
	m_end_insn (nullptr)
	{
	}

	// Construct a tree of call clobbers for the given ABI.
	inline ebb_call_clobbers_info::
	ebb_call_clobbers_info (const predefined_function_abi *abi)
	: m_next (nullptr),
	m_abi (abi)
	{
	}

	// Construct an EBB whose first block is FIRST_BB and whose last block
	// is LAST_BB.
	inline ebb_info::ebb_info (bb_info first_bb, bb_info last_bb)
	: m_first_phi (nullptr),
	m_phi_insn (nullptr),
	m_first_bb (first_bb),
	m_last_bb (last_bb),
	m_first_call_clobbers (nullptr)
	{
	}

	// Record register definition DEF in last_access, pushing a definition
	// to def_stack where appropriate.
	inline void
	function_info::build_info::record_reg_def (def_info *def)
	{
	unsigned int regno = def->regno ();
	auto prev_dominating_def = safe_as_a<def_info > (last_access[regno + 1]);
	if (!prev_dominating_def)
	// Indicate that DEF is the first dominating definition of REGNO.
	def_stack.safe_push (def);
	else if (prev_dominating_def->bb () != def->bb ())
	// Record that PREV_DOMINATING_DEF was the dominating definition
	// of REGNO on entry to the current block.
	def_stack.safe_push (prev_dominating_def);
	last_access[regno + 1] = def;
	}

	// Set the contents of last_access for memory to DEF.
	inline void
	function_info::build_info::record_mem_def (def_info *def)
	{
	last_access[0] = def;
	}

	// Return the current value of live register REGNO, or null if the register's
	// value is completedly undefined.
	inline set_info *
	function_info::build_info::current_reg_value (unsigned int regno) const
	{
	return safe_dyn_cast<set_info *> (last_access[regno + 1]);
	}

	// Return the current value of memory.
	inline set_info *
	function_info::build_info::current_mem_value () const
	{
	return as_a<set_info *> (last_access[0]);
	}

	// Allocate a T on the function's main obstack, passing ARGS
	// to its constructor.
	template<typename T, typename... Ts>
	inline T *
	function_info::allocate (Ts... args)
	{
	static_assert (std::is_trivially_destructible<T>::value,
	"destructor won't be called");
	static_assert (alignof (T) <= obstack_alignment,
	"too much alignment required");
	void *addr = obstack_alloc (&m_obstack, sizeof (T));
	return new (addr) T (std::forward<Ts> (args)...);
	}

	// Allocate a T on the function's temporary obstack, passing ARGS
	// to its constructor.
	template<typename T, typename... Ts>
	inline T *
	function_info::allocate_temp (Ts... args)
	{
	static_assert (std::is_trivially_destructible<T>::value,
	"destructor won't be called");
	static_assert (alignof (T) <= obstack_alignment,
	"too much alignment required");
	void *addr = obstack_alloc (&m_temp_obstack, sizeof (T));
	return new (addr) T (std::forward<Ts> (args)...);
	}

	// Add INSN to the end of the function's list of instructions.
	inline void
	function_info::append_insn (insn_info *insn)
	{
	gcc_checking_assert (!insn->has_insn_links ());
	if (insn_info *after = m_last_insn)
	add_insn_after (insn, after);
	else
	// The first instruction is for the entry block and is always a nondebug
	// insn
	m_first_insn = m_last_insn = m_last_nondebug_insn = insn;
	}

	// Start building a new list of uses and definitions for an instruction.
	inline void
	function_info::start_insn_accesses ()
	{
	gcc_checking_assert (m_temp_defs.is_empty ()
	&& m_temp_uses.is_empty ());
	}

	// Return a mode that encapsulates two distinct references to a register,
	// one with mode MODE1 and one with mode MODE2. Treat BLKmode as a
	// "don't know" wildcard.
	inline machine_mode
	combine_modes (machine_mode mode1, machine_mode mode2)
	{
	if (mode1 == E_BLKmode)
	return mode2;

	if (mode2 == E_BLKmode)
	return mode1;

	return wider_subreg_mode (mode1, mode2);
	}

	// PRINTER (PP, ARGS...) prints ARGS... to a pretty_printer PP. Use it
	// to print ARGS... to FILE.
	template<typename Printer, typename... Args>
	inline void
	dump_using (FILE *file, Printer printer, Args... args)
	{
	pretty_printer pp;
	printer (&pp, args...);
	pp_newline (&pp);
	fprintf (file, "%s", pp_formatted_text (&pp));
	}

	}